Effects of hormones on differentiation of parotid glands of suckling mice in vitro

The hormonal requirements for functional differentiation of mouse parotid glands were investigated using organ cultures in chemically defined medium. The hormones tested were insulin, thyroxine and prednisolone, and the parameters examined were alpha-amylase activity and the ultrastructure of the tissue. It is found that most of the amylase in the cultures (80%) was released into the culture medium after 5 days of cultivation. Prednisolone (5 . 10(-3) mg/ml) alone resulted in a 3--4-fold increase in specific activity of amylase (total amylase activity in the medium and culture) over that in its absence, but neither insulin nor thyroxine alone induced the enzyme. Prednisolone plus thyroxine (over 1 . 10(-7) mg/ml) or insulin (over 1 . 10(-3) unit/ml) induced markedly the enzyme, amylase specific activity being as much as 4- or 6-fold that with prednisolone alone. Moreover the enzyme specific activity was dependent on the prednisolone concentration (5 . 10(-7) - 5 . 10(-3) mg/ml) in the presence of thyroxine (1 . 10(-2) mg/ml) or insulin (1 . 10(-2) unit/ml). Morphological differentiation was also observed in explants cultivated in medium containing prednisolone plus thyroxine or insulin. These results suggest that besides glucocorticoids, insulin and thyroxine are involved in increase in amylase activity in mouse parotid glands during the late suckling period.     

Precocious differentiation of mouse parotid glands and pancreas induced by hormones

Changes of alpha-amylase activity (1,4-alpha-D-glucan glucanohydrolase, EC 3.2.1.1) in mouse parotid gland and pancreas were investigated during embryonic and postnatal development. Amylase activity in the parotid gland increased from around day 12 and reached the adult level on day 30. On the other hand, the activity in the pancreas increased during the last stage of gestation, decreased after birth, and then gradually increased from around day 15, reaching the adult level on day 35. Precocious differentiation of the parotid gland was induced by injections of hydrocortisone or thyroxine after birth, but these hormones did not have additive effects on the parotid gland. Injection of insulin had little effect when given alone, but suppressed the effects of the other two hormones on the gland. Only hydrocortisone increased the amylase activity in mouse pancreas during postnatal development, the other two hormones causing slight decrease in pancreatic amylase. Adrenalectomy and injection of hydrocortisone affected the parotid gland but not the pancreas of adult mice. These results suggest that hydrocortisone is involved in cytodifferentiations of the parotid gland and pancreas, and in maintenance of the parotid gland. Thyroxine may also be important in differentiation of the parotid gland.     

Synergistic effects of thyroxine and glucocorticoid in induction of trypsin-like esteroprotease in mouse submandibular gland.

The actions of thyroxine, 5 alpha-dihydrotestosterone and hydrocortisone singly or in combination in enzyme regulation in the submandibular gland were studied in intact and adrenalectomized female mice. 1. Adrenalectomy decreased the activity of trypsin-like esteroprotease (EC 3.4.4.-), and administration of hydrocortisone to adrenalectomized mice restored the activity to normal. 2. Hydrocortisone and thyroxine had synergistic effects in induction of esteroprotease in adrenalectomized mice, but 5 alpha-dihydrotestosterone and hydrocortisone did not have synergistic effects in either intact or adrenalectomized mice. 3. The activity of glucose-6-phosphate dehydrogenase (EC 1.1.1.49) was not influenced by change in the glucocorticoid level, but was increased by thyroxine and 5 alpha-dihydrotestosterone in both adrenalectomized mice and intact mice.4. Isoelectric focusing in polyacrylamide gel showed that there are three distinct activities of esteroprotease in this gland with isoelectric points of 5.6, 6.2 and 7.3. Both thyroxine and 5 alpha-dihydrotestosterone similarly induced these activities and glucocorticoids did not affected the isozyme patterns induced by the other two hormones.     

Effect of hormones on hydrolase activities and DNA synthesis in kidney of the developing mouse

The postnatal development of brush border enzyme activities, namely maltase, trehalase, alkaline phosphatase, gamma-glutamyltranspeptidase, and leucylnaphthylamidase, as well as the ontogenic profile of DNA synthesis has been determined in the mouse kidney. In addition, these parameters were evaluated following daily administration of hormones during 3 days to 8-day-old mice. Insulin or epidermal growth factor induced a 34% increase of maltase activity over that of 11-day-old controls. Trehalase activity was precociously and significantly augmented by cortisone alone or combined with thyroxine (p less than 0.05), although thyroxine alone had no influence. Only epidermal growth factor had a significant effect on alkaline phosphatase activity. gamma-Glutamyltranspeptidase activity was significantly decreased when insulin and thyroxine were given simultaneously, but was not modified by any of the hormones injected separately. The level of leucylnaphthylamidase activity was enhanced by 70% after cortisone injection, but it was significantly reduced by thyroxine injected in combination with insulin or cortisone. The incorporation of [3H]thymidine into DNA was increased by 107% after epidermal growth factor administration, but it was decreased by 33% after the cortisone treatment. In spite of this precocious reduction, the level of incorporation was still 2 times higher than that in adult mice. These results show that hormones act separately or in cooperation to accelerate or retard the maturation of the suckling mouse kidney.     

