SIGNAL-SMART ONCOLYTIC VIRUSES IN TREATMENT OF HUMAN CANCERS
20190151383 ยท 2019-05-23
Inventors
Cpc classification
C12N2710/16651
CHEMISTRY; METALLURGY
A61K48/0058
HUMAN NECESSITIES
C12N2710/16621
CHEMISTRY; METALLURGY
C12N15/1135
CHEMISTRY; METALLURGY
Y02A50/30
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
A01K2207/12
HUMAN NECESSITIES
C07K16/28
CHEMISTRY; METALLURGY
C12N15/8509
CHEMISTRY; METALLURGY
International classification
A61K38/16
HUMAN NECESSITIES
C07K16/28
CHEMISTRY; METALLURGY
C12N15/113
CHEMISTRY; METALLURGY
Abstract
A recombinant lytic virus transcriptionally targeted against malignant cells. A promoter for a viral gene controlling replication is replaced with a promoter for a malignant factor such that the promoter for the malignant factor controls expression of the viral gene controlling replication. Accordingly, the recombinant lytic virus of the present invention only replicates within and kills cells expressing the malignant factor. In an embodiment, the recombinant lytic virus is a recombinant herpes simplex virus, and the viral gene controlling replication is a herpes alpha gene. In an embodiment, the recombinant lytic virus is transcriptionally targeted against cancer stem cells (CSCs). In an embodiment, the recombinant lytic virus is a recombinant herpes simplex virus-1 (HSV-1) with the promoter of CD133 controlling the expression of infected cell protein-4 (ICP4). In another embodiment, the recombinant lytic virus is a recombinant HSV-1 with the promoter of Ezh2 controlling the expression of ICP4.
Claims
1. A recombinant oncolytic virus configured for transcriptionally targeting cells expressing a pro-oncogenic factor, wherein: a promoter for a viral gene controlling viral replication is deleted; a natural or synthetic sequence capable of driving expression of said viral gene controlling viral replication and including a promoter for said pro-oncogenic factor is inserted in controlling relation to said viral gene controlling viral replication in place of said promoter for said viral gene controlling viral replication such that said promoter for said malignant factor controls expression of said viral gene controlling viral replication; said viral gene controlling viral replication is only expressed within cells expressing said pro-oncogenic factor; and expression of said viral gene controlling viral replication results in replication of said virus within and destruction of an infected cell.
2. The recombinant oncolytic virus according to claim 1, wherein said pro-oncogenic factor comprises one of the group consisting of: a cancer stem cell (CSC) marker, a pro-oncogenic signaling pathway, a transcription factor, and a malignancy-promoting factor.
3. The recombinant oncolytic virus according to claim 1, wherein said recombinant oncolytic virus comprises a recombinant herpes simplex virus.
4. The recombinant oncolytic virus according to claim 3, wherein said recombinant herpes simplex virus comprises a recombinant herpes simplex virus-1 (HSV-1).
5. The recombinant oncolytic virus according to claim 3, wherein said viral gene controlling viral replication comprises a herpes alpha gene.
6. The recombinant oncolytic virus according to claim 5, wherein said herpes alpha gene comprises a gene selected from the group consisting of: infected cell protein-4 (ICP4), infected cell protein-6 (ICP6), infected cell protein 34.5 (ICP34.5), and infected cell protein-27 (ICP27).
7. The recombinant oncolytic virus according to claim 1, wherein said recombinant oncolytic virus comprises a recombinant virus selected from the group consisting of: adenovirus, vaccinia virus, vesicular stomatitis virus, poliovirus, reovirus, senecavirus, RIGVIR, Semliki Forest virus, measles virus, Newcastle disease virus, coxsackie virus, Maraba virus, and retrovirus.
8. The recombinant oncolytic virus according to claim 1, wherein said pro-oncogenic factor is selected from the group consisting of: CD133, Ezh2, CD24, CD34, CD38, CD117, CD44, CD90, CD271, ABCB5, EpCAM, JAK/STAT pathway, Wnt/-catenin pathway, Hedgehog pathway, Notch pathway, TGF- pathway, Ral pathway, Ras pathway, multidrug resistance pump ABC, CXCL12/CXCR4, VEGF/VEGFR, Cripto-1, Kpnb1, Enox-1, Enox-2, 3 integrin, Elk-1 binding factor, Oct4, sox2, nanog, Lin-29, KLf-4, c-myc, and combinations thereof.
9. The recombinant oncolytic virus according to claim 1, wherein said recombinant oncolytic virus is further coated with one of the group consisting of polymers, nanomers, and combinations thereof configured to improve efficiency of targeting said pro-oncogenic factor.
10. The recombinant oncolytic virus according to claim 1, wherein said recombinant oncolytic virus is further equipped with one of the group consisting of antibodies, aptamers, receptors, homing devices, and combinations thereof to improve efficiency of targeting said pro-oncogenic factor.
11. A recombinant herpes simplex virus configured for transcriptionally targeting cancer stem cells (CSCs) expressing a CSC marker, wherein: a promoter for a herpes alpha gene is deleted; a natural or synthetic sequence capable of driving expression of said herpes alpha gene and including a promoter for said CSC marker is inserted in controlling relation to said herpes alpha gene such that said promoter for said CSC marker controls expression of said herpes alpha gene; said herpes alpha gene is only expressed within cells expressing said CSC marker; and expression of said herpes alpha gene results in replication of said herpes simplex virus within and destruction of an infected cell.
12. The recombinant herpes simplex virus according to claim 11, wherein said recombinant herpes simplex virus comprises a recombinant herpes simplex-1 virus.
13. The recombinant herpes simplex virus according to claim 11, wherein said herpes alpha gene comprises infected cell protein-4 (ICP4).
14. The recombinant herpes simplex virus according to claim 11, wherein said CSC marker comprises CD133.
15. The recombinant herpes simplex virus according to claim 11, wherein said CSC marker comprises Ezh2.
16. A method of treating cancer in a subject comprising the steps of: administering to a subject the recombinant oncolytic virus according to claim 1; and said virus selectively killing tumor cells.
17. The method according to claim 16, wherein: the tumor cells are selected from the group consisting of: hepatocellular carcinoma, colorectal carcinoma, melanoma, and glioma cells.
18. The method according to claim 16, wherein: said administering to a subject the recombinant oncolytic virus is carried out by one of the group consisting of: injection, infusion, instillation, inhalation, and pharmaceutical ingestion.
