Interrelationships between the gonads and the adrenal cortex of the golden hamster (mesocricetus auratus).

Snyder, Julian Gilbert

January 1951

Thesis (Ph.D.)--Boston University. / The literature concerning the physiology of the mammalian adrenal cortex is voluminous. However, little has been reported on the physiology of the adrenal cortex of the hamster, Mesocricetus auratus. The present investigation of the effects of adrenalectomy in the hamster was initiated in order that fundamental data such as survival time, electrolyte levels, and changes in estrus cycle of the female could be determined. Since the golden hamster is being used more and more as a laboratory animal, this data would serve as a basis for further investigation. All results obtained in the study of the hamster are compared and contrated to those reported for the rat, the most commonly used laboratory animal in endocrinological investigation. A great many phenomena have been observed by endocrinologists which have demonstrated an apparent interrelationship between the adrenal cortices and gonads of mammals. These phenomena are so numerous that Parkes (1945) was forced to adopt an artificial classification of these interrelationships in orer to review the field with some order and clarity. The effects of adrenalectomy in the hamster were such that it was felt that in this study greater emphasis should be placed on the interrelationships between the gonads and the adrenal cortices than on any other aspect of the adrenal cortical physiology of the animals. It was hoped thereby that the mechanisms involved in these interrelationships would be further elucidated. [Truncated]

Adrenal cortex

Gonads

The plasma corticosteroids: their determination and normal variations

Lewis, Barry

08 April 2020

The current interest in the secretions of the adrenal cortex is shared by physiologist, physician and pharmacologists alike. such attention is not surprising in the case of a gland which is immediately essential to life, which can produce syndromes as varied as precocious puberty, virilisation; Addison's disease; Cushing's syndrome, and the newly described hyperaldosteronism syndrome of Conn (1955), a gland which has been implicated in the parthenogenesis of diabetes (Hoet and Lukens, 195; Jackson, 1955), hypertension (Sepeika, 1948, 1955), pre-eclampsia, and atherosclerosis, and which profoundly effects so many of the metabolic processes of the body. The need for accurate measurement of adrenocortical function has therefore been accentuated in recent years. The purpose of this study was to find out as direct a method as possible for determining the rate of secretion of this gland and to define with this method the norms and normal variations.

Adrenal Cortex Hormones

Action of ACTH peptides on the adrenal gland

Hansell, D. J.

January 1987

No description available.

572

Peptide effects/adrenal cortex

Genetic variation in the adrenal cortex of Mus musculus

Badr, Fouad Mohamed

January 1965

No description available.

576.5

Adrenal cortex ; Mice--Genetics

The influence of pro-opiomelanocortin (POMC) gene delivery on adrenal cortex

Chu, Chih-Hsun

03 February 2006

Pro-opiomelanocortin (POMC) is the precursor of many neuropeptides which includ adrenocorticotropin (ACTH). ACTH has a biological activity in regulating adrenocortical function. In the present study, we will investigate the effect of POMC gene transfer on adrenal cortex cells in cell cultures and animal models. The study included adrenal cortical H295R cells for adenovirus-mediated gene delivery. The effects of POMC gene on H295R cell steroidogenesis and cell proliferation were investigated. In addition, there were 32 SD rats dividing into three groups. 1) Control, injected with normal saline via tail vein (n = 8); 2) Ad-GFP, injected with adenovirus containing GFP (n=12); 3) Ad-POMC, injected with adenovirus containing recombinant POMC gene (n=12). Body weight (BW) was measured. Adrenals were collected, fixed and a series of sections were cut for stains for PCNA and MC2-R. The plasma cortisol and VEGF levels of rats were measured. The results showed that Ad-POMC delivery significantly increased the ACTH and cortisol levels by 50-100 fold and 20-100% in H295R cells, respectively. In addition, Ad-POMC delivery significantly inhibited the cell proliferation and increased the apoptotic cells. The expression of MC2-R protein of H295R cells was also suppressed after Ad-POMC delivery. In the study of SD rats, the Ad-POMC-treated rats exhibited reduced weight gain compared with other groups in the first 2 weeks; however, there was no significant change in BW between Ad-POMC and Ad-GFP groups during the experimental period. The weight of adrenal in Ad-POMC-treated rats was significantly higher than Ad-GFP group in the 8th week. Comparing the sequential adrenal weights in Ad-POMC group, those in 6th week were significantly higher than in 2nd and 4th weeks. The plasma VEFG levels of Ad-POMC-treated rats were higher than Ad-GFP group in the 8th week. The adrenal sections showed that Ad-POMC treated rats had moreanti-PCNA stained cells than Ad-GFP treated rats in 8th week. However, less anti-MC2R stained cells were found in Ad-POMC treated rats in 8th week. Ad-POMC treated rats had higher plasma cortisol levels than those in Ad-GFP treated rats, however, there were no statistical significances. In conclusion, POMC gene transfer modulates the morphology and function of the adrenal cortex. POMC gene inhibits the H295R cells proliferation by inducing MC2-R down-regulation and cells apoptosis. In SD rat adrenal, however, it stimulates adrenal cortex in biphasic pattern. The rapid growing pattern noted in the later phase may be due to the effect of VEGF. Besides, the physical regulation of cortisol synthesis is much stricter than that of ACTH.

