Synthesis of the translational apparatus is regulated at the translational level.

The synthesis of many mammalian proteins associated with the translational apparatus is selectively regulated by mitogenic and nutritional stimuli, at the translational level. The apparent advantages of the regulation of gene expression at the translational level are the speed and the readily reversible nature of the response to altering physiological conditions. These two features enable cells to rapidly repress the biosynthesis of the translational machinery upon shortage of amino acids or growth arrest, thus rapidly blocking unnecessary energy wastage. Likewise, when amino acids are replenished or mitogenic stimulation is applied, then cells can rapidly respond in resuming the costly biosynthesis of the translational apparatus. A structural hallmark, common to mRNAs encoding many components of the translational machinery, is the presence of a 5' terminal oligopyrimidine tract (5'TOP), referred to as TOP mRNAs. This structural motif comprises the core of the translational cis-regulatory element of these mRNAs. The present review focuses on the mechanism underlying the translational control of TOP mRNAs upon growth and nutritional stimuli. A special emphasis is put on the pivotal role played by ribosomal protein S6 kinase (S6K) in this mode of regulation, and the upstream regulatory pathways, which might be engaged in transducing external signals into activation of S6K. Finally, the possible involvement of pyrimidine-binding proteins in the translational control of TOP mRNAs is discussed.     

Differential regulation of protein biosynthesis at translational level in the fat body cells of adult Locusta migratoria

Vitellogenin (Vg) and lipophorin (Lp) are synthesized by the fat body of adult locust (Locusta migratoria) females. We have shown by an immunohistochemical technique that both proteins are produced in the same cells of the fat body. The rate of Vg synthesis was measured with the use of double immunoprecipitation of labeled proteins at oviposition and 24 h later. It was found that the rate of Vg synthesis declined significantly by the time of oviposition; however, 24 h later, it was raised to the highest possible level. The rate of Lp synthesis remained constant at both indicated points. The similar postlaying increase in the Vg synthesis rate was observed in the fat bodies of females treated by alpha-amanitin immediately after oviposition. The data provide evidence that Vg biosynthesis in L. migratoria is regulated by selective periodical repression and derepression of Vg mRNAs in the fat body cells but not by total inhibition and stimulation of protein-synthesizing machinery.     

Evolutionary process of amino acid biosynthesis in Corynebacterium at the whole genome level

Corynebacterium glutamicum, which is the closest relative of Corynebacterium efficiens, is widely used for the large scale production of many kinds of amino acids, particularly glutamic acid and lysine, by fermentation. Corynebacterium diphtheriae, which is well known as a human pathogen, is also closely related to these two species of Corynebacteria, but it lacks such productivity of amino acids. It is an important and interesting question to ask how those closely related bacterial species have undergone such significant functional differentiation in amino acid biosynthesis. The main purpose of the present study is to clarify the evolutionary process of functional differentiation among the three species of Corynebacteria by conducting a comparative analysis of genome sequences. When Mycobacterium and Streptomyces were used as out groups, our comparative study suggested that the common ancestor of Corynebacteria already possessed almost all of the gene sets necessary for amino acid production. However, C. diphtheriae was found to have lost the genes responsible for amino acid production. Moreover, we found that the common ancestor of C. efficiens and C. glutamicum have acquired some of genes responsible for amino acid production by horizontal gene transfer. Thus, we conclude that the evolutionary events of gene loss and horizontal gene transfer must have been responsible for functional differentiation in amino acid biosynthesis of the three species of Corynebacteria.     

Amino acid biosynthesis in plants: Approaching an understanding at the molecular level

Summary The genes encoding GS and EPSP synthase have already been cloned. Clones containing portions of the genes encoding aspartate amino transferase and asparagine synthetase tentatively have been identified by this and other laboratories. It is certain that many other genes encoding other important enzymes involved in amino acid biosynthesis will also be identified in the near future. It is evident that new techniques for the separation of proteins will greatly aid in identifying low abundance genes more rapidly and efficiently. Micro techniques need to be further developed and the necessary equipment made available to laboratories. Hopefully the cost of the required equipment will decrease and commercial enterprises will offer more contract services for work requiring the more expensive equipment. Graduate training in advanced techniques of separating proteins at high resolutions should be encour-aged expanded so that our future scientists are well versed in protein biochemistry as well as in techniques of molecular biology.     

