Harlan E. Ives

Mechanical strain of rat vascular smooth muscle cells is sensed by specific extracellular matrix/integrin interactions.

Cyclic mechanical strain (1 Hz) causes a mitogenic response in neonatal rat vascular smooth muscle cells due to production and secretion of PDGF. In this study, the mechanism for sensing mechanical strain was investigated. Silicone elastomer strain plates were coated at varying densities with elastin, laminin, type I collagen, fibronectin, or vitronectin. Strain was applied by cyclic application of a vacuum under the dishes. Cells adhered, spread, and proliferated on each matrix protein, but the mitogenic response to strain was matrix dependent. Strain increased DNA synthesis in cells on collagen, fibronectin, or vitronectin, but not in cells on elastin or laminin. When strain was applied on matrices containing both laminin and vitronectin, the mitogenic response to strain depended upon the vitronectin content of the matrix. Fibronectin, in soluble form (0-50 micrograms/ml), and the integrin binding peptide GRGDTP (100 micrograms/ml) both blocked the mitogenic response to mechanical strain in cells grown on immobilized collagen. Neither soluble laminin nor the inactive peptide GRGESP blocked the response to strain. GRGDTP did not alter the mitogenic response to exogenous PDGF or alpha-thrombin but did prevent the secretion of PDGF in response to strain. Furthermore, GRGDTP, but not GRGESP, prevented strain-induced expression of a PDGF-A chain promoter 890 bp-chloramphenicol acetyltransferase construct that was transiently transfected into vascular smooth muscle cells. Finally, the response to strain was abrogated by antibodies to both beta 3 and alpha v beta 5 integrins but not by an antibody to beta 1 integrins. Thus interaction between integrins and specific matrix proteins is responsible for sensing mechanical strain in vascular smooth muscle cells.

Mechanical Strain Increases Smooth Muscle and Decreases Nonmuscle Myosin Expression in Rat Vascular Smooth Muscle Cells

The effect of cyclic (1-Hz) mechanical strain on expression of myosin heavy chain isoforms was examined in neonatal rat vascular smooth muscle cells cultured on silicone elastomer plates. Myosin heavy chain isoforms were identified by immunoblot using antibodies recognizing (1) smooth muscle myosin heavy chain isoforms SM-1 and SM-2, (2) SM-1 exclusively, and (3) nonmuscle myosin heavy chains A and B. In response to 36 to 72 hours of strain, SM-1 and SM-2 increased by fourfold to sixfold, whereas nonmuscle myosin A decreased to 30% of control. Nonmuscle myosin B was unaffected by strain. SM-1 mRNA increased by twofold to threefold after 12 hours of strain but decreased toward control levels thereafter. SM-2 mRNA was only barely detectable. Nonmuscle myosin A mRNA decreased to 50% of control after 3 hours of strain and then returned to the control level. Since these cells secrete platelet-derived growth factor (PDGF) in response to strain, we assessed the effects of PDGF on myosin isoform expression. Exogenous PDGF (10 ng/mL) decreased SM-1 expression by 35% and increased nonmuscle myosin expression twofold, opposite the effect of strain. In cells exposed to strain with neutralizing antibodies to PDGF-AB, the strain-induced increase in SM-1 was enhanced 10-fold, and nonmuscle myosin A was reduced to 40% of control. Finally, the effect of extracellular matrix on transduction of the strain signal was studied. Forty-eight hours of cyclic strain increased SM-1 by twofold in cells cultured on collagen type 1 and threefold in cells cultured on laminin. In fibronectin-cultured cells, strain elicited no increase in SM-1. Thus, mechanical strain, sensed through specific interactions with the matrix, can alter myosin isoform expression toward that found in a more differentiated state.

Physical interaction between aldolase and vacuolar H+-ATPase is essential for the assembly and activity of the proton pump.

Vacuolar proton-translocating ATPases (V-ATPases) are a family of highly conserved proton pumps that couple hydrolysis of cytosolic ATP to proton transport out of the cytosol. Although V-ATPases are involved in a number of cellular processes, how the proton pumps are regulated under physiological conditions is not well understood. We have reported that the glycolytic enzyme aldolase mediates V-ATPase assembly and activity by physical association with the proton pump (Lu, M., Holliday, L. S., Zhang, L., Dunn, W. A., and Gluck, S. L. (2001) J. Biol. Chem. 276, 30407–30413 and Lu, M., Sautin, Y., Holliday, L. S., and Gluck, S. L. (2004) J. Biol. Chem. 279, 8732–8739). In this study, we generate aldolase mutants that lack binding to the B subunit of V-ATPase but retain normal catalytic activities. Functional analysis of the aldolase mutants shows that disruption of binding between aldolase and the B subunit of V-ATPase results in disassembly and malfunction of V-ATPase. In contrast, aldolase enzymatic activity is not required for V-ATPase assembly. Taken together, these findings strongly suggest an important role for physical association between aldolase and V-ATPase in the regulation of the proton pump.

