Content Of Immunoreactive Beta-endorphin Research Articles

Beta-endorphin secretion in rams related to season and photoperiod.

A newly established RIA was used to measure changes in the concentration of beta-endorphin in peripheral blood and pituitary tissue from adult Soay rams living outside under natural conditions and housed indoors under artificial photoperiods. A pronounced seasonal cycle in plasma beta-endorphin immunoreactivity occurred in the outdoor animals, with low levels in spring and early summer (February-May; less than 200 pg/ml plasma) and maximal levels 10-20 times higher in late summer and autumn (July-October). Seasonal changes in plasma levels of PRL, FSH, and cortisol, testis size, and body weight were also monitored; the seasonal cycle in the levels of immunoreactive beta-endorphin occurred in parallel with the cycle in plasma FSH and body weight. There were no significant seasonal changes in plasma cortisol concentrations. Marked changes in the plasma levels of beta-endorphin were also seen in rams kept under the artificial photoperiod regimen of alternating 12- to 16-week periods of long days (16 h of light and 8 h of darkness; 16L:8D) and short days (8L:16D). Transfer from long days to short days led to a greater than 20-fold increase in the levels of beta-endorphin, reaching a maximum after 4-8 weeks; the reverse switch in photoperiod led to a rapid decrease in the levels. There was no diurnal rhythm in the plasma levels of beta-endorphin based on hourly samples collected for 24 h under long and short days. The total content of immunoreactive beta-endorphin in the pituitary gland was lower in rams under short days than under long days, converse to the pattern in the blood. Sephadex chromatography of the plasma samples revealed that most of the beta-endorphin immunoreactivity coeluted with synthetic beta-endorphin-(1-31), and a small amount of activity eluted with beta-lipotropin. The seasonal and photoperiod-induced changes were largely due to changes in the levels of beta-endorphin. Extracts of pituitary tissue revealed a large proportion of beta-lipotropin to beta-endorphin compared to plasma, with no consistent change in ratio related to the photoperiod. The overall results illustrate that there are pronounced seasonal and photoperiod-induced changes in immunoreactive plasma beta-endorphin levels in the ram. Under artificial photoperiods, long days inhibit and short days stimulate beta-endorphin secretion. Under natural conditions, the development of refractoriness to both the inhibitory effects of long days and the stimulatory effects of short days may explain the timing of the annual cycle of beta-endorphin secretion.

Neurotransmitters and estrogen interact to affect beta-endorphin levels in castrated female rats

The possibility of an interaction between neurotransmitter systems and estrogen in affecting levels of immunoreactive beta-endorphin (IR-BE) in the anterior pituitary (AP), the neurointermediate lobe of the pituitary (NIL) and the hypothalamus was investigated in ovariectomized (OVX) female rats. Chronic administration of the dopamine antagonist, haloperidol (HALO), had no effect on IR-BE levels in the AP. By contrast, the content of IR-BE in the NIL was increased and the content of IR-BE in the hypothalamus was decreased by HALO. Chronic treatment with estradiol benzoate (EB) produced a decrease in IR-BE in all three tissues. The effect of EB on IR-BE levels in the AP and NIL was reversed by administration of HALO, while EB and HALO appeared to act independently on the hypothalamus. Gel chromatography indicated that alterations in IR-BE in the AP corresponded to similar changes in beta-endorphin (BE) and beta-lipotropin (LPH) and that BE alone comprised the immunoreactivity detected in the NIL and hypothalamus regardless of treatment. Chronic treatment with the alpha-adrenergic agonist, clonidine (CLON), increased, whereas treatment with EB decreased, IR-BE levels in the AP, NIL and hypothalamus. EB attenuated the effect of CLON on IR-BE levels in the AP and hypothalamus. Chronic treatment with CLON appeared to promote the formation of BE in the AP, whereas the proportions of BE and LPH were similar in the AP of controls and animals treated with EB or EB and CLON. BE alone was detected in the NIL and hypothalamus of treated and control animals. These data indicate that in castrated female rats, IR-BE levels in the AP are regulated by the alpha-adrenergic system and IR-BE levels in the NIL and hypothalamus are controlled by both alpha-adrenergic and dopaminergic mechanisms. Estrogen and dopamine may interact to modulate IR-BE levels in the AP and NIL, while an interaction between the alpha-adrenergic system and EB may influence IR-BE levels in the AP and hypothalamus.

Pregnancy-associated changes in ovarian immunoreactive beta-endorphin in rats.

