Murine Brain Tumor Model Research Articles

TMIC-09. DENDRITIC CELL DYSFUNCTION RESTRICTS TUMOR ANTIGEN SPREADING IN ADOPTIVE CELLULAR TRANSFER THERAPY-ESCAPED GLIOMAS: IMPLICATIONS FOR TUMOR IMMUNE EVASION

Abstract Dendritic cells (DCs) play a pivotal role in initiating anti-tumor immune responses. Our group has developed an adoptive cellular transfer therapy (ACT) that significantly increases the infiltration of DCs and T cells into tumors, markedly enhancing survival in murine brain tumor models. However, tumors develop mechanisms to restrict the immune surveillance and the efficacy of immunotherapy, leading to tumor escape. In this study, we identified a mechanism involving DC dysfunction in ACT-escaped brain tumors. The finding that DCs are enriched after ACT treatment prompts an investigation into whether DC function is impaired in ACT-escaped tumors. Our results showed that DCs from both primary and ACT-escaped tumors were dysfunctional in their ability to activate T cells when co-cultured with tumor-reactive T cells or OT1 T cells. RNA-seq data revealed that, compared to primary tumor DCs, ACT-escaped tumor DCs exhibited a more pronounced reduction in conventional DC markers and antigen-presenting genes, alongside increased tolerance markers. Gene set enrichment analysis indicated that epithelial-mesenchymal transition (EMT) and hypoxia pathways were significantly enriched in ACT-escaped tumor DCs, suggesting divergent DC dysfunction mechanisms in primary versus escaped tumors. The anti-tumor role of DCs is primarily exerted through the activation of tumor-reactive T cells. Therefore, we assessed the cytotoxicity and exhaustion status of T cells in tumors. Surprisingly, we found that T cells from ACT-escaped tumors exhibited significantly higher levels of cytotoxicity and lower levels of T cell exhaustion compared to primary tumors. This suggests a T cell exhaustion-independent mechanism in ACT-escaped tumors. We further demonstrated that T cells in ACT-escaped tumor are mainly sourced from the adoptive transferred T cells, which recognize primary tumor antigens but not escaped tumor antigens. These results suggest that a combined mechanism of tumor antigen shifting and impaired DC function leads to a failure of antigen spreading and tumor eradication.

Development of a murine laser interstitial thermotherapy system.

The objective of this study was to develop a murine system for the delivery of laser interstitial thermotherapy (LITT) with probe-based thermometry as a model for human glioblastoma treatment to investigate thermal diffusion in heterogeneous brain tissue. First, the tissue heating properties were characterized using a diode-pumped solid-state near-infrared laser in a homogeneous tissue model. The laser was adapted for use with a repurposed stereotactic surgery frame utilizing a micro laser probe and Hamilton syringe. The authors designed and manufactured a stereotactic frame attachment to work as a temperature probe stabilizer. Application of this novel design was used as a precise method for real-time thermometry at known distances from the thermal ablative center mass during murine LITT studies. Temperature measurements were achieved during LITT that verified the direct thermometry capability of the system without the need for MR-based thermal monitoring. Application of multiple stereotactic design iterations led to an accurately reproducible surgical laser ablation procedure. Histological staining confirmed precise thermal ablation and controllable lesion size based on time and temperature control. Treatment of a syngeneic intracranial glioma model highly resistant to conventional therapy resulted in a modest survival benefit. The authors have successfully developed a murine model system of LITT with direct in situ thermometry for investigation into the effects of thermal ablation and combinatorial treatments in murine brain tumor models.

Abstract 7458: Inhibition of brain cancer progression via resolution of inflammation

