Measurement of protein synthesis in rat lungs perfused in situ

Source of amino acids for tRNA acylation. Implications for measurement of protein synthesis

Estimates of protein-synthesis rates using radioisotopes require accurate measurement of the specific radioactivity of the label in protein and in the precursor pool over time. Although the extracellular and intracellular pools of amino acids are easiest to sample, the tRNA pool is the direct precursor and is the appropriate pool for sampling. To test if the intracellular or extracellular pools reflect the tRNA specific radioactivity, a chicken macrophage cell line was incubated in medium containing either 0.23 mM-leucine and 14.5 microCi of [3H]leucine (tracer dose) or 2.3 microM-leucine plus 145.0 microCi of [3H]leucine (flooding dose). At both leucine levels, the tRNA specific radioactivity reached a plateau quickly, but did not equilibrate with either the extracellular or intracellular specific radioactivity within 30 min, and remained closer to that of protein. In a second experiment, proteins in chicken macrophages were labelled with [3H]leucine for 2 days. Labelling medium was removed, and the cells were washed free of residual free [3H]leucine and incubated with medium containing either 0.23 mM- or 2.3 mM-leucine (unlabelled). The specific radioactivity of leucyl-tRNA leucine reached a plateau within 2 min and remained considerably closer to that in the protein than that in intracellular or extracellular pools for at least 60 min. These results suggest that amino acids from protein degradation are a primary source for charging tRNA. When protein-synthesis rates are estimated by label incorporation, use of extracellular or intracellular specific-radioactivity values result in a marked underestimation.

The acute and chronic effects of ethanol on cardiac muscle protein synthesis in the rat in vivo

An investigation was made into the acute and chronic effects of ethanol on rates of protein synthesis in the hearts of young rats (80-100 g body weight). Acute ethanol administration (75 mmol/kg body weight, IP) significantly reduced the fractional rate of protein synthesis by 20% after 2.5 hr, compared with saline-treated controls. Chronic ethanol feeding (36% of total calories) for 6 weeks significantly reduced cardiac wet weight by 11%, when compared to rats fed isovolumetric amounts of the same diet in which ethanol was substituted by isocaloric glucose. Neither the concentration nor the content of mixed cardiac proteins relative to body weight were overtly altered by chronic ethanol feeding, although, the total content of mixed cardiac proteins were significantly decreased. RNA concentrations and RNA relative to body weight increased slightly, but total cardiac DNA decreased. Indices for the capacity or potential of the heart to synthesis protein (indicated by the RNA/protein and RNA/DNA ratios) and the "DNA-unit" (protein/DNA ratio) were increased in response to chronic ethanol treatment. The fractional and absolute rates of mixed protein synthesis in the heart were (relatively) unaltered by chronic ethanol treatment, as was RNA efficiency and synthesis relative to DNA. It was concluded that the heart displays contrasting responses to acute and chronic ethanol exposure.

Metabolic effects of isoflurane on rat lungs perfused in situ

1. The current experiments studied the effects of the inhalation anesthetic, isoflurane, on 5-hydroxytryptamine (5-HT) metabolism, protein synthesis, and angiotensin-converting enzyme activity in perfused rat lungs. 2. Under first order reaction conditions, isoflurane decreased the accumulation of tissue 5-hydroxyindoleacetic acid, the principle metabolite of 5-HT in a concentration-related, competitive, and reversible manner, indicating inhibition of endothelial 5-HT uptake. 3. In apparent contrast, isoflurane appeared to stimulate uptake of 5-HT by an imipramine-sensitive process, into a cell type unable to metabolize the parent amine. 4. Isoflurane increased absolute angiotensin-converting enzyme activity only at an inspired concentration of 5%. The anesthetic did not affect lung protein synthesis.

Inflation-associated increases in lung polyamine uptake: role of altered pulmonary vascular flow

Unilateral pneumonectomy in rats leads to rapid compensatory growth of the remaining lung. Previous studies showed that postoperative increases in lung mass are preceded by enhanced uptake of exogenous polyamines and by alterations in adenosine 3',5'-cyclic monophosphate (cAMP) metabolism. These effects are both mimicked in lungs of intact animals subjected to increased inflation in vitro. Partial pneumonectomy also leads to increased flow to the contralateral lung associated with reduced pulmonary vascular resistance. This raises the possibility that the postoperative metabolic response is initiated by changes in pulmonary artery pressure (Pa) or flow, rather than altered inflation. The present studies were designed to investigate this issue. Uptake of exogenous [14C]spermidine by isolated perfused rat lungs was examined over a wide range (greater than 4-fold) of pulmonary flow and ventilation at fixed PaS. Assessment of tissue metabolism from rates of protein synthesis suggested stability of the isolated lung preparations. Apnea (0 ventilation) had no effect on spermidine uptake or flow rate, compared with lungs evaluated under normal conditions of ventilation (inspiratory pressure, 15 cmH2O; positive end expiratory pressure, 2 cmH2O; rate, 70 breaths/min). At both high and low Pa (at a flow rate of 37 +/- 1 and 11 +/- 2 ml/min, respectively, with 0 ventilation), removal of the left lung from the perfusion circuit increased specific right lung flow rate greater than 30% but had no effect on spermidine uptake. Similar alterations in flow rate to the right or both apneic lungs had no effect on the tissue content of cAMP.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of ketamine and fentanyl on lung metabolism in perfused rat lungs

