1. Field of the Invention
The present invention relates to systems, compositions of matter, and techniques for the specific identification and tracking of genes and cells. In particular, the invention relates to positron emission tomography (PET) and single photon emission computed tomography (SPECT) reporter genes and reporter probe systems.
2. Description of Related Art
Gene and cell-based therapies hold great promise in oncology and many other areas of medicine. In such technologies, targeted therapeutic cells (TCs) or therapeutic transgenes (TGs) can be injected into patients to restore normal organ function in degenerative diseases, eliminate cancer cells, or correct a system malfunction in other diseases. In such contexts, the selection of appropriate cells, optimization of the cells (e.g., in vitro genetic engineering) to perform a specific therapeutic function, and determination of an appropriate administration route and cell dose are necessary to achieve the desired cell therapeutic effect. Similarly, identifying the appropriate transgenes and determining an optimal delivery of the transgenes to target tissues are necessary to achieve the desired gene therapeutic effect. However, achieving these objectives remains a major challenge. Despite decades of research in gene- and cell-based therapies, there are currently no approved products for routine oncological applications in the United States.
A formidable roadblock in this technology is an inability to routinely monitor the tissue pharmacokinetics (PK) of therapeutic genes and cells and correlate this information with therapeutic outcomes. Most cell/gene therapy trials use invasive biopsy techniques to localize TGs or TCs at target sites. This is a significant problem since tissue biopsies are prone to sampling errors, cannot reveal either whole body therapeutic gene or cell distribution at any one time or alterations in distribution with time. Moreover, biopsies are invasive procedures that may put patients at risk. Inappropriate administration of TCs or TGs based on incomplete and/or unreliable tissue PK data may not yield good treatment efficacy and may lead to severe adverse effects, up to and including lethality (see, e.g. Morgan, R. A., et al. Molecular Therapy (2010) 18 4, 843-851). Thus there is an unmet need for techniques to monitor the whole-body tissue distribution of TCs and TGs—to quantify TCs and to measure TG expression at all locations, non-invasively and sequentially following treatment.
Unmet needs in this technology are reflected, for example, in the hurdles encountered in clinical trials of Adoptive Cellular Gene Therapy (ACGT) against melanoma. ACGT is a cancer immunotherapy technique under evaluation in multiple FDA-approved clinical trials. In ACGT, billions of patient-derived T cell receptor (TCR) transgenic cytotoxic T lymphocytes (CTLs) generated ex vivo are transplanted back into the patient (the immunological term for T cell transplantation is “adoptive transfer”). Adoptively transferred T cells proliferate, seek out and kill tumor cells (see, e.g. Rosenberg, S. A., et al. Nat Rev Cancer 8:299-308, 2008; FIG. 2A). Building on the pioneering work by Rosenberg and colleagues (see, e.g. Rosenberg, S. A., et al. N Engl J Med 359:1072, 2008), studies have shown that ACGT induces partial responses in patients with advanced melanoma. Unfortunately, these responses are not sustained and most patients relapsed within 6 months.
An alternative to biopsies is a non-invasive, repeated, quantifiable imaging of therapeutic genes and cells throughout the bodies of living subjects. One such alternative is the use of PET reporter gene (PRG) imaging, which provides a possible solution to the tissue PK measurements problem affecting gene and cell-based therapies. A PRG encodes a protein that mediates the specific cellular accumulation of a PET reporter probe (PRP) labeled with a positron-emitting isotope. Several types of PET reporter gene/probe (PRG-PRP) systems have been developed (see, e.g.
In a typical PET/SPECT reporter gene embodiment, a foreign gene is introduced into cells of interest; the activity of the reporter gene leads to preferential cellular accumulation of a radioactive probe. Cells engineered to express the PET/SPECT reporter gene are in this way “tagged” and their presence can be detected and quantified at various locations within the body using PET or SPECT. Alternatively, PET/SPECT reporter gene systems can be used to study gene expression in vivo. This is accomplished by placing the reporter gene downstream from a promoter or regulatory region of interest. While numerous PET/SPECT reporter gene systems have been described in recent years, most of them are based on one of the following mechanisms: (i) enzymatic modification of the PET/SPECT probe followed by intracellular trapping; (ii) accumulation via plasma membrane transport mechanisms; and, (iii), cell surface receptor mapping using radioactive ligands or monoclonal antibody fragments. A brief summary of conventional PET reporter gene systems and probes is presented in
Various molecular imaging groups have worked to develop PRG-PRP techniques for non-invasively, repeatedly and quantitatively measuring gene expression in living animals. One of the first studies developed Dopamine type 2 receptor (D2R) as a PRG, and 3-(2′[18F]fluoroethyl)spiperone (FESP)—a ligand that binds to the D2R—as the PRP (see, e.g.
Herpes Simplex Virus type 1 thymidine kinase (HSV1-tk) has also been developed as a catalytic PRG and 18F-labeled fluoroganciclovir (FGCV) as a PRP (see, e.g. Gambhir, S. S., et al. J Nucl Med 39:2003-2011, 1998). Similar studies are known in the art (see, e.g. Tjuvajev, J. G., et al. Cancer Res 58:4333-4341, 1998). To increase sensitivity, researchers searched for “second generation” HSV1-tk reporter genes that utilized acycloguanosines more effectively, and thymidine (the “natural” substrate) less effectively, and identified HSV1-sr39tk as a substantially more sensitive PRG (see, e.g. Gambhir, S. S., et al. Proc Natl Acad Sci USA 97:2785-2790, 2000). To improve the PRG-PRP system further, researchers tested a series of 18F-labelled acycloguanosines and determined their relative efficacies as PRPs with HSV1-sr39tk (see, e.g. Min, J. J., et al. Eur J Nucl Med Mol Imaging 30:1547-1560, 2003; Yaghoubi, S., et al. J Nucl Med 42:1225-1234, 2001). 9-[(4-[18F]fluoro-3-hydroxymethylbutyl)guanine (FHBG) was identified in these studies. Human FHBG PK and dosimetry studies have been conducted in preparation for clinical trials (see, e.g. Yaghoubi, S., et al. J Nucl Med 42:1225-1234, 2001), to participate in comparative quantification of the D2R80A and HSV1-sr39tk reporter systems (see, e.g. Yaghoubi, S. S., et al. Gene Ther 8:1072-1080, 2001), and to use FHBG to monitor the progress of HSV1-sr39tk/ganciclovir suicide gene therapy in cancer (see, e.g. Yaghoubi, S. S., et al. Cancer Gene Ther 12:329-339, 2005). The development of “second generation” PRG-PRPs for the HSV1-tk and D2R systems demonstrates an early and continued commitment to optimizing PRG-PRP pairings, for experimental and clinical applications.
The HSV1-sr39tk/FHBG system is the current standard of comparison in evaluating new PRG-PRP combinations. The gold standard for PRG imaging is the viral HSV1-tk and sr39tk, its optimized analog (see, e.g. Min, J. J., et al. Handb Exp Pharmacol, 277-303, 2008). The advantages of HSV1-tk over other PRGs are its high sensitivity and dual function as a suicide/safety gene. However, its main disadvantage is immunogenicity, due to the very low sequence homology (˜10%, see, e.g. Eriksson, S., et al. Cell Mol Life Sci 59, 1327-1346, 2002) between the viral protein and human nucleoside kinases.
One solution to the immunogenicity problem is to replace the viral PRG with human PRGs. Several human-gene derived PRGs have been investigated including D2R (see, e.g. Liang, Q., et al. Gene Ther 8:1490-1498, 2001), human somatostatin receptor 2 (hSSR2) (see, e.g. Rogers, B. E., et al. J Nucl Med 46:1889-1897, 2005), sodium-iodide symporter (NIS) (see, e.g. Che, J., et al. Mol Imaging 4:128-136, 2005), human norepinephrine transporter (hNET) (see, e.g. Buursma, A. R., et al. J Nucl Med 46:2068-2075, 2005; Moroz, M. A., et al. J Nucl Med 48:827-836, 2007), truncated human thymidine kinase 2 (hTK2) (see, e.g. Ponomarev, V., et al. J Nucl Med 48:819-826, 2007), and human deoxycytidine kinase (dCK) (see, e.g. Likar, Y., et al. J Nucl Med 51:1395-1403, 2010). Since direct comparisons are lacking, it is not known how hSSR2, D2R, and NIS compare to HSV1-sr39tk. The un-mutated hTK2 PRG is significantly less sensitive than sr39tk (see, e.g. Ponomarev, V., et al. J Nucl Med 48:819-826, 2007). hNET has comparable or slightly lower sensitivity than HSV1-tk, with both PRGs enabling detection by microPET of as few as 104 CTLs injected into tumor xenografts (see, e.g. Doubrovin, M. M., et al. Cancer Res 67:11959-11969, 2007). However, using the hNET/[124I]MIBG system for clinical imaging may require the development of 18F-labeled probes, since 124I has a long half-life and patients may be exposed to high doses of radiation.
For the reasons noted above, there is a need in the art for novel PET reporter gene/reporter probe systems. Embodiments of the invention disclosed herein meet this as well as other needs.
Embodiments of the present invention provide systems, materials, and methods for non-invasive imaging of gene expression. Embodiments of the invention can be used, for example, in monitoring the kinetics of therapeutic genes and cells in vivo using positron emission tomography (PET) or single photon emission computed tomography (SPECT). Such PET technologies are useful in quantitative, non-invasive molecular imaging, a methodological approach the applicable in a variety of preclinical and clinical settings. Illustrative embodiments of the invention include a highly sensitive, non-immunogenic reporter gene that can function with a set of novel, radiolabeled probes in whole body molecular imaging applications using positron emission tomography or single photon emission computed tomography.
Embodiments of the invention have a variety of applications. For example, embedding PET reporter gene imaging in clinical trials of cell and gene therapies can be used to prevent “blinded” attempts to optimize these therapies. Embodiments of the invention also provide the means to detect the occurrence of adverse physiological phenomena, such as malignant transformation of cells and autoimmune-mediated destruction of normal tissues. The PET reporter gene (PRG) based imaging kits described herein further have the benefit of encouraging those of skill in cellular and gene therapy technologies to apply long-term non-invasive molecular imaging to pharmacokinetic studies.
As discussed below, embodiments of the invention disclosed herein can addresses key limitations of current PRG technologies. In particular, instead of the commonly used highly immunogenic viral proteins of conventional PRGs, a number novel PET reporters based on fully human proteins are disclosed herein. The use of human genes in embodiments of the invention significantly reduces the probability of patients developing immunity against therapeutic cells (and other delivery systems) engineered to express PRGs, one of the most significant challenges to the clinical implementation of current PRGs. The disclosure further describes the effect of reporter gene expression on nucleotide pools.
In typical embodiments of the invention, a PET/SPECT reporter gene uses an enhanced version of human mitochondrial thymidine kinase 2 (htk2) expressed in cytoplasm to preferentially trap novel PET/SPECT radiolabeled L and D-enantiomer analogs of thymidine, a natural substrate. Endogenous hTK2 enzyme provides the first phosphorylation step in the salvage pathway of deoxyribonucleosides. In one exemplary embodiment, the enhanced htk2 is not immunogenic in humans. In addition, the enhanced htk2 reporter gene can serve as a safety gene to destroy cells expressing it when they malfunction. A method is also provided for mutating the htk2 gene to enhance the catalytic activity of its enzyme product for the phosphorylation of several thymidine analogs or to decrease the catalytic activity of its enzyme product for the phosphorylation of D-enantiomer thymidine.
