Changes in the content of glutamic, aspartic and gamma-aminobutyric acids in mitochondrial fractions of limbic system structures of the dog brain during postnatal ontogenesis

Calculation of the amount of mitochondria isolated from 1 g of fresh tissue has shown that the amount of glutaminic (GA), aspartic (AsA) and gamma-aminobutyric (GABA) acids in the initial mitochondrial fraction of the limbic structure increased during the postnatal ontogenesis and reached the "adult" level in dogs aged 1 year. The GA amount in all the studied periods of the ontogenesis exceeded the AsA and GABA levels in the mitochondrial fraction of the limbic structure.     

Ontogenesis of Monoamine-Synthesizing Enzyme Activities and Biopterin Levels in Rat Brain or Salivary Glands, and the Effect of Thyroxine Administration

Neonatal changes in the activities of tyrosine hydroxylase (TH) and tryptophan hydroxylase (TrpH) and in the content of the co-factor, biopterin, were studied in rat midbrain for the first 20 days after birth. Changes in TH activity in the parotid and submandibular glands were also examined. Changes in TH activity per unit weight in the developing rat brain were briefly similar to those in the salivary glands; the activity increased from day 2 or 4 to day 9 after birth, and remained constant or slightly decreased at day 12, then rapidly increased on day 16. TrpH activity in the midbrain increased about twofold up to day 16. The biopterin concentration in the brain increased, reached a maximum level on day 12 after birth, and thereafter decreased. The effect of hyperthyroidism in rats given 0.2 mg/kg i.p. of thyroxine every 2 days postnatally was studied on the activity of TH in rat salivary glands at 12-day-old rats. In parotid or submandibular gland of hyperthyroid rats, TH activity increased at day 12 postnatally. In comparison with the effect on TH activity in the salivary glands, TH activity in the midbrain on day 20 postnatally was not induced by hyperthyroidism. Furthermore, increase of the TrpH activity and biopterin and catecholamine levels in the midbrain of hyperthyroid rats was not found on day 20 after birth in comparison with the corresponding controls. From these data, we suppose that postnatal hyperthyroidism may cause precocious induction of TH in rat salivary gland, but may not increase the activity of TH or TrpH, and the level of their co-factor, biopterin, in rat midbrain.     

Postnatal Changes in Enzyme Activities in Synaptosomes Isolated from Hamster Optic Nerve Endings

Subsynaptosomal fractions isolated from optic terminal nuclei of adult and neonatal hamsters exhibited developmental changes in specific density, mitochondrial activity, and K+-stimulated, ouabain-inhibited p-nitrophenylphosphatase (K-pNPPase) activity around the time of eye opening. The specific activity of K-pNPPase was six- to sevenfold higher after eye opening (14-16 days postnatal). A significant proportion of high-specific- activity K-pNPPase was recovered from the lightest subsynaptosomal fraction at all ages. This fraction contained very little external membrane by galactose oxidase - NaB3H4 labeling, suggesting that it may represent an internal pool, possibly the axonally transported form of the enzyme. Synaptic mitochondrial cytochrome c. oxidase activity also approximately doubled in the period between 12 and 16 days. The specific density of the external membrane increased very slowly, banding at 1.0 M sucrose at 12 and 16 days, and at 1.2 M in adults. These maturational events may reflect increased energetic needs for optic nerve endings following eye opening.     

Creatine biosynthesis enzymes in the postnatal development of rats: the role of cyclo-3',5'-AMP and glucagon in the postnatal induction of liver guanidine acetate-N-methyltransferase]

The activity of enzymes of creatin biosynthesis in the rat liver and kidneys has been studied during the postnatal development. The activity of transamidinase of kidneys (E.C. 2.1.4.1.) increases gradually and linearly up to the 20th day after birth, then decreases on the 12th--25th days and increases again up to the level characteristic of the adult organism. The activity of guanidine acetate-N-methyl transferase (E.C. 2.1.1.2.) is rather high during the first days of postnatal development, then decreases and from the 15th day on increases again attaining the maximal level by the 23rd--25th day. The second period of the increase in the enzyme activity begins on the 29th--30th day of postnatal development. The results obtained suggest that the sharp increase of activity of guanidine acetate-N-methyl transferase of the rat liver during the early postnatal development is realized with the participation of cyclic 3',5'-AMP which appears to mediate the glucagon action.     

