Regulation of Protein Synthesis in Chick Oviduct

Translation attenuation via 3' terminal codon usage in bovine csn1s2 is responsible for the difference in αs2- and β-casein profile in milk

The rate of secretion of αs2-casein into bovine milk is approximately 25% of that of β-casein, yet mammary expression of their respective mRNA transcripts (csn1s2 and csn2) is not different. Our objective was to identify molecular mechanisms that explain the difference in translation efficiency between csn1s2 and csn2. Cell-free translational efficiency of csn2 was 5 times that of csn1s2. Transcripts of csn1s2 distributed into heavier polysomes than csn2 transcripts, indicating an attenuation of elongation and/or termination. Stimulatory and inhibitory effects of the 5' and 3' UTRs on translational efficiency were different with luciferase and casein sequences in the coding regions. Substituting the 5' and 3' UTRs from csn2 into csn1s2 did not improve csn1s2 translation, implicating the coding region itself in the translation difference. Deletion of a 28-codon fragment from the 3' terminus of the csn1s2 coding region, which displays codons with low correlations to cell fitness, increased translation to a par with csn2. We conclude that the usage of the last 28 codons of csn1s2 is the main regulatory element that attenuates its expression and is responsible for the differential translational expression of csn1s2 and csn2.

CPEB2-eEF2 interaction impedes HIF-1α RNA translation

Translation of mRNA into protein proceeds in three phases: initiation, elongation, and termination. Regulated translation allows the prompt production of selective proteins in response to physiological needs and is often controlled by sequence-specific RNA-binding proteins that function at initiation. Whether the elongation phase of translation can be modulated individually by trans-acting factors to synthesize polypeptides at variable rates remains to be determined. Here, we demonstrate that the RNA-binding protein, cytoplasmic polyadenylation element binding protein (CPEB)2, interacts with the elongation factor, eEF2, to reduce eEF2/ribosome-triggered GTP hydrolysis in vitro and slow down peptide elongation of CPEB2-bound RNA in vivo. The interaction of CPEB2 with eEF2 downregulates HIF-1α RNA translation under normoxic conditions; however, when cells encounter oxidative stress, CPEB2 dissociates from HIF-1α RNA, leading to rapid synthesis of HIF-1α for hypoxic adaptation. This study delineates the molecular mechanism of CPEB2-repressed translation and presents a unique model for controlling transcript-selective translation at elongation.

Protein elongation rates in tissues of growing and adult sheep

To identify the relative roles of translation initiation and elongation in the long term control of protein synthesis in ovine tissues, fractional synthesis rates (FSR) and ribosomal transit times (RTT) were measured in vivo in 24 ewe lambs at 3 levels of intake [maintenance (M), 1.5M, and 2M] and 8 mature ewes at 2M intake. After 17 to 25 d on treatment, animals were given an i.v. flooding dose of l-[ring-2,6-(3)H]phenylalanine and tissues were collected for analysis of radioactivity in free protein, total protein, and nascent ribosome-associated proteins. Ribosome transit time (the inverse of elongation rate) averaged 83, 393, 183, 241, 85, and 113 s for liver, duodenum, skin, rumen, semimembranosus, and LM, respectively. In response to an increased level of intake, protein FSR increased (P < 0.01) in all tissues except rumen and was attributed to greater translational efficiency. There was no effect (P > 0.50) of intake on RTT in these tissues, and the estimated proportion of ribosomes attached to and actively translating mRNA was increased (P < 0.07), indicating that an upregulation of initiation was responsible for the greater FSR. Mature ewes exhibited lower (P < 0.10) protein FSR in all tissues compared with lambs, which was related to a decline in the RNA:protein ratio in all tissues except for liver and duodenum. In all tissues but liver and semimembranosus, RTT increased (P < 0.10) with age. The lower elongation rate was not considered to have influenced the protein synthetic rate, but it caused an increase in the proportion of ribosomes actively translating mRNA. It is anticipated that this work will provide direction to future studies of the molecular mechanisms of chronic FSR control.

Visualization of mRNA translation in living cells

The role of mRNA localization is presumably to effect cell asymmetry by synthesizing proteins in specific cellular compartments. However, protein synthesis has never been directly demonstrated at the sites of mRNA localization. To address this, we developed a live cell method for imaging translation of β-actin mRNA. Constructs coding for β-actin, containing tetracysteine motifs, were transfected into C2C12 cells, and sites of nascent polypeptide chains were detected using the biarsenial dyes FlAsH and ReAsH, a technique we call translation site imaging. These sites colocalized with β-actin mRNA at the leading edge of motile myoblasts, confirming that they were translating. β-Actin mRNA lacking the sequence (zipcode) that localizes the mRNA to the cell periphery, eliminated the translation there. A pulse-chase experiment on living cells showed that the recently synthesized protein correlated spatially with the sites of its translation. Additionally, localization of β-actin mRNA and translation activity was enhanced at cell contacts and facilitated the formation of intercellular junctions.

Studies on the posttranscriptional site of cAMP action in the regulation of the synthesis of tyrosine aminotransferase

Synthesis of L-tyrosine:2-oxoglutarate aminotransferase (EC 2.6.1.5) can be induced by N6,O2'-dibutyryl-adenosine 3',5'-monophosphate (Bt2cAMP) in Reuber H35 cell cultures. Actinomycin D fails to block this induction which indicates a target for Bt2cAMP at a posttranscriptional level. We have determined the influence of Bt2cAMP on several translational events during the tyrosine aminotransferase synthesis with the following results. (1) The number of nascent tyrosine aminotransferase chains increased, whereas no effect was measured on the number of nascent total protein chains. (2) The rate of elongation along the tyrosine aminotransferase mRNA and total mRNA is not enhanced by Bt2cAMP. (3) The induced synthesis of tyrosine aminotransferase is more sensitive to the inhibition of elongation. We conclude from our results that Bt2cAMP induces the synthesis of tyrosine aminotransferase by an increase in the rate of initiation on the tyrosine aminotransferase mRNA.

