Flow Mediates Collecting Duct Histone Deacetylase 1 Nuclear Export

Abstract

Urinary flow within the renal tubules, especially the inner‐medullary collecting duct (IMCD), increases after high sodium consumption. We previously reported that this natriuretic response is due, in part, to elevated nitric oxide (NO) production without associated changes in NO synthase (NOS) expression. This suggests that high flow increases NO production via increased NOS activity. Histone deacetylase 1 (HDAC1) has recently been cited as a flow‐responsive protein and may post‐translationally deacetylate lysines on non‐histone proteins. Therefore, we hypothesized that flow‐mediated increases in NO production occur via HDAC1. Mouse IMCD cells were grown to confluency on glass slides, then placed under static conditions or 10 dynes/cm2 fluid‐flow for 1 hour at 37°C in the presence of vehicle (0.1% DMSO) or MS‐275 (300 nM), HDAC1‐selective inhibitor. Nitrite production, analyzed by HPLC, increased in response to flow >5‐fold (static: 231.4±31.1, flow: 1291.49.2±183.8 pmol/mg pr/hr; n=7/group, p<0.0001). MS‐275 significantly decreased NO production in response to flow (MS‐275: 342.8±44.0 pmol/mg pr/hr; n=9/group, p<0.0001). HDAC1 expression (static: 1.00±0.2, flow: 0.98±0.1 RDU/β‐actin; n=6/group, p>0.05) and activity (static: 1.00±0.06, flow: 0.85±0.02 RDU/β‐actin; n=3/group, p>0.05) was unchanged with flow in whole cell lysate. However, HDAC1 immunofluorescent staining of post‐flow IMCD cells suggested the presence of both nuclear and cytosolic HDAC1 and nuclear extraction of these flowed samples revealed a significant decrease in nuclear HDAC1 expression (static: 1.00±0.1, flow: 0.68±0.1 RDU; n=6/group, p<0.05), indicating nuclear export. Calcium, a key player in classical NOS activation, has also been reported to activate HDAC nuclear export. Thus, we further hypothesized that flow activation of NO production as well as flow‐mediated export of HDAC1 is calcium‐dependent. Flow‐induced NO production was abolished in the absence of calcium (flow+vehicle: 2038.1±402.0; flow+BAPTA: 377.7±75.3 pmol/mg pr/hr; flow+calcium‐free media: 474.8±133.2 pmol/mg pr/hr; n= 5–11/group, p<0.001). However, flow mediated nuclear HDAC1 export was similar in the presence and absence of BAPTA treatment (flow: 0.75±0.04, flow+BAPTA: 0.74±0.03 RDU; n=6/group, p>0.05). In conclusion, IMCD NO production in response to flow is both calcium‐ and HDAC1‐dependent, but extracellular calcium appears not to facilitate the flow‐mediated nuclear export of HDAC1. Further studies will elucidate the disparate mechanism(s) of flow‐mediated HDAC1‐dependent NO production from flow‐mediated HDAC1 nuclear export.Support or Funding InformationThis work was supported by funding from the National Institutes of Health ‐ P01 HL136267 to Dr. Jennifer Pollock and F31 DK111067 to Randee Sedaka.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.