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Abstract
Germline BRCA1/2 pathogenic variant (PV) carriers have elevated young-onset breast cancer risk. To define the pretreatment genomic landscapes of young-onset gBRCA-associated breast cancer, we evaluated 136 treatment-naïve tumors diagnosed before age 50 (92.6% ≤40): gBRCA1 86(63.2%); gBRCA2 50(36.8%) in the prospective POSH study, and 66 noncarriers from The Cancer Genome Atlas. Using whole exome sequencing, we analyzed somatic variation, allele-specific loss of heterozygosity (asLOH), homologous recombination deficiency (HRD), and single-base substitution signatures (SBS). gBRCA1(93%) and gBRCA2(96%) breast cancers had high rates of asLOH, but differed significantly in average HRD scores (57.4 ± 1.3 vs 43.7 ± 1.5, P < 0.0001) and median SBS composition (%): SBS1 (aging-associated) 12.9 vs 7.3, P = 0.013; SBS18 (reactive oxygen species [ROS]-associated) 1.4 vs 0, P = 0.007; and SBS3 (HRD-associated) 27.3 vs 42.6, P = 0.002. Compared to gBRCA2 tumors, gBRCA1 tumors with asLOH were significantly enriched for alterations in Hallmark ROS, DNA repair, and epithelial-mesenchymal transition pathways. In ER-positive, HER2-negative tumors from gBRCA1/2 carriers compared to noncarriers, we found significant enrichment of RB1 (OR:6.3;95%CI:2.8–15.4;padj = 0.001), TP53 (OR:4.6;95%CI:1.9–12.1;padj = 0.017), FAT1 (OR:3.9;95%CI:1.84–8.7;padj = 0.013), and MYC (OR:4.0;95%CI:1.8–9.1;padj = 0.017) SNV/indels/CNVs, associated with CDK4/6i resistance. Together, these findings demonstrate significant differences between gBRCA1 and gBRCA2-associated breast cancers, and preexisting CDK4/6i resistance mechanisms supporting prospective trials with individualized therapy for gBRCA1 vs gBRCA2 carriers, and comparing PARPi to CDK4/6i for ER-positive gBRCA1/2-associated breast cancer.
Authors
Mwangala P. Akamandisa, Mingyi Xia, Wilson Cheah, Bradley Wubbenhorst, Kurt P. D'Andrea, Mengyao Fan, Jake S. Shilan, Dana Pueschl, Anupma Nayak, Hayley McKenzie, William Tapper, Ellen R. Copson, Ramsey I. Cutress, Susan M. Domchek, Diana M. Eccles, Katherine L. Nathanson
Abstract
CHI3L1, a chitinase-like protein, is implicated in pulmonary fibrosis, yet its mechanisms incompletely understood. In this study, we demonstrated that CHI3L1 coordinates profibrotic macrophage activation and invasive myofibroblast differentiation, and their crosstalk. In vitro, CHI3L1 drove M2-like macrophage polarization as evidenced by increased CD163, CD206, and PD-L1, and amplified TGF-β1-induced fibroblast responses, including myofibroblast transformation, migration, and invasion. Mechanistically, CHI3L1 enhanced TGF-β1 signaling through SMAD, AKT, and ERK pathways, and PD-L1 was required for CHI3L1/TGF-β1-driven myofibroblast transformation. Co-culture studies further demonstrated the ability of CHI3L1 to induce profibrotic macrophage activation that enhanced myofibroblast transformation mediated via a CD44–PD-L1 axis. In vivo, following bleomycin challenge, CHI3L1 transgenic mice exhibited increased PD-L1+ M2 macrophages, PD-L1+/PDGFRα+ fibroblasts, and PD-1+ immune cells compared with wild-type controls. Therapeutically, combined anti-CHI3L1 and anti-PD-1 antibodies, as well as a bispecific anti-CHI3L1-anti-PD-1 antibody, produced greater anti-fibrotic efficacy than monotherapy. These findings demonstrate crosstalk between CHI3L1 and the PD-1/PD-L1 pathway that promotes profibrotic macrophage activation and invasive fibroblast differentiation and support dual targeting of CHI3L1 and PD-1/PD-L1 as a promising therapeutic strategy for pulmonary fibrosis.
