Nutrition and fetal brain maturation : II. Impact of maternal starvation on changing levels of acetylcholinesterase and enolase in vitro

The impact of maternal starvation during Days 17-20 of gestation was examined in 20-day fetal rat brain tissue cultured for 6 days in MEM and 10% adult rat serum. Acetylcholinesterase (AChE) activities were consistently greater in fetal brain cell cultures from starved mothers. When fetal tissues from starved mothers were continuously exposed to 72-h fasted serum, AChE activities increased from 1.03 +/- 0.14 to 1.59 +/- 0.21 mumol/h/mg protein (P less than 0.001). In fetal tissues from fed mothers, lower AChE activities were increased from 0.78 +/- 0.09 to 1.04 +/- 0.07 mumol/h/mg protein (P less than 0.05) when 72-h fasted serum was used to replace the fed serum during incubation. When fetal brain cell cultures from fed mothers were exposed for 6 days to graded concentrations of fed serum (2.5-15%), the activities of AChE fell reciprocally from 1.34 +/- 0.10 to 0.82 +/- 0.12 mumol/h/mg protein (P less than 0.05). The levels of AChE activity in tissues exposed to fasted serum were consistently greater, but fell similarly from 1.62 +/- 0.10 to 0.97 +/- 14 mumol/h/mg protein (P less than 0.01), when serum concentrations were increased from 2.5 to 15%. AChE activities were 30% higher in tissues incubated with cycloheximide 10(-3) M (P less than 0.02). Unlike AChE, fetal brain enolase activities were unaffected by maternal starvation. In fetal brain cell cultures from fed mothers, enolase fell from 1.85 +/- 0.10 to 1.37 +/- 0.12 mumol/min/mg protein following exposure to fasted instead of fed serum (P less than 0.02). In fetal cultures from starved mothers, enolase activities were depressed similarly from 1.76 +/- 0.08 to 1.41 +/- 0.09 mumol/min/mg protein when fasted replaced fed serum (P less than 0.02). Thus, the fetal brain cell cultures appear to maintain enzymatic realignments imposed by maternal starvation for at least 6 days. In addition, serum from fasted animals has significant growth inhibiting properties manifested by heightened activities of AChE and lower activities of enolase.     

Insulin-like growth factors and binding proteins in the fetal rat: Alterations during maternal starvation and effects in fetal brain cell culture

Maternal malnutrition adversely affects fetal body and brain growth during late gestation. We utilized a fetal brain cell culture model to examine whether alternations in circulating factors may contribute to reduce brain growth during maternal starvation; we then used specific immunoassay and western blotting techniques, and purified peptides to investigate the potential role that altered levels of insulin-like growth factors (IGFs) and IGF binding proteins (IGFBPs) may play in impaired growth during maternal nutritional restriction.Fetal, body, liver, and brain weight were reduced after 72 hr maternal starvation, and plasma from starved fetuses were less potent than fed fetal plasma in stimulating brain cell growth. Circulating levels of IGF-I were reduced in starved compared to fed fetuses, while levels of IGF-II were similar in both groups. In contrast, [¹²⁵I]-IGF-I binding assay demonstrated an increase in the availability of plasma IGFBPs following starvation. Western ligand blotting and densitometry indicated that levels of 32 Kd IGFBPs were 2-fold higher in starved compared to fed fetal plasma. Immunoblotting and immunoprecipitation with antiserum against rat IGFBP-1 confirmed that heightened levels of immunoreactive IGFBP-1 accounted for the increase in 32 Kd IGFBPs in starved plasma. Levels of 34 Kd BPs, representing IGFBP-2, were unaffected by starvation. Reconstitution experiments in cell culture showed that IGF-I promoted fetal brain cell growth, and that when they were supplemented with IGF-I, the growth promoting activity of starved fetal plasma was restored to fed levels. These changes were measured using MTT to assess mitochondrial reductase activity. Conversely, addition of physiological amounts of rat IGFBP-1 inhibited the effects of fed fetal plasma on brain cell growth, and bioactivity was reduced even further with higher concentrations of IGFBP-1. Based on these results, we conclude that reciprocal changes in circulating levels of IGFBP-1 (increased) and IGF-I (decreased) may combine to reduce the availability of IGF-I to this tissue and limit fetal brain cell growth when maternal nutrition is impaired.     

