Computational and site‐specific mutagenesis analyses of the asymmetric charge distribution on calmodulin

Weber, Patricia C; Lukas, Thomas J.; Craig, Theodore A.; Wilson, Erica; King, Michael M.; Kwiatkowski, A; Watterson, Daniel

doi:10.1002/prot.340060107

Cited by 59 publications

(73 citation statements)

References 81 publications

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“…Many of the mutants have differences in charged amino acids which affect their ability to activate selected CaM-dependent enzymes such as MLCK [14,23,24], CaM-dependent protein kinase II [14], phosphorylase kinase [15], and plasma membrane Ca 2÷-ATPase [22]. In our study of CaM mutants we found that the results with the CaM mutants can be divided into three groups, as shown in Table 1.…”

Section: Resultsmentioning

confidence: 90%

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Interaction of smooth muscle caldesmon with calmodulin mutants

Медведева

Bushueva²,

Shirinsky³

et al. 1995

FEBS Letters

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The interaction of avian smooth muscle caldesmon with calmodulin (CAM) was investigated by studying the ability of selected mutant calmodulins to induce fluorescence changes in caldesmon. Different types of CaM mutants were used including point charge mutants, cluster mutations, and mutations which alter the calcium binding of CaM. The caldesmon binding properties were only slightly affected by E84K-CaM or by the double mutation E84Q/E120Q-CaM. Affinity of calmodulin to caldesmon was decreased 2-4 times by point mutation G33V-CaM, double mutation E841(dEI20K-CaM, deletion of residues 82-84, and by cluster mutations DEEll8-120-->KKK or EEE82-84--~KKK. Mutations of the first (E31A-CaM) and the second (E67A-CaM) calcium binding sites reduced the affinity of calmodulin to caldesmon by at least 5-fold; in addition these calmodulin mutants exhibited smaller changes in the fluorescence spectra of caldesmon. Simultaneous mutation of the two negatively charged clusters of calmodulin EEE82-84--~ KKK and DEEll8-120 --> KKK resulted in a more than 15-fold decrease in the affinity of calmodulin for caldesmon. The data indicate that charged and uncharged amino acids in both halves of CaM play an important role in the binding of calmodulin to caldesmon, and that Ca 2+ binding must be maintained in the amino-terminal sites for maximal interaction with caldesmon.

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Section: Resultsmentioning

confidence: 90%

“…Site-directed mutagenesis was used to generate the various mutant calmodulins [13,14]. The mutations are described in Table 1.…”

Section: Methodsmentioning

confidence: 99%

Interaction of smooth muscle caldesmon with calmodulin mutants

Медведева

Bushueva²,

Shirinsky³

et al. 1995

FEBS Letters

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“…It is inferred from in vitro studies that interactions between CaM and its target enzymes involve structurally overlapping sites on the CaM molecule (29). It has also been speculated that selection pressure for CaM to remain highly conserved across phylogenetic lines is a consequence of tight substrate specificity for CaM-binding sites within CaM-dependent proteins.…”

Section: Resultsmentioning

confidence: 99%

Primary Structures of Arabidopsis Calmodulin Isoforms Deduced from the Sequences of cDNA Clones

Ling¹,

Perera²,

Zielinski³

1991

Plant Physiol.

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Complementary DNA (cDNA) clones encoding calmodulin isoforms were isolated from an Arabidopsis leaf XgtlO library by screening with cloned barley calmodulin cDNA probes. Two cDNAs, one a 626-base pair partial-length clone (ACaM-1) and one a 1400-base pair full-length clone (ACaM-2), encode calmodulin polypeptides that differ by four conservative amino acid substitutions. None of the amino acid sequence differences occur within the four Ca2+-binding domains of the proteins. Whereas the deduced amino acid sequences of the two Arabidopsis calmodulin isoforms share 97% identity, the nucleotide sequences encoding the two isoforms share 87% sequence identity. Most of these nucleotide sequence differences (80%) occur in codon wobble positions. ACaM-1 and ACaM-2 both hybridize with a distinct set of restriction fragments of Arabidopsis total DNA, indicating that they were derived from transcripts of separate genes; these genes are single-or very low-copy in the Arabidopsis genome. Both cDNAs hybridize to messenger RNA (mRNA) species of 0.8 kilobases that are expressed to a greater extent in developing siliques compared with leaves, flowers, and stems. Northern blot and polymerase chain reaction assays both indicate that ACaM-1 mRNA is more highly expressed than ACaM-2 mRNA in developing siliques. The steady-state levels of both isoform mRNAs increase as a result of touch stimulation; the kinetics and extent of increase are comparable for the two mRNAs.