Sepsis-induced changes in protein synthesis: differential effects on fast- and slow-twitch muscles

Sepsis is associated with severe muscle wasting. Mechanisms responsible for sepsis-induced alterations in muscle protein metabolism were investigated in vivo and compared with changes induced by nonseptic inflammation. The rate of protein synthesis in mixed hindlimb muscles was not altered in inflammation but was inhibited 50% in sepsis. This inhibition did not result from a decreased RNA content. Instead, the translational efficiency was significantly reduced by 50% in skeletal muscle of septic animals compared with control. The effect of sepsis to lower the rate of protein synthesis was further examined using individual muscles containing different fiber types. Both the protein concentration and protein synthetic rate in fast-twitch muscles were reduced by sepsis, whereas neither of these parameters was affected in slow-twitch muscles or heart. The decreased translational efficiency did not result from a change in the rate of peptide-chain elongation. Instead, the sepsis-induced inhibition of protein synthesis resulted from a restraint in peptide-chain initiation because sepsis caused a 1.6-fold increase in free ribosomal subunits. Overall, sepsis, but not inflammation, caused an inhibition of protein synthesis primarily in muscles composed of fast-twitch fibers. The mechanism involved in the reduced rates of protein synthesis in muscles resulted from an inhibition of peptide-chain initiation, with no change in peptide-chain elongation.

Regulation of hepatic protein synthesis in chronic inflammation and sepsis

The regulation of protein synthesis was determined in livers from control, sterile inflammatory, and septic animals. Total liver protein was increased in both sterile inflammation and sepsis. The rate of protein synthesis in vivo was measured by the incorporation of [3H]phenylalanine into liver proteins in a chronic (5 day) intra-abdominal abscess model. Both sterile inflammation and sepsis increased total hepatic protein synthesis approximately twofold. Perfused liver studies demonstrated that the increased protein synthesis rate in vivo resulted from a stimulation in the synthesis of both secreted and nonsecreted proteins. The total hepatic RNA content was increased 40% only in sterile inflammation, whereas the translational efficiency was increased twofold only in sepsis. The increase in translational efficiency was accompanied by decreases in the amount of free 40S and 60S ribosomal subunits in sepsis. Rates of peptide-chain elongation in vivo were increased 40% in both sterile inflammation and sepsis. These results demonstrate that sepsis induces changes in the regulation of hepatic protein synthesis that are independent of the general inflammatory response. In sterile inflammation, the increase in protein synthesis occurs by a combination of increased capacity and translational efficiency, while in sepsis, the mechanism responsible for accelerated protein synthesis is an increased translational efficiency.

Elongation factor-2 in chick embryo is phosphorylated on tyrosine as well as serine and threonine

An endogenous 95 kDa chick embryo cytosolic protein (p95) was phosphorylated in the presence of [gamma-32P]ATP and the kinase activity for p95 was mostly associated with particulate fraction. Phosphorylation of p95 was prominent in embryos of early developmental stage. Hydrolysis of p95 phosphoprotein yielded phosphotyrosine in addition to phosphothreonine and phosphoserine. Native p95 was also tyrosine-phosphorylated. p95 phosphoprotein was purified by DEAE-Sephacel chromatography and immunoprecipitation with anti-phosphotyrosine antibody and the amino acid sequence was determined. The N-terminal sequence, Val-Asn-Phe-Thr-Val-Asp-Gln-Ile-Arg-Ala-Ile-Met-Asp- Lys-Lys-Ala-Asn-Ile-Arg-Asn-Met-, was found to be identical to those of elongation factor-2 (EF-2) of both rat and hamster. Our results suggest the presence of other EF-2 kinase in chick embryo cell than the previously reported Ca2+/calmodulin-dependent protein kinase III.

Characterization of the translational defect to fiber synthesis in monkey cells abortively infected with human adenovirus: role of ancillary leaders

Synthesis of the fiber protein of human adenovirus serotype 2 (Ad2) is 100-fold lower in abortively infected monkey cells, compared with productive infections, despite only a 5- to 10-fold reduction in fiber mRNA levels. Previously Anderson and Klessig (Proc. Natl. Acad Sci. USA 81:4023-4027, 1984) demonstrated a direct correlation between the productive nature of the infection, efficient synthesis of the fiber protein in vivo, and the presence of the x or y ancillary leaders on 10 to 25% of fiber messages. To determine at what level in translation these leaders might be important, the relative rate of initiation and elongation of each class of fiber message was assessed. The presence of the y ancillary leader in productively infected cells increased the rate of initiation about twofold, although translational elongation was similar on all fiber messages. However, the rate of elongation of all fiber messages was threefold slower in abortively infected than in productively infected cells. This reduced elongation rate in abortive infections was specific for fiber. The similar distribution of fiber mRNAs on polysomes in both infections suggests that initiation must also be partially blocked in abortive infections. Since the majority of the fiber mRNA even in productive infections did not contain the ancillary leaders, the initiation and elongation defects in the abortive infection cannot be fully explained by the absence of these leaders. Therefore, other factors in the infected cell must be influencing the rate of translation.

