Marta Pace

Spinal muscular atrophy genotyping by gene dosage using multiple ligation-dependent probe amplification

Spinal muscular atrophy (SMA) is an autosomal recessive disease characterized by degeneration of the anterior horn cells of the spinal cord, causing symmetric proximal muscle weakness. SMA is classified in three clinical types, SMA I, SMA II, and SMA III, based on the severity of the symptoms and the age of onset. About 95% of SMA cases are caused by homozygous deletion of the survival motor neuron 1 (SMN1) gene (5q13), or its conversion to SMN2. The molecular diagnosis of this disease is usually carried out by a polymerase chain reaction–restriction fragment length polymorphism approach able to evidence the absence of both SMN1 copies. However, this approach is not able to identify heterozygous healthy carriers, which show a very high frequency in general population (1:50). We used the multiple ligation-dependent probe amplification (MLPA) approach for the molecular diagnosis of SMA in 19 affected patient and in 57 individuals at risk to become healthy carriers. This analysis detected the absence of the homozygous SMN1 in all the investigated cases, and allowed to discriminate between SMN1 deletion and conversion to SMN2 on the basis of the size showed by the peaks specific for the different genes mapped within the SMA critical region. Moreover, MLPA analysis evidenced a condition of the absence of the heterozygous SMN1 in 33 out of the 57 relatives of the affected patients, demonstrating the usefulness of this approach in the identification of healthy carriers. Thus, the MLPA technique represents an easy, low cost, and high throughput system in the molecular diagnosis of SMA, both in affected patients and in healthy carriers.

Familial idiopathic hyper-CK-emia: An underrecognized condition

Persistent elevation of serum creatine kinase (CK) in individuals with normal neurological and laboratory examinations has been called idiopathic hyperCKemia (IH). IH has been reported in rare families and was recently ascribed to caveolin‐3 gene mutations. We retrospectively found that IH was familial in 13 of 28 subjects in whom serum CK was measured in relatives. These 13 families had a total of 41 subjects with IH, including six over 60 years of age. In eight families there was male‐to‐male transmission and a higher prevalence of males with hyperCKemia. Muscle biopsy in one member of all families was normal or showed minimal, nonspecific changes. Morphometric examination disclosed different patterns of changes in fiber size and distribution. Caveolin‐3 expression was normal and in five families molecular genetics excluded caveolin‐3 gene mutations. Our findings suggest that IH is familial in 46% of cases. Familial IH is a benign genetically heterogeneous condition that is autosomal‐dominant in at least 60% of cases, with a higher penetrance in men. Muscle Nerve, 2006

Polymorphisms of CD1 genes in chronic dysimmune neuropathies

CD1 are MCH-like glycoproteins specialized in capturing and presenting glycolipid to T cells. Expression of CD1 molecules has been observed on endoneurial machrophages in patients with chronic inflammatory demyelinating polyneuropathy (CIDP) and vasculitis and polymorphisms of CID1A and CD1E genes have been associated with susceptibility to develop Guillain-Barré syndrome. In 46 patients with CIDP, in 13 patients with multifocal motor neuropathy and in 132 controls we genotyped exon 2 of CD1A and CD1E genes. We found no association between chronic dysimmune neuropathies, with or without anti-ganglioside antibodies, and polymorphisms of CD1A and CD1E genes.

Possible role for nitric oxide dysregulation in critical illness myopathy.

Muscle fiber inexcitability and myosin loss underlie weakness in critical illness myopathy (CIM). Nitric oxide (NO) takes part in the maintenance of muscle fiber resting potential and, in pathological conditions accompanied by oxidative stress, may damage proteins through peroxynitrite generation. Sepsis and other conditions associated with CIM may differentially affect expression of NO synthases (NOSs), so that both downregulation and upregulation with excessive peroxynitrite production can be hypothesized. In six patients with CIM we studied NOS1, NOS2, and NOS3 protein expression by immunohistochemistry and Western blot. To investigate peroxynitrite production, we performed immunohistochemistry for nitrotyrosine and measured nitrotyrosine levels by enzyme‐linked immunosorbent assay. In three patients, sarcolemmal staining for NOS1 was selectively absent. In the others, it was absent in atrophic fibers and absent or reduced in non‐atrophic fibers. Total NOS1 protein content was reduced by 41% in patients compared to controls, whereas no significant changes were found in levels and localization of NOS2, NOS3, and nitrotyrosine. Further studies are warranted to determine whether NOS1 loss plays a role in the pathophysiology of CIM, possibly reducing the release of NO at the sarcolemma and affecting muscle fiber excitability. Muscle Nerve, 2007