Proliferative growth of neonatal cerebellar cells in culture: Regulation by male and by maternal serum in late gestation

Neonatal cerebellar cells were utilized as a model system to examine the effect of 20 day pregnant rat serum on proliferative growth in the CNS. Cells were prepared by mechanical dissociation and cultured as mixed cells or populations enriched in astrocytes or oligodendrocytes. Cell proliferation was estimated by measurement of DNA, protein, and/or mitochondrial reductase activity (MTT). When mixed cells were incubated with 10% male rat serum, both total DNA and protein content increased after 6 days of culture. By contrast, neither of these parameters were altered in cultures incubated with 10% pregnant serum. When cells were incubated with either male or pregnant sera, changes in MTT activity paralleled changes in protein content. Graded concentrations of pregnant serum (5–20%) added to mixed cell cultures produced consistently lower MTT values when compared with identical concentrations of male serum. In addition, MTT activity was diminished in both astrocytes and oligodendrocytes incubated with graded concentrations of pregnant sera when compared with similar concentrations of non-pregnant sera. When potential effects of these different sera on the cell cycle were examined, an increase in the number of cells in the S and G2/M phase was similar, and DNA doubling began to increase at 96 hrs in the presence of either male or 20 day pregnant sera. Thus the inhibition of cell growth by pregnant serum was not likely a result of either cytotoxicity or a delay of entry of cells into the cell cycle. To examine whether this inhibition of cell growth may reflect the effect of pregnant serum on endogenous growth factor production, we tested the production of IGF-II by cerebellar cells. Production of an endogenous source of IGF-II was apparent using an RNAse protection assay and was noted using Slot Blot analysis of mRNA extracted at sequential times during cell incubation. Mixed cell cultures also secreted immunologically defined IGF-II. These observations are consistent with the previous demonstration that the fraction of pregnant serum which bound IGF-II also inhibited cell growth. The inhibitory effect of pregnant serum was diminished by preincubating aliquots of sera with graded concentrations of IGF-I prior to adding sera to tissue culture medium. Pregnant serum inhibition was also diminished by prolonging incubation times beyond 6 days. The blunting of pregnant serum inhibition may have been consequent to either a continuing production of endogenous growth factors or to the potential emergence of resistant cells due to prolonged tissue culture incubation. Since cells studied in a primary culture of limited duration may more accurately reflect the physiologic properties of this tissue, the model presented herein could provide a new approach to study brain development.West Side Medical CenterNorthwestern University medical School     

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.     

The impact of maternal serum on development of enolase activity in fetal rat brain cell culture

The effect of gestational age on serum-mediated changes in enolase activity was tested in a fetal rat brain cell culture. After 6 days exposure to graded concentrations (10 and 20%) of nonpregnant female rat sera, enolase activity in brain cell cultures increased from 2.83 +/- 0.03 to 3.74 +/- 0.19 mumol/min/mg protein, P less than 0.01. By contrast, similar concentrations of 20-day maternal serum progressively decreased enzyme activity from 1.52 +/- 0.14 to 1.19 +/- 0.08 mumol/min/mg protein. The inhibitory effect was apparent at 14 days gestation and became progressively greater during late gestation to reach a maximum at 20 days. Combining equal concentrations of 20-day pregnant with either nonpregnant or adult male serum neutralized the inhibitory activity. When serum from 20-day pregnant rats was partitioned by a dialysis membrane with a 50,000 MW pore size, inhibitory activity could be similarly neutralized by male or nonpregnant female serum. When 20-day maternal serum was passed successively through filters with a greater than 300,000, 100,000, and 50,000 MW exclusion, the inhibitory activity was apparent in all fractions excluded by a molecular weight of 50,000. No inhibition was apparent in fractions that were not excluded by 50,000 MW pore size. Inhibition of enolase activity was greatest in the fraction with MW greater than 300,000. Binding of IGF II could also be demonstrated in this fraction. Binding of IGF II was evident in the fraction greater than 100,000 MW but could not be demonstrated in fractions with a lower molecular weight. The presence of mRNA for IGF II in 20-day fetal rat brain cell cultures was evident when total cellular RNA was analyzed by an RNAase protection assay. It is proposed that a high-molecular-weight component of maternal serum in late gestation can bind endogenously generated IGF II. Such binding, by depleting the necessary growth factors, could inhibit in vitro growth and development of enolase activity.     

