Heat shock modulates the ability of A-549 cell line from human lung adenocarcinoma to regulate the intensity of DNA and protein biosynthesis by an autocrine mechanism]

A-549 cells of human lung adenocarcinoma were subjected to heat shock (30 min, 44 degrees C) which caused substantial decreases in the rates of biosynthesis of the great bulk of cellular proteins with simultaneous increases in the synthesis rates of the 70 kDa protein predominantly localized in cell cytosol. By the 6th hour after the heat shock cessation this protein synthesis reached its maximum; by the 18th hour it was no longer detectable, while the protein itself was not denatured. During the recovery after the heat shock the ability of the serum-free culture medium conditioned by A-549 cells in autocrine regulation of [3H]thymidine incorporation into DNA and [3H]leucine incorporation into proteins changed also. The conditioned medium obtained within 1-3 hours after the heat shock did not influence the intensity of DNA synthesis, while the medium obtained 4-48 hours after the heat shock stimulated this process, the maximal effect (3.3-fold stimulation) being observed in the case of the 48-hour conditioned medium. Temporary (1 hour) acidification of the conditioned media down to pH 2.0 resulted in complete inhibition of the stimulating activity. Besides, these media acquired an ability to inhibit [3H]thymidine incorporation into the DNA of tracer cells. Study of effects of conditioned media on the rate of [3H]leucine incorporation into A-549 cell proteins revealed that the media obtained 1-4 hours after the heat shock inhibited this process, while the media obtained 6-18 hours thereafter stimulated it 1.2-2.1-fold. In the test systems under study temporary acidification of the media increased their stimulating influence on [3H]leucine incorporation into cellular proteins.     

Cadmium metabolism by rat liver endothelial and Kupffer cells.

The metabolism of cadmium was investigated in Wistar-rat liver non-parenchymal cells. Kupffer and endothelial cells, the major cell populations lining the sinusoidal tracts, were isolated by collagenase dispersion and purified by centrifugal elutriation. At 20 h after subcutaneous injection of the metal salt (1.5 mg of Cd/kg body weight), endothelial cells accumulated 2-fold higher concentrations of Cd than did Kupffer or parenchymal cells. Most of the Cd in non-parenchymal cells was associated with cytosolic metallothionein (MT), the low-Mr heavy-metal-binding protein(s). When MT was quantified in cytosols from cells isolated from control rats by a 203Hg competitive-binding assay, low levels were found to be present in Kupffer, endothelial and parenchymal cells. Cd injection significantly increased MT levels in all three cell types. The induction of MT synthesis was investigated in vitro by using primary monolayer cultures. The incorporation of [35S]cysteine into MT increased 47% over constitutive levels in endothelial-cell cultures after the addition of 0.8 microM-Cd2+ to the medium for 10 h. MT synthesis in Kupffer cells was not observed. The lack of MT synthesis by monolayer cultures of Kupffer cells in vitro was associated with a decreased capacity of these cells to accumulate heavy metals from the extracellular medium. This apparent decreased ability to transport metals did not reflect a general defect in either cellular function or metabolic activity, since isolated Kupffer cells incorporated [3H]leucine into protein at rates comparable with those shown by liver parenchymal cells and readily phagocytosed particles.     

Incorporation of [h]leucine and [h]valine into protein of freshwater bacteria: uptake kinetics and intracellular isotope dilution

