Avian fatty acid synthetase: Evidence for short-term regulation of activity

Liver biopsies were performed on starved chicks at 0 and 4 h after refeeding a fat-free diet. Fatty acid synthetase activity increased after refeeding, and administration of cycloheximide did not prevent the rise of enzyme activity. Incorporation of [carboxyl-¹⁴C]leucine into fatty acid synthetase was measured in enzyme purified from the livers of starved chicks, starved-refed (4 h) chicks, and starved-refed chicks injected with cycloheximide. The data suggest that the synthesis of enzyme protein was inhibited in starved and cycloheximide-treated refed chicks in comparison with refed chicks. Liver cytosol from fed or starved chicks was filtered through centrifuge ultrafiltration membranes and the residues were suspended in the same or opposite filtrates. Fatty acid synthetase activity in residues from starved chicks was stimulated when suspended in filtrates from fed chicks. The evidence is consistent with the hypothesis that a portion of the fatty acid synthetase in the liver of starved chicks is present as an inactive form which can be activated upon refeeding.     

A stimulated S6 kinase from rat liver: identity with the mitogen activated S6 kinase of 3T3 cells.

A number of approaches were tested for their ability to induce S6 phosphorylation and S6 kinase activation in rat liver, including i.p. injection of insulin, sodium orthovanadate or cycloheximide, as well as refeeding starved animals. All treatments led to increased S6 phosphorylation and activation of the apparent same enzyme. The most potent activator of the S6 kinase in liver extracts was cycloheximide. Maximum activation was achieved in 20 min at 1 mg cycloheximide/100 g body weight, with half-maximal activation in 10 min. Based on these findings a large-scale kinase purification procedure was established involving seven steps of chromatography. Following the final step a major protein band of Mr 70,000 was revealed. The protein was purified 20,000-fold, had a sp. act. of 640 nmol/min/mg of protein towards S6, autophosphorylated and was inactivated by phosphatase 2A. Peptide maps of autophosphorylated material were identical to those derived from the mitogen-activated kinase of 3T3 cells.     

Cycloheximide Insensitive Amoebo-Flagellate Transformation in Starved Amoebae of Physarum polycephalum

The requirement of protein synthesis for amoebo-flagellate transformation of Physarum polycephalum was re-examined. When amoebae were grown on nutrient agar in association with live food bacteria and harvested in mid-exponential phase of growth, it took ca. 2 hours for half the cells to form flagella after suspension in phosphate buffer. The transformation was completely inhibited by 5 μg/ml cycloheximide. To the contrary, when the amoebae in mid-exponential phase were starved for 3 hr on non-nutrient agar and then suspended in phosphate buffer, the duration required for this process was shortened to ca. 8 min and it was not inhibited by up to 100 μg/ml cycloheximide. A similar result was obtained using bactobolin, another inhibitor of protein synthesis. When amoebae were starved on non-nutrient agar containing 5 μg/ml cycloheximide, however, the starvation effect described above was not observed. The results indicate that protein(s) necessary for the transformation might be synthesized during the starvation period, and that the amoebo-flagellate transformation may or may not require concomitant protein synthesis depending upon preculture conditions.     

Glucose upshift of carbon-starved marine Vibrio sp. strain S14 causes amino acid starvation and induction of the stringent response.

The physiological status of carbon-starved cells of the marine Vibrio sp. strain S14 has been investigated by the analysis of their immediate response to carbon and energy sources. During the first minute after glucose addition to 48-h-starved cells, the pools of ATP and GTP increased rapidly, and the [ATP]/[ADP] ratio reached the level typical for growing cells within 4 min. The total rates of RNA and protein synthesis increased initially but were inhibited 4 to 5 min after glucose addition by the induction of the stringent response. A mutation in the relA gene abolished stringent control during the recovery and significantly prolonged the lag phase, before the starved cells regrew, after the addition of a single source of carbon. However, both the wild-type and the relA cells regrew without a significant lag phase when given glucose supplemented with amino acids. On the basis of these results, it is suggested that carbon-starved cells are deficient in amino acid biosynthesis and that ppGpp and the stringent response are involved in overcoming this deficiency, presumably by depressing the synthesis of amino acid biosynthetic enzymes. Furthermore, the data suggest that the starved cells primarily are starved for energy, and evidence is presented that the step-up in the rate of protein synthesis after refeeding is partially dependent on de novo RNA synthesis.     