steroidogenesis

pro-opiomelanocortin

adrenal cortex

Chromatin, SF-1, and CtBP structural and post-translational modifications induced by ACTH/cAMP accelerate CYP17 transcription rate

Dammer, Eric B.

January 2008

Thesis (Ph.D)--Biology, Georgia Institute of Technology, 2009. / Committee Chair: Marion B. Sewer; Committee Member: Alfred H. Merrill, Jr.; Committee Member: Donald F. Doyle; Committee Member: Dr. Edward T. Morgan; Committee Member: Kirill S. Lobachev. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Adrenal cortical function during pregnancy and lactation in the mouse, reflected by the circulating eosinophils

Shaw, Kenneth Edward,

January 1959

Thesis (Ph. D.)--University of Wisconsin--Madison, 1959. / Typescript. Abstracted in Dissertation abstracts, v. 20 (1959) no. 3, p. 1108-1109. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Growth and maintenance of the mouse adrenal cortex

Chang, Su-Ping

January 2008

The adrenal cortex is classically divided into three morphologically and biochemically distinct zones, covered by a thin, cellular capsule. The adult adrenal cortex is a dynamic tissue in which distinct regions of cell proliferation, movement and death have been identified. Several models for stem cell maintenance of the adult adrenal cortex have been proposed, but adrenocortical stem cells have not yet been identified. Adrenal cortices of 21OH/LacZ transgenic mice show similar mosaic patterns of β-galactosidase staining to X- inactivation mosaics and LacZ ↔ wildtype chimeras. 21OH/LacZ mice provide a tool for lineage analysis, which may help to i) identify clones of cells produced by stem cells in the adult, ii) determine when stem cells begin to function and iii) evaluate different models of how stem cells maintain the adrenal cortex. Analysis of 21OH/LacZ transgenic adrenal cortices showed that the randomly orientated clusters of fetal patches change progressively during the perinatal period to adult radial stripes. Correlation of changes in mosaic patterns and the locations of cell proliferation suggests that the stripes arise by edge-biased growth during the perinatal growth period. Although stem cells may not be involved in the initial formation of stripes, it seems likely that stem cells later maintain the stripes by producing clones of cells that move centripetally to displace the earlier fetal patterns and later replace aging cells. Various combinations of BrdU labelling and chase periods demonstrated that most cell division occurred in the outer 40% of the adrenal cortex, confirmed that cells moved towards the medulla and identified a population of label-retaining cells near the capsule, which could include stem cells. (Stem cells have been recognised as BrdU label-retaining cells in other tissues because they divide less frequently than their daughter cells so dilute the incorporated BrdU more slowly.) Stripe patterns in adult 21OH/LacZ transgenic adrenal cortices were examined to try to distinguish between various models proposed for stem cell maintenance of the adrenal cortex. The observed continuous radial stripe pattern favours the general hypothesis that a single population of stem cells in the periphery maintains the entire adrenal cortex, although other explanations are possible. Quantitative analysis of adult stripe patterns did not show the reduction in stripe number that might be predicted if an age-related decline in adrenocortical stem cell function occurs, as may happen in some other tissues.