Brain TRH and Cyclo (His-Pro) and brain protein in the newborn rat are altered by maternal liquid protein feeding

Liquid protein diet (LPD) has been shown previously to produce maternal and fetal weight loss and fetal congenital anomalies, including cataracts and craniofacial malformations. Therefore, to examine the effects of LPD in pregnancy upon the central nervous system of pups, pregnant dams were fed either a 20% casein diet ad libitum, a 20% LPD, or pair-fed with a 20% casein diet. LPD was associated with significant maternal weight loss, and pups had significantly lower birth weights (5.14 +/- 0.64) than pups from the pair-fed controls (5.70 +/- 0.46, p less than 0.05). Total brain protein content was reduced significantly in pups of both sexes from pregnant fed LPD. Moreover, the concentrations of two brain peptides neurotransmitters, thyrotropin-releasing hormone (TRH), and its biologically active metabolite, histidyl-proline diketopiperazine Cyclo (His-Pro), were elevated in the pups from LPD-fed mothers. In contrast, there was no significant difference in brain protein or brain peptides in pups from pair-fed mothers vs. pups from mothers fed ad libitum. These data suggest that qualitative alterations of the protein component in maternal dietary composition have deleterious effects upon the ontogeny of the rat fetal CNS, as reflected by reduced total protein and elevated concentrations of TRH and Cyclo (His-Pro).     

MAO, COMT, and GABA-T Activities in Primary Astroglial Cultures

Cultures from cerebral hemispheres of newborn rats contain the enzymes monoamine oxidase (MAO), catechol-O-methyltransferase (COMT), and gamma-aminobutyric acid alpha-ketoglutarate transaminase (GABA-T). The COMT activity was higher in the cultures than in adult rat cerebral hemispheres. The MAO activity was comparable in the cultures and in the rat cerebral hemispheres. The activities of both these enzymes increased with age in the cultures and in the rat brain hemispheres. In the culture the activities were further potentiated by removal of fetal calf serum and addition of 0.1 mM dibutyryl-cyclic AMP (dB-cAMP). GABA-T activity was, however, lower in the cultures than in the adult rat brain hemispheres. The activity increased in brain during postnatal maturation. No changes in the enzyme activity were observed in the cultures, either during growth or after removal of fetal calf serum and addition of dB-cAMP.     

Effects of fetal versus postnatal sera upon adipose tissue stromal-vascular cells in primary culture

Summary This experiment was conducted to determine if serum factors are responsible for differences in cellularity of prenatal and postnatal pig adipose tissue as determined by in vitro measurement of cellular proliferation and enzyme-histochemical metabolic development. Cellular proliferation of stromal-vascular cells derived from rat inguinal adipose tissue was measured by [³H]-thymidine incorporation. Coverslip cultures were used for analysis of histochemical differentiation. Cells were incubated in media containing 10% fetal bovine, fetal pig, mature pig, or various combinations of these sera. Fetal bovine serum promoted more [³H]-thymidine incorporation than fetal or postnatal pig sera. Fetal pig sera also stimulated more [³H]-thymidine incorporation than mature pig sera. Sera from adult pigs promoted differentiation and lipid filling of adipocytes. Fetal pig sera stimulated histochemical expression of enzymes, but did not induce lipid filling. Fetal bovine serum produced histochemically undifferentiated cells. Addition of fetal bovine serum to media containing mature pig sera reduced lipid accumulation and histochemical reactivity of cells. This effect of fetal serum was thus due to specific inhibition of lipid deposition and not substrate restriction. These experiments demonstrated that serum factors have a major influence on morphological development of fetal and postnatal adipose tissue.     

