Efficacy and safety evaluation of human reovirus type 3 in immunocompetent animals: racine and nonhuman primates.

PURPOSE: Human reovirus type 3 has been proposed to kill cancer cells with an activated Ras signaling pathway. The purpose of this study was to investigate the efficacy of reovirus in immunocompetent glioma animal models and safety/toxicity in immunocompetent animals, including nonhuman primates. EXPERIMENTAL DESIGN: Racine glioma cells 9L and RG2 were implanted s.c. or intracranially in Fisher 344 rats with or without reovirus antibodies, followed by treatment of reovirus. To study whether reovirus kills contralateral tumors in the brain and to determine viral distribution, we established an in situ dual tumor model followed by reovirus intratumoral inoculation only into the ipsilateral tumor. To evaluate neurotoxicity/safety of reovirus, Cynomolgus monkeys and immunocompetent rats were given intracranially with reovirus, and pathological examination and/or behavioral studies were done. Viral shedding and clinical biochemistry were systematically studied in monkeys. RESULTS: Intratumorally given reovirus significantly suppressed the growth of both s.c. and intracranially tumors and significantly prolonged survival. The presence of reovirus-neutralizing antibodies did not abort the reovirus' antitumor effect. Reovirus inhibited glioma growth intracranially in the ipsilateral but not the contralateral tumors; viral load in ipsilateral tumors was 15 to 330-fold higher than the contralateral tumors. No encephalitis or behavioral abnormalities were found in monkeys and rats given reovirus intracranially. No treatment-related clinical biochemistry changes or diffuse histopathological abnormality were found in monkeys inoculated intracranially with Good Manufacturing Practice prepared reovirus. Microscopic changes were confined to the region of viral inoculation and were dose related, suggesting reovirus intracranially was well tolerated in nonhuman primates. CONCLUSIONS: These data show the efficacy and safety of reovirus when it is used in the treatment of gliomas in immunocompetent hosts. Inoculation of reovirus into the brain of nonhuman primates did not produce significant toxicities.     

Effects of lipid association on lomustine (CCNU) administered intracerebrally to syngeneic 36B-10 rat brain tumors

A syngeneic, intracerebral rat brain tumor model was developed and characterized and then used to evaluate the therapeutic enhancement of lipid-associated 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU). The Fisher rat glioma cell 36B-10 (100,000-500,000 cells) was implanted intracranially to Fisher F-344 rats into the caudate nucleus. Animals treated with lipid-associated CCNU showed a 2- to 10-fold decrease in tumor size compared with animals treated with free CCNU, indicating that lipid association increases the therapeutic index of intracerebral CCNU treatment. Moreover, the syngeneic rat brain tumor model may be useful for evaluation of other therapeutic modalities.     

Response of brain specific microenvironment to P-glycoprotein inhibitor: an important factor determining therapeutic effect of P-glycoprotein inhibitor on brain metastatic tumors

P-glycoprotein (P-gp), a factor responsible for the multidrug resistance of tumors, is specifically expressed in brain microenvironment. To test its roles in brain metastatic tumor chemoresistance, we implanted the paclitaxel-sensitive melanoma cell line, K1735, into the skin or brain of mice and examined its paclitaxel resistances. When implanted into the skin, paclitaxel inhibited tumor growth, however, it had no inhibitory effect on cells implanted into the brain. The paclitaxel resistance of the brain K1735 tumors was eliminated by combined treatment with a P-gp inhibitor, HM30181A, and paclitaxel. Previously we found that there is a defined therapeutic window for combined treatment of brain tumors with HM30181A and paclitaxel. To determine whether it is due to responses of the brain microenvironment we measured changes in P-gp expression and function of brain endothelial cells in response to HM30181A treatment in vitro and in vivo. They were significantly increased by high-dose HM30181A treatment and it was related with the therapeutic effect loss of high-dose HM30181A treatment. Therefore, P-gp in the brain microenvironment has crucial roles in the brain metastatic tumor chemoresistance and brain microenvironment responses to P-gp inhibitor treatment should be considered in the development of brain endothelial cell-targeted chemotherapy using P-gp inhibitor.     

