Research
Abstract
Loss-of-function mutations in the GBA1 gene are a prevalent risk factor for Parkinson’s disease (PD). Defining features are Lewy bodies that can be rich in α-synuclein (αS), vesicle- and other lipid membranes coupled with striatal dopamine loss and progressive motor dysfunction. Of these, lipid abnormalities are the least understood. An altered lipid metabolism in PD patient-derived neurons, carrying mutations in either GBA1, encoding for glucocerebrosidase, or αS can shift the physiological αS tetramer-monomer (T:M) equilibrium, resulting in PD phenotypes. We previously reported inhibition of stearoyl-CoA desaturase (SCD), the rate-limiting enzyme for fatty acid desaturation, stabilized αS tetramers and improved motor deficits in αS mice. Here we show that mutant GBA-PD cultured neurons have increased SCD products (monounsaturated fatty acids, MUFAS) and reduced αS T:M ratios that were improved by inhibiting SCD. Oral treatment of symptomatic L444P- and E326K Gba1 mutant mice with 5b also improved the αS T:M homeostasis and dopaminergic striatal integrity. Moreover, SCD inhibition normalized GCase maturation and dampened lysosomal and lipid-rich clustering, key features of neuropathology in GBA-PD. In conclusion, this study supports brain MUFA metabolism links GBA1 genotype and wildtype αS homeostasis to downstream neuronal and behavioral impairments, identifying SCD as a therapeutic target for GBA-PD.
Authors
Silke Nuber, Harrison Hsiang, Esra'a Keewan, Tim E. Moors, Sydney J. Reitz, Anupama Tiwari, Gary P. H. Ho, Elena Su, Wolf Hahn, Marie-Alexandre Adom, Riddhima Pathak, Matthew Blizzard, Sangjune Kim, Han Seok Ko, Xiaoqun Zhang, Per Svenningsson, Dennis J. Selkoe, Saranna Fanning
Abstract
In asthma, airway epithelial remodeling is characterized by aberrant goblet cell metaplastic differentiation accompanied by epithelial cell hyperplasia and hypertrophy. These pathologic features in severe asthma indicate a loss of control of proliferation, cell size, differentiation, and migration. mTOR is a highly conserved pathway that regulates protein synthesis, cell size, and proliferation. We hypothesized that the balance between mTOR and autophagy regulates mucous cell metaplasia. Airways from individuals with severe asthma showed increased mTOR signaling by RPS6 phosphorylation, which was reproduced using an IL-13-activated model of primary human airway epithelial cells (hAECs). mTOR inhibition by rapamycin led to a decrease of IL-13-mediated cell hypertrophy, hyperplasia, and MUC5AC mucous metaplasia. BrdU labeling during IL-13-induced mucous metaplasia confirmed that mTOR was associated with increased basal-to-apical hAEC migration. mTOR activation by genetic deletion of Tsc2 in cultured mouse AECs increased IL-13-mediated hyperplasia, hypertrophy, and mucous metaplasia. Transcriptomic analysis of IL-13-stimulated hAEC identified mTOR-dependent expression of genes associated with epithelial migration and cytoskeletal organization. In summary, these findings point to IL-13-dependent and independent roles of mTOR signaling in the development of pathogenic epithelial changes contributing to airway obstruction in severe asthma.
Authors
Katrina M. Kudrna, Luis F. Vilches, Evan M. Eilers, Shailendra K. Maurya, Steven L. Brody, Amjad Horani, Kristina L. Bailey, Todd A. Wyatt, John D. Dickinson
Abstract
Vascular smooth muscle cells (VSMCs) exhibit significant heterogeneity and plasticity, enabling them to switch between contractile and synthetic states, which is crucial for vascular remodeling. NEXN has been identified as a high confidence gene associated with dilated cardiomyopathy (DCM). Existing evidence indicate NEXN is involved in phenotypic switching of VSMCs. However, a comprehensive understanding of the cell-specific roles and precise mechanisms of NEXN in vascular remodeling remains elusive. Using integrative transcriptomics analysis and smooth muscle specific lineage tracing mice, we demonstrate NEXN is highly expressed in VSMCs, and the expression of NEXN is significantly reduced during the phenotypic transformation of VSMCs and intimal hyperplasia induced by vascular injury. VSMC-specific NEXN deficiency promoted the phenotypic transition of VSMCs and exacerbated neointimal hyperplasia in mice following vascular injury. Mechanistically, we found NEXN primarily mediated VSMCs proliferation and phenotypic transition through endoplasmic reticulum (ER) stress and KLF4 signaling. Inhibiting ER stress ameliorated VSMCs phenotypic transition by reducing cell cycle activity and proliferation caused by NEXN deficiency. These findings indicate targeting NEXN could be explored as a promising therapeutic approach for proliferative arterial diseases.
