Cloning and developmental regulation of alpha 1 acid glycoprotein in swine

A cDNA clone of porcine alpha 1 acid glycoprotein (alpha 1AGP) has been isolated and sequenced. Sequence homologies between porcine, human, and rat indicate that porcine alpha 1AGP is similar in structure to the rat and human proteins. RNA blots from days 40, 60, 80, and 110 fetal, newborn, and adult livers showed that alpha 1AGP mRNA is relatively abundant throughout fetal development, particularly at the later stages and in the newborn; there is a rapid decline in abundance following birth. From birth to 3 days of age, there is a three- to four-fold decline in abundance, and alpha 1AGP mRNA is approximately 100 times less abundant in the adult liver than in that of perinatal pigs. Southern blots showed that alpha 1AGP is probably a single-copy gene. The isolation of a cloned cDNA for porcine alpha 1AGP provides a tool to investigate the molecular mechanisms involved in the developmental regulation of the gene and to correlate changes in gene expression during development with fetal growth and well being.     

Developmental Changes in the in Vitro Activated Regenerative Activity of Primitive Mammary Epithelial Cells

Many normal adult tissues contain rare stem cells with extensive self-maintaining regenerative potential. During development, the stem cells of the hematopoietic and neural systems undergo intrinsically specified changes in their self-renewal potential. In the mouse, mammary stem cells with transplantable regenerative activity are first detectable a few days before birth. They share some phenotypic properties with their adult counterparts but are enriched in a subpopulation that displays a distinct gene expression profile. Here we show that fetal mammary epithelial cells have a greater direct and inducible growth potential than their adult counterparts. The latter feature is revealed in a novel culture system that enables large numbers of in vitro clonogenic progenitors as well as mammary stem cells with serially transplantable activity to be produced within 7 days from single fetal or adult input cells. We further show that these responses are highly dependent on novel factors produced by fibroblasts. These findings provide new avenues for elucidating mechanisms that regulate normal mammary epithelial stem cell properties at the single-cell level, how these change during development, and how their perturbation may contribute to transformation.     

Cloning and developmental regulation of α1 acid glycoprotein in swine

A cDNA clone of porcine alpha₁ acid glycoprotein (α₁AGP) has been isolated and sequenced. Sequence homologies between porcine, human, and rat indicate that porcine α₁AGP is similar in structure to the rat and human proteins. RNA blots from days 40, 60, 80, and 110 fetal, newborn, and adult livers showed that α₁AGP mRNA is relatively abundant throughout fetal development, particularly at the later stages and in the newborn; there is a rapid decline in abundance following birth. From birth to 3 days of age, there is a three- to four-fold decline in abundance, and α₁AGP mRNA is approximately 100 times less abundant in the adult liver than in that of perinatal pigs. Southern blots showed that α₁AGP is probably a single-copy gene. The isolation of a cloned cDNA for porcine α₁AGP provides a tool to investigate the molecular mechanisms involved in the developmental regulation of the gene and to correlate changes in gene expression during development with fetal growth and well being.     

Acquisition of antigens characteristic of adult pericentral hepatocytes by differentiating fetal hepatoblasts in vitro

Antigens specific to pericentral hepatocytes have been studied in adult mouse liver, during fetal development, and in cultured fetal hepatoblasts. Antibody reactive with glutamine synthetase stained all fetal liver cells but almost all cells lost this antigen after birth; only a single layer of pericentral cells retained it in adulthood. In contrast, monoclonal antibodies to major urinary protein (MUP) did not detect the antigen until approximately 3 wk after birth, after which time the cells within 6-10 cell diameters of the central veins were positive. Cultured fetal liver cells from embryos at 13 +/- 1 d of gestation were capable of differentiating in vitro to mimic events that would occur had the cells remained in the animal. About 10-20% of the explanted cells grew into clusters of hepatocyte-like cells, all of which stained with albumin antibodies. MUP monoclonals were reactive with one-half of the differentiated fetal hepatocytes. Glutamine synthetase was present in all hepatocytes after several days in culture and gradually decreased and remained in only occasional cells, all of which also contained the MUP antigen. These findings suggest that a sequence of gene controls characterizes expression of specific genes in developing liver, and that differentiating fetal hepatoblasts are capable of undergoing similar patterns of gene activity in culture.     

Rat liver and intestinal mucosa differ in the developmental pattern and hormonal regulation of carbamoyl-phosphate synthetase I and ornithine carbamoyl transferase gene expression

cDNA probes were employed to measure levels of carbamoyl-phosphate synthetase I (CPS) and ornithine carbamoyltransferase (OCT) mRNAs in fetal and neonatal livers and intestines. In the fetal liver, significant levels of OCT mRNA were present at 15-days gestation while CPS mRNA could not be detected until day 17 of fetal development. Apart from a small decline just after birth, amounts of both mRNAs increased steadily to reach adult levels in postnatal life. In contrast to the situation in liver, CPS and OCT mRNA levels in the fetal intestine rose rapidly to peak at day 21 of gestation and then declined steadily in the first seven days after birth. Using the methyl-sensitive restriction isoschizomeric pair, MspI/HpaII, the 5' ends of both the CPS and OCT genes were shown to undergo demethylation during development. In the case of the OCT gene, however, the hypomethylation characteristic of the adult liver and intestinal mucosa was not observed in the 15-day-old fetal liver, where significant levels of gene expression had already been established. Levels of CPS and OCT mRNA in livers of adults responded to glucagon in normal animals (1.5-fold and 2.2-fold increases, respectively) and to dexamethasone in experimentally induced diabetic animals (3-fold increase in CPS mRNA with no change in OCT mRNA). These treatments were all without effect on the levels of CPS and OCT mRNA in intestinal mucosa.     

