Energy cost of whole-body protein synthesis measured in vivo in chicks

1. Energy cost of whole-body protein synthesis was measured in vivo in chicks by comparing the changes in protein synthesis and heat production after the administration of cycloheximide, an inhibitor of protein synthesis. 2. Incorporation of phenylalanine into whole-body protein fraction was promptly inhibited after the intravenous injection of cycloheximide, and the effect was sustained for at least 3 hr. 3. Both whole-body protein synthesis and total heat production were significantly reduced by the cycloheximide administration. 4. The energy cost of whole-body protein synthesis was calculated to be 5.35 kJ per g protein synthesis, and hence on a molar basis 7.52 ATPs are required per peptide bond synthesis.     

Mechanism of lymphocyte activation. II. Requirements for macromolecular synthesis in the production of lymphokines

Reversible inhibitors of protein synthesis, cycloheximide and puromycin, and an irreversible inhibitor of RNA synthesis, actinomycin D, were employed to study the kinetics and types of macromolecular synthetic events required for the production of migration inhibitory factor (MIF) and macrophage activating factor (MAF) by Con A-stimulated lymphocytes. Reversible inhibition of protein synthesis during the first 2 hr of stimulation completely inhibited MIF and MAF production. The same treatment, performed 4 hr after the beginning of the stimulation, had no effect. When the inhibitors of protein synthesis were left in the cultures, a block of lymphokine production was observed when the drugs were added at 6 hr as well as at time 0. In contrast, irreversible inhibition of RNA synthesis at 6 hr was ineffective and only treatment at the beginning of culture blocked lymphokine production. These data suggest that a critical protein is synthesized during the first few hours of stimulation, which is required for subsequent production of lymphokines. After this special early requirement, however, continued protein synthesis is needed for lymphokine production. In contrast, the RNA required for MIF and MAF production seemed to be completely synthesized within 4 to 6 hr of stimulation. The possibility that suppressor macrophages inhibit lymphokine production via modulation of macromolecular synthesis is discussed.     

Effect of protein-synthesis inhibitors on testosterone production in rat testis interstitial tissue and Leydig-cell preparations.

Luteinizing-hormone-stimulated testosterone biosynthesis was inhibited by cycloheximide during incubation of rat testis intersitial tissue in vitro and also by puromycin and cycloheximide during incubation of Leydig-cell preparations, but not by chloramphenicol. These results suggest that a protein regualtor(s) formed by cytoplasmic protein synthesis is involved in steroidogenesis in the rat testis. The specific effect of cycloheximide and puromycin on protein synthesis rather than on other non-specific processes is suggested by the inhibition of protein synthesis and steroidogenesis with different doses of the inhibitors and the lack of effect of cycloheximide on luteinizing-hormone-induced adenosine 3':5'-cyclic monophosphate production. Stimulation of testosterone production by luteinizing hormone during superfusion of interstitial tissue was detectable within 10-20 min and reached a maximum of 120 min, and thereafter slowly decreased. Cycloheximide added at maximum steroid production caused a rapid decrease in testosterone synthesis which followed first-order kinetics (half-life 13 min), thus indicating that the protein regulator(s) has a short half-life. No effect of cycloheximide, puromycin or chloramphenicol on testosterone production in the absence of added luteinizing hormone was found, suggesting that the basal production of testosterone is independent of protein synthesis.     

Effect of low ambient temperature on protein turnover and heat production in chicks

1. Effect of low ambient temperature on protein turnover in the liver and whole body was investigated in chicks together with the contribution of protein synthesis to the total heat production. 2. Both protein synthesis and degradation in the whole body were increased, the latter to a larger extent, at low ambient temperature (LT, 22 degrees C) compared with adequate temperature (AT, 30 degrees C). Liver protein synthesis was not significantly altered by the temperature treatment. 3. The total heat production of LT group was as high as 160% of the AT group. 4. The increased heat production due to enhanced whole-body protein synthesis accounted for only 1.4% of the heat increment in thermogenesis at low ambient temperature, suggesting that protein synthesis would contribute little, if any, to cold-induced thermogenesis in chicks.     