Susceptibility to chronic inflammatory demyelinating polyradiculoneuropathy is associated to polymorphic GA repeat in the SH2D2A gene

The SH2D2A gene encodes a T-cell-specific adapter protein involved in the negative control of T-cell activation. The genotype GA13-16 homozygote of the SH2D2A gene promoter has been associated with the susceptibility to develop multiple sclerosis. Chronic inflammatory demyelinating polyradiculoneuropathy (CIDP) is an immune-mediated neuropathy sharing several pathogenetic mechanisms with multiple sclerosis. We genotyped the SH2D2A promoter region in 105 controls and 48 patients with CIDP. We found a significant association between CIDP and the genotype GA13-16 homozygote (OR 3.167; p 0.013). We hypothesize that this genotype is associated with the susceptibility to develop CIDP and may be implicated in the persistence of the disease.

Neuroprotective effect of cathodal transcranial direct current stimulation in a rat stroke model

Experimental focal brain ischemia generates in the penumbra recurrent depolarizations which spread across the injured cortex inducing infarct growth. Transcranial direct current stimulation can induce a lasting, polarity-specific, modulation of cortical excitability. To verify whether cathodal transcranial direct current stimulation could reduce the infarct size and the number of depolarizations, focal ischemia was induced in the rat by the 3 vessels occlusion technique. In the first experiment 12 ischemic rats received cathodal stimulation (alternating 15 min on and 15 min off) starting 45 min after middle cerebral artery occlusion and lasting 4 h. In the second experiment 12 ischemic rats received cathodal transcranial direct current stimulation with the same protocol but starting soon after middle cerebral artery occlusion and lasting 6 h. In both experiments controls were 12 ischemic rats not receiving stimulation. Cathodal stimulation reduced the infarct volume in the first experiment by 20% (p=0.002) and in the second by 30% (p=0.003). The area of cerebral infarction was smaller in animals receiving cathodal stimulation in both experiments (p=0.005). Cathodal stimulation reduced the number of depolarizations (p=0.023) and infarct volume correlated with the number of depolarizations (p=0.048). Our findings indicate that cathodal transcranial direct current stimulation exert a neuroprotective effect in the acute phase of stroke possibly decreasing the number of spreading depolarizations. These findings may have translational relevance and open a new avenue in neuroprotection of stroke in humans.

Polymorphism of CD1 and SH2D2A genes in inflammatory neuropathies

In the quest for susceptibility factors of inflammatory neuropathies, many genes implicated in the pathogenesis of autoimmune diseases have been investigated with negative or conflicting results. We studied, with a gene candidate approach, the CD1 system specialized in capturing and presenting glycolipids to antigen‐specific T cells, and the SH2D2A gene encoding for a T‐cell‐specific adapter protein implicated in control of early T‐cell activation. In Guillain–Barré syndrome, an initially positive association study with polymorphism of CD1A and CD1E genes was not confirmed. In chronic inflammatory demyelinating polyneuropathy, we did not find an association with CD1 genes, but we found an association with a homozygous genotype for a low repeat number of tandem GA in the SH2D2A gene. This genotype could result in defective control and elimination of autoreactive T cells. All the studies were performed on relatively small size populations. Confirmation in larger sized studies is required both for CD1 and SH2D2A genes. Considering the relative rarity of patients with inflammatory neuropathies, this can only be accomplished by international collaboration.

