Hereditary axonal neuropathy related to MME gene mutation in a family with fetomaternal alloimmune glomerulonephritis.

We report a consanguineous family with a homozygous and heterozygous membrane metallo-endopeptidase (MME) mutation (c.467delC) and two clinical conditions: fetomaternal alloimmune membranous glomerulopathy (FMG) and hereditary motor and sensory axonal neuropathy. The penetrance of both phenotypes was variable. Some individuals experienced unusually fast neurological degradation. Pain and vasomotor signs were frequent complaints, possibly due to a loss of the neutral endopeptidase (NEP, the MME gene product) function and its subsequent inability to degrade substance P and vasomotor peptides. Electrophysiological and nerve biopsy findings were consistent with predominantly axonal neuropathy. This specific clinical phenotype was attributed to a c.467delC MME gene mutation. Diagnosis of such a mutation is important but can be challenging, due to allele dropout. Heterozygous subjects who had already reached the expected age of disease onset had peripheral neuropathy, but also suffered from additional diseases. Neurologists should advise women of childbearing age with MME mutations to seek pre-pregnancy genetic advice and nephrologists should search for neuropathy in patients with FMG.

Consequence of parvalbumin deficiency in the mdx mouse: histological, biochemical and mechanical phenotype of a new double mutant.

We tested the hypothesis whether the mild dystrophy in mdx mice could result from the contribution of the cytosolic calcium buffer parvalbumin in maintaining a normal cytosolic [Ca2+]i, in spite of an increased passive Ca2+ influx. By crossing mdx mice with parvalbumin-deficient mice, double mutant mice, lacking both dystrophin and parvalbumin, were obtained. Though resting cytosolic [Ca2+]i and total calcium content were similar to that of mdx muscles, this new animal model presented a slightly more severe phenotype than the mdx mouse. Muscle pseudo-hypertrophy, the density of myotubes and of centronucleated fibres as well as the loss of IIB fibres were all increased in parvalbumin-deficient mdx mice. Many of these deficits were overcome in late adulthood, albeit fibrosis was clearly more pronounced than in mdx muscles. At 90 days, parvalbumin-deficient mdx mice showed higher levels of creatine phosphokinase and lower muscle strength, in vivo, than mdx mice. Isometric tension of isolated muscle was reduced, but the susceptibility to eccentric contraction was not increased. The slight aggravation of muscle dystrophy observed in mdx mice deprived of parvalbumin cannot explain the severity of the affection observed in xmd dogs and Duchenne dystrophy patients where parvalbumin is constitutively not expressed.

Prevention of pathology in mdx mice by expression of utrophin: analysis using an inducible transgenic expression system.

Duchenne muscular dystrophy results from the absence of dystrophin, a cytoskeletal protein. Previously, we have shown in a transgenic mouse model of the disease (mdx) that high levels of expression of the dystrophin-related protein, utrophin can prevent pathology. We developed a new transgenic mouse model where muscle specific utrophin expression was conditioned by addition of tetracycline in water. Transgene expression was turned on at different time points: in utero, at birth, 10 and 30 days after birth. We obtained moderate levels of expression, variable from fibre to fibre (mosaicism) but sufficient to induce a correct localization of the dystro-sarcoglycan complex. Histology revealed a reduction of necrotic foci and of the percentage of centronucleated fibres, which remained still largely above the normal level. Isometric force was not improved but the resistance to eccentric contractions was significantly stronger. When utrophin expression was activated 30 days after birth, improvements were marginal, suggesting that the age at which utrophin therapy is initiated could be an important factor. Our results also provide an unexpected insight into the pathogenesis of the dystrophinopathies. We observed a complete normalization of the characteristics of the mechano-sensitive/voltage-independent Ca(2+) channels (occurrence, open probabilities and Ca(2+) currents), while the classical markers of dystrophy were still abnormal. These observations question the role of increased Ca(2+) channel activity in initiating the dystrophic process. The new model shows that utrophin therapy, initiated after birth, can be effective, but the extent of correction of the various symptoms of dystrophinopathy critically depends on the amount of utrophin expressed.

