Effect of protein malnutrition and maternal caffeine intake on the growth of fetal rat brain

Pregnant dams were divided into two subgroups on day 10 of gestation. Half were fed a 20% protein diet and the other half an 8% protein diet. A second group also subdivided was pair-fed with rats of the first group. Their diet was supplemented with caffeine in amount calculated to provide daily doses of 2 mg/100 g body weight. On days 18, 20, and 22 randomly selected dams were injected with 3H-thymidine intraperitoneally and 1.5 h later their fetuses were delivered surgically in order to determine the rate of DNA synthesis along the gestation. The rest of the fetuses were delivered surgically on day 22. Pups' brains were rapidly removed and DNA, RNA, protein and 3H-thymidine uptake were studied. Average body weights of the fetuses in the caffeine-supplemented control group were smaller than those of the noncaffeine group. Effects of caffeine that were similar in both diet groups included a decrease in brain DNA content and concentration and an increase in brain protein content and concentration. However, the percent decrease and increase, respectively, was different depending on the nutritional status. DNA synthesis was not affected by malnutrition or caffeine supplementation on day 18 of gestation. Caffeine's effect on the rate of DNA synthesis was different on day 20 of gestation depending on nutritional status. Caffeine supplementation resulted in a decrease in DNA synthesis in both groups on day 22 of gestation. These data indicate that caffeine intake during pregnancy produces differential effects on fetal rat brain depending on dietary protein content.     

Effects of orally administered caffeine on cellular response in protein energy-malnourished neonatal rat brain

The purpose of this study was to determine the effects of caffeine on growing rats and how protein energy malnutrition can modify these potential effects. Caffeine (1,3,7-trimethylxanthine) is not only the most commonly consumed, neurally active stimulant in our daily lives, but it is widely used in the management of apnea in the premature neonate. One group of dams (20%) (n = 6) was begun on a 20% protein diet ad libitum. The second group (6%) (n = 4) was begun on a 6% protein diet. A third group (20% + C) (n = 4) was pair-fed to group 1 (20%) with the 20% protein diet, but beginning on day 3 the pups received 10 mg/kg body weight of caffeine via intragastric feeding needle every other day. The fourth group (6% + C) (n = 5) was pair-fed with group 2 (6%) with the 6% protein diet and the pups received 10 mg/kg of caffeine in the same manner as the 20% + C group from day 3. Although the 6% protein diet was associated with the expected reduced body and brain growth, there were no additional growth alterations associated with caffeine administration in either the 20% or 6% diet groups. This growth failure was accompanied by the expected reductions in total whole brain DNA, RNA, protein, and cholesterol content regardless of whether caffeine was received or not. Effects of caffeine which were similar in both diet groups included an increase in brain RNA content and concentration and an increase in the RNA/DNA ratio. However, there were differential effects of caffeine seen depending on diet group assignment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of intrauterine ethanol exposure on fetal lung growth

Lung weight, DNA, RNA, protein, and total body weight were analyzed in fetuses from 14 pregnant Sprague-Dawley rats fed a nutritionally complete liquid diet containing v/v 6% ethanol (ethanol group). Each ethanol rat was matched with an isocalorically pair-fed animal (control group) who received the same liquid diet with carbohydrate substituted for ethanol. The rats were killed on day 20 of gestation. The mean maternal blood ethanol concentration at 0700 h on day 20 was 170 +/- 22 (SE) mg/dl. Compared to controls, ethanol fetuses had reduced body weight (21%), lung dry weight (39%), lung wet weight/body weight ratio (10%), DNA (21%), RNA (25%), protein (28%), and protein/DNA ratio (8%) (p less than 0.05). The results indicate that prenatal ethanol exposure inhibits cellular growth in the fetal lung, resulting in hypoplastic lungs which have fewer and smaller cells. The effect on the lung appears to be greater than on the body as a whole. These hypoplastic lungs may be predisposed to the development of pulmonary disease and may explain observations of more frequent and severe lower respiratory infections in children with prenatal ethanol exposure.     

