Tara A. Barone

Neural stem cell detection, characterization, and age-related changes in the subventricular zone of mice.

The mammalian brain contains neural stem cells (NSCs) that allow continued neurogenesis throughout the life of the animal. However, neurogenesis is known to decline during aging and, to the extent that neurogenesis is required for normal CNS function, this may contribute to neurodegenerative disease. Decreased neurogenesis could result from loss of NSCs or dysfunction at some later step, and distinguishing these possibilities is important for understanding the cause of the decline. However, because of the inability to distinguish NSCs from their rapidly dividing progeny in situ, it has not been possible to quantitatively assess the NSC populations in young and old animals. In this report we show that the G1 phase-specific expression of the replication factor Mcm2 is a useful marker for detecting slowly cycling putative NSCs in situ and confirm the identity of these cells using both cytosine β-d-arabinofuranoside (Ara-C) treatment and a double nucleoside analog-labeling technique. The ability to distinguish NSCs from proliferative progenitors has allowed characterization of the expression of several markers including Nestin, Musashi, and GFAP in these different cell types. Furthermore, comparison of the NSC populations in the subventricular zones of young (2-4 months) and old (24-26 months) mice demonstrates an approximately twofold reduction in the older mice. A similar twofold reduction is also observed in the number of neurospheres recovered in culture from old relative to young animals. The reduction in the neural stem cell population documented here is sufficient to account for the reduced level of neurogenesis in old animals.

Antitumor effects of a xenogeneic survivin bone marrow derived dendritic cell vaccine against murine GL261 gliomas

Survivin is a member of the inhibitor of apoptosis protein family. Gliomas and many other tumors express survivin at high levels; whereas, normal fully differentiated cells generally do not. Therefore, survivin represents a tumor-specific target for cancer vaccine therapy. It has been shown that it is possible to produce a MHC-I-restricted cellular immunologic response to survivin vaccines. To study differences in immunogenicity between murine and human survivin proteins, we vaccinated C57BL/6 mice with bone marrow dendritic cells (BMDC) transfected with expression vectors containing the murine and human survivin genes. Mice vaccinated with BMDCs expressing a truncated human survivin protein developed cytotoxic T lymphocyte to subcutaneous GL261 glioma cells and exhibited prolonged tumor-free survival compared to mice vaccinated with BMDCs transfected with vector alone (P<0.01). While mice challenged with intracerebral GL261 cells had increased survival, no cures were observed. In contrast, vaccinated mice that fully resisted subcutaneous tumor challenge were rendered resistant to intracerebral GL261 re-challenge. BMDCs transfected with the full-length human survivin molecule were significantly more effective at prolonging survival than BMDCs expressing the full-length murine survivin gene (P=0.0175). Therefore, xenogeneic differences between human and murine sequences might be exploited to develop more immunogenic tumor vaccines.

Antitumor cytotoxic T-cell response induced by a survivin peptide mimic

Survivin is a tumor-associated antigen with significant potential as a cancer vaccine target. We have identified a survivin peptide mimic containing human MHC class I epitopes and a potential class II ligand that induces a potent antitumor response in C57BL/6 mice with GL261 cerebral gliomas. This peptide is able to elicit both CD8+ CTL and T helper cell responses in C57BL/6 mice. The corresponding region of the human survivin molecule represented by peptide SVN53-67 is 100% homologous to the murine protein, but SVN53-67 is weakly immunogenic in man. We evaluated several amino acid substitutions in putative human MHC I anchor positions in SVN53-67 to identify potential peptide mimics that could provide an enhanced antitumor immune response against human glioma and primary central nervous system lymphoma (PCNSL) cells in culture. We evaluated survivin peptides with predicted binding to human HLA-A*0201 antigen using peptide-loaded dendritic cells from PBMC of patients with these malignancies. One alteration (M57) led to binding to HLA-A*0201 with significantly higher affinity. We compared the ability of autologous dendritic cells loaded with SVN53-67 peptide and SVN53-67/M57 in CTL assays against allomatched and autologous, survivin-expressing, human malignant glioma and PCNSL cells. Both SVN53-67 and SVN53-67/M57 produced CTL-mediated killing of malignant target cells; however, SVN53-67/M57 was significantly more effective than SVN53-67. Thus, SVN53-67/M57 may act as a peptide mimic to induce an enhanced antitumor CTL response in tumor patients. The use of SVN53-67/M57 as a cancer vaccine might have application for cancer vaccine therapy.

Syngeneic central nervous system transplantation of genetically transduced mature, adult astrocytes.

