Expression of the Synechocystis sp. strain PCC 6803 tRNA(Glu) gene provides tRNA for protein and chlorophyll biosynthesis

The role of the 5' sensing function of ribonuclease E in cyanobacteria

RNA degradation is critical for synchronising gene expression with changing conditions in prokaryotic and eukaryotic organisms. In bacteria, the preference of the central ribonucleases RNase E, RNase J and RNase Y for 5'-monophosphorylated RNAs is considered important for RNA degradation. For RNase E, the underlying mechanism is termed 5' sensing, contrasting to the alternative 'direct entry' mode, which is independent of monophosphorylated 5' ends. Cyanobacteria, such as Synechocystis sp. PCC 6803 (Synechocystis), encode RNase E and RNase J homologues. Here, we constructed a Synechocystis strain lacking the 5' sensing function of RNase E and mapped on a transcriptome-wide level 283 5'-sensing-dependent cleavage sites. These included so far unknown targets such as mRNAs encoding proteins related to energy metabolism and carbon fixation. The 5' sensing function of cyanobacterial RNase E is important for the maturation of rRNA and several tRNAs, including tRNAGluUUC. This tRNA activates glutamate for tetrapyrrole biosynthesis in plant chloroplasts and in most prokaryotes. Furthermore, we found that increased RNase activities lead to a higher copy number of the major Synechocystis plasmids pSYSA and pSYSM. These results provide a first step towards understanding the importance of the different target mechanisms of RNase E outside Escherichia coli.

Regulated expression of glutamyl-tRNA synthetase is directed by a mobile genetic element in the cyanobacterium Tolypothrix sp. PCC 7601

The genome of Tolypothrix sp. PCC 7601 carries two copies of a novel insertion sequence, ISTosp1. One of the two copies is located upstream of the gene encoding glutamyl-tRNA synthetase, an enzyme playing a key role in protein and pigment synthesis. The tnpA gene of the IS element and gltX were co-transcribed and their expression was transiently upregulated upon retrieval of the ammonium source irrespective of whether nitrate or no nitrogen source were available. The second copy is also transcribed and shows a similar regulatory pattern. Structural elements of the promoter (-10 and -35 sequences) directing the expression of the tnpA-gltX operon have been localized within the IS. Regulatory sequences involving the NtcA transcription factor in the control of tnpA-gltX expression were found both within and in sequences upstream of the insertion element. The expression of gltX in a closely related cyanobacterium, Nostoc sp. PCC 7120, which lacks the insertion upstream of gltX, decreased upon ammonium retrieval, a regulatory pattern that markedly differs from that observed in Tolypothrix sp. PCC 7601. ISTosp1 constitutes a good example of how cells can make use of a transposable element to evolve an original regulatory mechanism.

Physical and kinetic interactions between glutamyl-tRNA reductase and glutamate-1-semialdehyde aminotransferase of Chlamydomonas reinhardtii

In plants, algae, and most bacteria, the heme and chlorophyll precursor 5-aminolevulinic acid (ALA) is formed from glutamate in a three-step process. First, glutamate is ligated to its cognate tRNA by glutamyl-tRNA synthetase. Activated glutamate is then converted to a glutamate 1-semialdehyde (GSA) by glutamyl-tRNA reductase (GTR) in an NADPH-dependent reaction. Subsequently, GSA is rearranged to ALA by glutamate-1-semialdehyde aminotransferase (GSAT). The intermediate GSA is highly unstable under physiological conditions. We have used purified recombinant GTR and GSAT from the unicellular alga Chlamydomonas reinhardtii to show that GTR and GSAT form a physical and functional complex that allows channeling of GSA between the enzymes. Co-immunoprecipitation and sucrose gradient ultracentrifugation results indicate that recombinant GTR and GSAT enzymes specifically interact. In vivo cross-linking results support the in vitro results and demonstrate that GTR and GSAT are components of a high molecular mass complex in C. reinhardtii cells. In a coupled enzyme assay containing GTR and wild-type GSAT, addition of inactive mutant GSAT inhibited ALA formation from glutamyl-tRNA. Mutant GSAT did not inhibit ALA formation from GSA by wild-type GSAT. These results suggest that there is competition between wild-type and mutant GSAT for binding to GTR and channeling GSA from GTR to GSAT. Further evidence supporting kinetic interaction of GTR and GSAT is the observation that both wild-type and mutant GSAT stimulate glutamyl-tRNA-dependent NADPH oxidation by GTR.

