Developmental changes in hepatocyte growth factor mRNA and its receptor in rat liver, kidney and lung.

Hepatocyte growth factor (HGF) is a mesenchymal-derived factor which induces mitosis, cell movement and morphogenesis of tissue-like structure. We analyzed changes in HGF mRNA and its receptor, the c-met proto-oncogene product, in the liver, kidney and lung during late fetal and postnatal development in rats. In the liver, the HGF-mRNA level was very low during late gestation and in neonates, it increased remarkably and reached a maximum two weeks postnatally, to be followed by a decrease to 33% of the maximum. HGF mRNA in the kidney and lung was either undetectable or very low during late gestation and the neonatal period and increased markedly to reach a maximum, respectively, 3-4 weeks postnatally. HGF-mRNA level in the adult rat lung was fivefold higher than that in the liver and kidney. The number of HGF receptors on plasma membranes of these tissues was low in neonates but there was a rapid increase after birth and a maximum was reached within three weeks. The number of HGF receptors/ng plasma membrane protein at the maximal level was highest in the liver and lowest in the lung. c-met/HGF-receptor mRNA in the liver was also low during late-gestation or in early neonatal periods and increased postnatally. Since HGF-mRNA and HGF-receptor levels changed differently in liver, kidney and lung, the expression of HGF and its receptor may be independently regulated in each organ. However, in these organs, HGF mRNA and the HGF receptor increased within a few weeks of birth, HGF may play roles in organ growth, organ maturation and the maintenance of tissue homeostasis during the postnatal period, presumably through its potential to act as mitogen, motogen and morphogen.     

Growth hormone receptors in ovary and liver during gametogenesis in female rainbow trout (Oncorhynchus mykiss).

Changes of growth hormone receptivity in the ovary during the reproductive cycle were studied in rainbow trout (Oncorhynchus mykiss). A method for characterizing growth hormone receptors in crude ovary homogenate was required for this. Binding of radiolabelled recombinant rainbow trout growth hormone (125I-labelled rtGH) to crude ovary preparation was dependent on ovarian tissue concentration. The sites were specific to growth hormone, with no affinity for prolactins and gonadotrophins. Similar high affinities for 125I-labelled rtGH were obtained with crude ovary (4.2 x 10(9) +/- 0.3 mol l-1) and crude liver preparations (4.9 x 10(9) +/- 0.1 mol l-1) at all stages of ovogenesis, and with ovarian membrane preparations (8.2 x 10(9) mol l-1) tested at the beginning of vitellogenesis. Ovarian growth hormone receptor concentration was highest during the early phases of follicular development (endogenous vitellogenesis: 315-310 fmol g-1 ovary) and decreased regularly during oocyte and follicular growth (exogenous vitellogenesis) to reach a minimal value at oocyte maturation (42 fmol g-1 ovary). In postovulated fish, binding was at a similar level (297 fmol g-1 ovary) to that found in endogenous vitellogenesis. Conversely, the absolute binding capacity of the whole ovary was low from immaturity to early exogenous vitellogenesis (0.1-0.6 pmol per pair of gonads), increased slowly during vitellogenesis and more markedly during rapid oocyte growth and at the time of final maturation (10.8 pmol per pair of gonads). In postovulated fish, the absolute binding capacity decreased partially (4.4 pmol per pair of gonads). Mean hepatic growth hormone receptor concentration did not vary with the reproductive stage for most of the cycle (3.0-4.5 pmol g-1 liver) except in endogenous vitellogenesis where significantly higher concentrations were observed (6.7 pmol g-1 liver). Individual ovarian growth hormone receptor concentrations were correlated with hepatic growth hormone receptor concentrations, indicating that they are regulated in a similar way. We conclude that growth hormone receptors are present in the ovary during the entire ovarian cycle in rainbow trout, probably mainly in somatic cells as indicated by the same concentration of binding sites in immature and in postovulated fish. Growth hormone is potentially important during oocyte recruitment in vitellogenesis and initiation of growth and during final follicular maturation.     

