Abstract
Cardiac troponin I is a phosphorylation target for endothelin-activated protein kinase C. Earlier work in cardiac myocytes expressing nonphosphorylatable slow skeletal troponin I provided evidence that protein kinase C-mediated cardiac troponin I phosphorylation accelerates relaxation. However, replacement with the slow skeletal isoform also alters the myofilament pH response and the Ca2+ transient, which could influence endothelin-mediated relaxation. Here, differences in the Ca2+ transient could not explain the divergent relaxation response to endothelin in myocytes expressing cardiac versus slow skeletal troponin I nor could activation of Na+/H+ exchange. Three separate clusters within cardiac troponin I are phosphorylated by protein kinase C, and we set out to determine the contribution of the Thr144 and Ser23/Ser24 clusters to the endothelin-mediated contractile response. Myocyte replacement with a cardiac troponin I containing a Thr144 substituted with the Pro residue found in slow skeletal troponin I resulted in prolonged relaxation in response to acute endothelin compared with control myocytes. Ser23/Ser24 also is a target for protein kinase C phosphorylation of purified cardiac troponin I, and although this cluster was not acutely phosphorylated in intact myocytes, significant phosphorylation developed within 1 h after adding endothelin. Replacement of Ser23/Ser24 with Ala indicated that this cluster contributes significantly to relaxation during more prolonged endothelin stimulation. Overall, results with these mutants provide evidence that Thr144 plays an important role in the acute acceleration of relaxation, whereas Ser23/Ser24 contributes to relaxation during more prolonged activation of protein kinase C by endothelin.
Highlights
Earlier work demonstrated that cardiac troponin I (cTnI) phosphorylation is correlated with the positive inotropic response to ET [4, 8, 18]
The similar Ca2ϩ transient responses to ET coupled with the divergent shortening response of cTnI- versus slow skeletal troponin I (ssTnI)-expressing myocytes indicates that cTnI contributes significantly to the enhanced peak shortening and accelerated relaxation rate observed in response to Protein kinase C (PKC) activation by ET compared with myocytes expressing ssTnI
These results support the idea that Naϩ/Hϩ exchange and the ensuing alkalosis is important for the enhanced peak shortening response, whereas cTnI plays a more critical role in the accelerated relaxation rate response to ET
Summary
Earlier work demonstrated that cTnI phosphorylation is correlated with the positive inotropic response to ET [4, 8, 18]. The final aim of the present work was to determine the contribution of individual phosphorylation sites within cTnI to the PKC-mediated changes in intact adult myocyte relaxation rate in response to ET. The Ser23/Ser cluster is a target for PKC in purified cTnI and is a major myofilament target for protein kinase A (PKA) [26] Phosphorylation of this cluster by PKA significantly decreases myofilament Ca2ϩ sensitivity [27] and accelerates relaxation during -adrenergic activation [28]. A similar increase in relaxation is expected if this Ser cluster is phosphorylated by PKC in intact adult myocytes
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