19. The method according to claim 16, wherein: said subject comprises a human.
20. The method according to claim 16, wherein: said administering to a subject the recombinant oncolytic virus comprises administering said recombinant oncolytic virus in a preventative treatment to prevent development of malignancies.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] The drawings constitute a part of this specification and include exemplary embodiments of the present invention illustrating various objects and features thereof.
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DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
I. Introduction and Environment
[0063] As required, detailed aspects of the present invention are disclosed herein, however, it is to be understood that the disclosed aspects are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art how to variously employ the present invention in virtually any appropriately detailed structure.
[0064] Certain terminology will be used in the following description for convenience in reference only and will not be limiting. For example, up, down, front, back, right and left refer to the invention as orientated in the view being referred to. The words, inwardly and outwardly refer to directions toward and away from, respectively, the geometric center of the aspect being described and designated parts thereof. Forwardly and rearwardly are generally in reference to the direction of travel, if appropriate. Said terminology will include the words specifically mentioned, derivatives thereof and words of similar meaning.
[0065] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art of the invention. Methods and materials are described herein for use in the present invention, but other, suitable methods and materials known in the art can also be used. The materials, methods, and examples are illustrative only and not intended to be limiting. All publications, patent applications, patents, sequences, database entries, and other references mentioned herein are incorporated by reference in their entirety. However, in case of conflict, the present specification will control.
[0066] The present invention contemplates a novel, recombinant lytic virus configured for transcriptionally targeting and destroying cancer cells. Viruses which replicate via the lytic cycle cause destruction of an infected cell upon viral replication. Thus, a lytic virus can be very damaging to the health of a host organism, as the virus kills cells it infects and replicates within. However, if a lytic virus can be modified to only allow replication within, and thus destruction of, unwanted cells, such as malignant cells, such a modified lytic virus could be an effective mechanism for treatment to kill those unwanted cells. Accordingly, the present invention is a recombinant lytic virus which only permits replication in the presence of a known malignant factor promoter.
[0067] In order to selectively attack unwanted malignant cells, the recombinant virus of the present invention is transcriptionally targeted against cells having a known malignant factor or cancer stem cell marker, which is a biological substance, such as but not limited to a protein, known to be highly expressed within cancer cells. To accomplish this, the natural promoter for a gene which controls replication of the virus is replaced with a promoter for a cancer stem cell marker or other malignant factor highly expressed within malignant cells. With this arrangement, the new promoter for the controlling gene for replication of the virus requires expression of the targeted cancer stem cell marker or malignant factor to initiate transcription of the controlling gene. Accordingly, the virus can only replicate in cells expressing the cancer stem cell marker or malignant factor, and replication of the virus results in destruction of the cell within which it replicates.
[0068] In an exemplary embodiment, a recombinant lytic virus of the present invention is used to transcriptionally target cells expressing a known cancer stem cell (CSC) marker. The concept of cancer stem cells, which is well-studied and well-supported by those skilled in the art, hinges on the theory that malignant tumors are structured similarly to organs, having an array of different cell types with specific assignments within the tumor. According to this theory, a subset of tumor cells, referred to as cancer stem cells (CSCs), show stem cell characteristics including being capable of self-renewal and differentiation. The motivation for targeting cancer stem cells is that if all cancer stem cells are killed, the tumor will no longer have cells which can self-renew and differentiate, and the tumor will regress as the life cycles of differentiated cancer cells expire.
[0069] In embodiments, an oncolytic virus is used as the vehicle for composing a recombinant virus of the present invention. Any virus that can be transcriptionally regulated in terms of replication can be used as a vehicle for the present invention. Such embodiments may include, but are not limited to, members of the Human Herpes family, including but not limited to herpes simplex virus-1 (HSV-1) and herpes simplex virus-2 (HSV-2), adenoviruses, vaccinia virus, vesicular stomatitis virus, poliovirus, reovirus, senecavirus, RIGVIR, Semliki Forest virus, measles virus, Newcastle disease virus, coxsackie virus, Maraba virus, and retroviruses.
[0070] The virus is transcriptionally targeted against cancer cells by replacing the promoter for a gene which controls replication of the virus, such as immediate early genes, with the promoter for a malignant factor. In an exemplary embodiment, the oncolytic virus of the present invention is a recombinant HSV-1. In HSV-1, five proteins collectively referred to as herpes alpha genes, also known as class A genes, are immediate early genes most important in replication of HSV-1. These herpes alpha genes are controlled by promoters and are required for the herpes virus to replicate within an infected cell. Replacing the promoter for a herpes alpha gene with the promoter for a known cancer marker or malignant factor allows the mutated herpes virus to be transcriptionally targeted against cancer cells. In a preferred embodiment, the promoter for infected cell protein-4 (ICP4), also known as HSV-1 alpha-4 gene, is replaced with the promoter for a cancer marker. ICP4 controls of the expression of progeny of HSV-1 and is most important for HSV-1 to replicate. In alternative embodiments, promoters for herpes alpha genes other than ICP4, such as but not limited to infected cell protein-6 (ICP6), infected cell protein-3.54 (ICP34.5), and infected cell protein-27 (ICP27), may be replaced with the promoter for a cancer marker.
[0071] Researchers have identified many different cancer promoters, sometimes referred to as markers, malignant factors, or pro-oncogenic proteins, which are highly expressed within cancer cells. In the present invention, promoters of such cancer markers can be inserted within an oncolytic virus in place of the promoter for a viral gene controlling viral replication to transcriptionally target cancer cells with the oncolytic virus. Embodiments of recombinant viruses of the present invention can utilize any natural or synthetic sequences containing any elements of a cancer gene's promoters capable of driving the expression of a viral gene. Targets which have shown preferential expression in CSCs include surface markers such as CD24, CD34, CD38, CD117, CD44, CD90, CD133, CD271, ABCB5, and EpCAM, which have been shown to indicate a CSC subpopulation within a range of malignancies. Other target embodiments include pathways such as the JAK/STAT, Wnt/-catenin, Hedgehog, Notch, TGF-, Ral, and Ras pathways. Multidrug resistance pump ABC could be targeted or markers of microenvironment such as CXCL12/CXCR4 and VEGF/VEGFR. Further embodiments include promoters involved in expression of Cripto-1, Kpnb1, Enox-1, Enox-2, and 3 integrin and promoters containing Elk-1 binding factor. Additionally, transcription factors such as Oct4, sox2, nanog, Lin-29, KLf-4, c-myc and microRNAs specifically or preferentially expressed in CSCs could be transcriptionally targeted with a virus of the present invention.
