An in vivo effect of the metabolites L-alanine and glycyl-L-leucine on the properties of the lysyl-tRNA synthetase from Escherichia coli K-12. II. Kinetic evidence

Model-based inference of gene expression dynamics from sequence information

A dynamic model of prokaryotic gene expression is developed that makes considerable use of gene sequence information. The main contribution arises from the fact that the combined gene expression model allows us to access the impact of altering a nucleotide sequence on the dynamics of gene expression rates mechanistically. The high level of detail of the mathematical model is considered as an important step towards bringing together the tremendous amount of biological in-depth knowledge that has been accumulated at the molecular level, using a systems level analysis (in the sense of a bottom-up, inductive approach). This enables to the model to provide highly detailed insights into the various steps of the protein expression process and it allows us to access possible targets for model-based design. Taken as a whole, the mathematical gene expression model presented in this study provides a comprehensive framework for a thorough analysis of sequence-related effects on the stages of mRNA synthesis, mRNA degradation and ribosomal translation, as well as their nonlinear interconnectedness. Therefore, it may be useful in the rational design of recombinant bacterial protein synthesis systems, the modulation of enzyme activities in pathway design, in vitro protein biosynthesis, and RNA-based vaccination.

Lysyl-tRNA synthetase

Lysyl-tRNA synthetase catalyses the formation of lysyl-transfer RNA, Lys-tRNA(Lys), which then is ready to insert lysine into proteins. Lysine is important for proteins since it is one of only two proteinogenic amino acids carrying an alkaline functional group. Seven genes of lysyl-tRNA synthetases have been localized in five organisms, and the nucleotide and the amino acid sequences have been established. The lysyl-tRNA synthetase molecules are of average chain lengths among the aminoacyl-tRNA synthetases, which range from about 300 to 1100 amino acids. Lysyl-tRNA synthetases act as dimers; in eukaryotes they can be localized in multienzyme complexes and can contain carbohydrates or lipids. Lysine tRNA is recognized by lysyl-tRNA synthetase via standard identity elements, namely anticodon region and acceptor stem. The aminoacylation follows the standard two-step mechanism. However the accuracy of selecting lysine against the other amino acids is less than average. The first threedimensional structure of a lysyl-tRNA synthetase worked out very recently, using the enzyme from the Escherichia coli lysU gene which binds one molecule of lysine, is similar to those of other class II synthetases. However, none of the reaction steps catalyzed by the enzyme is clarified to atomic resolution. Thus surprising findings might be possible. Lysyl-tRNA synthetase and its precursors as well as its substrates and products are targets and starting points of many regulation circuits, e.g. in multienzyme complex formation and function, dinucleoside polyphosphate synthesis, heat shock regulation, activation or deactivation by phosphorylation/dephosphorylation, inhibition by amino acid analogs, and generation of antibodies against lysyl-tRNA synthetase. None of these pathways is clarified completely.

Comparison of the enzymatic properties of the two Escherichia coli lysyl-tRNA synthetase species

In Escherichia coli, lysyl-tRNA synthetase activity is encoded by either a constitutive lysS gene or an inducible one, lysU. The two corresponding enzymes could be purified at homogeneity from a delta lysU and a delta lysS strain, respectively. Comparison of the pure enzymes, LysS and LysU, indicates that, in the presence of saturating substrates, LysS is about twice more active than LysU in the ATP-PPi exchange as well as in the tRNALys aminoacylation reaction. Moreover, the dissociation constant of the LysU-lysine complex is 8-fold smaller than that of the LysS-lysine complex. In agreement with this difference, the activity of LysU is less sensitive than that of LysS to the addition of cadaverine, a decarboxylation product of lysine and a competitive inhibitor of lysine binding to its synthetase. This observation points to a possible useful role of LysU, under physiological conditions causing cadaverine accumulation in the bacterium. Remarkably, these conditions also induce lysU expression. Homogeneous LysU and LysS were also compared in Ap4A synthesis. LysU is only 2-fold more active than LysS in the production of this dinucleotide. This makes unlikely that the heat-inducible LysU species could be preferentially involved in the accumulation of Ap4A inside stressed Escherichia coli cells. This conclusion could be strengthened by determining the concentrations of Ap4N (N = A, C, G, or U) in a delta lysU as well as in a lysU+ strain, before and after a 1-h temperature shift at 48 degrees C. The measured concentration values were the same in both strains.