A fetal skeletal muscle actin mRNA in the mouse and its identity with cardiac actin mRNA

We compare a recombinant cDNA plasmid (pAF81) complementary to a fetal skeletal muscle actin mRNA with a plasmid (pAM91) complementary to the actin mRNA expressed in adult skeletal muscle. The two mRNAs are significantly diverged in silent nucleotide positions; they are coexpressed in fetal skeletal muscle, and in differentiating muscle cell cultures their accumulation begins coordinately. The sequence of pAF81 shows that the amino acid sequence of mouse fetal skeletal muscle actin is almost identical to that of adult bovine cardiac actin. Hybridization of pAF81 to RNA from different mouse tissues shows that fetal skeletal muscle actin mRNA is very homologous or identical to fetal and adult cardiac actin mRNA. Only one gene homologous to pAF81 is detected on blots of restricted mouse DNA. We conclude that this gene must be expressed both in fetal skeletal muscle and in fetal heart. Whereas mRNA transcribed from this gene is the major actin mRNA species in adult heart, it is present in low amounts, if at all, in adult skeletal muscle.     

The localization of laminin mRNA and protein in the postimplantation embryo and placenta of the mouse: an in situ hybridization and immunocytochemical study

In situ hybridization (ISH) and immunocytochemistry were used to localize sites of synthesis and deposition of the basement membrane glycoprotein laminin during development in the postimplantation mouse embryo and extraembryonic membranes. In addition, similar studies were performed on postnatal viscera during the first 20 days after birth. Up to 10 days post coitum, embryonic laminin synthesis was confined to parietal endoderm. In maternal tissue, intense laminin mRNA expression was detected in decidual cells in the mesometrial and antimesometrial endometrium at 5-7 days. At 10 days, uniform expression was still seen within the mesometrial endometrium, with higher levels around migrating trophoblast, but in the antimesometrial aspect expression was restricted to the basal zone. High levels of mRNA expression persisted in parietal endoderm throughout gestation but much lower levels were detected in visceral yolk sac. In the mature placenta, laminin mRNA expression was also found associated with fetal vessels in the labyrinth and giant cells at the fetal/maternal boundary. In the embryo, the external limiting membrane of the cerebral vesicles and spinal cord stained for laminin protein and detectable mRNA was found in the pia mater. Growing peripheral nerves and dorsal and ventral root fibres expressed laminin mRNA and stained for laminin protein. Laminin mRNA expression was found in ureteric buds and nephrogenic vesicles (but not in metanephric blastema) during early prenatal kidney development, and in glomeruli, Bowman's capsule, loops of Henle and collecting duct cells at later stages of development, and after birth. All these structures possessed laminin-rich basement membrane (BM). Laminin mRNA expression fell to below detectable levels in the kidney around weaning. In the gut, laminin expression and protein staining was confined to the muscularis externa and the lamina propria during embryogenesis. After birth, the muscularis externa, muscularis mucosa and lamina propria cells corresponding to fibroblasts had detectable laminin mRNA, but in adult gut no laminin mRNA could be demonstrated in any cell type. In liver, low levels of laminin mRNA were seen in the capsule and in periportal connective tissue. After birth, laminin mRNA was associated with intrahepatic bile channels; no laminin mRNA was detected in the parenchyma and protein deposition was restricted to blood sinus BM. In the adult liver, no laminin mRNA was detected in any cell type. The developing heart showed uniform expression of laminin mRNA from 12 days to before birth. Postnatally, labelling was restricted to connective tissue cells.     

Developmental changes in endothelial nitric oxide synthase expression and activity in ovine fetal lung

Endothelial nitric oxide (NO) synthase (eNOS) produces NO, which contributes to vascular reactivity in the fetal lung. Pulmonary vasoreactivity develops during late gestation in the ovine fetal lung, during the period of rapid capillary and alveolar growth. Although eNOS expression peaks near birth in the fetal rat, lung capillary and distal air space development occur much later than in the fetal lamb. To determine whether lung eNOS expression in the lamb differs from the timing and pattern reported in the rat, we measured eNOS mRNA and protein by Northern and Western blot analyses and NOS activity by the arginine-to-citrulline conversion assay in lung tissue from fetal, newborn, and maternal sheep. Cellular localization of eNOS expression was determined by immunohistochemistry. eNOS mRNA, protein, and activity were detected in samples from all ages, and eNOS was expressed predominantly in the vascular endothelium. Lung eNOS mRNA expression increases from low levels at 70 days gestation to peak at 113 days and remains high for the rest of fetal life. Newborn eNOS mRNA expression does not change from fetal levels but is lower in the adult ewe. Lung eNOS protein expression in the fetus rises and peaks at 118 days gestation but decreases before birth. eNOS protein expression rises in the newborn period but is lower in the adult. Lung NOS activity also peaks at 118 days gestation in the fetus before falling in late gestation and remaining low in the newborn and adult. We conclude that the pattern of lung eNOS expression in the sheep differs from that in the rat and may reflect species-related differences in lung development. We speculate that the rise in fetal lung eNOS may contribute to the marked lung growth and angiogenesis that occurs during the same period of time.