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Abstract
Chronic neuropathic pain is frequently comorbid with anxiety disorders, yet the neural circuits underlying this interaction remain poorly defined. The parafascicular nucleus of the thalamus (PF) integrates nociceptive and affective signals, but its specific regulatory mechanisms in pain-anxiety comorbidity are not well known. Using spared nerve injury (SNI) model mice, we combined viral neural tracing, chemogenetics, pharmacology, and electrophysiology to dissect the locus coeruleus (LC)-PF neural pathway. Viral tracing revealed monosynaptic projections from norepinephrinergic (NEergic) neurons in the dorsal LC to calcium/calmodulin dependent protein kinase IIα (CaMKIIα)- immunopositive neurons within the PF. Chemogenetic inhibition/activation of this pathway were performed in naïve and SNI mice, alongside intra-PF microinjection of the alpha-2 adrenergic receptor (ADRA2) antagonist yohimbine. Behavioral tests assessed mechanical/thermal hypersensitivity and anxiety-like behaviors. Results showed that 92.1% of PF-projecting LC neurons were NEergic, with 70.1% localized dorsally. Chemogenetic inhibition of LCNE-PFCaMKIIα neural pathway significantly alleviated both acute-phase mechanical hypersensitivity (< 7 days post-surgery) and chronic-phase anxiety-like behaviors in SNI mice, while activation of this pathway induced pain sensitization and anxiety-like behaviors in naïve mice. Intra-PF yohimbine reversed SNI-induced allodynia and anxiety-like behaviors. Electrophysiology confirmed yohimbine increased PF neuronal intrinsic excitability. These results suggest that the LCNE-PFCaMKIIα neural pathway promotes neuropathic pain and comorbid anxiety via ADRA2-mediated suppression of PF neuronal activity. Targeted inhibition of this circuit may represent a therapeutic strategy for pain-related affective disorders.
Authors
Zhong-Yi Liu, Fei Li, Li-Ming Liu, Yao-Hua Liu, Jia Li, Zi-Ang Li, Jin Cheng, Tian-Yu Zhao, Hui-Min Tian, Dong-Ning Li, Sha-Sha Tao, Hui Li, Fen-Sheng Huang, Yun-Qing Li
Abstract
Subendothelial retention of cholesterol-rich apolipoprotein-B-containing lipoproteins drives atherosclerotic arterial disease. In peripheral interstitial fluid from patients with type 2 diabetes (T2D), levels of such particles have been shown to be paradoxically reduced relative to those in serum, presumably reflecting their increased retention within the arterial wall. To identify possible mechanisms involved in lipoprotein retention in T2D, we obtained serum and skin blister fluid from such patients and matched controls, together with skin biopsies in a subset of individuals. In T2D, smaller LDL and VLDL remnant particles were more prominent in serum, but not in interstitial fluid, reflecting their enhanced vascular entrapment. The interstitial-fluid-to-serum ratio of apolipoprotein-B was 58% lower in T2D than in controls (0.14 vs 0.33), concomitant with increased susceptibility for LDL binding to proteoglycans. The most marked differences were seen in patients with clinically evident cardiovascular disease. The degree of transvascular retention was positively related to the propensity of isolated serum LDL to bind aortic proteoglycans, both in T2D and in controls. Skin unesterified cholesterol levels were higher in T2D patients relative to healthy controls. With aging, both proteoglycan binding and apparent vascular retention of LDL increased in controls, but not in T2D, indicating that these mechanisms may also be relevant for atherogenesis in non-diabetic individuals.