571.1

Investigating the maintenance of the mouse definitive adrenal cortex

Zhao, Xin

January 2013

The adrenal gland is an important endocrine organ, protecting the body against acute and chronic stress. The adrenal cortex consists of three morphologically and functionally distinct zones: the outer zona glomerulosa (zG), the zona fasciculata (zF), and the innermost zona reticularis (zR). In rodents, zG cells produce mineralocorticoids (mainly aldosterone), while zF cells secrete glucocorticoids (mainly corticosterone). The functions of zG and zF are defined by the mutually exclusive expression of Cyp11b2 and Cyp11b1 that encode the enzymes aldosterone synthase and 11β-hydroxylase, which catalyze the terminal reactions in the production of aldosterone and corticosterone, respectively. This thesis aims to investigate the maintenance of the definitive mouse adrenal cortex. This involves studies to identify the location of adrenal stem/progenitor cells, and the mechanisms by which differentiated adrenocortical cells are replenished in the adult mice. BrdU pulse-chase studies provided valuable information about cell division and cell fate under physiological or pathophysiological stimulations. The distribution of adrenocortical cells with nuclei stained positively for BrdU and/or Ki67 was identified. Ki67 labelling marked actively dividing cells and showed that adrenocortical cells originate at or around the zG/zF interface. BrdU labelling indicated that, following cell division, cells are displaced inwards and outwards. Acute angiotensin II treatment was shown to have no significant effects on the cell proliferation or turnover in any of the adrenocortical zones. The pathophysiological effects of long-term ACTH treatment were analyzed in a mouse model of congenital adrenal hyperplasia caused by a null mutation of Cyp11b1. Cell hypertrophy was evident in all regions of the adrenal cortex due to the impaired negative-feedback of the HPA axis. Adrenocortical cell proliferation was also increased particularly in the outer zona fasciculata at the border between zG and zF where adrenocortical stem/progenitor cells might be located. The intervening steps between cell proliferation and the final differentiation into steroidogenic zG and zF cells have yet to be discovered. A visual method of monitoring levels of Cyp11b2 and Cyp11b1would offer a convenient approach to track the stages of adult stem cell differentiation that lead to normal adrenal maintenance in vivo and in vitro. In the present study an AS-mCherry-11B-EGFP BAC construct was successfully engineered, in which Cyp11b2 and Cyp11b1 were substituted by mCherry and EGFP, respectively. This BAC construct was characterized in mouse adrenocortical Y1 cells. It was determined that EGFP faithfully recapitulated the expression of Cyp11b1. Forskolin or cAMP treatment induced a rapid cell rounding effect and caused the increased expression of EGFP transgene and endogenous Cyp11b1. An attempt was made to establish a transgenic mouse model, in which zG and zF cells would be marked with mCherry and EGFP respectively, allowing the differentiation of an adrenocortical stem cell to be traced. Following microinjection of the BAC into mouse zygotes, twoAS-mCherry-11B-EGFP transgenic founder mice were identified. Unfortunately, neither of them was able to transmit the transgene through germline, suggesting the mosaicism of transgene integration. Indeed, mosaicism of the transgenic adrenals was demonstrated by RT-PCR and immunostaining, which also revealed that the exogenous EGFP expression faithfully recapitulated the endogenous Cyp11b1 in adrenals. Although it is assumed that expression of Cyp11b2 and Cyp11b1 are mutually exclusive, zG and zF cells may have the plasticity to allow the transition from one cell type into another. The AS-mCherry-11B-EGFP BAC construct is a useful tool for studying in vitro ES cell differentiation towards the adrenocortical lineage. Transgenic AS-mCherry-11B-EGFP ES cells were successfully differentiated into mesenchymal stem cells, as identified by the expression of molecular markers for the mesenchymal lineage. It has been reported that steroidogenic factor (Sf1) can promote the differentiation of MSCs into steroidogenic cells, and Shh plays an important role in Sf1 expression and the consequent adrenal development. However, Shh treatment failed to achieve transformation of mesenchymal cells into adrenocortical cells. It is thought there might be a requirement for additional factors to combine with Shh in promoting the transdifferentiation of ESC-derived mesenchymal cells. Future studies will focus on the genetic control of Cyp11b1 and Cyp11b2 in transgenic AS-mCherry-11B-EGFP ES cells. In conclusion, the location and fate of the adrenocortical progenitor cells were demonstrated by the BrdU pulse-chase studies in different mouse models. An AS-mCherry-11B-EGFP BAC construct was generated, and used to study the mutual and differential controls of Cyp11b1 and Cyp11b2 expression in adrenocortical cells in vitro and in transgenic mice in vivo.

612.4

The characterisation of steroidogenic factor 1 during human development

Hanley, Neil Anthony

January 2001

No description available.

572.8