The stress of starvation: glucocorticoid restraint of beta cell development.

Developmental insults during gestation, such as under-nutrition, are known to restrict the number of beta cells that form in the fetal pancreas and are maintained in adulthood, leading to increased risk of type 2 diabetes. There are now substantial data indicating that glucocorticoids mediate this effect of under-nutrition on beta cell mass and that even at physiological levels they restrain fetal beta cell development in utero. There are emerging clues that this occurs downstream of endocrine commitment by neurogenin 3 but prior to terminal beta cell differentiation. Deciphering the precise mechanism will be important as it might unveil new pathways by which to manipulate beta cell mass that could be exploited as novel therapies for patients with diabetes.

Chronological expression of Ciliated Bronchial Epithelium 1 during pulmonary development.

Ciliated Bronchial Epithelium (CBE) 1 is a novel gene, which is expressed in ciliated cells. As cilia are important during embryogenesis, the present authors characterised the murine homologue of CBE1 (Cbe1) and compared its temporal expression during murine and human lung development. Cbe1 cDNA was cloned and characterised using sequencing, standard PCR and Western blotting. Mouse and human embryonic/fetal lungs (HELs) were harvested for mRNA analysis and protein localisation in vivo and in vitro using RT-PCR and immunohistochemistry. The Cbe1 amino acid sequence was >75% identical with CBE1 and its alternative splicing and tissue distribution were highly conserved. Pulmonary expression of Cbe1 mRNA was increased at embryonic day (E)16, 1 day later than Foxj1, which is consistent with a role in ciliogenesis. In HELs, CBE1 mRNA was detectable at 8-9 weeks post-conception and increased in explant culture. CBE1 protein expression was weak at 10 weeks post-conception but strong at 12.3 weeks post-conception, in parallel with cilia formation. Additionally, Cbe1 mRNA was expressed at E11 (4-5 weeks post-conception in HELs) in the absence of Foxj1, implying a distinct role in early development. Chronological regulation of CBE1/Cbe1 expression during pulmonary differentiation suggests involvement in ciliogenesis, with an additional role during early lung development.

Human embryo and early fetus research.

Studies of human embryos and fetuses have highlighted developmental differences between humans and model organisms. In addition to describing the normal biology of our own species, a justification in itself, studies of early human development have aided identification of candidate disease genes mapped by positional cloning strategies, understanding pathophysiology, where human disorders are not faithfully reproduced by models in other species, and, more recently, potential therapies based on human embryonic stem and embryonic germ cells. In this article, we review these applications. We also discuss when and how to study human embryo and early fetuses and some of the regulations of this research.

Beta cell differentiation during early human pancreas development.

Understanding gene expression profiles during early human pancreas development is limited by comparison to studies in rodents. In this study, from the inception of pancreatic formation, embryonic pancreatic epithelial cells, approximately half of which were proliferative, expressed nuclear PDX1 and cytoplasmic CK19. Later, in the fetal pancreas, insulin was the most abundant hormone detected during the first trimester in largely non-proliferative cells. At sequential stages of early fetal development, as the number of insulin-positive cell clusters increased, the detection of CK19 in these cells diminished. PDX1 remained expressed in fetal beta cells. Vascular structures were present within the loose stroma surrounding pancreatic epithelial cells during embryogenesis. At 10 weeks post-conception (w.p.c.), all clusters containing more than ten insulin-positive cells had developed an intimate relationship with these vessels, compared with the remainder of the developing pancreas. At 12-13 w.p.c., human fetal islets, penetrated by vasculature, contained cells independently immunoreactive for insulin, glucagon, somatostatin and pancreatic polypeptide (PP), coincident with the expression of maturity markers prohormone convertase 1/3 (PC1/3), islet amyloid polypeptide, Chromogranin A and, more weakly, GLUT2. These data support the function of fetal beta cells as true endocrine cells by the end of the first trimester of human pregnancy.

Novel SOX9 expression during human pancreas development correlates to abnormalities in Campomelic dysplasia.

