Systemic lupus erythematosus (SLE) is a heterogeneous systemic autoimmune disease, yet the molecular basis underlying this variability remains incompletely understood. We profiled the plasma proteome in 260 SLE patients and 86 healthy volunteers (HVs) using the SomaScan v4.1 platform, quantifying 7,288 analytes corresponding to 6,595 unique proteins. We identified 215 proteins that were robustly differentially abundant between SLE patients and HVs in both discovery (n=207 SLE, n=45 HVs) and validation sets (n=53 SLE, n=41 HVs). Within-cases analyses identified 421 proteins associated with disease activity. Network-based clustering delineated correlated protein modules, including an interferon-associated module and a renal-associated module. Autoantibody-stratified analyses further uncovered distinct proteomic endotypes: positivity for antibodies targeting RNA-binding proteins (anti-Sm, anti-Ro-60, anti-RNP68, anti-RNP-A) was associated with increased interferon-stimulated protein levels (e.g., MX1, ISG15, CXCL10), independent of disease activity. Anti-Sm, anti-RNP-A and anti-Ro52 antibodies were associated with reduced plasma levels of their respective autoantigens. Anti-dsDNA antibodies were associated with elevated levels of CD40 ligand (CD40LG) and the neutrophil protease proteinase-3. Moreover, we identified an association between CD40LG and disease activity specific to the anti-dsDNA positive subgroup. Together, these data define plasma protein signatures of SLE and disease activity, highlight autoantibody-specific molecular phenotypes, and provide a basis for precision medicine.
Geoffrey H. D. Leung, Charlotte Bottomley, Norzawani Buang, Robert T. Maughan, Benjamin J. Whittle, Boroumand Zeidaabadi, Yun-Ju Huang, Tabitha Turner-Stokes, Marie Condon, Liz Lightstone, Tom Cairns, Marina Botto, Matthew C. Pickering, James E. Peters
Vascular tortuosity (VT) is a critical biomarker of disease progression and decision to treat ischemic retinal disorders, particularly retinopathy of prematurity (ROP). The murine oxygen-induced retinopathy model is the most widely-used model of ischemic retinopathy. Although VT has been described in OIR, its temporal dynamics have not been systematically defined. In this study, a semi-automated artificial intelligence (AI)-based pipeline was used to quantify VT throughout OIR. Retinal flat mounts from age-matched normoxic and OIR mice (postnatal days [P]10-P56) underwent vessel segmentation using a generative adversarial network (GAN), and VT was quantified as a cumulative tortuosity index (CTI) with the iROP-Assist algorithm. Concurrently, standard OIR outcomes of neovascularization (NV) and vaso-obliteration (VO) were quantified using OIRseg.org. NV peaked at P17 and resolved by P23, while VO regressed over a similar interval. VT peaked with NV at P17 but remained elevated through P56. These temporal changes mirror both the development of VT and its persistence after NV regression observed clinically in ROP. Collectively, these findings establish VT as a durable, quantifiable phenotype in OIR and expand the model’s utility beyond neovascular endpoints, providing a translational platform for investigating VT pathogenesis and evaluating the effects of therapeutic agents on vascular tortuosity.
Kyle V. Marra, Tomoya Murakami, Jimmy S. Chen, Edith Aguilar, Jacob I. Robinson, Maxwell Prenner, Richard Daneman, Martin Friedlander, Eric Nudleman
Spreading depolarizations (SDs) are propagating waves of near-complete breakdown of transmembrane ion gradients that occur during acute ischemic stroke and worsen outcome by driving calcium overload and glutamate release in neurons and astrocytes. The plasmalemmal sodium-calcium exchanger (NCX) plays a key role in such changes, in that the complex ionic disequilibrium during ischemia induces reverse-mode activity of NCX, leading to cellular calcium overload in exchange for sodium. However, the cell type-specific roles of NCX in neurons and astrocytes during SDs remain unclear. Here, we used ion and glutamate reporters in an in vivo stroke model in mice carrying inducible, cell-specific deletions of NCX isoform-1. Neuronal NCX1 deletion reduced neuronal and astrocytic calcium transients, increased neuronal sodium transients, decreased extracellular glutamate levels, and raised SD initiation threshold. In contrast, astrocytic NCX1 deletion increased sodium transients in both neurons and astrocytes, and increased neuronal calcium as well as extracellular glutamate levels. A computational model of ischemia confirmed that these effects are consistent with reverse-mode NCX1 activity. Together, these findings indicate opposing roles of reverse-mode NCX1 during ischemia. Neuronal NCX1 promotes SD susceptibility, calcium overload and glutamate release, whereas astrocytic NCX1 exerts protective effects by attenuating glutamate elevation and neuronal calcium accumulation.