[0072] The present invention further covers recombinant lytic viruses as described above further coated with polymers, nanomers, or any combination thereof to improve the efficiency of targeting cells expressing CSC stem cells or other malignant factors. The present invention also covers recombinant lytic viruses as described above further equipped with antibodies, aptamers, receptors, homing devices, or any combinations thereof to improve the efficiency of targeting cells expressing CSC stem cells or other malignant factors.
II. Signal-Smart 2 (SS2) Virus
[0073] In an exemplary embodiment of the present invention, a recombinant HSV-1, referred to herein as Signa-Smart 2 (SS2) virus, is used to target cells expressing CD133. CD133, also referred to as prominin-1, is a surface glycoprotein which has been identified as an important marker of CSCs in many different types of malignancies. CD133 has been shown to be highly expressed in CSCs in medulloblastomas, glioblastomas, colorectal tumors, hepatocellular carcinomas, prostate cancers, melanomas, and malignant peripheral nerve sheath tumors. Circulating melanoma cells have also been identified as CD133 expressing and indicative of poor prognosis. While CD133 is expressed in low levels in differentiated cancer cells and in some other human cells, its highest expression has been shown to be in CSCs, making CD133 expressing cells an effective target for the present invention.
[0074] In this embodiment, the HSV-1 virus is engineered to insert the promoter for CD133 within the virus in place of the promoter for infected cell protein-4 (ICP4) such that the expression of ICP4 is controlled by the promoter of CD133. The CD133 promoter is activated in the presence of expressed CD133. With such an arrangement, ICP4, which controls the expression of HSV-1 progeny and is required for replication of HSV-1, is only expressed in cells which express CD133. Accordingly, this embodiment of a recombinant HSV-1 virus is configured for selectively replicating within and killing cells which express CD133.
[0075]
[0076] To construct a plasmid containing the ICP4 gene controlled by the CD133 promoter, the CD133 promoter was amplified using polymerase chain reaction (PCR) from human genomic DNA, isolated from a cultured Hep3B2 cell. Hep3B2 cells are hepatocellular carcinoma cells which have shown to express high levels of CD133. The CD133 promoter was isolated from utilizing sense and antisense primers having added AgeI and SpeI sites, respectively.
[0077] The pTIIDT plasmid was constructed as described by Pan et al. in Utilizing ras signaling pathway to direct selective replication of herpes simplex virus-1, PLoS One, 2009; 4:e6514, which is incorporated by reference herein in its entirety. The ICP4 gene was amplified from DNA template pGH108 using PCR. The PCR product was inserted into the vector pCR-Blunt-TOPO (Invitrogen, catalog no: K2800-20), and an EcoRI-ICP4-EcoRI fragment was isolated and subcloned into the vector pIRES/DsRed express (Clontech, catalog no: 632463) between CMV and IRES/DsRed genes at the EcoRI single site. This construct is referred to as pIID. Part of the human thymidine kinase (TK) gene was amplified from DNA template pHSV106 using PCR, and the PCR product was then cloned into the vector pCRII-TOPO (Invitrogen, catalog no: K4600-01). A NheI-TK-NheI fragment, TK5, from the TOPO-clone was subcloned into the plasmid pIID, upstream of the ICP4 gene. This construct was designated as pTIID. The 3 segment of the viral TK gene was also amplified from pHSV106 using PCR and subcloned into pCRII-TOPO. A HpaI-TK-HpaI fragment, TK3, was cloned into the plasmid, pTIID, on the 3 of the IRES/DsRed genes at its HpaI single site. This construct was designated as pTIIDT.
[0078] The CD133 PCR fragment was inserted into the pTIIDT plasmid by homologous recombination via AgeI and SpeI restriction sites. This resulting plasmid is referred to as pTKCD133IDT, the structure of which is shown in
[0079] E5 cells were grown in vitro and transfected with pTKCD133IDT using Liprofectamine 2000 (Invitrogen, CA). The cells were infected with the d120 virus 72 hours later. The d120 virus is a mutant HSV-1 void of ICP4-genes, which can produce a recombinant virus once the ICP4 gene is provided in trans by E5 cells. Three days after pTKCD133IDT infected with d120 virus, the virus was harvested. CD133-rich Hep3B2 cells were used for recombinant virus purification to eliminate ICP4 negative virus. The virus was then serially diluted, and a sample from each dilution was tested with Hep3B2 cells. The well with the highest dilution and positive virus signal was determined to contain the isolated virus, named Signal-Smart 2 (SS2) virus. The genomic composition of the recombinant virus was identified and confirmed by different PCR primer pairs (see
[0080] Experiments have shown the SS2 oncolytic virus to preferentially target CD133 expressing cells, particularly when compared to infection by parental HSV-1. Furthermore, the SS2 virus has shown a loss of viability for cells it infects. Reduction in tumor cell population by SS2 virus appears more prominent at later time points, such as five days or more post-infection. This is in contrast to parental HSV-1, which typically kills cells within the first 24 hours post-infection. Further experimentation has shown that infection with SS2 virus has decreased invasiveness of cells cancer cells expressing CD133 and induced apoptosis. The SS2 virus has been shown to inhibit tumor growth in mice, cause tumor regression in mice, and cause tumor regression in an orthotopic mouse hepatocellular carcinoma (HCC) model. Moreover, the SS2 virus did not appear to infect vital, non-malignant organs in mice.
[0081] Tests have shown the SS2 virus to be effective in treatments against hepatocellular carcinoma (liver cancer) colorectal cancers, and melanoma (skin cancer), but SS2 appears likely to be effective for treating any cancer cells which highly express CD133. Treatment with SS2 virus could be conducted via a pharmaceutical composition containing the SS2 virus, injection, infusion, instillation, inhalation or any other form of medical administration. SS2 virus may be used to preferentially target CSCs and/or differentiated cancer cells expressing CD133 in humans or in other mammals.
III. Signal-Smart 3 (SS3) Virus
[0082] In another exemplary embodiment of the present invention, a recombinant HSV-1, referred to herein as Signal-Smart 3 (SS3) virus, is used to target cells expressing Ezh2. A range of malignancies have shown overexpression of Exh2. For instance, Ezh2 is overexpressed in differentiated glioblastoma (GBM) cells and is also highly involved in the biology of GBM stem cells (GSCs). The expression of Ezh2 in a number of well-studied glioma cell lines is shown to be elevated in terms of the amount of protein expressed and the subpopulation of cells positive for Ezh2. GSCs, as studied by sorting for SP cells, were found to be high in Ezh2 expression as compared with non-SP cells. GSCs are proposed to be responsible for not only replenishing the tumor population but also for resistance to chemotherapy, so the ability to target this subpopulation with the SS3 virus is promising. Promoter activity is also universally high in the cell lines that were tested, showing that Ezh2 is readily permissive to the SS3 virus.