Estradiol regulation of reactions involved in turnover of the amino acid acceptor terminus of tRNA in the rat uterus

Estradiol (E2) increases the specific amino acid acceptor activity of rat uterine tRNAs by increasing the proportion of certain tRNAs with intact and functional 3'-CCA acceptor termini. Activities of tRNA nucleotidyltransferase and 3'-exoribonuclease which synthesize and degrade this terminus, respectively, were measured and neither enzyme was modified by hormone treatment. Since cytidine triphosphate (CTP) levels are below reported Km values for nucleotidyltransferase, changes in CTP concentrations may regulate nucleotidyltransferase activity. An E2-induced 3-fold increase was seen in CTP synthetase activity (conversion of uridine triphosphate, UTP, into CTP). Uterine CTP levels in controls are minute (9 nmol/uterus, approx. 90 microM), and are increased 2.5-fold in E2(12 h)-treated rats. The rate of incorporation of [3H]UTP into the 3'-CCA terminus of tRNA was measured as coupled CTP synthetase-nucleotidyltransferase reactions and a 2.5-fold increase in incorporation occurred 8-12 h after E2 treatment. Injection of azaserine, (inhibitor of CTP synthetase) reduced E2-induced increases in CTP levels, CTP synthetase activity, and leucine acceptor activity of tRNAs. These results indicate that E2 regulates CTP levels by modulation of CTP synthetase activity, and that regulation of synthesis and/or repair of the 3'-CCA terminus of tRNA is proportional to E2-induced uterine cytosolic CTP levels.

Positive and negative regulatory elements control the steroid-responsive ovalbumin promoter

Steroid hormones regulate the transcriptional activity of the chicken ovalbumin gene both in vivo and in cell culture. To identify the regulatory elements involved, primary oviduct cell cultures were transfected with constructs containing the promoter and 5'-flanking region of the ovalbumin gene fused to the bacterial chloramphenicol acetyltransferase (CAT) gene. Induction of the OvCAT genes by estrogen, progesterone, or corticosterone mimics that of the endogenous ovalbumin gene, indicating that the transfected DNA is accurately regulated. Deletion analysis revealed that a steroid response element (SRE) resides between nucleotide coordinates -880 and -585 and that a negative regulatory element (NRE) resides between -350 and -248 in the ovalbumin gene. Thus, an NRE represses expression of the ovalbumin gene unless steroid hormones relieve this negative control through interactions involving a more distal SRE. Neither the SRE nor the NRE alone regulates the heterologous thymidine kinase promoter, suggesting either that they function as a single entity or that they are conditional regulatory elements. The NRE is functional in MCF-7 cells, but the SRE cannot be activated by steroids in this heterologous estrogen-responsive cell line. These data indicate that the steroid-receptor complex induces the ovalbumin gene through direct or indirect actions at an SRE to relieve represssion at an NRE.

Estradiol regulation of the synthesis of uterine proteins with clusters of proline- and glycine-rich peptide sequences

Estradiol (E2) regulates the synthesis of uterine proteins at both the transcriptional and translational levels. E2 induces an increase in the specific amino acid acceptor activity of uterine tRNA, with the largest increases seen for proline, glycine and methionine. The synthesis of three uterine proteins that are rich in proline and glycine, estrogen receptor, progesterone receptor and glucose-6-phosphate dehydrogenase, is induced by E2. E2-induced increases in these proteins were preceded by an correlated with stimulation of tRNA acceptor activity for proline and glycine and these responses were specifically and simultaneously inhibited by prior azaserine treatment, which inhibits the E2-induced repair and synthesis of the 3'-CCA acceptor terminus of tRNAs. The high frequency and clustering of proline and glycine residues in estrogen receptor, progesterone receptor and glucose-6-phosphate dehydrogenase suggests that the translating ribosomes may slow down during synthesis of these proteins due to limiting levels of these tRNAs in E2-deprived uteri.

Apolipoprotein B: structure, biosynthesis and role in the lipoprotein assembly process

The complete amino acid sequence of the liver-synthesized apolipoprotein B (apoB) species, apoB 100, has been derived from cloned cDNA. The protein consists of 4536 amino acids (+ a 27 amino acid signal sequence). Cysteine is clustered in the N-terminal 1/10 of the protein, suggesting the presence of a stabilized tertiary structure in this part of the molecule. Three types of structure are suggested to be of importance for the binding of the protein to lipids; (i) hydrophobic sequences with a high probability for beta-sheet structure, (ii) strict amphipathic beta-sheets, and (iii) amphipathic alfa-helices. An apoB 100 molecule is completed within 10-14 min and secreted after approximately 30 min, 1/3 of which is due to the transfer through the endoplasmic reticulum (ER), while 2/3 is spent in the Golgi apparatus. ApoB 100 is co-translationally N-glycosylated and 25% of the oligosaccharide chains is processed in the Golgi compartment. Other posttranslational modifications that have been discussed include covalent acylation and phosphorylation. It has also been suggested that the lipid moiety of the apoB 100 lipoproteins are modified during the passage through the Golgi apparatus. The site of lipoprotein assembly is suggested to be separated from the site of apoB 100 synthesis, and apoB 100 appears to be co-translationally bound to the ER membrane and from this transferred to the ER lumen. Based on these observations a model for the assembly of apoB 100 lipoproteins is discussed in this paper. The intestinal derived apoB species, apoB 48, has a molecular mass of 210 kDa and appears to correspond to the N-terminal 48% of apoB 100. The mechanism by which apoB 48 is formed is still not known. Available data indicate that the protein is formed within the intestinal cells, these data also argue against the possibility that apoB 48 is formed by posttranslational proteolysis of apoB 100. The formation of a separate apoB 48 mRNA by alternative splicing has been suggested, based on the observation of a 7 kb mRNA which corresponds to the 5' portion of the apoB 100 mRNA. However, the most abundant apoB mRNA species found in the intestine have a size that corresponds to that of the apoB 100 mRNA, furthermore the observation that apoB 48 appears to terminate in a 7.5 kb exon that appears to lack alternative splice sites, does not favour the possibility of alternative splicing.