Authors
Han-Seok Jeong, Takayuki Sadanaga, Joyce H. Lee, Suchitra Kamle, Bing Ma, Yang Zhou, Sung Jae Shin, Jack A. Elias, Chun Geun Lee
Abstract
Aortic dissection or rupture is a leading cause of mortality in vascular Ehlers-Danlos syndrome (VEDS), a disorder caused by mutations in the COL3A1 gene. Col3a1G938D/+ mice recapitulate features of VEDS, including high risk of aortic rupture. As in people with VEDS, aortic risk in this model accelerates at the onset of puberty, especially in males. We identify developmentally regulated gene programs associated with this vulnerability and that are targeted by treatments that mitigate aortic risk. Both genetic and pharmacological inhibition of the androgen receptor (AR) eliminated survival differences between sexes, while treatment with a dual AR and mineralocorticoid receptor (MR) antagonist provided near-complete and durable protection in both sexes. Pathways targeted by dual AR/MR inhibition, including those related to extracellular matrix (ECM) organization and cell-ECM interactions, largely overlapped with those also modulated by isolated MR antagonism. Selective targeting of MR signaling emerged as an effective therapeutic strategy in both sexes that avoids sexual side effects in males.
Authors
Emily E. Juzwiak, Caitlin J. Bowen, Rhiannon Edwards, Leda Restrepo, Serena Lee, Cassie A. Parks, Anthony Zeng, Maya M. Black, Oscar E. Reyes Gaido, Emily E. Bramel, Dustin T. Shigaki, Michael A. Beer, Chiara Bellini, Harry C. Dietz, Elena Gallo MacFarlane
Abstract
Eosinophilic esophagitis (EoE) is a type 2 allergic disease characterized by esophageal inflammation and epithelial cell dysfunction. The acquired loss of the anti-serine protease of kazal type 7 (SPINK7) in the squamous epithelium of the esophagus has a causal role in EoE pathogenesis. Yet there is a limited understanding of the factors that regulate its expression and responsiveness to inflammatory stimuli. Herein, we have identified the transcription factor, ovo like transcriptional repressor 1 (OVOL1) as an esophageal selective gene product that regulates SPINK7 promoter activity. Overexpression of OVOL1 increased SPINK7 expression, whereas its depletion decreased SPINK7 expression, impaired epithelial barrier and increased production of the pro-atopy cytokine thymic stromal lymphopoietin (TSLP). Stimulation with IL-13 abrogated the nuclear translocation of OVOL1 and promoted enhanced degradation of OVOL1 protein. This effect of IL-13 was dependent on the esophageal specific cysteine protease calpain-14 at least in part. Analysis of human esophageal biopsies demonstrated that the expression of esophageal OVOL1 correlated with SPINK7 transcript expression and was lost as a function of EoE disease activity. In summary, our study identifies key regulatory mechanisms in EoE pathogenesis, demonstrating that OVOL1 promotes SPINK7 transcription, whereas IL-13 suppresses this pathway in EoE.
