METHODS AND COMPOSITIONS FOR CANCER TREATMENT RELATING TO BRCA1 BRCT DOMAIN RECOGNITION OF PHOSPHORYLATED BACH1

REFERENCE TO SEQUENCE LISTING

The Sequence Listing submitted Apr. 19, 2012, as a text file named “MIT_—10393J_DIV_CON_Sequence_Listing.txt,” created on Apr. 19, 2012, and having a size of 450,522 bytes is hereby incorporated by reference.

BACKGROUND OF THE INVENTION

The present invention relates to compounds (e.g., peptidomimetics) that inhibit cellular proliferation involving a protein having tandem BRCT domains and methods of treating proliferative disorders. Methods of designing and discovering such compounds are also provided. Applicants have discovered the three-dimensional structure of a BRCT domain-BACH1 phosphopeptide complex.

The breast-cancer susceptibility protein, BRCA1, plays important roles in cell cycle control, transcriptional regulation, chromatin remodelling, and the response to DNA-damage. BRCA1 is a large, modular protein of 1,863 amino-acid residues containing an N-terminal RING domain, a central region rich in SQ/TQ dipeptide pairs, and tandem BRCT (BRCA1 C-terminal) domains. BRCA1 interacts with a large number of protein partners at different stages of the cell cycle and following genotoxic stress. For example, BRCA1 interacts with the DNA helicase BACH1 during S and G2 in normally cycling cells, whereas BRCA1 interacts with a subset of ATM/ATR substrates in response to DNA damage. In both S-phase and irradiated/mutagen-treated cells, BRCA1 localizes to distinct nuclear foci thought to represent sites of DNA-damage where BRCA1 is thought to function, at least in part, as a scaffold for the assembly of DNA-repair complexes.

Mutations in BRCA1 occur in 50% of women with inherited breast cancer and up to 90% of women with combined breast and ovarian cancer. Most frameshift and deletion mutants truncate all or part of the BRCT repeats, while more than 70 missense mutations lie within the BRCT domains themselves. BRCT domains are α/β structures that occur singly or as multiple repeats in a number of proteins, in addition to BRCA1, that are involved in cell-cycle regulation and DNA-damage responses. Comprised of 80-100 amino acids, BRCT domains are generally thought to function as protein-protein recognition modules.

There exists a need to better understand the mechanism by which defects in the BRCA1 pathway mediate cancer and a need for therapies that may be provided to prevent or treat the resulting cancers. Specifically, there is a need to better understand the function that the BRCT domains of BRCA1 play in this process.

SUMMARY OF THE INVENTION

We recently discovered that a subset of tandem BRCT domains, including those of BRCA1, function as phosphoserine/phosphothreonine (pSer/pThr)-binding modules, indicating that some BRCT-mediated interactions with proteins involved in DNA-damage and cell-cycle control are regulated by protein phosphorylation. Oriented peptide library screening of tandem BRCT domains revealed phospho-dependent binding specificity extending from the pSer/pThr+1 to the pSer/pThr+5 position, with particularly strong selection for aromatic or aromatic/aliphatic residues in the pSer/pThr+3 position. High affinity phosphopeptides selected by in vitro oriented library screens were able to block the interaction of the tandem BRCT domains of BRCA1 and the transcriptional regulator PTIP with ATM/ATR-phosphorylated substrates. We concluded that the tumor-suppressor function of BRCA1 may directly depend on this interaction since its disruption is sufficient to abrogate the G2-M checkpoint following DNA damage.

To determine the structural basis for phosphopeptide binding and phosphopeptide-motif selection, and investigate alternative structural mechanisms underlying BRCA1 BRCT mutations and cancer predisposition, we solved the high resolution X-ray crystal structure of the BRCA1 tandem BRCT repeats bound to a BACH1 phosphopeptide. We now provide a molecular rationale for phosphospecific binding, and show that a set of cancer-associated BRCA1 BRCT mutations eliminates phosphopeptide binding in vitro and BACH1 phosphoprotein binding in vivo, or alter the phosphopeptide recognition motif for the BRCA1 tandem BRCT domains. Our findings reveal a structural basis for mutation-associated loss of BRCA1 function. This discovery has allowed us to design compounds for the treatment of proliferative diseases associated with BRCA1 and further methods for designing and identifying additional compounds.

Accordingly, in a first aspect, the invention features a computer that includes a processor in communication with a memory which has stored therein (a) at least one atomic coordinate, or a surrogate thereof, for all of the non-hydrogen atoms listed in Table 2 from each of a first group of residues that includes Ser1655, Gly1656, and Lys1702 of BRCA1 tandem BRCT domain complexed with a BACH1 phosphopeptide, or at least one atomic coordinate, or a surrogate thereof, for all of the non-hydrogen atoms listed in Table 2 from each of a second group of residues that includes Phe1704, Met1775, and Leu1839 of the tandem BRCT domain, or atomic coordinates that have a root mean square deviation of less than 3 Å from the coordinates of either the first or second groups of residues; and (b) a program for generating a three-dimensional model of the coordinates. In an embodiment, the memory has stored therein atomic coordinates for all of the non-hydrogen atoms, or surrogates thereof, of either the first or second group of residues, or atomic coordinates that have a root mean square deviation of less than 3 Å from the coordinates of either the first or second groups of residues.

In another aspect, the invention features a computer that includes a processor in communication with a memory that has stored therein a pharmacophore model of a compound that binds to a tandem BRCT domain and a program for displaying the model, where the model includes at least one of the following: (a) a phosphate group on a phosphorylated residue of the phosphopeptide that participates in at least one hydrogen-bonding interaction; and (b) a phenylalanine or tyrosine residue at the +3 position of the phosphopeptide, where the phenylalanine or tyrosine side chain is directed towards the surface of the tandem BRCT domain. In one embodiment, the tandem BRCT domain is a BRCA1 tandem BRCT domain. In another embodiment, the tandem BRCT domain is a PTIP tandem BRCT domain.

In another aspect, the invention features a computer that includes a processor in electrical communication with a memory that has stored therein a pharmacophore model of BRCA1 tandem BRCT domain ligands and a program for displaying the model which includes at least three of the following parameters:

(a) a hydrogen bond acceptor group that forms a hydrogen bond with the side chain hydroxyl group of Ser1655 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the hydroxyl group and the acceptor group is less than 4 Ångstroms;

(b) a hydrogen bond acceptor group that forms a hydrogen bond with the backbone amide group of Gly1656 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 4 Ångstroms;

(c) a hydrogen bond acceptor group that forms a hydrogen bond with the side chain amine group of Lys1702 of the BRCA1 tandem BRCT domain, where the distance between a hydrogen of the amine group and the acceptor group is less than 4 Ångstroms;

(d) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with the backbone amide group of Leu1657 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 6 Ångstroms;

(e) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with a second water molecule, where the second water molecule in turn forms a hydrogen bond with the backbone amide group of Leu1701 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 8 Ångstroms;

(f) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with a second water molecule, where the second water in turn forms a hydrogen bond with a third water molecule, where the third water molecule in turn forms a hydrogen bond with the backbone carbonyl group of Asn1774, where the distance between the oxygen of the carbonyl group and the acceptor group is less than 11 Ångstroms;

(g) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with a second water molecule, where the second water molecule in turn forms a hydrogen bond with a third water molecule, where the third water molecule in turn forms a hydrogen bond with a fourth water molecule, where the fourth water molecule in turn forms a hydrogen bond with the backbone amide group of Ile1680 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 10 Ångstroms;

(h) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with a second water molecule, where the second water molecule in turn forms a hydrogen bond with a third water molecule, where the third water molecule in turn forms a hydrogen bond with a fourth water molecule, where the fourth water molecule in turn forms a hydrogen bond with the side chain amide group of Gln1779 of the BRCA 1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 14 Ångstroms;

(i) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with the backbone amide group of Arg1699 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the amide group and the acceptor group is less than 7 Ångstroms;

(j) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with the side chain carboxyl group of Glu1698 of the BRCA1 tandem BRCT domain, where the distance between an oxygen of the carboxyl group and the acceptor group is less than 6 Ångstroms;

(k) a hydrogen bond acceptor group that forms a hydrogen bond with the side chain guanidinium group of Arg1699 of the BRCA1 tandem BRCT domain, where the distance between a hydrogen of the side guanidinium group and the acceptor group is less than 4 Ångstroms;

(l) a hydrogen bond donor group that forms a hydrogen bond with the side chain carbonyl group of Arg1699 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the donor group and the carbonyl oxygen is less than 4 Ångstroms;

(m) a hydrophobic group that is less than 5 Ångstroms away from an atom of Phe1704, Met1775, or Leu1839 of the BRCA1 tandem BRCT domain.

(n) a hydrogen bond acceptor group that forms a hydrogen bond with a water molecule, where the water molecule in turn forms a hydrogen bond with the side chain carboxyl group of Glu1836 of the BRCA1 tandem BRCT domain, where the distance between an oxygen of the carboxyl group and the acceptor group is less than 6 Ångstroms; or

(o) a hydrogen bond donor group that forms a hydrogen bond with the side chain carboxyl group of Asp1840 of the BRCA1 tandem BRCT domain, where the distance between the hydrogen of the donor group and a carboxyl oxygen is less than 4 Ångstroms.

In another aspect, the invention features a method of producing a structure for a candidate compound for a BRCA1 tandem BRCT domain that includes the steps of:

(a) providing a three-dimensional structure of the tandem BRCT domain having at least one atomic coordinate, or a surrogate thereof, for all of the non-hydrogen atoms listed in Table 2 from each of a first group of residues that includes Ser1655, Gly1656, and Lys1702 of BRCA1 tandem BRCT domain complexed with a BACH1 phosphopeptide, or at least one atomic coordinate, or a surrogate thereof, for all of the non-hydrogen atoms listed in Table 2 from each of a second group of residues that includes Phe1704, Met1775, and Leu1839 of the tandem BRCT domain, or atomic coordinates that have a root mean square deviation of less than 3 Å from the coordinates of either the first or second groups of residues; and

(b) producing a structure for a candidate compound where the structure defines a molecule having sufficient surface complementary to the tandem BRCT domain structure to bind the tandem BRCT domain in an aqueous solution.

In one embodiment, the memory has stored therein atomic coordinates for all of the non-hydrogen atoms, or surrogates thereof, of either the first or second group of residues, or atomic coordinates that have a root mean square deviation of less than 3 Å from the coordinates of either the first or second groups of residues.

In another embodiment, the candidate compound is a peptidomimetic compound. Desirable examples of peptidomimetic compounds include those that include a phosphate moiety or a phosphonate moiety. In another embodiment, the compound binds a tandem BRCT domain.

In another aspect, the invention features a compound having a structure produced by a method that includes the steps of:

In an embodiment, the memory has stored therein atomic coordinates for all of the non-hydrogen atoms, or surrogates thereof, of either the first or second group of residues, or atomic coordinates that have a root mean square deviation of less than 3 Å from the coordinates of either the first or second groups of residues.

In another aspect, the invention features a crystal of a complex comprising a tandem BRCT domain bound to a phosphopeptide. In one embodiment, the tandem BRCT domain is a PTIP tandem BRCT domain. In another embodiment, the phosphopeptide includes the amino acid sequence [pSer/pThr]-X-X-[Phe/Tyr] (SEQ ID NO.: 42). In one example, the +1 position of the phosphopeptide can be proline. In another example the phosphopeptide includes the amino acid sequence Ser-Arg-Ser-Thr-pSer-Pro-Thr-Phe-Asn-Lys (SEQ ID NO.: 43). In another embodiment, the tandem BRCT domain is a BRCA1 tandem BRCT domain. In one example, the tandem BRCT domain is BRCA1_1646-1859(SEQ ID NO.: 4). In other examples, the tandem BRCT domain can be BRCA1_1646-1863or BRCA1_1633-1863(SEQ ID NO.: 8). In yet another embodiment, the crystal has a space group of P3₂21 and a unit cell dimension of a=b=65.8 Å and c=93.1 Å).

In another aspect, the invention features a method for selecting or identifying a compound that is a modulator of phosphopeptide binding to a BRCA1 tandem BRCT domain that includes the steps of:

a) contacting a BACH1 phosphopeptide and the tandem BRCT domain under conditions that allow for the formation of a complex between the phosphopeptide and the tandem BRCT domain;

b) contacting the complex of step (a) with a candidate compound; and

c) measuring the displacement of the phosphopeptide from the tandem BRCT domain, where the displacement of the phosphopeptide from the tandem BRCT domain indicates that the candidate compound is a peptidomimetic compound that modulates phosphopeptide binding to a tandem BRCT domain.

In one embodiment, the candidate compound is identified using rational drug design. In another embodiment, the compound modulates phosphopeptide binding to a tandem BRCT domain.

In another aspect, the invention features a method for treating or inhibiting cellular proliferation in a subject that includes administering any of the compounds of the invention in an amount sufficient to treat or inhibit the cellular proliferative disorder in the subject. In one embodiment, the method further includes administering a chemotherapeutic agent, where the phosphopeptide and the chemotherapeutic agent are administered in amounts sufficient to inhibit the cellular proliferative disorder in the subject, and where the chemotherapeutic agent is administered simultaneously or within twenty-eight days of administering the phosphopeptide. Examples of useful chemotherapeutic agent are listed in Table 3.

In another embodiment, the method further includes radiation therapy, where the phosphopeptide and the radiation therapy are administered in amounts sufficient to treat or inhibit the cellular proliferative disorder in the subject, and where the radiation therapy is administered simultaneously or within twenty-eight days of administering the phosphopeptide.

The cellular proliferative disorder can be a neoplasm or cancer, such as, for example, those cancers selected from the group consisting of acoustic neuroma, acute leukemia, acute lymphocytic leukemia, acute monocytic leukemia, acute myeloblastic leukemia, acute myelocytic leukemia, acute myelomonocytic leukemia, acute promyelocytic leukemia, acute erythroleukemia, adenocarcinoma, angiosarcoma, astrocytoma, basal cell carcinoma, bile duct carcinoma, bladder carcinoma, brain cancer, breast cancer, bronchogenic carcinoma, cervical cancer, chondrosarcoma, chordoma, choriocarcinoma, chronic leukemia, chronic lymphocytic leukemia, chronic myelocytic leukemia, colon cancer, colon carcinoma, craniopharyngioma, cystadenocarcinoma, embryonal carcinoma, endotheliosarcoma, ependymoma, epithelial carcinoma, Ewing's tumor, glioma, heavy chain disease, hemangioblastoma, hepatoma, Hodgkin's disease, large cell carcinoma, leiomyosarcoma, liposarcoma, lung cancer, lung carcinoma, lymphangioendotheliosarcoma, lymphangiosarcoma, macroglobulinemia, medullary carcinoma, medulloblastoma, melanoma, meningioma, mesothelioma, myxosarcoma, neuroblastoma, non-Hodgkin's disease, oligodendriglioma, osteogenic sarcoma, ovarian cancer, pancreatic cancer, papillary adenocarcinomas, papillary carcinoma, pinealoma, polycythemia vera, prostate cancer, rhabdomyosarcoma, renal cell carcinoma, retinoblastoma, schwannoma, sebaceous gland carcinoma, seminoma, small cell lung carcinoma, squamous cell carcinoma, sweat gland carcinoma, synovioma, testicular cancer, uterine cancer, Waldenstrom's fibrosarcoma, and Wilm's tumor.

Any of the compounds of the invention can be in prodrug form, such as, for example, those prodrugs that include hydrolysable esters (e.g., methyl esters) or sulfonate groups. Other useful prodrugs of compounds of the invention are those in which a charged group of the compound is masked or those in which the prodrug includes a caged compound.

The invention also features a pharmaceutical composition that includes any of the compounds of the invention, or prodrugs thereof, and a pharmaceutically acceptable excipient.

DEFINITIONS

As used throughout this specification and the appended claims, the following terms have the meanings specified.

As used herein, the terms “alkyl” and the prefix “alk-” are inclusive of both straight chain and branched chain groups and of cyclic groups, i.e., cycloalkyl and cycloalkenyl groups. Cyclic groups can be monocyclic or polycyclic and preferably have from 3 to 8 ring carbon atoms, inclusive. Exemplary cyclic groups include cyclopropyl, cyclopentyl, cyclohexyl, and adamantyl groups.

By an “amino acid fragment” is meant an amino acid residue that has been incorporated into a peptide chain via its alpha carboxyl, its alpha nitrogen, or both. A terminal amino acid is any natural or unnatural amino acid residue at the amino-terminus or the carboxy-terminus. An internal amino acid is any natural or unnatural amino acid residue that is not a terminal amino acid.

By “analog” is meant a molecule that is not identical but has analogous features. For example, a polypeptide analog retains the biological activity of a corresponding naturally-occurring polypeptide, while having certain biochemical modifications that enhance the analog's function relative to a naturally occurring polypeptide. Such biochemical modifications could increase the analog's protease resistance, membrane permeability, or half-life, without altering, for example, ligand binding. An analog may include an unnatural amino acid.

By “antigenicity” is meant the ability of a substance to elicit an immune response. As one example, a compound may elicit an immune response through interaction with an antibody.

By “apoptosis” is meant the process of cell death where a dying cell displays at least one of a set of well-characterized biological hallmarks, including cell membrane blebbing, cell soma shrinkage, chromatin condensation, or DNA laddering.

By “aromatic residue” is meant an aromatic group having a ring system with conjugated π electrons (e.g., phenyl or imidazole). The ring of the aryl group is preferably 5 to 6 atoms. The aromatic ring may be exclusively composed of carbon atoms or may be composed of a mixture of carbon atoms and heteroatoms. Preferred heteroatoms include nitrogen, oxygen, sulfur, and phosphorous. Aryl groups may optionally include monocyclic, bicyclic, or tricyclic rings, where each ring has preferably five or six members. The aryl group may be substituted or unsubstituted. Exemplary substituents include alkyl, hydroxyl, alkoxy, aryloxy, sulfhydryl, alkylthio, arylthio, halo, fluoroalkyl, carboxyl, carboxyalkyl, amino, aminoalkyl, monosubstituted amino, disubstituted amino, and quaternary amino groups.

By “aryl” is meant a carbocyclic aromatic ring or ring system. Unless otherwise specified, aryl groups are from 6 to 18 carbons. Examples of aryl groups include phenyl, naphthyl, biphenyl, fluorenyl, and indenyl groups.

Aryl, heteroaryl, and heterocyclyl groups may be unsubstituted or substituted by one or more substituents selected from the group consisting of C_1-5alkyl, hydroxy, halo, nitro, C_1-5alkoxy, C_1-5alkylthio, trihalomethyl, C_1-5acyl, arylcarbonyl, heteroarylcarbonyl, nitrile, C_1-5alkoxycarbonyl, oxo, arylalkyl (wherein the alkyl group has from 1 to 5 carbon atoms) and heteroarylalkyl (wherein the alkyl group has from 1 to 5 carbon atoms).

By “atomic coordinates” (or “structural coordinates”) is meant those mathematical three-dimensional coordinates of the atoms in a crystalline material derived from mathematical equations related to the patterns obtained on diffraction of x-rays by the atoms (x-ray scattering centers) of the crystalline material. The diffraction data are used to calculate an electron density map of the unit cell of the crystal. These electron density maps are used to establish the positions of the individual atoms within the unit cell of the crystal. Atomic coordinates can be transformed, as is known to those skilled in the art, to different coordinate systems (i.e., surrogate systems) without affecting the relative positions of the atoms.

By “BACH1 nucleic acid” is meant a nucleic acid, or analog thereof, that encodes all or a portion of a BACH1 polypeptide or is substantially identical to all or a portion of the nucleic acid sequence of Genbank Accession No. 13661818 (SEQ ID NO.: 24).

By “BACH1 polypeptide” is meant a polypeptide substantially identical to all or a portion of the polypeptide sequence of Genbank Accession No. 13661819 (SEQ ID NO.: 25), or analog thereof.

By “BACH1 phosphopeptide” is meant a phosphorylated polypeptide substantially identical to all or a portion of the polypeptide sequence of Genbank Accession No. 13661819, or analog thereof, and having binding activity to a BRCA1 tandem BRCT domain.

By “basic pocket” is meant a discrete region of a molecule possessing net positive charge at pH 7.0. Such a region may be able to interact with a second molecule of complementary shape, charge, or other features, for example a therapeutic candidate compound. In one embodiment, such a region may be able to interact with a negatively charged group such as a phosphate moiety of a ligand. The basic pocket of a BRCA1 tandem BRCT domain is minimally defined by the BRCA1 tandem BRCT domain residues Ser1655, Gly1656, and Lys1702.

By “biased phosphopeptide library” is meant a phosphoserine, phosphothreonine, and/or phosphotyrosine degenerate peptide library, wherein specific amino acid residues of the phosphopeptide are fixed so as to be expressed in all phosphopeptides in the specific library. For instance, a biased phosphopeptide library can be synthesized to contain the core sequence Ser-pSer-Pro or Ser-pThr-Pro. In a desirable embodiment, the amino acid residue adjacent to the phosphoserine, phosphothreonine, or phosphotyrosine residue is also fixed.

By “binding to BRCA1” is meant having a physicochemical affinity for BRCA1. Binding may be measured by any of the methods of the invention, for example using an in vitro translation binding assay.

By “biological activity” is meant a polypeptide or other compound having structural, regulatory, or biochemical functions of a naturally occurring molecule. For example, one biological activity of a BRCA1 tandem BRCT domain is phosphopeptide binding, which may be measured using in vivo or in vitro binding assays.

By “BRCA1 biological activity” is meant at least one of the following: function in a DNA damage response pathway, cell cycle control, transcriptional regulation, chromatin remodeling, or phosphopeptide binding. In one assay for BRCA1 biological activity, the ability of BRCA1, or a fragment or mutant thereof comprising a tandem BRCT domain, to bind a BACH1 phosphopeptide is measured.

By “BRCA1 nucleic acid” is meant a nucleic acid that encodes all or a portion of BRCA1 or is substantially identical to all or a portion of the nucleic acid sequence of Genbank Accession No. 30039658 (SEQ ID NO.: 1), or analog thereof.

By “BRCA1 polypeptide” is meant a polypeptide substantially identical to all or a portion of the polypeptide sequence of Genbank Accession No. 30039659 (SEQ ID NO.: 2), or analog thereof, and having BRCA1 biological activity.

By “BRCT domain” is meant a polypeptide of at least 80 amino acids that, together with a second BRCT domain, functions to bind phosphoserine- and phosphothreonine-containing polypeptides. In one embodiment, a BRCT domain is a polypeptide sequence that adopts a three-dimensional structure comprising at least three alpha helices and four beta strands.

By “BRCT nucleic acid” is meant a nucleic acid that encodes at least one tandem BRCT domain, or analog thereof. For example, a nucleic acid substantially identical to PTIP BC033781[21707457] (SEQ ID NO.: 31), or NM_—007349 (PAX transcription activation domain interacting protein 1 mRNA) (SEQ ID NO.: 40) or Gene Bank Accession No: AY273801[30039658], is a BRCT nucleic acid.

By “BRCA1 tandem BRCT domain mutant” is meant a polypeptide encoded by at least one mutation of a BRCA1 nucleic acid.

By “caged compound” is meant a biologically active molecule coupled to a cleavable moiety such that the resulting coupled compound lacks biological activity as long as the moiety remains attached. Such a moiety prevents bioaction by sterically shielding one or more chemical groups of the molecule. The moiety may be removed by any means, including enymatic, chemical, or photolytic; removal of the moiety results in restoration of the molecule's biological activity.

By “candidate compound” is meant any nucleic acid molecule, polypeptide, or other small molecule, that is assayed for its ability to alter gene or protein expression levels, or the biological activity of a gene or protein by employing one of the assay methods described herein. Candidate compounds include, for example, peptides, polypeptides, synthesized organic molecules, naturally occurring organic molecules, nucleic acid molecules, and components thereof.

By “cellular proliferative disorder” or “disease or disorder characterized by inappropriate cell cycle regulation” is meant any pathological condition in which there is an abnormal increase or decrease in cell proliferation. Exemplary cellular proliferative disorders include cancer or neoplasms, inflammatory diseases, or hyperplasias (e.g. some forms of hypertension, prostatic hyperplasia).

By “chemotherapeutic agent” is meant one or more chemical agents used in the treatment or control of proliferative diseases, including cancer. Chemotherapeutic agents include cytotoxic and cytostatic agents. Examples of chemotherapeutic agents include cytotoxic and cytostatic agents such as alemtuzumab, altretamine, aminoglutethimide, amsacrine, anastrozole, azacitidine, bicalutamide, bleomycin, busulfan, capecitabine, carboplatin, carmustine, celecoxib, chlorambucil, 2-chlorodeoxyadenosine, cisplatin, colchicine, cyclophosphamide, cytarabine, cytoxan, dacarbazine, dactinomycin, daunorubicin, docetaxel, doxorubicin, epirubicin, estramustine phosphate, etodolac, etoposide, exemestane, floxuridine, fludarabine, 5-fluorouracil, flutamide, formestane, gemcitabine, gentuzumab, goserelin, hexamethylmelamine, hydroxyurea, hypericin, ifosfamide, imatinib, interferon, irinotecan, letrozole, leuporelin, lomustine, mechlorethamine, melphalen, mercaptopurine, 6-mercaptopurine, methotrexate, mitomycin, mitotane, mitoxantrone, nilutamide, paclitaxel, pentostatin, procarbazine, raltitrexed, rituximab, rofecoxib, streptozocin, tamoxifen, temozolomide, teniposide, 6-thioguanine, topotecan, toremofine, trastuzumab, vinblastine, vincristine, vindesine, and vinorelbine, or any combination of these. Other chemotherapeutic agents include, but are not limited to, those listed in Table 3.

By “three-dimensional model” is meant a three-dimensional representation of a molecule's structure. Computer modeling may be used to generate such a model in conjunction with structural data. These data could include x-ray crystallographic data, nuclear magnetic resonance data, electron microscopy data, or any other source of experimental or theoretical data useful for generating a model of a molecule or complex of molecules.

By “complex” is meant a chemical association of two or more molecules. Complexes may include a network of weak electrostatic bonds that maintain the association of the molecules. Other types of interactions, such as covalent, ionic, hydrogen bond, hydrophobic, or van der Waals interactions, may be present instead of or in addition to electrostatic bonds between members of a complex.

By “computer modeling” is meant the application of a computational program to determine one or more of the following: the location and binding proximity of a ligand to a binding moiety, the occupied space of a bound ligand, the amount of complementary contact surface between a binding moiety and a ligand, the deformation energy of binding of a given ligand to a binding moiety, and some estimate of hydrogen bonding strength, van der Waals interaction, hydrophobic interaction, and/or electrostatic interaction energies between ligand and binding moiety. Computer modeling can also provide comparisons between the features of a model system and a candidate compound. For example, a computer modeling experiment can compare a pharmacophore model of the invention with a candidate compound to assess the fit of the candidate compound with the model. Examples of techniques useful in the above evaluations include: quantum mechanics, molecular mechanics, molecular dynamics, Monte Carlo sampling, systematic searches and distance geometry methods. Further descriptions of computer modeling programs are provided elsewhere herein.

By “detectably-labeled” is meant any means for marking and identifying the presence of a molecule, e.g. a phosphopeptide or a peptidomimetic small molecule that interacts with a BRCA1 tandem BRCT domain. Methods for detectably-labeling a molecule are well known in the art and include, without limitation, radionuclides (e.g., with an isotope such as ³²P, ³³P, ¹²⁵I, or ³⁵S), nonradioactive labeling (e.g., chemiluminescent labeling or fluorescein labeling), and epitope tags.

If required, molecules can be differentially labeled using markers that can distinguish the presence of multiply distinct molecules. For example, a phosphopeptide that interacts with a PBD domain can be labeled with fluorescein and a PBD domain polypeptide can be labeled with Texas Red. The presence of the phosphopeptide can be monitored simultaneously with the presence of the PBD.

By “drug” is meant a compound of the present invention that is, within the scope of sound medical judgment, suitable for use in contact with the tissues of humans and animals without undue toxicity, irritation, allergic response, and the like, commensurate with a reasonable benefit/risk ratio, and effective for their intended use, as well as the zwitterionic forms, where possible, of the compounds of the invention.

By “fragment” is meant a portion of a polypeptide or nucleic acid having a region that is substantially identical to a portion of a reference protein or nucleic acid and retains at least 50% or 75%, more preferably 80%, 90%, or 95%, or even 99% of at least one biological activity of the reference protein or nucleic acid.

By “inhibitory fragment” is meant a portion of a polypeptide or nucleic acid having a region that is substantially identical to a portion of a reference protein or nucleic acid and inhibits biological activity of the reference protein or nucleic acid by at least 5%, more desirably, by at least 10%, even more desirably, by at least 25%, 50%, or 75%, and most desirably, by 90% or more.

By “halide” or “halogen” or “halo” is meant bromine, chlorine, iodine, or fluorine.

By “heteroaryl” is meant an aromatic ring or ring system that contains at least one ring hetero-atom (e.g., O, S, N). Unless otherwise specified, heteroaryl groups are from 1 to 9 carbons. Heteroaryl groups include furanyl, thienyl, pyrrolyl, imidazolyl, pyrazolyl, oxazolyl, isoxazolyl, thiazolyl, isothiazolyl, triazolyl, oxadiazolyl, oxatriazolyl, pyridyl, pyridazyl, pyrimidyl, pyrazyl, triazyl, benzofuranyl, isobenzofuranyl, benzothienyl, indole, indazolyl, indolizinyl, benzisoxazolyl, quinolinyl, isoquinolinyl, cinnolinyl, quinazolinyl, naphtyridinyl, phthalazinyl, phenanthrolinyl, purinyl, and carbazolyl groups.

By “heterocycle” is meant a non-aromatic ring or ring system that contains at least one ring heteroatom (e.g., O, S, N). Unless otherwise specified, heterocyclic groups are from 1 to 9 carbons. Heterocyclic groups include, for example, dihydropyrrolyl, tetrahydropyrrolyl, piperazinyl, pyranyl, dihydropyranyl, tetrahydropyranyl, tetrahydrofuranyl, dihydrothiophene, tetrahydrothiophene, and morpholinyl groups.

By “hydrophobic pocket” is meant a discrete region of a molecule possessing hydrophobic character. Such a region may be able to interact with a second molecule of complementary shape, charge, or other features, for example a therapeutic candidate compound. In one embodiment, such a region may be able to interact with a hydrophobic group such as an aromatic side chain of a ligand. The hydrophobic pocket of a BRCA1 tandem BRCT domain is minimally defined by the BRCA1 tandem BRCT domain residues Phe1704, Met1775, and Leu1839.

By “hydrogen bond acceptor (HBA)” is meant any atom that has a lone pair of electrons available for interacting with a hydrogen atom. Typical hydrogen bond acceptors include oxygen, sulfur, or nitrogen atoms, including those oxygen or nitrogen atoms that are SP₂-hybridized.

By “hydrogen bond donor (HBD)” is meant a heteroatom, such as, for example, an oxygen, sulfur, or nitrogen, that bears a hydrogen.

By “isolated polynucleotide” is meant a nucleic acid (e.g., a DNA) that is free of the genes which, in the naturally-occurring genome of the organism from which the nucleic acid molecule of the invention is derived, flank the gene. The term therefore includes, for example, a recombinant DNA that is incorporated into a vector; into an autonomously replicating plasmid or virus; or into the genomic DNA of a prokaryote or eukaryote; or that exists as a separate molecule (for example, a cDNA or a genomic or cDNA fragment produced by PCR or restriction endonuclease digestion) independent of other sequences. In addition, the term includes an RNA molecule which is transcribed from a DNA molecule, as well as a recombinant DNA which is part of a hybrid gene encoding additional polypeptide sequence.

By “main-chain atoms” or “main chain group” are meant those atoms in an amino acid, peptide, or protein that include the carbon and oxygen atom(s) of an amino acid's C1 carboxyl or carbonyl group; an amino acid's C2 carbon, and any hydrogen atom(s) bonded to the C2 carbon; and an amino acid's alpha-amine, and any hydrogen atom(s) bonded to the alpha amine.

By “modulate” is meant a change, such as an decrease or increase. For example, the change could refer to a biological activity. Desirably, the change is either an increase or a decrease of at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or 95% in expression or biological activity, relative to a reference or to control expression or activity, for example the expression or biological activity of a naturally occurring BRCA1 polypeptide.

By “mutation” is meant an alteration in a naturally-occurring or reference nucleic acid sequence, such as an insertion, a deletion, a substitution, or a frameshift mutation. Desirably, the nucleic acid sequence has at least one base pair alteration from a naturally-occurring sequence.

By “neoplasia” is meant a disease characterized by the pathological proliferation of a cell or tissue and its subsequent migration to or invasion of other tissues or organs. Neoplasia growth is typically uncontrolled and progressive, and occurs under conditions that would not elicit, or would cause cessation of, multiplication of normal cells. Neoplasias can affect a variety of cell types, tissues, or organs, including but not limited to an organ selected from the group consisting of bladder, bone, brain, breast, cartilage, glia, esophagus, fallopian tube, gallbladder, heart, intestines, kidney, liver, lung, lymph node, nervous tissue, ovaries, pancreas, prostate, skeletal muscle, skin, spinal cord, spleen, stomach, testes, thymus, thyroid, trachea, urogenital tract, ureter, urethra, uterus, and vagina, or a tissue or cell type thereof. Neoplasias include cancers, such as acoustic neuroma, acute leukemia, acute lymphocytic leukemia, acute monocytic leukemia, acute myeloblastic leukemia, acute myelocytic leukemia, acute myelomonocytic leukemia, acute promyelocytic leukemia, acute erythroleukemia, adenocarcinoma, angiosarcoma, astrocytoma, basal cell carcinoma, bile duct carcinoma, bladder carcinoma, brain cancer, breast cancer, bronchogenic carcinoma, cervical cancer, chondrosarcoma, chordoma, choriocarcinoma, chronic leukemia, chronic lymphocytic leukemia, chronic myelocytic leukemia, colon cancer, colon carcinoma, craniopharyngioma, cystadenocarcinoma, embryonal carcinoma, endotheliosarcoma, ependymoma, epithelial carcinoma, Ewing's tumor, glioma, heavy chain disease, hemangioblastoma, hepatoma, Hodgkin's disease, large cell carcinoma, leiomyosarcoma, liposarcoma, lung cancer, lung carcinoma, lymphangioendotheliosarcoma, lymphangiosarcoma, macroglobulinemia, medullary carcinoma, medulloblastoma, melanoma, meningioma, mesothelioma, myxosarcoma, neuroblastoma, non-Hodgkin's disease, oligodendriglioma, osteogenic sarcoma, ovarian cancer, pancreatic cancer, papillary adenocarcinomas, papillary carcinoma, pinealoma, polycythemia vera, prostate cancer, rhabdomyosarcoma, renal cell carcinoma, retinoblastoma, schwannoma, sebaceous gland carcinoma, seminoma, small cell lung carcinoma, squamous cell carcinoma, sweat gland carcinoma, synovioma, testicular cancer, uterine cancer, Waldenstrom's fibrosarcoma, and Wilm's tumor.

By “nucleic acid” is meant an oligomer or polymer of ribonucleic acid or deoxyribonucleic acid, or analog thereof. This term includes oligomers consisting of naturally occurring bases, sugars, and intersugar (backbone) linkages as well as oligomers having non-naturally occurring portions which function similarly. Such modified or substituted oligonucleotides are often preferred over native forms because of properties such as, for example, enhanced cellular uptake and increased stability in the presence of nucleases.

Specific examples of some preferred nucleic acids may contain phosphorothioates, phosphotriesters, methyl phosphonates, short chain alkyl or cycloalkyl intersugar linkages or short chain heteroatomic or heterocyclic intersugar linkages. Most preferred are those with CH₂—NH—O—CH₂, CH₂—N(CH₃)—O—CH₂, CH₂—O—N(CH₃)—CH₂, CH₂—N(CH₃)—N(CH₃)—CH₂and O—N(CH₃)—CH₂—CH₂backbones (where phosphodiester is O—P—O—CH₂). Also preferred are oligonucleotides having morpholino backbone structures (Summerton, J. E. and Weller, D. D., U.S. Pat. No. 5,034,506). In other preferred embodiments, such as the protein-nucleic acid (PNA) backbone, the phosphodiester backbone of the oligonucleotide may be replaced with a polyamide backbone, the bases being bound directly or indirectly to the aza nitrogen atoms of the polyamide backbone (P. E. Nielsen et al. Science 199: 254, 1997). Other preferred oligonucleotides may contain alkyl and halogen-substituted sugar moieties comprising one of the following at the 2′ position: OH, SH, SCH₃, F, OCN, O(CH₂)_nNH₂or O(CH₂)_nCH₃, where n is from 1 to about 10; C₁to C₁₀lower alkyl, substituted lower alkyl, alkaryl or aralkyl; Cl; Br; CN; CF₃; OCF₃; O—, S—, or N-alkyl; O—, S—, or N-alkenyl; SOCH₃; SO₂CH₃; ONO₂; NO₂; N₃; NH₂; heterocycloalkyl; heterocycloalkaryl; aminoalkylamino; polyalkylamino; substituted silyl; an RNA cleaving group; a conjugate; a reporter group; an intercalator; a group for improving the pharmacokinetic properties of an oligonucleotide; or a group for improving the pharmacodynamic properties of an oligonucleotide and other substituents having similar properties. Oligonucleotides may also have sugar mimetics such as cyclobutyls in place of the pentofuranosyl group.

Other preferred embodiments may include at least one modified base form. Some specific examples of such modified bases include 2-(amino)adenine, 2-(methylamino)adenine, 2-(imidazolylalkyl)adenine, 2-(aminoalklyamino)adenine, or other heterosubstituted alkyladenines

By “OE1,” “OE2,” “OD1,” and “OD2,” the following is meant. By “OE1” is meant the side chain oxygen of a glutamic acid residue such that the torsion angle formed by the side chain atoms CB (the beta carbon), CD (the delta carbon), CG (the gamma carbon), and OE1 is between −90 and 90 degrees.

By “OE2” is meant the side chain oxygen of a glutamic acid residue such that the torsion angle formed by the side chain atoms CB (the beta carbon), CD (the delta carbon), CG (the gamma carbon), and OE2 is not between −90 and 90 degrees.

By “OD1” is meant the side chain oxygen of an aspartic acid residue such that the torsion angle formed by the side chain atoms CA (the alpha carbon), CB, CG, and OD1 is between −90 and 90 degrees.

By “OD2” is meant the side chain oxygen of an aspartic acid residue such that the torsion angle formed by the side chain atoms CA, CB, CG, and OD2 is not between −90 and 90 degrees.

Other amino acid residue side chain atoms are similarly defined, where torsion angle of the instant atom, combined with the three most adjacent atoms connecting the instant atom to the main chain carboxyl group is measured and the instant atom is assigned a “1” designation if the torsion angle is between −90 and 90 degrees and a “2” designation if the torsion angle is not between −90 and 90 degrees. For symmetrical side chain ring atoms in tyrosine and phenylalanine residues, ring atoms including or most nearly connected to the two instant ring atoms are assigned a “CD1” designation if the torsion angle formed by CA, CB, CG, and CD1 is between −90 and 90 degrees and a “CD2” designation if the torsion angle formed by CA, CB, CG, and CD2 is not between −90 and 90 degrees.

By “peptide” is meant any compound composed of amino acids, amino acid analogs, chemically bound together. In general, the amino acids are chemically bound together via amide linkages (CONH); however, the amino acids may be bound together by other chemical bonds known in the art. For example, the amino acids may be bound by amine linkages. Peptide as used herein includes oligomers of amino acids, amino acid analog, or small and large peptides, including polypeptides.

By a “peptidomimetic” is meant a compound that is capable of mimicking or antagonizing the biological actions of a natural parent peptide. A peptidomimetic may include non-peptidic structural elements, unnatural peptides, synthesized organic molecules, naturally occurring organic molecules, nucleic acid molecules, and components thereof. Identification of a peptidomimetic can be accomplished by screening methods incorporating a binding pair and identifying compounds that displace the binding pair. Alternatively, a peptidomimetic can be designed in silico, by molecular modeling of a known protein-protein interaction, for example, the interaction of a phosphopeptide of the invention and a PBD. Desirably, the peptidomimetic will displace one member of a binding pair by occupying the same binding interface. More desirably the peptidomimetic will have a higher binding affinity to the binding interface.

By “pharmaceutically acceptable excipient” is meant a carrier that is physiologically acceptable to the subject to which it is administered and that preserves the therapeutic properties of the compound with which it is administered. One exemplary pharmaceutically acceptable excipient is physiological saline. Other physiologically acceptable excipients and their formulations are known to one skilled in the art and described, for example, in “Remington: The Science and Practice of Pharmacy” (20th ed., ed. A.R. Gennaro AR., 2000, Lippincott Williams & Wilkins).

By “pharmacophore” or “pharmacophore model” is meant the ensemble of steric and electronic features that is used to optimize supramolecular interactions with a specific biological target structure and to trigger (or to block) its biological response. A pharmacophore can be considered as the largest common denominator shared by a set of active molecules. Pharmacophore models are particularly useful in drug design.

In some embodiments, molecules may be derivatized with groups that introduce useful pharmacodynamic properties, such as those that transform an analog into a prodrug. Such groups are known to those skilled in the art, examples of which can be found in Testa and Mayer, Hydrolysis in Drug and Prodrug Metabolism: Chemistry, Biochemistry and Enzymology, published by Vch.

Verlagsgesellschaft Mbh. (2003), which is hereby incorporated by reference.

By “phosphopeptide” or “phosphoprotein” means a polypeptide in which one or more phosphate moieties are covalently linked to serine, threonine, tyrosine, aspartic acid, histidine amino acid residues, or amino acid analogs. A peptide can be phosphorylated to the extent of the number of serine, threonine, tyrosine, or histidine amino acid residues that is present. Desirably, a phosphopeptide is phosphorylated at 4 independent Ser/Thr/Tyr residues, at 3 independent Ser/Thr/Tyr residues, or at 2 independent Ser/Thr/Tyr residues. Most desirably, a phosphopeptide is phosphorylated at one Ser/Thr/Tyr residue regardless of the presence of multiple Ser, Thr, or Tyr residues.

Typically, a phosphopeptide is produced by expression in a prokaryotic or eukaryotic cell under appropriate conditions or in translation extracts where the peptide is subsequently isolated, and phosphorylated using an appropriate kinase. Alternatively, a phosphopeptide may be synthesized by standard chemical methods, for example, using N-α-FMOC-protected amino acids (including appropriate phosphoamino acids). In a desired embodiment, the use of non-hydrolysable phosphate analogs can be incorporated to produce non-hydrolysable phosphopeptides (Jenkins et al., J. Am. Chem. Soc., 124:6584-6593, 2002; herein incorporated by reference). Such methods of protein synthesis are commonly used and practiced by standard methods in molecular biology and protein biochemistry (Ausubel et al., Current Protocols in Molecular Biology, John Wiley & Sons, New York, N.Y., 1994, J. Sambrook and D. Russel, Molecular Cloning: A Laboratory Manual, 3^rdEdition, Cold Spring Harbor Laboratory Press, Woodbury N.Y., 2000). Desirably, a phosphopeptide employed in the invention is generally not longer than 100 amino acid residues in length, desirably less than 50 residues, more desirably less than 25 residues, 20 residues, 15 residues. Most desirably the phosphopeptide is 2, 3, 4, 5, 6, 7, 8, 9, or 10 amino acid residues long.

By a “Polo-like kinase” (Plk) is meant a polypeptide substantially identical to a Polo-like kinase amino acid sequence, having serine/threonine kinase activity, and having at least one Polo-box domain consisting of 2 Polo-boxes. Exemplary Polo-like kinase polypeptides include Plk-1 (GenBank Accession Number NP_—005021) (SEQ ID NO.: 33); Plk-2 (GenBank Accession Number NP 006613) (SEQ ID NO.: 34); and Plk-3 (GenBank Accession Number NP_—004064) (SEQ ID NO.: 35). Additional Polo-like kinase polypeptides include GenBank Accession Numbers P53350 (SEQ ID NO.: 36) and Q07832 (SEQ ID NO.: 37).