Genetically engineered neural stem cells migrate and suppress glioma cell growth at distant intracranial sites

Our previous study demonstrated successful treatment of an established rat brain tumor through the bystander effect by intra-tumoral injection of neural stem cells transduced with herpes simplex virus-thymidine kinase gene (NSCtk) followed by systemic ganciclovir (GCV) administration (NSCtk therapy). Since glioma has a strong tendency to infiltrate into surrounding brain tissue and that is one of the main causes of local treatment failure, we, in the present study, injected NSCtk cells at distant sites of rat brain tumors and evaluated migratory potential of NSCtk toward the tumor and anti-tumor effects of the NSCtk therapy of this experimental setting. NSCtk cells were intracranially implanted either at 2mm medial in the ipsilateral hemisphere or at the mirror point in the contralateral hemisphere to the C6 rat glioma cell implantation. Active migration of NSCtk cells toward C6 cells was observed even when NSCtk cells were implanted in the contralateral hemisphere. When GCV was systemically administered, growth of intracranial tumor was markedly inhibited and the survival was significantly prolonged through the bystander effect by NSCtk cells migrated from distant injection sites of the tumor. The results of the present study suggest that NSCtk therapy is still effective in the area far from the NSCtk injection site and, therefore, suitable for treatment of malignant gliomas that deeply infiltrate and widely disseminate in the brain.     

Carbonate and carbamate derivatives of 4-demethylpenclomedine as novel anticancer agents

Purpose  The purpose of this investigation was to synthesize a series of carbonate and carbamate derivatives of 4-demethylpenclomedine (DM-PEN), the major plasma non-toxic metabolite of penclomedine (PEN) seen in patients. DM-PEN has been observed to be an active antitumor agent in mouse human xenograft tumor models and non-neurotoxic in a rat model, however, activity in intracranially implanted human glioma xenograft models have not been reported. The major goal was to identify derivatives that are active in brain tumors. Methods  Derivatives were prepared from DM-PEN and evaluated in vivo against human U251 glioblastoma, D54 glioblastoma and MX-1 breast tumor xenografts and mammary tumor 16/C that were implanted in the mammary fat pad or intracranially (IC). Results  Carbonate and carbamate derivatives were found to be superior to DM-PEN against IC growing human glioblastoma xenografts. Conclusion  The activity of the carbonates and carbamates against human tumor xenografts in vivo suggests consideration of these two series of derivatives of DM-PEN for clinical development.     

Regression of orthotopic brain tumors by cytokine-assisted tumor vaccines primed in the brain.

This study investigated the therapeutic effects of a rat glioma cell line, C6, that was engineered to secrete mouse GM-CSF (mGM-CSF) on intracerebral (i.c.) brain tumors. Significant antitumor immunity was induced in rats when the live or irradiated mGM-CSF-secreting tumor vaccine was implanted i.c. The antitumor activity was effective on small tumors and, to a lesser extent, on large tumors or tumors existing in vivo for a longer duration. Immunohistochemical analysis revealed cellular infiltrates (granulocytes, macrophages, and CD4+ and CD8+ T cells) at both the vaccine site and the tumor site, indicating that immune responses were similarly activated when tumor vaccine was inoculated in the brain, as at the subcutis. Additional studies demonstrated that the therapeutic effects of tumor vaccines on the large tumors or the long-existing tumors were enhanced by strategies such as increasing the dosage of tumor vaccines, using combined vaccines consisting of mGM-CSF and human interleukin-2, or combining tumor vaccine with herpes simplex virus thymidine kinase/ganciclovir treatment. All of the modified strategies yielded synergistic therapeutic effects on the large tumor burdens. The data presented herein suggest that cytokine gene therapy is highly promising for the treatment of i.c. gliomas.     

