Catabolite repression of β-galactosidase synthesis in Escherichia coli

1. Repression by glucose of β-galactosidase synthesis is spontaneously reversible in all strains of Escherichia coli examined long before the glucose has all been consumed. The extent of recovery and the time necessary for reversal differ among various strains. Other inducible enzymes show similar effects. 2. This transient effect of glucose repression is observed in constitutive (i⁻) and permease-less (y⁻) cells as well as in the corresponding i⁺ and y⁺ strains. 3. Repression is exerted by several rapidly metabolizable substrates (galactose, ribose and ribonucleosides) but not by non-metabolized or poorly metabolized compounds (2-deoxyglucose, 2-deoxyribose, phenyl thio-β-galactoside and 2-deoxyribonucleosides). 4. The transient repression with glucose is observed in inducible cells supplied with a powerful inducer of β-galactosidase synthesis (e.g. isopropyl thio-β-galactoside) but not with a weak inducer (lactose); in the latter instance glucose repression is permanent. Diauxic growth on glucose plus lactose can be abolished by including isopropyl thio-β-galactoside in the medium. 5. In some strains phosphate starvation increases catabolite repression; in others it relieves it. Adenine starvation in an adenine-requiring mutant also relieves catabolite repression by glycerol but not that by glucose. Restoration of phosphate or adenine to cells starved of these nutrients causes a pronounced temporary repression. Alkaline-phosphatase synthesis is not affected by the availability of adenine. 6. During periods of transient repression of induced enzyme synthesis the differential rate of RNA synthesis, measured by labelled uracil incorporation in 2min. pulses, shows a temporary rise. 7. The differential rate of uracil incorporation into RNA falls during exponential growth of batch cultures of E. coli. This is equally true for uracil-requiring and non-requiring strains. The fall in the rate of incorporation has been shown to be due to a real fall in the rate of RNA synthesis. The significance of the changes in the rate of RNA synthesis is discussed. 8. A partial model of catabolite repression is presented with suggestions for determining the chemical identification of the catabolite co-repressor itself.     

Expression and characterization of Kluyveromyces lactis β-galactosidase in Escherichia coli

Kluyveromyces lactis -galactosidase gene, LAC4, was expressed in Escherichia coli as a soluble His-tagged recombinant enzyme under the optimized culture conditions. The expressed protein was multimeric with a subunit molecular mass of 118 kDa. The dimeric form of the -galactosidase was the major fraction but had a lower activity than those of the multimeric forms. The purified enzyme required Mn²⁺ for activity and was inactivated irreversibly by imidazole above 50 mM. The activity was optimal at 37 and 40 °C for o-nitrophenyl--d-galactopyranoside (oNPG) and lactose, respectively. The optimum pH value is 7. The K _m and V _max values of the purified enzyme for oNPG were 1.5 mM and 560 mol min^–1 mg^–1, and for lactose 20 mM and 570 mol min^–1 mg^–1, respectively.     

The expression of β-galactosidase by Escherichia coli during continuous culture

We have used the technique of continuous culture to study the expression of β-galactosidase in Escherichia coli. In these experiments the cultures were grown on carbon-limited media in which half of the available carbon was supplied as glycerol, glucose, or glucose 6-phosphate, and the other half as lactose. Lactose itself provided the sole source of inducer for the lac operon. The steady-state specific activity of the enzyme passed through a maximal value as a function of dilution rate. Moreover, the rate at which activity was maximal (0.40 h^?1) and the observed specific activity of the enzyme at a given growth rate were found to be identical in each of the three media tested. This result was unexpected, since the steady-state specific activity can be shown to be equal to the differential rate of enzyme synthesis, and since it is known that glycerol, glucose, and glucose-6-P-cause different degrees of catabolite repression in batch culture. The differential rate of β-galactosidase synthesis was an apparently linear function of the rate of lactose utilization per milligram protein regardless of the composition of the input medium. That is, it is independent of the rate of metabolism of substrates other than lactose which are concurrently being utilized and the enzyme level appears to be matched to the metabolic requirement for it. If this relationship is taken to indicate the existence of a fundamental control mechanism, it may represent a form of attenuation of the rate of β-galactosidase synthesis which is independent of cyclic AMP levels.     