Mechanical strain and collagen potentiate mitogenic activity of angiotensin II in rat vascular smooth muscle cells.

The effects of extracellular matrix proteins and mechanical strain on the mitogenic activity of angiotensins I and II (AI and AII) were examined in cultured rat vascular smooth muscle (VSM) cells. VSM cells on various extracellular matrices were exposed to AII (1 microM) for 48 h. On plastic, AII induced only a 1.6-fold increase in [3H]thymidine incorporation, but on fibronectin- or type I collagen-coated plastic, the response to AII was enhanced from two- to fourfold. On a type I collagen-coated silicone elastomer, to which mechanical strain was applied, [3H]thymidine incorporation dramatically increased to a maximum of 53-fold. Dup 753 (10(-5) M) blocked the AII-induced increase in DNA synthesis. AI also increased DNA synthesis in VSM cells, and this response was also enhanced by mechanical strain. Mitogenic activity of AI was blocked by ramiprilat (10(-5) M), indicating that its mitogenic activity was via conversion to AII. The synergy between AII and strain was completely eliminated by neutralizing antibodies to PDGF AB (3 micrograms/ml). Furthermore, the mitogenic effect of AII in unstrained cells was also synergistic with submaximal concentrations of PDGF AB (1 ng/ml). Thus, the synergy between AII and mechanical strain probably results from synergism between AII and PDGF secreted in response to strain.

Rapid Induction and Translocation of Egr-1 in Response to Mechanical Strain in Vascular Smooth Muscle Cells

The effect of mechanical strain on transcription and expression of the immediate-early genes, early growth response gene-1 (Egr-1), c-jun, and c-fos, was investigated in neonatal rat aortic vascular smooth muscle (VSM) cells. Cells grown on silicone elastomer plates were subjected to cyclic mechanical strain (1 Hz) at various durations and magnitudes. Egr-1 mRNA increased rapidly in response to cyclic strain, reached a maximum of 10-fold after 30 minutes, and returned to baseline after 4 hours. c-jun exhibited a similar pattern, whereas c-fos mRNA expression was unaffected by strain. Cycloheximide prolonged the increase in Egr-1 and c-jun mRNA and caused superinduction of both. The threshold level of continuous cyclic strain needed to induce expression was 5% for Egr-1 and c-jun. Even a single cycle of mechanical strain that lasted 1 second was sufficient to induce Egr-1 and c-jun mRNA. Strain also increased expression of a transiently transfected Egr-1 promoter-reporter construct. The effect of varying extracellular matrices on strain-induced Egr-1 and c-jun mRNA was examined. In contrast to collagen type 1- and pronectin-coated plates, strain did not significantly alter expression of Egr-1 and c-jun was less induced on laminin-coated plates. On collagen type 1, strain increased Egr-1 protein levels by 2.1-fold at 60 minutes. Immunofluorescence microscopy revealed translocation of Egr-1 to the nucleus in response to strain. These observations indicate that Egr-1 expression and translocation are sensitive to mechanical perturbation of the cell. c-jun is also induced by strain, but c-fos is not. The signal for this induction may involve specific cell-matrix interactions.

mTOR Complex-2 Activates ENaC by Phosphorylating SGK1

The serum- and glucocorticoid-induced kinase 1 (SGK1) plays a central role in hormone regulation of epithelial sodium (Na+) channel (ENaC)-dependent Na+ transport in the distal nephron. Phosphorylation within a carboxy-terminal domain, designated the hydrophobic motif (HM), determines the activity of SGK1, but the identity of the HM kinase is unknown. Here, we show that the highly conserved serine-threonine kinase mammalian target of rapamycin (mTOR) is essential for the phosphorylation of the HM of SGK1 and the activation of ENaC. We observed that mTOR, in conjunction with rictor (mTORC2), phosphorylated SGK1 and stimulated ENaC. In contrast, when mTOR assembled with raptor in the rapamycin-inhibited complex (mTORC1), it did not phosphorylate SGK1 or stimulate ENaC. Inhibition of mTOR blocked both SGK1 phosphorylation and ENaC-mediated Na+ transport, whereas specific inhibition of mTORC1 had no effect. Similarly, small hairpin RNA-mediated knockdown of rictor inhibited SGK1 phosphorylation and Na+ current, whereas knockdown of raptor had no effect. Finally, in co-immunoprecipitation experiments, SGK1 interacted selectively with rictor but not with raptor, suggesting selective recruitment of SGK1 to mTORC2. We conclude that mTOR, specifically mTORC2, is the HM kinase for SGK1 and is required for ENaC-mediated Na+ transport, thereby extending our understanding of the molecular mechanisms underlying Na+ balance.