The effects of starving and refeeding on the intra-acinar distribution pattern of alcohol-dehydrogenase activity in rat liver

Microquantitative determinations of ADH activity were carried out on the livers of male and female rats. The animals were either starved for 84 h, or starved and then refed with a carbohydrate-rich diet for 6 nights. When the enzyme activity is expressed in mumoles/min/g dry weight, fasting does not appear to alter liver ADH activity, while in starved and subsequently refed rats it is diminished by 20%. Microquantitative measurements of ADH activity in 50-150 ng lyophilized tissue samples, microdissected the whole way along the sinusoidal length, made the computer-aided plotting of intra-acinar distribution patterns possible. The results showed that, under the feeding conditions selected, only minor changes in the ADH activity profiles occur in the liver acinus. These are within the range of the standard deviations of the normal mean values. From these results it can be deduced that fasting and refeeding do not lead to specific inhibition or induction of liver ADH activity. - The decrease of ADH activity of total liver (mumol/min) per total body weight in starved rats is obviously the result of a loss of protein which affects the liver cells of all acinar zones almost equally.     

Ribosome biosynthesis in Tetrahymena thermophila. III. Regulation of ribosomal RNA degradation in growing and growth arrested cells

We have measured the turnover rate of ribosomal RNA in exponentially growing Tetrahymena thermophila cells, cells entering the plateau phase of growth, and nutrient-deprived (starved) cells. Ribosomal RNA is stable in cells in early log phase growth but it begins to turnover as the cells begin a deceleratory growth phase prior to entering a plateau state. Likewise, rRNA in cells transferred from early log phase growth to a starvation medium begins to be degraded immediately upon starvation. In both cases the degradation of rRNA exhibits biphasic kinetics. A rapid initial exponential degradation with a half time of nine and one-half hours lasting for six hours is followed by a slower exponential degradation with a half-life of 35 hours. When starved cells are transferred to fresh growth medium turnover of rRNA ceases. The evidence presented suggests that the alteration in degradation rate is a regulated process which is most likely independent of the cell cycle.     

Effect of Glucose Starvation on Glucose Transport in Neuronal Cells in Primary Culture from Rat Brain

The regulation of glucose transport into cultured brain cells during glucose starvation was studied. On glucose deprivation for 40 h, 2-deoxy-D-glucose (2-DG) uptake was stimulated twofold in neuronal cells but was not changed significantly in astrocytes. On refeeding, the increased activity of neuronal cells rapidly returned to the basal level, an observation indicating that the effect of glucose starvation was reversible. The increase was due solely to change in the Vmax, a finding suggesting that the number of glucose transporters on the plasma membrane is increased in starved cells. Cycloheximide inhibited this increase. In the presence of cycloheximide, the activity of 2-DG uptake of starved cells remained constant for 12 h and then slowly decreased, whereas that of fed cells decreased rapidly. These findings suggest that glucose starvation regulates glucose transport by changing the rate of net synthesis of the transporter in neuronal cells in culture.     

Synchronization of the Cell Cycle of Tetrahymena by Starvation and Refeeding*

SYNOPSIS The present report describes a simple and useful method for synchronizing mass cultures of the ciliate Tetrahymena pyriformis. The method employs a nutritional approach which involves starvation of the cells in a non-nutrient phosphate buffer followed by refeeding with an enriched nutritional growth medium. It takes 240 minutes after refeeding before the first cells start to divide. Radioautographic and DNA determinations taken together show that starved cells are stalled in the GI nuclear DNA condition and that essentially all of the cells replicate their DNA prior to their first cell division.     

Ribosome biosynthesis in Tetrahymena pyriformis. Regulation in response to nutritional changes

Ribosome contents of growing and 12-h-starved Tetrahymena pyriformis (strain B) were compared. These studies indicate that (a) starved cells contain 74% of the ribosomes found in growing cells, (b) growing cells devote 20% of their protein synthetic activity to ribosomal protein production, and (c) less than 3% of the protein synthesized in starved cells is ribosomal protein. Ribosome metabolism was also studied in starved cells which had been refed. For the first 1.5 h after refeeding, there is no change in ribosome number per cell. Between 1.5 and 2 h, there is an abrupt increase in rate of ribosome accumulation but little change in rate of cell division. By 3.5 h, the number of ribosomes per cell has increased to that found in growing cells. At this time, the culture begins to grow exponentially at a normal rate. During the first 2 h after refeeding, cells devote 30-40% of their protein synthetic activity to ribosomal protein production. We estimate that the rate of ribosomal protein synthesis per cell increases at least 80-fold during the first 1-1.5 h after refeeding, reaching the level found in exponentially growing cells. This occurs before any detectable change in ribosome number per cell. The transit time for the incorporation of these newly synthesized proteins into ribosomes is from 1 to 2 h during early refeeding, whereas in exponentially growing cells it is less than 30 min. The relationship between ribosomal protein synthesis and ribosome accumulation is discussed.     

