Effect of estrogen and placental lactogen on lactogenesis in pregnant rats

The removal of the corpora lutea or ovariectomy on Day 18 of pregnancy induced a rise in serum prolactin 24 h after surgery with a rapid decline to control values 4 h after the surge, only in the ovariectomized group. When hysterectomy was performed in addition to luteectomy or ovariectomy a similar rise in prolactin was obtained. Lactose synthetase activity in mammary tissue was significantly higher in the luteectomized and luteectohysterectomized rats when compared with ovariectomized, ovariohysterectomized rats and the sham-operated group. Estrogen treatment 12 h after ovariectomy increased serum prolactin and lactose synthetase activity to values similar to those measured in luteectomized rats, but this increase was significantly greater when compared with the ovariectomized-nontreated group. Treatment with Tamoxifen did not decrease serum prolactin in the luteectomized rats but lactose synthetase was reduced to values similar to that obtained in ovariectomized rats. Treatment with 2 bromo-alpha-ergocryptine-mesylate (CB-154) prevented the rise in serum prolactin in the ovariectomized, luteectomized and luteectohysterectomized groups, but lactose synthetase activity was lowered to control values (sham-operated rats) only in the luteectohysterectomized rats. According to these findings, rat placental lactogen in the absence of prolactin and progesterone induces lactose synthesis. Estrogen facilitates prolactin but not placental lactogen action on lactose synthetase activity.     

Possible growth hormone regulation of rat liver glutamine synthetase activity.

Hypophysectomy results in a marked decrease in glutamine synthetase activity of rat liver homogenates. The enzyme is affected to a lesser extent in the kidneys and is not influenced in the brain. Bovine growth hormone treatment of hypophysectomized rats elevates the diminished glutamine synthetase activity in liver and kidneys but has no effect on the brain enzyme. Adrenalectomy also results in decreased liver glutamine synthetase activity although less than the decline seen with hypophysectomy. Cortisol treatment has no effect on glutamine synthetase activity in hypophysectomized animals. Our results suggest that growth hormone is involved in the regulation of liver glutamine synthetase activity. This regulation may be important in the utilization of α-amino nitrogen from glucogenic amino acids associated with growth hormone enhanced glucose production.     

Lactose synthetase activity in mouse mammary glands is controlled by thyroid hormones

Epithelial cells in explants from the mammary glands of euthyroid mature virgin mice are proliferatively dormant. They must undergo DNA synthesis and traverse the cell cycle in vitro before they are able to differentiate fully in response to insulin, hydrocortisone, and prolactin, and synthesize enzymatically active alpha-lactalbumin (measured as lactose synthetase activity). In contrast, glands from hyperthyroid mature virgin mice do not require DNA synthesis in vitro to differentiate. Explants from the euthyroid virgin tissue overcome their dependence on DNA synthesis when 10(-9) M 3,5,3'-triiodo-L-thyronine is added directly to the cultures in addition to the other three hormones. Explants from involuted mammary glands from euthyroid primiparous mice do not require DNA synthesis in vitro to make the milk protein even though they, like explants from mature euthyroid virgin tissue, are proliferatively dormant and do not contain detectable lactose synthetase activity in vivo. Glands from primiparous animals made mildly hypothyroid by ingestion of 0.1% thiouracil in drinking water during 7 wk of involution remain morphologically indistinguishable from glands of their euthyroid counterparts. However, explants from the glands of these hypothyroid animals revert to a state of dependence on DNA synthesis to differentiate functionally. These observations suggest that the dependence on DNA synthesis and cell cycle traversal for hormonal induction of lactose synthetase activity in the mouse mammary gland is controlled by thyroid hormones.     