Subcellular distribution of the phosphate-activated glutaminase activity in the visual analyzer of the brain during postnatal ontogenesis in dogs

The level of general activity of phosphate-activated glutaminase (PAG) on the 1st postnatal day was higher in heavy and light synaptosomes of the exterior geniculate body (EGB) and lower--in the superior colliculus (SC) and visual cortex (field 17); in the subfractions of synaptic mitochondria (E) the general activity of the enzyme was higher in EGB and lower in the visual cortex (field 17) and SC. The level of general activity of the enzyme in the subcellular formations and certain formations of the visual analyzer on the 1st postnatal day was different. This difference varied in the course of postnatal development of the visual system in dogs. The PAG general activity in the subfractions of light (C), heavy (D) synaptosomes, synaptic mitochondria of the membranous enzymes and small synaptosomes sharply enhanced in the visual cortex (field 17) of SC and EGB from the 1st to the 12-14th postnatal days, the subfractions C and D of the visual cortex (field 17) showing the highest degree of the enzyme activity up to the 45th day. SC and EGB subfractions showed a considerable decrease in the enzyme activity of dogs aged 3 months; this peculiarity persisted up to the 6-month age in the above formations, especially in the subfractions B, C, D and E. Dogs aged 1 year exhibited a sharper decrease in the general activity of the enzyme of formations C, D, E in EGB and SC. It was established that with an advance of age the general activity of the enzyme in myelin subfractions (A) mostly increased, especially in the visual cortex (field 17) and EGB of dogs aged 1 year and in SC of dogs aged 6 months.     

Effect of cortisone on the developmental pattern of the neutral and the acid β-galactosidases of the small intestine of the rat

1. The developmental pattern and effect of cortisone on acid beta-galactosidase and neutral beta-galactosidase were studied in postnatal rats by a recently proposed method for their independent determination. 2. After birth the acid beta-galactosidase activity increases in the ileum, whereas it decreases slightly in the jejunum. On day 16 after birth the activity in the ileum decreases and in 20-day-old rats activity in both parts of the intestine decreases to adult values. In suckling animals the activity in the ileum exceeds the jejunal activity severalfold and in adult animals the activity in the jejunum is slightly higher than that in the ileum. 3. Neutral beta-galactosidase activity is high after birth and decreases in both jejunum and ileum after day 20 after birth. In 12-20-day-old rats activity in both parts is essentially the same, but in adult animals jejunal activity exceeds ileal activity four-to five-fold. 4. Cortisone (0.5, 2.0 or 5.0mg/100g body wt. daily for 4 days) does not influence the activity of either enzyme in 60-day-old rats. Acid beta-galactosidase activity is decreased after cortisone treatment in 8-, 12-, 16-and 18-day-old rats, with sensitivity to cortisone increasing with the approach of weaning. No effect of cortisone on acid beta-galactosidase is seen in 8-day-old rats. Neutral beta-galactosidase activity is increased in the ileum of 8-, 12-, 16- and 18-day old rats, but only in the jejunum of 8-and 12-day-old rats.     

Alterations in enzyme and cytochrome profiles of Rana catesbeiana liver organelles during thyroxine-induced metamorphosis. Changes in membrane-localized phosphohydrolases, oxidoreductases, and cytochrome levels in response to in vivo thyroxine administration.