Structurally, Polo or Polo-like kinases have a unique amino terminus followed by a serine/threonine kinase domain, a linker region, a Polo-box (PB1), a linker sequence, a second Polo-box (PB 2), and a small stretch of 12-20 amino acids at the carboxy terminus.

In desirable embodiments, Polo-like kinases include Saccaromyces cereviseae, CdcS, Schizosaccaromyces pombe, Plo-1, Drosophila melanogaster, Polo, Xenopus laevis, Plx (Plx-1, -2, -3), and mammalian Plk-1, Prk/Fnk, Snk, and Cnk. The Polo-box is approximately 70 amino acids in length.

By “Polo-like kinase biological activity” is meant any biological activity associated with Polo-like kinases, such as serine/threonine kinase activity. Other biological activities of Polo-like kinases include the localization of the kinase to the centrosomes, spindle apparatus, and microtubular organizing centers (MOCs).

By “Polo-like kinase (PLK) nucleic acid molecule” is meant a nucleic acid, or nucleic acid analog, that encodes a Polo-like kinase polypeptide. For example, a Plk-1 nucleic acid molecule is substantially identical to the nucleic acid sequence of GenBank Accession Number X73458 or NM_—005030; a Plk-2/SNK nucleic acid molecule is substantially identical to NM_—006622; a Plk-3 nucleic acid molecule is substantially identical to NM_—004073; a Plx-1 nucleotide sequence is substantially identical to the nucleic acid sequence of GenBank Accession Number U58205; and a Polo nucleic acid molecule is substantially identical to the nucleic acid sequence of GenBank Accession Number AY095028 (SEQ ID NO.: 38) or NM_—079455.

By “polypeptide” is meant any chain of at least two naturally-occurring amino acids, or unnatural amino acids (e.g., those amino acids that do not occur in nature) regardless of post-translational modification (e.g., glycosylation or phosphorylation), constituting all or part of a naturally-occurring or unnatural polypeptide or peptide, as is described herein. Naturally occurring amino acids include any one of the following: alanine (A or Ala), cysteine (C or Cys), aspartic acid (D or Asp), glutamic acid (E or Glu), phenylalanine (F or Phe), glycine (G or Gly), histidine (H, or His), isoleucine (I or Ile), lysine (K or Lys), leucine (L or Leu), methionine (M or Met), asparagine (N or Asn), proline (P or Pro), hydroxyproline (Hyp), glutamine (Q or Gln), arginine (R or Arg), serine (S or Ser), threonine (T or Thr), valine (V or Val), tryptophan (W or Trp), and tyrosine (Y or Tyr). Other amino acids that may also be incorporated into a polypeptide include Ornithine (O or Orn) and hydroxyproline (Hyp).

Polypeptides or derivatives thereof may be fused or attached to another protein or peptide, for example, as a Glutathione-S-Transferase (GST) fusion polypeptide. Other commonly employed fusion polypeptides include, but are not limited to, maltose-binding protein, Staphylococcus aureus protein A, Flag-Tag, HA-tag, green fluorescent proteins (e.g., eGFP, eYFP, eCFP, GFP, YFP, CFP), red fluorescent protein, polyhistidine (6×His), and cellulose-binding protein.

By “prodrug” is meant a compound that is modified in vivo, resulting in formation of a biologically active drug compound, for example by hydrolysis in blood. A thorough discussion of prodrug modifications is provided in T. Higuchi and V. Stella, Pro-drugs as Novel Delivery Systems, Vol. 14 of the A.C.S. Symposium Series, Edward B. Roche, ed., Bioreversible Carriers in Drug Design, American Pharmaceutical Association and Pergamon Press, 1987, and Judkins et al., Synthetic Communications 26(23):4351-4367, 1996, each of which is incorporated herein by reference.

By “PTIP” or “Pax2 trans-activation domain-interacting protein” is meant a polypeptide, or analog thereof, substantially identical to Genebank Accession No: AAH33781.1 (SEQ ID NO.: 32) or NP_—031375, and having PTIP biological activity.

By “PTIP biological activity” is meant function in a DNA damage response pathway or phosphopeptide binding. In one assay for PTIP biological activity, the ability of PTIP, or a fragment or mutant thereof comprising a tandem BRCT domain, to bind a phosphopeptide is measured.

By “PTIP biological activity” is meant function in a DNA damage response pathway or phosphopeptide binding.

By “PTIP nucleic acid” is meant a nucleic acid, or analog thereof, substantially identical to Genebank Accession No:21707457 or NM_—007349.

By “purified” is meant separated from other components that naturally accompany it. Typically, a factor is substantially pure when it is at least 50%, by weight, free from proteins, antibodies, and naturally-occurring organic molecules with which it is naturally associated. Desirably, the factor is at least 75%, more desirably, at least 90%, and most desirably, at least 99%, by weight, pure. A substantially pure factor may be obtained by chemical synthesis, separation of the factor from natural sources, or production of the factor in a recombinant host cell that does not naturally produce the factor. Proteins, vesicles, and organelles may be purified by one skilled in the art using standard techniques such as those described by Coligan et al. (Current Protocols in Protein Science, John Wiley & Sons, New York, 2000). The factor is desirably at least 2, 5, or 10 times as pure as the starting material, as measured using polyacrylamide gel electrophoresis or column chromatography (including HPLC) analysis (Coligan et al., supra). Exemplary methods of purification include (i) salting-out, i.e., (NH₄)₂SO₄precipitation; (ii) conventional chromatography, e.g., ion exchange, size exclusion, hydrophobic interaction, or reverse-phase; (iii) affinity chromatography, e.g., immunoaffinity, active site affinity, dye affinity, or immobilized-metal affinity; and (iv) preparative electrophoresis, e.g., isoelectric focusing or native PAGE.

By “rational drug design” is meant the design or selection of drugs using information about the structure of the drugs' protein target as a basis for the design or selection.

By “salt bridge” is meant an electrostatic interaction between groups in a protein structure that results in the formation of a non-covalent interaction between an ionizable hydrogen of a hydrogen bond donor group and a heteroatom of a hydrogen bond acceptor group. Typically, salt bridges are formed between the hydrogen atom of the side chain carboxyl group of an aspartic acid or a glutamic acid and a side chain nitrogen atom found in lysine, ornithine, arginine, histidine, or tryptophan.

By “side chain atoms” or “side chain group” are meant those atoms in an amino acid, peptide, or protein that do not include the carbon and oxygen atom(s) of an amino acid's C1 carboxyl or carbonyl group; an amino acid's C2 carbon, and any hydrogen atoms bonded to the C2 carbon; and an amino acid's alpha-amine, and any hydrogen atom(s) bonded to the alpha amine.

By “space group” is meant a collection of symmetry elements of the unit cell of a crystal.

By “subject” is meant any animal (e.g., a human). Other animals that can be treated using the methods, compositions, and kits of the invention include horses, dogs, cats, pigs, goats, rabbits, hamsters, monkeys, guinea pigs, rats, mice, lizards, snakes, sheep, cattle, fish, and birds.

By “substantially identical” is meant a polypeptide or nucleic acid exhibiting at least 75%, but preferably 85%, more preferably 90%, most preferably 95%, or even 99% identity to a reference amino acid or nucleic acid sequence. For polypeptides, the length of comparison sequences will generally be at least 35 amino acids, preferably at least 45 amino acids, more preferably at least 55 amino acids, and most preferably 70 amino acids. For nucleic acids, the length of comparison sequences will generally be at least 60 nucleotides, preferably at least 90 nucleotides, and more preferably at least 120 nucleotides.

Sequence identity is typically measured using sequence analysis software with the default parameters specified therein (e.g., Sequence Analysis Software Package of the Genetics Computer Group, University of Wisconsin Biotechnology Center, 1710 University Avenue, Madison, Wis. 53705). This software program matches similar sequences by assigning degrees of homology to various substitutions, deletions, and other modifications. Conservative substitutions typically include substitutions within the following groups: glycine, alanine, valine, isoleucine, leucine, methionine; aspartic acid, glutamic acid, asparagine, glutamine; serine, threonine; lysine, arginine; and phenylalanine, tyrosine.

By “surrogate,” in the context of atomic coordinates, is meant any modification (e.g., mathematical modification or scaling) of the coordinates that preserves the relative relationships among the coordinates.

By “tandem BRCT domain” is meant a protein having at least 2 tandem BRCT domains. For example, a protein substantially identical to the polypeptide sequence of AAH33781, NP_—031375, or Genbank Accession No. 30039659.

By “treating,” “stabilizing,” or “preventing” a disease, disorder, or condition is meant preventing or delaying an initial or subsequent occurrence of a disease, disorder, or condition; increasing the disease-free survival time between the disappearance of a condition and its reoccurrence; stabilizing or reducing an adverse symptom associated with a condition; or inhibiting, slowing, or stabilizing the progression of a condition. Desirably, at least 20, 40, 60, 80, 90, or 95% of the treated subjects have a complete remission in which all evidence of the disease disappears. In another desirable embodiment, the length of time a patient survives after being diagnosed with a condition and treated with a compound of the invention is at least 20, 40, 60, 80, 100, 200, or even 500% greater than (i) the average amount of time an untreated patient survives or (ii) the average amount of time a patient treated with another therapy survives.

By “unit cell” is meant the fundamental repeating unit of a crystal.

By “unnatural amino acid” is meant an organic compound that has a structure similar to a natural amino acid, where it mimics the structure and reactivity of a natural amino acid. The unnatural amino acid as defined herein generally increases or enhances the properties of a peptide (e.g., selectivity, stability, binding affinity) when the unnatural amino acid is either substituted for a natural amino acid or incorporated into a peptide.

Unnatural amino acids and peptides including such amino acids are described in U.S. Pat. Nos. 6,566,330 and 6,555,522.

Other features and advantages of the invention will be apparent from the following description of the desirable embodiments thereof, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A and FIG. 1B depict the structure of a BRCA1 tandem BRCT domain complexed with a BACH1 phosphopeptide. FIG. 1A is a ribbon representation of a BRCA1 tandem BRCT domain in complex with a pSer-containing BACH1 peptide shown as stick representation. The BACH1 phosphopeptide binds at the interface between the two BRCT repeats. The secondary-structure elements in BRCT2 are labelled ‘prime’ to differentiate them from the secondary-structure elements in BRCT1. Areas of 3₁₀-helix are not labelled. FIG. 1B is an electron density map (2F_o-F_c) covering the BACH1 phosphopeptide (amino acids 988-995 of SEQ ID NO:25).

FIG. 2A and FIG. 2B depict BRCA1 BRCT cancer-linked mutations and sequence conservation in relation to the BACH1 phosphopeptide binding-site. FIG. 2A is a molecular surface representation of a BRCA1 tandem BRCT domain showing how the cancer-associated mutations S1655F (SEQ ID NO.: 9), D1692Y (SEQ ID NO.: 11), C1697R (SEQ ID NO.: 12), R1699Q (SEQ ID NO.: 14), S1715R (SEQ ID NO.: 16), M1775R (SEQ ID NO.: 10) and Y1853X (SEQ ID NO.: 21) cluster with respect to the phosphopeptide binding-site. FIG. 2B is a comparison of the front and back views of the molecular surface showing the clustering of residues conserved in human, chimp, mouse, rat, chicken and Xenopus BRCA1 tandem BRCT domains. The BACH1 peptide binds in a conserved phosphopeptide binding-groove.

FIG. 3A, FIG. 3B, and FIG. 3C depict the functional effects of tandem BRCT domain mutations. FIG. 3A is a schematic representation of protein-peptide contacts between a BRCA1 tandem BRCT domain and the BACH1 phosphopeptide. Hydrogen bonds, Van der Waals interactions and water molecules are denoted by dashed lines, crescents, and circles respectively. In FIG. 3B, the wild-type and mutant myc-tagged BRCA1 tandem BRCT domain constructs containing the indicated mutations were analysed for binding to a bead-immobilized optimal tandem BRCT domain-interacting phosphopeptide, YDIpSQVFPF, or its non-phosphorylated counterpart. The weak phospho-independent binding of the R1699Q mutant was observed using 10-fold more sample input than used in the other lanes. In FIG. 3C, U2OS cells transfected with wild-type and mutant myc-tagged BRCA 1 tandem BRCT domain constructs were analysed for association with endogenous BACH1.

FIG. 4A, FIG. 4B, and FIG. 4C reveal that the Phe +3 position of the BACH1 phosphopeptide is essential for BRCA1 tandem BRCT domain binding-specificity. FIG. 4A shows that residues Phe 1704, Met 1775, and Leu 1704 from a BRCA1 tandem BRCT domain form a hydrophobic pocket to accommodate the Phe +3 position of the BACH1 phosphopeptide. In FIG. 4B, superposition of the crystal structure of a BRCA1 M1775R tandem BRCT domain mutant with the wild-type:BACH1 phosphopeptide complex reveals that this mutation occludes the BACH1 Phe +3 position. FIG. 4C depicts BRCA1 wild type tandem BRCT domain and the M1775R mutant binding to a BACH1 phosphopeptide spot array (columns A, C-I, K-N, P-T, V-W, and Y). The M1775R mutant spot blot was performed using 10 times the amount of protein and was exposed to film for a significantly longer amount of time than the wild-type protein.

FIG. 5A and FIG. 5B depict the localization of BRCA1 BRCT domains to nuclear phosphoproteins. FIG. 5A depicts the localization of wild-type, M1775R, or K1702M/S1655A versions of myc-tagged BRCA1 tandem BRCT domains in un-irradiated U2OS cells prior to (left panels) or following (right panels) extraction using Triton X-100-containing buffers. Bars indicate 25 μm. FIG. 5B depicts localization following Triton X-100 extraction as in FIG. 5A two hours following exposure of cells to 10 Gy of γ-radiation. Extracted cells were also stained using an anti-pSer/pThr-Gln epitope antibody that recognizes the phosphorylation motif generated by the DNA damage-response kinases ATM and ATR. Bars indicate 10 μm.

DESCRIPTION OF THE INVENTION
Structure of the BRCA1 BRCT:BACH1 Phosphopeptide Complex

The BRCA1 tandem BRCT domains bound to the interacting phosphopeptide from BACH1 (residues 986-995) (SEQ ID NO.: 29) was crystallized and its structure solved at 1.85 Å resolution by X-ray diffraction (FIG. 1A and FIG. 1B). Phases were determined by molecular replacement using the previously determined structure of the un-liganded BRCA 1 tandem BRCT domains (PDB ID 1JNX) as a search model (see Table 1). Difference Fourier maps revealed well-defined electron density for the phosphopeptide allowing modeling of eight residues corresponding to BACH1 Ser988-Lys995 (corresponding to residues 3-10 of SEQ ID NO.: 29). Each BRCT repeat forms a compact domain (FIG. 1A) in which a central, four-stranded beta-sheet is packed against two helices, α1 and α3, on one side and a single helix, α2 on the other. The two domains pack together through interaction between α2 of BRCT1 and the α1′/α3′ pair of BRCT2. A linker region connecting the two BRCT domains contains a β-hairpin-like structure βL and a short helical region, αL, that forms part of the interface through interactions with α2 of BRCT1 and the N-terminal end of α3′ from BRCT2. Overall, the structure of the tandem BRCT domain:phosphopeptide complex is similar to that of the un-liganded domains (rmsd ˜0.4 Å for all Cα atoms). However, superposition of the individual BRCT repeats reveals that phosphopeptide-binding is associated with a slight relative rotation of each BRCT domain and a translation of BRCT1 helix α1 towards the cleft between the domains.

The BACH1 phosphopeptide binds in an extended conformation to a groove located at the highly conserved interface between the N- and C-terminal BRCT domains (FIG. 1A and FIG. 2A), consistent with the requirement of both domains for efficient phosphopeptide binding. This mode of binding is distinct from that observed in the phospho-independent interaction between p53 and the tandem BRCT domains of 53BP-1, which occurs primarily through the linker region. Our structure clearly shows that the phospho-dependent interactions that are necessary and sufficient for formation of the BACH1/BRCA1 complex occur on the opposite side of the BRCT-BRCT interface from those involved in the p53:53 BP-1 interaction.

BRCA1 BRCT:Phosphopeptide Specificity

BRCA1 tandem BRCT domain binding to library-selected peptides in vitro, and to phosphorylated BACH1 in vivo is dominated by the presence of a phosphoserine/threonine and a phenylalanine three residues C-terminal to it (Phe +3). This is now confirmed by our structure which shows that the BACH1 pSer 990 phosphate moiety binds to a basic pocket through three direct hydrogen-bonding interactions involving the side chains of Ser1655 and Lys1702, and the main-chain NH of Gly1656 (FIG. 3A). All three of these residues are located in BRCT1 and all are absolutely conserved in BRCA1 homologues. Ser1655 and Gly1656 are situated within the loop preceding α1 and are brought into proximity with the phosphate moiety as a result of the conformational change that occurs upon phosphopeptide binding. Intriguingly, a S1655F mutation has been identified in a single breast cancer patient, although its link to disease has not been confirmed. In addition to these direct interactions, the phosphate, and some peptide main-chain atoms are also tethered through networks of water molecules, many of which are tetrahedrally hydrogen bonded (FIG. 3A). Indirect protein-solvent-phosphate contacts are unusual in phospho-dependent protein-protein interactions but have been observed previously in structures of phosphopeptide complexes of the human Plk1 Polo-box domain.

The Phe +3 peptide side-chain fits into a hydrophobic pocket at the BRCT interface consisting of the side chains of Phe1704, Met1775 and Leu1839 contributed from both BRCT domains (FIG. 3A and FIG. 4A). This finding rationalizes the strong selection for aromatic amino acids in the +3 position of the binding motif seen in peptide library experiments, as well as the observation of Yu et al. that mutation of Phe993 to Ala eliminates BRCA1:BACH1 binding. Additional hydrogen-bonds with the main-chain N and C═O atoms of Phe +3 are supplied by main- and side-chain atoms from Arg1699, a site of mutation also associated with cancer predisposition. The phosphorylated Ser990 of BACH1 is preceded by an Arg residue in the −3 position and followed by a proline residue in the +1 position, suggesting potential Ser990 phosphorylation by either basophilic and/or proline-directed kinases. The BRCA1 tandem BRCT domains are also known to interact with pSQ-containing motifs characteristic of PI 3-kinase-like kinases such as ATM and ATR. In the tandem BRCT:BACH1 phosphopeptide co-crystal structure, there are no direct interactions between the +1 Pro side chain and the BRCT domains. Instead, this residue participates in only a single water-mediated hydrogen bond involving its carbonyl oxygen (FIG. 3A), consistent with the idea that various types of protein kinases can generate tandem BRCT phospho-binding motifs. The Lys +5 side chain makes two salt-bridging interactions with residues in BRCT2 (FIG. 3A), consistent with the Lys selection observed in this position by spot blot and peptide library experiments.

Cancer-Associated BRCA1 BRCT Mutations

Residues that form or stabilize the phosphopeptide binding surface, and the domain-domain interface, are among the most highly conserved portions of the molecule in BRCA1 orthologues from humans, primates, rats and mice (FIG. 2B). Interestingly, these regions correlate strongly with the location of cancer-associated mutations (FIG. 2A). Some cancer-associated mutations may disrupt the global BRCT fold while others are more likely to specifically interfere with ligand binding. Approximately 80 tumor-derived mutations have been identified within the BRCA1 tandem BRCT domains, though only a few of these have been subsequently confirmed to result in cancer predisposition including D1692Y, C1697R, R1699W (SEQ ID NO.: 13), A1708E (SEQ ID NO.: 15), S1715R, G1738E (SEQ ID NO.: 17), P1749R (SEQ ID NO.: 18), M1775R, 5382InsC (a frameshift mutation that results in a stop codon at position 1829) (SEQ ID NO.: 22), and Y1853X (which truncates the last 11 residues). Most of these cluster at or near the phosphopeptide-interacting surface (FIG. 2A). Two of these mutated residues, Arg1699 and Met1775, directly interact with residues in the phosphopeptide (FIG. 3A). Two others, Pro1749 and Gly1738, are located at the BRCT1/BRCT2 interface beneath the molecular surface and their effects are likely to be mediated through alterations in the relative orientation of the tandem BRCT motifs that our structure suggests is necessary for phospho-dependent interactions with partner proteins.

To verify the phosphoserine phosphate interactions observed in the X-ray structure and to investigate the effects of the most common tumor-derived point mutations, we investigated the binding of a panel of site-directed mutant BRCA1 tandem BRCT domains to the interacting region of BACH1. Binding was determined by measuring the ability of in vitro transcribed and translated proteins to bind to either phosphorylated and non-phosphorylated biotinylated peptides (FIG. 3B). Wild-type BRCA1 tandem BRCT domains clearly bind to phosphorylated but not non-phosphorylated peptides, while mutation of the conserved Ser1655 and Lys1702 (SEQ ID NO.: 19), alone or in combination, completely abolished the interaction. Five bona fide cancer-linked mutations, P1749R, G1738E, M1775R, Y1853X and 5382InsC, all result in complete loss of phosphopeptide binding. A mutation R1699W is cancer-linked and a second, R1699Q, has been detected in breast cancer patients but has not yet been directly related to disease-predisposition. We surmised that the glutamine side-chain might still participate in main-chain hydrogen bonding to the peptide and this is, indeed, the only BRCA1 tandem BRCT domain mutant that retained a small degree of binding in our assays. Somewhat surprisingly, however, the R1699Q mutant largely loses phospho-specificity, and instead bound to both phosphorylated and non-phosphorylated peptides.

To investigate the in vivo binding of cancer-predisposing mutant BRCA1 tandem BRCT domains to endogenous BACH1, we transfected U2OS cells with a vector encoding the C-terminal 550 amino acids of BRCA1 containing a myc tag and an SV40 nuclear localization sequence as described by Chen et al. As shown in FIG. 3C, interaction between the wild type BRCA1 tandem BRCT domains with full-length BACH1 was easily detected. In contrast, no in vivo interaction was observed between BACH1 and mutant BRCA1 tandem BRCT domains that disrupt phosphate-binding or predispose to breast and ovarian cancer. All of these cancer-associated mutant proteins were expressed at comparable levels when transfected into mammalian cells (FIG. 3C), suggesting that gross structural destabilization is unlikely to account for their cancer proclivity.

Interpretation of the structural effects of the M1775R mutation is simplified since the X-ray crystal structure of the M1775R tandem BRCT domain mutant has been determined (PDB ID 1N50), revealing a nearly identical structure as the wild-type protein with an average rmsd of 0.35 Å for all Cα atoms. Superposition of the mutant structure with that of our BACH1 complex shows that the guanidine portion of the substituent arginine side-chain extrudes into the tandem BRCT cleft, where it occupies the binding site for the essential Phe +3 of the phosphopeptide (FIG. 4A and FIG. 4B). In this case, loss of phosphopeptide-binding in vitro and BACH1 binding in vivo appear to be attributable to the severe steric clash of the Arg 1775 side-chain with an important determinant of phospholigand specificity and affinity. The M1775R mutant protein does, however, bind weakly to a BACH1 phosphopeptide in which the +3 Phe is mutated to Asp or Glu (FIG. 4C). This is consistent with the introduction of a basic residue at the pSer +3 binding site and with the observation that this mutation creates new anion binding sites in the M1775R crystal structure. Thus, in addition to disrupting the native BRCA1:BACH1 interaction, this mutation may also result in the formation of inappropriate BRCA1 BRCT interactions.

Phosphopeptide-Binding and Nuclear Foci Formation

Subcellular localization and nuclear foci formation by the wild type, S1655A/K1702M phosphopeptide-binding mutant (SEQ ID NO.: 20) and the M1775R cancer-associated mutant BRCA1 BRCT domains were studied before and after DNA damage in unsynchronized U2OS cells (FIG. 5A and FIG. 5B). To maximize visualization of nuclear foci, the cells were permeabilized with buffers containing 0.5% Triton X-100 prior to fixation and immunostaining. In un-extracted cells the wild-type BRCT domains and both of the mutant BRCT proteins showed equivalent diffuse nuclear localization. Extraction of the un-irradiated cells prior to fixation resulted in near complete loss of BRCT domain staining in all cases (FIG. 5A). Under these conditions, less than 5% of the wild-type and M1775R tandem BRCT-containing cells displayed 5 or more nuclear foci, and no foci were observed with the S1655A/K1702M double mutant. When the cells were irradiated with 10 Gy of γ-irradiation, and 2 hrs later permeabilized, fixed, and stained, nearly all of the cells containing the wild-type BRCA1 tandem BRCT domains demonstrated sharp punctate nuclear foci that largely co-localized with the staining pattern of an anti-pSer/pThr-Gln epitope antibody that recognizes ATM- and ATR-phosphorylated substrates (FIG. 5B). In contrast, the S1655A/K1702M mutant protein displayed only faint staining with a very fine granular pattern that completely failed to co-localize with pSer/pThr-Gln staining. This failure of foci formation and pSer/pThr-Gln co-localization is strong evidence that the phospho-binding function of the BRCA1 tandem BRCT domains is critical for normal subcellular localization following DNA damage. The M1775R mutant protein that binds weakly to phosphopeptides with a different specificity than the wild-type BRCA1 BRCT domains also formed punctate nuclear foci, although these were slightly reduced in number and showed less co-localization with pSer/pThr-Gln staining foci than the wild-type protein. This localization might result from synergistic weak binding to alternative non-optimal phosphorylated ligands present in high abundance in nuclear foci following DNA damage, as has been observed for other phosphopeptide-binding domain interactions.

Analysis of BRCA1 Tandem BRCT Domain-BACH1 Phosphopeptide Structure

The 1.85 Å BRCA1 tandem BRCT domain:phosphopeptide structure described here is the highest resolution X-ray structure of any BRCT domain structure solved to date, and provides an enhanced structural framework within which the molecular basis of breast and ovarian cancer can be further investigated. The structure reveals why tandem BRCT repeats, rather than single BRCT domains, are required for binding to pSer- or pThr-containing phosphopeptides with high affinity and specificity, since motif recognition is mediated by residues contributed from both domains across the domain-domain interface. In addition, the structure rationalizes the observation that the BRCA1 BRCT domains do not bind to pTyr-containing sequences, since the phosphate recognition pocket appears too shallow to accept a bulky phenyl ring. Despite the fact that not all tandem BRCT domains appear to bind phosphopeptides, several residues involved in the binding are relatively conserved. Structures of additional BRCT:phosphopeptide complexes will be necessary to better understand negative determinants of binding.

The BRCA1 tandem BRCT:phosphopeptide structure, in combination with biochemical and cell biological analysis, shows that some pro-oncogenic mutations in the BRCA1 C-terminal domains directly disrupt phosphopeptide binding or perturb the BRCT interface that forms the phospho-dependent binding surface. Similar conclusions were reached by Williams et al., who reported the structure of the BRCA1 tandem BRCT domains bound to an alternative phosphopeptide determined from oriented peptide library screening, and the un-liganded structures of the M1775R and V1809F mutants.

Like the BRCT domains in PTIP, the BRCT domains in BRCA1 are sufficient for nuclear foci formation in response to DNA damage, and the phospho-binding function appears to be involved in this phenomenon. Four bona fide cancer-linked mutations, P1749R, G1738E, 5382InsC, and Y1853X all result in loss of phosphopeptide binding. A fifth mutation, M1775R, binds weakly to phosphopeptides with altered motif specificity, and can still form nuclear foci after DNA damage, however it completely loses the ability to interact with wild-type BACH1. These effects of the Pro 1749 and Met 1775 lesions confirm the previous observations that these mutations are sufficient to abrogate BRCA1-BACH1 interactions in vivo. Since BACH1 mutations have also been shown to be associated with the development of cancer, these findings suggest that the loss of this critical BRCA1 M1775R:BACH1 interaction may be the critical event responsible for cancer predisposition.

Despite the fact that mutations in BRCA1 ultimately predispose women to cancer, wild-type BRCA1 paradoxically constitutes a target for anti-cancer therapy. Given the importance of BRCA1 in homologous recombination and DNA repair, disruption of the pSer-binding function would be expected to result in enhanced sensitivity to chemotherapy and radiation, as has been observed in BRCA1 null murine embryonic stem cells. The structural delineation of the pSer binding surface provides a new target for rational drug design.

Protein Cloning, Expression, and Purification

For crystallization experiments, human BRCA1 BRCTs (residues 1646-1859) (SEQ ID NO.: 4) were expressed as glutathione S-transferase (GST) fusions in pGEX-4T1 (Amersham Pharmacia Biotech) in Escherichia coli BL21 at 18° C. The GST was removed by 48-hour treatment with thrombin before gel filtration. A BRCA1 BRCT clone (residues 1313-1863) (SEQ ID NO.: 3) in pcDNA3 containing a N-terminal Myc-tag and a SV40 nuclear localization sequence was used for the co-immunoprecipitation and immunofluorescence assays. Mutations were generated using the Stratagene Quick Change Mutagenesis Kit, and verified by sequencing. The pGEX-BRCA1 BRCT clone (residues 1633-1863) (SEQ ID NO.: 8) was described previously and was used for the peptide filter array. Induction of recombinant GST-BRCA1 BRCT domain protein was performed at 37° C. for 3 hrs in the presence of 0.4 mM IPTG. The GST-BRCA1 BRCT domains were isolated from bacterial lysates using glutathione agarose, followed by elution with 40 mM glutathione, 50 mM Tris/HCl (pH 8.1), and dialysis into 50 mM Tris/HCl (pH 8.1), 300 mM NaCl.

Crystallization and Structure Determination

Crystals were grown at 18° C. by microbatch methods. The BACH1 phosphopeptide (SRSTpS⁹⁹⁰PTFNK) was mixed with the BRCA1 BRCTs in a 1.5:1 stoichiometric excess and concentrated to 0.35 mM in a buffer containing 50 mM Tris-HCl (pH 7.5), 0.4M NaCl, and 3 mM DTT. Crystals grew from 50 mM MES (pH 6.5), 0.1 M (NH₄)₂SO₄, and 13% PEG 8K (w/v). Crystals belonged to the trigonal space group P3₂21 (a=b=65.8 Å, c=93.1 Å, α=β=90.0°, γ=120.0° with one complex in the asymmetric unit. Data were collected from flash-cooled crystals at 100K on a Raxis-II detector mounted on a Rigaku RU200 generator. Diffraction data were integrated and scaled using DENZO and SCALEPACK. The structure was solved by molecular replacement using the coordinates 1JNX.brk as a model with AMORE (CCP4 1994). Subsequent refinement was carried out using REFMAC5 (CCP4 1994) and manual model building in O. Figures were constructed using Pymol.

Peptide Binding

An optimal phosphopeptide for binding the BRCA1 BRCTs was determined by oriented peptide library screening as described previously. This peptide was synthesized in both its phosphorylated and non-phosphorylated form with a biotin group at the N-terminus using N-α-FMOC-protected amino acids and standard BOP/HOBt coupling chemistry. These peptides were conjugated to streptavidin coated beads (Sigma-Aldrich). The wild-type and mutant BRCA1 BRCT domain-containing constructs (residues 1313-1863) were transcribed and translated in vitro in the presence of [³⁵S]-methionine using the TNT kit (Promega). The bead-immobilized peptides (10 μL of beads) were added to 10 μL of the in vitro translated [³⁵S]-labeled protein pool in 150 μL binding buffer (50 mM Tris-HCl (pH7.6), 150 mM NaCl, 0.5% NP-40, 1 mM EDTA, 2 mM DTT, 8 μg/mL pepstatin, 8 μg mL⁻¹aprotinin, 8 μg mL⁻¹leupeptin, 800 μM Na3VO4, 25 mM NaF). After incubation at 4° C. for 3 hours, the beads were washed three times with 200 μL of binding buffer prior to analysis by SDS-PAGE (12.5% (w/v)) and autoradiography.

Peptide Filter Array

An ABIMED peptide arrayer with a computer controlled Gilson diluter and liquid handling robot was used to synthesize peptides onto an amino-PEG cellulose membrane using N-α-FMOC-protected amino acids and DIC/HOBT coupling chemistry. The membranes were blocked in 5% (w/v) milk in Tris-buffered saline containing 0.1% (v/v) Tween-20 (TBS-T) for 1 hr at room temperature, incubated with 0.025 μM GST-BRCA1 BRCTs or 0.25 μM GST-BRCA1 BRCTs M1775R (residues 1633-1863) in 5% (w/v) milk, 50 mM Tris-HCl (pH 7.6), 150 mM NaCl, 2 mM EDTA, 2 mM DTT for 1 hr at room temperature and washed four times with TBS-T. The membranes were then incubated with anti-GST conjugated HRP (Amersham) in 5% (w/v) milk/TBS-T for 1 hr at room temperature, washed five times with TBS-T, and binding analysed by ECL (Perkin-Elmer).

Co-Immunoprecipitation of BRCA1 BRCTs and BACH1

U2OS cells were grown to 50% confluency in 100 cm²dishes and transfected with the myc-tagged wild-type or mutant BRCA1 BRCT constructs (residues 1313-1863) (SEQ ID NO.: 6) using FuGene6 transfection reagent (Roche) according to manufacturer's protocol. Cells were collected 30 hrs following transfection, lysed in lysis buffer (50 mM Tris-HCl (pH7.6), 150 mM NaCl, 1.0% NP-40, 5 mM EDTA, 2 mM DTT, 8 μg/mL AEBSF, 8 μg mL⁻¹aprotinin, 8 μg mL⁻¹leupeptin, 2 mM Na₃VO₄, 10 mM NaF and the phosphatase inhibitors microcystin and okadaic acid). Lysates containing equal amounts of protein (3 mg) was incubated with 3 μL of a mouse anti-myc antibody (Cell Signaling) for 2 hr at 4° C. and then 10 μL of protein G-sepharose beads (Sigma-Aldrich) were added and samples incubated for an additional 2 hr at 4° C. Beads were washed four times with lysis buffer, bound proteins eluted in SDS-PAGE sample buffer, analysed on 6% polyacrylamide gels, transferred to PVDF membrane, and detected by blotting with rabbit anti-BACH1 antibody. A portion of the lysates were also run and blotted with the anti-BACH1 antibody and the anti-myc antibody to further ensure equal protein loading.

Immunofluorescence and Microscopy

U2OS cells were seeded onto 18 mm²coverslips and transfected with the BRCA1 BRCT construct (residues 1313-1863) and various mutants using FuGene6 transfection reagent (Roche) according to manufacturer's protocol. Thirty hours following transfection, the cells were either treated with 10 Gy of ionizing radiation or mock irradiated and allowed to recover for 120 minutes. Cells were fixed in 3% (v/v) paraformaldehyde/2% (w/v) sucrose for 15 min at RT and permeabilized with a 0.5% (v/v) Triton X-100 solution containing 20 mM Tris-HCl (pH 7.8), 75 mM NaCl, 300 mM sucrose, and 3 mM MgCl₂for 15 min at RT. When necessary, proteins were extracted after IR treatment as described previously. In brief, cells were incubated with extraction buffer (10 mM PIPES pH6.8, 100 mM NaCl, 300 mM sucrose, 3 mM MgCl₂, 1 mM EGTA, 0.5% (v/v) Triton X-100) for 5 minutes on ice followed by incubation with extraction stripping buffer (10 mM Tris-HCl pH 7.4, 10 mM NaCl, 3 mM MgCl₂, 0.5% (v/v) Triton X-100) for 5 minutes on ice followed by successive washes in ice cold PBS. Slides were fixed as above, stained with primary antibodies at 37° C. for 20 min, then stained with a anti-mouse or anti-rabbit secondary antibody for 20 min (Molecular Probes) at 37° C. Primary antibodies used were mouse anti-myc (Cell Signaling) and rabbit anti-(pSer/pThr)Gln (Cell Signaling). Images were collected on a Axioplan2 microscope (Carl Zeiss) and processed using OpenLab software (Improvision).

Coordinates

The atomic coordinates and structure factors have been deposited in the Protein Data Bank (Accession code 1T15). This information is shown in Table 2 (SEQ ID NOs.: 4 and 29).

TABLE 1

Summary of crystallographic analysis.

Data Collection:

Space group
P3₂21

Unit cell dimensions
a = b = 65.8 Å, c = 93.1 Å,

α = β = 90°, γ = 120°

Resolution range (Å)
15.0-1.85

Completeness (%)
93.9

Total observations
165,151

Unique reflections
19,219

Average I/σ(I)
35.6

R_sym* (%)
5.4

Model refinement:

Resolution (Å)
15.0-1.85

No. of reflections (free)
18,225 (911)

R_work/R_free^§ (%)
20.6/22.2

No. of protein atoms
1,750

No. of water atoms
157

rms deviations

bonds (Å)
0.01

angles (°)
1.35

Details of the crystallization and structure determination are provided in the supplementary information.

* R_sym= Σ_j| <I> − I_j|/Σ<I> where I_jis the intensity of the j^threflection and <I> is the average intensity.

^§ R_work= Σ_hkl| F_obs− F_calc|/Σ_hklF_obs, where R_freeis equivalent to R_workbut is calculated for a randomly chosen 5% of reflections omitted from the refinement process.

TABLE 2

HEADER
ANTITUMOR PROTEIN
15-APR-04 1T15

TITLE

CRYSTAL STRUCTURE OF THE BRCA1 BRCT DOMAINS IN COMPLEX WITH

TITLE
2
THE PHOSPHORYLATED INTERACTING REGION FROM BACH1 HELICASE

COMPND

MOL_ID: 1;

COMPND
2
MOLECULE: BREAST CANCER TYPE 1 SUSCEPTIBILITY PROTEIN;

COMPND
3
CHAIN: A;

COMPND
4
FRAGMENT: BCRT 1, BCRT 2;

COMPND
5
ENGINEERED: YES;

COMPND
6
MOL_ID: 2;

COMPND
7
MOLECULE: BRCA1 INTERACTING PROTEIN C-TERMINAL HELICASE 1;

COMPND
8
CHAIN: B;

COMPND
9
ENGINEERED: YES

SOURCE

MOL_ID: 1;

SOURCE
2
ORGANISM_SCIENTIFIC: HOMO SAPIENS;

SOURCE
3
ORGANISM_COMMON: HUMAN;

SOURCE
4
GENE: BRCA1;

SOURCE
5
EXPRESSION_SYSTEM: ESCHERICIA COLI;

SOURCE
6
EXPRESSION_SYSTEM_STRAIN: BL21;

SOURCE
7
EXPRESSION_SYSTEM_VECTOR_TYPE: PLASMID;

SOURCE
8
EXPRESSION_SYSTEM_PLASMID: PGEX-4T1;

SOURCE
9
MOL_ID: 2;

SOURCE
10
SYNTHETIC: YES

KEYWDS

PROTEIN-PEPTIDE COMPLEX

EXPDTA

X-RAY DIFFRACTION

AUTHOR

J. A. CLAPPERTON, I. A. MANKE, D. M. LOWERY, T. HO, L. F. HAIRE,

AUTHOR
2
M. B. YAFFE, S. J. SMERDON

JRNL

AUTH

J. A. CLAPPERTON, I. A. MANKE, D. M. LOWERY, T. HO, L. F. HAIRE,

JRNL

AUTH
2
M. B. YAFFE, S. J. SMERDON

JRNL

TITL

STRUCTURE AND MECHANISM OF BRCA1 BRCT DOMAIN

JRNL

TITL
2
RECOGNITION OF PHOSPHORYLATED BACH1 WITH

JRNL

TITL
3
IMPLICATIONS FOR CANCER

JRNL

REF

TO BE PUBLISHED

JRNL

REFN

REMARK
1

REMARK
2

REMARK
2
RESOLUTION. 1.85 ANGSTROMS.

REMARK
3

REMARK
3
REFINEMENT.

REMARK
3
PROGRAM
: REFMAC 5.0

REMARK
3
AUTHORS
: MURSHUDOV, VAGIN, DODSON

REMARK
3

REMARK
3
REFINEMENT TARGET: ENGH & HUBER

REMARK
3

REMARK
3
DATA USED IN REFINEMENT.

REMARK
3
RESOLUTION RANGE HIGH
(ANGSTROMS)
: 1.85

REMARK
3
RESOLUTION RANGE LOW
(ANGSTROMS)
: 15.00

REMARK
3
DATA CUTOFF
(SIGMA(F))
: 0.000

REMARK
3
COMPLETENESS FOR RANGE
(%)
: NULL

REMARK
3
NUMBER OF REFLECTIONS

: 18242

REMARK
3

REMARK
3
FIT TO DATA USED IN REFINEMENT.

REMARK
3
CROSS-VALIDATION METHOD
: NULL

REMARK
3
FREE R VALUE TEST SET SELECTION
: RANDOM

REMARK
3
R VALUE
(WORKING + TEST SET)
: NULL

REMARK
3
R VALUE
(WORKING SET)
: 0.206

REMARK
3
FREE R VALUE
: 0.222

REMARK
3
FREE R VALUE TEST SET SIZE
(%)
: 5.100

REMARK
3
FREE R VALUE TEST SET COUNT

: 972

REMARK
3

REMARK
3
FIT IN THE HIGHEST RESOLUTION BIN.

REMARK
3
TOTAL NUMBER OF BINS USED
: NULL

REMARK
3
BIN RESOLUTION RANGE HIGH
: NULL

REMARK
3
BIN RESOLUTION RANGE LOW
: NULL

REMARK
3
REFLECTION IN BIN
(WORKING SET)
: NULL

REMARK
3
BIN COMPLETENESS
(WORKING + TEST) (%)
: NULL

REMARK
3
BIN R VALUE
(WORKING SET)
: NULL

REMARK
3
BIN FREE R VALUE SET COUNT
: NULL

REMARK
3
BIN FREE R VALUE
: NULL

REMARK
3

REMARK
3
NUMBER OF NON-HYDROGEN ATOMS USED IN REFINEMENT.

REMARK
3
ALL ATOMS
: 1906

REMARK
3

REMARK
3
B VALUES.

REMARK
3
FROM WILSON PLOT
(A**2)
: NULL

REMARK
3
MEAN B VALUE
(OVERALL, A**2)
: NULL

REMARK
3
OVERALL ANISOTROPIC B VALUE.

REMARK
3
B11 (A**2) : NULL

REMARK
3
B22 (A**2) : NULL

REMARK
3
B33 (A**2) : NULL

REMARK
3
B12 (A**2) : NULL

REMARK
3
B13 (A**2) : NULL

REMARK
3
B23 (A**2) : NULL

REMARK
3

REMARK
3
ESTIMATED OVERALL COORDINATE ERROR.

REMARK
3
ESU BASED ON R VALUE
(A) :
NULL

REMARK
3
ESU BASED ON FREE R VALUE
(A) :
NULL

REMARK
3
ESU BASED ON MAXIMUM LIKELIHOOD
(A) :
NULL

REMARK
3
ESU FOR B VALUES BASED ON MAXIMUM LIKELIHOOD
(A**2) :
NULL

REMARK
3

REMARK
3
CORRELATION COEFFICIENTS.

REMARK
3
CORRELATION COEFFICIENT FO-FC
: NULL

REMARK
3
CORRELATION COEFFICIENT FO-FC FREE
: NULL

REMARK
3

REMARK
3
RMS DEVIATIONS FROM IDEAL VALUES
COUNT
RMS
WEIGHT

REMARK
3
BOND LENGTHS REFINED ATOMS
(A):
NULL ;
0.010 ;
NULL

REMARK
3
BOND LENGTHS OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
BOND ANGLES REFINED ATOMS
(DEGREES):
NULL ;
1.350 ;
NULL

REMARK
3
BOND ANGLES OTHERS
(DEGREES):
NULL ;
NULL ;
NULL

REMARK
3
TORSION ANGLES, PERIOD 1
(DEGREES):
NULL ;
NULL ;
NULL

REMARK
3
TORSION ANGLES, PERIOD 2
(DEGREES):
NULL ;
NULL ;
NULL

REMARK
3
TORSION ANGLES, PERIOD 3
(DEGREES):
NULL ;
NULL ;
NULL

REMARK
3
TORSION ANGLES, PERIOD 4
(DEGREES):
NULL ;
NULL ;
NULL

REMARK
3
CHIRAL-CENTER RESTRAINTS
(A**3):
NULL ;
NULL ;
NULL

REMARK
3
GENERAL PLANES REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
GENERAL PLANES OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
NON-BONDED CONTACTS REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
NON-BONDED CONTACTS OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
NON-BONDED TORSION REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
NON-BONDED TORSION OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
H-BOND (X . . . Y) REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
H-BOND (X . . . Y) OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
POTENTIAL METAL-ION REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
POTENTIAL METAL-ION OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
SYMMETRY VDW REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
SYMMETRY VDW OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3
SYMMETRY H-BOND REFINED ATOMS
(A):
NULL ;
NULL ;
NULL

REMARK
3
SYMMETRY H-BOND OTHERS
(A):
NULL ;
NULL ;
NULL

REMARK
3

REMARK
3
ISOTROPIC THERMAL FACTOR RESTRAINTS.
COUNT
RMS
WEIGHT

REMARK
3
MAIN-CHAIN BOND REFINED ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
MAIN-CHAIN BOND OTHER ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
MAIN-CHAIN ANGLE REFINED ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
SIDE-CHAIN BOND REFINED ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
SIDE-CHAIN ANGLE REFINED ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3

REMARK
3
ANISOTROPIC THERMAL FACTOR RESTRAINTS.
COUNT
RMS
WEIGHT

REMARK
3
RIGID-BOND RESTRAINTS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
SPHERICITY; FREE ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3
SPHERICITY; BONDED ATOMS
(A**2):
NULL ;
NULL ;
NULL

REMARK
3

REMARK
3
NCS RESTRAINTS STATISTICS

REMARK
3
NUMBER OF DIFFERENT NCS GROUPS : 0

REMARK
3

REMARK
3
TLS DETAILS

REMARK
3
NUMBER OF TLS GROUPS : 0

REMARK
3

REMARK
3
BULK SOLVENT MODELLING.