Authors
Pär Björklund, Jennifer Härdfeldt, Lauri Äikäs, Sara Straniero, Minna Holopainen, Katariina Öörni, Mats J. Rudling, Bo Angelin
Abstract
MD-PhD trainees increasingly pursue PhDs in humanities, social sciences, and public health (SSHPH). We characterized SSHPH trainee experiences and compared them to peers in traditional biomedical disciplines. From March-July 2023, a nationwide survey was sent to United States MD-PhD programs that accept SSHPH trainees. Both SSHPH and non-SSHPH trainees participated in a survey focused on belonging, challenges and barriers, funding, and leadership recommendations. Quantitative data were analyzed using Fisher’s exact tests, Student’s t-tests, and Wilcoxon rank sum tests. Qualitative comments were analyzed using a hybrid deductive-inductive approach. 234 MD-PhD trainees across the U.S. participated, with 111 (47.4%) in SSHPH and 123 (52.6%) in non-SSHPH disciplines. Overall, there were many similarities between trainees across disciplinary groups, but small and consistent differences were noted among SSHPH trainees, including decreased belonging, difficulty identifying role models, and increased work requirements during graduate school. Respondents had 5 recommendations for MD-PhD leaders and 3 recommendations for the National Institutes of Health, such as integrating SSHPH scholars into speaker series and incentivizing funding parity. Limitations include high percentages of missing responses. This exploratory study provides insights into SSHPH MD-PhD trainee experiences, highlighting similarities and unique needs that can be addressed within and across MD-PhD programs.
Authors
Cambray Smith, Evans K. Lodge, C. Ray Cheever, Seth M. Holmes, Anna R. Kahkoska
Abstract
Dedifferentiated liposarcoma (DDLS), myxofibrosarcoma (MFS), and undifferentiated pleomorphic sarcoma (UPS) are the most common types of genetically complex sarcoma. There is an urgent need to develop effective targeted therapy for these deadly sarcoma types. Despite their genetic complexity, these sarcomas share genomic alterations causing PI3K/Akt/mTOR and MAPK pathway activation, and both pathways control translation mediated by the RNA helicase eIF4A. We therefore investigated eIF4A inhibition as a therapeutic strategy. The eIF4A inhibitor CR-1-31B effectively suppressed tumor growth and induced apoptosis in DDLS, MFS, and UPS patient-derived cell lines and mouse xenografts. Transcriptome-scale ribosome footprinting identified eIF4A-dependent mRNAs such as the Hippo pathway transcriptional coactivators YAP1 (YAP) and WWTR1 (TAZ). Combined knockdown of YAP and TAZ induced apoptosis in DDLS, MFS, and UPS cell lines, and their ectopic expression partially rescued cells from apoptosis induced by CR-1-31B. Genomic analysis of patient tumors revealed that YAP and WWTR1 were frequently amplified or gained in DDLS, MFS, and UPS and were associated with worse clinical outcomes. Together, our findings identify a new strategy for targeting the Hippo pathway in incurable forms of sarcoma based on inhibition of eIF4A-dependent translation of the key oncogenic transcription factors YAP and TAZ.
Authors
Young-Mi Kim, Prathibha Mohan, Urmila Sehrawat, Evan Seffar, Rafaela Muniz De Queiroz, Kalyani Chadalavada, Nikita Persaud, Tomoyo Okada, Anirudh Kulkarni, Jianan Lin, Nathalie Lailler, Shaleigh Smith, Bhumika Jadeja, Nicholas D. Socci, Zhengqing Ouyang, Hans-Guido Wendel, Samuel Singer
Abstract
Hypoxia critically restricts the effectiveness of immunotherapy in triple-negative breast cancer (TNBC). Comprehensive bioinformatics analyses demonstrated that highly hypoxic TNBC tumors exhibited elevated T cell exhaustion, increased immune checkpoint molecule expression, and diminished responsiveness to immune checkpoint blockade (ICB). Consequently, strategies aimed at alleviating tumor hypoxia may effectively augment ICB therapy. Although ultrasound-targeted microbubble cavitation (UTMC) has been shown to reduce tumor hypoxia, the precise molecular mechanisms remain unclear. Here, we provided evidence that UTMC activated endothelial nitric oxide synthase (eNOS) through G protein–coupled signaling, resembling pathways induced by fluid shear stress. UTMC-induced eNOS activation was largely Ca²⁺-dependent and resulted in increased nitric oxide production. Enhanced nitric oxide generation was associated with improved tumor perfusion and reduced hypoxia. Combining UTMC with anti–PD-L1 therapy markedly improved the tumor immune microenvironment, characterized by increased CD8+ T cell infiltration, reduced T cell exhaustion, diminished regulatory T cell infiltration, increased macrophage polarization from an M2 to M1 phenotype, and elevated production of pro-inflammatory cytokines. Collectively, our findings identified UTMC as a promising adjunctive therapeutic approach to mitigate hypoxia and enhance the efficacy of anti–PD-L1 immunotherapy in TNBC. These results support further translational evaluation of UTMC-based combination strategies in hypoxic TNBC.