The invention disclosed herein has a number of embodiments. One embodiment of the invention comprises a human thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, wherein the thymidine kinase polypeptide comprises an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1. In typical embodiment, the thymidine kinase polypeptide is designed or selected to exhibit a certain functional activity, for example a decreased susceptibility to thymidine triphosphate mediated feedback inhibition as compared to wild type polypeptide shown in SEQ ID NO: 1, an ability to phosphorylate 2′-deoxy-2′-18F-5-methyl-1-β-L-arabinofuranosyluracil, or the like. In typical embodiments of the invention, the thymidine kinase polypeptide does not include the first 50 amino acids of SEQ ID NO: 1 and comprises an amino acid substitution at amino acid residue position 93 of SEQ ID NO: 1 (e.g. N93D) and an amino acid substitution at amino acid residue position 109 of SEQ ID NO: 1 (e.g. L109M or L109F). Optionally, the polypeptide comprises a set of amino acid mutations such as a polypeptide huΔ1-50TK2-N93D/L109M (see, e.g. the embodiments of huTK2 shown in
Other embodiments of the invention include a nucleic acid molecule comprising DNA encoding a human thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1. Typically in these embodiments, the thymidine kinase polypeptide comprises an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1. Such polypeptides can be designed/selected to exhibit a specific activity, for example an ability to phosphorylate and trap a reporter probe Embodiments of the invention include vectors comprising these nucleic acid molecules. Typically the human thymidine kinase 2 polynucleotide sequence is operably linked to control sequences (e.g. a promoter, an enhancer or the like) that is recognized by a host cell transfected with the vector. Embodiments of the invention also include a host cell transfected with the vector.
Yet another embodiment of the invention is a system for imaging a mammalian cell using positron emission tomography (PET) or single photon emission computed tomography (SPECT), the system comprising a PET reporter gene and a PET reporter probe. In this embodiment, the PET reporter gene encodes a human thymidine kinase such a human thymidine kinase 2 polypeptide (Uniprot ID O00142) and the PET reporter probe comprises a non-naturally occurring analog of thymidine. In this system, the polypeptide encoded by the PET reporter gene is selected for an ability to phosphorylate the non-naturally occurring analog of thymidine. In certain embodiments of this system, the PET reporter gene encodes a thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, wherein the thymidine kinase polypeptide comprises a deletion mutation or a substitution mutation that confers a decreased susceptibility to thymidine triphosphate mediated feedback inhibition as compared to wild type polypeptide shown in SEQ ID NO: 1. In typical embodiment of the invention, the PET reporter gene encodes a thymidine kinase polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, and further comprises at least one insertion, substitution or deletion mutation in SEQ ID NO: 1. Optionally, for example, the thymidine kinase polypeptide comprises an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1 (e.g. N93D/L109M or N93D/L109F).
Optionally in the system embodiments of the invention, the PET reporter probe is selected from the group consisting of: L-[18F]FMAU, L-[18F]FEAU, L-[18F]FBrVAU, L-[18F]FBU, D-[18F]FMAU, D-[18F]FEAU, D-[18F]FBrVAU, D-[18F]FCU, [18F]FHBG, FFU and FddUrd. In certain embodiments of the invention, the PET reporter probe and/or the PET reporter gene is combined with a pharmaceutically acceptable carrier. In some embodiments, the system is disposed in a kit, the kit comprising a first container comprising a vector that comprises the PET reporter gene, wherein the PET reporter gene is covalently coupled to vector control sequences recognized by a host cell transformed with the vector; and a second container comprising the PET reporter probe.
Yet another embodiment of the invention is a method of imaging a mammalian cell using positron emission tomography (PET) or single photon emission computed tomography (SPECT). In typical embodiments, the method comprise the steps of introducing a reporter gene into a mammalian cell, the reporter gene encoding a thymidine kinase polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, introducing a reporter probe comprising a non-naturally occurring analog of thymidine, wherein the thymidine kinase polypeptide encoded by the reporter gene is able to phosphorylate the non-naturally occurring analog of thymidine, and then detecting the reporter probe using positron emission tomography (PET) or single photon emission computed tomography (SPECT). In certain embodiments of the invention, the thymidine kinase polypeptide consists essentially of amino acid residues 51-265 of SEQ ID NO: 1 and further comprises at least one amino acid substitution at amino acid residue position 93 or amino acid residue position 109 of SEQ ID NO: 1 (e.g. N93D, L109M or L109F). In certain embodiments, the thymidine kinase polypeptide comprises a set of amino acid mutations comprising huΔ1-50TK2 and N93D/L109M or N93D/L109F. In typical embodiments, the reporter gene is introduced to the mammalian cell by transfecting the mammalian cell with a vector comprising a nucleic acid molecule encoding the thymidine kinase polypeptide and wherein the vector is operably linked to control sequences recognized by the mammalian cell transfected with the vector. Optionally in such methods, the reporter probe is selected from the group consisting of: L-[18F]FMAU, L-[18F]FEAU, L-[18F]FBrVAU, L-[18F]FBU, D-[18F]FMAU, D-[18F]FEAU, D-[18F]FBrVAU, D-[18F]FCU, [18F]FHBG, FFU and FddUrd.
In other embodiments of the invention, enhanced hTK2 PET/SPECT reporter transgenes are delivered into cells of interest ex vivo, using viral vectors or non-viral techniques. In one exemplary embodiment, the delivery method leads to permanent presence of the enhanced htk2 transgenes within the nucleous of the cells. Then the cells of interest overexpressing the enhanced htk2 reporter genes are transplanted through an appropriate route into a living organism where they can be visualized at any time point after administration with a PET or SPECT probes that can detect the expression of the enhanced htk2 reporter genes. The invention also has applications in gene therapy and general biomedical research in discovering intracellular events and analysis of the mechanisms of actions of therapeutic agents.
Other objects, features and advantages of the present invention will become apparent to those skilled in the art from the following detailed description. It is to be understood, however, that the detailed description and specific examples, while indicating some embodiments of the present invention are given by way of illustration and not limitation. Many changes and modifications within the scope of the present invention may be made without departing from the spirit thereof, and the invention includes all such modifications.
Unless otherwise defined, all terms of art, notations and other scientific terms or terminology used herein are intended to have the meanings commonly understood by those of skill in the art to which this invention pertains. In some cases, terms with commonly understood meanings are defined herein for clarity and/or for ready reference, and the inclusion of such definitions herein should not necessarily be construed to represent a substantial difference over what is generally understood in the art.
As described herein, “gene therapy” involves all forms of administering a therapeutic transgene, for example, viral vectors, naked DNA, liposomes, nanoparticles, and cells. The term “TG” (therapeutic genes) is used to refer to all forms of transgenes that are delivered to achieve a therapeutic outcome. The term “TC” (therapeutic cells) is used to indicate cells that are delivered to achieve a therapeutic outcome. TC may be genetically engineered to express a transgene to achieve its desired therapeutic effect or may have its own endogenous therapeutic mechanism.
Gene expression is defined herein as transcription of a gene into its messenger RNA (mRNA) and/or translation of its mRNA into protein. Monitoring the kinetics of a gene is defined herein as detecting the presence and locations of its expression and/or the magnitude of its expression in living mammals. Monitoring the kinetics of a cell is defined herein as detecting its presence or location, determining its survival, measuring its proliferation, and/or tracking changes in its characteristics over time in a living mammal.
Gene and cell-based therapies may overcome the limitations of conventional treatments for many types of diseases including but not limited to cancer and autoimmune, cardiovascular and neurological disorders. Therefore their market share is projected to grow significantly in the near future (
Positron emission tomography (PET) reporter gene imaging can be used to non-invasively monitor cell-based therapies. Therapeutic cells engineered to express a PET reporter gene (PRG) specifically accumulate a PET reporter probe (PRP) and can be detected by PET imaging. Expanding the utility of this technology requires the development of new non-immunogenic PRGs. In one embodiment of the present invention, a PRG-PRP system is provided that employs, as the PRG, a mutated form of human thymidine kinase 2 (TK2) and 2′-deoxy-2′-18F-5-methyl-1-O-L-arabinofuranosyluracil (L-18F-FMAU) as the PRP. In one embodiment, a TK2 double mutant (TK2-N93D/L109F) is provided that efficiently phosphorylates L-18F-FMAU. The N93D/L109F TK2 mutant has lower activity for the endogenous nucleosides thymidine and deoxycytidine than wild type TK2, and its ectopic expression in therapeutic cells is not expected to alter nucleotide metabolism. Imaging studies in mice indicate that the sensitivity of the new human TK2-N93D/L109F PRG is comparable with that of a widely used PRG based on the herpes simplex virus 1 thymidine kinase.
Development of PET reporter gene systems is a highly dynamic and innovative field in molecular imaging. The development of the hTK2-N93D PRG provided herein, started with an innovative concept wherein development of a new catalytic PET reporter system should not start with the PRG component, but rather with the identification of candidate PRPs. Only after the identification of optimal PRPs, should PRGs be engineered to provide maximal sensitivity and specificity. Specifically, PRPs should satisfy two criteria: (i) the probe should be amenable to routine 18F labeling, and (ii) the probe should demonstrate a high specific signal-to-background ratio. Furthermore, following injection, the candidate PRP should have access to the tissues but should also be rapidly cleared if the PRG is not expressed (i.e., the PRP should accumulate rapidly and specifically only in cells and tissues genetically engineered to express the PRG).
Embodiments of the present invention include a PET/SPECT reporter gene system that uses an enhanced version of human mitochondrial thymidine kinase 2 (htk2) expressed in cytoplasm to preferentially trap PET/SPECT radiolabeled L and D-enantiomer analogs of the natural substrate thymidine. In addition, the enhanced htk2 reporter gene can serve as a safety gene to destroy cells expressing it when they malfunction. Endogenous hTK2 enzyme provides the first phosphorylation step in the salvage pathway of deoxyribonucleosides. A method is also provided for mutating the htk2 gene to enhance the catalytic activity of its enzyme product for phosphorylation of several thymidine analogs.
The invention disclosed herein has a number of embodiments. One embodiment is a human thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, wherein the thymidine kinase polypeptide comprises an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1. In typical embodiments, the thymidine kinase polypeptide is selected for an ability to exhibit an activity as disclosed herein, for example an ability to phosphorylate and/or trap a non naturally occurring analog of thymidine such as 2′-deoxy-2′-18F-5-methyl-1-β-L-arabinofuranosyluracil. In certain embodiments of the invention, the thymidine kinase polypeptide does not include the first 50 amino acids of SEQ ID NO: 1 and comprises an amino acid substitution at amino acid residue position 93 of SEQ ID NO: 1 (e.g. N93D) and an amino acid substitution at amino acid residue position 109 of SEQ ID NO: 1 (e.g. L109M or L109F). Optionally, the polypeptide comprises a set of amino acid mutations such as a polypeptide huΔ1-50TK2-N93D/L109M (see, e.g.
Other embodiments of the invention include a nucleic acid molecule comprising DNA encoding a human thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1. Typically in these embodiments, the thymidine kinase polypeptide comprises a deletion such as huΔ1-50TK2, an insertion such as the N-terminal methionine in SEQ ID NO: 3 and 4, an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1 etc. In addition to these structural features, such polypeptides can also be selected to exhibit a specific activity, for example an ability to trap or phosphorylate a non naturally occurring analog of thymidine such as L-[18F]FMAU, L-[18F]FEAU, L-[18F]FBrVAU, L-[18F]FBU, D-[18F]FMAU, D-[18F]FEAU, D-[18F]FBrVAU, D-[18F]FCU, [18F]FHBG, FFU and FddUrd.