REMARK
3
METHOD USED : NULL

REMARK
3
PARAMETERS FOR MASK CALCULATION

REMARK
3
VDW PROBE RADIUS
: NULL

REMARK
3
IO N PROBE RADIUS
: NULL

REMARK
3
SHRINKAGE RADIUS
: NULL

REMARK
3

REMARK
3
OTHER REFINEMENT REMARKS: NULL

REMARK
4

REMARK
4
1T15 COMPLIES WITH FORMAT V. 2.3, 09-JULY-1998

REMARK
100

REMARK
100
THIS ENTRY HAS BEEN PROCESSED BY RCSB ON 19-APR-2004.

REMARK
100
THE RCSB ID CODE IS RCSB022182.

REMARK
200

REMARK
200
EXPERIMENTAL DETAILS

REMARK
200
EXPERIMENT TYPE
: X-RAY DIFFRACTION

REMARK
200
DATE OF DATA COLLECTION
: 17-JAN-2004

REMARK
200
TEMPERATURE
(KELVIN)
: 100.0

REMARK
200
PH

: 6.50

REMARK
200
NUMBER OF CRYSTALS USED
: 1

REMARK
200

REMARK
200
SYNCHROTRON
(Y/N)
: N

REMARK
200
RADIATION SOURCE
: ROTATING ANODE

REMARK
200
BEAMLINE
: NULL

REMARK
200
X-RAY GENERATOR MODEL
: NULL

REMARK
200
MONOCHROMATIC OR LAUE
(M/L)
: M

REMARK
200
WAVELENGTH OR RANGE
(A)
: NULL

REMARK
200
MONOCHROMATOR
: NULL

REMARK
200
OPTICS
: NULL

REMARK
200

REMARK
200
DETECTOR TYPE
: IMAGE PLATE

REMARK
200
DETECTOR MANUFACTURER
: RIGAKU RAXIS II

REMARK
200
INTENSITY-INTEGRATION SOFTWARE
: DENZO

REMARK
200
DATA SCALING SOFTWARE
: SCALEPACK

REMARK
200

REMARK
200
NUMBER OF UNIQUE REFLECTIONS
: 19219

REMARK
200
RESOLUTION RANGE HIGH
(A)
: 1.850

REMARK
200
RESOLUTION RANGE LOW
(A)
: 15.000

REMARK
200
REJECTION CRITERIA
(SIGMA(I))
: 2.500

REMARK
200

REMARK
200
OVERALL.

REMARK
200
COMPLETENESS FOR RANGE
(%)
: 93.9

REMARK
200
DATA REDUNDANCY

: NULL

REMARK
200
R MERGE
(I)
: NULL

REMARK
200
R SYM
(I)
: NULL

REMARK
200
<I/SIGMA(I)> FOR THE DATA SET
: NULL

REMARK
200

REMARK
200
IN THE HIGHEST RESOLUTION SHELL.

REMARK
200
HIGHEST RESOLUTION SHELL, RANGE HIGH
(A)
: 1.85

REMARK
200
HIGHEST RESOLUTION SHELL, RANGE LOW
(A)
: 1.93

REMARK
200
COMPLETENESS FOR SHELL
(%)
: 76.8

REMARK
200
DATA REDUNDANCY IN SHELL

: NULL

REMARK
200
R MERGE FOR SHELL
(I)
: NULL

REMARK
200
R SYM FOR SHELL
(I)
: NULL

REMARK
200
<I/SIGMA(I)> FOR SHELL

: NULL

REMARK
200

REMARK
200
DIFFRACTION PROTOCOL: SINGLE WAVELENGTH

REMARK
200
METHOD USED TO DETERMINE THE STRUCTURE: MOLECULAR REPLACEMENT

REMARK
200
SOFTWARE USED: AMORE

REMARK
200
STARTING MODEL: NULL

REMARK
200

REMARK
200
REMARK: NULL

REMARK
280

REMARK
280
CRYSTAL

REMARK
280
SOLVENT CONTENT, VS (%): NULL

REMARK
280
MATTHEWS COEFFICIENT, VM (ANGSTROMS**3/DA): NULL

REMARK
280

REMARK
280
CRYSTALLIZATION CONDITIONS: PEG 8000, AMMONIUM SULPHATE, MES,

REMARK
280
PH 6.5, MICROBATCH, TEMPERATURE 291 K

REMARK
290

REMARK
290
CRYSTALLOGRAPHIC SYMMETRY

REMARK
290
SYMMETRY OPERATORS FOR SPACE GROUP: P 32 2 1

REMARK
290

REMARK
290
SYMOP
SYMMETRY

REMARK
290
NNNMMM
OPERATOR

REMARK
290
1555
X, Y, Z

REMARK
290
2555
−Y, X − Y, 2/3 + Z

REMARK
290
3555
−X + Y, −X, 1/3 + Z

REMARK
290
4555
Y, X, −Z

REMARK
290
5555
X − Y, −Y, 1/3 − Z

REMARK
290
6555
−X, −X + Y, 2/3 − Z

REMARK
290

REMARK
290
WHERE
NNN
-> OPERATOR NUMBER

REMARK
290

MMM
-> TRANSLATION VECTOR

REMARK
290

REMARK
290
CRYSTALLOGRAPHIC SYMMETRY TRANSFORMATIONS

REMARK
290
THE FOLLOWING TRANSFORMATIONS OPERATE ON THE ATOM/HETATM

REMARK
290
RECORDS IN THIS ENTRY TO PRODUCE CRYSTALLOGRAPHICALLY

REMARK
290
RELATED MOLECULES.

REMARK
290
SMTRY1
1
1.000000
0.000000
0.000000
0.00000

REMARK
290
SMTRY2
1
0.000000
1.000000
0.000000
0.00000

REMARK
290
SMTRY3
1
0.000000
0.000000
1.000000
0.00000

REMARK
290
SMTRY1
2
−0.500000
−0.866025
0.000000
0.00000

REMARK
290
SMTRY2
2
0.866025
−0.500000
0.000000
0.00000

REMARK
290
SMTRY3
2
0.000000
0.000000
1.000000
62.05000

REMARK
290
SMTRY1
3
−0.500000
0.866025
0.000000
0.00000

REMARK
290
SMTRY2
3
−0.866025
−0.500000
0.000000
0.00000

REMARK
290
SMTRY3
3
0.000000
0.000000
1.000000
31.02500

REMARK
290
SMTRY1
4
−0.500000
0.866025
0.000000
0.00000

REMARK
290
SMTRY2
4
0.866025
0.500000
0.000000
0.00000

REMARK
290
SMTRY3
4
0.000000
0.000000
−1.000000
0.00000

REMARK
290
SMTRY1
5
1.000000
0.000000
0.000000
0.00000

REMARK
290
SMTRY2
5
0.000000
−1.000000
0.000000
0.00000

REMARK
290
SMTRY3
5
0.000000
0.000000
−1.000000
31.02500

REMARK
290
SMTRY1
6
−0.500000
−0.866025
0.000000
0.00000

REMARK
290
SMTRY2
6
−0.866025
0.500000
0.000000
0.00000

REMARK
290
SMTRY3
6
0.000000
0.000000
−1.000000
62.05000

REMARK
290

REMARK
290
REMARK: NULL

REMARK
300

REMARK
300
BIOMOLECULE: 1

REMARK
300
THIS ENTRY CONTAINS THE CRYSTALLOGRAPHIC ASYMMETRIC UNIT

REMARK
300
WHICH CONSISTS OF 2 CHAIN(S). SEE REMARK 350 FOR

REMARK
300
INFORMATION ON GENERATING THE BIOLOGICAL MOLECULE(S).

REMARK
350

REMARK
350
GENERATING THE BIOMOLECULE

REMARK
350
COORDINATES FOR A COMPLETE MULTIMER REPRESENTING THE KNOWN

REMARK
350
BIOLOGICALLY SIGNIFICANT OLIGOMERIZATION STATE OF THE

REMARK
350
MOLECULE CAN BE GENERATED BY APPLYING BIOMT TRANSFORMATIONS

REMARK
350
GIVEN BELOW. BOTH NON-CRYSTALLOGRAPHIC AND

REMARK
350
CRYSTALLOGRAPHIC OPERATIONS ARE GIVEN.

REMARK
350

REMARK
350
BIOMOLECULE: 1

REMARK
350
APPLY THE FOLLOWING TO CHAINS: A, B

REMARK
350
BIOMT1
1
1.000000
0.000000
0.000000
0.00000

REMARK
350
BIOMT2
1
0.000000
1.000000
0.000000
0.00000

REMARK
350
BIOMT3
1
0.000000
0.000000
1.000000
0.00000

REMARK
465

REMARK
465
MISSING RESIDUES

REMARK
465
THE FOLLOWING RESIDUES WERE NOT LOCATED IN THE

REMARK
465
EXPERIMENT. (M = MODEL NUMBER; RES = RESIDUE NAME; C = CHAIN

REMARK
465
IDENTIFIER; SSSEQ = SEQUENCE NUMBER; I = INSERTION CODE.)

REMARK
465

REMARK
465
M
RES
C
SSSEQI

REMARK
465

VAL
A
1646

REMARK
465

ASN
A
1647

REMARK
465

LYS
A
1648

REMARK
470

REMARK
470
MISSING ATOM

REMARK
470
THE FOLLOWING RESIDUES HAVE MISSING ATOMS(M = MODEL NUMBER;

REMARK
470
RES = RESIDUE NAME; C = CHAIN IDENTIFIER; SSEQ = SEQUENCE NUMBER;

REMARK
470
I = INSERTION CODE):

REMARK
470
M
RES
CSSEQI
ATOMS

REMARK
470

GLU
A1817
CG
CD
OE1
OE2

REMARK
470

ASP
A1818
CG
OD1
OD2

REMARK
470

ASN
A1819
CG
OD1
ND2

REMARK
500

REMARK
500
GEOMETRY AND STEREOCHEMISTRY

REMARK
500
SUBTOPIC: CLOSE CONTACTS IN SAME ASYMMETRIC UNIT

REMARK
500

REMARK
500
THE FOLLOWING ATOMS ARE IN CLOSE CONTACT.

REMARK
500

REMARK
500
ATM1
RES
C
SSEQI
ATM2
RES C
SSEQI

REMARK
500
O
GLU
A
1660
O
HOH
154

2.13

DBREF
1T15
A
1649
1859
SWS
P38398
BRC1_HUMAN
1649
1859

DBREF
1T15
B
6
13
GB
14042978
NP_114432
988
995

SEQADV
1T15
SEP B 8 GB 14042978 SER 990 MODIFIED RESIDUE

SEQRES
1
A
214
VAL
ASN
LYS
ARG
MET
SER
MET
VAL
VAL
SER
GLY
LEU
THR

SEQRES
2
A
214
PRO
GLU
GLU
PHE
MET
LEU
VAL
TYR
LYS
PHE
ALA
ARG
LYS

SEQRES
3
A
214
HIS
HIS
ILE
THR
LEU
THR
ASN
LEU
ILE
THR
GLU
GLU
THR

SEQRES
4
A
214
THR
HIS
VAL
VAL
MET
LYS
THR
ASP
ALA
GLU
PHE
VAL
CYS

SEQRES
5
A
214
GLU
ARG
THR
LEU
LYS
TYR
PHE
LEU
GLY
ILE
ALA
GLY
GLY

SEQRES
6
A
214
LYS
TRP
VAL
VAL
SER
TYR
PHE
TRP
VAL
THR
GLN
SER
ILE

SEQRES
7
A
214
LYS
GLU
ARG
LYS
MET
LEU
ASN
GLU
HIS
ASP
PHE
GLU
VAL

SEQRES
8
A
214
ARG
GLY
ASP
VAL
VAL
ASN
GLY
ARG
ASN
HIS
GLN
GLY
PRO

SEQRES
9
A
214
LYS
ARG
ALA
ARG
GLU
SER
GLN
ASP
ARG
LYS
ILE
PHE
ARG

SEQRES
10
A
214
GLY
LEU
GLU
ILE
CYS
CYS
TYR
GLY
PRO
PHE
THR
ASN
MET

SEQRES
11
A
214
PRO
THR
ASP
GLN
LEU
GLU
TRP
MET
VAL
GLN
LEU
CYS
GLY

SEQRES
12
A
214
ALA
SER
VAL
VAL
LYS
GLU
LEU
SER
SER
PHE
THR
LEU
GLY

SEQRES
13
A
214
THR
GLY
VAL
HIS
PRO
ILE
VAL
VAL
VAL
GLN
PRO
ASP
ALA

SEQRES
14
A
214
TRP
THR
GLU
ASP
ASN
GLY
PHE
HIS
ALA
ILE
GLY
GLN
MET

SEQRES
15
A
214
CYS
GLU
ALA
PRO
VAL
VAL
THR
ARG
GLU
TRP
VAL
LEU
ASP

SEQRES
16
A
214
SER
VAL
ALA
LEU
TYR
GLN
CYS
GLN
GLU
LEU
ASP
THR
TYR

SEQRES
17
A
214
LEU
ILE
PRO
GLN
ILE
PRO

SEQRES
1
B
8
SER
THR
SEP
PRO
THR
PHE
ASN
LYS

MODRES
1T15
SEP B
8
SER
PHOSPHOSERINE

HET
SEP
B
8

10

HETNAM
SEP
PHOSPHOSERINE

HETSYN
SEP
PHOSPHONOSERINE

FORMUL
2
SEP
C3H8N1O6P1

FORMUL
3
HOH
*156(H2O1)