Somayyeh Hamzei Taj, Pawan Kumar Thapaliya, Cordula Rakers, Niklas J. Gerkau, Christine R. Rose, Ghanim Ullah, Gabor C. Petzold
The sodium-dependent multivitamin transporter, encoded by SLC5A6, mediates cellular uptake of biotin and pantothenic acid, essential cofactors for energy metabolism. We identified two families with SLC5A6 mutations presenting with early-onset dilated cardiomyopathy (DCM). To investigate the link between vitamin deficiency and cardiomyopathy, we generated a cardiac-specific SLC5A6 knockout (Slc5a6cKO) mouse model and evaluated the impact of vitamin supplementation. Slc5a6cKO mice developed progressive cardiac dysfunction, culminating in cardiac pathology and premature death at 26 weeks; earlier stages exhibited cardiomyocyte hypertrophy, fibrosis, impaired Coenzyme A synthesis, and metabolic imbalance, indicating progression toward cardiomyopathy. Cardiac magnetic resonance imaging and ECG confirmed progressive functional decline. Proteomic analysis revealed early mitochondrial metabolic disruption and extracellular matrix protein upregulation at 8 weeks, preceding overt cardiac dysfunction. Strikingly, vitamin supplementation from preconception onwards prevented the cardiac phenotype, preserving cardiac structure, function, morphology and survival. This paralleled the clinical outcome in one patient who received early vitamin treatment, compared to another who required a heart transplant without vitamin treatment. This study establishes a direct link between SLC5A6-mediated vitamin transport, mitochondrial function, and cardiac health. It highlights how vitamin deficiency contributes to cardiomyopathy pathogenesis and supports early vitamin supplementation as a potential therapeutic strategy for metabolic cardiomyopathies.
Millie O. Fullerton, Lauren C. Phillips, Rachael E. Redgrave, Luke Spray, Vincent Haufroid, George Merces, Scott T. Kerridge, Gavin D. Richardson, Nathalie Mercier, Dominique Roland, Rebecca Crossley, Andrew D.H. Morgan, Joseph P. Dewulf, John Burn, Simon D. Bamforth, Helen M. Phillips
Virally suppressed people with HIV (PWH) remain at risk for developing comorbidities due to chronic inflammation with one potential contributor being the HIV reservoir. Associations between the CD4-reservoir and inflammation have been extensively characterized, while the role the monocyte-reservoir is poorly understood despite evidence that inflammatory monocytes play a role in HIV-associated comorbidities. Additionally, most studies focus on a single cellular reservoir, while it is highly likely that these reservoirs are interdependent. In a cohort of 164 PWH, we used the intact proviral DNA assay to quantify cell-specific reservoirs, applied unsupervised clustering to identify reservoir phenotypes, and then determined if reservoir phenotypes were associated with distinct immune signatures compared to people without HIV. Five unique reservoir clusters emerged driven primarily by variability in the monocyte reservoir, and each associated with a distinct immune landscape. These included profiles characterized by systemic inflammation, leukocyte–vascular activation, T cell activation with vascular and neuronal injury, enhanced CD8 activation and NK cell recovery, and altered monocyte survival, activation, and migration. This multidimensional approach provides a framework to identify reservoir-immune profiles that may explain heterogeneity in inflammation despite viral suppression and may inform strategies to mitigate HIV-associated comorbidities.