Abstract While inflammation is a hallmark of cancer, the mechanisms that disrupt its resolution in cancer are not well understood. A paradigm shift is emerging in our understanding that the resolution of inflammation is an active process controlled by specialized pro-resolving mediators (SPMs), including protectins and resolvins, which are endogenous lipid autacoids present in multiple tissues including the brain and cerebrospinal fluid. SPMs counter-regulate pro-inflammatory cytokine production and stimulate phagocytosis of cellular debris (“pro-resolution”) without being immunosuppressive. We hypothesized treatment with pro-resolving agonists such as SPMs presents a novel debris-clearing and resolution-enhancing therapeutic approach to complement cytotoxic brain cancer therapies. Here, we demonstrate the failure of resolution of inflammation via dysregulated SPMs may be a critical risk factor for aggressive brain cancer growth. Moreover, chemotherapy and targeted therapy further disrupt inflammation resolution via a tumor cell death (“debris”)-induced cytokine storm by macrophages. The SPM receptors GPR37 (protectin D1), GPR18/DRV2 (resolvin (Rv) D2), GPR32 (RvD1), and ChemR23/ERV (RvE1) are expressed in tumor-infiltrating macrophages and endothelial cells in the brain tumor microenvironment. Plasma levels of SPMs were significantly reduced in the medulloblastoma-bearing mice, suggesting that brain cancer progression is associated with a failure of endogenous resolution of inflammation. To determine whether failed resolution in brain cancer can be rescued by lipid mediator agonists, we systemically administered SPMs to subcutaneous and orthotopic glioblastoma and medulloblastoma murine brain tumor models. Significantly, RvD1 and RvD2 each inhibited the growth of human glioblastoma tumors by 15-fold at nanogram concentrations without toxicity. Likewise, RvD2 inhibited the growth of human medulloblastoma tumors by 3-fold. Protectins, PDX and PD1n-3, each inhibited growth of human medulloblastoma in mice by approximately 5-fold. Systemic administration of PDX or RvD2 prolonged survival of mice injected with orthotopic human D556 medulloblastoma and also glioblastoma models. Flow cytometry analysis of orthotopic glioblastoma tumors revealed increased immune infiltration into the brain tumor microenvironment in the PCTR1-treatment group when compared to the tumor-bearing non-treated group. At nanogram per day doses, protectins and resolvins suppressed orthotopic debris-stimulated brain tumor growth by activating macrophage and microglial phagocytosis of tumor cell debris and counter-regulating pro-inflammatory cytokines, including TNF-α, CCL2, CXCL1, and CCL4. Thus, stimulating the resolution of inflammation via the clearance of cellular debris with pro-resolving agonists represents a novel therapeutic approach to brain cancer, including glioblastoma and medulloblastoma. Citation Format: Jacqueline Capuano, Kimberly Vasquez, Katherine Quinlivan, Rachel Bayer, Sarina Virani, Michael Gillespie, Mark Kieran, Charles Serhan, Diane Bielenberg, Dipak Panigrahy. Inhibition of brain cancer progression via resolution of inflammation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7458.

Transcranial histotripsy parameter study in primary and metastatic murine brain tumor models

Objective This study investigated the effect of various histotripsy dosages on tumor cell kill and associated bleeding in two murine brain tumor models (glioma [Gl261] and lung metastasis [LL/2-Luc2]). Methods and materials GL261 or LL/2-Luc2 cells were cultured and implanted into the brains of C57BL/6 mice. Histotripsy (1-cycle pulses, 5 Hz PRF, 30 MPa-P) was performed using a 1 MHz transducer for five different dosages for each cell line: 5, 20 or 200 pulses per location (PPL) at a single treatment point, or 5 or 10–20 PPL at multiple treatment points. MRI, bioluminescence imaging and histology were used to assess tumor ablation and treatment effects within 4–6 h post-treatment. Results All treatment groups resulted in a reduction of BLI intensity for the LL/2-Luc2 tumors, with significant signal reductions for the multi-point groups. The average pre-/post-treatment BLI flux (photons/s, ×108) for the different treatment groups were: 4.39/2.19 (5 PPL single-point), 5.49/1.80 (20 PPL single-point), 3.86/1.73 (200 PPL single-point), 2.44/1.11 (5 PPL multi-point) and 5.85/0.80 (10 PPL multi-point). MRI and H&E staining showed increased tumor damage and hemorrhagic effects with increasing histotripsy dose for both GL261 and LL/2-Luc2 tumors, but the increase in tumor damage was diminished beyond 10–20 PPL for single-point treatments and outweighed by increased hemorrhage. In general, hemorrhage was confined to be within 1 mm of the treatment boundary for all groups. Conclusions Our results suggest that a lower number of histotripsy pulses at fewer focal locations can achieve substantial tumor kill while minimizing hemorrhage.

