Browsing by Author "Shireman, Jack M."
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Item Aging- and Tumor-Mediated Increase in CD8+CD28- T Cells Might Impose a Strong Barrier to Success of Immunotherapy in Glioblastoma(American Association of Immunologists, 2021-06-08) Huff, Wei X.; Bam, Marpe; Shireman, Jack M.; Kwon, Jae Hyun; Song, Leo; Newman, Sharlé; Cohen-Gadol, Aaron A.; Shapiro, Scott; Jones, Tamara; Fulton, Kelsey; Liu, Sheng; Tanaka, Hiromi; Liu, Yunlong; Wan, Jun; Dey, Mahua; Neurological Surgery, School of MedicineClinical use of various forms of immunotherapeutic drugs in glioblastoma (GBM), has highlighted severe T-cell dysfunction such as exhaustion in GBM patients. However, reversing T-cell exhaustion using immune checkpoint inhibitors in GBM clinical trials has not shown significant overall survival benefit. Phenotypically, CD8+ T cells with downregulated CD28 co-receptors, low CD27 expression, increased CD57 expression, and telomere shortening, are classified as senescent T cells. These senescent T cells are normally seen as part of aging and also in many forms of solid cancers. Absence of CD28 on T-cells leads to several functional irregularities including reduced TCR diversity, incomplete activation of T cells, and defects in antigen induced proliferation. In the context of GBM, presence and/or function of these CD8+CD28− T-cells is unknown. In this clinical correlative study, we investigated the effect of aging as well as tumor microenvironment on CD8+ T-cell phenotype as an indicator of its function in GBM patients. We systematically analyzed and describe a large population of CD8+CD28− T-cells in both the blood and tumor infiltrating lymphocytes of GBM patients. We found that phenotypically these CD8+CD28− T-cells represent a distinct population compared to exhausted T-cells. Comparative transcriptomic and pathway analysis of CD8+CD28− T cell populations in GBM patients revealed that tumor microenvironment might be influencing several immune related pathways and thus further exaggerating the age associated immune dysfunction in this patient population.Item Genomic analysis of human brain metastases treated with stereotactic radiosurgery reveals unique signature based on treatment failure(Elsevier, 2024-03-27) Shireman, Jack M.; White, Quinn; Ni, Zijian; Mohanty, Chitrasen; Cai, Yujia; Zhao, Lei; Agrawal, Namita; Gonugunta, Nikita; Wang, Xiaohu; Mccarthy, Liam; Kasulabada, Varshitha; Pattnaik, Akshita; Ahmed, Atique U.; Miller, James; Kulwin, Charles; Cohen-Gadol, Aaron; Payner, Troy; Lin, Chih-Ta; Savage, Jesse J.; Lane, Brandon; Shiue, Kevin; Kamer, Aaron; Shah, Mitesh; Iyer, Gopal; Watson, Gordon; Kendziorski, Christina; Dey, Mahua; Radiation Oncology, School of MedicineStereotactic radiosurgery (SRS) has been shown to be efficacious for the treatment of limited brain metastasis (BM); however, the effects of SRS on human brain metastases have yet to be studied. We performed genomic analysis on resected brain metastases from patients whose resected lesion was previously treated with SRS. Our analyses demonstrated for the first time that patients possess a distinct genomic signature based on type of treatment failure including local failure, leptomeningeal spread, and radio-necrosis. Examination of the center and peripheral edge of the tumors treated with SRS indicated differential DNA damage distribution and an enrichment for tumor suppressor mutations and DNA damage repair pathways along the peripheral edge. Furthermore, the two clinical modalities used to deliver SRS, LINAC and GK, demonstrated differential effects on the tumor landscape even between controlled primary sites. Our study provides, in human, biological evidence of differential effects of SRS across BM's.Item Genomic Analysis of Human Brain Metastases Treated with Stereotactic Radiosurgery Under the Phase-II Clinical Trial (NCT03398694) Reveals DNA Damage Repair at the Peripheral Tumor Edge(medRxiv, 2023-04-24) Shireman, Jack M.; White, Quinn; Agrawal, Namita; Ni, Zijian; Chen, Grace; Zhao, Lei; Gonugunta, Nikita; Wang, Xiaohu; Mccarthy, Liam; Kasulabada, Varshitha; Pattnaik, Akshita; Ahmed, Atique U.; Miller, James; Kulwin, Charles; Cohen-Gadol, Aaron; Payner, Troy; Lin, Chih-Ta; Savage, Jesse J.; Lane, Brandon; Shiue, Kevin; Kamer, Aaron; Shah, Mitesh; Iyer, Gopal; Watson, Gordon; Kendziorski, Christina; Dey, Mahua; Radiation