The LQT-associated calmodulin mutant E141G induces disturbed Ca2+-dependent binding and a flickering gating mode of the CaV1.2 channel

Calmodulin (CaM) mutations are associated with congenital long QT (LQT) syndrome (LQTS), which may be related to the dysregulation of the cardiac-predominant Ca2+ channel isoform CaV1.2. Among various mutants, CaM-E141G was identified as a critical missense variant. However, the interaction of this CaM mutant with the CaV1.2 channel has not been determined. In this study, by utilizing a semiquantitative pull-down assay, we explored the interaction of CaM-E141G with CaM-binding peptide fragments of the CaV1.2 channel. Using the patch-clamp technique, we also investigated the electrophysiological effects of the mutant on CaV1.2 channel activity. We found that the maximum binding (Bmax) of CaM-E141G to the proximal COOH-terminal region, PreIQ-IQ, PreIQ, IQ, and NT (an NH2-terminal peptide) was decreased (by 17.71–59.26%) compared with that of wild-type CaM (CaM-WT). In particular, the Ca2+-dependent increase in Bmax became slower with the combination of CaM-E141G + PreIQ and IQ but faster in the case of NT. Functionally, CaM-WT and CaM-E141G at 500 nM Ca2+ decreased CaV1.2 channel activity to 24.88% and 55.99%, respectively, compared with 100 nM Ca2+, showing that the inhibitory effect was attenuated in CaM-E141G. The mean open time of the CaV1.2 channel was increased, and the number of blank traces with no channel opening was significantly decreased. Overall, CaM-E141G exhibits disrupted binding with the CaV1.2 channel and induces a flickering gating mode, which may result in the dysfunction of the CaV1.2 channel and, thus, the development of LQTS. The present study is the first to investigate the detailed binding properties and single-channel gating mode induced by the interaction of CaM-E141G with the CaV1.2 channel.

Molecular Basis of pH and Ca2+ Regulation of Aquaporin Water Permeability

Aquaporins facilitate the diffusion of water across cell membranes. We previously showed that acid pH or low Ca2+ increase the water permeability of bovine AQP0 expressed in Xenopus oocytes. We now show that external histidines in loops A and C mediate the pH dependence. Furthermore, the position of histidines in different members of the aquaporin family can “tune” the pH sensitivity toward alkaline or acid pH ranges. In bovine AQP0, replacement of His40 in loop A by Cys, while keeping His122 in loop C, shifted the pH sensitivity from acid to alkaline. In the killifish AQP0 homologue, MIPfun, with His at position 39 in loop A, alkaline rather than acid pH increased water permeability. Moving His39 to His40 in MIPfun, to mimic bovine AQP0 loop A, shifted the pH sensitivity back to the acid range. pH regulation was also found in two other members of the aquaporin family. Alkaline pH increased the water permeability of AQP4 that contains His at position 129 in loop C. Acid and alkaline pH sensitivity was induced in AQP1 by adding histidines 48 (in loop A) and 130 (in loop C). We conclude that external histidines in loops A and C that span the outer vestibule contribute to pH sensitivity. In addition, we show that when AQP0 (bovine or killifish) and a crippled calmodulin mutant were coexpressed, Ca2+ sensitivity was lost but pH sensitivity was maintained. These results demonstrate that Ca2+ and pH modulation are separable and arise from processes on opposite sides of the membrane.

Calmodulin controls organization of the actin cytoskeleton via regulation of phosphatidylinositol (4,5)-bisphosphate synthesis in Saccharomyces cerevisiae

Phosphoinositides regulate a wide range of cellular processes, including proliferation, survival, cytoskeleton remodelling and membrane trafficking, yet the mechanisms controlling the kinases, phosphatases and lipases that modulate phosphoinositide levels are poorly understood. In the present study, we describe a mechanism controlling MSS4, the sole phosphatidylinositol (4)-phosphate 5-kinase in Saccharomyces cerevisiae. Mutations in MSS4 and CMD1, encoding the small Ca2+-binding protein calmodulin, confer similar phenotypes, including loss of viability and defects in endocytosis and in organization of the actin cytoskeleton. Overexpression of MSS4 suppresses the growth and actin defects of cmd1-226, a temperature-sensitive calmodulin mutant which is defective in the organization of the actin cytoskeleton. Finally, the cmd1-226 mutant exhibits reduced levels of phosphatidylinositol (4,5)-bisphosphate. These findings suggest that calmodulin positively controls MSS4 activity and thereby the actin cytoskeleton.

Increased Transmitter Release and Aberrant Synapse Morphology in a Drosophila Calmodulin Mutant

The ubiquitous calcium-binding protein calmodulin (CaM) has been implicated in the development and function of the nervous system in a variety of eukaryotic organisms. We have generated mutations in the single Drosophila Calmodulin (Cam) gene and examined the effects of these mutations on behavior, synaptic transmission at the larval neuromuscular junction, and structure of the larval motor nerve terminal. Flies hemizygous for Cam3c1, a mutation in the first Ca2+-binding site, exhibit behavioral, neurophysiological, and neuroanatomical abnormalities. In particular, adults exhibit defects in locomotion, coordination, and flight. Larvae exhibit increased neurotransmitter release from the motor nerve terminal at low [Ca2+] in the presence of the K+ channel-blocking drug quinidine. In addition, synaptic bouton structure at motor nerve terminals is altered. These effects are distinct from those produced by altering the activity of the CaM target enzymes CaM-activated kinase II (CaMKII) and CaM-activated adenylyl cyclase (CaMAC). Furthermore, previous in vitro studies of mutant Cam3c1 demonstrated that although its Ca2+ affinity is decreased, Cam3c1 protein can activate CaMKII, CaMAC, and CaM-activated phosphatase calcineurin in a manner similar to wild-type CaM. Thus, the Cam3c1 mutation might affect Ca2+ buffering or interfere with the activation or inhibition of a CaM target distinct from CaMKII or CaMAC.

