Regulation of the Escherichia coli K-12 uvrB operon

The UV light inducibility of the uvrB operon of Escherichia coli K-12 was previously demonstrated by exploiting a strain in which the gene for the enzyme beta-galactosidase was inserted into the uvrB operon. This insert is now shown to be located within the structural gene for the uvrB enzyme, leaving the regulatory sequences of the operon intact. Analyses to quantitate the induction of this system show that derepression of the operon is first detectable 5 min after UV exposure, with the rate of synthesis increasing to four to six times the uninduced rate during the subsequent 30 min. Induction is unaffected by mutations in other components of nucleotide excision repair. The control of uvrB was found to result from direct repression by the lexA gene product, with the recA gene product playing an indirect role. Nucleotide excision repair thus seems to be part of the SOS response.     

Antipolarity in the ilv operon of Escherichia coli K-12

The genes governing three of the enzymes of the isoleucine-valine biosynthetic pathway form the operon: operator-ilvA-ilvD-ilvE. The enzymes are: ilvA, l-threonine deaminase; ilvD, dihydroxy acid dehydrase; and ilvE, transaminase B. A nonsense mutation in the ilvD gene (D-ochre) and a nonsense mutation in the ilvE gene (E-amber) affect the properties of the proximal gene product, l-threonine deaminase (TD), in addition to inactivating the enzymes produced by the genes in which the mutations have occurred. The D-ochre mutation causes TD to move in diffusion and gel filtration experiments as though it were 30% smaller than the wild-type enzyme. The E-amber mutation causes TD to move in similar experiments as though it were much larger than the wild-type enzyme. Both mutations completely abolish the sensitivity of TD to l-isoleucine, the normal feedback inhibitor of the wild-type enzyme. The effects of the nonsense mutations on TD can be reversed in three ways: by genetic reversion of the D-ochre mutation; by treatment of the altered enzymes with 3.0 m urea; and by forming a heterozygous diploid, containing the wild-type allele as well as the mutant allele of ilvD or ilvE. The results suggest that the subunits of TD undergo abnormal aggregation in the presence of the partial polypeptides produced by the mutant alleles of ilvD or ilvE; multi-enzyme aggregates in extracts of wild type, however, could not be detected.     

The D-allose operon of Escherichia coli K-12.

Escherichia coli K-12 can utilize D-allose, an all-cis hexose, as a sole carbon source. The operon responsible for D-allose metabolism was localized at 92.8 min of the E. coli linkage map. It consists of six genes, alsRBACEK, which are inducible by D-allose and are under the control of the repressor gene alsR. This operon is also subject to catabolite repression. Three genes, alsB, alsA, and alsC, appear to be necessary for transport of D-allose. D-Allose-binding protein, encoded by alsB, is a periplasmic protein that has an affinity for D-allose, with a Kd of 0.33 microM. As was found for other binding-protein-mediated ABC transporters, the allose transport system includes an ATP-binding component (AlsA) and a transmembrane protein (AlsC). It was found that AlsE (a putative D-allulose-6-phosphate 3-epimerase), but not AlsK (a putative D-allose kinase), is necessary for allose metabolism. During this study, we observed that the D-allose transporter is partially responsible for the low-affinity transport of D-ribose and that strain W3110, an E. coli prototroph, has a defect in the transport of D-allose mediated by the allose permease.     

The cloning of the Escherichia coli K-12 deoxyribonucleoside operon

A 6.1-kb EcoRI DNA fragment containing the four structural genes (deoC, deoA, deoB, deoD) of the deoxyribonucleoside operon has been cloned into the plasmid pMFS53. By use of a unique, asymmetrically positioned HindIII site on the 6.1 kb insert, plasmids containing the deoC,deoA genes (pMFS50) or the deoB,deoD genes (pMFS55) have been constructed. Enzyme assays performed on extracts prepared from clones harboring pMFS53, pMFS50 or pMFS55 revealed that each clone possessed amplified deo enzyme levels and that the spectrum of enzyme amplification corresponded to the genetic composition of the plasmids carried by each clone. A plasmid (pMFS50l) having functional deoA, deoB and deoD genes but devoid of the deo regulatory region and a portion of the deoC structural gene has been isolated following treatment of BamHI cleaved pMFS53 and BAL31 nuclease. Comparison of the deo enzyme levels for clones harboring pMFS53 and pMFS501 suggest that plasmid pMFS53 possesses a functional deo regulatory region in addition to the four structural genes of the operon.     

Role of leader peptide synthesis in tryptophanase operon expression in Escherichia coli K-12.

We used site-directed mutagenesis to replace the Escherichia coli tryptophanase (tna) operon leader peptide start codon with AUC. This change greatly decreased the uninduced rate of tna operon expression, and it also lowered the response to inducer. We conclude that leader peptide synthesis plays an essential role in tna operon expression.     

Operator-constitutive mutants in the threonine operon of Escherichia coli K-12.

Three Escherichia coli K-12 mutant strains resistant to DL-alpha-amino-beta-hydroxyvaleric acid were isolated in which the expression of the thr operon is constitutive. The localization and dominance properties of the mutations involved, called thrO, are those of operator mutations. The gene sequence is OABC as suggested by earlier studies.     

Regulatory mutants of the aroF-tyrA operon of Escherichia coli K-12.

The regulatory region of the aroF-tyrA operon was fused to the chloramphenicol acetyltransferase (cat) gene on a plasmid vector. Expression of the cat gene was subject to repression by tyrR+. This fusion was used to isolate regulatory mutants with increased expression of the cat gene in which repression by tyrR+ was affected. Nucleotide sequencing of these mutants has led to the identification of three sites involved in the repression of aroF by tyrR+. The existence of a functional promoter divergently transcribing from the aroF regulatory region was also demonstrated by using the cat fusion vector. The expression of this promoter is also regulated by tyrR+.