CARBOHYDRATE AND ENERGY METABOLISM IN PERINATAL RAT BRAIN: RELATION TO SURVIVAL IN ANOXIA

The ability of rats of different ages to survive exposure to anoxia was correlated with rates of high energy phosphate consumption (metabolic rates) of the fore-brain. Fetal rats at term, delivered by hysterotomy following maternal decapitation, survived in nitrogen at 37°C twice as long as 1-day-old neo-nates, 5 times longer than 7-day-old rats, and 45 times longer than adults. During ischemia induced by decapitation, the cerebral concentrations of the labile energy reserves (ATP, ADP, P-creatine, glucose and glycogen) and of lactate were determined in fetuses, 1- and 7-day post-natal animals. From the changes, the cerebral energy use rates were calculated to be 1·57 mmol/kg/min in fetuses, 1·33 mmol/kg/min in 1-day-olds and 2·58 mmol/kg/min in 7-day-olds. Maximal rates of lactate accumulation during ischemia, as a measure of glycolytic capacity, were comparable in fetuses and neonates, but were about twice as great in 7-day-old rats. It is concluded that in post-natal animals survival in anoxia and cerebral energy consumption are inversely, and nearly quantitatively, related. However, the reduced cerebral energy requirement cannot entirely account for the greater anoxic resistance of fetuses.     

BRAIN EXTRACELLULAR POTASSIUM AND ENERGY METABOLISM DURING ISCHEMIA IN JUVENILE RATS AFTER EXPOSURE TO HYPOXIA FOR 24 h

Abstract— The ischemia-induced change of brain extracellular potassium concentration [K⁺]_e and brain energy metabolism was studied following decapitation of normal 7-dav-old rats and 7-day-old rats exposed to a simulated altitude of 6000 m ( p O₂= 70 mm Hg) for 24 h. Initially there was in both groups a slow rate of rise of [K ⁺]_e followed by a faster rise until a steep increase occurred. In the group exposed to hypoxia the initial rate of rise was lower and the duration until the steep increase twice as long as in the normal group. Energy consumption expressed as Δ# P and the rates of lactate accumulation were similar in the two groups in the first minute following decapitation. After 2 min the Δ# P and the rate of lactate accumulation was higher in the group exposed to hypoxia. These findings are explained by a doubling of the glucose concentration in the brain of the rats exposed to hypoxia, permitting anaerobic glycolysis to maintain ATP regeneration for a longer time during ischemia.     

Activity and Isoenzyme Pattern of Lactate Dehydrogenase in Neurons and Astroblasts Cultured from Brains of Chick Embryos

Primary cultures of neurons and glial cells (astroblasts) prepared from brains of 8-day-old and 15-day-old chick embryos, respectively, were grown for periods between 3 and 19 days. Specific activity of lactate dehydrogenase (LDH) increased in both types of cultures as a function of time and was always significantly higher in glial cells than in neurons. Glial cell extracts were found to contain predominantly the anaerobic isoenzymatic form of LDH (LDH-H4), and this pattern did not change over a period of 19 days. Cultured neurons contained predominantly the aerobic isoenzymatic form LDH-H4, and there was a progressive appearance of all other isoenzymes over an 8-day period. These results support the hypothesis of a different energy metabolism in neurons and glia.     

Rate of gluconeogenesis in the hepatocytes of the developing chick embryo

The rate of glucose formation from lactate was determined in the hepatocytes isolated from the liver of developing chick embryos and one day old chickens. The maximum rate of gluconeogenesis is observed in the hepatocytes of 16-17 day old chick embryos. A sharp fall in the rate of gluconeogenesis is noted in the hepatocytes of the embryos before hatching. It decreases still further in one day old chickens. The patterns of the gluconeogenesis rate are similar both for endogenous precursors and lactate.     

