Efficacy of oncolytic adenovirus expressing suicide genes and interleukin-12 in preclinical model of prostate cancer.

Oncolytic adenovirus-mediated suicide gene therapy has been shown to improve local tumor control in preclinical tumor models and in the clinic. Although local tumor control is important, for most human cancers, new therapies must also target metastatic disease if they are to have an impact on survival. Here, we test the hypothesis that adding cytokine gene therapy to our multimodal platform improves both local and metastatic tumor control in a preclinical model of prostate cancer. An oncolytic adenovirus (Ad5-yCD/mutTKSR39rep-mIL12) expressing two suicide genes and mouse interleukin-12 (IL-12) was generated. Relative to an adenovirus lacking IL-12 (Ad5-yCD/mutTKSR39rep), Ad5-yCD/mutTKSR39rep-mIL12 improved local and metastatic tumor control in the TRAMP-C2 prostate adenocarcinoma model, resulting in a significant increase in survival. Ad5-yCD/mutTKSR39rep-mIL12 resulted in high levels of IL-12 and interferon gamma in serum and tumor, increased natural killer (NK) and cytotoxic T-lymphocyte lytic activities, and the development of tumor-specific antitumor immunity. Immune cell depletion studies indicated that both the innate and adaptive arms of immunity were required for maximal Ad5-yCD/mutTKSR39rep-mIL12 activity. The results demonstrate that the addition of IL-12 significantly improves the efficacy of oncolytic adenovirus-mediated suicide gene therapy and provide the scientific basis for future trials targeting locally aggressive cancers.

Efficacy of suicide gene therapy in hypoxic rat 9L glioma cells.

Viral vector mediated suicide gene therapy (SGT) involving thymidine kinase (TK) or cytosine deaminase (CD) have considerable promise in the treatment of malignant brain tumors. An unresolved issue is to what extent tumor hypoxia influences the outcome of SGT since brain tumors characterized by regions of hypoxia have potentially reduced cellular metabolism and SGT's cytotoxicity is manifest through cellular metabolism. We studied in vitro and in vivo, the effect of hypoxia on the cytotoxicity of SGT in rat 9L glioma cells. Neither acute nor chronic hypoxia affected the cell killing of SGT by TK or CD. In vivo confirmation that SGT efficacy was not adversely affected by tumor hypoxia using the hypoxic cell marker pimonidazole was shown by the absence of a change in tumor hypoxia by SGT. These studies support the use of SGT utilizing either TK or CD gene strategies even when tumors are characterized by a hypoxic microenvironment.

Polyethylene glycol (molecular weight 400 DA) vehicle improves gene expression of adenovirus mediated gene therapy.

PURPOSE: A significant limitation of adenoviral mediated suicide gene therapy is poor gene distribution in vivo. The choice of vehicle has been demonstrated to affect the level of adenoviral delivered gene transduction. We examined the hypotheses that 1) adenovirus suspended in PEG400 improves gene expression in the naïve canine prostate model, 2) improved transgene expression with PEG400 results in improved tumor control and 3) vehicle affects the initial adenoviral spread from a single intratumor injection. MATERIALS AND METHODS: The magnitude and volume of gene expression were measured 24 hours following intraprostatic injection of adenovirus suspended in PEG400 (12.5% weight per volume) or saline as vehicle. Tumor growth delay was measured in mice bearing human tumor xenografts following the injection of adenovirus in PEG400 and saline. The initial spread of adenovirus was measured by confocal microscopy following a single injection of fluorescently labeled adenoviral particles in human tumor xenografts using each vehicle. RESULTS: Adenovirus suspended in PEG400 provided an average of twice the level of gene expression in the canine prostate and significantly better tumor control relative to saline in preclinical tumor models (p = 0.046 and 0.036, respectively). The initial spread of adenovirus with PEG400 was superior to that of adenovirus in saline and the latter was largely limited to the needle tract. CONCLUSIONS: Adenoviral gene therapy vectors suspended in PEG400 results in improved tumor control because of greater initial adenoviral spread, and the increased volume and magnitude of gene expression in vivo.