Enhancement of cisplatin efficacy by thalidomide in a 9L rat gliosarcoma model

With the aim of improving the treatment of glioblastoma multiforme, we investigated the potential of thalidomide to enhance the effectiveness of cisplatin chemotherapy in a rat glioma model. Female F344 rats were implanted with 9L gliosarcoma tumors either intracranially or subcutaneously and treated with 1 mg/kg cisplatin injected i.p. or with 1% thalidomide in the food or with these treatments combined. Cisplatin in combination with thalidomide significantly reduced both the subcutaneous tumor volume at 30 days to 22 ± 5% (mean ± SEM, P < 0.001) and the intracranial tumor volume at 18 days to 44 ± 15% (P < 0.05) of that with cisplatin alone. Thalidomide selectively increased the cisplatin concentration 10–fold in intracranial tumors (P < 0.05) and 2-fold in the subcutaneous tumors (P < 0.05) without increasing its concentration in major organs including brain and kidney. Cisplatin combined with thalidomide caused a significant decrease in vascular endothelial growth factor (VEGF) levels by 73% in intracranial tumors (P < 0.05) and by 50% in subcutaneous tumors (P < 0.05) and caused the level of active hepatic growth factor (a-HGF) to double in both the subcutaneous and intracranial tumors (P < 0.05), suggesting this treatment altered the vasculature in these tumors. We conclude the increased efficacy of cisplatin in the presence of thalidomide was due to the selective increase in cisplatin concentration within the tumors and speculate that this is the result of thalidomide or the cisplatin/thalidomide combination, selectively altering the tumor vasculature. Based on the selective effects of thalidomide on tumor cisplatin concentrations and the resulting increase in efficacy, thalidomide may also increase the efficacy of other drugs that are presently considered ineffective against glioma.     

Potential use of prostate specific membrane antigen (PSMA) for detecting the tumor neovasculature of brain tumors by PET imaging with <Superscript>89</Superscript>Zr-Df-IAB2M anti-PSMA minibody

Tumor angiogenesis has attracted increasing attention because of its potential as a valuable marker in the differential diagnosis of brain tumors as well as a novel therapeutic target. Prostate-specific membrane antigen (PSMA) is expressed by the neovasculature endothelium of some tumors, with little to no expression by the tumor cells or normal vasculature endothelium. The aim of this study was to investigate the potential of PSMA for the evaluation of the tumor neovasculature of various brain tumors and the possibility of detecting PSMA expression in brain tumors using PET imaging with ⁸⁹Zr-Df-IAB2M (anti-PSMA minibody). Eighty-three tissue specimens including gliomas, metastatic brain tumors, primary central nervous system lymphomas (PCNSL), or radiation necroses were analyzed by immunohistochemical staining with PSMA antibody. ⁸⁹Zr-Df-IAB2M PET scans were performed in three patients with recurrent high-grade gliomas or metastatic brain tumor. PSMA was highly expressed in the vascular endothelium of high-grade glioma and metastatic brain tumor, whereas PSMA was poorly expressed in the vascular endothelium of PCNSL and radiation necrosis. PSMA expression in high-grade gliomas and a metastatic brain tumor was clearly visualized by PET imaging with ⁸⁹Zr-Df-IAB2M. Furthermore, a trend toward a positive correlation between the degree of ⁸⁹Zr-Df-IAB2M uptake and PSMA expression levels in tumor specimens was observed. PET imaging of PSMA using ⁸⁹Zr-Df-IAB2M may have potential value in the differential diagnosis of high-grade glioma from PCNSL or radiation necrosis as well as in the prediction of treatment efficacy and assessment of treatment response to bevacizumab therapy for high-grade glioma.     

Cationic albumin-conjugated pegylated nanoparticles allow gene delivery into brain tumors via intravenous administration

