NOVEL HIGH AFFINITY BIVALENT HELICALLY CONSTRAINED PEPTIDE AGAINST CANCER

Abstract

The present invention describes a novel bivalent helically constrained peptide targeted against S100B that is an effective anti-cancer drug against cancers that over-express S100B. This helix mimetic targeted against S100B induces rapid apoptosis in cancer cells that over-express a calcium binding protein S100B through simultaneous inhibition of key growth pathways including activation of p53.

Description

FIELD OF INVENTION

The present invention relates to a novel high affinity bivalent helically constrained peptide against cancer and a process for the preparation thereof. In particular, the present invention relates to the treatment of human cancers having over-expression of S100B and or down-regulation of p53. More specifically, it relates to the treatment of several types of tumors including melanoma and glioma with a new high affinity bivalent helically constrained peptide. This helix mimetic targeted against S100B induces rapid apoptosis in cancer cells that over-express a calcium binding protein S100B through simultaneous inhibition of key growth pathways including activation of p53.

BACKGROUND OF THE INVENTION

Design of specific inhibitors of protein-protein interactions that are capable of turning off specific signaling pathways have an important bearing on the future of therapeutics. Cancer genome project has demonstrated that in many, if not all, tumors accumulate multiple mutations resulting in several dysregulated pathways favoring uncontrolled proliferation (Greenman et al., 2007; Weir et al., 2007). These combinations of dysregulated pathways may be necessary to overcome the multiple tumor suppressor functions present in differentiated cells (Bartkova et al., 2006; Jirina Bartkova, 2005; Weir et al., 2007). Specific targeting of multiple dysregulated pathways, either through a single agent or through multiple agents may provide useful advantage. Thus, drug targets that regulate multiple pathways are important. However, selectivity of inhibited pathways may be crucial to avoid off-target toxic effects. A classic example in oncology is that of imatinib, which inhibits Bcr-Abl kinase with significant degree of specificity (Druker, 2008).

Although small molecules are sometimes known to be protein-protein interaction inhibitors, they rarely exhibit low off-target effects. Secondary structure mimetics have been proposed as effective protein-protein interaction inhibitors (Banerjee et al., 2002; Saraogi and Hamilton, 2008; Walensky et al., 2004). Due to resemblance of the secondary structure mimetics to extant proteins, they may be superior to small molecules in causing lesser undesirable off-target effects. In many situations, a low nanomolar dissociation constant of receptor-drug complex is desirable or even mandatory (Overington et al., 2006). Many protein-protein interactions are weak and attaining high enough affinity for a secondary structure mimetic where the parent protein-protein interaction is weak remains a major challenge. Since many proteins are oligomeric in nature, we propose that properly designed oligomeric secondary structure mimetics (more than one secondary structure mimetic connected by a designed tether) may be a simple way to enhance affinity in such cases.

S100 family of proteins has been implicated in wide variety of tumors, although their precise role is still unclear. Increased levels of S100B are observed in several tumors (Harpio and Einarsson, 2004) and it has been suggested to contribute to tumor progression by interacting and down-regulating p53 and inhibiting its function as a tumor suppressor (Lin et al., 2001; Rustandi et al., 1999; Rustandi et al., 2000; Rustandi et al., 1998b; Wilder et al., 1998). Recent work suggests that other pro-survival pathways may also be regulated by S100B (Brozzi et al., 2009). Thus, inhibition of S100B may simultaneously regulate several key growth regulatory pathways and exert broad anti-tumor effect. Classes of melanomas and gliomas are prime examples of cancers where over-expression of S100B plays a crucial role in cancer development and progression (Markowitz et al., 2005). Thus, there is a real need of agents that block S100B interaction with other proteins.

Keeping in purview the hitherto reported prior art, it may be summarized that most of the therapeutic efforts have been focused on small molecules. There is a recent surge of interest in peptides, although the market is still small. Recent scientific developments have created tremendous opportunity in the therapeutic field. A number of peptides are now in market, but mostly in different phases of trial. However, none are known against melanoma and certainly not with high efficacy. Consequently, there is a dire need to design specific inhibitors of protein-protein interactions that are capable of turning off specific signaling pathways which have an important bearing on the future of therapeutics.

OBJECTS OF THE INVENTION

The main object of the present invention is therefore to provide novel high affinity bivalent helically constrained peptides useful as therapeutics for the treatment of cancers.

Another object of the present invention is to provide an effective therapeutic intervention and method of treatment of several types of tumors in which S100B a calcium binding protein is over-expressed.

Still another object of the present invention is to provide a peptide that completely inhibits melanoma growth without any significant observable toxicity.

