Stringent control during carbon starvation of marine Vibrio sp. strain S14: molecular cloning, nucleotide sequence, and deletion of the relA gene.

In order to evaluate the role of the stringent response in starvation adaptations of the marine Vibrio sp. strain S14, we have cloned the relA gene and generated relaxed mutants of this organism. The Vibrio relA gene was selected from a chromosomal DNA library by complementation of an Escherichia coli delta relA strain. The nucleotide sequence contains a 743-codon open reading frame that encodes a polypeptide that is identical in length and highly homologous to the E. coli RelA protein. The amino acid sequences are 64% identical, and they share some completely conserved regions. A delta relA::kan allele was generated by replacing 53% of the open reading frame with a kanamycin resistance gene. The Vibrio relA mutants displayed a relaxed control of RNA synthesis and failed to accumulate ppGpp during amino acid limitation. During carbon and energy starvation, a relA-dependent burst of ppGpp synthesis concomitant with carbon source depletion and growth arrest was observed. Also, in the absence of the relA gene, there was an accumulation of ppGpp during carbon starvation, but this was slower and smaller than that which occurred in the stringent strains, and it was preceded by a marked decrease in the [ATP]/[ADP] ratio. In both the wild-type and the relaxed strains, carbon source depletion caused an immediate decrease in the size of the GTP pool and a block of net RNA accumulation. The relA mutation did not affect long-term survival or the development of resistance against heat, ethanol, and oxidative stress during carbon starvation of Vibrio sp. strain S14.

Unconventional reading of the glycine codons.

We have used a protein-synthesizing in vitro system programmed with the phage message MS2-RNA to investigate the ability of glycyl-tRNAs with different anticodons to read the glycine codons. Under conditions of no competition, when the glycyl-tRNA analyzed was the only source of glycine for protein synthesis, each of the isoacceptors tested, tRNA1Gly (anticodon CCC), tRNA2Gly (anticodon N/UCC), tRNA3Gly (anticodon GCC) from Escherichia coli, and tRNAGly (anticodon UCC) from Mycoplasma mycoides, could read all of the glycine codons in the MS2 coat protein cistron (GGU, GGC, GGA, and GGG). However, tRNA1Gly seemed to have difficulties reading through the whole cistron. Experiments in which two glycyl-tRNAs competed for the same codon showed that the mycoplasma tRNAGly (anticodon UCC) was almost as efficient in the unorthodox reading of the codons GGU and GGC as it was in conventional reading. It would seem to be the only tRNAGly present in Mycoplasma mycoides and our results are consistent with this finding since the mycoplasma tRNAGly appears to have been designed to read all four glycine codons with approximately equal efficiency. The competition experiments furthermore showed that E. coli tRNA1Gly (anticodon CCC) reads the codon GGA more efficiently than it reads GGU and GGC suggesting that the mispair C . A between the wobble position of the anticodon and the third codon position might have appreciable stability.

Codon reading and translational error. Reading of the glutamine and lysine codons during protein synthesis in vitro.

The reading of glutamine and lysine codons during protein synthesis in vitro has been investigated using an MS2-RNA-programed system derived from Escherichia coli. Under conditions when either glutaminyl-tRNA1Gln (s2UUG) or glutaminyl-tRNA2Gln (CUG) was the only source of glutamine for protein synthesis both tRNAs were able to read the glutamine codons CAA and CAG as indicated by the incorporation of labeled glutamine into the pertinent coat protein tryptic peptides. On the other hand, when the two glutamine tRNAs competed for the codon CAA the reading efficiency of the anticodon s2UUG, which reads the codon according to the wobble rules, was almost 40 times higher than that of the competing anticodon CUG, which reads the codon by "two out of three," i.e. it cannot form a regular base pair with the third codon position. In reading the codon CAG the anticodon CUG was approximately eight times more efficient than the anticodon s2UUG. The lysyl-tRNA1Lys (CUU) could not alone sustain any detectable coat protein synthesis in the MS2 system indicating that there was no significant reading of the lysine codon AAA. This conclusion is supported by the outcome of experiments where lysyl-tRNA1Lys (CUU) and lysyl-tRNA2Lys (s2UUU) competed for the codon AAA. The reading efficiency of the anticodon CUU was less than 1% of that of the competing s2UUU which represents the limit of resolution of our experimental system. When the two lysine tRNAs competed for the codon AAG the anticodon CUU was about four times more efficient than s2UUU. These results are discussed in the context of the two out of three hypothesis, which attempts to relate the frequency of such reading to the hydrogen bonding properties of the codon nucleotides.

Aberrations of the classic codon reading scheme during protein synthesis in vitro.

Using a protein synthesizing in vitro system programmed with MS2-RNA, the ability of alanine tRNAs with the anticodons U*GC (U* represents 5-oxyacetic acid uridine monophosphate) and IGC to read the alanine codons in the coat protein cistron of MS2 has been determined both under conditions of no competition, where the alanyl-tRNA used was the only aminoacylated tRNAAla present in the system, and in experiments where the two alanyl-tRNAs were competing against each other. Under conditions of no competition, each of the anticodons can read all four alanine codons. However, when the anticodons compete for the codon GCC, the anticodon IGC, which can read all three positions of the codon according to the rules of Watson-Crick base pairing, is considerably more efficient than U*GC, which misreads the codon by reading only the first two positions and presumably disregards the third nucleotide of the codon. The outcome of the competition experiments also reveals two apparent violations of the wobble restrictions: the anticodon U*GC reads the codon GUU almost as effectively as does the anticodon IGC, and IGC is almost as effective as U*GC in reading the codon GCG.

Relative efficiency of anticodons in reading the valine codons during protein synthesis in vitro.

Using a protein synthesizing in vitro system programmed with MS 2-RNA, the relative efficiency (in the presence of each other) of valine tRNAs with the anticodons U*AC (U* represents 5-oxyacetic acid uridine monophosphate), GAC, and IAC to read the valine codons was investigated. An anticodon which can read all three positions of the codon according to the rules of Watson-Crick base-pairing and the wobble hypothesis is an order of magnitude more efficient than an anticodon which misreads the codon by reading only the first two positions and presumably disregards the third nucleotide of the codon. There are two seeming exceptions to this behavior: the anticodon U*AC reads the codon GUU quite efficiently and IAC is as effective as U*AC in reading the codon GUG. The significance of these exceptions is evaluated with respect to the organization and evolution of the genetic code.