Embodiments of the invention include vectors comprising these nucleic acid molecules. A wide variety of vectors can be adapted for use with embodiments of the present invention. Illustrative viral vectors include, for example, adenovirus-based vectors (see, e.g. Cantwell (1996) Blood 88:4676 4683; and Ohashi (1997) Proc Natl Acad Sci USA 94:1287 1292), Epstein-Barr virus-based vectors (see, e.g. Mazda (1997) J Immunol Methods 204:143 151), adenovirus-associated virus vectors, Sindbis virus vectors (see, e.g. Strong (1997) Gene Ther 4:624 627), herpes simplex virus vectors (see, e.g. Kennedy (1997) Brain 120:1245 1259) and retroviral vectors (see, e.g. Schubert (1997) Curr Eye Res 16:656 662). Typically the human thymidine kinase 2 polynucleotide sequence is operably linked to control sequences in the vector (e.g. a promoter, an enhancer or the like) that is recognized by a host cell transfected with the vector. Optionally, for example, the human thymidine kinase 2 polynucleotide sequence is operably linked to tissue specific control sequences in a vector so that it is selectively expressed in cells of a specific tissue lineage. Embodiments of the invention also include a host cell transfected with the vector.
Embodiments of the invention also include compositions of matter that comprise a non naturally occurring analog of thymidine, for example an imaging compound disclosed herein. Illustrative compositions can comprise L-[18F]FMAU, L-[18F]FEAU, L-[18F]FBrVAU, L-[18F]FBU, D-[18F]FMAU, D-[18F]FEAU, D-[18F]FBrVAU, D-[18F]FCU, [18F]FHBG, FFU or FddUrd. In certain embodiments of the invention, the PET reporter probe is combined with a pharmaceutically acceptable carrier.
Yet another embodiment of the invention is a system for imaging a mammalian cell using positron emission tomography (PET) or single photon emission computed tomography (SPECT), the system comprising a PET reporter gene and a PET reporter probe. In this embodiment, the PET reporter gene encodes a human thymidine kinase such a human thymidine kinase 2 polypeptide (Uniprot ID O00142) and the PET reporter probe comprises a non-naturally occurring analog of thymidine. In such systems, the polypeptide encoded by the PET reporter gene is selected for an ability to phosphorylate a non-naturally occurring analog of thymidine. In certain embodiments of this system, the PET reporter gene encodes a thymidine kinase 2 polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, and further comprises a deletion mutation or a substitution mutation that confers a decreased susceptibility to thymidine triphosphate mediated feedback inhibition as compared to wild type SEQ ID NO: 1. In typical embodiment of the invention, the PET reporter gene encodes a thymidine kinase polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, and further comprises at least one insertion, substitution or deletion mutation in SEQ ID NO: 1. Optionally, for example, the thymidine kinase polypeptide comprises an amino acid substitution at amino acid residue position 93 and/or amino acid residue position 109 of SEQ ID NO: 1 (e.g. N93D/L109M or N93D/L 109F).
Optionally in the system embodiments of the invention, the PET reporter probe is selected from the group consisting of: L-[18F]FMAU, L-[18F]FEAU, L-[18F]FBrVAU, L-[18F]FBU, D-[18F]FMAU, D-[18F]FEAU, D-[18F]FBrVAU, D-[18F]FCU, [18F]FHBG, FFU and FddUrd. In certain embodiments of the invention, the PET reporter probe and/or the PET reporter gene is combined with a pharmaceutically acceptable carrier. The PET reporter probe and/or the PET reporter gene may be administered as a pharmaceutical composition in a variety of forms including, but not limited to, liquids, powders, suspensions, tablets, pills, capsules, sprays and aerosols. The pharmaceutical compositions may include various pharmaceutically acceptable additives including, but not limited to, carriers, excipients, binders, stabilizers, antimicrobial agents, antioxidants, diluents and/or supports. Examples of suitable excipients and carriers are described, for example, in “Remington's Pharmaceutical Sciences,” Mack Pub. Co.; 17th edition New Jersey (2011). Some suitable pharmaceutical carriers will be evident to a skilled worker and include, e.g., water (including sterile and/or deionized water), suitable buffers (such as PBS), physiological saline or the like. A pharmaceutical composition or kit of the invention can contain other pharmaceuticals, in addition to the compositions of the invention.
Another embodiment of the invention is a kit useful for any of the methods disclosed herein, either in vitro or in vivo. Such a kit can comprise one or more of the compositions of the invention. Optionally, the kits comprise instructions for performing the method. Optional elements of a kit of the invention include suitable buffers, pharmaceutically acceptable carriers, or the like, containers, or packaging materials. The reagents of the kit may be in containers in which the reagents are stable, e.g., in lyophilized form or stabilized liquids. The reagents may also be in single use form, e.g., in single dosage form. In some embodiments, a system as disclosed herein is disposed in a kit, the kit comprising a first container comprising a vector that comprises the PET reporter gene, wherein the PET reporter gene is covalently coupled to vector control sequences recognized by a host cell transformed with the vector; and a second container comprising the PET reporter probe.
Yet another embodiment of the invention is a method of imaging a mammalian cell using positron emission tomography (PET) or single photon emission computed tomography (SPECT). In typical embodiments, the method comprise the steps of introducing a reporter gene into a mammalian cell, the reporter gene encoding a thymidine kinase polypeptide comprising amino acid residues 51-265 of SEQ ID NO: 1, introducing a reporter probe comprising a non-naturally occurring analog of thymidine, wherein the thymidine kinase polypeptide encoded by the reporter gene is able to phosphorylate the non-naturally occurring analog of thymidine, and then detecting the reporter probe using positron emission tomography (PET) or single photon emission computed tomography (SPECT). In certain embodiments of the invention, the thymidine kinase polypeptide consists essentially of amino acid residues 51-265 of SEQ ID NO: 1 and further comprises at least one amino acid substitution at amino acid residue position 93 or amino acid residue position 109 of SEQ ID NO: 1 (e.g. N93D, L109M or L109F). Optionally the huTK polypeptide is fused to a heterologous amino acid sequence. In certain embodiments, the thymidine kinase polypeptide comprises a set of amino acid mutations comprising huΔ1-50TK2 and N93D/L109M or N93D/L109F (see, e.g. the embodiments of this polypeptide shown in
In certain embodiments of the present invention, four novel PET probes are also provided: 18F-FBU (3′-[18F]fluoro-2′,3′-dideoxy-5-bromouridine), 18F-FCU (3′-[18F]fluoro-2′,3′-dideoxy-5-chlorouridine), 18F-FddUrd (3′-[18F]fluoro-2′,3′-dideoxy-uridine), and 18F-FFU (3′-[18F]fluoro-2′,3′-dideoxy-5-fluorouridine). Their chemical structures are shown in
In some embodiments, the enhanced hTK2 PET/SPECT reporter transgenes are delivered into cells of interest ex vivo, using viral vectors or non-viral techniques. In an exemplary embodiment, the delivery method leads to permanent presence of the enhanced htk2 transgenes within the nucleous of the cells. Then the cells of interest overexpressing the enhanced htk2 reporter genes are transplanted through an appropriate route into a living organism where they can be visualized at any time point after administration with a PET or SPECT probes that can detect the expression of the enhanced htk2 reporter genes.
This invention provides several improvements over existing PET/SPECT reporter gene approaches. First, the PET/SPECT reporter genes are based on a human gene and thus are less likely to induce unwanted immune responses if used in human subjects. Second, the invention includes novel L-enantiomers of thymidine analogs that have improved pharmacokinetics, because as unnatural substrates of mammalian TK enzymes they have much less background accumulation; hence superior signal-to-noise ratio in vivo compared to existing probes.
The sensitivity of the described mutant htk2 imaging reporter genes can be evaluated through cell culture assays and PET imaging in mouse tumor models. The invention has been successfully tested in Baf-3 cells with [18F]L-FEAU and [18F]L-FMAU. Further tests regarding the effect of expressing these reporter genes on various cells can be used to determine other potential targets. The examples disclosed herein demonstrate the superior pharmacokinetics of the L-enantiomer PET probes provided herein. Several enhanced htk2 mutant reporter genes have been designed and tested. Though the examples herein describe different probes and investigate the L probes mainly in mice, other mammals and in particular, humans are also within the scope of the invention. Silico models can be used to derive additional enhanced mutants from human htk2.
Applications of the present invention include non-invasive, whole body PET/SPECT-based tracking of tumor cells and therapeutic cells, including but not limited to stem cells or multiple types of immune cells. The invention can be used to optimize therapeutic strategies in gene or cell therapy or can be used as a tool in biomedical research in immunocompetent animals. The technologies disclosed herein are generalizable to many types of gene and cell-based therapies for cancer, regenerative medicine (neurological, cardiovascular, hematological, endocrine), and infectious diseases such as AIDS. The non-immunogenic PET reporter systems disclosed herein can enable investigators to observe the activity and predict consequences of emerging gene and cell therapies, and can provide essential information to accelerate the development and effective clinical implementation of these therapies.
The new poorly-immunogenic human TK PRGs (as compared to viral TK polypeptides) disclosed herein can serve purposes beyond gene and cell therapy monitoring. In general, these PRGs can be used to image gene expression, therefore, they are also useful in imaging the regulation of endogenous genes, imaging gene expression in transgenic mice, imaging protein-protein interactions, imaging signal transduction, and many other applications that involve imaging gene expression. In addition, their ability to tag cells for kinetics monitoring makes them useful for applications beyond just monitoring pharmacokinetics of therapeutic cells. These PRGs can be used to monitor kinetics of almost any type of cell that has been genetically engineered to express them either in vitro or in vivo. For example, they can also be used to track metastasis of tumor cells or migration and proliferation of human immune cells, for diagnostic or investigational purposes. In another aspect of the present invention, end-user-ready PET Reporter Gene (PRG) delivery kits co-marketed with PET Reporter Probes (PRP) are provided that enable whole body PK and therapeutic outcome information.
Embodiments and aspects of the invention are disclosed in the following Examples.
PET Reporter Probe (PRG-PRP) Systems.
Embodiments of the invention include a new PRG comprising at least one point mutant (e.g. N93D) in the human thymidine kinase 2 (tk2) gene. L-[18F]FMAU and L-[18F]FEAU, two hTK2-N93D substrates, are the new PRPs for use with this PRG. One can evaluate L-[18F]FMAU and L-[18F]FEAU in vitro, in cell culture, and in vivo. One can also analyze the potential immunogenicity of the hTK2-N93D PRG, and, if necessary, one can design hTK2-N93D variants unable to elicit T cell-mediated immunity in humans.
1.1. Preliminary Data.
To identify candidate PRPs, eight nucleoside analogs (
1. The protein encoded by the PRG should not cause an immune response against therapeutic cells.
2. To reduce background, the endogenous homolog of the transgenic PRG should not be expressed in cells/tissues of interest. If the endogenous gene is expressed in cells/tissues of interest, it should be localized to a region of the cell that is less accessible to the [18F]-probe (e.g., mitochondria).
3. The engineered PRG should be amenable to delivery by viral or non-viral vectors.
4. The PRG should be biologically inert. Expression of the nucleoside kinase PRG should not alter cytosolic deoxyribonucleoside triphosphate (dNTP) pools, since this may result in genomic instability (see, e.g. Mathews, C.K. FASEB J 20:1300-1314, 2006) and impaired cell division (see, e.g. Reichard, P. Annu. Rev. Biochem. 57:349-374, 1988). This potential complication is often not considered adequately in developing PRG-PRP systems based on nucleoside kinases.