A primary objective of the present study has been to determine the changes which occur in Rana catesbeiana liver organelle membranes during thyroxine-induced metamorphosis. To this end, enzyme and cytochrome profiles were determined for mitochondria, microsomes, and nuclear membrane fractions isolated from livers of R. catesbeiana tadpoles which had been fasted for 6 days at 15 +/- 0.5 degrees and then immersed in thyroxine, 2.6 X 10(-8) M, for periods of up to 12 days at 23.5 +/- 0.4 degrees. The ratio of total succinate-cytochrome c reductase activity in the initial homogenate fraction to the total activity of this mitochondrial "marker" enzyme recovered in the final mitochondrial fraction remained constant, approximately 0.5, throughout the course of thyroxine treatment; however, after a 3- to 4-day latency the mitochondrial protein mass recovered per unit mass of initial homogenate protein was found to increase significantly (approximately 2-fold by Day 10 of thyroxine treatment). A similar increase was also observed in the yield of microsomal, but not nuclear membrane, protein mass as a function of thyroxine treatment. Prolonged thyroxine treatment (12 days) resulted in approximately 50% decreases in tadpole liver homogenate and microsomal NADH-cytochrome c reductase specific activities; in contrast, mitochondrial and nuclear membrane NADH-cytochrome c reductase specific activities were not altered under the same conditions. In addition, homogenate and microsomal NADPH-cytochrome c reductase specific activities were found to have increased significantly after 12 days of thyroxine treatment; however, the specific activity of NADPH-cytochrome c reductase in the mitochondrial fraction was unchanged. It was also observed that thyroxine treatment resulted in increases in homogenate and microsomal glucose-6-phosphatase specific activities, whereas the mitochondrial as well as nuclear membrane glucose-6-phosphatase specific activities remained unchanged. Furthermore, in contrast to homogenate and mitochondrial monoamine oxidase specific activities, which decreased 30 and 40%, respectively, as a consequence of thyroxine treatment (12 days), the succinate-cytochrome c reductase and oligomycin-sensitive Mg2+ ATPase specific activities determined for these fractions increased significantly. In all instances, changes as a result of thyroxine treatment in membrane-localized homogenate or organelle enzyme specific activities were apparent only after a 3- to 4-day initial latent period. The in vitro effects of thyroxine (10(-10) - 10(-5) M) on the membrane-localized enzyme activities examined in this study were either negligible or, as in the case of mitochondrial succinate-cytochrome c reductase and microsomal NADH-cytochrome c reductase, opposite to the changes observed in response to in vivo thyroxine treatment, with the exception of microsomal NADPH-cytochrome c reductase activity which was enhanced approximately 2-fold by 10(-5) M thyroxine...     

Intracellular distribution of creatine kinase isoenzymes in the brains and hearts of rats at different stages of postnatal development]

The total activity and range of the creatine kinase (CK) isozymes have been studied in the homogenate and subcellular fractions (nuclei, mitochondria, cytoplasm) of the rat brain and heart during postnatal ontogenesis. The total activity of CK in the brain and heart of newborn rats was found to be 4 and 2 times less, resp., than in those of adults. The age patterns were established in the activity of cytoplasmic (CK-1, CK-2 and CK-3) and mitochondrial (CK-4) isozymes. During the whole postnatal development the rat brain contains only one cytoplasmic isozyme, CK-1. In the heart of newborn rats, as compared with adults, the content of CK-1 and CK-2 is much higher and that of CK-3 lower. On the 12-15th day of life the range of the CK isozymes approaches that characteristic of adult animals. The activity of CK-4 was found in the brain on the 5-7th day of life and in the heart on 12-15th day. In the range of the CK isozymes in the adult brain the content of mitochondrial CK amounts to 19.3% and in the heart to 16.5%. The data obtained complement the literary ones suggesting the low level of energy-forming processes in the brain and heart cells at the early stages of the rat postnatal development.     

Variations of D (-)-beta-hydroxybutyrate dehydrogenase activity of rat liver mitochondria during post-natal development

1. D(-)-beta-hydroxybutyrate dehydrogenase specific activity of rat liver mitochondria changes during ontogenesis: at birth, the activity is low, then increases to a maximum at 12 days, decreases until 50 days to keep constant thereafter. At the same time, mitochondrial protein amount increases regularly while succinatecytochrome c reductase specific activity slightly increases after birth to keep constant afterwards. 2. The observed changes in activity of D(-)-beta-hydroxybutyrate dehydrogenase are not related to possible interactions between the enzyme and phospholids since addition of lecithin to mitochondria does not change the activity. 3. Electrophoresis of mitochondrial proteins isolated from rats at different development stages demonstrates the presence of a protein band characterized by the same electrophoretic mobility as beta-hydroxybutyrate dehydrogenase and by significative changes of its proportion during maturation: the relative amount of this protein increases from the new-born to the 10-12 days old rat, to decrease afterwards. 4. These findings may signify that the increased activity of the enzyme with a maximum at 10-12 days followed by a decrease is related to the rate of the enzymes biosynthesis.     