Incorporation of [H]leucine and [H]valine into proteins of freshwater bacteria was studied in two eutrophic lakes. Incorporation of both amino acids had a saturation level of about 50 nM external concentration. Only a fraction of the two amino acids taken up was used in protein synthesis. At 100 nM, the bacteria respired 91 and 78% of leucine and valine taken up, respectively. Respiration of H and C isotopes of leucine gave similar results. Most of the nonrespired leucine was recovered in bacterial proteins, while only up to one-half of the nonrespired valine occurred in proteins. In intracellular pools of the bacteria, [H]leucine reached an isotope saturation of 88 to 100% at concentrations of >40 nM. For [H]valine, an isotope equilibrium of about 90% was obtained at concentrations of >80 nM. Within an incubation period of typically 1 h, tritiated leucine and valine incorporated into proteins of the bacteria reached an isotope saturation of 2 to 6%. In a 99-h batch experiment, bacterial protein synthesis calculated from incorporation of leucine and valine corresponded to 31 and 51% (10 nM) and 89 and 97% (100 nM), respectively, of the chemically determined protein production. Measured conversion factors of 100 nM leucine and valine were 6.4 x 10 and 6.6 x 10 cells per mol, respectively, and fell within the expected theoretical values. The present study demonstrates that incorporation of both valine and leucine produces realistic measurements of protein synthesis in freshwater bacteria and that the incorporation can be used as a measure of bacterial production.     

Divergent Effects of Acute Depolarization on Somatostatin Release and Protein Synthesis in Cultured Fetal and Neonatal Rat Brain Cells

The influence of membrane depolarization on somatostatin secretion and protein synthesis by fetal and neonatal cerebrocortical neurons was studied. Cortical cells obtained by mechanical dispersion were maintained as monolayer cultures for 8 days. The ability of fetal cerebrocortical and hypothalamic cells to release immunoreactive somatostatin (IR-SRIF) was confirmed. Total protein synthesis was determined by the incorporation of [3H]phenylalanine into trichloroacetic acid-precipitable proteins. To study the effect of acute depolarization on protein synthesis, cells were incubated for 30 min with [3H]phenylalanine or [3H]leucine and the depolarizing agent. In fetal cerebrocortical cells, potassium (30 and 56 mM) decreased protein synthesis and RNA levels and increased IR-SRIF release. Depolarization by veratridine, a sodium channel activator, induced a similar effect. The effect of veratridine on IR-SRIF and protein synthesis was reversed by tetrodotoxin, a sodium channel blocker, or verapamil, a calcium channel blocker. These findings suggest that protein synthesis by cerebrocortical cells is decreased in fetal brain cells by membrane depolarization and is dependent on Na+ and Ca2+ entry into cells. In postnatal (day 7) cerebrocortical cells, depolarization induced by high potassium concentrations led to a concomitant increase in protein synthesis, RNA content, and somatostatin release. These findings indicate that depolarization of the cellular membrane is coupled to an increase in protein synthesis in neonatal, but not in fetal, dispersed brain cells.     

Reconstitution of the L-leucine-H+ cotransporter of the plasma membrane from Chang liver cells into proteoliposomes

L-Leucine is cotransported with H+ in the plasma membrane of Chang liver cells (Mitsumoto, Y. et al. (1986) J. Biol. Chem. 261, 4549). The leucine transport system was solubilized from the plasma membrane of the cells with ocytl glucoside and reconstituted in proteoliposomes prepared by a rapid dilution of a mixture of the solubilized proteins, octyl glucoside and liposomes. The proteoliposomes exhibited H(+)-gradient and electrical potential-stimulated leucine uptake. The H(+)-gradient-stimulated leucine uptake could be completely inhibited by carbonyl cyanide p-trifluoro-methoxyphenylhydrazone (FCCP) and 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid (BCH). The stimulatory effect of H+ gradient on leucine uptake was shown to be mainly due to decrease of the Km, but not to change of the Vmax, of the transport kinetics. These results suggest that the leucine-H+ cotransporter is solubilized and reconstituted into proteoliposomes.     

Effect of post-ischaemic recovery on albumin synthesis and relative amount of translatable albumin messenger RNA in rat liver.

