Targeting to C-terminal myosin heavy chain may explain mechanotransduction involving focal adhesion kinase in cardiac myocytes.

Focal adhesion kinase (Fak) has been implicated as a signaling molecule involved in the early response of cardiac myocytes to mechanical stress. The mechanism of Fak activation by mechanical stimuli is not clear. In this study, we report the load-induced Fak activation and its association with myosin heavy chain in cardiac myocytes. Pressure overload lasting from 3 to 60 minutes was shown to induce Fak phosphorylation at Tyr-397, -576/7, -861, and -925 as detected by phosphospecific antibodies. This was paralleled by increases of Fak/Src association and Src activity (Tyr-418 phosphorylation). Yeast two-hybrid screening of an adult rat cDNA library revealed an interaction between Fak and C-terminal coiled-coil region of alpha-myosin heavy chain. This was confirmed by pulldown assay with GST-C-terminal myosin fragment and native Fak from rat left ventricle. Such interaction was confirmed by coimmunoprecipitation assay with anti-Fak and anti-heavy chain cardiac myosin antibodies, confocal microscopy of double-labeled isolated cardiac myocytes and immunoelectron microscopy with anti-Fak antibody. Fak activation by mechanical stress was accompanied by a reduction of Fak/myosin heavy chain association and its relocation at subcellular sites such as costameres, Z-discs, and nuclei. Thus, our present data identify Fak interaction with C-terminal region of myosin heavy chain adding comprehensive data on Fak activation by mechanical stress and mechanotransduction in cardiac myocytes.

Regulation and localization of CAS substrate domain tyrosine phosphorylation.

Crk-associated substrate (CAS) is a tyrosine kinase substrate implicated in integrin control of cell behavior. Phosphorylation, by Src family kinases, of multiple tyrosine residues in the CAS substrate domain (SD) is a major integrin signaling event that promotes cell motility. In this study, novel phosphospecific antibodies directed against CAS SD phosphotyrosine sites ("pCAS" antibodies) were characterized and employed to investigate the cellular regulation and localization of CAS SD tyrosine phosphorylation. An analysis of CAS and focal adhesion kinase (FAK) variants expressed in CAS- and FAK-deficient cell lines, respectively, indicated that CAS SD tyrosine phosphorylation is substantially achieved by Src family kinases brought into association with CAS through two distinct mechanisms: direct binding to the CAS Src-binding domain and indirect association through a FAK bridge. Cell immunostaining with pCAS antibodies revealed that CAS SD tyrosine phosphorylation occurs exclusively at sites of integrin adhesion including both nascent focal complexes formed at the edges of extending lamellipodia as well as mature focal adhesions underlying the cell body. These findings further document a role for FAK as an important upstream regulator of CAS SD tyrosine phosphorylation and implicate CAS-mediated signaling events in promoting membrane protrusion/lamellipodium extension during cell motility.

Early activation of p160ROCK by pressure overload in rat heart.

We investigated the effects of acute pressure overload on activation of p160(ROCK) in rat myocardium. Constriction of transverse aorta, controlled to increase peak systolic pressure of ascending aorta by approximately 40 mmHg, induced a rapid association of RhoA with Dbl-3 and p160(ROCK). The binding of p160(ROCK) to RhoA was rapidly increased, peaking at 30 min (approximately 3.5-fold), but reduced to lower levels (approximately 1.9-fold) by 60 min of pressure overload. The activity of immunoprecipitated p160(ROCK) toward myosin light chain increased approximately 2.5-fold within 10 min but decreased to lower levels (approximately 1.6-fold) after 60 min of pressure overload. Confocal microscopic analysis indicated that pressure overload induced the formation of aggregates of p160(ROCK) and RhoA along the longitudinal axis of cardiac myocytes. Immunoelectron microscopic analysis showed that pressure overload induced the association of p160(ROCK) and RhoA to Z-line, T-tubule, and subsarcolemmal areas. The rapid activation of p160(ROCK) by pressure overload and its aggregation in subcellular structures involved in transmission of mechanical force suggest a role for this enzyme in the mechanobiochemical transduction in the myocardium.

Load-induced focal adhesion kinase activation in the myocardium: role of stretch and contractile activity.

We investigated the influence of stretch and contractile activity on load-induced activation of focal adhesion kinase (FAK) and extracellular signal-regulated kinase (ERK)1/2 in isolated rat hearts. Increases of diastolic pressure from approximately 0 to approximately 15 mmHg rapidly increased FAK tyrosine phosphorylation (maximum: 2.3-fold) and binding to c-Src (maximum: 2.8-fold) and Grb2 (maximum: 3.6-fold). This was paralleled by activation (maximum: 2.8-fold) and binding of ERK1/2 to FAK. FAK and ERK1/2 were immunolocalized at sarcolemmal sites of cardiac myocytes and in the nuclei, in the case of ERK1/2. Balloon inflation to raise ventricular pressure in hearts perfused with cardioplegic solution also activated FAK and ERK1/2. However, increases in contractile activity induced by increasing calcium concentration in the perfusate (from 0.5 to 5 mM) did not activate the FAK multicomponent signaling complex or ERK1/2 in the myocardium. These results indicate that stretch rather than contractile activity induces FAK and ERK1/2 activation in the myocardium. In addition, the activation and binding of ERK1/2 to FAK suggest that FAK drives the load-induced activation of ERK1/2.