Lysosomal enzymes in the rat harderian gland are altered by either bromocriptine treatment or hypophysectomy and hormone replacement therapy

Four groups of adult male hypophysectomized rats were injected subcutaneously twice daily between 0800-0900 hr and 1600-1700 hr with either saline diluent, 150 micrograms sheep prolactin and/or growth hormone (GH); intact rats received either saline or 150 micrograms bromocriptine twice daily. After 4 days of treatment, lysosomal enzyme assays revealed significant elevations in both acid phosphatase and alpha-mannosidase enzyme activities in the Harderian glands of saline-injected hypophysectomized rats compared to those in intact controls. beta-Glucuronidase levels were depressed and hexosaminidase activity unaffected by hypophysectomy treatment alone compared to intact controls. Lysosomal enzyme activities in hypophysectomized animals treated with prolactin were not different from the hypophysectomized control animals. However, treatment with GH alone or in combination with prolactin had a significant inhibitory effect on beta-glucuronidase, hexosaminidase, and alpha-mannosidase enzyme activities in the Harderian gland of hypophysectomized animals. Bromocriptine treatment in intact rats only elevated acid phosphatase activity. In summary, the patterns of responses did not reveal a role for prolactin in the control of Harderian gland lysosomal enzyme activities by the pituitary. However, some of the influence on this target system may be exerted by growth hormone.     

The relationship between adenosine diphosphate-ribosylation and mammary gland differentiation

Poly(adenosine diphosphate [ADP]-ribosyl)ation, although associated with differentiation in many systems, exhibited a reciprocal relationship with mammary gland differentiation, and both the synthetic and degradatory pathways complemented each other in this regard. Poly(ADP-ribosyl)synthetase activity declined during pregnancy and lactation, while poly(ADP-ribose) degradatory activity rose late in pregnancy and peaked during lactation. In explant cultures, similar changes occurred and appeared to be under separate hormonal control; prolactin suppressed the synthetase activity, whereas insulin stimulated the poly(ADP-ribosyl)glycohydrolase activity. This latter effect may be mediated by a decline in cAMP levels for the following reasons: the glycohydrolase is known to be inhibited by cAMp, insulin decreased cAMP concentrations in mammary explants by 70%, and cholera toxin blocked the effects of insulin on poly(ADP-ribose) degradation. This reciprocal relationship between poly(ADP-ribosyl)ation and mammary gland differentiation is further supported by pharmacological studies: in the presence of insulin, cortisol, and prolactin, an inhibitor of the synthetase stimulated alpha-lactalbumin three-fold over hormone stimulation alone. However, this inhibitor was unable to induce differentiation in the absence of prolactin. Therefore, although there is a close association between a decline in enzyme activity and mammary differentiation, the data are insufficient to support a causal relationship.     

Comparison of effects of prolactin and growth hormone on adrenal 5alpha-reductase in hypophysectomized rats.

Adrenal 5alpha-reductase activity was measured in female rats 0, 2, 5, and 6 days after hypophysectomy. Enzyme activity increased progressively exhibing a 35-fold elevation at 6 days. The effects of high (250 mug/100 g of body wt), intermediate (25 mug/100 g of body wt), and low (2.5 mug/100 of body wt) daily doses of bovine prolactin and bovine growth hormone were compared at 2 and 5 days posthypophysectomy. At 2 days, enzyme activity was partially inhibited by the high and intermediate doses of prolactin and not affected by growth hormone. At 5 days all doses of prolactin were inhibitory, whereas enzyme activity was suppressed only by the high dose of growth hormone. With a given dose of hormone, the amount of suppression of enzyme activity is greater at 5 days than at 2 days posthypophysectomy. In 5-day hypophysectomized rats the inhibitory effects of prolactin and growth hormone were additive. It is concluded that: (i) hormonal sensitivity and responsiveness of the adrenal reductase pathway increases with duration of pituitary ablation; (ii) the reductive pathway is more sensitive to the effects of prolactin than growth hormone; and (iii) the effects of growth hormone and prolactin on reductase activity are mediated via different mechanisms, as suggested by the additive effects of individual hormones.     