HELIX
1
1
THR
A
1658
HIS
A
1673
1

16

HELIX
2
2
THR
A
1700
GLY
A
1709
1

10

HELIX
3
3
TYR
A
1716
GLU
A
1725
1

10

HELIX
4
4
ASN
A
1730
GLU
A
1735
5

6

HELIX
5
5
GLN
A
1747
GLU
A
1754
1

8

HELIX
6
6
PRO
A
1776
CYS
A
1787
1

12

HELIX
7
7
GLU
A
1794
PHE
A
1798
5

5

HELIX
8
8
GLN
A
1811
TRP
A
1815
5

5

HELIX
9
9
ASP
A
1818
ALA
A
1823
5

6

HELIX
10
10
ARG
A
1835
TYR
A
1845
1

11

HELIX
11
11
LEU
A
1850
LEU
A
1854
5

5

SHEET
1
A
4
THR
A1675
LEU
A1676
0

SHEET
2
A
4
SER
A1651
SER
A1655
1
N
MET
A1652
O
THR
A1675

SHEET
3
A
4
HIS
A1686
MET
A1689
1
O
VAL
A1688
N
VAL
A1653

SHEET
4
A
4
TRP
A1712
SER
A1715
1
O
TRP
A1712
N
VAL
A1687

SHEET
1
B
2
VAL
A1696
CYS
A1697
0

SHEET
2
B
2
GLY
A1738
ASP
A1739
1
O
GLY
A1738
N
CYS
A1697

SHEET
1
C
4
SER
A1790
VAL
A1791
0

SHEET
2
C
4
GLU
A1765
CYS
A1768
1
N
ILE
A1766
O
SER
A1790

SHEET
3
C
4
PRO
A1806
VAL
A1810
1
O
VAL
A1809
N
CYS
A1767

SHEET
4
C
4
VAL
A1832
THR
A1834
1
O
VAL
A1833
N
VAL
A1808

CISPEP
1
GLY
A
1770
PRO A 1771
0
6.36

CRYST1
65.837 65.837 93.075 90.00 90.00 120.00 P 32 2 1
6

ORIGX1
1.000000
0.000000
0.000000
0.00000

ORIGX2
0.000000
1.000000
0.000000
0.00000

ORIGX3
0.000000
0.000000
1.000000
0.00000

SCALE1
0.015189
0.008769
0.000000
0.00000

SCALE2
0.000000
0.017539
0.000000
0.00000

SCALE3
0.000000
0.000000
0.010744
0.00000

1ATOM
1
N
ARG
A
1649
21.350
25.980
38.428
1.00
37.86
N

ATOM
2
CA
ARG
A
1649
21.167
25.508
37.034
1.00
38.58
C

ATOM
3
C
ARG
A
1649
19.696
25.211
36.751
1.00
37.92
C

ATOM
4
O
ARG
A
1649
18.984
26.111
36.309
1.00
39.23
O

ATOM
5
CB
ARG
A
1649
22.041
24.284
36.737
1.00
38.99
C

ATOM
6
CG
ARG
A
1649
22.206
24.018
35.247
1.00
40.19
C

ATOM
7
CD
ARG
A
1649
23.156
24.960
34.544
1.00
41.68
C

ATOM
8
NE
ARG
A
1649
24.532
24.465
34.472
1.00
41.02
N

ATOM
9
CZ
ARG
A
1649
24.900
23.213
34.666
1.00
42.27
C

ATOM
10
NH1
ARG
A
1649
24.012
22.284
34.973
1.00
47.29
N

ATOM
11
NH2
ARG
A
1649
26.165
22.886
34.560
1.00
44.76
N

ATOM
12
N
MET
A
1650
19.253
23.967
37.004
1.00
36.61
N

ATOM
13
CA
MET
A
1650
17.864
23.524
36.769
1.00
34.88
C

ATOM
14
C
MET
A
1650
17.116
23.314
38.097
1.00
32.87
C

ATOM
15
O
MET
A
1650
17.716
22.872
39.078
1.00
33.22
O

ATOM
16
CB
MET
A
1650
17.823
22.184
36.015
1.00
35.73
C

ATOM
17
CG
MET
A
1650
18.760
22.063
34.822
1.00
39.54
C

ATOM
18
SD
MET
A
1650
18.701
20.447
33.985
1.00
47.40
S

ATOM
19
CE
MET
A
1650
17.014
19.948
34.263
1.00
43.86
C

ATOM
20
N
SER
A
1651
15.816
23.610
38.127
1.00
29.05
N

ATOM
21
CA
SER
A
1651
15.013
23.420
39.339
1.00
25.47
C

ATOM
22
C
SER
A
1651
13.556
23.243
38.904
1.00
24.50
C

ATOM
23
O
SER
A
1651
12.987
24.147
38.272
1.00
23.29
O

ATOM
24
CB
SER
A
1651
15.169
24.634
40.254
1.00
25.05
C

ATOM
25
OG
SER
A
1651
14.285
24.568
41.357
1.00
23.07
O

ATOM
26
N
MET
A
1652
12.958
22.099
39.240
1.00
23.28
N

ATOM
27
CA
MET
A
1652
11.609
21.768
38.746
1.00
22.67
C

ATOM
28
C
MET
A
1652
10.503
21.815
39.789
1.00
21.96
C

ATOM
29
O
MET
A
1652
10.752
21.600
40.963
1.00
21.38
O

ATOM
30
CB
MET
A
1652
11.582
20.346
38.170
1.00
22.94
C

ATOM
31
CG
MET
A
1652
12.716
19.972
37.236
1.00
26.44
C

ATOM
32
SD
MET
A
1652
12.543
18.260
36.657
1.00
29.06
S

ATOM
33
CE
MET
A
1652
12.877
17.308
38.164
1.00
29.60
C

ATOM
34
N
VAL
A
1653
9.280
22.103
39.333
1.00
21.77
N

ATOM
35
CA
VAL
A
1653
8.073
21.861
40.127
1.00
21.44
C

ATOM
36
C
VAL
A
1653
7.194
21.046
39.176
1.00
21.79
C

ATOM
37
O
VAL
A
1653
7.462
21.019
37.972
1.00
21.55
O

ATOM
38
CB
VAL
A
1653
7.348
23.124
40.597
1.00
21.82
C

ATOM
39
CG1
VAL
A
1653
8.236
23.964
41.512
1.00
21.08
C

ATOM
40
CG2
VAL
A
1653
6.869
23.986
39.400
1.00
21.69
C

ATOM
41
N
VAL
A
1654
6.174
20.374
39.710
1.00
22.15
N

ATOM
42
CA
VAL
A
1654
5.236
19.649
38.874
1.00
21.91
C

ATOM
43
C
VAL
A
1654
3.844
20.185
39.150
1.00
21.96
C

ATOM
44
O
VAL
A
1654
3.604
20.860
40.170
1.00
22.10
O

ATOM
45
CB
VAL
A
1654
5.243
18.129
39.137
1.00
22.11
C

ATOM
46
CG1
VAL
A
1654
6.635
17.546
38.954
1.00
21.48
C

ATOM
47
CG2
VAL
A
1654
4.613
17.772
40.509
1.00
21.70
C

ATOM
48
N
SER
A
1655
2.921
19.914
38.237
1.00
22.52
N

ATOM
49
CA
SER
A
1655
1.561
20.390
38.429
1.00
23.73
C

ATOM
50
C
SER
A
1655
0.600
19.446
37.735
1.00
24.21
C

ATOM
51
O
SER
A
1655
0.874
18.984
36.633
1.00
23.50
O

ATOM
52
CB
SER
A
1655
1.418
21.804
37.847
1.00
23.91
C

ATOM
53
OG
SER
A
1655
0.090
22.280
37.999
1.00
25.27
O

ATOM
54
N
GLY
A
1656
−0.511
19.142
38.390
1.00
25.03
N

ATOM
55
CA
GLY
A
1656
−1.515
18.293
37.784
1.00
26.90
C

ATOM
56
C
GLY
A
1656
−1.231
16.813
37.896
1.00
28.26
C

ATOM
57
O
GLY
A
1656
−1.951
16.007
37.322
1.00
28.33
O

ATOM
58
N
LEU
A
1657
−0.180
16.441
38.624
1.00
29.57
N

ATOM
59
CA
LEU
A
1657
0.151
15.039
38.777
1.00
31.48
C

ATOM
60
C
LEU
A
1657
−0.445
14.481
40.049
1.00
33.40
C

ATOM
61
O
LEU
A
1657
−0.551
15.187
41.046
1.00
33.77
O

ATOM
62
CB
LEU
A
1657
1.669
14.835
38.880
1.00
31.30
C

ATOM
63
CG
LEU
A
1657
2.557
15.339
37.751
1.00
29.72
C

ATOM
64
CD1
LEU
A
1657
3.959
14.805
37.938
1.00
27.61
C

ATOM
65
CD2
LEU
A
1657
1.962
14.855
36.430
1.00
31.43
C

ATOM
66
N
THR
A
1658
−0.788
13.205
40.012
1.00
35.92
N

ATOM
67
CA
THR
A
1658
−1.191
12.497
41.217
1.00
38.84
C

ATOM
68
C
THR
A
1658
0.057
12.373
42.092
1.00
40.25
C

ATOM
69
O
THR
A
1658
1.182
12.411
41.579
1.00
40.34
O

ATOM
70
CB
THR
A
1658
−1.622
11.102
40.860
1.00
38.58
C

ATOM
71
OG1
THR
A
1658
−0.515
10.438
40.250
1.00
41.39
O

ATOM
72
CG2
THR
A
1658
−2.657
11.119
39.761
1.00
38.93
C

ATOM
73
N
PRO
A
1659
−0.140
12.210
43.400
1.00
41.63
N

ATOM
74
CA
PRO
A
1659
0.957
12.021
44.353
1.00
42.36
C

ATOM
75
C
PRO
A
1659
1.924
10.967
43.837
1.00
43.26
C

ATOM
76
O
PRO
A
1659
3.126
11.067
44.074
1.00
43.63
O

ATOM
77
CB
PRO
A
1659
0.231
11.484
45.590
1.00
42.81
C

ATOM
78
CG
PRO
A
1659
−1.089
12.163
45.531
1.00
41.97
C

ATOM
79
CD
PRO
A
1659
−1.456
12.197
44.067
1.00
41.96
C

ATOM
80
N
GLU
A
1660
1.389
9.970
43.137
1.00
43.67
N

ATOM
81
CA
GLU
A
1660
2.188
8.905
42.561
1.00
44.09
C

ATOM
82
C
GLU
A
1660
3.084
9.406
41.447
1.00
44.00
C

ATOM
83
O
GLU
A
1660
4.296
9.177
41.457
1.00
44.31
O

ATOM
84
CB
GLU
A
1660
1.269
7.843
41.965
1.00
44.71
C

ATOM
85
CG
GLU
A
1660
1.888
7.156
40.761
1.00
47.07
C

ATOM
86
CD
GLU
A
1660
1.029
6.047
40.195
1.00
52.07
C

ATOM
87
OE1
GLU
A
1660
0.453
5.268
40.994
1.00
53.23
O

ATOM
88
OE2
GLU
A
1660
0.944
5.952
38.946
1.00
54.35
O

ATOM
89
N
GLU
A
1661
2.471
10.056
40.458
1.00
43.83
N

ATOM
90
CA
GLU
A
1661
3.201
10.544
39.293
1.00
43.45
C

ATOM
91
C
GLU
A
1661
4.341
11.405
39.783
1.00
42.90
C

ATOM
92
O
GLU
A
1661
5.428
11.398
39.210
1.00
43.62
O

ATOM
93
CB
GLU
A
1661
2.274
11.303
38.321
1.00
43.46
C

ATOM
94
CG
GLU
A
1661
1.496
10.413
37.354
1.00
44.55
C

ATOM
95
CD
GLU
A
1661
0.316
11.125
36.703
1.00
45.20
C

ATOM
96
OE1
GLU
A
1661
−0.205
12.081
37.309
1.00
45.12
O

ATOM
97
OE2
GLU
A
1661
−0.092
10.731
35.586
1.00
46.89
O

ATOM
98
N
PHE
A
1662
4.094
12.136
40.861
1.00
41.91
N

ATOM
99
CA
PHE
A
1662
5.119
12.949
41.478
1.00
42.12
C

ATOM
100
C
PHE
A
1662
6.268
12.034
41.906
1.00
41.38
C

ATOM
101
O
PHE
A
1662
7.423
12.448
41.923
1.00
40.80
O

ATOM
102
CB
PHE
A
1662
4.549
13.703
42.691
1.00
41.81
C

ATOM
103
CG
PHE
A
1662
5.567
14.513
43.442
1.00
44.40
C

ATOM
104
CD1
PHE
A
1662
6.062
15.689
42.920
1.00
44.89
C

ATOM
105
CD2
PHE
A
1662
6.034
14.093
44.671
1.00
45.16
C

ATOM
106
CE1
PHE
A
1662
6.994
16.427
43.606
1.00
46.33
C

ATOM
107
CE2
PHE
A
1662
6.966
14.816
45.361
1.00
45.74
C

ATOM
108
CZ
PHE
A
1662
7.452
15.993
44.830
1.00
46.57
C

ATOM
109
N
MET
A
1663
5.941
10.789
42.236
1.00
40.93
N

ATOM
110
CA
MET
A
1663
6.961
9.863
42.724
1.00
40.79
C

ATOM
111
C
MET
A
1663
7.881
9.337
41.619
1.00
39.37
C

ATOM
112
O
MET
A
1663
9.041
9.047
41.875
1.00
39.10
O

ATOM
113
CB
MET
A
1663
6.328
8.764
43.579
1.00
41.63
C

ATOM
114
CG
MET
A
1663
5.566
9.346
44.780
1.00
44.48
C

ATOM
115
SD
MET
A
1663
6.021
11.127
45.033
1.00
54.98
S

ATOM
116
CE
MET
A
1663
5.163
11.565
46.534
1.00
49.27
C

ATOM
117
N
LEU
A
1664
7.383
9.257
40.386
1.00
38.10
N

ATOM
118
CA
LEU
A
1664
8.242
8.893
39.269
1.00
36.62
C

ATOM
119
C
LEU
A
1664
9.166
10.076
38.963
1.00
35.32
C

ATOM
120
O
LEU
A
1664
10.353
9.882
38.687
1.00
35.19
O

ATOM
121
CB
LEU
A
1664
7.444
8.510
38.023
1.00
36.87
C

ATOM
122
CG
LEU
A
1664
6.989
7.054
37.865
1.00
38.76
C

ATOM
123
CD1
LEU
A
1664
5.785
6.970
36.936
1.00
39.32
C

ATOM
124
CD2
LEU
A
1664
8.138
6.155
37.371
1.00
40.42
C

ATOM
125
N
VAL
A
1665
8.623
11.294
39.025
1.00
33.46
N

ATOM
126
CA
VAL
A
1665
9.435
12.498
38.823
1.00
31.56
C

ATOM
127
C
VAL
A
1665
10.462
12.593
39.931
1.00
31.17
C

ATOM
128
O
VAL
A
1665
11.626
12.971
39.716
1.00
29.16
O

ATOM
129
CB
VAL
A
1665
8.601
13.787
38.830
1.00
32.18
C

ATOM
130
CG1
VAL
A
1665
9.514
15.015
38.599
1.00
29.50
C

ATOM
131
CG2
VAL
A
1665
7.528
13.727
37.769
1.00
31.04
C

ATOM
132
N
TYR
A
1666
10.035
12.225
41.128
1.00
30.24
N

ATOM
133
CA
TYR
A
1666
10.951
12.266
42.253
1.00
30.74
C

ATOM
134
C
TYR
A
1666
12.106
11.278
42.039
1.00
29.52
C

ATOM
135
O
TYR
A
1666
13.252
11.604
42.324
1.00
28.12
O

ATOM
136
CB
TYR
A
1666
10.237
11.948
43.558
1.00
32.14
C

ATOM
137
CG
TYR
A
1666
11.208
11.829
44.710
1.00
36.82
C

ATOM
138
CD1
TYR
A
1666
11.495
12.920
45.512
1.00
41.37
C

ATOM
139
CD2
TYR
A
1666
11.851
10.624
44.981
1.00
42.59
C

ATOM
140
CE1
TYR
A
1666
12.380
12.816
46.558
1.00
45.38
C

ATOM
141
CE2
TYR
A
1666
12.741
10.513
46.026
1.00
45.18
C

ATOM
142
CZ
TYR
A
1666
12.999
11.617
46.809
1.00
46.15
C

ATOM
143
OH
TYR
A
1666
13.882
11.544
47.858
1.00
49.62
O

ATOM
144
N
LYS
A
1667
11.792
10.085
41.541
1.00
29.17
N

ATOM
145
CA
LYS
A
1667
12.823
9.070
41.263
1.00
29.54
C

ATOM
146
C
LYS
A
1667
13.807
9.593
40.217
1.00
28.96
C

ATOM
147
O
LYS
A
1667
15.026
9.510
40.394
1.00
28.65
O

ATOM
148
CB
LYS
A
1667
12.174
7.756
40.819
1.00
30.32
C

ATOM
149
CG
LYS
A
1667
13.145
6.604
40.600
1.00
33.53
C

ATOM
150
CD
LYS
A
1667
12.516
5.477
39.763
1.00
37.99
C

ATOM
151
CE
LYS
A
1667
13.599
4.737
38.953
1.00
40.33
C

ATOM
152
NZ
LYS
A
1667
13.069
3.904
37.815
1.00
43.44
N

ATOM
153
N
PHE
A
1668
13.249
10.137
39.137
1.00
28.47
N

ATOM
154
CA
PHE
A
1668
13.986
10.780
38.054
1.00
27.75
C

ATOM
155
C
PHE
A
1668
14.944
11.880
38.550
1.00
27.27
C

ATOM
156
O
PHE
A
1668
16.136
11.869
38.220
1.00
25.79
O

ATOM
157
CB
PHE
A
1668
12.979
11.364
37.057
1.00
28.54
C

ATOM
158
CG
PHE
A
1668
13.594
12.000
35.836
1.00
28.84
C

ATOM
159
CD1
PHE
A
1668
14.241
11.237
34.875
1.00
32.22
C

ATOM
160
CD2
PHE
A
1668
13.470
13.352
35.630
1.00
31.36
C

ATOM
161
CE1
PHE
A
1668
14.777
11.837
33.750
1.00
32.35
C

ATOM
162
CE2
PHE
A
1668
14.000
13.943
34.508
1.00
32.38
C

ATOM
163
CZ
PHE
A
1668
14.662
13.178
33.578
1.00
31.43
C

ATOM
164
N
ALA
A
1669
14.424
12.810
39.349
1.00
25.62
N

ATOM
165
CA
ALA
A
1669
15.227
13.909
39.883
1.00
26.14
C

ATOM
166
C
ALA
A
1669
16.342
13.397
40.770
1.00
26.42
C

ATOM
167
O
ALA
A
1669
17.444
13.917
40.744
1.00
27.04
O

ATOM
168
CB
ALA
A
1669
14.358
14.888
40.681
1.00
25.21
C

ATOM
169
N
ARG
A
1670
16.027
12.413
41.595
1.00
26.98
N

ATOM
170
CA
ARG
A
1670
17.024
11.836
42.493
1.00
27.64
C

ATOM
171
C
ARG
A
1670
18.174
11.241
41.674
1.00
27.68
C

ATOM
172
O
ARG
A
1670
19.340
11.460
41.976
1.00
27.31
O

ATOM
173
CB
ARG
A
1670
16.346
10.771
43.343
1.00
28.45
C

ATOM
174
CG
ARG
A
1670
17.214
10.070
44.348
1.00
30.59
C

ATOM
175
CD
ARG
A
1670
16.421
9.137
45.243
1.00
35.94
C

ATOM
176
NE
ARG
A
1670
17.245
8.595
46.310
1.00
37.87
N

ATOM
177
CZ
ARG
A
1670
17.559
9.244
47.424
1.00
38.30
C

ATOM
178
NH1
ARG
A
1670
17.115
10.473
47.641
1.00
37.07
N

ATOM
179
NH2
ARG
A
1670
18.314
8.644
48.333
1.00
38.27
N

ATOM
180
N
LYS
A
1671
17.831
10.488
40.634
1.00
27.51
N

ATOM
181
CA
LYS
A
1671
18.830
9.814
39.823
1.00
28.46
C

ATOM
182
C
LYS
A
1671
19.742
10.798
39.104
1.00
27.96
C

ATOM
183
O
LYS
A
1671
20.948
10.602
39.043
1.00
27.41
O

ATOM
184
CB
LYS
A
1671
18.150
8.903
38.799
1.00
28.67
C

ATOM
185
CG
LYS
A
1671
19.057
8.452
37.645
1.00
30.60
C

ATOM
186
CD
LYS
A
1671
18.286
7.499
36.740
1.00
33.67
C

ATOM
187
CE
LYS
A
1671
19.181
6.743
35.765
1.00
37.14
C

ATOM
188
NZ
LYS
A
1671
18.327
5.889
34.877
1.00
40.72
N

ATOM
189
N
HIS
A
1672
19.156
11.871
38.579
1.00
27.95
N

ATOM
190
CA
HIS
A
1672
19.902
12.817
37.776
1.00
27.74
C

ATOM
191
C
HIS
A
1672
20.394
14.032
38.551
1.00
27.28
C

ATOM
192
O
HIS
A
1672
20.975
14.940
37.971
1.00
27.32
O

ATOM
193
CB
HIS
A
1672
19.064
13.248
36.571
1.00
28.24
C

ATOM
194
CG
HIS
A
1672
18.831
12.144
35.585
1.00
30.19
C

ATOM
195
ND1
HIS
A
1672
19.854
11.575
34.856
1.00
30.35
N

ATOM
196
CD2
HIS
A
1672
17.699
11.496
35.218
1.00
30.89
C

ATOM
197
CE1
HIS
A
1672
19.359
10.631
34.072
1.00
32.84
C

ATOM
198
NE2
HIS
A
1672
18.055
10.558
34.278
1.00
29.45
N

ATOM
199
N
HIS
A
1673
20.139
14.040
39.854
1.00
27.33
N

ATOM
200
CA
HIS
A
1673
20.579
15.125
40.716
1.00
27.56
C

ATOM
201
C
HIS
A
1673
20.016
16.447
40.211
1.00
26.59
C

ATOM
202
O
HIS
A
1673
20.742
17.422
40.081
1.00
26.83
O

ATOM
203
CB
HIS
A
1673
22.105
15.190
40.784
1.00
27.91
C

ATOM
204
CG
HIS
A
1673
22.627
15.924
41.984
1.00
29.65
C

ATOM
205
ND1
HIS
A
1673
22.540
15.415
43.261
1.00
31.89
N

ATOM
206
CD2
HIS
A
1673
23.235
17.127
42.101
1.00
31.98
C

ATOM
207
CE1
HIS
A
1673
23.076
16.270
44.116
1.00
29.99
C

ATOM
208
NE2
HIS
A
1673
23.506
17.316
43.438
1.00
32.36
N

ATOM
209
N
ILE
A
1674
18.723
16.431
39.893
1.00
26.22
N

ATOM
210
CA
ILE
A
1674
17.985
17.620
39.472
1.00
25.06
C

ATOM
211
C
ILE
A
1674
17.207
18.150
40.668
1.00
23.96
C

ATOM
212
O
ILE
A
1674
16.556
17.391
41.375
1.00
24.12
O

ATOM
213
CB
ILE
A
1674
16.976
17.245
38.356
1.00
25.75
C

ATOM
214
CG1
ILE
A
1674
17.681
16.534
37.193
1.00
26.59
C

ATOM
215
CG2
ILE
A
1674
16.239
18.495
37.847
1.00
26.27
C

ATOM
216
CD1
ILE
A
1674
16.718
16.040
36.103
1.00
28.27
C

ATOM
217
N
THR
A
1675
17.253
19.450
40.882
1.00
22.45
N

ATOM
218
CA
THR
A
1675
16.485
20.059
41.959
1.00
22.35
C

ATOM
219
C
THR
A
1675
14.987
19.928
41.677
1.00
22.01
C

ATOM
220
O
THR
A
1675
14.535
20.297
40.604
1.00
21.54
O

ATOM
221
CB
THR
A
1675
16.885
21.538
42.079
1.00
22.30
C

ATOM
222
OG1
THR
A
1675
18.262
21.649
42.480
1.00
23.67
O

ATOM
223
CG2
THR
A
1675
16.135
22.216
43.198
1.00
21.79
C

ATOM
224
N
LEU
A
1676
14.241
19.390
42.636
1.00
21.51
N

ATOM
225
CA
LEU
A
1676
12.798
19.250
42.545
1.00
21.73
C

ATOM
226
C
LEU
A
1676
12.184
19.848
43.821
1.00
21.93
C

ATOM
227
O
LEU
A
1676
12.568
19.463
44.928
1.00
21.14
O

ATOM
228
CB
LEU
A
1676
12.409
17.770
42.430
1.00
22.01
C

ATOM
229
CG
LEU
A
1676
10.926
17.437
42.592
1.00
22.31
C

ATOM
230
CD1
LEU
A
1676
10.079
18.140
41.503
1.00
24.34
C

ATOM
231
CD2
LEU
A
1676
10.676
15.920
42.607
1.00
22.73
C

ATOM
232
N
THR
A
1677
11.238
20.768
43.675
1.00
21.24
N

ATOM
233
CA
THR
A
1677
10.585
21.362
44.839
1.00
21.58
C

ATOM
234
C
THR
A
1677
9.065
21.271
44.704
1.00
21.67
C

ATOM
235
O
THR
A
1677
8.558
20.984
43.628
1.00
20.01
O

ATOM
236
CB
THR
A
1677
10.988
22.842
45.014
1.00
22.16
C

ATOM
237
OG1
THR
A
1677
10.362
23.634
43.998
1.00
25.10
O

ATOM
238
CG2
THR
A
1677
12.504
23.081
44.774
1.00
21.94
C

ATOM
239
N
ASN
A
1678
8.343
21.536
45.790
1.00
21.90
N

ATOM
240
CA
ASN
A
1678
6.887
21.534
45.746
1.00
23.71
C

ATOM
241
C
ASN
A
1678
6.299
22.921
45.458
1.00
24.19
C

ATOM
242
O
ASN
A
1678
5.175
23.041
44.968
1.00
25.65
O

ATOM
243
CB
ASN
A
1678
6.313
20.974
47.063
1.00
24.23
C

ATOM
244
CG
ASN
A
1678
6.673
21.839
48.285
1.00
24.68
C

ATOM
245
OD1
ASN
A
1678
7.688
22.559
48.296
1.00
22.56
O

ATOM
246
ND2
ASN
A
1678
5.842
21.767
49.321
1.00
25.85
N

ATOM
247
N
LEU
A
1679
7.063
23.958
45.767
1.00
24.17
N

ATOM
248
CA
LEU
A
1679
6.622
25.332
45.559
1.00
24.50
C

ATOM
249
C
LEU
A
1679
7.396
26.005
44.427
1.00
24.20
C

ATOM
250
O
LEU
A
1679
8.614
25.849
44.324
1.00
23.42
O

ATOM
251
CB
LEU
A
1679
6.803
26.146
46.850
1.00
25.12
C

ATOM
252
CG
LEU
A
1679
6.031
25.602
48.074
1.00
26.29
C

ATOM
253
CD1
LEU
A
1679
6.105
26.558
49.255
1.00
25.56
C

ATOM
254
CD2
LEU
A
1679
4.580
25.315
47.706
1.00
25.75
C

ATOM
255
N
ILE
A
1680
6.691
26.753
43.581
1.00
23.41
N

ATOM
256
CA
ILE
A
1680
7.349
27.455
42.495
1.00
23.78
C

ATOM
257
C
ILE
A
1680
7.921
28.780
43.027
1.00
24.30
C

ATOM
258
O
ILE
A
1680
7.326
29.418
43.904
1.00
23.93
O

ATOM
259
CB
ILE
A
1680
6.342
27.681
41.338
1.00
23.69
C

ATOM
260
CG1
ILE
A
1680
7.072
28.148
40.073
1.00
24.57
C

ATOM
261
CG2
ILE
A
1680
5.259
28.658
41.755
1.00
24.87
C

ATOM
262
CD1
ILE
A
1680
6.156
28.205
38.857
1.00
25.47
C

ATOM
263
N
THR
A
1681
9.097
29.157
42.541
1.00
24.43
N

ATOM
264
CA
THR
A
1681
9.762
30.395
42.951
1.00
25.11
C

ATOM
265
C
THR
A
1681
10.402
31.007
41.741
1.00
26.01
C

ATOM
266
O
THR
A
1681
10.366
30.429
40.676
1.00
25.92
O

ATOM
267
CB
THR
A
1681
10.917
30.103
43.930
1.00
24.96
C

ATOM
268
OG1
THR
A
1681
11.958
29.408
43.239
1.00
24.12
O

ATOM
269
CG2
THR
A
1681
10.490
29.130
45.002
1.00
24.40
C

ATOM
270
N
GLU
A
1682
11.071
32.142
41.921
1.00
27.46
N

ATOM
271
CA
GLU
A
1682
11.794
32.757
40.814
1.00
28.87
C

ATOM
272
C
GLU
A
1682
12.905
31.869
40.291
1.00
28.73
C

ATOM
273
O
GLU
A
1682
13.289
31.986
39.130
1.00
29.06
O

ATOM
274
CB
GLU
A
1682
12.405
34.085
41.248
1.00
29.96
C

ATOM
275
CG
GLU
A
1682
11.575
34.801
42.284
1.00
34.86
C

ATOM
276
CD
GLU
A
1682
11.797
34.244
43.680
1.00
39.53
C

ATOM
277
OE1
GLU
A
1682
12.877
34.510
44.255
1.00
45.24
O

ATOM
278
OE2
GLU
A
1682
10.906
33.551
44.201
1.00
39.80
O

ATOM
279
N
GLU
A
1683
13.447
31.002
41.143
1.00
27.80
N

ATOM
280
CA
GLU
A
1683
14.544
30.121
40.732
1.00
27.27
C

ATOM
281
C
GLU
A
1683
14.105
28.885
39.941
1.00
25.48
C

ATOM
282
O
GLU
A
1683
14.913
28.218
39.297
1.00
24.53
O

ATOM
283
CB
GLU
A
1683
15.384
29.710
41.944
1.00
28.00
C

ATOM
284
CG
GLU
A
1683
16.135
30.882
42.565
1.00
32.38
C

ATOM
285
CD
GLU
A
1683
15.242
31.826
43.357
1.00
38.54
C

ATOM
286
OE1
GLU
A
1683
14.320
31.343
44.041
1.00
40.84
O

ATOM
287
OE2
GLU
A
1683
15.469
33.061
43.313
1.00
41.64
O

ATOM
288
N
THR
A
1684
12.828
28.571
39.988
1.00
23.79
N

ATOM
289
CA
THR
A
1684
12.323
27.450
39.200
1.00
22.59
C

ATOM
290
C
THR
A
1684
12.605
27.689
37.725
1.00
22.04
C

ATOM
291
O
THR
A
1684
12.392
28.788
37.230
1.00
21.76
O

ATOM
292
CB
THR
A
1684
10.828
27.366
39.394
1.00
22.67
C

ATOM
293
OG1
THR
A
1684
10.549
27.162
40.788
1.00
22.03
O

ATOM
294
CG2
THR
A
1684
10.243
26.126
38.640
1.00
21.28
C

ATOM
295
N
THR
A
1685
13.111
26.671
37.037
1.00
22.20
N

ATOM
296
CA
THR
A
1685
13.356
26.759
35.619
1.00
22.50
C

ATOM
297
C
THR
A
1685
12.339
25.966
34.804
1.00
22.65
C

ATOM
298
O
THR
A
1685
12.127
26.270
33.629
1.00
22.47
O

ATOM
299
CB
THR
A
1685
14.743
26.231
35.282
1.00
22.28
C

ATOM
300
OG1
THR
A
1685
14.893
24.913
35.814
1.00
24.12
O

ATOM
301
CG2
THR
A
1685
15.841
27.089
35.989
1.00
22.27
C

ATOM
302
N
HIS
A
1686
11.735
24.949
35.425
1.00
22.23
N

ATOM
303
CA
HIS
A
1686
10.856
24.014
34.729
1.00
22.29
C

ATOM
304
C
HIS
A
1686
9.590
23.729
35.498
1.00
22.24
C

ATOM
305
O
HIS
A
1686
9.631
23.463
36.700
1.00
22.44
O

ATOM
306
CB
HIS
A
1686
11.529
22.643
34.547
1.00
21.81
C

ATOM
307
CG
HIS
A
1686
12.730
22.639
33.659
1.00
23.25
C

ATOM
308
ND1
HIS
A
1686
13.907
23.282
33.983
1.00
24.02
N

ATOM
309
CD2
HIS
A
1686
12.960
22.008
32.484
1.00
23.85
C

ATOM
310
CE1
HIS
A
1686
14.794
23.083
33.026
1.00
24.09
C

ATOM
311
NE2
HIS
A
1686
14.249
22.303
32.110
1.00
24.68
N

ATOM
312
N
VAL
A
1687
8.455
23.760
34.800
1.00
21.33
N

ATOM
313
CA
VAL
A
1687
7.193
23.413
35.404
1.00
20.85
C

ATOM
314
C
VAL
A
1687
6.746
22.190
34.611
1.00
21.60
C

ATOM
315
O
VAL
A
1687
6.501
22.287
33.410
1.00
21.78
O

ATOM
316
CB
VAL
A
1687
6.140
24.545
35.251
1.00
21.45
C

ATOM
317
CG1
VAL
A
1687
4.751
24.080
35.775
1.00
19.85
C

ATOM
318
CG2
VAL
A
1687
6.570
25.788
35.992
1.00
20.28
C

ATOM
319
N
VAL
A
1688
6.675
21.036
35.256
1.00
21.42
N

ATOM
320
CA
VAL
A
1688
6.325
19.806
34.553
1.00
22.22
C

ATOM
321
C
VAL
A
1688
4.828
19.561
34.714
1.00
22.17
C

ATOM
322
O
VAL
A
1688
4.344
19.213
35.795
1.00
22.13
O

ATOM
323
CB
VAL
A
1688
7.102
18.605
35.107
1.00
22.04
C

ATOM
324
CG1
VAL
A
1688
6.714
17.329
34.363
1.00
23.45
C

ATOM
325
CG2
VAL
A
1688
8.631
18.867
34.994
1.00
22.73
C

ATOM
326
N
MET
A
1689
4.097
19.763
33.630
1.00
22.26
N

ATOM
327
CA
MET
A
1689
2.641
19.634
33.672
1.00
22.34
C

ATOM
328
C
MET
A
1689
2.161
18.295
33.147
1.00
22.82
C

ATOM
329
O
MET
A
1689
2.653
17.812
32.137
1.00
22.06
O

ATOM
330
CB
MET
A
1689
1.995
20.655
32.733
1.00
22.42
C

ATOM
331
CG
MET
A
1689
2.339
22.103
32.947
1.00
21.00
C

ATOM
332
SD
MET
A
1689
1.570
22.779
34.399
1.00
21.36
S

ATOM
333
CE
MET
A
1689
−0.176
22.202
34.322
1.00
23.99
C

ATOM
334
N
LYS
A
1690
1.140
17.748
33.792
1.00
23.62
N

ATOM
335
CA
LYS
A
1690
0.445
16.596
33.234
1.00
25.55
C

ATOM
336
C
LYS
A
1690
−0.268
17.100
31.963
1.00
25.64
C

ATOM
337
O
LYS
A
1690
−0.953
18.119
31.994
1.00
25.20
O

ATOM
338
CB
LYS
A
1690
−0.605
16.107
34.223
1.00
26.03
C

ATOM
339
CG
LYS
A
1690
−1.477
14.981
33.698
1.00
29.48
C

ATOM
340
CD
LYS
A
1690
−0.635
13.779
33.360
1.00
33.58
C

ATOM
341
CE
LYS
A
1690
−1.483
12.536
33.133
1.00
37.81
C

ATOM
342
NZ
LYS
A
1690
−0.647
11.273
33.107
1.00
40.65
N

ATOM
343
N
THR
A
1691
−0.081
16.395
30.850
1.00
26.37
N

ATOM
344
CA
THR
A
1691
−0.747
16.736
29.598
1.00
27.47
C

ATOM
345
C
THR
A
1691
−1.366
15.488
28.971
1.00
28.22
C

ATOM
346
O
THR
A
1691
−1.142
14.352
29.421
1.00
28.13
O

ATOM
347
CB
THR
A
1691
0.224
17.340
28.545
1.00
26.46
C

ATOM
348
OG1
THR
A
1691
1.117
16.330
28.052
1.00
27.31
O

ATOM
349
CG2
THR
A
1691
1.153
18.411
29.136
1.00
26.70
C

ATOM
350
N
ASP
A
1692
−2.126
15.722
27.912
1.00
29.46
N

ATOM
351
CA
ASP
A
1692
−2.626
14.643
27.086
1.00
30.31
C

ATOM
352
C
ASP
A
1692
−1.538
14.384
26.030
1.00
31.07
C

ATOM
353
O
ASP
A
1692
−0.463
15.018
26.058
1.00
30.12
O

ATOM
354
CB
ASP
A
1692
−4.006
14.997
26.492
1.00
30.67
C

ATOM
355
CG
ASP
A
1692
−3.938
16.065
25.425
1.00
31.94
C

ATOM
356
OD1
ASP
A
1692
−2.836
16.523
25.075
1.00
30.65
O

ATOM
357
OD2
ASP
A
1692
−4.958
16.496
24.851
1.00
33.80
O

ATOM
358
N
ALA
A
1693
−1.770
13.447
25.113
1.00
31.57
N

ATOM
359
CA
ALA
A
1693
−0.712
13.074
24.165
1.00
31.83
C

ATOM
360
C
ALA
A
1693
−0.273
14.167
23.203
1.00
31.90
C

ATOM
361
O
ALA
A
1693
0.763
14.047
22.559
1.00
33.24
O

ATOM
362
CB
ALA
A
1693
−1.086
11.776
23.387
1.00
32.02
C

ATOM
363
N
GLU
A
1694
−1.056
15.229
23.098
1.00
32.07
N

ATOM
364
CA
GLU
A
1694
−0.715
16.332
22.200
1.00
32.13
C

ATOM
365
C
GLU
A
1694
−0.143
17.522
22.973
1.00
31.43
C

ATOM
366
O
GLU
A
1694
−0.069
18.648
22.455
1.00
31.29
O

ATOM
367
CB
GLU
A
1694
−1.938
16.761
21.394
1.00
32.51
C

ATOM
368
CG
GLU
A
1694
−2.199
15.883
20.177
1.00
36.64
C

ATOM
369
CD
GLU
A
1694
−3.629
15.983
19.665
1.00
40.87
C

ATOM
370
OE1
GLU
A
1694
−4.448
16.711
20.268
1.00
43.24
O

ATOM
371
OE2
GLU
A
1694
−3.948
15.301
18.659
1.00
45.34
O

ATOM
372
N
PHE
A
1695
0.262
17.258
24.209
1.00
30.33
N

ATOM
373
CA
PHE
A
1695
0.907
18.267
25.044
1.00
29.76
C

ATOM
374
C
PHE
A
1695
−0.009
19.435
25.420
1.00
28.82
C

ATOM
375
O
PHE
A
1695
0.433
20.586
25.460
1.00
28.63
O

ATOM
376
CB
PHE
A
1695
2.191
18.765
24.380
1.00
30.46
C

ATOM
377
CG
PHE
A
1695
3.214
17.676
24.152
1.00
32.35
C

ATOM
378
CD1
PHE
A
1695
4.097
17.744
23.096
1.00
34.87
C

ATOM
379
CD2
PHE
A
1695
3.276
16.584
25.002
1.00
33.51
C

ATOM
380
CE1
PHE
A
1695
5.041
16.741
22.886
1.00
37.03
C

ATOM
381
CE2
PHE
A
1695
4.209
15.575
24.800
1.00
35.91
C

ATOM
382
CZ
PHE
A
1695
5.091
15.656
23.742
1.00
36.18
C

ATOM
383
N
VAL
A
1696
−1.269
19.115
25.714
1.00
27.46
N

ATOM
384
CA
VAL
A
1696
−2.256
20.088
26.177
1.00
26.34
C

ATOM
385
C
VAL
A
1696
−2.547
19.834
27.643
1.00
26.15
C

ATOM
386
O
VAL
A
1696
−2.847
18.695
28.031
1.00
25.67
O

ATOM
387
CB
VAL
A
1696
−3.575
19.919
25.419
1.00
26.30
C

ATOM
388
CG1
VAL
A
1696
−4.613
20.873
25.965
1.00
27.23
C

ATOM
389
CG2
VAL
A
1696
−3.347
20.146
23.922
1.00
26.66
C

ATOM
390
N
CYS
A
1697
−2.478
20.884
28.461
1.00
25.76
N

ATOM
391
CA
CYS
A
1697
−2.659
20.727
29.907
1.00
25.77
C

ATOM
392
C
CYS
A
1697
−3.849
21.495
30.461
1.00
25.66
C

ATOM
393
O
CYS
A
1697
−4.570
22.195
29.739
1.00
26.07
O

ATOM
394
CB
CYS
A
1697
−1.401
21.198
30.648
1.00
25.57
C

ATOM
395
SG
CYS
A
1697
−1.058
22.988
30.437
1.00
25.15
S

ATOM
396
N
GLU
A
1698
−4.035
21.361
31.764
1.00
25.40
N

ATOM
397
CA
GLU
A
1698
−5.052
22.080
32.494
1.00
25.79
C

ATOM
398
C
GLU
A
1698
−4.429
23.376
32.999
1.00
25.04
C

ATOM
399
O
GLU
A
1698
−3.221
23.403
33.272
1.00
25.41
O

ATOM
400
CB
GLU
A
1698
−5.511
21.288
33.709
1.00
26.56
C

ATOM
401
CG
GLU
A
1698
−6.027
19.885
33.408
1.00
29.71
C

ATOM
402
CD
GLU
A
1698
−7.536
19.854
33.227
1.00
35.07
C

ATOM
403
OE1
GLU
A
1698
−8.084
18.747
33.042
1.00
38.52
O

ATOM
404
OE2
GLU
A
1698
−8.172
20.925
33.276
1.00
35.88
O

ATOM
405
N
ARG
A
1699
−5.240
24.415
33.147
1.00
23.34
N

ATOM
406
CA
ARG
A
1699
−4.765
25.689
33.671
1.00
23.38
C

ATOM
407
C
ARG
A
1699
−4.728
25.643
35.186
1.00
23.32
C

ATOM
408
O
ARG
A
1699
−5.783
25.723
35.848
1.00
23.77
O

ATOM
409
CB
ARG
A
1699
−5.672
26.845
33.226
1.00
23.24
C

ATOM
410
CG
ARG
A
1699
−5.728
27.087
31.724
1.00
23.08
C

ATOM
411
CD
ARG
A
1699
−6.177
28.513
31.333
1.00
21.06
C

ATOM
412
NE
ARG
A
1699
−7.466
28.900
31.915
1.00
24.04
N

ATOM
413
CZ
ARG
A
1699
−8.030
30.100
31.750
1.00
23.60
C

ATOM
414
NH1
ARG
A
1699
−7.412
31.027
31.038
1.00
22.34
N

ATOM
415
NH2
ARG
A
1699
−9.202
30.379
32.306
1.00
26.85
N

ATOM
416
N
THR
A
1700
−3.525
25.484
35.733
1.00
23.00
N

ATOM
417
CA
THR
A
1700
−3.304
25.581
37.162
1.00
22.49
C

ATOM
418
C
THR
A
1700
−2.518
26.849
37.474
1.00
22.18
C

ATOM
419
O
THR
A
1700
−1.971
27.496
36.570
1.00
22.02
O

ATOM
420
CB
THR
A
1700
−2.488
24.387
37.687
1.00
22.62
C

ATOM
421
OG1
THR
A
1700
−1.195
24.364
37.062
1.00
21.16
O

ATOM
422
CG2
THR
A
1700
−3.153
23.041
37.288
1.00
22.97
C

ATOM
423
N
LEU
A
1701
−2.464
27.209
38.756
1.00
21.41
N

ATOM
424
CA
LEU
A
1701
−1.682
28.380
39.170
1.00
21.28
C

ATOM
425
C
LEU
A
1701
−0.215
28.229
38.742
1.00
21.03
C

ATOM
426
O
LEU
A
1701
0.411
29.185
38.266
1.00
19.46
O

ATOM
427
CB
LEU
A
1701
−1.771
28.584
40.679
1.00
21.44
C

ATOM
428
CG
LEU
A
1701
−0.943
29.739
41.248
1.00
22.41
C

ATOM
429
CD1
LEU
A
1701
−1.233
31.072
40.481
1.00
24.93
C

ATOM
430
CD2
LEU
A
1701
−1.225
29.923
42.738
1.00
24.85
C

ATOM
431
N
LYS
A
1702
0.335
27.036
38.910
1.00
21.07
N

ATOM
432
CA
LYS
A
1702
1.730
26.789
38.500
1.00
21.06
C

ATOM
433
C
LYS
A
1702
1.941
26.935
36.992
1.00
21.34
C

ATOM
434
O
LYS
A
1702
3.007
27.388
36.548
1.00
21.87
O

ATOM
435
CB
LYS
A
1702
2.202
25.406
38.957
1.00
20.84
C

ATOM
436
CG
LYS
A
1702
2.683
25.335
40.409
1.00
22.93
C

ATOM
437
CD
LYS
A
1702
2.856
23.856
40.785
1.00
26.66
C

ATOM
438
CE
LYS
A
1702
3.409
23.668
42.189
1.00
29.07
C

ATOM
439
NZ
LYS
A
1702
3.288
22.244
42.623
1.00
28.40
N

ATOM
440
N
TYR
A
1703
0.948
26.515
36.207
1.00
20.21
N

ATOM
441
CA
TYR
A
1703
0.986
26.735
34.762
1.00
20.07
C

ATOM
442
C
TYR
A
1703
1.091
28.240
34.474
1.00
19.96
C

ATOM
443
O
TYR
A
1703
1.946
28.676
33.709
1.00
19.76
O

ATOM
444
CB
TYR
A
1703
−0.284
26.150
34.120
1.00
19.81
C

ATOM
445
CG
TYR
A
1703
−0.563
26.468
32.646
1.00
20.24
C

ATOM
446
CD1
TYR
A
1703
0.217
25.914
31.647
1.00
21.50
C

ATOM
447
CD2
TYR
A
1703
−1.640
27.283
32.257
1.00
23.08
C

ATOM
448
CE1
TYR
A
1703
−0.027
26.145
30.308
1.00
23.12
C

ATOM
449
CE2
TYR
A
1703
−1.902
27.531
30.902
1.00
22.29
C

ATOM
450
CZ
TYR
A
1703
−1.093
26.956
29.939
1.00
24.64
C

ATOM
451
OH
TYR
A
1703
−1.288
27.195
28.596
1.00
24.68
O

ATOM
452
N
PHE
A
1704
0.216
29.039
35.089
1.00
20.41
N

ATOM
453
CA
PHE
A
1704
0.206
30.483
34.824
1.00
20.31
C

ATOM
454
C
PHE
A
1704
1.526
31.143
35.237
1.00
20.81
C

ATOM
455
O
PHE
A
1704
2.066
32.006
34.534
1.00
20.33
O

ATOM
456
CB
PHE
A
1704
−0.901
31.171
35.624
1.00
19.51
C

ATOM
457
CG
PHE
A
1704
−2.280
30.893
35.124
1.00
21.69
C

ATOM
458
CD1
PHE
A
1704
−3.223
30.318
35.959
1.00
20.66
C

ATOM
459
CD2
PHE
A
1704
−2.651
31.222
33.819
1.00
20.16
C

ATOM
460
CE1
PHE
A
1704
−4.510
30.070
35.503
1.00
20.61
C

ATOM
461
CE2
PHE
A
1704
−3.933
30.978
33.363
1.00
20.80
C

ATOM
462
CZ
PHE
A
1704
−4.862
30.403
34.201
1.00
19.93
C

ATOM
463
N
LEU
A
1705
1.997
30.787
36.422
1.00
20.01
N

ATOM
464
CA
LEU
A
1705
3.213
31.397
36.934
1.00
20.31
C

ATOM
465
C
LEU
A
1705
4.428
30.950
36.125
1.00
20.24
C

ATOM
466
O
LEU
A
1705
5.375
31.714
35.969
1.00
20.22
O

ATOM
467
CB
LEU
A
1705
3.402
31.071
38.427
1.00
20.87
C

ATOM
468
CG
LEU
A
1705
2.374
31.696
39.380
1.00
20.79
C

ATOM
469
CD1
LEU
A
1705
2.540
31.143
40.792
1.00
20.90
C

ATOM
470
CD2
LEU
A
1705
2.464
33.246
39.405
1.00
21.34
C

ATOM
471
N
GLY
A
1706
4.413
29.708
35.647
1.00
19.39
N

ATOM
472
CA
GLY
A
1706
5.485
29.208
34.805
1.00
20.05
C

ATOM
473
C
GLY
A
1706
5.607
30.040
33.546
1.00
20.85
C

ATOM
474
O
GLY
A
1706
6.693
30.522
33.217
1.00
20.83
O

ATOM
475
N
ILE
A
1707
4.490
30.229
32.852
1.00
20.24
N

ATOM
476
CA
ILE
A
1707
4.482
31.055
31.654
1.00
20.50
C

ATOM
477
C
ILE
A
1707
4.835
32.496
32.017
1.00
20.72
C

ATOM
478
O
ILE
A
1707
5.659
33.113
31.355
1.00
21.45
O

ATOM
479
CB
ILE
A
1707
3.109
31.024
30.963
1.00
20.35
C

ATOM
480
CG1
ILE
A
1707
2.826
29.628
30.430
1.00
20.76
C

ATOM
481
CG2
ILE
A
1707
3.028
32.074
29.821
1.00
20.87
C

ATOM
482
CD1
ILE
A
1707
1.355
29.426
29.970
1.00
20.85
C

ATOM
483
N
ALA
A
1708
4.215
33.037
33.065
1.00
21.43
N

ATOM
484
CA
ALA
A
1708
4.499
34.419
33.462
1.00
21.67
C

ATOM
485
C
ALA
A
1708
5.982
34.623
33.729
1.00
22.15
C

ATOM
486
O
ALA
A
1708
6.518
35.700
33.464
1.00
22.03
O

ATOM
487
CB
ALA
A
1708
3.680
34.842
34.682
1.00
22.63
C

ATOM
488
N
GLY
A
1709
6.655
33.598
34.240
1.00
21.49
N

ATOM
489
CA
GLY
A
1709
8.072
33.707
34.538
1.00
21.26
C

ATOM
490
C
GLY
A
1709
9.010
33.337
33.400
1.00
21.16
C

ATOM
491
O
GLY
A
1709
10.241
33.296
33.572
1.00
20.59
O

ATOM
492
N
GLY
A
1710
8.432
33.051
32.237
1.00
20.37
N

ATOM
493
CA
GLY
A
1710
9.202
32.698
31.058
1.00
20.60
C

ATOM
494
C
GLY
A
1710
9.948
31.380
31.205
1.00
20.86
C

ATOM
495
O
GLY
A
1710
10.968
31.165
30.553
1.00
20.62
O

ATOM
496
N
LYS
A
1711
9.435
30.493
32.060
1.00
20.95
N

ATOM
497
CA
LYS
A
1711
10.079
29.197
32.366
1.00
21.11
C

ATOM
498
C
LYS
A
1711
9.794
28.147
31.300
1.00
22.21
C

ATOM
499
O
LYS
A
1711
8.994
28.387
30.394
1.00
21.97
O

ATOM
500
CB
LYS
A
1711
9.580
28.674
33.729
1.00
20.90
C

ATOM
501
CG
LYS
A
1711
9.688
29.696
34.875
1.00
20.67
C

ATOM
502
CD
LYS
A
1711
9.203
29.085
36.205
1.00
20.89
C

ATOM
503
CE
LYS
A
1711
9.101
30.141
37.337
1.00
21.43
C

ATOM
504
NZ
LYS
A
1711
10.410
30.822
37.623
1.00
21.62
N

ATOM
505
N
TRP
A
1712
10.476
27.008
31.390
1.00
22.17
N

ATOM
506
CA
TRP
A
1712
10.157
25.876
30.542
1.00
23.46
C

ATOM
507
C
TRP
A
1712
8.896
25.245
31.085
1.00
23.84
C

ATOM
508
O
TRP
A
1712
8.871
24.771
32.223
1.00
24.14
O

ATOM
509
CB
TRP
A
1712
11.251
24.820
30.590
1.00
23.18
C

ATOM
510
CG
TRP
A
1712
12.374
25.069
29.677
1.00
25.43
C

ATOM
511
CD1
TRP
A
1712
13.678
25.337
30.019
1.00
26.48
C

ATOM
512
CD2
TRP
A
1712
12.327
25.068
28.250
1.00
25.38
C

ATOM
513
NE1
TRP
A
1712
14.433
25.511
28.883
1.00
25.81
N

ATOM
514
CE2
TRP
A
1712
13.627
25.344
27.785
1.00
28.43
C

ATOM
515
CE3
TRP
A
1712
11.312
24.854
27.309
1.00
25.07
C

ATOM
516
CZ2
TRP
A
1712
13.935
25.408
26.426
1.00
27.08
C

ATOM
517
CZ3
TRP
A
1712
11.620
24.946
25.960
1.00
24.41
C

ATOM
518
CH2
TRP
A
1712
12.914
25.207
25.537
1.00
27.04
C

ATOM
519
N
VAL
A
1713
7.851
25.227
30.278
1.00
23.20
N

ATOM
520
CA
VAL
A
1713
6.612
24.590
30.687
1.00
23.43
C

ATOM
521
C
VAL
A
1713
6.478
23.366
29.784
1.00
23.67
C

ATOM
522
O
VAL
A
1713
6.119
23.477
28.620
1.00
23.51
O

ATOM
523
CB
VAL
A
1713
5.416
25.546
30.566
1.00
23.85
C

ATOM
524
CG1
VAL
A
1713
4.116
24.891
31.096
1.00
22.67
C

ATOM
525
CG2
VAL
A
1713
5.695
26.859
31.310
1.00
22.94
C

ATOM
526
N
VAL
A
1714
6.778
22.199
30.349
1.00
23.35
N

ATOM
527
CA
VAL
A
1714
6.914
20.969
29.586
1.00
23.64
C

ATOM
528
C
VAL
A
1714
6.024
19.865
30.092
1.00
23.92
C

ATOM
529
O
VAL
A
1714
5.615
19.859
31.260
1.00