The effects of ketamine and fentanyl on serotonin (5-hydroxytryptamine; 5-HT) metabolism, angiotensin-converting enzyme (ACE), and protein synthesis (PS) were investigated in an isolated lung model. Rat lungs were perfused in situ with a blood-free physiological salt solution. The pulmonary vasculature was exposed to ketamine (0.005-2.1 mM) or fentanyl (1.8-4.5 microM) for up to 2 h. After 1 h, accumulation of 5-[14C]hydroxyindoleacetic acid (5-HIAA) by the lung was monitored as an index of 5-HT metabolism. ACE activity was estimated from hydrolysis of [3H]benzoylphenylalanyl-alanyl-proline, a synthetic substrate for the enzyme. [3H]phenylalanine was added to the perfusate after 1 h, and its incorporation into acid-precipitable lung protein was measured over the subsequent hour. Ketamine inhibited 5-HT uptake in a concentration-related manner. The inhibition was characterized as competitive and reversible. Fentanyl had no effect on lung 5-HIAA accumulation. Neither drug altered ACE activity or protein synthesis over the concentration ranges tested. The results indicate an action by ketamine that inhibits the 5-HT membrane-transport process. The different effects observed by ketamine and fentanyl on this process could contribute to the diverse pharmacological properties of these two drugs.

Rapid measurement of whole body and forearm protein turnover using a [2H5]phenylalanine model

Whole body protein turnover was measured in six normal adults using a model based on a primed constant infusion of [2H5]phenylalanine and, independently, by an established method of a primed constant infusion of [1-13C]leucine. Isotopic plateau in plasma was achieved within 2 h for [2H5]phenylalanine and, in four of the subjects who received a priming dose of [2H4]tyrosine, for [2H4]tyrosine. In all subjects whole body protein turnover measured with the phenylalanine model (mean protein synthesis, 2.65 +/- (SD) 0.16 g.kg-1.24 h-1; catabolism, 3.58 +/- 0.26 g.kg-1.24 h-1) was similar to that measured using the leucine model (synthesis, 3.09 +/- 0.27 g.kg-1.24 h-1; catabolism, 3.70 +/- 0.35 g.kg-1.24 h-1). Mean forearm fractional muscle protein synthesis calculated by the phenylalanine model was 0.06 +/- 0.03%/h, which compares closely with literature values derived by other methods. The phenylalanine model allows the rapid assessment of whole body and muscle protein turnover from plasma samples alone, obviating the need for measurement of expired air CO2 production or enrichment.

The effect of chronic ethanol ingestion on synthesis and degradation of soluble, contractile and stromal protein fractions of skeletal muscles from immature and mature rats

1. An investigation was carried out into the response of soluble, myofibrillar and stromal protein fractions of skeletal muscle to chronic ethanol feeding. Groups of male Wistar rats, of approx. 85 or 280 g body wt., were pair-fed on a nutritionally complete liquid diet containing glucose or a diet in which 36% of the total energy was provided by ethanol. After 6 weeks, rates of protein synthesis were measured with a flooding dose of L-[4-3H]phenylalanine. 2. The protein contents of soluble, myofibrillar and stromal fractions in gastrocnemius muscle from small and large rats were decreased by ethanol feeding. Greater changes were observed in small than in large rats. 3. Fractional synthesis rates of soluble, myofibrillar and stromal proteins of gastrocnemius were all decreased by ethanol treatment. All fractions responded similarly, though percentage decreases in large rats were greater than in small rats. Absolute synthesis rates in gastrocnemius muscles were also decreased after ethanol treatment. All protein fractions responded similarly, and the magnitudes of the responses in large and small rats were also similar. 4. Fractional rates of breakdown, measured by the difference between fractional growth and synthesis rates, were apparently decreased, in both sets of rats, in all protein fractions. 5. It was concluded that chronic ethanol exposure causes perturbations in soluble, myofibrillar and stromal protein accretion by a mechanism involving unidirectional changes in protein synthesis and possibly breakdown.

Alterations in type II pneumocytes cultured after partial pneumonectomy

Type II pulmonary epithelial cells prepared from the lungs of normal rats were compared in primary culture to cells derived from the right lung of animals subjected previously to left pneumonectomy (PNX). Studies were initiated on the sixth post-PNX day, during the rapid phase of compensatory right lung growth. After 24 h in vitro, PNX cells were 30-40% larger than controls and contained 20-50% more DNA. The magnitude of these differences was dependent on serum concentration (fetal calf serum; 1 and 10%, respectively) and, under most conditions, decreased as culture time was extended to 48 or 72 h. Incorporation of [3H]thymidine into DNA was also elevated (greater than 50%) on the first culture day in the PNX group at both serum levels, and remained so through day 3 at low serum, as thymidine incorporation became more rapid in all cells. Similarly, rates of spermidine uptake were elevated in cells prepared from lungs of PNX animals on culture day 1, but this effect too was lost by day 3. Thus type II pneumocytes isolated from the lungs of PNX rats exhibit metabolic changes typical of accelerated cell growth at early intervals of primary culture in vitro. Although these changes are lost as culture time is extended and the cells lose differentiated characteristics, the results suggest that such pneumocytes may provide useful information regarding factors which regulate compensatory growth of lung tissue.