Biosynthesis of poly(A)-RNA and differentiation in chick erythrocytes

The rates of synthesis of poly(A)-containing RNA species in the nuclei of erythrocytes from 4- to 9-day-old chick embryos were determined by poly(T)-cellulose chromatography and were found to vary according to the developmental stages of the chick embryos. The rate appeared to increase 1 day prior to the onset of hemoglobin differentiation. The enzymatic activities of ATP polymerization in the nucleus of these erythrocytes were also examined. The enzymatic activity was resolved into two fractions on O-(diethylaminoethyl) cellulose. The ratio of the two enzymatic activities remained relatively constant in erythrocytes from 4- to 19-day-old embryos. However, a threefold increase in the total poly(A) polymerase activities was observed 1 day prior to the onset of hemoglobin differentiation. These results indicate that hemoglobin differentiation in these erythrocytes is associated with an increase in the rate of synthesis of poly(A)-containing RNA and in the activities of poly(A) polymerases.     

Energetics of Anaerobic Sodium Transport by the Fresh Water Turtle Bladder

Certain of the metabolic events associated with anaerobic sodium transport by the isolated bladder of the fresh water turtle have been investigated. The data suggest that energy for this transport arises from glycolysis and that endogenous glycogen was the major and perhaps the sole source of substrate. The rate of anaerobic glycolysis, as determined by lactate formation, correlates well with the rate as determined by glycogen utilization. Using lactate formation as the index of anaerobic glycolysis, a linear relationship was observed between glycolysis and net anaerobic sodium transport. In the absence of sodium transport, glycolysis decreased by approximately 45 per cent. Tissue ATP concentrations were maintained at about the same level under anaerobic as under aerobic conditions. Finally if it is assumed that in the conversion of glycogen to lactate anaerobically, 3 moles of ATP are generated per mole of glucose residue, an average of over 15 equivalents of sodium were transported for every mole of ATP generated.     

Metabolism of glucose by human embryos

Glucose turnover, as measured by CO2 production, lactate accumulation and carbon incorporation from [U-14C]glucose as sole energy substrate, was low on the 2nd day of culture of human embryos resulting from in-vitro fertilization but above that of unfertilized oocytes. In general, all parameters of metabolism increased substantially during the following 2 days of development but the rate of increase in lactate production was greater than that of CO2, especially between Days 3 and 4. Within developing embryos, no correlation was evident between the metabolic turnover of glucose and the method of patient stimulation, the morphological quality of embryos or the apparent rate of cleavage in culture. The results indicate that, before Day 3 of development, glucose is not effective as an energy source for the human embryo because of a blockade to glycolysis similar to that in mouse embryos.     

Energy metabolism of nerve cells during differentiation : O2 uptake, lactate production and ATP content of chick embryo brain cells before and after cultivation in the rose chamber

Mechanically dissociated brain cells from 7-day-old chick embryos were grown in Rose chambers. Cells in such cultures show a marked morphological differentiation into neuronal cells resting on a confluent monolayer. In the present study the rate of O₂ uptake and lactate production and the content of ATP per neuronal cell were measured at different times of cultivation and compared with the same parameters in cells obtained from the brain of the living embryo.In 2–4-day-old cultures, both O₂ uptake, lactate production, and ATP content were identical to the values observed in the ‘fresh’ cells from which the cultures had been prepared.The rate of O₂ uptake increased as a function of the age of the culture in parallel with the increase in the rate of O₂ uptake observed in the embryo. The rate of anaerobic lactate production increased during cultivation as a function of the age of the culture (as known from other in vitro systems), whereas the glycolytic rate in the embryo decreased with development. The ATP content remained approximately constant.The observations suggest that cultures of dissociated brain cells may undergo a considerable degree of metabolic differentiation and thus be well suited for studies of metabolic events in the nervous system.     

ACETYLCHOLINESTERASE IN DEVELOPING CHICK EMBRYO BRAIN

–Acetylcholinesterase has been assayed at different stages of development to see whether changes in the activity of this enzyme are correlated in any way with the ontogenesis of electrical activity in the brain of growing chick embryo. The specific activity of the enzyme was highest in the synaptosomal fraction of the brain. The activity of the enzyme increased progressively with the age of the embryo. There were three isozymic forms of the enzyme in the 6-day-old embryo brain. A new isozyme appeared around the 9th day. The K_m values of the enzyme for acetylthiocholine from 6- and 20-day-old embryo brains were 6.5 ± 10^-5m and 3.3 ± 10^-5m respectively. Enzyme preparations from 6-day-old embryos were found to lose 50 per cent of their activity when heated at 50°C for 10 min. Under similar conditions the loss in activity in 18-day-old embryo brain enzyme was 22 per cent.     

