Properties and kinetics of a population of B-lymphocytes during rat ontogenesis]

Cells bearing surface immunoglobulins (Ig+-cells) detected by the indirect immunofluorescent method and cells forming rosettes (RFC) with sheep erythrocytes coated with antibody and complement (EAC rosettes) were found in the liver and the spleen on the 15th and the 20th days of prenatal life of rats. The percentage of Ig+-cells and RFC in the liver was high and remained unchanged and at about the same level during the whole postnatal life. The spleen and the bone marrow displayed an increase of the Ig+-cells and RFC increased throughout the 1st month of postnatal life with the maximum at the 30th day after birth; a sharp decrease occurred in old animals. In the thymus the Ig+-cells and the RFC were either absent or present in very small amounts only at some periods of study. Ig+-cells with "capping" were discovered in the spleen and bone marrow on the 5th--10th days of postnatal life; their count increased considerably in 30-day and adult rats. Such cells were absent in the lymphoid tissues of old 40-month rats.     

Cytofluorimetric study of the content of glycogen and its fractions in rat liver cells in the course of the 1st week of postnatal ontogeny]

A cytofluorometric study of the total glycogen and its fractions in rat liver cells using the fluorescent PAS reaction was made during 1--7 days of the postnatal development. It was established that glycogen content was small on the first two days of development. The glycogen content increases only on the third day after birth. The glycogen of the rat liver cells during a first week of the postnatal development is different from that detected in adult liver cells in two aspects: in 3 day old hepatocytes soluble and stable glycogen fractions are equal, while in adult rat liver cells the former makes 80--90%; during the first week of the postnatal development, the stable fraction of rat liver cell is more labile, while in the adult rat liver the soluble fraction of glycogen is more labiles.     

Ontogeny of cyclic AMP-dependent protein phosphokinase during hepatic development of the rat.

The ontogeny of protein kinase (ATP: protein phosphotransferase, EC 2.7.1.37) and cyclic AMP-binding activity in subcellular fractions of liver was examined during prenatal and postnatal development of the male rat. 1. Protein kinase activity and cyclic AMP-binding activity were found in the nuclear, microsomal, lysosomal-mitochondrial, and soluble liver fractions. 2. The protein kinase activity of the soluble (105 000 X g supernatant) fraction measured with histone F1 as substrate was stimulated by cyclic AMP. Cyclic AMP did not stimulate the protein kinase activity of the particulate fractions. 3. The protein kinase activity of all subcellular fractions increased rapidly from the activity observed in prenatal liver (3-4 days before birth) to reach maximal activity in 2-day-old rats. Thereafter, the protein kinase activity declined more slowly and regained the prenatal levels at 10 days after birth. 4. Considerable latent protein kinase activity was associated with liver microsomal fractions which could be activated by treatment of microsomes with Triton X-100. The latent microsomal protein kinase activity was highest in prenatal liver, at the time of birth, and 2 days after birth. During the subsequent postnatal development the latent microsomal protein kinase activity gradually declined to insignificantly low levels. 5. During the developmental period examined (4 days before birth to age 60-90 days) marked alterations of the cyclic AMP-binding activity were determined in all subcellular fractions of rat liver. In general, cytosol, microsomal, and lysosomal-mitochondrial cyclic AMP-binding activity was highest in 10-11 day-old rats. Nuclear cyclic AMP-binding activity was highest 3-4 days before birth and declined at birth and during the postnatal period. There was no correlation between the developmental alteration of cyclic AMP-binding activity and cyclic AMP dependency of the protein kinase activity in any of the subcellular fractions. This suggests that the measured cyclic AMP-binding activity does not reflect developmental alterations of the cyclic AMP-binding regulatory subunit of cyclic AMP-dependent protein kinase.     

