Mizuyo Kojima

jumonji Downregulates Cardiac Cell Proliferation by Repressing cyclin D1 Expression

Spatiotemporal regulation of cell proliferation is necessary for normal tissue development. The molecular mechanisms, especially the signaling pathways controlling the cell cycle machinery, remain largely unknown. Here, we demonstrate a negative relationship between the spatiotemporal patterns of jumonji (jmj) expression and cardiac myocyte proliferation. cyclin D1 expression and cell proliferation are enhanced in the cardiac myocytes of jmj-deficient mutant embryos. In contrast, jmj overexpression represses cyclin D1 expression in cardiac cells, and Jmj protein binds to cyclin D1 promoter in vivo and represses its transcriptional activity. cyclin D1 overexpression causes hyperproliferation in the cardiac myocytes, but the absence of cyclin D1 in jmj mutant embryos rescues the hyperproliferation. Therefore, Jmj might control cardiac myocyte proliferation and consequently cardiac morphogenesis by repressing cyclin D1 expression.

jumonji gene is essential for the neurulation and cardiac development of mouse embryos with a C3H/He background.

The recessive mutant mouse jumonji (jmj), obtained by a gene trap strategy, shows neural tube defects in approximately half of homozygous embryos with a BALB/cA and 129/Ola mixed background, but no neural tube defects with BALB/cA, C57BL/6J, and DBA/2J backgrounds. Here, we show that neural tube and cardiac defects are observed in all embryos with a C3H/HeJ background. In addition, abnormal groove formation and prominent flexure are observed on the neural plate with full penetrance, suggesting that abnormal groove formation leads to neural tube defects. We found morphogenetic abnormalities in the bulbus cordis (future outflow tract and the right ventricle) of homozygous embryo hearts. Moreover, myocytes in the ventricular trabeculae show hyperplasia with cells filling the ventricles. Together with the observation that the jmj gene is expressed in the neural epithelium of the head neural plate and in myocytes in the bulbus cordis and trabeculae, the results show that the jmj gene plays essential roles in the normal development of the neural plate, morphogenesis of bulbus cordis, and proliferation of trabecular myocytes on a C3H/He background.

Organogenesis of the liver, thymus and spleen is affected in jumonji mutant mice

The recessive mutant mouse jumonji (jmj), obtained by a gene trap strategy, shows neural tube defects in approximately half of homozygotes with a Balb/cA and 129/Ola mixed background. Here, we show that no neural tube defects are observed with a Balb/cA background. We also found hypoplasia of the liver, thymus and spleen with full penetrance with a Balb/cA background. In the livers of homozygous embryos we found excessive cell death in the peripheral region. In both the thymus and spleen, the accumulation of hematopoietic cells is affected in mutant embryos. These phenotypes were also observed with C57BL/6J and DBA/2J backgrounds, suggesting that the jmj gene plays an essential role in the organogenesis of these tissues.

A Jumonji (Jarid2) Protein Complex Represses cyclin D1 Expression by Methylation of Histone H3-K9

Covalent modifications of histone tails have critical roles in regulating gene expression. Previously, we identified the jumonji (jmj, Jarid2) gene, the jmjC domain, and a Jmj family. Recently, many Jmj family proteins have been shown to be histone demethylases, and jmjC is the catalytic domain. However, Jmj does not have histone demethylase activity because the jmjC domain lacks conserved residues for binding to cofactors. Independently of these studies, we previously showed that Jmj binds to the cyclin D1 promoter and represses the transcription of cyclin D1. Here, we show the mechanisms by which Jmj represses the transcription of cyclin D1. We found that a protein complex of Jmj had histone methyltransferase activity toward histone H3 lysine 9 (H3-K9). We also found that Jmj bound to the H3-K9 methyltransferases G9a and GLP. Expression of Jmj recruited G9a and GLP to the cyclin D1 promoter and increased H3-K9 methylation. Inactivation of both G9a and GLP, but not of only G9a, inhibited the methylation of H3-K9 in the cyclin D1 promoter and repression of cyclin D1 expression by Jmj. These results suggest that Jmj methylates H3-K9 and represses cyclin D1 expression through G9a and GLP, and that Jmj family proteins can regulate gene expression by not only histone demethylation but also other histone modification.

Area- and lamina-specific organization of a neuronal subpopulation defined by expression of latexin in the rat cerebral cortex.

The aim of the present study was to investigate the density, laminar distribution, size, morphology, and neurotransmitter phenotype of rat cortical neurons expressing latexin, an inhibitor of carboxypeptidase A. Immunohistochemical analyses established that latexin-immunoreactive neurons are restricted essentially to the infragranular layers of lateral cortical areas in the rat. The overall density, laminar or sublaminar localization, and cell size distribution of latexin-positive neurons differed substantially across cytoarchitectonic areas within lateral cortex. Numerous latexin-positive neurons had the morphology of modified pyramidal cells especially of layer VI. The vast majority of latexin-positive neurons were glutamate-immunoreactive in the six lateral neocortical areas examined, while neurons immunoreactive for both latexin and GABA were virtually absent. Thus the majority of latexin-positive neurons are likely to be excitatory projection neurons. The area- and lamina-specific distribution of the latexin-expressing subpopulation of glutamate-immunoreactive neurons is a distinctive feature that may contribute to the functional specialization of the lateral cortical areas.