Effects of oral caffeine intubation on bones in protein-energy malnourished newborn rats

Lactating dams with 8 suckling pups were fed either a 6% or a 20% protein diet from the birth of the pups to day 15. The pups were divided into caffeine and noncaffeine groups. Every other day between days 3 and 13, pups were either intubated with caffeine (1 mg/100 mg) dissolved in 0.1 ml physiological saline solution, or 0.1 ml saline solution as a control. On day 15, mandible and long bone weights, DNA, protein and calcium contents, collagen synthesis and 45Ca uptake in these bones of the pups were studied. Nutritional factors exercised consistent effects on all the studied parameters, but there was no difference in effects attributable to caffeine intubation, except the increased collagen synthesis in the long bones of the group with 6% protein diet with caffeine as compared to noncaffeine members of the same dietary group. We concluded that the direct administration of a relatively small amount of caffeine to newborns causes minor effects on bone development under certain nutritional conditions.     

叶酸缺乏孕鼠子代脑组织DNA甲基化水平的变化

目的 :探讨叶酸缺乏对胎鼠宫内脑发育的影响 ,研究叶酸缺乏孕鼠子代脑组织基因组DNA甲基化水平的改变 ,为叶酸缺乏造成脑发育障碍提供分子和细胞水平的依据。方法 :雌性SD大鼠实验组 30只、对照组 2 0只 ,分别饲以不含叶酸和含 2mg叶酸 kg的纯合饲料 ,两周后与雄鼠交配 ,于怀孕第 2 0天对孕鼠剖腹取胎。对模型进行评价并观察叶酸缺乏对胎鼠发育的影响 ,高效液相色谱法检测胎鼠脑组织基因组DNA甲基化水平。对孕鼠妊娠晚期末血清叶酸、胎鼠血清叶酸及胎鼠脑组织DNA甲基化水平作相关分析。结果 :1 实验组孕鼠交配前及妊娠晚期末血清叶酸均明显低于对照组 ,外周血出现多分叶核粒细胞。实验组胎鼠血清叶酸也明显低于对照组 ,出现巨幼红细胞 ,RBC和Hb均低于对照组 ,且伴有宫内生长限制。 2 实验组胎鼠脑组织基因组DNA甲基化水平低于对照组 ,这种改变与孕鼠及胎鼠本身的血清叶酸浓度呈正相关。结论 :1 交配前两周开始限食叶酸直至妊娠期结束 ,所建立的叶酸缺乏孕鼠动物模型处于叶酸缺乏第三阶段 ,其胎鼠宫内生长受限制 ,红细胞出现巨幼变 ,但没有产生神经管闭合的异常。这是较理想的妊娠中晚期叶酸缺乏的大鼠动物模型。 2 母体叶酸缺乏时胎鼠的脑组织基因组DNA甲基化水平降低 ,这种改变与孕鼠及胎鼠本身的     

Effect of chronic caffeine intake on myocardial function during early growth

The purpose of these studies was to evaluate the effects of chronic caffeine ingestion on the myocardium during fetal and neonatal growth and development. The isolated perfused working heart preparation was used to evaluate cardiac function. During gestation and lactation, one group of dams consumed a caffeine supplemented diet (10 mg/kg/day). Their offspring were sacrificed and the hearts analyzed 50 days after birth. We found that the intake of caffeine by the dams resulted in significant increases in the offspring's coronary flow, peak systolic pressure, and myocardial work. A second group of dams ingested a diet containing caffeine (10 mg/kg/day) during lactation only. Their pups continued to consume the caffeine diet until 50 days. Pup hearts exhibited significant reductions in cardiac output, stroke volume, pressure development, myocardial work, and external efficiency when compared to controls. Caffeine did not affect body or heart weight or adipose size or number in these experiments. Thus, continued caffeine consumption following birth may alter cardiac performance of the offspring.     

Prenatal alcohol exposure: abnormalities in placental growth and fetal amino acid uptake in the rat

On day 20 of gestation, after ethanol feeding (27% ethanol calories, 25% protein), placental weights, DNA, RNA and water content were greater than in controls pair-fed an isocaloric diet without ethanol or those ad lib fed a pellet diet of similar composition. Rat litter size and fetal body, liver and brain weights were similar in all groups. In vivo fetal amino acid accumulation was significantly lower after alcohol exposure despite similar placental uptake. These results indicate that both placental hyperplasia and abnormal fetal amino acid uptake occur at a low alcohol dose when fetal body weight is unaffected.     

