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Nephrology

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Inherited salt retention is associated with increased IL-17 responses and autoimmunity
Muhammad Atif Rauf, Sanskriti Agarwal, Rebecca R. Baker, Jennifer Steeden, Alfredo Petrosino, Maria Kiliaris, Robert Unwin, Keith Siew, Alan D. Salama, Rhys D.R. Evans
Muhammad Atif Rauf, Sanskriti Agarwal, Rebecca R. Baker, Jennifer Steeden, Alfredo Petrosino, Maria Kiliaris, Robert Unwin, Keith Siew, Alan D. Salama, Rhys D.R. Evans
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Inherited salt retention is associated with increased IL-17 responses and autoimmunity

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Abstract

Authors

Muhammad Atif Rauf, Sanskriti Agarwal, Rebecca R. Baker, Jennifer Steeden, Alfredo Petrosino, Maria Kiliaris, Robert Unwin, Keith Siew, Alan D. Salama, Rhys D.R. Evans

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The risk of nephrotic range proteinuria and kidney failure in primary laminopathies is genotype-specific
Sebastian Sewerin, Charlotte Aurnhammer, Mohamed Hamed, Gwladys Revêchon, Ria Schönauer, Christin Findeisen, Konstanze Miehle, Šárka Tesařová, Theodoros Georgomanolis, Carsten Bergmann, Constantin A. Wolff, Marek Kollár, Baris Akinci, David Araujo-Vilar, Giovanni Ceccarini, Éva Csajbók, Alessandra Gambineri, Martin Heni, Thomas Scherer, Iztok Štotl, Ekaterina Sorkina, Marie-Christine Vantyghem, Elena Vorona, Martin Wabitsch, Julia von Schnurbein, Camille Vatier, Joëlle Roume, Yves Reznik, Maria Eriksson, Wolfram Antonin, Corinne Vigouroux, Jan Halbritter
Sebastian Sewerin, Charlotte Aurnhammer, Mohamed Hamed, Gwladys Revêchon, Ria Schönauer, Christin Findeisen, Konstanze Miehle, Šárka Tesařová, Theodoros Georgomanolis, Carsten Bergmann, Constantin A. Wolff, Marek Kollár, Baris Akinci, David Araujo-Vilar, Giovanni Ceccarini, Éva Csajbók, Alessandra Gambineri, Martin Heni, Thomas Scherer, Iztok Štotl, Ekaterina Sorkina, Marie-Christine Vantyghem, Elena Vorona, Martin Wabitsch, Julia von Schnurbein, Camille Vatier, Joëlle Roume, Yves Reznik, Maria Eriksson, Wolfram Antonin, Corinne Vigouroux, Jan Halbritter
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The risk of nephrotic range proteinuria and kidney failure in primary laminopathies is genotype-specific

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Abstract

BACKGROUND. Primary laminopathies are a heterogeneous group of rare diseases caused by nuclear lamina dysfunction due to pathogenic LMNA variants. However, despite their ubiquitous expression, LMNA variants have rarely been linked to chronic kidney disease (CKD). Here, we systematically investigate clinical implications and functional underpinnings of a distinct LMNA missense variant (lamin A/C p.(Arg349Trp)) that has sporadically been found in patients with a complex phenotype including lipodystrophy, proteinuria, and focal segmental glomerulosclerosis (FSGS). METHODS. In clinical and functional terms, we compare lamin A/C Arg349Trp with missense changes at Arg482, the most common hotspot residue for type 2 familial partial lipodystrophy (FPLD2). In particular, we assess renal endpoints in corresponding patient cohorts and investigate disease-associated alterations in vitro. RESULTS. In contrast to FPLD2 patients, individuals with lamin A/C Arg349Trp experience high-grade proteinuria and a rapid decline of glomerular filtration rate with kidney failure at a median age of 43 years. Mechanistically, we demonstrate that Arg349Trp associates with an abrogation of the structural interaction between lamin A/C and nucleoporin 155, nuclear pore complex aggregation, and an alteration of TGF-β1-dependent signaling. CONCLUSIONS. While patients with Lamin A/C Arg482 missense changes are at very low risk for progressive CKD, patients harboring Arg349Trp show nephrotic range proteinuria and kidney failure in midlife. Hence, high-grade proteinuric kidney disease is genotype-specific and patients with the Arg349Trp substitution require early renoprotective intervention to potentially halt progression and prevent kidney failure. FUNDING. German Research Foundation, project IDs 502928386, 445703531, and grants HA 9779/2-1, HA 6908/4-1, HA 6908/7-1, HA 6908/8-1, HA 6908/12-1.