Authors
Nurit P. Azouz, Andrea M. Klingler, Sierra S. Beach, Kalen A. Rossey, Mark Rochman, Misu Paul, Julie M. Caldwell, Michael Brusilovsky, Alexander T. Dwyer, Xiaoting Chen, Daniel Miller, Carmy Forney, Leah C. Kottyan, Matthew T. Weirauch, Marc E. Rothenberg
Abstract
Heterozygous TBX4 variants are the second most common genetic cause of pediatric pulmonary hypertension (PH), yet mechanisms underlying TBX4-related lung disease remain poorly understood. This study developed a lung mesenchyme-specific Tbx4 loss-of-function (Tbx4cKO) mouse model that bypasses embryonic lethality to investigate this condition. Adult Tbx4cKO mice demonstrated significantly impaired pulmonary flow acceleration consistent with PH. Three-dimensional analysis of embryonic lungs revealed reduced lobe volumes and decreased distance between pleural edges and muscularized vessels. In adult Tbx4cKO lungs, we identified extensive vascular remodeling characterized by medial thickening and the extension of muscularized arteries into normally non-muscularized subpleural parenchymal zones. Contrary to previous reports suggesting vascular simplification, three-dimensional analysis demonstrated an elaborated pulmonary artery (PA) tree in addition to pathologic wall muscularization. Depletion of a single Tbx5 allele in addition to both Tbx4 alleles exacerbated histologic phenotypes with worsened right ventricular dilation. This model also demonstrated dysregulated airway smooth muscle patterning and prominent subpleural smooth muscle bands, similar to those in human TBX4 syndrome. We identify TBX4 as a critical regulator of smooth muscle differentiation and patterning across multiple lung compartments. Our model recapitulates key features of human TBX4 syndrome and identifies dysregulated smooth muscle differentiation as a potential future therapeutic target.
Authors
Lea C. Steffes, Kaylie A. Chiles, Sehar R. Masud, Aleen Rahman, Madeline Dawson, Csaba Galambos, Maya E. Kumar, Ripla Arora
Abstract
Human γδ T cells are a rare but functionally diverse lymphocyte subset critical for tumor surveillance and antimicrobial immunity. Although they express natural killer (NK) cell-associated receptors such as Killer-cell Immunoglobulin-like Receptors (KIRs), the relevance of KIR expression on γδ T cells remains largely unexplored. Using flow cytometry, ATAC-seq and RNA-seq, we identified KIR expression as a marker that distinguished two functionally and molecularly distinct γδ T cell subsets. KIR⁺ γδ T cells exhibited an advanced, memory-like differentiation state characterized by heightened cytotoxicity, stable epigenetic remodeling and a predominant IFNγ-producing profile. In contrast, KIR⁻ γδ T cells maintained a naïve-like phenotype and preferentially produced IL-17 upon polarization. Notably, KIR+ γδ T cells were consistently observed across individuals but were significantly enriched in cytomegalovirus (CMV)-seropositive donors, suggesting that chronic antigenic stimulation could promote the emergence of KIR⁺ effector γδ T cells. These findings reveal a functional dichotomy in human γδ T cells defined by KIR expression, linking IFNγ-driven cytotoxicity with KIR⁺ cells and IL-17 production with KIR⁻ cells. This insight advances our understanding of γδ T cell heterogeneity and has implications for viral immunity, immune memory and the development of γδ T cell-based immunotherapies.
Authors
Mahya Razmi, Yeganeh Almasi, Marilee Larrivée, Jonathan B. Angel, Alexandre Blais, Zakia Djaoud
Abstract
Survival after lung transplantation is limited by chronic, progressive graft failure, termed chronic lung allograft dysfunction (CLAD). Graft-resident mesenchymal cells (MCs) drive CLAD pathogenesis and exhibit stable dysregulated signaling, yet the transcriptomic and epigenomic drivers underlying this fibrogenic transformation remain elusive. We used single-cell multi-omic profiling to characterize gene expression and chromatin accessibility in MCs isolated from lavage fluid of lung transplant recipients with and without CLAD, collected early post-transplantation or after disease onset. MCs obtained after CLAD onset demonstrated a distinct transcriptomic signature compared with non-CLAD controls, enabling classification of disease status at the single-cell level with > 98% accuracy using signature genes. Chromatin accessibility analyses identified enrichment of CCAAT-enhancer-binding protein family transcription factors, specifically CEBPD, in CLAD MCs. Early post-transplant MCs showed minimal accessibility differences, suggesting that CEBPD-associated regulatory changes emerge over time. Integration analyses identified eight MC states and a CLAD-specific shift towards a fibrotic state. CEBPD, SOX4, and FOXP2 were identified as putative regulators of this state with substantial overlap in predicted targets. Targeting CEBPD reversed fibrotic phenotypes of CLAD MCs (decreased ECM expression, contractility, proliferation, and migration). Together, these data provide insights into transcriptomic and epigenomic changes in post-transplant MCs, nominating biomarkers and therapeutic targets.