Physiological time structure of the tibialis anterior motor activity during sleep in mice, rats and humans

The validation of rodent models for restless legs syndrome (Willis–Ekbom disease) and periodic limb movements during sleep requires knowledge of physiological limb motor activity during sleep in rodents. This study aimed to determine the physiological time structure of tibialis anterior activity during sleep in mice and rats, and compare it with that of healthy humans. Wild‐type mice (n = 9) and rats (n = 8) were instrumented with electrodes for recording the electroencephalogram and electromyogram of neck muscles and both tibialis anterior muscles. Healthy human subjects (31 ± 1 years, n = 21) underwent overnight polysomnography. An algorithm for automatic scoring of tibialis anterior electromyogram events of mice and rats during non‐rapid eye movement sleep was developed and validated. Visual scoring assisted by this algorithm had inter‐rater sensitivity of 92–95% and false‐positive rates of 13–19% in mice and rats. The distribution of the time intervals between consecutive tibialis anterior electromyogram events during non‐rapid eye movement sleep had a single peak extending up to 10 s in mice, rats and human subjects. The tibialis anterior electromyogram events separated by intervals <10 s mainly occurred in series of two‐three events, their occurrence rate in humans being lower than in mice and similar to that in rats. In conclusion, this study proposes reliable rules for scoring tibialis anterior electromyogram events during non‐rapid eye movement sleep in mice and rats, demonstrating that their physiological time structure is similar to that of healthy young human subjects. These results strengthen the basis for translational rodent models of periodic limb movements during sleep and restless legs syndrome/Willis–Ekbom disease.

CD1A and CD1E gene polymorphisms are associated with susceptibility to multiple sclerosis.

Multiple sclerosis (MS) is thought to be an autoimmune T-cell-mediated disease directed at myelin antigens of the central nervous system. Besides myelin proteins, lipid components of CNS are supposed to play a role as antigens for T cells in MS. CD1 is a family of MHC-like glycoproteins specialized in capturing and presenting a variety of microbial and self lipids and glycolipids to antigen-specific T cells. CD1-restricted T cells specific for gangliosides and sulfatide have been isolated from subjects with MS and in mice with experimental allergic encephalopathy. We genotyped exon 2 of CD1A and CD1E in 205 MS patients and 223 unrelated healthy controls and determined their association with the presence of anti-ganglioside and anti-sulfatide antibodies. CD1E 01-01 is associated with a reduced risk of MS (OR 0.54, p=0.001); CD1A 02-02 (OR 1.99, p=0.012) or CD1E 02-02 (OR 2.45, p=0.000) with an increased risk. The combination of the genotypes CD1A 02-02 and CD1E 02-02 is present in 90.7% of patients but in only 9.4% controls (OR 94.16, p= 0.000). CD1A and CD1E polymorphisms contribute to the polygenic susceptibility to MS. The functional effects of CD1 polymorphisms are unknown, however changes in CD1 alleles may affect numerous immunological functions.

Evidence of an association between sleep and levodopa-induced dyskinesia in an animal model of Parkinson's disease

Levodopa-induced dyskinesia (LID) represents a major challenge for clinicians treating patients affected by Parkinsons disease (PD). Although levodopa is the most effective treatment for PD, the remodeling effects induced by disease progression and the pharmacologic treatment itself cause a narrowing of the therapeutic window because of the development of LID. Although animal models of PD provide strong evidence that striatal plasticity underlies the development of dyskinetic movements, the pathogenesis of LID is not entirely understood. In recent years, slow homeostatic adjustment of intrinsic excitability occurring during sleep has been considered fundamental for network stabilization by gradually modifying plasticity thresholds. So far, how sleep affects on LID has not been investigated. Therefore, we measured synaptic downscaling across sleep episodes in a parkinsonian animal model showing dyskinetic movements similar to LID. Our electrophysiological, molecular, and behavioral results are consistent with an impaired synaptic homeostasis during sleep in animals showing dyskinesia. Accordingly, sleep deprivation causes an anticipation and worsening of LID supporting a link between sleep and the development of LID.