Peritubular cells influence Sertoli cells at the level of translation

Conditioned medium from cultured peritubular cells (PTCM) was capable of increasing the incorporation of amino acids into acid-precipitable material in cultured Sertoli cells, while the incorporation of uridine into acid-precipitable material was unaffected. PTCM did not influence intracellular cAMP accumulation in a manner similar to follicle-stimulating hormone (FSH). PTCM was able to stimulate androgen-binding protein (ABP) secretion by Sertoli cells even in the presence of a maximal dose of FSH. PTCM increased the rate at which peptides are elongated 5-fold over control medium or medium from control fibroblasts. These studies indicate that peritubular cells influence Sertoli cells through different mechanisms than FSH and exert their influence, at least in part, at the level of translation by increasing the rate of peptide elongation.

Estrogen modulation of retinol-binding protein in immature chicks: comparison with riboflavin carrier protein

The kinetics of estrogen (E) modulation of retinol-binding protein (RBP) production in the liver of immature chicks were compared with those governing de novo induction of riboflavin carrier protein (RCP) in the same tissue. A single dose of E markedly enhanced the plasma levels of RBP without any detectable lag period to reach peak value by 24 h and this was followed by a decline to attain the baseline by 4 days. There was no amplification of the response during secondary stimulation unlike the case with RCP induction. With multiple E administration, the 4-fold increased plasma RBP concentrations were sustained at a steady state during both primary and secondary stimulations, whereas concomitant RCP concentration progressively increased with each hormone administration and this response was further amplified during secondary stimulation. Unlike RCP induction, enhanced RBP accumulation was not strictly E dose dependent although a minimal threshold level of the steroid was required to elicit measurable response. Progesterone (P) could neither modulate nor substitute for E in enhancing plasma levels of either of the 2 proteins while the anti-estrogens, en- and zuclomifene citrate severely suppressed the production of both the proteins. RCP induction was completely inhibited by both alpha-amanitin and cycloheximide for prolonged periods while E-stimulated RBP production was affected only partially by alpha-amanitin. Likewise, cycloheximide inhibition of RBP accumulation followed a pattern similar to that of hepatic general protein synthesis.

Evidence for a dissimilarity of chicken oviducts differentiated by diethylstilboestrol and oestradiol-17 beta: a study of progesterone-induced egg-white protein (avidin) synthesis

The growth and differentiation of chick oviducts were caused by daily diethylstilboestrol (DES) or oestradiol-17 beta (E2) injections, and the effects of these oestrogens on the progesterone-induced production of a biotin-binding egg-white protein (avidin) were studied. In the DES primed oviducts, but not in the E2 primed ones, both DES and E2 administered with progesterone potentiated avidin production 2 to 3-fold, even after 10-day oestrogen withdrawal. The results suggest that DES and E2 prime the avian reproductive target tissue differently.

Changes in the rate of translation with reactivation of delayed implanting mouse embryos

The transient embryonic diapause associated with delayed implantation in mice is characterized by decreases in the rates of synthesis of RNA and protein as well as a cessation of development. The present experiments were undertaken to examine the possibility that controls on protein synthesis at the level of translation of mRNA provide a regulatory mechanism in this situation. Rates of peptide chain elongation were determined in dormant embryos as well as in embryos that were reactivated either in vivo by estradiol-17 beta or by incubation in vitro. In dormant embryos the rate of peptide elongation was found to be approximately half that in active embryos. Although this change in translational efficiency appears to be sufficient to account for previously observed differences in overall rates of protein synthesis in dormant and reactivated embryos, the possibility that some changes also occur at the level of transcription during reactivation is not ruled out.

Insulin-stimulated protein synthesis in adipocytes. Enhanced rate of initiation associated with increased phosphorylation of ribosomal protein S6

The mechanisms of insulin stimulation of protein synthesis in adipocytes are presently unknown. Addition of 10 nM insulin to isolated rat adipocytes caused a 1.5-2.5-fold increase in the protein synthetic rate and a corresponding increase in nascent chain level, indicating that the effect of insulin on protein synthesis in adipocytes is mediated by a stimulation of ribosomal initiation. The effect on protein synthesis exhibited a lag time of 6-8 min after insulin addition. A similar time dependence was also observed for the insulin-induced phosphorylation of ribosomal protein S6. This supports the proposal that these two phenomena are causally linked.

Pulse-chase studies of the synthesis of apolipoprotein B in a human hepatoma cell line, Hep G2

We have used pulse-chase methodology to study the synthesis of apolipoprotein B in a human hepatoma-derived cell line, the Hep G2 cells. A 2-min pulse with [35S]methionine was followed by a chase period varying from 5-90 min. A protein of large molecular mass (estimated molecular mass: 312 +/- 41 kDa, mean +/- SD, n = 8) could be immunoprecipitated from the cells at all chase periods between 5 min and 60 min with both monoclonal antibodies to a narrow density cut of the low density lipoprotein LDL-2 (density: 1.030-1.055 g/ml) and polyclonal antibodies to the apolipoprotein B apo B 100 or to a narrow density cut of LDL-2 (density: 1.030-1.055 g/ml). In addition to this large molecular mass protein, nascent polypeptides could be precipitated after 5, 10 and 15 min of chase. The apolipoprotein B molecules that had been labelled during the pulse disappeared from the cells after 60-90 min of chase, while they started to appear in the medium after 30-35 min of chase. The results obtained indicate (a) that apolipoprotein B is synthesized as one polypeptide with a large molecular mass, (b) that newly synthesized apolipoprotein B molecules are secreted after a delay of 30-35 min, (c) that no intracellular accumulation of apolipoprotein B occurs, and (d) that apolipoprotein B is recovered in the density fraction less than 1.21 g/ml of the medium suggesting that it is secreted in lipoprotein form.