Duration of antagonizing effect of RU486 on the agonist induction of tyrosine aminotransferase via glucocorticoid receptor

The duration of the antagonizing activity of RU486 on tyrosine aminotransferase (TAT) induction and the glucocorticoid receptor in rat liver was studied. A single dose of RU486 (10 mg/kg) caused occupation of the cytosol glucocorticoid receptor in rat liver at 1h. During this time no nuclear binding of [³H]dexamethasone ([³H]Dex) receptor complex was recorded, and TAT induction was completely blocked. TAT inducibility recovery parallelled receptor binding in both the cytosol and the nuclei, reaching maximum at 12 h. In contrast, nuclear binding recovered in 24 h, and [³H]Dex receptor binding in cytosol 48 h after RU486 application. It is concluded that the inhibitory effect of a single dose of RU486 on TAT induction is of rather short duration. At concomitant presence of agonist and antagonist in vivo, no direct correlation between agonist receptor occupancy and TAT induction could be observed.     

Factors Affecting Developmental Increase of Tyrosine Aminotransferase in Rat Liver Immediately after Birth

Labeling with ³⁵S-methionine of dispersed hepatocytes prepared from neonatal rat liver and successive immunoprecipitation with antiserum against tyrosine aminotransferase (TAT) indicated that increase of TAT activity to a peak about 12 hours after birth and the decrease thereafter are mainly due to changes of TAT synthesis. Similar changes of TAT activity was also observed in the livers of premature neonates which were taken out by Caesarian section and nursed by foster mothers. This indicated that the appearance of TAT activity at this period is not an event programmed along with fetal development but is triggered by birth. The level of glucagon in neonatal plasma increased after birth. Administration of glucagon to neonates caused a great increase of TAT activity whereas the effect of dexamethasone was not so evident. These suggested that glucagon is an important factor affecting the abrupt appearance of TAT after birth.     

Postnatal changes in sublobular distribution of NADPH-cytochrome P-450 reductase in rat liver

Summary Immunohistochemical distribution of NADPH-cytochrome P-450 reductase (NADPH-ferrihaemoprotein reductase; EC 1.6.2.4.) in the liver lobule was examined during development of the rat. From the 19th day of gestation to 4 days after birth, the enzyme was distributed uniformly throughout the lobule. The immunostaining for the enzyme was weak before birth, and became slightly stronger after birth. A slightly uneven distribution of immunoreactivity, stronger in perivenular zones, appeared at 5 days after birth. Then, the staining intensity in perivenular zones became progressively stronger with age, except for a slight increase between 10 and 20 days of age. The intensity in periportal zones also increased gradually, although it remained weaker than that in perivenular zones. Around 30 days of age, the distribution of the immunostaining, stronger in perivenular than in periportal zones, was similar to that seen in the lobules of adult animals. thus, heterogeneity among hepatocytes with respect to the enzyme content is not present in fetal and newborn rats but develops gradually during postnatal development; the postnatal growth of the liver is accompanied by a change in the pattern of the distribution of this enzyme within the lobule.     

Effect of nutritional factors and cortisol on tyrosine aminotransferase activity in liver of brook trout, Salvelinus fontinalis Mitchill.

1. Starvation for over 50 days increased the activity of Tyrosine aminotransferase (TAT) from brook trout liver and decreased liver glycogen. 2. Cortisol (6-40 mg/100 g body wt) increased TAT activity, optimally 72 hr post-injection; liver glycogen response to cortisol was variable while tissue water either increased or remained constant. 3. Fish fed high-protein/low-carbohydrate had greater TAT activity than fish fed low-protein/high carbohydrate. There was food-induced peak of activity indicating a "diurnal rhythm" analogous to that of rat TAT. 4. TAT activity in brook trout appears to be correlated with protein catabolism.     

The appearance, properties, and functions of gluconeogenic enzymes in the liver and kidney of the guinea pig during fetal and early neonatal development.

