Allelic mutations of the sodium channel SCN8A reveal multiple cellular and physiological functions

Allelic mutations of Scn8a in the mouse have revealed the range of neurological disorders that can result from alternations of one neuronal sodium channel. Null mutations produce the most severe phenotype, with motor neuron failure leading to paralysis and juvenile lethality. Two less severe mutations cause ataxia, tremor, muscle weakness, and dystonia. The electrophysiological effects have been studied at the cellular level by recording from neurons from the mutant mice. The data demonstrate that Scn8a is required for the complex spiking of cerebellar Purkinje cells and for persistent sodium current in several classes of neurons, including some with pacemaker roles. The mouse mutations of Scn8a have also provided insight into the mode of inheritance of channelopathies, and led to the identification of a modifier gene that affects transcript splicing. These mutations demonstrate the value of mouse models to elucidate the pathophysiology of human disease.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/42795/1/10709_2004_Article_5381441.pd

The 13th Annual International Mammalian Genome Society Conference: A Meeting Report

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/42121/1/335-11-6-413_00110413.pd

Expression of transient receptor potential channels and two-pore potassium channels in subtypes of vagal afferent neurons in rat

Vagal afferent neurons relay important information regarding the control of the gastrointestinal system. However, the ionic mechanisms that underlie vagal activation induced by sensory inputs are not completely understood. We postulate that transient receptor potential (TRP) channels and/or two-pore potassium (K2p) channels are targets for activating vagal afferents. In this study we explored the distribution of these channels in vagal afferents by quantitative PCR after a capsaicin treatment to eliminate capsaicin-sensitive neurons, and by single-cell PCR measurements in vagal afferent neurons cultured after retrograde labeling from the stomach or duodenum. We found that TRPC1/3/5/6, TRPV1-4, TRPM8, TRPA1, TWIK2, TRAAK, TREK1, and TASK1/2 were all present in rat nodose ganglia. Both lesion results and single-cell PCR results suggested that TRPA1 and TRPC1 were preferentially expressed in neurons that were either capsaicin sensitive or TRPV1 positive. Expression of TRPM8 varied dynamically after various manipulations, which perhaps explains the disparate results obtained by different investigators. Last, we also examined ion channel distribution with the A-type CCK receptor (CCK-RA) and found there was a significant preference for neurons that express TRAAK to also express CCK-RA, especially in gut-innervating neurons. These findings, combined with findings from prior studies, demonstrated that background conductances such as TRPC1, TRPA1, and TRAAK are indeed differentially distributed in the nodose ganglia, and not only do they segregate with specific markers, but the degree of overlap is also dependent on the innervation target

Altered Subthreshold Sodium Currents and Disrupted Firing Patterns in Purkinje Neurons of Scn8a Mutant Mice

Sodium currents and action potentials were characterized in Purkinje neurons from ataxic mice lacking expression of the sodium channel Scn8a. Peak transient sodium current was ∼60% of that in normal mice, but subthreshold sodium current was affected much more. Steady-state current elicited by voltage ramps was reduced to ∼30%, and resurgent sodium current, an unusual transient current elicited on repolarization following strong depolarizations, was reduced to 8%–18%. In jolting mice, with a missense mutation in Scn8a, steady-state and resurgent current were also reduced, with altered voltage dependence and kinetics. Both spontaneous firing and evoked bursts of spikes were diminished in cells from null and jolting mice. Evidently Scn8a channels carry most subthreshold sodium current and are crucial for repetitive firing

Gene symbol: COL11A1 Disease: Marshall Syndrome

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/42261/1/439-102-4-498_81020498.pd

Neural proliferation and restoration of neurochemical phenotypes and compromised functions following capsaicin-induced neuronal damage in the nodose ganglion of the adult rat

We previously reported that neuronal numbers within adult nodose ganglia (NG) were restored to normal levels 60 days following the capsaicin-induced destruction of nearly half of the neuronal population. However, the nature of this neuronal replacement is not known. Therefore, we aimed to characterize neural proliferation, neurochemical phenotypes, and functional recovery within adult rat NG neurons following capsaicin-induced damage. Sprague-Dawley rats received intraperitoneal injections of capsaicin or vehicle solution, followed by 5-bromo-2-deoxyuridine (BrdU) injections to reveal cellular proliferation. NG were collected at multiple times post-treatment (up to 300 days) and processed for immunofluorescence, RT-PCR, and dispersed cell cultures. Capsaicin-induced cellular proliferation, indicated by BrdU/Ki-67-labeled cells, suggests that lost neurons were replaced through cell division. NG cells expressed the stem cell marker, nestin, indicating that these ganglia have the capacity to generate new neurons. BrdU-incorporation within β-III tubulin-positive neuronal profiles following capsaicin suggests that proliferating cells matured to become neurons. NG neurons displayed decreased NMDAR expression up to 180-days post-capsaicin. However, both NMDAR expression within the NG and synaptophysin expression within the central target of NG neurons, the NTS, were restored to pre-injury levels by 300 days. NG cultures from capsaicin-treated rats contained bipolar neurons, normally found only during development. To test the functional recovery of NG neurons, we injected the satiety molecule, CCK. The effect of CCK on food intake was restored by 300-days post-capsaicin. This restoration may be due to the regeneration of damaged NG neurons or generation of functional neurons that replaced lost connections

Marshall Syndrome Associated with a Splicing Defect at the COL11A1 Locus

Marshall syndrome is a rare, autosomal dominant skeletal dysplasia that is phenotypically similar to the more common disorder Stickler syndrome. For a large kindred with Marshall syndrome, we demonstrate a splice-donor–site mutation in the COL11A1 gene that cosegregates with the phenotype. The G +1→A transition causes in-frame skipping of a 54-bp exon and deletes amino acids 726–743 from the major triple-helical domain of the α1(XI) collagen polypeptide. The data support the hypothesis that the α1(XI) collagen polypeptide has an important role in skeletal morphogenesis that extends beyond its contribution to structural integrity of the cartilage extracellular matrix. Our results also demonstrate allelism of Marshall syndrome with the subset of Stickler syndrome families associated with COL11A1 mutations