Authors
Zhiyu Zhao, Li Ba, Siwei Li, Jianxin Wang, Yuzhou Luo, Sihan Wang, Yan Jin, Changjun Wu
Abstract
Pancreatic ductal adenocarcinoma (PDAC) shows profound resistance to immunotherapy due to its immunosuppressive tumor microenvironment. Here, we studied the relationship between T cell infiltration and innate immune signaling in PDAC, identifying Toll-like receptor 2 (TLR2) as a key regulator of T cell exclusion. TLR2 expression correlated with T cell infiltration in both human and mouse PDAC tumors. Using genetic knockout models and adoptive T cell transfer experiments, we found that TLR2 expression in both T cells and non-T cells contributes to T cell exclusion in PDAC. Notably, successful infiltration of adoptively transferred tumor-specific T cells required TLR2 deletion in both the transferred cells and the recipient host. The therapeutic implications of these findings are demonstrated through both genetic deletion and pharmacological inhibition of TLR2 using AAV-mediated and antibody-based approaches in murine models, resulting in decreased tumor growth and extended survival. Collectively, these findings identify TLR2 as a key modulator of T cell trafficking and immune suppression within the PDAC microenvironment, suggesting its potential as a therapeutic target for improving treatment outcomes.
Authors
Jacqueline Plesset, Meredith L. Stone, John C. McVey, Heather Coho, Kelly Markowitz, Kayjana Coho, Jesse Lee, Anna S. Thickens, Devora Delman, Gregory L. Beatty
Abstract
HIV infection rapidly impairs the gastrointestinal (GI) barrier, contributing to persistent mucosal immune dysfunction, microbial translocation, and systemic inflammation despite antiretroviral therapy (ART). Using SIV-infected rhesus macaques on long-term ART, we investigated mechanisms underlying impairment in gut barrier-protective IL-17/IL-22 responses and the potential modulation of this pathway by dietary indoles. Longitudinal profiling of colonic epithelial and lamina propria cells revealed a selective loss of IL-17/IL-22–producing γδT cells and type 3 innate lymphoid cells (ILC3s). This loss correlated with reduced expression of the transcription factors AHR and RORγt and was associated with elevated plasma markers of intestinal epithelial barrier disruption (IEBD), including intestinal fatty acid–binding protein (iFABP), zonulin, and LPS-binding protein (LBP). Targeting this transcriptional deficiency, dietary indole supplementation for one month restored colonic AHR⁺IL-22-producing γδ T cells, RORγt⁺ ILC3s, and Vδ1 T cells, and was associated with reduced iFABP and zonulin levels. Immunohistochemical analyses further demonstrated enrichment of AHR/RORγt-co-expressing cells in the colon of indole-supplemented animals during chronic SIV infection on ART. Collectively, these findings indicate that disruption of the AHR-RORγt axis is a key pathogenic mechanism underlying persistent IEBD in chronic SIV/HIV infection. Modulation of AHR and RORγt signaling pathways in the gut may therefore represent a promising therapeutic strategy to reinforce mucosal barrier function and mitigate chronic inflammation in people living with HIV.