Authors
Lu Lu, A. Patrick McLinden, Natalie M. Walker, Ragini Vittal, Yichen Wang, Fatemeh Fattahi, Stephen T. Russell, Michael P. Combs, Joshua D. Welch, Vibha N. Lama
Abstract
Pulmonary fibrosis is frequently accompanied by pulmonary hypertension, which can occur disproportionate to the extent of fibrosis, suggesting a fibrosis-independent vascular remodeling process. Here, we demonstrated that plasma growth differentiation factor 15 (GDF15) is elevated across diverse fibrotic lung disease subtypes and correlates with markers of elevated right heart pressures, but not pulmonary function indices, indicating a possible link to endothelial cell dysfunction. To investigate the import of endothelial GDF15 as a modifier of lung fibrosis pathogenesis, we generated endothelial cell-specific Gdf15 knockout mice, which showed protection from bleomycin-induced lung injury and fibrosis, with preserved lung function. RNA sequencing of human pulmonary microvascular endothelial cells revealed altered expression of barrier-regulatory genes in GDF15-deficient endothelial cells compared to controls. Functional studies confirmed that GDF15 knockdown attenuates thrombin-induced barrier disruption by reducing cytosolic Ca2+ responses. Together, these findings implicate endothelial GDF15 as a modifier of vascular permeability and Ca2+ signaling, and a contributor to lung injury and fibrosis.
Authors
Kristen Raffensperger, Marta Bueno, Brian J. Philips, Megan Miller, Máté Katona, Shuai Yuan, Adriana Estrada-Bernal, Byron Chuan, Pavan Suresh, Stephanie Taiclet, Scott Hahn, Yingze Zhang, Jonathan K. Alder, Seyed Mehdi Nouraie, Daniel J. Kass, Oliver Eickelberg, Adam C. Straub
Abstract
Idiopathic pulmonary fibrosis (IPF) is a progressive interstitial lung disease driven by aberrant fibroblast-to-myofibroblast differentiation, which requires metabolic reprogramming. Here, we identify alanine as an essential metabolite for myofibroblast differentiation. Transforming growth factor–β1 (TGF-β) increases intracellular alanine levels through enhanced synthesis and import in both normal and IPF lung fibroblasts. Alanine synthesis is primarily mediated by glutamate-pyruvate transaminase 2 (GPT2), whose expression is regulated by the glutamine–glutamate–α-ketoglutarate axis. Inhibition of GPT2 depletes alanine and suppresses TGF-β-induced α-SMA and COL1A1 expression, which are rescued by exogenous alanine. We also identify solute carrier family 38 member 2 (SLC38A2) as a transporter for both alanine and glutamine, upregulated by TGF-β or alanine deprivation. SLC38A2 and GPT2 form a coordinated regulatory axis sustaining intracellular alanine levels to support myofibroblast differentiation. Mechanistically, alanine deficiency impairs glycolytic flux and depletes tricarboxylic acid cycle intermediates, while alanine supplementation provides carbon and nitrogen for intracellular glutamate and proline biosynthesis, particularly under glutamine deprivation. Combined inhibition of alanine synthesis and uptake suppresses fibrogenic responses in fibroblasts and human precision-cut lung slices, highlighting dual metabolic targeting as a potential therapeutic strategy for fibrotic lung disease.