Abstract LB344: Complement-mediated signaling during cross-presentation of tumor antigen augments T cell responses

Abstract Production of complement C3a and C5a locally at the immune synapse by activated dendritic cells (DCs) enhances T cell responses in multiple experimental models. Complement signaling through cognate C3a receptor (C3aR) and C5a receptor (C5aR) modulate effector T cell stability, proliferation and differentiation. We have previously shown that complement C3 plays a mechanistic role in driving synergistic anti-tumor effects of blocking indoleamine 2,3-dioxygenase (IDO) during radiation and chemotherapy in a murine brain tumor model that expresses the gp10025-33 peptide antigen. We hypothesize that, when anti-tumor responses are allowed to happen, complement C3 production by local DCs acts as a costimulation factor, operating through C3aR and C5aR on the T cell surface to allow optimal T cell activation and proliferation. To study the role of complement C3 as a costimulation factor during T cell responses against a nominal tumor antigen (gp10025-33 peptide, expressed by B16F10 melanoma), we used T cells from syngeneic pmel-1 mice (TCR transgenic with CD8 T cells that recognize the cross-presented gp10025-33 peptide) co-cultured with gp10025-33 peptide and dendritic cells from either wild-type (WT) or C3-defiecient (C3-KO) mice. In addition, we used in vitro culture conditions where gp10025-33 tumor peptide was in stringent limited supply to model homeostatic conditions of the tumor microenvironment. We found that, when stimulated by DCs from C3-KO mice, pmel-1 CD8 T cells had decreased activation marker expression, proliferation, and cytokine effector function relative to stimulation by DCs from WT mice. Next, we bred pmel-1 mice onto a syngeneic background deficient in receptors for both C3a and C5a complement factors (C3aR-KO/C5aR-KO double knock-out mice). We used CD8 T cells from the resulting mouse strain (pmel-1/C3aR-KO/C5aR-KO) co-cultured with WT DCs to study the role of complement signaling in T cells during responses to tumor antigen. Using the same stringent antigen conditions, CD8 T cells from the pmel-1/C3aR-KO/C5aR-KO mice had decreased activation marker expression and proliferation, and differences in cytokine function compared to CD8 T cells from the pmel-1 mice. These findings suggest that lack of local complement production by the DCs in the tumor microenvironment may inhibit anti-tumor immune responses, and that complement signaling through C3aR and C5aR on T cells may play an important role during such anti-tumor responses. Citation Format: Caryn L. Bird, Gabriela A. Pacholczyk, Theodore S. Johnson. Complement-mediated signaling during cross-presentation of tumor antigen augments T cell responses [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 2 (Clinical Trials and Late-Breaking Research); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(8_Suppl):Abstract nr LB344.

466 Robust Model of Microglia Replacement With Circulation-Derived Microglia-Like Cells (CDMCs) in CNS Malignancies

INTRODUCTION: Tumor-associated microglia and macrophages (TAMs) represent a main cell type of brain malignancies and demonstrate complex interactions with cancerous cells and the tumor microenvironment. These interactions have important implications for the progression and treatment of malignant central nervous system (CNS) tumors. TAMs have therefore emerged as therapeutic targets, though their potential to date has been unfulfilled. METHODS: C57BL/6 mice were preconditioned for BMT with retroorbital busulfan injections (25 mg/kg), and native microglia were depleted via PLX5622 (1200 mg/kg, chow). Following transplantation, animals underwent intracranial stereotactic injection of syngeneic cell lines of either high-grade glioma (GL261) or breast cancer metastasis (E0771). Following animal sacrifice, we used single cell RNA sequencing of CD45-positive cells to profile the transcriptomic identity of glioma tumor-associated CDMCs (TA-CDMCs). RESULTS: Lineage tracing proved high intra- and peri-tumoral chimerism of BMT-graft derived cells among CNS myeloid cells in both models two weeks after tumor cell injection, demonstrating a robust ability to modify the tumor-immune microenvironment in animal models. TA-CDMCs showed a similarly activated morphology as naÏve TAMs under immunohistochemistry. Pathway enrichment analysis revealed an upregulation of immune response pathways in TA-CDMCs compared to regular TAMs, including the overexpression of genes relevant for the regulation of T cell activation, suggesting possible modification of the glioma immune-environment following CDMC repopulation. CONCLUSIONS: The present study offered a robust proof-of-concept that highly efficient TAM replacement could be achieved in orthotopic murine brain tumor models. Additionally, it appears that replaced CDMCs retain unique transcriptional patterns in the tumor-immune microenvironment, with the upregulation of several key immune response pathways. These efforts may represent a novel route of tumor-directed immunotherapy and offer exciting opportunities for ex-vivo CDMC manipulation to specifically target neoplastic cells.

