The location of InsP3 receptors in Purkinje cells of murine cerebellum does not supports a direct interaction in the transfer of calcium ions between ER and mitochondria

The inositol-3-phosphate receptors (IP3Rs) of cerebellar Purkinje cells are located in abundant, large stacks of endoplasmic reticulum (ER) cisternae. Using thin section electron microscopy, we identify very frequent associations of the ER stacks with mitochondria. The associations have two components: a single, close ER-mitochondria contact on one side to the stack, and multiple layers of ER cisternae decorated by IP3Rs receptors on the side away from the mitochondria. Due to their location in the stacks, IP3Rs are never in contact with the mitochondria, although they are in their vicinity. We conclude that transfer of Ca2+ between ER and mitochondria is not directly mediated by IP3Rs, but is based on mitochondrial Ca2+ uptake from the local cytoplasmic spikes during IP3Rs’ activity.

O-039 Mitochondrial ATP generation in mammalian eggs and Ca2+ signaling

text In metaphase II arrested mammalian oocytes (eggs) and cleavage stage embryos the mitochondria are responsible for nearly all ATP production because glycolysis is inactivated. Luciferase assays show that ATP levels in eggs are strictly dependent upon pyruvate and fatty acid oxidation. The level of ATP in eggs appears to be maximal in conventional medium because the addition of extra mitochondrial substrates to eggs does not increase cytosolic ATP. The only clear elevation of ATP is seen at fertilization and is associated with sperm induced Ca2+ oscillations. Our recent findings suggest that the level of ATP modulates events at fertilization. At fertilization, the egg is activated by sperm derived PLCzeta which triggers a series of Ca2+ oscillations, with each Ca2+ release event causes by inositol trisphosphate (InsP3). Previous studies have shown that mouse eggs are more sensitive to PLCzeta, and generate higher frequency Ca2+ oscillations, than human eggs. Mouse eggs also generate Ca2+ oscillations and activate in response to Sr2+ that directly stimulates InsP3 receptors. In contrast, human eggs that contain the same type of InsP3 receptors do not generate Ca2+ oscillations in response to Sr2+. The difference in sensitivity of Ca2+ release between species can be explained by the fact that mouse eggs are about ten times more sensitive to InsP3 than human eggs. The reason for this difference appears to be due to ATP. The ATP level in unfertilized mouse eggs is about twice that in human eggs. Furthermore, the ability of mouse eggs to Sr2+ medium can be abolished by removing the mitochondrial substrate pyruvate, which reduces the ATP level. Adding back pyruvate to such eggs restores ATP levels promotes Sr2+ induced Ca2+ levels in mouse eggs. These data suggest that the level of ATP, possibly as ATP4-, modulates the sensitivity of the InsP3 receptor and the ability of eggs to generate Ca2+ oscillations. The level of cytosolic ATP may represent a significant ‘egg factor’ in determining the success of fertilization in humans. Enhancing mitochondrial ATP production could be useful in improving activation and embryo development after fertilization, or after artificial egg activation. References: Dumollard et al. (2009) Seminar in Cell and Developmental Biology 20, 346-353 Campbell and Swann (2006) Developmental Biology 298, 225-233 Storey et al. (2021) Molecular Human Reproduction 27, gaaa086

Ca2+ release via InsP3Rs enhances RyR recruitment during Ca2+ transients by increasing dyadic [Ca2+] in cardiomyocytes

Excitation-contraction coupling (ECC) relies on temporally synchronized sarcoplasmic reticulum (SR) Ca2+ release via ryanodine receptors (RyRs) at dyadic membrane compartments. Neurohormones, such as endothelin-1 (ET-1), that act via Gαq-coupled G protein-coupled receptors (GPCRs) modulate Ca2+ dynamics during ECC and induce SR Ca2+ release events involving Ca2+ release via inositol 1,4,5-trisphosphate (InsP3) receptors (InsP3Rs). How the relatively modest Ca2+ release via InsP3Rs elicits this action is not resolved. Here we investigated whether the actions of InsP3Rs on Ca2+ handling during ECC were mediated by a direct influence on dyadic Ca2+ levels and whether this mechanism contributes to the effects of ET-1. Using a dyad-targeted genetically encoded Ca2+ reporter, we found that InsP3R activation augmented dyadic Ca2+ fluxes during Ca2+ transients and increased Ca2+ sparks. RyRs were required for these effects. These data provide the first direct demonstration of GPCR/InsP3 effects on dyadic Ca2+ and support the notion that Ca2+ release via InsP3Rs influences Ca2+ transients during ECC by facilitating the activation and recruitment of proximal RyRs. We propose that this mechanism contributes to neurohormonal modulation of cardiac function.