Significance of energy metabolism pathways for stimulation of DNA synthesis by cell migration and serum

The relationships between cell locomotion, pathways of energy metabolism, and DNA synthesis were studied on chick embryo fibroblasts growing in the presence of chick or calf serum. It was shown that: (a) 2'-Deoxyguanosine (2'GdR) inhibits the DNA synthesis but does not decrease the rates of cell locomotion, lactate production, and oxygen consumption. (b) Cell locomotion is dependent on energy from either glycolysis or oxidative phosphorylation. (c) The rate of DNA synthesis is not correlated with the rate of glycolysis. In the presence of ribose and glutamine instead of glucose, DNA synthesis occurred at the same rate as in the presence of glucose despite lactate production being ten times lower. (d) 2,4-Dinitrophenol (2,4-DNP) does not decrease the rate of DNA synthesis whereas KCN inhibits it. (e) Chick serum stimulates more strongly lactate production, oxygen consumption, and DNA synthesis as well as cell locomotion than calf serum. The metabolic basis for the often observed coupling between cell locomotion and DNA synthesis in anchorage-dependent cells is discussed as well as the reasons for uncoupling of these processes in cancer cells or in normal cells under experimental conditions.     

Lactate, 3-hydroxybutyrate,and glucose as substrates for the early postnatal rat brain

The dependence of cerebral energy metabolism upon glucose, 3-hydroxybutyrate, and lactate as fuel sources during the postnatal period was investigated. The brain of 6 day old suckling pups used very little glucose, but by the 15th postnatal day glucose was the major catabolite. Hydroxybutyrate was not a major brain fuel at either 6 or 15 days of age. Its utilization accounted for only 19% of the brain's total energy needs at 15 days of age, even though blood ketone concentrations are near maximal at this time. Seventy percent of the cerebral metabolic requirements were met by lactate in animals aged 6 days. The major role played by lactate as a substrate for brain metabolism in young pups was not a result of abnormally elevated blood lactate concentrations. The slow catabolism of glucose in young brain can not be explained by low rates of influx or inadequate enzymatic capacity.     

Na+-driven ATP synthesis of a psychrophilic marine bacterium, Vibrio sp. strain ABE-1

Abstract: In vivo ATP synthesis of a psychrophilic marine bacterium, Vibrio sp. strain ABE-1, derived from endogenous respiration, was examined. ATP was synthesized at both pH 6.5 and 8.5 after the start of the endogenous respiration by supplying O₂ to the anaerobic cell suspension. The ATP synthesis at pH 6.5, but not at pH 8.5, was completely inhibited by a H⁺ conductor, carbonylcyanide m -chlorophenylhydrazone (CCCP). The CCCP-resistant ATP synthesis at pH 8.5 was strongly inhibited by an inhibitor of the respiration-dependent primary Na⁺ pump, 2- n -heptyl-4-hydroxyquinoline N -oxide, and essentially required Na⁺. These results show that this bacterium synthesizes ATP at pH 6.5 by electrochemical potentials across the membrane Δ ∼ μ _H+, whereas at pH 8.5 by Δ ∼ μ _Na+ but not Δ ∼ μ _H+.     