Yet another object of the present invention is to provide a pharmaceutical composition for the treatment of cancers comprising the novel bi-helical peptidomimetic.

SUMMARY OF THE INVENTION

Direct inhibition of protein-protein interaction, particularly between weakly interacting proteins, is a major challenge in drug discovery. S100B, a calcium-regulated protein is known to play a crucial role in melanoma and glioma cell proliferation. The present invention relates to a therapeutic peptide against melanoma, glioma and other types of cancers that over-express S100B, a calcium regulated cell progression and differentiation protein. Increased levels of S100B in several tumors contribute to tumor progression by interacting and down regulating p53 and inhibiting its function as a tumor suppressor. Development of high affinity bivalent peptidomimetics is achieved through progressive modifications of p53 target sequence using S100B peptide as a guide. This high affinity bivalent helically constrained peptide against S100B has got the ability to kill cancer cells rapidly with high specificity by exerting anti-proliferative action through simultaneous inhibition of key growth pathways including activation of p53. At moderate intravenous dose, the peptide completely inhibits melanoma growth in a mouse model without any significant observable toxicity.

The present invention provides a high affinity bivalent helically constrained peptide against S100B, which rapidly kills several types of cancer cells that over-express S100B, with high specificity. The molecule exerts anti-proliferative action through simultaneous inhibition of key growth pathways including activation of p53. At moderate intravenous dose, the peptide completely inhibits melanoma growth in a mouse model without any significant observable toxicity. The invention described here provides an effective drug for cancers that over-express S100B.

The bivalent helically constrained peptide of the present invention specifically and effectively blocks S100B and causes rapid apoptosis. Comparison with a well-known p53 activating agent suggests that simultaneous inhibition of key growth pathways is a superior anti-tumor strategy. Also reported is in vivo efficacy of the peptide in a mouse model of melanoma.

Accordingly, the present invention provides a novel high affinity bivalent helically constrained peptide against cancer, wherein the said peptide is represented by SEQ ID No. 4-Lysine-SEQ ID No. 4 and having the following general formula:

In an embodiment, the present invention provides a pharmaceutical composition comprising a therapeutically effective amount of bi-helical peptidomimetic as an active ingredient optionally along with at least one pharmaceutically acceptable peptide stabilizer and pharmaceutically acceptable excipients, which composition is adapted for the treatment of human cancers in which S100B, a calcium binding protein, is over-expressed resulting in lower level of expression of wild type p53. Human cancers having over-expression of S100B and/or down regulation of p53 include but are not limited to melanoma, glioma, and sarcoma.

In another embodiment, the present invention provides a pharmaceutical composition wherein the bi-helical peptidomimetic comprises of one or more helix stabilizing amino acids and two parallel helices, wherein the polypeptide has enhanced cell penetrability relative to a corresponding unmodified peptide.

In yet another embodiment, the present invention provides the the helix-stabilizing amino acids, which stabilize an alpha-helix structure. The bi-helical polypeptide in some embodiment may have cross-linker linking helices in parallel orientation. The bi-helical polypeptide in some embodiment may have branching resulting in parallel orientation of the helices such as branched dimeric aib substituted TRTK (pBBD-TRTK), having highest affinity towards S100B, enhanced cell penetrability including enhanced energy-dependent transport across a cell membrane, including enhanced endocytosis. The bi-helical polypeptide also comprises a growth retarding, pro-apoptotic polypeptide, such as an alpha-helical domain of Actin capping family protein CapZ or a portion thereof and in some embodiment comprises a S100B binding domain of the protein, p53 or a portion thereof.

In still another embodiment of the present invention the said composition is formulated for oral, parental, subcutaneous, intravenous or intra-articular administration.

In yet another embodiment of the present invention, the said pharmaceutical composition comprises at least one approved chemotherapeutic agent.

In still another embodiment of the present invention, the said composition is adapted for the treatment of human cancers having over-expression of S100B and/or down-regulation of p53 in the dose of approximate 50 mg/kg body weight per day for a period of 1 to 7 days.

In yet another embodiment, the present invention provides a process for the preparation of a medicament for the treatment of S100B over-expressing and/or p53 under-expressing human cancers.

In still another embodiment, the said composition is adapted for inhibiting tumor growth through inhibition of phosphoinositide-3-kinase pathway. The phosphoinositide-3-kinase pathway in some forms initiates the stimulation of some growth factor receptors, e.g. EGFR. This pathway is one of the most crucial pathways for development of many types of cancers activation of which results phosphorylation of GSK-3-beta, Stat-3 and beta-catenin among others. In particular, this invention inhibits this pathway and as a result it reduces the phosphorylation of GSK-3-beta and beta-catenin.