In liver cells recovering from reversible ischaemia, total protein synthesis by postmitochondrial supernatant and membrane-bound and free polyribosomes is not different from that in sham-operated controls. However, the relative proportion of specific proteins is changed, since the incorporation of [3H]leucine in vivo into liver albumin, relative to incorporation into total protein, as determined by precipitation of labelled albumin with the specific antibody, decreases by 40-50% in post-ischaemic livers. Cell-free synthesis by membrane-bound polyribosomes and poly(A)-enriched RNA isolated from unfractionated liver homogenate shows that the decrease in albumin synthesis in liver of rats recovering from ischaemia is due to the relative decrease in translatable albumin mRNA.     

The synthesis of oxylate from hydroxypyruvate by isolated perfused rat liver. The mechanism of hyperoxaluria in L-glyceric aciduria

During recovery from silicate-starvation, a period of active DNA synthesis, synchronized cells of Cylindrotheca fusiformis incorporated 3 times more L-[U-14C]aspartate than did starved cells. Of the diatoms's four DNA polymerases, A and D are synthesized during silicate recovery, indicating that they are involved in silicate-dependent DNA replication. Polymerase B, and the chloroplast enzyme, polymerase C, are synthesized during silicate-starvation and their levels are unaffected by the addition of silicate. DEAE-Sephadex analysis of the DNA-binding proteins, labeled with [14C]- and [3H]asparate, shows that only three proteins are synthesized in cells recovering from silicate-starvation. Two of these proteins correspond to polymerases A and D, while the function of the third protein is not known. At least 15 other proteins are present in silicate-starved cells and their synthesis is repressed upon the addition of silicate. Models are proposed which describe the modes by which silicate might regulate DNA synthesis in the diatom.     

Incorporation of fucose and leucine into PNS myelin proteins in nerves undergoing early Wallerian degeneration

The simultaneous incorporation of [³H]fucose and [1-¹⁴C]leucine into normal rat sciatic nerve was examined using an in vitro incubation model. A linear rate of protein precursor uptake was found in purified myelin protein over 1/2–6 hr of incubation utilizing a supplemented medium containing amino acids. This model was then used to examine myelin protein synthesis in nerves undergoing degeneration at 1–4 days following a crush injury. Data showed a statistically significant decrease in the ratio of fucose to leucine at 2, 3, and 4 days of degeneration, which was the consequence of a significant increase in leucine uptake. These results, plus substantial protein recovery in axotomized nerves, are indicative of active synthesis of proteins that purify with myelin during early Wallerian degeneration.     

Incorporation of [3H]Leucine and [3H]Valine into Protein of Freshwater Bacteria: Uptake Kinetics and Intracellular Isotope Dilution

Incorporation of [³H]leucine and [³H]valine into proteins of freshwater bacteria was studied in two eutrophic lakes. Incorporation of both amino acids had a saturation level of about 50 nM external concentration. Only a fraction of the two amino acids taken up was used in protein synthesis. At 100 nM, the bacteria respired 91 and 78% of leucine and valine taken up, respectively. Respiration of ³H and ¹⁴C isotopes of leucine gave similar results. Most of the nonrespired leucine was recovered in bacterial proteins, while only up to one-half of the nonrespired valine occurred in proteins. In intracellular pools of the bacteria, [³H]leucine reached an isotope saturation of 88 to 100% at concentrations of >40 nM. For [³H]valine, an isotope equilibrium of about 90% was obtained at concentrations of >80 nM. Within an incubation period of typically 1 h, tritiated leucine and valine incorporated into proteins of the bacteria reached an isotope saturation of 2 to 6%. In a 99-h batch experiment, bacterial protein synthesis calculated from incorporation of leucine and valine corresponded to 31 and 51% (10 nM) and 89 and 97% (100 nM), respectively, of the chemically determined protein production. Measured conversion factors of 100 nM leucine and valine were 6.4 × 10¹⁶ and 6.6 × 10¹⁶ cells per mol, respectively, and fell within the expected theoretical values. The present study demonstrates that incorporation of both valine and leucine produces realistic measurements of protein synthesis in freshwater bacteria and that the incorporation can be used as a measure of bacterial production.     

