Liposome-mediated labeling of adrenocorticotropin fragments parallels their biological activity

To test our hypothesis that specific interactions of ACTH peptides with model lipid membranes reflect the biological importance of similar interactions on target cells, we investigated the liposome-mediated labeling of ACTH fragments with the extremely hydrophobic photolabel, 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine. Correlations were found between the labeling rates and the agonistic and antagonistic potencies of the peptides for in vitro steroidogenesis and inhibition of a synaptosomal protein kinase. A model for the cross-reactivity between ACTH and opioid peptides is discussed.     

Influence of training on the response to exercise of adrenocorticotropin and growth hormone plasma concentrations in human swimmers

The aim of the present study was to evaluate the response of adrenocorticotropin ([ACTH]) and growth hormone ([GH]) concentrations to a typical aerobic swimming set during a training season. Nine top-level male endurance swimmers (age range 17–23 years) were tested during three training sessions occurring 6, 12 and 18 weeks after the beginning of the season. During each session, after a standard warm-up, the swimmers performed a training set of 15 × 200-m freestyle, with 20 s of rest between repetitions, at a predetermined individual speed. Blood samples were collected before warm-up and at the end of the training set. A few days before each session, the individual swimming velocity corresponding to the 4 mmol · l⁻¹ blood lactate concentration (v ₄) was assessed as a standard of aerobic performance. Aerobic training affected v ₄ levels, which were highest 18 weeks after the beginning of the season; at the same time, while [ACTH] response was attenuated, [GH] response was enhanced. These results could be considered as adaptations to the exercise intensity. In our training programme, these adaptations seemed to have occurred between the 12th and 18th weeks of the training season. Accepted: 21 April 1998     

Immunohistochemical localization of adrenocorticotropin and melanocyte stimulating hormone in pars intermedia of rat hypophysis

Summary The sites of production of adrenocorticotropin (ACTH) and melanocyte stimulating hormone (MSH) are studied by the immunoglobulin-peroxidase bridge technique, using antisera prepared against synthetic porcine 1–24 and 17–39 ACTH, and bovine MSH on the rat adenohypophysis. Presence of ACTH all over the pars intermedia (PI) is indicated by staining with antisera _p 1–24 and _p 17-3-9 ACTH. There are darkly stained ACTH cells in the PI and pars tuberalis (PT), similar to those in the pars distalis (PD). With higher dilutions of the ACTH antiserum, staining intensity disappears or reduces markedly in majority of the PI cells, whereas, the ACTH cells in the PI, PD and PT do not vary much in their staining intensity. Therefore, it is concluded that majority of the PI glandular cells (light glandular and dark cells) contain less corticotropin than the ACTH cells. From these observations, it seems to me that the major amount of corticotropin is supplied by the ACTH cells of the PD, PI and PT, and less by the light glandular and dark cells of the PI. The antiserum is ineffective after absorption, so the staining reaction appears to be specific for _p 1–24 and _b 17–39 ACTH.Presence of MSH all over the PI is indicated by staining with antisera to bovine MSH. Majority of the PI cells are highly stained even with higher dilution of the antiserum. The unstained cells in the PI seem to be ACTH cells and/or marginal cuboidal cells. The antiserum was ineffective after absorption, so the staining reaction appears to be specific for _b MSH.Control over the PD corticotropin through the median eminence portal circulation and the PI and PT control through nervous system is also discussed.This study was supported by MRC of Canada Grant nos. MA-3759, and MA-5160.The author gratefully wishes to thank Drs. P. Desaulles and W. Rittel (CIBA, Basle, Switzerland) for the synthetic _p 1–24 ACTH and _b MSH, Dr. R. F. Phifer for _p 17–39 ACTH, and Dr. S. S. Spicer for providing samples of rabbit anti-porcine 17–39 ACTH and anti-human ACTH sera, Drs. George Sétáló and Paul Nakane for their valuable advice. He also acknowledges the help of Mr. Shankar Nayak to prepare the antisera and the skilful technical assistance of Miss. Elise Poiré.     

