Insulin and the phosphatidylinositol 3-kinase signaling pathway regulate Ribonuclease 7 expression in the human urinary tract.

Diabetes mellitus is a systemic disease associated with a deficiency of insulin production or action. Diabetic patients have an increased susceptibility to infection with the urinary tract being the most common site. Recent studies suggest that Ribonuclease 7 (RNase 7) is a potent antimicrobial peptide that plays an important role in protecting the urinary tract from bacterial insult. Because the impact of diabetes on RNase 7 expression and function are unknown, we investigated the effects of insulin on RNase 7 using human urine specimens. The urinary RNase 7 concentrations were measured in healthy control patients and insulin-deficient type 1 diabetics before and after starting insulin therapy. Compared with controls, diabetic patients had suppressed urinary RNase 7 concentrations, which increased with insulin. Using primary human urothelial cells, the mechanisms by which insulin stimulates RNase 7 synthesis were next explored. Insulin induced RNase 7 production via the phosphatidylinositide 3-kinase signaling pathway (PI3K/AKT) to shield urothelial cells from uropathogenic E. coli. In contrast, uropathogenic E. coli suppressed PI3K/AKT activity and RNase 7 production. Thus, insulin and PI3K/AKT signaling are essential for RNase 7 expression and increased infection risks in diabetic patients may be secondary to suppressed RNase 7 production. Our data may provide unique insight into novel urinary tract infection therapeutic strategies in at-risk populations.

Ribonucleases 6 and 7 have antimicrobial function in the human and murine urinary tract.

Recent evidence suggests antimicrobial peptides protect the urinary tract from infection. Ribonuclease 7 (RNase 7), a member of the RNase A superfamily, is a potent epithelial-derived protein that maintains human urinary tract sterility. RNase 7 expression is restricted to primates, limiting evaluation of its antimicrobial activity in vivo. Here we identified ribonuclease 6 (RNase 6) as the RNase A superfamily member present in humans and mice that is most conserved at the amino acid level relative to RNase 7. Like RNase 7, recombinant human and murine RNase 6 has potent antimicrobial activity against uropathogens. Quantitative real-time PCR and immunoblot analysis indicate that RNase 6 mRNA and protein are upregulated in the human and murine urinary tract during infection. Immunostaining located RNase 6 to resident and infiltrating monocytes, macrophages, and neutrophils. Uropathogenic E. coli induces RNase 6 peptide expression in human CD14(+) monocytes and murine bone marrow-derived macrophages. Thus, RNase 6 is an inducible, myeloid-derived protein with markedly different expression from the epithelial-derived RNase 7 but with equally potent antimicrobial activity. Our studies suggest RNase 6 serves as an evolutionarily conserved antimicrobial peptide that participates in the maintenance of urinary tract sterility.

Differential induction of podocyte heat shock proteins by prolonged single and combination toxic metal exposure.

Cadmium, mercury, and arsenite are among the most abundant toxic metals (TM) in our environment, and chronic TM exposure leads to injury to the kidney's glomerular filtration barrier. The small heat shock protein hsp25, highly expressed in glomerular podocytes, is induced during development of experimental nephrotic syndrome, and hsp25 overexpression can protect cultured podocytes from injury. Because little is known about the effect of multiple TM on podocytes, we measured the response of cultured podocytes to prolonged exposures to single and multiple TM. Podocyte viability declined by approximately 50% after 3 days of treatment with 20 microM cadmium, mercury, or arsenite, and 40 microM of any of these metals was lethal. The toxicity of equimolar concentrations of two or all three metals in combination was significantly altered compared to individual metal treatments. Single TM treatments induced only modest increases in the amounts of hsp25, alphaB-crystallin, and inducible hsp70. Toxic metal combinations induced greater stress protein accumulation, especially arsenite + cadmium or arsenite + cadmium + mercury treatments, the TM mixtures with the lowest toxicity. All TM treatments caused a rapid and sustained increase in hsp25 phosphorylation. The intracellular accumulation of cadmium was greater and that of mercury was less in cells treated with TM combinations than in cells treated with a single TM. Our results showed that multiple TM effects on podocyte viability were neither additive nor synergistic and that induction of heat shock proteins correlated with increased resistance to TM injury, suggesting that induction of small heat shock proteins may play an important role in preventing TM-induced podocyte injury.