Haploinsufficiency of SOX9, which encodes a homeodomain transcription factor, results in Campomelic dysplasia. Classical features of this disorder (e.g. skeletal dysplasia and 46,XY sex reversal) are in concordance with SOX9 expression profiles during human embryonic development. We report the robust expression of SOX9 throughout the pancreas during human embryogenesis, at levels of detection equivalent to the developing skeleton and testis. In the early foetal period, SOX9 expression declines and, in particular, is not apparent within the pancreatic islets. In keeping with this profile, examination of three cases with Campomelic dysplasia revealed abnormal pancreatic morphology. Epithelial cells were less densely packed within the mesenchymal stroma and islets less clearly formed with variable expression of hormone and beta cell markers. Taken together, these data indicate a novel potential role for SOX9 in pancreas development during human embryogenesis and early foetal life.

Steroidogenic enzyme expression within the adrenal cortex during early human gestation.

Aberrant adrenocortical function during the first trimester of human fetal development underlies the severe virilization of congenital adrenal hyperplasia due to cytochrome P450 21-hydroxylase (CYP21) deficiency. Although valuable information of human adrenocortical development after 12 weeks gestation is available, less is known earlier in pregnancy. In our studies, the adrenal cortex was first detected in human embryos by hematoxylin and eosin staining at 33 days post-conception (dpc) with distinction between the definitive and fetal zones possible at 52 dpc. Vascular development was apparent within the adrenal gland at 41 dpc. CYP11A and CYP17 were expressed centrally within the fetal zone at 50 dpc and all later time points during the first trimester. Weaker CYP11A immunoreactivity also was visible in the outer region of the adrenal cortex consistent with definitive zone expression. In this location, immunoreactivity was observed for 3beta-hydroxysteroid dehydrogenase and the proliferation marker, Ki67. These data raise the possibility of de novo cortisol biosynthesis during the first trimester of human development and are relevant to the pathophysiology of 46,XX virilization in CYP21 deficiency.

SF-1: a critical mediator of steroidogenesis.

Studies in knockout mice have established that the orphan nuclear receptor steroidogenic factor 1 (SF-1) plays essential roles in the development and function of the primary steroidogenic organs. These SF-1 knockout mice lacked adrenal glands and gonads, causing adrenocortical insufficiency and sex reversal of their internal and external genitalia. They also had impaired expression of pituitary gonadotropins and agenesis of the ventromedial hypothalamic nucleus (VMH), confirming roles of SF-1 at all three levels of the hypothalamic-pituitary-steroidogenic organ axis. Ongoing experiments are directed at developing methods to inactivate SF-1 in a tissue-specific manner.

Expression profiles of SF-1, DAX1, and CYP17 in the human fetal adrenal gland: potential interactions in gene regulation.

Cytochrome P450 17alpha-hydroxylase/17-20 lyase (P450(C17)) is a critical branchpoint enzyme for steroid hormone biosynthesis. During human gestation, P450(C17) is required for the production of dehydroepiandrostenedione sulfate by the fetal adrenal cortex and for testicular production of androgens that mediate male sexual differentiation. In this study, we investigate the regulation of the human CYP17 gene by two orphan nuclear receptors, steroidogenic factor 1 (SF-1) and DAX1. In human embryos, SF-1 and DAX1 are expressed throughout the developing adrenal cortex from its inception at 33 days post conception (dpc). In contrast, P450(C17) expression, which commences between 41 and 44 dpc, is limited to the fetal zone. The 5'-flanking region of the human CYP17 gene contains three functional SF-1 elements that collectively mediate a > or =25-fold induction of promoter activity by SF-1. In constructs containing all three functional SF-1 elements, DAX1 inhibited this activation by > or =55%. In the presence of only one or two SF-1 elements, DAX1 inhibition was lost even though SF-1 transactivation persisted. These data suggest that efficient repression of SF-1-mediated activation of the human CYP17 gene by DAX1 requires multiple SF-1 elements. Opposing effects of SF-1 and DAX1 may fine tune the differential responses of various SF-1 target genes in different endocrine tissues.

Steroidogenic factor 1 (SF-1) is essential for ovarian development and function.