Authors
Zexuan Lin, Chaojie Wang, Zhuohua Wen, Zhaohui Cai, Wenjie Guo, Xin Feng, Zengyan Huang, Rongjun Zou, Xiaoping Fan, Canzhao Liu, Hanyan Yang
Abstract
Human Caspase Recruitment Domain Containing Protein 9 (CARD9) deficiency predisposes to invasive fungal disease, particularly by Candida spp. Distinctly, CARD9-deficiency causes chronic central nervous system (CNS) candidiasis. Currently, no animal model recapitulates the chronicity of disease, precluding a better understanding of immunopathogenesis. We established a knock-in mouse homozygous for the recurring p.Y91H mutation (Y91HKI) and, in parallel to Card9-/- mice, titrated the intravenous fungal inoculum to the CARD9-genotype to develop a model of chronic invasive candidiasis. Strikingly, CARD9-deficient mice had predominantly CNS involvement, with neurological symptoms appearing late during infection and progressive brain fungal burden in the absence of fulminant sepsis, reflecting the human syndrome. Mononuclear cell aggregation at fungal lesions in the brain correlated with increased MHCII+Ly6C+ monocyte numbers at day 1 post-infection in WT and Y91HKI mice, but not in Card9-/- mice. At day 4 post-infection, neutrophils and additional Ly6C+ monocytes were recruited to the CARD9-deficient brain. As in humans, Y91HKI mutant mice demonstrated cerebral multinucleated giant cells and granulomata. Subtle immunologic differences between the hypomorphic (p.Y91H) and null mice were noted, perhaps explaining some of the variability seen in humans. Our work established a disease-recapitulating animal model to specifically decipher chronic CNS candidiasis due to CARD9 deficiency.
Authors
Marija Landekic, Isabelle Angers, Yongbiao Li, Marie-Christine Guiot, Marc-André Déry, Annie Beauchamp, Lucie Roussel, Annie Boisvert, Wen Bo Zhou, Christina Gavino, Julia Luo, Stéphane Bernier, Makayla Kazimerczak-Brunet, Yichun Sun, Brendan Snarr, Michail S. Lionakis, Robert T. Wheeler, Irah L. King, Salman Qureshi, Maziar Divangahi, Donald C. Vinh
Abstract
Single dose radiotherapy (SDRT) is a highly-curative modality that may transform radiotherapy practice. Unfortunately, only ~50% of oligometastatic lesions are SDRT treatable due to adjacent radiosensitive normal organs at risk. Here we address extent to which an anti-angiogenic drug, VEGFR2-antagonist DC101, radiosensitizes SDRT using murine MCA/129 fibrosarcomas and Lewis Lung Carcinomas, which display a dose range for SDRT lesional eradication virtually identical to that employed clinically (10-30Gy). SDRT induces unique tumor cure, stimulating rapid endothelial acid sphingomyelinase (ASMase)/ceramide signaling that yields marked vasoconstriction and perfusion defects in tumor xenografts and human oligometastases. Ensuing tumor parenchymal oxidative damage initiates a SUMO Stress Response (SSR), which inactivates multiple homologous recombination repair enzymes, radiosensitizing all tumor types. While VEGF inhibits neo-angiogenic ASMase, optimal radiosensitization occurs only upon anti-angiogenic drug delivery at ~1h preceding SDRT. Obeying these principles, we find DC101 radiosensitizes SSR, DNA double strand break unrepair and tumor cure by 4-8Gy at all clinically-relevant doses. Critically, DC101 fails to sensitize small intestinal endothelial injury or lethality from the gastrointestinal-acute radiation syndrome.
Authors
Jin Cheng, Liyang Zhao, Sahra Bodo, Prashanth K. B. Nagesh, Rajvir Singh, Adam O. Michel, Regina Feldman, Zhigang Zhang, Simon N. Powell, Zvi Fuks, Richard Kolesnick
Abstract
There is an emerging role for Stimulator of interferon genes (STING) signaling in pulmonary hypertension (PH) development. Related, prior resesarch has demonstrated the relevance of the immune checkpoint protein Programmed death ligand 1 (PD-L1) expression by immunoregulatory myeloid cells in PH. However, there remains a need to elucidate the cell-specific role of STING expression, and the STING/PD-L1 signaling axis in PH, before readily available disease-modifying therapies can be applied to patients with disease. Here, through generation of bone marrow chimeric mice, we show that STING-/- mice receiving wild-type (WT) bone marrow are protected against PH secondary to chronic hypoxia. We further demonstrate a cellular dichotomous role for STING in PH development with STING expression by smooth muscle cells contributing to PH, and its activation on myeloid cells being pivotal in severe disease prevention. Finally, we provide evidence that a STING-PD-L1 axis modulates disease severity, suggesting future potential therapeutic applications. Overall, these data provide concrete evidence of STING involvement in PH in a cell-specific manner, establishing biologic plausibility for cell-targeted STING-related therapies in PH treatment.