Authors
Fei Li, Niv Vigder, David R. Ziehr, Mari Kamiya, Hung N. Nguyen, Diana E. Ferreyra Faustino, Aseel H. Khalil, Hilaire C. Lam, Matthew L. Steinhauser, Edy Y. Kim, William M. Oldham
In Vivo Characterization of Candida Extracellular Vesicles Reveals Unique Infection Pathway Proteins
Abstract
Authors
Justin Massey, Robert Zarnowski, William Hartman Jr., Jeniel E. Nett, David R. Andes
Abstract
Fibroblast-like synoviocytes (FLSs) are crucial in driving synovial inflammation and joint damage in rheumatoid arthritis (RA). This study explored the functions and underlying mechanisms of GALNT1-mediated O-glycosylation, which is markedly upregulated in RA FLSs, in synovial aggression and subsequent experimental joint damage. Targeted suppression of GALNT1 effectively curtailed migration and invasion in RA FLSs and mitigated arthritis severity in a rat collagen-induced arthritis (CIA) model. Mechanistically, NEK9 was identified as a pivotal substrate and downstream effector of GALNT1, affecting the aggressive phenotype of RA FLSs. In vitro experiments further demonstrated that O-glycosylation of NEK9, mediated by GALNT1, promotes the pathogenic phenotype of RA FLSs by promoting cytoskeleton reorganization and restraining excessive endoplasmic reticulum (ER) stress activation. Our study provides mechanistic insights into the activation of RA FLSs and identifies GALNT1 as a potential therapeutic target for RA.
Authors
Yaoyao Zou, Haobo Lin, Jianling Su, Jieying Wang, Qin Zeng, Tianxiao Feng, Yunxia Lei, Jianda Ma, Hudan Pan, Hanshi Xu, Lie Dai, Yang Li
Abstract
Aortic dissection (AD) is a catastrophic vascular emergency with high mortality, and current pharmacologic interventions to prevent its progression are limited. Vascular smooth muscle cells (VSMCs) undergo a pathological phenotypic switch from a contractile to a synthetic state during AD, compromising aortic wall integrity; however, the underlying metabolic mechanisms remain poorly understood. In this study, we performed integrative transcriptomic analyses and identified glutaminase 1 (GLS1) as a key regulator of VSMC phenotypic switching in AD. GLS1 expression was significantly downregulated in VSMCs from both human AD aortic tissues and mouse models. Functionally, GLS1 deficiency promoted PDGF-BB–induced VSMC dedifferentiation in vitro. Smooth muscle cells specific Gls1 knockout (Gls1SMKO) mice exhibited aggravated AD upon BAPN treatment, whereas VSMCs specific GLS1 overexpression improved the contractile phenotype and reduced AD incidence. Mechanistically, GLS1 downregulation impaired glutamate metabolism, leading to reduced levels of glutathione and α-ketoglutarate. This metabolic disruption promoted reactive oxygen species accumulation and mitochondrial dysfunction, ultimately triggering VSMC phenotypic switching. Furthermore, we found that GLS1 transcription was repressed by retinoic acid receptor-α (RARα). Pharmacologic inhibition of RARα with AR7 restored GLS1 expression, ameliorated VSMC phenotypic switching, and conferred protection against AD. These findings reveal a critical role of GLS1-mediated glutamate metabolism in VSMC phenotypic switching and suggest a promising therapeutic strategy for AD.
Authors
Wei Xie, Chen Ning, Chen Lu, Dongjin Wang, Shuang Zhao, Tianyu Song, Hailong Cao
Abstract
Inflammatory bowel disease (IBD) is frequently accompanied by intestinal fibrosis, with non-response (NR) to long-term anti-tumor necrosis factor α (anti-TNFα) therapy occurring in approximately 23-46% of patients. Integrated analysis of single-cell and bulk RNA sequencing datasets revealed an expansion of IL11⁺ fibroblasts in inflamed intestine and their significant enrichment in non-responders. We further identified IL11⁺ fibroblasts as a central communication hub that engaged in extensive crosstalk with monocytes and may contribute to inflammatory amplification and fibrotic remodeling. Additionally, we employed machine learning approaches including least absolute shrinkage and selection operator (LASSO), support vector machines (SVM), and random forest (RF) to derive an IL11⁺ fibroblast-related gene signature effectively predicting NR to anti-TNFα in validation and test cohorts. IHC further confirmed the overexpression of IL-11 in non-responders. The signature genes we found are not only associated with immune and inflammatory responses but also with fibrosis, indicating a robust association between fibrosis and anti-TNFα treatment failure. In summary, this study highlights the important role of IL11⁺ fibroblasts in orchestrating both inflammation and fibrosis and provides an applicable model for predicting NR to anti-TNFα in IBD, thereby laying the foundation for precision medicine and targeted therapeutic strategies.