The orphan nuclear receptor steroidogenic factor 1 (SF-1) was identified originally as a key regulator of the tissue-specific expression of the cytochrome P450 steroid hydroxylases. Hints at considerably broader roles for SF-1 came from analyses of its expression pattern in mouse embryos. As anticipated, SF-1 was expressed in the adrenal glands and gonads from their early stages of development. Surprisingly, SF-1 also was expressed outside of the primary steroidogenic tissues in the anterior pituitary and hypothalamus. SF-1 knockout mice dramatically confirmed its multiple essential roles in vivo. These mice lacked adrenal glands and gonads, leading to adrenocortical insufficiency and male-to-female sex reversal of their internal and external genitalia. SF-1 knockout mice also had impaired pituitary expression of gonadotropins and agenesis of the ventromedial hypothalamic nucleus (VMH), confirming roles of SF-1 at all three levels of the hypothalamic-pituitary-gonadal axis. With some focus on the ovary, this review summarizes experiments that have defined essential roles of SF-1 in endocrine development, and highlights important areas for future studies.

SRY, SOX9, and DAX1 expression patterns during human sex determination and gonadal development.

SRY, SOX9, and DAX1 are key genes in human sex determination, by virtue of their associated male-to-female sex reversal phenotypes when mutated (SRY, SOX9) or over-expressed (DAX1). During human sex determination, SRY is expressed in 46,XY gonads coincident with sex cord formation, but also persists as nuclear protein within Sertoli cells at 18 weeks gestation. High-level SOX9 expression in the sex cords of the testis parallels that seen during mouse development, however in humans, SOX9 transcripts also are detected in the developing ovary. Low-level DAX1 expression predates peak SRY expression by at least 10 days, and persists in Sertoli cells throughout the entire sex determination period. In Dosage Sensitive Sex reversal, the anti-testis properties of DAX1 over-expression could act prior to the peak effects of SRY and continue during the period of SOX9 expression. These findings highlight expression differences for the SRY, SOX9, and DAX1 genes during sex determination in humans and mice. These results provide a direct framework for future investigation into the mechanisms underlying normal and abnormal human sex determination.

Approaches to define the role of SF-1 at different levels of the hypothalamic-pituitary-steroidogenic organ axis.

Targeted gene disruption has produced knockout mice globally deficient in the orphan nuclear receptor steroidogenic factor 1 (SF-1). These SF-1 knockout mice lacked adrenal glands and gonads and consequently exhibited adrenocortical insufficiency and sex reversal of their internal and external genitalia. They also had impaired expression of gonadtropins in the anterior pituitary gonadotropes and agenesis of the ventromedial hypothalamic nucleus (VMH), confirming roles of SF-1 at all three levels of the hypothalamic-pituitary-steroidogenic organ axis. Ongoing experiments are directed at using evolving techniques for tissue-specific gene inactivation to define the roles of SF-1 within discrete sites of the hypthalamic-pituitary-steroidogenic organ axis.

Expression of steroidogenic factor 1 and Wilms' tumour 1 during early human gonadal development and sex determination.

The transcription factors SF-1 and WT1 play pivotal roles in mammalian gonadal development and sexual differentiation. In human embryos, both SF-1 and WT1 are expressed when the indifferent gonadal ridge first forms at 32 days post-ovulation. As the sex cords develop - providing morphological evidence of testis differentiation - SF-1 localises predominantly to developing Sertoli cells in the sex cords, whereas WT1 retains a broader pattern of expression. Later, SF-1 localises predominantly to steroidogenic Leydig cells, and WT1 localises to the sex cords. In the ovary, SF-1 and WT1 transcripts persist in the gonadal ridge from the earliest developmental stages throughout the critical period of sex determination. These studies, which delineate for the first time the sequential expression profiles of SF-1 and WT1 during human gonadal development, provide a framework for understanding human sex reversal phenotypes associated with their mutations.

Survival in a case of life-threatening flecainide overdose.

Flecainide acetate is a potent class Ic anti-arrhythmic drug with major sodium channel blocking actions. On the surface electrocardiogram this results in QTc interval prolongation. Overdose with class Ic drugs (< 0.1% of total intoxications) is uncommon, but management is difficult and the mortality high [1]. Serious flecainide overdose is characterised by ventricular tachyarrhythmias, severe bradycardia and variable degrees of atrioventricular block. This report describes a case of life-threatening flecainide overdose in a previously fit individual, resulting in a combination of cardiac disturbances. The treatment options and management are discussed.

