Kaiqian Wang scite author profile

Key points Mutations in the calmodulin protein (CaM) are associated with arrhythmia syndromes. This study focuses on understanding the structural characteristics of CaM disease mutants and their interactions with the voltage‐gated calcium channel CaV1.2. Arrhythmia mutations in CaM can lead to loss of Ca2+ binding, uncoupling of Ca2+ binding cooperativity, misfolding of the EF‐hands and altered affinity for the calcium channel. These results help us to understand how different CaM mutants have distinct effects on structure and interactions with protein targets to cause disease. Abstract Calmodulinopathies are life‐threatening arrhythmia syndromes that arise from mutations in calmodulin (CaM), a calcium sensing protein whose sequence is completely conserved across all vertebrates. These mutations have been shown to interfere with the function of cardiac ion channels, including the voltage‐gated Ca2+ channel CaV1.2 and the ryanodine receptor (RyR2), in a mutation‐specific manner. The ability of different CaM disease mutations to discriminate between these channels has been enigmatic. We present crystal structures of several C‐terminal lobe mutants and an N‐terminal lobe mutant in complex with the CaV1.2 IQ domain, in conjunction with binding assays and complementary structural biology techniques. One mutation (D130G) causes a pathological conformation, with complete separation of EF‐hands within the C‐lobe and loss of Ca2+ binding in EF‐hand 4. Another variant (Q136P) has severely reduced affinity for the IQ domain, and shows changes in the CD spectra under Ca2+‐saturating conditions when unbound to the IQ domain. Ca2+ binding to a pair of EF‐hands normally proceeds with very high cooperativity, but we found that N98S CaM can adopt different conformations with either one or two Ca2+ ions bound to the C‐lobe, possibly disrupting the cooperativity. An N‐lobe variant (N54I), which causes severe stress‐induced arrhythmia, does not show any major changes in complex with the IQ domain, providing a structural basis for why this mutant does not affect function of CaV1.2. These findings show that different CaM mutants have distinct effects on both the CaM structure and interactions with protein targets, and act via distinct pathological mechanisms to cause disease.

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A Role for the Budding Yeast Separase, Esp1, in Ty1 Element Retrotransposition

Cheung

Manhas

et al. 2015

PLoS Genet

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Separase/Esp1 is a protease required at the onset of anaphase to cleave cohesin and thereby enable sister chromatid separation. Esp1 also promotes release of the Cdc14 phosphatase from the nucleolus to enable mitotic exit. To uncover other potential roles for separase, we performed two complementary genome-wide genetic interaction screens with a strain carrying the budding yeast esp1-1 separase mutation. We identified 161 genes that when mutated aggravate esp1-1 growth and 44 genes that upon increased dosage are detrimental to esp1-1 viability. In addition to the expected cell cycle and sister chromatid segregation genes that were identified, 24% of the genes identified in the esp1-1 genetic screens have a role in Ty1 element retrotransposition. Retrotransposons, like retroviruses, replicate through reverse transcription of an mRNA intermediate and the resultant cDNA product is integrated into the genome by a conserved transposon or retrovirus encoded integrase protein. We purified Esp1 from yeast and identified an interaction between Esp1 and Ty1 integrase using mass spectrometry that was subsequently confirmed by co-immunoprecipitation analysis. Ty1 transposon mobility and insertion upstream of the SUF16 tRNA gene are both reduced in an esp1-1 strain but increased in cohesin mutant strains. Securin/Pds1, which is required for efficient localization of Esp1 to the nucleus, is also required for efficient Ty1 transposition. We propose that Esp1 serves two roles to mediate Ty1 transposition – one to remove cohesin and the second to target Ty1-IN to chromatin.

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Arrhythmogenic Calmodulin Mutations Can Disrupt the Globular Structure and Uncouple Ca2+ Binding Cooperativity

Wang

Brohus

Holt

et al. 2020

Biophysical Journal

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Characterization of Arrhythmia Mutations in Calmodulin and their Interactions with the Voltage-Gated Calcium Channel

Wang

Holt

et al. 2019

Biophysical Journal

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Structural insights into calmodulin regulation and dysregulation of the L-type voltage-gated calcium channel

Wang¹

2021

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Kaiqian Wang

Arrhythmia mutations in calmodulin can disrupt cooperativity of Ca²⁺ binding and cause misfolding

A Role for the Budding Yeast Separase, Esp1, in Ty1 Element Retrotransposition

Arrhythmogenic Calmodulin Mutations Can Disrupt the Globular Structure and Uncouple Ca2+ Binding Cooperativity

Characterization of Arrhythmia Mutations in Calmodulin and their Interactions with the Voltage-Gated Calcium Channel

Structural insights into calmodulin regulation and dysregulation of the L-type voltage-gated calcium channel

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Kaiqian Wang

Arrhythmia mutations in calmodulin can disrupt cooperativity of Ca2+ binding and cause misfolding

A Role for the Budding Yeast Separase, Esp1, in Ty1 Element Retrotransposition

Arrhythmogenic Calmodulin Mutations Can Disrupt the Globular Structure and Uncouple Ca2+ Binding Cooperativity

Characterization of Arrhythmia Mutations in Calmodulin and their Interactions with the Voltage-Gated Calcium Channel

Structural insights into calmodulin regulation and dysregulation of the L-type voltage-gated calcium channel

Contact Info

Product

Resources

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Arrhythmia mutations in calmodulin can disrupt cooperativity of Ca²⁺ binding and cause misfolding