Substrate binding and catalysis by ribonuclease P from cyanobacteria and Escherichia coli are affected differently by the 3' terminal CCA in tRNA precursors

We have studied the effect of the 3' terminal CCA sequence in precursors of tRNAs on catalysis by the RNase P RNA or the holoenzyme from the cyanobacterium Synechocystis sp. PCC 6803 in a completely homologous system. We have found that the absence of the 3' terminal CCA is not detrimental to activity, which is in sharp contrast to what is known in other bacterial systems. We have found that this is also true in other cyanobacteria. This situation correlates with the anomalous structure of the J15/16 loop in cyanobacteria, which is an important loop in the CCA interaction in Escherichia coli RNase P, and with the fact that cyanobacteria do not code the CCA sequence in the genome but add it posttranscriptionally. Modification of nucleotides 330-332 in the J15/16 loop of Synechocystis RNase P RNA from GGU to CCA has a modest effect on kcat for CCA-containing substrates and has no effect on cleavage-site selection. We have developed a direct physical assay of the interaction between RNase P RNA and its substrate, which was immobilized on a filter, and we have determined that Synechocystis RNase P RNA binds with better affinity the substrate lacking CCA than the substrate containing it. Our results indicate a mode of substrate binding in RNase P from cyanobacteria that is different from binding in other eubacteria and in which the 3' terminal CCA is not involved.

Lack of gene- and strand-specific DNA repair in RNA polymerase III-transcribed human tRNA genes

UV light induces DNA lesions which are removed by nucleotide excision repair. Genes transcribed by RNA polymerase II are repaired faster than the flanking chromatin, and the transcribed strand is repaired faster than the coding strand. Transcription-coupled repair is not seen in RNA polymerase I-transcribed human rRNA genes. Since repair of genes transcribed by RNA polymerase III has not been analyzed before, we investigated DNA repair of tRNA genes after irradiation of human fibroblasts with UVC. We studied the repair of UV-induced cyclobutane pyrimidine dimers at nucleotide resolution by ligation-mediated PCR. A single-copy gene encoding selenocysteine tRNA, a tRNA valine gene, and their flanking sequences were analyzed. Protein-DNA footprinting showed that both genes were occupied by regulatory factors in vivo, and Northern blotting and nuclear run-on analysis of the tRNA indicated that these genes were actively transcribed. We found that both genes were repaired slower than RNA polymerase II-transcribed genes. No major difference between repair of the transcribed and the coding DNA strands was detected. Transcribed sequences of the tRNA genes were not repaired faster than flanking sequences. Indeed, several sequence positions in the 5' flanking region of the tRNA(Val) gene were repaired more efficiently than the gene itself. These results indicate that unlike RNA polymerase II, RNA polymerase III has no stimulatory effect on DNA repair. Since tRNA genes are covered by the regulatory factor TFIIIC and RNA polymerase III, these proteins may actually inhibit the DNA's accessibility to repair enzymes.

Partial inhibition of protein synthesis accelerates the synthesis of porphyrin in heme-deficient mutants of Escherichia coli

Mutants of Escherichia coli defective in the HemA protein grow extremely poorly as the result of heme deficiency. A novel hemA mutant was identified whose rate of growth was dramatically enhanced by addition to the medium of low concentrations of translational inhibitors, such as chloramphenicol and tetracycline. This mutant (H110) carries mutation at position 314 in the hemA gene, which resulted in diminished activity of the encoded protein. Restoration of growth of H110 upon addition of the drugs mentioned above was due to activation of the synthesis of porphyrin. However, this activation was not characteristic exclusively of cells with this mutant hemA gene since it was also observed in a heme-deficient strain bearing the wild-type hemA gene. The activation did not depend on the promoter activity of the hemA gene, as indicated by studies with fusion genes. It appears that partial inhibition of protein synthesis via inhibition of peptidyltransferase can promote the synthesis of porphyrin by providing an increased supply of glutamyl-tRNA for porphyrin synthesis. Glutamyl-tRNA is the common substrate for peptidyltransferase and HemA.