叶酸缺乏孕鼠子代血细胞形态学改变及脑额区皮层超微结构表现

探讨叶酸缺乏对胎鼠宫内脑发育的影响、研究叶酸缺乏孕鼠子代胎鼠脑组织超微结构的改变及为叶酸缺乏造成脑发育障碍提供细胞水平的依据 ,及采用雌性SD大鼠实验组 30只、对照组 2 0只 ,分别饲以不含叶酸和含 2mg叶酸 kg的纯合饲料 ,两周后与雄鼠交配 ,于怀孕第 2 0天对孕鼠剖腹取胎 ,对模型进行评价并观察叶酸缺乏对胎鼠发育的影响 ,应用透射电镜观察胎鼠额区皮层超微结构的改变。结果显示 :1 .实验组孕鼠交配前及妊娠晚期末血清叶酸均明显低于对照组 ,外周血出现多分叶核粒细胞。实验组胎鼠血清叶酸也明显低于对照组 ,出现巨幼红细胞 ,RBC和HB均低于对照组 ,且伴有宫内生长限制。 2 .实验组胎鼠额区皮层超微结构观察示 :神经元出现核切迹、局灶性核周腔扩张、异染色质减少、胞质内细胞器肿胀、核糖体减少 ;某些胶质细胞亦见类似改变 ;神经毡膜性结构不完整。结论 :1 .交配前两周开始限食叶酸直至妊娠期结束 ,所建立的叶酸缺乏孕鼠动物模型处于叶酸缺乏第三阶段 ,其胎鼠宫内生长限制 ,红细胞出现巨幼变 ,但没有产生神经管闭合的异常。这是较理想的妊娠中晚期叶酸缺乏的孕鼠动物模型。 2 .母体叶酸缺乏能造成胎鼠皮层脑组织超微结构的改变 ,可能导致神经元功能的紊乱和丧失 ,以致防碍脑结构和脑功能的正?     

Protein turnover in tissues of the fetal rat after prolonged maternal malnutrition

Protein turnover in fetal diaphragm, heart, liver, and brain was determined at 21 days gestation in fetal rats whose mothers had received a protein-restricted diet (6% protein) throughout gestation. This diet resulted in severe combined protein-calorie malnutrition. Fetal body weight was significantly decreased at days 19-22 gestation versus controls (27% protein diet) when pregnant animals were protein-restricted (e.g. 40% decrease in body weight at day 22 gestation versus controls). Protein synthesis was determined by intravenous injection of "massive" amounts of [3H]phenylalanine to pregnant animals and measuring free and protein-bound specific radioactivities in fetal tissues. Rate constants for protein degradation were calculated by subtracting fractional growth rate from protein synthesis. Fractional protein synthesis was reduced in diaphragm (0.26 versus 0.41 days-1), heart (0.41 versus 0.52 days-1), and liver (0.35 versus 0.89 days-1) in fetuses from malnourished mothers relative to controls. Similarly, fractional protein degradation was decreased in these fetal tissues-diaphragm (0.03 versus 0.06 days-1), heart (0.14 versus 0.18 days-1), and liver (0.25 versus 0.80 days-1). Reduced protein accretion during maternal malnutrition in these fetal tissues is secondary to decreased protein synthesis out of proportion to the concurrent reduction in protein degradation. Protein synthesis and degradation in fetal brain from malnourished mothers were not altered versus controls. These effects of malnutrition on protein turnover in fetal tissues throughout pregnancy in the rat correspond closely with the effect of protein restriction in young adult rats and the effect of protein-calorie malnutrition on whole body protein turnover in human infants.     

Placental growth and glycogen metabolism in streptozotocin diabetic rats

Placental glycogen metabolism was investigated in rat pregnancies complicated by streptozotocin-induced diabetes mellitus. Both diabetic and control placentas had increasing glycogen concentration from day 14 to day 16, after which glycogen concentration declined rapidly. The diabetic placentas had significantly elevated glycogen concentration when compared to controls from day 16 through term (day 22). Near term, when control glycogen content fell close to zero, the diabetic placentas still had appreciable glycogen levels. Total phosphorylase activity in the diabetic placentas was significantly higher than control values from day 16-22. Phosphorylase A activity, however, was lower in the diabetic placentas late in gestation, corresponding to the increased glycogen concentration seen at that time. Diabetic placentas had increased total synthase activity on the final 3 days of gestation, although synthase A activity was lower than corresponding control values. The placentas in this model are markedly increased in size late in gestation. No difference in protein concentration or protein/DNA ratio was noted. Total DNA content per placenta was significantly increased in the diabetic placentas after day 16 when compared to controls. Placental DNA in the diabetics continued to increase until day 18-19 of gestation, whereas DNA content in control placentas remained constant after day 16. Thus, the diabetic placentas apparently continue the process of DNA replication after DNA synthesis is complete in the controls.     