The role of complement-mediated signaling during antigen presentation

Abstract Local production of complement C3a and C5a at the immune synapse by activated dendritic cells (DCs) enhances T cell responses in a variety of experimental systems. We have shown that complement C3 plays a mechanistic role in driving synergistic anti-tumor effects of blocking indoleamine 2,3-dioxygenase (IDO) during radiation and chemotherapy in a murine brain tumor model. We hypothesize that, when anti-tumor responses are allowed to happen, locally produced complement C3 acts as a costimulation factor for activation of T cells. To study the role of complement C3 in promoting T cell responses against a nominal tumor antigen (gp10025–33 peptide expressed by B16F10 melanoma), we used T cells from syngeneic pmel-1 mice (TCR transgenic with CD8 T cells that recognize the cross-presented gp10025–33 peptide). We found florid deposition of complement C3 in B16F10 tumors when IDO-blockade was added to a pmel-1/gp10025–33 based vaccine. To model homeostatic conditions of the tumor microenvironment, we used an in vitro co-culture system with gp10025–33 peptide in stringent limited supply. Under these conditions, pmel-1 CD8 T cells stimulated by DCs from complement C3 knock-out (C3-KO) mice had decreased activation marker expression, proliferation, and cytokine effector function, relative to pmel-1 CD8 T cells stimulated by DCs from wild-type (WT) mice. These findings suggest that suppression of local complement production by DCs in the tumor microenvironment may inhibit anti-tumor immune responses. Supported by grants from Alex's Lemonade Stand Foundation, Press On Foundation, and Hyundai Hope On Wheels.

Eliciting an immune-mediated antitumor response through oncolytic herpes simplex virus-based shared antigen expression in tumors resistant to viroimmunotherapy

BackgroundOncolytic virotherapy (OV) is an immunotherapy that incorporates viral cancer cell lysis with engagement of the recruited immune response against cancer cells. Pediatric solid tumors are challenging targets because they...

Methods for intratumoral microdialysis probe targeting and validation in murine brain tumor models

BackgroundMicrodialysis is a well validated sampling technique that can be used for pharmacokinetic studies of oncological drugs targeting the central nervous system. This technique has also been applied to evaluate tumor metabolism and identify pharmacodynamic biomarkers of drug activity. Despite the potential utility of microdialysis for therapeutic discovery, variability in tumor size and location hamper routine use of microdialysis as a preclinical tool. Quantitative validation of microdialysis membrane location relative to radiographically evident tumor regions could facilitate rigorous preclinical studies. However, a widely accessible standardized workflow for preclinical catheter placement and validation is needed. New methodWe provide methods for a workflow to yield tailored placement of microdialysis probes within a murine intracranial tumor and illustrate in an IDH1-mutant patient-derived xenograft (PDX) model. This detailed workflow uses a freely available on-line tool built within 3D-slicer freeware to target microdialysis probe placement within the tumor core and validate probe placement fully within the tumor. ResultsWe illustrate use of this workflow to validate microdialysis probe location relative to implanted IDH1-mutant PDXs, using the microdialysis probes to quantify levels of extracellular onco-metabolite D-2 hydroxyglutarate. Comparison with existing methodsPrevious methods have used 3D slicer to reliably measure tumor volumes. Prior microdialysis studies have targeted expected tumor locations without validation. ConclusionsThe new method offers a streamlined and freely available workflow in 3D slicer to optimize and validate microdialysis probe placement within a murine brain tumor.

Differentiation of Brain Tumor Microvasculature From Normal Vessels Using Optical Coherence Angiography.