Studies on proinsulin and proglucagon biosynthesis and conversion at the subcellular level: I. Fractionation procedure and characterization of the subcellular fractions

Anglerfish islets were homogenized in 0.25 M sucrose and separated into seven separate subcellular fractions by differential and discontinuous density gradient centrifugation. The objective was to isolate microsomes and secretory granules in a highly purified state. The fractions were characterized by electron microscopy and chemical analyses. Each fraction was assayed for its content of protein, RNA, DNA, immunoreactive insulin (IRI), and immunoreactive glucagon (IRG). Ultrastructural examination showed that two of the seven subcellular fractions contain primarily mitochondria, and that two others consist almost exclusively of secretory granules. A fifth fraction contains rough and smooth microsomal vesicles. The remaining two fractions are the cell supernate and the nuclei and cell debris. The content of DNA and RNA in all fractions is consistent with the observed ultrastructure. More than 82 percent of the total cellular IRI and 89(percent) of the total cellular IRG are found in the fractions of secretory granules. The combined fractions of secretory granules and microsomes consistently yield >93 percent of the total IRG. These results indicate that the fractionation procedure employed yields fractions of microsomes and secretory granules that contain nearly all the immunoassayable insulin and glucagons found in whole islet tissue. These fractions are thus considered suitable for study of proinsulin and proglucagon biosynthesis and their metabolic conversion at the subcellular level.     

Differential effect of D-glucose anomers on proinsulin biosynthesis by the pancreatic islets.

Pancreatic islets of Langerhans of the rat were used to study effects of D-glucose anomers on the incorporation of [3H]leucine into proinsulin and other islet proteins. At low (1 mg/ml), but not at high (2 mg/ml) glucose concentration, the alpha-anomer stimulated more proinsulin biosynthesis than the beta-anomer. This observation adds to the growing list of islet functions showing anomeric preference for alpha-D-glucose.     

Inhibition of proinsulin biosynthesis and conversion by a putative insulin mediator

The phospho-oligosaccharide (POS), presumed to act at the postreceptor level as the insulin second messenger, was recently reported to inhibit glucose-stimulated insulin release from rat pancreatic islets. In the present study, POS was also found to inhibit glucose-stimulated proinsulin biosynthesis and conversion in rat islets. By comparison with prior findings on the effects of both exogenous insulin and anti-insulin serum upon proinsulin synthesis, these results argue against the view that insulin would normally exert a negative feedback control upon the biosynthetic and secretory activities of islet B-cells.     

Acylation of cell-associated IL-1 by palmitic acid

To determine whether membrane-associated IL-1 is palmitylated, we labeled LPS-activated human monocytes with [3H]palmitic acid. The plasma membranes were isolated, and the membrane proteins extracted and analyzed simultaneously by SDS-PAGE-autoradiography and Western blot analysis from the same gel. When the monocytes were labeled with [3H]palmitate, 23- and 31-kDa bands were visualized, for membrane-associated IL-1 and its precursor, respectively. The 31- and 23-kDa bands were excised from several gels and rehydrated and analyzed again by SDS-PAGE, autoradiography, and Western blot analysis. The 23- and 31-kDa bands appeared again by both methods. To further investigate membrane-associated IL-1 acylation, human monocytes were labeled with [3H]palmitate, the plasma membranes isolated, and the membrane proteins extracted by CHAPS detergent. Immunoprecipitation of isolated membrane proteins using anti-IL-1 antibodies revealed two bands of 23 and 31 kDa after autoradiography. The studies demonstrate that both membrane-associated IL-1 and the IL-1 precursor are acylated with palmitic acid.     

Mechanism of regulating the expression of λN gene by ribosomal protein at translational level

In ribosomal protein S12 mutant or L24 mutant the expression of λN gene was depressed at translational level. To study its mechanism the λN gene region of λN -lacZ gene fusion was trimmed from its 5′ end to 3′ end with DNA exonuclease III (DNA cxoIII) in order to alter the TIR (translational initiation region) and the ding region of λN gene. After DNA sequencing 23 species of different λN-lacZ fused genes were obtained. The β-galactosidase activities of these deletants in ribosomal protein mutant were compared with that in wild type strain. The result indicated that (i) S12 mutant could affect 305 subunit’s binding to the TIR of λN gene messenger and cause the difficulty in forming 30s initiation complex and then decrease the efficiency of translational initiation; (ii) in S12 mutant the coding region of λN gene alw affected the expression λN gene; (iii) in L24 mutant the inhibition of λN gene expression was not related to translational initiation and the 5′ end of the coding region of λN gene, but related to the 3′ end of λN gene.     

Stimulation of proinsulin biosynthesis and insulin release by pyruvate and lactate.

Increasing concentrations of pyruvate failed to stimulate proinsulin biosynthesis and insulin release in freshly isolated islets. Glycolytic flux (3H2O from [5-3H]glucose) decreased by 80-85%, but decarboxylation of [1(-14)C]pyruvate was unaffected in islets tested immediately after alloxan exposure. This strongly suggested that in freshly isolated islets, beta-cells, in relation to other islet cells, hardly contribute to the decarboxylation of pyruvate. Non-alloxan-treated cultured islets decarboxylated 2-2.5 times as much pyruvate as did alloxan-treated islets cultured for 15-18h. Thus the contribution of beta-cells to the metabolism of pyruvate after culturing markedly increased. Concomitantly beta-cells became responsive to pyruvate. At 20mM-pyruvate, release of prelabelled proinsulin and insulin and incorporation of [3H]leucine into proinsulin reached values approximately half of those obtained with 20mM-glucose. Lactate was as effective as pyruvate in inducing responses in cultured islets. The experiments indicate that a critical degree of substrate utilization is necessary for the generation of signals for insulin release and proinsulin biosynthesis.     