Caffeine decreases zinc and metallothionein levels in heart of newborn and adult rats.

The purpose of the present study is to show that dietary caffeine, heart tissue Zn levels, and metallothionein (MT) concentration are all interrelated in newborn rats. Dams with eight pups in the control group were fed a 20% protein diet upon delivery, whereas dams in the experimental group were fed a 20% protein diet supplemented with caffeine (2 mg/100 g body weight). Offspring were killed at d 22 postbirth and the hearts and livers were removed to determine the Zn and MT concentrations. Hearts of the newborn rats in the caffeine group showed decreased Zn levels as well as decreased MT concentration. To explain the observed effects in newborn rats, the relationship between Zn and MT levels was studied in adult female rats. They were injected intraperitoneally with either ZnCl2 (20 mg/kg body weight) dissolved in saline solution or ZnCl2 and caffeine (4 mg/kg body weight) over a period of 2 d. Injection of ZnCl2 into adult female rats resulted in an increase in heart MT levels, whereas injection of caffeine caused decreased Zn levels and MT concentration. Current findings indicate that dietary caffeine intake during the lactational period by newborn pups causes a decrease of the heart Zn and MT levels.     

Prenatal protein-energy malnutrition alters various biochemical components of the membranous bones in fetal rats

The effects of prenatal protein-energy malnutrition on the biochemical parameters of the membranous bone were studied using fetal rats. Timed pregnant rats were fed a protein-deficient diet as an experimental group from day 13 of gestation, whereas control dams were fed a normal protein diet. By day 15, radioactive Na2SO4 was injected. On day 22, all fetuses were delivered by cesarean section. The hexosamine content per milligram dry tissue, and the protein and hexosamine contents per guanidine-HCl extract were greater in the mandibles but less in the calvaria of the malnourished group than in those of the controls. Calcium content per gram dry tissue was lower in both bones of the malnourished group. 35S-sulfate uptake per milligram dry tissue or milligram proteoglycan was greater in the malnourished group than in the controls in both bones. The mandible in the malnourished group had less lower-weight molecular proteoglycan subunits in the dissociative condition. Protein-energy malnutrition affects the mandible and calvaria in different ways, although both bones originate from membranous bone. Insufficient degradation of proteoglycan could be the reason for the delay of mineralization in the malnourished bones.     

The postnatal development of rats born preterm and postterm. II. Liver, brain, heart and kidneys

Groups of 3 preterm (duration of gestation 22 days), 3 term (23 days), and 3 postterm (24 days) rats have been fed together by 1 mother rat. The postnatal growth of liver, brain, heart and kidney has been studied up to the 30th day of life. The postnatal loss of water shows good correlation with the maturation of each organ. The postnatal loss of water is marked in brain and kidneys, but only slight in liver and heart. The pronounced growth spurt of the brain at the about 10th day of life is probably due to the opening of the eyes. The growth spurt of the liver at the 15th day may be due to the supplementary food at the time of weaning. The effect of intrauterine undernutrition in postterm rats is most strikingly demonstrated in the liver. Postnatal undernutrition in preterm rats causes a retardation of growth of the liver and kidneys.     

Influence of different protein intake on renal growth in young rats

We have examined the effect of high protein intake on kidney growth and function in growing rats. The rats were kept on an isocaloric diet containing 12%, 21% and 50% protein, from weaning (16 days) until the time of investigation (18, 20, 24, 40 or 80 days). There was no significant difference between the 12% and 21% protein groups in any of the parameters studied. 50% protein increased body weight (BW) and kidney weight (KW). The increase in kidney weight was already evident after 2 days and exceeded the increase in body weight in all age groups. At 24 days renal cortical DNA and the protein/DNA ratio were significantly increased in the 50% protein group. At 40 days the cortical DNA content, but not the protein/DNA ratio, was significantly increased in the 50% group. The glomerular filtration rate GFR) was studied at 40 days. Total GFR as well as GFR/BW was significantly higher in the 50% group than in the 21% group. In one protocol the diet was discontinued at age 40 days and the rats were studied at age 80 days. In these rats all parameters of renal size and function were the same as in the rats that had had a normal (21%) protein intake from weaning. We conclude that in young rats high protein intake reversibly increases GFR out of proportion to BW and selectively and reversibly stimulates kidney growth by stimulating cell proliferation.     

