Effect of starvation on initiation of protein synthesis in skeletal muscle and heart

Application of a nonradioactive method of measuring protein synthesis in industrially relevant Chinese hamster ovary cells

Due to the high medical and commercial value of recombinant proteins for clinical and diagnostic purposes, the protein synthesis machinery of mammalian host cells is the subject of extensive research by the biopharmaceutical industry. RNA translation and protein synthesis are steps that may determine the extent of growth and productivity of host cells. To address the problems of utilization of current radioisotope methods with proprietary media, we have focused on the application of an alternative method of measuring protein synthesis in recombinant Chinese hamster ovary (CHO) cells. This method employs puromycin as a nonradioactive label which incorporates into nascent polypeptide chains and is detectable by western blotting. This method, which is referred to as SUnSET, successfully demonstrated the expected changes in protein synthesis in conditions that inhibit and restore translation activity and was reproducibly quantifiable. The study of the effects of feed and sodium butyrate addition on protein synthesis by SUnSET revealed an increase following 1 h feed supplementation while a high concentration of sodium butyrate was able to decrease translation during the same treatment period. Finally, SUnSET was used to compare protein synthesis activity during batch culture of the CHO cell line in relation to growth. The results indicate that as the cells approached the end of batch culture, the global rate of protein synthesis declined in parallel with the decreasing growth rate. In conclusion, this method can be used as a "snapshot" to directly monitor the effects of different culture conditions and treatments on translation in recombinant host cells.

Measuring protein synthesis with SUnSET: a valid alternative to traditional techniques?

Protein synthesis rates commonly are measured using isotopic tracers to quantify the incorporation of a labeled amino acid into muscle proteins. Here we provide evidence supporting our hypothesis that the nonisotopic SUnSET technique is a valid and accurate method for the measurement of in vivo changes in protein synthesis at the whole-muscle and single-muscle fiber levels.

Tissue-specific regulation of protein synthesis by insulin and free fatty acids

The purpose of the study described herein was to investigate how the mammalian target of rapamycin (mTOR)-signaling pathway and eukaryotic initiation factor 2B (eIF2B) activity, both having key roles in the translational control of protein synthesis in skeletal muscle, are regulated in cardiac muscle of rats in response to two different models of altered free fatty acid (FFA) and insulin availability. Protein synthetic rates were reduced in both gastrocnemius and heart of 3-day diabetic rats. The reduction was associated with diminished mTOR-mediated signaling and eIF2B activity in the gastrocnemius but only with diminished mTOR signaling in the heart. In response to the combination of acute hypoinsulinemia and hypolipidemia induced by administration of niacin, protein synthetic rates were also diminished in both gastrocnemius and heart. The niacin-induced changes were associated with diminished mTOR signaling and eIF2B activity in the heart but only with decreased mTOR signaling in the gastrocnemius. In the heart, mTOR signaling and eIF2B activity correlated with cellular energy status and/or redox potential. Thus FFAs may contribute to the translational control of protein synthesis in the heart but not in the gastrocnemius. In contrast, insulin, but not FFAs, is required for the maintenance of protein synthesis in the gastrocnemius.

The effect of isolated chloride depletion on growth and protein turnover in young rats

The effects of feeding a chloride-deficient (CD) diet were examined in young, growing rats. All animals were fed the same sodium-replete, CD diet. The experimental group drank distilled water, while the control group (CS) drank distilled water supplemented with 37 mM sodium chloride. By day 15, the CD rats had negligible concentrations of chloride in their urine and had developed hypochloremic metabolic alkalosis. Both groups had comparable urinary sodium concentrations and creatinine clearances. Food intake (256 vs. 226 g), weight (108.8 vs. 47.0 g) and length (9.6 vs. 7.4 cm) gains were greater in the CS animals and the efficiency of weight gain was lower in the CD rats (25.2 vs. 42.6 g gained/g of food intake). After 15-18 days, blood was drawn for testing, body composition measurements were performed and epitrochlearis muscle protein synthesis and net degradation rates determined. When incubated with or without the addition of insulin (I), epitrochlearis muscle protein synthesis, measured as the incorporation of 14C-phenylalanine, was significantly lower in CD rats [(I+ 45.7 vs. 36.76) and (I-34.72 vs. 26.3) nmol phenylalanine/g wet weight per hour (both P < 0.05)]. Net protein degradation rates were not significantly different between the two groups. Estimated nitrogen balance was significantly diminished in CD compared with CS rats. Gastrocnemius muscle RNA concentrations were also lower in CD rats (1.34 vs. 1.60 mg RNA/g wet weight, P < 0.001), but gastrocnemius protein concentrations were equal.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein metabolism in the tumour-bearing mouse. Rates of protein synthesis in host tissues and in an Ehrlich ascites tumour at different stages in tumour growth