Matrix deposition and extracellular processing of newly synthesized collagens in the isolated perfused rat lung

We have examined the matrix deposition and proteolytic processing of newly synthesized interstitial and basement membrane collagens in the isolated perfused adult rat lung. Isolated, perfused, and ventilated lungs were labeled for up to 4 h with radiolabeled proline. Collagens were partially purified from homogenates by salt fractionation and ion exchange chromatography and examined by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). The major collagenous species were identified as types I, III, and IV collagen by peptide mapping and indirect immunoprecipitation assays. Whereas extraction with neutral salts recovered radiolabeled types I and III collagen, extraction of the neutral salt residue with 2 M guanidine-HCl preferentially recovered types III and IV collagen. Reextraction of the guanidine-HCl residue in the presence of dithiothreitol selectively recovered type IV procollagen (PC) and covalently cross-linked aggregates of type IV chains. In pulse-chase experiments we observed extensive conversion of type I PC to collagen during a 4-h chase. Although type III PC was efficiently converted to p-collagen, only small amounts of fully processed chains were identified. Type IV PC did not undergo detectable proteolytic processing. The isolated perfused rat lung should prove useful for further studies of lung collagen metabolism.

Compensatory growth of the lung following partial pneumonectomy

In a variety of species, partial resection of the lung initiates rapid compensatory growth of the remaining tissue adequate to restore normal total lung mass. Increases in tissue content of protein, RNA, and DNA in proportion to dry lung weight suggest hyperplastic growth of the tissue, rather than cellular hypertrophy. A general acceleration of cell division is supported further by the results of quantitative morphometric studies, which indicate that both cellular and functional characteristics of the peripheral lung, including alveolar and capillary volumes and thickness and surface area of the blood-gas barrier, are maintained when compensatory growth is complete. The rate and nature of the growth response are subject to hormonal modulation, particularly by adrenal steroids and growth hormone. Little is known, however, regarding the specific actions of these agents or of additional factors that may be primary regulators of the initiation and cessation of accelerated compensatory growth. Definition of such regulatory mechanisms is of critical importance in understanding normal growth and development of the lung and the response of the lung to injury, as well as in future efforts to manipulate growth and/or repair of the tissue.

Culture of type II pneumocytes on a type II cell-derived fibronectin-rich matrix

Recent evidence suggests that during primary culture, type II pneumocytes synthesize and deposit components of an extracellular matrix. The present study investigated the response of freshly isolated type II cells to a preformed, fibronectin-rich matrix synthesized by type II cells over a 6-day interval of primary culture on a plastic surface. Type II cells on 6-day matrix (M6) degraded the preformed matrix and deposited newly synthesized fibronectin more rapidly than cells on plastic, suggesting that M6 itself stimulated type II cell-mediated matrix turnover. In type II cells on plastic, incorporation of radiolabeled thymidine into DNA increased 620 and 1,880% after 2 and 3 days in culture, respectively, as the cells assumed a more flattened phenotype. Although cells on M6 did not divide, both basal rates of thymidine labeling and sensitivity to serum modulators of DNA synthesis were enhanced by the M6 surface, as compared with plastic. Culture of type II cells on surfaces of purified fibronectin enhanced the rate of DNA synthesis in a manner similar to that observed on M6; this effect was blocked by antifibronectin. The data suggest that more rapid fibronectin synthesis and deposition are important components of the response of type II cells to primary culture. Extracellular matrix produced by type II cells appears to be similar to the basement membrane onto which these cells proliferate in vivo after lung injury. A fibronectin-rich surface in itself may thus induce additional extracellular matrix synthesis and further direct cellular differentiation and proliferation.

Developmental regulation of rat lung Cu,Zn-superoxide dismutase

In the present investigation we found that lung Cu,Zn-superoxide dismutase (SOD) activity (units/mg of DNA) increases steadily in the rat from birth to adulthood. The specific activity (units/micrograms of enzyme) of Cu,Zn-SOD was unchanged from birth to adulthood, excluding enzyme activation as a mechanism responsible for the increase in enzyme activity. Lung synthesis of Cu,Zn-SOD peaked at 1 day before birth and decreased thereafter to adult values. Calculations, based on rates of Cu,Zn-SOD synthesis and the tissue content of the enzyme, indicated that lung Cu,Zn-SOD activity increased during development owing to the rate of enzyme synthesis exceeding its rate of degradation by 5-10%. These calculations were supported by measurements of enzyme degradation in the neonatal (half-life, t1/2, = 12 h) and adult lung (t1/2 = greater than 100 h); the difference in half-life did not reflect the rates of overall protein degradation in the lung, since these rates were not different in lungs from neonatal and adult rats. We did not detect differences in the Mr or pI of Cu,Zn-SOD during development, but the susceptibility of the enzyme to inactivation by heat or copper chelation decreased with increasing age of the rats. We conclude that the progressive increase in activity of Cu,Zn-SOD is due to a rate of synthesis that exceeds degradation of the enzyme. The data also suggest that increased stabilization of enzyme conformation accounts for the greater half-life of the enzyme in lungs of adult compared with neonatal rats.