Influence of Different Protein Intake on Renal Growth in Young Rats

ABSTRACT. We have examined the effect of high protein intake on kidney growth and function in growing rats. The rats were kept on an isocaloric diet containing 12%, 21% and 50% protein, from weaning (16 days) until the time of investigation (18, 20, 24,40 or 80 days). There was no significant difference between the 12% and 21% protein groups in any of the parameters studied. 50% protein increased body weight (BW) and kidney weight (KW). The increase in kidney weight was already evident after 2 days and exeeded the increase in body weight in all age groups. At 24 days renal cortical DNA and the protein/DNA ratio were significantly increased in the 50% protein group. At 40 days the cortical DNA content, but not the protein/DNA ratio, was significantly increased in the 50% group. The glomerular filtration rate (GFR) was studied at 40 days. Total GFR as well as GFR/BW was significantly higher in the 50% group than in the 21% group. In one protocol the diet was discontinued at age 40 days and the rats were studied at age 80 days. In these rats all parameters of renal size and function were the same as in the rats that had had a normal (21%) protein intake from weaning. We conclude that in young rats high protein intake reversibly increases GFR out of proportion to BW and selectively and reversibly stimulates kidney growth by stimulating cell proliferation.     

Effect of early weaning and prolonged nursing on development of the rat pancreas

Pancreatic development was studied in rats 17-28 days of age. Control pups, weaned naturally at 21-24 days showed a gradual increase in body weight, pancreatic weight, total DNA and protein content with age. Pups weaned at 17 days showed a transient increase in pancreatic weight and protein content only at day 22; at no time did they show a difference in either DNA content or body weight. Pups nursed up to 25 days of age had a smaller body weight, but had DNA and protein content similar to control rats. Control pups showed gradual increases in lipase and trypsinogen with a sharp increase in amylase between days 22 and 25. Pups weaned at 17 days showed a precocious increase in trypsinogen and a sharp increase in amylase between days 19-22, but an immediate decrease in lipase which eventually returned to the control level at day 28. Pups nursed beyond the weaning stage showed an increase in lipase and trypsinogen but no sharp increase in amylase. A significant increase in all pancreatic enzymes, pancreatic mass, pancreatic DNA and protein content was seen in all groups of rats irrespective of their diet. The results suggest an inherent biological program as a basic control of pancreatic ontogeny with diet playing a modifying role.     

Biochemical Studies on the Effect of Maternal Hyperphenyl-alaninemia on Fetal Brain Maturation of Mice

Abstract The effects of maternal hyperphenylalaninemia during pregnancy on the biochemical maturation of neonatal mice brains were examined, thus establishing the critical concentration of phenylalanine in maternal blood and the critical period of maternal hyperphenylalaninemia during pregnancy. Hyperphenylalaninemia was induced by giving chow supplemented with 3%, 4%, 5%, or 6% phenylalanine (Phe.) and 0.12% p-chlorophenylalanine (PCPA) for at least one month and then throughout pregnancy. Some of the pregnant mice fed the 6% Phe. diet before pregnancy received a normal diet after conception (6%: A).
Offspring from each group were decapitated two days after birth. Their brains were removed and then divided into the cerebrum and the brain stem including the cerebellum. Total protein, RNA and DNA were measured biochemically. All kinds of markers of the newborn mice born to the 5% and 6% mothers, the weight and the contents of the protein, RNA and DNA, were reduced significantly in both the cerebrum and brain stem. In the 4% group, however, only the brain stem was affected. The 3% group showed reductions neither in the weight nor the protein and nucleic acids contents in both the cerebrum and brain stem. In the 6%:A group, in which the diet was returned to normal just after conception, total protein, RNA and DNA were reduced in the brain stem, but not in the cerebrum.
These results suggest that the critical concentration of maternal blood phenylalanine during pregnancy in the mouse is 11mg/dl, which is that corresponding to the 3% group, and also suggest that it is too late to begin the low phenylalanine diet after conception.     