Electron microscopic-immunocytochemical localization of adrenocorticotropin and melanocyte stimulating hormone in the pars intermedia cells of rats and mice

Summary Electron microscopic localization of adrenocorticotropin (ACTH) and melanocyte stimulating hormone (MSH) in light, dark and ACTH cells in the pars intermedia (PI) of rats and mice is attempted by using antisera to _p 1–24, _p 17–39 ACTH and _b MSH with the immunoglobulin-peroxidase bridge technique. All of the PI parenchymatous cells (light, dark and ACTH cells), except the marginal cuboidal and the ependymal like cells, in rats and mice show very good localization of ACTH and MSH staining. In the light and dark cells, stain of varying intensity is seen on the secretory granules, vesicles and also in many places on the surface of the rough endoplasmic reticulum. There is no staining on the mitochondria, in the nuclei or in the granules inside and around the cisternae of the Golgi complex. Dark stained dense core granules become larger and larger as they appear farther and farther away from the Golgi complex. On the other hand, in the ACTH cells of the PI, ACTH antisera show stronger stained granules in the Golgi complex including the cisternae, similar to the pars distalis (PD) ACTH cells. From these observations it is concluded that the corticotropin in light and dark cells, is not packaged or condensed in the Golgi complex like that in the ACTH cells. MSH synthesis in light and dark cells also seems to be similar to that of ACTH synthesis. It is likely that the granules accumulate ACTH and MSH secretions after they are liberated from the Golgi cisternae, and thus become bigger and bigger in size. In case of ACTH cells of PI and PD, corticotropin may be packaged in Golgi cisternae and the size of the granule does not change much. This shows that there are distinct immunocytochemical differences between the light, dark and ACTH cells of the PI. At the moment, it is difficult to say whether ACTH and MSH are present in the same granule or not.The present and previous studies show that the ACTH and MSH secretion in the PI of rats and mice depends on the hypothalamic neural control.This study was supported by MRC of Canada Grant nos. MA-3759, and MA-5160.The author gratefully wishes to thank Drs. P. Desaulles and W. Rittel (CIBA, Basle, Switzerland) for the synthetic _p 1–24 ACTH and _b MSH, Dr. R. F. Phifer for _p 17–39 ACTH, and Dr. S. S. Spicer for providing samples of rabbit anti-porcine 17–39 ACTH and anti-human ACTH sera, Drs. George Sétáló and Paul Nakane for their valuable advice. He also acknowledge the help of Mr. Shankar Nayak to prepare the antisera and the skilful technical assistance of Miss. Elise Poiré. He wishes to acknowledge Mr. Gatson Lambert for his photography.     

Pubertal maturation and time of day differentially affect behavioral and neuroendocrine responses following an acute stressor

Puberty markedly influences stress responsiveness such that prepubertal animals show a more protracted corticosterone (CORT) and progesterone response following acute stress compared to adults. In both adult and juvenile rats, circadian time modulates adrenocortical steroids with basal CORT and progesterone levels rising prior to the onset of the dark phase of the light-dark cycle (i.e., active period). How time of day affects the pubertal difference in stress responsiveness and if the behaviors of prepubertal and adult animals are differentially affected by stress and time of testing remain unknown. Thus, we exposed group housed (3 per cage) prepubertal (28d) and adult (77d) male rats to 30 min of restraint in either the early portion of the behaviorally inactive, light (circadian nadir of CORT and progesterone) or behaviorally active, dark (circadian peak) phase of their light-dark cycle and measured ACTH, CORT, progesterone, and home cage behavior before and after the stressor. We found that the extended hormonal stress response demonstrated by prepubertal males occurred at both times of day. However, differences in post-stress behavior were dependent on time of testing. Specifically, although pre- and post-stress behaviors were similarly affected by the stressor in the light phase in prepubertal and adult males, during the dark phase, stress suppressed play behavior in the prepubertal males, and increased their time spent resting together (huddling), while these behaviors were unaffected by stress in the adults. These data indicate that pubertal development and time of day interact to modulate post-stress behavior and demonstrate a dissociation between post-stress hormonal and behavioral responses.     