24.03
O

ATOM
530
CB
VAL
A
1714
8.372
20.455
29.653
1.00
24.06
C

ATOM
531
CG1
VAL
A
1714
9.341
21.534
29.107
1.00
23.74
C

ATOM
532
CG2
VAL
A
1714
8.732
20.071
31.075
1.00
25.07
C

ATOM
533
N
SER
A
1715
5.734
18.916
29.213
1.00
24.41
N

ATOM
534
CA
SER
A
1715
4.889
17.780
29.570
1.00
24.54
C

ATOM
535
C
SER
A
1715
5.593
16.773
30.451
1.00
24.94
C

ATOM
536
O
SER
A
1715
6.801
16.577
30.362
1.00
24.11
O

ATOM
537
CB
SER
A
1715
4.466
17.038
28.299
1.00
25.03
C

ATOM
538
OG
SER
A
1715
3.778
15.852
28.639
1.00
23.98
O

ATOM
539
N
TYR
A
1716
4.797
16.126
31.288
1.00
25.42
N

ATOM
540
CA
TYR
A
1716
5.231
15.017
32.125
1.00
26.37
C

ATOM
541
C
TYR
A
1716
5.869
13.931
31.247
1.00
27.10
C

ATOM
542
O
TYR
A
1716
6.785
13.212
31.683
1.00
26.35
O

ATOM
543
CB
TYR
A
1716
4.010
14.514
32.907
1.00
26.21
C

ATOM
544
CG
TYR
A
1716
4.195
13.230
33.680
1.00
29.12
C

ATOM
545
CD1
TYR
A
1716
3.331
12.154
33.481
1.00
32.06
C

ATOM
546
CD2
TYR
A
1716
5.231
13.074
34.608
1.00
28.52
C

ATOM
547
CE1
TYR
A
1716
3.486
10.956
34.178
1.00
34.47
C

ATOM
548
CE2
TYR
A
1716
5.389
11.881
35.311
1.00
31.81
C

ATOM
549
CZ
TYR
A
1716
4.514
10.828
35.094
1.00
34.25
C

ATOM
550
OH
TYR
A
1716
4.649
9.641
35.787
1.00
37.87
O

ATOM
551
N
PHE
A
1717
5.424
13.826
29.995
1.00
27.52
N

ATOM
552
CA
PHE
A
1717
6.034
12.870
29.075
1.00
28.82
C

ATOM
553
C
PHE
A
1717
7.538
13.059
28.921
1.00
28.84
C

ATOM
554
O
PHE
A
1717
8.240
12.126
28.548
1.00
29.28
O

ATOM
555
CB
PHE
A
1717
5.386
12.923
27.680
1.00
29.41
C

ATOM
556
CG
PHE
A
1717
4.021
12.301
27.626
1.00
30.82
C

ATOM
557
CD1
PHE
A
1717
2.906
13.073
27.348
1.00
32.52
C

ATOM
558
CD2
PHE
A
1717
3.857
10.941
27.856
1.00
33.31
C

ATOM
559
CE1
PHE
A
1717
1.641
12.504
27.304
1.00
34.86
C

ATOM
560
CE2
PHE
A
1717
2.597
10.365
27.815
1.00
34.29
C

ATOM
561
CZ
PHE
A
1717
1.489
11.147
27.532
1.00
35.25
C

ATOM
562
N
TRP
A
1718
8.042
14.255
29.197
1.00
28.34
N

ATOM
563
CA
TRP
A
1718
9.479
14.474
29.109
1.00
28.68
C

ATOM
564
C
TRP
A
1718
10.155
13.533
30.080
1.00
29.50
C

ATOM
565
O
TRP
A
1718
11.155
12.875
29.758
1.00
29.11
O

ATOM
566
CB
TRP
A
1718
9.822
15.914
29.482
1.00
28.52
C

ATOM
567
CG
TRP
A
1718
11.271
16.215
29.683
1.00
27.62
C

ATOM
568
CD1
TRP
A
1718
12.290
16.042
28.785
1.00
30.51
C

ATOM
569
CD2
TRP
A
1718
11.861
16.838
30.832
1.00
27.46
C

ATOM
570
NE1
TRP
A
1718
13.476
16.480
29.326
1.00
30.53
N

ATOM
571
CE2
TRP
A
1718
13.235
16.979
30.580
1.00
29.14
C

ATOM
572
CE3
TRP
A
1718
11.364
17.277
32.064
1.00
28.24
C

ATOM
573
CZ2
TRP
A
1718
14.113
17.539
31.509
1.00
29.76
C

ATOM
574
CZ3
TRP
A
1718
12.240
17.826
32.984
1.00
30.82
C

ATOM
575
CH2
TRP
A
1718
13.598
17.948
32.702
1.00
29.58
C

ATOM
576
N
VAL
A
1719
9.606
13.483
31.282
1.00
30.02
N

ATOM
577
CA
VAL
A
1719
10.142
12.624
32.316
1.00
31.76
C

ATOM
578
C
VAL
A
1719
9.977
11.161
31.922
1.00
33.27
C

ATOM
579
O
VAL
A
1719
10.969
10.427
31.827
1.00
33.42
O

ATOM
580
CB
VAL
A
1719
9.475
12.912
33.671
1.00
31.63
C

ATOM
581
CG1
VAL
A
1719
9.819
11.838
34.710
1.00
31.96
C

ATOM
582
CG2
VAL
A
1719
9.889
14.294
34.167
1.00
31.20
C

ATOM
583
N
THR
A
1720
8.740
10.743
31.651
1.00
34.96
N

ATOM
584
CA
THR
A
1720
8.554
9.313
31.340
1.00
36.85
C

ATOM
585
C
THR
A
1720
9.339
8.816
30.131
1.00
38.01
C

ATOM
586
O
THR
A
1720
9.913
7.730
30.159
1.00
38.60
O

ATOM
587
CB
THR
A
1720
7.081
8.877
31.234
1.00
36.66
C

ATOM
588
OG1
THR
A
1720
6.390
9.689
30.279
1.00
36.44
O

ATOM
589
CG2
THR
A
1720
6.357
9.118
32.547
1.00
36.41
C

ATOM
590
N
GLN
A
1721
9.365
9.602
29.070
1.00
39.54
N

ATOM
591
CA
GLN
A
1721
10.134
9.225
27.900
1.00
41.24
C

ATOM
592
C
GLN
A
1721
11.631
9.197
28.194
1.00
42.30
C

ATOM
593
O
GLN
A
1721
12.342
8.332
27.682
1.00
42.28
O

ATOM
594
CB
GLN
A
1721
9.833
10.158
26.732
1.00
41.41
C

ATOM
595
CG
GLN
A
1721
10.241
9.612
25.375
1.00
43.88
C

ATOM
596
CD
GLN
A
1721
9.451
8.376
24.973
1.00
46.02
C

ATOM
597
OE1
GLN
A
1721
9.825
7.679
24.029
1.00
48.31
O

ATOM
598
NE2
GLN
A
1721
8.357
8.107
25.678
1.00
47.45
N

ATOM
599
N
SER
A
1722
12.114
10.130
29.014
1.00
43.35
N

ATOM
600
CA
SER
A
1722
13.541
10.171
29.361
1.00
44.70
C

ATOM
601
C
SER
A
1722
13.932
8.901
30.108
1.00
46.65
C

ATOM
602
O
SER
A
1722
14.954
8.276
29.812
1.00
46.89
O

ATOM
603
CB
SER
A
1722
13.884
11.395
30.219
1.00
44.38
C

ATOM
604
OG
SER
A
1722
13.805
12.597
29.478
1.00
42.77
O

ATOM
605
N
ILE
A
1723
13.121
8.535
31.092
1.00
48.82
N

ATOM
606
CA
ILE
A
1723
13.350
7.313
31.838
1.00
50.90
C

ATOM
607
C
ILE
A
1723
13.396
6.162
30.852
1.00
52.25
C

ATOM
608
O
ILE
A
1723
14.337
5.363
30.844
1.00
52.74
O

ATOM
609
CB
ILE
A
1723
12.201
7.068
32.830
1.00
50.77
C

ATOM
610
CG1
ILE
A
1723
12.174
8.140
33.915
1.00
50.32
C

ATOM
611
CG2
ILE
A
1723
12.337
5.687
33.463
1.00
51.86
C

ATOM
612
CD1
ILE
A
1723
10.961
8.062
34.792
1.00
50.04
C

ATOM
613
N
LYS
A
1724
12.374
6.086
30.007
1.00
53.69
N

ATOM
614
CA
LYS
A
1724
12.253
4.996
29.045
1.00
54.98
C

ATOM
615
C
LYS
A
1724
13.473
4.834
28.133
1.00
55.52
C

ATOM
616
O
LYS
A
1724
13.712
3.750
27.595
1.00
55.87
O

ATOM
617
CB
LYS
A
1724
10.976
5.163
28.215
1.00
55.06
C

ATOM
618
CG
LYS
A
1724
10.795
4.128
27.117
1.00
56.82
C

ATOM
619
CD
LYS
A
1724
9.456
4.307
26.404
1.00
59.11
C

ATOM
620
CE
LYS
A
1724
9.501
3.770
24.978
1.00
61.01
C

ATOM
621
NZ
LYS
A
1724
10.015
2.372
24.900
1.00
62.45
N

ATOM
622
N
GLU
A
1725
14.244
5.904
27.967
1.00
55.67
N

ATOM
623
CA
GLU
A
1725
15.422
5.862
27.114
1.00
55.94
C

ATOM
624
C
GLU
A
1725
16.690
6.032
27.942
1.00
56.09
C

ATOM
625
O
GLU
A
1725
17.792
6.166
27.403
1.00
56.28
O

ATOM
626
CB
GLU
A
1725
15.335
6.944
26.039
1.00
56.03
C

ATOM
627
CG
GLU
A
1725
14.001
6.970
25.312
1.00
56.26
C

ATOM
628
CD
GLU
A
1725
14.052
7.765
24.023
1.00
56.75
C

ATOM
629
OE1
GLU
A
1725
15.170
8.047
23.543
1.00
57.44
O

ATOM
630
OE2
GLU
A
1725
12.975
8.104
23.481
1.00
57.51
O

ATOM
631
N
ARG
A
1726
16.517
6.036
29.260
1.00
56.32
N

ATOM
632
CA
ARG
A
1726
17.627
6.170
30.200
1.00
56.34
C

ATOM
633
C
ARG
A
1726
18.580
7.296
29.833
1.00
56.66
C

ATOM
634
O
ARG
A
1726
19.701
7.366
30.341
1.00
56.80
O

ATOM
635
CB
ARG
A
1726
18.398
4.856
30.303
1.00
56.21
C

ATOM
636
CG
ARG
A
1726
17.587
3.692
30.854
1.00
54.58
C

ATOM
637
CD
ARG
A
1726
18.448
2.440
31.127
1.00
52.29
C

ATOM
638
NE
ARG
A
1726
17.674
1.297
31.602
1.00
50.00
N

ATOM
639
CZ
ARG
A
1726
18.204
0.119
31.936
1.00
49.40
C

ATOM
640
NH1
ARG
A
1726
19.518
−0.091
31.853
1.00
49.31
N

ATOM
641
NH2
ARG
A
1726
17.418
−0.863
32.356
1.00
48.60
N

ATOM
642
N
LYS
A
1727
18.126
8.160
28.931
1.00
56.83
N

ATOM
643
CA
LYS
A
1727
18.871
9.338
28.523
1.00
56.73
C

ATOM
644
C
LYS
A
1727
18.240
10.517
29.239
1.00
56.20
C

ATOM
645
O
LYS
A
1727
17.349
10.347
30.065
1.00
56.46
O

ATOM
646
CB
LYS
A
1727
18.713
9.573
27.019
1.00
56.89
C

ATOM
647
CG
LYS
A
1727
19.526
8.674
26.096
1.00
58.87
C

ATOM
648
CD
LYS
A
1727
19.027
8.815
24.652
1.00
60.89
C

ATOM
649
CE
LYS
A
1727
20.012
8.266
23.630
1.00
62.65
C

ATOM
650
NZ
LYS
A
1727
19.537
8.509
22.231
1.00
63.70
N

ATOM
651
N
MET
A
1728
18.699
11.714
28.903
1.00
55.31
N

ATOM
652
CA
MET
A
1728
18.110
12.945
29.403
1.00
54.28
C

ATOM
653
C
MET
A
1728
17.630
13.702
28.185
1.00
52.90
C

ATOM
654
O
MET
A
1728
18.396
14.434
27.558
1.00
52.58
O

ATOM
655
CB
MET
A
1728
19.134
13.791
30.157
1.00
55.12
C

ATOM
656
CG
MET
A
1728
19.061
13.657
31.668
1.00
57.13
C

ATOM
657
SD
MET
A
1728
17.969
14.835
32.428
1.00
62.34
S

ATOM
658
CE
MET
A
1728
18.990
16.316
32.456
1.00
61.18
C

ATOM
659
N
LEU
A
1729
16.359
13.526
27.845
1.00
51.17
N

ATOM
660
CA
LEU
A
1729
15.822
14.156
26.651
1.00
49.34
C

ATOM
661
C
LEU
A
1729
15.739
15.670
26.766
1.00
48.47
C

ATOM
662
O
LEU
A
1729
15.840
16.236
27.860
1.00
47.88
O

ATOM
663
CB
LEU
A
1729
14.470
13.549
26.287
1.00
49.47
C

ATOM
664
CG
LEU
A
1729
14.538
12.037
26.083
1.00
49.29
C

ATOM
665
CD1
LEU
A
1729
13.160
11.493
25.790
1.00
49.48
C

ATOM
666
CD2
LEU
A
1729
15.506
11.682
24.956
1.00
49.60
C

ATOM
667
N
ASN
A
1730
15.564
16.317
25.622
1.00
47.11
N

ATOM
668
CA
ASN
A
1730
15.512
17.767
25.549
1.00
46.60
C

ATOM
669
C
ASN
A
1730
14.112
18.362
25.753
1.00
45.55
C

ATOM
670
O
ASN
A
1730
13.161
17.971
25.080
1.00
44.35
O

ATOM
671
CB
ASN
A
1730
16.090
18.222
24.213
1.00
46.97
C

ATOM
672
CG
ASN
A
1730
15.670
19.618
23.848
1.00
48.88
C

ATOM
673
OD1
ASN
A
1730
15.273
19.882
22.714
1.00
52.48
O

ATOM
674
ND2
ASN
A
1730
15.754
20.528
24.805
1.00
50.39
N

ATOM
675
N
GLU
A
1731
14.013
19.328
26.670
1.00
44.51
N

ATOM
676
CA
GLU
A
1731
12.757
20.025
26.965
1.00
43.45
C

ATOM
677
C
GLU
A
1731
11.958
20.402
25.744
1.00
43.01
C

ATOM
678
O
GLU
A
1731
10.771
20.100
25.660
1.00
43.43
O

ATOM
679
CB
GLU
A
1731
13.020
21.326
27.740
1.00
43.41
C

ATOM
680
CG
GLU
A
1731
13.592
21.127
29.119
1.00
41.76
C

ATOM
681
CD
GLU
A
1731
15.106
21.125
29.126
1.00
40.50
C

ATOM
682
OE1
GLU
A
1731
15.705
21.028
28.039
1.00
41.97
O

ATOM
683
OE2
GLU
A
1731
15.689
21.213
30.216
1.00
37.52
O

ATOM
684
N
HIS
A
1732
12.606
21.128
24.838
1.00
42.34
N

ATOM
685
CA
HIS
A
1732
12.002
21.610
23.605
1.00
41.79
C

ATOM
686
C
HIS
A
1732
11.046
20.608
23.027
1.00
40.24
C

ATOM
687
O
HIS
A
1732
9.946
20.944
22.603
1.00
40.42
O

ATOM
688
CB
HIS
A
1732
13.087
21.831
22.548
1.00
42.72
C

ATOM
689
CG
HIS
A
1732
13.424
23.268
22.296
1.00
44.10
C

ATOM
690
ND1
HIS
A
1732
14.661
23.800
22.590
1.00
45.91
N

ATOM
691
CD2
HIS
A
1732
12.706
24.269
21.731
1.00
45.21
C

ATOM
692
CE1
HIS
A
1732
14.685
25.073
22.241
1.00
46.35
C

ATOM
693
NE2
HIS
A
1732
13.508
25.385
21.723
1.00
46.39
N

ATOM
694
N
ASP
A
1733
11.492
19.362
22.999
1.00
38.11
N

ATOM
695
CA
ASP
A
1733
10.734
18.305
22.372
1.00
36.40
C

ATOM
696
C
ASP
A
1733
9.461
17.952
23.116
1.00
34.24
C

ATOM
697
O
ASP
A
1733
8.641
17.184
22.612
1.00
34.21
O

ATOM
698
CB
ASP
A
1733
11.636
17.089
22.171
1.00
37.03
C

ATOM
699
CG
ASP
A
1733
12.855
17.424
21.327
1.00
40.13
C

ATOM
700
OD1
ASP
A
1733
12.708
18.222
20.371
1.00
42.92
O

ATOM
701
OD2
ASP
A
1733
13.991
16.965
21.541
1.00
42.00
O

ATOM
702
N
PHE
A
1734
9.274
18.544
24.294
1.00
31.43
N

ATOM
703
CA
PHE
A
1734
8.103
18.239
25.088
1.00
29.37
C

ATOM
704
C
PHE
A
1734
7.389
19.471
25.613
1.00
27.75
C

ATOM
705
O
PHE
A
1734
6.595
19.357
26.524
1.00
27.33
O

ATOM
706
CB
PHE
A
1734
8.490
17.353
26.276
1.00
28.85
C

ATOM
707
CG
PHE
A
1734
9.074
16.045
25.875
1.00
29.54
C

ATOM
708
CD1
PHE
A
1734
10.430
15.924
25.619
1.00
28.38
C

ATOM
709
CD2
PHE
A
1734
8.258
14.921
25.748
1.00
29.90
C

ATOM
710
CE1
PHE
A
1734
10.971
14.697
25.245
1.00
32.16
C

ATOM
711
CE2
PHE
A
1734
8.784
13.709
25.387
1.00
28.92
C

ATOM
712
CZ
PHE
A
1734
10.135
13.584
25.137
1.00
29.87
C

ATOM
713
N
GLU
A
1735
7.679
20.638
25.049
1.00
26.09
N

ATOM
714
CA
GLU
A
1735
7.053
21.874
25.523
1.00
25.44
C

ATOM
715
C
GLU
A
1735
5.543
21.806
25.439
1.00
25.07
C

ATOM
716
O
GLU
A
1735
4.985
21.250
24.464
1.00
24.68
O

ATOM
717
CB
GLU
A
1735
7.563
23.075
24.717
1.00
25.36
C

ATOM
718
CG
GLU
A
1735
7.210
24.412
25.355
1.00
25.42
C

ATOM
719
CD
GLU
A
1735
7.957
25.570
24.722
1.00
23.84
C

ATOM
720
OE1
GLU
A
1735
8.502
25.402
23.597
1.00
23.61
O

ATOM
721
OE2
GLU
A
1735
8.007
26.647
25.349
1.00
23.68
O

ATOM
722
N
VAL
A
1736
4.845
22.329
26.444
1.00
25.06
N

ATOM
723
CA
VAL
A
1736
3.399
22.309
26.312
1.00
24.90
C

ATOM
724
C
VAL
A
1736
2.978
23.295
25.233
1.00
24.36
C

ATOM
725
O
VAL
A
1736
3.554
24.371
25.120
1.00
23.06
O

ATOM
726
CB
VAL
A
1736
2.554
22.340
27.627
1.00
26.50
C

ATOM
727
CG1
VAL
A
1736
3.344
22.090
28.906
1.00
25.92
C

ATOM
728
CG2
VAL
A
1736
1.468
23.443
27.666
1.00
25.83
C

ATOM
729
N
ARG
A
1737
2.039
22.850
24.398
1.00
24.08
N

ATOM
730
CA
ARG
A
1737
1.570
23.598
23.229
1.00
24.71
C

ATOM
731
C
ARG
A
1737
0.314
24.437
23.486
1.00
24.77
C

ATOM
732
O
ARG
A
1737
0.066
25.445
22.801
1.00
24.60
O

ATOM
733
CB
ARG
A
1737
1.289
22.617
22.072
1.00
24.14
C

ATOM
734
CG
ARG
A
1737
2.478
21.779
21.678
1.00
28.10
C

ATOM
735
CD
ARG
A
1737
2.253
20.906
20.461
1.00
33.08
C

ATOM
736
NE
ARG
A
1737
3.461
20.144
20.184
1.00
39.98
N

ATOM
737
CZ
ARG
A
1737
3.484
18.959
19.584
1.00
42.06
C

ATOM
738
NH1
ARG
A
1737
2.359
18.386
19.189
1.00
43.10
N

ATOM
739
NH2
ARG
A
1737
4.641
18.348
19.380
1.00
43.46
N

ATOM
740
N
GLY
A
1738
−0.483
24.021
24.461
1.00
24.52
N

ATOM
741
CA
GLY
A
1738
−1.685
24.761
24.799
1.00
24.68
C

ATOM
742
C
GLY
A
1738
−2.378
24.200
26.025
1.00
25.06
C

ATOM
743
O
GLY
A
1738
−1.812
23.382
26.766
1.00
25.42
O

ATOM
744
N
ASP
A
1739
−3.609
24.638
26.249
1.00
24.43
N

ATOM
745
CA
ASP
A
1739
−4.358
24.174
27.400
1.00
24.93
C

ATOM
746
C
ASP
A
1739
−5.838
23.971
27.056
1.00
25.86
C

ATOM
747
O
ASP
A
1739
−6.301
24.425
26.009
1.00
26.53
O

ATOM
748
CB
ASP
A
1739
−4.171
25.134
28.583
1.00
24.27
C

ATOM
749
CG
ASP
A
1739
−4.726
26.514
28.323
1.00
25.30
C

ATOM
750
OD1
ASP
A
1739
−5.988
26.673
28.306
1.00
22.40
O

ATOM
751
OD2
ASP
A
1739
−3.977
27.530
28.174
1.00
25.25
O

ATOM
752
N
VAL
A
1740
−6.585
23.334
27.954
1.00
25.85
N

ATOM
753
CA
VAL
A
1740
−7.982
22.984
27.668
1.00
27.39
C

ATOM
754
C
VAL
A
1740
−8.930
24.169
27.607
1.00
27.48
C

ATOM
755
O
VAL
A
1740
−10.110
24.011
27.300
1.00
27.81
O

ATOM
756
CB
VAL
A
1740
−8.518
22.016
28.720
1.00
27.51
C

ATOM
757
CG1
VAL
A
1740
−7.650
20.753
28.761
1.00
27.72
C

ATOM
758
CG2
VAL
A
1740
−8.572
22.721
30.100
1.00
28.36
C

ATOM
759
N
VAL
A
1741
−8.422
25.364
27.884
1.00
26.99
N

ATOM
760
CA
VAL
A
1741
−9.275
26.541
27.887
1.00
27.27
C

ATOM
761
C
VAL
A
1741
−8.992
27.473
26.722
1.00
27.50
C

ATOM
762
O
VAL
A
1741
−9.903
27.842
25.956
1.00
27.96
O

ATOM
763
CB
VAL
A
1741
−9.165
27.337
29.226
1.00
27.17
C

ATOM
764
CG1
VAL
A
1741
−9.882
28.675
29.123
1.00
27.78
C

ATOM
765
CG2
VAL
A
1741
−9.723
26.518
30.366
1.00
28.30
C

ATOM
766
N
ASN
A
1742
−7.731
27.820
26.535
1.00
26.85
N

ATOM
767
CA
ASN
A
1742
−7.425
28.860
25.560
1.00
27.45
C

ATOM
768
C
ASN
A
1742
−6.986
28.417
24.171
1.00
27.14
C

ATOM
769
O
ASN
A
1742
−6.782
29.261
23.293
1.00
28.01
O

ATOM
770
CB
ASN
A
1742
−6.407
29.829
26.163
1.00
26.91
C

ATOM
771
CG
ASN
A
1742
−6.965
30.573
27.367
1.00
27.80
C

ATOM
772
OD1
ASN
A
1742
−7.852
31.422
27.230
1.00
28.46
O

ATOM
773
ND2
ASN
A
1742
−6.462
30.253
28.549
1.00
24.00
N

ATOM
774
N
GLY
A
1743
−6.835
27.115
23.961
1.00
26.56
N

ATOM
775
CA
GLY
A
1743
−6.395
26.628
22.657
1.00
26.50
C

ATOM
776
C
GLY
A
1743
−5.375
25.510
22.722
1.00
26.14
C

ATOM
777
O
GLY
A
1743
−4.445
25.548
23.535
1.00
25.14
O

ATOM
778
N
ARG
A
1744
−5.507
24.538
21.823
1.00
25.51
N

ATOM
779
CA
ARG
A
1744
−4.651
23.369
21.853
1.00
26.02
C

ATOM
780
C
ARG
A
1744
−3.241
23.611
21.354
1.00
25.19
C

ATOM
781
O
ARG
A
1744
−2.360
22.805
21.626
1.00
25.63
O

ATOM
782
CB
ARG
A
1744
−5.281
22.215
21.048
1.00
25.81
C

ATOM
783
CG
ARG
A
1744
−6.598
21.754
21.636
1.00
28.55
C

ATOM
784
CD
ARG
A
1744
−7.147
20.493
21.013
1.00
30.52
C

ATOM
785
NE
ARG
A
1744
−6.331
19.330
21.342
1.00
33.35
N

ATOM
786
CZ
ARG
A
1744
−6.394
18.648
22.485
1.00
33.54
C

ATOM
787
NH1
ARG
A
1744
−7.241
19.002
23.452
1.00
34.73
N

ATOM
788
NH2
ARG
A
1744
−5.606
17.601
22.656
1.00
33.12
N

ATOM
789
N
ASN
A
1745
−3.030
24.683
20.591
1.00
24.58
N

ATOM
790
CA
ASN
A
1745
−1.707
24.941
20.031
1.00
24.66
C

ATOM
791
C
ASN
A
1745
−1.405
26.432
20.007
1.00
24.45
C

ATOM
792
O
ASN
A
1745
−0.840
26.930
19.052
1.00
25.27
O

ATOM
793
CB
ASN
A
1745
−1.587
24.343
18.613
1.00
25.58
C

ATOM
794
CG
ASN
A
1745
−0.138
24.299
18.099
1.00
26.95
C

ATOM
795
OD1
ASN
A
1745
0.793
24.017
18.841
1.00
27.90
O

ATOM
796
ND2
ASN
A
1745
0.044
24.617
16.831
1.00
31.89
N

ATOM
797
N
HIS
A
1746
−1.790
27.145
21.056
1.00
23.66
N

ATOM
798
CA
HIS
A
1746
−1.559
28.583
21.102
1.00
23.14
C

ATOM
799
C
HIS
A
1746
−0.078
28.956
21.278
1.00
23.27
C

ATOM
800
O
HIS
A
1746
0.321
30.099
21.010
1.00
23.59
O

ATOM
801
CB
HIS
A
1746
−2.449
29.255
22.157
1.00
23.84
C

ATOM
802
CG
HIS
A
1746
−2.192
28.797
23.560
1.00
24.37
C

ATOM
803
ND1
HIS
A
1746
−3.190
28.304
24.380
1.00
26.89
N

ATOM
804
CD2
HIS
A
1746
−1.057
28.779
24.296
1.00
21.40
C

ATOM
805
CE1
HIS
A
1746
−2.681
28.024
25.568
1.00
23.91
C

ATOM
806
NE2
HIS
A
1746
−1.383
28.275
25.532
1.00
27.21
N

ATOM
807
N
GLN
A
1747
0.726
27.994
21.724
1.00
21.90
N

ATOM
808
CA
GLN
A
1747
2.163
28.190
21.903
1.00
22.69
C

ATOM
809
C
GLN
A
1747
2.467
29.324
22.880
1.00
22.28
C

ATOM
810
O
GLN
A
1747
3.456
30.056
22.737
1.00
21.86
O

ATOM
811
CB
GLN
A
1747
2.876
28.416
20.549
1.00
22.24
C

ATOM
812
CG
GLN
A
1747
2.880
27.174
19.644
1.00
24.75
C

ATOM
813
CD
GLN
A
1747
3.813
26.050
20.128
1.00
28.16
C

ATOM
814
OE1
GLN
A
1747
4.806
26.306
20.844
1.00
29.19
O

ATOM
815
NE2
GLN
A
1747
3.509
24.808
19.727
1.00
28.13
N

ATOM
816
N
GLY
A
1748
1.606
29.463
23.877
1.00
21.59
N

ATOM
817
CA
GLY
A
1748
1.817
30.468
24.909
1.00
22.10
C

ATOM
818
C
GLY
A
1748
3.136
30.308
25.647
1.00
22.26
C

ATOM
819
O
GLY
A
1748
3.865
31.274
25.841
1.00
22.31
O

ATOM
820
N
PRO
A
1749
3.453
29.109
26.116
1.00
22.38
N

ATOM
821
CA
PRO
A
1749
4.722
28.941
26.832
1.00
22.37
C

ATOM
822
C
PRO
A
1749
5.935
29.398
26.013
1.00
21.94
C

ATOM
823
O
PRO
A
1749
6.760
30.146
26.542
1.00
22.26
O

ATOM
824
CB
PRO
A
1749
4.754
27.450
27.138
1.00
21.64
C

ATOM
825
CG
PRO
A
1749
3.282
27.108
27.273
1.00
22.05
C

ATOM
826
CD
PRO
A
1749
2.656
27.871
26.103
1.00
23.00
C

ATOM
827
N
LYS
A
1750
6.027
28.989
24.755
1.00
21.32
N

ATOM
828
CA
LYS
A
1750
7.130
29.403
23.893
1.00
21.74
C

ATOM
829
C
LYS
A
1750
7.147
30.925
23.711
1.00
21.91
C

ATOM
830
O
LYS
A
1750
8.204
31.531
23.745
1.00
21.20
O

ATOM
831
CB
LYS
A
1750
7.006
28.720
22.524
1.00
22.15
C

ATOM
832
CG
LYS
A
1750
7.929
29.271
21.427
1.00
22.74
C

ATOM
833
CD
LYS
A
1750
7.805
28.392
20.167
1.00
25.81
C

ATOM
834
CE
LYS
A
1750
8.765
28.810
19.020
1.00
26.22
C

ATOM
835
NZ
LYS
A
1750
8.569
30.219
18.581
1.00
27.71
N

ATOM
836
N
ARG
A
1751
5.976
31.536
23.539
1.00
21.71
N

ATOM
837
CA
ARG
A
1751
5.911
32.988
23.360
1.00
22.35
C

ATOM
838
C
ARG
A
1751
6.449
33.754
24.576
1.00
21.85
C

ATOM
839
O
ARG
A
1751
7.170
34.761
24.439
1.00
21.10
O

ATOM
840
CB
ARG
A
1751
4.481
33.438
23.026
1.00
23.43
C

ATOM
841
CG
ARG
A
1751
4.409
34.828
22.403
1.00
25.25
C

ATOM
842
CD
ARG
A
1751
3.261
34.995
21.382
1.00
29.76
C

ATOM
843
NE
ARG
A
1751
2.138
34.235
21.862
1.00
31.17
N

ATOM
844
CZ
ARG
A
1751
1.632
33.156
21.288
1.00
28.31
C

ATOM
845
NH1
ARG
A
1751
2.074
32.710
20.118
1.00
30.77
N

ATOM
846
NH2
ARG
A
1751
0.646
32.535
21.897
1.00
27.26
N

ATOM
847
N
ALA
A
1752
6.104
33.269
25.766
1.00
21.70
N

ATOM
848
CA
ALA
A
1752
6.598
33.888
26.989
1.00
22.04
C

ATOM
849
C
ALA
A
1752
8.111
33.729
27.096
1.00
20.96
C

ATOM
850
O
ALA
A
1752
8.821
34.668
27.457
1.00
21.13
O

ATOM
851
CB
ALA
A
1752
5.911
33.302
28.230
1.00
21.17
C

ATOM
852
N
ARG
A
1753
8.609
32.546
26.787
1.00
21.66
N

ATOM
853
CA
ARG
A
1753
10.058
32.339
26.834
1.00
22.12
C

ATOM
854
C
ARG
A
1753
10.731
33.325
25.907
1.00
22.24
C

ATOM
855
O
ARG
A
1753
11.835
33.791
26.166
1.00
23.14
O

ATOM
856
CB
ARG
A
1753
10.420
30.971
26.295
1.00
22.42
C

ATOM
857
CG
ARG
A
1753
10.230
29.803
27.216
1.00
22.67
C

ATOM
858
CD
ARG
A
1753
10.982
28.597
26.699
1.00
23.97
C

ATOM
859
NE
ARG
A
1753
10.466
28.027
25.449
1.00
23.88
N

ATOM
860
CZ
ARG
A
1753
11.042
28.143
24.244
1.00
24.85
C

ATOM
861
NH1
ARG
A
1753
12.135
28.884
24.059
1.00
24.13
N

ATOM
862
NH2
ARG
A
1753
10.510
27.520
23.202
1.00
24.17
N

ATOM
863
N
GLU
A
1754
10.055
33.627
24.807
1.00
22.93
N

ATOM
864
CA
GLU
A
1754
10.653
34.434
23.741
1.00
23.72
C

ATOM
865
C
GLU
A
1754
10.301
35.911
23.794
1.00
23.81
C

ATOM
866
O
GLU
A
1754
10.743
36.692
22.935
1.00
25.22
O

ATOM
867
CB
GLU
A
1754
10.285
33.828
22.368
1.00
23.29
C

ATOM
868
CG
GLU
A
1754
10.942
32.469
22.133
1.00
23.30
C

ATOM
869
CD
GLU
A
1754
10.563
31.775
20.826
1.00
27.24
C

ATOM
870
OE1
GLU
A
1754
9.548
32.149
20.191
1.00
26.54
O

ATOM
871
OE2
GLU
A
1754
11.294
30.824
20.437
1.00
25.87
O

ATOM
872
N
SER
A
1755
9.561
36.320
24.818
1.00
23.62
N

ATOM
873
CA
SER
A
1755
9.093
37.702
24.895
1.00
22.68
C

ATOM
874
C
SER
A
1755
9.408
38.385
26.203
1.00
22.66
C

ATOM
875
O
SER
A
1755
8.718
39.329
26.600
1.00
22.72
O

ATOM
876
CB
SER
A
1755
7.578
37.776
24.658
1.00
22.98
C

ATOM
877
OG
SER
A
1755
7.231
37.148
23.453
1.00
23.71
O

ATOM
878
N
GLN
A
1756
10.459
37.933
26.872
1.00
22.77
N

ATOM
879
CA
GLN
A
1756
10.830
38.532
28.139
1.00
23.68
C

ATOM
880
C
GLN
A
1756
11.280
39.990
28.046
1.00
24.52
C

ATOM
881
O
GLN
A
1756
11.255
40.693
29.046
1.00
23.97
O

ATOM
882
CB
GLN
A
1756
11.873
37.664
28.843
1.00
23.55
C

ATOM
883
CG
GLN
A
1756
11.269
36.348
29.285
1.00
23.77
C

ATOM
884
CD
GLN
A
1756
10.141
36.562
30.268
1.00
22.15
C

ATOM
885
OE1
GLN
A
1756
10.368
37.019
31.393
1.00
25.95
O

ATOM
886
NE2
GLN
A
1756
8.917
36.280
29.837
1.00
20.48
N

ATOM
887
N
ASP
A
1757
11.673
40.448
26.856
1.00
24.99
N

ATOM
888
CA
ASP
A
1757
12.064
41.844
26.689
1.00
25.99
C

ATOM
889
C
ASP
A
1757
10.852
42.710
26.355
1.00
25.49
C

ATOM
890
O
ASP
A
1757
10.955
43.929
26.283
1.00
25.57
O

ATOM
891
CB
ASP
A
1757
13.100
41.996
25.573
1.00
25.79
C

ATOM
892
CG
ASP
A
1757
14.477
41.547
25.992
1.00
29.24
C

ATOM
893
OD1
ASP
A
1757
14.805
41.582
27.206
1.00
29.38
O

ATOM
894
OD2
ASP
A
1757
15.300
41.150
25.151
1.00
30.88
O

ATOM
895
N
ARG
A
1758
9.712
42.072
26.132
1.00
25.82
N

ATOM
896
CA
ARG
A
1758
8.489
42.796
25.795
1.00
26.34
C

ATOM
897
C
ARG
A
1758
7.299
42.146
26.476
1.00
25.48
C

ATOM
898
O
ARG
A
1758
6.424
41.527
25.835
1.00
24.95
O

ATOM
899
CB
ARG
A
1758
8.279
42.827
24.290
1.00
26.91
C

ATOM
900
CG
ARG
A
1758
8.480
41.502
23.592
1.00
30.41
C

ATOM
901
CD
ARG
A
1758
7.575
41.327
22.384
1.00
36.98
C

ATOM
902
NE
ARG
A
1758
8.224
41.525
21.087
1.00
40.46
N

ATOM
903
CZ
ARG
A
1758
7.552
41.854
19.983
1.00
42.63
C

ATOM
904
NH1
ARG
A
1758
6.237
42.042
20.049
1.00
42.21
N

ATOM
905
NH2
ARG
A
1758
8.183
42.003
18.823
1.00
43.37
N

ATOM
906
N
LYS
A
1759
7.271
42.299
27.789
1.00
24.39
N

ATOM
907
CA
LYS
A
1759
6.260
41.648
28.600
1.00
24.35
C

ATOM
908
C
LYS
A
1759
4.855
42.177
28.314
1.00
24.82
C

ATOM
909
O
LYS
A
1759
4.672
43.362
27.997
1.00
24.88
O

ATOM
910
CB
LYS
A
1759
6.651
41.729
30.082
1.00
24.38
C

ATOM
911
CG
LYS
A
1759
8.007
41.043
30.344
1.00
25.02
C

ATOM
912
CD
LYS
A
1759
8.378
41.153
31.823
1.00
24.95
C

ATOM
913
CE
LYS
A
1759
9.664
40.425
32.149
1.00
28.10
C

ATOM
914
NZ
LYS
A
1759
9.863
40.333
33.620
1.00
31.56
N

ATOM
915
N
ILE
A
1760
3.875
41.283
28.408
1.00
24.02
N

ATOM
916
CA
ILE
A
1760
2.517
41.583
27.969
1.00
24.54
C

ATOM
917
C
ILE
A
1760
1.841
42.700
28.732
1.00
24.57
C

ATOM
918
O
ILE
A
1760
1.016
43.414
28.153
1.00
24.53
O

ATOM
919
CB
ILE
A
1760
1.636
40.319
27.961
1.00
24.05
C

ATOM
920
CG1
ILE
A
1760
1.639
39.637
29.326
1.00
24.38
C

ATOM
921
CG2
ILE
A
1760
2.073
39.349
26.852
1.00
23.90
C

ATOM
922
CD1
ILE
A
1760
0.599
38.501
29.393
1.00
23.37
C

ATOM
923
N
PHE
A
1761
2.215
42.891
30.000
1.00
23.67
N

ATOM
924
CA
PHE
A
1761
1.594
43.945
30.784
1.00
24.50
C

ATOM
925
C
PHE
A
1761
2.531
45.116
31.029
1.00
25.59
C

ATOM
926
O
PHE
A
1761
2.255
45.948
31.885
1.00
25.50
O

ATOM
927
CB
PHE
A
1761
1.051
43.428
32.122
1.00
24.34
C

ATOM
928
CG
PHE
A
1761
0.008
42.359
31.988
1.00
23.75
C

ATOM
929
CD1
PHE
A
1761
−0.098
41.368
32.954
1.00
23.52
C

ATOM
930
CD2
PHE
A
1761
−0.836
42.313
30.895
1.00
23.84
C

ATOM
931
CE1
PHE
A
1761
−1.025
40.341
32.840
1.00
25.32
C

ATOM
932
CE2
PHE
A
1761
−1.788
41.311
30.780
1.00
24.19
C

ATOM
933
CZ
PHE
A
1761
−1.883
40.325
31.758
1.00
24.88
C

ATOM
934
N
ARG
A
1762
3.618
45.210
30.268
1.00
26.42
N

ATOM
935
CA
ARG
A
1762
4.516
46.339
30.439
1.00
27.60
C

ATOM
936
C
ARG
A
1762
3.727
47.634
30.257
1.00
27.17
C

ATOM
937
O
ARG
A
1762
2.945
47.780
29.327
1.00
26.26
O

ATOM
938
CB
ARG
A
1762
5.689
46.269
29.449
1.00
28.28
C

ATOM
939
CG
ARG
A
1762
6.633
47.437
29.521
1.00
33.00
C

ATOM
940
CD
ARG
A
1762
7.099
47.919
28.120
1.00
42.26
C

ATOM
941
NE
ARG
A
1762
5.989
47.979
27.161
1.00
47.60
N

ATOM
942
CZ
ARG
A
1762
6.062
48.543
25.953
1.00
51.36
C

ATOM
943
NH1
ARG
A
1762
7.192
49.113
25.554
1.00
53.29
N

ATOM
944
NH2
ARG
A
1762
5.002
48.553
25.144
1.00
52.45
N

ATOM
945
N
GLY
A
1763
3.913
48.562
31.182
1.00
26.92
N

ATOM
946
CA
GLY
A
1763
3.252
49.860
31.081
1.00
26.68
C

ATOM
947
C
GLY
A
1763
1.835
49.890
31.617
1.00
26.75
C

ATOM
948
O
GLY
A
1763
1.106
50.864
31.416
1.00
27.22
O

ATOM
949
N
LEU
A
1764
1.428
48.824
32.298
1.00
26.19
N

ATOM
950
CA
LEU
A
1764
0.093
48.808
32.886
1.00
25.41
C

ATOM
951
C
LEU
A
1764
0.205
48.890
34.403
1.00
25.68
C

ATOM
952
O
LEU
A
1764
1.191
48.418
34.975
1.00
25.78
O

ATOM
953
CB
LEU
A
1764
−0.637
47.518
32.502
1.00
25.52
C

ATOM
954
CG
LEU
A
1764
−0.955
47.286
31.024
1.00
25.66
C

ATOM
955
CD1
LEU
A
1764
−1.713
45.958
30.840
1.00
22.88
C

ATOM
956
CD2
LEU
A
1764
−1.771
48.432
30.451
1.00
26.36
C

ATOM
957
N
GLU
A
1765
−0.782
49.503
35.051
1.00
25.40
N

ATOM
958
CA
GLU
A
1765
−0.849
49.516
36.509
1.00
25.54
C

ATOM
959
C
GLU
A
1765
−2.077
48.690
36.866
1.00
25.27
C

ATOM
960
O
GLU
A
1765
−3.167
49.022
36.444
1.00
24.89
O

ATOM
961
CB
GLU
A
1765
−1.046
50.932
37.059
1.00
26.09
C

ATOM
962
CG
GLU
A
1765
0.228
51.725
37.201
1.00
28.37
C

ATOM
963
CD
GLU
A
1765
0.103
52.849
38.220
1.00
29.58
C

ATOM
964
OE1
GLU
A
1765
−1.031
53.182
38.649
1.00
24.60
O

ATOM
965
OE2
GLU
A
1765
1.158
53.392
38.585
1.00
31.79
O

ATOM
966
N
ILE
A
1766
−1.915
47.640
37.661
1.00
25.07
N

ATOM
967
CA
ILE
A
1766
−3.047
46.767
37.965
1.00
25.10
C

ATOM
968
C
ILE
A
1766
−3.355
46.639
39.461
1.00
25.75
C

ATOM
969
O
ILE
A
1766
−2.452
46.414
40.289
1.00
25.20
O

ATOM
970
CB
ILE
A
1766
−2.785
45.356
37.384
1.00
25.40
C

ATOM
971
CG1
ILE
A
1766
−2.559
45.413
35.870
1.00
24.46
C

ATOM
972
CG2
ILE
A
1766
−3.904
44.395
37.767
1.00
25.24
C

ATOM
973
CD1
ILE
A
1766
−2.278
44.030
35.244
1.00
24.35
C

ATOM
974
N
CYS
A
1767
−4.628
46.794
39.808
1.00
25.42
N

ATOM
975
CA
CYS
A
1767
−5.047
46.584
41.183
1.00
26.50
C

ATOM
976
C
CYS
A
1767
−5.880
45.314
41.180
1.00
26.43
C

ATOM
977
O
CYS
A
1767
−6.894
45.247
40.485
1.00
26.80
O

ATOM
978
CB
CYS
A
1767
−5.873
47.753
41.703
1.00
26.42
C

ATOM
979
SG
CYS
A
1767
−6.536
47.543
43.396
1.00
27.72
S

ATOM
980
N
CYS
A
1768
−5.419
44.301
41.912
1.00
26.05
N

ATOM
981
CA
CYS
A
1768
−6.172
43.066
42.073
1.00
26.62
C

ATOM
982
C
CYS
A
1768
−7.088
43.276
43.286
1.00
26.73
C

ATOM
983
O
CYS
A
1768
−6.659
43.185
44.438
1.00
26.77
O

ATOM
984
CB
CYS
A
1768
−5.220
41.894
42.289
1.00
26.35
C

ATOM
985
SG
CYS
A
1768
−4.129
41.599
40.873
1.00
26.54
S

ATOM
986
N
TYR
A
1769
−8.345
43.564
42.996
1.00
26.38
N

ATOM
987
CA
TYR
A
1769
−9.317
44.004
43.985
1.00
27.38
C

ATOM
988
C
TYR
A
1769
−10.229
42.835
44.378
1.00
27.66
C

ATOM
989
O
TYR
A
1769
−11.058
42.389
43.593
1.00
26.66
O

ATOM
990
CB
TYR
A
1769
−10.100
45.181
43.378
1.00
27.50
C

ATOM
991
CG
TYR
A
1769
−10.926
45.996
44.355
1.00
29.17
C

ATOM
992
CD1
TYR
A
1769
−10.330
46.866
45.288
1.00
29.79
C

ATOM
993
CD2
TYR
A
1769
−12.300
45.931
44.316
1.00
30.16
C

ATOM
994
CE1
TYR
A
1769
−11.118
47.608
46.178
1.00
30.57
C

ATOM
995
CE2
TYR
A
1769
−13.080
46.678
45.185
1.00
32.31
C

ATOM
996
CZ
TYR
A
1769
−12.499
47.486
46.121
1.00
31.34
C

ATOM
997
OH
TYR
A
1769
−13.308
48.202
46.974
1.00
30.45
O

ATOM
998
N
GLY
A
1770
−10.019
42.327
45.595
1.00
28.90
N

ATOM
999
CA
GLY
A
1770
−10.709
41.134
46.094
1.00
29.31
C

ATOM
1000
C
GLY
A
1770
−12.176
41.304
46.425
1.00
30.06
C

ATOM
1001
O
GLY
A
1770
−12.705
42.422
46.404
1.00
31.36
O

ATOM
1002
N
PRO
A
1771
−12.818
40.204
46.807
1.00
30.31
N

ATOM
1003
CA
PRO
A
1771
−12.145
38.915
47.043
1.00
29.88
C

ATOM
1004
C
PRO
A
1771
−11.942
37.998
45.828
1.00
29.33
C

ATOM
1005
O
PRO
A
1771
−12.560
38.177
44.779
1.00
28.62
O

ATOM
1006
CB
PRO
A
1771
−13.121
38.183
47.983
1.00
29.86
C

ATOM
1007
CG
PRO
A
1771
−14.454
38.880
47.821
1.00
30.66
C

ATOM
1008
CD
PRO
A
1771
−14.278
40.096
46.972
1.00
30.69
C

ATOM
1009
N
PHE
A
1772
−11.102
36.982
46.013
1.00
28.54
N

ATOM
1010
CA
PHE
A
1772
−10.860
35.957
44.996
1.00
27.89
C

ATOM
1011
C
PHE
A
1772
−10.924
34.559
45.622
1.00
28.22
C

ATOM
1012
O
PHE
A
1772
−10.799
34.406
46.850
1.00
27.52
O

ATOM
1013
CB
PHE
A
1772
−9.489
36.138
44.324
1.00
27.92
C

ATOM
1014
CG
PHE
A
1772
−9.315
37.458
43.628
1.00
26.98
C

ATOM
1015
CD1
PHE
A
1772
−8.686
38.509
44.271
1.00
26.56
C

ATOM
1016
CD2
PHE
A
1772
−9.792
37.651
42.345
1.00
27.57
C

ATOM
1017
CE1
PHE
A
1772
−8.518
39.744
43.646
1.00
26.59
C

ATOM
1018
CE2
PHE
A
1772
−9.633
38.895
41.706
1.00
28.29
C

ATOM
1019
CZ
PHE
A
1772
−9.007
39.941
42.370
1.00
24.25
C

ATOM
1020
N
THR
A
1773
−11.130
33.547
44.778
1.00
28.39
N

ATOM
1021
CA
THR
A
1773
−11.074
32.177
45.232
1.00
29.16
C

ATOM
1022
C
THR
A
1773
−10.002
31.383
44.492
1.00
29.03
C

ATOM
1023
O
THR
A
1773
−9.651
31.684
43.343
1.00
28.55
O

ATOM
1024
CB
THR
A
1773
−12.443
31.458
45.060
1.00
29.72
C

ATOM
1025
OG1
THR
A
1773
−12.671
31.172
43.671
1.00
29.53
O

ATOM
1026
CG2
THR
A
1773
−13.582
32.392
45.445
1.00
30.21
C

ATOM
1027
N
ASN
A
1774
−9.492
30.368
45.186
1.00
29.25
N

ATOM
1028
CA
ASN
A
1774
−8.536
29.404
44.644
1.00
30.24
C

ATOM
1029
C
ASN
A
1774
−7.206
29.965
44.193
1.00
29.98
C

ATOM
1030
O
ASN
A
1774
−6.348
29.239
43.720
1.00
30.34
O

ATOM
1031
CB
ASN
A
1774
−9.188
28.599
43.520
1.00
30.62
C

ATOM
1032
CG
ASN
A
1774
−10.395
27.829
44.007
1.00
33.86
C

ATOM
1033
OD1
ASN
A
1774
−11.327
27.536
43.256
1.00
38.78
O

ATOM
1034
ND2
ASN
A
1774
−10.395
27.533
45.297
1.00
34.54
N

ATOM
1035
N
MET
A
1775
−7.040
31.253
44.341
1.00
30.26
N

ATOM
1036
CA
MET
A
1775
−5.780
31.854
43.959
1.00
30.54
C

ATOM
1037
C
MET
A
1775
−5.523
33.037
44.869
1.00
30.62
C

ATOM
1038
O
MET
A
1775
−6.146
34.085
44.717
1.00
31.41
O

ATOM
1039
CB
MET
A
1775
−5.810
32.262
42.483
1.00
30.05
C

ATOM
1040
CG
MET
A
1775
−4.477
32.792
41.944
1.00
30.94
C

ATOM
1041
SD
MET
A
1775
−4.637
33.327
40.209
1.00
30.61
S

ATOM
1042
CE
MET
A
1775
−4.763
31.773
39.369
1.00
28.57
C

ATOM
1043
N
PRO
A
1776
−4.618
32.862
45.829
1.00
30.40
N

ATOM
1044
CA
PRO
A
1776
−4.292
33.922
46.781
1.00
29.77
C

ATOM
1045
C
PRO
A
1776
−3.943
35.191
46.037
1.00
29.25
C

ATOM
1046
O
PRO
A
1776
−3.230
35.183
45.026
1.00
28.93
O

ATOM
1047
CB
PRO
A
1776
−3.069
33.387
47.530
1.00
29.89
C

ATOM
1048
CG
PRO
A
1776
−3.098
31.908
47.334
1.00
30.76
C

ATOM
1049
CD
PRO
A
1776
−3.842
31.634
46.061
1.00
30.92
C

ATOM
1050
N
THR
A
1777
−4.458
36.294
46.562
1.00
28.71
N

ATOM
1051
CA
THR
A
1777
−4.290
37.596
45.961
1.00
27.45
C

ATOM
1052
C
THR
A
1777
−2.855
37.948
45.632
1.00
27.45
C

ATOM
1053
O
THR
A
1777
−2.586
38.522
44.577
1.00
25.81
O

ATOM
1054
CB
THR
A
1777
−4.870
38.661
46.894
1.00
28.01
C

ATOM
1055
OG1
THR
A
1777
−6.289
38.477
46.953
1.00
27.40
O

ATOM
1056
CG2
THR
A
1777
−4.683
40.049
46.291
1.00
27.84
C

ATOM
1057
N
ASP
A
1778
−1.925
37.632
46.523
1.00
26.91
N

ATOM
1058
CA
ASP
A
1778
−0.547
38.018
46.248
1.00
27.03
C

ATOM
1059
C
ASP
A
1778
0.121
37.162
45.168
1.00
26.11
C

ATOM
1060
O
ASP
A
1778
1.205
37.492
44.695
1.00
26.57
O

ATOM
1061
CB
ASP
A
1778
0.313
38.160
47.515
1.00
27.89
C

ATOM
1062
CG
ASP
A
1778
0.442
36.877
48.309
1.00
30.00
C

ATOM
1063
OD1
ASP
A
1778
0.036
35.787
47.833
1.00
29.81
O

ATOM
1064
OD2
ASP
A
1778
0.948
36.893
49.465
1.00
33.69
O

ATOM
1065
N
GLN
A
1779
−0.540
36.098
44.751
1.00
25.07
N

ATOM
1066
CA
GLN
A
1779
−0.015
35.251
43.684
1.00
24.31
C

ATOM
1067
C
GLN
A
1779
−0.510
35.789
42.362
1.00
23.67
C

ATOM
1068
O
GLN
A
1779
0.208
35.740
41.357
1.00
22.63
O

ATOM
1069
CB
GLN
A
1779
−0.423
33.791
43.873
1.00
24.21
C

ATOM
1070
CG
GLN
A
1779
0.120
33.177
45.163
1.00
26.13
C

ATOM
1071
CD
GLN
A
1779
1.609
33.436
45.346
1.00
27.16
C

ATOM
1072
OE1
GLN
A
1779
2.014
34.357
46.083
1.00
30.91
O

ATOM
1073
NE2
GLN
A
1779
2.432
32.653
44.659
1.00
26.73
N

ATOM
1074
N
LEU
A
1780
−1.745
36.292
42.357
1.00
23.18
N

ATOM
1075
CA
LEU
A
1780
−2.262
36.977
41.179
1.00
23.21
C

ATOM
1076
C
LEU
A
1780
−1.404
38.228
40.982
1.00
22.75
C

ATOM
1077
O
LEU
A
1780
−1.034
38.558
39.857
