A structural view of the action of Escherichia coli (lacZ) beta-galactosidase.

The structures of a series of complexes designed to mimic intermediates along the reaction coordinate for beta-galactosidase are presented. These complexes clarify and enhance previous proposals regarding the catalytic mechanism. The nucleophile, Glu537, is seen to covalently bind to the galactosyl moiety. Of the two potential acids, Mg(2+) and Glu461, the latter is in better position to directly assist in leaving group departure, suggesting that the metal ion acts in a secondary role. A sodium ion plays a part in substrate binding by directly ligating the galactosyl 6-hydroxyl. The proposed reaction coordinate involves the movement of the galactosyl moiety deep into the active site pocket. For those ligands that do bind deeply there is an associated conformational change in which residues within loop 794-804 move up to 10 A closer to the site of binding. In some cases this can be inhibited by the binding of additional ligands. The resulting restricted access to the intermediate helps to explain why allolactose, the natural inducer for the lac operon, is the preferred product of transglycosylation.     

The necessity of magnesium cation for acid assistance aglycone departure in catalysis by Escherichia coli (lacZ) beta-galactosidase.

1. Removal of Mg2+ from Escherichia coli (lacZ) beta-galactosidase slightly increases the rate of hydrolysis of galactosyl pyridinium salts, but decreases the rate of hydrolysis of arylgalactosides. 2. Fair correlation of logkcat. and log (Km) with the pKa of aglycone is now observed for arglygalactosides, as well as for glycosyl pyridinium salts. 3. Degalactosylation of Mg2+-free enzyme is the rate-limiting step in the hydrolysis of 2,4-dinitrophenyl galactoside. 4. alpha-Deuterium kinetic isotope effects for both sets of substrates are consistent with the rate-determining generation of a glycosyl cation. 5. The pH-independent, SNl hydrolysis of 3,4-dinitrophenyl galactoside has been measured: it is as fast as that of the galactosyl 3-chloropyridinium ion. 6. Hydrolysis of these two substrates by Mg2+-free enzyme proceeds at very similar rates. 7. It is concluded that loss of both types of aglycone takes place, without acid catalysis, from the first ES complex of substrate and apoenzyme. 8. Data for galactosyl azide and thiopicrate confirm that neither charge nor change of atom is the cause of the differences in behavior between aryl galactosides and galactosylpyridinium salts.     

Reversion reactions of beta-galactosidase (Escherichia coli)

The reversion reactions of beta-galactosidase (Escherichia coli) produced beta-galactosyl-galactoses and beta-galactosyl-glucoses. About 10 beta-galactosyl-galactose and 10 beta-galactosyl-glucose gas-liquid chromatographic peaks were detected and it is thus very likely that every possible isomer of beta-galactosyl-galactose and beta-galactosyl-glucose was formed by the reversion reactions (taking into account both anomers for each isomer). The presence of lactose and allolactose among the beta-galactosyl-glucoses was confirmed with standards. An important finding relating to the role of allolactose as an inducer of the lac operon was that allolactose (beta-D-galactosyl-(1----6)-D-glucose) was the only disaccharide formed initially, and at equilibrium it was present in the largest amount (50%). Obviously the enzyme is specific in its ability to form allolactose, and allolactose is the most stable beta-galactosyl-glucose, both important inducer properties. The equilibrium constant (concentration of disaccharides divided by the concentration of reactants at equilibrium) of the reaction was about 9.5 mM-1. This is the first report of an equilibrium constant for the beta-galactosidase reaction. Of mechanistic significance is the fact that only three compounds were able to replace D-galactose as a reversion reactant. Two of these (L-arabinose and D-fucose) had alterations at carbon 6. The 6 position, therefore, is not essential for reactivity. The third compound was D-galactal. Any other sugars tested (even with very minor changes relative to D-galactose) did not react. Of special consequence is the 2 position. The results strongly suggest that there has to be either an equatorial hydroxyl at the 2 position of a sugar or a special reactivity (as with D-galactal) in order for the enzyme to catalyze the beta-galactosidase reaction.     

Sites within gene lacZ of Escherichia coli for formation of active hybrid beta-galactosidase molecules.