Ion transport defects and hypertension. Where is the link

Most of the recent thinking on the role of ion transport defects in hypertension flows from the hypothesis that essential hypertension is due to the production of circulating Na + transport inhibitors acting on renal epithelial cells and vascular smooth muscle cells

Formyl peptide-induced chemotaxis of human polymorphonuclear leukocytes does not require either marked changes in cytosolic calcium or specific granule discharge. Role of formyl peptide receptor reexpression (or recycling).

We examined the role of intracellular and extracellular calcium on the ability of human polymorphonuclear leukocytes to migrate chemotactically and reexpress (or recycle) formyl peptide receptors when challenged with the synthetic chemotactic peptide, N-formyl-methionyl-leucyl-phenylalanine (FMLP). Extracellular calcium was not required for either optimal chemotactic responses or receptor reexpression. Depletion and chelation of intracellular calcium resulted in significant diminution in the ability of polymorphonuclear leukocytes to release the specific granule constituents lactoferrin and vitamin B12-binding protein during the process of chemotaxis, but had no effect on the capability of these cells to respond chemotactically. Similarly, chelation of intracellular calcium did not affect the ability of these cells to reexpress a population of formyl peptide receptors. Inhibition of receptor reexpression, by a nonagglutinating derivative of wheat-germ agglutinin, was associated with inhibition of chemotactic responses to FMLP. Thus, it appears that large changes in cytosolic free calcium are not necessary for formyl peptide-induced polymorphonuclear leukocyte chemotaxis. In contrast, continuous reexpression (or recycling) of formyl peptide receptors is required for polymorphonuclear leukocyte chemotactic responses to FMLP, a process that appears to be independent from specific granule fusion with plasma membrane.

Phospholipase Cγ Activation, Phosphotidylinositol Hydrolysis, and Calcium Mobilization are Not Required for FGF Receptor-Mediated Chemotaxis

Basic fibroblast growth factor (FGF) is a potent angiogenic factor that stimulates several cell types to migrate along a chemotactic gradient. Most chemoattractant receptors appear to share a common mechanism that involves activation of phospholipase C (PLC), hydrolysis of phosphotidylinositol, and mobilization of intracellular calcium. We transfected two different cell lines with either human FGF receptor-1 cDNA or chimeric FGF receptor cDNA. Ligand stimulation induced chemotaxis, activation of PLC gamma, phosphotidylinositol hydrolysis, and calcium mobilization in both wild-type receptor cell lines. No such response was elicited in control cells. Mutation of the two fibroblast growth factor receptors at residue 766, replacing tyrosine with phenylalanine, made the receptors incapable of associating with and activating PLC gamma following ligand stimulation. These mutant receptors also failed to mediate phosphotidylinositol hydrolysis and calcium mobilization. However, cells transfected with the mutant fibroblast growth factor receptors were as chemotactically responsive to the appropriate ligand as were cells transfected with the wild-type receptors. These findings demonstrate that the ability of the fibroblast growth factor receptor to promote chemotaxis is not dependent on increased activation of PLC gamma, increased hydrolysis of phosphotidylinositol, or increased global mobilization of calcium.

mSIN1 protein mediates SGK1 protein interaction with mTORC2 protein complex and is required for selective activation of the epithelial sodium channel.

The mammalian target of rapamycin (mTOR) plays a central role in the regulation of a number of cellular processes including growth, metabolism, and ion transport. mTOR is found in two multiprotein complexes, mTORC1 and mTORC2, which phosphorylate distinct substrates and regulate distinct cellular processes. SGK1 is an mTORC2 substrate, which is a key regulator of epithelial Na+ transport mediated by the epithelial sodium channel. Although it is known that SGK1 physically interacts with mTORC2, it is unknown which mTORC2 component mediates this interaction or whether this interaction plays a physiologically relevant role in specific activation of SGK1. Here we identify mSIN1 as the mTORC2 component that mediates interaction with SGK1 and demonstrate that this interaction is required for SGK1 phosphorylation and epithelial sodium channel activation. We used the yeast two-hybrid system coupled with random mutagenesis to identify a mutant mSIN1 (mSIN1/Q68H), which does not interact with SGK1. Expression of this mutant does not restore SGK1 phosphorylation to wild-type levels in mSIN1-deficient murine embryo fibroblasts. Furthermore, in kidney epithelial cells, mSIN1/Q68H has a dominant-negative effect on SGK1 phosphorylation and on SGK1-dependent Na+ transport. Interestingly, this interaction appears to be specific in that another mTORC2 substrate, Akt, does not interact with mSIN1, and its phosphorylation and activity are unaffected by the Q68H mutation. These data support the conclusion that mTORC2 uses distinct strategies to phosphorylate different substrates and suggest a mechanism for mTORC2 specificity in the regulation of diverse cellular processes.