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

Effect of alteration of translation error rate on enzyme microheterogeneity as assessed by variation in single molecule electrophoretic mobility and catalytic activity

The role of translation error for Escherichia coli individual β-galactosidase molecule catalytic and electrophoretic heterogeneity was investigated using CE-LIF. An E. coli rpsL mutant with a hyperaccurate translation phenotype produced enzyme molecules that exhibited significantly less catalytic heterogeneity but no reduction of electrophoretic heterogeneity. Enzyme expressed with streptomycin-induced translation error had increased thermolability, lower activity, and no significant change to catalytic or electrophoretic heterogeneity. Modeling of the electrophoretic behaviour of β-galactosidase suggested that variation of the hydrodynamic radius may be the most significant contributor to electrophoretic heterogeneity.

TFIIS enhances transcriptional elongation through an artificial arrest site in vivo

Transcriptional elongation by RNA polymerase II has been well studied in vitro, but understanding of this process in vivo has been limited by the lack of a direct and specific assay. Here, we designed a specific assay for transcriptional elongation in vivo that involves an artificial arrest (ARTAR) site designed from a thermodynamic theory of DNA-dependent transcriptional arrest in vitro. Transcriptional analysis and chromatin immunoprecipitation experiments indicate that the ARTAR site can arrest Pol II in vivo at a position far from the promoter. TFIIS can counteract this arrest, thereby demonstrating that it possesses transcriptional antiarrest activity in vivo. Unexpectedly, the ARTAR site does not function under conditions of high transcriptional activation unless cells are exposed to conditions (6-azauracil or reduced temperature) that are presumed to affect elongation in vivo. Conversely, TFIIS affects gene expression under conditions of high, but not low, transcriptional activation. Our results provide physical evidence for the discontinuity of transcription elongation in vivo, and they suggest that the functional importance of transcriptional arrest sites and TFIIS is strongly influenced by the level of transcriptional activation.

Construction of a multiframe vector to express coding sequences inEscherichia coli

Cloning of foreign DNA fragments for coding sequence analysis in Escherichia coli usually involves sets of three vectors. To simplify this, we constructed an expression vector named pMFV7 containing three ATG codons in different frames downstream of a Shine-Dalgarno sequence, assuming that the ribosome can use any of the three start codons in an alternative manner. Translation beginning at either of the start codons would drive the expression of any coding fragment cloned downstream. To test the feasibility of this proposal, we cloned DNA fragments of the lacZ gene in each of the possible reading frames downstream from pMFV7 start codons. Sequence analysis of the N-terminus regions around the fusion sites indicates that ribosomes indeed initiate translation at each of the three initiation codons. In one case, levels of β-galactosidase activity depended largely on the N-terminus of the translation products. We conclude that pMFV7 may be useful for expressing coding sequences regardless of their reading frame.Key words: translation initiation, in-frame gene cloning, expression vectors.

High resolution refinement of beta-galactosidase in a new crystal form reveals multiple metal-binding sites and provides a structural basis for alpha-complementation

The unrefined fold of Escherichia coli beta-galactosidase based on a monoclinic crystal form with four independent tetramers has been reported previously. Here, we describe a new, orthorhombic form with one tetramer per asymmetric unit that has permitted refinement of the structure at 1.7 A resolution. This high-resolution analysis has confirmed the original description of the structure and revealed new details. An essential magnesium ion, identified at the active site in the monoclinic crystals, is also seen in the orthorhombic form. Additional putative magnesium binding sites are also seen. Sodium ions are also known to affect catalysis, and five putative binding sites have been identified, one close to the active site. In a crevice on the protein surface, five linked five-membered solvent rings form a partial clathrate-like structure. Some other unusual aspects of the structure include seven apparent cis-peptide bonds, four of which are proline, and several internal salt-bridge networks. Deep solvent-filled channels and tunnels extend across the surface of the molecule and pass through the center of the tetramer. Because of these departures from a compact globular shape, the molecule is not well characterized by prior empirical relationships between the mass and surface area of proteins. The 50 or so residues at the amino terminus have a largely extended conformation and mostly lie across the surface of the protein. At the same time, however, segment 13-21 contributes to a subunit interface, and residues 29-33 pass through a "tunnel" formed by a domain interface. Taken together, the overall arrangement provides a structural basis for the phenomenon of alpha-complementation.

Beta-galactosidase enzymatic activity as a molecular probe to detect specific antibodies

The main antigenic region of foot-and-mouth disease virus serotype C1, also called site A, has been inserted in zones of the beta-galactosidase important for the stabilization of the active site, causing important changes in the Km and the specific activity of the resulting enzymes. The peptide is displayed at the surface of the recombinant proteins and, in all the cases, presents a good antigenicity. Among the recombinant proteins constructed, in proteins M278VP1 and M275SVP1 the peptide is inserted in a large loop of the beta-galactosidase (amino acids 272-288) involved in the formation of the activating interface. In these constructs, the binding of the specific antibodies directed to the foreign peptide causes an increase of the beta-galactosidase activity up to about 200%. This phenomenon has been proved using monoclonal antibodies and also using polyclonal sera generated against the peptide. Different hypothesis of the mechanism of modulation upon antibody binding are discussed. This insertion site seems to be sensitive enough to enzymatic modulation mediated by antibody binding. We propose further exploring this insertion site as a tool for a rapid detection of specific antibodies in a quick and simple homogeneous assay based on the colorimetric determination of beta-galactosidase activity.

