The nature of the estrus-inhibiting substances in testis tissue extracts ... by David Robardson Lincoln Duncan

Duncan, David Robardson Lincoln,

January 1945

Thesis (Ph. D.)--University of Chicago, 1941. / Reproduced from type-written copy. Bibliography: p. 12-13.

Estrus. Hormones.

Variations in maternal behavior in the rat as a function of sex and hormonal state

Le Roy, Lawrence Michael,

January 1977

Thesis--Wisconsin. / Vita. Includes bibliographical references (leaves 81-92).

Progestational hormones.

Angiotensin receptors

Lin, Shoei-Yn Shiau,

January 1969

Thesis (Ph. D.)--University of Wisconsin--Madison, 1969. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Angiotensins. Hormones.

The effects of diethylstilbestrol, testosterone and progesterone on growth and fattening and on certain carcass characteristics of Western lambs

O'Mary, C. C.

January 1952

Thesis (Ph. D.)--University of Wisconsin--Madison, 1952. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves [66]-68).

Sheep. Hormones.

Mechanism of electron transport to cytochrome P-450 in adrenal cortex mitochondrial steroid monooxygenase systems

Hanukoglu, Israel.

January 1900

Thesis (Ph. D.)--University of Wisconsin--Madison, 1980. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Adrenocortical hormones.

Étude radioautographique de la fixation d'hormones stéroïdes tritiées, œstradiol, progestérone, promégestone, corticostérone, dexaméthasone, au niveau du système nerveux central, de l'hypophyse et du tractus génital chez divers Mammifères.

Warembourg, Maryvonne,

January 1900

Th.--Sci. nat.--Lille 1, 1979. N°: 467.

Hormones stéroides

The gonadotropin-releasing hormone gene : characterization, regulation and expression in two salmonids

Von Schalburg, Kristian Robert

16 October 2017

There are currently thirteen members of the gonadotropin-releasing hormone (GnRH) family. The GnRH members that activate the synthesis and release of the pituitary gonadotropins are the best understood. These members stand central to the development and maintenance of reproductive function. The roles of GnRH that act in the brain and not in the pituitary, or that are expressed in extraneural tissues, are not well characterized. My goal was to determine whether 1) the regulatory regions and organization of the GnRH gene is conserved between mammals and fish, 2) GnRH is expressed in tissues other than the brain of salmonids and 3) the processes that regulate the expression of GnRH are conserved between two salmonid species with different habitats and reproductive patterns (sockeye salmon, Oncorynchus nerka; rainbow trout, Oncorynchus mykiss). To determine whether the regulatory regions and organization of the GnRH gene were conserved across the species, I isolated and characterized salmon (s)GnRH gene 1 from rainbow trout and sGnRH gene2 from sockeye salmon. In salmon, which are tetraploid, each duplicated sGnRH gene encoded a different mRNA (mRNA1 or mRNA2), but the identical sGnRH peptide. A Southern blot analysis revealed that other related forms of GnRH exist in the sockeye salmon genome. Also, I determined from RT-PCR analysis that GnRH was not expressed in the heart, liver, gut, adrenal, spleen or retina, but was expressed in the gonads of sockeye salmon. To understand the function of GnRH in the gonads, it was necessary to learn when GnRH was expressed during development and throughout the reproductive cycle. Studies using RT-PCR analysis and primer extension analysis demonstrated that the reproductive tissues of salmonids use an upstream promoter to regulate GnRH expression. Intron 1 may be retained, resulting in mRNAs containing 5'-untranslated regions longer than their brain counterparts. These sGnRH transcripts are initiated by a TATA-less promoter region from a start site at 315 basepairs upstream from that utilized in the sockeye salmon brain. Using the same techniques, differences in the expression of GnRH in embryonic tissue and gonads of sockeye salmon and rainbow trout were noted over the first two years of their lives. First, the upstream promoter is transiently used for expression of GnRH as early as 14 days after fertilization in rainbow trout and 30 days after fertilization in sockeye salmon. Second, in sockeye salmon ovary and testis, GnRH was expressed in October of the first year and then only during May and June of the second year in precocious tissue. For rainbow trout, GnRH was expressed in the first year from May to October and in the second year only in December. Precociously mature ovary and testis expressed GnRH from June to October in the second year. It was also important to determine whether the GnRH mRNA expressed in the developing ovary and testis was translated into protein. High pressure liquid chromatography and radioimmunoassays were used to demonstrate the presence of at least three forms of GnRH in precociously mature ovaries and testes during the second year. The expression of sGnRH mRNA2 in the salmonid ovary and testis utilizes an alternative promoter. The resulting mRNAs have long 5'- untranslated regions that may be important in post-transcriptional control. Expression of GnRH in the brain is constant, but is intermittant in the salmonid gonad. GnRH mRNA is expressed in undifferentiated gonadal tissue in the first year and briefly in differentiated, but immature gonads. However, in precociously mature ovary and testis in the second year GnRH is transcribed and translated at the stage that precedes ovulation and spawning. Differences in pattern and longer duration of GnRH expression are shown in the ovary and testis of rainbow trout in comparison to sockeye salmon. This might indicate that GnRH is important in the regeneration of new sets of germ cells in the iteroparous rainbow trout, but not in the semelparous sockeye salmon. A comparison of the genes that encode sGnRH mRNA1 and mRNA2 reveals significant sequence divergence in their 5’-flanking regions following tetraploidization. A large portion of the sockeye salmon gene2 is missing in comparison to the Atlantic salmon gene2. However, the salmonid genes all share strong sequence identity in the proximalprom oter region. Although large segments of sequence identity do not exist in the regulatory regions of the GnRH-encoding genes of mammals and salmonids, some similarities exist in the positions of potential POU- homeodomain regulator and estrogen response element motifs. This suggests that some regulatory control for expression of GnRH in both the brain and gonads may be conserved. / Graduate