[0083] In this embodiment, the HSV-1 virus is engineered to insert the promoter for Ezh2 within the virus in place of the promoter for infected cell protein-4 (ICP4) such that the expression of ICP4 is controlled by the promoter of Ezh2. The Ezh2 promoter is activated in the presence of expressed Ezh2. With such an arrangement, ICP4, which controls the expression of HSV-1 progeny and is required for replication of HSV-1, is only expressed in cells which express Ezh2. Accordingly, this embodiment of a recombinant HSV-1 virus is configured for selectively replicating within and killing cells which express Ezh2.
[0084]
[0085] To construct a plasmid containing the ICP4 gene controlled by the Ezh2 promoter, the Ezh2 promoter was amplified using polymerase chain reaction (PCR) from human genomic DNA, purified from a cultured NCCIT cell. NCCIT cells are embryonic carcinoma cells which express high levels of Ezh2. The Ezh2 promoter was isolated from utilizing sense and antisense primers having added AgeI and SpeI sites, respectively.
[0086] The Ezh2 PCR fragment was inserted into the pTIIDT plasmid, as described above, by homologous recombination via AgeI and SpeI restriction sites. This resulting plasmid is referred to as pTEZH2IIDT, the structure of which is shown in
[0087] E5 cells were grown in vitro and transfected with pTEZH2IIDT using Liprofectamine 2000 (Invitrogen, CA). The cells were infected with the d120 virus, as described above, 72 hours later. Three days after pTEZH2IIDT infected with d120 virus, the virus was harvested. Vero cells were used for recombinant virus purification to eliminate ICP4 negative virus. The virus was then serially diluted, and a sample from each dilution was tested with Vero cells. The well with the highest dilution and positive virus signal was determined to contain the isolated virus, named Signal-Smart 3 (SS3) virus. The genomic composition of the recombinant virus was identified and confirmed by different PCR primer pairs (see
[0088] Experiments have shown the SS3 oncolytic virus to preferentially target Ezh2 expressing cells and reduce their proliferation and invasiveness. The SS3 virus has further been shown to inhibit tumor growth in mice, cause tumor regression in mice, and cause tumor regression in an orthotopic mouse brain tumor model.
[0089] Tests have shown the SS3 virus to be effective in treatments against glioma cells expressing Ezh2, but SS3 appears likely to be effective for treating any cancer cells which highly express Ezh2. SS3 virus may be used to preferentially target glioblastoma stem cells (GSCs) and/or differentiated cancer cells expressing Ezh2 in humans or in other mammals.
[0090] There are a number of possibilities for delivery of the SS3 virus to the site of brain tumors, including methods with and without disruption of the blood-brain barrier. In animal models, an osmotic pump to continuously deliver the virus may be a possibility for convective delivery. Subcutaneous reservoirs with catheters to the tumor bed are possible modes of reintroducing the virus over the postoperative course. Placement of the virus following a laser interstitial thermal therapy (LITT) treatment may also hold promise with a compromise in blood brain barrier. Additionally, novel polymers that hold the virus against the tumor bed wall and dissolve over time hold promise for placing the virus in closest proximity to neoplastic cells. Such advancements in pharmacokinetics of oncolytic viruses enhance their potentials to meet current clinical needs. Effective and specific versions of viruses, such as SS3, which are designed on the basis of cell signaling features of cancer cells can serve as attractive tools for therapy of brain tumors.
[0091] Additional embodiments of the present invention include any chemical modification of the viruses, such as coating the virus with polymers or nanomers to improve the efficiency, specificity, or biodistribution of the virus. Moreover, any chemical modification of these viruses to include antibodies, monoclonal antibodies, or natural or synthetic receptors or aptamers further comprise alternative embodiments of the present invention.
[0092] It is to be understood that while certain aspects, embodiments, and examples of the invention are described and shown herein, the invention is not limited thereto and can assume a wide range of other, alternative aspects, examples, and embodiments.
EXAMPLES
[0093] The following examples are provided to better illustrate the claimed invention and are not to be interpreted as limiting the scope of the invention. To the extent that specific materials are mentioned, it is merely for purposes of illustration and is not intended to limit the invention. One skilled in the art of the invention may develop equivalent means or reactants without the exercise of inventive capacity and without departing from the scope of the invention.
[0094] All values within these examples are expressed as meanstandard deviation (SD) and were analyzed using the two-tailed Student's t-test. p<0.05 was considered significant. The -value was set at 0.05.
Example 1
Construction of Plasmid Containing ICP4 Gene Controlled by CD133 Promoter
[0095] The plasmid pTIIDT, previously described by Pan et al. in Utilizing ras signaling pathway to direct selective replication of herpes simplex virus-1, PLoS One, 2009; 4:e6514, which is incorporated by reference herein in its entirety, was constructed as follows. Using a sense primer, 5-ctcacagctagcttgggtaacgccagggttttc-3 and an antisense primer, 5-actgtatagatctcgcccctcgaataaacaacgc-3, the ICP4 gene was amplified by PCR from DNA template, pGH108. The PCR product (4.2 KB) was then inserted into the vector, pCR-Blunt-TOPO (Invitrogen, catalog no: K2800-20). An EcoRI-ICP4-EcoRI fragment from the TOPO clone was then isolated and subcloned into the vector, pIRES/DsRed express (Clontech, catalog no: 632463), between CMV and IRES/DsRED genes at EcoRI single site. The construct was designated as pIID. Next, part of human thymidine kinase (TK) gene was amplified from DNA template, pHSV106, by using primers, 5-atcgctagctccaagactgacacatt-3 and 5-atgctagcactagtaccggtagtactgctgaggtgggctttggacgtctt-3. The PCR product was then cloned into the vector, pCRII-TOPO (Invitrogen, catalog no: K4600-01). A NheI-TK-NheI fragment, TK5, from the TOPO-clone was then subcloned into the plasmid, pIID, in front of the ICP4 gene. The construct was designated as pTIID. The 3 segment of the viral TK gene was also amplified from pHSV106 by primers 5-gggttaacatttaaatcaggtcgccgttgggggcca-3 and 5-gggttaacaaatgagtcttcggacctc-3 and subcloned into the pCRII-TOPO as mentioned above. The HpaI-TK-HpaI fragment, TK3, was cloned into the plasmid, pTIID, on the 3 of the IRES/DsRed genes at its HpaI single site. This construct was designated as pTIIDT.