Antenatal dexamethasone administration increases fetal lung DNA synthesis and RNA and protein content in nitrofen-induced congenital diaphragmatic hernia in rats

Antenatal glucocorticoids treatment has been shown to correct pulmonary immaturity. The thymidine analog bromodeoxyuridine (BrdU) is incorporated into S-phase cells and used as a marker of DNA synthesis. In this study, we investigated the effect of antenatal glucocorticoid administration on DNA synthesis and RNA and protein content in nitrofen-induced congenital diaphragmatic hernia (CDH) in rats to better understand the effect of antenatal glucocorticoids on CDH lung. The CDH model was induced in pregnant rats using nitrofen. Dexamethasone (0.25 mg/kg) was given on d 18.5 and 19.5 of gestation (term = 22 d). BrdU was administered 1 h before fetuses were killed on d 21, and detected by immunohistochemistry. DNA synthesis was evaluated by percentage of BrdU-incorporated nuclei (BrdU labeling index). Total RNA and soluble protein were extracted from another set of left lungs to measure RNA and protein content. BrdU labeling index and total RNA content were significantly decreased in CDH lung compared with control rats. Antenatal dexamethasone treatment significantly increased BrdU labeling index and RNA and protein content in the left CDH lung. Our findings of decreased DNA synthesis and decreased RNA and protein content in CDH lung suggest that lung growth and development are suppressed in hypoplastic CDH lung. Increased DNA synthesis and increased RNA and protein content in dexamethasone-treated CDH lung suggest that antenatal glucocorticoids may accelerate fetal lung growth and development in CDH.     

Neuropathological changes in the cerebrum of IUGR rat induced by synthetic thromboxane A2.

IUGR was induced by maternal administration of synthetic thromboxane A2 (STA2) from the 13th day of gestation. Fetuses and neonates showed a markedly significant weight reduction. In E16 IUGR brain, no pathological abnormalities were found, but morphological changes appeared in the cortical plate of E18 IUGR brain. In E20 IUGR brain, ectopic clusters of differentiating cells cytologically mimicking neuroblasts were found in the neuroepithelial layer, but these abnormal clusters of cells in IUGR brain of late gestation were never observed in PN7. Morphometric analysis of coronal-sectional areas of the brain and cortical plate demonstrated that there were no differences between IUGR rats and controls in E16 and E18. These areas were, however, significantly reduced in E20 and PN7 growth-retarded rats compared with the control. Because the period of STA2 administration coincides with the neuro-developmental stage of cell migration and differentiation, reduction of the uteroplacental blood supply might cause a transient abnormal cytoarchitecture of the cerebral cortex resulting in brain growth retardation.     

Vitamin D deficiency, pancreatic and small intestinal enzyme development in rats

Maternal vitamin D deficiency has been shown to lead to reduced body weights in developing rat pups. To evaluate the effects of vitamin D deficiency alone both in dams and pups during the perinatal age on the ontogeny of gastrointestinal enzymes, female weanling rats (3 weeks of age) were divided into three groups. Groups I and II were fed a control (vitamin-D-replete) diet. Group II were fed a vitamin-D-deficient diet. Six weeks afterward they were mated with normal male rats while continuing on their respective diets until sacrifice. Only rats that delivered their pups on the same day from each group were brought into the study. Litter sizes of groups I and II were adjusted to 10, while group III was adjusted to 13 such that the rate of growth paralleled that of group II. At 19 days after birth, all dams and pups were sacrificed. There were no differences in the calcium and phosphorus contents in breast milk obtained from dams of each group. The serum calcium concentration of pups from group II (vitamin-D-deficient) was lower than the other groups. Body weights of pups from groups II and III were significantly lower than those of group I. The mucosal weight, total mucosal protein, mucosal DNA, sucrase, and maltase activities from groups II and III were similar, but lower than group I. Pancreatic weight, total pancreatic protein, DNA, amylase, and lipase activities from groups II and III were also similar, but lower than group I. Vitamin D deficiency was confirmed in both dams and pups from group II.(ABSTRACT TRUNCATED AT 250 WORDS)