To identify candidate PRGs, the human nucleoside kinases: TK2, dGK, dCK and TK1 were considered (see Table 1 below). These kinases should lack immunogenicity (criterion 1 for PRGs), since they are expressed in human tissues (see, e.g. Amer, E. S., et al. Pharmacol Ther 67:155-186, 1995). As shown in Table 1, arguments can be constructed against and in favor of using any of these kinases as PRGs (see, e.g. Eriksson, S., et al. Cell Mol Life Sci 59, 1327-1346, 2002; Amer, E. S., et al. Pharmacol Ther 67, 155-186, 1995; Wang, J., et al. Biochemistry 38, 16993-16999, 1999; Liu, S. H., et al. Antimicrob Agents Chemother 42, 833-839, 1998; Wang, J., et al. Biochem Pharmacol 59, 1583-1588, 2000; Al-Madhoun, A. S., et al. Mini Rev Med Chem 4, 341-350, 2004; Wang, J., et al. Nucleosides Nucleotides 18, 807-810, 1999). It was reasoned that TK2 (which is normally expressed in the mitochondria—thus matching criterion 2 for PRGs) was the best choice. After truncating the sequence encoding the mitochondrial signal peptide (to target the PRG to the cytosol where it is directly accessible to the PRP), the TK2-based PRG is only 648 base pairs, an optimal size for viral and non-viral vectors (thus matching criterion 3 for PRGs). TK2 has a potential drawback: this kinase is regulated by thymidine triphosphate (dTTP) as part of a protective mechanism against imbalances in mitochondrial dNTP pools (see, e.g. Mikkelsen, N. E., et al. Biochemistry 42:5706-5712, 2003) Inhibition of a TK2-based PRG by dTTP could be problematic when imaging dividing therapeutic cells (e.g. intracellular dNTP pools in proliferating T cells are ˜30-foldhigher than resting lymphocytes (see, e.g. Cohen, A., et al. J Biol Chem 258:12334-12340, 1983) and such elevated levels are sufficient to inhibit TK2 activity, as shown in
To overcome the negative feedback limitation of TK2, a point mutation-N93D, was engineered. The work done by Piskur and colleagues on the structurally related Drosophila melanogaster deoxyribonucleoside kinase (see, e.g. Welin, M., et al. FEBS J 272:3733-3742, 2005) led one to predict that the N93D mutation would reduce the feedback inhibition of TK2 by dTTP. This prediction was confirmed by a comparison between the wild type (WT) and the TK2-N93D mutant in a kinase assay in which increasing concentrations of dTTP were added to inhibit TK2 enzymatic activity (
To compare TK2, TK2-N93D and HSV1-sr39tk in vivo, PRG-expressing L1210 cells were implanted subcutaneously in SCID mice that were then scanned with L-[18F]FMAU (
1.2.1. Compare L-[18F]FEAU and L-[18F]FMAU in the L1210 Tumor Model.
Although the L-[18F]FMAU preliminary data is promising, the second candidate PRP, L-[18F]FEAU was also investigated. The rationale to analyze L-[18F]FEAU is twofold: a) it is possible that TK2-N93D has a higher affinity for L-FEAU than for L-FMAU—if correct, then L-[18F]FEAU may be more sensitive; b) for a given PRP, the biodistribution pattern in mice may not predict its biodistribution in humans; it is thus conceivable that human biodistribution studies will reveal that L-[18F]FEAU is a better PRP than L-[18F]FMAU. In addition to the cell culture and in vivo studies described in Sect. 1.1 (
1.2.2. Evaluate the TK2-N93D/L-[18]FMAU and L-[18F]FEAU PRG Systems For Efficacy and Sensitivity Following Adenovirus PRG Vector Delivery to Mouse Liver.
The Ad-liver model described in Sect. 1.2.2. provides the means to rank various PRG-PRP combinations, before testing them in more elaborate hepatic metastases and melanoma targeting strategies. Adenovirus delivery of PRPs to the liver to evaluate PRP-PRG systems eliminates the heterogeneity of target size for PRG delivery encountered with tumors; it also eliminates heterogeneity in target vascularity (a confounding problem for both reporter and probe delivery), and minimizes differences in delivery of therapeutic genes. It is the most reproducible and quantifiable assay with the least number of biological variables. The amount of vector, PRG and target are quantifiable at the end. One can use Ad.CMV.HSV1sr39tk/FHBG as “reference”, and can construct viruses with the identical structure—with the exception that experimental PRGs can be substituted for sr39tk and experimental PRPs can be substituted for FHBG (see
1.2.3. Analyze the Potential Immunogenicity of the TK2-N93D PRG.
Although huTK2-N93D closely resembles the endogenous TK2 protein and will therefore be less immunogenic in humans than viral TK polypeptides, it cannot be assumed that this PRG completely lacks immunogenicity in humans. Not only the N93D mutation may render TK2-N93D immunogenic but also its overexpression may break immunological tolerance. The immunogenicity of an intracellular protein (such as TK2-N93D) is primarily determined by the presentation of short antigenic peptides on the cell surface in the context of Major Histocompatibility Complex (MHC) class I molecules and by the presence in the host immune repertoire of CD8+ T cells that express a T cell receptor (TCR) able to recognize the peptide-MHC class I complexes. Abolishing peptide-MHC presentation should eliminate the immunogenicity of any given protein. One can use in silico methods to determine the epitopes contained within the TK2-N93D PRG that can be presented by host MHC class I molecules. Several algorithms are available to obtain this information: SYFPEITHI (see, e.g. Rammensee, H., et al. Immunogenetics 50:213-219, 1999), NetMHC (see, e.g. Lundegaard, C., et al. Nucleic Acids Res 36:W509-512, 2008), NIH BIMAS (see, e.g. Parker, K. C., et al. J Immunol 152:163-175, 1994) and Rankpep (see, e.g. Reche, P. A., et al. Hum Immunol 63:701-709, 2002). One can use the consensus values obtained from these algorithms to identify all the potential HLA-A2-binding epitopes encoded by TK2-N93D. Given its predominance in humans, one focuses on the HLA-A2 allele; however, similar approaches are applicable to all human or mouse MHC haplotypes. A fluorescence-polarization assay (see, e.g. Bakker, A. H., et al. Proc Natl Acad Sci USA 105:3825-3830, 2008) can be used to validate the binding affinity for HLA-A2 of the in silico predicted binders. One can then design mutations in the identified TK2 encoded epitopes that can abolish their binding to HLA-A2 (and therefore eliminate the immunogenicity of TK2-N93D). The affinity of the mutants for L-[18F]FMAU and L-[18F]FEAU and their efficacy as PRGs in vivo in the Ad:liver model can be determined as described in Sect. 1.2.2.
The feasibility of this approach is supported by preliminary data. Most of the remaining steps to realize this goal involve either taking a second candidate probe (L-[18F]FEAU) through an identical validation algorithm as that described for L-[18F]FMAU or, as shown, for FHBG (in the adenovirus liver transduction model) (see, e.g. Garcia, K. C., et al. Proc Natl Acad Sci USA 98:6818-6823, 2001; Anderton, S. M., et al. J Exp Med 193:1-11, 2001; Radu, C. G., et al. Int Immunol 12:1553-1560, 2000; Radu, C. G., et al. J Immunol 160:5915-5921, 1998).
The best PRG-PRP candidates can be tested in a hepatic colorectal cancer (CRC) model (see, e.g. Li, H. J., et al. Cancer Res 69:554-564, 2009) to mimic a clinical application of viral vectors for tumor imaging and therapy. This can be carried out using a murine model of combined gene and cell immunotherapy against melanoma that is directly relevant to ongoing cancer immunotherapy clinical trials.
Investigating the sensitivity and specificity of the hTK2-N93D/L-[18F]FMAU and hTK2N93D/L-[18F]FEAU PRG-PRP Systems in Murine Models of Cancer Therapy.
The models one can use in such studies include (1) gene therapy of hepatic metastases of colorectal cancer and (2) T-cell immunotherapy of melanoma. These cancer therapy models are well established in laboratories and are used extensively in academia and industry.
One can use Ad vectors in which the sr39tk PRG and the experimental PRGs are driven by the human Cox2 promoter. Because COX-2 is expressed in CRCs and not expressed in liver (see, e.g. Fujita, T., et al. Cancer Res 58:4823-4826, 1998; Ishikawa, T. O., et al. Mol Imaging Biol 8:171-187, 2006), Cox2 “transcriptional restriction” results in an ˜24 fold difference in reporter gene expression in CRC metastases versus liver (see, e.g. Li, H. J., et al. Cancer Res 69:554-564, 2009). Human LS174T (rLuc) CRC cells (106) can be injected into the upper left liver lobe of nu/nu mice (see, e.g. Li, H. J., et al. Cancer Res 67:5354-5361, 2007). One can monitor tumor burden weekly by optical imaging (see, e.g. Liang, Q., et al. Mol Imaging Biol 6:385-394, 2004), using the rLuc substrate coelenterazine. Tumor burden is reproducible and easily measurable at three weeks (see, e.g. Li, H. J., et al. Cancer Res 69:554-564, 2009). At this time, groups of three mice can be injected with 108 Ad.Cox2HSVlsr39tk ifu, 108 experimental-PRG Ad ifu, 1010 Ad.Cox2HSVlsr39tk ifu or 1010 experimental-PRG Ad ifu. Three days later, mice can be injected with the appropriate PRP and imaged by microPET/CT. The following day mice can be imaged with [18F]FDG. [18F]PRP:[18F]FDG hepatic retention ratios can provide a non-invasive analysis of the sensitivity, and provide an indication of the dynamic range, of the experimental PRG-PRP system versus the HSVlsr39tk/FHBG system. After imaging, mice can be euthanized, and PRG enzyme activities in liver homogenates can be assayed. Adenovirus genomes, human genomes (to measure the tumor burden) and murine liver genomes (to normalize data) can be monitored by PCR (see, e.g. Li, H. J., et al. Cancer Res 69:554-564, 2009). These data will provide direct and quantitative comparisons of the sensitivity of experimental PRG-PRP systems in detecting colorectal cancer liver metastases. The data on relative efficacy and sensitivity of alternate PRG-PRP systems can be extrapolated to any PRG delivery system.
Evaluating New PRG-PRP Systems in a Murine Model of Combined Cell and Gene Therapy Against Melanoma.
The Pmel-1/B16 model (see, e.g. Overwijk, W. W., et al. J Exp Med 198:569-580, 2003) is extensively used by many groups working in the field of tumor immunology (see, e.g. Finkelstein, S. E., et al. J Leukoc Biol 76:333-337, 2004)). It closely resembles the ACGT clinical procedure shown in
2.3. Potential Caveats and Alternative Approaches.
Since Ad-CRC liver metastasis and melanoma cell-based immunotherapy animal models are routinely used in the laboratories, one does not anticipate any difficulties. It is possible however that data from these models will indicate that new PRG-PRP systems are less sensitive than the current HSV1-sr39tk/FHBG gold standard. Due to this possibility, one can collaborate with other laboratories to identify new TK2 mutants with improved catalytic activity towards L-FMAU and L-FEAU.
As yet another contingency plan, collaborative studies with the structure of nucleoside kinases have also been initiated. A number of new human TK2 mutants have been identified for improving the affinity and specificity for 18F-L-FMAU. The rationale behind the design of these new mutants was to improve the affinity of TK2 for L-nucleosides at the expense of the endogenous (natural) substrates that are in the D-nucleoside configuration. The new mutants suggested on both the wild type and N93D TK2 backbone have been generated. It has been found that one of the double mutants (TK2 N93D/L109F, referred to as “ΔTK2-DB” in
In embodiments of the invention, aspects of the technology can be translated as commercialized kits that can be used in labeling and long term cell-tracking PET studies. The products can be for preclinical animal model research; products can be disseminated for clinical use once they gain FDA approvals. ELIXYS™, an automated, modular radiochemistry platform can be obtained to produce and deliver L-[18F]FMAU and L-[18F]FEAU to other groups for use in preclinical therapeutic gene and cell tracking studies.
Develop, Validate, and Commercialize Kits for PRG Delivery into Murine and Human Therapeutic Cells and Disseminate this New Capability to Wider Communities of End-Users.
Kits can use both lentiviral and non-viral ΦC31 integrase technologies to obtain stable PRG expression. ELIXYS™, Sofie Biosciences'automated, modular radiochemistry platform that enables the synthesis of these probes with high yield and high specific activity, will be obtained to complement the kits with the L-[18F]FMAU or L-[18F]FEAU PRPs.
