Attenuation in the threonine operon: effects of amino acids present in the presumed leader peptide in addition to threonine and isoleucine

Summary We have studies in vivo the contribution of amino acids corresponding to codons of the leader sequence other than the so-called regulatory codons (for threonine and isoleucine) in the expression of the threonine operon. In the presence of threonine and isoleucine, addition of each amino acid encoded in the proximal part of the leader sequence resulted in a significant decrease of the expression of the operon, over and above that decrease observed in the sole presence of threonine and isoleucine. These effects were cumulative. No such effect was found with the amino acids encoded by the distal part of the leader sequence. These findings are discussed in the light of the current model of attenuation.     

Genetic complementation of the Saccharomyces cerevisiae leu2 gene by the Escherichia coli leuB gene.

The leucine operon of Escherichia coli was cloned on a plasmid possessing both E. coli and Saccharomyces cerevisiae replication origins. This plasmid, pEH25, transformed leuA, leuB, and leuD auxotrophs of E. coli to prototrophy; it also transformed leu2 auxotrophs of S. cerevisiae to prototrophy. beta-Isopropylmalate dehydrogenase was encoded by the leuB gene of E. coli and the leu2 gene of yeast. Verification that the leuB gene present on pEH26 was responsible for complementing yeast leu2 was obtained by isolating in E. coli several leuB mutations that resided on the plasmid. These mutant leuB- plasmids were no longer capable of complementing leu2 in S. cerevisiae. We conclude that S. cerevisiae is capable of transcribing at least a portion of the polycistronic leu operon of E. coli and can translate a functional protein from at least the second gene of this operon. The yeast Leu+ transformants obtained with pEH25, when cultured in minimal medium lacking leucine, grew with a doubling time three to four times longer than when cultured in medium supplemented with leucine.     

Threonyl-transfer ribonucleic acid synthetase and the regulation of the threonine operon in Escherichia coli.

Two threonine-requiring mutants with derepressed expression of the threonine operon were isolated from an Escherichia coli K-12 strain containing two copies of the thr operon. One of them carries a leaky mutation in ilvA (the structural gene for threonine deaminase), which creates an isoleucine limitation and therefore derepression of the thr operon. In the second mutant, the enzymes of the thr operon were not repressed by threonine plus isoleucine; the threonyl-transfer ribonucleic acid(tRNA) synthetase from this mutant shows an apparent Km for threonine 200-fold higher than that of the parental strain. The gene, called thrS, coding for threonyl-tRNA synthetase was located around 30 min on the E. coli map. The regulatory properties of this mutant imply the involvement of charged threonyl-tRNA or threonyl-tRNA synthetase in the regulation of the thr operon.     

Evolution of the mitochondrial genetic code III. Reassignment of CUN codons from leucine to threonine during evolution of yeast mitochondria

Summary Yeast mitochondria use UUR as the sole leucine codons. CUN, universal leucine codons, are read as threonine by aberrant threonine tRNA with anticodon sequence (UAG).The reassignment of CUN codons to threonine during yeast mitochondrial evolution could have proceeded by the disappearance of CUN codons from the reading frames of messenger RNA, through mutation mainly to UUR leucine codons as a result of AT pressure. We suggest that this was accompanied by a loss of leucine-accepting ability of tRNA Leu(UAG). This tRNA could have then acquired threonine-accepting activity through the appearance of an additional threonyl-tRNA synthetase. CUN codons that subsequently appeared from mutations of various other codons would have been translated as threonine. This change in the yeast mitochondrial genetic code is likely to have evolved through a series of nondisruptive nucleotide substitutions that produced no widespread replacement of leucine by threonine in proteins as a consequence.     

Leucine regulation of the ilvGEDA operon of Serratia marcescens by attenuation is modulated by a single leucine codon.

The effect of leucine limitation and of restricted leucine tRNA charging on the expression of the ilvGEDA operon of Serratia marcescens was examined. In this organism, the ilv leader region specifies a putative peptide containing only a single leucine codon that could be involved in leucine-mediated control by attenuation (E. Harms, J.-H. Hsu, C. S. Subrahmanyam, and H. E. Umbarger, J. Bacteriol. 164:207-216, 1985). A plasmid (pPU134) containing the DNA of the S. marcescens ilv control region and three of the associated structural genes was studied as a single chromosomal copy in an Escherichia coli strain auxotrophic for all three branched-chain amino acids. The S. marcescens ilv genes responded to a multivalent control similar to that found in other enteric organisms. Furthermore, the S. marcescens ilv genes were derepressed when the charging of leucine tRNA was restricted in a leuS derivative of E. coli that had been transformed with pPU134. It was concluded that ribosome stalling leading to deattenuation is not dependent on either tandem or a consecutive series of codons for the regulatory amino acid. However, the fact that the single leucine codon is a less frequently used codon (CUA) may be important. The procedure for obtaining the cloned ilv genes in single chromosomal copy exploited the dependence of ColE1 replicons on the polA gene. The cloning experiments also revealed a branched-chain amino acid-glutamate transaminase in S. marcescens that is different from transaminase B.