Survival and Recovery of Methanotrophic Bacteria Starved under Oxic and Anoxic Conditions

The effects of carbon deprivation on survival of methanotrophic bacteria were compared in cultures incubated in the presence and absence of oxygen in the starvation medium. Survival and recovery of the examined methanotrophs were generally highest for cultures starved under anoxic conditions as indicated by poststarvation measurements of methane oxidation, tetrazolium salt reduction, plate counts, and protein synthesis. Methylosinus trichosporium OB3b survived up to 6 weeks of carbon deprivation under anoxic conditions while maintaining a physiological state that allowed relatively rapid (hours) methane oxidation after substrate addition. A small fraction of cells starved under oxic and anoxic conditions (4 and 10%, respectively) survived more than 10 weeks but required several days for recovery on plates and in liquid medium. A non-spore-forming methanotroph, strain WP 12, displayed 36 to 118% of its initial methane oxidation capacity after 5 days of carbon deprivation. Oxidation rates varied with growth history prior to the experiments as well as with starvation conditions. Strain WP 12 starved under anoxic conditions showed up to 90% higher methane oxidation activity and 46% higher protein production after starvation than did cultures starved under oxic conditions. Only minor changes in biomass and morphology were seen for methanotrophic bacteria starved under anoxic conditions. In contrast, starvation under oxic conditions resulted in morphology changes and an initial 28 to 35% loss of cell protein. These data suggest that methanotrophic bacteria can survive carbon deprivation under anoxic conditions by using maintenance energy derived solely from an anaerobic endogenous metabolism. This capability could partly explain a significant potential for methane oxidation in environments not continuously supporting aerobic methanotrophic growth.     

Evidence for neuroendocrine regulation of preadipocyte proliferation and differentiation

Summary Cells in fetal adipose tissue and cells in vitro are characterized by rapid proliferation. Serum factors have been shown to be important for the rapid proliferation of cells in vitro. The present experiment was performed to determine if neuroendocrine regulatory mechanisms of the fetus can influence the actions of serum factors on preadipocyte proliferation and differentiation in vitro.Sera were obtained from decapitated fetal pigs and intact littermates during gestation. Sera were tested for their effects on primary cultures of preadipocytes and stromalvascular cells derived from inguinal adipose tissue of young Sprague-Dawley rats. Coverslip cultures were used for histochemical analysis of enzymes after 12 days of incubation with test media.Analysis of growth curves produced from sequential [³H]-thymidine labeling indicated that fetal age influences rates of proliferation. Sera from decapitated fetal pigs specifically reduced the number of proliferating preadipocytes in culture. Sera from decapitated fetal pigs induced a minimum of 50% less differentiation of sn-glycerol-3-phosphate dehydrogenase activity than sera from intact pigs at all fetal ages. Histochemical staining for enzymes of differentiating preadipocytes was also reduced in cultures incubated with sera from decapitated fetal pigs in comparison to sera from intact pigs. The present study has demonstrated that the in vivo effect of decapitation on fetal adipose tissue development is a consequence of alterations in systemic factors present in serum in response to removal of central regulation by the hypothalamic-pituitary axis.     

Food ingestion by planarian intestinal phagocytic cells — a study by scanning electron microscopy

Tissue-cultured fragments of the intestine of Dugesia japonica were examined by SEM for formation of pseudopodia in the phagocytic cells. For comparison, parallel experiments in vivo were performed using intact animals under starved and fed conditions. When cultures were incubated with fetal calf serum, individual phagocytic cells formed one or two large cup-like pseudopodia. Cultures incubated with latex beads showed pseudopodia that varied in shape according to the size of the beads and that had multiple folds or funnels. Pseudopodia and the modes of their endocytosis in this planarian, however, are morphologically like those of other phagocytes such as digestive cells of Hydra, rat macrophages, and human neutrophils. Culture in vitro of digestive tissue should be an important tool for studying the digestive physiology of planarians at the cellular level.     