Evaluation of the biodistribution, persistence, toxicity, and potential of germ-line transmission of a replication-competent human adenovirus following intraprostatic administration in the mouse.

Adenovirus-mediated gene transfer may hold much promise in the treatment of human cancer. However, concerns regarding vector dissemination beyond the target tissue, particularly with replication-competent viruses, require an evaluation of the persistence of viral infection in collateral tissue and vector-associated toxicities. In addition, for indications such as prostate cancer, the proximity of the point of viral administration to organs of the male reproductive system raises concerns regarding inadvertent germ-line transmission of genes carried by the virus. To address these concerns, the biodistribution, persistence, toxicity, and potential of germ-line transmission of a replication-competent adenovirus (Ad5-CD/TKrep) following intraprostatic administration in the mouse was examined. Ad5-CD/TKrep (10(10) vp, 5 x 10(11) vp/kg) was injected intraprostatically on Day 1 of the study and its presence in the major organs of the male urogenital tract (prostate, testes, seminal vesicles, and urinary bladder) and liver was determined on Days 8 and 29. For comparison, a parallel group of animals was injected with the same dose of a related replication-defective Ad5-FGNR virus. To evaluate germ-line transmission, Ad5-CD/TKrep-injected males were mated to females on Days 8 and 29 and resulting embryos were examined for AdS-CD/TKrep viral DNA. Ad5-CD/TKrep viral DNA was detected in all major organs of the adult male urogenital tract and liver 7 and 28 Days postinjection. Interestingly, relative to the replication-defective Ad5-FGNR adenovirus, the replication-competent Ad5-CD/TKrep virus accumulated to a much greater level (approximately 300-fold) and persisted for a longer period of time in prostate, testes, and liver. This difference could not be explained on the basis of differences in viral infectivity, suggesting that the AdS-CD/TKrep virus may be capable of replicating in mouse tissues in vivo. In vitro infection of six mouse cell lines representing prostate, testes, and liver demonstrated that the Ad5-CD/TKrep virus was indeed capable of replicating in these mouse cell types, albeit with reduced efficiencies relative to human cells. Despite the fact that the Ad5-CD/TKrep vector persisted in the adult male gonads and may have replicated in vivo, we observed no evidence of germ-line transmission in 149 offspring examined. To evaluate the toxicity of combining Ad5-CD/TKrep viral therapy with CD/5-FC and HSV-1 TK/GCV suicide gene therapies as a prerequisite for a human trial, an escalating dose (10(8), 10(9), 10(10) vp) of Ad5-CD/TKrep was administered intraprostatically followed by 7 days of 5-FC and GCV double prodrug therapy. Although the virus persisted in the mouse urogenital tract and liver for up to 28 days postinjection, most of the toxicities observed were expected, minimal, and self-limiting. These results lead us to believe that intraprostatic administration of the Ad5-CD/TKrep virus to humans concomitant with double suicide gene therapy will be associated with acceptable toxicities and will not result in vertical transmission of viral-encoded genes through the germ line.

In vivo antitumor activity of ONYX-015 is influenced by p53 status and is augmented by radiotherapy.

The E1B-deleted, replication-competent ONYX-015 (dl1520) adenovirus was originally described as being able to selectively kill p53-deficient cells due to a requirement of p53 inactivation for efficient viral replication. This hypothesis has become controversial because subsequent in vitro studies have demonstrated that the host range specificity of ONYX-015 is independent of p53 gene status. Using a pair of isogenic cell lines that differ only in their p53 status, we demonstrate here that although ONYX-015 can replicate in both p53 wild-type and mutant cells in vitro, the virus demonstrates significantly greater antitumor activity against mutant p53 tumors in vivo. Moreover, ONYX-015 viral therapy can be combined with radiation to improve tumor control beyond that of either monotherapy. The results demonstrate that ONYX-015 can discern in vivo between tumors having a different p53 status and that it may be an effective neoadjuvant to radiation therapy.