1.00
21.45
O

ATOM
1078
CB
LEU
A
1780
−3.757
37.347
41.336
1.00
23.73
C

ATOM
1079
CG
LEU
A
1780
−4.484
37.965
40.122
1.00
24.76
C

ATOM
1080
CD1
LEU
A
1780
−4.382
37.080
38.872
1.00
23.61
C

ATOM
1081
CD2
LEU
A
1780
−5.961
38.264
40.472
1.00
23.90
C

ATOM
1082
N
GLU
A
1781
−1.053
38.908
42.077
1.00
22.70
N

ATOM
1083
CA
GLU
A
1781
−0.215
40.099
41.964
1.00
22.82
C

ATOM
1084
C
GLU
A
1781
1.166
39.727
41.433
1.00
22.65
C

ATOM
1085
O
GLU
A
1781
1.712
40.398
40.566
1.00
22.98
O

ATOM
1086
CB
GLU
A
1781
−0.110
40.829
43.302
1.00
23.74
C

ATOM
1087
CG
GLU
A
1781
−1.450
41.413
43.720
1.00
25.21
C

ATOM
1088
CD
GLU
A
1781
−1.422
41.983
45.119
1.00
31.15
C

ATOM
1089
OE1
GLU
A
1781
−0.600
41.510
45.928
1.00
32.47
O

ATOM
1090
OE2
GLU
A
1781
−2.210
42.908
45.403
1.00
31.02
O

ATOM
1091
N
TRP
A
1782
1.732
38.643
41.944
1.00
21.92
N

ATOM
1092
CA
TRP
A
1782
3.039
38.200
41.452
1.00
21.24
C

ATOM
1093
C
TRP
A
1782
2.961
37.904
39.945
1.00
20.76
C

ATOM
1094
O
TRP
A
1782
3.822
38.327
39.143
1.00
18.96
O

ATOM
1095
CB
TRP
A
1782
3.515
36.973
42.243
1.00
21.65
C

ATOM
1096
CG
TRP
A
1782
4.941
36.541
41.916
1.00
23.52
C

ATOM
1097
CD1
TRP
A
1782
5.987
37.344
41.526
1.00
25.08
C

ATOM
1098
CD2
TRP
A
1782
5.460
35.208
41.972
1.00
23.57
C

ATOM
1099
NE1
TRP
A
1782
7.118
36.580
41.329
1.00
25.54
N

ATOM
1100
CE2
TRP
A
1782
6.820
35.266
41.599
1.00
23.80
C

ATOM
1101
CE3
TRP
A
1782
4.907
33.962
42.302
1.00
24.18
C

ATOM
1102
CZ2
TRP
A
1782
7.638
34.122
41.535
1.00
24.52
C

ATOM
1103
CZ3
TRP
A
1782
5.723
32.826
42.247
1.00
24.47
C

ATOM
1104
CH2
TRP
A
1782
7.067
32.918
41.858
1.00
24.87
C

ATOM
1105
N
MET
A
1783
1.910
37.189
39.557
1.00
20.12
N

ATOM
1106
CA
MET
A
1783
1.719
36.856
38.156
1.00
21.28
C

ATOM
1107
C
MET
A
1783
1.753
38.103
37.272
1.00
21.46
C

ATOM
1108
O
MET
A
1783
2.467
38.156
36.259
1.00
22.05
O

ATOM
1109
CB
MET
A
1783
0.373
36.142
37.970
1.00
21.69
C

ATOM
1110
CG
MET
A
1783
0.220
35.408
36.647
1.00
21.85
C

ATOM
1111
SD
MET
A
1783
−1.512
34.881
36.351
1.00
22.73
S

ATOM
1112
CE
MET
A
1783
−1.745
33.707
37.731
1.00
22.61
C

ATOM
1113
N
VAL
A
1784
0.958
39.103
37.611
1.00
21.18
N

ATOM
1114
CA
VAL
A
1784
0.947
40.285
36.755
1.00
21.52
C

ATOM
1115
C
VAL
A
1784
2.284
41.013
36.807
1.00
22.09
C

ATOM
1116
O
VAL
A
1784
2.729
41.537
35.799
1.00
21.53
O

ATOM
1117
CB
VAL
A
1784
−0.276
41.192
37.004
1.00
21.45
C

ATOM
1118
CG1
VAL
A
1784
−1.568
40.359
36.842
1.00
21.13
C

ATOM
1119
CG2
VAL
A
1784
−0.220
41.862
38.379
1.00
22.13
C

ATOM
1120
N
GLN
A
1785
2.948
41.003
37.963
1.00
23.00
N

ATOM
1121
CA
GLN
A
1785
4.251
41.649
38.077
1.00
24.82
C

ATOM
1122
C
GLN
A
1785
5.294
40.979
37.196
1.00
24.78
C

ATOM
1123
O
GLN
A
1785
6.104
41.643
36.540
1.00
24.69
O

ATOM
1124
CB
GLN
A
1785
4.741
41.635
39.517
1.00
26.16
C

ATOM
1125
CG
GLN
A
1785
4.171
42.738
40.352
1.00
32.52
C

ATOM
1126
CD
GLN
A
1785
4.792
42.783
41.733
1.00
37.16
C

ATOM
1127
OE1
GLN
A
1785
5.533
43.712
42.055
1.00
41.54
O

ATOM
1128
NE2
GLN
A
1785
4.508
41.767
42.546
1.00
41.37
N

ATOM
1129
N
LEU
A
1786
5.286
39.658
37.216
1.00
23.87
N

ATOM
1130
CA
LEU
A
1786
6.176
38.868
36.384
1.00
23.75
C

ATOM
1131
C
LEU
A
1786
5.915
39.218
34.927
1.00
23.54
C

ATOM
1132
O
LEU
A
1786
6.806
39.125
34.070
1.00
22.97
O

ATOM
1133
CB
LEU
A
1786
5.874
37.391
36.585
1.00
23.20
C

ATOM
1134
CG
LEU
A
1786
6.414
36.754
37.873
1.00
23.54
C

ATOM
1135
CD1
LEU
A
1786
5.777
35.425
38.059
1.00
24.11
C

ATOM
1136
CD2
LEU
A
1786
7.938
36.632
37.805
1.00
24.52
C

ATOM
1137
N
CYS
A
1787
4.674
39.602
34.663
1.00
23.42
N

ATOM
1138
CA
CYS
A
1787
4.244
39.955
33.309
1.00
23.93
C

ATOM
1139
C
CYS
A
1787
4.455
41.436
32.969
1.00
24.40
C

ATOM
1140
O
CYS
A
1787
3.934
41.940
31.961
1.00
23.74
O

ATOM
1141
CB
CYS
A
1787
2.784
39.549
33.077
1.00
24.32
C

ATOM
1142
SG
CYS
A
1787
2.557
37.759
32.865
1.00
24.92
S

ATOM
1143
N
GLY
A
1788
5.202
42.136
33.819
1.00
24.77
N

ATOM
1144
CA
GLY
A
1788
5.551
43.517
33.535
1.00
24.95
C

ATOM
1145
C
GLY
A
1788
4.697
44.588
34.170
1.00
25.18
C

ATOM
1146
O
GLY
A
1788
5.039
45.780
34.101
1.00
25.67
O

ATOM
1147
N
ALA
A
1789
3.590
44.208
34.805
1.00
25.56
N

ATOM
1148
CA
ALA
A
1789
2.741
45.242
35.394
1.00
26.40
C

ATOM
1149
C
ALA
A
1789
3.277
45.784
36.709
1.00
27.37
C

ATOM
1150
O
ALA
A
1789
4.032
45.112
37.422
1.00
27.03
O

ATOM
1151
CB
ALA
A
1789
1.326
44.724
35.606
1.00
26.61
C

ATOM
1152
N
SER
A
1790
2.827
46.991
37.034
1.00
27.98
N

ATOM
1153
CA
SER
A
1790
3.066
47.591
38.328
1.00
29.61
C

ATOM
1154
C
SER
A
1790
1.843
47.255
39.194
1.00
29.23
C

ATOM
1155
O
SER
A
1790
0.697
47.460
38.787
1.00
29.69
O

ATOM
1156
CB
SER
A
1790
3.250
49.107
38.185
1.00
29.58
C

ATOM
1157
OG
SER
A
1790
3.437
49.677
39.464
1.00
35.28
O

ATOM
1158
N
VAL
A
1791
2.086
46.689
40.368
1.00
28.99
N

ATOM
1159
CA
VAL
A
1791
1.019
46.317
41.279
1.00
29.25
C

ATOM
1160
C
VAL
A
1791
0.618
47.514
42.137
1.00
29.63
C

ATOM
1161
O
VAL
A
1791
1.466
48.204
42.720
1.00
29.53
O

ATOM
1162
CB
VAL
A
1791
1.441
45.133
42.201
1.00
28.68
C

ATOM
1163
CG1
VAL
A
1791
0.403
44.903
43.313
1.00
28.69
C

ATOM
1164
CG2
VAL
A
1791
1.621
43.862
41.380
1.00
30.13
C

ATOM
1165
N
VAL
A
1792
−0.683
47.751
42.202
1.00
29.72
N

ATOM
1166
CA
VAL
A
1792
−1.234
48.835
42.994
1.00
30.74
C

ATOM
1167
C
VAL
A
1792
−2.142
48.188
44.036
1.00
30.89
C

ATOM
1168
O
VAL
A
1792
−2.986
47.378
43.686
1.00
29.79
O

ATOM
1169
CB
VAL
A
1792
−2.033
49.793
42.080
1.00
30.90
C

ATOM
1170
CG1
VAL
A
1792
−2.978
50.638
42.884
1.00
30.73
C

ATOM
1171
CG2
VAL
A
1792
−1.071
50.651
41.236
1.00
31.57
C

ATOM
1172
N
LYS
A
1793
−1.970
48.540
45.310
1.00
32.08
N

ATOM
1173
CA
LYS
A
1793
−2.735
47.881
46.379
1.00
33.72
C

ATOM
1174
C
LYS
A
1793
−4.101
48.496
46.676
1.00
34.33
C

ATOM
1175
O
LYS
A
1793
−5.025
47.763
47.014
1.00
35.08
O

ATOM
1176
CB
LYS
A
1793
−1.907
47.782
47.669
1.00
34.32
C

ATOM
1177
CG
LYS
A
1793
−0.664
46.915
47.555
1.00
36.55
C

ATOM
1178
CD
LYS
A
1793
−1.003
45.423
47.603
1.00
40.35
C

ATOM
1179
CE
LYS
A
1793
0.256
44.557
47.500
1.00
42.72
C

ATOM
1180
NZ
LYS
A
1793
1.199
44.732
48.633
1.00
44.75
N

ATOM
1181
N
GLU
A
1794
−4.241
49.819
46.575
1.00
34.78
N

ATOM
1182
CA
GLU
A
1794
−5.551
50.454
46.822
1.00
35.65
C

ATOM
1183
C
GLU
A
1794
−6.058
51.230
45.606
1.00
34.89
C

ATOM
1184
O
GLU
A
1794
−5.267
51.766
44.832
1.00
34.81
O

ATOM
1185
CB
GLU
A
1794
−5.500
51.404
48.031
1.00
36.31
C

ATOM
1186
CG
GLU
A
1794
−4.507
51.007
49.112
1.00
40.43
C

ATOM
1187
CD
GLU
A
1794
−4.908
51.476
50.498
1.00
46.67
C

ATOM
1188
OE1
GLU
A
1794
−6.117
51.717
50.739
1.00
49.99
O

ATOM
1189
OE2
GLU
A
1794
−4.009
51.585
51.363
1.00
50.69
O

ATOM
1190
N
LEU
A
1795
−7.379
51.282
45.436
1.00
34.55
N

ATOM
1191
CA
LEU
A
1795
−7.967
52.058
44.341
1.00
34.48
C

ATOM
1192
C
LEU
A
1795
−7.456
53.514
44.319
1.00
34.20
C

ATOM
1193
O
LEU
A
1795
−7.067
54.025
43.275
1.00
34.82
O

ATOM
1194
CB
LEU
A
1795
−9.496
52.035
44.407
1.00
34.12
C

ATOM
1195
CG
LEU
A
1795
−10.092
50.631
44.290
1.00
34.35
C

ATOM
1196
CD1
LEU
A
1795
−11.634
50.609
44.319
1.00
34.41
C

ATOM
1197
CD2
LEU
A
1795
−9.568
49.911
43.045
1.00
33.04
C

ATOM
1198
N
SER
A
1796
−7.451
54.170
45.473
1.00
33.85
N

ATOM
1199
CA
SER
A
1796
−7.001
55.556
45.569
1.00
33.64
C

ATOM
1200
C
SER
A
1796
−5.520
55.749
45.220
1.00
33.01
C

ATOM
1201
O
SER
A
1796
−5.047
56.882
45.132
1.00
33.00
O

ATOM
1202
CB
SER
A
1796
−7.258
56.091
46.982
1.00
33.48
C

ATOM
1203
OG
SER
A
1796
−6.701
55.215
47.955
1.00
34.78
O

ATOM
1204
N
SER
A
1797
−4.797
54.651
45.007
1.00
32.29
N

ATOM
1205
CA
SER
A
1797
−3.349
54.710
44.783
1.00
31.84
C

ATOM
1206
C
SER
A
1797
−2.869
54.603
43.337
1.00
30.36
C

ATOM
1207
O
SER
A
1797
−1.666
54.496
43.095
1.00
30.34
O

ATOM
1208
CB
SER
A
1797
−2.643
53.634
45.610
1.00
32.61
C

ATOM
1209
OG
SER
A
1797
−2.594
53.987
46.976
1.00
35.22
O

ATOM
1210
N
PHE
A
1798
−3.787
54.584
42.382
1.00
29.13
N

ATOM
1211
CA
PHE
A
1798
−3.377
54.544
40.981
1.00
28.27
C

ATOM
1212
C
PHE
A
1798
−2.633
55.840
40.680
1.00
27.54
C

ATOM
1213
O
PHE
A
1798
−3.023
56.917
41.142
1.00
26.96
O

ATOM
1214
CB
PHE
A
1798
−4.591
54.468
40.047
1.00
27.93
C

ATOM
1215
CG
PHE
A
1798
−5.142
53.089
39.864
1.00
28.24
C

ATOM
1216
CD1
PHE
A
1798
−6.488
52.829
40.113
1.00
28.79
C

ATOM
1217
CD2
PHE
A
1798
−4.327
52.048
39.430
1.00
28.00
C

ATOM
1218
CE1
PHE
A
1798
−7.017
51.554
39.924
1.00
28.17
C

ATOM
1219
CE2
PHE
A
1798
−4.850
50.775
39.238
1.00
28.78
C

ATOM
1220
CZ
PHE
A
1798
−6.194
50.525
39.494
1.00
28.31
C

ATOM
1221
N
THR
A
1799
−1.560
55.726
39.909
1.00
26.11
N

ATOM
1222
CA
THR
A
1799
−0.850
56.889
39.435
1.00
25.21
C

ATOM
1223
C
THR
A
1799
−1.724
57.611
38.436
1.00
24.62
C

ATOM
1224
O
THR
A
1799
−2.408
56.974
37.639
1.00
24.51
O

ATOM
1225
CB
THR
A
1799
0.388
56.432
38.701
1.00
25.30
C

ATOM
1226
OG1
THR
A
1799
1.172
55.607
39.573
1.00
24.19
O

ATOM
1227
CG2
THR
A
1799
1.275
57.623
38.340
1.00
26.71
C

ATOM
1228
N
LEU
A
1800
−1.683
58.935
38.438
1.00
23.91
N

ATOM
1229
CA
LEU
A
1800
−2.497
59.685
37.475
1.00
24.00
C

ATOM
1230
C
LEU
A
1800
−1.670
60.194
36.303
1.00
23.62
C

ATOM
1231
O
LEU
A
1800
−0.476
60.390
36.425
1.00
23.32
O

ATOM
1232
CB
LEU
A
1800
−3.176
60.875
38.168
1.00
23.94
C

ATOM
1233
CG
LEU
A
1800
−4.104
60.525
39.327
1.00
25.45
C

ATOM
1234
CD1
LEU
A
1800
−4.663
61.829
39.955
1.00
28.64
C

ATOM
1235
CD2
LEU
A
1800
−5.234
59.638
38.820
1.00
26.80
C

ATOM
1236
N
GLY
A
1801
−2.314
60.437
35.168
1.00
23.19
N

ATOM
1237
CA
GLY
A
1801
−1.583
60.954
34.032
1.00
25.22
C

ATOM
1238
C
GLY
A
1801
−2.114
60.320
32.769
1.00
25.49
C

ATOM
1239
O
GLY
A
1801
−2.629
59.212
32.788
1.00
26.11
O

ATOM
1240
N
THR
A
1802
−2.058
61.079
31.681
1.00
26.23
N

ATOM
1241
CA
THR
A
1802
−2.548
60.612
30.398
1.00
26.84
C

ATOM
1242
C
THR
A
1802
−1.744
59.425
29.910
1.00
27.25
C

ATOM
1243
O
THR
A
1802
−2.208
58.689
29.055
1.00
28.30
O

ATOM
1244
CB
THR
A
1802
−2.467
61.743
29.352
1.00
27.62
C

ATOM
1245
OG1
THR
A
1802
−1.089
61.967
28.999
1.00
28.27
O

ATOM
1246
CG2
THR
A
1802
−2.883
63.061
29.977
1.00
25.34
C

ATOM
1247
N
GLY
A
1803
−0.545
59.229
30.446
1.00
27.35
N

ATOM
1248
CA
GLY
A
1803
0.317
58.148
30.007
1.00
28.09
C

ATOM
1249
C
GLY
A
1803
0.191
56.888
30.834
1.00
27.92
C

ATOM
1250
O
GLY
A
1803
0.850
55.874
30.567
1.00
28.48
O

ATOM
1251
N
VAL
A
1804
−0.658
56.955
31.852
1.00
27.70
N

ATOM
1252
CA
VAL
A
1804
−0.867
55.827
32.741
1.00
27.47
C

ATOM
1253
C
VAL
A
1804
−2.065
55.016
32.288
1.00
27.67
C

ATOM
1254
O
VAL
A
1804
−3.061
55.587
31.808
1.00
27.02
O

ATOM
1255
CB
VAL
A
1804
−1.120
56.308
34.169
1.00
27.03
C

ATOM
1256
CG1
VAL
A
1804
−1.325
55.108
35.098
1.00
28.08
C

ATOM
1257
CG2
VAL
A
1804
0.052
57.178
34.650
1.00
27.40
C

ATOM
1258
N
HIS
A
1805
−1.960
53.690
32.434
1.00
26.47
N

ATOM
1259
CA
HIS
A
1805
−3.069
52.823
32.090
1.00
27.22
C

ATOM
1260
C
HIS
A
1805
−3.413
51.972
33.303
1.00
26.98
C

ATOM
1261
O
HIS
A
1805
−2.804
50.919
33.522
1.00
27.22
O

ATOM
1262
CB
HIS
A
1805
−2.675
51.931
30.906
1.00
27.66
C

ATOM
1263
CG
HIS
A
1805
−2.300
52.702
29.677
1.00
30.66
C

ATOM
1264
ND1
HIS
A
1805
−1.015
53.135
29.433
1.00
33.02
N

ATOM
1265
CD2
HIS
A
1805
−3.052
53.155
28.647
1.00
32.98
C

ATOM
1266
CE1
HIS
A
1805
−0.990
53.808
28.295
1.00
34.99
C

ATOM
1267
NE2
HIS
A
1805
−2.213
53.839
27.801
1.00
33.22
N

ATOM
1268
N
PRO
A
1806
−4.364
52.431
34.106
1.00
27.41
N

ATOM
1269
CA
PRO
A
1806
−4.797
51.696
35.297
1.00
27.21
C

ATOM
1270
C
PRO
A
1806
−5.858
50.685
34.919
1.00
26.94
C

ATOM
1271
O
PRO
A
1806
−6.607
50.909
33.976
1.00
26.42
O

ATOM
1272
CB
PRO
A
1806
−5.410
52.787
36.169
1.00
27.64
C

ATOM
1273
CG
PRO
A
1806
−5.967
53.792
35.167
1.00
27.46
C

ATOM
1274
CD
PRO
A
1806
−5.092
53.711
33.947
1.00
28.06
C

ATOM
1275
N
ILE
A
1807
−5.886
49.559
35.617
1.00
26.23
N

ATOM
1276
CA
ILE
A
1807
−6.886
48.527
35.358
1.00
26.34
C

ATOM
1277
C
ILE
A
1807
−7.214
47.876
36.675
1.00
25.82
C

ATOM
1278
O
ILE
A
1807
−6.318
47.535
37.437
1.00
26.03
O

ATOM
1279
CB
ILE
A
1807
−6.350
47.434
34.411
1.00
26.45
C

ATOM
1280
CG1
ILE
A
1807
−5.870
48.039
33.090
1.00
27.84
C

ATOM
1281
CG2
ILE
A
1807
−7.435
46.373
34.164
1.00
26.41
C

ATOM
1282
CD1
ILE
A
1807
−5.146
47.047
32.202
1.00
30.14
C

ATOM
1283
N
VAL
A
1808
−8.494
47.710
36.949
1.00
25.46
N

ATOM
1284
CA
VAL
A
1808
−8.921
47.035
38.156
1.00
25.00
C

ATOM
1285
C
VAL
A
1808
−9.364
45.636
37.775
1.00
24.67
C

ATOM
1286
O
VAL
A
1808
−10.184
45.449
36.864
1.00
24.19
O

ATOM
1287
CB
VAL
A
1808
−10.085
47.765
38.830
1.00
25.12
C

ATOM
1288
CG1
VAL
A
1808
−10.517
47.022
40.109
1.00
24.18
C

ATOM
1289
CG2
VAL
A
1808
−9.692
49.214
39.121
1.00
25.14
C

ATOM
1290
N
VAL
A
1809
−8.785
44.647
38.440
1.00
24.13
N

ATOM
1291
CA
VAL
A
1809
−9.157
43.267
38.201
1.00
24.25
C

ATOM
1292
C
VAL
A
1809
−9.965
42.697
39.381
1.00
24.70
C

ATOM
1293
O
VAL
A
1809
−9.548
42.788
40.544
1.00
25.01
O

ATOM
1294
CB
VAL
A
1809
−7.905
42.393
37.933
1.00
24.82
C

ATOM
1295
CG1
VAL
A
1809
−8.283
40.922
37.783
1.00
23.99
C

ATOM
1296
CG2
VAL
A
1809
−7.173
42.872
36.670
1.00
22.98
C

ATOM
1297
N
VAL
A
1810
−11.108
42.091
39.068
1.00
25.04
N

ATOM
1298
CA
VAL
A
1810
−11.971
41.467
40.068
1.00
25.87
C

ATOM
1299
C
VAL
A
1810
−12.497
40.127
39.563
1.00
26.59
C

ATOM
1300
O
VAL
A
1810
−12.390
39.811
38.366
1.00
26.21
O

ATOM
1301
CB
VAL
A
1810
−13.208
42.337
40.406
1.00
25.71
C

ATOM
1302
CG1
VAL
A
1810
−12.789
43.700
40.838
1.00
25.83
C

ATOM
1303
CG2
VAL
A
1810
−14.110
42.434
39.204
1.00
27.95
C

ATOM
1304
N
GLN
A
1811
−13.042
39.337
40.488
1.00
26.75
N

ATOM
1305
CA
GLN
A
1811
−13.658
38.056
40.160
1.00
28.19
C

ATOM
1306
C
GLN
A
1811
−15.092
38.105
40.680
1.00
29.04
C

ATOM
1307
O
GLN
A
1811
−15.350
37.813
41.849
1.00
28.88
O

ATOM
1308
CB
GLN
A
1811
−12.896
36.913
40.834
1.00
27.91
C

ATOM
1309
CG
GLN
A
1811
−13.440
35.522
40.535
1.00
26.85
C

ATOM
1310
CD
GLN
A
1811
−12.854
34.485
41.485
1.00
27.47
C

ATOM
1311
OE1
GLN
A
1811
−11.860
34.757
42.156
1.00
25.51
O

ATOM
1312
NE2
GLN
A
1811
−13.458
33.312
41.539
1.00
25.63
N

ATOM
1313
N
PRO
A
1812
−16.022
38.501
39.818
1.00
30.07
N

ATOM
1314
CA
PRO
A
1812
−17.416
38.692
40.224
1.00
31.43
C

ATOM
1315
C
PRO
A
1812
−17.999
37.514
40.991
1.00
32.81
C

ATOM
1316
O
PRO
A
1812
−18.689
37.768
41.967
1.00
33.02
O

ATOM
1317
CB
PRO
A
1812
−18.153
38.900
38.885
1.00
31.51
C

ATOM
1318
CG
PRO
A
1812
−17.111
39.486
37.985
1.00
30.64
C

ATOM
1319
CD
PRO
A
1812
−15.808
38.797
38.395
1.00
30.23
C

ATOM
1320
N
ASP
A
1813
−17.732
36.275
40.587
1.00
34.65
N

ATOM
1321
CA
ASP
A
1813
−18.266
35.115
41.314
1.00
37.52
C

ATOM
1322
C
ASP
A
1813
−17.906
35.103
42.795
1.00
38.34
C

ATOM
1323
O
ASP
A
1813
−18.681
34.615
43.621
1.00
38.74
O

ATOM
1324
CB
ASP
A
1813
−17.768
33.795
40.711
1.00
38.37
C

ATOM
1325
CG
ASP
A
1813
−18.495
33.417
39.460
1.00
41.51
C

ATOM
1326
OD1
ASP
A
1813
−19.430
34.150
39.052
1.00
46.44
O

ATOM
1327
OD2
ASP
A
1813
−18.197
32.396
38.809
1.00
46.11
O

ATOM
1328
N
ALA
A
1814
−16.727
35.633
43.120
1.00
39.38
N

ATOM
1329
CA
ALA
A
1814
−16.216
35.648
44.485
1.00
40.56
C

ATOM
1330
C
ALA
A
1814
−17.056
36.514
45.413
1.00
41.84
C

ATOM
1331
O
ALA
A
1814
−17.077
36.292
46.620
1.00
41.65
O

ATOM
1332
CB
ALA
A
1814
−14.767
36.106
44.499
1.00
40.28
C

ATOM
1333
N
TRP
A
1815
−17.734
37.509
44.849
1.00
43.50
N

ATOM
1334
CA
TRP
A
1815
−18.610
38.368
45.632
1.00
45.71
C

ATOM
1335
C
TRP
A
1815
−20.000
37.745
45.670
1.00
47.78
C

ATOM
1336
O
TRP
A
1815
−20.353
36.930
44.810
1.00
48.50
O

ATOM
1337
CB
TRP
A
1815
−18.749
39.754
44.988
1.00
44.99
C

ATOM
1338
CG
TRP
A
1815
−17.475
40.465
44.624
1.00
43.59
C

ATOM
1339
CD1
TRP
A
1815
−16.396
39.948
43.967
1.00
41.97
C

ATOM
1340
CD2
TRP
A
1815
−17.168
41.847
44.864
1.00
43.30
C

ATOM
1341
NE1
TRP
A
1815
−15.432
40.915
43.805
1.00
41.30
N

ATOM
1342
CE2
TRP
A
1815
−15.881
42.090
44.344
1.00
41.67
C

ATOM
1343
CE3
TRP
A
1815
−17.850
42.903
45.477
1.00
43.55
C

ATOM
1344
CZ2
TRP
A
1815
−15.263
43.335
44.415
1.00
43.03
C

ATOM
1345
CZ3
TRP
A
1815
−17.224
44.158
45.547
1.00
44.60
C

ATOM
1346
CH2
TRP
A
1815
−15.946
44.356
45.017
1.00
43.32
C

ATOM
1347
N
THR
A
1816
−20.796
38.132
46.659
1.00
50.54
N

ATOM
1348
CA
THR
A
1816
−22.199
37.721
46.655
1.00
53.50
C

ATOM
1349
C
THR
A
1816
−23.074
38.657
47.466
1.00
54.65
C

ATOM
1350
O
THR
A
1816
−22.762
38.981
48.617
1.00
55.39
O

ATOM
1351
CB
THR
A
1816
−22.398
36.255
47.066
1.00
53.69
C

ATOM
1352
OG1
THR
A
1816
−21.946
35.405
46.004
1.00
55.36
O

ATOM
1353
CG2
THR
A
1816
−23.899
35.927
47.141
1.00
54.88
C

ATOM
1354
N
GLU
A
1817
−24.170
39.085
46.840
1.00
56.17
N

ATOM
1355
CA
GLU
A
1817
−25.099
40.042
47.432
1.00
57.11
C

ATOM
1356
C
GLU
A
1817
−24.331
41.344
47.508
1.00
57.59
C

ATOM
1357
O
GLU
A
1817
−24.725
42.301
48.181
1.00
58.16
O

ATOM
1358
CB
GLU
A
1817
−25.547
39.586
48.817
1.00
57.35
C

ATOM
1359
N
ASP
A
1818
−23.211
41.351
46.796
1.00
57.81
N

ATOM
1360
CA
ASP
A
1818
−22.324
42.498
46.744
1.00
57.64
C

ATOM
1361
C
ASP
A
1818
−22.179
42.973
45.306
1.00
57.34
C

ATOM
1362
O
ASP
A
1818
−21.088
42.909
44.731
1.00
57.73
O

ATOM
1363
CB
ASP
A
1818
−20.965
42.131
47.324
1.00
58.02
C

ATOM
1364
N
ASN
A
1819
−23.281
43.441
44.723
1.00
56.41
N

ATOM
1365
CA
ASN
A
1819
−23.259
43.998
43.372
1.00
55.19
C

ATOM
1366
C
ASN
A
1819
−22.342
45.215
43.412
1.00
54.27
C

ATOM
1367
O
ASN
A
1819
−22.476
46.161
42.629
1.00
54.46
O

ATOM
1368
CB
ASN
A
1819
−24.650
44.397
42.941
1.00
55.53
C

ATOM
1369
N
GLY
A
1820
−21.402
45.158
44.349
1.00
52.76
N

ATOM
1370
CA
GLY
A
1820
−20.465
46.230
44.593
1.00
50.77
C

ATOM
1371
C
GLY
A
1820
−19.363
46.312
43.570
1.00
49.40
C

ATOM
1372
O
GLY
A
1820
−18.653
47.306
43.551
1.00
49.11
O

ATOM
1373
N
PHE
A
1821
−19.208
45.288
42.730
1.00
48.28
N

ATOM
1374
CA
PHE
A
1821
−18.168
45.353
41.699
1.00
47.40
C

ATOM
1375
C
PHE
A
1821
−18.549
46.301
40.563
1.00
46.77
C

ATOM
1376
O
PHE
A
1821
−17.719
46.637
39.721
1.00
46.49
O

ATOM
1377
CB
PHE
A
1821
−17.703
43.975
41.190
1.00
47.19
C

ATOM
1378
CG
PHE
A
1821
−18.806
43.063
40.718
1.00
46.88
C

ATOM
1379
CD1
PHE
A
1821
−19.226
43.075
39.398
1.00
46.67
C

ATOM
1380
CD2
PHE
A
1821
−19.378
42.150
41.581
1.00
46.60
C

ATOM
1381
CE1
PHE
A
1821
−20.223
42.217
38.957
1.00
46.24
C

ATOM
1382
CE2
PHE
A
1821
−20.377
41.286
41.144
1.00
47.04
C

ATOM
1383
CZ
PHE
A
1821
−20.798
41.322
39.830
1.00
46.52
C

ATOM
1384
N
HIS
A
1822
−19.806
46.737
40.564
1.00
46.27
N

ATOM
1385
CA
HIS
A
1822
−20.294
47.691
39.573
1.00
45.79
C

ATOM
1386
C
HIS
A
1822
−20.103
49.119
40.075
1.00
45.74
C

ATOM
1387
O
HIS
A
1822
−20.285
50.078
39.326
1.00
45.39
O

ATOM
1388
CB
HIS
A
1822
−21.783
47.463
39.284
1.00
45.65
C

ATOM
1389
CG
HIS
A
1822
−22.080
46.180
38.575
1.00
45.31
C

ATOM
1390
ND1
HIS
A
1822
−21.830
45.996
37.233
1.00
45.05
N

ATOM
1391
CD2
HIS
A
1822
−22.609
45.016
39.021
1.00
44.73
C

ATOM
1392
CE1
HIS
A
1822
−22.191
44.775
36.883
1.00
43.91
C

ATOM
1393
NE2
HIS
A
1822
−22.667
44.160
37.949
1.00
44.25
N

ATOM
1394
N
ALA
A
1823
−19.730
49.254
41.343
1.00
45.52
N

ATOM
1395
CA
ALA
A
1823
−19.566
50.564
41.965
1.00
45.73
C

ATOM
1396
C
ALA
A
1823
−18.110
50.992
42.155
1.00
45.82
C

ATOM
1397
O
ALA
A
1823
−17.825
51.958
42.868
1.00
45.86
O

ATOM
1398
CB
ALA
A
1823
−20.287
50.592
43.296
1.00
45.70
C

ATOM
1399
N
ILE
A
1824
−17.188
50.276
41.523
1.00
45.79
N

ATOM
1400
CA
ILE
A
1824
−15.773
50.582
41.662
1.00
45.67
C

ATOM
1401
C
ILE
A
1824
−15.384
51.862
40.934
1.00
46.07
C

ATOM
1402
O
ILE
A
1824
−14.558
52.634
41.418
1.00
45.72
O

ATOM
1403
CB
ILE
A
1824
−14.929
49.395
41.174
1.00
45.63
C

ATOM
1404
CG1
ILE
A
1824
−15.073
48.222
42.146
1.00
44.55
C

ATOM
1405
CG2
ILE
A
1824
−13.470
49.799
41.043
1.00
45.22
C

ATOM
1406
CD1
ILE
A
1824
−14.753
46.890
41.537
1.00
44.07
C

ATOM
1407
N
GLY
A
1825
−15.992
52.089
39.774
1.00
46.76
N

ATOM
1408
CA
GLY
A
1825
−15.716
53.285
38.995
1.00
47.76
C

ATOM
1409
C
GLY
A
1825
−16.014
54.561
39.762
1.00
48.36
C

ATOM
1410
O
GLY
A
1825
−15.454
55.619
39.475
1.00
48.85
O

ATOM
1411
N
GLN
A
1826
−16.895
54.466
40.749
1.00
48.91
N

ATOM
1412
CA
GLN
A
1826
−17.243
55.624
41.566
1.00
49.49
C

ATOM
1413
C
GLN
A
1826
−16.095
55.971
42.498
1.00
49.02
C

ATOM
1414
O
GLN
A
1826
−16.036
57.074
43.029
1.00
49.38
O

ATOM
1415
CB
GLN
A
1826
−18.514
55.357
42.382
1.00
49.97
C

ATOM
1416
CG
GLN
A
1826
−19.808
55.529
41.598
1.00
51.43
C

ATOM
1417
CD
GLN
A
1826
−21.046
55.153
42.403
1.00
54.36
C

ATOM
1418
OE1
GLN
A
1826
−20.961
54.399
43.375
1.00
54.97
O

ATOM
1419
NE2
GLN
A
1826
−22.198
55.679
41.999
1.00
55.74
N

ATOM
1420
N
MET
A
1827
−15.181
55.027
42.695
1.00
48.40
N

ATOM
1421
CA
MET
A
1827
−14.037
55.266
43.562
1.00
47.67
C

ATOM
1422
C
MET
A
1827
−12.786
55.602
42.761
1.00
46.70
C

ATOM
1423
O
MET
A
1827
−11.827
56.145
43.306
1.00
47.08
O

ATOM
1424
CB
MET
A
1827
−13.779
54.061
44.476
1.00
48.21
C

ATOM
1425
CG
MET
A
1827
−14.996
53.626
45.308
1.00
49.52
C

ATOM
1426
SD
MET
A
1827
−14.722
52.190
46.386
1.00
53.09
S

ATOM
1427
CE
MET
A
1827
−13.316
52.736
47.333
1.00
51.51
C

ATOM
1428
N
CYS
A
1828
−12.784
55.283
41.472
1.00
44.88
N

ATOM
1429
CA
CYS
A
1828
−11.607
55.549
40.654
1.00
43.41
C

ATOM
1430
C
CYS
A
1828
−11.936
55.581
39.173
1.00
42.27
C

ATOM
1431
O
CYS
A
1828
−12.995
55.135
38.760
1.00
42.44
O

ATOM
1432
CB
CYS
A
1828
−10.526
54.494
40.913
1.00
43.25
C

ATOM
1433
SG
CYS
A
1828
−10.936
52.881
40.228
1.00
41.86
S

ATOM
1434
N
GLU
A
1829
−11.012
56.099
38.375
1.00
41.35
N

ATOM
1435
CA
GLU
A
1829
−11.222
56.159
36.937
1.00
40.53
C

ATOM
1436
C
GLU
A
1829
−10.322
55.150
36.238
1.00
38.88
C

ATOM
1437
O
GLU
A
1829
−9.191
55.463
35.880
1.00
38.27
O

ATOM
1438
CB
GLU
A
1829
−10.960
57.575
36.409
1.00
41.17
C

ATOM
1439
CG
GLU
A
1829
−12.014
58.066
35.424
1.00
44.69
C

ATOM
1440
CD
GLU
A
1829
−13.408
58.125
36.030
1.00
48.74
C

ATOM
1441
OE1
GLU
A
1829
−13.788
59.192
36.582
1.00
50.05
O

ATOM
1442
OE2
GLU
A
1829
−14.139
57.107
35.949
1.00
52.23
O

ATOM
1443
N
ALA
A
1830
−10.832
53.935
36.057
1.00
36.81
N

ATOM
1444
CA
ALA
A
1830
−10.075
52.873
35.405
1.00
35.20
C

ATOM
1445
C
ALA
A
1830
−11.043
51.817
34.936
1.00
33.76
C

ATOM
1446
O
ALA
A
1830
−12.043
51.585
35.593
1.00
33.71
O

ATOM
1447
CB
ALA
A
1830
−9.087
52.253
36.383
1.00
34.53
C

ATOM
1448
N
PRO
A
1831
−10.739
51.139
33.837
1.00
32.71
N

ATOM
1449
CA
PRO
A
1831
−11.636
50.086
33.365
1.00
31.65
C

ATOM
1450
C
PRO
A
1831
−11.636
48.991
34.425
1.00
30.62
C

ATOM
1451
O
PRO
A
1831
−10.646
48.837
35.143
1.00
30.23
O

ATOM
1452
CB
PRO
A
1831
−10.972
49.572
32.083
1.00
31.65
C

ATOM
1453
CG
PRO
A
1831
−9.751
50.394
31.844
1.00
33.18
C

ATOM
1454
CD
PRO
A
1831
−9.529
51.288
33.013
1.00
32.76
C

ATOM
1455
N
VAL
A
1832
−12.739
48.267
34.551
1.00
29.96
N

ATOM
1456
CA
VAL
A
1832
−12.818
47.182
35.512
1.00
28.63
C

ATOM
1457
C
VAL
A
1832
−13.037
45.900
34.724
1.00
28.14
C

ATOM
1458
O
VAL
A
1832
−13.941
45.812
33.901
1.00
27.69
O

ATOM
1459
CB
VAL
A
1832
−13.948
47.404
36.528
1.00
28.72
C

ATOM
1460
CG1
VAL
A
1832
−14.007
46.244
37.501
1.00
28.25
C

ATOM
1461
CG2
VAL
A
1832
−13.729
48.702
37.291
1.00
28.99
C

ATOM
1462
N
VAL
A
1833
−12.189
44.910
34.960
1.00
26.86
N

ATOM
1463
CA
VAL
A
1833
−12.252
43.685
34.192
1.00
26.03
C

ATOM
1464
C
VAL
A
1833
−12.229
42.492
35.112
1.00
26.16
C

ATOM
1465
O
VAL
A
1833
−11.826
42.601
36.285
1.00
25.71
O

ATOM
1466
CB
VAL
A
1833
−11.054
43.581
33.208
1.00
26.25
C

ATOM
1467
CG1
VAL
A
1833
−10.997
44.824
32.319
1.00
26.83
C

ATOM
1468
CG2
VAL
A
1833
−9.746
43.421
33.962
1.00
25.18
C

ATOM
1469
N
THR
A
1834
−12.648
41.352
34.571
1.00
25.65
N

ATOM
1470
CA
THR
A
1834
−12.643
40.118
35.330
1.00
25.41
C

ATOM
1471
C
THR
A
1834
−11.238
39.535
35.366
1.00
24.80
C

ATOM
1472
O
THR
A
1834
−10.394
39.834
34.528
1.00
23.67
O

ATOM
1473
CB
THR
A
1834
−13.584
39.050
34.724
1.00
25.08
C

ATOM
1474
OG1
THR
A
1834
−13.091
38.637
33.441
1.00
25.48
O

ATOM
1475
CG2
THR
A
1834
−14.990
39.602
34.441
1.00
28.02
C

ATOM
1476
N
ARG
A
1835
−11.032
38.628
36.307
1.00
24.05
N

ATOM
1477
CA
ARG
A
1835
−9.751
37.969
36.450
1.00
23.05
C

ATOM
1478
C
ARG
A
1835
−9.403
37.147
35.202
1.00
22.67
C

ATOM
1479
O
ARG
A
1835
−8.228
36.913
34.910
1.00
21.59
O

ATOM
1480
CB
ARG
A
1835
−9.756
37.116
37.726
1.00
22.89
C

ATOM
1481
CG
ARG
A
1835
−8.406
36.494
38.042
1.00
22.82
C

ATOM
1482
CD
ARG
A
1835
−8.424
35.599
39.261
1.00
22.87
C

ATOM
1483
NE
ARG
A
1835
−9.321
34.457
39.089
1.00
25.40
N

ATOM
1484
CZ
ARG
A
1835
−9.597
33.592
40.052
1.00
26.53
C

ATOM
1485
NH1
ARG
A
1835
−9.058
33.744
41.259
1.00
27.23
N

ATOM
1486
NH2
ARG
A
1835
−10.417
32.580
39.815
1.00
26.16
N

ATOM
1487
N
GLU
A
1836
−10.423
36.756
34.441
1.00
22.79
N

ATOM
1488
CA
GLU
A
1836
−10.205
36.019
33.195
1.00
23.13
C

ATOM
1489
C
GLU
A
1836
−9.402
36.833
32.171
1.00
22.88
C

ATOM
1490
O
GLU
A
1836
−8.769
36.256
31.288
1.00
21.70
O

ATOM
1491
CB
GLU
A
1836
−11.532
35.565
32.576
1.00
24.07
C

ATOM
1492
CG
GLU
A
1836
−12.172
34.356
33.248
1.00
24.34
C

ATOM
1493
CD
GLU
A
1836
−11.223
33.154
33.404
1.00
24.86
C

ATOM
1494
OE1
GLU
A
1836
−10.656
32.651
32.404
1.00
24.86
O

ATOM
1495
OE2
GLU
A
1836
−11.052
32.696
34.549
1.00
24.82
O

ATOM
1496
N
TRP
A
1837
−9.454
38.166
32.266
1.00
23.05
N

ATOM
1497
CA
TRP
A
1837
−8.649
39.011
31.379
1.00
22.56
C

ATOM
1498
C
TRP
A
1837
−7.191
38.684
31.664
1.00
22.15
C

ATOM
1499
O
TRP
A
1837
−6.398
38.493
30.756
1.00
21.97
O

ATOM
1500
CB
TRP
A
1837
−8.866
40.520
31.577
1.00
22.90
C

ATOM
1501
CG
TRP
A
1837
−7.804
41.318
30.821
1.00
23.50
C

ATOM
1502
CD1
TRP
A
1837
−7.695
41.457
29.471
1.00
24.18
C

ATOM
1503
CD2
TRP
A
1837
−6.681
42.014
31.380
1.00
23.99
C

ATOM
1504
NE1
TRP
A
1837
−6.581
42.202
29.155
1.00
24.02
N

ATOM
1505
CE2
TRP
A
1837
−5.948
42.565
30.310
1.00
25.57
C

ATOM
1506
CE3
TRP
A
1837
−6.234
42.253
32.683
1.00
24.91
C

ATOM
1507
CZ2
TRP
A
1837
−4.796
43.333
30.500
1.00
24.16
C

ATOM
1508
CZ3
TRP
A
1837
−5.088
43.009
32.869
1.00
23.43
C

ATOM
1509
CH2
TRP
A
1837
−4.387
43.544
31.783
1.00
25.83
C

ATOM
1510
N
VAL
A
1838
−6.837
38.678
32.940
1.00
22.17
N

ATOM
1511
CA
VAL
A
1838
−5.480
38.277
33.300
1.00
21.29
C

ATOM
1512
C
VAL
A
1838
−5.183
36.839
32.894
1.00
21.91
C

ATOM
1513
O
VAL
A
1838
−4.190
36.571
32.202
1.00
21.90
O

ATOM
1514
CB
VAL
A
1838
−5.204
38.421
34.802
1.00
21.57
C

ATOM
1515
CG1
VAL
A
1838
−3.828
37.911
35.117
1.00
19.05
C

ATOM
1516
CG2
VAL
A
1838
−5.381
39.879
35.267
1.00
21.21
C

ATOM
1517
N
LEU
A
1839
−6.009
35.886
33.329
1.00
21.21
N

ATOM
1518
CA
LEU
A
1839
−5.729
34.473
33.037
1.00
21.35
C

ATOM
1519
C
LEU
A
1839
−5.598
34.144
31.540
1.00
21.35
C

ATOM
1520
O
LEU
A
1839
−4.640
33.487
31.136
1.00
20.77
O

ATOM
1521
CB
LEU
A
1839
−6.679
33.510
33.778
1.00
21.33
C

ATOM
1522
CG
LEU
A
1839
−6.766
33.796
35.290
1.00
21.58
C

ATOM
1523
CD1
LEU
A
1839
−7.698
32.787
35.975
1.00
21.78
C

ATOM
1524
CD2
LEU
A
1839
−5.377
33.770
35.933
1.00
22.19
C

ATOM
1525
N
ASP
A
1840
−6.524
34.620
30.709
1.00
21.59
N

ATOM
1526
CA
ASP
A
1840
−6.397
34.364
29.280
1.00
21.84
C

ATOM
1527
C
ASP
A
1840
−5.147
35.017
28.690
1.00
22.13
C

ATOM
1528
O
ASP
A
1840
−4.446
34.414
27.876
1.00
22.50
O

ATOM
1529
CB
ASP
A
1840
−7.605
34.907
28.528
1.00
23.14
C

ATOM
1530
CG
ASP
A
1840
−8.875
34.143
28.824
1.00
22.65
C

ATOM
1531
OD1
ASP
A
1840
−8.815
33.085
29.483
1.00
22.05
O

ATOM
1532
OD2
ASP
A
1840
−9.997
34.564
28.444
1.00
24.79
O

ATOM
1533
N
SER
A
1841
−4.878
36.254
29.082
1.00
21.76
N

ATOM
1534
CA
SER
A
1841
−3.714
36.959
28.554
1.00
21.52
C

ATOM
1535
C
SER
A
1841
−2.415
36.230
28.858
1.00
21.64
C

ATOM
1536
O
SER
A
1841
−1.554
36.088
28.008
1.00
21.52
O

ATOM
1537
CB
SER
A
1841
−3.650
38.381
29.105
1.00
22.07
C

ATOM
1538
OG
SER
A
1841
−4.682
39.186
28.552
1.00
23.47
O

ATOM
1539
N
VAL
A
1842
−2.288
35.756
30.084
1.00
20.65
N

ATOM
1540
CA
VAL
A
1842
−1.084
35.041
30.486
1.00
20.95
C

ATOM
1541
C
VAL
A
1842
−0.908
33.697
29.736
1.00
21.41
C

ATOM
1542
O
VAL
A
1842
0.141
33.433
29.151
1.00
22.02
O

ATOM
1543
CB
VAL
A
1842
−1.080
34.861
32.003
1.00
20.46
C

ATOM
1544
CG1
VAL
A
1842
−0.040
33.761
32.413
1.00
20.51
C

ATOM
1545
CG2
VAL
A
1842
−0.827
36.196
32.703
1.00
20.42
C

ATOM
1546
N
ALA
A
1843
−1.938
32.859
29.725
1.00
21.20
N

ATOM
1547
CA
ALA
A
1843
−1.867
31.560
29.054
1.00
21.99
C

ATOM
1548
C
ALA
A
1843
−1.459
31.705
27.595
1.00
22.35
C

ATOM
1549
O
ALA
A
1843
−0.686
30.909
27.074
1.00
22.74
O

ATOM
1550
CB
ALA
A
1843
−3.227
30.822
29.140
1.00
20.95
C

ATOM
1551
N
LEU
A
1844
−2.018
32.702
26.922
1.00
23.32
N

ATOM
1552
CA
LEU
A
1844
−1.696
32.943
25.510
1.00
23.68
C

ATOM
1553
C
LEU
A
1844
−0.421
33.759
25.346
1.00
24.51
C

ATOM
1554
O
LEU
A
1844
0.091
33.894
24.231
1.00
24.87
O

ATOM
1555
CB
LEU
A
1844
−2.830
33.742
24.871
1.00
23.66
C

ATOM
1556
CG
LEU
A
1844
−4.200
33.049
24.826
1.00
22.84
C

ATOM
1557
CD1
LEU
A
1844
−5.296
34.093
24.558
1.00
24.05
C

ATOM
1558
CD2
LEU
A
1844
−4.178
31.993
23.742
1.00
23.11
C

ATOM
1559
N
TYR
A
1845
0.068
34.296
26.462
1.00
23.99
N

ATOM
1560
CA
TYR
A
1845
1.155
35.282
26.493
1.00
24.59
C

ATOM
1561
C
TYR
A
1845
0.911
36.357
25.427
1.00
25.26
C

ATOM
1562
O
TYR
A
1845
1.784
36.665
24.610
1.00
25.20
O

ATOM
1563
CB
TYR
A
1845
2.627
34.733
26.469
1.00
23.49
C

ATOM
1564
CG
TYR
A
1845
3.497
35.718
27.236
1.00
23.87
C

ATOM
1565
CD1
TYR
A
1845
3.364
35.843
28.618
1.00
21.67
C

ATOM
1566
CD2
TYR
A
1845
4.343
36.615
26.575
1.00
22.80
C

ATOM
1567
CE1
TYR
A
1845
4.080
36.777
29.334
1.00
22.40
C

ATOM
1568
CE2
TYR
A
1845
5.076
37.555
27.288
1.00
23.19
C

ATOM
1569
CZ
TYR
A
1845
4.920
37.640
28.664
1.00
22.98
C

ATOM
1570
OH
TYR
A
1845
5.604
38.573
29.393
1.00
21.63
O

ATOM
1571
N
GLN
A
1846
−0.280
36.928
25.472
1.00
25.19
N

ATOM
1572
CA
GLN
A
1846
−0.631
38.011
24.570
1.00
26.63
C

ATOM
1573
C
GLN
A
1846
−1.686
38.831
25.279
1.00
26.16
C

ATOM
1574
O
GLN
A
1846
−2.706
38.309
25.725
1.00
25.68
O

ATOM
1575
CB
GLN
A
1846
−1.120
37.457
23.220
1.00
27.43
C

ATOM
1576
CG
GLN
A
1846
−2.621
37.358
23.067
1.00
33.52
C

ATOM
1577
CD
GLN
A
1846
−3.019
36.946
21.646
1.00
37.64
C

ATOM
1578
OE1
GLN
A
1846
−2.157
36.526
20.863
1.00
41.72
O

ATOM
1579
NE2
GLN
A
1846
−4.308
37.049
21.324
1.00
36.71
N

ATOM
1580
N
CYS
A
1847
−1.414
40.113
25.449
1.00
26.49
N

ATOM
1581
CA
CYS
A
1847
−2.331
40.955
26.185
1.00
27.23
C

ATOM
1582
C
CYS
A
1847
−3.663
41.085
25.462
1.00
27.54
C

ATOM
1583
O
CYS
A
1847
−3.702
41.666
24.398
1.00
28.42
O

ATOM
1584
CB
CYS
A
1847
−1.718
42.334
26.347
1.00
27.25
C

ATOM
1585
SG
CYS
A
1847
−2.629
43.347
27.508
1.00
29.32
S

ATOM
1586
N
GLN
A
1848
−4.751
40.580
26.043
1.00
28.34
N

ATOM
1587
CA
GLN
A
1848
−6.052
40.636
25.370
1.00
28.42
C

ATOM
1588
C
GLN
A
1848
−6.686
42.019
25.431
1.00
28.76
C

ATOM
1589
O
GLN
A
1848
−6.449
42.788
26.368
1.00
28.33
O

ATOM
1590
CB
GLN
A
1848
−7.045
39.637
25.981
1.00
28.38
C

ATOM
1591
CG
GLN
A
1848
−6.620
38.171
25.955
1.00
29.42
C

ATOM
1592
CD
GLN
A
1848
−6.360
37.694
24.548
1.00
30.00
C

ATOM
1593
OE1
GLN
A
1848
−7.299
37.437
23.795
1.00
32.22
O

ATOM
1594
NE2
GLN
A
1848
−5.099
37.601
24.179
1.00
28.64
N

ATOM
1595
N
GLU
A
1849
−7.512
42.338
24.435
1.00
29.64
N

ATOM
1596
CA
GLU
A
1849
−8.286
43.574
24.502
1.00
30.42
C

ATOM
1597
C
GLU
A
1849
−9.195
43.461
25.716
1.00
30.05
C

ATOM
1598
O
GLU
A
1849
−9.608
42.355
26.082
1.00
30.02
O

ATOM
1599
CB
GLU
A
1849
−9.098
43.779
23.217
1.00
30.93
C

ATOM
1600
CG
GLU
A
1849
−8.217
43.963
21.988
1.00
32.10
C

ATOM
1601
CD
GLU
A
1849
−7.398
45.244
22.035
1.00
34.27
C

ATOM
1602
OE1
GLU
A
1849
−7.781
46.199
22.751
1.00
36.49
O

ATOM
1603
OE2
GLU
A
1849
−6.353
45.300
21.360
1.00
37.55
O

ATOM
1604
N
LEU
A
1850
−9.500
44.582
26.364
1.00
30.45
N

ATOM
1605
CA
LEU
A
1850
−10.329
44.543
27.570
1.00
30.93
C

ATOM
1606
C
LEU
A
1850
−11.805
44.264
27.326
1.00
31.98
C

ATOM
1607
O
LEU
A
1850
−12.518
43.795
28.215
1.00
30.45
O

ATOM
1608
CB
LEU
A
1850
−10.236
45.869
28.317
1.00
31.44
C

ATOM
1609
CG
LEU
A
1850
−8.838
46.340
28.673
1.00
31.79
C

ATOM
1610
CD1
LEU
A
1850
−8.946
47.646
29.435
1.00
33.57
C

ATOM
1611
CD2
LEU
A
1850
−8.151
45.270
29.510
1.00
31.94
C