Authors
Ann T. Pham, Shiza Virk, Aline C. Oliveira, Matthew D. Alves, Chunhua Fu, Yutao Zhang, Jimena Alvarez-Castanon, Brian B. Lee, Keira L. Lee, Radwan Mashina, Katherine E. Ray, Patrick Donabedian, Elnaz Ebrahimi, Harsh Patel, Reeha Patel, Duncan Lewis, Zhiguang Huo, Harry Karmouty-Quintana, Li Chen, Lei Jin, Andrew J. Bryant
Abstract
CD16 is an activating Fc receptor on natural killer cells that mediates antibody-dependent cellular cytotoxicity (ADCC), a key mechanism in antiviral immunity. However, the role of NK cell-mediated ADCC in SARS-CoV-2 infection remains unclear, particularly whether it limits viral spread and disease severity or contributes to the immunopathogenesis of COVID-19. We hypothesized that the high-affinity CD16AV176 polymorphism influences these outcomes. Using a novel in vitro reporter system, we demonstrated that CD16AV176 is a more potent and sensitive activator than the common CD16AF176 allele. To assess its clinical relevance, we analyzed 1,027 hospitalized COVID-19 patients from the Immunophenotyping Assessment in a COVID-19 Cohort (IMPACC), a comprehensive longitudinal dataset with extensive transcriptomic, proteomic, and clinical data. The high-affinity CD16AV176 allele was associated with a significantly reduced risk of ICU admission, mechanical ventilation, and severe disease trajectories. Lower anti-SARS-CoV-2 IgG titers were correlated to CD16AV176; however, there was no difference in viral load across CD16 genotypes. Proteomic analysis revealed that participants homozygous for CD16AV176 had lower levels of inflammatory mediators. These findings suggest that CD16AV176 enhances early NK cell-mediated immune responses, limiting severe respiratory complications in COVID-19. This study identifies a protective genetic factor against severe COVID-19, informing future host-directed therapeutic strategies.
Authors
Anita E. Qualls, Tasha Tsao, Irene Lui, Shion A. Lim, Yapeng Su, Ernie Chen, Dylan Duchen, Holden T. Maecker, Seunghee Kim-Schulze, Ruth R. Montgomery, Florian Krammer, Charles R. Langelier, Ofer Levy, Lindsey R. Baden, Esther Melamed, Lauren I.R. Ehrlich, Grace A. McComsey, Rafick P. Sekaly, Charles B. Cairns, Elias K. Haddad, Albert C. Shaw, David A. Hafler, David B. Corry, Farrah Kheradmand, Mark A. Atkinson, Scott C. Brakenridge, Nelson I. Agudelo Higuita, Jordan P. Metcalf, Catherine L. Hough, William B. Messer, Bali Pulendran, Kari C. Nadeau, Mark M. Davis, Ana Fernandez-Sesma, Viviana Simon, Monica Kraft, Christian Bime, Carolyn S. Calfee, David J. Erle, Joanna Schaenmann, Al Ozonoff, Bjoern Peters, Steven H. Kleinstein, Alison D. Augustine, Joann Diray-Arce, Patrice M. Becker, Nadine Rouphael, IMPACC Network, Jason D. Goldman, Daniel R. Calabrese, James R. Heath, James A. Wells, Elaine F. Reed, Lewis L. Lanier, Harry Pickering, Oscar A. Aguilar
Abstract
Diabetic kidney disease (DKD) is the leading cause of end stage kidney disease. Kidney tubular cells have a high energy demand, dependent on fatty acid oxidation (FAO). Although carnitine is indispensable for FAO, the pathological role of carnitine deficiency in DKD is not fully understood. We showed here that ectopic lipid accumulation due to impaired FAO increased in patients with DKD and inversely correlated with renal function. OCTN2 deficient mice exhibited systemic carnitine deficiency with increased renal lipid accumulation. Cell death and inflammation were induced in OCTN2-deficient, but not wild-type tubular cells exposed to high salt and high glucose. Compared with SDT fatty rats, uninephrectomized SDT fatty rats fed with 0.3% NaCl had higher lipid accumulation and exhibited increased urinary albumin excretion with renal dysfunction and tubulointerstitial injury, all of which were ameliorated by L-carnitine supplementation via stimulating FAO and mitochondrial biogenesis. In our single-center randomized control trial with patients undergoing peritoneal dialysis, L-carnitine supplementation preserved residual renal function and increased urine volume, the latter of which was correlated with improvement of tubular injury. The present study demonstrates the pathological role of impairment of carnitine-induced FAO in DKD, suggesting that L-carnitine supplementation is a potent therapeutic strategy for this devastating disorder.
