The relative position of RyR feet and DHPR tetrads in skeletal muscle

In skeletal muscle, L-type calcium channels (or dihydropyridine receptors, DHPRs) are coupled functionally to the calcium release channels of the sarcoplasmic reticulum (or ryanodine receptors, RyRs) within specialized structures called calcium release units (CRUs). The functional linkage requires a specific positioning of four DHPRs in correspondence of the four identical subunits of a single RyR type 1. Four DHPRs linked to the four binding sites of the RyR1 cytoplasmic domain (or foot), define the corners of a square, constituting a tetrad. RyRs self-assemble into ordered arrays and by associating with them, DHPRs also assemble into ordered arrays. The approximate location of the four DHPRs relative to the four identical subunits of a RyR-foot can be predicted on the basis of the relative position of tetrads and feet within the arrays. However, until recently one vital piece of information has been lacking: the orientation of the two arrays relative to one another. In this work we have defined the relative orientation of the RyR and DHPR arrays by directly superimposing replicas of rotary shadowed images of rows of feet, obtained from isolated SR vesicles, and replicas of tetrad arrays obtained by freeze-fracture. If the orientation for the two sets of images is carefully maintained, the superimposition provides specific constraints on the DHPR-RyR relative position.     

Acidic intracellular Ca stores and caveolae in Ca signaling and diabetes

Acidic Ca²⁺ stores, particularly lysosomes, are newly discovered players in the well-orchestrated arena of Ca²⁺ signaling and we are at the verge of understanding how lysosomes accumulate Ca²⁺ and how they release it in response to different chemical, such as NAADP, and physical signals. Additionally, it is now clear that lysosomes play a key role in autophagy, a process that allows cells to recycle components or to eliminate damaged structures to ensure cellular well-being. Moreover, lysosomes are being unraveled as hubs that coordinate both anabolism via insulin signaling and catabolism via AMPK. These acidic vesicles have close contact with the ER and there is a bidirectional movement of information between these two organelles that exquisitely regulates cell survival. Lysosomes also connect with plasma membrane where caveolae are located as specialized regions involved in Ca²⁺ and insulin signaling. Alterations of all these signaling pathways are at the core of insulin resistance and diabetes.     

Calcium-dependent facilitation and graded deactivation of store-operated calcium entry in fetal skeletal muscle

Activation of store-operated Ca²⁺ entry (SOCE) into the cytoplasm requires retrograde signaling from the intracellular Ca²⁺ release machinery, a process that involves an intimate interaction between protein components on the intracellular and cell surface membranes. The cellular machinery that governs the Ca²⁺ movement in muscle cells is developmentally regulated, reflecting maturation of the junctional membrane structure as well as coordinated expression of related Ca²⁺ signaling molecules. Here we demonstrate the existence of SOCE in freshly isolated skeletal muscle cells obtained from embryonic days 15 and 16 of the mouse embryo, a critical stage of muscle development. SOCE in the fetal muscle deactivates incrementally with the uptake of Ca²⁺ into the sarcoplasmic reticulum (SR). A novel Ca²⁺-dependent facilitation of SOCE is observed in cells transiently exposed to high cytosolic Ca²⁺. Our data suggest that cytosolic Ca²⁺ can facilitate SOCE whereas SR luminal Ca²⁺ can deactivate SOCE in the fetal skeletal muscle. This cooperative mechanism of SOCE regulation by Ca²⁺ ions not only enables tight control of SOCE by the SR membrane, but also provides an efficient mechanism of extracellular Ca²⁺ entry in response to physiological demand. Such Ca²⁺ signaling mechanism would likely contribute to contraction and development of the fetal skeletal muscle.     

Regulation of cardiac sarcoplasmic reticulum Ca release by luminal [Ca] and altered gating assessed with a mathematical model

Cardiac excitation-contraction coupling is initialized by the release of Ca from the sarcoplasmic reticulum (SR) in response to a sudden increase in local cytosolic [Ca] ([Ca]i) within the junctional cleft. We have tested the hypothesis that functional ryanodine receptor (RyR) regulation plays a major role in the regulation of myocyte Ca. A mathematical model with unique characteristics was used to simulate Ca homeostasis. Specifically, the model was designed to accurately represent the SR [Ca]-dependence of release from a variety of experimentally produced data sets. The simulated data for altered RyR Ca sensitivity demonstrated a regulatory feedback loop that resulted in the same release at lower [Ca]SR. This suggests that the primary role of myocyte RyR regulation may be to decrease SR [Ca] without decreasing the size of the [Ca]i transient. The model results suggest that this action moderates the increased SR [Ca] observed with adrenergic stimulation and may keep the [Ca]SR below the threshold for delayed afterdepolarizations and arrhythmia. However, increased Ca affinity of the RyR increased the probability of delayed afterdepolarizations when heart failure was simulated. We conclude that RyR regulation may play a role in preventing arrhythmias in healthy myocytes but that the same regulation may have the opposite effect in chronic heart failure.     

Post-natal heart adaptation in a knock-in mouse model of calsequestrin 2-linked recessive catecholaminergic polymorphic ventricular tachycardia

Cardiac calsequestrin (CASQ2) contributes to intracellular Ca²⁺ homeostasis by virtue of its low-affinity/high-capacity Ca²⁺ binding properties, maintains sarcoplasmic reticulum (SR) architecture and regulates excitation–contraction coupling, especially or exclusively upon β-adrenergic stimulation. Catecholaminergic polymorphic ventricular tachycardia (CPVT) is an inherited arrhythmogenic disease associated with cardiac arrest in children or young adults. Recessive CPVT variants are due to mutations in the CASQ2 gene. Molecular and ultra-structural properties were studied in hearts of CASQ2^R33Q/R33Q and of CASQ2^−/− mice from post-natal day 2 to week 8. The drastic reduction of CASQ2-R33Q is an early developmental event and is accompanied by down-regulation of triadin and junctin, and morphological changes of jSR and of SR-transverse-tubule junctions. Although endoplasmic reticulum stress is activated, no signs of either apoptosis or autophagy are detected. The other model of recessive CPVT, the CASQ2^−/− mouse, does not display the same adaptive pattern. Expression of CASQ2-R33Q influences molecular and ultra-structural heart development; post-natal, adaptive changes appear capable of ensuring until adulthood a new pathophysiological equilibrium.