Collagen synthesis in human fibroblasts: Effects of ascorbic acid and regulation by hydrocortisone

The effects of hydrocortisone and ascorbic acid on collagen and noncollagen protein synthesis, and on growth were examined in fibroblasts derived from normal human dermis. When the medium was supplemented with 0.28 mM ascorbic acid, the apparent rate of collagen production increased 2--3 fold over the culture cycle. Ascorbic acid also caused a small increase in the apparent rate of synthesis of noncollagen protein and an elevation in growth rate and maximum cell density. Growth was not required for the increase in collagen production since addition of ascorbate to confluent cultures induced a similar increase. Hydrocortisone (1.5 μM) blocked the ascorbate-related increase in collagen production during growth and in confluent cultures. The hormone simultaneously increased the apparent rate of noncollagen protein production and maximum cell density, suggesting that the effect on collagen synthesis was specific. Inhibition of collagen production by hydrocortisone was observed only in the presence of ascorbate, while the increase in growth and noncollagen protein production occurred in the presence and absence of the vitamin.     

IL-6 protein production by airway epithelial(-like) cells disabled in IL-6 mRNA degradation

IL-6 mRNA and protein expression in human airway epithelial-like H292 cells depends on rapid, but regulable IL-6 mRNA degradation. We restricted IL-6 mRNA degradation by partially inhibiting protein synthesis and studied the IL-6 response. Despite partial inhibition of protein synthesis, IL-6 protein production was increased and prolonged. Furthermore, the threshold concentration for stimuli of IL-6 protein production decreased and the dose-response curves became steeper. Similar findings were obtained with primary human bronchial epithelial cells. This exaggerated production may apply to other proteins encoded by labile mRNA and is likely to occur during viral infection of airway epithelial cells.     

Lutropin stimulates de novo synthesis of short-lived proteins required for lutropin-dependent steroid production in tumour Leydig cells

Continuous protein synthesis is required for the hormonal regulation of cholesterol side chain cleavage activity. A protein with a short half-life (t1/2 = 2-13 min) is believed to play an important role, but the regulation of the synthesis of this putative rapidly-turning-over protein is largely unknown. The steroid production rate in tumour Leydig cells can be increased more than 4-fold after addition of lutropin. However, steroid production by cells preincubated for 60 min with medium containing cycloheximide (89 microM) could not be stimulated when lutropin was added to the medium. Thus, the putative protein with the short half-life is apparently not derived from a stable precursor protein. Moreover, in tumour Leydig cells incubated with low concentrations of cycloheximide (0.2-0.8 microM), inhibition of steroid production was significantly greater in lutropin-stimulated cells than in control cells. These results support the hypothesis that lutropin regulates the de novo synthesis of rapidly-turning-over proteins by increasing the rate of initiation of the translation step of protein synthesis.     

Stimulation of Tentoxin Synthesis by Aged-Culture Filtrates and Continued Synthesis in the Presence of Protein Inhibitors

Tentoxin, a cyclic tetrapeptide produced by Alternaria alternata (Fries) Keissler, induces chlorosis in certain seedling plants. It can be extracted from culture filtrates of the fungus. Tentoxin production is stimulated and increased by using a mixture of aged culture filtrates and modified Richards solution. Aged culture filtrates can be obtained from 3-week-old or older cultures of A. alternata in modified Richards solution or Pratts solution. A mixture of aged culture filtrate and fresh medium in the ratio 2:3 gives the maximal enhancement of tentoxin production. This growth system provided us with a model for studying the effects of protein synthesis inhibitors on tentoxin production. Two antibiotics which inhibit protein synthesis at the ribosomal level were tested on growth, protein synthesis, and tentoxin production in A. alternata cultures. Cycloheximide at concentrations of 500 μg/ml or emetine at concentrations of 250 μg/ml did not inhibit tentoxin synthesis, although they stopped mycelial growth and protein synthesis of the fungus at the logarithmic growth stage in the enhancement medium. These results led us to conclude that tentoxin, like certain other bioactive cyclic peptides, is synthesized by a nonribosomal peptide synthesis mechanism.     