Despite rapid advances and discoveries in medical imaging, monitoring therapeutic efficacy for malignant gliomas and monitoring tumor vasculature remains problematic. The purpose of this studyis to utilize optical coherence angiography for vasculature characterization inside and surrounding brain tumors in a murine xenograft brain tumor model. Features included in our analysis include fractional blood volume, vessel tortuosity, diameter, orientation, and directionality. In this study, five tumorous mice models at 4 weeks of age were imaged. Human glioblastoma cells were injected into the brain and allowed to grow for 4 weeks and then imaged using optical coherence tomography. Results suggest that blood vessels outside the tumor contain a greater fractional blood volume as compared with vessels inside the tumor. Vessels inside the tumor are more tortuous as compared with those outside the tumor. Results indicate that vessels near the tumor margin are directed inward towards the tumor while normal vessels show a more random orientation. Quantification of vascular microenvironments in brain gliomas can provide functional vascular parameters to aid various diagnostic and therapeutic studies. © 2021 Wiley Periodicals LLC.

Validation of Cadherin HAV6 Peptide in the Transient Modulation of the Blood-Brain Barrier for the Treatment of Brain Tumors.

The blood-brain barrier (BBB) poses a major obstacle by preventing potential therapeutic agents from reaching their intended brain targets at sufficient concentrations. While transient disruption of the BBB has been used to enhance chemotherapeutic efficacy in treating brain tumors, limitations in terms of magnitude and duration of BBB disruption exist. In the present study, the preliminary safety and efficacy profile of HAV6, a peptide that binds to the external domains of cadherin, to transiently open the BBB and improve the delivery of a therapeutic agent, was evaluated in a murine brain tumor model. Transient opening of the BBB in response to HAV6 peptide administration was quantitatively characterized using both a gadolinium magnetic resonance imaging (MRI) contrast agent and adenanthin (Ade), the intended therapeutic agent. The effects of HAV6 peptide on BBB integrity and the efficacy of concurrent administration of HAV6 peptide and the small molecule inhibitor, Ade, in the growth and progression of an orthotopic medulloblastoma mouse model using human D425 tumor cells was examined. Systemic administration of HAV6 peptide caused transient, reversible disruption of BBB in mice. Increases in BBB permeability produced by HAV6 were rapid in onset and observed in all regions of the brain examined. Concurrent administration of HAV6 peptide with Ade, a BBB impermeable inhibitor of Peroxiredoxin-1, caused reduced tumor growth and increased survival in mice bearing medulloblastoma. The rapid onset and transient nature of the BBB modulation produced with the HAV6 peptide along with its uniform disruption and biocompatibility is well-suited for CNS drug delivery applications, especially in the treatment of brain tumors.

Estimation of cellular-interstitial water exchange in dynamic contrast enhanced MRI using two flip angles.

To investigate the feasibility of using multiple flip angles in dynamic contrast enhanced (DCE) MRI to reduce the uncertainty in estimation of intracellular water lifetime (τi ). Numerical simulation studies were conducted to assess the uncertainty in estimation of τi using dynamic contrast enhanced MRI with one or two flip angles. In vivo experiments with a murine brain tumor model were conducted at 7T using two flip angles. The in vivo data were used to compare τi estimation using the single-flip-angle (SFA) protocol with that using the double-flip-angle (DFA) protocol. Data analysis was conducted using the two-compartment exchange model combined with the three-site-two-exchange model for water exchange. In the numerical simulation studies with a range of contrast kinetic parameters and signal-to-noise ratio=20, the median bias of τi estimation decreased from 72ms with SFA to 65ms with DFA, and the corresponding median inter-quartile range reduced from 523ms to 156ms. In the in vivo studies, τi estimation with SFA was not successful in most voxels in the tumors, as the estimated τi values reached the upper limit of the parameter range (2s). In contrast, the estimated τi values with DFA were mostly between 0.2 and 1.5s and homogeneously distributed spatially across the tumor. The τi estimation with DFA was less sensitive to arterial input function scaling but more sensitive to pre-contrast T1 than the other contrast kinetic parameters. This study results demonstrate the feasibility of using multiple flip angles to encode the post-contrast time-intensity curve with different weighting of water exchange effect to reduce the uncertainty in τi estimation.

