DNA repeat size in chick embryonic lens epithelium, lens fiber, brain and liver cell nuclei

The DNA repeat size is determined by micrococcal nuclease digestion kinetics and subsequent electrophoresis of the products among various chick embryonic tissues. The repeat size is found to be not significantly different from 193 to 197 bp, for brain and liver at 11 days and for lens epithelium and fiber at different embryonic stages. However, the pattern of micrococcal digestion seems to reveal an overall chromatin modification as a function of development in the lens fibers.     

Ophthalmic acid is a marker of oxidative stress in plants as in animals

Background

Ophthalmic acid (OPH), γ-glutamyl-L-2-aminobutyryl-glycine, a tripeptide analogue of glutathione (GSH), has recently captured considerable attention as a biomarker of oxidative stress in animals. The OPH and GSH biosynthesis, as well as some biochemical behaviors, are very similar. Here, we sought to investigate the presence of OPH in plants and its possible relationship with GSH, known to possess multiple functions in the plant development, growth and response to environmental changes.

Gel electrophoretic analysis of histones in lens epithelium, lens fiber, liver, brain, and erythrocytes of late chick embryos.

Histones from 19-day-old chick embryo lens epithelium, lens fibers, liver, brain, and erythrocytes were electrophoresed in polyacrylamide gels using buffers containing sodium dodecylsulfate, acetic acid urea, or mixtures of Triton X-100 acetic acid urea. In the last two buffer systems, histone bands were characterized by their apparent molecular weights determined by electrophoresis in the second dimension in sodium dodecylsulfate containing polyacrylamide gels. From the densitograms of the stained gels, the relative proportion of protein in different histone bands was estimated. With the exception of the erythrocyte-specific histone H5, all histones from different tissues examined at any of the gel systems migrated with the same mobilities. In lens epithelium and lens fibers, all histones were present in identical proportions. As compared to liver and brain, the total amount of histone Hl was significantly lower in lens cells and erythrocytes, possibly reflecting differences between the differentiated states. However, no tissue-specific differences were found in the relative distribution of histone Hl I and Hl II among lens epithelium, lens fiber, liver and, brain, but a threefold higher Hl I : Hl II ratio (0.5--0.7) was found in erythrocytes.     

Comparative analysis of the mechanisms of attack and defense among higher brain animals

Many studies have investigated different mechanisms of attack and defense in different species of higher brain animals including cats, rats, rodents, mice, and even in some bird species. However, detailed comparative analysis has not been carried out to understand the major similarities in the mechanisms of attack and defense across the different species of vertebrates. Although there are differences, there are also significant similarities as well, which warrant comparative assessment. By considering ethological ideas associated with the motivational defense system, we investigated the motor patterns of attack and defense in cats and rats, using the “resident-intruder” experimental paradigm. Our results reveal specific similarities and differences in the motor patterns of attack and defense in rats and cats. We discuss comparatively the mechanisms of attack and defense across different species of vertebrates, focusing on motor patterns, neuromodulating factors, brains neural substrates, and circuitry.     

Reversal of docosahexaenoic acid deficiency in the rat brain, retina, liver, and serum

The loss of docosahexaenoic acid (DHA) from the retina or brain has been associated with a loss in nervous-system function in experimental animals, as well as in human infants fed vegetable oil-based formulas. The reversibility of the loss of DHA and the compensation by an increase in the n-6 docosapentaenoic acid (DPAn-6) was studied in young adult rats. Long-Evans rats were subjected to a very low level of n-3 fatty acids through two generations. The F2 generation, n-3-deficient animals at 7 weeks of age were provided a repletion diet containing both alpha-linolenate and DHA. A separate group of F2 generation rats had been maintained on an n-3-adequate diet of the same composition. Tissues from the brain, retina, liver, and serum were collected on weeks 0, 1, 2, 4, and 8 from both groups of animals. The concentrations of DHA, DPAn-6, and other fatty acids were determined and the rate of recovery and length of time needed to complete DHA recovery were determined for each tissue. The DHA level in the brain at 1 and 2 weeks after diet reversal was only partially recovered, rising to approximately 20% and 35%, respectively, of the n-3-adequate group level. Full recovery was not obtained until 8 weeks after initiation of the repletion diet. Although the initial rate of retinal DHA accretion was greater than that of brain DHA, the half-time for DHA recovery was only marginally greater. On the other hand, the levels of DHA in the serum and liver were approximately 90% and 100% replaced, respectively, within 2 weeks of diet reversal. A consideration of the total amounts and time courses of DHA repleted in the nervous system compared with the liver and circulation suggests that transport-related processes may limit the rate of DHA repletion in the retina and brain.-- Moriguchi, T., J. Loewke, M. Garrison, J. N. Catalan, N. Salem, Jr. Reversal of docosahexaenoic acid deficiency in the rat brain, retina, liver, and serum. J. Lipid Res. 2001. 42: 419--427.     