Ruoyu Wang, Aparna B. Bhattacharyya, Lily Pohlenz, Erin N. Shirk, Hayley S. Romero, Katherine Haas, Jennifer M. Coughlin, Raha M. Dastgheyb, Leah H. Rubin, Rebecca T. Veenhuis
Idiopathic Pulmonary Fibrosis (IPF) is a fatal, aging-related disease characterized by persistent lung fibroblast activation, progressive lung scarring and several vascular abnormalities. We have previously demonstrated that aging-associated vascular dysfunction drives maladaptive endothelial responses to injury and exacerbates lung fibrosis via secretion of pro-fibrotic endothelial-derived factors. However, regulatory mechanisms governing endothelial dysfunction during progressive lung fibrosis remain poorly understood. Here, using preclinical mouse models of progressive lung fibrosis as well as human IPF lungs, we demonstrate that miR-205-5p is overexpressed in lung ECs from fibrotic lungs, and coordinates gene expression programs implicated in endothelial dysfunction and progressive fibrosis. Mechanistically, miR-205-5p induces senescence in lung ECs, mirroring the senescent phenotype of IPF lung ECs. Consistently, conditioned medium derived from lung ECs overexpressing miR-205-5p promotes lung fibroblast activation. Importantly, miR-205-5p inhibition in IPF lung ECs attenuates endothelial senescence and limits paracrine fibroblast activation. Finally, inhibition of miR-205-5p in vivo preserves the pulmonary vascular network and attenuates lung fibrosis progression in aged mice challenged with bleomycin. Collectively, our findings support a novel connection between lung endothelial miR-205-5p, endothelial senescence and pro-fibrotic alteration of the endothelial secretome, and highlight miR-205-5p inhibition as a potential therapeutic intervention for pulmonary fibrosis.
Giuseppe Muscato, Benjamin B. Roos, Sharonda Harris, Xiaoyu Tracy Cai, Gina Civettini, Enrico Sciacca, Ahmed Raslan, Alessandra Castaldi, Sharon Elliot, Marilyn K. Glassberg, Carlo Vancheri, Daniel J. Tschumperlin, Giovanni Ligresti, Nunzia Caporarello
Identifying mechanisms of kidney disease commonly involves comparing diseased samples to healthy reference tissues; however, the effects of variability in tissue procurement, storage, and donor characteristics remain underexplored. In this study, we systematically evaluated three reference tissue types—tumor nephrectomy (TN), pre-transplant biopsies from living donors (LD), and percutaneous biopsies from healthy control volunteers (HC)—to determine their impact on differential gene expression across three diabetic kidney disease (DKD) states. We observed distinct injury markers, cell state proportions, and gene signatures associated with procurement method, sex, and donor age. Adjustment for these confounding factors significantly influenced pathway analysis results. Specifically, correcting for age and sex eliminated significant enrichment of interferon gamma response in the diabetes mellitus–resilient (DM-R) versus HC comparison. Processes related to biological aging were enriched in older reference tissues, potentially confounding disease-specific interpretations. Importantly, tumor necrosis factor signaling via nuclear factor-κB remained enriched in LD and TN samples relative to HC, even after accounting for confounders. These results underscore the critical importance of selecting appropriate control tissues and rigorously adjusting for confounding variables to reliably discern the molecular mechanisms underlying kidney diseases.