Double suicide gene therapy augments the antitumor activity of a replication-competent lytic adenovirus through enhanced cytotoxicity and radiosensitization.

Replication-competent adenoviruses may provide a highly efficient means of delivering therapeutic genes to tumors. Previously, we evaluated in vitro a replication-competent adenovirus (Ad5-CD/TKrep) containing a cytosine deaminase (CD)/herpes simplex type 1 thymidine kinase (HSV-1 TK) fusion gene that allows lytic viral therapy to be combined with double suicide gene therapy. Both the CD/5-FC and HSV-1 TK/GCV enzyme/prodrug systems enhanced the tumor cell-specific cytopathic effects of the Ad5-CD/TKrep virus in vitro and sensitized cells to radiation. To extend these in vitro findings in vivo, we evaluated the antitumor activity of the Ad5-CD/TKrep virus in combination with double prodrug therapy and radiation therapy. The Ad5-CD/TKrep virus independently demonstrated significant antitumor activity against C33A cervical carcinoma xenografts. Therapeutic outcome was dramatically improved with systemic administration of double, but not single, prodrug (5-FC + GCV) therapy. When used in a neoadjuvant setting, Ad5-CD/TKrep-mediated double suicide gene therapy dramatically potentiated the effectiveness of radiation therapy. The trimodal approach of Ad5-CD/TKrep viral, double suicide gene, and radiotherapies produced significant tumor regression and ultimately 100% tumor cure. The results demonstrate the high therapeutic potential of the trimodal approach and provide a solid foundation for future clinical trials.

Efficacy of adenovirus-mediated CD/5-FC and HSV-1 thymidine kinase/ganciclovir suicide gene therapies concomitant with p53 gene therapy.

Recent evidence has suggested that tumor cells having a wild-type p53 status are more sensitive to chemotherapeutic agents and radiation than cells that lack functional p53. The heightened sensitivity of wild-type p53 cells is thought to be attributable to their propensity to undergo p53-mediated apoptosis after insult. Given that suicide gene therapy is essentially tumor-targeted chemotherapy, we examined the hypothesis that coexpression of wild-type p53 could enhance the efficacy of adenovirus-mediated suicide gene therapy. Human Hep3B and SK-OV-3 cells, which are null for p53, were infected with a pair of replication-deficient adenoviruses that expressed a cytosine deaminase/herpes simplex virus thymidine kinase (CD/HSV-1 TK) fusion gene without (fusion gene nonreplicative adenovirus, FGNR) or with (FGNRp53) the wild-type human p53 gene. The sensitivity of cells to the CD/5-fluorocytosine (CD/5-FC) and HSV-1 TK/ ganciclovir (GCV) enzyme/prodrug systems was determined in vitro and in vivo. Coexpression of p53 did not enhance the cytotoxicity of either the CD/5-FC or HSV-1 TK/GCV system in vitro. The failure to observe an effect of p53 could not be explained on the basis of insufficient or transient p53 expression, because FGNRp53-infected cells growth arrested in G1, induced Bax, and underwent apoptosis at an increased rate after prodrug treatment, particularly when the adenovirus E1A protein was present. Intratumoral injection of FGNRp53 concomitant with single or double pro-drug therapy resulted in a tumor growth delay that was equal to or less than that observed with the FGNR virus. Our results indicate that coexpression of p53 may not necessarily improve the efficacy of adenovirus-mediated CD/ 5-FC and HSV-1 TK/GCV suicide gene therapies in vivo.

Selective radiosensitization of 9L glioma in the brain transduced with double suicide fusion gene.

