Cerebral biochemical pathways in experimental autoimmune encephalomyelitis and adjuvant arthritis: a comparative metabolomic study.

Many diseases, including brain disorders, are associated with perturbations of tissue metabolism. However, an often overlooked issue is the impact that inflammations outside the brain may have on brain metabolism. Our main goal was to study similarities and differences between brain metabolite profiles of animals suffering from experimental autoimmune encephalomyelitis (EAE) and adjuvant arthritis (AA) in Lewis rat models. Our principal objective was the determination of molecular protagonists involved in the metabolism underlying these diseases. EAE was induced by intraplantar injection of complete Freund's adjuvant (CFA) and spinal-cord homogenate (SC-H), whereas AA was induced by CFA only. Naive rats served as controls (n = 9 for each group). Two weeks after inoculation, animals were sacrificed, and brains were removed and processed for metabolomic analysis by NMR spectroscopy or for immunohistochemistry. Interestingly, both inflammatory diseases caused similar, though not identical, changes in metabolites involved in regulation of brain cell size and membrane production: among the osmolytes, taurine and the neuronal marker, N-acetylaspartate, were decreased, and the astrocyte marker, myo-inositol, slightly increased in both inoculated groups compared with controls. Also ethanolamine-containing phospholipids, sources of inflammatory agents, and several glycolytic metabolites were increased in both inoculated groups. By contrast, the amino acids, aspartate and isoleucine, were less concentrated in CFA/SC-H and control vs. CFA rats. Our results suggest that inflammatory brain metabolite profiles may indicate the existence of either cerebral (EAE) or extra-cerebral (AA) inflammation. These inflammatory processes may act through distinct pathways that converge toward similar brain metabolic profiles. Our findings open new avenues for future studies aimed at demonstrating whether brain metabolic effects provoked by AA are pain/stress-mediated and/or due to the presence of systemic proinflammatory molecules. Regardless of the nature of these mechanisms, our findings may be of interest for future clinical studies, e.g. by in-vivo magnetic resonance spectroscopy.

Multiminicore disease in a family susceptible to malignant hyperthermia: histology, in vitro contracture tests, and genetic characterization.

BACKGROUND: Histological anomalies associated with malignant hyperthermia (MH) have been scarcely reported. In some patients susceptible to MH (MHS), central cores have been identified and a genetic association has been proposed, but multiminicore lesions have not been systematically reported. OBJECTIVE: To analyze the association between multiminicores and MHS in a large family with MH with an approach combining histology, in vitro contracture tests, and genetic analysis. PATIENTS AND METHODS: Twenty-nine members of an MH family (147 members) were investigated. MAIN OUTCOME MEASURES: Muscle biopsy specimens were analyzed histologically and with in vitro contracture tests. Genetic analyses were performed to determine the presence of mutations in the ryanodine receptor (RYR1) gene. RESULTS: According to the gold standard in vitro contracture tests, 17 patients were diagnosed as having MHS and 10 as not being susceptible. Multiminicores were found in 16 of the 17 MHS patients and in a single nonsusceptible participant. A linkage between the MH trait and the RYR1 locus in chromosome 19 was demonstrated, whereas no already known mutations were found. Two missense heterozygous mutations (R2676W and T2787S) were identified from sequencing of the entire coding complementary DNA. Overall, we found a significant association between MHS and the presence of multiminicores (chi(2) = 26.5, P<.001) on the one hand and the presence of new mutations in the RYR1 gene (chi(2) = 19.0, P<.001) on the other hand. This remarkably high occurrence of multiminicores in an MHS family is uncommon, and genetic analyses indicate that the association between multiminicores and MHS is linked to a novel R2656W and T2787S substitution present on the same allele of the RYR1 gene. CONCLUSIONS: These results indicate that multiminicore lesions are observed in MHS patients with neither clinical signs related to multiminicore disease nor histological features of congenital myopathies. These multiminicore lesions may be secondary to mutations in the RYR1 gene. As a consequence, these patients must be distinguished from patients with multiminicore disease and from other MHS patients for whom multiminicores are not observed.