Authors
Wangyue Li, Wei Huang, Jiaxin Wang, Yiwen Tu, Qidi Yang, Yao Zhou, Zile Zhang, Haiming Zhuang, Yubei Gu, Duowu Zou, Yao Zhang
Abstract
Inhibiting the mammalian target of rapamycin (mTOR) during acute viral infection generates highly functional memory CD8 T cells. We investigated the effects of inhibiting mTOR by using rapamycin during the effector and contraction phases of the immune response to a DNA prime and Modified Vaccinia Ankara (MVA) boost SIV vaccination in rhesus macaques. Rapamycin administered either during MVA boosts alone (DMR) or during both primes and boosts (DRMR) reduced the contraction of effector CD8 T cells, resulting in higher frequencies of SIV-specific memory CD8 T cells with enhanced quality as indicated by expression of Bcl-2 and CD127. Additionally, rapamycin reduced the frequency of proliferating CCR5+ CD4 T cells in the blood following the MVA boost. Post SIV251 infection, rapamycin-treated macaques demonstrated marked expansion of SIV-specific CD8 T cells (reaching up to 50% in blood and 25% in gut). The heightened expansion of SIV-specific CD8 T cells in the DMR group was associated with markedly lower (2-logs compared to unvaccinated and 1-log compared to DM) peak viral load in the gut and set-point viremia, along with improved survival post infection. Thus, inhibiting the mTOR pathway during MVA boosts of a DNA/MVA vaccine enhances vaccine efficacy by improving memory CD4 and CD8 T cell function.
Authors
Shanmugalakshmi Sadagopal, Kasey Stokdyk, Suefen Kwa, Rahul Basu, Sailaja Gangadhara, Rafi Ahmed, Smita S. Iyer, Koichi Araki, Rama Rao Amara
Abstract
Background Cancer accounts for over 20% of late post-transplant mortality, yet the contribution of genetic susceptibility to post-transplant cancer risk remains unclear. This study investigates germline genetic risk factors for post-transplant cancer in the Finnish population using data from the FinnGen cohort. Methods A pan-cancer polygenic risk score (PRS) was constructed using genetic variants identified in UK and US populations to assess the influence of common germline variants on time to first cancer diagnosis in 1,802 Finnish kidney transplant recipients (KTRs), of whom 317 developed post-transplant cancer. The PRS was first validated in the FinnGen non-transplantation cohort and subsequently applied to KTRs, with replication in lung and liver transplant recipients (n = 476). Functional relevance was explored by assessing associations between the PRS and expression levels of 2,923 plasma proteins in the UK Biobank (n = 53,013). Results Compared to a matched non-transplantation cohort (n = 68,294), KTRs exhibited earlier cancer onset. The PRS was significantly associated with time to first cancer diagnosis in the non-transplantation population (HR 1.04; 95% CI 1.038-1.056; p = 3.75 x 10-25). Among KTRs younger than 40 years, higher PRS was associated with earlier cancer onset (HR, 1.08; 95% CI ,1.01-1.17; p = 0.036), indicating a stronger genetic effect at younger ages. The PRS significantly (Bonferroni < 0.05) altered the regulation of 87 plasma proteins, several of which were known cancer-related markers. Conclusion Inherited genetic predisposition, captured by pan-cancer PRS, may contribute to individual susceptibility to cancer after solid organ transplantation, particularly at younger ages.
