Thr region between the operator and first structural gene of the tryptophan operon of Escherichia coli may have a regulatory function

Among a collection of 34 independent mutants with internal deletions in the trp operon of Escherichia coli we found six that fail to recombine with any known point mutant in trpE, the first gene in the operon. These six deletion mutants are regulated normally by tryptophan and thus appear to have the trp operator region intact. However, four of these deletions result in alterations in the maximum level of expression of the trpC, B and A genes when compared with wild type or with an internal deletion of similar length which retains a small operatorproximal segment of trpE. Two of these deletion mutants, trpΔED1 and trpΔED12, have lower levels of the protein products of trpB and trpA than the control strains. In contrast, deletions trpΔED2 and trpΔED102 both markedly increase the levels of the trpB and trpA polypeptides. Deletion mutant trpΔED2 has 3 to 3.5 times and mutant trpΔED102 has seven to eight times as much tryptophan synthetase β₂ and α proteins as the wild-type or deletion control strains. The increase in tryptophan synthetase β₂ and α proteins seen is a consequence of an increase in the level of trp mRNA directing the synthesis of these enzymes. The rate of synthesis of trpBA mRNA is increased in trpΔAED2 about twofold, and in trpΔED102 about four- to sixfold over the control strain. The left-hand deletion end-points of both trpΔED2 and trpΔAED102 have been shown to map to the right of a known trp operator-constitutive mutation and appear to lie before the first translation start codon in trpE (M. Bronson, C. Squires &; C. Yanofsky, unpublished results). We propose that these deletions alter a region between the earliest known trpE point mutation and the trp operator which influences the maximum rate of synthesis of trp operon mRNA.     

Polarity suppressors increase expression of the wild-type tryptophan operon of Escherichia coli

Three new polarity suppressors, selected to relieve the polar effect of nonsense mutations in the tryptophan (trp) and lactose (lac) operons of Escherichia coli, increase expression distal to nonsense mutations in both operons to a greater extent than suA. These suppressors relieve the polarity created by amber, ochre and frameshift mutations with equal efficiency.Two of the three polarity suppressors elevate enzyme synthesis in the wildtype trp operon two- and fivefold, respectively. The increase in enzyme levels is in each case correlated with increased levels and rates of synthesis of structural gene trp messenger RNA. Since expression of all genes is elevated, these findings suggest the existence of a site early in the wild-type trp operon that affects the extent of operon expression. We located the site affected by these two polarity suppressors between the operator and the first structural gene, trpE. Although the third polarity suppressor also relieves mutational polarity efficiently, it has no detectable effect on expression of the wild-type trp operon.     

Genetic fusions that help define a transcription termination region in Escherichia coli

The trpA gene product was analyzed from a class of strains of Escherichia coli K12 in which the lac operon has been fused by deletion to the trp operon. These are strains that have retained the ability to synthesize tryptophan. Two of these strains are shown to make a wild-type trpA product; these strains retain intact all structural genes of the ttrp operon. It is proposed that the lac operon in these strains is fused to a region of the trp operon between trpA, the last gene in the operon, and the region where trp messenger RNA synthesis terminates. The region where trp messenger RNA synthesis terminates thus is distinct from the trp structural genes.     

Different half-lives of messenger RNA corresponding to different segments of the tryptophan operon of Escherichia coli

In genetically derepressed strains (trpR⁻) of Escherichia coli which are growing exponentially, messenger RNA regions corresponding to different segments of the trp operon are labeled with different kinetics, suggesting that operator-proximal and distal regions of trp-mRNA have different half-lives. This conclusion was confirmed by direct measurement of trp-mRNA decay; the half-lives for different mRNA regions at 30 °C were found to be 60 seconds for trpE-mRNA, 75 seconds for trpDC-mRNA, and 95 to 115 seconds for trpBA-mRNA. Deletions of genetic segments within the operator-proximal region of the operon reduce the half-life of trp BA-mRNA. Large deletions which place the BA region near the operator reduce the half-life of trpBA-mRNA to values similar to that of trpE-mRNA in the parental strain. Therefore location in the message rather than primary structure appears to determine the half-life of each mRNA region. Several of the internal deletions have a polar effect on the synthesis of the trpB and trpA polypeptides. However, the reduction in trpBA-mRNA half-life does not appear to be due to polarity because trpBA-mRNA half-life is reduced to the same value in three deletion mutants in which there is a sevenfold difference in polarity. These results are compatible with a model of trp-mRNA degradation in which the initial degradative event occurs near the 5′ end of the mRNA molecule and is followed by over-all degradation in the 3′ direction, with random or non-random delays causing an increase in half-life of about 10% per 1000 nucleotides mRNA. Our findings are not compatible with a model of normal degradation in which the entire mRNA molecule is the target for the initial degradative event.     

Re-initiation of tryptophan operon expression in a promoter deletion strain of Salmonella typhimurium.

Summary A genetic and enzymological study was made of five spontaneous prototrophic revertants of a tryptophan auxotroph of Salmonella typhimurium which carries a deletion extending from the closely linked supX locus into the trp operator-promoter region. The revertants were found to have regained initiation of expression of all five trp genes. Recombinational tests showed that in each case the genetic change responsible for re-initiation is cotransducible with the trp-cysB region of the chromosome. Two different mechanisms leading to re-initiation of trp gene expression were established: (a) an extension of the limits of the original deletion resulting in the fusion of the trp structural genes with a nearby gene or gene set located outside the operator end of trp, and (b) translocation of a duplicate set of the trp structural genes to other chromosomal sites, located operator-distal to the normal trp operon, in such a manner that they are functionally fused to foreign genetic units. One revertant which arose by mechanism (a) was shown to have an extended deletion with one new terminus in trp and the other in the nearby cysB locus. All the revertants exhibit constitutive expression of the trp enzymes, with activities varying among strains from five to forty five times greater than the fully repressed wild type level. The protein product of trpA, the first structural gene of the operon, appears to have been partially damaged by the re-initiation event in at least two strains, while in the other strains, the enzyme appears in preliminary tests to be indistinguishable from that of wild type.