To take full advantage of PET reporter gene imaging technology, the PRG should be delivered such that it is stably expressed in the original and in all progeny cells, via chromosomal integration, following delivery. Given the risk of genotoxicity by random genomic integration of most viral gene delivery approaches, non-viral strategies are preferred for clinical applications. However, viral strategies are more robust and are still widely used in gene therapy (see, e.g. Chowdhury, E. H. Expert Opin Drug Deliv 6:697-703, 2009). One can incorporate the non-immunogenic PRGs developed in Examples 1 and 2 into viral and non-viral vectors, to create the essential components of Ready-To-Use kits for permanent labeling of TCs. This can be divided into three subaims:
Produce PRG Lentiviral Delivery Vectors.
Lentiviral vectors infect both dividing and non-dividing cells and integrate stably into the genome, favoring introns over exons (see, e.g. Pluta, K. et al. Acta Biochimica Polonica 56:531-595, 2009). Table 2 below describes a plan to develop lentivector-based PRG delivery kits (see, e.g. Pluta, K., et al. Acta Biochimica Polonica 56, 531-595, 2009; De, A., et al. Gene Therapy Protocols: Production and In Vivo Applications of Gene Transfer Vectors, Vol. 1 (ed. Le Doux, J. M.) 177-202, Humana Press, Totowa, 2008; Loebinger, M. R., et al. Thorax 65, 362-369, 2010; Motaln, H., et al. Cancer 116, 2519-2530, 2010; Kode, J. A., et al. Cytotherapy 11, 377-391, 2009; Yaghoubi, S. S., et al. Nat Protoc 1, 2137-2142, 2006; Chalberg, T. W., et al. Journal of Molecular Biology 357, 28-48, 2006; Keravala, A., et al. J. Neurosci. Methods 173, 299-305, 2008; Wu, J. C., et al. Physiol Genomics 25, 29-38, 2006; Menon, L. G., et al. Stem Cells 25, 520-528, 2007; Yaghoubi, S. S., et al. Nat Protoc 1, 3069-3075, 2007). The final products are four Ready-To-Use viral PRG cell-labeling kits: 1) lentivirus, pseudotyped for mouse T cells carrying TK2-N93D or other tk2 mutants; 2) lentivirus, pseudotyped for hMSCs, carrying TK2-N93D or other tk2 mutants; 3) lentivirus pseudotyped, for mouse T cells, carrying HSV1-sr39tk; 4) lentivirus, pseudotyped for hMSCs, carrying HSV1-sr39tk. Kits can include all reagents and optimized protocols for mouse CD8+ T cell or hMSC transduction.
Although lentiviral vectors can achieve stable transgene expression in most TCs, their random integration, possible production of replication competent viruses, regulatory concerns and the high cost of GMP grade lentivirus may limit their utility in certain clinical trials. The ΦC31 integrase enzyme (encoded by a Streptomyces soil bacteria phage) catalyzes site-specific chromosomal transgene integration following plasmid delivery (see, e.g. Keravala, A., et al. (eds. Davis, G. & Kayser, K. J.) Chromosomal Mutagenesis, Vol. 435:165-173, Humana Press Inc., Totowa, N. J., 2008; Ginsburg, D. S., et al. Advances in Genetics 54:179-187, 2005). ΦC31 integrase is functional in mammalian cells (see, e.g. Calos, M. P. Current Gene Therapy 6:633-645, 2006).
The enzyme recognizes two ˜30 base pair sequences, attB and attP. When plasmids carrying both attB and ΦC31 integrase (pCMV-Int) are introduced into mammalian cells, the enzyme carries out sequence-specific recombination with chromosomal sequences (pseudo attP sites) that resemble attP. Approximately 100 potential integration sites, have been identified, most of which are intergenic and none are near known cancer genes; thus oncogene activation is unlikely (see, e.g. Chalberg, T. W., et al. Journal of Molecular Biology 357:28-48, 2006). ΦC31 integrase typically generates only one integration event per cell (see, e.g. Chalberg, T. W., et al. Journal of Molecular Biology 357:28-48, 2006). Studies have demonstrated integration and expression of multiple genes carried on a single plasmid (see, e.g. Calos, M. P. Current Gene Therapy 6:633-645, 2006). Table 2 describes a proposed plan for developing non-viral PRG delivery kits. The final products are four Ready-To-Use ΦC31 integrase-based PRG cell-labeling kits containing the two essential plasmids, nucleofection reagents, and optimized protocols. These kits can allow delivery of either TK2-N93D or sr39tk to mouse T cells and to hMSCs.
Determine Conversion Factors to Estimate the Numbers of Therapeutic Cells In Vivo, Using PET Reporter Gene Imaging.
Increasing numbers (5, 10, 50, 100, 200, 500, and 800×103) of mouse CD8+ T cells or hMSCs with stably integrated PRGs can be injected into colon cancer tumor xenografts. One recognizes that direct injections into tumor lesions lack clinical relevance. However, this approach is only intended for the initial determination of conversion factors, which can then be validated in the clinically relevant models described above. PRG expression per cell can be determined immediately prior to injection. Four hours after TC injection, mice can receive L-[18F]FMAU and can be scanned three hours after tracer injection. L-[18F]FMAU percent injected dose (% ID) can be measured within an ROI drawn over the entire xenograft; % ID/tumor can be calculated. One can use >3 mice per group to obtain statistically significant values. These measurements can be related to cell numbers and normalized by cell expression level, to obtain conversion factors to estimate TC numbers present in tumor xenografts, based on L-[18F]FMAU/FEAU signal intensity.
3.4. Commercialization Strategy.
The kits can be marketed in two ways: (i) selling kits to investigators who wish to label TCs for pre-clinical studies. Quality control data (Table 2) and calibration studies (Sect. 4.2.3.3) can be published and also provided on a website to help customers decide whether the kits are appropriate for their cell therapy applications and offer better alternatives to other options for TC PK monitoring; (ii) establish service contracts and use the kits technologies to custom-prepare PRG-labeled TCs for clients that want to monitor the PK of their cells. The contracts, can—at the client's option—include additional services, such as quality assurances for specific PRG labeled TCs, determination of integration sites, PET imaging in small or large research animal models and PET image data analysis to estimate cell quantities. To perform PET imaging services for its customers, ELYXIS™, an automated modular radiochemistry device developed by Sofie Biosciences can be purchased. The PRPs used to generate the preliminary data shown in
Data can be generated for the eIND submission. One can provide a study coordinator, recruit healthy volunteers in accordance with FDA requirements, ensure the study follows the FDA approved protocol, make protocol amendments as needed, process the safety data, report necessary protocol deviations, and report any adverse effects.
Obtain Exploratory Investigational New Drug (eIND) Approval to Test the New PRPs in Humans.
An eIND application can be submitted to the FDA to enable clinical evaluation of L-[18F]FMAU and L-[18F]FEAU. One can then determine the biodistribution and dosimetry of these PRPs in healthy volunteers. These “first-in-human” studies can set the stage for a follow-up study in which a full IND application can be submitted to the FDA to initiate clinical testing of the new PRG-PRP systems in cancer patients.
The FDA eIND regulatory process allows microdosing studies ( 1/100th of the dose calculated to yield a pharmacologic effect) in small numbers of human subjects during early phase 1 (phase “0”) clinical trials. The steps required for submitting of an eIND application are: 1) preclinical safety/toxicity; 2) preclinical dosimetry; 3) chemistry, manufacturing and quality controls and 4) clinical protocols.
4.1. Preclinical Safety/Toxicity Studies:
The projected mass dose of L-[18F]FMAU and L-[18F]FEAU is ˜4 μg single dose. This dose is 2500-fold lower than that used as the lowest pharmacological L-FMAU (Clevudine, 10 mg/day for a minimum of 28 days (see, e.g. Marcellin, P., et al. 40:140-148, 2004)). Given the magnitude of this difference, any pharmacological effects or toxicity are highly improbable, both for L-FMAU and for the related compound L-FEAU. To obtain eIND approval from the FDA one can perform additional toxicity studies in rats. Rats can be administered a dose 100× higher than those given for imaging in humans on day 0 and monitored over a period of 14 days. Any side effects or organ damage can be determined by clinical chemistry, necropsy and histology on days −1, +1, +7 and +14.
4.2. Dosimetry Studies.
The radiation safety of the probes can also be evaluated by doing a dosimetry analysis in mice, as previously described (see, e.g. Yaghoubi, S. S., et al. J Nucl Med 47:706-715, 2006). The biodistribution of the PRPs can be studied in healthy human subjects. Tracer concentrations in all organs can be quantified non-invasively. Similar biodistribution/dosimetry clinical studies with the FAC imaging probes have been conducted.
4.3. Chemistry, Manufacturing, Controls and eIND Submission.
Briefly, F-18 ions are generated by a cyclotron particle accelerator, transferred to a “hot cell” and dried to remove water. The radiosynthesis is carried out and the probe product is purified by preparative HPLC, analyzed by HPLC and GC, and sterile filtered into multi-dose sterile vials. One can follow FDA recommendations that specify safety considerations for diagnostic radiopharmaceuticals including: verification of the mass dose of the radiolabeled and unlabeled moiety; assessment of the mass, and toxic potency; assessment of potential pharmacologic or physiologic effects due to molecules that bind with enzymes; and evaluation of all components in the final formulation for toxicity (e.g., excipients, reducing drugs, stabilizers, anti-oxidants, chelators, impurities, and residual solvents).
Upon completion of pre-clinical safety studies described above, a pre-eIND meeting can be scheduled with the FDA to review the submitted results and address potential questions. Following that meeting, one can submit an eIND for L-[18F]FMAU and L-[18F]FEAU. Within 30 days of eIND submission, the phase “0” clinical trials can be initiated.
4.4. Potential Caveats and Alternative Approaches.
It is possible that the biodistribution of the L-[18F]FMAU PET reporter gene probe in humans might be less favorable than what has been observed in mice. It was critically important to address this potential caveat before proceeding with the eIND application. Thus, approval has been obtained to perform the first ever L-[18F]FMAU whole-body PET/CT imaging in a healthy human volunteer. The image (
4.5. Additional Contingency Plans.
Recent studies show that increased retention of D-[18F]FMAU in human tumors reflects trapping of this probe by endogenous TK2 during mitochondrial stress (see, e.g. Tehrani, O, S., et al. European journal of nuclear medicine and molecular imaging 35:1480-1488, 2008). L-[18F]FMAU uptake may also increase in tumors that experience mitochondrial stress and this may interfere with the detection at these sites of therapeutic cells genetically labeled with the new mutant TK2 reporter genes. One can use previously described experimental approaches (see, e.g. Tehrani, O, S., et al. European journal of nuclear medicine and molecular imaging 35:1480-1488, 2008) to compare under conditions of mitochondrial stress the uptake of D-[18F]FMAU and L-[18F]FMAU by cells that express the mutant TK2 PRGs or vector (eYFP only) control. One expects that overexpression of a PRG optimized for L-[18F]FMAU and engineered to localize in the cytosol will allow these cells to accumulate much higher amounts of L-[18F]FMAU than those accumulated by control cells via the expression of endogenous TK2. If this is not the case, one can focus on L-[18F]FEAU, the other candidate PET reporter gene described in this application. Compared to D-[18F]FMAU and L-[18F]FMAU, L-[18F]FEAU is expected to have much lower affinity for endogenous human TK2 and thus its uptake in tumors should be insensitive to mitochondrial stress.
4.6 Future Directions.
Future directions include evaluating ΔTK2-DB/L-FMAU in a murine ACT model and in a model of gene therapy; solving the crystal structure of TK2 with L-FMAU; further optimization of ΔTK2 reporter genes; and evaluation of L-FEAU/L-FPAU as reporter probes.