Insertion of a 27 amino acid viral peptide in different zones of Escherichia coli beta-galactosidase: effects on the enzyme activity

Seven internal, putatively exposed regions of Escherichia coli beta-galactosidase have been explored regarding their tolerance to insertions of large foreign peptides. Small sequence modifications, including amino acid substitutions and small deletions, were introduced into the lacZ gene to generate unique BamHI restriction sites. By using these mutant genes, a 27 amino acid stretch reproducing the hypervariable loop of foot-and-mouth disease virus VP1 protein (site A) was further inserted in predefined regions of the enzyme. Among the 13 resulting engineered proteins only three, carrying sequence modifications within a short region, are active, with only moderate reduction of their specific activities. The identified permissive region, which involves amino acids 275 to 279, seems to be a flexible area that could be appropriate to incorporate and study biological properties of heterologous peptides in correctly folded beta-galactosidase chimeric proteins.

Location of tolerated insertions/deletions in the structure of the maltose binding protein

In a previous study [(1987) J. Mol. Biol. 194, 663-673], we isolated ten insertion/deletion mutants (indels) of the maltose binding protein for which the maltose binding constant was only a little or not at all affected. In this paper, we have localized these mutations in the recently solved three-dimensional structure. Contrary to the general expectation, most of the insertion/deletion modifications occurred within elements of secondary structure. An analysis of the inserted residues for three indels found within alpha helices allowed an interpretation regarding protein structure accommodation to such modifications.

Uses of beta-galactosidase tag in on-line monitoring production of fusion proteins and gene expression in Escherichia coli

A simple method for monitoring and quantifying automatically the production by fermentation of beta-galactosidase fusion proteins, making use of the remaining activity of the beta-galactosidase part, is considered. A hybrid protein carrying the major antigenic domain of foot-and-mouth disease virus C1 joined at the N-terminus of beta-galactosidase has been expressed in Escherichia coli. The yield of the chimeric protein has been monitored by flow injection analysis (FIA) during batch fermentations at laboratory scale, and a high correlation between values of product concentration from FIA and from immunological quantizations has been obtained. Because of the possibility of employing FIA in large-scale experiments, and the high sampling frequency, versatility, and reproducibility offered by this method, we propose FIA as a general, simple, quick, flexible, and reliable instrument for both monitoring the yield of recombinant proteins produced industrially, and performing basic research at laboratory scale.

Insertional mutagenesis of hydrophilic domains in the lactose permease of Escherichia coli

The lactose permease of Escherichia coli is a membrane transport protein postulated to contain a hydrophilic N terminus (hydrophilic domain 1), 12 hydrophobic transmembrane alpha-helices that traverse the membrane in zigzag fashion connected by hydrophilic domains, and a hydrophilic C terminus (hydrophilic domain 13). To test whether the hydrophilic domains are important for function, each domain was independently disrupted by insertion of two or six contiguous histidine residues, and the mutants were characterized with respect to initial rate of lactose transport and steady-state level of accumulation. Remarkably, histidine insertions into 10 out of 13 hydrophilic domains result in molecules that catalyze lactose accumulation effectively, although the initial rate of transport is compromised in certain cases. In contrast, insertions into hydrophilic domain 3, 9, or 10 cause a marked decrease in transport activity. As judged by immunoblots and [35S]methionine pulse-chase experiments, diminished activity is not due to decreased expression of the mutated permeases, defective insertion into the membrane, or increased rates of proteolysis after insertion. The results (i) suggest that most of the hydrophilic domains in the permease do not play an essential role in the transport mechanism and (ii) focus on the region of the permease containing putative helices IX and X as being particularly important for activity.

Sequence of the Kluyveromyces lactis beta-galactosidase: comparison with prokaryotic enzymes and secondary structure analysis

The LAC4 gene encoding the beta-galactosidase (beta Gal) of the yeast, Kluyveromyces lactis, was cloned on a 7.2-kb fragment by complementation of a lacZ-deficient Escherichia coli strain. The nucleotide sequence of the structural gene, with 42 bp and 583 bp of the 5'- and 3'-flanking sequences, respectively, was determined. The deduced amino acid (aa) sequence of the K. lactis beta Gal predicts a 1025-aa polypeptide with a calculated M(r) of 117618 and reveals extended sequence homologies with all the published prokaryotic beta Gal sequences. This suggests that the eukaryotic beta Gal is closely related, evolutionarily and structurally, to the prokaryotic beta Gal's. In addition, sequence similarities were observed between the highly conserved N-terminal two-thirds of the beta Gal and the entire length of the beta-glucuronidase (beta Glu) polypeptides, which suggests that beta Glu is clearly related, structurally and evolutionarily, to the N-terminal two-thirds of the beta Gal. The structural analysis of the beta Gal alignment, performed by mean secondary structure prediction, revealed that most of the invariant residues are located in turn or loop structures. The location of the invariant residues is discussed with respect to their accessibility and their possible involvement in the catalytic process.