Molar proportions and relative rates of synthesis of histones in rat testis

The molar proportions and relative rates of synthesis of histones in normal and hypophysectomized rat testis seminiferous epithelial cells were determined. After hypophysectomy the molar proportions of histones H1, H2B and (H2A + protein A24) in seminiferous epithelial cells of rat testis increased while their corresponding variants TH1-x, TH2B-x and X₂ decreased, but the molar proportions of major-class histones (i.e., sum of subfractions) remained relatively constant and similar to the proportions in somatic cells. The apparent molar proportions of the labeled histones, determined immediately after 2-h periods of [³H]leucine incorporation, were much higher relative to H4 than the proportions of total histones determined by dye binding. The values, however, approached the molar proportions of total histones when rats were killed 11 days after the [³H]leucine injection. Two-dimensional gel electrophoresis confirmed that the high initial molar proportions relative to H4 by [³H]leucine incorporation were not due to the possible contamination by highly-labeled non-histone proteins. The specific activity of histone H4 relative to the specific activity of DNA, determined immediately after 3-h periods of [³H]leucine and [¹⁴C]thymidine incorporations was similar to the value when rats were killed 13 days after the injections. It is proposed that histones of seminiferous epithelial cells are synthesized disproportionally relative to H4 and in excess of the quantities required for polynucleosome assembly. The excess histones are subsequently displaced or degraded slowly.     

Demonstration that some of the nonhistone proteins, inducible to translocate into the nucleus, are glycosylated

Con A, NaF, and eserine (lysosomotropic agents) induced marked translocation of acidic [3H] nonhistone proteins (NHP) from the cytoplasm to the nucleus in lymphocytes prelabeled with [3H]-2-mannose. The nuclear [3H] NHP contents were 38-120% higher in cells treated with these agents than in control cells. Tunicamycin, a strong inhibitor of N-glycosylation via the dolichol pathway, caused a concentration-dependent inhibition of [3H]-2-mannose incorporation into the nuclear [3H] NHP. Considerable amounts of nuclear [3H] NHP from lymphocytes labeled with either [3H]-2-mannose or [3H] leucine, bound specifically to Con A-Sepharose and could be eluted by alpha-methyl mannoside. Con A and NaF caused also nuclear translocation of acidic [3H] NHP in cells labeled with [3H] glucosamine, [3H] galactose, or [3H] fucose. Fractionation of the nuclear proteins by isoelectric focusing in a pH gradient of 2.5-6.5 showed that multiple species of acidic NHP were labeled with each of the four 3H-sugars. These results indicate that a fraction of the acidic nuclear NHP are N-glycosylated proteins and that gene activation and mitogenesis are associated with the translocation of these glycoproteins to the nucleus. Considering the known intracellular traffic of nascent glycoproteins our results suggest that at least some of the acidic NHP are synthesized and glycosylated in the endoplasmic reticulum and the Golgi (secretory pathway). It is likely that these proteins, after completion of synthesis and glycosylation, emerge from the trans-stack of the Golgi packaged in vesicles and accumulate in the cytoplasm. Induction of nuclear translocation of such NHP by various agents may be mediated by a vesicular transport mechanism.     

Cell cycle-specific effects of sodium arsenite and hyperthermic exposure on incorporation of radioactive leucine and phosphate by stress proteins from mouse lymphoma cell nuclei

