Muscle calcium stress cleaves junctophilin1, unleashing a gene regulatory program predicted to correct glucose dysregulation.

Calcium ion movements between cellular stores and the cytosol govern muscle contraction, the most energy-consuming function in mammals, which confers skeletal myofibers a pivotal role in glycemia regulation. Chronic myoplasmic calcium elevation ("calcium stress"), found in malignant hyperthermia-susceptible (MHS) patients and multiple myopathies, has been suggested to underlie the progression from hyperglycemia to insulin resistance. What drives such progression remains elusive. We find that muscle cells derived from MHS patients have increased content of an activated fragment of GSK3ß - a specialized kinase that inhibits glycogen synthase, impairing glucose utilization and delineating a path to hyperglycemia. We also find decreased content of junctophilin1, an essential structural protein that colocalizes in the couplon with the voltage-sensing CaV1.1, the calcium channel RyR1 and calpain1, accompanied by an increase in a 44 kDa junctophilin1 fragment (JPh44) that moves into nuclei. We trace these changes to activated proteolysis by calpain1, secondary to increased myoplasmic calcium. We demonstrate that a JPh44-like construct induces transcriptional changes predictive of increased glucose utilization in myoblasts, including less transcription and translation of GSK3ß and decreased transcription of proteins that reduce utilization of glucose. These effects reveal a stress-adaptive response, mediated by the novel regulator of transcription JPh44.

Intracellular calcium leak lowers glucose storage in human muscle, promoting hyperglycemia and diabetes.

Most glucose is processed in muscle, for energy or glycogen stores. Malignant Hyperthermia Susceptibility (MHS) exemplifies muscle conditions that increase [Ca2+]cytosol. 42% of MHS patients have hyperglycemia. We show that phosphorylated glycogen phosphorylase (GPa), glycogen synthase (GSa) - respectively activated and inactivated by phosphorylation - and their Ca2+-dependent kinase (PhK), are elevated in microsomal extracts from MHS patients' muscle. Glycogen and glucose transporter GLUT4 are decreased. [Ca2+]cytosol, increased to MHS levels, promoted GP phosphorylation. Imaging at ~100 nm resolution located GPa at sarcoplasmic reticulum (SR) junctional cisternae, and apo-GP at Z disk. MHS muscle therefore has a wide-ranging alteration in glucose metabolism: high [Ca2+]cytosol activates PhK, which inhibits GS, activates GP and moves it toward the SR, favoring glycogenolysis. The alterations probably cause these patients' hyperglycemia. For basic studies, MHS emerges as a variable stressor, which forces glucose pathways from the normal to the diseased range, thereby exposing novel metabolic links.

Animals and humans move by contracting the skeletal muscles attached to their bones. These muscles take up a type of sugar called glucose from food and use it to fuel contractions or store it for later in the form of glycogen. If muscles fail to use glucose it can lead to excessive sugar levels in the blood and a condition called diabetes. Within muscle cells are stores of calcium that signal the muscle to contract. Changes in calcium levels enhance the uptake of glucose that fuel these contractions. However, variations in calcium have also been linked to diabetes, and it remained unclear when and how these 'signals' become harmful. People with a condition called malignant hyperthermia susceptibility (MHS for short) have genetic mutations that allow calcium to leak out from these stores. This condition may result in excessive contractions causing the muscle to over-heat, become rigid and break down, which can lead to death if left untreated. A clinical study in 2019 found that out of hundreds of patients who had MHS, nearly half had high blood sugar and were likely to develop diabetes. Now, Tammineni et al. ­ including some of the researchers involved in the 2019 study ­ have set out to find why calcium leaks lead to elevated blood sugar levels. The experiments showed that enzymes that help convert glycogen to glucose are more active in patients with MHS, and found in different locations inside muscle cells. Whereas the enzymes that change glucose into glycogen are less active. This slows down the conversion of glucose into glycogen for storage and speeds up the breakdown of glycogen into glucose. Patients with MHS also had fewer molecules that transport glucose into muscle cells and stored less glycogen. These changes imply that less glucose is being removed from the blood. Next, Tammineni et al. used a microscopy technique that is able to distinguish finely separated objects with a precision not reached before in living muscle. This revealed that when the activity of the enzyme that breaks down glycogen increased, it moved next to the calcium store. This effect was also observed in the muscle cells of MHS patients that leaked calcium from their stores. Taken together, these observations may explain why patients with MHS have high levels of sugar in their blood. These findings suggest that MHS may start decades before developing diabetes and blood sugar levels in these patients should be regularly monitored. Future studies should investigate whether drugs that block calcium from leaking may help prevent high blood sugar in patients with MHS or other conditions that cause a similar calcium leak.

Causes of sore throat after intubation: a prospective observational study of multiple anesthesia variables.

BACKGROUND: Sore throat is common after intubation for surgery. This observational study investigated cuff pressure and a large range of clinical covariates to explore the etiology of sore throat. METHODS: Approximately 24 hours after surgery six questions relating to pain, upper airway symptoms and sore throat were delivered to patients who had undergone intubation. Sore throat was correlated with demographics, anesthesia variables and cuff pressure (measured for a subset of patients). RESULTS: Sore throat was reported by 270/518 (52%) patients with VAS Score 45.9±25.1 (range 0-100). Sore throat patients were significantly younger, had a lower ASA status, were more frequently female, had shorter surgeries and lower nitrous oxide exposure, had a higher proportion of smaller tracheal tubes (7.5 mm internal diameter vs. 8 mm), had a higher incidence of nasogastric drainage, higher propofol doses and a higher usage of ketorolac. Decreasing age (odds ratio 0.976, 95% confidence intervals 0.961-0.992, P=0.003) and the presence of a nasogastric tube when the questionnaire was delivered (OR 1.83, 95% CI: 1.06-3.14, P=0.03) remained significant predictors of sore throat on multivariate analysis. Mean cuff pressure (measured for 160 patients) was 56.8±41.9 mmHg. Cuff pressure was similar amongst patients with and without sore throat (57±46 vs. 53±38 mmHg, P=0.58). There was no correlation between cuff pressure and severity of sore throat (r=0.004, P=0.37). CONCLUSIONS: Only age and the presence of a nasogastric tube after surgery were significant predictors for sore throat. This result contradicts most other studies of cuff pressure where fewer covariates were measured.

Malignant hyperthermia susceptibility diagnosed with a family-specific ryanodine receptor gene type 1 mutation.

Malignant hyperthermia (MH) is an autosomal dominant disorder of skeletal muscle calcium regulation, and the rate of calcium-induced calcium release (CICR), determined by using skinned fibers of skeletal muscle, has been employed as a diagnostic test for MH susceptibility in Japan. The ryanodine receptor (RYR1), encoding the major calcium-release channel in skeletal muscle sarcoplasmic reticulum, has been shown to be mutated in a number of MH pedigrees. We experienced the detection of accelerated CICR and/or an RYR1 mutation in a patient with an MH episode and his family. Accelerated CICR and an RYR1 mutation (c.14512C>G, p.L4838V) were found in the patient and his father. The MH-causative mutation (c.14512C>G, p.L4838V) was also found in his brother and his son (resulting in the diagnosis of MH without the CICR test), but the mutation was not found in his mother or two daughters. With the detection of the family-specific mutation in other family members, the diagnosis of MH was made without the invasive CICR test.