Ca2+ Binding and Energy Coupling in the Calmodulin-Myosin Light Chain Kinase Complex

Anthony Persechini,Kenji Yano,Paul M Stemmer

doi:10.1074/jbc.275.6.4199

Abstract

We have previously shown that 3 Ca(2+) ions are released cooperatively and 1 independently from the complex between (Ca(2+))4-calmodulin and skeletal muscle myosin light chain kinase or a peptide containing its core calmodulin-binding sequence. We now have found that three Ca(2+)-binding sites also function cooperatively in equilibrium Ca(2+) binding to these complexes. Replacement of sites I and II in calmodulin by a copy of sites III and IV abolishes these cooperative effects. Energy coupling-dependent increases in Ca(2+)-binding affinity in the mutant and native calmodulin complexes with enzyme are considerably less than in the peptide complexes, although the complexes have similar affinities. Ca(2+) binding to three sites in the native calmodulin-enzyme complex is enhanced; the affinity of the remaining site is slightly reduced. In the mutant enzyme complex Ca(2+) binding to one pair of sites is enhanced; the other pair is unaffected. In this complex reversal of enzyme activation occurs when Ca(2+) dissociates from the pair of sites with enhanced affinity; more rapid dissociation from the other pair has no effect, although both pairs participate in activation. Ca(2+)-independent interactions with calmodulin clearly play a major role in the enzyme complex, and appear to weaken Ca(2+)-dependent interactions with the core calmodulin-binding sequence.

Highlights

The ever present Ca2ϩ-dependence for enzyme activation suggesting that (Ca2ϩ)-binding protein, calmodulin (CaM),1 plays a key role in the subcellular transduction of Ca2ϩ signals, functioning as a Ca2ϩ-dependent regulatory subunit for a large array of different target proteins, including protein kinases, ion channels and pumps, nitric-oxide synthases, adenylyl cyclases, and phosphodiesterases [1,2,3,4,5,6,7,8,9,10]
We previously reported that release of Ca2ϩ from the complex between CaM and skeletal muscle myosin light chain kinase follows a 3ϩ1 kinetic mechanism: 1 Ca2ϩ ion is released independently with a rate constant Ͼ1000 sϪ1, and 3 are released in a cooperative manner with a rate constant of 1.6 sϪ1, which is similar to the rate constant for reversal of CaM-dependent enzyme activation [16]
All 4 Ca2ϩ ions are released with a single apparent rate constant of 0.11 sϪ1 from the complex between skPEP and CaMCC, in which the N-terminal EF hand pair has been replaced by a copy of the C-terminal pair

Summary

Introduction

The ever present Ca2ϩ-binding protein, calmodulin (CaM), plays a key role in the subcellular transduction of Ca2ϩ signals, functioning as a Ca2ϩ-dependent regulatory subunit for a large array of different target proteins, including protein kinases, ion channels and pumps, nitric-oxide synthases, adenylyl cyclases, and phosphodiesterases [1,2,3,4,5,6,7,8,9,10]. We previously reported that release of Ca2ϩ from the complex between CaM and skeletal muscle myosin light chain kinase (skMLCK) follows a 3ϩ1 kinetic mechanism: 1 Ca2ϩ ion is released independently with a rate constant Ͼ1000 sϪ1, and 3 are released in a cooperative manner with a rate constant of 1.6 sϪ1, which is similar to the rate constant for reversal of CaM-dependent enzyme activation [16]. We reported that a 3ϩ1 Ca2ϩ release mechanism is preserved in the complex between CaM and a 19 residue peptide (skPEP) that contains the core CaM-binding sequence in the enzyme, the rates for Ca2ϩ release are 10 –100-fold slower [16]. In this study we further investigate the structural basis for the 3ϩ1 Ca2ϩrelease mechanism, determine its relationship to steady-state Ca2ϩ binding, and investigate energy coupling in the skMLCK and skPEP complexes with native CaM and with a mutant that no longer exhibits a 3ϩ1 release mechanism

Methods

Results

Conclusion