Lacee J. Laufenberg

Interdependence of Muscle Atrophy and Bone Loss Induced by Mechanical Unloading

Mechanical unloading induces muscle atrophy and bone loss; however, the time course and interdependence of these effects is not well defined. We subjected 4‐month‐old C57BL/6J mice to hindlimb suspension (HLS) for 3 weeks, euthanizing 12 to 16 mice on day (D) 0, 7, 14, and 21. Lean mass was 7% to 9% lower for HLS versus control from D7–21. Absolute mass of the gastrocnemius (gastroc) decreased 8% by D7, and was maximally decreased 16% by D14 of HLS. mRNA levels of Atrogin‐1 in the gastroc and quadriceps (quad) were increased 99% and 122%, respectively, at D7 of HLS. Similar increases in MuRF1 mRNA levels occurred at D7. Both atrogenes returned to baseline by D14. Protein synthesis in gastroc and quad was reduced 30% from D7–14 of HLS, returning to baseline by D21. HLS decreased phosphorylation of SK61, a substrate of mammalian target of rapamycin (mTOR), on D7–21, whereas 4E‐BP1 was not lower until D21. Cortical thickness of the femur and tibia did not decrease until D14 of HLS. Cortical bone of controls did not change over time. HLS mice had lower distal femur bone volume fraction (−22%) by D14; however, the effects of HLS were eliminated by D21 because of the decline of trabecular bone mass of controls. Femur strength was decreased approximately 13% by D14 of HLS, with no change in tibia mechanical properties at any time point. This investigation reveals that muscle atrophy precedes bone loss during unloading and may contribute to subsequent skeletal deficits. Countermeasures that preserve muscle may reduce bone loss induced by mechanical unloading or prolonged disuse. Trabecular bone loss with age, similar to that which occurs in mature astronauts, is superimposed on unloading. Preservation of muscle mass, cortical structure, and bone strength during the experiment suggests muscle may have a greater effect on cortical than trabecular bone.

Chronic use of PPI and H2 antagonists decreases the risk of pouchitis after IPAA for ulcerative colitis.

IntroductionBacteria have been implicated in the development of pouchitis after ileal pouch anal anastomosis. The change in gastric pH with the use of proton pump inhibitors and H2 antagonists may lead to alteration of enteric bacteria. We hypothesized that chronic use of these medications would decrease the incidence of pouchitis.MethodsPatients who had undergone ileal pouch anal anastomosis for ulcerative colitis were classified by history of pouchitis. Patients were further classified by their use of proton pump inhibitors, H2 blockers, antacids, and other known risk factors for pouchitis.ResultsEighty-five patients were identified. There was a statistically significant increase in the use of daily acid suppression in patients without pouchitis. There was also a statistically significant increase in the use of antacids in patients without pouchitis. Occasional use of acid suppression did not alter the rate of pouchitis.ConclusionsOur data suggest that the daily use of proton pump inhibitors, H2 antagonists, or antacids is associated with a decreased risk of pouchitis in ulcerative colitis. Occasional use of these agents did not seem to afford the same protection. These data suggest that altering the pH of the gastrointestinal tract may influence the development of pouchitis.

Salutary effect of aurintricarboxylic acid on endotoxin- and sepsis-induced changes in muscle protein synthesis and inflammation.

ABSTRACT Small molecule nonpeptidyl molecules are potentially attractive drug candidates as adjunct therapies in the treatment of sepsis-induced metabolic complications. As such, the current study investigates the use of aurintricarboxylic acid (ATA), which stimulates insulinlike growth factor 1 receptor and AKT signaling, for its ability to ameliorate the protein metabolic effects of endotoxin (lipopolysaccharide [LPS]) + interferon &ggr; (IFN-&ggr;) in C2C12 myotubes and sepsis in skeletal muscle. Aurintricarboxylic acid dose- and time-dependently increases mTOR (mammalian or mechanistic target of rapamycin)–dependent protein synthesis. Pretreatment with ATA prevents the LPS/IFN-&ggr;–induced decrease in protein synthesis at least in part by maintaining mTOR kinase activity, whereas posttreatment with ATA is able to increase protein synthesis when added up to 6 h after LPS/IFN-&ggr;. Aurintricarboxylic acid also reverses the amino acid resistance, which is detected in response to nutrient deprivation. Conversely, ATA decreases the basal rate of protein degradation and prevents the LPS/IFN-&ggr; increase in proteolysis, and the latter change is associated reduced atrogin 1 and MuRF1 mRNA. The ability of ATA to antagonize LPS/IFN-&ggr;–induced changes in protein metabolism was associated with its ability to prevent the increases in interleukin 6 and nitric oxide synthase 2 and decreases in insulinlike growth factor 1. In vivo studies indicate ATA acutely increases skeletal muscle, but not cardiac, protein synthesis and attenuates the loss of lean body mass over 5 days. These data suggest ATA and other small molecule agonists of endogenous anabolic hormones may prove beneficial in treating sepsis by decreasing the inflammatory response and improving muscle protein balance.