Advances in the development of highly infectious, replication-deficient recombinant retroviruses provide an efficient means of stable transfer of gene expression. Coupled with ex vivo transduction, surrogate cell populations can be readily implanted into the brain, thus serving as vehicles for delivering selected gene products into the central nervous system (CNS). Here we report that rat astrocytes can be routinely and safely isolated from brain tissue of a living donor by use of short-term gelatin sponge implants. The mature, nontransformed astrocytes were easily expanded, maintained in long-term tissue cultures and were efficiently transduced with an amphotropic retrovirus harboring a heterologous, fused transgene. In vitro retroviral infection rendered the nontransformed cells essentially 100% viable after exposure. The level of efficiency of infection (30–50% effective genome integration of provirus and expression of transgene in target cell populations) and minimal cell toxicity obviated the need to harvest large numbers of target cells. Cultured transduced astrocytes were resilient and exhibited select peptide expression for up to 1 year. Subsequently, transduced astrocytes were used in a series of experiments in which cells were transplanted intracerebrally in syngeneic animals. Post-implantation, astrocytes seeded locally and either insinuated into the surrounding parenchyma in situ or exhibited a variable degree of migration, depending on the anatomic source of astrocytes and the targeted brain implantation site. Transduced astrocytes remained viable in excess of 8 months post-transplantation and exhibited sustained transgenic peptide expression of green fluorescent protein/neomycin phosphotransferase in vivo. The sequential isolation and culture of nontransformed, mature, adult astrocytes and recombinant retrovirus-mediated transduction in vitro followed by brain reimplantation represents a safe and effective means for transferring genetic expression to the CNS. This study lays the foundation for exploring the utility of using a human autologous transplantation system as a potential gene delivery approach to treat neurological disorders. Prepared and utilized in this manner, autologous astrocytes may serve as a vehicle to deliver gene therapy to the CNS.

Estrogen increases survival in an orthotopic model of glioblastoma

Despite the male preponderance for developing glial tumors and a body of published literature that suggests a female gender advantage for long term survival in both human and animal studies, there have been relatively few rigorous investigations into the hormonal effects on glial tumor growth. In a previous study, we concluded that estrogen played a major role in the female survival bias seen in an intracerebral nude rat model of glioblastoma multiforme. Here we explore the potential therapeutic effect of exogenous estradiol delivery in nude rats with orthotopic glioblastoma tumors and examine the mechanism of action of estradiol on reducing tumor growth in this animal model. We administered estradiol, in several dosing regimens, to male, female and ovariectomized nude rats in a survival study. Brain sections, taken at various time points in tumor progression, were analyzed for estrogen receptor protein, proliferative index and apoptotic index. Estradiol increased survival of male, female and ovariectomized nude rats with intracerebral U87MG tumors, in a gender specific manner. The estradiol mediated effect occurred early in tumor progression, and appeared to be caused in-part by an increase in apoptotic activity. It remains unclear if estradiol’s effect is direct or indirect and if it is estrogen receptor mediated. Estradiol-based or adjunctive therapy may be beneficial in treating GBM and further study is clearly warranted.

Intratumoral infusion of topotecan prolongs survival in the nude rat intracranial U87 human glioma model

Topotecan is a topoisomerase (topo) I inhibitor with promising activity in preclinical studies. We hypothesized that low-dose intratumoral delivery of topotecan would be highly effective for gliomas. Human glioma cell lines (U87, U138 and U373) displayed different sensitivities to topotecan (IC50 range: 0.037 μM to 0.280 μM) in cell culture. The most resistant of the glioma cell lines (U87) was implanted stereotactically into the brains of nude rats. Twelve days later, at which time tumor diameter measured 2 to 2.5 mm, animals were randomized to three groups: group I, intratumoral topotecan infused via osmotic pump (n = 12); group II, intratumoral saline infusion (n = 7); and group III, no treatment (n = 10). Animals were sacrificed when signs of deterioration developed, or at 60 days. Animals in group I had a mean survival time (MST) of > 55 days (range=40–60); whereas, those in groups II and III had MST of 26.1 (range=21–31) and 26.5 (range = 20–30) days, respectively. The differences in survival between group I and each of the other groups were statistically significant (p < 0.0001; Logrank Mantel-Cox). None of the animals that survived 60 days had histological evidence of residual tumor at sacrifice. Measurement of topotecan levels in normal brain revealed cytotoxic concentrations up to 4.5 mm from the site of infusion. This study demonstrates that intratumoral topotecan delivered via an osmotic pump prolongs survival in the U87 human glioma model.