Rat lung lectin synthesis, degradation and activation. Developmental regulation and modulation by dexamethasone

Soluble lectins are widely distributed cell-agglutinating proteins. Their activity is developmentally regulated in several tissues, including the lung, but virtually nothing is known about the mechanisms of the developmental regulation or the turnover of these proteins. We studied mechanisms that might be responsible for the developmentally regulated changes in the activity of a lectin (beta-galactoside-binding protein) found in the lung, and determined if its activity or turnover could be modulated by treatment of rat pups with a glucocorticosteroid hormone (dexamethasone). Our studies on the activity and turnover of the lectin indicated that the peak of lectin activity (units/mg of protein) that occurred at age 12 days appeared to be brought about by two means: an increase in the activity of the lectin molecule itself (units/micrograms of lectin) that occurred at age 8 days, and 1.5-fold increase in the absolute rate of lectin synthesis at age 11 days. The decline in lectin activity was associated with a decrease in its rate of synthesis, return to the baseline extent of activation, and an increased rate of degradation. Treatment of rat pups with dexamethasone diminished the peak of lectin activity (units/mg of protein) by about 25%. This effect of dexamethasone was due, at least in part, to the complete prevention of activation of the lectin molecule (units/micrograms of lectin) and a premature increase in the rate of lectin degradation. Perhaps the normal fall in lectin activity after age 11 days is caused by mechanisms induced by the increase in serum corticosteroid that occurs at that age.

Pre- and post-natal growth and protein turnover in the lung of the rat

The growth of the rat lung was studied at six ages, from 18 days of fetal life to old age (i.e. 105 weeks). Most of the increase in lung size appeared to involve cellular hyperplasia rather than hypertrophy, the DNA content of the lung increasing 96-fold from one extreme of life to the other. Pulmonary rates of protein turnover were high and were, age for age, consistently greater than the rates in the whole body. The age-related decline in the rate of lung growth corresponded to a marked decrease in the fractional rate of protein synthesis, i.e. from 93 to 33% per day during fetal and neonatal life. This in turn correlated with a 58% fall in the ribosomal capacity. From weaning onwards, synthesis rates remained between 30 and 40% per day. In contrast, the degradation of lung proteins was unchanged, at 28-38% per day throughout both fetal and post-natal life.

Effect of altered inflation on pulmonary uptake of methylglyoxal bis(guanylhydrazone)

The effects of increased pulmonary ventilation on uptake of an exogenous, nonmetabolized polyamine analog, methylglyoxal bis(guanylhydrazone) [MGBG] were investigated in rat lungs perfused in situ with buffer containing 4.5% bovine serum albumin, 5.6 mM glucose and plasma levels of amino acids. The perfusate was equilibrated and the lungs were ventilated with warmed, humidified O2/N2/CO2 (20:75:5). A 28% increase in lung inflation rapidly accelerated MGBG uptake at low (1.5 microM) but not at high (50 microM) substrate concentration, a change which appeared to reflect a decrease in the apparent Km of the uptake pathway. This effect was not associated with acute alterations in pulmonary vascular permeability or resistance, nor with instability of the preparations. Taken with observations made previously, these results suggest that deformation of the tissue by increased inflation may account for increased MGBG uptake by lungs from rats subjected to partial pneumonectomy.

Protein synthesis in the growing rat lung

Developmental control of protein synthesis in the postnatal growth of the lung has not been systematically studied. In male Fischer 344 rats, lung growth continues linearly as a function of body weight (from 75 to 450 g body weight). To study total protein synthesis in lungs of growing rats, we used the technique of constant intravenous infusion of tritiated leucine, an essential amino acid. Lungs of sacrificed animals were used to determine the leucine incorporation rate into newly synthesized protein. The specific radioactivity of the leucine associated with tRNA extracted from the same lungs served as an absolute index of the precursor leucine pool used for lung protein synthesis. On the basis of these measurements, we were able to calculate the fractional synthesis rate (the proportion of total protein destroyed and replaced each day) of pulmonary proteins for each rat. Under the conditions of isotope infusion, leucyl-tRNA very rapidly equilibrates with free leucine of the plasma and of the extracellular space of the lung. Infusions lasting 30 minutes or less yielded linear rates of protein synthesis without evidence of contamination of lung proteins by newly labeled intravascular albumin. The fractional synthesis rate is considerably higher in juvenile animals (55% per day) than in adult rats (20% per day). After approximately 12 weeks of age, the fractional synthesis rate remains extremely constant in spite of continued slow growth of the lung. It is apparent from these data that in both young and adult rats the bulk of total protein synthesis is devoted to rapidly turning over proteins and that less than 4 percent of newly made protein is committed to tissue growth.