The genes aroA and trnQ are located upstream of psbO in the chromosome of Synechocystis 6803

We have identified the existence of two genes, trnQ and aroA, located upstream of the psbO gene in Synechocystis sp. PCC 6803. The trnQ gene encodes a glutamine-specific transfer RNA (tRNA(Gln)) and the sequence given is the first reported for any cyanobacterium. The gene seems to exist as a single copy since its deletion results in non-viable mutation. The aroA gene encodes for 5-enolpyruvylshikimate 3-phosphate synthase and its discovery in the genome of Synechocystis 6803 is the first genetic evidence for the existence of the shikimate biosynthetic pathway in cyanobacteria. Interestingly, the partial sequence shares close homologies with the sequences of aroA from Gram-positive bacteria.

Expression of the Chlamydomonas reinhardtii chloroplast tRNA(Glu) gene in a homologous in vitro transcription system is independent of upstream promoter elements

Chloroplast tRNA(Glu) is a bifunctional molecule involved in both the early steps of chlorophyll synthesis and chloroplast protein biosynthesis. Recently the enzymes involved in these processes have been characterized from the green alga Chlamydomonas reinhardtii. In order to investigate whether transcription of the gene for the tRNA(Glu) cofactor would be a possible point of regulation for the biosynthesis of chlorophyll, a homologous in vitro transcription system for C. reinhardtii chloroplast RNA polymerase was developed. The enzymatic activity was partially purified by ion-exchange chromatography to separate it from nuclear RNA polymerases. The highest rate of synthesis was found at pH 7.9, 40 mM KCl, 9 mM MgCl2 and with 25 micrograms plasmid DNA containing the chloroplast tRNA gene per milliliter. The activity was not sensitive to high amounts of alpha-amanitin (500 micrograms/ml) and rifampicin, but was clearly inhibited by heparin. This system was used to undertake a promoter analysis of one of the two identical tRNA(Glu) gene copies found in the C. reinhardtii chloroplast genome (trnE1). The analyzed tRNA gene behaved like a single transcription unit driven by its own promoter. The transcript terminated in a run of four consecutive T residues downstream of the gene. The nucleotide sequence in the 5' region of the gene revealed several potential promoter elements with homology to known chloroplast promoters of the "-10 and -35 region" and the "Euglena promoter" types. Surprisingly, deletion of the complete 5' region did not affect in vitro transcription, while partial deletions of the 5' and 3' coding region totally abolished transcription. This indicates the presence of an internal control region previously found for genes transcribed by nuclear RNA polymerase III. Protein binding studies with the coding region of trnE1 using gel retardation assays demonstrated the formation of two differently sized complexes. In vitro transcription of the tRNA(Glu) gene in extracts prepared from light and dark grown algae failed to demonstrate any significant influence of light on the transcription reaction.

Glutamyl-transfer RNA: a precursor of heme and chlorophyll biosynthesis

In green plants, archaebacteria and many eubacteria, the porphyrin ring that is common to both chlorophyll and heme is synthesized from 5-aminolevulinic acid (ALA) via an interesting pathway. This two-step process involves the unusual enzymes glutamyl-tRNA reductase and glutamate-1-semialdehyde 2,1-aminomutase. Interest in this pathway has increased since it was discovered that a tRNA cofactor was required for the formation of ALA. This tRNA(Glu) is common to the biosyntheses of both porphyrins and proteins.

delta-Aminolevulinic Acid Biosynthesis from Glutamatein Euglena gracilis: Photocontrol of Enzyme Levels in a Chlorophyll-Free Mutant