Discrepant time course of cranial and spinal subdural collections in a case of SIH treated by EBP.

The MR monitoring of a patient with acute spontaneous intracranial hypotension successfully treated by epidural blood patch revealed strikingly different time course of the initially concomitant cranial and spinal subdural fluid collections. This undescribed feature suggested different pathophysiological mechanisms for the disorder in the two locations and should be kept in mind when imaging patients with the condition.

Tetanus relaxation of fast skeletal muscles of the mouse made parvalbumin deficient by gene inactivation.

The effects of tetanus duration on the relaxation rate of extensor digitorum longus (EDL) and flexor digitorum brevis (FDB) muscles were studied in normal (wild-type, WT) and parvalbumin-deficient (PVKO) mice, at 20 C. In EDL of PVKO, the relaxation rate was low and unaffected by tetanus duration (< 3.2 s). In contrast, the relaxation rate of WT muscles decreased when tetanus duration increased from 0.2 to 3.2 s. In WT muscles, fast relaxation recovered as the rest interval increased. Specific effect of parvalbumin was asserted by calculating the difference in relaxation rate between WT and PVKO muscles. For EDL, the rate constant of relaxation slowing was 1.10 s-1 of tetanization; the rate constant of relaxation recovery was 0.05 s-1 of rest. In FDB, the effects of tetanus duration on WT and PVKO muscles were qualitatively similar to those observed in EDL. Relaxation slowing as tetanus duration increases, reflects the progressive saturation of parvalbumin by Ca2+, while recovery as rest interval increases reflects the return to Ca2+-free parvalbumin. At all tetanus durations, relaxation rate still remained slightly faster in WT muscles. This suggested that parvalbumin facilitates calcium traffic from myofibrils to the SR. No difference was found between WT and PVKO muscles for: (i) the expression of the fast isoforms of myosin heavy chains, (ii) the force-velocity relationship and maximal shortening velocity and (iii) the Ca2+-activated ATPase activity from isolated preparations of the sarcoplasmic reticulum (SR).

Resolution of early diffusion-weighted and FLAIR MRI abnormalities in a patient with TIA.

We report a patient with a clinical history and neurologic examination consistent with acute stroke. Diffusion-weighted and fast fluid-attenuated inversion recovery MRI obtained 4 hours after stroke onset detected focal abnormalities suggestive of acute ischemic brain damage. The neurologic deficit and the imaging abnormalities both resolved completely at follow-up. This patient illustrates complete resolution of early changes observed with diffusion-weighted MRI at the hyperacute phase in a TIA.

Glycine antagonist and NO synthase inhibitor protect the developing mouse brain against neonatal excitotoxic lesions.

The prevention of cerebral palsy and neuroprotection of the immature brain continue to be health care priorities. The pathophysiology of perinatal brain lesions associated with cerebral palsy seems to be multifactorial and includes pre- and perinatal factors such as preconceptional events, hormone and growth factors deficiencies, maternal infections with production of cytokines, and hypoxic/ischemic perfusion failures. Excitotoxic cascade could represent a common pathway that leads to neural cell death and subsequent brain damage. Brain injuries induced by ibotenate, a glutamatergic analog, which are essentially mediated through the N-methyl-D-aspartate receptor, mimic some aspects of the white matter cysts and transcortical necrosis observed in human perinatal brain damage. The purpose of the present study was to assess the protective role of several pharmacological agents, administered in conjunction with ibotenate, against induced excitotoxic lesions. We injected ibotenate in the developing mouse brain 5 d postnatally, after the full settlement of neuronal layers. Co-treatment with kynurenic acid, an antagonist of the facilitating glycine site of the N-methyl-D-aspartate receptor, or with N(G)-nitro-L-arginine, an inhibitor of nitric oxide synthesis, induced a dose-dependent neuroprotective effect. Conversely, zinc gluconate, a blocking agent of the channel linked to the N-methyl-D-aspartate receptor, and a free radical scavenger (U74389F), were unable to protect the developing brain against excitotoxic attack. These data help to clarify some molecular mechanisms involved in excitotoxic lesions of the developing mouse brain and permit us to envision new strategies in the prevention of cerebral palsy.