In yet another embodiment, the said composition is adapted for inhibiting tumor growth through inhibition of Src family kinases. In particular, the peptides of this invention inhibit Src-kinase and as a result reduce phosphorylation of Stat-3, resulting in complete inhibition of cell migration.

In still another embodiment, the said composition is adapted for raising the wild-type p53 levels by more than about 50% and 100%. The increase occurs in both cytoplasmic and nuclear compartments.

In yet another embodiment, the said composition is adapted for including rapid apoptosis in a group of cancers having wild-type p53 which is down-regulated by S100B. The rapid apoptosis start in 6 hrs, 2 hrs and 1 hr.

In still another embodiment, the said composition comprises approximate 20% to 80% (w/w) of the bi-helical peptidomimetics, which composition is adapted for the treatment of human cancers having over-expression of S100B and or down-regulation of p53.

In a further embodiment, the present invention provides a method for the treatment of human cancers having over-expression of S100B and/or down-regulation of p53 comprising administering a therapeutically effective amount of the aforesaid composition to a patient in need thereof wherein the said peptidomimetic interacts with S100B.

In another embodiment, the peptidomimetic antagonizes the interaction between S100B and p53.

In still another embodiment, the peptidomimetic antagonizes the interaction between S100B and Src-family kinases.

In yet another embodiment, the present invention provides methods of treatment indicated herein, wherein the peptidomimetic is administered in conjunction with a standard method of care. The standard method of care may, for example be chemotherapy. Alternatively, the standard method of care may be radiation therapy. In a further embodiment, the standard method of care is surgery.

In still another embodiment, the peptidomimetic represented by SEQ ID No. 4-Lysine-SEQ ID No. 4 has enhanced cell penetrability relative to the corresponding unmodified peptides represented by SEQ ID No. 3-Lysine-SEQ ID No. 3 and SEQ ID No. 5-Lysine-SEQ ID No. 5.

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWING/FIGURES

FIG. 1. (A) Structure of S100B-TRTK peptide complex. The two subunits of S100B shaded differently and the bound peptides are shown as blue ribbons. (B) Design strategy for Aib substitutions. One face of the helix primarily interacts with S100B. The Aib substitutions were made on the opposite face. The substituted residues are marked in blue. The peptide shown represents residues 375-389 of human p53 in the conformation bound to S100B (1DT7) and the substituted residues are 378, 381 and 388. (C) Synthesis strategy for pBBDR-TRTK. The details are given in the description of the invention.

FIG. 2. (A) Table of some representative peptides synthesized and their dissociation constants. Binding isotherm of pBBD-TRTK with (B) S-100B and (C) S100P and (D) pBBD-TRTK-AA with S100B. Fluorescein labeled, 5 nM pBBD-TRTK or pBBD-TRTK-AA was titrated with increasing concentrations of S100B or S100P in 50 mM Tris-HCl buffer, pH 7.5, containing 50 mM NaCl and 10 mM CaCl₂ at ambient temperatures which was 25±1 degree C. Anisotropy was determined at each point. The each point is averaging of at least three independent experiments. The line is best fit to a single site binding equation given in description of the invention.

FIG. 3. Phase contrast microscopy of SK-MEL5 cells (A) 2 hrs after treatment with 10 microM pBBDR-TRTK; (B) 18 hrs after treatment with 20 microM pBBDR-TRTK-AA; (C) 2 hr after treatment with pBBD-TRTK (without the cell penetration tag) and (D) control.

FIG. 4. (A) Assay of cell viability using incorporation of ³H-thymidine after treatment with different concentrations of pBBDR-TRTK for 18 hrs. (B) Flow cytometry of SK-MEL5 cells before and after treatment with 10 microM pBDR-TRTK, using Annexin V and Propidium Iodide (lower panel) and forward/side scatter (upper panel).

FIG. 5. (A) Confocal Fluorescence microscopic images at 30 minutes of phalloidin (green) and DAPI (blue) stained SK-MEL5 cells; Left: Untreated, Right: Treated with 10 microM pBBDR-TRTK. (B) Confocal Fluorescence microscopic images of Cytochrome C antibody (green) and DAPI (blue) stained SK-MEL5 cells (Left) Control; (Right) 2 h after treatment with 10 microM pBBDR-TRTK.

FIG. 6. (A) Phase contrast microscopy of SK-MEL5 cells (Upper panel) 10 microM pBDR-TRTK (Lower panel) 10 microM pBDR-TRTK, pre-treated with 10 microM pifithrin-micro, 1 hr after treatment. (B) Confocal microscopic images of merged p53 (green) and mitotracker (red), Top untreated and bottom, 1 h after treatment with pBBDR-TRTK.