Effects of Adrenocorticotropin Treatment on Estrogen,Luteinizing Hormone,and Progesterone Secretion in the Female Rhesus Monkey

Adrenocorticotropin (ACTH) was administered to female rhesus monkeys in order to determine the effects of adrenal axis activation on the endocrine events occurring during the menstrual cycle. ACTH injected twice daily during the follicular period and through the time of expected ovulation was found to prevent the rise of estrogens during the follicular phase. In addition, the ACTH administration also blocked the preovulatory surge of LH, prevented the luteal rise of progesterone, and extended the length of the menstrual cycle.     

Colocalization of GH,TSH and prolactin,but not ACTH,with βLH-immunoreactivity: evidence for pluripotential cells in the ovine pituitary

Increasing evidence suggests that multihormonal cells in the pituitary gland may be more commonplace than previously thought. This has forced us to reconsider our classical view of cell populations in the pituitary gland. Studies so far have focused almost exclusively on the rat, and there is a dearth of information on other species. Our first objective was to determine whether a subpopulation of gonadotropes also express somatotropin in the ewe, as reported in the rat. In addition, we sought to determine whether gonadotropes express any of the other known pituitary hormones. Finally, we investigated whether the stage of the estrous cycle influenced the occurrence of these pluripotential gonadotropes. We found that a small population of LH-immunoreactive cells also expresses immunoreactive GH, prolactin and TSH. No gonadotropes colocalized with ACTH. Significantly (P<0.001) more gonadotropes expressed GH during the luteal (10.7±0.4%) than the late follicular (5.4±0.3%) phase but there was no difference between the luteal and follicular phases in the proportion of gonadotropes expressing prolactin (follicular: 5.7±0.7%; luteal: 5.5±0.6%) or TSH (follicular: 3.1±0.7%; luteal: 4.2±0.5%). Similarly, there was a significant (P<0.05) difference in the proportion of GH-immunoreactive cells expressing LH immunoreactivity in the luteal (5.9±0.3%) and follicular (3.4±0.5%) phases but no difference in the proportion of prolactin- (follicular: 2.2±0.7%; luteal: 2.0±0.8%) or TSH-immunoreactive cells (follicular: 9.6±3.7%; luteal: 10.8±2.9%) expressing LH. The specific function of these multihormonal gonadotropes in sheep remains to be determined. This research was supported by NIH grant (5 P20 RR15553).     

Immunocytochemistry of somatotrophs,gonadotrophs, prolactin and adrenocorticotropin cells in larval sea bream (Sparus auratus) pituitaries

Summary The chronological appearance of endocrine cells in the pituitary of sea-bream (Sparus auratus) larvae was studied using antisera against salmon prolactin, trout growth hormone, salmon gonadotropin and N-terminal human adrenocorticotropin. The larval pituitary (1–12 days after hatching) was oval in shape and was composed of a dense mass of cells with few neurohypophysial fibres. By 60 days after hatching it began to resemble the adult and was divisible into a distinct rostral pars distalis containing prolactin and adrenocorticotropin cells; a proximal pars distalis containing somatotrophs and gonadotrophs and a pars intermedia. Cells immunoreactive with antisera against growth hormone were observed immediately after hatching (2 days post-fertilization). Weakly staining prolactin cells were observed 2 days later in the region corresponding to the rostral pars distalis. Cells immunoreactive with anti-gonadotropin and anti-adrenocorticotropin sera were observed in the pituitary 6 and 8 days after hatching, respectively. All the cell-types studied were immunoreactive from the time they were first identified until the final samples 90 days after hatching.