X-linked microtubule-associated protein, Mid1, regulates axon development

Opitz syndrome (OS) is a genetic neurological disorder. The gene responsible for the X-linked form of OS, Midline-1 (MID1), encodes an E3 ubiquitin ligase that regulates the degradation of the catalytic subunit of protein phosphatase 2A (PP2Ac). However, how Mid1 functions during neural development is largely unknown. In this study, we provide data from in vitro and in vivo experiments suggesting that silencing Mid1 in developing neurons promotes axon growth and branch formation, resulting in a disruption of callosal axon projections in the contralateral cortex. In addition, a similar phenotype of axonal development was observed in the Mid1 knockout mouse. This defect was largely due to the accumulation of PP2Ac in Mid1-depleted cells as further down-regulation of PP2Ac rescued the axonal phenotype. Together, these data demonstrate that Mid1-dependent PP2Ac turnover is important for normal axonal development and that dysregulation of this process may contribute to the underlying cause of OS

A yeast model of Down syndrome

The recent discovery that cellular proliferation was reduced in aneuploid haploid yeast supports a long-standing argument that the developmental neurophenotype of Down syndrome is not uniquely a result of the effects of increased gene dosage. Instead, some phenotypic outcomes appear to resemble those caused by disrupted cellular homeostasis induced by aneuploidy. Decreased cellular proliferation has been identified in the cerebellum and hippocampus of Down syndrome mouse models and in the post-mortem hippocampus and germinal matrix of Down syndrome fetuses. Consistent with predominantly stochastic gene expression and increased energy demands induced by aneuploidy, the "buffering" canalization processes in Down syndrome would be reduced thereby giving rise to increased variance to less stable developmental pathways such as proliferation. The nature and extent of phenotypes due to reduced canalization would depend on the tissue; which is also a question for future research to address. A conceptual model is presented here to demonstrate the nature of influences affecting phenotypes. Ultimately, in Down syndrome, exigent periods of neurodevelopment increasingly appear to reflect the burden of disrupted homeostasis

Emerging Signalling and Protein Interactions Mediated Via Metabotropic Glutamate Receptors

Metabotropic glutamate receptors (mGlu) are GTP-binding (G) protein-coupled receptors (GPCRs) that are involved in learning and memory, cardiovascular control and motor function. Their structure and pharmacology has been reviewed recently in Current Drug Targets: CNS and Neurological Disorders (Vol. 1, Issue 3) where their roles in a variety of neurological disorders were highlighted. The present review focuses on the emerging evidence for interactions of mGlu receptors with other GPCRs in the CNS at the membrane interface and amongst signaling cascades in the cytosol (e.g. intracellular Ca2+, cAMP and scaffolding proteins). While initially non-selective activity was thought to be responsible for many atypical responses, increasing evidence points to GPCR interactions in neurons and glia, with adrenoceptors, adenosine receptors, dopamine receptors and muscarinic receptors. For example, group II mGlu receptors were found to be required for group I mGlu receptor induction of long-term potentiation at the postsynaptic terminal. Increasing evidence demonstrates the intimate interaction of adenosine receptors and mGlu receptors, particularly in the regulation of neurotransmitter release. While adenosine itself can be released from astrocytes by co-activation of group II mGlu and bgr-adrenergic receptors. Given the complexity of neurological disorders such as ischemic stroke, Alzheimer's disease and epilepsy, exploitation mGlu receptor-associated GPCR interactions may prove efficacious in the treatment of such disorder

Transmembrane protein 50b (C21orf4), a candidate for Down syndrome neurophenotypes, encodes an intracellular membrane protein expressed in the rodent brain

Transmembrane protein 50b, Tmem50b, previously referred to as C21orf4, encodes a predicted transmembrane protein and is one of few genes significantly over-expressed during cerebellar development in a Down syndrome mouse model, Ts1Cje. In order to assess potential mechanisms by which Tmem50b could contribute to Down syndrome–related phenotypes, we determined the expression patterns of Tmem50b mRNA, as well as Tmem50b protein distribution, expression and subcellular localization. In situ hybridization in mice at embryonic day 14.5 showed cortical plate and spinal cord mRNA expression. By postnatal day 7, strong mRNA expression was seen in the cerebellum, hippocampus and olfactory bulb, with diffuse cortical expression. Quantitative PCR of adult mouse tissue showed Tmem50b mRNA expression in the brain, heart and testis. A rabbit polyclonal antibody was generated against Tmem50b and rat and mouse tissue screening by Western blot, and immunohistochemistry showed that protein expression concurred with mRNA expression. Double immunofluorescence revealed that Tmem50b is highly expressed in rat and mouse glial fibrillary acidic protein–positive cells in vivo and in vitro, but less so in neuronal MAP2- or β-tubulin II-positive cells in vitro. Tmem50b is invariably expressed in cultured mouse neural precursor cells. In adult mouse cerebellum sections, Tmem50b immunoreactivity was found in Purkinje and Golgi cell somata and in Bergmann glial processes. Electron microscopy confirmed that Tmem50b was present on endoplasmic reticulum (ER) and Golgi apparatus membranes. Results indicate that Tmem50b is a developmentally-regulated intracellular ER and Golgi apparatus membrane protein that may prove important for correct brain development through functions associated with precursor cells and glia

Formation of functional areas in the cerebral cortex is disrupted in a mouse model of autism spectrum disorder

Background: Autism spectrum disorders (ASD) are a group of poorly understood behavioural disorders, which have increased in prevalence in the past two decades. Animal models offer the opportunity to understand the biological basis of these disorders. Studies comparing different mouse strains have identified the inbred BTBR T + tf/J (BTBR) strain as a mouse model of ASD based on its anti-social and repetitive behaviours. Adult BTBR mice have complete agenesis of the corpus callosum, reduced cortical thickness and changes in early neurogenesis. However, little is known about the development or ultimate organisation of cortical areas devoted to specific sensory and motor functions in these mice that may also contribute to their behavioural phenotype

The cerebellar transcriptome during postnatal development of the Ts1Cje mouse, a segmental trisomy model for Down syndrome

The central nervous system of persons with Down syndrome presents cytoarchitectural abnormalities that likely result from gene-dosage effects affecting the expression of key developmental genes. To test this hypothesis, we have investigated the transcriptome of the cerebellum of the Ts1Cje mouse model of Down syndrome during postnatal development using microarrays and quantitative PCR (qPCR). Genes present in three copies were consistently overexpressed, with a mean ratio relative to euploid of 1.52 as determined by qPCR. Out of 63 three-copy genes tested, only five, nine and seven genes had ratios >2 o