Patients with malignant gliomas have a poor prognosis because these tumors do not respond well to conventional treatments. Studies of glioma xenografts suggest that they may be amenable to gene therapy with cytotoxic genes, such as the proapoptotic Apo2 ligand/tumor necrosis factor-related apoptosis-inducing ligand (Apo2L/TRAIL). Gene therapy of gliomas ideally employs i.v. given vectors, thus excluding viral vectors as they cannot cross the brain microvascular endothelium or blood-brain barrier. Recently, we reported the synthesis of cationic albumin-conjugated pegylated nanoparticles (CBSA-NP) and showed their accumulation in mouse brain cells upon i.v. administration. In this study, plasmid pORF-hTRAIL (pDNA) was incorporated into CBSA-NP, and the resulting CBSA-NP-hTRAIL was evaluated as a nonviral vector for gene therapy of gliomas. Thirty minutes after transfection of C6 glioma cells, CBSA-NP-hTRAIL was internalized and mostly located in the cytoplasm, whereas NP-hTRAIL was entrapped in the endolysosomal compartment. At 6 and 48 hours after transfection, respectively, released pDNA was present in the nuclei and induced apoptosis. At 30 minutes after i.v. administration of CBSA-NP-hTRAIL to BALB/c mice bearing i.c. C6 gliomas, CBSA-NP-hTRAIL colocalized with glycoproteins in brain and tumor microvasculature and, via absorptive-mediated transcytosis, accumulated in tumor cells. At 24 and 48 hours after i.v. administration of CBSA-NP-hTRAIL, respectively, hTRAIL mRNA and protein were detected in normal brain and tumors. Furthermore, repeated i.v. injections of CBSA-NP-hTRAIL induced apoptosis in vivo and significantly delayed tumor growth. In summary, this study indicates that CBSA-NP-hTRAIL is a promising candidate for noninvasive gene therapy of malignant glioma.     

Identification of the bromosulfophthalein-sensitive efflux route for methotrexate as the site of action of vincristine in the vincristine-dependent enhancement of methotrexate uptake in L1210 cells

The mechanism by which vincristine enhances the uptake of methotrexate in leukemic L1210 mouse cells has been investigated. Methotrexate uptake after 30 min at 37 degrees C increased 44% relative to untreated controls in cells suspended in a 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid/bicarbonate-buffered saline medium containing 20 microM vincristine. This stimulation was half-maximal at a vincristine concentration of 4 microM. An enhancement of methotrexate uptake by vincristine was also observed in the presence of glucose but a reversal could be achieved by prior treatment of the cells with taxol, a drug which prevents microtubule disassembly by vincristine. When the effect of vincristine was determined on the individual influx and efflux components for methotrexate, the increased uptake of methotrexate correlated with the inhibition of the unidirectional efflux route for methotrexate that is sensitive to bromosulfophthalein. Inhibition of this route was half-maximal at 3 microM vincristine and it exceeded 90% at high concentrations of the inhibitor. Transport via the bidirectional exchange carrier for methotrexate was not affected by vincristine, while the unidirectional efflux route sensitive to probenecid was inhibited by vincristine but only at concentrations 10-fold higher than required to inhibit the bromosulfophthalein-sensitive route. Vincristine did not increase methotrexate uptake in CCRF-CEM lymphoblasts, a human cell line which contains much lower levels of bromosulfophthalein-sensitive efflux route for methotrexate. Concentrations of vincristine which inhibited the bromosulfophthalein-sensitive efflux route of L1210 cells by 80-90% had little or no effect on the intracellular pH or on intracellular levels of ATP, GTP, cyclic AMP, K+, or oxidized glutathione. A significant increase was observed in the cellular uptake of tetraphenylphosphonium ions, suggesting that vincristine causes a hyperpolarization of the plasma membrane.     

Expression and functional activity of the ABC-transporter proteins P-glycoprotein and multidrug-resistance protein 1 in human brain tumor cells and astrocytes

The poor prognosis of glioma patients is partly based on the minor success obtained from chemotherapeutic treatments. Resistance mechanisms at the tumor cell level may be, in addition to the blood–brain barrier, involved in the intrinsic chemo-insensitivity of brain tumors. We investigated the expression of the drug-transporter proteins P-glycoprotein (P-gp) and multidrug-resistance protein 1 (MRP1) in cell lines (N=24) and primary cell cultures (N=36) from neuroectodermal tumors, as well as in brain tumor extracts (N=18) and normal human astrocytes (N=1). We found that a considerable expression of P-gp was relatively rare in glioma cells, in contrast to MRP1, which was constitutively overexpressed in cells derived from astrocytomas as well as glioblastomas. Also, normal astrocytes cultured in vitro expressed high amounts of MRP1 but no detectable P-gp. Meningioma cells frequently co-expressed P-gp and MRP1, while, most of the neuroblastoma cell lines express higher P-gp but lower MRP1 levels as compared to the other tumor types. Both, a drug-exporting and a chemoprotective function of P-gp as well as MRP1 could be demonstrated in selected tumor cells by a significant upregulation of cellular ³H-daunomycin accumulation and daunomycin cytotoxicity via administration of transporter antagonists. Summing up, our data suggest that P-gp contributes to cellular resistance merely in a small subgroup of gliomas, but frequently in neuroblastomas and meningiomas. In contrast, MRP1 is demonstrated to play a constitutive role in the intrinsic chemoresistance of gliomas and their normal cell counterpart.     