Gene and cell based therapies hold the promise of curing a variety of incurable diseases if therapeutic transgene (TG) and therapeutic cell (TC) pharmacokinetic issues hampering their progress can be resolved. Radionuclide-based imaging reporter gene (IRG) systems are currently the only IRG systems sensitive enough for general and non-invasive monitoring of TG and TC kinetics in humans. A variety of positron emission tomography (PET) IRGs (PRGs) have been developed, but none are yet ideal TG or TC kinetics imaging tools. A new development strategy is pursued which began by evaluating the biodistribution of several candidate fluorine-18 radiolabeled PET tracers in vivo to identify the most suitable PET reporter probe (PRP) for a class of potentially non-immunogenic human derived PRGs.
5.1 Method.
Initially, a group of nucleoside analogs amenable to fluorine-18 labeling were identified. These PET tracers, 5 of which were novel, were then screened to determine their biodistribution in C57/BL6 mice (n=3 for each PET tracer) through dynamic microPET scans. Whole-body clinical PET scans were performed in a healthy male human volunteer at 4 time points for up to 2.5 hours to determine tissue time activities of the top candidate, 1-(2′-[18F]fluoro-5-methyl-β-L-arabinofuranosyl)uracil ([18F]L-FMAU). Rational design is utilized to introduce mutations into human nucleoside kinase thymidine kinase 2 (TK2) to improve the affinity of the kinase for the top candidate probe. The sensitivity and specificity of the novel PET reporter probe/gene pair was then determined in vitro and in vivo using a murine cancer model.
5.2 Results.
Of the 8 PET tracers synthesized, 4 exhibited lower abdominal background than 9-[4-[18F]fluoro-3-(hydroxymethyl)butyl]guanine ([18F]FHBG), the only PRP that has thus far been used for imaging TCs in patients. Of these four probes, 18F-L-FMAU was selected as the top candidate based on its biodistribution in mice and the fact that a compound with the same chemical structure had already been investigated in humans, facilitating relatively rapid translation into clinical studies. Whole-body 18F-L-FMAU PET scans in the healthy human volunteer showed that it had lower intestinal background than [18F]FHBG, indicating 18F-L-FMAU may be more suitable for imaging TG and TC kinetics in the lower abdomen of patients. A TK2 point mutant (TK2-N0, referring to the TK2-N93D mutant) is designed that showed a two-fold increase in in vivo uptake of 18F-L-FMAU compared to TK2 when assayed in a murine xenograft cancer model. A second TK2 mutant (TK2-N5, referring to the TK2-N93D/L109F mutant) was also identified that showed a two-fold increase in in vitro uptake of 18F-LFMAU as well as less resistance to inhibition by thymidine compared to TK2-N0.
5.3 Conclusions.
Using a novel platform for the development of PRG/PRP systems, 18F-L-FMAU has been identified as a suitable PRP for imaging mutant human tk2 PRGs. Paired with the novel PET reporter gene, TK2-N5, this can expand the utility of PET reporter gene systems in pre-clinical systems and potentially in clinical applications.
Positron emission tomography (PET) reporter gene imaging can be used to non-invasively monitor cell-based therapies. Therapeutic cells engineered to express a PET reporter gene (PRG) specifically accumulate a PET reporter probe (PRP) and can be detected by PET imaging. Expanding the utility of this technology requires the development of new non-immunogenic PRGs. Here, a new PRG-PRP system is described that employs, as the PRG, a mutated form of human thymidine kinase 2 (TK2) and 2′-deoxy-2′-18F-5-methyl-1-β-L-arabinofuranosyluracil (L-18F-FMAU) as the PRP. L-18F-FMAU was identified as a candidate PRP and its biodistribution was determined in mice and humans. Using structure-guided enzyme engineering, a TK2 double mutant (TK2-N93D/L109F) was generated that efficiently phosphorylates L-18F-FMAU. The N93D/L109F TK2 mutant has lower activity for the endogenous nucleosides thymidine and deoxycytidine than wild type TK2, and its ectopic expression in therapeutic cells is not expected to alter nucleotide metabolism. Imaging studies in mice indicate that the sensitivity of the new human TK2-N93D/L109F PRG is comparable with that of a widely used PRG based on the herpes simplex virus 1 thymidine kinase. These findings provide evidence that the TK2-N93D/L109F/L-18F-FMAU PRG-PRP system is useful in preclinical and clinical applications of cell-based therapies.
The inability to routinely monitor the tissue pharmacokinetics of therapeutic genes and cells and correlate this information with therapeutic outcomes represents a significant roadblock in the clinical adoption of these emerging therapies. Most cell/gene therapy trials use invasive biopsy techniques to localize therapeutic genes or therapeutic cells at target sites. However, invasive techniques are prone to sampling errors and carry risks for the patients. There is an unmet need for techniques to monitor the whole-body tissue distribution of therapeutic cells and therapeutic genes, to quantify therapeutic cells, and to measure therapeutic gene expression at all locations non-invasively and sequentially after treatment.
This unmet need can be addressed by PET3 reporter gene (PRG) imaging (see, e.g. Herschman, H. R. (2004) Crit. Rev. Oncol. Hematol. 51, 191-204). A PRG encodes a protein that mediates the specific accumulation of a PET reporter probe (PRP) labeled with a positron-emitting isotope (see, e.g. Gambhir, S. S., and Yaghoubi, S. S. (eds) (2010) Molecular Imaging With Reporter Genes, pp. 258-274, Cambridge University Press, Cambridge, UK). Such non-invasive PET measurements may predict and/or evaluate treatment efficacy and the risk of side effects; they can provide information that complements data obtained using invasive techniques, such as serial biopsies (see, e.g. Gambhir, S. S., and Yaghoubi, S. S. (eds) (2010) Molecular Imaging With Reporter Genes, pp. 258-274, Cambridge University Press, Cambridge, UK). PRGs developed to date encode proteins with various activities, including enzymes, transporters, and receptors (for review, see, e.g. Nair-Gill, E. D., et al. (2010) in Molecular Imaging with Reporter Genes (Gambhir, S. S., and Yaghoubi, S. S., eds) pp. 258-274. Cambridge University Press, Cambridge, UK). In theory, enzyme-encoding PRGs should have the highest sensitivity among different classes of PRGs as a result of signal amplification by the catalytic turnover of the enzymatic reaction that traps the probe.
The most commonly used PRGs are based on herpes simplex virus type 1 thymidine kinase (HSV1-tk) (see, e.g. Tjuvajev, J. G., et al. (1996) Cancer Res. 56, 4087-4095) and its optimized mutant, sr39tk (see, e.g. Gambhir, S. S., et al. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 2785-2790). Both wild type (WT) HSV1-tk and sr39tk have been used to study the kinetics of therapeutic cells in preclinical settings (see, e.g. Shu, C. J., et al. (2005) Proc. Natl. Acad. Sci. U.S.A. 102, 17412-17417; Yaghoubi, S. S., et al. (2007) J. Biomed. Opt. 12, 064025; Wu, J. C., et al. (2003) Circulation 108, 1302-1305; Hung, S. C., et al. (2005) Clin. Cancer Res. 11, 7749-7756). Several PRPs can be used to image cells engineered to express HSV1-tk-based PRGs: 9-[4-18F-3-(hydroxymethyl)butyl]guanine (18F-FHBG) (see, e.g. Yaghoubi, S. S., et al. (2009) Nat. Clin. Pract. Oncol. 6, 53-58; Peñuelas, I., et al. (2005) Gastroenterology 128, 1787-1795; Yaghoubi, et al. (2001) J. Nucl. Med. 42, 1225-1234), 2′-deoxy-2′-18F-5-ethyl-1-β-D-arabinofuranosyluracil (18F-FEAU) (see, e.g. Chin, F. T., et al. (2008) Mol. Imaging. Biol. 10, 82-91; Miyagawa, T., et al. (2008) J. Nucl. Med. 49, 637-648; Alauddin, M. M., et al. (2007) Eur. J. Nucl. Med. Mol. Imaging 34, 822-829), and 2′-deoxy-2′-18F-5-iodo-1-β-D-arabinofuranosyluracil (18F-FIAU) (see, e.g. Alauddin, M. M., et al. (2007) Eur. J. Nucl. Med. Mol. Imaging. 34, 822-829). To date, HSV1-tk is the only PRG that has been used to image therapeutic cells in patients (see, e.g. Yaghoubi, S. S., et al. (2009) Nat. Clin. Pract. Oncol. 6, 53-58).
The main disadvantage of HSV1-tk as a PRG is its immunogenicity, which can lead to immune-mediated elimination of therapeutic cells. This phenomenon has been documented in clinical trials (see, e.g. Traversari, C., et al. (2007) Blood 109, 4708-4715; Berger, C., et al. (2006) Blood 107, 2294-2302). The immunogenicity problem may be solved by replacing the viral kinase with a human orthologue (see, e.g. Amer, E. S., et al. (1995) Pharmacol. Ther. 67, 155-186). Two potentially non-immunogenic candidate PRGs based on human nucleoside kinases have been developed; that is, a double mutant of deoxycytidine kinase (dCK) (see, e.g. Likar, Y., et al. (2010) J. Nucl. Med. 51, 1395-1403) and a truncated form of mitochondrial thymidine kinase 2 (TK2) (see, e.g. Ponomarev, V., et al. (2007) J. Nucl. Med. 48, 819-826). These PRGs phosphorylate and trap the PRP 18F-FEAU. The sensitivity of the dCK-double mutant/18F-FEAU PRG-PRP system was comparable with that of HSV1-tk/18F-FEAU, whereas TK2/18F-FEAU had lower sensitivity. In non-human primates 18F-FEAU has a favorable biodistribution as a candidate PRP, with tracer accumulation in the liver, small intestine, kidneys, and urinary bladder (see, e.g. Dotti, G., et al. (2009) Mol. Imaging. 8, 230-237) but not in other organs and tissues. Human biodistribution data for this candidate PRP are not available.
The utility of a PRG-PRP system is dependent on its sensitivity (the ability to detect few therapeutic cells at various anatomical locations) and specificity (the probe should accumulate only in cells engineered to express the PRG). Another equally important parameter is the requirement that a PRG should be biologically inert. In other words its ectopic expression in therapeutic cells should not alter the metabolism or normal function of these cells. This requirement is especially important in the case of nucleoside kinase PRGs. Ectopic expression of a nucleoside kinase could perturb the normal regulation of nucleotide metabolism through excess phosphorylation of endogenous nucleosides. Such metabolic alterations can lead to imbalanced nucleotide pools and increased risk of genotoxicity (see, e.g. Kumar, D., et al. (2011) Nucleic Acids Res. 39, 1360-1371; Song, S., et al. (2003) J. Biol. Chem. 278, 43893-43896; Sargent, R. G., et al. (1987) J. Biol. Chem. 262, 5546-5553; Kumar, D., et al. (2010) Nucleic Acids Res. 38, 3975-3983). In this context the dCK-double mutant has significantly higher activity than WT dCK toward endogenous nucleosides such as deoxycytidine and thymidine (see, e.g. Hazra, S., et al. (2009) Biochemistry 48, 1256-1263). Truncated TK2 also retains normal activity with natural substrates. Whether these new PRGs fulfill the critical requirement of being biologically inert remains to be determined.
Here, the development of a new PRG-PRP system that meets the specifications mentioned above is described. The biodistribution of L-18F-FMAU, the candidate PRP, was determined in mice and humans. Enzyme engineering was used to develop a mutant PRG enzyme that is orthogonal to the wild type enzyme regarding its ability to phosphorylate endogenous nucleosides. The resulting PRG-PRP system, TK2-N93D/L109F as PRG and L-18F-FMAU as PRP, should find utility in various preclinical and clinical therapeutic cell tracking applications. The approach used to develop this system should be generalizable to the identification and evaluation of other pairs of nucleoside analogs and nucleoside kinases for PET reporter gene imaging applications.