Perinatal olfactory learning in the domestic dog

The ability of individuals to learn about chemosensory stimuli in the prenatal, or immediate postnatal, period may be advantageous in acquiring information about "safe" foods after weaning. In this study, we examined the influence of perinatal exposure to aniseed via the mother's diet on a two-choice food test in the domestic dog. Pups were tested at 10 weeks of age following "prenatal" exposure to aniseed (the last 20 days of gestation), "postnatal" exposure to aniseed (the first 20 days after birth), "perinatal" exposure to aniseed (pre- and postnatal exposure combined), or no exposure to aniseed prenatally or postnatally (control). Perinatal exposure resulted in a significantly greater preference for the aniseed food than the other types of exposure. At 10 weeks, there was no evidence for the retention of any prenatal learning of the aniseed. It is suggested that exposure to a chemosensory stimulus across the perinatal period results in a greater effect than simply the sum of pre- and postnatal exposure due to priming of the chemosensory system via prenatal chemosensory experience. Such a system may confer survival advantages by promoting the acquisition of information about safe foods.     

Expression patterns of mRNAs for ammoniametabolizing enzymes in the developing rat: the ontogenesis of hepatocyte heterogeneity

Summary The expression patterns of the mRNAs for the ammonia-metabolizing enzymes carbamoylphosphate synthetase (CPS), glutamine synthetase (GS) and glutamate dehydrogenase (GDH) were studied in developing pre- and neonatal rat liver byin situ hybridization.In the period of 11 to 14 embryonic days (ED) the concentrations of GS and GDH mRNA increases rapidly in the liver, whereas a substantial rise of CPS mRNA in the liver does not occur until ED 18. Hepatocyte heterogeneity related to the vascular architecture can first be observed at ED 18 for GS mRNA, at ED 20 for GDH mRNA and three days after birth for CPS mRNA. The adult phenotype is gradually established during the second neonatal week, i.e. GS mRNA becomes confined to a pericentral compartment of one to two hepatocytes thickness, CPS mRNA to a large periportal compartment being no longer expressed in the pericentral compartment and GDH mRNA is expressed over the entire porto-central distance, decreasing in concentration going from central to portal. Comparison of the observed mRNA distribution patterns in the perinatal liver, with published data on the distribution of the respective proteins, points to the occurrence of posttranslational, in addition to pretranslational control mechanisms in the period of ontogenesis of hepatocyte heterogeneity.Interestingly, during development all three mRNAS are expressed outside the liver to a considerable extent and in a highly specific way, indicating that several organs are involved in the developmentally regulated expression of the mRNAs for the ammonia-metabolizing enzymes, that were hitherto not recognized as such.     

Developmental and growth-related regulation of expression of serine dehydratase mRNA in rat liver

In rat liver, serine dehydratase mRNA is undetectable in the late prenatal period, but its level increases rapidly after birth to a transient peak, and then after decrease gradually increases again to a maximum 2 weeks after birth that is slightly higher than that of adult liver. To determine whether mature quiescent hepatocytes proliferate without loss of differentiated functions, we measured the serine dehydratase mRNA contents in regenerating liver and primary cultured hepatocytes from adult rats. Partial hepatectomy resulted in a dramatic decrease in the mRNA content within 24 h and then its recovery within a week. In subconfluent cultures of adult rat hepatocytes that did not grow even in the presence of mitogens, serine dehydratase mRNA was maintained at a high level. However, when the hepatocytes were cultured at low cell density without added mitogens, their serine dehydratase mRNA content decreases to a quarter of that of subconfluent cultures. The possibility that the expression of serine dehydratase mRNA is regulated in G0/G1 transition before entry into the S phase and the relationship of the mRNA with growth are discussed.     

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.     