Authors

Sebastian Sewerin, Charlotte Aurnhammer, Mohamed Hamed, Gwladys Revêchon, Ria Schönauer, Christin Findeisen, Konstanze Miehle, Šárka Tesařová, Theodoros Georgomanolis, Carsten Bergmann, Constantin A. Wolff, Marek Kollár, Baris Akinci, David Araujo-Vilar, Giovanni Ceccarini, Éva Csajbók, Alessandra Gambineri, Martin Heni, Thomas Scherer, Iztok Štotl, Ekaterina Sorkina, Marie-Christine Vantyghem, Elena Vorona, Martin Wabitsch, Julia von Schnurbein, Camille Vatier, Joëlle Roume, Yves Reznik, Maria Eriksson, Wolfram Antonin, Corinne Vigouroux, Jan Halbritter

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Microvascular autophagy and caspase-3 activation are central regulators of renal fibrosis after ischemia-reperfusion
Hyunyun Kim, Francis Migneault, Shanshan Lan, Imane Kaci, Julie Turgeon, Annie Karakeussian Rimbaud, Martin Dupont, Shijie Qi, Mélanie Dieudé, Marie-Josée Hébert
Hyunyun Kim, Francis Migneault, Shanshan Lan, Imane Kaci, Julie Turgeon, Annie Karakeussian Rimbaud, Martin Dupont, Shijie Qi, Mélanie Dieudé, Marie-Josée Hébert
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Microvascular autophagy and caspase-3 activation are central regulators of renal fibrosis after ischemia-reperfusion

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Ischemia-reperfusion injury (IRI) is a common cause of acute kidney injury (AKI) leading to renal fibrosis. Here, we investigate the kinetics of autophagy, apoptosis, and necroptosis activation in tubular epithelial cells (TECs) and peritubular capillaries (PTCs) after renal IRI, and their relative contributions to renal fibrogenesis. IRI with renal artery clamping in GFP-LC3 transgenic mice induced a predominant and sustained necroptotic response in TECs, while apoptosis and autophagy played minor roles. PTCs showed early and persistent activation of apoptosis, brief necroptosis induction, and increased autophagy at a distance from IRI. Disruption of the autophagic process with chloroquine (CHQ) injections in association with renal IRI did not modulate tubular death but enhanced PTC apoptosis and increased microvascular rarefaction and fibrosis. Apoptosis-deficient GFP-LC3/Caspase-3–/– mice exposed to renal IRI showed enhanced PTC autophagy, reduced PTC rarefaction, and inhibition of renal fibrosis, in spite of increased necroptosis in TECs. Inhibition of both autophagy with CHQ and apoptosis in GFP-LC3/Caspase-3–/– mice led to a marked switch toward necroptosis in PTCs. This was associated with aggravated microvascular rarefaction, increased leukocyte infiltration, and enhanced renal fibrosis. These findings establish a predominant role for PTC autophagy and caspase-3–dependent apoptosis in the development of renal fibrosis after IRI.