FIG. 7. (A) Kinetics of implanted tumor (B16F10 melanoma cell) growth in syngenic mouse model when treated with 50 mg/kg body wt. i.v. pBBDR-TRTK (black circles) or vehicle control (blue circles). (B) Histopathology of tumor section after sacrifice of the animals after treatment with pBBDR-TRTK (upper panel) or vehicle control (lower panel). (C) Antibody staining for PCNA in tumor sections after treatment with pBBDR-TRTK (lower panel) or vehicle control (upper panel).

FIG. 8. Efficacy of the peptidomimetic (pBBDR-TRTK) in a C57BL/6J melanoma xenograft model as measured by reduced tumor burden in treated animals.

FIG. 9. p53 staining of the tumor sections after treatment with 1 dose of 50 mg/Kg body weight of pBBDR-TRTK (left panel) and vehicle control (right panel).

FIGS. 10 and 11. Flow charts illustrating the process/steps of development of high affinity bivalent peptidomimetics achieved through progressive modifications of p53 target sequence using S100B peptide as a guide.

LIST OF ABBREVIATIONS USED

TABLE 1
Chart of Amino Acid with their structure and abbreviation
		Abbreviation
Sl.No	Name of Amino Acid	used	Structure
01	Threonine(Thr)	T
02	Arginine(Arg)	R
03	Lysine(Lys)	K
04	Isoleucine(Ile)	I
05	Leucine(Leu)	L
06	Aminoisobutyric Acid(Aib)	B
07	Aspartic Acid (Asp)	D
08	Tryptophan(Trp)	W
09	Aminohexanoic acid (Ahx)	Ahx
10	Glycine (Gly)	G
11	Cysteine (Cys)	C
12	Phenylalanine (Phe)	F
13	Methionine (Met)	M
14	Histidine (His)	H
15	Serine (Ser)	S
16	Glutamine (Gln)	Q

TABLE 2
Details of all the synthesized pepties
	Name of the	What it signifies/	The exact sequence in terms
Sl.No.	peptide/	means/pertains to	of one letter amino acid codes
1.	P3	Wild type P53 peptide	QSTSRHKKLMFKTEG
2.	pBM53	P53 substituted	QSTBRHBKLMFKTBG
		monomer peptide
3.	pBDC-53	pBM53 dimerised with a properly designed crosslinker
4.	pBM-TRK	Aib substitued TRTK	TRTKIDWBKILBGGGCG
		monomer peptide
5.	pBDC-TRTK	pBM-TRTK dimerised with a properly designed crosslinker [Wild type TRTK peptides bind to two subunits of S100B in a head-to-head fashion. In order to make a dimeric peptide a linker was designed which spans the distance between two C-termini of the peptides. Modeling indicated that addition of GGGCG at the C-terminus along with BMH cross-linker spans this distance.]
6.	pBBD-TRTK	pBM-TRTK branched dimerised with a proper crosslinker
7.	pBBD-TRTK-AA	pBM-TRTK double mutant branched dimer mutated at (Ile-5 and Trp-7)
8.	pBBDR-TRTK	pBM-TRTK branched dimerised with a properly designed crosslinker and tagged with hexa-arginine
9.	pBDCR-TRTK	pBM-TRTK dimerised with a properl crosslinker and tagged with hexa-arginine

List of sequences used in the invention
Sequence                  Sequence ID No.
TRTKIDWNKILS              SEQ ID No. 1
TRTKIDWBKILBGGGCG         SEQ ID No. 2
TRTKIDWBKILBKAhx          SEQ ID No. 3
RRRRRRTRTKIDWBKILBKAhx    SEQ ID No. 4
TRTKADABKILBKAhx          SEQ ID No. 5
QSTSRHKKLMFKTEG           SEQ ID No. 6
QSTBRHBKLMFKTBG           SEQ ID No. 7
QSTBRHBKLMFKTBGGGCG       SEQ ID No. 8
RRRRRRQSTBRHBKLMFKTBGGGCG SEQ ID No. 9

DETAILED DESCRIPTION OF THE INVENTION

Two target sequences of S100B [TRTK (12 a.a.) and 375-389 of p53 are helical when bound to the receptor (FIG. 1 (A)]. Small peptides generally do not have definite structures in solution and hence binding to the receptor involves sacrifice of entropy as the structure becomes more ordered upon binding. A constrained helical peptide may have higher affinity due to less sacrifice of entropy upon binding and enhanced in vivo stability as was shown for stapled monomeric helix mimetics (Moellering et al., 2009). We have chosen substitution of helicogenic alpha-amino-isobutyric acid (Aib) substitution as an alternative due to its simple synthesis methodology and possibly better scaling up potential for bivalent molecules (Vijayalakshmi et al., 2000). Using the structures of the S100B-peptide as a guide, we replaced only those residues in the target peptides that are not interacting with S100B, but are still part of the target sequence (Banerjee et al., 2002) (FIG. 1(B)). Wild type TRTK peptides bind to two subunits of S100B in a head-to-head fashion. In order to make a dimeric peptide a linker was designed which spans the distance between two C-termini of the peptides. Modeling indicated that addition of GGGCG at the C-terminus along with BMH cross-linker spanned this distance.