Cytosolic [Ca2+] regulation of InsP3-evoked puffs

InsP3-mediated puffs are fundamental building blocks of cellular Ca2+ signalling, and arise through the concerted opening of clustered InsP3Rs (InsP3 receptors) co-ordinated via Ca2+-induced Ca2+ release. Although the Ca2+ dependency of InsP3Rs has been extensively studied at the single channel level, little is known as to how changes in basal cytosolic [Ca2+] would alter the dynamics of InsP3-evoked Ca2+ signals in intact cells. To explore this question, we expressed Ca2+-permeable channels (nicotinic acetylcholine receptors) in the plasma membrane of voltage-clamped Xenopus oocytes to regulate cytosolic [Ca2+] by changing the electrochemical gradient for extracellular Ca2+ entry, and imaged Ca2+ liberation evoked by photolysis of caged InsP3. Elevation of basal cytosolic [Ca2+] strongly increased the amplitude and shortened the latency of global Ca2+ waves. In oocytes loaded with EGTA to localize Ca2+ signals, the number of sites at which puffs were observed and the frequency and latency of puffs were strongly dependent on cytosolic [Ca2+], whereas puff amplitudes were only weakly affected. The results of the present study indicate that basal cytosolic [Ca2+] strongly affects the triggering of puffs, but has less of an effect on puffs once they have been initiated.

Abstract 298: CaMKII-Mediated Phosphorylation of InsP3R2 Activates Hypertrophic Gene Transcription

Inositol 1,4,5-triphosphosphate receptors are a family of intracellular Ca2+ channels, modulated by the ligands InsP3 and Ca2+ in response to an array of neuro-hormonal stimuli to release Ca2+ from internal stores. In cardiac myocytes, the InsP3R2, CaMKII and CaM are components of a macromolecular signalplex. However, modulation of InsP3R’s Ca2+ channel and the underlying mechanism(s) that converge and integrate nuclear hypertrophic signals to initiate transcription is not fully established. Here, we delineate the mechanistic regulation of nuclear InsP3R2’s bidirectional Ca2+ channel activity and its effect on the activation of nuclear hypertrophic signaling. We show that, endothelin-1 (ET1) stimulates elevated InsP3 induced Ca2+ release into the nucleus from perinuclear InsP3 receptors. This elevated nuclear Ca2+ release is due to CaMKIIδ mediated phosphorylation of cytoplasmic oriented InsP3R2 inhibiting Ca2+ release to the cytoplasm. This increase in nuclear Ca2+ activates Ca2+ sensitive transctiption factors thereby activating gene expression. The elevated nuclear Ca2+ and gene expression can be attenuated by CaMKII inhibitor KN-93 and InsP3R antagonist 2-ABP. We also show that, exogenous InsP3R2 was phosphorylated by both cytoplasmic (CaMKIIδC) and nuclear (CaMKIIδB) isoforms of CaMKIIδ. Intriguingly, CaMKIIδC phosphorylates endogenous InsP3R2 in cardiomyocytes more efficiently than CaMKIIδB and not by its kinase-dead derivatives. In conclusion, our findings demonstrate that, InsP3R2 mediated Ca2+ signaling integrates and vectors the GPCR activated hypertrophic signals to the nucleus triggering gene transcription underlying cardiac hypertrophy.

InsP3 receptors and Orai channels in pancreatic acinar cells: co-localization and its consequences

Orai1 proteins have been recently identified as subunits of SOCE (store-operated Ca2+ entry) channels. In primary isolated PACs (pancreatic acinar cells), Orai1 showed remarkable co-localization and co-immunoprecipitation with all three subtypes of IP3Rs (InsP3 receptors). The co-localization between Orai1 and IP3Rs was restricted to the apical part of PACs. Neither co-localization nor co-immunoprecipitation was affected by Ca2+ store depletion. Importantly we also characterized Orai1 in basal and lateral membranes of PACs. The basal and lateral membranes of PACs have been shown previously to accumulate STIM1 (stromal interaction molecule 1) puncta as a result of Ca2+ store depletion. We therefore conclude that these polarized secretory cells contain two pools of Orai1: an apical pool that interacts with IP3Rs and a basolateral pool that interacts with STIM1 following the Ca2+ store depletion. Experiments on IP3R knockout animals demonstrated that the apical Orai1 localization does not require IP3Rs and that IP3Rs are not necessary for the activation of SOCE. However, the InsP3-releasing secretagogue ACh (acetylcholine) produced a negative modulatory effect on SOCE, suggesting that activated IP3Rs could have an inhibitory effect on this Ca2+ entry mechanism.