Activity and stability of Escherichia coli β-galactosidase in cosolvent systems

The kinetic parameters of E.coli -galactosidase were not altered by the addition of 2-propanol or ethyl acetate (1.6% v/v). While ethylene glycol (1.6% v/v) doubled the values of both KM (0.29 mM) and kcat (1393 s–), tetraethyleneglycol-dimethylether (Tetraglyme,1.6% v/v) preserved KM, but decreased kcat. At 50°C all the cosolvents dramatically shortened the enzymatic half life, and so did Tetraglyme and 2-propanol at 28°C. At 28°C, both ethyl acetate and ethylene glycol stabilised the enzyme 9- and 6-fold respectively. This fact, together with the activation effect of ethylene glycol may lead to practical applications. © Rapid Science Ltd. 1998     

Ethanol-mediated gene-amplification in Escherichia coli enhances derepressed synthesis of β-galactosidase

Summary The presence of ethanol (5 % v/v), in nutrient medium, ehanced DNA synthesis per E. coli cell nearly 2.8-fold compared to that in control cells. At this concentration, the derepressed synthesis of -galactosidase per bacterium also increased about 3-fold. We, therefore, propose that the ethanol-mediated gene-amplification proportionately elevated the induced synthesis of -galactosidase.     

Galactooligosaccharide synthesis by active β-galactosidase inclusion bodies-containing Escherichia coli cells

In this study, galactooligosaccharide (GOS) was synthesized using active β-galactosidase (beta-gal) inclusion bodies (IBs)- containing Escherichia coli (E. coli) cells. Analysis by MALDI-TOF (matrix-assisted laser desorption/ionizationtime of flight) mass spectrometry revealed that a trisaccharide was the major constituent of the synthesized GOS mixture. Additionally, the optimal pH, lactose concentration, amounts of E. coli β-gal IBs, and temperature for GOS synthesis were 7.5, 500 g/l, 3.2 U/ml, and 37 °C, respectively. The total GOS yield from 500 g/l of lactose under these optimal conditions was about 32%, which corresponded to 160.4 g/l of GOS. Western blot analyses revealed that β-gal IBs were gradually destroyed during the reaction. In addition, when both the reaction mixture and E. coli β-gal hydrolysate were analyzed by high-performance thin-layer chromatography (HP-TLC), the trisaccharide was determined to be galactosyl lactose, indicating that a galactose moiety was most likely transferred to a lactose molecule during GOS synthesis. This GOS synthesis system might be useful for the synthesis of galactosylated drugs, which have recently received significant attention owing to the ability of the galactose molecules to improve the drugs solubility while decreasing their toxicity. β-Gal IB utilization is potentially a more convenient and economic approach to enzymatic GOS synthesis, since no enzyme purification steps after the transgalactosylation reaction would be required.     

Latent β-galactosidase inEscherichia coli

Incubation of washedEscherichia coli cells with crystalline RNase lead to increased β-galactosidase activity. The height of the increase depended on the type of strain and the conditions of cultivation. RNase only raised the level of the β-galactosidase which was bound to the relatively easily sedimenting cellular particles. It had no effect on the activity of β-galactosidase present in soluble form in the supernatant after the disruption of cells or on the activity of purified β-galactosidase in solution. Another basic protein, histone, was found to have a similar effect to that of RNase.     

Repeated-batch operation of immobilized β-galactosidase inclusion bodies-containing Escherichia coli cell reactor for lactose hydrolysis

In this study, we investigated the performance of an immobilized β-galactosidase inclusion bodies-containing Escherichia coli cell reactor, where the cells were immobilized in alginate beads, which were then used in repeated-batch operations for the hydrolysis of o-nitrophenyl-β-D-galactoside or lactose over the long-term. In particular, in the Tris buffer system, disintegration of the alginate beads was not observed during the operation, which was observed for the phosphate buffer system. The o-nitrophenyl-β-D-galactoside hydrolysis was operated successfully up to about 80 h, and the runs were successfully repeated at least eight times. In addition, hydrolysis of lactose was successfully carried out up to 240 h. Using Western blotting analyses, it was verified that the beta-galactosidase inclusion bodies were sustained in the alginate beads during the repeated-batch operations. Consequently, we experimentally verified that β-galactosidase inclusion bodies-containing Escherichia coli cells could be used in a repeated-batch reactor as a biocatalyst for the hydrolysis of o-nitrophenyl-β-D-galactoside or lactose. It is probable that this approach can be applied to enzymatic synthesis reactions for other biotechnology applications, particularly reactions that require long-term and stable operation.     