Authors
Sakuya Ito, Kensei Taguchi, Goh Kodama, Saori Kubo, Tomofumi Moriyama, Yuya Yamashita, Yunosuke Yokota, Yosuke Nakayama, Yusuke Kaida, Masami Shinohara, Kyoko Tashiro, Keisuke Ohta, Sho-ichi Yamagishi, Kei Fukami
Abstract
Benign prostatic hyperplasia (BPH) is the most common urologic condition in elderly men, characterized by the reactivation of developmental programs such as prostatic budding and branching. However, the molecular mechanisms underlying this reactivation in BPH remain unclear. In this study, we identified TIAM1 (T-lymphoma invasion and metastasis-inducing protein-1) as a critical regulator of prostatic budding and branching. By generating an unbiased BPH transcriptomic signature from patient datasets, we discovered an upregulation of TIAM1, which was subsequently validated at the protein level. Functional assays using organoid cultures derived from human prostatic cell lines revealed that TIAM1 is essential for prostatic budding and branching. Additionally, the BPH transcriptomic signature identified NSC23766, a small molecule inhibitor of TIAM1-RAC1 signaling, as a therapeutic proof-of-concept agent for BPH. Genetic knockdown of TIAM1 in human prostatic cell lines markedly reduced organoid branching, an effect mirrored by administration of NSC23766. The translational relevance of these findings is underscored by the growth inhibition observed in patient-derived BPH organoids treated with NSC23766. In conclusion, our findings identify TIAM1 as a key driver of prostatic branching and growth, and suggest that targeting TIAM1-RAC1 signaling could be a promising therapeutic strategy for BPH.
Authors
Hamed Khedmatgozar, Sayanika Dutta, Michael Dominguez, Murugananthkumar Raju, Girijesh Kumar Patel, Daniel Latour, Melanie Johnson, Mohamed Fokar, Irfan Warraich, Allan Haynes, Barry J. Maurer, Werner de Riese, Luis Brandi, Robert J. Matusik, Srinivas Nandana, Manisha Tripathi
Abstract
DNA repair is essential for preserving genome integrity. Podocytes, post-mitotic epithelial cells of the kidney filtration unit, bear limited regenerative capacity, yet their survival is indispensable for kidney health. Podocyte loss is a hallmark of the aging process and of many diseases, but the underlying factors remain unclear. We investigated the consequences of DNA damage in a podocyte-specific knockout mouse model for Ercc1 and in cultured podocytes under genomic stress. Furthermore, we characterized DNA damage-related alterations in mouse and human renal tissue of different ages and patients suffering from minimal change disease and focal segmental glomerulosclerosis. Ercc1 knockout resulted in accumulation of DNA damage, ensuing albuminuria and kidney disease. Podocytes reacted to genomic stress by activating mTORC1 signaling in vitro and in vivo. This was abrogated by inhibiting DNA damage signaling through DNA-PK and ATM kinases and inhibition of mTORC1 modulated the development of glomerulosclerosis. Perturbed DNA repair gene expression and genomic stress in podocytes was also detected in focal segmental glomerulosclerosis. Beyond that, DNA damage signaling occurred in podocytes of healthy aging mice and humans. We provide evidence that genome maintenance in podocytes is linked to the mTORC1 pathway, involved in the aging process and the development of glomerulosclerosis.
Authors
Fabian Braun, Amrei M. Mandel, Linda Blomberg, Milagros N. Wong, Georgia Chatzinikolaou, David H. Meyer, Anna Reinelt, Viji Nair, Roman Akbar-Haase, Phillip J. McCown, Fabian Haas, He Chen, Mahdieh Rahmatollahi, Damian Fermin, Robin Ebbestad, Gisela G. Slaats, Tillmann Bork, Christoph Schell, Sybille Koehler, Paul T. Brinkkoetter, Maja T. Lindenmeyer, Clemens D. Cohen, Martin Kann, David Unnersjö-Jess, Wilhelm Bloch, Matthew G. Sampson, Martijn E.T. Dollé, Victor G. Puelles, Matthias Kretzler, George A. Garinis, Tobias B. Huber, Bernhard Schermer, Thomas Benzing, Björn Schumacher, Christine E. Kurschat
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