Cultured mouse lymphoma cells incorporated [3H]leucine and [32P]phosphate into nuclear stress proteins within 3 h after exposure to either elevated temperature (45 degrees C) or sodium arsenite. Radiolabeled proteins were detected by autoradiography after two-dimensional polyacrylamide gel electrophoresis. To determine the cell cycle stage specificity of labeling, nuclei were isolated and sorted into two cell cycle phases using a fluorescent activated cell sorter. After either heat shock or sodium arsenite treatment, the majority of [3H]leucine incorporation into stress proteins occurred during the G0 + G1 phase with minimal labeling in the G2 phase. On the other hand, 32P labeling of stress proteins occurred in both the G0 + G1 and G2 phases after exposure to sodium arsenite, while incorporation of 32P was limited after heat stress. Following sodium arsenite treatment, a distinct set of four stress proteins (80-84 kDa) was detected with [3H]leucine only in G0 + G1 phase, but with [32P]phosphate these stress proteins were labeled in both G0 + G1 and G2. There was differential [32P]phosphate labeling between proteins of the 80-84 kDa set during cell cycling. Individual proteins of this set were isolated from gel plugs after sodium arsenite or heat-shock treatment. Coelectrophoresis of proteins from the two treatment groups showed that they had similar electrophoretic mobilities. All four proteins of the 80-84 kDa set (sodium arsenite induced) possessed similar polypeptide maps after digestion with V8 protease. Cytofluorometric analysis demonstrated a reduction in the number of nuclei in both S and G2 phases of the cell cycle two h after heat shock, but not following sodium arsenite treatment. However, there was a significant depression in the number of nuclei in S and G2 4 h after exposure to sodium arsenite and very modest labeling with 32P of stress proteins was observed at this time.     

Membrane morphogenesis in retinal rod outer segments: inhibition by tunicamycin

Isolated Xenopus laevis retinas were incubated with 3H-labeled mannose or leucine in the presence or absence of tunicamycin (TM), a selective inhibitor of dolichyl phosphate-dependent protein glycosylation. At a TM concentration of 20 micrograms/ml, the incorporation of [3H]mannose and [3H]leucine into retinal macromolecules was inhibited by approximately 66 and 12-16%, respectively, relative to controls. Cellular uptake of the radiolabeled substrates was not inhibited at this TM concentration. Polyacrylamide gel electrophoresis revealed that TM had little effect on the incorporation of [3H]leucine into the proteins of whole retinas and that labeling of proteins (especially opsin) in isolated rod outer segment (ROS) membranes was negligible. The incorporation of [3H]mannose into proteins of whole retinas and ROS membranes was nearly abolished in the presence of TM. Autoradiograms of control retinas incubated with either [3H]mannose or [3H]leucine exhibited a discrete concentration of silver grains over ROS basal disc membranes. In TM-treated retinas, the extracellular space between rod inner and outer segments was dilated and filled with numerous heterogeneously size vesicles, which were labeled with [3H]leucine but not with [3H]mannose. ROS disc membranes per se were not labeled in the TM-treated retinas. Quantitative light microscopic autoradiography of retinas pulse-labeled with [3H]leucine showed no differences in labeling of rod cellular compartments in the presence or absence of TM as a function of increasing chase time. These results demonstrate that TM can block retinal protein glycosylation and normal disc membrane assembly under conditions where synthesis and intracellular transport of rod cell proteins (e.g., opsin) are not inhibited.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

Biosynthesis of mouse erythrocyte membrane proteins by friend erythroleukemia cells

The synthesis of mouse erythrocyte membrane proteins by Friend erythroleukemia cells during dimethyl sulfoxide-induced differentiation was studied. Untreated and dimethyl sulfoxide-treated cells were incubated with l-[³H] leucine and the incorporation of radioactivity into total trichloroacetic acid-insoluble proteins and into proteins immunoprecipitated with a multivalent rabbit antibody to mouse erythrocyte membranes was determined. The immunoprecipitated membrane proteins were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and radioactivity was detected by fluorography. The incorporation of l-[³H]leucine into total cell proteins was linear for 20 min in both untreated and treated cells. Exposure of the cells to dimethyl sulfoxide had an inhibitory effect on protein synthesis, with a significant decrease noted on the fourth day of treatment and a continued decline occurring until the seventh day when protein synthesis was 42% that of untreated cells. The synthesis of erythrocyte membrane proteins was 0.49% that of total cell proteins in untreated cells, was increased to 1.27% by the third day of treatment and remained at about 1% of total protein synthesis from the fourth to the seventh day. Untreated cells synthesized low levels of spectrin, bands 5 and 6 proteins. Treatment with dimethyl sulfoxide caused a staggered increase in synthesis of a number of erythrocyte membrane proteins. Spectrin synthesis increased 4-fold by the third day of treatment and declined thereafter. The synthesis of membrane proteins with electrophoretic mobilities similar to bands 3 and 4 was increased 2–3-fold by the fourth day, while bands 6 and 5 proteins attained maximal synthesis (4-fold) on the fifth and sixth days of treatment.     