Authors
Jarmo Ritari, Kati Hyvärinen, Kirsi Jahnukainen, Jukka Partanen, Ilkka Helanterä, Timo Jahnukainen
Abstract
Donnai-Barrow Syndrome (DBS) arises from loss-of-function (LoF) variants in the endocytic receptor LRP2/megalin and is characterized by low molecular weight (LMW) proteinuria and developmental abnormalities. Urinary proteomics of nine DBS patients revealed that the urinary proteome of a DBS patient with the missense variant LRP2 p.C1400R was indistinguishable from that of patients with splice site, nonsense, or frameshift mutations. A CRISPR mouse model of the variant was generated to determine the mechanism of LoF and proteinuria. The mutant LRP2 was expressed and observed to dimerize and localize to the proximal tubule apical membrane. However, both fluid-phase and receptor-mediated endocytosis were impaired in the context of a general perturbation of endocytic flux. Immunofluorescence revealed aberrant endocytic recycling with mislocalized RAB11+ and TFR1+ compartments and enlarged lysosomes. Structural modeling showed the LRP2 assembly likely tolerates the cysteine to arginine substitution at the cell surface, but at endosomal pH the variant introduced steric clashes that may disrupt intramolecular interfaces and disturb receptor recycling. These findings point to the importance of LRP2 recycling for global endocytic flux and offer a blueprint for leveraging patient-specific alleles to dissect proximal tubule function.
Authors
Andrew Beenken, Tian H. Shen, Aryan Ghotra, Hediye Erdjument-Bromage, Jeong Lee, Jared S. Kushner, Rachel E. Sturley, Atlas Khan, Jeffrey R. Arace, Leora Kronenberg, Lucy D. Shen, Gabriel H. Rahmani, Patricia K. Donahoe, Thomas A. Neubert, Frances A. High, Ora A. Weisz, Jonathan Barasch
Abstract
Chronic hyperglycemia induces microvascular complications in patients with type 2 diabetes (T2D), particularly diabetic retinopathy, nephropathy, and neuropathy. We revisited to examine such vascular damage in the pancreas in 3D. Using thick pancreatic tissue slices, we analyzed volumetric intraislet and peri-islet exocrine capillary density (vICD and vECD), as well as interface capillary counts along the islet periphery to quantify vascular integration between the islets and surrounding acinar cells. Contrary to the previous reports, vICD was not homogeneous, but highly heterogeneous across the five species studied (human, monkey, pig, ferret and mouse), especially in smaller islets (15%–80%). vICD became less variable with increasing islet size converging at approximately 20%. With this foundation of islet vascularization, pancreatic tissues from non-diabetic (ND) and T2D subjects consisting of eight age- and sex-matched pairs (age range of 35-65 years with various duration: 0-15 years) were examined. Strikingly, no significant differences in microvasculature were found, where mean vICD (~30%) and mean vECD (~15%) were nearly equivalent between the groups. Capillary integration with respect to islet size was comparable. It suggests that integrated pancreatic blood flow with robust crosstalk between the endocrine and exocrine pancreas may facilitate microvascular preservation in T2D via local distribution of insulin.
Authors
Alex M. Tollefson, Frank R. Marsico, Manami Hara
Abstract
Primary sclerosing cholangitis (PSC) is a chronic, idiopathic cholestatic liver disease characterized by inflammation and fibrosis of the bile ducts, yet the cellular crosstalk driving periductal fibrosis remains poorly defined. This study applied a multi-omics approach integrating spatial transcriptomics, RNA-seq, and proteomics to characterize fibrotic periductal regions and their cell–cell communications. Macrophages (MP) subsets, including monocyte-drived-(Mo)MP and lipid-associated-macrophage (LAM)-like, co-localized with cholangiocytes, lymphocytes, and hepatic stellate cells (HSC1). Cell niche analysis identified periductal regions with elevated fibrotic signals, where cell–cell communication analysis revealed potential MP–HSC interactions involving 17 fibrotic driver genes in MP, including ITGB2, GRN, and CCL21, and 6 fibrotic effector genes in HSC. In validation analyses, bulk RNA-seq data showed higher driver and effector gene expression in PSC with established fibrosis compared to early-stage PSC or healthy control (HC). Plasma proteins encoded by MP driver genes were elevated in PSC and in patients with elevated (≥3.29 kPa) liver stiffness on MR elastography. Furthermore, immunofluorescence and SHG imaging showed enrichment of CD68+/CD18+(ITGB2) macrophages in fibrotic regions of PSC liver biopsies. These findings revealed enrichment of MoMP and LAM-like macrophages in fibrotic regions and suggest that they likely contribute to fibrotic activation of nearby HSCs in PSC.