PURPOSE: Suicide gene therapy has proved to be successful in enhancing the therapeutic index by sensitizing genetically modified tumor cells to prodrugs. Two of the most widely studied suicide genes, herpes simplex virus type 1 thymidine kinase and Escherichia coli cytosine deaminase, have proved effective at selectively eliminating malignant tumor cells. We previously demonstrated that transduced 9L glioma cells expressing E. coli cytosine deaminase and herpes simplex virus type 1 thymidine kinase concomitantly as a fusion protein exhibited greater levels of targeted cytotoxicity and radiosensitization than could be achieved by single suicide gene therapy. The present in vivo studies were carried out to determine whether double suicide gene therapy would enhance the tumor control rate of orthotopically implanted malignant glioma growing in the brain when coupled with radiotherapy. MATERIALS AND METHODS: Rat 9L gliosarcoma cells were transfected with retroviral vectors containing an E. coli cytosine deaminase and herpes simplex virus type 1 thymidine kinase fusion gene and maintained in Dulbecco's modified Eagle's medium. The antitumor response of 9L E. coli cytosine deaminase and herpes simplex virus type 1 thymidine kinase tumors growing in the brain of Fischer rats was evaluated with small tumors (6-day-old tumors) versus large tumors (14-day-old tumors) against single versus double prodrug treatments. In the large brain tumors, the therapeutic efficacy of the combined single and double prodrugs coupled with radiotherapy was evaluated. RESULTS: Double suicide gene therapy using two prodrugs, 5-fluorocytosine (500 mg/kg) and ganciclovir (30 mg/kg), was effective in achieving long-term tumor control (50% survival) against early-stage brain tumors (6 days after implantation) but was only marginally effective against advanced stage tumors (14 days old). However, when these prodrugs were combined with radiotherapy and double suicide gene therapy against advanced-stage tumors, more than 70% of the animals were cured, whereas radiotherapy alone (20 Gy) failed to achieve any cure at all. Combined radiotherapy and single prodrug therapy showed a moderate increase in the animal survival rate (17% and 40% for 5-fluorocytosine and ganciclovir, respectively) but was inferior to the combination therapy of radiation and double prodrugs. CONCLUSION: The present in vivo results indicate that double suicide gene therapy combined with radiotherapy may represent a new, effective approach to achieve a high tumor cure rate without producing any excessive normal tissue damage.

A novel three-pronged approach to kill cancer cells selectively: concomitant viral, double suicide gene, and radiotherapy.

Two obstacles limiting the efficacy of nearly all cancer gene therapy trials are low gene transduction efficiencies and the lack of tumor specificity. Recently, a replication-competent, E1B-attenuated adenovirus (ONYX-015) was developed that could overcome these limitations, because it was capable of efficiently and selectively destroying tumor cells lacking functional p53. In an attempt to improve both the efficacy and safety of this approach, we constructed a similar adenovirus (FGR) containing a cytosine deaminase (CD)/herpes simplex virus type-1 thymidine kinase (HSV-1 TK) fusion gene, thereby allowing for the utilization of double-suicide gene therapy, which has previously been demonstrated to produce significant antitumor effects and potentiate the therapeutic effects of radiation. The FGR virus exhibited the same tumor cell specificity and replication kinetics as the ONYX-015 virus in vitro. Importantly, both the CD/5-FC and HSV-1 TK/GCV suicide gene systems markedly enhanced the tumor cell-specific cytopathic effect of the virus, and, as expected, sensitized tumor cells to radiation. By contrast, neither the FGR virus nor either suicide gene system showed significant toxicity to normal human cells. Both suicide gene systems could be used to suppress viral replication effectively, thereby providing a means to control viral spread. The results support the thesis that the three-pronged approach of viral therapy, suicide gene therapy, and radiotherapy may represent a powerful and safe means of selectively destroying tumor cells in vivo.

Human translocation liposarcoma-CCAAT/enhancer binding protein (C/EBP) homologous protein (TLS-CHOP) oncoprotein prevents adipocyte differentiation by directly interfering with C/EBPbeta function.