Inhibition of growth of Brochothrix thermosphacta by palmitic acid

Palmitic acid was inhibitory to the growth of Brochothrix thermosphacta in liquid culture at 0.5 mmol/l. Uptake of [1-¹⁴C]-palmitic acid by the organism has been demonstrated, and was reduced at acid pH. These findings are discussed in relation to the known effects of fatty acids on bacteria.     

Mechanism of regulating the expression of λN gene by ribosomal protein at translational level

In ribosomal protein S12 mutant or L24 mutant the expression of λN gene was depressed at translational level. To study its mechanism the λN gene region of λN -lacZ gene fusion was trimmed from its 5′ end to 3′ end with DNA exonuclease III (DNA cxoIII) in order to alter the TIR (translational initiation region) and the ding region of λN gene. After DNA sequencing 23 species of different λN-lacZ fused genes were obtained. The β-galactosidase activities of these deletants in ribosomal protein mutant were compared with that in wild type strain. The result indicated that (i) S12 mutant could affect 305 subunit’s binding to the TIR of λN gene messenger and cause the difficulty in forming 30s initiation complex and then decrease the efficiency of translational initiation; (ii) in S12 mutant the coding region of λN gene alw affected the expression λN gene; (iii) in L24 mutant the inhibition of λN gene expression was not related to translational initiation and the 5′ end of the coding region of λN gene, but related to the 3′ end of λN gene. Project supported by the National Natural Science Foundation of China (Grant Nos. 39480014, 39570162) and Chinese Academy of Sciences.     

Gene expression regulation at the translational level: contribution of marine organisms

Gene expression regulation is crucial for organism survival. Each step has to be regulated, from the gene to the protein. mRNA can be stored in the cell without any direct translation. This process is used by the cell to control protein synthesis rapidly at the right place, at the right time. Protein synthesis costs a lot of energy for the cell, so that a precise control of this process is required. Translation initiation represents an important step to regulate gene expression. Many factors that can bind mRNA and recruit different partners are involved in the inhibition or stimulation of protein synthesis. Oceans contain an important diversity of organisms that are used as important models to analyse gene expression at the translational level. These are useful to study translational control in different physiological processes for instance cell cycle (meiosis during meiotic maturation of starfish oocytes, mitosis following fertilization of sea urchin eggs) or to understand nervous system mechanisms (aplysia). All these studies will help finding novel actors involved in translational control and will thus be useful to discover new targets for therapeutic treatments against human diseases.     

Protection of palmitic acid-mediated lipotoxicity by arachidonic acid via channeling of palmitic acid into triglycerides in C2C12

Background

Excessive saturated fatty acids have been considered to be one of major contributing factors for the dysfunction of skeletal muscle cells as well as pancreatic beta cells, leading to the pathogenesis of type 2 diabetes.

Results

PA induced cell death in a dose dependent manner up to 1.5 mM, but AA protected substantially lipotoxicity caused by PA at even low concentration of 62 μM, at which monounsaturated fatty acids including palmitoleic acid (POA) and oleic acid (OA) did not protect as much as AA did. Induction of cell death by PA was resulted from mitochondrial membrane potential loss, and AA effectively blocked the progression of apoptosis. Furthermore, AA rescued significantly PA-impaired glucose uptake and -signal transduction of Akt in response to insulin.Based on the observations that polyunsaturated AA generated competently cellular droplets at low concentration within the cytosol of myotubes compared with other monounsaturated fatty acids, and AA-driven lipid droplets were also enhanced in the presence of PA, we hypothesized that incorporation of harmful PA into inert triglyceride (TG) may be responsible for the protective effects of AA against PA-induced lipotoxicity. To address this assumption, C2C12 myotubes were incubated with fluorescent probed-PA analogue 4, 4-difluoro-5, 7-dimethyl-4-boro-3a,4a-diaza-s-indacene-3-hexadecanoic acid (BODIPY FL C16) in the presence of AA and their subsequent lipid profiles were analyzed. The analyses of lipids on thin layer chromatograpy (TLC) showed that fluorescent PA analogue was rapidly channeled into AA-driven TG droplets.

Conclusion

Taken together, it is proposed that AA diverts PA into inert TG, therefore reducing the availability of harmful PA into intracellular target molecules.