Inhibition of Host Deoxyribonucleic Acid Synthesis by T4 Bacteriophage in the Absence of Protein Synthesis

The requirement for phage protein synthesis for the inhibition of host deoxyribonucleic acid synthesis has been investigated by using a phage mutant unable to catalyze the production of any phage deoxyribonucleic acid. It has been concluded that the major pathway whereby phage inhibit host syntheses requires protein synthesis. The inhibition of host syntheses by phage ghosts is not affected by inhibitors of protein synthesis.     

Activation of protein kinase C is coupled to prostaglandin E2 synthesis in swine granulosa cells

We have examined the role of phospholipid-sensitive calcium-dependent protein kinase (protein kinase C) in prostaglandin E2 synthesis by monolayer cultures of swine granulosa cells. Specific phorbol ester derivatives known to activate protein kinase C significantly augmented the production of prostaglandin E2. These stimulatory actions were dose and time-dependent, and could be abolished by the cyclooxygenase inhibitor, indomethacin, or the protein synthesis inhibitor, cycloheximide. Moreover, the rank order of potency of phorbol esters in enhancing prostaglandin E2 production was concordant with that demonstrated for activation of protein kinase C. Phorbol ester in conjunction with the divalent cation ionophore, A23187, increased prostaglandin E2 production synergistically. In addition, a non-phorbol stimulator of protein kinase C, 1-octanoyl-2-acetylglycerol, also significantly enhanced prostaglandin E2 biosynthesis. The stimulated synthesis of prostaglandin E2 was confirmed by high-pressure liquid chromatographic purification of this radiolabeled metabolite of 3H-arachidonic acid, and by capillary gas chromatography high-resolution mass spectrometry. Thus, the present studies indicate that the protein kinase C effector pathway is functionally coupled to prostaglandin E2 production in the swine granulosa cell.     

Selective inhibition of collagen synthesis by the Ca2+ ionophore A23187 in cultured human fibroblasts

The question of whether the Ca2+ ionophore A23187 affects collagen production relative to total protein synthesis or has possible effects on collagen degradation was investigated. Cultured normal human fibroblasts were incubated with radioactive proline, and the radioactivity of collagenase-sensitive and -resistant proteins was used to calculate the rates of protein production. The net production of collagen relative to total proteins was inhibited by A23187 in a dose-related manner, and 50% inhibition of basal collagen production was achieved with 0.6 microM A23187. There was a 70% decrease in the absolute rate of collagen production in the presence of 0.6 microM A23187 which represented a 4-fold greater inhibition of collagen production than of noncollagen protein production. The major mechanism for the decreased net production of collagen was decreased synthesis, rather than increased degradation. Ca2+ mobilization induced by cholecystokinin octapeptide was also associated with selective inhibition of collagen production in normal human fibroblasts. These studies establish that the Ca2+ ionophore A23187 induces a selective decrease in collagen polypeptide synthesis by normal human fibroblasts and suggest a modulatory role of Ca2+ on collagen metabolism.     

Protein synthesis involvement in regulating pituitary-induced progesterone levels in ovarian follicles of Rana pipiens

Involvement of protein synthesis in frog pituitary homogenate (FPH)-induced progesterone production and/or accumulation in ovarian follicles was investigated. In amphibians, cycloheximide (C), an inhibitor of protein synthesis, inhibits progesterone and FPH-induced germinal vesicle breakdown (GVBD). However, the site and mechanisms of action of cycloheximide within ovarian follicles have not been elucidated. Intrafollicular progesterone produced by FPH is considered to mediate oocyte maturation; thus, cycloheximide may interfere with production and/or action of progesterone. Simultaneous treatment of FPH-stimulated follicles with cycloheximide inhibited FPH-induced progesterone accumulation (measured by RIA) and the accompanying-GVBD in a dose-dependent fashion. Inhibitory effects of cycloheximide on either FPH-induced progesterone production or GVBD were not reversed when follicles were washed and returned to fresh medium devoid of FPH and cycloheximide. However, subsequent restimulation of washed follicles with FPH resulted in increased progesterone levels and oocyte maturation. The extent of reversibility, in terms of GVBD and progesterone production, after FPH restimulation varied between animals. Pretreatment of follicles with cycloheximide for 6 hours, without FPH, had little or no effect on progesterone production when follicles were washed and treated with FPH. Delayed addition of cycloheximide to follicles following FPH stimulation blocked further progesterone accumulation as indicated by measurement of intrafollicular progesterone at the time of cycloheximide addition and at the end of the incubation period. The results indicate that cycloheximide rapidly inhibits progesterone production and that continuous protein synthesis is required for progesterone accumulation. Furthermore, protein synthesis does not appear to be required for progesterone metabolism since intrafollicular progesterone declined with prolonged culture even in the presence of cycloheximide. The nature of protein(s) involved in follicular progesterone production remains to be elucidated. FPH mediation of oocyte maturation within ovarian follicles appears to depend upon protein synthesis in somatic follicle cells, which is required for progesterone production, and in the oocyte, to mediate the response to the steroid trigger.     