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“…Structural information has been derived from examination of calmodulin bound to peptides (Ikura et al, 1992;Meador et al, 1992Meador et al, , 1993 and by analysis of structural modifications of calmodulin on its activation of target enzymes (Craig et al, 1987;Persechini et al, 1989;Weber et al, 1989;Kosk-Kosicka and Bzdega, 1991 ;Cao et al, 1993 light-chain kinase (Ikura et al, 1992;Meador et al, 1992) and Ca*'/calmodulin-dependent protein kinase I1 (Meador et al, 1993). The crystal structure of calmodulin bound to Ca2'-ATPase is not known, but the complex appears to adopt a more extended conformation than the globular shape seen with the other peptides (Kataoka et al, 1991).…”

Section: Discussionmentioning

confidence: 99%

Analysis of Phosphorylation and Mutation of Tyrosine Residues of Calmodulin on Its Activation of the Erythrocyte Ca²⁺‐transporting ATPase

Sacks

López

et al. 1996

European Journal of Biochemistry

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The role played by the phosphorylation sites of calmodulin on its ability to activate the human erythrocyte Ca' +-transporting ATPase (Ca" -ATPase) was evaluated. Phosphorylation of mammalian calmodulin on serine/threonine residues by casein kinase TI decreased its affinity for Ca'+-ATPase by twofold. In contrast, tyrosine phosphorylation of mammalian calmodulin by the insulin-receptor kinase did not significantly alter calmodulin-stimulated Ca'? -ATPase activity. Two variant calmodulins, each containing only one tyrosine residue (the second Tyr is replaced by Phe) were also examined: [F138]calmodulin, a mutant containing tyrosine at position 99, and wheat germ calinodulin which has tyrosine at position 139. The concentrations of [FI 38 Jcalmodulin and wheat germ calmodulin required for half-maximal activation of Ca' ' -,4TPase were tenfold and fourfold higher, respectively, than mammalian calmodulin.Phosphorylation at Tyr99 of [F138]calmodulin shifted its affinity for Ca'+-ATPase towards that of mammalian calmodulin. However, phosphorylation at Tyrl39 of wheat germ calmodulin had essentially no effect on its interaction with Ca'+-ATPase. Thus, all of the observed effects of both phosphorylation and substitution of residues of calmodulin are on its affinity for Ca*+-ATPase, not on V,,,.,,. The effects are dependent on the site of phosphate incorporation. Replacement of tyrosine with phenylalanine has a larger effect than phosphorylation of tyrosine, suggesting that the observed functional alterations reflect a seco'ndary conformational change in the C-terminal half of calmodulin, the region that is itnportant in its activation of Ca2+-ATPase.

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Computational and site‐specific mutagenesis analyses of the asymmetric charge distribution on calmodulin

Cited by 59 publications

References 81 publications

Interaction of smooth muscle caldesmon with calmodulin mutants

Interaction of smooth muscle caldesmon with calmodulin mutants

Primary Structures of Arabidopsis Calmodulin Isoforms Deduced from the Sequences of cDNA Clones

Analysis of Phosphorylation and Mutation of Tyrosine Residues of Calmodulin on Its Activation of the Erythrocyte Ca²⁺‐transporting ATPase

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Computational and site‐specific mutagenesis analyses of the asymmetric charge distribution on calmodulin

Cited by 59 publications

References 81 publications

Interaction of smooth muscle caldesmon with calmodulin mutants

Interaction of smooth muscle caldesmon with calmodulin mutants

Primary Structures of Arabidopsis Calmodulin Isoforms Deduced from the Sequences of cDNA Clones

Analysis of Phosphorylation and Mutation of Tyrosine Residues of Calmodulin on Its Activation of the Erythrocyte Ca2+‐transporting ATPase

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Analysis of Phosphorylation and Mutation of Tyrosine Residues of Calmodulin on Its Activation of the Erythrocyte Ca²⁺‐transporting ATPase