Rajasree Menon, Paul L. Kimmel, Edgar A. Otto, Lalita Subramanian, Christopher L. O'Connor, Bradley Godfrey, Cathy Smith, Fadhl Alakwaa, Celine C. Berthier, Minnie M. Sarwal, E. Steve Woodle, Laura Pyle, Ye Ji Choi, Patricia Ladd, John R. Sedor, Sylvia E. Rosas, Sushrut S. Waikar, Abhijit S. Naik, Ricardo Melo Ferreira, Michael T. Eadon, Markus Bitzer, Petter Bjornstad, Jeffrey B. Hodgin, Matthias Kretzler
HLA-E-restricted HIV-specific T cells offer exciting possibilities for immunotherapy. However, HLA-E binding peptides are rare. A recent study showed that in HLA-B*57:01 people living with HIV (PLWH), the peptide that dominates the T cell response, KAFSPEVIPMF (KF11), also stimulates HLA-E-restricted T cells, even though direct binding of this peptide to HLA-E could not be demonstrated. We therefore changed position 2 alanine for methionine in the peptide (referred to as KMF11) which greatly enhanced binding to HLA-E. This enabled the generation of stabilised HLA-E-KMF11 tetramers which were used to select and then grow specific T cell clones from T cells of HLA-B*57:01 negative blood donors primed with this peptide in vitro. Approximately 20% of these T cell clones reacted with HLA-E positive cells presenting the native KF11 peptide. Furthermore, these T cells inhibited replication of HIV-1 NL4-3 in CD4 T cells in vitro. Therefore, this native peptide can be presented by HLA-E to CD8 T cells, although priming in vivo may depend on cross reactivities to classical MHC Ia types. Nevertheless, such T cells could be exploitable for immunotherapy given the conservation of this HIV1 peptide epitope and the non-polymorphism in HLA-E.
Hong Sun, Hongbing Yang, Max N. Quastel, Simon Brackenridge, Wanlin He, Anna E. Kliszczak, Margarida Rei, Persephone Borrow, Geraldine M. Gillespie, Andrew J. McMichael
Biallelic loss-of-function variants in the adaptor protein complex 4 (AP-4) disrupt trafficking of transmembrane proteins at the trans-Golgi network, including the autophagy-related protein 9A (ATG9A), leading to childhood-onset hereditary spastic paraplegia (AP-4-HSP). AP-4-HSP is characterized by features of both a neurodevelopmental and degenerative neurological disease. To investigate the molecular mechanisms underlying AP-4-HSP and identify potential therapeutic targets, we conducted an arrayed CRISPR/Cas9 loss-of-function screen of 8,478 genes, targeting the ‘druggable genome’, in a human neuronal model of AP-4 deficiency. Through this phenotypic screen and subsequent experiments, key modulators of ATG9A trafficking were identified, and complementary pathway analyses provided insights into the regulatory landscape of ATG9A transport. Knockdown of ANPEP and NPM1 enhanced ATG9A availability outside the trans-Golgi network, suggesting they regulate ATG9A localization. These findings deepen our understanding of ATG9A trafficking in the context of AP-4 deficiency and offer a framework for the development of targeted interventions for AP-4-HSP.
Marvin Ziegler, Cedric Günter, Julian E. Alecu, Xutong Xue, Hyo-Min Kim, Afshin Saffari, Alexandra K. Davies, Mustafa Sahin, Darius Ebrahimi-Fakhari
Idiopathic pulmonary fibrosis (IPF) is characterized by parenchymal scarring reflecting an imbalance between collagen deposition by myofibroblasts (MFs) and its turnover. Although collagen clearance is essential for fibrosis resolution, this process and its potential for therapeutic modulation in IPF are poorly understood. Here we evaluated internalization of degraded collagen and the role of its requisite endocytic receptor mannose receptor C-type 2 (MRC2), in lung tissue and MFs from IPF patients and bleomycin-injured mice. Fibrotic human and murine lung tissue exhibited an accumulation of degraded collagen, highlighting a failure of its clearance. MFs from fibrotic lung demonstrated a reduced capacity to internalize extracellular degraded collagen, with a concomitant reduction in MRC2 expression and endolysosomal activity. Both diminished collagen uptake and MRC2 expression recovered to baseline levels during spontaneous resolution of bleomycin fibrosis. In vitro treatment of IPF or TGF-β-elicited MFs with a variety of mechanistically distinct agents known to effect phenotypic dedifferentiation restored defective collagen internalization. Although enhanced uptake was MRC2-dependent, it involved increased endolysosomal activity rather than increased MRC2 expression. These results implicate defective MRC2-dependent collagen internalization and endolysosomal function in MFs as important factors contributing to fibrosis that may be therapeutically targeted to promote resolution.