Engineering of Escherichia coli β-galactosidase for solvent display of a functional scFv antibody fragment

Protein engineering allows the generation of hybrid polypeptides with functional domains from different origins and therefore exhibiting new biological properties. We have explored several permissive sites in Escherichia coli β-galactosidase to generate functional hybrid enzymes displaying a mouse scFv antibody fragment. When this segment was placed at the amino-terminus of the enzyme, the whole fusion protein was stable, maintained its specific activity and interacted specifically with the target antigen, a main antigenic determinant of foot-and-mouth disease virus. In addition, the antigen-targeted enzyme was enzymatically active when bound to the antigen and therefore useful as a reagent in single-step immunoassays. These results prove the flexibility of E. coli β-galactosidase as a carrier for large-sized functional domains with binding properties and prompt the further exploration of the biotechnological applicability of the scFv enzyme targeting principle for diagnosis or other biomedical applications involving antigen tagging.     

Expression of a β-galactosidase gene from Lactobacillus sake in Escherichia coli

Summary A -galactosidase gene from Lactobacillus sake coding for lactose hydrolysis was cloned and expressed in Escherichia coli. Chromosomal DNA from L. sake was partially digested with the restriction enzyme Sau3AI, and the 3–6 Kb fragment was ligated to the cloning vector pSP72 digested with BamHI. One E. coli transformant expressing -galactosidase was isolated on X-gal plates. It contained a plasmid with an insertion of approx. 4 Kb. The restriction map of the recombinant plasmid was constructed. The characteristics of the recombinant -galactosidase were compared with those of the wild type. The optima pH and temperature for both enzymes was 6.5 and 50°C, respectively. Stability of the enzymes at different temperatures and activity on lactose were determined.     

An enzymatic glycosylation of nucleoside analogues using β-galactosidase from Escherichia coli

A new enzymatic method for the synthesis of β-galactosides of nucleosides and acyclic nucleoside analogues has been developed, using β-galactosidase from Escherichia coli as a catalyst and lactose as a sugar donor. The method is very rapid, feasible and last but not least inexpensive. Its applicability has been proven for a broad variety of possible substrates with respect to its scaling up for preparative use. Five new compounds from a series of nucleoside and acyclic nucleoside analogues have been prepared on a scale of several hundred milligrams, in all cases revealing very good results of the method concerning the reproducibility of the reaction yields and simplicity of the purification process.     

Restoration of β-galactosidase to Escherichia coli M15. Complementation studies

Carboxymethylated beta-galactosidase from Escherichia coli was dissociated at 100 degrees C to form carboxymethylated fragments A and B. The mol.wts. of carboxymethylated fragments A and B were determined by gel filtration to be 64300 and 22400 respectively. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis of carboxymethylated fragments A and B that had been pretreated with 2-mercaptoethanol and sodium dodecyl sulphate yielded mol.wts. of 64000 and 22100 respectively. Carboxymethylated fragments A and B had arginine as their C-terminal amino acid. When a crude extract of E. coli M15 was filtered through a column of Sepharose 6B, it was found that carboxymethylated fragment B could restore beta-galactosidase activity when added to fractions having mol.wts. estimated to be 123000, 262000 and 506000. These fractions are referred to as ;complementable fractions'. Similarly, it was found that carboxymethylated fragment A could restore enzyme activity to tractions having mol.wts. estimated to be 63000, 253000 and 506000. Estimates of the molecular weights of the beta-galactosidase activity obtained by restoration with carboxymethylated fragments A and B were made by filtering the active enzyme through another column of Sepharose 6B. The enzyme obtained by complementation with carboxymethylated fragment B, i.e. the complemented enzyme, had mol.wt. 525000, and that obtained with carboxymethylated fragment A had mol.wts. of 525000, 646000 and 2000000. The latter finding suggests that multiple forms of complemented beta-galactosidase can exist.     

Vectors for regulated high-level expression of proteins fused to truncated forms of Escherichia coli β-galactosidase

Vectors were constructed that allow the expression of large quantities of fused proteins in Escherichia coli. The plasmids carry the E. coli lac UV5 promotor and different portions of the coding sequence of the E. coli lacZ gene. The truncated lacZ genes are flanked by a polylinker region either at their 5′ end or their 3′ end, which has several unique restriction sites. Thus, coding sequences of any prokaryotic and eukaryotic gene can be ligated in frame to the truncated lacZ genes. These vectors were used for high-level production of herpes simplex virus type 1 envelope glycoprotein D antigens.     

