Additive dominant effect of a SOX10 mutation underlies a complex phenotype of PCWH.

Distinct classes of SOX10 mutations result in peripheral demyelinating neuropathy, central dysmyelinating leukodystrophy, Waardenburg syndrome, and Hirschsprung disease, collectively known as PCWH. Meanwhile, SOX10 haploinsufficiency caused by allelic loss-of-function mutations leads to a milder non-neurological disorder, Waardenburg-Hirschsprung disease. The cellular pathogenesis of more complex PCWH phenotypes in vivo has not been thoroughly understood. To determine the pathogenesis of PCWH, we have established a transgenic mouse model. A known PCWH-causing SOX10 mutation, c.1400del12, was introduced into mouse Sox10-expressing cells by means of bacterial artificial chromosome (BAC) transgenesis. By crossing the multiple transgenic lines, we examined the effects produced by various copy numbers of the mutant transgene. Within the nervous systems, transgenic mice revealed a delay in the incorporation of Schwann cells in the sciatic nerve and the terminal differentiation of oligodendrocytes in the spinal cord. Transgenic mice also showed defects in melanocytes presenting as neurosensory deafness and abnormal skin pigmentation, and a loss of the enteric nervous system. Phenotypes in each lineage were more severe in mice carrying higher copy numbers, suggesting a gene dosage effect for mutant SOX10. By uncoupling the effects of gain-of-function and haploinsufficiency in vivo, we have demonstrated that the effect of a PCWH-causing SOX10 mutation is solely pathogenic in each SOX10-expressing cellular lineage in a dosage-dependent manner. In both the peripheral and central nervous systems, the primary consequence of SOX10 mutations is hypomyelination. The complex neurological phenotypes in PCWH patients likely result from a combination of haploinsufficiency and additive dominant effect.

A sharp cadherin-6 gene expression boundary in the developing mouse cortical plate demarcates the future functional areal border.

The mammalian cerebral cortex can be tangentially subdivided into tens of functional areas with distinct cyto-architectures and neural circuitries; however, it remains elusive how these areal borders are genetically elaborated during development. Here we establish original bacterial artificial chromosome transgenic mouse lines that specifically recapitulate cadherin-6 (Cdh6) mRNA expression profiles in the layer IV of the somatosensory cortex and by detailing their cortical development, we show that a sharp Cdh6 gene expression boundary is formed at a mediolateral coordinate along the cortical layer IV as early as the postnatal day 5 (P5). By further applying mouse genetics that allows rigid cell fate tracing with CreERT2 expression, it is demonstrated that the Cdh6 gene expression boundary set at around P4 eventually demarcates the areal border between the somatosensory barrel and limb field at P20. In the P6 cortical cell pellet culture system, neurons with Cdh6 expression preferentially form aggregates in a manner dependent on Ca(2+) and electroporation-based Cdh6 overexpression limited to the postnatal stages perturbs area-specific cell organization in the barrel field. These results suggest that Cdh6 expression in the nascent cortical plate may serve solidification of the protomap for cortical functional areas.

Bacterial artificial chromosomes as analytical basis for gene transcriptional machineries.

Bacterial Artificial Chromosomes (BACs) had been minimal components of various genome-sequencing projects, constituting perfect analytical basis for functional genomics. Here we describe an enhancer screening strategy in which BAC clones that cover any genomic segments of interest are modified to harbor a reporter cassette by transposon tagging, then processed to carry selected combinations of gene regulatory modules by homologous recombination mediated systematic deletions. Such engineered BAC-reporter constructs in bacterial cells are ready for efficient transgenesis in mice to evaluate activities of gene regulatory modules intact or absent in the constructs. By utilizing the strategy, we could speedily identify a critical genomic fragment for spatio-temporally regulated expression of a mouse cadherin gene whose structure is extraordinarily huge and intricate. This BAC-based methodology would hence provide a novel screening platform for gene transcriptional machineries that dynamically fluctuate during development, pathogenesis and/or evolution.

Classic cadherin expressions balance postnatal neuronal positioning and dendrite dynamics to elaborate the specific cytoarchitecture of the mouse cortical area.

A unique feature of the mammalian cerebral cortex is in its tangential parcellation via anatomical and functional differences. However, the cellular and/or molecular machinery involved in cortical arealization remain largely unknown. Here we map expression profiles of classic cadherins in the postnatal mouse barrel field of the primary somatosensory area (S1BF) and generate a novel bacterial artificial chromosome transgenic (BAC-Tg) mouse line selectively illuminating nuclei of cadherin-6 (Cdh6)-expressing layer IV barrel neurons to confirm that tangential cellular assemblage of S1BF is established by postnatal day 5 (P5). When we electroporate the cadherins expressed in both barrel neurons and thalamo-cortical axon (TCA) terminals limited to the postnatal layer IV neurons, S1BF cytoarchitecture is disorganized with excess elongation of dendrites at P7. Upon delivery of dominant negative molecules for all classic cadherins, tangential cellular positioning and biased dendritic arborization of barrel neurons are significantly altered. These results underscore the value of classic cadherin-mediated sorting among neuronal cell bodies, dendrites and TCA terminals in postnatally elaborating the S1BF-specific tangential cytoarchitecture. Additionally, how the "protocortex" machinery affects classic cadherin expression profiles in the process of cortical arealization is examined and discussed.