The RyR1 P3528S Substitution Alters Mouse Skeletal Muscle Contractile Properties and RyR1 Ion Channel Gating.

The recessive Ryanodine Receptor Type 1 (RyR1) P3527S mutation causes mild muscle weakness in patients and increased resting cytoplasmic [Ca2+] in transformed lymphoblastoid cells. In the present study, we explored the cellular/molecular effects of this mutation in a mouse model of the mutation (RyR1 P3528S). The results were obtained from 73 wild type (WT/WT), 82 heterozygous (WT/MUT) and 66 homozygous (MUT/MUT) mice with different numbers of observations in individual data sets depending on the experimental protocol. The results showed that WT/MUT and MUT/MUT mouse strength was less than that of WT/WT mice, but there was no difference between genotypes in appearance, weight, mobility or longevity. The force frequency response of extensor digitorum longus (EDL) and soleus (SOL) muscles from WT/MUT and MUT/MUT mice was shifter to higher frequencies. The specific force of EDL muscles was reduced and Ca2+ activation of skinned fibres shifted to a lower [Ca2+], with an increase in type I fibres in EDL muscles and in mixed type I/II fibres in SOL muscles. The relative activity of RyR1 channels exposed to 1 µM cytoplasmic Ca2+ was greater in WT/MUT and MUT/MUT mice than in WT/WT mice. We suggest the altered RyR1 activity due to the P2328S substitution could increase resting [Ca2+] in muscle fibres, leading to changes in fibre type and contractile properties.

The Anthracycline Metabolite Doxorubicinol Abolishes RyR2 Sensitivity to Physiological Changes in Luminal Ca2+ through an Interaction with Calsequestrin.

The chemotherapeutic anthracycline metabolite doxorubicinol (doxOL) has been shown to interact with and disrupt the function of the cardiac ryanodine receptor Ca2+ release channel (RyR2) in the sarcoplasmic reticulum (SR) membrane and the SR Ca2+ binding protein calsequestrin 2 (CSQ2). Normal increases in RyR2 activity in response to increasing diastolic SR [Ca2+] are influenced by CSQ2 and are disrupted in arrhythmic conditions. Therefore, we explored the action of doxOL on RyR2's response to changes in luminal [Ca2+] seen during diastole. DoxOL abolished the increase in RyR2 activity when luminal Ca2+ was increased from 0.1 to 1.5 mM. This was not due to RyR2 oxidation, but depended entirely on the presence of CSQ2 in the RyR2 complex. DoxOL binding to CSQ2 reduced both the Ca2+ binding capacity of CSQ2 (by 48%-58%) and its aggregation, and lowered CSQ2 association with the RyR2 complex by 67%-77%. Each of these effects on CSQ2, and the lost RyR2 response to changes in luminal [Ca2+], was duplicated by exposing native RyR2 channels to subphysiologic (≤1.0 µM) luminal [Ca2+]. We suggest that doxOL and low luminal Ca2+ both disrupt the CSQ2 polymer, and that the association of the monomeric protein with the RyR2 complex shifts the increase in RyR2 activity with increasing luminal [Ca2+] away from the physiologic [Ca2+] range. Subsequently, these changes may render the channel insensitive to changes of luminal Ca2+ that occur through the cardiac cycle. The altered interactions between CSQ2, triadin, and/or junctin and RyR2 may produce an arrhythmogenic substrate in anthracycline-induced cardiotoxicity.

A new cytoplasmic interaction between junctin and ryanodine receptor Ca2+ release channels.

Junctin, a non-catalytic splice variant encoded by the aspartate-ß-hydroxylase (Asph) gene, is inserted into the membrane of the sarcoplasmic reticulum (SR) Ca(2+) store where it modifies Ca(2+) signalling in the heart and skeletal muscle through its regulation of ryanodine receptor (RyR) Ca(2+) release channels. Junctin is required for normal muscle function as its knockout leads to abnormal Ca(2+) signalling, muscle dysfunction and cardiac arrhythmia. However, the nature of the molecular interaction between junctin and RyRs is largely unknown and was assumed to occur only in the SR lumen. We find that there is substantial binding of RyRs to full junctin, and the junctin luminal and, unexpectedly, cytoplasmic domains. Binding of these different junctin domains had distinct effects on RyR1 and RyR2 activity: full junctin in the luminal solution increased RyR channel activity by ∼threefold, the C-terminal luminal interaction inhibited RyR channel activity by ∼50%, and the N-terminal cytoplasmic binding produced an ∼fivefold increase in RyR activity. The cytoplasmic interaction between junctin and RyR is required for luminal binding to replicate the influence of full junctin on RyR1 and RyR2 activity. The C-terminal domain of junctin binds to residues including the S1-S2 linker of RyR1 and N-terminal domain of junctin binds between RyR1 residues 1078 and 2156.