[0096] A 1.8 kb fragment containing the CD133 promoter was amplified by nested PCR from human genomic DNA isolated from cultured Hep3B2 cells. The first round of PCR was performed using forward primer 5-aaactgtctttcctggcttc-3 and reverse 5-ttccttaaacatactcaccg-3. The nested PCR was performed using forward primers 5-tgaaccggtcctgcaagcggcacatcagag-3 (AgeI site, underlined, was added to this primer) and reverse primer 5-tgaactagtgcgttagcatcgctttaattcag-3 (SpeI site, underlined, was added to this primer). The PCR fragment containing the CD133 promoter was inserted into the plasmid pTIIDT (Pan et al.), via AgeI and SpeI restriction sites and flanked by 1 kb sequence of HSV-1 thymidine kinase (TK) DNA. The resulting plasmid was named pTKCD133IDT.
Example 2
Generation of the SS2 Virus, an Oncolytic HSV-1 Targeting CD133+ Cells
[0097] E5 cells grown on a 150 mm dish to 80% confluency were transfected with pTKCD133IDT using Lipofectamine 2000 (Invitrogen, CA, USA) according to the manufacturer's instructions. Transfected cells were infected with d120 virus 72 h later. The d120 virus is a mutant HSV-1 void of ICP4-genes, which can produce a recombinant virus once the ICP4 gene is provided in trans by E5 cells, described by Su et al. in Evidence that the immediate-early gene product ICP4 is necessary for the genome of herpes simplex virus type 1 ICP4 deletion mutant strain d120 to circularize in infected cells, J Virol, 2006; 80:11589-11597; by DeLuca et al. in Isolation and characterization of deletion mutants of herpes simplex virus type 1 in the gene encoding immediate-early regulatory protein ICP4, J Virol, 1985; 56:558-570; and by Wu et al. in Prolonged gene expression and cell survival after infection by a herpes simplex virus mutant defective in the immediate-early genes encoding ICP4, ICP27, and ICP22, J Virol, 1996; 70:6358-6369, each of which is incorporated by reference in its entirety. In this stage, recombination of the plasmid with genomic viral DNA (HSV-1 TK with insertion of CD133-promoter-ICP4 gene) results in insertion of recombinant ICP4 gene in the HSV-1 TK gene of the d120 virus and production of the recombinant virus expressing ICP4 under control of the CD133 promoter. The supernatant containing the virus was harvested 3 days later.
[0098] Next, Hep3B2 (hepatocellular carcinoma expressing high levels of CD133) was used for further amplification and purification of the recombinant virus. Briefly, the virus was passed in Hep3B2 cells for three rounds to eliminate any ICP4-negative variants. The last batch of virus was then serially diluted (10.sup.1 to 10.sup.9), and a volume of 500 l from each dilution was added to the duplicate wells of a 24-well plate containing Hep3B2 cells at 80% confluency. The culture was harvested 4 days later. The well with the highest dilution and positive virus signal, determined with PCR for HSV-1 polymerase, was considered to contain the isolated recombinant virus. Using PCR by different primer pairs (
[0099] The oncolytic SS2 virus was constructed on the basis of the d120 system as described above. The virus was purified, characterized, and concentrated; and stocks were stored in a 80 C. freezer in 3% autoclaved non-fat milk. Viral titration was assessed by immunofluorescence microscopy as well as polymerase chain reaction (PCR) and was determined to be 10.sup.7 plaque forming unit (pfu)/ml.
Example 3
SS2 Oncolytic Virus Preferentially Targets CD133+ Cells
[0100] In order to study the specificity of the SS2 virus against CD133+ cancer stem cells, three different models of cancer cells that contained a CD133+ subpopulation were tested. Cell lines UACC257 (melanoma), Caco-2 (colorectal cancer), and Hep3B2 (hepatocellular carcinoma) were used as cells with high levels of CD133 for this study. UACC257 contained 6% CD133+ cells, while Hep3B2 and Caco-2 contained 80% CD133+ cells. Cells with lower percentages of CD133 expression (<1-3%) included melanoma SK103, SW480 colorectal cancer, and human hepatocytes. Each of these cells were infected with the SS2 virus and multiplicity of infection pictures (MOI3) were taken at 48 h post-infection.
[0101] The cells were also subjected to immunofluorescence studies using a monoclonal antibody against glycoprotein-C (gC), a global standard for detection of virus infection and replication. For immunofluorescence analysis, different cells were grown in 8-well slide chambers (Falcon, Calif., USA) and infected with SS2 or HSV-1 (strain F), or mock-infected using 3% autoclaved milk. At different times post-infection, cells were fixed in 100% acetone for 10-15 minutes and left at room temperature to dry before incubation with a fluorescin-labeled mouse monoclonal antibody against HSV-1 gC antigen (Labvision, MI, USA) for 30 min at 37 C. The anti-gC antibody preparation contained Texas Red stain as well. The slides were then washed with distilled water, dried, mounted using a media containing DAPI (4, 6-diamidino-2-phenylindole), viewed with an inverted Olympus DP71 and an attached computer, and processed with appropriate software. Cells were also photographed for their morphology using light microscopy.