We describe the genetic analysis of 21 Escherichia coli strains in which the amino-terminal sequence of beta-galactosidase has been removed and replaced by an amino-terminal sequence from one or another of the proteins involved in maltose transport. Genetic mapping of the lacZ end of these fused genes indicates that only those fusions in which fewer than 41 amino acids are removed from the amino-terminal sequence of beta-galactosidase result in enzymatically active molecules. Within the region between amino acid 17 and amino acid 41 there are at least four or five sites where enzymatically active hybrid proteins can be formed.     

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.     

Energy transduction during catalysis by Escherichia coli DNA photolyase.

Native DNA photolyase from Escherichia coli contains 1,5-dihydroFAD (FADH2) plus 5,10-methenyltetrahydropteroylpolyglutamate. Quantum yield and action spectral data for thymine dimer repair were obtained by using a novel multiple turnover approach under aerobic conditions. This method assumes that catalysis proceeds via a (rapid-equilibrium) ordered mechanism with light as the second substrate, as verified in steady state kinetic studies. The action spectrum observed with native enzyme matched its absorption spectrum and an action spectrum simulated based on an energy transfer mechanism where dimer repair is initiated either by direct excitation of FADH2 or by pterin excitation followed by singlet-singlet energy transfer to FADH2. The quantum yield observed for dimer repair with native enzyme (phi Native = 0.722 +/- 0.0414) is similar to that observed with enzyme containing only FADH2 (phi EFADH2 = 0.655 +/- 0.0256), as expected owing to the high efficiency of energy transfer from the natural pterin to FADH2 [EET = 0.92]. The quantum yield observed for dimer repair decreased (2.1-fold) when the natural pterin was partially (68.8%) replaced with 5,10-CH(+)-H4folate (phi obs = 0.342 +/- 0.0149). This is consistent with the energy transfer mechanism (phi calc = 0.411 +/- 0.0118) since a 2-fold lower energy transfer efficiency is observed when the natural pterin is replaced with 5,10-CH(+)-H4folate (EET = 0.46) (Lipman & Jorns, 1992). The action spectrum observed for 5,10-CH(+)-H4folate-supplemented enzyme matched a simulated action spectrum which exhibited a small (5 nm) hypsochromic shift as compared with the absorption spectrum (lambda max = 385 nm).(ABSTRACT TRUNCATED AT 250 WORDS)     

Linker mutagenesis in the lacZ gene of Escherichia coli yields variants of active beta-galactosidase

Synthetic octameric oligonucleotides that code for a unique restriction site were cloned into a randomly linearized plasmid that carries the lacZ gene. The insertions were mapped by digestion with appropriate restriction endonucleases. 12 mutants were identified which carry an insertion within the lacZ gene and still express active beta-galactosidase. Small deletions or duplications of the wild-type sequence occurred at these positions which restore the correct reading frame. The insertions occurred in the first and the last third of the internal duplication of the lacZ gene and within the domain homologous to dihydrofolate reductase.     

Insertion of d(pCpG)n.d(pCpG)n into the lacZ gene of Escherichia coli inhibits expression of beta-galactosidase in vivo

Plasmids that contain a d(pCpG)13.d(pCpG)13 insert instead of a lac operator show a 34-fold decrease of beta-galactosidase synthesis. The same sequence causes a 24-fold decrease when inserted between codons 5 and 6 of the lacZ gene. In such constructs with d(pCpG)n.d(pCpG)n inserts, beta-galactosidase activity decreases approximately 1.6-fold per d(pCpG).d(pCpG) unit when n ranges from 5 to 16.     

Crystallization of beta-galactosidase from Escherichia coli.

Two crystal forms of beta-galactosidase have been obtained from Escherichia coli. One crystal form is hexagonal space group P6222 or enantiomorph, with cell dimensions a = b = 154 A, c = 750 A. The second form is monoclinic, space group P21, with cell dimensions a = 107.9 A, b = 207.5 A, c = 509.9 A, beta = 94.7 degrees. The monoclinic form seems better suited to detailed structural analysis. The crystals are radiation-sensitive, but by using synchrotron radiation in conjunction with a long (400 mm) crystal-to-film distance it was possible to resolve the individual reflections. On the basis of crystal density measurements, there are four tetramers each of molecular weight 465,000 per asymmetric unit. The Patterson function strongly suggests that two of the tetramers are related to the other two by translation. The data are consistent with the tetramers having 222 point symmetry, but this is not proven.     