P-glycoprotein expression in brain tumors

Summary Overexpression of P-glycoprotein (P-gp) in cancer cells can result in resistance to several chemotherapy agents (multidrug resistance) including doxorubicin and vincristine. The drugs to which resistance develops also penetrate the blood brain barrier poorly. P-gp expression in brain capillary endothelial cells suggests that P-gp may restrict drug entry into brain tumors and thus be another mechanism of drug resistance. To seek evidence for either of these roles in the drug resistance of brain tumors, we examined the location of expression of P-gp in 49 brain tumors, using an anti-P-gp mouse monoclonal antibody and immunohistochemistry. P-gp expression was observed in tumor cells of two glioblastomas and a meningeal sarcoma but not in low-grade primary or metastatic tumors. In low-grade primary tumors, P-gp was present in all vascular endothelial cells. In the vascular endothelial cells of anaplastic primary brain tumors and brain metastases, P-gp expression was heterogeneous or absent. These findings are consistent with a role for P-gp in the resistance of some brain tumors to chemotherapy agents.     

Development of a xenograft glioma model in mouse brain

Xenograft intracerebral glioma models have been developed in normal mice by growing the rat C6 glioma in either adult or neonatal mouse brains. Using this tumor line it was possible to grow discrete intracerebral gliomas in either CBA or AKR adult mice or neonatal mice. The size of the tumor mass and length of survival was directly related to the number of tumor cells injected and the time after implantation. To obtain localized intracranial tumor growth cells were suspended in a 1% agarose solution before implantation. Following injection of 10(6) cells into the frontal lobe of adult CBA or AKR mice, discrete tumor masses greater than 4 mm in diameter were obtained in 90% of animals at 14 days, and the largest tumors in adult mice occurred between 21 and 28 days after implantation. The tumor size following implantation of 10(6) cells was significantly greater than with 10(5) cells at 7 days (P less than 0.05) and at 14 and 21 days (P less than 0.01). Less than 60% of mice of BALB/c, RIII, or C57 black strains developed tumors greater than 4 mm diameter at 14 days after intracerebral injection of 10(6) C6 cells. Using neonatal mice it was found that when 10(5) cells were injected intracranially tumors greater than 4 mm in diameter developed in 14 of 15 animals within 2 weeks (CBA mice). Similar results were seen in the RIII, AKR, C57 black, and BALB/c strains. Longer growth periods resulted in larger tumors, up to 8 mm in diameter (6 of 10 animals at 20 days). The tumors in the neonatal animals were not as discrete as in the adult mice, and tumor often spread to the meninges and into the lateral ventricles. The tumor harvested from the brain had a cloning efficiency of 1.2 +/- 0.4% (SD). A panel of monoclonal antibodies was raised to the C6 glioma, and this was used to define clearly the margins of the tumor within the brain. The xenograft mouse models should prove useful for the study of the therapy of gliomas.     

Tumor stromal-derived factor-1 recruits vascular progenitors to mitotic neovasculature, where microenvironment influences their differentiated phenotypes