Starvation-induced changes in rat brain corticotropin-releasing factor (CRF) and pituitary-adrenocortical response

Starvation-induced changes in CRF concentration in major brain regions and abnormalities in the pituitary-adrenal axis were examined in rats using rat CRF radioimmunoassay. The CRF concentrations in the hypothalamus and cerebellum were significantly reduced in the completely starved rats, while those in the midbrain, thalamus and neurointermediate lobe of the pituitary were significantly increased in the semi-starved or completely starved rats. No significant changes in the CRF concentrations were found in the pons, medulla oblongata and cerebral cortex. In the completely starved rats, the serum ACTH level was significantly reduced, whereas the serum corticosterone level was markedly elevated. These observations suggest that starvation may stimulate the CRF-ACTH-corticosterone system and that not only hypothalamic CRF but also extrahypothalamic CRF may be discretely related to feeding behavior or starvation. The reduced serum ACTH level in starved rats may be ascribed to the negative feedback effect of the elevated serum corticosterone.     

The effect of donor cell serum starvation and oocyte activation compounds on the development of somatic cell cloned embryos

Two experiments, one comparing nuclear transfer (NT) embryo activation compounds, the other donor cell treatments, were conducted with a goal of identifying factors that improve the in vitro development of cloned bovine embryos. In experiment 1, 539 NT embryos were produced by combining serum starved bovine fetal fibroblasts with enucleated in vitro matured oocytes, activated with ionomycin, then randomly allocated to be incubated for 4 hours in either Butyrolactone-I (BL-I) or 6-dimethylaminopurine (DMAP). There was no significant difference in development to blastocyst or compact morula of fused embryos at Day 6.5 between BL-I and DMAP activated embryos (22.4% vs. 20.2%; p = 0.18). Karyotyping of 20 blastocysts and compact morula from each group determined that 65% of BL1 and 63% of DMAP embryos were diploid with the remainder mixoploid (2n + 4n). In Experiment 2, the development of 389 NT embryos reconstructed from either serum starved or serum fed fetal fibroblasts was assessed. More Day 7 blastocysts and compact morula developed in the serum starved group (34.5% vs. 18.8%; p = 0.008). To verify the viability of BL-I activated embryos, 10 blastocytes from experiment 2 were transferred into 4 recipient cows. Two morphologically normal fetuses, genetically identical to the original fetal cell line, were surgically recovered at day 45 of gestation. In summary, serum starvation of bovine fetal fibroblasts prior to NT significantly improved development to blastocyst. Additionally, we have shown that BL-I is a novel alternative compound for use in combination with ionomycin to activate NT embryos.     

Factors regulating the induction of ornithine decarboxylase in fetal rat liver cells in culture.

Various hormonal and non-hormonal agents were tested for their ability to induce ornithine decarboxylase (EC 4.1.1.17) in primary cultures of fetal rat liver cells that retain many of the differentiated functions of hepatocytes. The only agents to induce ornithine decarboxylase in this cell type were fetal calf serum, prostaglandin E1 and cyclic AMP derivatives. Also, the amino acid arginine would induce ornithine decarboxylase in this cell type following arginine starvation for 24 h. These observations are in contrast to the wide range of hormones, e.g. insulin, hydrocortisone, glucagon and growth hormone, than can induce ornithine decarboxylase in vivo in the adult rat liver but which are all without effect on fetal rat liver cells.     

Effects of food deprivation on expression of growth hormone receptor and proximate composition in liver of black seabream Acanthopagrus schlegeli

