Hiroharu Shiba

Bio: Hiroharu Shiba is an academic researcher from Kindai University. The author has contributed to research in topics: Gonadotropic cell & Hypothalamus. The author has an hindex of 1, co-authored 1 publications receiving 324 citations.

Developmental defects of the ventromedial hypothalamic nucleus and pituitary gonadotroph in the Ftz‐F1 disrupted mice

Abstract: Ad4BP (or SF-1) has been iden- tified as a transcription factor which regulates all the steroidogenic P450 genes in the peripheral or- gans, and is encoded by the mammalian homo- logue of Drosophila FTZ-F1 gene. mRNA coding for Ad4BP was detected in the hypothalamus and pituitary of rats by RT-PCR. Immunohistochemi- cal analyses using an antiserum to Ad4BP in the brain and pituitary revealed that the transcrip- tion factor is expressed in nuclei of the dorso- medial part of the ventromedial hypothalamus (dmVMH) and in some subpopulation of the ade- nohypophysial cells. Double immunostaining of the pituitary for Ad4BP and trophic peptide hor- mones, FSH, TSH, and ACTH, indicated a re- stricted localization of Ad4BP to the gonadotroph. Disruption of the mouse Ftz-FI gene was clarified to induce severe defects in the organization of the dmVMH and the function of the pituitary gona- dotroph. However, some of the dm VMH neurons and pituitary gonadotrophs persisted, which pro- vided a sharp contrast to complete agenesis of the peripheral steroidogenic tissues (adrenal and go- nads) in the mutant mouse. Additional abnormal- ities were seen in the ventrolateral part of VMH and dorsomedial hypothalamic nucleus, both of which do not express Ad4BP but have strong reciprocal fiber-connections with the dmVMH. Aromatase P450-containing cells in the medial preoptico-amygdaloid region, which were devoid of Ad4BP, persisted even in the brain of the gene disrupted mice. The present results clearly showed that the hypothalamic and pituitary Ad4BPs are essential to normal development of the functional VMH and gonadotroph through some mechanism distinct from that in the periph-

Orphan nuclear receptors: from gene to function.

Abstract: I. Introduction II. Nuclear Receptors: General Concepts A. Anatomy of nuclear receptors B. Mechanisms of action III. Orphan Nuclear Receptors A. Definition B. Nomenclature C. Structural and functional diversity IV. Novel Hormone Response Systems: RXR and Its Heterodimeric Partners A. RXR: rexinoids B. PPAR: multiple ligands, multiple functions C. PXR: pregnanes, xenobiotic compounds, and benzoate derivatives D. CAR (constitutive androstane receptor): androstanes and phenobarbital E. LXR: control of cholesterol metabolism by oxysterols F. FXR: bile acids receptor V. Orphans in Search of a Home A. HNF4: diabetes and possible regulation by acyl-coenzyme A (CoA) thioesters B. FTZ-F1: steroidogenesis and sexual development C. Rev-Erb: singular members of the superfamily D. ROR: neuron development and T cell selection E. TR2: the testis receptors F. TLX: forebrain development G. COUP-TF: neurogenesis, angiogenesis, and heart development H. ERR: placenta development and control of lipid metabolism I. NGFI-B: hyp...

Steroidogenic Factor 1: A Key Determinant of Endocrine Development and Function

Abstract: I. Introduction II. The Initial Identification of SF-1 as a Key Determinant of Steroid Hormone Biosynthesis A. Overview of steroidogenesis B. SF-1 and the regulation of steroidogenesis C. Cloning and structural characterization of SF-1 1. Structural features of SF-1 2. Multiple transcripts are encoded by the gene encoding SF-1 3. The gene encoding SF-1 is evolutionarily conserved in vertebrates and invertebrates III. Characterization of Sites of SF-1 Expression and Identification of Its Target Genes A. Profiles of SF-1 expression 1. Adult steroidogenic tissues 2. Embryonic steroidogenic tissues 3. Other sites of SF-1 expression B. Target genes regulated by SF-1 1. Steroidogenic cells 2. Sertoli cells 3. Gonadotropes 4. VMH IV. The Roles Of SF-1 in Vivo: Targeted Gene Disruption to Create SF-1 Knockout Mice A. General features of the SF-1 knockout mice B. Primary steroidogenic tissues in SF-1 knockout mice C. Pituitary and hypothalamic defects in SF-1 knockout mice V. Perspectives and Future Directions A. ...

Sex Determination and Gonadal Development in Mammals

Abstract: Arguably the most defining moment in our lives is fertilization, the point at which we inherit either an X or a Y chromosome from our father. The profoundly different journeys of male and female life are thus decided by a genetic coin toss. These differences begin to unfold during fetal development, when the Y-chromosomal Sry ("sex-determining region Y") gene is activated in males and acts as a switch that diverts the fate of the undifferentiated gonadal primordia, the genital ridges, towards testis development. This sex-determining event sets in train a cascade of morphological changes, gene regulation, and molecular interactions that directs the differentiation of male characteristics. If this does not occur, alternative molecular cascades and cellular events drive the genital ridges toward ovary development. Once testis or ovary differentiation has occurred, our sexual fate is further sealed through the action of sex-specific gonadal hormones. We review here the molecular and cellular events (differentiation, migration, proliferation, and communication) that distinguish testis and ovary during fetal development, and the changes in gene regulation that underpin these two alternate pathways. The growing body of knowledge relating to testis development, and the beginnings of a picture of ovary development, together illustrate the complex mechanisms by which these organ systems develop, inform the etiology, diagnosis, and management of disorders of sexual development, and help define what it is to be male or female.