Effect of growth hormone on rat liver N-acetyl-L-glutamate

Earlier studies have revealed, upon hypophysectomy, a specific increase in mitochondrial urea cycle enzymes, namely carbamyl phosphate synthetase and ornithine transcarbamylase. Administration of growth hormone to hypophysectomized rats brought these enzyme activities back to normal. Since growth hormone plays a role in the formation of citrulline and ultimately urea, in the present study its effect on the levels of N-acetyl-L-glutamate, an allosteric activator of carbamyl phosphate synthetase has been investigated. A significant increase in N-acetyl-L-glutamate concentration in rat liver on hypophysectomy and its reversal back to normal levels on growth hormone administration was reported. These results suggest that the lack of growth hormone tends to amplify urea production by the liver.     

Effects of TRH and somatostatin on releases of prolactin and growth hormone in vitro by the pituitary of Poecilia latipinna

Summary Pituitary glands from a teleost fish were incubated in the presence of the synthetic hypophysiotropic peptides, thyrotrophin-releasing hormone and somatostatin, in two media of different osmotic pressure.The effects on prolactin and growth hormone cells were detected by electron-microscopic morphometry with the aid of an image analyser. Thyrotrophin-releasing hormone caused changes in prolactin cell ultrastructure consistent with stimulated hormone release and, in the low osmotic pressure medium, appeared to increase synthetic activity. There was no effect on growth hormone cells. After somatostatin treatment, both synthesis and release in prolactin cells appeared to be inhibited, and there was an obvious inhibition of synthesis and release in growth hormone cells. The response of both cell types to somatostatin did not appear to be dependent on the osmotic pressure of the medium.     

Growth hormone and rat liver mitochondria effects on urea cycle enzymes

Effects of hypophysectomy and subsequent growth hormone administration on mitochondrial enzymes of the urea cycle were investigated in rat liver. Hypophysectomy increased the activities of the two mitochondrial enzymes, carbamyl phosphate synthetase and ornithine transcarbamylase but not of the cytosolic enzyme, argininosuccinate synthetase. The activity of mitochondrial phosphate dependent glutaminase was not affected. Administration of bovine growth hormone (100 μg/100 g body weight) for two weeks decreased the activities of carbamyl phosphate synthetase and ornithine transcarbamylase almost to the normal level. These results suggest a specific effect of growth hormone on mitochondrial enzymes of the urea cycle and serve to explain the increased urea formation in hypopituitarism.     

Inhibition by progesterone of the lactogenic effect of prolactin in the pseudopregnant rabbit.

The effects of progesterone on lactose synthesis activity and changes in mammary gland cells were studied in pseudopregnant rabbits simultaneously treated with prolactin. The injection of progesterone alone on Days 15 and 17 of pseudopregnancy decreased the activity of lactose synthetase (LSA) and galactosyl transferase (GTA), while the administration of prolactin for 2-4 days increased their activities. Th e simultaneous administration of progesterone and prolactin decreased the increase in LSA observed with prolactin alone by 70% on the 4th day of treatment, and decreased GTA by 30%. Progesterone completely suppressed the polyribosome profile and the ratio of endoplasmic reticulum bound polyribosomes to free polyribosomes induced by prolactin. The increase in RNA content in the mammary gland induced by prolactin was also suppressed by progesterone. The results suggest that progesterone inhibits the lactogenic action of prolactin without interfe ring with its mammogenic role.     

Thyroid hormone regulation of prolactin binding to mouse mammary glands.

Membranes from mammary glands of mildly hypothyroid mice show a 70–85% reduction in prolactin binding while those from hyperthyroid mice bound 66% more prolactin compared to similar preparations from euthyroid animals. The prolactin binding data for mammary glands correlate well with the ability of the tissue from animals in various thyroid states to respond to prolactin $\text{in}\text{vitro}$ with increased lactose synthetase activity. Binding of prolactin to mammary membranes is enhanced when explants from mid-pregnant mice are cultured overnight in the presence of insulin, hydrocortisone and 10^?9 M L-T₃. This enhancement is not blocked by puromycin. These data suggest that thyroid hormones control the level of prolactin binding in mouse mammary tissue. This may be accomplished, at least in part, by activation of preexisting receptor molecules.     

Effects of glucocorticoids on casein gene expression in the rabbit.

