Nutrition and fetal brain maturation : I. Responses in vitro and in vivo

The glycolytic enzyme enolase increases during the perinatal period of brain development and was utilized as a marker for examining the effect of culture environment on differentiation of cells from 20-day fetal rat brain. Enolase activity in cell cultures increased from 0.91 +/- 0.03 (Day 0) to 2.11 +/- 0.10 mumol/min/mg protein (Day 6). Comparable levels were not reached in vivo until neonatal pups were 15 days old. The in vitro increase was inhibited by both cycloheximide and actinomycin D. Enolase activity in the cells responded to alterations in both incubation media and homologous serum. After 6 days in culture, cells incubated in rat serum (10%) added to MEM or RPMI produced twice as much enolase activity as cells incubated similarly in Ham's medium, i.e., 1.96 +/- 0.09 and 1.85 +/- 0.21 vs 1.02 +/- 0.09, P less than 0.001. Results of a comparable magnitude were obtained when fetal calf serum replaced adult rat serum, but enolase production was somewhat lower when newborn calf serum replaced adult rat or fetal calf serum. When cells were incubated for 6 days with graded concentrations of adult rat serum (2.5-15%), enolase activity increased progressively. The pattern of enolase response suggests that the fetal rat brain cell model described herein will provide a sensitive probe with which to gain insight into nutrition and fetal brain development.     

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.     

Intramolecular base pairing between the nematode spliced leader and its 5'' splice site is not essential for trans-splicing in vitro.

The spliced leader RNAs of both trypanosomes and nematodes can form similar secondary structures where the trans-splice donor site is involved in intramolecular base pairing with the spliced leader sequence. It has been proposed that this base pairing could serve to activate autonomously the SL RNA splice donor site. Here, we have examined exon requirements for trans-splicing in a nematode cell free system. Complete disruption of secondary structure interactions at and around the trans-splice donor site did not affect the ability of the SL RNA to function in trans-splicing. In addition, the highly conserved 22 nt sequence could be productively replaced by artificial exons ranging in size from 2 to 246 nucleotides. These results reinforce the view that the 'intron' portion of the SL RNA functions as an independent Sm snRNP whose role is to deliver exon sequences to the trans-spliceosome.     

Ketone body metabolism in the mother and fetus

Pregnancy is characterized by a rapid accumulation of lipid stores during the first half of gestation and a utilization of these stores during the latter half of gestation. Lipogenesis results from dietary intake, an exaggerated insulin response, and an intensified inhibition of glucagon release. Increasing levels of placental lactogen and a heightened response of adipose tissue to additional lipolytic hormones balance lipogenesis in the fed state. Maternal starvation in late gestation lowers insulin, and lipolysis supervenes. The continued glucose drain by the conceptus aids in converting the maternal liver to a ketogenic organ, and ketone bodies produced from incoming fatty acids are not only utilized by the mother but cross the placenta where they are utilized in several ways by the fetus: as a fuel in lieu of glucose; as an inhibitor of glucose and lactate oxidation with sparing of glucose for biosynthetic disposition; and for inhibition of branched-chain ketoacid oxidation, thereby maximizing formation of their parent amino acids. Ketone bodies are widely incorporated into several classes of lipids including structural lipids as well as lipids for energy stores in fetal tissues, and may inhibit protein catabolism. Finally, it has recently been shown that ketone bodies inhibit the de novo biosynthesis of pyrimidines in fetal rat brain slices. Thus during maternal starvation ketone bodies may maximize chances for survival both in utero and during neonatal life by restraining cell replication and sustaining protein and lipid stores in fetal tissues.     

Characterization of biological properties of synthetic and biological leukotriene B3

The effect of micropuncture of the renal papilla through an intact ureter on urinary concetrating ability of rats was examined. Micropuncture of the renal papilla caused a fall in urine osmolality in the punctured kidney from 1718 ± 106 to 1035 ± 79 mosmol/kg·H₂O. In order to investigate the role of renal prostaglandins in this process, PGE₂ excretion was measured and found to increase from 63.4 ± 14.0 to 205.5 ± 57.1 pg/min. Urine osmolality and PGE₂ excretion from the contralateral kidney were not significantly altered. In animals given meclofenamate (2 mg/kg·hr), renal PGE₂ excretion was reduced to 22.3 ± 5.1 pg/min prior to micropuncture and it remained low at 8.9 ± 1.8pg/min after papillary micropuncture. Meclofenamate also blocked the fall in urine osmolality caused by micropuncture of the renal papilla, with urine osmolality averaging 1940 ± 122 before and 1782 ± 96 mosmol/kg·H₂O after the micropuncture. These results indicated that papillary micropuncture through an intact ureter increased renal PGE₂ excretion and that a rise in renal production of PGE₂ or some other prostanoid is associated with a fall in urine concentrating ability.     

