Dependence of lactose metabolism upon mutarotase encoded in the gal operon in Escherichia coli.

A new gene (galM) has been identified as the fourth cistron of the gal operon, encoding enzymes for the metabolism of galactose and lactose in Escherichia coli. Induction of the gal operon either from the gal promoters or from a neighboring prophage lambda promoter expresses the galM gene as well. The new structure of the gal operon from the promoter end is galE-galT-galK-galM in counter-clockwise orientation on the chromosome. Genetic and biochemical analyses have revealed that the galM gene product has mutarotase activity, which converts alpha-aldose to the beta-anomer. Unlike mutarotase from other bacteria in which the enzyme is primarily processed for export and secretion, the mutarotase from E. coli does not appear to be processed and yet is still found in periplasm (and culture media when overexpressed) in significant amounts. Although the interconversion of the sugar anomers occurs spontaneously in pure water in vitro, the in vivo formation of alpha-D-galactopyranose (the substrate for phosphorylation) from beta-D-galactopyranose (generated by beta-galactosidase hydrolysis of lactose) is largely dependent upon the presence of the mutarotase. This shows that efficient lactose metabolism requires mutarotase. These results give credence to the idea that the activity of intracellular water is not high enough to permit a simple extrapolation of observed in vitro reactions to in vivo situations in every case.

Detection of conformational and net charge differences in DNA-protein complexes by quantitative electrophoresis on polyacrylamide-agarose copolymer gels.

The Galactosidase repressor (GalR) of Escherichia coli modulates the expression of the gal operon by binding to two DNA operators, OE and O1. The OE and O1 elements are 16 bp pallindromic DNA sequences, differing in four of the base pairs. OE and O1 DNA fragments, both free and complexed with repressor, were analyzed by "quantitative gel electrophoresis". By the criteria of that method, applied to the linear Ferguson plots of both DNA fragments and the linear ranges of those of the DNA-GalR complexes, it was shown that the apparent size of DNA increases upon repressor binding. Moreover, this size increase is greater for the complex with the O1 operator than for the complex with the OE operator in the case that GalR is located in the center of a 155 bp DNA fragment. This is not the case when GalR is located in a peripheral position. By contrast with their size differences, the centrally located GalR-O1 and GalR-OE complexes appear to possess indistinguishable net surface charge densities as judged from the intercepts with the mobility axis. The larger size of the complex with centrally located O1 fragment, as compared with that bearing the OE fragment, is interpreted as being due to bending of the DNA-protein complex, since an authentically bent fragment of a plasmid with bent upstream activator sequence also exhibits a larger slope of the Ferguson plot, and thus the larger size, than predicted on the basis of its DNA chain length (bp).(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular cloning of Ehrlichia risticii and development of a gene probe for the diagnosis of Potomac horse fever.

A gene bank of Ehrlichia risticii was constructed in plasmid vector pUC13. Five clones representing discrete regions of the E. risticii genome were tested for their ability to hybridize specifically to E. risticii DNA. None of the clones cross-hybridized with Ehrlichia equi DNA, whereas four of these clones cross-hybridized with Ehrlichia canis and Ehrlichia sennetsu DNAs. However, one clone carrying a 1-kilobase HindIII fragment of E. risticii DNA failed to cross-react with the genomes of E. sennetsu, E. canis, and E. equi in dot blot hybridization assays. The sensitivity of this probe for the detection of E. risticii DNA was approximately 0.5 pg. By using this probe, the E. risticii DNA was detected in the peripheral blood mononuclear cells of 30 experimentally infected horses by 7 days postinfection (p.i.); the detection of E. risticii DNA peaked between 14 and 17 days p.i., a period immediately after the peak of the second rise in body temperature, during leukopenia and at the onset of diarrhea. E. risticii DNA was not detectable by 25 to 30 days p.i. E. risticii DNA was not detected in noninfected control horses.

Escherichia coli gal operon proteins made after prophage lambda induction.

Expression of the EScherichia coli gal operon under the control of the prophage lambda promoter pL leads to gross discoordinacy of gal expression. Expression of the most promoter-distal cistron galK is much greater than expression of the promoter-proximal cistron galE. We had previously shown that transcription of the gal operon is coordinate after prophage induction. A survey of protein synthesized after prophage induction indicated that lack of expression of galE is due to a failure of translation of the galE sequence in the pL-gal transcript. This failure of translation of the galE sequence may be due to extensive dyad symmetry present in the vicinity of the gal promoter region of the pL-gal transcript. This symmetry could result in a ribonucleic acid stem-loop structure, blocking the attachment of ribosomes at the Shine-Dalgarno sequence of galE. To test this model, strains bearing the IS1 or IS2 insertion, deletion, or new promoter mutation within the symmetrical region were constructed. The restoration of some galE expression after such disruptions of the symmetrical region indicated that the ribonucleic acid stem-loop structure did play a role in the discoordinate expression of gal from pL. However, failure to obtain galE expression coordinated with high levels of galK expression suggested that other components were involved, perhaps other symmetries between galE and the pL transcript.

Evidence that ribosomal protein S10 participates in control of transcription termination.

We report the isolation of an Escherichia coli K-12 strain with a mutation, nusE71, that results in a change in ribosomal protein S10. Phage lambda fails to grow in hosts carrying the nusE71 mutation because the lambda N gene product is not active. The N product regulates phage gene expression by altering transcription complexes so that they can overcome termination barriers. This suggests that a ribosomal protein is involved in antitermination of transcription.