The effects of food deprivation on the hepatic level growth hormone receptor (GHR) were investigated in black seabream (Acanthopagrus schlegeli) both at the protein level (by radioreceptor assay) and at the mRNA level (by ribonuclease protection assay). Serum levels of growth hormone (GH) and triiodothyronine (T₃) were also measured. Condition factor and hepatic proximate composition of the fish were also assessed. Significant decrease in hepatic GHR binding was recorded as early as on day 2 of starvation. On day 30 this decrease was even more pronounced, with the level in the starved fish reaching less than 20% the fed control level. A concomitant decrease in the hepatic GHR mRNA content was also noted during this period, with a progressive decrease from day 2 to day 30 of starvation. The extent of decrease in the mRNA content was less pronounced than the decrease in receptor binding, with the hepatic GHR mRNA content in the day 30 starved fish representing approximately 30% of the level in the fed control. In large contrast, serum GH level increased progressively during starvation. After 30 days of starvation, serum GH levels in the starved fish were more than three times the concentration found in the fed control. Serum T₃ levels, on the other hand, decreased during starvation, with the difference reaching significance on day 15 and day 30. After 30 days of starvation, serum T₃ levels in the starved fish were only approximately 40% the concentration found in the fed control. The hepatic lipid content exhibited an increasing trend during starvation. On day 30 the hepatic lipid content of the starved fish had doubled the level found in the fed control. However, the hepatic protein content did not exhibit much change during starvation. There was also a minor decrease in the moisture content of the liver during starvation, but the condition factor of the fish as a whole registered a gradual decrease during the course of food deprivation.     

Glucose-dependent regulation of glucose transport activity, protein, and mRNA in primary cultures of rat brain glial cells

D-Glucose deprivation of primary rat brain glial cell cultures, by incubation with 25 mM D-fructose for 24 h, resulted in a 4-5-fold induction of D-glucose transport activity. In contrast, 24-h D-glucose starvation of primary rat brain neuronal cultures had only a marginal effect (1.5-2-fold) on D-glucose transport activity. Northern blot analysis of total cellular RNA demonstrated that under these conditions the rat brain glial cells specifically increased the steady-state level of the D-glucose transporter mRNA 4-6-fold, whereas Northern blot analysis of the neuronal cell cultures revealed no significant alteration in the amount of D-glucose transporter mRNA by D-glucose deprivation. These findings demonstrated that the D-glucose-dependent regulation of the D-glucose transporter system occurred in a brain cell type-specific manner. The ED50 for the D-glucose starvation increase in the D-glucose transporter mRNA, in the glial cell cultures, occurred at approximately 3.5 mM D-glucose with maximal effect at 0.5 mM D-glucose. Readdition of D-glucose to the starved cell cultures reversed the increase in the D-glucose transporter mRNA levels and D-glucose transport activity to control values within 24 h. The increase in the D-glucose transporter mRNA was relatively rapid with half-maximal stimulation at approximately 2 h and maximal induction by 6-12 h of D-glucose deprivation. A similar time course was also observed for the starvation-induced increase in D-glucose transport activity and D-glucose transporter protein, as determined by Western blot analysis. These results document that, in rat brain glial cells, D-glucose transport activity, protein, and mRNA are regulated by the extracellular D-glucose concentration. Further, this suggests a potential role for hyperglycemia in the down-regulation of the D-glucose transport system in vivo.     

Factors regulating the induction of ornithine decarboxylase in fetal rat liver cells in culture

Various hormonal and non-hormonal agents were tested for their ability to induce ornithine decarboxylase (EC 4.1.1.17) in primary cultures of fetal rat liver cells that retain many of the differentiated functions of hepatocytes. The only agents to induce ornithine decarboxylase in this cell type were fetal calf serum, prostaglandin E₁ and cyclic AMP derivatives. Also, the amino acid arginine would induce ornithine decarboxylase in this cell type following arginine starvation for 24 h. These observations are in contrast to the wide range of hormones, e.g. insulin, hydrocotisone, glucagon and growth hormone, that can induce ornithine decarboxylase in vivo in the adult rat liver but which are all without effect on fetal rat liver cells.     

Respiratory metabolism of the soft tick,Ornithodoros turicata (Dugès)

The rate of oxygen consumption was investigated in fed larval, nymphal and adult Ornithodoros turicata ticks and in starved nymphal and adult ticks. Oxygen consumption rate of fed adult ticks increased with increasing temperature. The metabolic rate of adult ticks was affected by starvation whereby starved adult ticks showed a significantly lower oxygen consumption than their fed counterparts. The oxygen consumption rate of fed female ticks was significantly higher than that of fed males but, there was no significant difference between the oxygen consumption rates of starved female versus starved male ticks. Oxygen consumption of fed larvae was significantly greater than those of fed first through third instar nymphs. Fed and starved nymphal ticks as well as fed adult ticks ventilated continuously. In contrast, starved adults ventilated discontinuously. The ability to reduce metabolic rate, plus the capability to ventilate discontinuously allow O. turicata adults to cope with prolonged starvation.     