Nuclear DNA in normal and refed Amoeba proteus

Amoeba proteus synthesizes DNA in G2 phase of the cell cycle upon feeding after starvation. The characteristics of the DNA synthesized in G2 have been studied by microscope photometry of individual Feulgen-stained nuclei and by buoyant density centrifugation of nuclear DNA in CsCl. Amoeba nuclei were found to contain 42.8 pg of DNA. This DNA bands in CsCl at a density of 1.693 g/cm³ with a satellite at 1.714 g/cm³ which makes up 24% of nuclear DNA. DNA from whole cells has an additional non-nuclear satellite at 1.726 g/cm³. When cells are starved and re-fed with food labeled with [³H]thymidine, the DNA synthesized is predominantly the 1.714 satellite. The amount of DNA synthesized in G2 is small since there is no measurable difference in Feulgen dye binding to nuclei of starved vs starved and re-fed cells. The data suggest that refeeding induces a resumption of late S phase DNA synthesis, or the preferential synthesis of specific DNA sequences such as rRNA genes.     

Effect of protein synthesis inhibitor cycloheximide on starvation,fasting and feeding oxygen consumption in juvenile spiny lobster Sagmariasus verreauxi

Metabolism in aquatic ectotherms evaluated by oxygen consumption rates reflects energetic costs including those associated with protein synthesis. Metabolism is influenced by nutritional status governed by feeding, nutrient intake and quality, and time without food. However, little is understood about contribution of protein synthesis to crustacean energy metabolism. This study is the first using a protein synthesis inhibitor cycloheximide to research contribution of cycloheximide-sensitive protein synthesis to decapod crustacean metabolism. Juvenile Sagmariasus verreauxi were subject to five treatments: 2-day fasted lobsters sham injected with saline; 2-day fasted lobsters injected with cycloheximide; 10-day starved lobsters injected with cycloheximide; post-prandial lobsters fed with squid Nototodarus sloanii with no further treatment; and post-prandial lobsters injected with cycloheximide. Standard and routine metabolic rates in starved lobsters were reduced by 32% and 41%, respectively, compared to fasted lobsters, demonstrating metabolic downregulation with starvation. Oxygen consumption rates of fasted and starved lobsters following cycloheximide injection were reduced by 29% and 13%, respectively, demonstrating protein synthesis represents only a minor component of energy metabolism in unfed lobsters. Oxygen consumption rate of fed lobsters was reduced by 96% following cycloheximide injection, demonstrating protein synthesis in decapods contributes a major proportion of specific dynamic action (SDA). SDA in decapods is predominantly a post-absorptive process likely related to somatic growth. This work extends previously limited knowledge on contribution of protein synthesis to crustacean metabolism, which is crucial to explore the relationship between nutritional status and diet quality and how this will affect growth potential in aquaculture species.

     

Effect of cell population density on G2 arrest in Tetrahymena

The ciliated protozoan, Tetrahymena pyriformis strain GL-C, has been used to study the effect of cell population density during starvation on the synchrony obtained after refeeding and on the number of cells arrested in G2 phase of the cell cycle. At high cell densities two peaks of division indices were observed after refeeding while only one was observed at low cell densities. Cell division began earlier in cultures starved at high cell densities. Most importantly, the proportion of cells in G2 was considerably higher in populations starved at high cell densities. When tritiated thymidine was present during the refeeding period, radioautographs of cell samples at different times showed that the first cells to exhibit division furrows contained unlabeled nuclei. The first peak in the division index after refeeding was observed only at higher cell densities and is attributed to the cells arrested in G2. These results suggest that Tetrahymena is an excellent organism to study the concept of resting stages in the cell cycle and their control.     