Protein synthesis in perfused rat lungs: determinations based on incorporation of radioactive proline

Functional compartmentation and metabolism of radioactive proline was evaluated to define conditions under which synthesis of lung proteins could be measured accurately based on proline incorporation. Rat lungs were perfused with Krebs-Henseleit bicarbonate buffer equilibrated with O2/N2/CO2 (20:75:5) and containing 4.5% (w/v) bovine serum albumin, 5.6 mM glucose and amino acids at plasma levels. Intracellular proline increased linearly as perfusate proline concentration was increased from 108 microM, the plasma level, to 540 or 1080 microM. At each concentration, the pool of proline which provided precursors to protein synthesis rapidly reached a steady-state specific radioactivity, but when extracellular proline was 108 microM, this pool was diluted significantly by proline from endogenous sources. At 540 or 1080 microM extracellular proline, the specific radioactivities of perfusate and intracellular proline approached equality and rates of protein synthesis calculated based on the specific radioactivity of extracellular proline compared favorably with those calculated from the specific radioactivity of phenylalanyl-tRNA. Similar results were obtained in lungs of two groups of rats in which intracellular proline concentration differed 3-fold. Thus, the contribution of endogenous proline to the pathway of protein synthesis was minimized when extracellular proline was present at high concentration. Under this condition, calculations of protein synthesis based on proline incorporation were most accurate.

Protein synthesis in rat lung. Measurements in vivo based on leucyl-tRNA and rapidly turning-over procollagen I

The relationships of the specific radioactivities of leucine in serum, leucine acylated to tRNA and leucine in procollagen I, procollagen III and total protein in lungs of unanaesthetized young male rats in vivo were assessed as a function of time during constant intravenous infusion of radiolabelled leucine. The specific radioactivity of free leucine in plasma reached a steady-state plateau value within 30 min of initiation of [3H]leucine infusion. Leucine acylated to tRNA isolated from lungs had the same specific radioactivity as free serum leucine. Leucine in procollagen I rapidly achieved a specific radioactivity equal to that of serum leucine and leucyl-tRNA, indicating that serum leucine and leucyl-tRNA isolated from total lung were in rapid equilibrium with the precursor leucine pool for procollagen I synthesis. On the basis of leucyl-tRNA or free serum leucine as the precursor, half-times of fractional conversion of procollagen I and III were calculated as 9 and 38 min respectively. The incorporation of leucine into mixed lung proteins calculated from the tracer studies was 6.8 mumol/day for the first 30 min of the infusion, after which the calculated rate increased to 15.0 mumol/day. This apparent increase correlated with the appearance of rapidly labelled plasma proteins trapped in the lungs. On the basis of short infusions lasting 30 min or less, followed by vascular perfusion of the lung, the average fractional synthesis rate of mixed pulmonary proteins in young male rats was 20%/day.

Comparison of protein-synthesis rate of alveolar macrophages in vivo and in vitro

This paper describes and validates a novel method for measuring rates of protein synthesis of rabbit alveolar macrophages in vivo. A rate of 9.3%/day was obtained, compared with 48.9%/day measured in vitro. This study suggests that the procedures involved in the isolation of alveolar macrophages for study in vitro may themselves activate the cell.

Characteristics of amino acid metabolism by isolated alveolar type II cells

Alveolar type II cells of the lung are important in producing the lipoprotein surfactant. Most studies about metabolism in type II cells have focussed on lipid precursors for phospholipid metabolism. Surfactant contains a unique apoprotein; yet relatively little is known about the metabolism of amino acids by type II cells. Type II cells were isolated using density gradient centrifugation followed by centrifugal elutriation. Alanine (Ala), leucine (Leu), valine (Val), and phenylalanine (Phe) incorporation into protein and lipid and oxidation to CO2 was measured after the cells were incubated for 2 h. For alanine metabolism, 22% of total radioactivity from alanine was incorporated into protein, 20% into lipid, and 58% oxidized to CO2. For leucine, 51% was incorporated into protein, 23% into lipid, and 22% oxidized to CO2. Fifty percent of radioactivity from valine metabolism was incorporated into protein, 5% into lipid, and 47% oxidized to CO2. Virtually all (95%) of phenylalanine, however, was utilized for protein synthesis only. Puromycin and cycloheximide decreased protein synthesis from Ala, Leu, and Phe but had little affect on Ala and Leu metabolism to lipid or CO2. The hypolipidemic drug clofibrate inhibited all aspects of amino acid metabolism. In summary, type II cell amino acid metabolism is regulated similar to that of cells from skeletal muscle and adipose tissue, but in contrast to hepatocytes, type II cells readily oxidize valine and utilize leucine for lipid as well as protein synthesis.

Regulation of protein synthesis in lung by amino acids and insulin

Acute effects of amino acid availability and insulin on protein synthesis were investigated in rat lungs perfused in situ with buffer containing either 4.5% fraction V bovine serum albumin (FrV BSA), 4.5% essentially fatty acid-free (FAF) BSA, or 4.5% dextran to maintain colloid osmotic pressure. In the presence of FrV BSA, protein synthesis was unaffected by perfusion for 1 or 3 h with buffer containing no added amino acids (0X), as compared with amino acids at concentrations one (1X) or five (5X) times those in rat plasma. Regardless of the amino acid concentration, addition of insulin was without effect. Likewise, in lungs perfused for 1 h with either FAF BSA or dextran, protein synthesis was insensitive to amino acid availability or to insulin. After 3 h, however, protein synthesis decreased 34 and 37%, respectively, when these lungs were perfused in the absence of both amino acids and insulin. In both cases, the inhibition was prevented by addition of insulin to the perfusate; addition of the hormone to perfusate containing 1X amino acids or elevating perfusate amino acids to 5X did not affect protein synthesis. The deficit in protein synthesis observed in the absence of both amino acids and insulin was not accompanied by ATP depletion or by lower intracellular concentrations of amino acids. Similarly, the effect of insulin was not associated with a general elevation in intracellular amino acid concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Glucose stimulation of testosterone-maintained protein synthesis in the rat ventral prostate