Ovaries from pregnant and postpartum Sprague-Dawley rats were examined for content of immunoreactive beta-endorphin by radioimmunoassay, and for its localization by the peroxidase-antiperoxidase technique. In addition, the molecular forms of beta-endorphin immunoreactivity were separated by gel chromatography and reverse-phase high performance liquid chromatography (RP-HPLC). Ovaries from rats early in pregnancy showed intense granular cytoplasmic staining of luteal cells, with an even distribution of granular material throughout the cytoplasm. By middle to late pregnancy the staining pattern was changed, with immunoreactive material showing a less granular and unevenly distributed staining pattern and with some areas of the cytoplasm totally devoid of immunoreactive material. The concentrations of immunoreactive beta-endorphin measured during pregnancy were significantly lower than levels in mature non-pregnant rat ovary. The ovarian concentration of immunoreactive beta-endorphin fell progressively during pregnancy and early lactation, returning to normal cyclic rat levels at 20 days post partum. The ovarian concentration of beta-endorphin-like material was lowest at 6 days post partum (0.53 +/- 0.08 ng/g wet weight; mean +/- S.E.M.), representing approximately 10% of the concentration found in pooled ovaries from randomly cyclic adult rats. Gel chromatography revealed only a single peak of immunoreactive beta-endorphin, co-eluting with 3.5 kD molecular weight ovine beta-endorphin (1-31). This contrasts with gel profiles of adult cyclic rat ovary, where large molecular weight species pro-opiomelanocortin (31 kD) and beta-lipotrophin (11.5 kD) are also present. On RP-HPLC the predominant species of low molecular weight immunoreactive material co-eluted with beta-endorphin(1-31).(ABSTRACT TRUNCATED AT 250 WORDS)

Diabetes induced by streptozocin results in a decrease in immunoreactive beta-endorphin levels in the pituitary and hypothalamus of female rats.

Immunoreactive beta-endorphin (IR-BE) was measured by radioimmunoassay in the anterior pituitary (AP), neurointermediate lobe of the pituitary (NIL), and hypothalamus of female rats 4 wk after being made diabetic by a single injection of streptozocin (STZ). STZ-induced diabetes resulted in a significant reduction in the content and concentration of IR-BE in the AP and the content of IR-BE in the hypothalamus. Total hypothalamic protein was also significantly diminished. IR-BE levels in the NIL were unchanged. Column chromatography indicated that the reduction in IR-BE in the AP of the diabetic female rats represented a decrease in peptides that co-eluted with beta-endorphin and beta-lipotropin. In the hypothalamus, the reduction in IR-BE was represented solely by a decrease in a peptide co-eluting with beta-endorphin. Beta-lipotropin was not detectable in the hypothalami of control or diabetic female rats. These results suggest that, in the rat, diabetes may produce alterations in the mechanism(s) that regulate endogenous opiate levels in the pituitary and hypothalamus.

Human semen inhibits T rosette formation through an opiate mediated mechanism.

Seminal plasma contains high levels of opioid peptides and both seminal plasma and endogenous opioids can influence the immune system. In order to investigate whether these two findings can be related, semen was collected from 7 normal subjects, and assayed for beta-endorphin content and for its in vitro ability to inhibit the total T rosette formation of human lymphocytes in the presence or in the absence of 10(-6) M naloxone, an universal opiate antagonist. The results were as follows: 1) immunoreactive beta-endorphin content in seminal plasma was 4 to 12 times higher than the peripheral plasma levels detected in the same subjects (76.1 +/- 42.1 SD vs 10.5 +/- 2.0 SD pg/ml); 2) increasing concentrations of seminal plasma (1%, 5%, and 10%) in RPMI 1640 significantly depressed the T rosette formation ability of lymphocytes; and 3) the simultaneous addition to the incubation mixture of 10(-6) M naloxone prevented the phenomenon, while naloxone per se was ineffective. The possibility that endogenous opioids may play a role in the immunomodulatory action of human semen is suggested.

Comparison of rat anterior and intermediate pituitary in tissue culture: corticotropin (ACTH) and beta-endorphin.

The forms of immunoreactive beta-endorphin-sized material in extracts of anterior and intermediate-posterior pituitary from the rat examined by the ion exchange chromatography method of Zakarian & Smyth. The anterior pituitary primarily contained material that co-migrated with synthetic camel beta-endorphin(1-31), whereas the intermediate-posterior pituitary contained relatively little such material. The majority of immunoactive beta-endorphin-sized peptides in the intermediate pituitary eluted at lower concentrations of NaCl than did camel beta-endorphin. Conditions were developed for the stable, long-term tissue culture of dissociated intermediate-posterior pituitary cells. Extracts of cells maintained in tissue culture for 18 h or nine days had the same content of immunoreactive beta-endorphin, 16k fragment, ACTH(18-39) (or CLIP) and ACTH(17-24). Throughout the nine days in culture, characteristic cells that could be immunostained with antibodies to various regions of pro-ACTH/endorphin were present; during the time in culture, non-reactive background cells multiplied rapidly. The major proteolytic processing of pro-ACTH/endorphin remained characteristic of intermediate pituitary tissue throughout the nine days in tissue culture, and did not become similar to the simpler pattern of proteolytic processing found in the anterior pituitary.