Mechanisms underlying tumor vasculogenesis, the homing and engraftment of bone marrow-derived vascular progenitors, remain undefined. We hypothesized that tumor cell-secreted factors regulate vasculogenesis. We studied vasculogenic and nonvasculogenic intracranial murine gliomas. A PCR screen identified stromal-derived factor-1 (SDF-1/CXCL12) and vascular endothelial growth factor (VEGF) expression by vasculogenic glioma cells and spontaneously arising vasculogenic tumors in NF1+/-:Trp53+/- mice, but not by nonvasculogenic glioma cells. Enforced SDF-1, not VEGF, expression in nonvasculogenic cells caused vasculogenesis. Combined SDF-1 and VEGF expression augmented vasculogenesis over SDF-1 expression alone. Blocking SDF-1 receptor CXCR4 reduced short-term homing and long-term engraftment of vascular progenitors. Implanting tumor cells secreting SDF-1 was therefore necessary and sufficient to incorporate marrow-derived precursors into tumor endothelium. SDF-1 seemed to exert these effects by acting locally intratumorally and did not cause an efflux of marrow-derived progenitors into circulation. Tumor microenvironment determined additional fates of marrow-derived cells. Hypoxia, observed with ectopic s.c. murine tumors at levels approximating that of intracranial human glioblastoma, interacted with tumor-secreted SDF-1 to expand engrafted vascular progenitor differentiated phenotypes to include pericytes as well as endothelium. In contrast, less hypoxic orthotopic intracranial murine gliomas contained only marrow-derived endothelium without marrow-derived pericytes. Furthermore, we found that vasculogenesis is significant for tumors because it generates endothelium with a higher mitotic index than endothelium derived from local sources. Although CXCR4 blockade selectively targeted endothelium generated by vasculogenesis, completely inhibiting vessel formation may require combination therapy targeting locally derived and marrow-derived endothelium.     

Local intracerebral delivery of endogenous inhibitors by osmotic minipumps effectively suppresses glioma growth in vivo

The systemic administration of endogenous inhibitors significantly reduced the growth of human glioma in vivo, but required the production of a large amount of biologically active protein. In this study we reduced the amount of protein needed and optimized the therapeutical response by delivering the endogenous inhibitors locally into the brain by osmotic minipumps. Human hemopexin fragment of MMP-2 or COOH-terminal fragment of platelet factor-4 were delivered locally and continuously into the brain of mice implanted intracranially with glioma cells, by osmotic minipumps connected to an intracranial catheter. Local delivery of human hemopexin fragment of MMP-2 and COOH-terminal fragment of platelet factor-4 significantly inhibited the growth of well-established malignant glioma in nude and BALB/C mice. When the inhibitors were given at the same concentration, the efficacy of the local delivery was much higher than that reached with the systemic administration, both when the inhibitor was administered daily or continuously by s.c. minipumps. Moreover, the local delivery reduced the amount of protein needed to reach a significant therapeutic response. Intracerebral delivery maintained a long-term control of glioma growth and inhibited glioma recurrence in a surgical resection model. Treatment showed no side effects. Histochemical analysis of tumors showed that the tumor growth inhibition was the result of a decrease in tumor vasculature and a change in tumor vessel morphology. Our data demonstrate that local intracerebral delivery of endogenous inhibitors effectively inhibits malignant glioma growth and reduces the amount of protein needed to reach a therapeutical response.     

Controlled delivery of 1,3-bis(2-chloroethyl)-1-nitrosourea from ethylene-vinyl acetate copolymer

1,3-Bis(2-chloroethyl)-1-nitrosourea (BCNU) has been found to be an effective chemotherapeutic agent against brain tumors. However, because it has a very short half-life in plasma, the exposure of neoplastic cells to BCNU is very brief. The delivery of BCNU may be enhanced by using controlled release polymers. We measured the release of BCNU from ethylene-vinyl acetate copolymer (EVAc) into blood, phosphate buffer, and brain tissue. BCNU-EVAc cylinders that weighed 60 mg were implanted in the peritoneum of rats, and BCNU was detected in blood for 6 days. Studies carried out in vitro showed that BCNU was released from EVAc at a decreasing rate for 195 h. BCNU-EVAc cylinders that weighed 15 mg were implanted either intracranially (i.c.) or i.p. in Fischer 344 rats. Controlled release of BCNU from the i.c. BCNU-EVAc implants was observed over 9 days, with peak drug levels of 49.6 micrograms/g of brain tissue in the implanted hemisphere. The BCNU levels in the contralateral hemisphere and the peripheral circulation were much lower and were detectable for only 1 day. By contrast, peak BCNU levels in the brain from the i.p. BCNU-EVAc implants were 2.7-3.0 micrograms/g for only 12 h, accompanied by peak BCNU levels in blood of 1.0 micrograms/ml tapering over 1 day. These results demonstrate the controlled release of intact BCNU from EVAc in vitro and in vivo. Furthermore, the i.c. implants resulted in localized, prolonged, high levels of the drug in the implanted hemisphere. Hence, the i.c. controlled delivery of BCNU may be more efficacious for the treatment of localized brain tumors.     