Acute alcohol administration inhibits the refeeding response after starvation in rat skeletal muscle

This study determined whether an acute alcohol dose could inhibit the refeeding response in starved muscle. Rats starved for 24 h were pretreated with alcohol or saline before refeeding by intragastric or intravenous infusion of enteral diet (ENT), total parenteral nutrition (TPN), or saline. Refeeding by TPN or ENT stimulated increases in the fractional rate of protein synthesis (k(s)) in skeletal muscle. Alcohol prevented the increase in k(s) when refeeding occurred intragastrically (TPN or ENT) (P < 0.001) but not intravenously (TPN). Upon intragastric refeeding, alcohol inhibited the increase in both eukaryotic initiation factor 4E-binding protein-1 (4E-BP1) and p70 S6 kinase (p70(S6K)) phosphorylation in plantaris but caused only partial inhibition in soleus muscle (ENT only). When rats were refed intravenously, alcohol had no effect on the increased 4E-BP1 or p70(S6K) phosphorylation in either muscle. Plasma insulin levels were augmented by alcohol. Alcohol-related changes in plasma amino acid concentrations were similar irrespective of the route of feeding, whereas IGF-I levels showed differential changes. This is the first study to demonstrate that acute alcohol ingestion impedes the starved-to-fed response in skeletal muscle.     

The influence of starvation and natural refeeding on the rate of triacylglycerol/fatty acid substrate cycling in brown adipose tissue and different white adipose sites of the ratin vivo. The role of insulin and the sympathetic nervous system

Triacylglycerol/fatty acid substrate cycling was measuredin vivo in brown adipose tissue (BAT) and white adipose tissue (WAT) of fed, starved and refed rats. Starvation (24 h) significantly decreased the rate of cycling in BAT, and refeeding chow diet led to a rapid, 6-fold increase in cycling. Cycling rate in WAT was much lower than in BAT, and was not influenced by fasting or refeeding. Similar rates of cycling were found in epididymal, mesenteric, subcutaneous, and scapular WAT depots. Sympathetic denervation of interscapular BAT abolished the response of the tissue to refeeding, as did acute suppression of insulin secretion. Similarly, rats fasted for 3 days showed no acute increase in the activity of the cycle following refeeding.     

Cytoplasmic membrane changes in conjugating Tetrahymena

Summary The formation of stacks of smooth-surfaced cisternae was studied in samples of Tetrahymena pyriformis that were prepared for electron microscopy after starvation for 2 days in buffer, and in samples of organisms of different mating type that were starved for 2 days and then mixed to induce conjugation. The number of stacks of cisternae was greater in starved ciliates than in those from stock cultures, and the size and number of stacks increased further after mixing animals of different mating type. When cells were either starved or mixed in buffer to which the protein synthesis inhibitor cycloheximide had been added, the formation of the membranous stacks was almost completely abolished. Addition of the RNA synthesis inhibitor actinomycin D, however, did not result in a significant decrease in the size and number of the stacks of saccules. Conjugation did not occur in the presence of either cycloheximide or actinomycin. The results suggest that protein synthesis is required for the formation of the stacks, but RNA synthesis is no longer necessary for their formation at this stage. The previous identification of the stacks as a Golgi apparatus and the possible functions of these membranes are considered.Supported by grants from NSF (GB-32285) and the American Cancer Society (E-500).The authors acknowledge the technical assistance of Mrs. Sue Thompson.     

Developmental regulation of gene expression in Tetrahymena

The onset of gene expression in Tetrahymena thermophila during macronuclear differentiation was investigated by assay of galactokinase in conjugating deoxygalactose-resistant heterokaryons. Our results distinguish three successive states of galactokinase gene expression for cells developing a new macronucleus: stage 0, refractory to induction; stage 1, inducible by refeeding; and stage 2, induced. The refractory period ends at 12 to 13 hr after the onset of conjugation; this corresponds to the time of pair separation, and occurs several hours after the new macronuclei have become morphologically distinguishable. Stage 1 cells behave indistinguishably from mature starved cells. Inhibitor studies suggest that galactokinase synthesis is induced coincidentally with the induction of bulk protein synthesis during conjugation: thus it behaves developmentally like a typical protein; and that galactokinase mRNA is probably transcribed within 1 hr prior to its translation. Thus, when conjugating cells are refed during the refractory period, some developmental condition prevents the swift induction of protein (and galactokinase) synthesis observed upon refeeding starved (nonmating) cells. The possible nature of this developmental phenomenon is discussed.     