Ontogenetic changes in protein dephosphorylating activity of the cytosolic compartment of rat erythrocytes

Total casein phosphatase activity of erythrocytes from one-month-old rats was separated by DEAE-cellulose chromatography into three peaks--E1, E2 and E3--and only into two peaks--E1 and E3--when the erythrocyte donors were six- and 12-month-old rats. The activity of E1 (Mr 330 K) decreased continuously in erythrocytes during the first year of postnatal life. E2 (Mr 230 K) also decreased and completely disappeared from the cells of 12-month-old rats. E3 (Mr 180 K) was the dominant molecular form in the cytosol of erythrocytes during the first year of life. It decreased only up to six months of life. In this form E3 seems to be cooperative with respect to the substrate and to inhibitor molecules. The decrease of its kinetic parameters (Vmax and K0.55) was also found during postnatal ontogenesis. E3 isolated from erythrocytes of older rats (6 and 12 months) was more susceptible to inhibitory effect of pyrophosphate and to the change of ionic strength of eluting buffer than the enzyme from one-month-old rats. 0.2 mol.1(-1) NaCl lowered Mr of E3 phosphatase from 180 K to 128 K only in older rats.     

Cyclooxygenase-2 contributes to elevated renin in the early postnatal period in rats

We asked whether cyclooxygenase (COX) activity controls the renin-angiotensin system in the postnatal period. During kidney development, renin peaked at postnatal days 0-1 at the mRNA, tissue protein [renal renin concentration (RRC)], and plasma renin concentration (PRC) levels and was widely expressed along preglomerular vessels. PRC and renin mRNA expression was elevated until weaning in the 4th postnatal week compared with adult rats. Renocortical COX-2 was restricted to Tamm-Horsfall protein-positive cells in the thick ascending limb of Henle's loop, and cortical COX-2 mRNA and protein expression were elevated along with PRC in the 2nd and 3rd postnatal weeks. In contrast, cortical COX-1 expression was constant, but medullary COX-1 expression increased eightfold from the 1st to 4th postnatal week. A COX-2-selective blocker, parecoxib, and a nonselective blocker, indomethacin, given in a period with COX-2 induction from postnatal day 6 to day 12, markedly decreased PRC, but not renin mRNA or RRC. Inhibition of angiotensin AT(1) receptors by candesartan from postnatal day 1 to day 5 increased COX-2 mRNA (2.5-fold), protein, and distribution, renin mRNA (7-fold) and PRC (20- to 70-fold), but had no influence on COX-1 mRNA. Thus, due to very low levels of expression, COX-2 is unlikely to be responsible for the birth peak of renin, but COX-2 activity supports renin secretion later in the suckling period. ANG II negatively feeds back on renocortical COX-2 expression in the 1st postnatal days with high activity of the renin system. We suggest that suckling in the rat is correlated to an enhanced, COX-2-mediated, secretory activity of renin-producing juxtaglomerular cells.     

Development of the hypothalamic-cortical interrelations in the ontogeny of the cat

Under chloralose narcosis, employing the evoked potentials method, studies have been made on the projection of the posterior hypothalamus to the frontal cortex in 1-30 days old kittens. The animals were divided into 3 age groups: 1-9, 10-19 and 20-30 days. Studies of the EPs in different points of pericruciate zone showed that these potentials are observed in all the investigated points from the first days of postnatal life. The latent period of responses in the youngest animals varied from 40 to 80 ms, exhibiting insignificant fluctuations depending on the cortical zone investigated. From the very beginning of postnatal life, in the same cortical zone the EPs may be observed in response to stimulation of the ischiadic nerve as well. In older animals, the latent period of the EPs decreases in all the points, the decrease being most significant near the crucial fissure. To the 30th day of postnatal life, the EPs in this zone with respect to their latency and configuration became quite similar to those in adult animals. In the third age period, the latency varies from 6 to 10 ms in the focus of maximum activity; with the removal of the recording electrode from this zone the latent period of the hypothalamo-cortical responses increases up to 30-40 ms. Overlapping of the EPs in response to central and peripheral stimulation was observed at all age periods.     