Cardiac ryanodine receptor activation by a high Ca²âº store load is reversed in a reducing cytoplasmic redox environment.

Here, we report the impact of redox potential on isolated cardiac ryanodine receptor (RyR2) channel activity and its response to physiological changes in luminal [Ca(2+)]. Basal leak from the sarcoplasmic reticulum is required for normal Ca(2+) handling, but excess diastolic Ca(2+) leak attributed to oxidative stress is thought to lower the threshold of RyR2 for spontaneous sarcoplasmic reticulum Ca(2+) release, thus inducing arrhythmia in pathological situations. Therefore, we examined the RyR2 response to luminal [Ca(2+)] under reducing or oxidising cytoplasmic redox conditions. Unexpectedly, as luminal [Ca(2+)] increased from 0.1 to 1.5 mM, RyR2 activity declined when pretreated with cytoplasmic 1 mM DTT or buffered with GSH∶GSSG to a normal reduced cytoplasmic redox potential (-220 mV). Conversely, with 20 µM cytoplasmic 4,4'-DTDP or buffering of the redox potential to an oxidising value (-180 mV), RyR2 activity increased with increasing luminal [Ca(2+)]. The luminal redox potential was constant at -180 mV in each case. These responses to luminal [Ca(2+)] were maintained with cytoplasmic 2 mM Na2ATP or 5 mM MgATP (1 mM free Mg(2+)). Overall, the results suggest that the redox potential in the RyR2 junctional microdomain is normally more oxidised than that of the bulk cytoplasm.

A bivalent remipede toxin promotes calcium release via ryanodine receptor activation.

Multivalent ligands of ion channels have proven to be both very rare and highly valuable in yielding unique insights into channel structure and pharmacology. Here, we describe a bivalent peptide from the venom of Xibalbanus tulumensis, a troglobitic arthropod from the enigmatic class Remipedia, that causes persistent calcium release by activation of ion channels involved in muscle contraction. The high-resolution solution structure of φ-Xibalbin3-Xt3a reveals a tandem repeat arrangement of inhibitor-cysteine knot (ICK) domains previously only found in spider venoms. The individual repeats of Xt3a share sequence similarity with a family of scorpion toxins that target ryanodine receptors (RyR). Single-channel electrophysiology and quantification of released Ca2+ stores within skinned muscle fibers confirm Xt3a as a bivalent RyR modulator. Our results reveal convergent evolution of RyR targeting toxins in remipede and scorpion venoms, while the tandem-ICK repeat architecture is an evolutionary innovation that is convergent with toxins from spider venoms.

Mechanisms of palmitate-induced cell death in human osteoblasts.

Lipotoxicity is an overload of lipids in non-adipose tissues that affects function and induces cell death. Lipotoxicity has been demonstrated in bone cells in vitro using osteoblasts and adipocytes in coculture. In this condition, lipotoxicity was induced by high levels of saturated fatty acids (mostly palmitate) secreted by cultured adipocytes acting in a paracrine manner. In the present study, we aimed to identify the underlying mechanisms of lipotoxicity in human osteoblasts. Palmitate induced autophagy in cultured osteoblasts, which was preceded by the activation of autophagosomes that surround palmitate droplets. Palmitate also induced apoptosis though the activation of the Fas/Jun kinase (JNK) apoptotic pathway. In addition, osteoblasts could be protected from lipotoxicity by inhibiting autophagy with the phosphoinositide kinase inhibitor 3-methyladenine or by inhibiting apoptosis with the JNK inhibitor SP600125. In summary, we have identified two major molecular mechanisms of lipotoxicity in osteoblasts and in doing so we have identified a new potential therapeutic approach to prevent osteoblast dysfunction and death, which are common features of age-related bone loss and osteoporosis.