We have investigated the time course of the changes in protein metabolism in skeletal muscle and liver in mice during the progression of growth of an Ehrlich ascites tumour. The rate of protein synthesis in muscle begins to fall very rapidly, and the decrease is clearly established by the time the tumour first becomes visible at 4 days after implantation of the cells. Liver protein synthesis increases substantially, and protein breakdown in muscle increases, but the onset of both these changes occurs later than the fall in muscle protein synthesis. A decrease in food intake in these animals occurs very rapidly after introduction of the cells. The fractional rate of protein synthesis in the tumour cells falls from 73%/day at 5 days to 26%/day at 12 days after injection, but on an absolute basis the rate of protein synthesis in the tumour at 5 days of growth is very small compared with that in muscle and liver. These results are consistent with the notion that the initial effects on muscle protein synthesis and food intake are brought about by humoral factors rather than as direct consequences of the metabolic demands of the growing tumour.

Protein synthesis and degradation during starvation-induced cardiac atrophy in rabbits

To determine the relative importance of protein degradation in the development of starvation-induced cardiac atrophy, in vivo fractional synthetic rates of total cardiac protein, myosin heavy chain, actin, light chain 1, and light chain 2 were measured in fed and fasted rabbits by continuous infusion of [3H] leucine. In addition, the rate of left ventricular protein accumulation and loss were assessed in weight-matched control and fasted rabbits. Rates of total cardiac protein degradation were then estimated as the difference between rates of synthesis and growth. Fasting produced left ventricular atrophy by decreasing the rate of left ventricular protein synthesis (34.8 +/- 1.4, 27.3 +/- 3.0, and 19.3 +/- 1.2 mg/day of left ventricular protein synthesized for 0-, 3-, and 7-day fasted rabbits, respectively). Inhibition of contractile protein synthesis was evident by significant reductions in the fractional synthetic rates of all myofibrillar protein subunits. Although fractional rates of protein degradation increased significantly within 7 days of fasting, actual amounts of left ventricular protein degraded per day were unaffected. Thus, prolonged fasting profoundly inhibits the synthesis of new cardiac protein, including the major protein constituents of the myofibril. Both this inhibition in new protein synthesis as well as a smaller but significant reduction in the average half-lives of cardiac proteins are responsible for atrophy of the heart in response to fasting.

Influence of starvation and total protein deprivation on cardiac mRNA levels

The effect of starvation and of protein-deprivation on the extractable amount of cardiac mRNA was investigated in male rats. Cardiac mRNA was determined by either (a) isolation of cardiac mRNA by SDS-Phenol/oligo-dT-cellulose, or by (b) hybridization of cardiac mRNA to 3H-Poly(U). During starvation (1-6 days) the extractable amount of cardiac microsomal RNA decreased from 870 micrograms/g heart (controls) to 606 micrograms/g (3 days) and to 547 micrograms/g (6 days), the extractable amount of mRNA fell from 28.6 micrograms/g heart (controls) to 18.7 micrograms/g (3 days) and to 14.5 micrograms/g (6 days). When a normocaloric but protein-deficient diet was fed, the decreases in cardiac microsomal RNA and mRNA were qualitatively similar, but slightly less severe. An analysis of the intracellular distribution of cardiac microsomal RNA and mRNA in the hearts of normal animals and of animals starved or fed a protein-deficient diet indicates that during starvation cardiac mRNA does not accumulate in the cell sap, but gets rapidly degraded. In the refeeding period, mRNA is transported from the nucleus to the cytoplasm and engages in polyribosome formation. The specific mRNA species coding for the major myofibrillar cardiac proteins are affected to a similar extent by these changes during starvation/protein-deprivation and refeeding.

Effects of starvation, diabetes and acute insulin treatment on the regulation of polypeptide-chain initiation in rat skeletal muscle

The rate of protein synthesis in skeletal muscle is greatly decreased in response to diabetes and starvation. Analysis of polyribosome profiles indicates that polypeptide-chain initiation is impaired under these conditions. To identify the step in initiation that is affected, we assayed the incorporation of [35S]methionyl-tRNAfMet into [35S]methionyl-tRNAfMet . 40S-ribosomal-subunit initiation complexes in cell-free extracts based on postmitochondrial supernatants prepared from gastrocnemius muscle. Extracts from either starved or diabetic rats were 30-40% less active in forming these complexes compared with those derived from fed or insulin-maintained controls respectively. This change could be reversed by treatment of either starved or diabetic rats with insulin in vivo 30 min before death. Formation of 40S initiation complexes by extracts from either fed or starved rats could be stimulated by the addition of exogenous purified initiation factor eIF-2, but extracts from starved or diabetic rats were more sensitive than controls to stimulation by low concentrations of the factor. These results provide evidence for the acute regulation by insulin of protein synthesis in skeletal muscle at the level of polypeptide-chain initiation, and suggest that in this tissue, as in certain other eukaryotic systems, control of initiation appears to be mediated by changes in the activity of initiation factor eIF-2.