Low Glucose but Not Galactose Enhances Oxidative Mitochondrial Metabolism in C2C12 Myoblasts and Myotubes

Background

Substituting galactose for glucose in cell culture media has been suggested to enhance mitochondrial metabolism in a variety of cell lines. We studied the effects of carbohydrate availability on growth, differentiation and metabolism of C2C12 myoblasts and myotubes.

Methodology/Principal Findings

We measured growth rates, ability to differentiate, citrate synthase and respiratory chain activities and several parameters of mitochondrial respiration in C2C12 cells grown in media with varying carbohydrate availability (5 g/l glucose, 1 g/l glucose, 1 g/l galactose, and no added carbohydrates). C2C12 myoblasts grow more slowly without glucose irrespective of the presence of galactose, which is not consumed by the cells, and they fail to differentiate without glucose in the medium. Cells grown in a no-glucose medium (with or without galactose) have lower maximal respiration and spare respiratory capacity than cells grown in the presence of glucose. However, increasing glucose concentration above physiological levels decreases the achievable maximal respiration. C2C12 myotubes differentiated at a high glucose concentration showed higher dependency on oxidative respiration under basal conditions but had lower maximal and spare respiratory capacity when compared to cells differentiated under low glucose condition. Citrate synthase activity or mitochondrial yield were not significantly affected by changes in the available substrate concentration but a trend towards a higher respiratory chain activity was observed at reduced glucose levels.

Conclusions/Significance

Our results show that using galactose to increase oxidative metabolism may not be applicable to every cell line, and the changes in mitochondrial respiratory parameters associated with treating cells with galactose are mainly due to glucose deprivation. Moderate concentrations of glucose (1 g/l) in a growth medium are optimal for mitochondrial respiration in C2C12 cell line while supraphysiological concentrations of glucose cause mitochondrial dysfunction in C2C12 myoblasts and myotubes.     

The kinetics of the cell population of human liver parenchyma at different periods of life]

Processes of polyploidization in the liver parenchyma were investigated in the course of postnatal organism growth, stabilization of growth and ageing, using cytophotometry on the slides of isolated hepatocytes from normal livers of 140 donors aged from 1 day to 92 years. In addition, livers of human embryos (4, 5, 6 and 7 month old) were investigated. It is concluded that polyploid cells in the human liver appear in individuals aged from 1 to 5 years. However, during the postnatal development their relative number increases insignificantly. At the end of the intensive postnatal growth period the share of polyploid human liver cells is less than 3%. Binuclear cells with diploid nuclei are seen as early as in the embryonic liver. After birth their number increases slowly to reach 7.1% in the 16-20 year age group. The postnatal growth of human liver is due mainly to mitotic divisions of mononuclear diploid hepatocytes whose relative number is more than 90% during the postnatal growth. During the period of maturity (from 21 to 50 years), when the liver practically stops to grow, the levels of hepatocyte ploidy are changed insignificantly: part of 2c-hepatocytes decreases slowly (up to 84.8% by the end of period) and (2c x 2)-hepatocyte number increases slowly too. The number of polyploid cells increases by several times, but is equal only to 6.6% of all the hepatocytes counted. Under ageing, on the background of human liver atrophy, acceleration of hepatocyte polyploidization takes place. In the age group of 86-92 years parts of 2c- and (2c x 2)-hepatocytes reach 60.3 and 14.3%, resp., and the total share of polyploid cells is as much as near 25%, calculated from the cell population of liver parenchyma. The maximum ploidy levels in hepatocytes of normal human liver during ageing is becoming 16c and 8c x 2 for mononuclear and binuclear cells, resp. Transition rates among hepatocytes of different ploidy classes (2c--2c, 2c--2c x 2, 2c x 2--4c, 2c--4c) were calculated in addition to the coefficient of changing of the hepatocyte proliferative activity with the increase in its ploidy and cell death rate in different periods of human life. A rather high hepatocyte proliferative activity in the early postnatal period of human life was seen to lower during the following years of life. In maturity it is the lowermost to make less than 5% of that in newborns. During ageing the hepatocyte DNA-synthesizing activity being almost 1.6-1.7 times as much as in maturity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Risk of incarceration of inguinal hernia among infants and young children awaiting elective surgery

Background

We determined the rate of incarceration of inguinal hernia among infants and young children waiting for elective surgery and examined the relation to wait times. We also explored the relation between wait times and the use of emergency department services before surgery.