Authors
Yunguan Wang, David Adeleke, Xiangfei Xie, Zi F. Yang, Xiangya Wang, Giulia Loi, Annika Yang vom Hofe, Manavi Singh, Astha Malik, Ramesh Kudira, Cyd Castro-Rojas, Liva Pfuhler, Mosab Alquraish, Pamela Sylvestre, Jonathan R. Dillman, Andrew T. Trout, Emily R. Miraldi, Alexander G. Miethke
Abstract
High dietary salt intake elevates blood pressure and drives multi-organ damage. However, the molecular programs underlying progressive organ injury remain poorly defined. Here, we present a longitudinal multi-organ transcriptomic atlas of salt-induced hypertensive injury. We profiled kidney cortex, kidney medulla, heart, and liver across four stages spanning early hypertension to advanced pathology in Dahl salt-sensitive rats. We identified dynamic and tissue-specific molecular trajectories, including a shared early proliferative response that converges on proinflammatory and fibrotic remodeling. Notably, we uncovered compartment-specific renal responses, showing that the cortex and medulla, despite their proximity, follow distinct molecular trajectories during disease progression. We further identified 79 stage- and tissue-specific transcription factors that drive gene expression dynamics in salt-induced hypertensive injury. Integration with human genome-wide association studies revealed conserved pathways in endocrine signaling, ion transport, lipid metabolism, and detoxification, establishing cross-species relevance and highlighting mechanistic targets of clinical importance. Compound–transcriptome analysis revealed stage- and organ-specific therapeutic opportunities, prioritizing kinase and epigenetic modulators as candidates to rebalance maladaptive gene programs. Overall, this study provides a resource for understanding molecular mechanisms from early salt-induced hypertension to tissue-specific injury and underscores the need for precision interventions.
Authors
Ratnakar Tiwari, Olha Kravtsova, Lashodya V. Dissanayake, Melissa Lowe, Biyang Xu, Vladislav Levchenko, Steven Didik, Ruslan Bohovyk, Daria V. Ilatovskaya, Oleg Palygin, Alexander Staruschenko
Abstract
Extracellular matrix (ECM) disorder was considered as the result of fibrosis, but it is recently recognized that fibrotic ECM initiates a self-reinforcing circuit and contributes to development of fibrosis. Versican, an ECM component, participates in cell-ECM interaction and ECM regeneration. In pleura, versican is primarily derived from pleural mesothelial cells (PMCs). However, the role and mechanism of versican in pleural fibrosis remained unknown. In this study, versican and versican-mediated pleural viscoelasticity was found elevated in both human and murine pleural fibrotic tissues. Versican knockdown by shRNA prevented increases of viscoelasticity as well as pleural fibrosis. High level of versican and viscoelasticity promoted mesothelial to mesenchymal transition (MesoMT) in PMCs. Mechanistically, increased viscoelasticity induced pleural fibrosis through CD44/USP10/Smad4 mechanotransduction pathway. In conclusion, these results revealed that excessive versican in fibrotic pleural ECM enhanced ECM viscoelasticity, and consequently promoted progression of pleural fibrosis.
Authors
Zi-Heng Jia, Xin-Liang He, Xiao-Lin Cui, Qian Li, Pei-Pei Cheng, Li-Qin Zhao, Shu-Yi Ye, Shi-He Hu, Chen-Yue Lian, He-De Zhang, Li-Mei Liang, Lin-Jie Song, Fan Yu, Liang Xiong, Fei Xiang, Xiaorong Wang, Meng Wang, Xiyong Dai, Hong Ye, Wan-Li Ma