Rates of protein turnover in vivo and in vitro in ventricular muscle of hearts from fed and starved rats

Starvation of 300 g rats for 3 days decreased ventricular-muscle total protein content and total RNA content by 15 and 22% respectively. Loss of body weight was about 15%. In glucose-perfused working rat hearts in vitro, 3 days of starvation inhibited rates of protein synthesis in ventricles by about 40-50% compared with fed controls. Although the RNA/protein ratio was decreased by about 10%, the major effect of starvation was to decrease the efficiency of protein synthesis (rate of protein synthesis relative to RNA). Insulin stimulated protein synthesis in ventricles of perfused hearts from fed rats by increasing the efficiency of protein synthesis. In vivo, protein-synthesis rates and efficiencies in ventricles from 3-day-starved rats were decreased by about 40% compared with fed controls. Protein-synthesis rates and efficiencies in ventricles from fed rats in vivo were similar to values in vitro when insulin was present in perfusates. In vivo, starvation increased the rate of protein degradation, but decreased it in the glucose-perfused heart in vitro. This contradiction can be rationalized when the effects of insulin are considered. Rates of protein degradation are similar in hearts of fed animals in vivo and in glucose/insulin-perfused hearts. Degradation rates are similar in hearts of starved animals in vivo and in hearts perfused with glucose alone. We conclude that the rates of protein turnover in the anterogradely perfused rat heart in vitro closely approximate to the rates in vivo in absolute terms, and that the effects of starvation in vivo are mirrored in vitro.

Protein synthesis in skeletal muscle of the perfused rat hemicorpus compared with rates in the intact animal

The rate of protein synthesis was measured in muscles of the perfused rat hemicorpus, and values were compared with rates obtained in whole animals. In gastrocnemius muscle of fed rats the rate of synthesis measured in the hemicorpus was the same as that in the whole animal. However, in plantaris, quadriceps and soleus muscles rates were higher in the hemicorpus than those in vivo. In the hemicorpus, starvation for 1 day decreased the rate of protein synthesis in gastrocnemius and plantaris muscles, in parallel with decreases in the RNA content, but the soleus remained unaffected. Similar effects of starvation were observed in vivo, so that the relationships between rates in vivo and in the hemicorpus were the same as those in fed rats. Proteins of quadriceps and plantaris muscles were separated into sarcoplasmic and myofibrillar fractions. The rate of synthesis in the sarcoplasmic fraction of the hemicorpus from fed rats was similar to that in vivo, but synthesis in the myofibrillar fraction was greater. In the plantaris of starved rats the rates of synthesis in both fractions were lower, but the relationships between rates measured in vivo and in the perfused hemicorpus were similar to those seen in fed rats. The addition of insulin to the perfusate of the hemicorpus prepared from 1-day-starved animals increased the rates of protein synthesis per unit of RNA in gastrocnemius and plantaris muscles to values above those seen in fed animals when measured in vivo or in the hemicorpus. Insulin had no effect on the soleus. Overall, the rates of protein synthesis in the hemicorpus differed from those in vivo. However, the effect of starvation when measured in the whole animal was very similar to that measured in the isolated rat hemicorpus when insulin was omitted from the perfusate.

Regulation of cathepsin D metabolism in rabbit heart: evidence for a role for precursor processing in the control of enzyme activity

Production of active lysosomal enzymes may involve limited proteolysis of inactive high molecular weight precursors. Precursor processing potentially regulates lysosomal enzyme activity. To test whether rabbit cardiac cathepsin D is first synthesized as a precursor and whether prolonged fasting (a condition affecting both cathepsin D and total cardiac protein turnover) influences precursor processing, rates of cathepsin D synthesis and processing were compared in left ventricular slices of control and 3-d-fasted rabbits incubated in vitro with [(35)S]methionine. (35)S-labeled cathepsin D was isolated by butanol-Triton X-100 extraction, immunoprecipitation, and dodecyl sulfate-polyacrylamide gel electrophoresis. Total cardiac protein synthesis was measured by tracer incorporation and normalized for differences in precursor pool size by direct measurement of [(35)S]aminoacyl-tRNA-specific radioactivity. Relative cathepsin D synthetic rates were obtained by comparing (35)S incorporation into cathepsin D with (35)S incorporation into all cardiac proteins. Enzyme processing was assessed in pulse-chase experiments and assayed by autoradiography. The results indicate that (a) rabbit cardiac cathepsin D is synthesized as a precursor (53,000 mol wt) that is processed to a 48,000-mol wt form, (b) rates of both cathepsin D and total cardiac protein synthesis are similar in control and fasted rabbits, suggesting that decreased enzyme degradation rather than increased synthesis is responsible for the elevated levels of cardiac cathepsin D in starvation, and (c) cathepsin D processing in hearts of fasted animals is incomplete, with accumulation of the precursor during pulse-chase experiments of 6 h duration. Based upon these results, a three-stage model for the regulation of cathepsin D activity in rabbit heart is proposed.