Methods

We used linked data from administrative databases to identify infants and children less than 2 years of age who underwent surgical repair of an inguinal hernia between Apr. 1, 2002, and Mr. 31, 2004. We determined the rate of hernia incarceration during the wait for surgery and stratified the risk by patient age and sex. We used logistic regression analysis to examine factors associated with hernia incarceration and wait times.

Results

A total of 1065 infants and children less than 2 years old underwent surgical repair of an inguinal hernia during the study period. The median wait time was 35 days (interquartile range 17–77 days). Within 30 days after diagnosis, 126 (11.8%) of the patients had at least 1 emergency department visit; 23.8% of them presented with hernia incarceration. The overall rate of hernia incarceration was 11.9%. The rate was 5.2% with a wait time of up to 14 days (median time from diagnosis to first emergency department visit), as compared with 10.1% with a wait time of up to 35 days (median wait time to surgery) (p < 0.001). Factors associated with an increased risk of incarcerated hernia were age less than 1 year (odds ratio [OR] 2.07, 95% confidence interval [CI] 1.32–3.23), female sex (OR 1.75, 95% CI 1.04–2.93) and emergency department visits (1 visit, OR 2.73, 95% 1.65–4.50; ≥ 2 visits, OR 3.77, 95% CI 1.89–7.43). Children less than 1 year old who waited longer than 14 days had a significant 2-fold risk of incarcerated hernia (OR 1.92, 95% CI 1.11–3.32).

Interpretation

A wait time for surgery of more than 14 days was associated with a doubling of the risk of hernia incarceration among infants and young children with inguinal hernia. Our data support a recommendation that inguinal hernias in this patient population be repaired within 14 days after diagnosis.Inguinal hernias in infants and young children are a result of a failure of the processus vaginalis to close.¹ Once diagnosed, an inguinal hernia should be promptly repaired on an elective basis to prevent the risk of hernia incarceration. Incarceration occurs in about 12% of infants and young children with an inguinal hernia. The incidence is highest (approaching 30%) among infants (< 1 year old).² Boys who experience incarceration of an inguinal hernia have a 30% risk of testicular atrophy that may affect future fertility.³Many countries are struggling with long wait times for elective surgical procedures.^4–6 To date, research has been skewed toward examining wait times for surgery and other medical or diagnostic care in adults.^7–10 Prolonged wait times for surgery to repair hernias have not been associated with adverse outcomes in adults,¹¹ but the effect of prolonged wait times in children has not been well studied.^1,12We conducted this study to examine the relation between wait times for elective surgery and the risk of incarceration of inguinal hernia in infants and young children. We also explored the relation between wait times and the use of emergency department services before surgery.     

Glutathione decreases in dopaminergic PC12 cells interferewith the ubiquitin protein degradation pathway: relevance for Parkinson's disease?

Parkinson's disease (PD) is characterized by the presence of proteinaceous neuronal inclusions called Lewy bodies in susceptible dopaminergic midbrain neurons. Inhibition of the ubiquitin-proteasome protein degradation pathway may contribute to protein build-up and subsequent cell death. Ubiquitin is normally activated for transfer to substrate proteins by interaction with the E1 ubiquitin ligase enzyme via a thiol ester bond. Parkinson's disease is also characterized by decreases in midbrain levels of total glutathione which could impact on E1 enzyme activity via oxidation of the active site sulfhydryl. We have demonstrated that increasing reductions in total glutathione in dopaminergic PC12 cells results in corresponding decreases in ubiquitin-protein conjugate levels suggesting that ubiquitination of proteins is inhibited in a glutathione-dependent fashion. Decreased ubiquitinated protein levels appears to be due to inhibition of E1 activity as demonstrated by reductions in endogenous E1-ubiquitin conjugate levels as well as decreases in the production of de novo E1-ubiquitin conjugates when glutathione is depleted. This is a reversible process as E1 activity increases upon glutathione restoration. Our data suggests that decreases in cellular glutathione in dopaminergic cells results in decreased E1 activity and subsequent disruption of the ubiquitin pathway. This may have implications for neuronal degeneration in PD.     