Authors

Hyunyun Kim, Francis Migneault, Shanshan Lan, Imane Kaci, Julie Turgeon, Annie Karakeussian Rimbaud, Martin Dupont, Shijie Qi, Mélanie Dieudé, Marie-Josée Hébert

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Constitutive YAP activation in distal nephron segments disrupts epithelial identity and nephron patterning
Zeinab Dehghani-Ghobadi, Eunah Chung, Mohammed Sayed, Christopher Ahn, Hyojin Alex Choi, Annissa Aamoum, Benjamin R. Thomson, Yueh-Chiang Hu, Hee-Woong Lim, Joo-Seop Park
Zeinab Dehghani-Ghobadi, Eunah Chung, Mohammed Sayed, Christopher Ahn, Hyojin Alex Choi, Annissa Aamoum, Benjamin R. Thomson, Yueh-Chiang Hu, Hee-Woong Lim, Joo-Seop Park
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Constitutive YAP activation in distal nephron segments disrupts epithelial identity and nephron patterning

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The distal nephron segments play a critical role in maintaining electrolyte balance, yet the mechanisms that preserve epithelial identity and segmental organization within this region remain poorly defined. Yes-associated protein (YAP), a key effector of Hippo signaling, is essential for kidney development, but its function in distal nephron epithelia is unknown. Using a genetic gain-of-function approach to activate YAP selectively in distal nephron segments, we found that sustained YAP activity profoundly disrupts epithelial organization and nephron patterning. Lineage tracing revealed that both distal convoluted tubule and connecting tubule cells originate from Slc12a3-expressing cells, and YAP activation in these segments led to increased proliferation, displacement of lineage-labeled cells beyond expected segment boundaries, and loss of segment-specific gene expression. These changes were accompanied by defects in apicobasal polarity and junctional integrity, consistent with epithelial plasticity. Unexpectedly, YAP activation in distal nephron segments also suppressed proximal tubule gene expression, indicating non-cell-autonomous effects on nephron differentiation. Together, these findings identify YAP as a critical regulator of epithelial identity in the distal nephron segments and reveal a previously unrecognized role for Hippo signaling in coordinating intersegmental organization during kidney development.

Authors

Zeinab Dehghani-Ghobadi, Eunah Chung, Mohammed Sayed, Christopher Ahn, Hyojin Alex Choi, Annissa Aamoum, Benjamin R. Thomson, Yueh-Chiang Hu, Hee-Woong Lim, Joo-Seop Park

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Apical Proximal Tubule Fatty Acid Uptake-Generated Ceramides Cause Endoplasmic Reticulum Stress From Altered Membrane Fluidity
Zhiyu Liu, Robert J. Gaivin, Shenaz Khan, Vincent Li, Amal Chaba, Fraser J. Moss, Usman Sabir, Takhar Kasumov, Tingwei Mu, Jeffrey R. Schelling
Zhiyu Liu, Robert J. Gaivin, Shenaz Khan, Vincent Li, Amal Chaba, Fraser J. Moss, Usman Sabir, Takhar Kasumov, Tingwei Mu, Jeffrey R. Schelling
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Apical Proximal Tubule Fatty Acid Uptake-Generated Ceramides Cause Endoplasmic Reticulum Stress From Altered Membrane Fluidity

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Abstract

Circulating fatty acids (FA) are constitutively taken up by basolateral kidney proximal tubule transporters and are the preferred metabolic substrate. In many chronic kidney diseases, the damaged glomerular filtration barrier permits passage of albumin-bound FA, which are reabsorbed by apical FA transport protein-2 (FATP2). Bilateral FA uptake leads to lipotoxicity and progressive renal function decline, but the relative apical versus basolateral contribution and intracellular mechanisms are not established. Apical or bilateral (but not basolateral) palmitate incubation with human proximal tubule cells stimulated endoplasmic reticulum (ER) stress gene expression, ER stress pathway activation, and ER fragmentation. Apical or bilateral palmitate was associated with reduced lipid droplets, and decreased expression of ER-localized lipid droplet biogenesis transcripts. Inhibition of lipid droplet formation also precipitated ER stress, suggesting diminished sequestration of FA metabolites as the cause. Indeed, C16:0 ceramide was increased in bilateral palmitate-treated cells, and in kidneys from mice that phenocopy progressive diabetic kidney disease. Ceramide synthesis inhibition abrogated ER stress, and transfection with C16:0 ceramide decreased ER membrane fluidity and caused ER stress. We conclude that aberrant filtration and uptake of FA by apical FATP2 exceeded the capacity for lipid droplet incorporation, and led to cytotoxicity from ceramide-induced ER lipid bilayer stress.