Binding affinity of alb substituted p53 (pBM-53) (and all other peptides) was estimated by fluorescence anisotropy using N-terminal fluorescein labeled peptides. pBM-53 binds to S100B somewhat stronger than the unmodified peptide but the dissociation constant is still in the micromolar range. Since S100B is a dimer, one possible way to enhance the binding is to synthesize a bivalent molecule, which can simultaneously bind to two subunits. pBM-53 was dimerized with a properly designed cross-linker through inserted cysteine residues (pBDC-53). The C-terminal side of the two peptides (bound to two different subunits) comes fairly close and is separated by shallow groove allowing a cross-linker to fit.

The length of the cross-linker was chosen such that it spans the separation between the two cysteine residues in the predicted structure. The dimerization leads to approximately 15 fold increases in affinity. This suggests that proper structure guided dimerization is a tool for enhancing affinity of the therapeutic peptides. pBM-TRTK on the other hand binds to S100B with a K_d of about 300 nM, significantly tighter than pM-53 and pBM-53. When cross-linked through suitably placed cysteine residues (pBDC-TRTK), the dimeric peptide showed approximately an order of magnitude tighter binding. However, the yield of cysteine cross-linked reaction is generally low and hence we have attempted to create a bivalent peptide by synthesizing a branched peptide on solid-phase (pBBD-TRTK) (FIG. 1 (C)). The synthesis of the branched peptide in solid phase gave much superior yield and even higher affinity, thus making scale-up possible for in vivo work.

Binding data of the several of these peptides are shown in FIG. 2 (A) and some of the corresponding binding isotherms are shown FIG. 2(B-D). Of the two branched mimetics based on TRTK target sequence, pBBD-TRTK, has the highest affinity towards S100B with a dissociation constant of 7.7+3.5 nM. The selectivity of the bivalent peptide, pBBD-TRTK was demonstrated by approximately 7-fold weaker binding of pBBD-TRTK to S100P, the closest paralog of S100B (Marenholz et al., 2004). Also synthesized was a mutant branched peptide (pBBD-TRTK-AA) bearing two mutations in the interacting residues. This peptide binds to S100B with a K_d of 135±18.5 nM. This peptide will be used as a control in the cellular experiments to be described later.

The effect of all the synthesized peptides on several melanoma cell lines which are known to over-express S100B was investigated. The pBBDR-TRTK (pBBD-TRTK with six D-arginine residues as cell penetrating peptide in each branch at the N-terminal end) induces apoptosis at lowest concentrations among all the peptides and in all melanoma and glioma cell lines tested; henceforth results will be largely described using this molecule and pre-dominantly on SK-MEL5 cells, unless specifically mentioned otherwise. FIG. 3 shows the change of appearance of SK-Mel-5 at 10 μM concentration of the p-BBDR-TRTK. The cells change shape within a few minutes after addition of pBBDR-TRTK and shows typical apoptotic changes, such as blebbing within 1 hr. pBBDR-TRTK enters the cell within a short period of time.

Specificity of the peptide was tested by using the previously described double mutant peptide pBBDR-TRTK-AA, which binds to S100B with about 20 fold lower affinities. This peptide, which is otherwise identical to pBBDR-TRTK, does not show any apoptotic effect at 20 microM, even at 18 hrs. pBBD-TRTK, which lacks the cell penetration tag, shows no apoptotic effect on SK-MEL5 cell line, suggesting that the effect of pBBDR-TRTK is due to specific inhibition of intracellular S100B.

The effect of pBBDR-TRTK on viability was also measured by ³H thymidine uptake (FIG. 4 (A)). The measured IC₅₀ by this method was less than 2 μM. The apoptosis of SK-Mel5 cells was quantitated using flow cytometry. 49% of cells were determined to be apoptotic and 11% necrotic at 2 hrs using annexin V stain. Corresponding figures for 6 hrs were 57% and 14%, respectively (FIG. 4(B)). From the results presented here and analysis of growth promoting pathways described later-S100B appears to be a generalized growth promoter, when over-expressed.

