The action of beta-galactosidase (Escherichia coli) on allolactose.

The parameters involved in the action of beta-galactosidase (EC 3.2.1.23) (Escherichia coli) on allolactose, the natural inducer of lac operon in E. coli, were studied. At low allolactose concentrations only galactose and glucose were formed, while at high allolactose concentrations transgalactolytic oligosaccharides were also produced. Detectable amounts of lactose were not formed. The V and Km values (49.6 U/mg and 0.00120 M, respectively) indicated that allolactose is as good if not a better substrate of beta-galactosidase as lactose. The pH optimum with allolactose (7.8-7.9) as well as its activation by K+ (as compared to activation by Na+) were similar to the case with lactose as substrate. The alpha-anomer of allolactose was hydrolyzed about two times as rapidly as was the beta-anomer.     

Genomic hsd-Mu(lac) operon fusion mutants of Escherichia coli K-12.

Genomic (chromosomal)hsd-Mu(lac) operon fusions have been constructed in two strains of Escherichia coli K-12 for the three hsd genes, hsdRK, hsdMK and hsdSK, using MudX and lambda placMu53. Expression of hsdK mutants ranged from 16 to 74 units (u) (with a mean of 52 u) for fusions to promoter pres and ranged from 26-75 u (also with a mean of 52 u) for fusions to promoter pmod. The expression of the two hsdK promoters was measured in different stages of growth. The pres fusion mutant showed a lag in beta-galactosidase (beta Gal) production, as compared to the pmod fusion mutant. One r-Km-K mutant (JR205) showed more than ten times the beta Gal activity of other insertion mutants. The activity of this mutant decreased by 20-fold upon the transfer of F101-102, which includes the wild-type hsd region. Positive gene-dosage effect was observed using F' plasmids containing the hsd-lacZ region.     

Glu-537, not Glu-461, is the nucleophile in the active site of (lac Z) beta-galactosidase from Escherichia coli.

The covalent intermediate formed during catalysis by the lac Z beta-galactosidase from Escherichia coli can be trapped by reaction of the enzyme with 2',4'-dinitrophenyl 2-deoxy-2-fluoro-beta-D-galactopyranoside, thereby inactivating the enzyme. Kinetic parameters for this inactivation process with the holo- and apo-enzymes have been determined. The intermediate so formed turns over only very slowly (t1/2 = 11.5 h) resulting in reactivation of the enzyme. The nucleophilic amino acid involved has been identified as Glu-537 by using a tritium-labeled inactivator to label the enzyme, then cleaving the labeled protein into peptides and purifying and sequencing the labeled peptide. This residue is conserved in five homologous beta-galactosidases and is different from that (Glu-461) proposed to be the nucleophile (Herrchen, M., and Legler, G. (1984) Eur. J. Biochem. 138, 527-531) on the basis of affinity labeling studies with conduritol C cis-epoxide. A role for glutamic acid residue 461 as the acid/base catalyst is proposed and justified.     

Corepressor system for catabolite repression of the lac operon in Escherichia coli

Acetylated amino sugars, normally used in the biosynthesis of cell walls and cell membranes, were found to play a role as corepressors for catabolite repression of the lac operon in Escherichia coli. This conclusion was derived from studies conducted on mutants of E. coli that were able to assimilate an exogenous source of N-acetylglucosamine (AcGN) but were unable to dissimilate or grow on this compound. At concentrations less than 10(-4)m, AcGN caused severe catabolite repression of beta-galactosidase synthesis in cultures grown under either nonrepressed or partially repressed conditions. This repression occurred in the absence of any effect of AcGN on either the carbon and energy metabolism or the growth of the organism. In addition, this repression by AcGN occurred in a mutant strain that is constitutive for beta-galactosidase production, demonstrating that the AcGN effect does not involve the uptake of inducer. This model for the corepressor system of catabolite repression is discussed in relation to the existing theories on repression of the lac operon.     

Lack of evidence for horizontal transfer of the lac operon into Escherichia coli

The idea that Escherichia coli gained the lac operon via horizontal transfer, allowing it to invade a new niche and form a new species, has become a paradigmatic example of bacterial nonpathogenic adaptation and speciation catalyzed by horizontal transfer. Surprisingly, empirical evidence for this event is essentially nonexistent. To see whether horizontal transfer occurred, I compared a phylogeny of 14 Enterobacteriaceae based on two housekeeping genes to a phylogeny of a part of their lac operon. Although several species in this clade appear to have acquired some or all of the operon via horizontal transfer, there is no evidence of horizontal transfer into E. coli. It is not clear whether the horizontal transfer events for which there is evidence were adaptive because those species which have acquired the operon are not thought to live in high lactose environments. I propose that vertical transmission from the common ancestor of the Enterobacteriaceae, with subsequent loss of these genes in many species can explain much of the patchy distribution of lactose use in this clade. Finally, I argue that we need new, well-supported examples of horizontal transfer spurring niche expansion and speciation, particularly in nonpathogenic cases, before we can accept claims that horizontal transfer is a hallmark of bacterial adaptation.     