Natalie M. Walker, Sean M. Fortier, Jennifer Speth, Steven K. Huang, Sergey Gutor, Timothy S. Blackwell, Marc Peters-Golden
Aging drives systemic metabolic dysfunction (SMD) and increases the risk of chronic illnesses such as metabolic dysfunction–associated steatotic liver disease (MASLD) and chronic kidney disease (CKD). However, mechanisms that connect aging to multi-organ deterioration are poorly understood. In this study, we identify hepatocyte Hedgehog signaling as a central regulator of ferroptosis. Using mice with hepatocyte-specific deletion of Smoothened (Smo), a key Hedgehog pathway component, we show that loss of hepatocyte Hedgehog signaling induces ferroptotic stress, lipid peroxidation, and cellular senescence. These changes were sufficient to cause spontaneous MASLD and to trigger secondary kidney injury. Smo deletion also disrupted systemic iron balance, increased hepatocyte production of the angiotensinogen, and reduced liver perfusion. Similar responses (iron dysregulation, vascular dysfunction, and reduced Hedgehog signaling) were observed in patients with MASLD and advanced fibrosis. Inhibition of ferroptosis with ferrostatin-1 reversed hepatocyte senescence, restored hepatic blood flow, and improved both liver and kidney injury in Smo-deficient mice. Overall, these findings show that hepatocyte Hedgehog signaling preserves liver homeostasis by restraining ferroptotic stress and coordinating iron-dependent vasoactive pathways. The results reveal an unrecognized aging-related communication axis between liver and kidney and identify the Hedgehog–ferroptosis pathway as a promising therapeutic target for age-associated metabolic diseases.
Ji Hye Jun, Rajesh K. Dutta, Soon-Woo Cho, Rui Yao, Seh Hoon Oh, Zhi Li, Kuo Du, David S. Umbaugh, Nanchao Wang, Yirui Xu, Jingting Li, Lingyan Shi, Jen-Tsan Chi, Junjie Yao, Anna Mae Diehl
Sarah Platt, Norhan B.B. Mohammed, Joseph Brancale, Caroline S.C. Tippett, Kevin Seo, Silvia Vilarinho
Ubiquitin-Specific Protease 18 (USP18) is a deISGylation enzyme and antineoplastic target. To develop USP18 inhibitors, an enzymatically active human recombinant USP18 protein was engineered suitable for high-throughput screening of ~80,000 chemical compounds. Three of them substantially inhibited USP18 enzymatic activity with β-lapachone having prominent antineoplastic activity. Independent β-lapachone treatments of murine and human lung cancer cell lines statistically-significantly reduced proliferation and increased apoptosis. Gain of USP18 expression antagonized these effects. β-lapachone treatments statistically-significantly repressed lung cancer xenograft growth. β-lapachone increased reactive oxygen species (ROS), but antineoplastic effects occurred at dosages with negligible ROS production. ROS scavenger treatments did not rescue β-lapachone effects at these concentrations, consistent with an ROS-independent mechanism. Interferon-Stimulated Response Element (ISRE) reporter assays following β-lapachone treatment activated this reporter. USP18 co-transfection antagonized this activity. β-lapachone treatments increased global ISGylation. RNA sequencing of lung cancer cells engineered with or without enhanced USP18 expression showed specific pathways affected by β-lapachone treatment. Proteomic analysis of these treated cells revealed known and new ISGylated proteins. In silico modeling identified a unique USP18 pocket where these USP18 inhibitors bind. Engineered mutation of this pocket disrupted β-lapachone activity. Taken together, β-lapachone is an antineoplastic tool compound useful for USP18 inhibitor development.
