Many neural disorders are associated with aberrant activity in specific cell types or neural projection pathways embedded within the densely-wired, heterogeneous matter of the brain. An ideal therapy would permit correction of activity just in specific target neurons, while leaving other neurons unaltered. Recently our lab revealed that the naturally-occurring light-activated proteins channelrhodopsin-2 (ChR2) and halorhodopsin (Halo/NpHR) can, when genetically expressed in neurons, enable them to be safely, precisely, and reversibly activated and silenced by pulses of blue and yellow light, respectively. We here describe the ability to make specific neurons in the brain light-sensitive, using a viral approach. We also reveal the design and construction of a scalable, fully-implantable optical prosthetic capable of delivering light of appropriate intensity and wavelength to targeted neurons at arbitrary 3-D locations within the brain, enabling activation and silencing of specific neuron types at multiple locations. Finally, we demonstrate control of neural activity in the cortex of the non-human primate, a key step in the translation of such technology for human clinical use. Systems for optical targeting of specific neural circuit elements may enable a new generation of high-precision therapies for brain disorders.
Exonic circular RNAs (circRNAs) produce predominantly non-coding RNA species that have been recently profiled in many tumors. However, their functional contribution to cancer progression is still poorly understood. Here, we identify the circRNAs expressed in soft tissue sarcoma cells and explore how the circRNAs regulate sarcoma growth in vivo. We show that circCsnk1g3 and circAnkib1 promote tumor growth by shaping a pro-tumorigenic microenvironment, possibly due to their capabilities to regulate tumor-promoting elements extrinsic to the tumor cells. Accordingly, circCsnk1g3 and circAnkib1 can control the expression of interferon-related genes and pro-inflammatory factors in the sarcoma cells, thus directing immune cell recruitment into the tumor mass, and hence their activation. Mechanistically, circRNAs may repress pro-inflammatory elements by buffering activation of the pathways mediated by RIG-I, the cytosolic viral RNA sensor. The current findings suggest that the targeting of specific circRNAs could augment the efficacy of tumor and immune response to mainstay therapies.
Trafficking of T lymphocytes from the lymph nodes to the tumor microenvironment is a critical process of the tumor immunity cycle to elicit cytotoxic anti-tumor responses driven by CD8+ T cells. However, some tumors termed “immune excluded” recruit lymphocytes to the tumor site, but the lymphocytes are unable to penetrate the tumor parenchyma and localize primarily in the peritumoral region. In soft tissue sarcoma patients, most tumors are poorly infiltrated by T cells, which is associated with a poor response to immunotherapies. It has been described that cancer associated fibroblasts (CAFs) are enriched in immune excluded tumors and may directly block the migration of T cells via the production of dense extracellular matrix or by forging an immunosuppressive niche. We generated two models of undifferentiated pleomorphic sarcoma (UPS) that recapitulate the “immune excluded” and “inflamed” microenvironments observed in sarcoma patients. These syngeneic models rely on p53KO mesenchymal stem cells overexpressing either Ccne1 or Vgll3, which are frequently amplified in UPS patients. These models differ in their overall proportion of infiltrating TILs, and specifically T cells, making them ideal for comparative studies to investigate the mechanisms driving T cell exclusion in the TME. Using single-cell RNA-sequencing, we identified a population of CAFs expressing Nt5e, encoding CD73, which are spatially enriched in the peritumoral region of immune excluded Ccne1 tumors and closely associate with CD8+ T cells located at the tumor margin. Using transwell invasion assays, we show that CD73+ CAFs but not CD73- CAFs are able to block the migration of activated T cells towards tumor cells, even in the presence of CXCL10. Further, we show that Nt5e CAFs are enriched for signatures of glucose metabolism, and hypoxia, thus we hypothesized that CD73+ CAFs may block the migration of T cells into tumors by forging a nutrient poor metabolic barrier around the tumor. To test this, we treated Ccne1 tumors with BAY-876, a GLUT1 inhibitor and observed a significant accumulation of infiltrating CD8+ T cells compared to controls. GLUT1 treated CAFs expressed significantly less Nt5e, indicating that CD73 may play a role in the maintenance of glucose metabolism in CAFs. Furthermore, blockade of CD73 in CD73+ CAFs decreases the expression of the glucose transporter, Glut1. All together, these data suggest that CD73 may serve as a marker of glucose dependent CAFs that alter the metabolic niche to block T cell infiltration into tumors. Citation Format: Marina Broz, Emily Ko, Jinfen Xiao, Marco DeSimone, Roberta Piras, Kristin Ishaya, Xen Ping Hoi, Jlenia Guarnerio. Glucose dependent CD73+ CAFs enforce a tumor metabolic barrier that promotes T cell exclusion [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1255.
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