Human NCI-H295 adrenocortical carcinoma cells: a model for angiotensin-II-responsive aldosterone secretion.

Excessive secretion of aldosterone from the adrenal results in the most common form of endocrine hypertension. An understanding of the regulatory processes involved in aldosterone synthesis and release is needed to define the biomolecular mechanisms controlling excessive production of aldosterone. However, in vitro studies regarding the regulatory mechanisms of human aldosterone production have been limited because of difficulties in obtaining tissue and the subsequent isolation of aldosterone-secreting glomerulosa cells. Herein we describe an adrenocortical carcinoma cell line, NCI-H295, which provides a suitable angiotensin-II (AII)-responsive model system to investigate the acute and chronic regulation of aldosterone synthesis. The cells were characterized with regard to the effects of AII on second messenger systems, aldosterone release, and levels of aldosterone synthase (P450c18) mRNA. In the presence of lithium, AII caused a rapid, but transient, increase in the production of inositol tris- and bisphosphates, whereas a prolonged gradual accumulation of inositol monophosphate occurred. Treatment with AII resulted in a 4.5-fold increase in total inositol phosphates in a concentration-dependent manner and an increase in intracellular cytoplasmic free Ca2+. Significant increases in aldosterone (3.5-fold) were detected within 1 h of AII addition. Aldosterone release occurred in a concentration-and time-dependent manner. The type 1 AII (AT1) receptor was shown to be responsible for activation of phosphoinositidase-C, increased intracellular free Ca2+, and aldosterone production, as determined by use of the AT1 receptor antagonist DuP753. In addition, AII treatment resulted in a time-dependent increase in levels of P450c18 mRNA, as detected by RNAse protection assay. In summary, NCI-H295 cells provide a valuable model system to define mechanisms regulating human aldosterone production.

Regulation of human adrenal carcinoma cell (NCI-H295) production of C19 steroids.

The regulation of biosynthesis of the adrenal C19 steroids (the so-called adrenal androgens) remains unclear. Understanding adrenal production of C19 steroids is important when the benefits of these steroids are considered on processes and diseases associated with aging. In vitro studies defining the mechanisms that regulate the production of human adrenal C19 steroids have been limited because of the difficulties in obtaining adrenal tissue. A cell line that retains differentiated adrenal functions would greatly facilitate research in this area. Herein, we describe the use of the human adrenocortical tumor H295 cell line as a model to evaluate mechanisms controlling C19 and C21 steroid production. The cells were characterized with regard to ACTH, forskolin, and dibutyryl cAMP (dbcAMP) responsiveness, as measured by increased cAMP production, synthesis of steroids, and induction of 17 alpha-hydroxylase cytochrome P450 (P450c17). Forskolin and dbcAMP, which were more effective than ACTH, enhanced the production of cortisol, dehydroepiandrosterone (DHEA), DHEA sulfate (DHEAS), and androstenedione over a 48-h treatment period. Comparison of the relative amounts of measured steroid secreted under forskolin treatment indicated that the primary product was cortisol (70%), followed by androstenedione (14%), DHEA (9%), and DHEAS (7%). Cortisol was also demonstrated to be the major steroid product by examination of UV-detectable steroids after high performance liquid chromatographic separation. The increases in steroid production caused by ACTH, forskolin, and dbcAMP occurred in a concentration- and time-dependent manner. A key enzyme in the production of C19 steroids is P450c17. ACTH, forskolin, and dbcAMP increased the activity of 17 alpha-hydroxylase by approximately 2.5-, 10-, and 10-fold, respectively. These effects on enzyme activity occurred in a concentration-dependent manner and coincided with increased levels of P450c17 mRNA. In summary, H295 cells should provide a much-needed model to study mechanisms controlling the secretion of glucocorticoids and C19 steroids, because steroid production in these cells is hormonally controlled and associated with the induction of P450c17.