Human translocation liposarcoma (TLS)-CCAAT/enhancer binding protein (C/EBP) homologous protein (CHOP) is a fusion oncoprotein found specifically in a malignant tumor of adipose tissue and results from a t(12;16) translocation that fuses the amino-terminal part of TLS to the entire coding region of CHOP. Being that CHOP is a member of the C/EBP transcription factor family, proteins that comprise part of the adipocyte differentiation machinery, we examined whether TLS-CHOP blocked adipocyte differentiation by directly interfering with C/EBP function. Using a single-step retroviral infection protocol, either wild-type or mutant TLS-CHOP were co-expressed along with C/EBPbeta in naïve NIH3T3 cells, and their ability to inhibit C/EBPbeta-driven adipogenesis was determined. TLS-CHOP was extremely effective at blocking adipocyte differentiation when expressed at a level comparable to that observed in human myxoid liposarcoma. This effect of TLS-CHOP required a functional leucine zipper domain and correlated with its ability to heterodimerize with C/EBPbeta and inhibit C/EBPbeta DNA binding and transactivation activity in situ. In contrast, the TLS-CHOP basic region was dispensable, making it unlikely that the inhibitory effect of TLS-CHOP is attributable to unscheduled gene expression resulting from TLS-CHOP's putative transactivation activity. Another adipogenic transcription factor, PPARgamma2, was able to rescue TLS-CHOP-inhibited cells, indicating that TLS-CHOP interferes primarily with C/EBPbeta-driven adipogenesis and not with other requisite events of the adipocyte differentiation program. Together, the results demonstrate that TLS-CHOP blocks adipocyte differentiation by directly preventing C/EBPbeta from binding to and transactivating its target genes. Moreover, they provide strong support for the thesis that a blockade to normal differentiation is an important aspect of the cancer process.

Antileukemic activity of TNF-alpha gene therapy with myeloid progenitor cells against minimal leukemia.

Tumor necrosis factor-alpha (TNF-alpha) has exhibited antitumor activity against a variety of tumors in rodents and human tumor xenografts in nude mice, but it has been only marginally effective in cancer patients because of dose-limiting toxicity associated with systemic TNF-alpha therapy. To circumvent toxicity and to test the antileukemic activity against quantitated minimal leukemia, we have cloned human TNF-alpha (HuTNF-alpha) gene in an advanced myeloid progenitor cell line. 32Dcl3 myeloid progenitor cells transfected with HuTNF-alpha cDNA by the retroviral supernatant infection method stably express HuTNF-alpha gene and secrete substantial amounts of HuTNF-alpha. When injected i.v. into irradiated mice, transduced cells could be detected in the marrow but not in spleen or liver 10-12 days later. Injection of 5 x 10(6) transduced cells produced no obvious symptoms of TNF-alpha toxicity (i.e., weight loss, cachexia, or fever) suggesting that TNF-alpha producing cells are well tolerated by the recipient mice. Coinjection of 5 x 10(6) transduced cells and 10(2) or 10(3) 32Dp210 leukemia (BCR/ABL+) cells resulted in inhibition of leukemia development by 10(2) but not 10(3) 32Dp210 cells. An equal dose of nontransduced 32Dcl3 cells was ineffective in inhibiting leukemia progression by 10(2) 32Dp210 cells. Mice that rejected leukemia were BCR/ABL oncogene negative 8 weeks after leukemia cell injection. These data demonstrate the potential for TNF-alpha gene therapy for destroying residual leukemia, without the toxicity of systemic TNF-alpha therapy, following cytoreductive therapy and bone marrow transplant.

Preferential radiosensitization of 9L glioma cells transduced with HSV-tk gene by acyclovir.

The antiviral drug acyclovir, an analogue of purine, was found to selectively enhance the radiosensitivity of rodent tumor cells which were transduced with the herpes simplex virus thymidine kinase gene (HSV-tk). 9L rat glioma cells transduced with HSV-tk and treated with acyclovir (20 micrograms/ml) for 24 hr before or after irradiation were highly sensitive to radiation, as compared with non-transduced glioma cells. When 9L cells transduced with HSV-tk gene were exposed to acyclovir and radiation, the sensitizer enhancement ratio (SER) was 1.6. In vivo, a significant increase in the median survival time of rats with 9L-tk tumors was observed when acyclovir was administered before and after single-dose irradiation, relative to the survival time of similar rats receiving radiation alone. The results show that an antiviral agent can selectively enhance cell killing by radiation in cells transduced with the HSV-tk, and suggest that the addition of HSV-tk gene therapy to standard radiation therapy will improve the effectiveness of treatment for brain tumors.