Precocious differentation of mouse parotid glands and pancreas induced by hormones

Changes of α-amylase activity (1,4-α-D-glucan glucanohydrolase, EC 3.2.1.1) in mouse parotid gland pancreas were investigated during embryonic and postnatal development. Amylase activity in the parotid gland increased from around day 12 and reached the adult level on day 30. On the other hand, the activity in the pancreas increased during the last stage of gestation, decreased after birth, and then gradually increased from around day 15, reaching the adult level on day 35. Precocious differentiation of the parotid gland was induceed by injections of hydrocortisone or thyroxine after birth, but these hormones did not have additive effects on the parotid gland. Injection of insulin had little effect when given alone, but suppressed the effects of the other two hormones on the gland. Only hydrocortisone increased the amylase activity in mouse pancreas during postnatal development, the other two hormones causing slight decrease in pancreatic amylase. Adrenalectomy and injection of hydrocortisone affected the parotid gland but not the pancreas of adult mice. These results suggest that hydrocortisone involved in cytodifferentiations of the parotid gland and pancreas, and in maintenance of the parotid gland. Thyroxine may also be important in differentiation of the parotid gland.     

Comparative study of the effect of hydrocortisone and thyroxine on suckling mouse small intestine in organ culture

The influence of hydrocortisone (10(-8)--10(-5) M) and thyroxine (10 (-9)--10(-6) M) on intestinal epithelial cell differentiation and proliferation have been studied using explants of suckling mouse jejunum maintained in serum-free organ culture. Hydrocortisone induced the appearance of sucrase activity and increased trehalase, glucoamylase, lactase and alkaline phosphatase activities. Thyroxine was completely ineffective at all the concentrations used. None of these hormones affected the mitotic activity or the 3H-thymidine incorporation into DNA. These results demonstrate that hydrocortisone but not thyroxine acts directly on intestinal brush border membrane differentiation and that both hormones do not influence the proliferation of the epithelial cells during postnatal development.     

Precocious differentiation of chick embryo pancreas in vitro: Roles of prednisolone,insulin and L-thyroxine

The hormonal requirements for functional differentiation of chick embryo pancreas were investigated by using organ cultures in chemically defined medium. The hormones tested were prednisolone, insulin and thyroxine, and the parameters examined were α-amylase (EC 3.2.1.1) and chymotrypsinogen (EC 3.4.4.5) activities, and the ultrastructure of the tissues. Addition of prednisolone alone to explants from 14-day-old chicken embryo pancreas for 3 days increased the activities of amylase and chymotrypsinogen in the tissues by 3.4- and 6.6-fold, respectively, those of tissues before cultivation. Neither thyroxine or insulin alone, nor both hormones together affected pancreatic exocrine differentiation. Thyroxine enhanced the effect of prednisolone on both enzymes, but insulin did not. When the explants were cultured in the medium containing all three hormones, maximum enzyme activities were observed; amylase or chymotrypsinogen activity being 7- or 18-fold, respectively, that of tissues before cultivation. But these three hormones were not simultaneously necessary. Morphological differentiation was also observed in explants cultivated in medium containing these three hormones. These results suggest that glucocorticoids are essential for normal differentiation of chick pancreas during the late fetal period, possibly with insulin and thyroxine, and also support the idea that pancreatic enzymes are controlled separately.     

Precocious differentiation of chick embryo pancreas in vitro. Roles of prednisolone, insulin and L-thyroxine.

The hormonal requirement for functional differentiation of chick embryo pancreas were investigated by using organ cultures in chemically defined medium. The hormones tested were prednisolone, insulin and thyroxine, and the parameters examined were alpha-amylase (EC 3.2.1.1) and chymotrypsinogen (EC 3.4.4.5) activities, and the ultrastructure of the tissues. Addition of prednisolone alone to explants from 14-day-old chicken embryo pancreas for 3 days increased the activities of amylase and chymotrypsinogen in the tissues by 3.4- and 6.6-fold, respectively, those of tissues before cultivation. Neither thyroxine or insulin alone, nor both hormones together affected pancreatic exocrine differentiation. Thyroxine enhanced the effect of prednisolone on both enzymes, but insulin did not. When the explants were cultured in the medium containing all three hormones, maximum enzyme activities were observed; amylase or chymotrypsinogen activity being 7- or 18-fold, respectively, that of tissues before cultivation. But these three hormones were not simultaneously necessary. Morphological differentiation was also observed in explants cultuvated in medium containing these three hormones. These results suggest that glucocorticoids are essential for normal differentiation of chick pancreas during the late fetal period, possibly with insulin and thyroxine, and also support the idea that pancreatic enzymes are controlled separately.     