Effects of fibroblastic growth factor on protein degradation, the migration of non-histone proteins to the nucleus and DNA synthesis in diploid fibroblasts

Stimulation of resting WI38 cells, prelabeled with [3H]leucine, with fibroblastic growth factor (FGF) or serum, caused increased nuclear translocation of [3H]non-histone proteins [( 3H]NHP) and DNA synthesis, and a parallel decrease of proteolysis. [3H]NHP migration was independent of protein synthesis. Fractionation of the nuclear proteins in a pH gradient of 2.5-6.5 showed that [3H]NHP fractions with high degradation rates in resting cells corresponded to the [3H]NHP fractions with high migration rates in stimulated cells, suggesting that degradation and migration of [3H]NHP are linked. FGF inhibited cellular uptake of [3H]chloroquine, suggesting that FGF inhibits NHP degradation via lysosomes. The lysosomotropic amine eserine had similar effects as FGF. It is proposed that FGF induces NHP migration to the nucleus by inhibiting their lysosomal degradation. FGF also caused migration of [3H]histones, however, the mechanism is not clear.     

Inhibition of protein synthesis also inhibits synthesis of lipid-linked oligosaccharides.

Studies were initiated to determine whether the formation of lipid-linked oligosaccharides was coupled to the synthesis of protein. Canine kidney cells were grown with [2-3H]mannose or [3H]leucine in the presence of cycloheximide or puromycin and the effect of these inhibitors on the synthesis of proteins and lipid-linked oligosaccharides was measured. In all cases, the inhibition of protein synthesis resulted in a substantial inhibition in the incorporation of mannose into the lipid-linked oligosaccharides, although the synthesis of mannosyl-phosphoryl-dolichol was only slightly inhibited. Cycloheximide had no effect on the in vitro incorporation of mannose into lipid-linked oligosaccharides when GDP-[14C]mannose was incubated with aorta microsomal preparations. The inhibition of lipid-linked oligosaccharides was apparently not due to a decrease in the amount of glycosyltransferases as a result of protein degradation in the absence of protein synthesis, nor was it the result of a more rapid degradation of lipid-linked oligosaccharides. The inhibition also did not appear to be due to limitations in the available dolichyl-phosphate. The results suggest that the formation of lipid-linked oligosaccharides may be regulated by end product inhibition.     

Effects of serum and conditioned medium on protein degradation, migration of nonhistone proteins to the nucleus, and DNA synthesis in transformed cells

Stimulation of resting transformed cells (Chang liver cells), prelabeled with [3H] leucine, with fetal calf serum, caused increased nuclear translocation of [3H] nonhistone proteins ([3H] NHP) and DNA synthesis and a parallel inhibition of proteolysis of cellular proteins. [3H] NHP migration was independent of protein synthesis. Fractionation of the nuclear proteins in a pH gradient of 2.5-6.5, showed that [3H] NHP fractions with high degradation rates in resting cells corresponded to the [3H] NHP fractions with high migration rates in stimulated cells, suggesting that degradation and migration of [3H] NHP are linked. Conditioned medium (COM) produced by Chang cells had similar effects as serum, suggesting that factors produced by these transformed cells, control cell growth by a mechanism that is similar to serum. The lysosomotropic amine eserine had similar effects as serum and COM. Based on the similarity of the effects, it would appear that serum and COM inhibit lysosomal proteolysis. It is proposed that serum and COM induce NHP migration to the nucleus by inhibiting lysosomal degradation of these proteins. Serum and COM caused also migration of [3H] histones to the nucleus, however the mechanism is not clear.     

