Relationships Between the Regulation of the Lactose and Galactose Operons of Escherichia coli

A group of structurally related compounds, including galactose, fucose, and a number of galactosides, are regulatory effectors for both the lac and gal operons of Escherichia coli. Although a common set of effectors exists, each operon appears to be regulated independently of the other. Experiments with various regulatory mutants have shown, first, that the presence of the proteins of one operon is without effect on the regulation of the other and, second, that the influence an effector has on one operon is independent of the presence or the functional state of the regulatory genes of the other operon. It is unlikely, therefore, that the two operons share a common regulatory macromolecule. Both gal R(-) and gal o(c) regulatory mutants are equally resistant to repression by glucose and galactosides. It has been possible to show, in the gal operon, that induction and repression are competitive processes. For this operon, the differential rate of enzyme synthesis is set by the relative intracellular concentrations of inducer (fucose) and repressor (isopropylthiogalactoside).     

Isolation and characterization of regulatory mutations affecting the expression of the guaBA operon of Escherichia coli K-12

Summary We isolated strains of Escherichia coli K 12 in which the lac structural genes were fused to the structural genes of the guaBA operon. These strains were used to isolate regulatory mutations that increased the expression of the guaBA operon under normal repressing conditions as compared to the wild type parental fusion strain. Three classes of guaBA specific regulatory mutations were identified. Class I regulatory mutations were trans-acting and unlinked to the guaBA operon as shown by bacteriophage P1 transduction. Class II regulatory mutations were tightly linked to the guaBA operon, cis-dominant to the wild type allele in a cis-trans analysis and were regarded as control region mutations. Class III regulatory mutations were tightly linked to the guaBA operon and trans-recessive to the wild type allele in a cis-trans analysis. We have designated the locus responsible for the class III regulatory mutations as guaR. The guaR locus is tightly linked and was mapped to the counterclockwise side of the guaBA operon. The guaR locus is proposed to specify a trans acting regulatory element involved in the regulation of the guaBA operon.     

Genetic regulation of the constitutive D-ribose operon in Escherichia coli B/r.

Merodiploid complementation analysis of the constitutive synthesis of the D-ribokinase and the D-ribose permease in Escherichia coli B/r has shown that the constitutive D-ribose operon is genetically controlled by a transdominant regulatory gene closely linked to the D-ribokinase and D-ribose permease structural genes. The regulatory mechanism for this operon shows no requirement for operator-repressor interaction, rather a truly positive control mechanism and thus suggests an extension of the operon model in its application to constitutive enzyme regulation in bacteria.     

A second positive regulatory function in the mer (mercury resistance) operon

Transpositional mutagenesis of the mer operon of the IncFII plasmid, R100, has revealed a second, trans-acting positive regulatory function. Mutants in this function do not synthesize any of the three small mer operon peptides and have no inducible Hg(II) uptake activity. This second regulatory function is part of complementation group B and so depends upon the activity of the previously described trans-acting positive regulatory function merR. All mutants in this new function map in the amino-terminal 20 kDal of the Hg(II) reductase, suggesting either that this enzyme is also a regulatory protein or that there is a distinct protein whose reading frame is superimposed on that of the Hg(II) reductase. While we have only seen the five previously described mer operon peptides of 69, 66, 15.1, 14 and 12 (13) kDal encoded in minicells by single-copy plasmids, we have observed two new HgCl2-inducible polypeptides of approx. 20 kDal in minicells carrying a multicopy derivative of the mer operon of R100. Sequence data for the Hg(II) reductase region of the related mer operon of the transposon, Tn501 [Brown, N.L., Ford, S.J., Pridmore, R.D. and Fritzinger, D.C., Biochemistry 22 (1983) 4089-4095], shows a second reading frame very rich in cysteine and arginine which overlaps the amino-terminal 20 kDal of the Hg(II) reductase structural gene. We believe that this reading frame is the structural gene for this new regulatory function and propose the name merC (for control).     

Control of temperature-dependent synthesis of K99 fimbriae

The influence of temperature on the production of K99 fimbriae by Escherichia coli was determined in cultures growing at constant specific growth rate in continuous cultures. In a wild type strain, in which the K99 operon is present on a low copy number plasmid, low cultivation temperature repressed the K99 production. This temperature-dependent production was not observed after introduction of multicopies of the regulatory region of the K99 operon into this strain, nor in E. coli K12 harbouring a recombinant, multicopy plasmid encoding the K99 operon. These results are in agreement with a regulation model in which a regulatory factor, most likely a repressor, inhibits expression of the K99 operon at low temperatures.     

The Escherichia coli K-12 cyn operon is positively regulated by a member of the lysR family.

A regulatory gene, cynR, was found to be located next to the cyn operon but transcribed in the opposite direction. cynR encodes a positive regulatory protein that controls the cyn operon as well as its own synthesis. Positive regulation of the cyn operon requires cyanate and the cynR protein, but the negative autoregulation of the cynR gene appears to be independent of cyanate. The predicted amino acid sequence of the cynR protein derived from the DNA sequence was found to have significant homology to the predicted amino acid sequence of the lysR family of regulatory proteins.     

Molecular analysis of the lac operon encoding the binding-protein-dependent lactose transport system and β-galactosidase in Agrobacterium radiobacter

The genes coding for the binding-protein-dependent lactose transport system and beta-galactosidase in Agrobacterium radiobacter strain AR50 were cloned and partially sequenced. A novel lac operon was identified which contains genes coding for a lactose-binding protein (lacE), two integral membrane proteins (lacF and lacG), an ATP-binding protein (lacK) and beta-galactosidase (lacZ). The operon is transcribed in the order lacEFGZK. The operon is controlled by an upstream regulatory region containing putative -35 and -10 promoter sites, an operator site, a CRP-binding site probably mediating catabolite repression by glucose and galactose, and a regulatory gene (lacl) encoding a repressor protein which mediates induction by lactose and other galactosides in wild-type A. radiobacter (but not in strain AR50, thus allowing constitutive expression of the lac operon). The derived amino acid sequences of the gene products indicate marked similarities with other binding-protein-dependent transport systems in bacteria.     

Instability in tyrR Strains of Plasmids Carrying the Tyrosine Operon: Isolation and Characterization of Plasmid Derivatives with Insertions or Deletions

The transformation of tyrR strains of Escherichia coli with multicopy plasmids which carry the tyrosine operon gave rise to modified plasmids with either insertions or deletions. The effect of each of these insertions or deletions was to decrease the level of expression of this operon. It is proposed that plasmid instability arose as a direct consequence of the metabolic effects of an overproduction of the enzymes coded for by the tyrosine operon. The results have significant implications for the cloning of genes that are repressed by the product of a regulatory gene. Since the predominant plasmid modification observed was the insertion of an IS1 element near the regulatory region of the tyrosine operon, the results also suggest a role for IS1 elements in the regulation of gene expression.