Herbivore-induced changes in plant carbon allocation: assessment of below-ground C fluxes using carbon-14

Effects of above-ground herbivory on short-term plant carbon allocation were studied using maize (Zea mays) and a generalist lubber grasshopper (Romalea guttata). We hypothesized that above-ground herbivory stimulates current net carbon assimilate allocation to below-ground components, such as roots, root exudation and root and soil respiration. Maize plants 24 days old were grazed (c. 25–50% leaf area removed) by caging grasshoppers around individual plants and 18 h later pulse-labelled with¹⁴CO₂. During the next 8 h,¹⁴C assimilates were traced to shoots, roots, root plus soil respiration, root exudates, rhizosphere soil, and bulk soil using carbon-14 techniques. Significant positive relationships were observed between herbivory and carbon allocated to roots, root exudates, and root and soil respiration, and a significant negative relationship between herbivory and carbon allocated to shoots. No relationship was observed between herbivory and¹⁴C recovered from soil. While herbivory increased root and soil respiration, the peak time for¹⁴CO₂ evolved as respiration was not altered, thereby suggesting that herbivory only increases the magnitude of respiration, not patterns of translocation through time. Although there was a trend for lower photosynthetic rates of grazed plants than photosynthetic rates of ungrazed plants, no significant differences were observed among grazed and ungrazed plants. We conclude that above-ground herbivory can increase plant carbon fluxes below ground (roots, root exudates, and rhizosphere respiration), thus increasing resources (e.g., root exudates) available to soil organisms, especially microbial populations.     

Homologs of the yeast neck filament associated genes: isolation and sequence analysis of Candida albicans CDC3 and CDC10

Morphogenesis in the yeast Saccharomyes cerevisiae consists primarily of bud formation. Certain cell division cycle (CDC) genes, CDC3, CDC10, CDC11, CDC12, are known to be involved in events critical to the pattern of bud growth and the completion of cytokinesis. Their products are associated with the formation of a ring of neck filaments that forms at the region of the mother cell-bud junction during mitosis. Morphogenesis in Candida albicans, a major fungal pathogen of humans, consists of both budding and the formation of hyphae. The latter is thought to be related to the pathogenesis and invasiveness of C. albicans. We have isolated and characterized C. albicans homologs of the S. cerevisiae CDC3 and CDC10 genes. Both C. albicans genes are capable of complementing defects in the respective S. cerevisiae genes. RNA analysis of one of the genes suggests that it is a regulated gene, with higher overall expression levels during the hyphal phase than in the yeast phase. Not surprisingly, DNA sequence analysis reveals that the proteins share extensive homology at the amino acid level with their respective S. cerevisiae counterparts. Related genes are also found in other species of Candida and, more importantly, in filamentous fungi such as Aspergillus nidulans and Neurospora crassa. A database search revealed significant sequence similarity with two peptides, one from Drosophila and one from mouse, suggesting strong evolutionary conservation of function.     

High-efficiency and multilocus targeted integration in CHO cells using CRISPR-mediated donor nicking and DNA repair inhibitors

Efforts to leverage clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) for targeted genomic modifications in mammalian cells are limited by low efficiencies and heterogeneous outcomes. To aid method optimization, we developed an all-in-one reporter system, including a novel superfolder orange fluorescent protein (sfOrange), to simultaneously quantify gene disruption, site-specific integration (SSI), and random integration (RI). SSI strategies that utilize different donor plasmid formats and Cas9 nuclease variants were evaluated for targeting accuracy and efficiency in Chinese hamster ovary cells. Double-cut and double-nick donor formats significantly improved targeting accuracy by 2.3–8.3-fold and 19–22-fold, respectively, compared to standard circular donors. Notably, Cas9-mediated donor linearization was associated with increased RI events, whereas donor nicking minimized RI without sacrificing SSI efficiency and avoided low-fidelity outcomes. A screen of 10 molecules that modulate the major mammalian DNA repair pathways identified two inhibitors that further enhance targeting accuracy and efficiency to achieve SSI in 25% of transfected cells without selection. The optimized methods integrated transgene expression cassettes with 96% efficiency at a single locus and with 53%–55% efficiency at two loci simultaneously in selected clones. The CRISPR-based tools and methods developed here could inform the use of CRISPR/Cas9 in mammalian cell lines, accelerate mammalian cell line engineering, and support advanced recombinant protein production applications.     

Changes in proteoglycan synthesis of chondrocytes in articular cartilage are associated with the time-dependent changes in their mechanical environment

Explant loading experiments were conducted to investigate the effect of load duration on proteoglycan synthesis. A compressive load of 0.1 MPa applied for 10 min was found to stimulate proteoglycan synthesis, while the same load applied for 20 h suppressed synthesis. This bimodal response suggests that the cells are responding to different mechanical stimuli as time progresses. A theoretical model has therefore been developed to describe the mechanical environment perceived by cells within soft hydrated tissues (e.g. articular cartilage) while the tissue is being loaded. The cells are modeled, using the biphasic theory, as fluid-solid inclusions embedded in and attached to a biphasic extracellular matrix of distinct material properties. A method of solution is developed which is valid for any axisymmetric loading configuration, provided that the cell radius, a, is small relative to the tissue height, h (i.e. h/a 1). A closed-form analytical solution for this inclusion problem is then presented for the confined compression configuration. Results from this model show that the mechanical environment in and around the cells is time dependent and inhomogeneous, and can be significantly influenced by differences in properties between the cell and the extracellular matrix.