Inhibition of the aminoacylation of selected tRNA molecules by an estrogen-regulated factor on uterine ribosomes. Regulation of aminoacylation of tRNA by estrogens

Administration of estradiol to ovariectomized mature rats for 1 h induces a transient increase in the peptide elongation rate on uterine ribosomes. An inhibitor of the peptide elongation rate, which appears to be regulated by estrogen treatment in vivo, can be extracted from ribosomes of estrogen-deprived rats. The extracted inhibitor or a native inhibitor-ribosome complex affects the rate of the peptide elongation reaction in a uterine cell-free protein synthesis system by inhibiting the ability of selected tRNAs in the assay to be charged with amino acids by their respective aminoacyl-tRNA synthetases. The degree of inhibition of charging of the affected tRNAs ranges from 22% to 78%, the order of inhibition being Pro greater than Val greater than Arg greater than Try greater than Leu greater than Glu greater than Ile greater than Gly greater than His greater than Ser greater than Lys. Inhibition results from a specific dose-dependent, and presumably reversible, effect of the inhibitor on tRNA, but not on the aminoacyl-tRNA synthetase. The effect does not result from removal of A-C-C terminal nucleotides from the 3' end of tRNA, but does inhibit the ability of selected tRNAs to bind to the aminoacyl-tRNA synthetases. We propose that regulation of the peptide elongation rate on uterine ribosomes by estradiol occurs through the estradiol-induced inactivation of a ribosome-associated inhibitor, which causes a reversible alteration to selected tRNAs. The modified tRNAs are unable to bind to their respective aminoacyl-tRNA synthetase to become charged with an amino acid thus causing the availability of selected aminoacyl-tRNAs to become rate-limiting in the sequential elongation of peptides.

Differential inhibition of protein synthesis: a possible biochemical mechanism of thalidomide teratogenesis

A theory concerning the chemical and biochemical mechanisms of thalidomide teratogenesis is presented. A considerable body of evidence suggests that the glutarimide ring of thalidomide may exert its biological activity because of its resemblance to the imide pyrimidines thymine and uracil. In addition to the glutarimide ring, thalidomide contains a moderately reactive phthalimide moiety, which allows the spontaneous formation of various glutarimide derivatives in fetal tissues. A model is proposed in which the phthalimide group reacts with small nucleophiles, most likely the polyamines, to produce a derivative(s) having a similar biochemical potential to that of cycloheximide, a glutarimide which is a powerful inhibitor of the elongation phase of protein synthesis. Interference in the elongation phase results in the selective inhibition of the translation of messages which have a high translational efficiency. Evidence is reviewed concerning the differential inhibition or protein synthesis by cycloheximide and the effects of this inhibition on various biochemical and biological processes which are critical during development and differentiation. A similar biochemical activity by the putative thalidomide derivative(s) could explain its extreme teratogenic potential. A number of parallels between the biological effects of thalidomide and cycloheximide are discussed which support the idea that a similar biochemical activity is involved. The theory readily explains many of the observed biological effects of thalidomide including the large difference between fetal and adult toxicity. In addition, evidence is reviewed which suggests that the teratogenic properties of a number of drugs which are structurally related to thalidomide may have a common chemical basis due to the similarity of their imide core structures to thymine and uracil.

Adenovirus VAI RNA facilitates the initiation of translation in virus-infected cells

The adenovirus VAI RNA is a small polymerase III-transcribed species that is required for optimal translation of mRNAs late after infection. Mutant dl331 fails to produce this RNA species and, as a result, grows poorly. Mutant-infected cells contain normal levels of late mRNAs, but reduced levels of polypeptides are synthesized late after infection. Translational elongation occurs at normal rates in mutant, as compared to wild-type, virus-infected cells. Initiation of translation occurs with reduced efficiency in dl331 -infected cells. VAI RNA is required for formation of a stable 48S preinitiation complex and very likely functions to facilitate the interaction between 43S preinitiation complex and mRNA to form the 48S species.

Kinetics for changes in enzyme synthesis and mRNA content and hormones required for induction of 6-phosphogluconate dehydrogenase in hepatocytes

