Characterization and Role of Secretoneurin in the Ovulatory Cycle of Zebrafish

Peng, Di

22 June 2022

Secretoneurin (SN) is a 31-42 amino acid neuropeptide, derived from the proteolytic processing of the precursor protein secretogranin-II (Scg2). In zebrafish, SNa and SNb are respectively 34 and 31 amino acids long, deriving from selective processing of the distinct Scg2a and Scg2b precursors. Our lab recently reported that frameshift mutations in Scg2 leads to reduces sexual behavior and disrupted spawning. This defect was partially rescued by injection of SNa. In my work, we determined the distribution of SNa in relation to other known reproductive hormones in zebrafish brain and pituitary by double immunofluorescent staining. SNa-immunoreactivity (ir) was observed in neuronal cell bodies in the ventral telencephalon, preoptic area (POA) and hypothalamus. Neuronal fibers staining for SNa projecting from the magnocellular POA passed through the pituitary stalk and terminated largely in the neurointermediate lobe (NIL). The SNa-ir fibers were less abundant but clearly present in the pars distalis. Moreover, SNa colocalized with isotocin in cell bodies in the POA and fibers in the NIL. Using the lhb-RFP x fshb-eGFP transgenic zebrafish line, we observed SNa-ir near gonadotroph cell bodies but not in them. Peptidomic analysis uncovered shorter processed fragments of both in SNa and SNb in whole brain and pituitary. We performed mass spectrometry to determine natural periovulatory variations and studied their potential bioactivities. Both SNa1-34 and SNa1-14 in the brain varied during the ovulatory cycle, while SNb-related peptides were relatively stable. The levels of SNa1-34 in brain peaked coincident with increased Gnrh3 at the time of the luteinizing hormone (Lh) surge. The levels of SNa1-14 in brain and ovaries peaked at the time of ovulation. To investigate the potential bioactivity of SNa1-34 and SNa1-14, we performed intraperitoneal injections and analyzed the expression numerous reproductive genes. The results suggested that SNa1-34 could induce ovulation by stimulating time-dependent expression of gnrh3 in brain, cga and lhb in pituitary and npr in ovaries. In contrast, SNa1-14 exhibited far fewer effects, but stimulated the expression of gnrh2 but suppressed gnrhr2, so its natural biological function remains unknown. After a single injection of SNa1-34 in females isolated from males, 61% (11/18) zebrafish ovulated. This compares favorably with the effects of the Lh analog human chorionic gonadotropin, inducing ovulation in 72% (13/18) of females. Natural variations in levels of SN in relation to other well-known neuropeptides and biological activity data in the zebrafish model support the hypothesis that SNa is a new stimulatory reproductive hormone. The SN peptides are conserved in evolution so what we uncover in fish may help us speculate on its importance in other vertebrates.

Secretogranin 2

Secretoneurin

Zebrafish

Ovulation

Brain

Pituitary

Expression of ZNF292 Linear and Circular RNAs in Rat MtT Pituitary Cell Lines is Related to Somatotroph Differentiation

Morris, Samantha, Klein, Jeffrey D, Geren, Kellee B., Leferves, Kayce M, Carnevale, Patrick C., Hurley, David L

07 April 2022

ZNF292 is a complex protein of ≈3000 amino acids with 16 zinc finger DNA binding domains. First discovered as a Growth Hormone (GH) transcription activator, ZNF292 was then found to play a role in the initiation of certain cancers, in specific autism spectrum disorder types, and to produce high levels of unique circular RNAs (circRNAs). In the rat, we have found that ZNF292 circRNAs are present in multiple related structures containing differing combinations of exons 1-7, thus increasing in sizes like “babushka” or nested Russian dolls. To begin to understand the functions of these ZNF292 circRNAs, we assayed expression in four rat MtT cell lines that model stages of pituitary somatotroph development. These cell lines have specific GH levels: MtT/E are empty: MtT/Se have estrogen stimulated GH expression; MtT/SM somatomammotrophs have both GH and PRL; and MtT/S somatotrophs produce only GH. Rat GH3 somatomammotroph cells were also assayed for comparison. Thus, the defined stages of pituitary development in these cells are an excellent model for evaluating linear or circular ZNF292 RNA changes. All cell lines were grown according to standard conditions, then harvested and total RNA was extracted (RNeasy kit, Qiagen) and used in qRT-PCR assays where both RT and PCR were performed in each well (Luna kit, NEB). Primers were designed in MacVector: RPL19 as a normalization control, and GH, linear, and circular ZNF292 primers targeted selected exons. Standards for quantitation used purified total rat RNA (ThermoFisher). After qRT-PCR, all data was normalized to the amount of RPL19 in each sample, then average RNA levels calculated for each cell line using Excel and GraphPad Prizm. We found that GH RNA rose from 0% in MtT/E and MtT/Se cells to 157% in MtT/SM and 275% in MtT/S cells. Linear ZNF292 was increased to 219% in MtT/Se cells, then declined to 110% in MtT/S and 37% in MtT/SM cells. Circular ZNF292 was expressed in MtT/E cells at 26%, increased to 184% in MtT/Se cells and fell to ≈100% in MtT/SM and MtT/S cells. GH3 cell expression was similar in pattern to MtT/SM cells but reduced in relative abundance. Statistical analysis with two-way ANOVA indicated significant differences. First, these data confirmed that GH RNA levels correlate with stages of somatotroph differentiation in these cell lines. Second, ZNF292 linear RNA expression increases prior to the onset of GH expression, agreeing with the function of linear ZNF292 in initiating GH transcription. Third, ZNF292 circRNAs have a developmental pattern of expression that is higher in somatomammotroph cells. Expression of other RNAs central to pituitary development will be used to evaluate whether ZNF292 circRNA levels specifically relate to GH status or another criterion of cellular differentiation.