Sublethal heat stress of Vibrio parahaemolyticus.

When Vibrio parahaemolyticsu ATCC 17802 was heated at 41 degrees C for 30 min in 100 mM phosphate-3% NaCl buffer (pH 7.0), the plate counts obtained when using Trypticase soy agar containing 0.25% added NaCl (0.25 TSAS) were nearly 99.9% higher than plate counts using Trypticase soy agar containing 5.5% added NaCl (5.5 TSAS). A similar result was obtained when cells of V. parahaemolyticus were grown in a glucose salts medium (GSM) and heated at 45 degrees C. The injured cells recovered salt tolerance within 3 h when placed in either 2.5 TSBS or GSM at 30 degrees C. The addition of chloramphenicol, actinomycin D, or nalidixic acid to 2.5 TSBS during recovery of cells grown in 2.5 TSBS indicated that recovery was dependent upon protein, ribonucleic acid (RNA, and deoxyribonucleic acid (DNA) synthesis. Penicillin did not inhibit the recovery process. Heat-injured, GSM-grown cells required RNA synthesis but not DNA synthesis during recovery in GSM. Chemical analyses showed that total cellular RNA decreased and total cellular DNA remained constant during heat injury. The addition of [6-3H]uracil, L-[U-14C]leucine, and [methyl-3H]thymidine to the recovery media confirmed the results of the antibiotic experiments.     

Kinetics of insulin action on protein synthesis in isolated adipocytes. Ability of glucose to selectively desensitize the glucose transport system without altering insulin stimulation of protein synthesis

When adipocytes were exposed to [3H]leucine for times ranging from 5 to 180 s, leucine was found to enter cells rapidly and equilibrate with the cell interior within 5 s. After an additional 15-30 s [3H]leucine was incorporated into nascent protein, and the rate of incorporation was linear for up to 6 h in both control and insulin-treated cells. Since treatment of adipocytes with 10 ng/ml insulin enhanced the rate of leucine incorporation 2-3-fold with minimal or no effect on the rate of protein degradation or leucine uptake, we conclude that the predominant effect of insulin is on enhancement of protein synthesis. To assess the time required for insulin to stimulate protein synthesis, we preincubated cells with 10 ng/ml of insulin for various times from 2 to 30 min and then measured [3H]leucine incorporation into protein during a 4-min assay. These results revealed that the insulin stimulation of protein synthesis is rapid (t 1/2 of 4.4 min), but 9-fold slower than insulin activation of glucose transport (t 1/2 less than 0.5 min under identical conditions). In contrast to the rapidity of insulin activation, we found that deactivation proceeded at much slower rates (t 1/2 of 32 and 21 min for protein synthesis and glucose transport, respectively). Desensitization of the glucose transport system has previously been shown to occur after adipocytes are exposed to high glucose and insulin. To examine the specificity of desensitization, we treated cells for 6 h with 20 mM glucose and 25 ng/ml insulin and then examined insulin sensitivity and maximal insulin responsiveness of both the glucose transport and protein synthesis systems. After treatment, the glucose transport was markedly insulin-resistant (60% loss in maximal insulin responsiveness and a marked loss in insulin sensitivity), whereas the protein synthesis system exhibited neither diminished insulin responsiveness nor loss of insulin sensitivity. In fact, insulin sensitivity actually increased, as indicated by the finding that less insulin was required to stimulate protein synthesis (insulin ED50 values of 0.25 and 18 ng/ml at 0 and 6 h of treatment). From these studies we conclude that desensitization of the glucose transport system by glucose and insulin treatment appears to be specific for this particular effector system and does not reflect a state of generalized cellular insulin resistance.