Divider size and the cell cycle after prolonged starvation ofTetrahymena corlissi

Cell growth and division of the ciliateTetrahymena corlissi were examined upon refeeding after prolonged starvation of up to 12 days. Division did not automatically occur when a certain critical cell size was reached. Rather, it varied both with the nutritional history of the cell and the nutrient conditions in which the cell was growing. Upon refeeding, cells starved for 12 days divided at a smaller size and later than cells starved for 6 days. Cells refed at high density took longer to begin division than cells refed at low density. The results are discussed with respect to the relative starvation and critical constituent models of the cell cycle and in terms of the polymorphic life cycle ofTetrahymena species.     

Gastrin and ACTH-like immunoreactivity occurs in two ultrastructurally distinct cell types of rat antropyloric mucosa

Summary The properties of endocrine cells of rat antropyloric mucosa, which simultaneously store both gastrin and ACTH-like immunoreactivity have been examined. In freely fed animals all or nearly all antral gastrin cells contain also large quantities of ACTH-like immunoreactivity. Following three days of fasting the gastrin cell content of ACTH-like peptides is drastically reduced, but increases rapidly upon refeeding of the starved animals for 30 min. At the electron microscopical level, the vast majority of cells storing both gastrin and ACTH-like peptides are identified as G cells but, in addition, a few, previously unrecognized, endocrine cells have also been found to store both types of peptides. The latter new cell type has tentatively been labelled the G_a cell. In normal freely fed animals the G cell is characterized by the occurrence of both electron-dense and electron-lucent granules. Correlative immunocytochemical and ultrastructural studies indicate that gastrin and the ACTH-like peptides are both stored in the cytoplasmic granules. Our results indicate that the gastrin cells release their content of ACTH-like peptides in response to fasting and that this release is blocked by refeeding. The differential release of two hormone-like substances from the same endocrine cell type is of great interest for analysis of mechanisms of peptide hormone release.     

An analysis of the recovery of tetrahymena from effects of cycloheximide

When cycloheximide (0.2 μg per ml) was added to synchronized cultures of Tetrahymena pyriformis GL-C, the initial rate of incorporation of ¹⁴C-leucine was reduced to about 20% of the rate observed in control cells. After one hour, the rate increased fairly abruptly to about 60% of the control rate. The cells in cycloheximide underwent synchronous division about three hours after addition of cycloheximide. A second addition of cycloheximide had little effect on either the rate of incorporation or on the time of cell division in the drug. The medium in which cells had recovered brought about full inhibition of ¹⁴C-leucine incorporation in fresh cells, indicating that recovery was not accompanied by appreciable degradation of the cycloheximide. It was therefore concluded that during recovery the cells were either adapting to the cycloheximide or excluding it. The recovery process shows some specificity, since cells which had recovered from cycloheximide, and had become insensitive to a second dose of this drug, still retained full sensitivity to another drug, colchicine. Conversely, cells recovering in colchicine became insensitive to fresh colchicine but remained sensitive to cycloheximide.     

Autogamy in Paramecium cell cycle stage-specific commitment to meiosis

Autogamy is a process of meiosis and fertilization which takes place in unpaired Paramecium cells, and which is triggered by starvation. This study examines the consequences of nutritional down-shift at various points within the cell cycle on the occurrence of autogamy. It shows that cells become committed to autogamy in a two-step process. An initial point of commitment to autogamy occurs about 100 min prior to the median time of cell division (cell cycle duration, 330 min). Cells which have become committed to autogamy initiate meiosis following the next fission, others complete another vegetative cell cycle before undergoing meiosis. Treatments that perturb the cell cycle and displace the point of commitment to division also displace the point of initial commitment to autogamy to the same extent.The initial commitment to autogamy can be reversed by refeeding. The second, final, point of commitment to autogamy occurs about 30 min after the fission, immediately prior to initiation of meiosis, and coincides with the beginning of meiosis. If cells are refed at this point, or at later stages, autogamy continues.Autogamy is not well synchronized either in naturally starved cultures or in those subjected to abrupt nutritional down-shift. This is a consequence of the cell cycle stage dependence of entry into autogamy. Autogamy occurs synchronously in samples of dividers selected from asynchronous cultures 2 or more hours after nutritional down-shift. The timing of the events of conjugation and autogamy coincide when the pre-autogamous fission is aligned temporally with the initial contact of mating cells.