Nitric oxide and nitric oxide-generating compounds inhibit hepatocyte protein synthesis.

Hepatocytes are stimulated to produce nitric oxide (NO.) from L-arginine in response to conditioned Kupffer cell medium or a combination of cytokines. Associated with the production of NO.in hepatocytes, there is a profound decrease in total protein synthesis ([3H]leucine incorporation). This report demonstrates that authentic NO.and the NO.-generating compound S-nitroso-N-acetylpenicillamine inhibit hepatocyte total protein synthesis in a reversible and concentration-dependent fashion. In parallel with the suppression of hepatocyte total protein synthesis, authentic NO.inhibits the production of two specific hepatocyte proteins, albumin and fibrinogen, without influencing the quantity of albumin mRNA. Although authentic NO.induces a rapid increase in cGMP levels in hepatocytes, the addition of the cGMP analog 8-bromoguanosine 3':5' cyclic monophosphate to unstimulated HC cultures does not reproduce the inhibition of total protein synthesis. These data show that NO.is the hepatocyte L-arginine metabolite that inhibits protein synthesis. Furthermore, these findings indicate that NO.does not inhibit hepatocyte protein synthesis solely through the activation of soluble guanylate cyclase but appears to affect a translational or posttranslational process.     

Dependence of Ribonucleic Acid Synthesis on Continuous Protein Synthesis in Yeast

Using an auxotrophic strain of Saccharomyces cerevisiae, we examined the kinetics of ribonucleic acid (RNA) synthesis following inhibition of protein synthesis caused by amino acid starvation or cycloheximide. Removal of a required amino acid immediately stopped net protein synthesis. After a brief lag, RNA synthesis also ceased. Cycloheximide, a ribosome-inhibiting drug, also immediately halted net protein synthesis. Again RNA synthesis stopped after a brief lag. Although cycloheximide and amino acid starvation affect different steps in protein biosynthesis, both inhibited RNA synthesis in identical fashion. This indicates that amino acids do not play a unique role in the control of RNA production in rapidly growing yeast; rather, it suggests that RNA synthesis is responsive to the overall rate of protein synthesis itself.     

Interferon production in chick-embryo cells. The effect of puromycin and p-fluorophenylalanine

1. When chick-embryo cells were treated with ultraviolet-inactivated influenza virus (Melbourne strain), interferon was produced after a lag period of about 10hr. 2. The addition of small amounts of either puromycin or p-fluorophenylalanine immediately after the virus inhibited the subsequent production of interferon. Both inhibitors primarily affected protein synthesis, and it is concluded that interferon production involves new protein synthesis. 3. Results obtained by the addition of either inhibitor for short periods during the lag phase demonstrated a requirement for protein synthesis during the second half of the lag phase. 4. Addition of puromycin during the course of interferon production caused almost immediate inhibition, but interferon formation became insusceptible to the action of p-fluorophenylalanine at about 26hr. after infection. Possible explanations of this effect are discussed.     