Early Morphogenesis of Chick Gonad in the Absence of Mesonephros

The development of the gonads in male and female chick embryos with induced unilateral mesonephric agenesis was studied using grafting, histoenzymology, and electron microscopy. As in embryos with a mesonephros, proliferation of the coelomic epithelium and its interaction with mesenchymal cells to form the medullary cords take place in the amesonephric gonads. In a similar manner, gonadal sexual differentiation and the differentiation of steroidogenic tissue, detectable by the presence of Δ5-3β-hydroxysteroid dehydrogenase, do not appear to be affected by the absence of an organized mesonephros. However, the initiation of gonadal development, further growth, and the onset of meiosis observable in developing ovaries are retarded. This delay appears to be reversible, as was demonstrated by experiments in which ovaries from chicks with complete mesonephric agenesis were transplanted into the coelomic cavity of male and female 3 1/2-day-old embryos. Meiosis finally occurred in the oocytes of all ovaries, regardless of the sex of the host. Therefore, the presence of a differentiated mesonephros in chick embryos is not required for the establishment of an undifferentiated gonad and sexual differentiation, or for initiation of meiosis.     

THE ONTOGENY OF DOPAMINE-DEPENDENT INCREASE OF ADENOSINE 3'',5''-CYCLIC MONOPHOSPHATE IN THE CHICK RETINA

The adenosine 3′,5′-cyclic monophosphate level of chick embryonic retina changes during the course of development. In retinas from 6- to 15-day-old embryos the cAMP level is approximately 7 pmol/mg protein. A sharp 3-fold increase is observed between the 16th and 18th embronic day and remains constant thereafter. A dopamine-dependent increase in cAMP of the chick retina is already present in 7-day-old embryos, and by the 8th embryonic day maximal response is attained. Glutamate promotes a 2-fold stimulation. Carbachol, γ-aminobutyric acid and glycine do not cause any significant change in the level of cAMP of the embryonic tissue. Guanosine 3′,5′-cyclic monophosphate also accumulates during development. Its concentration is approx 0.5 pmol/mg protein from the 8th to the 14th embryonic day, then increases gradually until the 19th day of development when the level observed is approx 14 pmol/mg protein.     

Effect of nanoparticles of silver and gold on metabolic rate and development of broiler and layer embryos

This investigation evaluated the effects of nanoparticles of silver (AgNano) and gold (AuNano) on metabolic rate (O₂ consumption, CO₂ production and heat production-HP) and the development of embryos from different breeds of broiler and layer chicken. Gaseous exchange was measured in an open-air-circuit respiration unit, and HP was calculated for 10, 13, 16 and 19-day-old embryos. Relative chick and muscle weights were used as a measure of growth rate and development. AgNano but not AuNano increased the rates of O₂ consumption and HP of the layer embryos. The metabolic rate of broiler embryos was not affected by either of the treatments, but it was significantly higher compared to the layer embryos. Neither of the nanoparticles promoted nor depressed growth and development of the embryos, irrespective of breed. Although the metabolic rate of AgNano-injected layer embryos was significantly increased, their BW and muscle weights at hatching were similar to those of the control group, which suggests that the concentration of AgNano used was adequate for increasing the metabolic rate but not enough to affect growth and development. The results show that AgNano could be a potential metabolic modifier for layer embryos; however, the exact mechanism of action should be elucidated in future research.     

SENSITIVITY OF EARLY EMBRYONIC THYMIC LYMPHOID DEVELOPMENT TO 3H-THYMIDINE OF HIGH SPECIFIC ACTIVITY

The pulse technique, using high specific activity ³H-TdR to selectively kill cells in cell cycle, was applied to the thymic anlagen of chick embryos. With optimal specific and total ³H-TdR activities and pulse times of 2–4 hr the subsequent lymphoid development in organ culture of the thymic anlagen of 10-day-old chick embryos could be almost completely inhibited. The most important effect of the ³H-TdR was on the lymphoid precursor cells of the anlagen. The thymic epithelium appeared more resistant to ³H-TdR and allowed a lymphoid development of pulsed anlagen grafted to the chorioallantoic membrane of chick embryos when new lymphoid precursor cells were provided. The lymphoid precursor cells of the thymic anlagen of 10-day-old chick embryos therefore appeared to be in cell cycle with short generation time. The thymic anlagen of 8-, 9- and 10-day-old but not 7-day-old embryos showed a lymphoid development in organ culture. They did not differ with respect to the sensitivity to hot pulses of ³H-TdR. Thus no evidence of a lag in the onset of lymphoid precursor cell proliferation during the development of the early embryonic chick thymus was noted.     