[0102] Another important measure of permissiveness to SS2, herpetic protein synthesis, was evaluated by western blotting (
Example 4
Infection with SS2 Oncolytic Virus Results in Loss of Viability
[0103] In the next step, we evaluated the proliferation of cancer cells following exposure to the SS2 virus (MOI2). Cells were plated in 96-well plates and cultured in growth medium overnight. On the following day, the cells were infected with viral particles or 3% autoclaved non-fat milk as a control. At the indicated time points, the proliferation assay was performed using the WST-1 assay (Millipore, MA, USA). As can be seen in
Example 5
Infection with SS2 Oncolytic Virus Results in Loss of Invasiveness
[0104] In the next step, the in vitro invasiveness of infected cells was evaluated using a modified Boyden chamber assay. The cell invasion assay was performed using a BioCoat Matrigel Invasion Chamber (BD Biosciences, MD, USA). Cancer cells were seeded into Matrigel-coated inserts fitting 24-well plates. After 8 h, cells were infected with SS2 at MOI2-3. As the cells infiltrated through the layer of Matrigel in the next 24 h, the fraction of invaded cells attached to the bottom disks were detected by fixing them with 100% methanol and placing them on a slide glass with mounting medium containing 4,6-diamidino-2-phenylindole (DAPI). Quantification was performed by counting the DAPI-stained nuclei on this disk under a fluorescence microscope. Once UACC257 and SK103 cells were infected with SS2 (MOI3), a significant reduction in invasiveness of UACC257 cells was seen at 60 h post-infection (
[0105] In the next step, we tested colorectal cancer cells for invasiveness after exposure to the SS2 virus. As expected, the Caco-2 cells with >70% CD133+ cells were much more inhibited in terms of their invasiveness, compared to SW480 cells with <4% CD133+ cells (
Example 6
Exposure to SS2 Induces Apoptosis
[0106] In many cases, oncolytic viruses destroy cancer cells by the way of necrosis through lytic infection. However, it has also been previously shown that exposure to oncolytic herpes can result in induction of apoptosis in non-permissive cells. Additionally, cells which are less permissive to oncolytic herpes seem to undergo apoptosis at higher levels. Similarly, induction of apoptosis was studied by evaluating the activation of caspase-3 in Caco-2 and SW480 cells after exposure to SS2. In order to evaluate apoptosis, an ApoLive-Glo multiplex assay (Promega, WI, USA) was used. Apoptosis was quantified by caspase-3/7 (a key biomarker of apoptosis) cleavage of a luminogenic substrate containing the tetrapeptide DEVD sequence (Asp-Glu-Val-Asp). Following such caspase-induced cleavage, a substrate for luciferase is released, thus resulting in the luciferase reaction and production of light.
[0107] Both cells showed an increase in apoptosis 24 h post-infection, with SW480 cells, which showed lower permissiveness of SS2 as mentioned above, showing a higher level of caspase activation (
Example 7
SS2 Inhibits In Vivo Growth of Tumors in SC Mouse Model for Melanoma, HCC, and Colorectal Cancer
[0108] In order to evaluate the outcome of targeting CD133+ cells in vivo, we used subcutaneous (SC) xenografts of human cancer cells in male athymic nude mice (Hsd: Athymic Nude-Foxn1.sup.nu 5-7 weeks of age, Harlan, Ind.) purchased from Harlan. In this model, 3-510.sup.6 cancer cells (UACC257, Caco-2, or Hep3B2) were injected in each flank to evaluate the potential growth inhibitory effects of SS2. Cancer cells were grown in vitro, trypsinized, re-suspended, and checked for viability using Trypan Blue/Giemsa staining prior to SC injection. The cells were either mixed with SS2 (MOI3) or with autoclaved 3% milk (vehicle of virus suspension as the control) immediately before SC injection into the mice. Cancer cells (3-510.sup.6) were injected subcutaneously in a 1:1 mixture of growth media/matrigel, with a final injection volume of 100 l, to the flank of each subject bilaterally. The virus-treated cells were injected into the right flank, while the control-treated cells were injected into the left flank. Tumor growth was evaluated over the course of the next 4-10 weeks based on the cell line used. Tumor diameters were measured using a digital caliper on a weekly basis, and tumor volume was calculated by the formula [tumor volume (mm.sup.3)=(length [mm])(width [mm])0.52]. At the end point of the study, the animals were terminated and tumors were extracted, measured, and photographed.
[0109] Individual tumor sizes and averages for each group are shown in the charts in
Example 8
SS2 Causes Regression in Established Melanoma Tumors
[0110] In this example, the potential of the SS2 virus to cause tumor regression in previously established tumors was studied in male athymic nude mice (Hsd: Athymic Nude-Foxn1.sup.nu 5-7 weeks of age<Harlan, Ind.) were purchased from Harlan. For this model, melanoma UACC257 cells were used to establish SC tumors. 2.510.sup.6 cells were injected subcutaneously, and subsequent tumor development was followed by using a digital caliper. Once tumors reached 80-100 mm.sup.3, an injection of 510.sup.6 pfu/50 l was administered to the tumors on the right side (test group), while the left side tumors (control group) were injected with 50 l of 3% autoclaved milk. The injections on each side were repeated on a 3-day interval for a total of 5 injections for both sides in four subjects. Following this treatment, tumor growth was monitored for 60 days after the initial injection. At the conclusion of the 60-day period, all animals were sacrificed, and the tumors were excised, measured and photographed.
[0111] In the next step, it was important to investigate the replication of SS2 in treated tumors. Once extracted, tumors for this model were stained for CD133 expression. A significantly lower level of this marker (
[0112] The replication of SS2 in treated tumors was also studied. As shown in
Example 9
SS2 Causes Regression in Orthotopic Mouse HCC Model
[0113] Systemic therapy using oncolytic viruses is a major clinical need because many tumor types are accessible mainly via systemic routes. In an effort to model systemic treatment using SS2, human-in-mouse orthotopic xenograft for HCC were used. An important feature of the cell used for this experiment, HepG2Luc, is the fact that it's only 4-6% positive for CD133. HepG2 cells were exposed to SS2 in-vitro (MOI3.0) for up to 9 days post-infection with a significant loss of viability observed as early as 3 days post-infection (
Example 10
SS2 does not Infect Vital Organs in Immune-Deficient Mice or Non-Malignant Human Kidney Cells
[0114] An important question for future use of SS2 virus is if this virus is capable of targeting vital organs and inducing toxic effects once injected systemically. To study this, the SS2 virus was injected into a cohort of three athymic nude mice (6-8 weeks of age) for 13 weeks with a weekly dose of 1.410.sup.7 pfu/week via IV and compared that with the regular course of animal growth. No signs of morbidity were observed, and the average weight of the animals was not affected by such therapy (
