Tight junctions control paracellular permeability and cell polarity. Rho GTPase regulates tight junction assembly, and ATP depletion of Madin-Darby canine kidney (MDCK) cells (an in vitro model of renal ischemia) disrupts tight junctions. The relationship between Rho GTPase signaling and ATP depletion was examined. Rho inhibition resulted in decreased localization of zonula occludens-1 (ZO-1) and occludin at cell junctions; conversely, constitutive Rho signaling caused an accumulation of ZO-1 and occludin at cell junctions. Inhibiting Rho before ATP depletion resulted in more extensive loss of junctional components between transfected cells than control junctions, whereas cells expressing activated Rho better maintained junctions during ATP depletion than control cells. ATP depletion and Rho signaling altered phosphorylation signaling mechanisms. ZO-1 and occludin exhibited rapid decreases in phosphoamino acid content following ATP depletion, which was restored on recovery. Expression of Rho mutant proteins in MDCK cells also altered levels of occludin serine/threonine phosphorylation, indicating that occludin is a target for Rho signaling. We conclude that Rho GTPase signaling induces posttranslational effects on tight junction components. Our data also demonstrate that activating Rho signaling protects tight junctions from damage during ATP depletion.
The Escherichia coli FadR protein regulates the transcription of many unlinked genes and operons encoding proteins required for fatty acid synthesis and degradation. Previously, we demonstrated that the ability of purified FadR to bind DNA in vitro is inhibited by long chain acyl coenzyme A esters (DiRusso, D. D., Heimert, T. L., and Metzger, A. K. (1992) J. Biol. Chem. 267, 8685-8691). In the present work, we show that FadR binds acyl-CoA directly. Ligand binding resulted in a shift in the apparent pI of FadR from 6.9 to 6.2 and in a marked decrease in intrinsic fluorescence. The Km for FadR binding of oleoyl coenzyme A was determined to be 12.1 nM using the fluorescence quenching assay. The binding site for acyl-CoA was identified by selection of non-inducible mutations in the FadR gene. One altered protein carrying the change Ser219 to Asn (S219N) was purified and shown to have a reduced affinity for oleoyl coenzyme A as evidenced by a Km of 257 nM. S219N retained the ability to bind DNA and to repress or activate transcription. Alanine substitution of amino acid residues 215 through 230 identified Gly216 and Trp223 as also required specifically for induction. This region of FadR shares amino acid identities and similarities with the coenzyme A-binding site of Clostridium thermoaceticum CO dehydrogenase/acetyl-coenzyme A synthase. Due to the alteration in binding affinity of the purified S219N protein, the non-inducible phenotype of several proteins carrying alanine substitutions and similarities to CO dehydrogenase/acetyl-coenzyme A synthase we propose this region of FadR forms part of the acyl-CoA-binding domain.
Actin cytoskeletal disruption is a hallmark of ischemic injury and ATP depletion in a number of cell types, including renal epithelial cells. We manipulated Rho GTPase signaling by transfection and microinjection in LLC-PK proximal tubule epithelial cells and observed actin cytoskeletal organization following ATP depletion or recovery by confocal microscopy and quantitative image analysis. ATP depletion resulted in disruption of stress fibers, cortical F-actin, and apical actin bundles. Constitutively active RhoV14 prevented disruption of stress fibers and cortical F-actin during ATP depletion and enhanced the rate of stress fiber reassembly during recovery. Conversely, the Rho inhibitor C3 or dominant negative RhoN19 prevented recovery of F-actin assemblies upon repletion. Actin bundles in the apical microvilli and cytosolic F-actin were not affected by Rho signaling. Assembly of vinculin and paxillin into focal adhesions was disrupted by ATP depletion, and constitutively active RhoV14, although protecting stress fibers from disassembly, did not prevent dispersion of vinculin and paxillin, resulting in uncoupling of stress fiber and focal adhesion assembly. We propose that ATP depletion causes Rho inactivation during ischemia and that recovery of normal cellular architecture and function requires Rho.
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