Nociceptin receptor signaling in sympathetic neurons from septic rats

BACKGROUND The endogenous opioid peptide, nociception (Noc), contributes to the regulation of systemic blood pressure and regional blood flow. Recent clinical and animal studies have reported that Noc and its receptor (nociceptin/orphanin FQ [NOP]) are involved in inflammation and sepsis. The purpose of the present study was to examine the modulation of Ca(2+) channels by Noc in acutely isolated stellate ganglion (SG) neurons from control and septic rats. MATERIALS AND METHODS Sepsis was induced in male Sprague-Dawley rats via cecal ligation and puncture. SG neurons were isolated 24 and 72 h after sepsis induction. Thereafter, the concentration-response relationships for the Noc-stimulated NOP receptor Ca(2+) current inhibition were determined using the whole-cell patch clamp technique. In addition, the Noc precursor (prepronociceptin [PNOC]) and NOP receptor messenger RNA (mRNA) levels were determined by quantitative real-time polymerase chain reaction, and PNOC protein levels were measured by Western blot analysis. RESULTS Comparison of the Noc concentration-response relationships in SG neurons from control and septic rats 24 h after sepsis revealed similar potency and efficacy. Moreover, 72 h after sepsis, neurons from control and septic rats exhibited an increased potency compared with both groups at the 24-h time point--an effect that was more pronounced in neurons from septic rats. PNOC mRNA levels were significantly greater in SG neurons isolated from septic rats compared with control neurons, but NOP receptor mRNA levels remained unchanged during the 72-h period. CONCLUSIONS Our study demonstrates the cecal ligation and puncture model-induced temporal upregulation of components within the NOP receptor signaling pathway in rat sympathetic neurons. As SG neurons provide the main sympathetic input to the heart, an increased Noc release and potency during sepsis may compromise cardiovascular function.

Modulation of voltage-gated Ca2+ channels by G protein-coupled receptors in celiac-mesenteric ganglion neurons of septic rats.

Septic shock, the most severe complication associated with sepsis, is manifested by tissue hypoperfusion due, in part, to cardiovascular and autonomic dysfunction. In many cases, the splanchnic circulation becomes vasoplegic. The celiac-superior mesenteric ganglion (CSMG) sympathetic neurons provide the main autonomic input to these vessels. We used the cecal ligation puncture (CLP) model, which closely mimics the hemodynamic and metabolic disturbances observed in septic patients, to examine the properties and modulation of Ca2+ channels by G protein-coupled receptors in acutely dissociated rat CSMG neurons. Voltage-clamp studies 48 hr post-sepsis revealed that the Ca2+ current density in CMSG neurons from septic rats was significantly lower than those isolated from sham control rats. This reduction coincided with a significant increase in membrane surface area and a negligible increase in Ca2+ current amplitude. Possible explanations for these findings include either cell swelling or neurite outgrowth enhancement of CSMG neurons from septic rats. Additionally, a significant rightward shift of the concentration-response relationship for the norepinephrine (NE)-mediated Ca2+ current inhibition was observed in CSMG neurons from septic rats. Testing for the presence of opioid receptor subtypes in CSMG neurons, showed that mu opioid receptors were present in ~70% of CSMG, while NOP opioid receptors were found in all CSMG neurons tested. The pharmacological profile for both opioid receptor subtypes was not significantly affected by sepsis. Further, the Ca2+ current modulation by propionate, an agonist for the free fatty acid receptors GPR41 and GPR43, was not altered by sepsis. Overall, our findings suggest that CSMG function is affected by sepsis via changes in cell size and α2-adrenergic receptor-mediated Ca2+ channel modulation.