D-glucose stimulates mesangial cell GLUT1 expression and basal and IGF-I-sensitive glucose uptake in rat mesangial cells: implications for diabetic nephropathy.

The complications of diabetes arise in part from abnormally high cellular glucose uptake and metabolism. To determine whether altered glucose transporter expression may be involved in the pathogenesis of diabetic nephropathy, we investigated the effects of elevated extracellular glucose concentrations on facilitative glucose transporter (GLUT) expression in rat mesangial cells. GLUT1 was the only transporter isoform detected. Cells exposed to 20 mmol/l glucose medium for 3 days demonstrated increases in GLUT1 mRNA (134%, P < 0.002), GLUT1 protein (68%, P < 0.02), and V(max) (50%, P < 0.05) for uptake of the glucose analog [3H]2-deoxyglucose (3H2-DOG), when compared to cells chronically adapted to physiologic glucose concentrations (8 mmol/l). The increase in GLUT1 protein was sustained at 3 months, the latest time point tested (77% above control, P < 0.01). In contrast, hypertonic mannitol had no effect on GLUT1 protein levels. Insulin-like growth factor I (IGF-I; 30 ng/ml) increased the uptake of 3H2-DOG by 28% in 8 mmol/l glucose-treated cells (P < 0.05) and by 75% in cells switched to 20 mmol/l glucose for 3 days (P < 0.005). These increases in 3H2-DOG uptake occurred despite a lack of effect of IGF-I on GLUT1 protein levels (P > 0.5 vs. control). Therefore, hyperglycemia and IGF-I treatment both lead to increases in mesangial cell glucose uptake, and hyperglycemia induces increased GLUT1 expression, which can directly lead to the pathological changes of diabetic nephropathy. The effects of high glucose and of IGF-I to stimulate 3H2-DOG uptake also appear to be additive.

Glioma cells transduced with an Escherichia coli CD/HSV-1 TK fusion gene exhibit enhanced metabolic suicide and radiosensitivity.

To ascertain whether concomitant expression of Escherichia coli deaminase (CD) and herpes simplex virus type-1 thymidine kinase (HSV-1 TK) could mediate greater levels of cytotoxicity beyond that observed with either suicide gene alone, 9L gliosarcoma cells were transduced with a retrovirus encoding a CD/HSV-1 TK fusion gene. The resultant CD/HSV-1 TK fusion protein (CDglyTK) was found to be bifunctional via CD and HSV-1 TK enzymatic assays, and conferred upon cells prodrug sensitivities equivalent to or better than that observed for each enzyme independently (ganciclovir [GCV] and bromovinyldeoxyuridine [BVdU] for HSV-1 TK and 5-fluorocytosine [5-FC] for CD). Simultaneous treatment of CDglyTK-expressing cells with prodrugs specific for HSV-1 TK and CD (GCV/5-FC or BVdU/5-FC) resulted in slight synergistic toxicity, two- to three-fold greater than that expected if the cytotoxic effects of each prodrug were purely additive. More importantly, co-treatment with HSV-1 TK- and CD-specific prodrugs was found to increase greatly the radiosensitivity of CDglyTK-expressing cells. Sensitivity enhancement ratios of 2.44 (GCV/5-FC) and 3.90 (BVdU/5-FC) were achieved. The results suggest that double suicide gene therapy, using a bifunctional CD/HSV-1 TK fusion gene, coupled with radiotherapy may provide a highly efficient means of selectively treating cancer.

Pronounced antitumor effects and tumor radiosensitization of double suicide gene therapy.