ZNF292

circular RNA

pituitary

Molecular Biology

Sexual maturational changes in the pituitary and testes of ram lambs and predictability of adult reproductive function

Yarney, Thaddeus A.

January 1985

No description available.

Testis.

Pituitary gland.

Sheep -- Reproduction.

Sheep -- Physiology.

A role for serotonin in the hypothalamic-pituitary-adrenal response to insulin stress.

Yehuda, Rachel

01 January 1983

Controversy exists concerning the possible involvement of serotonin in the pituitary-adrenocortical response to stress. In the present research, a variety of physiological and pharmacological manipulations were used in male rats to study the role of this neurotransmitter in the adrenocortical response to insulin- induced hypoglycemia. First, the effect of insulin stress on hypothalamic 5-HT metabolism was examined, and an increased turnover was found as determined by an enhanced accumulation of 5-HT following monoamine oxidase inhibition. The corticos terone response to insulin was potentiated by prior administration of L-tryptophan, and blocked by pretreatment with valine, an amino acid that competes with tryptophan for transport across the blood-brain barrier. Treatment with the 5-HT receptor blocker methysergide, or serotonin depletion by intraventricular injection of 5 , 7-dihydroxy tryptamine significantly attenuated the insulin- induced rise in circulating corticosterone.

Insulin resistance

Serotonin

Pituitary-adrenal function tests

Hormonal regulation of dopamine release in vitro from the posterior pituitary and stalk-median eminence

Garris, Paul A.

January 1990

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Dopamine

Pituitary Gland, Posterior

Median Eminence

Hormones

Prepubertal hormone levels in the bovine and their relationship to estimated breeding values, first lactation production and reproductive performance /

Gilson, Warren David

January 1976

No description available.

Agriculture

Pituitary hormones

Cattle

Steroid hormones

Evaluation of the Normal Equine Pituitary Gland

McKlveen, Tori Leigh

10 June 2002

Computed tomography (CT) is becoming more available as a diagnostic tool in the evaluation of the equine skull and brain. Objectives of this study were: 1) refine a CT protocol for evaluating the equine pituitary gland, 2.) define the CT anatomy of the pituitary region, 3.) determine a set of normal values for the pituitary dimensions (length, width, height, volume and weight), 4.) refine CT techniques for measuring pituitary size. Horses were scanned using 10x10mm, 10x5mm, 4x4mm and 4x2mm slice thickness and interval combinations. The pituitary glands were removed immediately after CT and gross measurements were performed. CT measurements were compared with gross pituitary measurements using analysis of variance (ANOVA) in a randomized block design. Accuracy percentages were also calculated using gross measurements as the known value. Mean dimensions of the histologically normal pituitary glands were: length 21.07mm, width 21.62mm, height 9.78mm and volume 2.66cm³. The weights ranged from 1.7g to 3.4g with a mean of 2.6g. Computed tomographic measurement analysis demonstrated that the 10mm slices were the most accurate way to estimate the length of the gland. The 4mm slices yielded the highest accuracy values for width, height and volume of the pituitary gland. The volume was underestimated by all interval and slice thickness combinations performed by CT. No evidence of an overlap effect was identified for any of the dimensions. Our findings indicated that contrast-enhanced CT is an accurate technique for estimating pituitary linear dimensions. Three-dimensional CT volumetry may not be an accurate method for estimating pituitary volume. / Master of Science

Horses

pituitary gland

CT

Computed tomography

equine

Characterization of Pituitary Protein Expression Patterns During Stages in the Reproductive Cycle of Turkey Hens