Partial characterization of a lysU mutant of Escherichia coli K-12

The Escherichia coli K-12 strain GNB10181 shows no inducible lysyl-tRNA synthetase (LysRS) activity. Two-dimensional gel electrophoretic analysis of the polypeptides synthesized by this strain indicates that the normal lysU gene product, LysU, is absent. When both GNB10181 and its parent, MC4100, were grown at elevated temperatures (42 to 45 degrees C) no significant difference between their growth rates was observed. The lysU mutation was transferred to other E. coli K-12 backgrounds by using P1 transduction. The lysU transductants behaved comparably to their lysU+ parents at different growth temperatures. Therefore, the LysU proteins does not appear to be essential for growth at high temperatures, at least under the conditions examined here. In addition, lysU transductants were found to be defective for inducible lysine decarboxylase, (LDC), inducible arginine decarboxylase (ADI), and melibiose utilization (Mel), which are all missing in GNB10181. Complementation of the above missing functions was achieved by using the Clarke-Carbon plasmids pLC4-5 (LysU LDC) and pLC17-38 (LysU Mel ADI). From these experiments, it appears that GNB10181 has suffered a chromosomal deletion between 93.4 and 93.7 min, which includes the lysU gene. By using plasmid pLC17-38, the position of ADI on two-dimensional gels was identified. Finally, lysS delta lysU double mutants were constructed which can potentially be used as positive selection agents for the isolation of LysRS genes from other sources.

Roles of the two lysyl-tRNA synthetases of Escherichia coli: analysis of nucleotide sequences and mutant behavior

The complete nucleotide sequence of lysU, the gene for the heat-inducible lysyl-tRNA synthetase of Escherichia coli, was determined and compared with the published sequence of lysS (herC), the gene for the constitutive lysyl-tRNA synthetase. These unlinked genes were found to be identical over 72% of their lengths. The deduced amino acid sequences of the respective gene products, LysU and LysS, were identical over 85% and similar over 92% of their lengths. Accumulation of high levels of LysU during growth of strains carrying the wild-type allele of lysU on multicopy plasmids had no observable effect on growth or on the synthesis of LysS. A lysU deletion strain was constructed and was shown to grow normally at low temperature (28 degrees C) but poorly at 44 degrees C; the slow growth (45% of normal) at elevated temperature was fully reversed by plasmids bearing wild-type lysU. The implications of these findings for the existence of two aminoacyl-tRNA synthetases for lysine are discussed.

Homology of lysS and lysU, the two Escherichia coli genes encoding distinct lysyl-tRNA synthetase species

In Escherichia coli, two distinct lysyl-tRNA synthetase species are encoded by two genes: the constitutive lysS gene and the thermoinducible lysU gene. These two genes have been isolated and sequenced. Their nucleotide and deduced amino acid sequences show 79% and 88% identity, respectively. Codon usage analysis indicates the lysS product being more efficiently translated than the lysU one. In addition, the lysS sequence exactly coincides with the sequence of herC, a gene which is part of the prfB-herC operon. In contrast to the recent proposal of Gampel and Tzagoloff (1989, Proc. Natl. Acad. Sci. USA 86, 6023-6027), the lysU sequence is distinct from the open reading frame located adjacent to frdA, although large homologies are shared by these two genes.

Lysyl-tRNA synthetase from Escherichia coli K12. Chromatographic heterogeneity and the lysU-gene product

In contrast with most aminoacyl-tRNA synthetases, the lysyl-tRNA synthetase of Escherichia coli is coded for by two genes, the normal lysS gene and the inducible lysU gene. During its purification from E. coli K12, lysyl-tRNA synthetase was monitored by its aminoacylation and adenosine(5')tetraphospho(5')adenosine (Ap4A) synthesis activities. Ap4A synthesis was measured by a new assay using DEAE-cellulose filters. The heterogeneity of lysyl-tRNA synthetase (LysRS) was revealed on hydroxyapatite; we focused on the first peak, LysRS1, because of its higher Ap4A/lysyl-tRNA activity ratio at that stage. Additional differences between LysRS1 and LysRS2 (major peak on hydroxyapatite) were collected. LysRS1 was eluted from phosphocellulose in the presence of the substrates, whereas LysRS2 was not. Phosphocellulose chromatography was used to show the increase of LysRS1 in cells submitted to heat shock. Also, the Mg2+ optimum in the Ap4A-synthesis reaction is much higher for LysRS1. LysRS1 showed a higher thermostability, which was specifically enhanced by Zn2+. These results in vivo and in vitro strongly suggest that LysRS1 is the heat-inducible lysU-gene product.