The stimulatory effect of exogenous glucose on protein synthesis maintained by testosterone was studied by measuring the in vitro incorporation of amino acids into proteins in the rat ventral prostate. The addition of glucose did not influence the specific activity of the extracellular or intracellular amino acid pools. The amount of newly-synthetized proteins was increased in the presence of glucose. Mannose was as effective as glucose, whereas a variety of other substrates (e.g. pyruvate, lactate, amino acids, acetate) which are readily metabolized by the prostate, failed to support to the same extent hormone-activated protein synthesis. None of the substrates increased protein synthesis in the prostate of castrated rats. The incubation of the prostate without any substrate led to a decline in the level of ATP, the ATP/ADP ratio and the adenylate energy charge and to a rise in the levels of ADP and AMP irrespective of the hormonal state of the tissue. The addition of glucose restored the levels and ratios of the adenine nucleotides, but several other substrates were also able to maintain the initial ATP levels in the prostate of castrated, as well as castrated, testosterone-treated rats. The stimulatory effect of glucose on hormone-maintained protein synthesis cannot be explained by changes in the adenine nucleotides. Nevertheless, the activation of glucose metabolism may play an important role by providing energy for increased synthetic reactions. Moreover, glucose and mannose molecules themselves or a glycolytic metabolite (proximal to pyruvate) may be required for the full expression of the transcriptional effect of testosterone on protein synthesis in the ventral prostate of castrated rats.

Reversible inhibition of protein synthesis in lung by halothane

Alterations in the synthesis and degradation of proteins were investigated in intact lungs exposed to the volatile anaesthetic halothane. In rat lungs perfused in situ with Krebs-Henseleit bicarbonate buffer containing 4.5% (w/v) bovine serum albumin, 5.6 mM-glucose, plasma concentrations of 19 amino acids and 690 microM-[U-14C]-phenylalanine and equilibrated with O2/N2/CO2 (4:15:1), protein synthesis, calculated based on the specific radioactivity of aminoacyl-tRNA, was inhibited by halothane. The anaesthetic did not affect degradation of lung proteins. The inhibition of protein synthesis was rapid in onset, dose-dependent, and quickly reversible. It did not appear to be associated with overall energy depletion, with non-specific changes in cellular permeability, or with decreased availability of amino acids as substrates for protein synthesis.

Pinocytosis and intracellular degradation of exogenous protein: modulation by amino acids

Intracellular degradation of exogenous (serum) proteins provides a source of amino acids for cellular protein synthesis. Pinocytosis serves as the mechanism for delivering exogenous protein to the lysosomes, the major site of intracellular degradation of exogenous protein. To determine whether the availability of extracellular free amino acids altered pinocytic function, we incubated monolayers of pulmonary alveolar macrophages with the fluid-phase marker, [14C]sucrose, and we dissected the pinocytic process by kinetic analysis. Additionally, intracellular degradation of endogenous and exogenous protein was monitored by measuring phenylalanine released from the cell monolayers in the presence of cycloheximide. Results revealed that in response to a subphysiological level of essential amino acids or to amino acid deprivation, (a) the rate of fluid-phase pinocytosis increased in such a manner as to preferentially increase both delivery to and size of an intracellular compartment believed to be the lysosomes, (b) the degradation of exogenously supplied albumin increased, and (c) the fraction of phenylalanine derived from degradation of exogenous albumin and reutilized for de novo protein synthesis increased. Thus, modulation of the pinosome-lysosome pathway may represent a homeostatic mechanism sensitive to the availability of extracellular free amino acids.

Altered rates of collagen synthesis in in vitro aged human lung fibroblasts

Absolute rates of protein and collagen synthesis based on prolyl-tRNA as the precursor were determined in two age groups of IMR-90 human lung fibroblasts. Compared with midrange fibroblasts [population doubling level (PDL) = 20 to 30] aged fibroblasts (PDL greater than 40] were larger in size in terms of protein and RNA per cell, generally proliferated more slowly, exhibited different steady state [3H] proline transfer RNA (tRNA) precursor pool specific radioactivities, synthesized collagen at a substantially lower rate, and exhibited a reduction in the percent commitment to collagen synthesis. Total protein synthetic rates were reduced slightly in aged versus midrange fibroblasts but the difference was not statistically significant. Proliferative capacity (PDL/wk) correlated better with these changes than cumulative PDL. Cell size (protein/cell) was the variable that had the highest correlation with the reduction in collagen synthesis observed in human lung fibroblasts. Thus, an important differentiated function of human lung fibroblasts, collagen synthesis, is greatly diminished in vitro in large, slowly dividing fibroblasts.