ATOM
1612
N
ASP
A
1851
−12.241
44.544
26.104
1.00
33.13
N

ATOM
1613
CA
ASP
A
1851
−13.661
44.543
25.747
1.00
34.63
C

ATOM
1614
C
ASP
A
1851
−14.556
43.446
26.324
1.00
34.22
C

ATOM
1615
O
ASP
A
1851
−15.501
43.744
27.049
1.00
34.06
O

ATOM
1616
CB
ASP
A
1851
−13.814
44.586
24.225
1.00
35.68
C

ATOM
1617
CG
ASP
A
1851
−12.956
45.662
23.586
1.00
39.32
C

ATOM
1618
OD1
ASP
A
1851
−12.616
46.653
24.268
1.00
43.83
O

ATOM
1619
OD2
ASP
A
1851
−12.563
45.593
22.404
1.00
44.60
O

ATOM
1620
N
THR
A
1852
−14.269
42.189
26.000
1.00
34.07
N

ATOM
1621
CA
THR
A
1852
−15.130
41.091
26.421
1.00
33.71
C

ATOM
1622
C
THR
A
1852
−15.063
40.806
27.916
1.00
33.36
C

ATOM
1623
O
THR
A
1852
−15.854
40.022
28.427
1.00
32.23
O

ATOM
1624
CB
THR
A
1852
−14.855
39.781
25.617
1.00
34.36
C

ATOM
1625
OG1
THR
A
1852
−13.557
39.261
25.933
1.00
34.49
O

ATOM
1626
CG2
THR
A
1852
−14.770
40.057
24.115
1.00
35.54
C

ATOM
1627
N
TYR
A
1853
−14.128
41.454
28.615
1.00
32.06
N

ATOM
1628
CA
TYR
A
1853
−13.960
41.216
30.037
1.00
31.98
C

ATOM
1629
C
TYR
A
1853
−14.523
42.346
30.882
1.00
32.79
C

ATOM
1630
O
TYR
A
1853
−14.733
42.181
32.087
1.00
31.91
O

ATOM
1631
CB
TYR
A
1853
−12.473
41.022
30.374
1.00
31.05
C

ATOM
1632
CG
TYR
A
1853
−11.801
39.933
29.560
1.00
28.55
C

ATOM
1633
CD1
TYR
A
1853
−11.015
40.249
28.467
1.00
26.82
C

ATOM
1634
CD2
TYR
A
1853
−11.970
38.591
29.880
1.00
26.26
C

ATOM
1635
CE1
TYR
A
1853
−10.392
39.262
27.706
1.00
25.64
C

ATOM
1636
CE2
TYR
A
1853
−11.355
37.595
29.119
1.00
26.13
C

ATOM
1637
CZ
TYR
A
1853
−10.557
37.943
28.047
1.00
25.03
C

ATOM
1638
OH
TYR
A
1853
−9.931
36.983
27.280
1.00
24.41
O

ATOM
1639
N
LEU
A
1854
−14.766
43.492
30.249
1.00
33.66
N

ATOM
1640
CA
LEU
A
1854
−15.232
44.683
30.965
1.00
34.46
C

ATOM
1641
C
LEU
A
1854
−16.504
44.494
31.764
1.00
35.09
C

ATOM
1642
O
LEU
A
1854
−17.434
43.842
31.317
1.00
35.00
O

ATOM
1643
CB
LEU
A
1854
−15.445
45.852
30.009
1.00
34.47
C

ATOM
1644
CG
LEU
A
1854
−14.215
46.608
29.509
1.00
35.64
C

ATOM
1645
CD1
LEU
A
1854
−14.625
47.533
28.359
1.00
36.58
C

ATOM
1646
CD2
LEU
A
1854
−13.553
47.400
30.639
1.00
34.53
C

ATOM
1647
N
ILE
A
1855
−16.525
45.077
32.955
1.00
35.82
N

ATOM
1648
CA
ILE
A
1855
−17.679
45.017
33.834
1.00
37.37
C

ATOM
1649
C
ILE
A
1855
−18.335
46.389
33.844
1.00
38.72
C

ATOM
1650
O
ILE
A
1855
−17.672
47.384
34.115
1.00
38.69
O

ATOM
1651
CB
ILE
A
1855
−17.225
44.649
35.250
1.00
37.41
C

ATOM
1652
CG1
ILE
A
1855
−16.713
43.208
35.275
1.00
37.27
C

ATOM
1653
CG2
ILE
A
1855
−18.355
44.861
36.256
1.00
38.04
C

ATOM
1654
CD1
ILE
A
1855
−15.959
42.856
36.526
1.00
36.90
C

ATOM
1655
N
PRO
A
1856
−19.636
46.449
33.565
1.00
40.18
N

ATOM
1656
CA
PRO
A
1856
−20.346
47.738
33.538
1.00
41.38
C

ATOM
1657
C
PRO
A
1856
−20.243
48.462
34.875
1.00
42.08
C

ATOM
1658
O
PRO
A
1856
−20.470
47.844
35.908
1.00
42.24
O

ATOM
1659
CB
PRO
A
1856
−21.806
47.349
33.279
1.00
41.39
C

ATOM
1660
CG
PRO
A
1856
−21.735
45.980
32.678
1.00
41.56
C

ATOM
1661
CD
PRO
A
1856
−20.515
45.302
33.267
1.00
40.34
C

ATOM
1662
N
GLN
A
1857
−19.897
49.744
34.856
1.00
43.27
N

ATOM
1663
CA
GLN
A
1857
−19.830
50.512
36.094
1.00
44.87
C

ATOM
1664
C
GLN
A
1857
−20.950
51.546
36.196
1.00
46.28
C

ATOM
1665
O
GLN
A
1857
−21.118
52.384
35.310
1.00
46.50
O

ATOM
1666
CB
GLN
A
1857
−18.469
51.196
36.255
1.00
44.60
C

ATOM
1667
CG
GLN
A
1857
−17.303
50.227
36.463
1.00
43.44
C

ATOM
1668
CD
GLN
A
1857
−17.454
49.382
37.710
1.00
42.10
C

ATOM
1669
OE1
GLN
A
1857
−17.500
49.911
38.828
1.00
41.92
O

ATOM
1670
NE2
GLN
A
1857
−17.525
48.065
37.529
1.00
40.14
N

ATOM
1671
N
ILE
A
1858
−21.702
51.478
37.291
1.00
47.79
N

ATOM
1672
CA
ILE
A
1858
−22.771
52.431
37.573
1.00
49.45
C

ATOM
1673
C
ILE
A
1858
−22.206
53.841
37.743
1.00
50.11
C

ATOM
1674
O
ILE
A
1858
−21.270
54.048
38.517
1.00
50.29
O

ATOM
1675
CB
ILE
A
1858
−23.525
51.989
38.838
1.00
49.49
C

ATOM
1676
CG1
ILE
A
1858
−24.407
50.779
38.511
1.00
50.34
C

ATOM
1677
CG2
ILE
A
1858
−24.339
53.138
39.414
1.00
50.30
C

ATOM
1678
CD1
ILE
A
1858
−25.163
50.212
39.698
1.00
51.57
C

ATOM
1679
N
PRO
A
1859
−22.787
54.808
37.033
1.00
50.83
N

ATOM
1680
CA
PRO
A
1859
−22.304
56.194
37.052
1.00
51.24
C

ATOM
1681
C
PRO
A
1859
−22.064
56.721
38.463
1.00
51.47
C

ATOM
1682
O
PRO
A
1859
−22.991
56.675
39.275
1.00
52.19
O

ATOM
1683
CB
PRO
A
1859
−23.449
56.967
36.394
1.00
51.29
C

ATOM
1684
CG
PRO
A
1859
−24.085
55.974
35.484
1.00
51.64
C

ATOM
1685
CD
PRO
A
1859
−23.980
54.646
36.183
1.00
50.96
C

TER
1686

PRO
A
1859

ATOM
1687
N
SER
B
6
−4.459
15.911
41.006
1.00
39.58
N

ATOM
1688
CA
SER
B
6
−3.840
16.534
42.215
1.00
38.75
C

ATOM
1689
C
SER
B
6
−4.833
17.415
42.958
1.00
38.34
C

ATOM
1690
O
SER
B
6
−5.948
17.650
42.500
1.00
39.29
O

ATOM
1691
CB
SER
B
6
−2.601
17.360
41.836
1.00
39.15
C

ATOM
1692
OG
SER
B
6
−2.941
18.694
41.537
1.00
37.83
O

ATOM
1693
N
THR
B
7
−4.414
17.889
44.119
1.00
37.73
N

ATOM
1694
CA
THR
B
7
−5.228
18.771
44.926
1.00
37.38
C

ATOM
1695
C
THR
B
7
−5.255
20.180
44.301
1.00
35.24
C

ATOM
1696
O
THR
B
7
−6.021
21.044
44.739
1.00
35.41
O

ATOM
1697
CB
THR
B
7
−4.596
18.879
46.332
1.00
37.44
C

ATOM
1698
OG1
THR
B
7
−5.022
17.778
47.152
1.00
42.36
O

ATOM
1699
CG2
THR
B
7
−5.131
20.089
47.068
1.00
39.08
C

HETATM
1700
N
SEP
B
8
−4.430
20.416
43.278
1.00
32.99
N

HETATM
1701
CA
SEP
B
8
−4.302
21.772
42.722
1.00
30.87
C

HETATM
1702
CB
SEP
B
8
−3.049
21.883
41.828
1.00
30.51
C

HETATM
1703
OG
SEP
B
8
−1.880
21.560
42.566
1.00
27.95
O

HETATM
1704
C
SEP
B
8
−5.540
22.248
41.957
1.00
29.89
C

HETATM
1705
O
SEP
B
8
−5.979
21.597
41.022
1.00
29.41
O

HETATM
1706
P
SEP
B
8
−0.542
21.347
41.689
1.00
25.10
P

HETATM
1707
O1P
SEP
B
8
−0.407
22.545
40.622
1.00
28.57
O

HETATM
1708
O2P
SEP
B
8
−0.648
19.952
40.948
1.00
26.27
O

HETATM
1709
O3P
SEP
B
8
0.647
21.417
42.775
1.00
27.15
O

ATOM
1710
N
PRO
B
9
−6.089
23.397
42.334
1.00
29.40
N

ATOM
1711
CA
PRO
B
9
−7.257
23.935
41.625
1.00
28.97
C

ATOM
1712
C
PRO
B
9
−6.958
24.139
40.149
1.00
28.38
C

ATOM
1713
O
PRO
B
9
−5.800
24.405
39.790
1.00
27.24
O

ATOM
1714
CB
PRO
B
9
−7.477
25.299
42.281
1.00
29.34
C

ATOM
1715
CG
PRO
B
9
−6.830
25.197
43.625
1.00
29.99
C

ATOM
1716
CD
PRO
B
9
−5.658
24.262
43.446
1.00
29.53
C

ATOM
1717
N
THR
B
10
−7.976
23.976
39.307
1.00
27.13
N

ATOM
1718
CA
THR
B
10
−7.842
24.301
37.891
1.00
27.79
C

ATOM
1719
C
THR
B
10
−8.730
25.495
37.620
1.00
26.89
C

ATOM
1720
O
THR
B
10
−9.653
25.784
38.383
1.00
27.00
O

ATOM
1721
CB
THR
B
10
−8.241
23.136
36.992
1.00
27.55
C

ATOM
1722
OG1
THR
B
10
−9.538
22.661
37.388
1.00
28.31
O

ATOM
1723
CG2
THR
B
10
−7.288
21.952
37.221
1.00
28.82
C

ATOM
1724
N
PHE
B
11
−8.439
26.202
36.542
1.00
26.51
N

ATOM
1725
CA
PHE
B
11
−9.164
27.413
36.253
1.00
27.05
C

ATOM
1726
C
PHE
B
11
−9.842
27.345
34.915
1.00
27.64
C

ATOM
1727
O
PHE
B
11
−9.238
27.618
33.893
1.00
26.95
O

ATOM
1728
CB
PHE
B
11
−8.219
28.598
36.346
1.00
27.22
C

ATOM
1729
CG
PHE
B
11
−7.701
28.786
37.726
1.00
25.62
C

ATOM
1730
CD1
PHE
B
11
−6.608
28.058
38.179
1.00
26.44
C

ATOM
1731
CD2
PHE
B
11
−8.370
29.607
38.603
1.00
25.53
C

ATOM
1732
CE1
PHE
B
11
−6.156
28.188
39.487
1.00
26.35
C

ATOM
1733
CE2
PHE
B
11
−7.925
29.754
39.906
1.00
25.43
C

ATOM
1734
CZ
PHE
B
11
−6.827
29.039
40.350
1.00
26.32
C

ATOM
1735
N
ASN
B
12
−11.116
26.983
34.948
1.00
28.81
N

ATOM
1736
CA
ASN
B
12
−11.895
26.875
33.728
1.00
30.08
C

ATOM
1737
C
ASN
B
12
−12.912
27.998
33.637
1.00
30.52
C

ATOM
1738
O
ASN
B
12
−13.030
28.836
34.548
1.00
31.49
O

ATOM
1739
CB
ASN
B
12
−12.562
25.499
33.633
1.00
30.75
C

ATOM
1740
CG
ASN
B
12
−11.573
24.372
33.782
1.00
32.28
C

ATOM
1741
OD1
ASN
B
12
−10.696
24.185
32.941
1.00
33.02
O

ATOM
1742
ND2
ASN
B
12
−11.699
23.616
34.862
1.00
35.51
N

ATOM
1743
N
LYS
B
13
−13.636
28.051
32.526
1.00
30.56
N

ATOM
1744
CA
LYS
B
13
−14.613
29.123
32.347
1.00
31.23
C

ATOM
1745
C
LYS
B
13
−15.905
28.783
33.072
1.00
32.26
C

ATOM
1746
O
LYS
B
13
−16.744
29.665
33.296
1.00
32.52
O

ATOM
1747
CB
LYS
B
13
−14.877
29.405
30.862
1.00
31.58
C

ATOM
1748
CG
LYS
B
13
−13.653
29.896
30.071
1.00
30.38
C

ATOM
1749
CD
LYS
B
13
−13.412
31.388
30.258
1.00
30.46
C

ATOM
1750
CE
LYS
B
13
−12.203
31.900
29.451
1.00
28.05
C

ATOM
1751
NZ
LYS
B
13
−11.788
33.220
30.019
1.00
26.69
N

TER
1752

LYS
B
13

HETATM
1753
O
HOH

2
−13.452
35.972
36.780
1.00
13.79
O

HETATM
1754
O
HOH

3
5.465
30.066
17.850
1.00
21.35
O

HETATM
1755
O
HOH

4
12.653
36.338
25.818
1.00
23.18
O

HETATM
1756
O
HOH

6
3.759
26.707
44.073
1.00
24.12
O

HETATM
1757
O
HOH

7
7.923
26.759
28.024
1.00
24.16
O

HETATM
1758
O
HOH

8
4.534
26.718
23.569
1.00
21.61
O

HETATM
1759
O
HOH

9
21.408
15.707
35.455
1.00
37.40
O

HETATM
1760
O
HOH

10
6.703
37.676
31.585
1.00
21.82
O

HETATM
1761
O
HOH

12
−12.761
40.418
43.310
1.00
26.49
O

HETATM
1762
O
HOH

13
0.402
52.504
33.466
1.00
30.11
O

HETATM
1763
O
HOH

14
−16.205
35.546
38.233
1.00
26.90
O

HETATM
1764
O
HOH

15
−12.691
27.037
37.482
1.00
32.90
O

HETATM
1765
O
HOH

16
1.263
60.489
32.218
1.00
25.18
O

HETATM
1766
O
HOH

17
9.234
36.965
33.821
1.00
26.85
O

HETATM
1767
O
HOH

18
11.279
32.720
35.936
1.00
32.65
O

HETATM
1768
O
HOH

19
−14.783
37.111
32.130
1.00
31.36
O

HETATM
1769
O
HOH

20
15.346
25.795
43.568
1.00
32.73
O

HETATM
1770
O
HOH

21
−5.266
36.132
49.503
1.00
42.15
O

HETATM
1771
O
HOH

22
−11.235
33.894
37.065
1.00
26.80
O

HETATM
1772
O
HOH

23
−0.948
25.060
40.939
1.00
24.62
O

HETATM
1773
O
HOH

25
6.144
20.311
42.468
1.00
25.20
O

HETATM
1774
O
HOH

26
−5.044
60.327
34.893
1.00
32.08
O

HETATM
1775
O
HOH

27
−8.866
49.985
48.098
1.00
32.25
O

HETATM
1776
O
HOH

28
−4.677
57.401
33.408
1.00
31.32
O

HETATM
1777
O
HOH

29
−9.766
37.283
24.696
1.00
33.03
O

HETATM
1778
O
HOH

30
−15.283
49.012
33.433
1.00
29.57
O

HETATM
1779
O
HOH

31
9.082
44.380
28.816
1.00
27.14
O

HETATM
1780
O
HOH

33
−10.873
30.195
35.523
1.00
29.80
O

HETATM
1781
O
HOH

34
−3.525
25.672
41.049
1.00
24.58
O

HETATM
1782
O
HOH

35
2.599
38.538
22.916
1.00
33.63
O

HETATM
1783
O
HOH

36
−7.194
35.792
47.834
1.00
34.60
O

HETATM
1784
O
HOH

37
6.924
24.791
21.372
1.00
28.18
O

HETATM
1785
O
HOH

38
7.239
30.104
29.291
1.00
23.23
O

HETATM
1786
O
HOH

39
7.146
33.205
20.041
1.00
31.82
O

HETATM
1787
O
HOH

40
−12.072
50.005
48.450
1.00
43.04
O

HETATM
1788
O
HOH

41
1.667
13.837
30.563
1.00
28.78
O

HETATM
1789
O
HOH

42
−6.233
51.842
31.514
1.00
32.16
O

HETATM
1790
O
HOH

43
−3.255
44.471
43.526
1.00
34.15
O

HETATM
1791
O
HOH

44
14.799
13.474
48.663
1.00
29.54
O

HETATM
1792
O
HOH

45
−8.201
23.973
33.336
1.00
29.42
O

HETATM
1793
O
HOH

46
−2.591
19.321
33.390
1.00
30.65
O

HETATM
1794
O
HOH

47
−10.285
29.829
47.903
1.00
36.69
O

HETATM
1795
O
HOH

48
−11.849
41.285
24.888
1.00
35.55
O

HETATM
1796
O
HOH

49
2.758
22.327
17.454
1.00
36.72
O

HETATM
1797
O
HOH

50
4.780
32.302
45.937
1.00
34.60
O

HETATM
1798
O
HOH

51
−0.253
26.099
43.327
1.00
29.48
O

HETATM
1799
O
HOH

52
−6.915
35.455
42.376
1.00
30.40
O

HETATM
1800
O
HOH

53
11.656
24.759
41.744
1.00
27.69
O

HETATM
1801
O
HOH

54
14.117
13.588
43.980
1.00
35.88
O

HETATM
1802
O
HOH

55
−14.123
35.014
30.225
1.00
30.18
O

HETATM
1803
O
HOH

56
1.792
27.942
42.621
1.00
29.19
O

HETATM
1804
O
HOH

57
17.437
25.002
28.429
1.00
31.49
O

HETATM
1805
O
HOH

58
−8.572
47.068
25.046
1.00
37.03
O

HETATM
1806
O
HOH

59
12.243
38.944
24.353
1.00
34.72
O

HETATM
1807
O
HOH

60
1.020
17.759
41.133
1.00
29.32
O

HETATM
1808
O
HOH

61
20.420
13.169
43.660
1.00
38.76
O

HETATM
1809
O
HOH

62
−4.332
27.518
42.865
1.00
30.84
O

HETATM
1810
O
HOH

63
−10.394
23.183
40.730
1.00
39.20
O

HETATM
1811
O
HOH

64
8.578
42.225
35.381
1.00
35.02
O

HETATM
1812
O
HOH

65
−19.050
52.750
39.473
1.00
46.86
O

HETATM
1813
O
HOH

67
19.116
22.461
44.869
1.00
29.06
O

HETATM
1814
O
HOH

69
4.932
48.579
34.082
1.00
41.55
O

HETATM
1815
O
HOH

70
0.674
41.247
23.802
1.00
32.46
O

HETATM
1816
O
HOH

71
−4.735
26.612
19.260
1.00
32.06
O

HETATM
1817
O
HOH

72
−16.624
38.354
30.446
1.00
41.17
O

HETATM
1818
O
HOH

73
−9.563
31.888
24.802
1.00
47.45
O

HETATM
1819
O
HOH

74
−8.024
40.395
22.455
1.00
37.25
O

HETATM
1820
O
HOH

75
22.334
15.119
30.416
1.00
38.23
O

HETATM
1821
O
HOH

76
10.412
36.360
44.040
1.00
53.49
O

HETATM
1822
O
HOH

77
0.194
50.468
45.917
1.00
36.75
O

HETATM
1823
O
HOH

78
11.735
30.457
17.770
1.00
31.20
O

HETATM
1824
O
HOH

79
13.615
30.264
21.492
1.00
31.47
O

HETATM
1825
O
HOH

80
1.981
29.997
44.422
1.00
35.31
O

HETATM
1826
O
HOH

81
−1.459
20.290
20.816
1.00
30.21
O

HETATM
1827
O
HOH

82
−13.609
26.086
30.220
1.00
27.77
O

HETATM
1828
O
HOH

83
−3.780
17.446
35.325
1.00
34.26
O

HETATM
1829
O
HOH

84
−8.279
32.849
46.738
1.00
40.78
O

HETATM
1830
O
HOH

85
−5.186
58.013
42.604
1.00
39.40
O

HETATM
1831
O
HOH

86
−3.704
44.611
23.069
1.00
41.93
O

HETATM
1832
O
HOH

87
−2.399
13.221
36.493
1.00
35.84
O

HETATM
1833
O
HOH

88
10.819
26.096
46.328
1.00
28.53
O

HETATM
1834
O
HOH

89
−15.466
31.518
36.743
1.00
65.91
O

HETATM
1835
O
HOH

90
25.544
18.911
44.692
1.00
44.66
O

HETATM
1836
O
HOH

91
−15.403
35.810
34.537
1.00
31.61
O

HETATM
1837
O
HOH

92
12.209
37.191
20.365
1.00
43.77
O

HETATM
1838
O
HOH

93
−3.822
19.157
19.331
1.00
40.98
O

HETATM
1839
O
HOH

94
−8.775
20.995
23.829
1.00
43.80
O

HETATM
1840
O
HOH

95
5.036
46.212
41.225
1.00
38.26
O

HETATM
1841
O
HOH

96
10.876
37.114
35.849
1.00
37.29
O

HETATM
1842
O
HOH

97
−2.877
37.361
49.248
1.00
43.97
O

HETATM
1843
O
HOH

98
1.058
55.760
42.110
1.00
46.37
O

HETATM
1844
O
HOH

99
−4.680
56.635
36.039
1.00
40.94
O

HETATM
1845
O
HOH

100
8.956
38.521
20.300
1.00
52.56
O

HETATM
1846
O
HOH

101
22.213
12.620
29.359
1.00
39.12
O

HETATM
1847
O
HOH

102
5.384
45.205
25.481
1.00
44.15
O

HETATM
1848
O
HOH

103
12.540
26.873
43.950
1.00
37.63
O

HETATM
1849
O
HOH

104
−7.868
51.651
24.151
1.00
52.45
O

HETATM
1850
O
HOH

106
9.349
33.376
38.461
1.00
31.86
O

HETATM
1851
O
HOH

107
−7.249
56.630
41.970
1.00
40.55
O

HETATM
1852
O
HOH

108
−5.184
47.738
27.394
1.00
59.47
O

HETATM
1853
O
HOH

109
13.089
34.408
37.600
1.00
44.84
O

HETATM
1854
O
HOH

110
0.705
11.419
30.955
1.00
36.41
O

HETATM
1855
O
HOH

111
−4.798
14.017
42.480
1.00
53.45
O

HETATM
1856
O
HOH

112
−4.843
19.488
39.633
1.00
40.43
O

HETATM
1857
O
HOH

113
−18.670
51.048
32.220
1.00
41.38
O

HETATM
1858
O
HOH

114
−12.102
30.530
38.025
1.00
47.93
O

HETATM
1859
O
HOH

115
−13.776
27.216
27.707
1.00
35.44
O

HETATM
1860
O
HOH

116
−2.334
27.065
44.853
1.00
44.72
O

HETATM
1861
O
HOH

117
2.870
52.316
40.206
1.00
46.36
O

HETATM
1862
O
HOH

118
−18.440
40.445
31.729
1.00
56.81
O

HETATM
1863
O
HOH

119
−6.962
31.452
48.249
1.00
54.20
O

HETATM
1864
O
HOH

120
−10.628
27.328
40.404
1.00
45.21
O

HETATM
1865
O
HOH

122
16.096
24.639
45.922
1.00
37.79
O

HETATM
1866
O
HOH

123
−0.872
8.832
43.975
1.00
49.75
O

HETATM
1867
O
HOH

124
−16.751
49.961
31.151
1.00
39.48
O

HETATM
1868
O
HOH

126
21.867
21.890
45.103
1.00
32.28
O

HETATM
1869
O
HOH

127
0.221
23.594
44.786
1.00
42.23
O

HETATM
1870
O
HOH

129
5.798
20.569
21.887
1.00
38.97
O

HETATM
1871
O
HOH

130
0.027
33.658
49.447
1.00
33.97
O

HETATM
1872
O
HOH

131
17.726
22.984
30.315
1.00
51.39
O

HETATM
1873
O
HOH

133
−7.039
56.697
37.326
1.00
46.16
O

HETATM
1874
O
HOH

134
−18.445
35.870
30.843
1.00
53.20
O

HETATM
1875
O
HOH

135
−1.408
11.649
29.254
1.00
40.99
O

HETATM
1876
O
HOH

136
4.882
31.262
20.482
1.00
36.08
O

HETATM
1877
O
HOH

137
−15.536
34.962
48.398
1.00
38.30
O

HETATM
1878
O
HOH

138
5.748
22.881
20.087
1.00
40.17
O

HETATM
1879
O
HOH

139
−8.361
23.876
24.021
1.00
38.36
O

HETATM
1880
O
HOH

140
−14.676
29.695
41.150
1.00
50.58
O

HETATM
1881
O
HOH

141
9.061
41.220
16.046
1.00
57.28
O

HETATM
1882
O
HOH

142
−1.839
32.308
19.350
1.00
52.87
O

HETATM
1883
O
HOH

143
−5.811
50.543
29.103
1.00
37.21
O

HETATM
1884
O
HOH

144
−12.815
25.160
26.023
1.00
46.91
O

HETATM
1885
O
HOH

145
8.064
6.927
44.309
1.00
47.85
O

HETATM
1886
O
HOH

146
−6.794
49.781
22.800
1.00
51.07
O

HETATM
1887
O
HOH

147
−10.949
48.372
24.823
1.00
52.18
O

HETATM
1888
O
HOH

148
−11.633
30.356
41.316
1.00
35.73
O

HETATM
1889
O
HOH

150
19.648
17.166
27.875
1.00
49.78
O

HETATM
1890
O
HOH

152
1.645
8.928
31.444
1.00
51.22
O

HETATM
1891
O
HOH

153
−2.974
16.595
45.799
1.00
47.36
O

HETATM
1892
O
HOH

154
4.114
7.772
39.862
1.00
44.72
O

HETATM
1893
O
HOH

156
11.495
43.419
29.767
1.00
39.89
O

HETATM
1894
O
HOH

157
14.755
27.975
19.472
1.00
47.52
O

HETATM
1895
O
HOH

159
20.000
25.195
44.085
1.00
56.30
O

HETATM
1896
O
HOH

160
−2.672
23.925
45.847
1.00
50.24
O

HETATM
1897
O
HOH

161
3.604
50.595
35.259
1.00
51.76
O

HETATM
1898
O
HOH

162
19.673
24.416
41.389
1.00
61.54
O

HETATM
1899
O
HOH

163
−6.458
30.497
20.646
1.00
45.53
O

HETATM
1900
O
HOH

164
−6.717
60.196
42.547
1.00
44.71
O

HETATM
1901
O
HOH

166
3.377
39.489
45.416
1.00
51.19
O

HETATM
1902
O
HOH

168
15.857
6.255
34.567
1.00
60.54
O

HETATM
1903
O
HOH

169
−4.347
11.625
25.428
1.00
48.48
O

HETATM
1904
O
HOH

170
−4.966
56.028
29.753
1.00
59.27
O

HETATM
1905
O
HOH

172
−3.276
23.889
48.407
1.00
63.97
O

HETATM
1906
O
HOH

173
16.051
7.381
41.619
1.00
46.25
O

HETATM
1907
O
HOH

176
10.033
37.532
40.812
1.00
47.17
O

HETATM
1908
O
HOH

179
−7.499
54.256
31.031
1.00
49.63
O

CONECT
1700
1701

CONECT
1701
1700
1702
1704

CONECT
1702
1701
1703

CONECT
1703
1702
1706

CONECT
1704
1701
1705

CONECT
1705
1704

CONECT
1706
1703
1707
1708
1709

CONECT
1707
1706

CONECT
1708
1706

CONECT
1709
1706

MASTER
256 0 1 10 10 0 0 6 1906 2 10 18

END

Peptide Library Screening

One skilled in the art would be able to utilize a peptide library screen to identify peptides that bind to a BRCA 1 tandem BRCT domain or other biologically relevant binding target. Peptides identified in such a screen, or related compounds, would have potential therapeutic benefit due to their ability to modulate the biological activity of BRCA1.

Phosphoserine and phosphothreonine oriented degenerate peptide libraries consisting of the sequences

(SEQ ID NO.: 44)

Gly-Ala-X-X-X-B-(pSer/pThr)-Gln-J-X-X-X-Ala-Lys-

Lys-Lys,

(SEQ ID NO.: 45)

Met-Ala-X-X-X-X-pThr-X-X-X-X-Ala-Lys-Lys-Lys,

and

(SEQ ID NO.: 46)

Met-Ala-X-X-X-XpSer-X-X-X-X-X-Ala-Lys-Lys-Lys;

where pS is phosphoserine, pT is phosphothreonine; and X denotes all amino acids except Cys. In the (pSer/pThr)-Gln library, B is a biased mixture of the amino acids A, I, L, M, N, P, S, T, V, and J represents a biased mixture of 25% E, 75% X, where X denotes all amino acids except Arg, Cys, His, Lys. Peptides were synthesized using N-α-FMOC-protected amino acids and standard BOP/HOBt coupling chemistry. Peptide library screening was performed using 125 μl of glutathione beads containing saturating amounts of GST-PTIP BRCT or GST-BRCA1 BRCT domains (1-1.5 mg) as described by Yaffe and Cantley (Methods Enzymol 328:157-70, 2000). Beads were packed in a 1 mL column and incubated with 0.45 mg of the peptide library mixture for 10 minutes at room temperature in PBS (150 mM NaCl, 3 mM KCl, 10 mM Na2HPO4, 2 mm KH2PO4, pH 7.6). Unbound peptides were removed from the column by two washes with PBS containing 1.0% NP-40 followed by two washes with PBS. Bound peptides were eluted with 30% acetic acid for 10 minutes at room temperature, lyophilized, resuspended in H2O, and sequenced by automated Edman degradation on a PROCISE protein microsequencer (Perkin-Elmer Corporation, Norwalk Conn.). Selectivity values for each amino acid were determined by comparing the relative abundance (mole percentage) of each amino acid at a particular sequencing cycle in the recovered peptides to that of each amino acid in the original peptide library mixture at the same position.

Prodrugs

Disruption of the BRCA1-BACH1 interaction can be used to promote enhanced sensitivity of cells to chemotherapy and radiation treatment. The treatment, stabilization, or prevention of a disease or disorder associated with BRCA1 can be mediated by administering a compound, peptide, or nucleic acid molecule. In some cases, however, a compound that is effective in disrupting the BRCA1-BACH1 interaction in vitro is not an effective therapeutic agent in vivo. For example, this could be due to low bioavailability of the compound. One way to circumvent this difficulty is to administer a modified drug, or prodrug, with improved bioavailability that converts naturally to the original compound following administration. Such prodrugs must undergo transformation before exhibiting their full pharmacological effects. Prodrugs contain one or more specialized protective groups that are specifically designed to alter or to eliminate undesirable properties in the parent molecule. Once administered, a prodrug is metabolised in vivo into an active compound.

Prodrugs may be useful for improving one or more of the following characteristics of a drug: solubility, absorption, distribution, metabolization, excretion, site specificity, stability, patient accepability, reduced toxicity, or problems of formulation. For example, an active compound may have poor oral bioavailability, but by attaching an appropriately-chosen covalent linkage that is metabolized in the body, oral bioavailability may improve sufficiently to enable the prodrug to be administered orally without adversely affecting the parent compound's activity within the body.

A prodrug may be carrier-linked, meaning that it contains a group such as an ester that can be removed enzymatically. Optimally, the additional chemical group has little or no pharmacologic activity, and the bond connecting this group to the parent compound is labile to allow for efficient in vivo activation. Such a carrier group may be linked directly to the parent compound (bipartate), or it may be bonded via a linker region (tripartate). Common examples of chemical groups attached to parent compounds to form prodrugs include esters, sulfates, phosphates, alcohols, amides, imines, phenyl carbamates, and carbonyls.

As one example, methylprednisolone is a poorly water-soluble corticosteroid drug. In order to be useful for aqueous injection or ophthalmic administration, this drug must be converted into a prodrug of enhanced solubility. Methylprednisolone sodium succinate ester is much more soluble than the parent compound, and it is rapidly and extensively hydrolysed in vivo by cholinesterases to free methylprednisolone.

Caged compounds may also be used as prodrugs. A caged compound has a photolyzable chemical groups attached that renders the compound biologically inactive. Flash photolysis releases the caging group (and activates the compound) in a spatially or temporally controlled manner.

For further description of the design and use of prodrugs, see Testa and Mayer, Hydrolysis in Drug and Prodrug Metabolism: Chemistry, Biochemistry and Enzymology, published by Vch. Verlagsgesellschaft Mbh. (2003)

Peptidomimetics

Peptide derivatives (e.g. peptidomimetics) include cyclic peptides, peptides obtained by substitution of a natural amino acid residue by the corresponding D-stereoisomer, or by a unnatural amino acid residue, chemical derivatives of the peptides, dual peptides, multimers of the peptides, and peptides fused to other proteins or carriers. A cyclic derivative of a peptide of the invention is one having two or more additional amino acid residues suitable for cyclization. These residues are often added at the carboxyl terminus and at the amino terminus. A peptide derivative may have one or more amino acid residues replaced by the corresponding D-amino acid residue. In one example, a peptide or peptide derivative of the invention is all-L, all-D, or a mixed D,L-peptide. In another example, an amino acid residue is replaced by a unnatural amino acid residue. Examples of unnatural or derivatized unnatural amino acids include Na-methyl amino acids, Cα-methyl amino acids, and β-methyl amino acids.

A chemical derivative of a peptide of the invention includes, but is not limited to, a derivative containing additional chemical moieties not normally a part of the peptide. Examples of such derivatives include: (a) N-acyl derivatives of the amino terminal or of another free amino group, where the acyl group may be either an alkanoyl group, e.g., acetyl, hexanoyl, octanoyl, an aroyl group, e.g., benzoyl, or a blocking group such as Fmoc (fluorenylmethyl-O—CO—), carbobenzoxy (benzyl-O—CO—), monomethoxysuccinyl, naphthyl-NH—CO—, acetylamino-caproyl, adamantyl-NH—CO—; (b) esters of the carboxyl terminal or of another free carboxyl or hydroxy groups; (c) amides of the carboxyl terminal or of another free carboxyl groups produced by reaction with ammonia or with a suitable amine; (d) glycosylated derivatives; (e) phosphorylated derivatives; (f) derivatives conjugated to lipophilic moieties, e.g., caproyl, lauryl, stearoyl; and (g) derivatives conjugated to an antibody or other biological ligand. Also included among the chemical derivatives are those derivatives obtained by modification of the peptide bond —CO—NH—, for example, by: (a) reduction to —CH₂—NH—; (b) alkylation to —CO—N(alkyl)—; and (c) inversion to —NH—CO—. Peptidomimetics may also comprise phosphonate or sulfonate moieties.

A dual peptide of the invention consists of two of the same, or two different, peptides of the invention covalently linked to one another, either directly or through a spacer.

Multimers of the invention consist of polymer molecules formed from a number of the same or different peptides or derivatives thereof.

In one example, a peptide derivative is more resistant to proteolytic degradation than the corresponding non-derivatized peptide. For example, a peptide derivative having D-amino acid substitution(s) in place of one or more L-amino acid residue(s) resists proteolytic cleavage.

In another example, the peptide derivative has increased permeability across a cell membrane as compared to the corresponding non-derivatized peptide. For example, a peptide derivative may have a lipophilic moiety coupled at the amino terminus and/or carboxyl terminus and/or an internal site. Such derivatives are highly preferred when targeting intracellular protein-protein interactions, provided they retain the desired functional activity.

In another example, a peptide derivative binds with increased affinity to a ligand (e.g., a tandem BRCT domain).

The peptides or peptide derivatives of the invention are obtained by any method of peptide synthesis known to those skilled in the art, including synthetic and recombinant techniques. For example, the peptides or peptide derivatives can be obtained by solid phase peptide synthesis which, in brief, consists of coupling the carboxyl group of the C-terminal amino acid to a resin and successively adding N-alpha protected amino acids. The protecting groups may be any such groups known in the art. Before each new amino acid is added to the growing chain, the protecting group of the previous amino acid added to the chain is removed. The coupling of amino acids to appropriate resins has been described by Rivier et al. (U.S. Pat. No. 4,244,946). Such solid phase syntheses have been described, for example, by Merrifield, J. Am. Chem. Soc. 85:2149, 1964; Vale et al., Science 213:1394-1397, 1984; Marki et al., J. Am. Chem. Soc. 10:3178, 1981, and in U.S. Pat. Nos. 4,305,872 and 4,316,891. In a preferred aspect, an automated peptide synthesizer is employed.

Purification of the synthesized peptides or peptide derivatives is carried out by standard methods, including chromatography (e.g., ion exchange, affinity, and sizing column chromatography), centrifugation, differential solubility, hydrophobicity, or by any other standard technique for the purification of proteins. In one embodiment, thin layer chromatography is employed. In another embodiment, reverse phase HPLC (high performance liquid chromatography) is employed.

Finally, structure-function relationships determined from the peptides, peptide derivatives, and other small molecules of the invention may also be used to prepare analogous molecular structures having similar properties. Thus, the invention is contemplated to include molecules in addition to those expressly disclosed that share the structure, hydrophobicity, charge characteristics and side chain properties of the specific embodiments exemplified herein.

In one example, such derivatives or analogs that have the desired binding activity can be used for binding to a molecule or other target of interest, such as any tandem BRCT domain. Derivatives or analogs that retain, or alternatively lack or inhibit, a desired property-of-interest (e.g., inhibit tandem BRCT binding to a natural ligand), can be used to inhibit the biological activity of a tandem BRCT domain (e.g. from BRCA1 or PTIP).

In particular, peptide derivatives are made by altering amino acid sequences by substitutions, additions, or deletions that provide for functionally equivalent molecules, or for functionally enhanced or diminished molecules, as desired. Due to the degeneracy of the genetic code, other nucleic acid sequences that encode substantially the same amino acid sequence may be used for the production of recombinant peptides. These include, but are not limited to, nucleotide sequences comprising all or portions of a peptide of the invention that is altered by the substitution of different codons that encode a functionally equivalent amino acid residue within the sequence, thus producing a silent change.

The derivatives and analogs of the invention can be produced by various methods known in the art. The manipulations that result in their production can occur at the gene or protein level. For example, a cloned nucleic acid sequence can be modified by any of numerous strategies known in the art (Sambrook et al., 1989, Molecular Cloning, A Laboratory Manual, 2d ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.). The sequence can be cleaved at appropriate sites with restriction endonuclease(s), followed by further enzymatic modification if desired, isolated, and ligated in vitro.

Modified Phosphopeptides

A phosphopeptide of the invention may include, but it is not limited to, an unnatural N-terminal amino acid of the formula (III):

embedded image

where A¹is an amino acid or peptide chain linked via an α-amino group; R¹and R³are independently hydrogen, C_1-5branched or linear C_1-5alkyl, C_1-5alkaryl, heteroaryl, and aryl, each of which are unsubstituted or substituted with a substitutent selected from: 1 to 3 of C_1-5alkyl, 1 to 3 of halogen, 1 to 2 of —OR⁵, N(R⁵)(R⁶), SR⁵, N—C(NR⁵)NR⁶R⁷, methylenedioxy, —S(O)_mR⁵, 1 to 2 of —CF₃, —OCF₃, nitro, —N(R⁵)C(O)(R⁶), —C(O)OR⁵, —C(O)N(R⁵)(R⁶), -1H-tetrazol-5-yl, —SO₂N(R⁵)(R⁶), —N(R⁵)SO₂aryl, or —N(R⁵)SO₂R⁶; R⁵, R⁶and R⁷are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; or R²and R′ are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur, or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl, or R²and R³are joined to form a C_3-8cyclic ring, optionally substituted by hydroxyl and optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl; R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; and R⁴is hydrogen, C_1-5branched or linear C_1-5alkyl, C_1-5alkaryl, heteroaryl, and aryl, each of which are unsubstituted or substituted with a substitutent selected from: 1 to 3 of C_1-5alkyl, 1 to 3 of halogen, 1 to 2 of —OR⁵, N(R⁵)(R⁶), N—C(NR⁵)NR⁶R⁷, methylenedioxy, —S(O)_mR⁵(where m is 0-2), 1 to 2 of —CF₃, —OCF₃, nitro, —N(R⁵)C(O)(R⁶), —N(R⁵)C(O)(OR⁶), —C(O)OR⁵, —C(O)N(R⁵)(R⁶), -1H-tetrazol-5-yl, —SO₂N (R⁵)(R⁶), —N(R⁵)SO₂aryl, or —N(R⁵)SO₂R⁶, R⁵, R⁶and R⁷are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl.