Neurite outgrowth from PC12 cells is enhanced by an inhibitor of mechanical channels

GsMTx4, a peptide inhibitor for mechanosensitive ion channels (MSCs), promoted neurite outgrowth from PC12 cells in the presence of NGF in a dose-dependent manner between 5 and 100 microM peptide. Enhanced neurite growth required >12 h of peptide exposure in cells grown with NGF. Adsorption of GsMTx4 to serum proteins in the media lowered the free peptide concentration of 100 microM to a free concentration of 5 microM, a concentration shown to completely inhibit MSCs in the patch clamp assay. Outside-out patches from PC12 cells grown in NGF had mechanically activated cation channels that were reversibly inhibited by GsMTx4. These results are similar to those observed by Gomez and co-workers in Xenopus spinal cord. The inhibition of mechanosensitive channels by GsMTx4 may be a useful approach to accelerate regeneration of neurons in neurodegenerative diseases and spinal cord injury.

In vitro assessment of neurotrophic activity from the striatum of aging rats

Neurotrophic factors are produced in the striatum following trauma and have a demonstrable effect on in vitro bioassays and on in vivo graft survival. We have previously measured the in vitro effect of these factors following trauma to the striatum of young rats. However, the effect of age on this neurotrophic response has not been evaluated. In this study we report on the in vitro effects of extracts (obtained from gelfoam) removed from striatal cavities 7 days following trauma. Gelfoam extract from aged rats (18-24 months) had a reduced neurite-promoting response in dorsal root ganglia (DRG) and SH-SY5Y (a dopamine-producing neuroblastoma cell line) assays, compared to gelfoam from young rats (2-3 months). In contrast, extracts from both young and old rats showed significant neuroprotection of SH-SY5Y cells from the dopaminergic neurotoxins N-methy-4phenylpyridinium ion (MPP +) and 6-hydroxydopamine (6-OHDA). The results suggest that the striatum of aged individuals may have (1) a diminished capacity of neurite promotion and/ or (2) that neurite outgrowth and neuroprotection may be influenced by different factors or different levels of the same factors. The direct implication is that aged animals would be the most appropriate models to study experimental therapies for Parkinsons disease.

Anticancer drug candidate CBL0137, which inhibits histone chaperone FACT, is efficacious in preclinical orthotopic models of temozolomide-responsive and -resistant glioblastoma

Background The survival rate for patients with glioblastoma (GBM) remains dismal. New therapies targeting molecular pathways dysregulated in GBM are needed. One such clinical-stage drug candidate, CBL0137, is a curaxin, small molecules which simultaneously downregulate nuclear factor-kappaB (NF-ĸB) and activate p53 by inactivating the chromatin remodeling complex, Facilitates Chromatin Transcription (FACT). Methods We used publicly available databases to establish levels of FACT subunit expression in GBM. In vitro, we evaluated the toxicity and effect of CBL0137 on FACT, p53, and NF-ĸB on U87MG and A1207 human GBM cells. In vivo, we implanted the cells orthotopically in nude mice and administered CBL0137 in various dosing regimens to assess brain and tumor accumulation of CBL0137, its effect on tumor cell proliferation and apoptosis, and on survival of mice with and without temozolomide (TMZ). Results FACT subunit expression was elevated in GBM compared with normal brain. CBL0137 induced loss of chromatin-unbound FACT, activated p53, inhibited NF-ĸB-dependent transcription, and was toxic to GBM cells. The drug penetrated the blood-brain barrier and accumulated in orthotopic tumors significantly more than normal brain tissue. It increased apoptosis and suppressed proliferation in both U87MG and A1207 tumors. Intravenous administration of CBL0137 significantly increased survival in models of early- through late-stage TMZ-responsive and -resistant GBM, with a trend toward significantly increasing the effect of TMZ in TMZ-responsive U87MG tumors. Conclusion CBL0137 targets GBM according to its proposed mechanism of action, crosses the blood-brain barrier, and is efficacious in both TMZ-responsive and -resistant orthotopic models, making it an attractive new therapy for GBM.

A murine model of targeted infusion for intracranial tumors

Historically, intra-arterial (IA) drug administration for malignant brain tumors including glioblastoma multiforme (GBM) was performed as an attempt to improve drug delivery. With the advent of percutaneous neuorovascular techniques and modern microcatheters, intracranial drug delivery is readily feasible; however, the question remains whether IA administration is safe and more effective compared to other delivery modalities such as intravenous (IV) or oral administrations. Preclinical large animal models allow for comparisons between treatment routes and to test novel agents, but can be expensive and difficult to generate large numbers and rapid results. Accordingly, we developed a murine model of IA drug delivery for GBM that is reproducible with clear readouts of tumor response and neurotoxicities. Herein, we describe a novel mouse model of IA drug delivery accessing the internal carotid artery to treat ipsilateral implanted GBM tumors that is consistent and reproducible with minimal experience. The intent of establishing this unique platform is to efficiently interrogate targeted anti-tumor agents that may be designed to take advantage of a directed, regional therapy approach for brain tumors.