The effect of insulin infusion and food intake on muscle protein synthesis in postabsorptive rats

1. Insulin was infused into young male rats in the postabsorptive state. Rates of protein synthesis in skeletal muscle were determined during the final 10 min of infusion from the incorporation of label into protein after intravenous injection of a massive dose of [3H]phenylalanine. Rates of synthesis were not altered during the first 10 min of insulin infusion, but were increased significantly between 10 and 60 min. 2. Rats were infused with different amounts of insulin for 30 min. When concentrations were increased from 10 to 40 microunits/ml of plasma there was no change in muscle protein synthesis, but concentrations higher than 70 microunits/ml caused a significant stimulation. Concentrations below 10 microunits/ml, obtained by infusion of anti-insulin serum, did not depress synthesis below that found in the postabsorptive rat. 3. Infusion of glucose for 30 or 60 min led to an increase in plasma insulin to 40 microunits/ml, but this also failed to stimulate muscle protein synthesis. 4. Rates of synthesis in postabsorptive rats, even when stimulated maximally by insulin, were not so high as those in fed rats or in postabsorptive rats refed for 60 min. However, in fed and refed rats insulin concentrations were below that required to stimulate synthesis in postabsorptive animals. Despite this, infusion of large amounts of insulin into fed rats did not increase synthesis further. 5. The sensitivity of plasma glucose to insulin infusion was different from that of protein synthesis. A decrease in glucose concentration preceded the increase in synthesis and occurred at lower insulin concentrations. 6. It is concluded that changes in circulating insulin may have been partly responsible for the increase in muscle protein synthesis brought about by feeding, but that other factors must also play a part.

Identification of specific proteins synthesized by type II pneumocytes in primary culture

Proteins from primary cultures of type II granular pneumocytes have been examined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis to identify type II cell-specific proteins. The distribution of Coomassie Blue-stained bands in preparations of cellular proteins, culture medium, lavage and lamellar bodies have been compared. The most prominent stained band in the serum-free medium from type II cell cultures (HS1; Mr 39900) corresponds to a major protein in acellular sedimentable (20000 g for 30 min) crude surfactant obtained from rat lungs by saline (0.9% NaCl) lavage. A second protein (HS2; Mr 12000) is also found both in type II cell-conditioned medium and in lavage. Neither rat serum nor donor calf serum (used in the isolation of the type II cells) contains a protein co-migrating with HS1 or HS2 proteins. HS1 is also found in Coomassie Blue-stained gels of cellular proteins and of lamellar bodies isolated from whole lungs. Cultures of type II cells incorporate [14C]phenylalanine into HS1 and HS2 as shown by autoradiography of sodium dodecyl sulphate/polyacrylamide gels of culture medium. Rat lungs perfused in situ incorporate [35S]methionine into HS1 in the lamellar body fraction. A third protein (HS3; Mr 47000) is observed only in autoradiographs of cell culture medium; no corresponding Coomassie Blue-stained band can be identified in medium, in cells or in lung lavage. No protein bands corresponding to HS1, HS2 or HS3 are found in conditioned media from pulmonary alveolar macrophages, rat fibroblasts or bovine aorta endothelial cells. Two-dimensional gel electrophoresis of HS1 shows a single polypeptide with an isoelectric point of 6.3; HS3 appears as a chain of spots with a range of isoelectric points from 6.3 to 6.6. HS2 has not been identified on two-dimensional gels. The amino acid composition of HS1 does not differ significantly from that of surfactant apoproteins studied previously; however, HS1 is not detected by glycoprotein stains, nor does it appear to be a subunit of a thiol-linked multimer.

Effect of halothane on metabolism of 5-hydroxytryptamine by rat lungs perfused in situ

The effect of halothane (2-bromo-2-chloro-1,1,1-trifluoroethane) on the uptake of 14C-labelled 5-hydroxytryptamine (5-HT) and its metabolism to 5-hydroxyindol-3-ylacetic acid (5-HIAA) was investigated in rat lungs perfused in situ. The rate of accumulation of 14C-labelled 5-HIAA in the tissue, monitored as an index of 5-HT metabolism, was linear with time, displayed saturation kinetics and remained stable for at least 180 min of perfusion. Exposure of the lungs to halothane (4%) for 60 min reversibly reduced production of 5-HIAA through an increase in the apparent Km for metabolism of the amine from 1.45 to 3.52 microM (P less than 0.001); the anaesthetic had no effect on the Vmax. of the process. The magnitude of the inhibition increased with time of exposure to the anaesthetic. Halothane exposure did not alter the distribution of [3H]sorbitol or [14C]5-HT, pulmonary vascular resistance, levels of ATP or the kinetics of amino acid transport in the tissue. Inhibition of protein synthesis by cycloheximide did not mimic the effect of the anaesthetic. These observations, together with those made in lungs exposed to inhibitors of 5-HT uptake and metabolism, were consistent with a halothane-mediated inhibition of 5-HT uptake, which did not appear to involve non-specific changes in membrane permeability.