The changes in the activity and properties of the four gluconeogenic enzymes have been followed during development of the guinea pig. Pyruvate carboxylase was almost exclusively mitochondrial and kinetically identical to the adult liver enzyme and did not appear in significant activity until after day 50 when it rose to values several times higher than those in the adult liver, then fell after birth. Little activity was detected in the fetal kidney. Phosphoenolpyruvate carboxylase appeared in the fetal liver from day 30 on, both in the mitochondrial and cytoplasmic fractions. The cytoplasmic enzyme was kinetically and chromatographically identical to the mitochondrial enzyme of the fetal and maternal liver. After birth the activity of the cytoplasmic enzyme increased and that of the particulate enzyme fell. Fetal kidney activity appeared several days before birth. Fructose 1,6-diphosphatase and glucose 6-phosphatase appeared in the fetal liver and kidney after day 40; the former showed no postnatal change while the latter rose 10-fold after birth. Fetal liver fructose 1,6-diphosphatase was more sensitive to AMP and fructose 1,6-diphosphate inhibition but was chromatographically indistinguishable from the maternal liver enzyme. Despite the presence of the gluconeogenic enzymes, gluconeogenesis and glyconeogenesis were not detected in the fetal liver until 7–9 days before birth. While the synthesis of glyceride-glycerol from 3-carbon compounds was detected from 35–40 days onwards and some of the gluconeogenic enzymes participate in that pathway, gluconeogenesis was not detected in the fetal kidney.     

Postnatal changes of cathepsin D activity in rat liver and brain

Total and specific activity of cathepsin D (EC. 3.4.23.5) were measured in rat liver and brain from 1 to 98 days of age. The activity of cathepsin D in the liver of adult and newborn rats was the same while in the rat brain it was higher in adult than in newborn rats. In the liver maximum specific activity of cathepsin D occurred on the 10th postnatal day and minimum on the fourth day of age. In the brain maximum specific activity of the enzyme occurred on the 14th postnatal day. Total activity of cathepsin D increased after birth in rat liver and brain. These results are discussed in relation to the functional role of cathepsin D in the rat liver and the brain.     

Development of masticatory muscles and oral behavior from suckling to chewing in dogs.

1. At the age of 20 postnatal days, more than a half of the dogs (13/20) showed incisor eruption. At the age of 25 postnatal days, half of the dogs (10/20) showed molar eruption. 2. At the age of 24 postnatal days, half of the dogs (10/20) started chewing behavior. 3. EMG amplitudes of temporal muscle were larger than that of masseter muscle until 26.5 days after birth, but they were reversed at 26.5 days after birth. 4. This suggests that in dogs the earlier teeth erupted, the earlier the dominant oral behavior was changed from suckling to mastication, and concomitantly the dominant muscle for the oral behavior was changed from the temporal to the masseter muscle.     

Time of origin of the rat pineal gland cells. A bromodeoxyuridine immunohistochemical study

The immunohistochemical detection of bromodeoxyuridine (BrdU) was used to study the time of origin of the cells in the pineal gland of the rat. A study was made involving 17 groups of 4 rats each, administered with a single dose of bromodeoxyuridine (BrdU, 25 mg/kg) in 7 phases of the embryonic period (E15 to E21) and in 10 postnatal phases (between P0 and P30), followed by determination in each rat of the number of visible immune-labeled cells in the pineal gland 60 days after birth. The results show that approximately 60% of the pineal cells underwent the last division(s) prior to differentiation in the prenatal period between E18 and E21. The rest of the pineal cells originated after birth, particularly in the first 5 postnatal days.     

Clonogenic hemopoietic cells (CFU-S) in mouse pre- and postnatal ontogeny

Content of three classes of clonogenic haemopoietic cells (CFU-S-7, CFU-S-11 and CFU-S-ep) was determined in haemopoietic organs of mouse during embryogenesis (10, 14 and 18 day) and postnatal ontogenesis (2, 3 and 7 day, 1, 2, 3 and 18 month). CFU-S-7 and CFU-S-11 that from big splenic colonies on 7th and 11th days of transplantation are present in liver, spleen and bone marrow at all developmental stages. However their concentration and CFU-S-7 CFU-S-11 ratio change in haemopoietic organs. CFU-S-ep that form small colonies on 11th day are observed before birth in liver and spleen and 1 week after birth there and also in bone marrow but are practically absent from haemopoietic organs of older animals. Thus, CFU-S compartment structure is characterized by definite ratio of its subpopulations. It seems to reflect functional state of haemopoietic system during development.     