Blessing O. Ogunlade, Kevin N. Dalby, Samuel C. Okpechi, Eun Jeong Cho, Liliya Tyutyunyk-Massey, Zibo Chen, Xiuxia Liu, Joseph Ivanic, Brian Luke, Shyamal D. Desai, Yair Alfaro, Ashwini K. Devkota, Rae M. Sammons, Gilbert G. Privé, Xi Liu, Ethan Dmitrovsky
Ischemia/reperfusion (IR) enhances oxidative stress, leading to myocardial injury. Although Perm1 promotes cytoprotective mechanisms, the underlying mechanisms are poorly understood. Cysteine oxidation of Keap1 alleviates Cul3-mediated ubiquitination/degradation of Nrf2 and promotes antioxidant transcription. Here we show that Perm1 activates Nrf2 through cysteine oxidation of Keap1 and stabilization of Nrf2. Endogenous Perm1 was downregulated during IR, whereas the rescue of Perm1 reduced IR injury. Downregulation of Perm1 exacerbated oxidative stress, whereas upregulation of Perm1 alleviated it, accompanied by downregulation and upregulation of Nrf2-regulated antioxidant genes, respectively. Perm1 promoted oxidation of cysteine residues in Keap1, possibly through thiol-disulfide exchange reactions, which decreases Keap1-Nrf2 interaction and inhibits Cul3-mediated degradation of Nrf2. We identified Cys121 and Cys746 in Perm1 as critical for Keap1 oxidation and cardioprotection. Thus, Perm1 induces cysteine oxidation of Keap1, thereby conferring myocardial resistance to IR injury by inducing Nrf2 stabilization and transcriptional activation of antioxidant genes.
Shin-ichi Oka, Chun-Yang Huang, Masato Matsushita, Allen Sam Titus, Yasuki Nakada, Risa Mukai, Samta Veera, Youssef Mourad, Ghassan Yehia, Peter Romanienko, Yimin Tian, Peiyong Zhai, Junichi Sadoshima
Kawasaki disease (KD) is an acute febrile systemic vasculitis of unknown etiology and the leading cause of acquired heart disease among children. Complement activation has long been observed in patients with acute KD, however, its contribution to disease development remains unknown. Here, using publicly available datasets, we showed that patients with acute KD exhibited higher expression of complement products in whole blood, consistent with the activation of the complement pathway. Similarly, in the Lactobacillus casei cell wall extract (LCWE) murine model of KD, LCWE injection induced increased expression of complement products in cardiovascular tissues, suggestive of activation of the complement pathways. C3-deficient mice or WT mice treated with the complement C5a Receptor 1 (C5ar1) antagonist developed significantly more severe LCWE-induced cardiovascular lesions and vasculitis. Furthermore, we observed that LCWE binds to serum C3, an opsonizing factor that labels microbial targets for clearance, and LCWE deposition in the liver was significantly higher in C3-deficient mice compared to WT mice. Overall, our data indicate that blocking the complement system significantly exacerbates LCWE-induced KD vasculitis, likely by impairing C3-mediated clearance of LCWE. These data suggest that the complement pathway may play a protective role in KD pathogenesis by promoting clearance of potential bacterial or viral trigger of KD.
Asli E. Atici, Begüm Kocatürk, Benjamin L. Ross, Emily A. Aubuchon, Rebecca A. Porritt, Thacyana T. Carvalho, Takahiro Namba, Youngho Lee, Magali Noval Rivas, Moshe Arditi
Antibody production by B cells has emerged as an important factor in regulating anti-tumor immunity with both suppressive and promotive roles in cancer. However, the specific impact of antibody deficiency during development of pancreatic ductal adenocarcinoma (PDAC) has not been explored. To address this question, we crossed the well-established KPC mouse model to mice lacking all circulating immunoglobulin (Ig) due to genetic ablation of both Ig secretion and Ig class switching (KPC-μSAID mice). KPC-μSAID mice exhibited a two-fold acceleration in tumor formation, a two-fold reduction in median survival, and increased liver metastases versus KPC-WT control mice. Immunofluorescence analysis of pancreatic tissues from antibody-sufficient KC- and KPC-WT mice showed that IgG was predominantly localized within extracellular matrix (ECM). Furthermore, in both KC- and KPC-μSAID mice, ECM density and podoplanin+ cancer-associated fibroblasts (CAFs) were significantly reduced. In the KPC-μSAID tumor microenvironment (TME), intratumoral myeloid-derived suppressor cells (MDSC) were also increased, while CD4+ and CD8+ T cells decreased, relative to tumor-bearing KPC-WT mice, with macrophage exhibiting a mixed polarization phenotype. These findings were recapitulated in antibody-subclass-deficient, KPC-AID mice, suggesting a potentially novel function of IgG in suppressing PDAC progression, by directly or indirectly regulating pancreatic fibrosis and the density of the ECM.