Example 11
Cell Culture
[0115] E5 and Vero cells (American Type Culture Collection, ATCC, VA), human fetal astrocytes (Lonza, MD) and glioma cell lines (ATCC) were grown in Dulbecco's Modified Eagle's Medium (DMEM) (Sigma-Aldrich, MO) with 10% fetal bovine serum (Thermo Fisher Scientific, MA) and 1% penicillin and streptomycin (Sigma-Aldrich) at 37 C., 5% CO.sub.2 and 95% relative humidity. NCCIT cells (ATCC) were grown in Roswell Park Memorial Institute (RPMI)-1640 media with 10% FBS and antibiotics under similar incubation conditions. U87 expressing luciferase (U87MGLuc) were obtained from Perkin Elmer (OH) and grown in DMEM 10% FBS. Cells were passaged at 70-80% confluency
Example 12
Construction of Plasmid Containing ICP4 Gene Controlled by Ezh2 Promoter
[0116] A 1.1 kb fragment (1,143 bps, sequence spanning 1,095 to +48)(Poulsen et al., 2008) of the human EZH2 promoter was amplified by nested PCR from human genomic DNA purified from cultured NCCIT cell (ATCC: CRL-2073). First round PCR primers were: sense 5-tgcagaggcggcaagtgaacag-3 and antisense ttctgagtcccaccgggtgtcg-3. Second round PCR primers were: 5-taccggtgaactacgaacagtgg-3 (sense, AgeI site was created, underlined letters) and 5-tactagtcggaccgagcgccaaac-3 (antisense, SpeI site was created, underlined letters). The PCR fragment was inserted into pTIIDT (Pan et. al, 2009, as described above in Example 1) between the HSV-1 thymidine kinase (TK)-5 DNA and ICP4 gene via AgeI and SpeI restriction sites. The resulted plasmid was named as pTEZH2IIDT (
Example 13
Generation and Purification of SS3 Virus
[0117] E5 cells were transfected with pTEZH2IIDT using Lipofectamine 2000 (Thermo Fisher Scientific; Invitrogen, CA) according to the manufacturer's instructions. Cells were infected with d120 virus 72 hours later, thereby creating a recombinant herpes virus expressing the ICP4 gene under control of the human EZH2 gene promoter. The virus was harvested 3 days post infection. Vero cells were used for recombinant virus purification. The virus was passed in Vero cells for three rounds to eliminate ICP4-negative variants. The last batch of virus was then serially diluted (10.sup.1 to 10.sup.), A volume of 500 L from each dilution was added to duplicate wells in a 24-well plate (BD Biosciences, CA) containing Vero cells (80% confluency) after removal of existing media. The cell culture was harvested 4 days later. The well with the highest dilution and positive virus signal by HSV polymerase was considered to contain the isolated virus (10.sup.6). Viral titration was performed through immunofluorescence microscopy. The virus was stored in autoclaved 3%-nonfat milk at 80 C. with various concentrations between 1-610.sup.4 particles per microliter (L).
[0118] The genomic composition of this recombinant virus was identified and confirmed using PCR by different primer pairs (
Example 14
Restriction Analysis of Viral DNA
[0119] Viral DNA was purified as previously described in (Pan et al., 2009). E5 cells were grown up in a 10 cm culture dish and infected with the SS3 virus, and the infected cells were harvested when maximum cytopathic effects (CPE) were observed. Cells were then lysed by three freeze-thaw cycles with a dry ice ethanol bath. After spinning at 5000 rpm 4 C. for 10 minutes, the supernatant was treated with RNase A and DNase I at 37 C. for 2 hours, and subsequently, it was treated with protease K and Sodium dodecyl sulfate (SDS) at 56 C. for 1 hour. Viral DNA was then purified by a Qiagen DNeasy Blood & Tissue Kit (Cat. No. 69506) according to manufacturers' instructions. Purified viral DNA was digested with restriction enzyme BamH1 and analyzed in 1% agarose gel. Pattern similarities in restriction maps between SS3, d120, and parental HSV-1 indicated that there were no major differences in overall genomic structure between the viruses (
Example 15
Ezh2 is Highly Expressed in GBM Cells but not in Non-Malignant Human Astrocytes
[0120] In order to confirm the increased expression of Ezh2 in GBM, five well-studied and widely-used glioma cell lines were examined along with fetal human astrocytes (feHA). Western blotting showed high levels of protein across all cancerous cell lines but not in feHA (
[0121] Further examination by flow cytometry showed that in cancer cell lines, the proportion of cells expressing Ezh2 ranged from 65.3% to 99.9% (
[0122] Further, Ezh2 promoter activation was analyzed using a luciferase reporter assay.
Example 16
Ezh2 Expression is Higher in Side Population (SP) of Glioma Cells as Compared with Non-Side Population Cells (Non-SP)
[0123] SP cells are a sub-population of cells that are different from the main population on the basis of characteristics used for their isolation. In this study, the efflux capacity of cells was used against DCV in order to sort cells with high efflux (SP cells) that are enriched in glioma stem cells (GSCs). Cells with low efflux are considered to be of differentiated nature and are referred to as non-SP cells. Glioma stem cells (GSCs) were sorted with a modified version of the Hoechst side population (SP) analysis, using Vybrant DyeCycle Violet (DCV) (Thermo Fisher Scientific) as described previously (Mathew et al., 2009; Telford et al., 2007). U251 glioma cells were passaged at 80-90% confluency from 100 cm cell culture dishes and suspended in DMEM for 15 minutes at 37 C. Verapamil (Sigma-Aldrich) 50 M was added to the efflux pump inhibitor control group and incubated for 15 minutes. Afterwards, DCV 10 M was added to all groups and incubated for 90 minutes at 37 C. with frequent agitation. Cells were then pelleted by centrifugation and re-suspended in an ice-cold SP buffer (Hank's Balanced Salt Solution [HBSS] containing 2% FBS and 2 mM 4-[2-hydroxyethyl]-1-piperazineethanesulfonic acid [HEPES] buffer). 7-amino-actinomycinD (7-AAD) (Thermo Fisher Scientific) was added for viability assessment. SP cells were sorted using a BD FACSAria cell sorter (BD Biosciences). Both SP and non-SP cells were lysed for enzyme-linked immunosorbent assay (ELISA).
[0124] Once analyzed in U251 cells, isolated SP cells examined by ELISA expressed 55% higher levels of Ezh2 (1.630.04 ng/ml) as compared with non-SP cells (1.050.07 ng/ml) (p=0.009,
Example 17
SS3 Virus Targets GBM Cells and Reduces their Proliferation and Invasiveness
[0125] The expression of HSV-1 envelope protein glycoprotein-C (gC) is used as an established marker for replication of the virus. Three GBM cell lines were analyzed with immunohistochemistry (IHC) for expression of gC (green fluorescence, FITC) after being exposed to the SS3 virus (MOI3) or a control (3% autoclaved nonfat-milk as the vehicle for SS3) for 36 hours. As displayed in
[0126] The profile of SS3 viral proteins produced in GBM cell lines is shown in
[0127] Next, the outcome of SS3 replication on viability and invasiveness of cancer cells was evaluated.