Murine glutamine synthetase: Cloning, developmental regulation, and glucocorticoid inducibility

We have cloned the murine glutamine synthetase (GS) gene and measured GS enzyme activity and mRNA in five tissues (retina, brain, liver, kidney, and skeletal muscle) during perinatal development. Retinal GS enzyme activity increases 200-fold between Day 1 and Day 21 and is accompanied by an increase in the level of GS mRNA; developmental regulation in other tissues is much less dramatic. Based on Southern blotting analysis, a single GS gene gives rise to the tissue-specific patterns of GS mRNA expression. The increase in murine retinal GS observed during perinatal development is similar in magnitude to that observed in the chicken retina just prior to hatching. In the embryonic chicken retina, glucocorticoid hormones mediate a large increase in the level of GS mRNA. However, although glucocorticoids induce a 12-fold increase in GS mRNA in murine skeletal muscle, expression of the retinal enzyme and mRNA is only modestly glucocorticoid-inducible in the mouse. Therefore, despite the hormonal responsiveness of the murine GS gene, it is not likely that glucocorticoids are important physiological modulators of the developmental rise in murine retinal GS.     

CYSTATHIONINE SYNTHESIS AND DEGRADATION IN BRAIN, LIVER AND KIDNEY OF THE DEVELOPING MONKEY

Abstract— The concentration of cystathionine, along with the specific activities of the enzymes involved in its synthesis and degradation, cystathionine synthasc and cystathionase, respectively, have been measured in brain, liver and kidney of the developing Rhesus monkey from mid-gestation, through birth and neonatal life, to maturity. The concentration of cystathionine and the specific activity of cystathionine synthase are low in fetal brain. Both parameters increase slowly after birth and reach values found in adult brain at approx 3 months of postnatal age. The activity of cystathionase in brain is low throughout development.
Liver provides a direct contrast in that the concentration of cystathionine and the specific activity of cystathionine synthase are high in the fetus, decreasing rapidly after birth to values found in the adult by 2 weeks of postnatal age. Cystathionase activity is low in fetal liver and increases slowly after birth reaching values found in adult liver after 2–3 months. Kidney has no more than trace amounts of cystathionine throughout development, higher activity of cystathionine synthase in the fetus than in the adult and high, unchanged activity of cystathionase throughout the period of development studied.
These results indicate that the high concentrations of cystathionine found in primate brain are reached postnatally and suggest that this high concentration of cystathionine may be associated with the functioning of mature brain.     

A burst of c-fos gene expression in the mouse occurs at birth.

Expression of the c-fos gene during murine perinatal development was studied. Before birth, all eight of the prenatal organs tested expressed undetectable or low levels of c-fos mRNA. On the day of birth, there occurred a 10- to 100-fold increase in the level of c-fos message in all of these organs. The expression was transient, in that 1 day after birth, the level of c-fos mRNA precipitously dropped. The c-fos gene expression at birth is unrelated to the expression of the c-myc gene and major histocompatibility complex class I genes, which display distinct kinetics during the perinatal development. The c-fos gene was also expressed locally and transiently in the gravid uterus 1 to 2 days prior to delivery. These results indicate that an event associated with birth induced c-fos gene expression in the mother and newborn.     

Levels of mRNAs coding for lipogenic enzymes in rat lung upon fasting and refeeding and during perinatal development

The relative amounts of mRNAs coding for fatty-acid synthase (EC 2.3.1.85), acetyl-CoA carboxylase (EC 6.4.1.2), ATP citrate lyase (EC 4.1.3.8) and malic enzyme (EC 1.1.1.40) were determined in lungs and livers of adult rats that were normally fed, starved for 48 h or starved for 48 h and subsequently refed for 72 h with a carbohydrate-rich, fat-free diet. In the liver, starvation caused a small decrease in the relative abundance of the mRNAs which was not statistically significant. Subsequent refeeding caused a statistically significant increase in mRNAs for all of the enzymes studied. In the lung, no significant changes were found, indicating that the regulation of the abundance of mRNAs encoding the lipogenic enzymes in the lung differs from that in the liver. In the developing rat lung, mRNA for fatty-acid synthase increased 3-fold in abundance between fetal days 18 and 20 and decreased directly after birth (at day 22 of gestation). A similar pattern was observed for ATP citrate lyase mRNA. The level of acetyl-CoA carboxylase mRNA decreased significantly after birth. These observations indicate that in perinatal rat lungs, pretranslational regulation is involved in the control of the synthesis of these enzymes. The abundance of acetyl-CoA carboxylase mRNA did not change in the prenatal period, a time during which the specific activity of this enzyme increases. This lack of correlation between the specific activity of acetyl-CoA carboxylase and the abundance of its mRNA may indicate that translational regulation of the synthesis of the enzyme or post-synthetic regulatory effects on enzyme molecules are involved in the control of this enzyme in the prenatal period. No changes in the abundance of lung malic enzyme mRNAs were observed throughout the perinatal period.     