Developmental changes in collagen glycosyltransferase activities in chick embryos

The developmental pattern of collagen galactosyltransferase and collagen glucosyltransferase activities was determined in chick embryos between the 4th and 21st day of growth. Both enzyme activities increased up to the 16th day and decreased thereafter in whole chick embryos and in most tissues studied. The highest collagen glycosyltransferase activities were found in the leg tendons of the 16-day-old embryos, and the activities found in cartilage were higher than those noted in either skin or skull, indicating that the the activities of the collagen glycosyltransferases may play a part in the regulation of the carbohydrate content of the collagen synthesized by a given tissue. The changes observed in the collagen glycosyltransferase activities agree with previous data on the development of prolyl and lysyl hydroxylase activities and also with findings on collagen turnover in the developing chick embryo.     

Erratum

Cultured heart cells from 2–3 day old and 5–6 day old neonatal rats have been used as a model system for the characterization of carbohydrate metabolism in developing cardiac tissue. The rate of depletion of glucose from the growth medium was dependent on (1) the age of the animals from which the cultured cells were obtained, and (2) the presence and absence of serum and/or insulin in the growth medium. The glucose depletion rate in insulin and serumcontaining medium was 9.63 ± 0.96 nmol/min/mg protein for heart cell cultures from, 2 day old rats and 3.51 ± 0.68 nmol/min/mg protein in heart cell cultures from 5 day old rats. Appearance of lactate in the medium during these experiments occurred at the rates of 18.6 ± 7.9 nmol/min/mg and 6.4 ± 1.2 nmol/min/mg, respectively. In the absence of serum and insulin, the medium glucose depletion rates were 5.7 ± 1.6 and 2.2 ± 0.5 nmol/min/mg for cells derived from 2-day-old and 5-day-old rats, respectively. It is apparent from these data that immature cardiac cells depend upon glucose as a primary source of energy for muscle contraction and cellular growth, and that less-efficient energy-yielding metabolic pathways are used to obtain ATP.     

Cultivation of the cercaria of Himasthla quissetensis (Trematoda) on the chick chorioallantois

Cercariae of Himasthla quissetensis were cultivated on the chick chorioallantois maintained at 38 ± 1°C and a relative humidity of 70–75%. Of 68, 6-day-old eggs, each inoculated with 100 cercariae, 28 (41%) were examined 1–9 days post-inoculation. Of the 28 eggs, 23 (82%) were infected with a total of 224 live worms plus 10 encysted metacercariae. Worms contained blood or hematin-like material in their intestinal caeca and showed considerable development of reproductive structures. A total of 58, 6- or 7-day-old chorioallantoic-worms were serially transferred to new 6-day-old embryos, but only a single live worm was recovered after 13 days on two membranes. Based on fixed and stained specimens, 7-day-old chorioallantoic-worms increased their body area about 4× compared to cercariae and the 13-day-old worm increased its body area about 10×.     

Developmental changes in prolyl hydroxylase activity and protein in chick embryo.

Changes in prolyl hydroxylase activity and immunoreactive protein were studied in various chick embryo tissues during the embryonic development. Both the enzyme activity and the amoung of immunoreactive protein increased till the 16th day of development and declined thereafter in all tissues studied. Comparison of the enzyme activity to the content of the total immuno-reactive protein indicated that there are distinct differences in the degree of enzyme activity between different chick embryo tissues, and in the same tissue between different stages of embryonic development. The highest relative enzyme activities were found in cartilage and skin, in which about 60% of the enzyme was active on the 16th day of development and only 20-30% was active on the 20th day of development; the lowest values were observed in spleen and large vessels, in which below 10% of the enzyme protein was in the active form on the 20th day of development Gel filtration studies demonstrated that in cartilage of 16-day-old chick embryos about 60% of the total immunoreactive enzyme in the tissue was present in the form of active prolylhydroxylase tetramer, whereas on the 20th day of development only 30% of the enzyme protein in cartilage was in the tetramer form. By contrast, in large vessels of the 16-day-old chick embryos, essentially all the enzyme was in the form of prolyl hydroxylase monomers.