Effects on induction of tyrosine aminotransferase in fetal mouse liver in vitro of prednisolone,insulin and thyroxine

The hormonal requirements for formation of tyrosine aminotransferase (EC 2.6.1.5) in fetal mouse liver were investigated in organ culture using chemically defined medium. The hormones tested were insulin, thyroxine and prednisolone. Prednisolone alone resulted in a two-fold increase in tyrosine amino-transferase activity in explanted liver in hormone-free medium on day 6, and its effect was dose dependent, but neither insulin nor thyroxine alone induced the enzyme. Addition of prednisolone plus thyroxine and prednisolone plus insulin increased the enzyme activity 1.4- and 1.3-fold, respectively, over that of explants with prednisolone alone. These three hormones together had the greatest effect, causing induction of 1.5-fold more activity than that with prednisolone plus insulin or plus thyroxine. The three hormones were not all needed continuously during the culture period: prednisolone and insulin were required during the early part of cultivation and thyroxine during the later part. The effects of these hormones were blocked by actinomycin D or puromycin, suggesting that these hormones increase de novo synthesis of tyrosine aminotransferase. Phase-contrast microscopy showed that prednisolone stimulated liver epithelial cell outgrowth, probably acting with insulin.     

In vitro studies of the influence of prolactin on tail regeneration in the adult newtNotophthalmus viridescens

Summary In vitro experiments were carried out to determine the effects of prolactin, and prolactin in combination with other hormones on the regeneration of adult newt tail blastemata. A total of 271 blastemata were explanted 13 days postamputation and were organ cultured for 96 h at 20 (±1)°C. Treatment with prolactin alone resulted in an increase in the blastema cell density of the tail regenerates. Cell accumulation and cell alignment were observed ventral to the reconstituted spinal cord. Prolactin and thyroxine, in combination, improved development of tail regenerates as compared with treatment with prolactin or thyroxine singly, supporting the results of earlier in vivo studies. Optimal development was obtained only when prolactin, insulin, thyroxine and hydrocortisone were added to the culture medium. Regeneration of tail explants maintained in medium augmented with the four hormones closely resembles that of in vivo tail blastemata 17 days post-amputation.Supported by grant A-1208 from the Natural Sciences and Engineering Research Council of Canada to R.A.L.     

Premature induction of pepsinogen in developing rat gastric mucosa by hormones

Daily injection of ACTH into rats from the age of 9 days caused precocious development of peptic activity in the gastric mucosa. A single injection of hydrocortisone into rats aged 2 to 9 days also evoked premature development of peptic activity in the gastric mucosa. The patterns on polyacrylamide gel electrophoresis of pepsinogen from adults and from infants treated with hormone were quite similar but differed from that of untreated infants. Enzyme from the gastric mucosa of adult rats and enzyme evoked with hormones were more stable than that from infant rats.     

Effect of hydrocortisone and thyroxine on ATPase activities of neuronal and glial cell lines in culture

The effect of hydrocortisone and thyroxine, on the activities of Ca²⁺-and Mg²⁺-ATPase was studied in cultured neuronal (clone M1) and glial (clones NN and C6) cell lines. For M1 and NN cells an increase in Ca²⁺-and Mg²⁺-ecto-ATPase activity was found when the cells were cultured during 4–6 days in presence of hydrocortisone or together with thyroxine. In the same conditions, a decrease in Ca²⁺-and Mg²⁺-ecto-ATPase activity was found for the C6 cells. In C6 cells the effect of hormones was more pronounced for the Mg²⁺-than for the Ca²⁺-ecto-ATPase activity. The observed decrease may be related to the tumoral origin of the C6 cells. The activity of (Na⁺, K⁺)-ATPase in all three cell lines increased in presence of hydrocortisone or together with thyroxine when the cells were cultured during 4–6 days, in presence of the hormones, whereas the total Mg²⁺-ATPase activity increased only after 6 days of treatment. Thyroxine alone has very few effect either on Ca²⁺-and Mg²⁺-ecto-ATPase, or on (Na⁺, K⁺)-and total Mg²⁺-ATPase activity. These observations are interpreted to indicate that hormones may modulate or induce enzymatic activities involved in active transport phenomena in nervous tissue.     

Development of the small intestine in the hypophysectomized rat. II. Influence of cortisone, thyroxine, growth hormone, and prolactin.