An experimental device applied in the research of radiotherapy on murine brain tumor models

An experimental device applied in the research of radiotherapy on murine brain tumor models

Velocity-based Adaptive Registration and Fusion for Fractionated Stereotactic Radiosurgery Using the Small Animal Radiation Research Platform

To implement Velocity-based image fusion and adaptive deformable registration to enable treatment planning for preclinical murine models of fractionated stereotactic radiosurgery (fSRS) using the small animal radiation research platform (SARRP). C57BL6 mice underwent 3 unique cone beam computed tomography (CBCT) scans: 2 in the prone position and a third supine. A single T1-weighted post-contrast magnetic resonance imaging (MRI) series of a murine metastatic brain tumor model was selected for MRI-to-CBCT registration and gross tumor volume (GTV) identification. Two arms were compared: Arm 1, where we performed 3 individual MRI-to-CBCT fusions using rigid registration, contouring GTVs on each, and Arm 2, where the authors performed MRI-to-CBCT fusion and contoured GTV on the first CBCT followed by Velocity-based adaptive registration. The first CBCT and associated GTV were exported from MuriPlan (Xstrahl Life Sciences) into Velocity (Varian Medical Systems, Inc, Palo Alto, CA). In Arm 1, the second and third CBCTs were exported similarly along with associated GTVs (Arm 1), while in Arm 2, the first (prone) CBCT was fused separately to the second (prone) and third (supine) CBCTs, performing deformable registrations on initial CBCTs and applying resulting matrices to the contoured GTV. Resulting GTVs were compared between Arms 1 and2. Comparing GTV overlays using repeated MRI fusion and GTV delineation (Arm 1) versus those of Velocity-based CBCT and GTV adaptive fusion (Arm 2), mean deviations±standard deviation in the axial, sagittal, and coronal planes were 0.46±0.16, 0.46±0.22, and 0.37±0.22mm for prone-to-prone and 0.52±0.27, 0.52±0.36, and 0.68±0.31mm for prone-to-supine adaptive fusions, respectively. Velocity-based adaptive fusion of CBCTs and contoured volumes allows for efficient fSRS planning using a single MRI-to-CBCT fusion. This technique is immediately implementable on current SARRP systems, facilitating advanced preclinical treatment paradigms using existing clinical treatment planning software.

The abscopal effect induced by in situ-irradiated peripheral tumor cells in a murine GL261 brain tumor model

Background: Localized radiotherapy is considered to act as an adjuvant for systemic anti-tumor immunity. We examined whether in situ-irradiated peripheral tumor cells can evoke an abscopal effect in the brain inhibiting malignant tumor growth.

A longitudinal magnetic resonance elastography study of murine brain tumors following radiation therapy

An accurate and noninvasive method for assessing treatment response following radiotherapy is needed for both treatment monitoring and planning. Measurement of solid tumor volume alone is not sufficient for reliable early detection of therapeutic response, since changes in physiological and/or biomechanical properties can precede tumor volume change following therapy. In this study, we use magnetic resonance elastography to evaluate the treatment effect after radiotherapy in a murine brain tumor model. Shear modulus was calculated and compared between the delineated tumor region of interest (ROI) and its contralateral, mirrored counterpart. We also compared the shear modulus from both the irradiated and non-irradiated tumor and mirror ROIs longitudinally, sampling four time points spanning 9–19 d post tumor implant. Results showed that the tumor ROI had a lower shear modulus than that of the mirror ROI, independent of radiation. The shear modulus of the tumor ROI decreased over time for both the treated and untreated groups. By contrast, the shear modulus of the mirror ROI appeared to be relatively constant for the treated group, while an increasing trend was observed for the untreated group. The results provide insights into the tumor properties after radiation treatment and demonstrate the potential of using the mechanical properties of the tumor as a biomarker. In future studies, more closely spaced time points will be employed for detailed analysis of the radiation effect.

What underlies the diversity of brain tumors?

Glioma and medulloblastoma represent the most commonly occurring malignant brain tumors in adults and in children, respectively. Recent genomic and transcriptional approaches present a complex group of diseases and delineate a number of molecular subgroups within tumors that share a common histopathology. Differences in cells of origin, regional niches, developmental timing, and genetic events all contribute to this heterogeneity. In an attempt to recapitulate the diversity of brain tumors, an increasing array of genetically engineered mouse models (GEMMs) has been developed. These models often utilize promoters and genetic drivers from normal brain development and can provide insight into specific cells from which these tumors originate. GEMMs show promise in both developmental biology and developmental therapeutics. This review describes numerous murine brain tumor models in the context of normal brain development and the potential for these animals to impact brain tumor research.