Treatment with pBBDR-TRTK causes cells to quickly become round. Attempts were made to find out whether this involved reorganization of actin cytoskeleton. Phalloidin staining was used to observe the actin fibers (FIG. 5(A)). The cells looked elongated in the beginning with distinct fibers of actin visible upon phalloidin staining. Upon treatment with pBBDR-TRTK, the cells changed shape within 30 minutes and the actin fibers reorganized. The massive reorganization of actin fibers was accompanied by cell shape change followed by signs of typical apoptotic changes such as blebbing. Apoptotic nature of cell death was confirmed by release of cytochrome C from mitochondria (FIG. 5(B).

Given the rapidity of apoptosis initiation, the examination of the recently reported direct mitochondrial translocation pathway was also done by the method if Vaseva and Moll, 2009. It has been reported that a small molecule pifithrin-micro blocks this pathway without affecting the canonical transcription-dependent pathway of p53 initiated apoptosis and a close analog, pifithrin-α blocks the canonical pathway without affecting the direct mitochondrial pathway (Strom et al., 2006). In these experiments, pBDCR-TRTK (pBDC-TRTK with DR₆ tags at two branches) was used which was nearly as potent as pBBDR-TRTK. FIG. 6 (A) shows the effect of pifithrin-μ on the apoptosis induced by p-BDCR-TRTK. Interestingly in the presence of pifithrin-μ the cells change shape very quickly, but blebbings are not seen, whereas in its absence both shape change and blebbings are seen, indicating initiation of apoptosis. The direct translocation of p53 to mitochondria was also verified by confocal microscopy (FIG. 6(B)). Thus, early shape change of the cells involving actin cytoskeleton may be a p53 independent effect, hypothetically as a result of direct role of S100B on actin cytoskeleton.

The effect of pBBDR-TRTK was tested in a syngenic mouse model of melanoma. pBBDR-TRTK was found to be non-lethal and showed no demonstrable toxicity upto a tested concentration of 50 mg/Kg body weight. Histopathology of some key target organs after 8 days of treatment was normal, indicating no significant toxicity. At this dose level the tumor growth was completely inhibited up to 8 days (maximum tested) (FIG. 7 (A)). Histopathology of tumor sections, when compared to untreated tumors, showed large areas devoid of live cells (FIG. 7(B)) Immuno-histochemistry of growth marker PCNA indicates complete loss of this antigen in the residual tumor mass upon treatment, indicating complete loss of proliferating cells (FIG. 7(C)).

The significance of this invention relates to the possibility that peptides may be better therapeutic molecules than small molecules for certain class of targets. The small molecules today are the mainstay of drug discovery research and as tools of chemical genetics. However, they have deficiency as protein-protein interaction inhibitors, a new class of drug targets. Peptides are thought to have superior specificity as protein-protein interaction inhibitors, but suffer from disadvantages. Constrained secondary structure mimetics are potential drugs but may not have high affinity when the parent protein-protein interactions are weak. In this study, we have shown that designed construction of bivalent helix mimetic against a dimeric protein, S100B, is an effective way to increase the affinity. The specificity of the bivalent mimetic is high as it is able to discriminate against a close paralog. When this molecule is directed inside the cell by attachment to a cell penetrating peptide, it specifically induces rapid apoptosis in cancer cells that over-express S100B. The invented molecule is shown to be effective against implanted melanoma in a mouse model of tumor.

EXAMPLES

The following examples are given by way of illustration and therefore should not be construed to limit the scope of the present invention.

Example 1

Synthesis and Purification of Bivalent Helically Branched Peptide

The bivalent helically branched peptide of TRTK-12, from the actin capping protein CapZ of residues 265-276: TRTKIDWNKILS (Weber. et, al 2002) with Aib substituted at N8 and S12 was synthesized on 0.3 mmol scale by using a solid-phase peptide synthesis strategy using 9-fluorenylmethoxy carbonyl chemistry, amino acid/HCTU/DIPEA in the ratio 1:1:2, dry mixed solvent DMF/NMP in the ratio 3:2 and rink amide pega resin (Novabiochem) in (PS3, Protein Technologies Inc.). Capping of the undesired coupled product and the desired uncoupled amino acid was performed essentialy after each coupling by using acetic anhydride and lutidine as base (200 μl acetic anhydride, 300 μl lutidine mixed with 5 ml DMF and coupled for 10 minutes in each capping procedure). First fmoc-lys(fmoc)-OH is attached with the resin mentioned above then both the 9-fluorenylmethoxy carbonyl is cleaved using 20% piperidene in DMF then fmoc ε-aminohexanoic acid is attached with it followed by fmoc-lys(boc)-OH and finally Aib substituted 12 mer TRTK peptide is attached with it using same protocol. Cleavage of the peptide from rink amide pega resin (Novabiochem) and removal of all the side chainprotecting groups were achieved in 87.5% trifluoroacetic acid solution containing 2.5% TIS, 5% EDT and 5% phenol.

