Effect of immunosuppressants on a mouse model of osteogenesis imperfecta type V harboring a heterozygous Ifitm5 c.-14C > T mutation.

Osteogenesis imperfecta (OI) type V is an autosomal dominant disorder caused by the c.-14C > T mutation in the interferon-induced transmembrane protein 5 gene (IFITM5), however, its onset mechanism remains unclear. In this study, heterozygous c.

Neu-medullocytes, sialidase-positive B cells in the thymus, express autoimmune regulator (AIRE).

Neu-medullocytes, which were previously identified and named by our group, are sialidase (neuraminidase)-positive B cells that express immunoglobulin and Mac-1 in the mouse thymus. Recently, B cells that migrated into the thymus were reported to express autoimmune regulator (AIRE) and to contribute to self-tolerance. We sought to determine whether Neu-medullocytes also express AIRE.

Tetraploidy-associated centrosome overduplication in mouse early embryos.

Recently, we observed that tetraploidization of certain types of human cancer cells resulted in upregulation of centrosome duplication cycles and chronic generation of the extra centrosome. Here, we investigated whether tetraploidy-linked upregulation of centrosome duplication also occurs in non-cancer cells using tetraploidized parthenogenetic mouse embryos. Cytokinesis blockage at early embryonic stage before de novo centriole biogenesis provided the unique opportunity in which tetraploidization can be induced without transient doubling of centrosome number.

Existence of NEU1 sialidase on mouse thymocytes whose natural substrate is CD5.

Membrane-bound sialidases in the mouse thymus are unique and mysterious because their activity at pH 6.5 is equal to or higher than that in the acidic region. The pH curve like this has never been reported in membrane-bound form.

Uncoordinated centrosome cycle underlies the instability of non-diploid somatic cells in mammals.

In animals, somatic cells are usually diploid and are unstable when haploid for unknown reasons. In this study, by comparing isogenic human cell lines with different ploidies, we found frequent centrosome loss specifically in the haploid state, which profoundly contributed to haploid instability through subsequent mitotic defects. We also found that the efficiency of centriole licensing and duplication changes proportionally to ploidy level, whereas that of DNA replication stays constant.

A comprehensive glycome profiling of Huntington's disease transgenic mice.

Background: Huntington's disease (HD) is an autosomal, dominantly inherited and progressive neurodegenerative disease, nosologically classified as the presence of intranuclear inclusion bodies and the loss of GABA-containing neurons in the neostriatum and subsequently in the cerebellar cortex. Abnormal processing of neuronal proteins can result in the misfolding of proteins and altered post-translational modification of newly synthesized proteins. Total glycomics, namely, N-glycomics, O-glycomics, and glycosphingolipidomics (GSL-omics) of HD transgenic mice would be a hallmark for central nervous system disorders in order to discover disease specific biomarkers.