Jeremy B. Foote, Sujith Sarvesh, Sameer Al Diffalha, David K. Crossman, Changde Cheng, Myng-Hee Kim, Cherlene Hardy, Julienne L. Carstens, Kyoko Kojima, Bart J. Rose, Christopher A. Klug
Because older donor age is a major concern when considering kidneys for potential transplantation, we explored the actual impact of donor age on the features of kidneys that have been transplanted. We studied the correlations of donor age with molecular injury and rejection scores in 4502 kidney transplant biopsies assessed by microarrays, as well as function and postbiopsy survival. We used multivariable analyses to correct for the correlations of donor age with other predictive variables: recipient age, time of biopsy posttransplant, and deceased vs. living donors. Older donor age correlated with lower GFR and increased acute and chronic injury transcripts, but had no effect on rejection, which anti-correlated with recipient age. Acute injury transcripts peaked immediately posttransplant and regressed. Older donor age had little effect on acute molecular injury immediately posttransplant but strongly increased molecular injury scores at later times, peaking about 1-year posttransplant, indicating that older age does not increase molecular injury but increases failed repair post-injury. As expected, older donor age correlated with increased chronic injury and lower GFR, evident from the earliest time posttransplant, pre-transplant aging. However, despite significant age-related effects, the quantitative contribution of donor aging to molecular injury, function, and survival was very small.
Katelynn Madill-Thomsen, Martina Mackova, Jessica Chang, Enver Akalin, Tarek Alhamad, Sanjiv Anand, Miha Arnol, Rajendra Baliga, Mirosław Banasik, Christopher Blosser, Georg Böhmig, Daniel Brennan, Jonathan Bromberg, Klemens Budde, Andrzej Chamienia, Kevin V Chow, Michał Ciszek, Declan de Freitas, Dominika Dęborska-Materkowska, Alicja Dębska-Ślizień, Arjang Djamali, Leszek Domański, Magdalena Durlik, Gunilla Einecke, Farsad Eskandary, Richard Fatica, Iman Bajjoka-Francis, Justyna Fryc, John Gill, Jagbir Gill, Maciej Glyda, Sita Gourishankar, Marta Gryczman, Gaurav Gupta, Petra Hruba, Peter Hughes, Arskarapuk Jittirat, Zeljka Jurekovic, Layla Kamal, Mahmoud Kamel, Sam Kant, Nika Kojc, Joanna Konopa, James Lan, Roslyn Mannon, Arthur Matas, Joanna Mazurkiewicz, Marius Miglinas, Thomas Mueller, Marek Myślak, Beata Naumnik, Anita Patel, Agnieszka Perkowska-Ptasińska, Michael Picton, Grzegorz Piecha, Emillio Poggio, Silvie Rajnochova Bloudickova, Thomas Schachtner, Sung Shin, Soroush Shojai, Majid Sikosana, Janka Slatinská, Katarzyna Smykal-Jankowiak, Ashish Solanki, Zeljka Veceric Haler, Ondrej Viklicky, Ksenija Vucur Simic, Matthew R. Weir, Andrzej Wiecek, Zbigniew Włodarczyk, Ziad Zaky, Philip F. Halloran
Skeletal muscle pathology is a critical but poorly understood contributor to neuromuscular degeneration in spinal and bulbar muscular atrophy (SBMA), a CAG/polyglutamine (polyQ) expansion disorder caused by mutation in the androgen receptor (AR). Using a gene-targeted SBMA mouse model, we applied single-nucleus RNA sequencing to identify a disease-specific population of skeletal muscle myonuclei that replaced normal myonuclear subtypes. This transition was associated with dysregulation of the pathway governed by PGC-1α, a central regulator of myofiber specification and metabolic identity. PGC-1α dysfunction in SBMA muscle was age-, hormone-, and polyQ length–dependent and was partially rescued by subcutaneous delivery of AR-targeted antisense oligonucleotides. Integrated ChIP-seq and RNA-seq analyses revealed that aberrant PGC-1α activity promoted the expression of a distinct set of myofiber specification genes while downregulating those that define healthy Type IIb and Type IIx myonuclei. We propose a model in which this dysfunction arose downstream of polyQ-mediated sequestration of PGC-1α cofactors MEF2, CREB, and CBP, leading to transcriptional reprogramming and cellular dysfunction. These findings implicated PGC-1α dysregulation as a key event linking AR polyQ expansion to skeletal muscle degeneration and suggested a shared mechanism for polyQ-mediated muscle pathology across related neurodegenerative diseases.