Wild-type Euglena gracillis cells synthesize the key chlorophyll precursor, delta-aminolevulinic acid (ALA), from glutamate in their plastids. The synthesis requires transfer RNA(Glu) (tRNA(Glu)) and the three enzymes, glutamyl-tRNA synthetase, glutamyl-tRNA reductase, and glutamate-1-semialdehyde aminotransferase. Non-greening mutant Euglena strain W(14)ZNaIL does not synthesize ALA from glutamate and is devoid of the required tRNA(Glu). Other cellular tRNA(Glu)s present in the mutant cells were capable of being charged with glutamate, but the resulting glutamyl-tRNAs did not support ALA synthesis. Surprisingly, the mutant cells contain all three of the enzymes, and their cell extracts can convert glutamate to ALA when supplemented with tRNA(Glu) obtained from wild-type cells. Activity levels of the three enzymes were measured in extracts of cells grown under a number of light conditions. All three activities were diminished in extracts of cells grown in complete darkness, and full induction of activity required 72 hours of growth in the light. A light intensity of 4 microeinsteins per square meter per second was sufficient for full induction. Blue light was as effective as white light, but red light was ineffective, in inducing extractable enzyme activity above that of cells grown in complete darkness, indicating that the light control operates via the nonchloroplast blue light receptor in the mutant cells. Of the three enzyme activities, the one that is most acutely affected by light is glutamate-1-semialdehyde aminotransferase, as has been previously shown for wild-type Euglena cells. These results indicate that the enzymes required for ALA synthesis from glutamate are present in an active form in the nongreening mutant cells, even though they cannot participate in ALA formation in these cells because of the absence of the required tRNA(Glu), and that the activity of all three enzymes is regulated by light. Because the absence of plastid tRNA(Glu) precludes the synthesis of proteins within the plastids, the three enzymes must be synthesized in the cytoplasm and their genes encoded in the nucleus in Euglena.

Separation and partial characterization of enzymes catalyzing delta-aminolevulinic acid formation in Synechocystis sp. PCC 6803

Formation of the universal tetrapyrrole precursor, delta-aminolevulinic acid (ALA), from glutamate via the five-carbon pathway requires three enzymes: glutamyl-tRNA synthetase, glutamyl-tRNA reductase, and glutamate-1-semialdehyde (GSA) aminotransferase. All three enzymes were separated from extracts of the unicellular cyanobacterium Synechocystis sp. PCC 6803, and two of them, glutamyl-tRNA synthetase and GSA aminotransferase, were partially characterized. After an initial high speed centrifugation and differentiatial ammonium sulfate fractionation of cell extract, the enzymes were separated by successive affinity chromatography on Reactive Blue 2-Sepharose and 2',5'-ADP-agarose. All three enzyme fractions were required to reconstitute ALA formation from glutamate. The apparent native molecular masses of glutamyl-tRNA synthetase and GSA aminotransferase were determined by gel filtration chromatography to be 63 and 98 kDa, respectively. Neither glutamyl-tRNA synthetase nor GSA aminotransferase activity was affected by hemin concentrations up to 10 and 30 microM, respectively, and neither activity was affected by protochlorophyllide concentrations up to 2 microM. GSA aminotransferase was inhibited 50% by 0.5 microM gabaculine. The gabaculine inhibition was reversible for up to 1 h after its addition, if the gabaculine was removed by gel filtration before the enzyme was incubated with substrate. However, irreversible inactivation was obtained by preincubating the enzyme at 30 degrees C either for several hours with gabaculine alone or for a few minutes with both gabaculine and GSA. Neither pyridoxal phosphate nor pyridoxamine phosphate significantly affected the activity of GSA aminotransferase at physiologically relevant concentrations, and neither of these compounds reactivated the gabaculine-inactivated enzyme. It was noted that the presence of pyridoxamine phosphate in the ALA assay mixture produced a false positive color reaction even in the absence of enzyme.