Preclinical Evaluation of a Genetically Engineered Herpes Simplex Virus Expressing Interleukin-12

Herpes simplex virus 1 (HSV-1) mutants that lack the γ(1)34.5 gene are unable to replicate in the central nervous system but maintain replication competence in dividing cell populations, such as those found in brain tumors. We have previously demonstrated that a γ(1)34.5-deleted HSV-1 expressing murine interleukin-12 (IL-12; M002) prolonged survival of immunocompetent mice in intracranial models of brain tumors. We hypothesized that M002 would be suitable for use in clinical trials for patients with malignant glioma. To test this hypothesis, we (i) compared the efficacy of M002 to three other HSV-1 mutants, R3659, R8306, and G207, in murine models of brain tumors, (ii) examined the safety and biodistribution of M002 in the HSV-1-sensitive primate Aotus nancymae following intracerebral inoculation, and (iii) determined whether murine IL-12 produced by M002 was capable of activating primate lymphocytes. Results are summarized as follows: (i) M002 demonstrated superior antitumor activity in two different murine brain tumor models compared to three other genetically engineered HSV-1 mutants; (ii) no significant clinical or magnetic resonance imaging evidence of toxicity was observed following direct inoculation of M002 into the right frontal lobes of A. nancymae; (iii) there was no histopathologic evidence of disease in A. nancymae 1 month or 5.5 years following direct inoculation; and (iv) murine IL-12 produced by M002 activates A. nancymae lymphocytes in vitro. We conclude that the safety and preclinical efficacy of M002 warrants the advancement of a Δγ(1)34.5 virus expressing IL-12 to phase I clinical trials for patients with recurrent malignant glioma.

Tumor-secreted SDF-1 promotes glioma invasiveness and TAM tropism toward hypoxia in a murine astrocytoma model

A distinguishing feature of high-grade gliomas is the infiltration of neoplastic cells into adjacent brain tissues that mark most of these tumors surgically incurable. To study the factors associated with tumor invasion, we established a new murine brain tumor model, ALTS1C1 derived from SV40 large T antigen-transfected astrocytes. This new brain tumor model recapitulates several histopathological features of human high-grade glioma including increased cellularity, prominent cellular pleomorphism, geographic necrosis, active mitosis, and extensive invasion of tumor cells into adjacent brain tissues. More importantly, ALTS1C1 expressed a relatively high level of stromal-derived factor-1 (SDF-1/CXCL12) in vitro and in vivo and higher microvascular density (MVD) in vivo. To define the roles of SDF-1 in this tumor model, the expression of SDF-1 in ALTS1C1 cells was inhibited by specific siRNA. SDF-knockdown ALTS1C1 (SDFkd) cells took longer than parental ALTS1C1 cells to form tumors and in contrast to the wild-type tumors they had well-defined regular borders and lacked infiltration tracts. The SDFkd tumors were also associated with a lower MVD and more hypoxic areas. In contrast to parental tumors, the density of F4/80-positive tumor-associated macrophages (TAMs) in SDFkd tumor was higher in non-hypoxic than in hypoxic regions. SDF-1 production by tumor cells therefore seems critical for the aggregation of TAMs into areas of hypoxia and tumor invasiveness. This study not only provides new insight into the role of SDF-1 in brain tumor invasion and the relationship between TAMs and hypoxia, but also provides a new preclinical brain tumor model for designing new treatment options for invasive cases.

Decreased CCAAT/enhancer binding protein β expression inhibits the growth of glioblastoma cells

C/EBPβ is a leucine-zipper transcription factor implicated in the control of metabolism, development, cell differentiation, and proliferation. However, it remains unclear its role in tumor development. Here, we show that down-regulation of C/EBPβ by RNA interference inhibits proliferation in the GL261 murine glioblastoma cell line, induces an arrest of the cell cycle at the G0/G1 boundary, and diminishes their transformation capacity and migration. In addition, we show that C/EBPβ regulates the expression of several DNA damage response- and invasion-related genes. Lastly, C/EBPβ depletion significantly retards tumor onset and prolongs survival in a murine orthotopic brain tumor model. Immunohistochemical analysis revealed a significant diminution of proliferating cell nuclear antigen (PCNA) labeling in tumors derived from C/EBPβ-depleted GL261 cells compared with that in controls. These results show, for the first time, the dependence of glioma cells on C/EBPβ and suggest a potential role of this transcription factor in glioma development.