Purification of the Bivalent Helically Branched Peptide

The crude peptide was purified by reversed-phase high performance liquid chromatography (Waters Associates) with a water reversed-phase C18 column (micro Bondapac) with linear gradients of Water/acetonitrile containing 0.1% trifluoroacetic acid. Peptide masses and purity were checked by positive ion mode electrospray ionization mass spectrometry (Waters Inc.) and MALDI-TOF mass spectrometry.

Peptide Labelling

The bivalent helically branched peptide was labeled with 5(6)-carboxy Fluorescein in solid phase at both the N-termini Dry resin bound N-terminal deprotected peptide (3 μmol) was taken in a 2 ml polypropylene syringe and reacted with 10 times molar excess of 5(6)-carboxy Fluorescein and HOBT (1:1) in DMF mixed with 2-4 μl of DIPC. The reaction was incubated for 4-6 hours in dark at 25° C. After completion of the reaction, the resin was washed thoroughly with 20% piperidene solution in DMF until the washed solution becomes colorless. Resin was then washed consecutively with DMF and finally with diethyl ether for five times and then dried under nitrogen atmosphere. After labeling, peptide was cleaved using the same protocol as mentioned above and purified by HPLC, which was monitored at 490 nm wave length and Masses were checked by Mass Spectrometry.

Since S100B is a dimer, one possible way to enhance the binding is to synthesize a bivalent molecule, which can simultaneously bind to two subunits. pBM-53 was dimerized with a properly designed cross-linker through inserted cysteine residues (pBDC-53).

The cross linker used was BMH (1,6-bismalimeido hexane) which has the carbon-carbon covalent bond distance near about 16.5° A and attached with the sulphur of cysteine of both the limbs of the peptide. The structure of BMH is as follows

Example 2

Animal Studies: The Invented Molecule was Shown to be Effective Against Implanted Melanoma in a Mouse Model of Tumor

Experiments were carried out under protocols approved by the Institutional Animal Ethics Committee and institutional guidelines for the proper use of animals in research were followed. National guidelines had been followed. C57BL/6J female mice (mean initial weight, 20 g) were kept in one mice in one cage at 19° C. to 23° C. with a 12 hour light/12 hour dark cycle. They had free access to water and food. To generate tumor, 1×10⁶ B16F10 cells were mixed with Matrigel (BD bioscience) and inoculated S.C. in the right flank of 6 week-old mice. Tumors (typically 2 mm in diameter) were palpable 5 days after subcutaneous injection. Peptide treatments (50 mg/kg body weight) were administered by intravenous tail vein injection on the day tumors became apparent (day 0) and then days 1, 2, 3, 4, 5, 6 and 7. Control mice were treated only with saline vehicle. Mice were weighted, and tumor volumes were calculated with the following formula: π/6× larger diameter×(smaller diameter)² The tumor sections after only one treatment of pBBDR-TRTK was stained for p53, which exhibited significant enhancement in contrast to a control tumor section (FIG. 8).

Example 3

Branched Peptides Synthesis and Purification

The branched peptide pBBDR-TRTK having the sequence DR₆ TRTKIDWAibKILAibKAhxKAhxKAibLIKAibWDIKTRT-^DR₆ [SEQ ID No. 4-Lysine-SEQ ID No. 4] and its mutant peptide pBBD-TRTK-AA having the sequence TRTKADAAibKILAibKAhxKAhxKAibLIKAibADAKTRT-(I5A,W7A) [SEQ ID No. 5-Lysine-SEQ ID No. 5] along with their hexa-arginine tagged variety were synthesized on a PS3 Protein Technologies peptide synthesizer at 0.3 mmol scale by using a solid-phase peptide synthesis strategy using 9-fluorenylmethoxy carbonyl chemistry and Rink amide PEGA, resin. The branching of the peptide starts from α-NH₂ as well as δ-NH₂ group of (fmoc)Lys(Fmoc) and the linker ε-Aminohexanoic acid to maintain the distance 30A. Cleavage of the peptides from Rink amide PEGA resin and removal of all side chain-protecting groups were achieved in 87.5% trifluoroacetic acid, 2.5% water, 2.5% 1,2-ethanedithiol and 2.5% triisopropylsilan solution 2.5% water. The crude peptides were purified by reversed-phase high-performance liquid chromatography (Waters Associates) with a C₁₈ column (Hypersil gold, Thermo Fisher) with linear gradients of water/acetonitrile containing 0.1% trifluoroacetic acid. Peptides masses and purity (>95%) were checked by ESI (Waters Inc,) and MAIDI.