The phosphopeptides of the invention may also include an unnatural internal amino acid of the formula:

embedded image

where A²is an amino acid or peptide chain linked via an α-carboxy group; A¹is an amino acid or peptide chain linked via an α-amino group; R¹and R³are independently hydrogen, C_1-5branched or linear C_1-5alkyl, C_1-5alkaryl, heteroaryl, and aryl, each of which are unsubstituted or substituted with a substitutent selected from: 1 to 3 of C_1-5alkyl, 1 to 3 of halogen, 1 to 2 of —OR⁵, N(R⁵)(R⁶), SR⁵, N—C(NR⁵)NR⁶R⁷, methylenedioxy, —S(O)_mR⁵(m is 1-2), 1 to 2 of —CF₃, —OCF₃, nitro, —N(R⁵)C(O)(R⁶), —C(O)OR⁵, —C(O)N(R⁵)(R⁶), -1H-tetrazol-5-yl, —SO₂N (R⁵)(R⁶), —N(R⁵)SO₂aryl, or —N(R⁵)SO₂R⁶; R⁵, R⁶and R⁷are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; and R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; or R²and R′ are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl, or R²and R³are joined to form a C_3-8cyclic ring, optionally substituted by hydroxyl and optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl.

The invention also includes modifications of the phosphopeptides of the invention, wherein an unnatural internal amino acid of the formula:

embedded image

is present, where A²is an amino acid or peptide chain linked via an α-carboxy group; A¹is an amino acid or peptide chain linked via an α-amino group; R¹and R³are independently hydrogen, C_1-5branched or linear C_1-5alkyl, and C_1-5alkaryl; R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; or R²and R′ are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; X is O or S; and R⁵and R⁶are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; or R⁵and R⁶are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl.

The phosphopeptides of the invention may also include a C-terminal unnatural internal amino acid of the formula:

embedded image

where A²is an amino acid or peptide chain linked via an α-carboxy group; R¹and R³are independently hydrogen, C_1-5branched or linear C_1-5alkyl, C_1-5alkaryl, heteroaryl, and aryl, each of which are unsubstituted or substituted with a substitutent selected from: 1 to 3 of C_1-5alkyl, 1 to 3 of halogen, 1 to 2 of —OR⁵, N(R⁵)(R⁶), SR⁵, N—C(NR⁵)NR⁶R⁷, methylenedioxy, —S(O)_mR⁵, 1 to 2 of —CF₃, —OCF₃, nitro, —N(R⁵)C(O)(R⁶), —C(O)OR⁵, —C(O)N(R⁵)(R⁶), -1H-tetrazol-5-yl, —SO₂N(R⁵)(R⁶), —N(R⁵)SO₂aryl, or —N(R⁵)SO₂R⁶; R⁵, R⁶and R⁷are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; or R²and R′ are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; or R²and R³are joined to form a C_3-8cyclic ring, optionally substituted by hydroxyl and optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl; R²is hydrogen, F, C_1-5linear or branched alkyl, C_1-5alkaryl; and Q is OH, OR⁵, or NR⁵R⁶, where R⁵, R⁶are independently selected from hydrogen, C_1-5linear or branched alkyl, C_1-5alkaryl, aryl, heteroaryl, and C_3-7cycloalkyl, and where two C_1-5alkyl groups are present on one atom, they optionally are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or NR⁷, where R⁷is hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl. Methods well known in the art for modifying peptides are found, for example, in “Remington: The Science and Practice of Pharmacy” (20th ed., ed. A.R. Gennaro, 2000, Lippincott Williams & Wilkins, Philadelphia).

Therapeutic Uses

Peptide Synthesis and Conjugation

Phosphopeptides of the invention are prepared as detailed above. Alternatively, phosphopeptides can be prepared using standard FMOC chemistry on 2-chlorotrityl chloride resin (Int. J. Pept. Prot. Res. 38, 1991, 555-61). Cleavage from the resin is performed using 20% acetic acid in dichloromehane (DCM), which leaves the side chain still blocked. Free terminal carboxylate peptide is then coupled to 4′(aminomethy)-fluorescein (Molecular Probes, A-1351; Eugene, Oreg.) using excess diisopropylcarbodiimide (DIC) in dimethylformamide (DMF) at room temperature. The fluorescent N—C blocked peptide is purified by silica gel chromatography (10% methanol in DCM). The N terminal FMOC group is then removed using piperidine (20%) in DMF, and the N-free peptide, purified by silica gel chromatography (20% methanol in DCM, 0.5% HOAc). Finally, any t-butyl side chain protective groups are removed using 95% trifluoroacetic acid containing 2.5% water and 2.5% triisopropyl silane. The peptide obtained in such a manner should give a single peak by HPLC and is sufficiently pure for carrying on with the assay described below.

Phosphopeptide Modifications

It is understood that modifications can be made to the amino acid residues of the phosphopeptides of the invention, to enhance or prolong the therapeutic efficacy and/or bioavailability of the phosphopeptide. Accordingly, α-amino acids having the following general formula (I):

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where R defines the specific amino acid residue, may undergo various modifications. Exemplary modifications of α-amino acids, include, but are not limited to, the following formula (II):

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R₁, R₂, R₃, R₄, and R₅, are independently hydrogen, hydroxy, nitro, halo, C_1-5branched or linear alkyl, C_1-5alkaryl, heteroaryl, and aryl; wherein the alkyl, alkaryl, heteroaryl, and aryl may be unsubstituted or substituted by one or more substituents selected from the group consisting of C_1-5alkyl, hydroxy, halo, nitro, C_1-5alkoxy, C_1-5alkylthio, trihalomethyl, C_1-5acyl, arylcarbonyl, heteroarylcarbonyl, nitrile, C_1-5alkoxycarbonyl, oxo, arylalkyl (wherein the alkyl group has from 1 to 5 carbon atoms) and heteroarylalkyl (wherein the alkyl group has from 1 to 5-carbon atoms); alternatively, R₁and R₂are joined to form a C_3-8cyclic ring, optionally including oxygen, sulfur or hydrogen, or C_1-5alkyl, optionally substituted by hydroxyl; or R₂and R₃are joined to form a C_3-8cyclic ring, optionally substituted by hydroxyl and optionally including oxygen, sulfur, C_1-5aminoalkyl, or C_1-5alkyl. Methods well known in the art for making modifications are found, for example, in “Remington: The Science and Practice of Pharmacy” (20th ed., ed. A.R. Gennaro, 2000, Lippincott Williams & Wilkins), hereby incorporated by reference.

Assays and High Throughput Assays

Fluorescence polarization assays can be used in displacement assays to identify small molecule peptidomimetics. The following is an exemplary method for use of fluorescence polarization, and should not be viewed as limiting in any way. For screening, all reagents are diluted at the appropriate concentration and the working solution, kept on ice. The working stock concentration for GST and GST fusion proteins are ˜4 ng/μL, Fluorescein-labeled phosphopeptides can be used at a concentration of 1.56 fmol/μL, while cold phosphopeptides and peptides at 25 pmol/μL. Samples are incubated at a total volume of 200 μL per well in black flat bottom plates, Biocoat, #359135 low binding (BD BioSciences; Bedford, Mass.). Assays are started with the successive addition using a Labsystem Multi-Drop 96/384 device (Labsystem; Franklin, Mass.) of 50 μL, test compounds, diluted in 10% DMSO (average concentration of 28 μM), 50 μL of 50 mM MES-pH 6.5, 50 μL of Fluorescein-phosphopeptide, 50 μL of GST-BRCA1 tandem BRCT domain fusion, 50 μL of unlabeled phosphopeptide, or unphosphorylated peptide can be used as a negative control. Once added, all the plates are placed at 4° C. Following overnight incubation at 4° C., the fluorescence polarization is measured using a Polarion plate reader (Tecan, Research Triangle Park, N.C.). A xenon flash lamp equipped with an excitation filter of 485 nm and an emission filter of 535 nm. The number of flashes is set at 30. Raw data can then be converted into a percentage of total interaction(s). All further analysis can be performed using SPOTFIRE data analysis software (SPOTFIRE, Somerville, Mass.)

Upon selection of active compounds, auto-fluorescence of the hits is measured as well as the fluorescein quenching effect, where a measurement of 2000 or more units indicates auto-fluorescence, while a measurement of 50 units indicates a quenching effect. Confirmed hits can then be analyzed in dose-response curves (IC₅₀) for reconfirmation. Best hits in dose-response curves can then be assessed by isothermal titration calorimetry using a GST-BRCA1 tandem BRCT domain fusion.

Alternate Binding and Displacement Assays

Fluorescence polarization assays are but one means to measure phosphopeptide-protein interactions in a screening strategy. Alternate methods for measuring phosphopeptide-protein interactions are known to the skilled artisan. Such methods include, but are not limited to mass spectrometry (Nelson and Krone, J. Mol. Recognit., 12:77-93, 1999), surface plasmon resonance (Spiga et al., FEBS Lett., 511:33-35, 2002; Rich and Mizka, J. Mol. Recognit., 14:223-8, 2001; Abrantes et al., Anal. Chem., 73:2828-35, 2001), fluorescence resonance energy transfer (FRET) (Bader et al., J. Biomol. Screen, 6:255-64, 2001; Song et al., Anal. Biochem. 291:133-41, 2001; Brockhoff et al., Cytometry, 44:338-48, 2001), bioluminescence resonance energy transfer (BRET) (Angers et al., Proc. Natl. Acad. Sci. USA, 97:3684-9, 2000; Xu et al., Proc. Natl. Acad. Sci. USA, 96:151-6, 1999), fluorescence quenching (Engelborghs, Spectrochim. Acta A. Mol. Biomol. Spectrosc., 57:2255-70, 70; Geoghegan et al., Bioconjug. Chem. 11:71-7, 2000), fluorescence activated cell scanning/sorting (Barth et al., J. Mol. Biol., 301:751-7, 2000), ELISA, and radioimmunoassay (RIA).

Test Extracts and Compounds

In general, peptidomimetic compounds that affect phosphopeptide-protein interactions are identified from large libraries of both natural products, synthetic (or semi-synthetic) extracts or chemical libraries, according to methods known in the art.

Those skilled in the art will understand that the precise source of test extracts or compounds is not critical to the screening procedure(s) of the invention. Accordingly, virtually any number of chemical extracts or compounds can be screened using the exemplary methods described herein. Examples of such extracts or compounds include, but are not limited to, plant-, fungal-, prokaryotic- or animal-based extracts, fermentation broths, and synthetic compounds, as well as modifications of existing compounds. Numerous methods are also available for generating random or directed synthesis (e.g., semi-synthesis or total synthesis) of any number of chemical compounds, including, but not limited to, saccharide-, lipid-, peptide-, and nucleic acid-based compounds. Synthetic compound libraries are commercially available from, for example, Brandon Associates (Merrimack, N.H.) and Aldrich Chemical (Milwaukee, Wis.)

Alternatively, libraries of natural compounds in the form of bacterial, fungal, plant, and animal extracts are commercially available from a number of sources, including, but not limited to, Biotics (Sussex, UK), Xenova (Slough, UK), Harbor Branch Oceangraphics Institute (Ft. Pierce, Fla.), and PharmaMar, U.S.A. (Cambridge, Mass.). In addition, natural and synthetically produced libraries are produced, if desired, according to methods known in the art (e.g., by combinatorial chemistry methods or standard extraction and fractionation methods). Furthermore, if desired, any library or compound may be readily modified using standard chemical, physical, or biochemical methods.

Administration of Therapeutic Compounds

By selectively disrupting or preventing a phosphoprotein from binding to its natural partner(s) through its binding site, the phosphopeptides of the invention, or derivatives, or peptidomimetics thereof, can significantly alter the biological activity or the biological function of a tandem BRCT domain. Therefore, the phosphopeptides, or derivatives thereof, of the invention can be used for the treatment of a disease or disorder characterized by inappropriate cell cycle regulation or apoptosis.

Diseases or disorders characterized by inappropriate cell cycle regulation, include hyperproliferative disorders, such as neoplasias. Examples of neoplasms include, without limitation, acoustic neuroma, acute leukemia, acute lymphocytic leukemia, acute monocytic leukemia, acute myeloblastic leukemia, acute myelocytic leukemia, acute myelomonocytic leukemia, acute promyelocytic leukemia, acute erythroleukemia, adenocarcinoma, angiosarcoma, astrocytoma, basal cell carcinoma, bile duct carcinoma, bladder carcinoma, brain cancer, breast cancer, bronchogenic carcinoma, cervical cancer, chondrosarcoma, chordoma, choriocarcinoma, chronic leukemia, chronic lymphocytic leukemia, chronic myelocytic leukemia, colon cancer, colon carcinoma, craniopharyngioma, cystadenocarcinoma, embryonal carcinoma, endotheliosarcoma, ependymoma, epithelial carcinoma, Ewing's tumor, glioma, heavy chain disease, hemangioblastoma, hepatoma, Hodgkin's disease, large cell carcinoma, leiomyosarcoma, liposarcoma, lung cancer, lung carcinoma, lymphangioendotheliosarcoma, lymphangiosarcoma, macroglobulinemia, medullary carcinoma, medulloblastoma, melanoma, meningioma, mesothelioma, myxosarcoma, neuroblastoma, non-Hodgkin's disease, oligodendriglioma, osteogenic sarcoma, ovarian cancer, pancreatic cancer, papillary adenocarcinomas, papillary carcinoma, pinealoma, polycythemia vera, prostate cancer, rhabdomyosarcoma, renal cell carcinoma, retinoblastoma, schwannoma, sebaceous gland carcinoma, seminoma, small cell lung carcinoma, squamous cell carcinoma, sweat gland carcinoma, synovioma, testicular cancer, uterine cancer, Waldenstrom's fibrosarcoma, and Wilm's tumor.

A tandem BRCT domain-binding phosphopeptide or peptidomimetic small molecule may be administered within a pharmaceutically-acceptable diluent, carrier, or excipient, in unit dosage form. Conventional pharmaceutical practice may be employed to provide suitable formulations or compositions to administer the compounds to patients suffering from a disease that is caused by excessive cell proliferation. Administration may begin before the patient is symptomatic. Any appropriate route of administration may be employed, for example, administration may be parenteral, intravenous, intra-arterial, subcutaneous, intramuscular, intracranial, intraorbital, ophthalmic, intraventricular, intracapsular, intraspinal, intracisternal, intraperitoneal, intranasal, aerosol, suppository, or oral administration. For example, therapeutic formulations may be in the form of liquid solutions or suspensions; for oral administration, formulations may be in the form of tablets or capsules; and for intranasal formulations, in the form of powders, nasal drops, or aerosols.

Pharmaceutical Formulations

The pharmaceutical compositions of the present invention are prepared in a manner known per se, for example by means of conventional dissolving, lyophilising, mixing, granulating or confectioning processes. Methods well known in the art for making formulations are found, for example, in “Remington: The Science and Practice of Pharmacy” (20th ed., ed. A.R. Gennaro, 2000, Lippincott Williams & Wilkins, Philadelphia).

Solutions of the active ingredient, and also suspensions, and especially isotonic aqueous solutions or suspensions, are preferably used, it being possible, for example in the case of lyophilized compositions that comprise the active ingredient alone or together with a carrier, for example mannitol, for such solutions or suspensions to be produced prior to use. The pharmaceutical compositions may be sterilized and/or may comprise excipients, for example preservatives, stabilisers, wetting and/or emulsifying agents, solubilisers, salts for regulating the osmotic pressure and/or buffers, and are prepared in a manner known per se, for example by means of conventional dissolving or lyophilising processes. The said solutions or suspensions may comprise viscosity-increasing substances, such as sodium carboxymethylcellulose, carboxymethylcellulose, dextran, poly vinylpyrrolidone or gelatin.

Suspensions in oil comprise as the oil component the vegetable, synthetic or semi-synthetic oils customary for injection purposes. There may be mentioned as such especially liquid fatty acid esters that contain as the acid component a long-chained fatty acid having from 8 to 22, especially from 12 to 22, carbon atoms, for example lauric acid, tridecylic acid, myristic acid, pentadecylic acid, palmitic acid, margaric acid, stearic acid, arachidic acid, behenic acid or corresponding unsaturated acids, for example oleic acid, elaidic acid, erucic acid, brasidic acid or linoleic acid, if desired with the addition of anti oxidants, for example, vitamins E, β-carotene, or 3,5-di-tert-butyl-4-hydroxytoluene. The alcohol component of those fatty acid esters has a maximum of 6 carbon atoms and is a mono- or poly-hydroxy, for example a mono-, di- or tri-hydroxy, alcohol, for example methanol, ethanol, propanol, butanol or pentanol or the isomers thereof, but especially glycol and glycerol. The following examples of fatty acid esters are therefore to be mentioned: ethyl oleate, isopropyl myristate, isopropyl palmitate, “Labrafil M 2375” (poly oxyethylene glycerol trioleate, Gattefoss, Paris), “Miglyol 812” (triglyceride of saturated fatty acids with a chain length of C₈to C₁₂, Huls AG, Germany), but especially vegetable oils, such as cottonseed oil, almond oil, olive oil, castor oil, sesame oil, soybean oil and more especially groundnut oil.

The injection compositions are prepared in customary manner under sterile conditions; the same applies also to introducing the compositions into ampoules or vials and sealing the containers.

Pharmaceutical compositions for oral administration can be obtained by combining the active ingredient with solid carriers, if desired granulating a resulting mixture, and processing the mixture, if desired or necessary, after the addition of appropriate excipients, into tablets, drage cores or capsules. It is also possible for them to be incorporated into plastics carriers that allow the active ingredients to diffuse or be released in measured amounts.

Suitable carriers are especially fillers, such as sugars, for example lactose, saccharose, mannitol or sorbitol, cellulose preparations and/or calcium phosphates, for example tricalcium phosphate or calcium hydrogen phosphate, and binders, such as starch pastes using for example corn, wheat, rice or potato starch, gelatin, tragacanth, methylcellulose, hydroxypropylmethylcellulose, sodium carboxymethylcellulose and/or polyvinyl-pyrrolidone, and/or, if desired, disintegrates, such as the above-mentioned starches, also carboxymethyl starch, crosslinked polyvinylpyrrolidone, agar, alginic acid or a salt thereof, such as sodium alginate. Excipients are especially flow conditioners and lubricants, for example silicic acid, talc, stearic acid or salts thereof, such as magnesium or calcium stearate, and/or polyethylene glycol. Drage cores are provided with suitable, optionally enteric, coatings, there being used, inter alia, concentrated sugar solutions which may comprise gum arabic, talc, polyvinylpyrrolidone, polyethylene glycol and/or titanium dioxide, or coating solutions in suitable organic solvents, or, for the preparation of enteric coatings, solutions of suitable cellulose preparations, such as ethylcellulose phthalate or hydroxypropylmethylcellulose phthalate. Capsules are dry-filled capsules made of gelatin and soft sealed capsules made of gelatin and a plasticiser, such as glycerol or sorbitol. The dry-filled capsules may comprise the active ingredient in the form of granules, for example with fillers, such as lactose, binders, such as starches, and/or glidants, such as talc or magnesium stearate, and if desired with stabilisers. In soft capsules the active ingredient is preferably dissolved or suspended in suitable oily excipients, such as fatty oils, paraffin oil or liquid polyethylene glycols, it being possible also for stabilisers and/or antibacterial agents to be added. Dyes or pigments may be added to the tablets or drage coatings or the capsule casings, for example for identification purposes or to indicate different doses of active ingredient.

The pharmaceutical compositions comprise from approximately 1% to approximately 95%, preferably from approximately 20% to approximately 90%, active ingredient. Pharmaceutical compositions according to the invention may be, for example, in unit dose form, such as in the form of ampoules, vials, suppositories, drages, tablets or capsules.

The formulations can be administered to human patients in a therapeutically effective amount (e.g., an amount that decreases, suppresses, attenuates, diminishes, arrests, or stabilizes the development or progression of a disease, disorder, or infection in a eukaryotic host organism). The preferred dosage of therapeutic agent to be administered is likely to depend on such variables as the type and extent of the disorder, the overall health status of the particular patient, the formulation of the compound excipients, and its route of administration.

For any of the methods of application described above, a compound that interacts with a tandem BRCT domain may be applied to the site of the needed therapeutic event (for example, by injection), or to tissue in the vicinity of the predicted therapeutic event or to a blood vessel supplying the cells predicted to require enhanced therapy.

The dosages of compounds that interact with a tandem BRCT domain depend on a number of factors, including the size and health of the individual patient, but, generally, between 0.1 mg and 1000 mg inclusive are administered per day to an adult in any pharmaceutically acceptable formulation. In addition, treatment by any of the approaches described herein may be combined with more traditional therapies.

Combination Therapy

As described above, if desired, treatment with compounds that interact with a tandem BRCT domain may be combined with therapies for the treatment of proliferative disease, such as radiotherapy, surgery, or chemotherapy. Chemotherapeutic agents that may be administered with compounds that interact with a tandem BRCT domain are listed in Table 3.

TABLE 3

Alkylating agents
cyclophosphamide
lomustine

busulfan
procarbazine

ifosfamide
altretamine

melphalan
estramustine phosphate

hexamethylmelamine
mechlorethamine

thiotepa
streptozocin

chlorambucil
temozolomide

dacarbazine
semustine.

carmustine

Platinum agents
cisplatin
carboplatinum

oxaliplatin
ZD-0473 (AnorMED)

spiroplatinum,
lobaplatin (Aeterna)

carboxyphthalatoplatinum,
satraplatin (Johnson Matthey)

tetraplatin
BBR-3464 (Hoffmann-La Roche)

ormiplatin
SM-11355 (Sumitomo)

iproplatin
AP-5280 (Access)

Antimetabolites
azacytidine
tomudex

gemcitabine
trimetrexate

capecitabine
deoxycoformycin

5-fluorouracil
fludarabine

floxuridine
pentostatin

2-chlorodeoxyadenosine
raltitrexed

6-mercaptopurine
hydroxyurea

6-thioguanine
decitabine (SuperGen)

cytarabin
clofarabine (Bioenvision)

2-fluorodeoxy cytidine
irofulven (MGI Pharma)

methotrexate
DMDC (Hoffmann-La Roche)

idatrexate
ethynylcytidine (Taiho)

Topoisomerase
amsacrine
rubitecan (SuperGen)

inhibitors
epirubicin
exatecan mesylate (Daiichi)

etoposide
quinamed (ChemGenex)

teniposide or mitoxantrone
gimatecan (Sigma-Tau)

irinotecan (CPT-11)
diflomotecan (Beaufour-Ipsen)

7-ethyl-10-hydroxy-camptothecin
TAS-103 (Taiho)

topotecan
elsamitrucin (Spectrum)

dexrazoxanet (TopoTarget)
J-107088 (Merck & Co)

pixantrone (Novuspharma)
BNP-1350 (BioNumerik)

rebeccamycin analogue (Exelixis)
CKD-602 (Chong Kun Dang)

BBR-3576 (Novuspharma)
KW-2170 (Kyowa Hakko)

Antitumor
dactinomycin (actinomycin D)
amonafide

antibiotics
doxorubicin (adriamycin)
azonafide

deoxyrubicin
anthrapyrazole

valrubicin
oxantrazole

daunorubicin (daunomycin)
losoxantrone

epirubicin
bleomycin sulfate (blenoxane)

therarubicin
bleomycinic acid

idarubicin
bleomycin A

rubidazone
bleomycin B

plicamycinp
mitomycin C

porfiromycin
MEN-10755 (Menarini)

cyanomorpholinodoxorubicin
GPX-100 (Gem Pharmaceuticals)

mitoxantrone (novantrone)

Antimitotic
paclitaxel
SB 408075 (GlaxoSmithKline)

agents
docetaxel
E7010 (Abbott)

colchicine
PG-TXL (Cell Therapeutics)

vinblastine
IDN 5109 (Bayer)

vincristine
A 105972 (Abbott)

vinorelbine
A 204197 (Abbott)

vindesine
LU 223651 (BASF)

dolastatin 10 (NCI)
D 24851 (ASTAMedica)

rhizoxin (Fujisawa)
ER-86526 (Eisai)

mivobulin (Warner-Lambert)
combretastatin A4 (BMS)

cemadotin (BASF)
isohomohalichondrin-B (PharmaMar)

RPR 109881A (Aventis)
ZD 6126 (AstraZeneca)

TXD 258 (Aventis)
PEG-paclitaxel (Enzon)

epothilone B (Novartis)
AZ10992 (Asahi)

T 900607 (Tularik)
IDN-5109 (Indena)

T 138067 (Tularik)
AVLB (Prescient NeuroPharma)

cryptophycin 52 (Eli Lilly)
azaepothilone B (BMS)

vinflunine (Fabre)
BNP-7787 (BioNumerik)

auristatin PE (Teikoku Hormone)
CA-4 prodrug (OXiGENE)

BMS 247550 (BMS)
dolastatin-10 (NIH)

BMS 184476 (BMS)
CA-4 (OXiGENE)

BMS 188797 (BMS)

taxoprexin (Protarga)

Aromatase
aminoglutethimide
exemestane

inhibitors
letrozole
atamestane (BioMedicines)

anastrazole
YM-511 (Yamanouchi)

formestane

Thymidylate
pemetrexed (Eli Lilly)
nolatrexed (Eximias)

synthase inhibitors
ZD-9331 (BTG)
CoFactor ™ (BioKeys)

DNA antagonists
trabectedin (PharmaMar)
mafosfamide (Baxter International)

glufosfamide (Baxter International)
apaziquone (Spectrum Pharmaceuticals)

albumin + 32P (Isotope Solutions)
O6 benzyl guanine (Paligent)

thymectacin (NewBiotics)

edotreotide (Novartis)

Farnesyltransferase
arglabin (NuOncology Labs)
tipifarnib (Johnson & Johnson)

inhibitors
lonafarnib (Schering-Plough)
perillyl alcohol (DOR BioPharma)

BAY-43-9006 (Bayer)

Pump inhibitors
CBT-1 (CBA Pharma)
zosuquidar trihydrochloride (Eli Lilly)

tariquidar (Xenova)
biricodar dicitrate (Vertex)

MS-209 (Schering AG)

Histone
tacedinaline (Pfizer)
pivaloyloxymethyl butyrate (Titan)

acetyltransferase
SAHA (Aton Pharma)
depsipeptide (Fujisawa)

inhibitors
MS-275 (Schering AG)

Metalloproteinase
Neovastat (Aeterna Laboratories)
CMT-3 (CollaGenex)

inhibitors
marimastat (British Biotech)
BMS-275291 (Celltech)

Ribonucleoside
gallium maltolate (Titan)
tezacitabine (Aventis)

reductase inhibitors
triapine (Vion)
didox (Molecules for Health)

TNF alpha
virulizin (Lorus Therapeutics)
revimid (Celgene)

agonists/antagonists
CDC-394 (Celgene)

Endothelin A
atrasentan (Abbott)
YM-598 (Yamanouchi)

receptor antagonist
ZD-4054 (AstraZeneca)

Retinoic acid
fenretinide (Johnson & Johnson)
alitretinoin (Ligand)

receptor agonists
LGD-1550 (Ligand)

Immuno-
interferon
dexosome therapy (Anosys)

modulators
oncophage (Antigenics)
pentrix (Australian Cancer Technology)

GMK (Progenics)
ISF-154 (Tragen)

adenocarcinoma vaccine (Biomira)
cancer vaccine (Intercell)

CTP-37 (AVI BioPharma)
norelin (Biostar)

IRX-2 (Immuno-Rx)
BLP-25 (Biomira)

PEP-005 (Peplin Biotech)
MGV (Progenics)

synchrovax vaccines (CTL Immuno)
β-alethine (Dovetail)

melanoma vaccine (CTL Immuno)
CLL therapy (Vasogen)

p21 RAS vaccine (GemVax)

Hormonal and
estrogens
prednisone

antihormonal
conjugated estrogens
methylprednisolone

agents
ethinyl estradiol
prednisolone

chlortrianisen
aminoglutethimide

idenestrol
leuprolide

hydroxyprogesterone caproate
goserelin

medroxyprogesterone
leuporelin

testosterone
bicalutamide

testosterone propionate; fluoxymesterone
flutamide

methyltestosterone
octreotide

diethylstilbestrol
nilutamide

megestrol
mitotane

tamoxifen
P-04 (Novogen)

toremofine
2-methoxyestradiol (EntreMed)

dexamethasone
arzoxifene (Eli Lilly)

Photodynamic
talaporfin (Light Sciences)
Pd-bacteriopheophorbide (Yeda)

agents
Theralux (Theratechnologies)
lutetium texaphyrin (Pharmacyclics)

motexafin gadolinium (Pharmacyclics)
hypericin

Tyrosine Kinase
imatinib (Novartis)
kahalide F (PharmaMar)

Inhibitors
leflunomide (Sugen/Pharmacia)
CEP-701 (Cephalon)

ZD1839 (AstraZeneca)
CEP-751 (Cephalon)

erlotinib (Oncogene Science)
MLN518 (Millenium)

canertinib (Pfizer)
PKC412 (Novartis)

squalamine (Genaera)
phenoxodiol ( )

SU5416 (Pharmacia)
trastuzumab (Genentech)

SU6668 (Pharmacia)
C225 (ImClone)

ZD4190 (AstraZeneca)
rhu-Mab (Genentech)

ZD6474 (AstraZeneca)
MDX-H210 (Medarex)

vatalanib (Novartis)
2C4 (Genentech)

PKI166 (Novartis)
MDX-447 (Medarex)

GW2016 (GlaxoSmithKline)
ABX-EGF (Abgenix)

EKB-509 (Wyeth)
IMC-1C11 (ImClone)

EKB-569 (Wyeth)

Miscellaneous agents

SR-27897 (CCK A inhibitor, Sanofi-Synthelabo)
BCX-1777 (PNP inhibitor, BioCryst)

tocladesine (cyclic AMP agonist, Ribapharm)
ranpirnase (ribonuclease stimulant, Alfacell)

alvocidib (CDK inhibitor, Aventis)
galarubicin (RNA synthesis inhibitor, Dong-A)

CV-247 (COX-2 inhibitor, Ivy Medical)
tirapazamine (reducing agent, SRI International)

P54 (COX-2 inhibitor, Phytopharm)
N-acetylcysteine (reducing agent, Zambon)

CapCell ™ (CYP450 stimulant, Bavarian Nordic)
R-flurbiprofen (NF-kappaB inhibitor, Encore)

GCS-100 (gal3 antagonist, GlycoGenesys)
3CPA (NF-kappaB inhibitor, Active Biotech)

G17DT immunogen (gastrin inhibitor, Aphton)
seocalcitol (vitamin D receptor agonist, Leo)

efaproxiral (oxygenator, Allos Therapeutics)
131-I-TM-601 (DNA antagonist, TransMolecular)

PI-88 (heparanase inhibitor, Progen)
eflornithine (ODC inhibitor, ILEX Oncology)

tesmilifene (histamine antagonist, YM BioSciences)
minodronic acid (osteoclast inhibitor, Yamanouchi)

histamine (histamine H2 receptor agonist, Maxim)
indisulam (p53 stimulant, Eisai)

tiazofurin (IMPDH inhibitor, Ribapharm)
aplidine (PPT inhibitor, PharmaMar)

cilengitide (integrin antagonist, Merck KGaA)
rituximab (CD20 antibody, Genentech)

SR-31747 (IL-1 antagonist, Sanofi-Synthelabo)
gemtuzumab (CD33 antibody, Wyeth Ayerst)

CCI-779 (mTOR kinase inhibitor, Wyeth)
PG2 (hematopoiesis enhancer, Pharmagenesis)

exisulind (PDE V inhibitor, Cell Pathways)
Immunol ™ (triclosan oral rinse, Endo)

CP-461 (PDE V inhibitor, Cell Pathways)
triacetyluridine (uridine prodrug, Wellstat)

AG-2037 (GART inhibitor, Pfizer)
SN-4071 (sarcoma agent, Signature BioScience)

WX-UK1 (plasminogen activator inhibitor, Wilex)
TransMID-107 ™ (immunotoxin, KS Biomedix)

PBI-1402 (PMN stimulant, ProMetic LifeSciences)
PCK-3145 (apoptosis promotor, Procyon)

bortezomib (proteasome inhibitor, Millennium)
doranidazole (apoptosis promotor, Pola)

SRL-172 (T cell stimulant, SR Pharma)
CHS-828 (cytotoxic agent, Leo)

TLK-286 (glutathione S transferase inhibitor, Telik)
trans-retinoic acid (differentiator, NIH)

PT-100 (growth factor agonist, Point Therapeutics)
MX6 (apoptosis promotor, MAXIA)

midostaurin (PKC inhibitor, Novartis)
apomine (apoptosis promotor, ILEX Oncology)

bryostatin-1 (PKC stimulant, GPC Biotech)
urocidin (apoptosis promotor, Bioniche)

CDA-II (apoptosis promotor, Everlife)
Ro-31-7453 (apoptosis promotor, La Roche)

SDX-101 (apoptosis promotor, Salmedix)
brostallicin (apoptosis promotor, Pharmacia)

ceflatonin (apoptosis promotor, ChemGenex)

Gene Therapy

In another embodiment of the invention, the BRCA1 gene, or another gene encoding for a peptide of the invention, may be administered to a subject using gene therapy techniques. See, generally, Morgan et al., Ann. Rev. Biochem. 62:191-217, 1993; Culver et al., Trends Genet. 10:174-178, 1994; and U.S. Pat. No. 5,399,346 (French et al.). The general principle is to introduce the BRCA1 gene, for example, into a cancer cell in a patient, such that the BRCA1 gene is expressed and produces a BRCA1 polypeptide, or a biologically-active fragment thereof, that can supplement the activity of the endogenous, defective, or absent BRCA1 polypeptide.

A desired mode of gene therapy is to provide the BRCA1 polynucleotide in such a way that it will replicate inside the cell, thereby enhancing and prolonging the interference effect. Thus, the BRCA1 polynucleotide can be operably linked to a suitable promoter, such as the natural promoter of the corresponding gene, a heterologous promoter that is intrinsically active in cancer cells, or a heterologous promoter that can be induced by a suitable agent.

In another aspect of gene therapy according to the invention, a polynucleotide is introduced into a cancer cell such that the polynucleotide interferes with the expression of a BRCA1-related gene, for example, a gene involved in cell cycle regulation (e.g., cdk2). The administered polynucleotide blocks expression of the BRCA1-related gene by forming a complex with the BRCA1-related gene directly, or by complexing with the RNA transcribed from the BRCA1-related gene. Desirably, the construct is designed so that the polynucleotide sequence is complementary to the sequence of the BRCA1-related gene. Thus, once integrated into the cellular genome, the transcript of the administered polynucleotide will be complementary to the transcript of the BRCA1-related gene, and therefore, the polynucleotide will be capable of hybridizing with the BRCA1-related gene transcript. This approach is known as anti-sense therapy or RNAi. See, for example, Culver et al., supra; and Roth, Ann. Surg. Oncol. 1:79-86, 1994.

Exemplary disease targets include, but are not limited to, prostate cancer, ovarian cancer, colorectal cancer, stomach cancer, lung cancer, esophageal cancer, head cancer, neck cancer, bladder cancer, squamous cell cancer, breast cancer, cervical cancer, and endometrial cancer.

For general reviews of the methods of gene therapy, see Goldspiel et al., Clinical Pharmacy 12:488-505, 1993; Wu and Wu, Biotherapy 3:87-95, 1991; Tolstoshev, Ann. Rev. Pharmacol. Toxicol. 32:573-596, 1993; Mulligan, Science 260:926-932, 1993; and Morgan and Anderson, supra. Methods commonly known in the art of recombinant DNA technology that can be used are described in Ausubel et al. supra; and Kriegler, 1990, Gene Transfer and Expression, A Laboratory Manual, Stockton Press, NY.

It is envisioned that a patient that has been diagnosed with, or that has a propensity for developing, a cancer-related condition can be administered a BRCA1 gene, using a suitable method known in the art and as described herein, such that the BRCA1 gene is incorporated into one or more cells of the patient and is expressible by the cell(s) and/or progeny of the cell(s). The method can encompass in vivo administration of the BRCA1 gene in a suitable composition, or the method can involve ex vivo therapy in which one or more cells of the patient are removed, transformed with the BRCA1 gene, optionally expanded, and readministered to the patient. Expression of the BRCA1 gene in the transformed cells will reactivate BRCA1 activity in the patient, thereby promoting regulation of the cell cycle, as is discussed above, and therefore, inhibition of the cancer-related condition, thus leading to improvement of the diseased condition afflicting the patient.

Transformation of a target cell with a BRCA1 nucleic acid molecule is facilitated by suitable techniques known in the art, such as providing the BRCA1 nucleic acid molecule in the form of a suitable vector, or encapsulation of the BRCA1 nucleic acid molecule in a liposome. The nucleic acid molecule may be provided to the cancer site by an antigen-specific homing mechanism, or by direct injection. In one approach, the nucleic acid molecule is operably linked to a promoter and is contained in an expression vector. In another approach, the nucleic acid molecule is contained in a recombinant viral vector, for example an adenoviral vector (see e.g., Kozarsky and Wilson, Current Opinion in Genetics and Development 3:499-503, 1993; Rosenfeld et al., Science 252:431-434, 1991; Rosenfeld et al., Cell 68:143-155, 1992; and Mastrangeli et al., J. Clin. Invest. 91:225-234, 1993), an adeno-associated viral vector (AAV; see, for example, Walsh et al., Proc. Soc. Exp. Biol. Med. 204:289-300, 1993), a lentiviral vector, a herpes viral vector, a retroviral vector (see, e.g., Miller et al., 1993, Meth. Enzymol. 217:581-599; Boesen et al., Biotherapy 6:291-302, 1994; Clowes et al., J. Clin. Invest. 93:644-651, 1994; Kiem et al., Blood 83:1467-1473, 1994; Salmons and Gunzberg, Human Gene Therapy 4:129-141, 1993; and Grossman and Wilson, Curr. Opin. in Genetics and Devel. 3:110-114, 1993), a pox virus vector, or a baculoviral vector.

Non-viral vectors can also be used for gene therapy. For example, naked DNA can be delivered via liposomes, receptor-mediated delivery, calcium phosphate transfection, lipofection, electroporation, particle bombardment (gene gun), microinjection, cell fusion, chromosome-mediated gene transfer, microcell-mediated gene transfer, spheroplast fusion, or pressure-mediated gene delivery. Numerous techniques are known in the art for the introduction of foreign genes into cells (see, e.g., Loeffler and Behr, Meth. Enzymol. 217:599-618, 1993; Cohen et al., Meth. Enzymol. 217:618-644, 1993; Cline, Pharmac. Ther. 29:69-92, 1985), and may be used in accordance with the present invention, provided that the necessary developmental and physiological functions of the recipient cells are not disrupted. Usually, the method of transfer includes the transfer of a selectable marker to the cells. The cells are then placed under selection to isolate those cells that have taken up and are expressing the transferred gene. Those transformed cells are then delivered to a patient. The technique should provide for the stable transfer of the gene to the cell, so that the gene is expressible by the cell and preferably heritable and expressible by progeny of the cell.

Preferably, a desired gene is introduced intracellularly and incorporated within the host precursor cell DNA for expression, by homologous recombination (see, e.g., Koller and Smithies, Proc. Natl. Acad. Sci. USA 86:8932-8935, 1989; Zijlstra et al., Nature 342:435-438, 1989).

The vector containing the BRCA1 gene, or a fragment thereof, can be administered as is described above for the administration of a peptide agent or candidate compound of the invention, for example, to an artery at the site of a tumor or other cancerous cell.

Various reports have been presented regarding the efficacy of gene therapy for the treatment of monogeneic diseases, early stage tumors, and cardiovascular disease. (See, e.g., Blaese et al., Science 270:475-480, 1995; Wingo et al., Cancer 82:1197-1207, 1998; Dzao, Keystone Symposium Molecular and Cellular Biology of Gene Therapy, Keystone, Co. January 19-25, 1998; and Isner, Keystone Symposium Molecular and Cellular Biology of Gene Therapy, Keystone, Co. January 19-25, 1998.)

In a preferred embodiment, patients diagnosed with prostate cancer, ovarian cancer, colorectal cancer (e.g., colorectal adenocarcinoma), stomach cancer, lung cancer, esophageal cancer, head cancer, neck cancer, bladder cancer (e.g., bladder transitional cell carcinoma), squamous cell cancer, breast cancer, cervical cancer, or endometrial cancer can be treated using in vivo methods consisting of the administration of a recombinant retrovirus containing a BRCA1 cDNA under the control of a promoter (e.g., a prostate-, ovary-, colon-, stomach-, lung-, esophageal-, head-, neck-, bladder-, squamous cell-, breast-, cervical-, or endometrial-specific promoter) for expression in tumor cells. In vivo therapy involves transfection of a BRCA1 nucleic acid molecule directly into the cells of a patient without the need for prior removal of those cells from the patient.

In vivo delivery is desirably accomplished by (1) infusing a recombinant retrovirus vector construct into a blood vessel that perfuses the tumor or (2) injecting a recombinant retrovirus vector construct directly into the tumor. In an especially desired in vivo embodiment, a catheter is inserted into a blood vessel in the neck of an organism and the tip of the indwelling catheter is advanced with fluoroscopic guidance to a position in an artery that perfuses a portion of the tumor. It is desired that the tip of an indwelling catheter be placed in proximity to an area of the tumor so that the cells can be directly targeted and transfected. The retroviral construct can also be directly targeted to cancer cells using cancer cell-specific surface antigens, although this is not required. The recombinant retrovirus is administered to patients desirably by means of intravenous administration in any suitable pharmacological composition, either as a bolus or as an infusion over a period of time. Injection of the recombinant retrovirus directly into the tumor, or into a blood vessel that perfuses the tumor will promote incorporation of the BRCA1 cDNA into tumor cells, thereby inhibiting cell growth of the tumor and preventing further tumor formation.

After delivery of a recombinant retrovirus vector construct to the cells of the tumor, the cells are maintained under physiological conditions to allow sufficient time for the retrovirus vector construct to infect the cancer cells and for cellular expression of the BRCA1 polypeptide contained in that construct. A time period sufficient for expression of a BRCA1 polypeptide in a cancer cell varies as is well known in the art depending on the type of retrovirus vector used and the method of delivery. It should also be pointed out that because that the retrovirus vector employed may be replication defective, it may not be capable of replicating in the cells that are ultimately infected.

A retrovirus vector construct is typically delivered in the form of a pharmacological composition that comprises a physiologically acceptable carrier and the retrovirus vector construct. An effective amount of a retrovirus vector construct is delivered, and consists of 1 pfu/cell, 5 pfu/cell, 10 pfu/cell, or 20 pfu/cell, or any other amount that is effective for promoting expression of a BRCA1 polypeptide in the target cancer cells. Means for determining an effective amount of a retrovirus vector construct are well known in the art.

As is also well known in the art, a specific dose level for any particular subject depends upon a variety of factors including the infectivity of the retrovirus vector, the age, body weight, general health, sex, diet, time of administration, route of administration, rate of excretion, and the severity of the condition of the patient.

Genes other than those encoding BRCA1, such as those encoding BRCA1-binding peptides of the invention (e.g. a gene encoding a BACH1 polypeptide), may alternatively be used in the foregoing methods of gene therapy.

INCORPORATION BY REFERENCE

The following documents are incorporated by reference: 60/426,132, filed Nov. 14, 2002; 60/485,641, filed Jul. 8, 2003; 60/487,899, filed Jul. 17, 2003; and 10/713,978, filed Nov. 14, 2003.

All patents and publications mentioned in this specification are hereby incorporated by reference to the same extent as if each independent publication or patent application was specifically and individually indicated to be incorporated by reference.

Other Embodiments

From the foregoing description, it is apparent that variations and modifications may be made to the invention described herein to adopt it to various usages and conditions. Such embodiments are also within the scope of the following claims.

	Number	Date	Country
Parent	11126022	May 2005	US
Child	12229740		US

	Number	Date	Country
Parent	12229740	Aug 2008	US
Child	13451209		US

METHODS AND COMPOSITIONS FOR CANCER TREATMENT RELATING TO BRCA1 BRCT DOMAIN RECOGNITION OF PHOSPHORYLATED BACH1

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