Peripheral immunization against malignant rat glioma can induce effective antitumor immunity in the brain

Using two malignant rat glioma cell lines, we tested to what extent peripheral immunization could affect tumor growth in the brain of syngeneic rats. Peripheral subcutaneous (s.c.) immunization was performed with autologous Newcastle-disease-virus (NDV)-infected or non-infected live tumor cells. Thus immunized rats or non-immunized controls were intracerebrally implanted with increasing numbers of the respective malignant glioma cells. Without immunization the mean survival time after intracerebral implantation of 1x10(4) TZ363 or RG2 glioma cells was 9 and 29 days respectively. After s.c. immunization with either NDV-infected or non-infected TZ363 cells only 25% or less of challenged animals developed tumors in the brain. Immunization with NDV only had no effect. In RG2 glioma, s.c. immunization had no effect on tumor growth in the central nervous system and on survival time, no matter what kind of vaccine was used. These results clearly show, that in principle the efferent arm of the anti-tumor response can be effective accross the blood-brain barrier and extend into the microenvironment of the central nervous system. Whether or not glioma lines can induce this immunity and respond to it, seems to depend on their individual immunobiological characteristics.     

The effect of P-glycoprotein on paclitaxel brain and brain tumor distribution in mice

It may be inferred from the presence of P-glycoprotein (Pgp) in brain capillaries that this drug efflux pump is a factor in limiting the penetration of certain agents into brain tumors. However, by contrast with normal brain capillaries which constitute the blood-brain barrier, brain tumor capillaries are compromised or "leaky," and the extent to which Pgp expression in brain tumor neovasculature retains its capacity to limit drug penetration has not been determined. To address this question, we studied the normal brain and brain tumor distribution of paclitaxel (PAC), a known Pgp substrate, using steady-state PAC dosing regimens in wild-type and Pgp knockout (mdr1a -/- and mdr1b -/-) mice bearing an intracerebral B-16 melanoma. At comparable steady-state PAC plasma concentrations of approximately 5 microg/ml, steady-state PAC brain concentrations in Pgp knockout mice were approximately 3-, 1.8-, and 1.7-fold greater in left brain, right brain, and brain tumor, respectively, than in wild-type mice and statistically different (P < 0.05) in each brain region. Determination of the steady-state brain/plasma concentration ratios or partition coefficients, which take into account any differences in plasma concentrations between each group, indicated a similar pattern as did the absolute brain concentrations. It is concluded that even in the neovasculature of brain tumors, Pgp has the facility to limit drug penetration, although somewhat less so than in normal brain.     

Expression of bisecting GlcNAc in pediatric brain tumors and its association with tumor cell response to vinblastine.

Increased expression of the bisecting GlcNAc has been correlated with tumor progression in several experimental tumor models. Its expression and function in brain tumors are, however, not yet known. In this study, we investigated expression of the bisecting GlcNAc structure in a series of pediatric brain tumors and its relationship to tumor response to vinblastine. A plant lectin (E-PHA) that recognizes the bisecting GlcNAc structure was used for detection of this molecule in a total of 90 pediatric brain tumors and normal brain tissue specimens. Our results showed that, whereas E-PHA staining was undetectable in the normal brain tissue, pediatric brain tumor specimens exhibited different levels of reactivity. Lectin staining was particularly prominent in high-grade astrocytomas (73%) and ependymomas (72%). In astrocytomas, there was a positive correlation with the tumor grade, which suggests that the bisecting GlcNAc may be of particular interest as a tumor marker for diagnosis and/or prognosis. By using a human glioma cell culture model, we have found that treatment of these cells with E-PHA lectin enhances their sensitivity to vinblastine. E-PHA interacted directly with the drug transporter P-glycoprotein and inhibited its drug efflux function. In a drug-resistant glioma cell line transfected with the mdr1 gene, drug resistance was reversed by E-PHA. Our findings indicate that: (a) expression of the bisecting GlcNAc in pediatric brain tumors may have a potential relevance as a tumor marker; and (b) glioma response to chemotherapy may be modulated through the bisecting GlcNAc.