Escherichia coli K-12 lysyl-tRNA synthetase mutant with a novel reversion pattern

Fast-growing revertants have been selected from a slow-growing lysyl-tRNA synthetase mutant. All of the revertants had increased lysyl-tRNA synthetase activity compared with the mutant (5- to 85-fold), and in some revertants this amounted to two to three times the wild-type synthetase activity. Two-dimensional gel electrophoresis of a whole-cell extract of revertant IH2018 (1.5- to 2-fold wild-type synthetase activity) showed that the increase in synthetase activity is due to the induction of cryptic lysyl-tRNA synthetase forms and not to a change in the constitutive lysyl-tRNA synthetase. Genetic studies have shown that a locus termed rlu (for regulation of lysU ) which is cotransducible with purF at 49.5 min influences the amount of the cryptic lysyl-tRNA synthetase.

Multiple forms of lysyl-transfer ribonucleic acid synthetase in Escherichia coli

Lysyl-transfer ribonucleic acid synthetase (EC 6.1.1.6) was identified as four polypeptide spots after two-dimensional polyacrylamide gel electrophoresis of whole-cell lysates of Escherichia coli. Identification was made by migration with partially purified enzyme preparations, by peptide map patterns, by mutant analysis, and by correlation of spot intensities with changes in enzyme levels under different growth conditions. Wild-type cells growing at 37 degrees C in glucose minimal medium displayed the enzyme predominantly as two spots (spots I and III). Growth at 46 degrees C, growth in the presence of alanine or glycyl-L-leucine, or growth of a strain with a mutational deficiency in S-adenosylmethionine synthetase (metK) greatly increased the synthesis of two other spots (spots II and IV). Polypeptides I and III, but not polypeptides II and IV, had altered isoelectric points in a lysyl-transfer ribonucleic acid synthetase mutant. These data suggest that multiple forms of lysyl-transfer ribonucleic acid synthetase exist in vivo and that they may be encoded by more than one gene.

Two modes of metabolic regulation of lysyl-transfer ribonucleic acid synthetase in Escherichia coli K-12

Lysyl-transfer ribonucleic acid (tRNA) synthetase activity was compared in three independently isolated Escherichia coli K-12 mutants of the enzyme S-adenosyl-L-methionine synthetase (metK mutants) and their isogenic parents. In all three cases the activity of the lysyl-tRNA synthetase was elevated two- to fourfold in the mutant strains. Glycyl-L-leucine (3 mM) usually enhanced lysyl-tRNA synthetase activity two- to threefold in wild-type cells but did not further stimulate the synthetase activity in metK mutants. By two other criteria, the lysyl-tRNA synthetase from wild-type cells grown with the peptide and from the metK mutant RG62, grown in minimal medium, were similar. These criteria are enhanced resistance to thermal inactivation and altered susceptibility to endogenous proteases when compared with the synthetase from wild-type cells grown in minimal medium. In a separate set of experiments, the activities of the lysyl-, arginyl-, seryl-, and valyl-tRNA synthetases were measured in an isogenic pair of relt and rel strains of E. coli grown in a relatively poor growth medium (acetate) and in enriched medium. In the rel+ strain the level of all four synthetases was higher (two- to fourfold) in the enriched medium as expected. In the rel strain the difference in the activities of the synthetases between the two media were diminished. In all four cases the activities of the synthetases were higher in acetate medium in the rel strain. Evidence is presented that these two modes of metabolic regulation act independently.

An in vivo effect of the metabolites L-alanine and glycyl-L-leucine on the properties of lysyl-tRNA synthetase from Escherichia coli K-12. I. Influence on subunit composition and molecular weight distribution

Lysyl-tRNA synthetase was purified to 70-90% of homogeneity from Escherichia coli K-12. The enzyme was purified from wild-type cells grown in minimal medium, or minimal medium containing either 20 mM L-alanine or 3 mM glycly-L-leucine. The synthetase was similarly purified from a mutant strain grown in minimal medium plus 20 mM L-alanine. Results based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gel filtration, and trypsin inactivation studies indicate (A) that the presence of L-alanine of glycyl-L-leucine in the culture medium alters the properties of the wild-type enzyme; (B) that the alteration of the synthetase by l-alanine and glycyl-L-leucine is different; and (c) that the molecular weight of lysyl-tRNA synthetase is at least 135000--140000. The results suggest that most likely the metabolites modify the structure of lysyl-tRNA synthetase, but the possibility that the metabolites induce the synthesis of a new lysyl-tRNA synthetase cannot be completely eliminated.