Efflux of beta-galactosidase products from Escherichia coli.

Several different strains of Escherichia coli were grown on a variety of carbon sources under various growth conditions. Lactose was added (usually at mid-log phase), and the concentrations of the products of beta-galactosidase action on this sugar (galactose, glucose, and allolactose) were determined at various times thereafter in the total culture and in the medium. It was found that with each strain, with all carbon sources, and under all of the conditions studied, a very large proportion of the products were found in the medium. Control studies were carried out which showed that these results were not artifacts of the method of separating the cells from the medium. The results also did not arise from the secretion of beta-galactosidase into the medium, from the diffusion of substrates and products into and out of the cells due to leaks in the membrane, or from faults in the method of sugar analysis. In addition, the results showed that there were very high levels of products inside the cells under the conditions used and that the efflux of the products was rapid. The efflux might be energetically advantageous to the cell as well as being a means of storing excess products until needed.     

Sequence of the lacZ gene of Escherichia coli.

The nucleotide sequence of the lacZ gene coding for beta-galactosidase (EC 3.2.1.23) in Escherichia coli has been determined. Beta-Galactosidase is predicted to consist of 1023 residues, resulting in a protein with a mol. wt. of 116 353 per subunit. The protein sequence originally determined by Fowler and Zabin was shown to be essentially correct and in an Appendix these authors comment on the discrepancies.     

Metal ion requirement by glutamine synthetase of Escherichia coli in catalysis of gamma-glutamyl transfer.

The requirement for metal ions by glutamine synthetase of Escherichia coli in catalyzing the γ-glutamyl transfer reaction has been investigated. In order of decreasing V at pH 7.0, Cd²⁺, Mn²⁺, Mg²⁺, Ca²⁺, Co²⁺, or Zn²⁺ will support the activity of the unadenylylated enzyme in the presence of ADP. With AMP substituted for ADP to satisfy the nucleotide requirement, only Mn²⁺ or Cd²⁺ will support the activity of the unadenylylated enzyme. Kinetic and equilibrium binding measurements show a 1:1 interaction between the nonconsumable substrate ADP and each enzyme subunit of the dodecamer. (To obtain this result, each enzyme subunit must be active in catalyzing γ-glutamyl transfer.) The stability constant of the unadenylylated subunit for ADP-Mn is 3.5 × 10⁵m^?1, or ～2.86 × 10⁷m^?1 under assay conditions, with arsenate, Mn²⁺, and glutamine being responsible for this large affinity increase. Saturation of two Mn²⁺ ion-binding sites per enzyme subunit is absolutely required for activity expression. While apparently not affecting the affinity of the first Mn²⁺ bound (K′ = 1.89 × 10⁶ M^?1), glutamine increases the stability constant for the second Mn²⁺ bound from 2 × 10⁴ to 5.9 × 10⁵m^?1. Reciprocally, increasing Mn²⁺ concentrations decreases the apparent K_m′ value for glutamine. Glutamine (by producing a net uptake of protons in binding to the enzyme) is responsible for changing the proton release from 3 to about 1 for 2 Mn²⁺ bound per enzyme subunit, with ～0.5 H⁺ displaced in both fast and slow processes. The uv spectral change induced by the binding of the first Mn²⁺ to each enzyme subunit remains unchanged by the presence of glutamine. However, glutamine reduces the half-time of the spectral change or slow proton release from ～30 to ～20 sec at 37 °C. Binding and kinetic results indicate a mechanism involving a random addition of Mn²⁺ to two subunit sites. Saturation of the high-affinity site with Mn²⁺ induces a conformational change to an active configuration, while activity expression depends also on the saturation of a second Mn²⁺ binding site (at or near the catalytic site). Once the first Mn²⁺ binding site of the subunit is saturated, an active enzyme complex can be formed either by the sequential binding of Mn²⁺ and ADP at the second site or by the binding of ADP-Mn complex directly to this site if the concentration of ADP-Mn is greater than 10^?8m in the assay. Some additional observations on the binding of Mg²⁺, Ba²⁺, Ca²⁺, and Zn²⁺ to the enzyme are presented.     