Rats fasted for 2 days were refed a 60% glucose diet for varying periods of time in order to follow the kinetics for changes in 6-phosphogluconate dehydrogenase synthesis and mRNA content. Hepatocytes isolated from control or induced rats were incubated with actinomycin D and the rate of decline in 6-phosphogluconate dehydrogenase mRNA was determined by translating RNA in a nuclease-treated reticulocyte lysate. The half-life for 6-phosphogluconate dehydrogenase mRNA under both of these conditions was about 2 h. Thus, increases in transcription or the processing of nuclear RNA may increase 6-phosphogluconate dehydrogenase mRNA during the dietary induction of this enzyme. Hepatocytes prepared from fasted rats were cultured with 5% serum and various hormones and energy sources. If hepatocytes were isolated from thyroidectomized rats and cultured in serum from a thyroidectomized calf, the 4-fold induction of 6-phosphogluconate dehydrogenase was primarily dependent upon added insulin. In the presence of optimal insulin concentrations (10(-7) M) triiodothyronine slightly stimulated 6-phosphogluconate dehydrogenase induction. The gut hormones somatostatin and secretin had no effect on 6-phosphogluconate dehydrogenase induction in cultured hepatocytes. Hepatocytes cultured in carbohydrate-free medium and 5% serum required added insulin for maximal induction. 8-Br-cGMP did not significantly affect 6-phosphogluconate dehydrogenase induction in hepatocytes either in the presence or absence of added insulin. Dibutyryl cAMP did not alter the time course or extent of 6-phosphogluconate dehydrogenase induction in cultured hepatocytes. We have concluded that under these conditions insulin is a potent signal regulating the levels of 6-phosphogluconate dehydrogenase mRNA and that this induction is not mediated by cyclic nucleotides.

The regulation of macrophage protein turnover by a colony stimulating factor (CSF-1)

CSF-1 is a hemopoietic growth factor that specifically regulates the survival, proliferation, and differentiation of mononuclear phagocytic cells. A homogeneous population of mononuclear phagocytes, bone marrow derived macrophages (BMM), were used to study the regulation of protein turnover by CSF-1. Removal of CSF-1 (approximately 0.4 nM) from exponentially growing BMM cultured in 15% fetal calf serum containing medium decreases the rate of DNA synthesis by more than 100-fold. Addition of CSF-1 to these cells causes them to resume DNA synthesis within 12 h. More immediate effects of CSF-1 were observed on BMM protein metabolism. BMM cultured for 24 h in the absence of CSF-1 reduce their protein synthetic rate by 50-60%. The protein synthetic rate commences to decrease at 2-3 h after CSF-1 removal. Readdition of CSF-1 to BMM previously incubated in its absence causes a return to the protein synthetic rate of exponentially growing cells within 2 h. In the presence of CSF-1, BMM synthesize protein at a rate of approximately 8.7%/h and degrade it at a rate of approximately 0.9%/h. Removal of CSF-1 results in a decrease in the protein synthetic rate to approximately 3.4%/h and an increase in the rate of protein degradation to approximately 3.4%/h. The rate of protein synthesis by BMM increases linearly with CSF-1 concentration over the range of concentrations stimulating both survival and proliferation, while the rate of protein degradation decreases exponentially over the range of concentrations stimulating survival without proliferation. Therefore, it appears that the stimulation of the rate of protein synthesis and inhibition of the rate of protein degradation are two distinct effects of CSF-1, both part of the pleiotropic response to this growth factor. The inhibition of the rate of protein degradation by CSF-1 may be most significant for its survival inducing effect.

Estradiol-induced hepatic protein synthesis and transaminase activity in the male flounder, Platichthys flesus (L.)

A continued accumulation of vitellogenin was observed in the serum through 28 days after administration of spaced large doses of estradiol. The level of estradiol in the serum reached a maximum on Day 4, followed by a continued decrease until a basal concentration was reached at Day 15. The estradiol treatment increased the in vitro hepatic protein synthesis activity, measured as polyphenylalanine synthesis per unit cytoplasmic RNA, within 2-4 days reaching a maximum after 7 days. The effect was transitory and reduced to less than 50% within 15 days. After restimulation a second rise in protein synthesis activity was observed. The cellular content of bulk RNA i the liver showed a slow but steady accumulation through the 28 days. The specific activity of glutamate-oxaloacetate transaminase and glutamate-pyruvate transaminase in the liver decreased 35 and 20% relative to control, respectively, within 7 days after the first stimulation and again 14 days after restimulation. The concentration of serum protein showed a steady increase throughout the experimental period. The concentration of serum ninhydrine positive substances was lowered to 50% relative to the controls within the first 7 days after start of treatment with hormone.

Direct measurement of histone peptide elongation rate in cleaving sea urchin embryos

Regulation of protein synthesis can be exercised at a number of levels. One of the more experimentally difficult levels to approach has been the measurement of peptide elongation rate. This paper presents a new application of the cyanogen bromide (CNBr) cleavage of proteins in a direct measurement of histone peptide elongation rate in cleaving sea urchin embryos (Strongylocentrotus purpuratus). The data indicate an elongation rate (at 15 degrees C) for histones H2B and H1 alpha of 0.69 and 0.80 codons per s, respectively. These values fall within the range of previously published values of average peptide elongation rate for total protein in these cells. This method should be generally applicable to many systems for which the measurement of peptide elongation rate may provide a key to the understanding of the regulation of protein synthesis.

Variations in some molecular events during the early phases of the Reuber H35 hepatoma cell cycle. III. Role of protein synthesis in the initiation of DNA synthesis and the mechanism of stimulation of protein synthesis by serum

Induction of DNA synthesis by serum and amino acids has been investigated in cultured Reuber H35 hepatoma cells. Commitment of DNA synthesis was found to occur 6-8 hours before the actual start of this synthesis. The rate of initiation of DNA synthesis is proportional to the stimulation of protein synthesis by serum and/or amino acids. The increased protein synthesis is important for the proliferation only during the early period after serum addition. The withdrawal of serum and the inhibition by cycloheximide confirm this finding. Actinomycin D hardly influenced the early effect of serum on protein synthesis and it is concluded that the serum-stimulated protein synthesis is carried out on pre-existing mRNA's. The mechanism of stimulation of protein synthesis by serum has been studied by determination of the polyribosome size, the number of growing polypeptide chains, and the ribosomal transit time. The rate of the initiation of translation has been found to be specifically enhanced while the rate of elongation remained unchanged. Two-dimensional gel electrophoresis showed that the early stimulation of protein synthesis by serum involves all types of major cellular proteins, and no new proteins could be detected.

