Differential targeting and signalling of voltage‐gated T‐type Ca<sub>v</sub>3.2 and L‐type Ca<sub>v</sub>1.2 channels to ryanodine receptors in mesenteric arteries

Fan, Gang; Kaßmann, Mario; Hashad, Ahmed M.; Welsh, Donald G.; Gollasch, Maik

doi:10.1113/jp276923

Cited by 16 publications

(44 citation statements)

References 52 publications

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“…The T‐type Ca v 3.2 channel blocker Ni 2+ decreased Ca 2+ spark frequency and fraction of cells with sparks in young VSMCs (see also (Fan et al, 2018; Hashad et al, 2018)), while it failed to decrease Ca 2+ spark events in old VSMCs (Figure 1). These data suggest that Ca v 3.2 channels contribute to generation of Ca 2+ sparks in young but not in old VSMC.…”

Section: Resultsmentioning

confidence: 74%

“…The data also show that SR Ca 2+ load is controlled by SERCA (Nelson et al, 1995). We next studied how Ca v 1.2 channel ablation and reduced [Ca 2+ ] SR load affect the Ca V 3.2‐RyR axis, that is, direct coupling between Ca V 3.2 channels and RyRs to generate Ca 2+ sparks (Fan et al, 2018; Hashad et al, 2018; Löhn et al, 2000). Consistent with our previous results (Essin et al, 2007), we found that [Ca 2+ ] SR was lower in Ca v 1.2 −/− (SMAKO) VSMCs compared to Ca v 1.2 +/+ control cells.…”

Section: Resultsmentioning

confidence: 99%

“…STOCs were measured in presence of Cd 2+ and/or Ni 2+ after depletion of the [Ca 2+ ] SR by thapsigargin. The holding potential was set to −40 mV, a physiological membrane potential that should drive T‐type Ca 2+ channel‐mediated Ca 2+ sparks, enabling the activation of BK Ca channels (Fan et al, 2018; Harraz et al, 2014; Hashad et al, 2018). Figure shows that thapsigargin removed ~60% of STOCs in VSMCs (Figure e–g).…”

Section: Resultsmentioning

confidence: 99%

“…As a result, Ca 2+ spark–BK Ca channel coupling induces vascular smooth muscle cell (VSMCs) hyperpolarization and attenuation of arterial constriction (Brenner et al, 2000; Löhn et al, 2001; Pérez, Bonev, Patlak, & Nelson, 1999). In previous studies, we demonstrated that L‐type Ca V 1.2 channels play the predominant role (~75%) in Ca 2+ sparks generation in mesenteric arterial VSMCs, and T‐type Ca V 3.2 channels, localized in caveolae, represent an additional source (~25%) (Fan, Kaßmann, Hashad, Welsh, & Gollasch, 2018; Hashad et al, 2018). In the latter pathway, caveolae position Ca V 3.2 channels sufficiently close to RyRs (<40 nm) of the sarcoplasmic reticulum (SR) for extracellular Ca 2+ influx to trigger Ca 2+ sparks and large‐conductance Ca 2+ ‐activated K + channel feedback in vascular smooth muscle (Fan et al, 2018; Harraz et al, 2014; Hashad et al, 2018; Löhn et al, 2000).…”

Section: Introductionmentioning

confidence: 92%

“…In previous studies, we demonstrated that L‐type Ca V 1.2 channels play the predominant role (~75%) in Ca 2+ sparks generation in mesenteric arterial VSMCs, and T‐type Ca V 3.2 channels, localized in caveolae, represent an additional source (~25%) (Fan, Kaßmann, Hashad, Welsh, & Gollasch, 2018; Hashad et al, 2018). In the latter pathway, caveolae position Ca V 3.2 channels sufficiently close to RyRs (<40 nm) of the sarcoplasmic reticulum (SR) for extracellular Ca 2+ influx to trigger Ca 2+ sparks and large‐conductance Ca 2+ ‐activated K + channel feedback in vascular smooth muscle (Fan et al, 2018; Harraz et al, 2014; Hashad et al, 2018; Löhn et al, 2000). These conclusions were mainly derived from experiments using Ca V 3.2 channel ( Cacna1h −/− ) and caveolin‐1 ( Cav1 −/− ) knockout mice.…”