Spellerberg, Amy Marie

20 July 2004

Improvements in turkey reproductive efficiency is a very desirable goal for the turkey industry. The ability to maintain turkey hens in the egg-laying (LAY) stage and produce one additional egg per hen a year is estimated to save the turkey industry approximately $1.5 million dollars per year. Overall protein expression generated by tissues of the hypothalamic-hypophyseal complex, namely the anterior pituitary, of the mature turkey hen have a profound impact on reproductive cycling (Scanes, 2000). One of the key physiological factors produced by the anterior pituitary and shown to play a significant role in the regulation of egg laying is the protein prolactin (Prl). The objectives for this study are to examine the overall protein expression patterns from turkey hen pituitary tissue during the nonphotostimulated (NPS), photostimulated (PS), and egg laying (LAY) stages. Attempts to isolate transcription factors that regulate the expression of Prl using an affinity chromatography technique or southwestern screening of a bacteriophage expression library were not successful. A global analysis of protein expression, using two-dimensional polyacrylamide gels (2D gels), was conducted using whole cell, cytoplasmic and nuclear protein extracts from pituitary tissue collected during the NPS, PS and LAY reproductive stages. Approximately 1,046 proteins ranging in pI from 4.6-8.2 and molecular weights between 100 kDa-6kDa were resolved. Protein expression patterns were replicated and verified using pituitaries harvested from NPS, PS and LAY stage turkey hens from another laboratory. Proteins showing considerable changes (563 proteins increased in expression and 98 proteins decreased in expression from the NPS to the LAY stage) in their expression between the reproductive stages were grouped in analysis sets for future identification. These proteins may prove to be important to the reproductive cycling of the turkey hen and warrant future investigation. The results of this study contribute to the overall understanding of the role that the pituitary, as a critical part of the hypothalamic-hypophyseal complex, plays in turkey hen reproductive cycling. / Master of Science

protein expression

turkey

pituitary

reproductive cycle

The proneural bHLH genes Mash1, Math3 and NeuroD are required for pituitary development / bHLHプロニューラル遺伝子のMash1, Math3およびNeuroDは下垂体の発生に必要である

Ando, Mitsushige

25 March 2024

京都大学 / 新制・論文博士 / 博士(医学) / 乙第13605号 / 論医博第2315号 / 京都大学大学院医学研究科医学専攻 / (主査)教授 渡邉 大, 教授 斎藤 通紀, 教授 髙橋 良輔 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Mash1

Math3

NeuroD

pituitary development

490

The expression of steroidogenic enzymes and their regulation in the pituitary gland.

January 2005

Wong Chiu. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2005. / Includes bibliographical references (leaves 73-85). / Abstracts in English and Chinese. / Abstract --- p.i / Acknowledgements --- p.v / Abbreviations --- p.viii / Chapter 1 --- Introduction --- p.1 / Overview --- p.1 / Chapter a. --- Steroidogenesis --- p.1 / Chapter i --- Ectopic steroidogenesis --- p.2 / Chapter ii --- Steroidogenesis in the pituitary --- p.5 / Chapter iii --- Proteins and enzymes involved in steroidogenesis and their distribution in brain and other sites --- p.6 / Chapter iv --- Regulation of adrenal steroidogenesis --- p.11 / Chapter b. --- Regulation of pituitary ACTH secretion --- p.13 / Chapter i --- Hypothalamic regulation --- p.13 / Chapter ii --- Paracrine regulation --- p.14 / Chapter iii --- Feedback regulation --- p.15 / Chapter c. --- Aims of the study --- p.15 / Chapter 2 --- Materials and methods --- p.18 / Chapter a. --- Materials --- p.18 / Chapter b. --- In vivo experiments --- p.25 / Chapter i --- Steroidogenic enzyme mRNA expression in rat and mouse pituitary --- p.25 / Chapter ii --- "Effects of hormonal treatments on weights of body, adrenal glands and testis, and steroidogenic enzyme mRNA expression in rats" --- p.25 / Chapter iii --- Effects of adrenalectomy and/or gonadectomy on the expression of steroidogenic enzyme mRNAs in rat pituitary --- p.26 / Chapter c. --- In vitro experiments --- p.26 / Chapter i --- Effects of CRF and forskolin on cAMP production in mouse and rat pituitary cell-lines --- p.28 / Chapter ii --- Expression of steroidogenic enzyme mRNAs in rat and mouse pituitary cell-lines --- p.28 / Chapter iii --- Effects of CRF on the expression of steroidogenic enzyme mRNAs in rat and mouse pituitary cell-lines --- p.29 / Chapter d. --- Statistical analysis --- p.29 / Chapter 3 --- Results --- p.30 / Chapter a. --- In vivo experiments --- p.30 / Chapter i --- Steroidogenic enzyme mRNA expression in rat and mouse pituitary --- p.30 / Chapter ii --- "Effects of hormonal treatments on weights of body, adrenal glands and testis, and steroidogenic enzyme mRNA expression in rats" --- p.38 / Chapter iii --- Effects of adrenalectomy and/or gonadectomy on the expression of steroidogenic enzyme mRNAs in rat pituitary --- p.47 / Chapter b. --- In vitro experiments --- p.51 / Chapter i --- Effects of CRF and forskolin on cAMP production in mouse and rat pituitary cell-lines --- p.51 / Chapter ii --- Expression of steroidogenic enzyme mRNAs in rat and mouse pituitary cell-lines --- p.55 / Chapter iii --- Effects of CRF on the expression of steroidogenic enzyme mRNAs in rat and mouse pituitary cell-lines --- p.57 / Chapter 4 --- Discussion --- p.58 / Further studies --- p.71 / References --- p.73 / Appendix 1 --- p.86

Enzymes--genetics

Pituitary gland

Genetic regulation

Enzymes--genetics

Pituitary Gland

Gene Expression Regulation