The efficacy of HSV-1 thymidine kinase (TK) and Escherichia coli cytosine deaminase (CD) suicide gene therapies as cancer treatments are currently being examined in humans. We demonstrated previously that compared to single suicide gene therapy, greater levels of targeted cytotoxicity and radiosensitization can be achieved in vitro by genetically modifying tumor cells to express CD and HSV-1 TK concomitantly, as a fusion protein. In the present study, the efficacy of the combined double suicide gene therapy/radiotherapy approach was examined in vivo. Nude mice were injected either s.c. or i.m. with 9L gliosarcoma cells expressing an E. coli CD/HSV-1 TK fusion gene. Double suicide gene therapy using 5-fluorocytosine (500 mg/kg) and ganciclovir (30 mg/kg) proved to be markedly better at delaying tumor growth and achieving a tumor cure than single suicide gene therapy, which used 5-fluorocytosine or ganciclovir administered independently. Importantly, double suicide gene therapy was highly effective against large experimental tumors (>2 cm3), reducing tumor volume an average of 99% and producing a 40% tumor cure. Moreover, double suicide gene therapy profoundly potentiated the antitumor effects of radiation. The results indicate that double suicide gene therapy, particularly when coupled with radiotherapy, may represent a highly effective means of eradicating tumors.

Radiosensitization by 5-fluorocytosine of human colorectal carcinoma cells in culture transduced with cytosine deaminase gene.

Recently, use of the suicide gene, cytosine deaminase (CD), has shown a selective antitumor activity of 5-fluorocytosine (5-FC) on human colorectal carcinoma cells grown in vitro and in vivo. We hypothesized that the radiosensitivity of human colorectal carcinoma cells transduced with a retroviral vector encoding the bacterial CD gene would be selectively enhanced by the nontoxic prodrug 5-FC. The radiobiological rationale of using suicide gene therapy is based on the fact that a toxic metabolite of 5-FC, 5-fluorouracil, is a well-known radiation enhancer for the treatment of gastrointestinal and other tumors. 5-FC was found to enhance selectively the radiation cytotoxicity of human colorectal carcinoma cells expressing the CD gene. Colorectal carcinoma cells transduced with the CD gene (WiDr-CD) were highly sensitive to radiation compared with parental cells (WiDr) when exposed to 20 microgram/ml 5-FC for 72 h prior to irradiation. The sensitization enhancement ratio was 2.38. This magnitude of radiation enhancement is comparable to that obtained with 5-fluorouracil. These results suggest that the addition of radiation would substantially improve the therapeutic potential of CD gene therapy for the treatment of locally advanced colorectal carcinomas.

Selective enhancement of radiation response of herpes simplex virus thymidine kinase transduced 9L gliosarcoma cells in vitro and in vivo by antiviral agents.

PURPOSE: To demonstrate in a well-characterized tumor model that the radiosensitivity of tumor cells transduced with a herpes simplex virus thymidine kinase gene (HS-tk) would be selectively enhanced by antiviral agents. METHODS AND MATERIALS: Rat 9L gliosarcoma cells transduced with a retroviral vector containing an HS-tk gene, 9L-tk cells were exposed to various doses of irradiation under either in vitro or in vivo conditions. The radiation sensitizing potential of two antiviral drugs, bromovinyl deoxyuridine (BVdU) and dihydroxymethyl ethyl methyl guanine (acyclovir), was evaluated in vitro. The radiosensitizing ability of BVdU was also evaluated with a 9L-tk tumor growing in the rat brain. Tumors growing in the right hemisphere of rat brains were irradiated stereotactically with single-dose irradiation. RESULTS: The radiation response of 9L-tk cells was selectively enhanced by antiviral agents relative to nontransduced cells. In the cell culture, when a 24-h drug exposure (20 micrograms/ml) preceded radiation, the sensitizer enhancement ratio (SER) for BVdU and acyclovir was 1.4 +/- 0.1 and 1.3 +/- 0.1, respectively. Exposure of cells to 10 micrograms/ml acyclovir for two 24-h periods both pre- and postirradiation resulted in a SER of 1.6 +/- 0.1. In vivo, a significant increase in median survival time of rats with 9L-tk tumors was found when BVdU was administered prior to single-dose irradiation relative to the survival time of similar rats receiving radiation alone. CONCLUSION: An antiviral agent can enhance cell killing by radiation with selective action in cells transduced with the herpes simplex virus thymidine kinase gene. The results suggest that the three-pronged therapy of HS-tk gene transduction, systemically administered antiviral drug, and stereotactically targeted radiation therapy will improve the effectiveness of radiation therapy for the treatment of radioresistant tumors.