Chain elongation of fatty acid in brain: a comparison of mitochondrial and microsomal enzyme activities

The activities of mitochondrial and microsomal fatty acid-elongating enzymes have been measured in rat brain during postnatal development and in brains of jimpy, msd, and quaking mice. The microsomal enzyme activity rose from a low in the immature brain to a maximum at 21 days of age and then declined to low levels in the mature brain. The developmental patterns were similar for all acyl-CoAs tested. The maximum activity fell sharply from C₁₆ to C₁₈ and then fell gradually with increase in fatty acid chain length up to C₂₄. The activities for monounsaturated acyl-CoAs were slightly higher than for corresponding saturated esters. The mitochondrial enzyme activity was high in the immature brain and remained virtually unchanged during further brain development. This activity steadily decreased with increasing chain length from C₁₆ to C₂₄. The microsomal enzyme activity was reduced in myelin-deficient mutants compared to their controls. The extent of reduction was most severe for C₂₀- to C₂₄-CoAs followed by C₁₈-CoA and then C₁₆-CoA, for which the activity was reduced only in the jimpy mouse. The activities for C₂₀- to C₂₄-CoAs in jimpy, msd, and quaking mice were 12, 38, and 52% of the control, respectively. The mitochondrial enzyme activity was not affected by these mutations. Fatty acid synthetase activity was similar in the mutant and control mice. These results suggest that the deficiency of long-chain fatty acids in the central nervous system of myelin-deficient mouse mutants is due to reduced synthesis by the microsomal enzyme, which is directly related to myelination. The brain mitochondrial enzyme appears to be unrelated to myelination.     

Developmental pattern of poly (ADP-ribose) synthetase and NAD glycohydrolase in the brain of the fetal and neonatal rat

Poly (ADP-ribose) synthetase and NAD glycohydrolase were examined in nuclear fractions from rat brain at sequential times during late fetal and the first two weeks of neonatal life. In whole brain, both enzymes were demonstrable at all stages of development, but followed separate patterns. Activity of the synthetase which was greatest in fetal life, fell steadily with fetal maturation from 3.90±0.06 nmol/mg DNA at 16 days, to reach a nadir of 1.36±0.09 nmol/mg DNA on the 4th postnatal day. Subsequently it underwent a non sustained neonatal rise reaching a peak of 2.46±0.07 nmol/mg DNA on the 8th day. By contrast, NAD glycohydrolase activity increased steadily throughout late fetal and during the first two weeks of neonatal life, from 12.77±0.40 nmol/mg DNA on day 16 of gestation to 25.80±.95 nmol/mg DNA on neonatal day 12. In neonatal cerebellum the activity of poly (ADP-ribose) synthetase was greater at 8 than at 4 days, could be stimulated with graded concentrations of sonicated DNA up to 100 g, but was inhibited by higher concentrations of DNA and by all concentrations of exogenous histone. In an in vitro culture system of fetal rat brain cells, the activity of poly (ADP-ribose) synthetase increased steadily over six days. Cycloheximide 10^–3 M completely inhibited the activity of this enzyme. NAD glycohydrolase activity increased progressively in vitro, and after 6 days in cycloheximide (10^–3 M), the cultures contained significantly greater levels of enzyme activity. It is suggested that changing activities of poly (ADP-ribose) synthetase and NAD glycohydrolase could both provide potential markers for brain cell differentiation in this system.     

Changes in protein kinase activity in rat testes during development.

Protein kinase activity in rat testes remained fairly constant from day 16 1/2 of embryonic life up to 10 days after birth. At the 21st postnatal day a nadir of activity was observed, and after an increase at 35 days of age a decrease in activity at 60 days was seen. The enzyme reached maximal specific activity in the testes of 90-day-old rats.