Proteochondroitin sulfate is the main proteoglycan synthesized in fetal hepatocytes

The synthesis of total and specific types of glycosaminoglycans (GAG) with emphasis on proteochondroitin sulfate (PCS) was studied in late embryonic and early postnatal liver parenchymal cells. In contrast to adult hepatocytes, which synthesize almost exclusively proteoheparan sulfate (PHS), PCS proved to be the major type of GAG synthesized in fetal hepatocytes (more than 60% of total GAG) whereas PHS contributes less than 40% of total GAG synthesis. Starting immediately after birth PCS synthesis in hepatocytes declines progressively, at the 6th postnatal day PCS formation is one-fifteenth of that measured in embryonic liver cells. Adult levels are reached around the 10th postnatal day. A significant portion of plasma membrane-associated proteoglycans in fetal hepatocytes is represented by PCS, its fraction declines in early postnatal life. Between the synthesis rate of PCS and [3H]thymidine incorporation into DNA exists a strong positive statistic correlation (r = 0.949). In conclusion, fetal hepatocytes have a completely different profile of GAG synthesis characterized by preponderant production of PCS. This ability is lost early after birth but might be regained in hepatocellular carcinoma cells and parenchymal cells in chronically injured liver tissue developing fibrosis.     

Diurnal variations in inducibility of rat liver tyrosine aminotransferase activity.

The activity of tyrosine aminotransferase (TAT) was measured in the livers of rats which were entrained to eat for the first 2 hours of a daily 12 hour dark period (‘2+22’ schedule) and were treated with the synthetic glucocorticoid dexamethasone and with glucagon at several times of day. TAT activity in untreated animals varies diurnally with a maximum 4 to 6 hours after the beginning of feeding. In both fed and fasted rats there was a small diurnal variation in inducibility by dexamethasone: in fed rats induction was greatest near the beginning of the dark period, shortly after feeding; in fasted rats induction increased towards the end of the dark period. Glucagon induction showed a marked diurnal variation in fed rats with a decrease coincident with the decline in control TAT activity after its food-induced peak. This variation did not appear to be depemdent on food intake, however, since the decline in inducibility occurred in fasted rats at the same time as in fed rats. Co-treatment with dexamethasone did not affect the decrease in glucagon inducibility. The diurnal variation in TAT induction may reflect a diurnal rhythm in the components of the enzyme synthesizing system (e.g. in the availability of mRNA or in enzyme degradation).     

Developmental changes in cyclic AMP, protein kinase, phosphorylase kinase, and phosphorylase in liver, heart, and skeletal muscle of the rat

Changes in cyclic AMP, protein kinase, phosphorylase kinase, and phosphorylase levels were examined during development in the rat. In liver, cyclic AMP increased prenatally and for the first 10 postnatal days; protein kinase levels (both cyclic AMP-dependent and independent activities) were high prenatally and declined during the first 10 postnatal days. Both phosphorylase and phosphorylase kinase in liver increased rapidly prenatally and more slowly postnatally. In heart and skeletal muscle cyclic AMP increased prenatally and for the first 10 days after birth, then declined. Protein kinase in both these tissues was highest prenatally and declined perinatally. In heart and skeletal muscle phosphorylase and phosphorylase kinase activities were extremely low prenatally although both enzymes were largely in their activated forms. Postnatally the nonactive form of both enzymes increased greatly throughout 30 postnatal days. In all three tissues, particularly heart and skeletal muscle, these changes could not be correlated with levels of tissue glycogen.