Authors

Zhiyu Liu, Robert J. Gaivin, Shenaz Khan, Vincent Li, Amal Chaba, Fraser J. Moss, Usman Sabir, Takhar Kasumov, Tingwei Mu, Jeffrey R. Schelling

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Single nuclei RNA-sequencing reveals transcriptional heterogeneity in the blastema of favorable histology Wilms tumor
Mike Adam, Keri A. Drake, Naomi Pode-Shakked, Katherine VandenHeuvel, Steve Potter, James Geller
Mike Adam, Keri A. Drake, Naomi Pode-Shakked, Katherine VandenHeuvel, Steve Potter, James Geller
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Single nuclei RNA-sequencing reveals transcriptional heterogeneity in the blastema of favorable histology Wilms tumor

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While Wilms tumors commonly arise from renal precursor cells and maintain features of the developing kidney, recent studies have demonstrated significant genetic, histologic, and molecular heterogeneity. To further investigate tumor variability as well as unifying features in tumor biology, we performed single nuclei RNA-sequencing (snRNA-seq) on treatment naïve, favorable histology Wilms tumors utilizing a reference atlas established from tumor-adjacent kidney samples and fetal kidney. Transcriptional profiles of blastemal, stromal, and epithelial components were correlated with tumor histology and demonstrate developmental-lineage plasticity, with PAX2 and PAX8 expression normally restricted to the nephron lineage of the fetal kidney found to be expressed in tumor stroma, as well as the stromal marker POSTN identified in tumor blastema. Further analyses of the blastema show shared transcriptional features with the differentiation trajectory of “uninduced” to “early differentiating” fetal nephron progenitor cells as well as aberrant expression of stromal signatures. A number of pathways from fetal nephron progenitors were maintained in the blastema, including regulation of stem cell maintainence and axonogenesis, whereas other pathways appear enriched in specific tumor samples, demonstrating the ability of snRNA-seq to identify both unifiying transcriptional signatures and uncover distinct molecular targets in signaling pathways and/or biological drivers of Wilms tumorigenesis.

Authors

Mike Adam, Keri A. Drake, Naomi Pode-Shakked, Katherine VandenHeuvel, Steve Potter, James Geller

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FOXC2 and WT1 regulate transcriptional reprogramming during the podocyte response to injury
Sandrine Ettou, Anya Greenberg, Sangyoon Lee, Arjun Rajesh, Liang Sun, Nahid Tabibzadeh, Haruka Oishi, Ran Konoe, Phillip J. McCown, Sean Eddy, Victoria Driscoll, Tomoya Miyoshi, Ken Hiratsuka, Jason Lam, R. Sathish Srinivasan, Youngsook L. Jung, Biju Isaac, Mingwei Sun, Mary E. Taglienti, Keith Keller, Hong Chen, Matthias Kretzler, Astrid Weins, Ryuji Morizane, Shira Rockowitz, Valerie A. Schumacher, Dongwon Lee, Jordan A. Kreidberg
Sandrine Ettou, Anya Greenberg, Sangyoon Lee, Arjun Rajesh, Liang Sun, Nahid Tabibzadeh, Haruka Oishi, Ran Konoe, Phillip J. McCown, Sean Eddy, Victoria Driscoll, Tomoya Miyoshi, Ken Hiratsuka, Jason Lam, R. Sathish Srinivasan, Youngsook L. Jung, Biju Isaac, Mingwei Sun, Mary E. Taglienti, Keith Keller, Hong Chen, Matthias Kretzler, Astrid Weins, Ryuji Morizane, Shira Rockowitz, Valerie A. Schumacher, Dongwon Lee, Jordan A. Kreidberg
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FOXC2 and WT1 regulate transcriptional reprogramming during the podocyte response to injury

