Characteristics of intracellular proteolysis in the cells of Bacillus subtilis

The rate of total protein degradation down to acid-soluble products in the B. subtilis cells growing on a minimal medium is about 4--5% per hour. Under amino acid deficiency the rate of proteolysis depends on the allelic state of the relA gene, so that in the rel+ cells it increases two-fold, while in the rel- cells it remains low. Elimination of NH4+, PO43- and Mg2+ from the culture medium or an addition of NaN3 (8 mM) or 2,4-dinitrophenol (2 mM) results in 1.5--2.0-fold stimulation of proteolysis independently of the relA gene. In all cases studied the rate of proteolysis decreases after addition of chloramphenicol (100 micrograms/ml). It is proposed that chloramphenicol decreases the intracellular concentration of ppGpp, which is believed to exert pleiotropic alterations of cellular metabolism under condition of growth limitation. Quite different is the case of degradation of anomalous proteins synthesized in the presence of the lysine analog--S-2-aminoethylcystein. Degradation of anomalous proteins proceeds very rapidly (about 70% per hour); chloramphenicol (100 micrograms/ml) decreases the rate of proteolysis only two-fold. It was found that tetracycline (100 micrograms/ml) effectively inhibits the degradation of anomalous proteins. This activity of tetracycline was not observed in the presence of 50 mM of Mg2+ and seems to be dependent on the capacity of the antibiotic to form complexes with bivalent cations. These results reveal common features of control of proteolysis in the cells of B. subtilis and E. coli.     

The influence of chloramphenicol on synthesis of ribosomes and beta and beta' subunits of RNA polymerase]

The effect of low chloramphenicol concentrations on the biosynthesis of RNA, ribosomal proteins and RNA polymerase in E. coli CP 78 cells was studied. When protein synthesis was decreased by 50--70%, 14C-uracil incorporation in DNA increased twice, the rRNA synthesis being stimulated preferentially. In the presence of antibiotic the RNA/DNA ratio increased from 5,7 to 13,3. The differential rate of r-protein synthesis increased simultaneously with the stimulation of rRNA synthesis, so that alphar rises from 0,083 (without antibiotic) to 0,122 and 0,161 at 5 and 10 microgram/ml of chloramphenicol, respectively. The inhibition of protein synthesis by chloramphenicol is accompanied also by the increase of differential rate of synthesis of beta and beta' subunits of RNA polymerase. In the presence of 5 and 10 microgram/ml of chloramphenicol, alphap increased from 0,90% to 1,44 and 1,57%, respectively. It is assumed that the genes for beta and beta' subunits of RNA polymerase as the ribosomal genes are negatively controlled by guanosine tetraphosphate which intracellular concentration decreased in the presence of chloramphenicol. The known data on the influence of streptolydigin and rifampicin on the RNA polymerase biosynthesis are discussed in view of proposed hypothesis.     

Translation of poly U by ribosomes from rel+ and rel- E. coli strains]

A translation of polyU in a cell-free system from CP78 (relA+) and CP79 (relA-) E. coli strains is investigated. The strains studied no not differ in misreading at Mg2+ concentration of 20 mM and concentrations of 16 mM (optimal for phenylalanine incorporation) and 18-22 mM (optimal for leucine incorporation) respectively. It is found that leucine incorporation increases similarly in both strains under conditions simulating an amino acid deficience (in phenylalanine-free incubation medium): the ratio leucine(-phenylalanine)/leucine (+phenylalanine) is 3.5-4 at a concentration of enzymatic fraction protein being 15-30 mkg per example, and it is 2 st a concentration of enzymatic fraction of 60-180 mkg of protein. It is suggested that differences in activities of a number of enzymes under amino acid starvation in Rel+ and Rel- cells are not due to differences in the precision of mRNA translation, but depend on the activity of respective genes.     

Interaction of yeast importin alpha with the NLS of prothymosin alpha is insufficient to trigger nuclear uptake of cargos

A proliferation-related human protein prothymosin alpha displays exclusively nuclear localization when produced in human and Saccharomyces cerevisiae cells, whereas its isolated bipartite NLS confers nuclear targeting of the GFP reporter in human but not in yeast cells. To test whether this observation is indicative of the existence of specific requirements for nuclear targeting of proteins in yeast, a set of prothymosin alpha deletion mutants was constructed. Subcellular localization of these mutants fused to GFP was determined in yeast and compared with their ability to bind yeast importin alpha (Srp1p) in vitro. The NLS of prothymosin alpha turned out to be both necessary and sufficient to provide protein recognition by importin alpha. However, the NLS-importin alpha interaction did not ensure nuclear targeting of prothymosin alpha derivatives. This defect could be complemented by adding distinct prothymosin alpha sequences to the NLS-containing import substrate, possibly by providing binding site(s) for additional components of the yeast nuclear import machinery.     

Construction of an l-phenylalanine-producing tyrosine-prototrophic Escherichia coli strain using tyrA ssrA-like tagged alleles

To construct a Phe-producing Tyr⁺ Escherichia coli strain, TyrA (chorismate mutase/prephenate dehydrogenase) activity was varied by engineering a proteolytically unstable protein. The tyrA in the E. coli BW25113 was altered to include ssrA-like tags. The tagged tyrA genes, which ensured different growth rates in M9 medium, were introduced into a Phe-producing strain to replace ΔtyrA. Strains with unstable TyrA-(A)ANDENYALAA proteins had a lower biomass yield and a higher Phe accumulation than strains generating the more stable TyrA-(A)ANDENYALDD. The Tyr/Phe ratio produced by the TyrA-tag strains was 10-fold less than that produced by the TyrA^wt strain.     

Anaerobic synthesis of succinic acid by recombinant <Emphasis Type="Italic">Escherichia coli</Emphasis> strains with activated NAD<Superscript>+</Superscript>-reducing pyruvate dehydrogenase complex

Effect of constitutive expression of the aceEF-lpdA operon genes coding for the enzymes of NAD⁺-reducing pyruvate dehydrogenase complex on the anaerobic production of succinic acid from glucose by recombinant Escherichia coli strains was studied. Basic producer strains were obtained by inactivation of the main pathways for synthesis of acetic and lactic acids through deletion of the genes ackA, pta, poxB, and ldhA (SGM0.1) in E. coli MG1655 strain and by additional introduction of the Bacillus subtilis pyruvate carboxylase (SGM0.1 [pPYC]). A constitutive expression of the genes aceEF-lpdA in derivatives of the basic strains SGM0.1 P_L-aceEF-lpdA and SGM0.1 P_L-aceEF-lpdA [pPYC] was provided by replacing the native regulatory region of the operon with the lambda phage PL promoter. Molar yields of succinic acid in anaerobic glucose fermentation by strains SGM0.1 P_L-aceEF-lpdA and SGM0.1 P_L-aceEF-lpdA [pPYC] exceeded the corresponding yields of control strains by 2 and 33% in the absence and by 9 and 26% in the presence in media of HCO₃⁻ ion. It is concluded that an increase in the succinic acid production by strain SGM0.1 P_L-aceEF-lpdA [pPYC] as compared with the strains SGM0.1 and SGM0.1 [pPYC], which synthesize this substance in the reductive branch of the tricarboxylic acid cycle, is caused by activation of the glyoxylate shunt.