Insulin receptor signaling regulates renal collecting duct and intercalated cell antibacterial defenses
Matthew J. Murtha, … , Brian Becknell, John David Spencer
Matthew J. Murtha, … , Brian Becknell, John David Spencer
Published November 12, 2018
Citation Information: J Clin Invest. 2018;128(12):5634-5646. https://doi.org/10.1172/JCI98595.
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Research Article Immunology Nephrology

Insulin receptor signaling regulates renal collecting duct and intercalated cell antibacterial defenses

Abstract

People with diabetes mellitus have increased infection risk. With diabetes, urinary tract infection (UTI) is more common and has worse outcomes. Here, we investigate how diabetes and insulin resistance impact the kidney’s innate defenses and urine sterility. We report that type 2 diabetic mice have increased UTI risk. Moreover, insulin-resistant prediabetic mice have increased UTI susceptibility, independent of hyperglycemia or glucosuria. To identify how insulin resistance affects renal antimicrobial defenses, we genetically deleted the insulin receptor in the kidney’s collecting tubules and intercalated cells. Intercalated cells, located within collecting tubules, contribute to epithelial defenses by acidifying the urine and secreting antimicrobial peptides (AMPs) into the urinary stream. Collecting duct and intercalated cell–specific insulin receptor deletion did not impact urine acidification, suppressed downstream insulin-mediated targets and AMP expression, and increased UTI susceptibility. Specifically, insulin receptor–mediated signaling regulates AMPs, including lipocalin 2 and ribonuclease 4, via phosphatidylinositol-3-kinase signaling. These data suggest that insulin signaling plays a critical role in renal antibacterial defenses.

Authors

Matthew J. Murtha, Tad Eichler, Kristin Bender, Jackie Metheny, Birong Li, Andrew L. Schwaderer, Claudia Mosquera, Cindy James, Laura Schwartz, Brian Becknell, John David Spencer

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Figure 5

IR deletion in the kidney’s ICs suppresses antimicrobial peptide expression.

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IR deletion in the kidney’s ICs suppresses antimicrobial peptide express...
(A) Quantification of AMP mRNA expression in FACS-isolated ICs from noninfected V-ATPase-Cre+ tdT+/+ mice (n = 5). Transcript expression was determined by normalizing mRNA expression to serial dilutions of gene-specific plasmids. (B) Relative AMP mRNA expression in FACS-isolated ICs from noninfected V-ATPase-Cre+ tdT+/+ (striped bars) and IRKO mouse kidneys (white bars). Graphs show the mean and SEM (n = 6 mice/genotype). Asterisks denote significant P values for the pairwise comparisons (Mann-Whitney U test). (C) Representative Western blots on FACS-isolated ICs from V-ATPase-Cre+ tdT+/+ and IRKO mouse kidneys. (D) Relative total kidney AMP mRNA expression in IRflox (gray bars) and IRKO mice (white bars) at the indicated points postinfection (n = 7–8 mice/genotype). Relative transcript expression is normalized to IRflox expression at each time point. (E, F) Urinary AMP concentrations, normalized to urine creatinine (UCr), in IRflox (squares) and IRKO (triangles) mice at the indicated points postinfection. The horizontal line indicates the median of each group (n = 12–13 mice/genotype). (G) Isolated mouse urine from IRflox (squares) and IRKO (triangles) mice was incubated with and without anti–RNase4 antibody, anti–Lcn2 antibody, or an irrelevant antibody (IgG) prior to UPEC inoculation. The number of CFU was determined after a 90-minute incubation. The horizontal line indicates the median of each group (n = 7–9 mice/genotype). (EG) Asterisks indicate significant P values for the indicated pairwise comparison (Kruskal-Wallis). (H) UPEC strains (UTI89 or MDR-UPEC) were incubated with serial dilutions of RNase4 peptide. After a 2-hour incubation, UPEC strains were plated on LB agar and colony counts were performed the following day. Repeat testing was performed on all bacterial isolates in triplicate. Data are mean CFU and SEM. *P < 0.05, **P < 0.01, ***P < 0.001.