Glycine Transporter Blockade Ameliorates Motor Ataxia in a Mouse Model of Spinocerebellar Atrophy

Pelvic axis-based gait analysis for ataxic mice

BACKGROUND

Although different gait analysis methods such as Walking Track Analysis exist, they cannot be used to demonstrate the physical condition of mice with specific gait disorder characteristic. Therefore, we developed a new method for the gait analysis of such mice to accurately assess hind limb angle based on the pelvic axis.

NEW METHOD

We established and verified a gait analysis method capable of pelvic axis-based limb angle measurement by video-recording the gait of a control mice group (C57BL/6J(B6)) and three ataxic mice (ataxic B6-wob/t, Parkinson's disease model (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine treated (MPTP)), and cerebellum hypoplasia (cytosine-β-d-arabinofuranoside treated)) from the ventral side.

RESULTS

The assessed hind limb angles of B6-wob/t and MPTP-treated mice were significantly wider than B6 mice (p<0.01). Moreover, we could draw separating lines with slopes of minus one that could separate the data of each group in the scatter plot of the normalized hind limb step width and angle.

COMPARISON WITH EXISTING METHODS

We found no significance when we applied the already existing nose-tail method for the analysis of the hind limb angles of B6 and B6-wob/t mice. In the nose-tail method, since the whole body axis of the trunk varies while the trunk of the mouse is laterally bent changing the hind limb angle, B6 and B6-wob/t mice could not be differentiated. However, the two mice groups could be differentiated by the pelvic axis-based gait analysis method.

CONCLUSION

The pelvic axis-based gait analysis method is promising and valid for mice with gait disorder.

Computational prediction of the polyQ and CAG repeat spinocerebellar ataxia network based on sequence identity to untranslated regions

Computational prediction of biological networks would be a tremendous asset to systems biology and personalized medicine. In this paper, we use a moving window bioinformatic screen to identify transcripts with partial identity to the 5' and 3'UTRs of the polyQ spinocerebellar ataxia (SCA) genes ATXN1, ATXN2, ATXN3, ATXN7, TBP and CACNA1A and the CAG repeat expansion gene PPP2R2B. We find that the bioinformatic screen enriches for transcripts that encode proteins that interact and that have functions relevant to polyQ SCA. Transcription control and RNA binding are the primary functional groups represented in the proteins from the combined screens. The insulin growth factor pathway, the WNT pathway, long term potentiation, melanogenesis and ATM mediated DNA repair pathways were identified as important pathways. UGUUU repeats were identified as an abundant motif in the SCA network and PAXIP1, CELF2, CREBBP, EBF1, PLEKHG4, SRSF4, C5orf42, NFIA, STK24, and YWHAG were identified as statistically significant proteins in the polyQ and PPP2R2B network.

Timing-dependent reduction in ethanol sedation and drinking preference by NMDA receptor co-agonist d-serine

NMDA receptors become a major contributor to acute ethanol intoxication effects at high concentrations as ethanol binds to a unique site on the receptor and inhibits glutamatergic activity in multiple brain areas. Although a convincing body of literature exists on the ability of NMDA receptor antagonists to mimic and worsen cellular and behavioral ethanol effects, receptor agonists have been less well-studied. In addition to a primary agonist site for glutamate, the NMDA receptor contains a separate co-agonist site that responds to endogenous amino acids glycine and d-serine. d-serine is both selective for this co-agonist site and potent in boosting NMDA dependent activity even after systemic administration. In this study, we hypothesized that exogenous d-serine might ameliorate some acute ethanol behaviors by opposing NMDA receptor inhibition. We injected adult male C57 mice with a high concentration of d-serine at various time windows relative to ethanol administration and monitored sedation, motor coordination and voluntary ethanol drinking. d-serine (2.7 g/kg, ip) prolonged latency to a loss of righting reflex (LoRR) and shortened LoRR duration when given 15 min before ethanol (3 g/kg) but not when it was injected with or shortly after ethanol. Blood samples taken at sedative recovery and at fixed time intervals revealed no effect of d-serine on ethanol concentration but an ethanol-induced decrease in l-serine and glycine content was prevented by acute d-serine pre-administration. d-serine had no effect on ethanol-induced (2 g/kg) rotarod deficits in young adult animals but independently and interactively degraded motor performance in a subset of older mice. Finally, a week-long series of daily ip injections resulted in a 50% decrease in free choice ethanol preference for d-serine treated animals compared to saline-injected controls in a two-bottle choice experiment.

Human umbilical mesenchymal stem cells enhance the expression of neurotrophic factors and protect ataxic mice

Cerebellar ataxias, which comprise a wide spectrum of progressive disorders, are incurable at present. It has been reported that human umbilical mesenchymal stem cell (HU-MSC) transplantation has a protective effect on neurodegenerative diseases. In this study, we investigated the effect of HU-MSCs on ataxic mice induced by cytosine beta-D-arabinofuranoside (Ara-C). The ataxic mouse received an intravenous injection of 2×10(6) HU-MSCs once a week for three consecutive weeks. Neurological function was scored weekly by rotarod test and open field test. The mouse cerebellar volume and weight were also measured. The apoptotic cells, pathological alternations and distribution of HU-MSCs were determined by TUNEL assay and immunohistochemistry staining respectively. Double immunostaining was carried out to investigate the dynamics of HU-MSCs in the host animals. Neurotrophic factors in cerebellar tissue and serum were measured by Q-PCR and ELISA. Our results showed that HU-MSCs implantation significantly improved the motor skills of ataxic mice 8 weeks after application. HU-MSCs also alleviated cerebellar atrophy and decreased the number of apoptotic cells in the therapeutic group. Implanted HU-MSCs stayed in cerebellum for at least three months with no obvious differentiation. HU-MSC treated mice had enhanced expression of insulin-like growth factor-1 (IGF-1) and vascular endothelial growth factor (VEGF) in cerebellum extraction and blood serum. Double immunostaining revealed that a few MAB1287 positive cells co-localized with IGF-1 or VEGF express cells. Our results suggest that HU-MSC treatment is capable of alleviating the motor impairments and cerebellar atrophy in the ataxic mouse model, probably via promoting particular neurotrophic factors.

Longitudinal tracking of gait and balance impairments in cerebellar disease

Cerebellar damage typically results in ataxia and can be caused by stroke, tumor, or one of many forms of degenerative disease. Since few pharmacological options are available, most treatments rely heavily on rehabilitation therapy. Little data exist on methods for tracking the progression of ataxia, which is critical for assessing the efficacy of current and newly developing treatments. Here, we tracked the severity of ataxia, with a particular emphasis on gait and balance dysfunction, in a group of individuals with cerebellar damage using the International Cooperative Ataxia Rating Scale (ICARS) and several instrumented laboratory measures of gait and balance impairments over 1 year. We found that the ICARS was able to distinguish between subjects with static lesions and those with degenerative disorders, was sensitive to increases in ataxia severity occurring over 1 year, and correlated well with specific instrumented measures of gait in persons with cerebellar degeneration. These results suggest the ICARS is a valuable tool for clinicians and investigators to document and track long-term changes in gait and balance performance in individuals with cerebellar degenerative disorders.