Milk protein synthesis is initiated by prolactin and a glucocorticoid. In the rabbit, prolactin alone is sufficient. However, glucocorticoids potentiate the action of prolactin. The stimulatory effect of glucocorticoids was evaluated after injections of hydrocortisone acetate alone or associated with prolactin by measurements of (a) the total RNA and DNA content of mammary glands, (b) the lactose synthetase activity, (c) casein synthesis, and (d) the concentration of casein mRNA in total cellular RNA and in polysomal RNA by hybridization with its cDNA. The glucocorticoid, totally inactive alone, proved to have a stimulatory effect proportional to the dose injected when prolactin was present. This effect was more evident with low doses of prolactin. Glucocorticoids proceeded by amplifying the capacity of prolactin to enhance the concentration of casein mRNA available for translation. A parallel effect of glucocorticoids on translation of casein mRNA was suspected. Glucocorticoids injected with low doses of prolactin were unable to mimic all the effects of high doses of prolactin alone.     

Effect of indomethacin on the lactogenic action of prolactin

The action of indomethacin on the lactogenic activity of prolactin has been evaluated usind the technique of rabbit mammary gland organ culture. Indomethacin is totally unable to inhibit prolactin action as estimated by lactose synthetase activity and casein synthesis. These data suggest, as opposed to previous works, that prostaglandins are not involved in the mechanism of prolactin action on lactogenesis.     

Pineal and pituitary involvement in the photoperiodic regulation of body weight, coat color and testicular size of the Djungarian hamster, Phodopus sungorus

Hypophysectomy of 40-day-old male hamsters kept under long photoperiods resulted in a change in coat color from the brownish summer coat to the whitish winter coat, within 5 wk of the surgery, cessation of growth, and, most frequently, an additional loss in body weight. The testes of the hypophysectomized animals were involuted within 14 days after surgery. Continuous substitution of prolactin by implantation of two anterior pituitaries under the kidney capsule was able to reverse partly or totally the inhibitory effects of hypophysectomy on coat color and body weight, although there was no influence on testicular volume. The same effects could be achieved by daily s.c. injections of prolactin (100 micrograms ovine-PRL/day) into hypophysectomized hamsters, whereas the injection of adrenocorticopropic hormone (5 IU porcine-ACTH/day) or melanocyte-stimulating hormone (35 micrograms synthetic alpha-MSH/day) was ineffective. Additional pinealectomy influenced neither the inhibitory effects of hypophysectomy on coat pigmentation and body weight nor the stimulatory effects of prolactin substitution in hypophysectomized animals. Thus, the study provides evidence that the effects of the pineal gland on annual changes in body weight and coat color are mediated via the pituitary.     

Biosynthesis and degradation of prolactin in the rat anterior pituitary gland. Time course of incorporation of label in vitro and evidence for rapid degradation.

Biosynthesis of prolactin was studied in anterior pituitary glands from female rats, incubated in vitro. In this system [3H]leucine was incorporated into pituitary proteins, including somatotropin (growth hormone) and prolactin. The rate of uptake of label into prolactin (and to a lesser extent into total protein) slowed considerably during the first 2 h of incubation, although the rate of uptake into somatotropin was constant for 8 h. The most probable explanation for this apparent decrease in the rate of prolactin synthesis is degradation of prolactin in the gland. Degradation of this hormone was also demonstrated by incubating prelabelled pituitaries in unlabelled medium and following the content of labelled prolactin, and by studying the hormonal content of pituitary glands (by radioimmunoassay) before and after incubation. Degradation of prolactin appears to be much more rapid than that of somatotropin, and may represent a physiological mechanism whereby over-accumulation of prolactin is prevented when secretion of the hormone has been rapidly switched off.     

