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OBJECTIVE: To identify the causative gene mutation in a 5-generation Belgian family with dominantly inherited spinocerebellar ataxia and polyneuropathy, in which known genetic etiologies had been excluded. METHODS: We collected DNA samples of 28 family members, including 7 living affected individuals, whose clinical records were reviewed by a neurologist experienced in ataxia. We combined linkage data of 21 family members with whole exome sequencing in 2 affected individuals to identify shared heterozygous variants mapping to potentially linked regions. Variants were screened for rarity and for predicted damaging effect. A candidate mutation was confirmed by Sanger sequencing and tested for cosegregation with the disease. RESULTS: Affected individuals presented with late-onset sensorimotor axonal polyneuropathy; all but one also had cerebellar ataxia. We identified a variant in the MME gene, p.C143Y, that was absent from control databases, cosegregated with the phenotype, and was predicted to have a strong damaging effect on the encoded protein by all algorithms we used. CONCLUSIONS: MME encodes neprilysin (NEP), a zinc-dependent metalloprotease expressed in most tissues, including the central and peripheral nervous systems. The mutated cysteine 143 forms a disulfide bridge, which is 100% conserved in NEP and in similar enzymes. The recent identification of recessive MME mutations in 10 unrelated individuals from Japan with axonal polyneuropathy further supports the causality of the mutation, despite the dominant mode of inheritance and the presence of cerebellar involvement in our study family. Functional studies are needed to identify the mechanisms underlying these differences.
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INTRODUCTION: Delayed-onset muscle soreness (DOMS), a condition triggered by eccentric exercise, affects muscle cells at a biochemical level in a poorly understood fashion. The objective of the present study was to examine human muscle proteome modifications induced by strenuous eccentric exercises after a specific training aimed to prevent DOMS. METHODS: Biopsy samples of the rectus femoris were obtained from healthy human volunteers in three successive conditions: 1) at rest, 2) 24 h after an injuring exercise protocol consisting of three series of 30 maximal contractions of the quadriceps on an isokinetic dynamometer, and 3) 24 h after a similar exercise bout preceded either by five eccentric training sessions or by no training. RESULTS: Muscle damage was assessed before and 1 d after each maximal eccentric test by comparing three indirect markers: plasma activity of creatine kinase, muscle stiffness, and subjective pain intensity. Compared with the first eccentric test, those markers were reduced after the second test and further reduced if this second test followed the eccentric training, thus confirming the protective effect of such training. Muscle protein extracts were subjected to a two-dimensional difference gel electrophoresis proteomic analysis coupled with matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry protein identification. Surprisingly, we observed that myosin heavy chains decreased after the first eccentric test and were reduced further with other contractile proteins after the second test. Furthermore, the expression of several glycolytic enzymes decreased only after the second test, which was preceded by a specific training. CONCLUSIONS: These findings suggest that the eccentric training resulted in a switch to oxidative metabolism, which may be associated with protection from DOMS.