Radiochemical Synthesis of 18F-Labeled PET Probes—
18FFHBG was synthesized as previously described (see, e.g. Yaghoubi, S., et al. (2001) J. Nucl. Med. 42, 1225-1234). The radiochemical synthesis of L-18F-FMAU is described herein (see, e.g. Example 7).
Molecular Modeling of Human TK2—
A homology model of TK2 was generated using the SWISS-MODEL server (see, e.g. Arnold, K., et al. (2006) Bioinformatics 22, 195-201). The solved structures of human dCK (35% identity, 50% homology to TK2) in both its closed (PDB ID 1P5Z) and open conformation (PDB ID 3QEO) (see, e.g. Sabini, E., et al. (2003) Nat. Struct. Biol. 10, 513-519; Hazra, S., et al. (2011) Biochemistry 50, 2870-2880) served as templates.
Generation of TK2 Mutants—
The Δ50N truncation variant of TK2 was used (which lacks the mitochondrial sorting signal), referred to as the WT enzyme. Numbering of residues is based on the full-length sequence of human TK2 (Uniprot ID O00142, see, e.g.
Expression and Purification of Recombinant TK2 Proteins—
Expression and purification of TK2 have been described previously (see, e.g. Hazra, S., et al. (2010) Biochemistry 49, 6784-6790). In short, Escherichia coli BL21 (DE3) C41 harboring the modified pET14b vector (to include a SUMO tag between the hexahistidine sequence and TK2) were grown at 37° C. until an optical density of ˜0.8 was reached. At that point the temperature was reduced to 18° C.; the culture was induced with 0.5 mM isopropyl β-D-1-thiogalactopyranoside and left to shake overnight. Cells were harvested by centrifugation, washed, and stored at −80° C. until use. Purification involved two steps. The first step used a metal affinity column (HisTRAP HP column, GE Healthcare); after elution of the His-SUMO-TK2 fusion protein, the SUMO protease was added. The cleaved protein was reapplied onto the nickel column to separate TK2 from the His-SUMO tag. The second step involved a gel filtration column (S200, GE Healthcare) equilibrated with 25 mM Tris, pH 7.5, 200 mM NaCl, and 3 mM DTT. Pure TK2 was pooled, concentrated to ˜10 mg/ml, separated into aliquots, flash-frozen in liquid nitrogen, and stored at −80° C. until use.
Kinetic Analyses of TK2-based Candidate PRGs—
A NADH-dependent enzyme coupled assay (see, e.g. Agarwal, K. C., et al. (1978) Methods Enzymol. 51, 483-490) was used. Using a Cary UV spectrophotometer, measurements were made in triplicate at 37° C. in a buffer containing 100 mM Tris, pH 7.5, 100 mM KCl, 5 mM MgCl2, and 1 mM ATP. For data in which kobs is given, a single nucleoside concentration of 200 μM was used. For data in which both Km and kcat are given, the nucleoside concentration was varied between 15 and 500 μM. TK2 concentration in the cuvette was 400 nM. Data were fit to the Michaelis-Menten equation using SigmaPlot. Of note, in some previous reports, negative cooperativity was observed with thymidine but not with deoxycytidine (see, e.g. Barroso, J. F., et al. (2005) Biochemistry 44, 4886-4896; Wang, L., et al. (2003) J. Biol. Chem. 278, 6963-6968). When the data for WT TK2 was fitted using the Hill equation, one also saw the same magnitude of negative cooperativity as reported by others (n=˜0.7) with thymidine and the analogs tested. However, the quality of the fit of the data is only marginally improved compared with that using the simple Michaelis-Menten equation. When the data of the TK2 mutants are fit using the Hill equation, a more complicated behavior is observed, with some conditions having a Hill coefficient below 1, some above 1, and some nearly one. Here again, the quality of the fit is not dramatically improved by adding the extra parameter of the Hill coefficient. Therefore, all of the kinetic data using the Michaelis-Menten equation without the Hill coefficient is presented.
Cell Lines—
The L1210 cell line (see, e.g. Jordheim, L. P., et al. (2004) Clin. Cancer Res. 10, 5614-5621) was a gift. Cells were cultured at 5% v/v CO2 and 37° C. in RPMI supplemented with 5% v/v FCS. Murine stem cell virus (pMSCV)-based helper-free retroviruses encoding the TK2 mutants (or sr39tk), an internal ribosomal entry site, and the yellow fluorescent protein (YFP) were produced by transient co-transfection of the amphotrophic retrovirus packaging cell line Phoenix (American Type Culture Collection, SD 3443) (see, e.g. Hawley, R. G., et al. (1994) Gene. Ther. 1, 136-138). L1210 cells underwent spinfection with the pMSCV-TK2 mutants-internal ribosomal entry site-YFP retrovirus with 2 μg/ml Polybrene (1000×g, 120 min, 37° C.). L1210 cells expressing various PRGs, (L1210-PRG) were FACS-sorted to ensure that each population had equivalent levels of PRG expression.
Probe Uptake Assays Using Transduced L1210 Cell Lines—
L1210 cells transduced with the indicated PET reporter genes (L1210-PRG) were seeded at a density of 500,000 cells/well in 24-well plates. 5 μCi of L-18F-FMAU were added to the L1210-PRG cells simultaneously with the indicated amounts of D-thymidine (D-dT) at a final volume of 1 ml/well. After 1 h at 37° C., cells were harvested and washed four times with ice-cold PBS. Radioactivity was measured using a gamma counter.
MicroPET/CT Imaging Studies in Mice—
Animal studies were approved and carried out according to specific guidelines. C57/BL6 mice were injected with the indicated probe and underwent micro-PET/CT analyses at 1- and 3-h post probe injection (Inveon, Siemens Medical Solutions USA Inc.; microCAT; Imtek Inc.). For tumor imaging studies, SCID mice were injected subcutaneously on day −7 in the right and left flanks with 1×106 L1210-PRG-expressing cells in 50% v/v phosphate-buffered saline and 50% v/v Matrigel™ (BD Biosciences). For imaging experiments, mice were kept warm and under gas anesthesia (2% v/v isoflurane) and were injected intravenously with 200 μCi of 18F-labeled probes. A 3-h interval was allowed between probe administration and microPET/CT scanning Static microPET images were acquired for 600 s. Image data were evaluated in three-dimensional histograms and reconstructed with a zoom factor of 2.1 using three-dimensional ordered set expectation maximization (OSEM) with 2 iterations followed by MAP (maximum a posteriori) reconstruction with 18 iterations (beta=0.1). Images were analyzed using OsiriX Imaging Software Version 3.8.
Human PET/CT Studies—
All studies involving human volunteers were approved. A 53-year-old healthy male and a 44-year-old healthy female volunteer were recruited for the L-18F-FMAU biodistribution study. Each volunteer received a bolus intravenous injection of ˜56 MBq (1.5 mCi) sterile L-18F-FMAU and had four consecutive whole-body (starting from just above the head to above the knees, 6 bed positions, 5-min scan at each bed position) PET scans (Biograph 64, Siemens), with the first scan starting shortly after intravenous injection of L-18F-FMAU. A low dose CT scan was also obtained for attenuation correction. Volunteers urinated after all scans had been performed. The region of interest analysis was performed to measure mean standard uptake values of L-18F-FMAU in major organs/tissues. To illustrate the biodistribution of 18F-FHBG, unpublished scan from a previous study (see, e.g. Yaghoubi, S. S., et al. (2009) Nat. Clin. Pract. Oncol. 6, 53-58) was used.
Statistical Analysis—
Data are presented as the means±S.E. All p values are two-tailed, and p values of <0.05 are considered to be statistically significant. Graphs were generated and analyzed using the Prism 5 software (GraphPad).
Comparison of Biodistribution of L-18F-FMAU and 18F-FHBG in Mice—
Nucleoside analogs are being increasingly used as PET probes for assaying nucleotide metabolism, cell proliferation, and mitochondrial function (see, e.g. Radu, C. G., et al. (2008) Nat. Med. 14, 783-788; Shields, A. F. (2003) J. Nucl. Med. 44, 1432-1434; Sun, H., et al. (2005) J. Nucl. Med. 46, 292-296; Mangner, T. J., et al. (2003) Nucl. Med. Biol. 30, 215-224; Namavari, M., et al. (2011) Mol. Imaging. Biol. 13, 812-818). Nucleosides can adopt one of two enantiomeric configurations. Naturally occurring nucleosides are in the D configuration (see, e.g. de Leder Kremer, R. M., et al. (2004) Adv. Carbohydr. Chem. Biochem. 59, 9-67). Recently there has been increasing interest in using nucleoside analogs with the non-natural L configuration as PET probes to image the activity of endogenous nucleoside kinases (see, e.g. Shu, C. J., et al. (2010) J. Nucl. Med. 51, 1092-1098; Nishii, R., et al. (2008) Eur. J. Nucl. Med. Mol. Imaging. 35, 990-998; Mukhopadhyay, U., et al. (2007) Appl. Radiat. Isot. 65, 941-946; Schwarzenberg, J., et al. (2011) Eur. J. Nucl. Med. Mol. Imaging. 38, 711-721). To date, L nucleosides have not been evaluated as PRPs. Determination of the potential value of L nucleosides as PRPs focused on L-18F-FMAU, the non-natural counterpart of D-18F-FMAU, one of the pyrimidine analogs that has been previously evaluated as a candidate PRP for the HSV1-tk PRG (see, e.g. Alauddin, M. M., et al. (2004) Mol. Imaging. 3, 76-84).
The biodistribution of L-18F-FMAU in mice was compared with that of 18F-FHBG, a well characterized and frequently used PRP (see, e.g. Yaghoubi, et al. (2001) J. Nucl. Med. 42, 1225-1234; Alauddin, M. M., et al. (1998) Nucl. Med. Biol. 25, 175-180; Alauddin, M. M., et al. (2001) J. Nucl. Med. 42, 1682-1690). To achieve optimal signal to noise ratios, PRPs should not accumulate in cells and tissues that do not express the corresponding PRG. For instance, the accumulation of the candidate PRP should be minimal or undetectable in all tissues, except in those involved in probe clearance from the body. C57/BL6 mice were scanned 3 h after administration of either L-18F-FMAU or 18F-FHBG (
Development of New PRG to be Used in Conjunction with L-18F-FMAU Candidate PRP—
L-FMAU has been shown to be a substrate for human TK2, a nucleoside kinase that due to its lack of enantiomeric specificity can phosphorylate both D and L nucleosides (see, e.g. Wang, J., et al. (1999) Biochemistry 38, 16993-16999). Ideally, modifications to the TK2 sequence should achieve two objectives; (i) increase sensitivity by reducing the negative feedback regulation of the enzyme and by increasing the phosphorylation rate of the L-FMAU PRP; (ii) reduce the activity of the PRG kinase for the endogenous substrates thymidine and deoxycytidine (to avoid competition between L-FMAU and endogenous nucleosides and potentially genotoxic perturbations of endogenous nucleotide pools).
The enzymatic activity of TK2 is regulated by thymidine triphosphate (dTTP) through negative feedback inhibition (see, e.g. Radivoyevitch, T., et al. (2011) Nucleosides Nucleotides Nucleic Acids 30, 203-209). dTTP is produced by de novo synthesis and through the salvage of thymidine (via the cytosolic nucleoside kinase TK1). dTTP levels fluctuate throughout the cell cycle and are highest during the S phase, when they increase by as much as 2.5-20-fold compared with the G1 phase (see, e.g. Bianchi, V., et al. (1997) J. Biol. Chem. 272, 16118-16124; Spyrou, G., et al. (1988) Mutat. Res. 200, 37-43). It is possible that fluctuations in dTTP levels during the cell cycle can reduce sensitivity and result in difficult to interpret changes in PET signals.