[0128] Classical signs of infection such as rounding and clumping were observed as early as 2-3 days post-infection for Gli36 cells, as shown in
[0129] Additionally, cell invasion (evaluated by a modified Boyden chamber assay) was severely inhibited at early time post-infection (20 hours) when viability of cells is not affected. Assays of U118 and U251 showed reduction of invasiveness to 42.325.7 (p=0.05) and 22.913.3 (p=0.001) percent of control, respectively (
Example 18
SS3 Virus Inhibits the Growth of Mouse Glioma Cells but not Non-Malignant Mouse Astrocytes
[0130] The RCAS/TVA (replication competent ALV-LTR, splice receptor/Tumor Virus A) system has been successfully utilized to model gliomas. In this model, the TVA receptor is expressed from the nestin promoter (N-TVA) restricting its expression to neural and glial stem and progenitor cells. Mutant Kras (G12D) expression combined with either Akt activation or deletion of the Ink4a/Arf locus in N-TVA; Ink4a/Arf.sup.lox/lox mice results in the generation of high-grade gliomas. To evaluate the effects of SS3 on mouse glioma cells, three different cell types were tested: 1-Kras.sup.G12D/Akt expression along with Ink4a/Arf deletion, named as MC41-Kras/Akt/Cre glioma cells; 2-EGFRvIII/Akt expression along with Ink4a/Arf deletion, named as EGFRvIII/Akt/Cre glioma cells; and 3-Ink4a/Arf deletion, named as MC41-Cre cells, which are considered non-transformed background cells.
[0131] Since the SS3 virus is constructed with the human Ezh2 promoter, it was important to determine if this promoter is active in mouse glioma cells. This was tested by transfecting cells with a reporter construct expressing luciferase from the human Ezh2 promoter in comparison to expression of luciferase from the cytomegalovirus (CMV) promoter as a constitutive promoter. As shown in
[0132] Flow cytometry data showed that all three cell lines contained Ezh2+ cells (
Example 19
SS3 Infection Prevents Tumor Development in Subcutaneous (SC) Mouse Model
[0133] The SS3 virus' ability to combat the growth of U87 cells in-vivo was studied in a preventative mouse model. For this purpose, 1.510.sup.6 U87 cells (1:1 media/matrigel) were mixed with the SS3 virus (MOI3) or a control (3% autoclaved nonfat-milk as the vehicle for SS3) and injected via SC in the flank area of an athymic male nude mouse (Hsd: Athymic Nude-Foxn1.sup.nu, Harlan, Ind.) at 6-8 weeks of age.
[0134] Tumor cell cultures were passaged, pelleted, and re-suspended in a 1:1 mixture of DMEM/Matrigel (BD Biosciences) and MOI1 of SS3 virus or an equivalent volume of 3% autoclaved nonfat-milk. Two million cells were subcutaneously injected in each flank of the mice, with the left side serving as control and the right side receiving cells that were mixed with SS3. Tumor sizes were measured with digital calipers twice weekly for four weeks. Tumor volume was estimated by the formula: Tumor Volume (mm.sup.3)=lengthwidth.sup.2*0.5. After four weeks, the mice were sacrificed, and the tumors were extracted and re-measured.
[0135] Tumor engraftment and growth in all animal subjects were completely inhibited in the right flank (SS3-treated), while the left flank (control-treated) gave rise to sizeable tumors during 31 days after SC cell inoculation.
Example 20
SS3 Infection Inhibits the Growth of Pre-Established SC Human Tumors in Nude Mice
[0136] To test the SS3 virus for inhibition of pre-established tumors, 2.010.sup.6 U87Luc cells were suspended in a 1:1 mixture of DMEM/Matrigel and injected via SC in the flank area of male athymic nude mice. Tumors were measured twice weekly, and the tumors were allowed to grow to 80-100 mm.sup.3. At this volume, the SC tumors were injected with 610.sup.6 plaque forming unit (pfu) of the SS3 virus (in 100 ml of 3% autoclaved nonfat-milk) on one side while the tumor on the other side was injected with nonfat milk upon reaching the same volume. All tumors received an injection of the SS3 or milk on a weekly basis up to 6 injections, and the tumor volume was measured up to 6-10 weeks post initial cell inoculation. The mice were sacrificed when the tumor burden and disease process impacted quality of life or reached >250 mm.sup.3 as determined by IACUC protocol. Tumors were extracted, re-measured, and graphed for their growth curve and also averages. The radiance of SC tumors was evaluated by injecting 0.3 ml of 15 mg/ml of luciferin solution 10 minutes ahead of IVIS imaging. The luminescence of U87Luc cells (represented by region of interest or ROI) was detected using IVIS (IVIS SpectrumCT Pre-clinical In Vivo Imaging System) following injection of the luciferin solution and graphed as photons/s.sup.1cm.sup.2sr.sup.1.
[0137] A shown in
Example 21
Single Injection of SS3 Inhibits Intracranial Tumor Progression
[0138] Intracranial injection of U87Luc (310.sup.5/6 L injection) cells were used to establish orthotopic tumors in the brain of athymic nude mice approximately 6 weeks of age. For each mouse, after proper anesthesia, a 1 cm longitudinal incision was made. The bregma was identified, and a small burr hole was made 2 mm lateral and 1 mm posterior. Using a Kopf stereotactic frame, 6 microliters of the U87 cells solution was carefully injected 2.5 mm deep into the brain. The burr hole site was judiciously observed to make sure that fluid was not refluxing out of the syringe. After completion of the injection, the syringe was left in place for 1 minute prior to withdrawal. The mouse was removed from the stereotactic frame and veterinary tissue glue was used to close the incision. The mouse was then placed on a heating pad until the animal woke up.
[0139] At two weeks post cell inoculation and confirmation of tumor growth by IVIS, the mice received a single injection of SS3 (2.010.sup.5 pfu/20 L) or control (milk) at the approximate same location of original intracranial tumor cell inoculation. Each mouse was sufficiently anesthetized using isoflurane, first in an induction chamber and then attached to a mouse gas anesthesia head holder through which the mouse continued to receive isoflurane. The previous incision was reopened, and the burr hole was visualized. Either virus or milk was aspirated into a Hamilton syringe, which was then injected through the burr hole using the stereotactic frame. 20 microliters of SS3 or control was slowly injected 2.5 mm deep into the brain. The incision was then reclosed using veterinary tissue glue. The mouse was removed from the head holder and placed on a heating pad and monitored until recovery from anesthesia.
[0140] Intracranial tumors were imaged using IVIS at 1 week post treatment. A reduction in the radiance of intracranial tumors was observed once tumors before and after therapy were compared.