Peptides Labeling

The branched peptides and its mutant (I5, W7) along with their hexa-arginine tagged variety were labeled with 5,6-carboxy fluorescein in solid phase and cleaved as unlabeled peptides and purified by HPLC.

Testing of cytotoxic activity of bi-valent helically constrained peptides on cancer cell lines of different origin which are known to over-express S100B and peripheral blood mononuclear cells of normal individuals was carried out in vitro. The in vitro studies indicated that the bi-valent helically constrained peptides show preferential cytotoxicity towards cancer cell lines of different origin leaving normal human peripheral blood mononuclear cells unaffected. In vivo efficacy of bi-valent helically constrained peptide was evaluated on tumors of syngenic mouse model of melanoma. It was observed that the peptides when administered intravenously were effective in vivo in syngenic mouse by destroying the tumor. Treatment with the prepared peptides caused cells to quickly become round. The massive reorganization of actin fibers was accompanied by cell shape change followed by signs of typical apoptotic changes such as blebbing.

It was conclude that the bivalent helically constrained peptides described above induced the direct translocation of p53 to mitochondria, which is responsible for cancer cell killing.

The best peptide/peptidomimetic having therapeutic significance was observed to be pBBDR-TRTK (pBM-TRTK branched dimerised with a proper crosslinker and tagged with hexa-arginine) represented by SEQ ID No. 4-Lysine-SEQ ID No. 4 and having the following general formula:

Advantages

• • The present disclosure provides an effective therapeutic intervention and treatment of several types of tumor in which S100B a calcium binding protein is over-expressed.
  • These proliferative disorders include Melanoma, glioma and other types of cancers in which the wild-type p53 level is lowered.
  • The invention presented here demonstrated that certain designed peptide exhibit high efficacy of tumor cell killing with high degree of specificity in above mentioned cancers.

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Claims

1. A novel high affinity bivalent helically constrained peptide against cancer, wherein the said peptide is represented by SEQ ID No. 4-Lysine-SEQ ID No. 4 and having the following general formula:

2. A peptide as claimed in claim 1, wherein it has enhanced cell penetrability relative to the corresponding unmodified peptides represented by SEQ ID No. 3-Lysine-SEQ ID No. 3 and SEQ ID No. 5-Lysine-SEQ ID No. 5.

3. A peptide as claimed in claim 1, wherein it comprises of one or more helix stabilizing amino acids and two parallel helices.

4. A peptide as claimed in claim 1, useful for the treatment of human cancers having over-expression of S100B and/or down regulation of p53 including but not limited to melanoma, glioma and sarcoma.

5. A pharmaceutical composition comprising a therapeutically effective amount of the novel high affinity bivalent helically constrained peptide as claimed in claim 1 as an active ingredient optionally along with at least one pharmaceutically acceptable peptide stabilizer and excipients.

6. A composition as claimed in claim 5, further comprising at least one approved chemotherapeutic agent.

7. A composition as claimed in claim 5, wherein the said composition comprises 20% to 80% (w/w) of the bi-helical peptidomimetic represented by SEQ ID No. 4-Lysine-SEQ ID No. 4.

8. A composition as claimed in claim 5, wherein the said composition is formulated for oral, parental, subcutaneous, intravenous or intra-articular administration.

9. A composition as claimed in claim 5, wherein the said composition is administered in the dosage of approximately 50 mg/kg body weight per day for a period of 1 to 7 days.

10. A composition as claimed in claims 5 to 9, useful for the treatment of human cancers having over-expression of S100B and/or down regulation of p53 including but not limited to melanoma, glioma and sarcoma.

11. A composition as claimed in claims 5 to 9, wherein the said composition is useful for inducing rapid apoptosis within 1 to 6 hours in a group of cancers having wild-type p53 which is down-regulated by S100B.

12. Use of the composition as claimed in the claim 5 for the manufacture of a medicament for the treatment of S100B over-expressing and/or p53 under-expressing human cancers.

13. A method for the treatment of human cancers having over-expression of S100B and/or down-regulation of p53 comprising administering a therapeutically effective amount of the composition as claimed in claim 5 to a patient in need thereof.

14. A method as claimed in claim 13, wherein the composition is administered parenterally, subcutaneously, intravenously or intraarticularly.

15. A method as claimed in claim 13, wherein the composition is administered in a dosage of about 50 mg/kg body weight per day for a period of 1 to 7 days.

16. A method as claimed in claim 13, wherein the composition is administered in conjunction with a standard method of care including chemotherapy, radiation therapy and surgery.