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Query: UNIPROT:P01189 (
beta-endorphin
)
21,003
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
GRF promotes follicular maturation and ovulation when administered with FSH in the treatment of infertility. Such actions could be mediated by stimulation of GH secretion and insulin-like growth factor I production, but the known actions of the structurally related hormone, vasoactive intestinal peptide (VIP), on granulosa cell function suggested that GRF may also act directly on the ovary to stimulate follicular development. Radioligand binding and activation studies, performed in granulosa cells from immature estrogen-treated rats, revealed a common receptor for VIP and rat (r) GRF in the ovary. Specific binding of [125I]VIP to granulosa cells was saturable and dependent on time and temperature. The relative potencies of VIP-related peptides for inhibition of radioligand binding were: VIP greater than rGRF greater than peptide histidine isoleucinamide greater than [His1,Nle27] human GRF(1-32)NH2 greater than secretin. In binding studies with the potent GRF agonist, [125I] [His1,Nle27]GRF(1-32)NH2, relative potencies were: rGRF(1-43)OH greater than [His1,Nle27]human GRF(1-32)NH2 greater than VIP greater than peptide histidine isoleucinamide greater than secretin. Glucagon and gastric inhibitory peptide, other peptides of the glucagon superfamily, and unrelated peptides including CRF and
beta-endorphin
, did not inhibit binding of either radioligand to ovarian receptors. In cultured granulosa cells, rGRF and VIP stimulated cAMP formation, consistent with coupling of their receptors to the adenylate cyclase system, and potentiated FSH-induced cAMP production. Both peptides also amplified FSH-induced progesterone biosynthesis, aromatase activity, and LH receptor formation. These observations demonstrate that rGRF is a potent cAMP-mediated agonist in the rat ovary and acts on a common VIP/
GRF receptor
in maturing granulosa cells. It is likely that the potentiating effect of administered GRF on gonadotropin-stimulated follicular development in vivo is in part mediated by direct actions of the peptide on the VIP/
GRF receptor
. Also, since GRF is present in the gonads, it is possible that the locally-produced peptide promotes follicular maturation by paracrine modulation of the stimulatory action of FSH on granulosa cell function.
...
PMID:Receptor-mediated actions of growth hormone releasing factor on granulosa cell differentiation. 217 7
There is a 2- to 3-fold increase in luteinizing hormone-beta (LHbeta) or follicle-stimulating hormone-beta (FSHbeta) antigen-bearing gonadotropes during diestrus in preparation for the peak LH or FSH secretory activity. This coincides with an increase in cells bearing LHbeta or FSHbeta mRNA. Similarly, there is a 3- to 4-fold increase in the percentage of cells that bind GnRH. In 1994, we reported that this augmentation in gonadotropes may come partially from subsets of somatotropes that transitionally express LHbeta or FSHbeta mRNA and GnRH-binding sites. The next phase of the study focused on questions relating to the somatotropes themselves. Do these putative somatogonadotropes retain a somatotrope phenotype? As a part of ongoing studies that address this question, a biotinylated analog of GHRH was produced, separated by HPLC and characterized for its ability to elicit the release of GH as well as bind to pituitary target cells. The biotinylated analog (Bio-GHRH) was detected cytochemically by the avidin-peroxidase complex technique. It could be displaced by competition with 100-1000 nM GHRH but not
corticotropin
-releasing hormone or GnRH. In cells from male rats exposed to 1 nM Bio-GHRH, 28+/-6% (mean+/-s.d) of pituitary cells exhibited label for Bio-GHRH (compared with 0.8+/-0.6% in the controls). There were no differences in percentages of GHRH target cells in populations from proestrous (28+/-5%) and estrous (25+/-5%) rats. Maximal percentages of labeled cells were seen following addition of 1 nM analog for 10 min. In dual-labeled fields, GHRH target cells contained all major pituitary hormones, but their expression of ACTH and TRH was very low (less than 3% of the pituitary cell population) and the expression of prolactin (PRL) and gonadotropins varied with the sex and stage of the animal. In all experimental groups, 78-80% of Bio-GHRH-reactive cells contained GH (80-91% of GH cells). In male rats, 33+/-6% of GHRH target cells contained PRL (37+/-9% of PRL cells) and less than 20% of these GHRH-receptive cells contained gonadotropins (23+/-1% of LH and 31+/-9% of FSH cells). In contrast, expression of PRL and gonadotropins was found in over half of the GHRH target cells from proestrous female rats (55+/-10% contained PRL; 56+/-8% contained FSHbeta; and 66+/-1% contained LHbeta). This reflected GHRH binding by 71+/-2% PRL cells, 85+/-5% of LH cells and 83+/-9% of FSH cells. In estrous female rats, the hormonal storage patterns in GHRH target cells were similar to those in the male rat. Because the overall percentages of cells with Bio-GHRH or GH label do not vary among the three groups, the differences seen in the proestrous group reflect internal changes within a single group of somatotropes that retain their
GHRH receptor
phenotype. Hence, these data correlate with earlier findings that showed that somatotropes may be converted to transitional gonadotropes just before proestrus secretory activity. The LH and FSH antigen content of the GHRH target cells from proestrous rats demonstrates that the LHbeta and FSHbeta mRNAs are indeed translated. Furthermore, the increased expression of PRL antigens by these cells signifies that these convertible somatotropes may also be somatomammotropes.
...
PMID:Differential expression of gonadotropin and prolactin antigens by GHRH target cells from male and female rats. 1042 55
Segregation and medicated early weaning are technologies used to optimize the productivity and health of pigs, but these practices may also cause aberrant behaviors indicative of stress. Thus, differences in early- (=10 d of age) and late- (=30 d of age) weaned pigs were investigated. At weaning, pigs were housed in groups of four in 16 pens (eight pens per treatment) in the same facility, and, thus, they were not segregated. Body weights were recorded at birth, weaning, and at approximately 42, 65, 102, 137, and 165 d of age (at slaughter). One-minute, instantaneous scan samples during a 10-min period (at 0600, 1000, 1400, and 1800) were used to record the frequency of lying, standing, and sitting, total number of drinks, feeder investigations, and time spent playing/fighting on 2, 3, and 4 d after weaning. Five-minute, direct observations of each pig were conducted at approximately 40, 60, 80, and 150 d of age. Direct observations were also made of the entire pen for 10 min at approximately 50, 95, 123, and 160 d of age to record aberrant behaviors. At 62 d of age, a handling and blood collection stress was imposed. At 165 d of age, a second stress test was conducted in response to rough handling and transport. Early-weaned pigs spent more time playing/ fighting (P < .006) than late-weaned pigs during the 4 d after weaning, manipulated conspecifics more often at 40 d of age (P < .002), had greater percentage of hemoglobin (P < .03) during Stress Test 1, had greater ADG at 42 d of age (P < .03), and had greater hypothalamic
growth hormone-releasing hormone receptor
mRNA at slaughter (P < .06). Late-weaned pigs had greater ADG between 137 and 165 d of age (P < .03) and greater pro-
opiomelanocortin
at slaughter (P < .04). Overall, most differences found between early-weaned and late-weaned pigs were evident soon after weaning, but they disappeared before slaughter.
...
PMID:Few differences found between early- and late-weaned pigs raised in the same environment. 1068 1