Overexpression of glucose transporters in rat mesangial cells cultured in a normal glucose milieu mimics the diabetic phenotype.

An environment of high glucose concentration stimulates the synthesis of extracellular matrix (ECM) in mesangial cell (MC) cultures. This may result from a similar increase in intracellular glucose concentration. We theorized that increased uptake, rather than glucose concentration per se is the major determinant of exaggerated ECM formation. To test this, we compared the effects of 35 mM glucose on ECM synthesis in normal MCs with those of 8 mM glucose in the same cells overexpressing the glucose transporter GLUT1 (MCGT1). Increasing medium glucose from 8 to 35 mM caused normal MCs to increase total collagen synthesis and catabolism, with a net 81-90% increase in accumulation. MCs transduced with the human GLUT1 gene (MCGT1) grown in 8 mM glucose had a 10-fold greater GLUT1 protein expression and a 1.9, 2.1, and 2.5-fold increase in cell myo-inositol, lactate production, and cell sorbitol content, respectively, as compared to control MCs transduced with bacterial beta-galactosidase (MCLacZ). MCGT1 also demonstrated increased glucose uptake (5-fold) and increased net utilization (43-fold), and greater synthesis of individual ECM components than MCLacZ. In addition, total collagen synthesis and catabolism were also enhanced with a net collagen accumulation 111-118% greater than controls. Thus, glucose transport activity is an important modulator of ECM formation by MCs; the presence of high extracellular glucose concentrations is not necessarily required for the stimulation of matrix synthesis.

Murine collagen intron-binding factor I (CIBF-I) is the same protein as transcription factor Oct-1.

The recognition sequence (CIB) of collagen intron-binding factor I (CIBF-I) loosely resembles the consensus octamer-binding motif (OCT). In the present study we investigate whether CIBF-I is actually the OCT-binding protein, Oct-1. Electrophoretic mobility-shift assays (EMSA) demonstrate that a consensus OCT motif effectively competes for CIBF-I binding. CIBF-I and Oct-1 complexes display similar EMSA characteristics, and both factors are detected in nuclear extracts of five different cell types. In addition, pre-incubation of nuclear extracts with antiserum directed against the POU domain of Oct-1 inhibits CIBF-I complex formation. Finally, DNA transfection experiments demonstrate that a single copy of the CIB site is sufficient to stimulate transcription from the SV40 early promoter in NIH 3T3 cells. These results suggest that CIBF-I is the ubiquitously distributed OCT-binding protein, Oct-1, and represent the first report that an octamer-binding protein contributes to the transcriptional activity of a collagen-encoding gene.

Selective enhancement by an antiviral agent of the radiation-induced cell killing of human glioma cells transduced with HSV-tk gene.

The activation of antiviral drugs as a consequence of thymidine kinase expression has been shown in recent years to have potential as a treatment for malignant tumors. It was hypothesized that the property of the drugs that make them effective against viruses and proliferating cells, namely their ability to interfere with the integrity of the DNA, may be exploited to sensitize cells to radiation damage. The antiviral drug, BVdUrd, structurally a pyrimidine analogue, was found to enhance selectively the radiation cytotoxicity of human tumor cells transduced with the HSV-tk thymidine kinase gene. Human glioma cells from the U-251 lineage transduced with HSV-tk and exposed to 40 micrograms/ml of BVdUrd for 24 h prior to irradiation were more sensitive to radiation compared with control cells under the same conditions; the sensitization enhancement ratio was 1.9. The results suggest that the addition of radiation will improve the effectiveness of HSV-tk gene therapy for the treatment of brain tumors.