L-Ascorbic acid and lysosomal acid hydrolase activities of guinea pig liver and brain

The effects of L-ascorbic acid deficiency on guinea pig hepatic and brain lysosomal hydrolases were examined. In general, hepatic beta-N-acetylhexosaminidase, beta-D-glucoronidase, alpha-D-galactosidase, alpha-D-mannosidase, and acid phosphatase were elevated in scorbutic animals. This appears to be independent of the starved state. Brain beta-D-glucoronidase and acid phosphatase followed a similar pattern to that observed with the liver enzymes, but brain beta-N-acetylhexosaminidase was not affected by L-ascorbic acid decreased the activity of hepatic beta-N-acetylhexosaminiadase was unaffected by dietary treatments although the activity of beta-N-acetylhexosaminidase A tended to increase in the scorbutic animals. Subcellular fractions were obtained from the three groups of animals and the recoveries of protein, beta-N-acetylhexosaminidase, and glucose-6-phosphatase estimated.     

A comparison by species, age and sex of cysteinesulfinate decarboxylase activity and taurine concentration in liver and brain of animals

Cysteinesulfinate decarboxylase activity and taurine concentration were determined in liver and brain of rats, mice, cats, guinea-pigs and sheep. Values were compared for male and female animals and in some cases measurements were also made in animals of different ages. Cysteinesulfinate decarboxylase activity and taurine concentration were also measured in liver and brain of male and female rat pups during the postnatal period. Hepatic cysteinesulfinate decarboxylase activity increased in both male and female rat pups during the postnatal period and then declined markedly in female rats so that activity in adult males was 16-fold that in adult females. Cysteinesulfinate decarboxylase activity in liver of 5- to 6-week old kittens was 73 times that observed in liver of 15-month old cats. Taurine level in liver of guinea-pigs was much lower than that in liver of any other species studied.     

Nucleic acid content and growth of fetal brain, liver and heart during inanition in pigs

Previous investigations have indicated that gilts deprived of dietary intake for periods up to 40 days are capable of maintaining pregnancy and producing offspring of normal body weight. The present experiment was designed to study the effects of inanition during middle or late pregnancy on growth and on protein and nucleic acid content of porcine fetal brain, liver and heart. Gilts were subjected to prolonged inanition (40 days; 0 kcal/day; water only) during either the middle third (Days 30-70, n = 3) or last third (Days 70-110, n = 3) of pregnancy; controls received a full diet (7028 kcal/day) until Day 70 (n = 3) or 110 (n = 3) when all dams were hysterectomized. Inanition during middle or late pregnancy had no detrimental effect on fetal brain development. Brain weight, cell size (protein/DNA ratio) and cell number (total DNA) were similar in all fetuses at Day 70 or 110. RNA concentrations at Days 70 and 110, protein concentration at Day 70 and total protein at Day 110 were higher in fetuses from starved dams than in those from controls, indicating greater protein synthetic activity in fetal brains from nutrient-deprived dams. Prolonged inanition during midpregnancy had only a limited effect on fetal liver and heart. Only liver RNA concentration and content at Day 70 differed in fetuses from starved dams; however, 40 days inanition during late gestation had marked detrimental effects. Liver weight, cell size and cell number were reduced in inanition as compared with controls by Day 110.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dietary lipid effects on microsome fatty acid composition of liver and brain, on liver glucose-6-phosphatase, and on brain 5'-nucleotidase activity in the rat

The effects of incorporation of dietary oils with different n6/n3 ratio and polyunsaturated fatty acids content into rat liver and brain microsomes has been studied. The investigation of membrane fatty acid composition of liver microsomes and that of brain microsomes gave different results. In particular, liver microsomes of rats fed fish oil showed a relatively higher content of 20:5n3 and 22:6n3, and a lower content of 20:4n6. Under these conditions, a reduced glucose-6-phosphatase activity was measured. Brain microsomal fatty acid composition was only slightly affected by dietary lipid intake. The 5'-nucleotidase activity of those particles was similar, although statistically different values were found in fish-oil-fed rats and in olive-oil-fed rats. The effects of membrane fatty acid composition on membrane-bound enzyme activity are discussed.     

Purification of quinolinic acid phosphoribosyltransferase from rat liver and brain

Quinolinic acid phosphoribosyltransferase (EC 2.4.2.19) was purified 3600-fold from rat liver and 280-fold from rat brain. Kinetic analyses (K_m = 12 μM for the substrate quinolinic acid and K_m 23 μM for the cosubstrate phosphoribosylpyrophosphate), physicochemical properties of the purified enzymes, inhibition by phthalic acid (K_i = 1.4 μM) and molecular weight determination (M_r 160 000 for the holoenzyme, consisting of five identical 32 kDa subunits) indicated the structural identity of quinolinic acid phosphoribosyltransferase from the two rat tissues. This was further confirmed immunologically, using antibodies raised against purified rat liver quinolinic acid phosphoribosyltransferase. Rat quinolinic acid phosphoribosyltransferase differs in several aspects from quinolinic acid phosphoribosyltransferase isolated from other organisms. The purified enzyme will prove a useful tool in the examination of a possible role of quinolinic acid in cellular function and/or dysfunction.