Section: Introductionmentioning

confidence: 92%

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Age attenuates the T‐type Ca_V3.2‐RyR axis in vascular smooth muscle

et al. 2020

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Caveolae position Ca V 3.2 (T-type Ca 2+ channel encoded by the α-3.2 subunit) sufficiently close to RyR (ryanodine receptors) for extracellular Ca 2+ influx to trigger Ca 2+ sparks and large-conductance Ca 2+ -activated K + channel feedback in vascular smooth muscle. We hypothesize that this mechanism of Ca 2+ spark generation is affected by age. Using smooth muscle cells (VSMCs) from mouse mesenteric arteries, we found that both Ca v 3.2 channel inhibition by Ni 2+ (50 µM) and caveolae disruption by methyl-ß-cyclodextrin or genetic abolition of Eps15 homology domain-containing protein (EHD2) inhibited Ca 2+ sparks in cells from young (4 months) but not old (12 months) mice. In accordance, expression of Ca v 3.2 channel was higher in mesenteric arteries from young than old mice. Similar effects were observed for caveolae density. Using SMAKO Ca v 1.2 −/− mice, caffeine (RyR activator) and thapsigargin (Ca 2+ transport ATPase inhibitor), we found that sufficient SR Ca 2+ load is a prerequisite for the Ca V 3.2-RyR axis to generate Ca 2+ sparks. We identified a fraction of Ca 2+ sparks in aged VSMCs, which is sensitive to the TRP channel blocker Gd 3+ (100 µM), but insensitive to Ca V 1.2 and Ca V 3.2 channel blockade. Our data demonstrate that the VSMC Ca V 3.2-RyR axis is down-regulated by aging. This defective Ca V 3.2-RyR coupling is counterbalanced by a Gd 3+ sensitive Ca 2+ pathway providing compensatory Ca 2+ influx for triggering Ca 2+ sparks in aged VSMCs. K E Y W O R D Saging, calcium sparks, caveolae, ryanodine receptors, T-type calcium channels, vascular smooth muscle

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Section: Resultsmentioning

confidence: 74%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 92%

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Age attenuates the T‐type Ca_V3.2‐RyR axis in vascular smooth muscle

et al. 2020

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An inactivating human TRPC6 channel mutation without focal segmental glomerulosclerosis

Batool,

Hariharan,

et al. 2023

Cell. Mol. Life Sci.

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Transient receptor potential cation channel-6 (TRPC6) gene mutations cause familial focal segmental glomerulosclerosis (FSGS), which is inherited as an autosomal dominant disease. In patients with TRPC6-related FSGS, all mutations map to the N- or C-terminal TRPC6 protein domains. Thus far, the majority of TRPC6 mutations are missense resulting in increased or decreased calcium influx; however, the fundamental molecular mechanisms causing cell injury and kidney pathology are unclear. We report a novel heterozygous TRPC6 mutation (V691Kfs*) in a large kindred with no signs of FSGS despite a largely truncated TRPC6 protein. We studied the molecular effects of V691Kfs* TRPC6 mutant using the tridimensional cryo-EM structure of the tetrameric TRPC6 protein. The results indicated that V691 is localized at the pore-forming transmembrane region affecting the ion conduction pathway, and predicted that V691Kfs* causes closure of the ion-conducting pathway leading to channel inactivation. We assessed the impact of V691Kfs* and two previously reported TRPC6 disease mutants (P112Q and G757D) on calcium influx in cells. Our data show that the V691Kfs* fully inactivated the TRCP6 channel-specific calcium influx consistent with a complete loss-of-function phenotype. Furthermore, the V691Kfs* truncation exerted a dominant negative effect on the full-length TRPC6 proteins. In conclusion, the V691Kfs* non-functional truncated TRPC6 is not sufficient to cause FSGS. Our data corroborate recently characterized TRPC6 loss-of-function and gain-of-function mutants suggesting that one defective TRPC6 gene copy is not sufficient to cause FSGS. We underscore the importance of increased rather than reduced calcium influx through TRPC6 for podocyte cell death.

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