It has recently been shown that at relatively high molar ratios of myosin light-chain kinase (MLCKase) to calmodulin (CM) almost complete inhibition of the kinase activity occurs [Sobieszek (1991) J. Mol. Biol. 220, 947-957]. This inhibition resulted in a highly co-operative activation of MLCKase by CM, whereas the opposite activation (of CM by kinase) was hyperbolic, as expected (unco-operative). This difference in activation was observed only for kinase preparations preincubated with sub-stoichiometric amounts of CM, and only when micromolar concentrations of Ca2+ were present. The inhibitory effect was variable and depended not only on the concentration ratio of kinase to CM but also on the MLCKase preparation. For most of the preparations full inhibition required 5-15 min of preincubation at 25 degrees C and a 3-6-fold molar excess of kinase over CM. The inhibition was reversible, since full activity could be obtained after saturation of the kinase by additional CM. The inhibitory effect did not require ATP (excluding phosphorylation-type modifications of the kinase), and dephosphorylation of the kinase was not involved, since inhibition of an endogenous MLCK phosphatase by microcystin-LR did not decrease the inhibitory effect. Since the co-operative activation by CM was observed for cross-linked MLCKase preparations enriched in kinase dimers, but was absent for the analogous preparations enriched in the oligomers, we concluded that Ca(2+)-CM-dependent changes in the oligomeric state of the kinase were responsible for the modification observed. The exact nature of these modifications remains to be established.
A myofibrillar form of smooth muscle myosin light chain phosphatase (MLCPase) was purified from turkey gizzard myofibrils, and it was found to be closely associated with the myosin light chain kinase (MLCKase). For this reason we have named this phosphatase the kinase-and myosin-associated protein phosphatase (KAMPPase). Subunits of the KAMPPase could be identified during the first ion exchange chromatography step. After further purification on calmodulin (CaM) and on thiophosphorylated regulatory myosin light chain affinity columns we obtained either a homogenous preparation of a 37-kDa catalytic (PC) subunit or a mixture of the PC subunit and variable amounts of a 67-kDa targeting (PT) subunit. The PT subunit bound the PC subunit to CaM affinity columns in a Ca 2؉ -independent manner; thus, elution of the subunits required only high salt concentration. Specificity of interaction between these subunits was shown by the following observations: 1) activity of isolated PC subunit, but not of the PTC holoenzyme, was stimulated 10 -20-fold after preincubation with 5-50 M of CoCl 2 ; 2) the pH activity profile of the PC subunit was modified by the PT subunit (the specific activity of the PTC holoenzyme was higher at neutral pH and lower at alkaline pH); and 3) affinity of the holoenzyme for unphosphorylated myosin was 3-fold higher, and for phosphorylated myosin it was 2-fold lower, in comparison with that of the purified PC subunit. KAMPPase was inhibited by okadaic acid (K i ؍ 250 nM), microcystin-LR (50 nM) and calyculin A (1.5 M) but not by arachidonic acid or the heat-stable inhibitor (I-2), which suggested that this is a type PP1 or PP2A protein phosphatase.
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