On the mechanism by which insulin stimulates protein synthesis in chick embryo fibroblasts

It has been known that insulin raises the rate of incorporation of [3H]leucine into the total protein of hormone-deficient chick embryo fibroblasts by approximately 1.5-fold. The elevation is not dependent upon the production of new messenger ribonucleic acids (mRNAs). Evidence is now presented in support of the following points: the greater labelling is due to more rapid polypeptide synthesis, not to an increase in the specific activity of leucyl-tRNA; the enhanced synthesis derives largely or entirely from a speeding up of the process of initiation, rather than that of elongation or termination; and the 1.5-fold stimulation is due to the elevated rates of formation of at least many of the fibroblast proteins. The hormone was shown before to stimulate posttranscriptionally and highly preferentially for formation of ribosomal proteins in the resting chick embryo cells. The question has been asked here whether insulin increases the production of total cell ribosomal protein by chemically altering preformed mRNAs. Results obtained by translating messages from deprived and hormone-treated cells in wheat germ and reticulocyte preparations do not support a mechanism involving covalent modification of preformed mRNAs. The observations, coupled with those previously made with inhibitors of translation, lead us to suggest that insulin stimulates protein synthesis in the resting chick embryo cells by activating limiting components of the initiation system. The effects of the hormone are greatest with messages, such as those for the ribosomal proteins, that have low affinities for the limiting initiation components.

Estradiol-induced vitellogenin synthesis in duck liver

We have studied the induction of vitellogenin by estradiol in duck liver. From the accumulation of vitellogenin in blood plasma we calculated that the rate of vitellogenin synthesis increases linearly with time for about 4 days after estradiol administration. Vitellogenin from chicken and duck cross-react immunologically and their mRNAs show only 7% sequence divergence. We could therefore determine vitellogenin mRNA content of duck liver using chicken vitellogenin cDNA as a hybridization probe. The number of vitellogenin mRNA molecules per hepatocyte increases from less than one in normal duck liver to 18 000 at 4 days after estradiol injection. The rate of vitellogenin synthesis in vivo is roughly proportional to vitellogenin mRNA content, although the data suggest a somewhat enhanced translation of vitellogenin mRNA at later times after hormone administration. Vitellogenin mRNA levels had returned to control values after 4 weeks after hormone administration. In the first 11 h after secondary administration of hormone vitellogenin mRNA accumulates at an only slightly higher rate than is observed after primary hormonal stimulation.

Does quantitative tRNA adaptation to codon content in mRNA optimize the ribosomal translation efficiency? Proposal for a translation system model

Neither a dynamic nor an energetic approach of the translation process has taken into account that intracellular levels of iso-tRNA species are adapted or adjusted to the codon frequency of mRNA being decoded (Bombyx mori silk gland, rabbit reticulocyte). A critical study of available experimental data suggests that the average elongation rate of a protein is maximized in the presence of an adapted tRNA population, usually an homologous tRNA. In addition, the amount of synthesized protein parallels that of corresponding mRNA. Other evidences--including in vitro and in vivo elongation assays with fibroin mRNA--show that individual elongation rates are not uniform. Pauses occur at certain sites of the mRNA chain. The relative lifetime of these pauses depends on the tRNA pool used. Finally, it appears that translation accuracy also depends on the balanced tRNA population. We propose to explain these different effects by using a codon-anticodon recognition model, called "trial and error system" based on a stochastic processing of the ribosome. Accordingly, various acylated tRNA species which surround a ribosome randomly encounter the receptor A site. Every trapped tRNA species is tested for a proper pairing with the codon to be recognized at the level of a comparator or discriminator function. If the pairing is correct, transpeptidation becomes irreversible. If not, the aminoacyl-tRNA is rejected and another randomly trapped tRNA is processed in turn. Mathematical analysis of this model shows that the mean number of trials used for translating the whole sequence of a mRNA is minimized when the proportion of different iso-tRNA species is correlated with the square root of codon frequency. Quantitations of reticulocyte tRNA support such a parabolic relation. Our translation system model brings some light into the role of tRNA adaptation for optimizing translation efficiency, i.e. maximizing both speed and accuracy. Some consequences of the model are discussed.

A critical period of ecdysterone action on sensitive clones of Drosophila cultured in vitro: the maturation of the cells

Ecdysterone-sensitive clones cultured in vitro were isolated from established cell lines of Drosophila melanogaster. The clones FC and 89K are ecdysterone-inducible for two enzymatic activities: acetylcholinesterase and beta-galactosidase. No activity could be detected in untreated cells, whereas after treatment with 50-250 nM ecdysterone, the activity appeared after one day and increased during 3-4 days. We wanted to modulate the response of the cells by varying the conditions of the hormonal stimulus. Mimicking the physiological situation of Drosophila (the ecdysterone peak corresponding to the molts is preceded by low levels) we pretreated the cells with a subthreshold concentration (1-5 nM) for 2 days and then we added the stimulating concentration of 50-250 nM ecdysterone. The enzymatic activities were then detectable within the following hours and the final level of induction was about twice the one of cells without pretreatment. Thus, the continuous presence of a subthreshold concentration of ecdysterone provokes the maturation of the cells which become able to respond to the hormonal stimulus by a quicker and higher enzymatic induction. The cellular maturation seems to be a critical period. It is altosid-sensitive. Altosid (a juvenile hormone analog) abolishes the effects of the ecdysterone-induced maturation.