The intestinal deficiencies caused by hypophysectomy of rats at 6 days of age can be repaired to varying degrees by thyroxine or cortisone but not by growth hormone or prolactin. Administration of daily doses of thyroxine alone from 19–22 days raises duodenal alkaline phosphatase activity to normal levels at 24 days; it has a strong effect on jejunal sucrase and maltase, although these activities remain below those of controls. Thyroxine causes a marked increase in rough endoplasmic reticulum and restores the Golgi complexes to their normal appearance. It also elicits an intensification of periodic acid-Schiff (PAS) stainability of the brush border. Cortisone acetate given from 19 to 22 days elevates sucrase and maltase to normal levels but does not fully restore phosphatase activity. Like thyroxine, cortisone causes intensification of PAS staining of the brush border and also increases rough endoplasmic reticulum. It seems to stimulate Golgi activity, but results in the appearance of a variety of abnormal forms. The defects in Golgi configuration, brush border carbohydrate content, and activity of glycoprotein enzymes that are bound to the brush border may all reflect impaired glycosylation in the hypophyseoprivic state; the results of thyroxine or cortisone administration suggest that both hormones may affect glycosylation but in different ways.     

Hormonal control of renal phosphoenolpyruvate carboxykinase activity during development of the rat.

The effect of injections of hormones in utero on fetal rat kidney and liver extramitochondrial phosphoenolpyruvate carboxykinase activity has been studied. Glucagon and thyroxine induced the liber enzyme but none of the hormones tested affected the renal enzyme. In the postnatal rat, the hepatic phosphoenolpyruvate barboxykinase activity is increased after triamcinolone or thyroxine injection but only triamcinolone injection increases the activity of the kidney enzyme. It is suggested that the rise in renal phosphoenolpyruvate carboxykinase activity at about 10 days of age is due to the increase in blood corticosterone content occurring at the same age.     

Hormone-induced increase of hydroxyindole. O. methyltransferase activity in the embryonic chick pineal gland in organ culture.

The technique of organ culture was used to investigate the regulation of the increase of hydroxyindole.O.methyltransferase activity of the pineal gland during embryonic development. Glands of 15- and 17-day chick embryos developed small increases of enzyme activity when incubated in organ culture with a standard tissue culture medium. The increase of enzyme activity was markedly stimulated by a combination of hydrocortisone, somatotropin and thyroxine, and simulated the pre-hatch increase found $\text{in ovo}$. All three hormones appeared to be required for consistent development of maximal increases in enzyme activity but none was essential for some increase in activity.     

Reversible inhibition by DMSO of hydrocortisone-induced keratinization of chick embryonic skin

Hydrocortisone, at a physiological concentration of 10^?8 M, induces keratinization of chick embryonic tarsometatarsal skin in a chemically defined medium in 4 days [1]. The presence of 1–4% DMSO with hydrocortisone reversibly prevented this keratinization. DMSO suppressed the appearance of epidermal structural protein, which was preferentially induced by hydrocortisone. It also suppressed hydrocortisone-induced epidermal transglutaminase activity; which was presumably responsible for polymerization and decrease in solubility of epidermal protein in keratinization, and it suppressed increase of epidermal protein. When DMSO was added to differentiated skin or added concomitantly with a higher concentration of hydrocortisone, epidermal transglutaminase activity was suppressed. Electron microscopic studies showed that hydrocortisone induced tonofilament bundles and keratinized cells with cellular envelopes, which are all characterestic of α-type keratinization of chick embryonic skin [2], and that DMSO inhibited hydrocortisone induced keratinization and kept the epidermis in an undifferentiated state. Moreover, DMSO inhibited epidermal DNA synthesis and increase in thickness of the epidermis during culture of hydrocortisone-treated skin, indicating that it suppressed cell proliferation as well as cell differentiation. DMSO by itself at 1 or 2 % did not affect epidermal cell differentiation, but suppressed cell proliferation when compared with untreated control.     

Studies on L-arginase in developing rat small intestine, brain, and kidney. II. Effect of hydrocortisone and thyroxine

The influences of hydrocortisone and thyroxine on the developmental changes of arginase activity in intestine, kidney, and brain of suckling rats were studied. A single injection of hydrocortisone (50 mg/kg) into rats aged 9 days evoked premature increase of jejunal arginase activity due to precocious formation of arginase A4. Arginase A4 can be detected about 48 hr after hydrocortisone injection, whereas in intact rats the enzyme appears in the intestinal mucosa on the 19th-21st days of postnatal life. After hydrocortisone administration to rats aged 6 days, a similar pattern of arginase activity in jejunum was observed. Under the same conditions, the influence of hydrocortisone on kidney arginase was weaker. The hormone did not have any influence on the activity of brain arginase. Daily injection of thyroxine (2 mg/kg) to 6-day-old rats (for 6 consecutive days) caused a precocious increase of the arginase activity in intestine. Under the same conditions, only a slight increase of the arginase activity was observed in kidney, whereas in brain the activity was unaffected.