Curtis J. Kuo, Laura B. Chopp, Zhigang Yu, Luhan Ni, Hien T. Zhao, Janghoo Lim, Andrew P. Lieberman
Cancer-induced bone pain (CIBP) is among the most common and debilitating symptoms in patients with bone metastasis. Current treatments are somewhat effective but have severe side effects. For the future development of safer CIBP treatment, in this study, we sought to investigate the mechanisms whereby the cancer/nerve interaction controls CIBP. We found that c-Kit, a receptor tyrosine kinase, was activated in the dorsal root ganglia (DRG) sensory neurons of mice with CIBP and that c-Kit’s sole ligand, stem cell factor (SCF), was enhanced in the bone marrow with bone metastasis. When DRGs were treated SCF or conditioned medium from high SCF-expressing cancer cells, in vitro nerve sprouting was enhanced, and this effect was abolished with c-Kit inhibitors. Mice, intrafemorally inoculated with cancer cells that had varying SCF-expression developed CIBP and enhanced peripheral nerve sprouting in an SCF-dependent manner. Downstream proteomic analysis revealed that SCF upregulated and activated fibroblast growth factor 1 (FGF1) in DRGs. When FGF1 was knocked down in DRGs, SCF-mediated nerve sprouting was prevented. Taken together, our studies demonstrate the importance of the SCF/c-Kit axis in CIBP and nerve sprouting, and identify the SCF/c-Kit/FGF1 pathway as a potential therapeutic target for CIBP.
Kelly F. Contino, Jenna Ollodart, Yang Yu, Sun H. Park, Shunsuke Tsuzuki, Kara Rollins, Tyler M. Heethouse, Joshua Chu, Laiton R. Steele, Takahiro Kimura, Jingyun Lee, Cristina M. Furdui, Lance D. Miller, Fang-Chi Hsu, Yusuke Shiozawa
The lungs have a remarkable capacity to undergo homoeostatic repair and regeneration after injury, which often occurs in patients with acute respiratory distress syndrome (ARDS) and in the single-dose bleomycin mouse model. Fibroblasts are critical mediators of fibrotic disease and RNA sequencing has identified significant heterogeneity within pulmonary fibroblast populations. However, the contribution of distinct fibroblast subsets to the repair process has been understudied compared to their role in fibrosis initiation and progression. Therefore, we sought to define the transcriptional landscape of three phenotypically-defined fibroblast subsets that occupy discrete spatial locations in naïve lungs. Using TdTomato-lineage tracing approaches, we identified and interrogated collagen1a1+ (Col1a1) fibroblasts, perilipin 2+ (Plin2) alveolar fibroblasts, and a-smooth muscle actin+ (Acta2) myofibroblasts during fibrosis development and resolution after single-dose bleomycin. Quantification of fibroblast numbers showed that all three subsets expand during fibrosis and contract towards naïve levels with resolution. Principal component and gene-set enrichment analyses indicated that each subset undergoes major transcriptomic shifts during fibrosis development, converging on a similar pro-fibrotic transcriptional profile. However, during resolution, Plin2+ and Acta2+ fibroblasts revert towards a pre-fibrotic transcriptional state, whereas Col1a1+ fibroblasts acquire a distinct program that suggests suggesting an active role in mediating the repair processes.
Daniel G. Foster, Nomin Javkhlan, Bart P. Black, Brian E. Vestal, David W.H. Riches, Elizabeth F. Redente