Proteome and radioimmunoassay analyses of pituitary hormones and proteins in response to feed restriction of dairy cows

The hypothalamic-pituitary system controls homeostasis during feed energy reduction. In order to examine which pituitary proteins and hormone variants are potentially associated with metabolic adaptation, pituitary glands from ad libitum and energy restrictively fed dairy cows were characterized using RIA and 2-DE followed by MALDI-TOF-MS. We found 64 different spots of regulatory hormones: growth hormone (44), preprolactin (16), luteinizing hormone (LH) (1), thyrotropin (1), proopiomelanocortin (1) and its cleavage product lipotropin (1), but none of these did significantly differ between feeding groups. Quantification of total pituitary LH and prolactin concentrations by RIA confirmed the results obtained by proteome analysis. Also, feed energy restriction provoked increasing non-esterified fatty acid, decreasing prolactin, but unaltered glucose, LH and growth hormone plasma concentrations. Energy restriction decreased the expression of glial fibrillary acidic protein, triosephosphate isomerase, purine-rich element-binding protein A and elongation factor Tu, whereas it increased expression of proline synthetase co-transcribed homolog, peroxiredoxin III, β-tubulin and annexin A5 which is involved in the hormone secretion process. Our results indicate that in response to feed energy restriction the pituitary reservoir of all posttranslationally modified hormone forms remains constant. Changing plasma hormone concentrations are likely attributed to a regulated releasing process from the gland into the blood.     

Temporal effect of prolactin on the activities of lactose synthetase, alpha-lactalbumin, and galactosyl transferase in mouse mammary gland explants

The onset of the prolactin (PRL) stimulation of lactose synthesis is between 4 and 8 hr after adding PRL to cultured mouse mammary tissues. The synthesis of lactose is catalyzed by the enzyme lactose synthetase, which is composed of two parts, alpha-lactalbumin and galactosyl transferase. In time-sequence studies, it was found that the activity of galactosyl transferase is enhanced by PRL in concert with the onset of the PRL stimulation of lactose synthesis. In contrast, the earliest detectable effect of PRL on alpha-lactalbumin activity occurred 24 hr after adding PRL to the cultures. It is, therefore, apparent that the rate-limiting component for the PRL stimulation of lactose synthesis in cultured mouse mammary tissues is galactosyl transferase activity.     

Pre-parturitional changes in serum prolactin, placental lactogen, growth hormone, progesterone, and corticosterone in the C3H/HeN mouse

Pre-parturitional changes in serum prolactin, placental lactogen, growth hormone, progesterone, and corticosterone in the C3H/HeN mouse are described. Serum prolactin concentrations display an apparent biphasic pre-parturitional increase. Both serum placental lactogen and growth hormone concentrations are elevated during the second half of pregnancy. Serum placental lactogen concentrations remain elevated until parturition, whereas serum growth hormone concentrations decline on the last two days of pregnancy. Serum progesterone and corticosterone concentrations are elevated during the latter half of pregnancy and decline on the day preceding parturition.     

Prolactin and parenting in the pigeon family

The relationship between plasma prolactin and: crop growth; incubation; brooding; and feeding young in Columbiformes is reviewed. There is a good parallel between changes in crop growth and plasma prolactin fluctuations during the breeding cycle. Prolactin does not play a role in the initiation of incubation, though it can maintain the response. Toward the end of breeding, a decline in prolactin precedes the decline in incubation (of infertile eggs) or brooding (of young), while exogenously administered prolactin can prolong the response. There is no evidence of a necessary relationship between prolactin secretion and parental feeding of young, as this behavior can precede and outlast the secretion of the hormone during breeding.     

Changes in the enzyme pattern of the mammary gland of the lactating rat after hypophysectomy and weaning

1. The enzymes glucose 6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, phosphoglucomutase, UDP-glucose pyrophosphorylase, phosphofructokinase, ATP-citrate lyase and acetyl-CoA carboxylase have been assayed in rat mammary glands in various stages of involution after hypophysectomy and weaning. 2. After hypophysectomy all seven enzymes decline in activity over a 12–16hr. period but the extent of the decline varies, with acetyl-CoA carboxylase becoming almost totally inactive, ATP-citrate lyase and phosphofructokinase showing a large decrease, and the remaining enzymes a less marked decline. 3. Within 24hr. of removing the litter a change in the pattern of enzyme activity is found very similar to that after hypophysectomy. 4. The significance of these results is discussed in relation to the endocrine control of mammary gland metabolism and the mechanisms of involution.