Authors
Siva Thirugnanam, Alison R. Van Zandt, Alexandra B. McNally, Victoria A. Hart, Isabelle Berthelot, Cecily C. Midkiff, Lara A. Doyle-Meyers, David A. Welsh, Robert V. Blair, Andrew G. MacLean, Namita Rout
Abstract
Spinocerebellar Ataxia Type 14 (SCA14) is an autosomal dominant neurodegenerative disease caused by mutations in the gene encoding protein kinase C gamma (PKCγ), a Ca2+/diacylglycerol (DG)-dependent serine/threonine kinase dominantly expressed in cerebellar Purkinje cells. These mutations impair autoinhibitory constraints to increase the basal activity of the kinase, resulting in deficits in the cerebellum that are not observed upon simple deletion of the gene, and severe ataxia. To better understand the impact of aberrant PKCγ signaling in disease pathology, we developed a knock-in murine model of the SCA14 mutation ΔF48 in PKCγ. This fully-penetrant mutation is severe in humans and is mechanistically informative as it has high basal activity but is unresponsive to agonist stimulation. Genetic, behavioral, and molecular testing revealed that ΔF48 PKCγ mice have ataxia-related phenotypes and an altered cerebellar phosphoproteome driven primarily by enhanced Ca2+/calmodulin-dependent Kinase II (CaMKII) signaling, effects that were more severe in male mice. Analysis of existing human data revealed that SCA14 has a significantly earlier age of onset for males compared with females. Data from this clinically relevant mutation suggested that enhanced basal activity of PKCγ is sufficient to cause ataxia and that treatment strategies to modulate aberrant PKCγ may be particularly beneficial in males.
Authors
Sarah A. Wolfe, Yuliang Ma, Tomer M. Yaron-Barir, Carly Chang, Caila A. Pilo, Majid Ghassemian, Amanda J. Roberts, Sang Ryeul Lee, Benjamin A. Henson, Kristen Jepsen, Jared L. Johnson, Lewis C. Cantley, Susan S. Taylor, George Gorrie, Alexandra C. Newton
Abstract
Authors
William J. Crisler, Noor Sohail, Samuel J. Steuart, Maria Vazquez-Machado, Arjun Mahajan, Maureen Whittelsey, Alex Pickering, Michael J. Martinez, Theresa Hutchins, Jessica E. Teague, Qian Zhan, Shannan Ho Sui, Ruth Ann Vleugels, Kathryn S. Torok, Heidi Jacobe, Rachael A. Clark, Avery LaChance
Abstract
Huntington’s disease (HD) is a fatal neurodegenerative disease caused by an expanded polyglutamine (CAG) repeat in the N-terminal of the Huntingtin protein (HTT). Microglial activation and elevated pro-inflammatory cytokines are observed in HD brains, but the mechanisms regulating neuroinflammation and microglial activation are poorly understood. Metformin-mediated neuroprotection has been demonstrated in experimental models of neurodegeneration, including HD. We found that metformin inhibits mitochondrial DNA (mtDNA) release and subsequent neuroinflammation in the cortex and striatum of a mouse model of HD. Moreover, elevated pro-inflammatory cytokines and microglial activation are inhibited by metformin in HD transgenic mice brain. Metformin reduced pathological microglial clusters and shifted towards a quiescent, homeostatic phenotype. Metformin improved aberrant immunometabolism in HD mouse brain and primary microglia. Mechanistically found that metformin regulates mitochondrial fission, reprograms deregulated metabolism in HD microglia, and controls microglial activation and inflammation in HD transgenic mice.
Authors
Abhishek Jauhari, Adam C. Monek, Olena S. Abakumova, Tanisha Singh, Sukhman Singh, Xiaomin Wang, Carley S. Clise, Diane L. Carlisle, Robert M. Friedlander
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