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Transcriptional reprogramming has an important role in kidney glomerular disease. Using in vivo murine models of podocyte injury, we studied the roles of the FOXC2 and WT1 transcription factors (TFs) in podocyte injury. Podocytes are a crucial cell type of glomeruli, the filtration units of each nephron. Podocyte injury is often the incipient event leading to chronic kidney disease. It is well established that the TFs FOXC2 and WT1 are required in podocytes to maintain the glomerular filtration barrier. Their role in the response to injury is less well understood. Here, we tested the hypothesis that FOXC2 and WT1 act together to mediate transcriptional reprogramming in response to podocyte injury. Similarly to that of WT1, genome-wide FOXC2 binding to target genes is dynamic during the course of injury, initially increasing, but late in injury there is a dramatic decrease in FOXC2 expression and in its binding to target genes. Podocyte-specific inactivation of FoxC2 or Wt1 in adult mice limits the transcriptional response to injury. Correlating FOXC2 and WT1 ChIP-seq analyses demonstrated that they co-bind many genes expressed in podocytes. Thus, reprogramming the transcriptome involves dynamic changes in the binding of FOXC2 and WT1 to their target genes during a reparative injury response.

Authors

Sandrine Ettou, Anya Greenberg, Sangyoon Lee, Arjun Rajesh, Liang Sun, Nahid Tabibzadeh, Haruka Oishi, Ran Konoe, Phillip J. McCown, Sean Eddy, Victoria Driscoll, Tomoya Miyoshi, Ken Hiratsuka, Jason Lam, R. Sathish Srinivasan, Youngsook L. Jung, Biju Isaac, Mingwei Sun, Mary E. Taglienti, Keith Keller, Hong Chen, Matthias Kretzler, Astrid Weins, Ryuji Morizane, Shira Rockowitz, Valerie A. Schumacher, Dongwon Lee, Jordan A. Kreidberg

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Benchmarking urinary cell transcriptomes for noninvasive differentiation of BK polyomavirus–associated nephropathy from T cell–mediated rejection
Franco B. Mueller, Carol Li, Darshana M. Dadhania, Surya V. Seshan, Thalia Salinas, Vijay K. Sharma, Jenny Z. Xiang, Hans H. Hirsch, Thangamani Muthukumar, Manikkam Suthanthiran
Franco B. Mueller, Carol Li, Darshana M. Dadhania, Surya V. Seshan, Thalia Salinas, Vijay K. Sharma, Jenny Z. Xiang, Hans H. Hirsch, Thangamani Muthukumar, Manikkam Suthanthiran
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Benchmarking urinary cell transcriptomes for noninvasive differentiation of BK polyomavirus–associated nephropathy from T cell–mediated rejection

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Abstract

BK polyomavirus–associated nephropathy (BKVN) adversely impacts kidney allograft survival and often mimics acute T cell–mediated rejection (TCMR), confounding diagnosis and management. To address this conundrum, we performed unbiased RNA sequencing of urinary cells matched to biopsies classified as BKVN with intragraft inflammation (BKVN-P), BKVN without inflammation (BKVN-N), TCMR, or no rejection (NR). BKVN-N displayed dominant host DNA replication, cell cycle, and repair programs, while BKVN-P samples exhibited expansive innate immune activation, antigen presentation, chemokine upregulation, and epithelial injury. Both BKVN subtypes shared signatures of T cell exhaustion and mature and tolerogenic dendritic cell activation but differed in immune orientation — Th1 predominance in BKVN-N versus Treg and CD8 enrichment in BKVN-P. Compared with TCMR samples, BKVN-P lacked robust TCR/CD28 signaling and was enriched for viral and innate modules; BKVN-N lacked alloimmune activation. B cell exhaustion characterized BKVN-N, while BKVN-P displayed robust B cell activation with metabolic downregulation. A ratiometric urinary cell biomarker, CXCL10 mRNA/CD3E mRNA, distinguished both BKVN subtypes from TCMR with diagnostic accuracy, replicated by quantitative reverse transcription PCR for clinical translation, and confirmed in an independent cohort. These findings demonstrate the utility of urinary cell transcriptomics for resolving viral injury from alloimmunity, enabling precision diagnostics and targeted immunomodulation in kidney transplantation.