Oncology, School of MedicineStereotactic Radiosurgery (SRS) is one of the leading treatment modalities for oligo brain metastasis (BM), however no comprehensive genomic data assessing the effect of radiation on BM in humans exist. Leveraging a unique opportunity, as part of the clinical trial (NCT03398694), we collected post-SRS, delivered via Gamma-knife or LINAC, tumor samples from core and peripheral-edges of the resected tumor to characterize the genomic effects of overall SRS as well as the SRS delivery modality. Using these rare patient samples, we show that SRS results in significant genomic changes at DNA and RNA levels throughout the tumor. Mutations and expression profiles of peripheral tumor samples indicated interaction with surrounding brain tissue as well as elevated DNA damage repair. Central samples show GSEA enrichment for cellular apoptosis while peripheral samples carried an increase in tumor suppressor mutations. There are significant differences in the transcriptomic profile at the periphery between Gamma-knife vs LINAC.Item Interleukin-8/CXCR2 signaling regulates therapy-induced plasticity and enhances tumorigenicity in glioblastoma(Springer Nature, 2019-03-29) Hasan, Tanwir; Caragher, Seamus P.; Shireman, Jack M.; Park, Cheol H.; Atashi, Fatemeh; Baisiwala, Shivani; Lee, Gina; Guo, Donna; Wang, Jennifer Y.; Dey, Mahua; Wu, Meijing; Lesniak, Maciej S.; Horbinski, Craig M.; James, C. David; Ahmed, Atique U.; Neurological Surgery, School of MedicineEmerging evidence reveals enrichment of glioma-initiating cells (GICs) following therapeutic intervention. One factor known to contribute to this enrichment is cellular plasticity-the ability of glioma cells to attain multiple phenotypes. To elucidate the molecular mechanisms governing therapy-induced cellular plasticity, we performed genome-wide chromatin immunoprecipitation sequencing (ChIP-Seq) and gene expression analysis (gene microarray analysis) during treatment with standard of care temozolomide (TMZ) chemotherapy. Analysis revealed significant enhancement of open-chromatin marks in known astrocytic enhancers for interleukin-8 (IL-8) loci as well as elevated expression during anti-glioma chemotherapy. The Cancer Genome Atlas and Ivy Glioblastoma Atlas Project data demonstrated that IL-8 transcript expression is negatively correlated with GBM patient survival (p = 0.001) and positively correlated with that of genes associated with the GIC phenotypes, such as KLF4, c-Myc, and HIF2α (p < 0.001). Immunohistochemical analysis of patient samples demonstrated elevated IL-8 expression in about 60% of recurrent GBM tumors relative to matched primary tumors and this expression also positively correlates with time to recurrence. Exposure to IL-8 significantly enhanced the self-renewing capacity of PDX GBM (average threefold, p < 0.0005), as well as increasing the expression of GIC markers in the CXCR2 population. Furthermore, IL-8 knockdown significantly delayed PDX GBM tumor growth in vivo (p < 0.0005). Finally, guided by in silico analysis of TCGA data, we examined the effect of therapy-induced IL-8 expression on the epigenomic landscape of GBM cells and observed increased trimethylation of H3K9 and H3K27. Our results show that autocrine IL-8 alters cellular plasticity and mediates alterations in histone status. These findings suggest that IL-8 signaling participates in regulating GBM adaptation to therapeutic stress and therefore represents a promising target for combination with conventional chemotherapy in order to limit GBM recurrence.Item Surgical Neuro-Oncology: Management of Glioma(Elsevier, 2022) Mitchell, Dana; Shireman, Jack M.; Dey, Mahua; Pediatrics, School of MedicineGliomas are the most common intrinsic brain tumor in adults. Although maximal tumor resection improves survival, this must be balanced with preservation of neurologic function. Technological advancements have greatly expanded our ability to safely maximize tumor resection and design innovative therapeutic trials that take advantage of intracavitary delivery of therapeutic agents after resection. In this article, we review the role of surgical intervention for both low-grade and high-grade gliomas and the innovations that are driving and expanding the role of surgery in this therapeutically challenging group of malignancies.