Coordinated regulation of differentiation and proliferation of embryonic cardiomyocytes by a jumonji (Jarid2)-cyclin D1 pathway

In general, cell proliferation and differentiation show an inverse relationship, and are regulated in a coordinated manner during development. Embryonic cardiomyocytes must support embryonic life by functional differentiation such as beating, and proliferate actively to increase the size of the heart. Therefore, progression of both proliferation and differentiation is indispensable. It remains unknown whether proliferation and differentiation are related in these embryonic cardiomyocytes. We focused on abnormal phenotypes, such as hyperproliferation, inhibition of differentiation and enhanced expression of cyclin D1 in cardiomyocytes of mice with mutant jumonji (Jmj, Jarid2), which encodes the repressor of cyclin D1. Analysis of Jmj/cyclin D1 double mutant mice showed that Jmj was required for normal differentiation and normal expression of GATA4 protein through cyclin D1. Analysis of transgenic mice revealed that enhanced expression of cyclin D1 decreased GATA4 protein expression and inhibited the differentiation of cardiomyocytes in a CDK4/6-dependent manner, and that exogenous expression of GATA4 rescued the abnormal differentiation. Finally, CDK4 phosphorylated GATA4 directly, which promoted the degradation of GATA4 in cultured cells. These results suggest that CDK4 activated by cyclin D1 inhibits differentiation of cardiomyocytes by degradation of GATA4, and that initiation of Jmj expression unleashes the inhibition by repression of cyclin D1 expression and allows progression of differentiation, as well as repression of proliferation. Thus, a Jmj-cyclin D1 pathway coordinately regulates proliferation and differentiation of cardiomyocytes.

Histone H3 lysine 9 methyltransferases, G9a and GLP are essential for cardiac morphogenesis.

Lysine methylation of the histone tail is involved in a variety of biological events. G9a and GLP are known as major H3-K9 methyltransferases and contribute to transcriptional silencing. The functions of these genes in organogenesis remain largely unknown. Here, we analyzed the phenotypes of cardiomyocyte specific GLP knockout and G9a knockdown (GLP-KO/G9a-KD) mice. The H3-K9 di-methylation level decreased markedly in the nuclei of the cardiomyocytes of GLP-KO/G9a-KD mice, but not single G9a or GLP knockout mice. In addition, GLP-KO/G9a-KD mice showed neonatal lethality and severe cardiac defects (atrioventricular septal defects, AVSD). We also showed that hypoplasia in the atrioventricular cushion, which is a main part of the atrioventricular septum, caused AVSD. Expression analysis revealed downregulation of 2 AVSD related genes and upregulation of several non-cardiac specific genes in the hearts of GLP-KO/G9a-KD mice. These data indicate that G9a and GLP are required for sufficient H3-K9 di-methylation in cardiomyocytes and regulation of expression levels in multiple genes. Moreover, our findings show that G9a and GLP have an essential role in normal morphogenesis of the atrioventricular septum through regulation of the size of the atrioventricular cushion.

A role of jumonji gene in proliferation but not differentiation of megakaryocyte lineage cells

In this study, megakaryocytopoiesis was investigated in the recessive mutant mouse, jumonji, obtained by a gene-trap strategy. We investigated the number of megakaryocyte progenitors in the fetal liver, yolk sac, and peripheral blood of jumonji homozygous embryos by in vitro colony forming assay and monitored colony formation from single megakaryocyte progenitors. We also investigated the differentiation of jumonji-deficient megakaryocytes in terms of the expression of megakaryocyte differentiation markers PF4, CD62P, and GATA-1, proplatelet formation, cytoplasmic maturation, and endomitosis. We found that the population of megakaryocyte progenitors in the fetal liver, yolk sac, and peripheral blood of jumonji homozygotes increased. A fraction of megakaryocyte progenitors derived from the fetal liver of jumonji homozygotes formed larger colonies in vitro when compared with controls. This abnormality is caused by delayed growth arrest in the progeny. Immature megakaryocyte progenitors showed this abnormality. The megakaryocytes of jumonji homozygotes expressed PF4, CD62P, and GATA-1, obtained cytoplasmic maturation, extended proplatelet-like processes, and underwent endomitosis. The loss of the jumonji gene causes an increase in the number of megakaryocyte lineage cells. Our data suggest that the jumonji gene regulates proliferation but not differentiation of megakaryocyte lineage cells.

Enhancement by estrogen treatment of -bungarotoxin binding in fetal mouse amygdala cells reaggregated in vitro

Dissociated amygdala cells from 17-day-old mouse fetuses were cultivated in a flask for 7 days to form aggregates. In the aggregates there developed typical synaptic structures and [125I]alpha-bungarotoxin binding capacity. An addition of estradiol (100 ng/ml) in the culture medium caused a significant increase in the toxin binding capacity. From these results it is concluded that estradiol enhances alpha-bungarotoxin binding capacity in the amygdala by exerting direct effects on the developing amygdala cells.