Ontogeny of erythropoietin mRNA expression in liver, kidneys and testes of the foetal and the neonatal pig

Erythropoietin (EPO) mRNA expression in kidneys, liver and testes of foetal and neonatal pigs was analysed using a competitive RT-PCR assay. The results indicate that in the foetal pig, erythropoietin expression is greatest in the liver, at birth; hepatic and renal expression are nearly identical, and by 5 weeks of age there is mainly renal expression. The dynamics of the renal expression of EPO mRNA in the perinatal period provide a correlate for observations made earlier of plasma EPO concentrations. Early in foetal life (30 days after artificial insemination), the mesonephroi contained large amounts of EPO mRNA. As in the rat, the testes produced EPO mRNA in amounts comparable to the liver on a per gram tissue basis, though much less on a per organ basis.     

Genetic prenatal maternal effects on organ size in mice and their potential contribution to evolution

Two embryo transfer experiments were carried out in order to estimate the magnitude of prenatal maternal effects, independent of postnatal maternal factors, on the growth of internal organs and fat pads in mice. Reciprocal embryo transfers between the inbred mouse strains C3HeB/FeJ and SWR/J yielded three significant findings. First, all traits were not equally influenced by prenatal maternal factors. Genetic prenatal maternal factors, stemming from the genotype of the uterine mother, had a significant effect on testis weight, subcutaneous fat pad weight and epididymal fat pad weight in 21 day old progeny, but they had no effect on cranial capacity, an index of brain size, kidney weight, or liver weight. Prenatal litter size, defined as the sum of live and dead pups at birth, had a significant negative relationship with 21 day testis weight and kidney weight, and a significant positive association with subcutaneous and epididymal fat pad weights. Cranial capacity and liver weight at 21 days postnatally were not influenced by prenatal litter size. Second, the experiments demonstrated that there was ontogenetic variability in the strength of prenatal maternal effects. At 70 days of age, only subcutaneous fat pad weight was significantly influenced by genetic prenatal effects, and prenatal litter size had a significant negative relationship only with subcutaneous fat pad weight and body weight. Third, genetic prenatal effects had a significant influence on the among-trait covariances at 21 days postnatally, but not at 70 days. Because multivariate evolution involves covariances among characters, the latter results suggest that prenatal effects due to the mother's genotype can affect phenotypic evolution of mammals, especially for selection imposed early in life.     

Perinatal kynurenine pathway metabolism in the normal and asphyctic rat brain

Summary. The kynurenine pathway of tryptophan degradation contains several metabolites which may influence brain physiology and pathophysiology. The brain content of one of these compounds, kynurenic acid (KYNA), decreases precipitously around the time of birth, possibly to avoid deleterious N-methyl-D-aspartate (NMDA) receptor blockade during the perinatal period. The present study was designed to determine the levels of KYNA, the free radical generator 3-hydroxykynurenine (3-HK), and their common precursor L-kynurenine (L-KYN) between gestational day 16 and adulthood in rat brain and liver. The cerebral activities of the biosynthetic enzymes of KYNA and 3-HK, kynurenine aminotransferases (KATs) I and II and kynurenine 3-hydroxylase, respectively, were measured at the same ages. Additional studies were performed to assess whether and to what extent kynurenines in the immature brain derive from the mother, and to examine the short-term effects of birth asphyxia on brain KYNA and 3-HK levels. The results revealed that 1) the brain and liver content of L-KYN, KYNA and 3-HK is far higher pre-term than postnatally; 2) KAT I and kynurenine 3-hydroxylase activities are quite uniform between E-16 and adulthood, whereas KAT II activity rises sharply after postnatal day 14; 3) during the perinatal period, KYNA, but not L-KYN, may originate in part from the maternal circulation; and 4) oxygen deprivation at birth affects the brain content of both KYNA and 3-HK 1 h but not 24 h later. Received August 31, 1999 Accepted September 20, 1999     