To reduce the susceptibility of TK2 to dTTP-mediated feedback inhibition, one took advantage of the 40% sequence identity between human TK2 and Drosophila melanogaster deoxyribonucleoside kinase (Dm-DNK) (see, e.g. Eriksson, S., et al. (2002) Cell. Mol. Life. Sci. 59, 1327-1346) and of the identification of a point mutation (N64D) in Dm-DNK that has been shown to reduce the effect of dTTP feedback inhibition (see, e.g. Welin, M., et al. (2005) FEBS J. 272, 3733-3742). The residue in TK2 corresponding to Asn-64 in D. melanogaster deoxyribonucleoside kinase is Asn-93; the corresponding mutation in TK2 is N93D. To predict the effects of the N93D mutation on the structure of TK2, molecular modeling was used. One took advantage of the fact that dCK belongs to the same family of nucleoside kinases as TK2. The sequence identity and homology between dCK and TK2 are 35 and 50%, respectively. Based on previous works with dCK (see, e.g. Sabini, E., et al. (2003) Nat. Struct. Biol. 10, 513-519; Hazra, S., et al. (2011) Biochemistry 50, 2870-2880), a homology model of TK2 was obtained (
To test this hypothesis, kinase assays using L-FMAU and recombinant WT TK2 and TK2-N93D were performed in the presence of varying amounts of dTTP (
Cell-based uptake assays were then used to determine whether the decreased susceptibility to feedback inhibition conferred by the N93D mutation increases L-18F-FMAU uptake. As shown in
To confirm that the increase in signal can also be detected in vivo, mice implanted with L1210 cells transduced with the WT TK2 and mutant TK2-N93D PRGs (
Further Improvements of Selectivity and Affinity of TK2-Derived PRG for L-18F-FMAU—
For enzymatic PRGs, the higher the catalytic turnover (kcat) of the enzyme, the more the PRP can accumulate per unit time, leading to a higher PET signal. The kcat of mutated TK2 PRG for L analogs was determined compared with the endogenous substrate, D-dT. Relative to WT TK2, the N93D mutation reduced the kcat of the enzyme toward D-dT, L-dT, and L-FMAU (
To identify additional mutations that may further improve the selectivity of the TK2 PRG for L analogs, high resolution structures of dCK in complex with L and D substrates (see, e.g. Sabini, E., et al. (2007) J. Med. Chem. 50, 3004-3014) were used to generate a homology model of TK2 with bound L-dT and D-dT (
Based on these observations, TK2-N93D/L109F was generated with the expectation that this double mutant will combine the enzymatic properties of the two single mutants. As shown in
To determine the preference of the TK2 mutants for L-18F-FMAU over D-dT, uptake assays were performed using L1210 cells in the presence or absence of 5 μM D-dT (
Next, one investigated whether TK2-N93D/L109F had low activity toward deoxycytidine, the other endogenous nucleoside that is phosphorylated by WTTK2. TK2-N93D/L109F has a kobs (dC) that is 62% that of TK2 (
In Vivo Comparison Between TK2-N93D/L109F/L-18FFMAU and HSV1-sr39tk/18F-FHBG PRG-PRP Systems—
Mice implanted with L1210 cells expressing TK2-based PRGs were scanned by microPET/CT using L-18F-FMAU (
L-18F-FMAU Biodistribution in Humans—
As the first step toward clinical translation of the newly developed PRG-PRP system, the biodistribution of L-18F-FMAU in humans was determined.
To develop a PRG that can be used in conjunction with L-18F-FMAU, a thymidine analog with the unnatural L-conformation, the mitochondrial sorting sequence was removed in human TK2. As shown previously, the truncated protein is expected to localize in the cytosol rather than in the mitochondria (see, e.g. Ponomarev, V., et al. (2007) J. Nucl. Med. 48, 819-826). Rational design was then used to improve the sensitivity and selectivity of the TK2 PRG. This led to the development of TK2-N93D/L109F, a double mutant TK2 kinase characterized by reduced affinity for the natural substrates D-thymidine and D-deoxycytidine and increased affinity for L-FMAU. Studies in mice indicated that the TK2-N93D/L109F PRG has comparable sensitivity to that of the widely used HSV1-sr39tk/18F-FHBG system. The biodistribution of L-FMAU in humans has also been determined.
Advantages of TK2-N93D/L109F/L-18F-FMAU PRG System—
In mice, L-18F-FMAU accumulates in the liver 1-h post injection (data not shown). The progression of the signal from the liver to the gallbladder and then to the GI indicates that L-18F-FMAU is excreted via a hepato-biliary mechanism, similar to that observed for 18F-FHBG (see, e.g. Yaghoubi, et al. (2001) J. Nucl. Med. 42, 1225-1234). However, the GI activity in L-18F-FMAU-injected mice is significantly less intense than that observed in mice injected with 18F-FHBG. The intense signal in the GI of mice injected with 18F-FHBG leads to spillover in other organs in the lower abdomen, limiting the utility of 18F-FHBG for cell tracking applications in mice if these cells localize in the abdominal cavity.
In addition to its human origin (which is expected to reduce immunogenicity compared with the viral PRGs), the TK2-N93D/L109F PRG also has the advantage of reduced activity toward the endogenous nucleosides, D-thymidine and D-deoxycytidine. PRGs are typically overexpressed in therapeutic cells. In this context, if the mutant PRG retains the ability to efficiently phosphorylate thymidine and/or deoxycytidine, then this may alter cellular metabolism due to overproduction of dTTP and/or dCTP. Such effects would be of particular concern in preclinical settings as serum levels of thymidine in mice and rats are 9-15 times higher than those in humans (see, e.g. Nottebrock, H., et al. (1977) Biochem. Pharmacol. 26, 2175-2179). Any changes in nucleotide metabolism and dNTP pools in therapeutic cells may have genotoxic consequences, especially when prolonged persistence in vivo of these cells is anticipated (for example in the case of stem cells). In contrast to previously reported PRG such as dCK-double mutant, TK2-N93D/L109F is less likely to perturb cellular nucleotide metabolism and genomic integrity due to the decreased activity of the double mutant enzyme toward natural substrates.
In contrast to mice, in humans L-18F-FMAU accumulates in the myocardium and liver. Regarding L-18F-FMAU accumu-mitochondria (see, e.g. Schaper, J., et al. (1985) Circ. Res. 56, 377-391). Moreover, the reported activity of the WT mitochondrial TK2 enzyme from human heart tissue is nearly 10 times higher than that of the enzyme from mouse heart tissue (see, e.g. Saada, A., et al. (2003) Mol. Genet. Metab. 79, 1-5; Wang, L., et al. (2000) Biochem. J. 351, 469-476). This difference may explain the observed differences in L-18F-FMAU myocardial accumulation between mice and humans. L-18F-FMAU is taken up by the liver of both mice and humans. However, L-18F-FMAU eventually clears the murine liver but is retained in the human liver. One reason for this difference may be that, similar to 18F-FLT (3′-deoxy-3′-18-fluorothymidine) (see, e.g. Shields, A. F., et al. (1998) Nat. Med. 4, 1334-1336), L-18F-FMAU may also undergo glucuronidation in human liver tissue. Glucuronidation of thymidine analogs is significantly less extensive in mice than in humans (see, e.g. Barthel, H., et al. (2003) Cancer Res. 63, 3791-3798). Myocardial accumulation in humans may be reduced if L-18F-FMAU is modified to decrease its phosphorylation by WT TK2. Replacing the 5-methyl group with a larger substituent such as ethyl or propyl may achieve this objective.
As disclosed herein, a structure guided approach was used to develop a human nucleoside kinase-based PRG characterized by high specificity and selectivity for L-18F-FMAU, a non-natural nucleoside analog PRP. The initial findings in mice and the observed biodistribution of L-18F-FMAU in mice and humans warrant additional studies in both species and provide evidence for strategies to further improve the sensitivity and specificity of the new human TK2-based PET reporter gene assay.
As shown in
The solution was evaporated at 115° C. with a stream of nitrogen gas. The residue was dried by the azeotropic distillation with acetonitrile (3×0.5 mL). To the dry residue, a solution of the triflate 1 (10 mg) in 0.7 mL of acetonitrile was added and the reaction mixture was heated at 165° C. for 15 min in a sealed vessel. The solution was cooled to room temperature and passed through a Waters silica gel Sep-Pak. The product was eluted from the cartridge with 5 mL of ethyl acetate. The ethyl acetate solution was evaporated to dryness and 0.1 mL of a solution of 30% HBr in acetic acid was added followed by 0.4 mL of dichloroethane.
This new reaction mixture was heated at 80° C. in a sealed vessel for 10 min and the solution was concentrated to ˜50% of the initial volume. Toluene (0.7 mL) was then added and the solution was evaporated at 110° C. to give the bromo compound 3. A solution of the disilyl derivative of 5-methyluracil (4, 20 mg, Aldrich Chemical Company) was dissolved in 1 mL of dichloroethane and added to the bromo compound 3. The condensation reaction was carried out at 160° C. in a sealed vessel for 30 min. The reaction mixture was cooled to room temperature and then passed through a Waters silica gel Sep-Pak.
The product was eluted off the column using 5 mL of a solution mixture of 10% methanol and 90% dichloromethane. This solution was evaporated to dryness at 100° C. and then treated with 0.5 mL of a solution of 0.5 M sodium methoxide in methanol. The reaction mixture was heated at 100° C. for 5 min in a sealed vessel. The basic reaction mixture was neutralized with 0.25 mL of 1M HCl in water. This reaction mixture was diluted to a total volume of 3 mL with a mixture of 4% acetonitrile and 96% 50 mM ammonium acetate in water and injected into a semi-preparative HPLC column (Phenomenex Gemini C-18 column; 25 cm×1 cm). The HPLC column was eluted with a solvent mixture of 4% acetonitrile and 96% 50 mM ammonium acetate at a flow rate of 5.0 mL/min. The effluent from the HPLC column was monitored with a 254 nm UV detector followed by a gamma radioactive detector. The chemically and radiochemically pure L-[18F] FMAU (6) that eluted off the column with a retention time of ˜24 min was collected and the solvents were evaporated in a rotary evaporator. One mL of ethanol was added to the residue and evaporated to remove the last traces of acetonitrile. This was followed by an addition of one mL sterile water and evaporation to remove the ethanol. The product was finally dissolved in 5 mL of sterile water and made isotonic with saline and sterilized by passing through a Millipore filter (0.22 μm) into a sterile multi-dose vial.
As number of illustrative PRPs are disclosed including FFU, FCU, FBU and FddUrd (
As shown in
All four probes satisfy condition (b). One has been able to synthesize all of them in amounts that were more than sufficient for animal studies.
Representative images of the biodistribution of the 4 candidate probes in mice are shown in
Regarding condition (d), one has obtained the microsomal stability profiles for 3 out of 4 compounds (FCU, FBU and FddUrd using the glucuronidation conditions). Of these three candidate probes, only FBU showed decrease stability over time in the microsomal assay (data not shown).
FCU has previously been evaluated in humans for its anti-HIV properties. The existence of a toxicology study in humans can allow for us to get initial biodistribution studies of FCU in humans.
This concludes the description of the preferred embodiment of the present invention. The foregoing description of one or more embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching.
Certain aspects of the invention are disclosed in Campbell et al., J Biol. Chem. 2012 287(1):446-54, the contents of which are incorporated by reference. All publications, patents, and patent applications cited herein are hereby incorporated by reference in their entirety for all purposes.
This application claims priority under Section 119(e) from U.S. Provisional Application Ser. No. 61/515,743, filed Aug. 5, 2011, the contents of which are incorporated herein by reference.
This invention was made with Government support of Grant No. CA160770-02 awarded by the National Institutes of Health. The Government has certain rights in this invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2012/049753 | 8/6/2012 | WO | 00 | 4/28/2014 |
Number | Date | Country | |
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61515743 | Aug 2011 | US |