Authors

Franco B. Mueller, Carol Li, Darshana M. Dadhania, Surya V. Seshan, Thalia Salinas, Vijay K. Sharma, Jenny Z. Xiang, Hans H. Hirsch, Thangamani Muthukumar, Manikkam Suthanthiran

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Overexpression of small-conductance Ca2+-activated K+ channel 2 attenuates pain-like behavior in female mice with cystitis
Guadalupe Manrique-Maldonado, Xuejiao Sun, Allison L. Marciszyn, Nicolas Montalbetti, Marcelo D. Carattino
Guadalupe Manrique-Maldonado, Xuejiao Sun, Allison L. Marciszyn, Nicolas Montalbetti, Marcelo D. Carattino
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Overexpression of small-conductance Ca2+-activated K+ channel 2 attenuates pain-like behavior in female mice with cystitis

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Abstract

Small-conductance Ca2+-activated K+ (SK) channels regulate neuronal excitability and act as a feedback mechanism to limit firing during sustained stimulation. In the present study, we demonstrated that SK2 plays an important role in the control of bladder function and visceral pain processing. SK2 channels are expressed in bladder-innervating afferent neurons, and ablation of this subunit results in elevated afferent firing rates in response to physiological levels of bladder distension, supporting a role for SK2 in modulating mechanosensory excitability. Mice overexpressing SK2 exhibit increased bladder capacity and reduced voiding frequency. Furthermore, overexpression of SK2 prevents the onset of pelvic mechanical allodynia and attenuates the exaggerated visceromotor response to bladder distension seen in wild-type mice with chemical cystitis. Thus, SK2 may be a promising target for treating overactive bladder and pain originating from the urinary bladder and other pelvic organs.

Authors

Guadalupe Manrique-Maldonado, Xuejiao Sun, Allison L. Marciszyn, Nicolas Montalbetti, Marcelo D. Carattino

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HMGB1-mediated formation of IL-33–abundant NETs drives lung-to-kidney injury in severe pneumonia–associated acute kidney injury
Mengqing Ma, Hao Zhang, Weijuan Deng, Xia Du, Mengxing Chen, Dawei Chen, Binbin Pan, Zhaowei Wang, Ting Chen, Caimei Chen, Xin Wan, Changchun Cao
Mengqing Ma, Hao Zhang, Weijuan Deng, Xia Du, Mengxing Chen, Dawei Chen, Binbin Pan, Zhaowei Wang, Ting Chen, Caimei Chen, Xin Wan, Changchun Cao
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HMGB1-mediated formation of IL-33–abundant NETs drives lung-to-kidney injury in severe pneumonia–associated acute kidney injury

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Acute kidney injury (AKI) is a common and fatal complication of severe pneumonia, yet the mechanisms linking pulmonary inflammation to remote kidney injury remain poorly understood. Multicenter cohort data (n = 300) revealed that the incidence of severe pneumonia–associated AKI (SP-AKI) was 53.6%, with a mortality rate of 24.2%. SP-AKI was associated with elevated circulating levels of HMGB1, NETs, and IL-33. Murine experiments demonstrated that alveolar HMGB1 triggers the formation of IL-33–enriched NETs, which migrate to the kidney and activate tubular ST2/NF-κB signaling, driving inflammation and apoptosis. Genetic knockout of IL-33, ST2, or the NET-forming key enzyme PAD4, as well as pharmacological inhibition of HMGB1, IL-33, or NETs, all attenuated lung and kidney injury. Exogenous HMGB1 amplified NET-mediated IL-33 release, establishing a self-sustaining HMGB1/NET/IL-33 feed-forward loop. PAD4 deficiency completely blocked NET generation and disrupted HMGB1/IL-33 signaling. This study identified and validated a damage-associated molecular pattern–driven (DAMP-driven) HMGB1/NET/IL-33 signaling axis that mediates remote kidney injury in SP-AKI, redefining NETs from local effectors to cross-organ pathogenic carriers, thereby providing potential DAMP-targeted therapeutic avenues for SP-AKI.

Authors

Mengqing Ma, Hao Zhang, Weijuan Deng, Xia Du, Mengxing Chen, Dawei Chen, Binbin Pan, Zhaowei Wang, Ting Chen, Caimei Chen, Xin Wan, Changchun Cao

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