Salmonidae

Hormones

The regulation of stanniocalcin-1 gene expression in rat sertoli and leydig cells

Li, Lei

01 January 2006

No description available.

Glycoprotein hormones

The effect of subcutaneous injections of antuitrin-S on the sexually inactive adult male ground squirrel

Baker, Burton Lowell

January 1935

Typescript, etc.

Hormones, Sex

Changes in the function and ionic composition of the alimentary tract in response to dietary cation deficiences, and the possible role of adrenal medullary and cortical hormones in mediating these responses

Bass, Paul

January 1955

The possibility that loss of intestinal motility occurs as a result of potassium or sodium depletion has been investigated. A new technique, based on the passage of a solution containing the dye, gentian violet, was developed for estimating upper bowel motility. Lower bowel motility was not objectively studied. The sodium and potassium content of various portions of the gut from rats on a low sodium, low potassium diet and on a high sodium, low potassium diet have been determined and compared with that of similar portions of the gut of animals on a control diet. The possibility that excess adrenal cortical or medullary hormones may cause or permit electrolyte and motility changes has been studied. The response to dietary potassium restriction in the presence of a high sodium intake were also determined after adrenalectomy, both with and without medullory or cortical hormonal supplementation. The electrolyte pattern of plasma liver and of skeletal muscle from different portions of the body were analysed and compared in order to aid in understanding the overall electrolyte shifts. Analyses of the selected tissues of the body indicated that initial electrolyte concentrations and responses to diets and hormones vary within similar tissues as well as between different organs. It was not possible to correlate alterations in the gastro-intestinal tract content of sodium and/or potassium with changes in motility. Dietary potassium deprivation led to depletion of potassium only in plasma, skeletal muscle and certain portions of the gastro-intestinal tract in intact animals. This effect was prevented by adrenalectomy. Evidence is presented that cortisone can influence the electrolytes of the body by acting in the cells of peripheral tissues as well as on the kidney and that the high dose administered (4 mgm/day) had direct dietary potassium deficiency actions in addition to permitting depletion to occur in the presence of certain tissues. The hypothesis that excess adrenal cortical hormones cause intestinal immotility through loss of potassium or a gain of sodium in this tissue was not confirmed by the data. Evidence is presented indicating that adrenalin can partially restore the ability to excrete potassium and the ability of tissues to undergo potassium depletion in adrenalectomized animals on a potassium deficient diet. It does not correct the electrolyte levels in adrenalectomized animals on a control diets The possibility that adrenalin may play some role in maintaining electrolyte homeostatis is discussed. / Medicine, Faculty of / Anesthesiology, Pharmacology and Therapeutics, Department of / Graduate

Hormones

Diet