Requirement of de novo synthesis of the OdhI protein in penicillin-induced glutamate production by Corynebacterium glutamicum

We found that penicillin-induced glutamate production by Corynebacterium glutamicum is inhibited when a de novo protein synthesis inhibitor, chloramphenicol, is added simultaneously with penicillin. When chloramphenicol was added 4 h after penicillin addition, glutamate production was essentially unaffected. ³H-Leucine incorporation experiments revealed that protein synthesis continued for 1 h after penicillin addition and then gradually decreased. These results suggest that de novo protein synthesis within 4 h of penicillin treatment is required for the induction of glutamate production. To identify the protein(s) necessary for penicillin-induced glutamate production, proteome analysis of penicillin-treated C. glutamicum cells was performed with two-dimensional gel electrophoresis. Of more than 500 proteins detected, the amount of 13 proteins, including OdhI (an inhibitory protein for 2-oxoglutarate dehydrogenase complex), significantly increased upon penicillin treatment. Artificial overexpression of the odhI gene resulted in the decreased specific activity of the 2-oxoglutarate dehydrogenase complex and increased glutamate production without any triggers. These results suggest that the de novo synthesis of OdhI is the necessary factor for penicillin-induced glutamate overproduction by C. glutamicum. Moreover, continuous glutamate production was achieved by overexpression of odhI without any triggers. Thus, the odhI-overexpressing strain of C. glutamicum can be useful for efficient glutamate production.     

Engineering Chinese hamster ovary (CHO) cells to achieve an inverse growth – associated production of a foreign protein, β-galactosidase

Protein synthesis in mammalian cells can be observed in two strikingly different patterns: 1) production of monoclonal antibodies in hybridoma cultures is typically inverse growth associated and 2) production of most therapeutic glycoproteins in recombinant mammalian cell cultures is found to be growth associated. Production of monoclonal antibodies has been easily maximized by culturing hybridoma cells at very low growth rates in high cell density fed- batch or perfusion bioreactors. Applying the same bioreactor techniques to recombinant mammalian cell cultures results in drastically reduced production rates due to their growth associated production kinetics. Optimization of such growth associated production requires high cell growth conditions, such as in repeated batch cultures or chemostat cultures with attendant excess biomass synthesis. Our recent research has demonstrated that this growth associated production in recombinant Chinese hamster ovary (CHO) cells is related to the S (DNA synthesis)-phase specific production due to the SV40 early promoter commonly used for driving the foreign gene expression. Using the stably transfected CHO cell lines synthesizing an intracellular reporter protein under the control of SV40 early promoter, we have recently demonstrated in batch and continuous cultures that the product synthesis is growth associated. We have now replaced this S-phase specific promoter in new expression vectors with the adenovirus major late promoter which was found to be active primarily in the G1-phase and is expected to yield the desirable inverse growth associated production behavior. Our results in repeated batch cultures show that the protein synthesis kinetics in this resulting CHO cell line is indeed inverse growth associated. Results from continuous and high cell density perfusion culture experiments also indicate a strong inverse growth associated protein synthesis. The bioreactor optimization with this desirable inverse growth associated production behavior would be much simpler than bioreactor operation for cells with growth associated production. This revised version was published online in August 2006 with corrections to the Cover Date.     

Cell-free synthesis of 15N-labeled proteins for NMR studies

Modern cell-free in vitro protein synthesis systems present powerful tools for the synthesis of isotope-labeled proteins in high yields. The production of selectively 15 N-labeled proteins from 15 N-labeled amino acids is particularly economic and yields are often sufficient to analyze the proteins very quickly by two-dimensional NMR spectra recorded of the crude reaction mixture without concentration or chromatographic purification of the protein. We review methodological aspects of cell-free in vitro protein synthesis based on an Escherichia coli cell extract, in particular with regard to the production of 15 N-labeled proteins for analysis by NMR spectroscopy.     

Preparation of Escherichia coli cell extract for highly productive cell-free protein expression

As structural genomics and proteomics research has become popular, the importance of cell-free protein synthesis systems has been realized for high-throughput expression. Our group has established a high-throughput pipeline for protein sample preparation for structural genomics and proteomics by using cell-free protein synthesis. Among the many procedures for cell-free protein synthesis, the preparation of the cell extract is a crucial step to establish a highly efficient and reproducible workflow. In this article, we describe a detailed protocol for E. coli cell extract preparation for cell-free protein synthesis, which we have developed and routinely use. The cell extract prepared according to this protocol is used for many of our cell-free synthesis applications, including high-throughput protein expression using PCR-amplified templates and large-scale protein production for structure determinations.