A rapid and simple chemiluminescent assay for Escherichia coli beta-galactosidase.

We describe a chemiluminescent assay for E. coli beta-galactosidase using Lumi-Gal 530, a commercial formulation containing a stable phenylgalactose-substituted dioxetane as the substrate. Removal of the galactose moiety leads to the generation of an unstable dioxetane which decomposes to provide the observed chemiluminescence which is measured with a luminometer. Advantages of the assay are that it is simple, inexpensive and has 20-fold greater sensitivity than the standard spectrophotometric assay. Additional advantages are that the dioxetane is quite stable in the commercial formulation, and beta-galactosidase functions efficiently and is not degraded during the course of an assay. As luminometers are becoming commonplace in molecular biology laboratories, this assay provides a preferable alternative to the spectrophotometric assay.     

His-391 of beta-galactosidase (Escherichia coli) promotes catalyses by strong interactions with the transition state.

His-391 of beta-galactosidase (Escherichia coli) was substituted by Phe, Glu, and Lys. Homogeneous preparations of the substituted enzymes were essentially inactive unless very rapid purifications were performed, and the assays were done immediately. The inactive enzymes were tetrameric, just like wild-type beta-galactosidase and their fluorescence spectra were identical to the fluorescence spectrum of wild-type enzyme. Analyses of two of the substituted enzymes that were very rapidly purified to homogeneity and rapidly assayed while they were still active (at only a few substrate concentrations so that the data could be rapidly obtained), showed that the kinetic values were very similar to the values obtained with the same enzymes that were only partially purified. This showed that the kinetics were not affected by the degree of purity and allowed kinetic analyses with partially purified enzymes so that large numbers of points could be used for accuracy. The data showed that His-391 is a very important residue. It interacts strongly with the transition state and promotes catalysis by stabilizing the transition state. Activation energy differences (deltadelta G(S) double dagger), as determined by differences in the kcat/Km values, indicated that substitutions for His-391 caused very large destabilizations (22.8-35.9 kJ/mol) of the transition state. The importance of His-391 for transition state stabilization was confirmed by studies that showed that transition state analogs are very poor inhibitors of the substituted enzymes, while inhibition by substrate analogs was only affected in a small way by substituting for His-391. The poor stabilities of the transition states caused significant decreases of the rates of the glycolytic cleavage steps (galactosylation, k2). Degalactosylation (k3) was not decreased to the same extent.     

Tyr-503 of beta-galactosidase (Escherichia coli) plays an important role in degalactosylation.

Substitutions for Tyr-503 of beta-galactosidase caused large decreases of the activity. Both the galactosylation (k2) and degalactosylation (k3) rates were decreased. Substitutions by residues without transferable protons, caused k3 to decrease much more than k2 while substitutions with residues having transferable protons, caused approximately equal decreases of k2 and k3. Several lines of evidence showed this. The Km values of the substituted enzymes were much smaller than those for the wild type if the substituted amino acid residues did not have transferable protons; this was not the case when the substituted residues had transferable protons. Inhibition studies showed that the Km values were not small because of small Ks values but were small because of relatively small k3 values (compared with the k2 values). The conclusion that the k3 values are small relative to k2 upon substitution with residues without transferable protons is also based upon other studies: studies indicating that the reaction rates were similar with different substrates, studies in the presence of alcohol acceptors, studies showing that the rate of inactivation by 2,4-dinitrophenyl-2-deoxy-2-F-beta-D-galactopyranoside decreased much less than the rate of reactivation; studies on burst kinetics, and pH studies. The data suggest that Tyr-503 may be important for the degalactosylation reaction because of its ability to transfer protons and thereby facilitate cleavage of the transient covalent bond between galactose and Glu-537.