Rates of collagen synthesis in lung, skin and muscle obtained in vivo by a simplified method using [3H]proline

Methods for measurement of rates of collagen synthesis in vivo have thus far been technically difficult and often subject to quite large errors. In this paper a simplified method is described for obtaining synthesis rates of collagen and non-collagen proteins, for tissues of rabbits. This involves an intravenous injection of [3H]proline, administered with a large dose of unlabelled proline, and measurement of the specific radioactivity of proline and hydroxyproline in body tissues up to 3 h later. The specific radioactivity of [3H]proline in plasma and the tissue free pools rises rapidly to a plateau value which is maintained for at least 2 h, when the specific radioactivity of the type I collagen precursors, isolated from the skin, was similar to that of the plasma and tissue-free pool. Furthermore, over this period, the increase in the specific radioactivity of proline in collagen and non-collagen protein was linear with respect to time. These results suggest that the large dose of proline floods the precursor pools for protein synthesis, and that this effect can be maintained for quite long periods of time. Such kinetics greatly simplified the method for obtaining collagen synthesis rates in vivo, which were calculated for lung, heart, skin and skeletal muscle, and shown to be quite rapid, ranging between about 3 and 10%/day. The lung was a particularly metabolically active tissue, with synthesis rates of about 10%/day for collagen and 35%/day for total non-collagen proteins, indicating rapid turnover of both intracellular and extracellular proteins of this tissue.

The measurement of protein synthesis in biological systems

Attempts to quantitate metabolism in the lung and other tissues using radioactive precursors may be subject to significant errors arising from inappropriate assumptions regarding precursor metabolism, compartmentation and specific radioactivity. This article reviews the type and magnitude of error which may complicate such measurements by presenting specific data from experiments using radioactive amino acids to estimate the rate of protein synthesis. The applicability of these observations to other metabolic systems is discussed briefly in order to develop a more general awareness of the errors which may result from incomplete validation of experimental measurements using radioisotopes.

A quantitative autoradiographic method for the measurement of local rates of brain protein synthesis

We have developed a new method for measuring local rates of brain protein synthesis in vivo. It combines the intraperitoneal injection of a large dose of low specific activity amino acid with quantitative autoradiography. This method has several advantages: 1) It is ideally suited for young or small animals or where immobilizing an animal is undesirable. 2 The amino acid injection "floods" amino acid pools so that errors in estimating precursor specific activity, which is especially important in pathological conditions, are minimized. 3) The method provides for the use of a radioautographic internal standard in which valine incorporation is measured directly. Internal standards from experimental animals correct for tissue protein content and self-absorption of radiation in tissue sections which could vary under experimental conditions.

Prolyl-tRNA-based rates of protein and collagen synthesis in human lung fibroblasts

Knowledge of the dynamics of collagen turnover requires information regarding rates of synthesis of this group of connective-tissue proteins. The relationship of various amino acid pools to the tRNA precursor pool used for protein synthesis is known to vary between different cell types and tissues, even for essential amino acids. We studied extracellular, intracellular and tRNA-proline pools in cultured human lung IMR-90 fibroblasts to determine the relationship between them as candidate proline precursor pools for total protein and collagen synthesis. Time-course experiments showed that the three proline pools attained distinctly different steady-state specific radioactivities (extracellular greater than intracellular greater than tRNA) at the extracellular proline concentration of 0.2 mM. The kinetics of radioisotope incorporation into cell protein and collagenase-digestible protein indicated that the intracellular free proline pool could not be used reliably as a precursor for calculating synthetic rates. However, tRNA-proline behaved isotopically as if it were the precursor and provided synthesis rates 2-3-fold higher than those calculated by using either free proline pool. The incorporation of labelled lysine and leucine was constant over a wide range of extracellular proline concentrations. Fractional rates of protein synthesis based on tRNA-amino acid were the same with [3H]phenylalanine as with [3H]proline. The specific radioactivity of cell-associated hydroxyproline reached a steady-state value 8-10h after radioisotope administration which matched the mean tRNA-proline specific radioactivity, suggesting that tRNA-proline is not isotopically compartmentalized. A model of cellular proline-pool relationship is presented and discussed.

Protein turnover in pulmonary macrophages. Utilization of amino acids derived from protein degradation

Conditions were defined under which rates of protein synthesis and degradation could be estimated in alveolar macrophages isolated from rabbits by pulmonary lavage and incubated in the presence of plasma concentrations of amino acids and 5.6 mM-glucose. Phenylalanine was validated as suitable precursor for use in these studies: it was not metabolized appreciably, except in the pathways of protein synthesis and degradation; it entered the cells rapidly; it maintained a stable intracellular concentration; and it was incorporated into protein at measurable rates. When extracellular phenylalanine was raised to a concentration sufficient to minimize dilution of the specific radioactivity of the precursor for protein synthesis with amino acid derived from protein degradation, the specific radioactivity of phenylalanyl-tRNA was only 60% of that of the extracellular amino acid. This relationship was unchanged in cells where proteolysis increased 2.5-fold after uptake and degradation of exogenous bovine serum albumin. In contrast, albumin prevented the decrease in phenylalanine incorporation observed in macrophages deprived of an exogenous source of amino acids. These observations suggested that macrophages preferentially re-utilized amino acids derived from the degradation of endogenous, but not from exogenous (albumin), protein. However, when the extracellular supply of amino acids was restricted, substrates derived from albumin catabolism could support the protein-synthetic pathway.