Effects of cell density and cell growth alterations on cyclic nucleotide levels in cultured human diploid fibroblasts.

cGMP and cAMP concentrations were studied in cultures of two strains of normal human diploid lung fibroblasts, WI38 and KL-2, under various conditions which alter growth rate. Higher levels of cAMP were found in fibroblasts grown in medium with low (0.1 – 1.0%) serum concentration and thus exhibiting a decreased rate of growth. A rise in cAMP also preceded the decreased growth rate when medium was not changed for 4 days or longer (starvation). The reinitiation of cell growth by addition of fresh medium containing the standard 10% serum to either starved or serum-restricted cells was preceded by a rapid drop in cAMP level. Cellular cAMP levels increased to a moderate extent as sparse cultures first increased in density, but did not continue to rise as the culture approached saturation density. cGMP levels were inversely related to cell density: much higher cellular cGMP levels were found at low density than at higher cell density, whether cells were rapidly proliferating under standard growth conditions or had their growth arrested by omission of medium change or restriction of serum. Thus, under these conditions the steady state levels of cGMP appear to be related to cell density rather than rate of cell proliferation. However, a transient but appreciable increase in cGMP did occur upon the addition of fresh medium containing 10% serum to starved or serum-restricted cells, a condition leading to reinitiation of cell proliferation. Smaller but significant increases in cGMP were also evident following routine addition of fresh medium with serum to growing cells fed every other day and following mild EDTA-trypsin treatment of confluent WI38 fibroblasts. Thus, at least dual control mechanisms appear to be involved in the regulation of cGMP levels. Comparison of mid- and late-passage WI38 cells revealed no significant differences either in the levels of cGMP at sparse densities or in the density-dependent change in levels. These results suggest that levels of both cAMP and cGMP are influenced by cell density and also by conditions which alter the rate of cell proliferation.     

Exo-(1----3)-beta-glucanase, autolysin and trehalase activities during yeast growth and germ-tube formation in Candida albicans

Exo-(1----3)-beta-glucanase, beta-glucosidase, autolysin and trehalase were assayed in situ in Candida albicans during yeast growth, starvation and germ-tube formation. Cell viability, germ-tube formation, intracellular glucose-6-phosphate dehydrogenase and beta-glucosidase were unaffected in cells incubated in 0.1 M-HC1 for 15 min at 4 degrees C. However, in situ trehalase, (1----3)-beta-glucanase and autolysin activities in acid-treated cells decreased by 95, 50 and 35% respectively, indicating that these enzymes are, in part, associated with the cell envelope. Trehalase activity increased throughout yeast growth and remained elevated during the first hour of incubation for germ-tube formation. All of the in situ trehalase activity in starved yeast cells could be measured without the permeabilizing treatment. beta-Glucosidase activity declined throughout yeast growth and did not alter during germ-tube formation. Both the (1----3)-beta-glucanase and autolysin activities were optimal at pH 5 X 6, inhibited by gluconolactone and HgCl2, and maximal at 15-16 h during yeast growth. Although autolysin activity increased by 50-100% when starved yeast cells were incubated for germ-tube formation, the in situ (1----3)-beta-glucanase remained constant. When acid-treated starved yeast cells were similarly induced, in situ (1----3)-beta-glucanase increased 100% over 3 h of germ-tube formation. Yeast cells secreted (1----3)-beta-glucanase into the growth medium. This was highest in early exponential phase cultures (34% of the maximum in situ activity) and declined throughout growth. (1----3)-beta-Glucanase was also secreted into the medium during germ-tube formation and this represented 80-100% of the in situ activity in germ-tube forming cells. Both secretion of (1----3)-beta-glucanase and germ-tube formation were inhibited by 2-deoxyglucose, ethidium bromide, trichodermin and azaserine.