215例出生缺陷围生儿临床分析

目的：探讨近几年出生缺陷发生率的变化,反思出生缺陷的发生与干预措施之间的关系。方法：收集1999年1月至2010年12月在我院分娩的围生儿7875例,回顾分析十二年我院检查及分娩的胎儿出生缺陷变化情况,分析其出生缺陷的种类及发生率的变化、结果：有出生缺陷的围产几215例,发生率为27．30‰。行产前诊断确诊后在孕妇知情同意下选择治疗性引产的88例,纠正足月活产婴儿的出生缺陷率为16．13‰,差异有显著意义（X2=22．16,P〈0．01）。结论：有效的产前诊断技术能及早作出出生缺陷的宫内诊断,对优生优育、提高人口素质及疾病控制有很大帮助。     

Delayed development of interstitial cells of Cajal in the ileum of a human case of gastroschisis

The Interstitial Cells of Cajal (ICC) are responsible for rhythmic electrical activity. A paralytic ileus is present in gastroschisis (GS), a malformation due to a defective closure of the abdominal wall through which part of the intestine herniates during pregnancy. In experimental GS, ICC morphological immaturity was shown in the rat foetus at-term but it could not be demonstrated whether differentiation is accomplished post-natally. For this purpose we morphologically investigated ICC, as well as enteric neurons and smooth muscle cells, in a case of human GS at birth and 1 month later when peristaltic activity had initiated. A 36 weeks gestation female was born by c/section with prenatal diagnosis of GS and possible volvulus of the herniated intestine. At birth, the necrotic intestine was resected and both ileostomy and colostomy were performed. The intestine continuity was restored after 4 weeks. Intestinal specimens, taken during both operations at the level of the proximal stoma, were immunostained with c-kit, neuron-specific-enolase and alpha-smooth-muscle-actin antibodies and some processed for electron microscopy. ICC were present at the myenteric plexus only. At birth, these cells were rare and ultrastructurally immature; 1 month later, when partial enteral feeding was tolerated, they formed rows or groups and many of them were ultrastructurally differentiated. Neurons and smooth muscle cells, immature at birth, had developed after 1 month. Therefore, ICC differentiation, as well as that of neurons and smooth muscle cells, is delayed at birth and this might explain the paralytic ileus in GS. One month later, differentiation quickly proceeded at all cellular levels paralleling the increasing tolerance of enteral nutrition.     

Development of tyrosine aminotransferase in perinatal rat liver: changes in functional messenger RNA and the role of inducing hormones

Expression of the hepatic enzyme tyrosine aminotransferase was analyzed in the perinatal period of development in the rat, when this expression undergoes significant changes associated with hepatocyte differentiation. In late prenatal liver both enzyme and functional mRNA gene products are present at levels 10- to 15-fold below those in the fully differentiated adult liver. This low level of expression in fetal liver is refractory to induction by glucocorticoids, but both gene products are increased to a limited extent by cyclic AMP. This induction by cyclic AMP (cAMP) does not confer glucocorticoid-responsiveness on expression. By 3 hr after birth both functional mRNA and enzyme levels are significantly increased, an increase which continues until a peak is reached at 12 hr that is appreciably above the adult levels. Both gene products then decline until adult levels are reached by 24 hr. The postnatal shift in aminotransferase expression is accompanied by acquisition of the capacity to respond to glucocorticoids. Treatment of newborns with an antiglucocorticoid steroid or with glucose suppresses the postnatal overshoot of expression, but neither treatment affects the increase from fetal to adult levels of expression. The results indicate that prior to birth, expression of the aminotransferase gene is partially repressed, a repression that is lifted essentially immediately upon birth. The hormones capable of inducing aminotransferase synthesis have no apparent necessary role in this process.