Asp-863 is a key residue for calcium-dependent activity of Escherichia coli RTX toxin alpha-haemolysin

alpha-Haemolysin is a protein toxin secreted by pathogenic strains of Escherichia coli and requires sub-millimolar Ca(2+) for optimum lytic activity. As a member of the so-called RTX toxin family it contains a Gly-rich, Asp-rich Ca(2+)-binding domain, consisting of a series of nonapeptides repeated in tandem. Asp-863 is located immediately after the last-but-one nonapeptide. A mutant in which Asp-863 has been substituted by Gly displays a requirement for Ca(2+) that is 100-fold higher than the wild-type. Membrane lytic activity, as well as a conformational change revealed through an increase in intrinsic fluorescence, and the appearance of Ca(2+)-bound protein monomers resolvable by fast protein liquid chromatography, are all three dependent on Ca(2+) concentrations in the 2-20 mM range. Most RTX toxins have an Asp or Glu residue located at a position homologous to Asp-863, thus the key role of this residue for Ca(2+) requirements of alpha-haemolysin may be a general feature of this family of toxins.     

Ground-state, transition-state, and metal-cation effects of the 2-hydroxyl group on beta-D-galactopyranosyl transfer catalyzed by beta-galactosidase (Escherichia coli, lac Z)

Substitution of the C2-OH group by C2-H at 4-nitrophenyl-beta-d-galactopyranoside to give 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside causes (1) a change in the rate-determining step for beta-galactosidase-catalyzed sugar hydrolysis from formation to breakdown of a covalent intermediate; (2) a 14 000-fold decrease in the second-order rate constant k(3)/K(d) for enzyme-catalyzed transfer of the beta-d-galactopyranosyl group from the substrate to form a covalent adduct to the enzyme; and (3) a larger 320 000-fold decrease in the first-order rate constant k(s) for hydrolysis of this covalent adduct. Only a small fraction (ca. 7%) of the 2-OH substituent effect is expressed in the ground-state Michaelis complex, so that the (apparent) strong interactions between the enzyme and 2-OH group that stabilize the transition state for beta-d-galactopyranosyl transfer only develop upon moving from the Michaelis complex to the transition state. Mg(2+) activates beta-galactosidase for cleavage of both 4-nitrophenyl-beta-d-galactopyranoside and 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside. This suggests that Mg(2+) activation does not involve interactions with the 2-OH group. The removal of Mg(2+) from beta-galactosidase causes a change in the rate-determining step for enzyme-catalyzed hydrolysis of 4-nitrophenyl-2-deoxy-beta-d-galactopyranoside from breakdown to formation of the covalent intermediate. The observed 2-OH effect would require a very large (10-11 kcal/mol) stabilization of the transition state for beta-d-galactopyranosyl group transfer to water by interactions between beta-galactosidase and the neutral 2-OH group. We suggest that the apparent effect of the neutral substituent is more simply rationalized by ionization of the 2-OH to form a 2-O(-) anion, which provides effective electrostatic stabilization of the cationic transition state for glycoside cleavage at an active site of relatively low dielectric constant.     

Bistable behavior in a model of the lac operon in Escherichia coli with variable growth rate

This work is a continuation from another study previously published in this journal. Both the former and the present works are dedicated to investigating the bistable behavior of the lac operon in Escherichia coli from a mathematical modeling point of view. In the previous article, we developed a detailed mathematical model that accounts for all of the known regulatory mechanisms in this system, and studied the effect of inducing the operon with lactose instead of an artificial inducer. In this article, the model is improved to account, in a more detailed way, for the interaction of the repressor molecules with the three lac operators. A recently discovered cooperative interaction between the CAP molecule (an activator of the lactose operon) and Operator 3 (which influences DNA folding) is also included in this new version of the model. The growth rate dependence on the rate of energy entering the bacteria (in the form of transported glucose molecules and of metabolized lactose molecules) is also considered. A large number of numerical experiments is carried out with this improved model. The results are discussed in regard to the bistable behavior of the lactose operon. Special attention is paid to the effect that a variable growth rate has on the system dynamics.