Ca2+-calmodulin promotes survival of pheromone-induced growth arrest by activation of calcineurin and Ca2+-calmodulin-dependent protein kinase.

The cmd1-6 allele contains three mutations that block Ca2+ binding to calmodulin from Saccharomyces cerevisiae. We find that strains containing cmd1-6 lose viability during cell cycle arrest induced by the mating pheromone alpha-factor. The 50% lethal dose (LD50) of alpha-factor for the calmodulin mutant is almost fivefold below the LD50 for a wild-type strain. The calmodulin mutants are not more sensitive to alpha-factor, as measured by activation of a pheromone-responsive reporter gene. Two observations indicate that activation of the Ca2+-calmodulin-dependent protein phosphatase calcineurin contributes to survival of pheromone-induced arrest. First, deletion of the gene encoding the calcineurin regulatory B subunit, CNB1, from a wild-type strain decreases the LD50 of alpha-factor but has no further effect on a cmd1-6 strain. Second, a dominant constitutive calcineurin mutant partially restores the ability of the cmd1-6 strain to survive exposure to alpha-factor. Activation of the Ca2+-calmodulin-dependent protein kinase (CaMK) also contributes to survival, thus revealing a new function for this enzyme. Deletion of the CMK1 and CMK2 genes, which encode CaMK, decreases the LD50 of pheromone compared with that for a wild-type strain but again has no effect in a cmd1-6 strain. Furthermore, the LD50 of alpha-factor for a mutant in which the calcineurin and CaMK genes have been deleted is the same as that for the calmodulin mutant. Finally, the CaMK and calcineurin pathways appear to be independent since the ability of constitutive calcineurin to rescue a cmd1-6 strain is not blocked by deletion of the CaMK genes.

A dosage-dependent suppressor of a temperature-sensitive calmodulin mutant encodes a protein related to the fork head family of DNA-binding proteins

The cmd1-1 mutation of calmodulin causes temperature-sensitive growth in Saccharomyces cerevisiae. We have isolated a dosage-dependent suppressor of cmd1-1, designated HCM1. Twentyfold overexpression of HCM1 permits strains carrying cmd1-1 to grow at temperatures up to and including 34 degrees C but does not suppress the lethality of either cmd1-1 at higher temperatures or the deletion of CMD1. Thus, overexpression of HCM1 does not bypass the requirement for calmodulin but enhances the ability of the mutant calmodulin to function. HCM1 is not essential for growth, but deletion of HCM1 exacerbates the phenotype of a strain carrying cmd1-1. HCM1 is located on chromosome III, which was recently sequenced. Our results correct errors in the published DNA sequence. The putative polypeptide encoded by HCM1 is 564 amino acids long and has a predicted molecular weight of 63,622. Antisera prepared against Hcm1p detect a protein that is overproduced in yeast strains overexpressing HCM1 and has an apparent molecular mass of 65 kDa. Eighty-six amino acid residues in the N terminus of Hcm1p show 50% identity with a DNA-binding region of the fork head family of DNA-binding proteins. When fused to the DNA-binding domain of Gal4p, residues 139 to 511 of Hcm1p can act as a strong activator of transcription. However, overexpression of HCM1 does not affect the expression of calmodulin. Furthermore, Hcm1p does not bind to calmodulin in a gel overlay assay. Thus, overexpression of HCM1 enhances calmodulin function by an apparently indirect mechanism.

A dosage-dependent suppressor of a temperature-sensitive calmodulin mutant encodes a protein related to the fork head family of DNA-binding proteins.

The cmd1-1 mutation of calmodulin causes temperature-sensitive growth in Saccharomyces cerevisiae. We have isolated a dosage-dependent suppressor of cmd1-1, designated HCM1. Twentyfold overexpression of HCM1 permits strains carrying cmd1-1 to grow at temperatures up to and including 34 degrees C but does not suppress the lethality of either cmd1-1 at higher temperatures or the deletion of CMD1. Thus, overexpression of HCM1 does not bypass the requirement for calmodulin but enhances the ability of the mutant calmodulin to function. HCM1 is not essential for growth, but deletion of HCM1 exacerbates the phenotype of a strain carrying cmd1-1. HCM1 is located on chromosome III, which was recently sequenced. Our results correct errors in the published DNA sequence. The putative polypeptide encoded by HCM1 is 564 amino acids long and has a predicted molecular weight of 63,622. Antisera prepared against Hcm1p detect a protein that is overproduced in yeast strains overexpressing HCM1 and has an apparent molecular mass of 65 kDa. Eighty-six amino acid residues in the N terminus of Hcm1p show 50% identity with a DNA-binding region of the fork head family of DNA-binding proteins. When fused to the DNA-binding domain of Gal4p, residues 139 to 511 of Hcm1p can act as a strong activator of transcription. However, overexpression of HCM1 does not affect the expression of calmodulin. Furthermore, Hcm1p does not bind to calmodulin in a gel overlay assay. Thus, overexpression of HCM1 enhances calmodulin function by an apparently indirect mechanism.