Induction of plasma proangiotensin by steroid hormones in nephrectomized rats

The response of plasma proangiotensin to various steroids was studied in bilaterally nephrectomized rats. In male animals, estradiol and testosterone increased the proangiotensin level up to 250% and 180% respectively. In female animals, both hormones lead to an increase of proangiotensin up to 220% of the controls, when given at optimal dose. The dose dependence on estradiol and testosterone was about the same in male rats, whereas in female animals the formation of proangiotensin was stimulated by much lower doses of estradiol as compared to testosterone. Adrenalectomy plus nephrectomy reduced the proangiotensin level to 20-30% of the value measured in animals nephrectomized only. Cortisol caused a rapid increase of plasma proangiotensin up to 1000% in adrenalectomized animals. Independent from the adrenal state, the amounts of cortisol necessary to induce proangiotensin were very low as compared to the dose response of other proteins, biosynthesis of which is regulated by cortisol. 21-Dehydrocortisol and aldosterone induced proangiotensin with the same efficiency as cortisol, whereas several other chemically related steroids were less active or inactive. Comparing the biological activity of the various steroids tested, it has to be concluded that the delta 4-ene-3-one structure of ring A, the 11 beta-OH group of ring C and the carbonyl group at C-20 of the ketol side-chain of cortisol are very important with respect to proangiotensin induction. The response of proangiotensin to cortisol, 21-dehydrocortisol and aldosterone could be inhibited by actinomocin D and cycloheximide, whereas the effects of estradiol and testosterone could be reversed by cycloheximide only.

Evidence for control of protein synthesis in HeLa cells via the elongation rate

The effects of fresh medium and serum on protein synthesis in suspension-cultured HeLa cells after growth to high cell density (> 5 x 10(5) cells/ml) were studied. Cells which were resuspended in fresh medium plus serum and grown for 24 hours (control) were compared with cells grown for 2 hours after resuspension (stimulated). The spectrum of proteins being synthesized by control and stimulated cells does not appear to be grossly different; that is, the weight and number average molecular weights of newly synthesized whole-cell protein are about the same in both cultures. Also, no significant differences were observed in the number of ribosomes per polysome or in the fraction of total ribosomes in polysomes. However, the transit times (combined elongation and termination times) were found to differ significantly; the average transit time for control cells was 2.24 minutes, while the average transit time for stimulated cells was 1.26 minutes. (An appendex evaluating the methodology involved in measuring the transit time is included.) In aggreement with the difference in transit time, the absolute rate of protein synthesis in stimulated cells was approximately 1.8 times the rate measured in control cells. These data are taken as evidence that under certain conditions, the rate of elongation and/or termination of polypeptide chains limits the overall rate of translation, and that cells can respond to growth conditions by changing the elongation and/or termination rate of protein synthesis.

Initiation of endogenous messenger RNA translation on hen oviduct polysomes

The eIF-2A fraction of reticulocyte ribosomal salt wash is capable of maximally stimulating the translation of endogenous messenger RNA by hen oviduct polysomes. The factor increases the initiation of protein synthesis 2--3-fold when measured by the factor-dependent synthesis of NH2-terminal peptides. The addition to these polysomes of elongation factor, EF-1, also increases protein synthesis but at a distinctly different rate and Mg2+ concentration optimum than the eIF-2A fraction. Moreover, there is no stimulation of NH2-terminal peptide synthesis with EF-1 alone. In contrast, all the known initiation factors are required for the translation of exogenous globulin mRNA on oviduct polysomes. Reticulocyte polysomes isolated by an identical procedure to that used for oviduct polysomes or by standard methods also require all the initiation factors for the translation of either endogenous mRNA or exogenous ovalbumin mRNA. Addition of 7-methylguanosine 5'-monophosphate does not inhibit the factor-dependent stimulation of oviduct polysomes except at high concentrations (1.0 mM) indicating that the sites with which 7-methylguanosine 5'-monophosphate normally competes are already occupied. These findings suggest that the messenger RNA remains bound to the oviduct polysomes or initiation factors. Hence the addition of exogenous factors which are involved with mRNA recognition and binding to the ribosome are not required. It has been previously shown that eIF-2A is capable of binding in vitro the initiatior tRNA to an existing Ado-Urd-Gua-40 S complex and initiating protein synthesis when such a complex is present. These present studies indicate that such an initiation complex may exist within the oviduct cell on membrane-associated polysomes. Under these circumstances eIF-2A mediates binding of the initiator tRNA and initiates protein synthesis.

Polyribosome size analysis. Measurement of number-average polyribosome sizes

The analysis of translational efficiencies of specific mRNAs requires a determination of the polyribosome size. The appropriate value to use in such calculations is the number-average size. A method is described for accurately measuring the number-average size of total and of specific protein synthesizing polyribosomes using isokinetic sucrose density gradients and 125I-labeled antibodies. By this method, we demonstrated that albumin synthesizing polyribosomes from a serum albumin secreting mouse hepatoma cell line exist over a broad range from trimers to 20-mers (mean 6-10). The specificity of antibody interaction with polyribosomes was demonstrated using cells not synthesizing mouse serum albumin, and by demonstrating that 125I-anti ovalbumin does not bind to mouse hepatoma polyribosomes. Treatment of the mouse hepatoma cells with 1 MUM cycloheximide shifted practically all of the monomers into polyribosomes resulting in an increase in the number-average size of the albumin synthesizing polyribosomes. Cycloheximide treatment, however, did not eliminate the size heterogeneity in the albumin synthesizing polyribosomes.