Interaction of the lacZ β-galactosidase of Escherichia coli with some β-d-galactopyranoside competitive inhibitors

1. The location of the bivalent metal cation with respect to bound competitive inhibitors in Escherichia coli (lacZ) beta-galactosidase was investigated by proton magnetic resonance. 2. Replacement of Mg(2+) by Mn(2+) enhances both longitudinal and transverse relaxation of the methyl groups of the beta-d-galactopyranosyltrimethylammonium ion, and of methyl 1-thio-beta-d-galactopyranoside; linewidths are narrowed by increasing temperature. 3. The Mn(2+) ion is located 8-9A (0.8-0.9nm) from the centroid of the trimethylammonium group and 9A (0.9nm) from the average position of the methylthio protons. 4. The effective charge at the active site was probed by measurement of competitive inhibition constants (K(i) (o) and K(i) (+) respectively) for the isosteric ligands, beta-d-galactopyranosylbenzene and the beta-d-galactopyranosylpyridinium ion. 5. The ratio of inhibition constants (Q=K(i) (+)/K(i) (o)) obtained with 2-(beta-d-galactopyranosyl)-naphthalene and the beta-d-galactopyranosylisoquinolinium ion at pH7 with Mg(2+)-enzyme was identical, within experimental error, with that obtained with the monocyclic compounds. 6. The variation of Q for Mg(2+)-enzyme can be described by Q=0.1(1+[H(+)]/4.17x10(-10))/1+[H(+)]/10(-8)). 7. This, in the theoretical form for a single ionizable group, is ascribed to the ionization of the phenolic hydroxy group of tyrosine-501. 8. The variation of Q for Mg(2+)-free enzyme is complex, probably because of deprotonation of the groups normally attached to Mg(2+) as well as tyrosine-501.     

Two distinct states of Escherichia coli cells that overexpress recombinant heterogeneous β-galactosidase

The mechanism by which inclusion bodies form is still not well understood, partly because the dynamic processes of the inclusion body formation and its solubilization have hardly been investigated at an individual cell level, and so the important detailed information has not been acquired for the mechanism. In this study, we investigated the in vivo folding and aggregation of Aspergillus phoenicis β-D-galactosidase fused to a red fluorescence protein in individual Escherichia coli cells. The folding status and expression level of the recombinant β-D-galactosidase at an individual cell level was analyzed by flow cytometry in combination with transmission electron microscopy and Western blotting. We found that individual E. coli cells fell into two distinct states, one containing only inclusion bodies accompanied with low galactosidase activity and the other containing the recombinant soluble galactosidase accompanied with high galactosidase activity. The majority of the E. coli cells in the later state possessed no inclusion bodies. The two states of the cells were shifted to a cell state with high enzyme activity by culturing the cells in isopropyl 1-thio-β-D-galactopyranoside-free medium after an initial protein expression induction in isopropyl 1-thio-β-D-galactopyranoside-containing medium. This shift of the cell population status took place without the level change of the β-D-galactosidase protein in individual cells, indicating that the factor(s) besides the crowdedness of the recombinant protein play a major role in the cell state transition. These results shed new light on the mechanism of inclusion body formation and will facilitate the development of new strategies in improving recombinant protein quality.     

Cloning and expression of β-galactosidase gene from Bifidobacterium infantis into Escherichia coli

Bifidobacterium infantis HL96 produces three -galactosidases (-gal I, II and III). A genomic bank of B. infantis was constructed in E. coli by using pBR322 as a cloning vector. Two E. coli transformants, BIG1 and BIG4, possessing -galactosidase activity, were selected from X-gal plates. They contained two different recombinant plasmids with insert DNA fragments of approx. 4.6 and 4.4 kb, respectively. The restriction maps of pBIG1 and pBIG4 were constructed. -Galactosidases from crude cell-free extracts of B. infantis and of two E. coli recombinants were analyzed by native PAGE and characterized by activity staining. pBIG1 and pBIG4 were shown to carry the genes for -gal I and -gal III, respectively. Optimal pH and temperature for hydrolytic activity of the native enzyme were 7.5 and 40°C, while those for recombinant BIG1 and BIG4 were 7.5, 50°C and 8.0, 40°C, respectively. © Rapid Science Ltd. 1998     

Disulfide bond formation and activation of Escherichia coli β-galactosidase under oxidizing conditions

Escherichia coli β-galactosidase is probably the most widely used reporter enzyme in molecular biology, cell biology, and biotechnology because of the easy detection of its activity. Its large size and tetrameric structure make this bacterial protein an interesting model for crystallographic studies and atomic mapping. In the present study, we investigate a version of Escherichia coli β-galactosidase produced under oxidizing conditions, in the cytoplasm of an Origami strain. Our data prove the activation of this microbial enzyme under oxidizing conditions and clearly show the occurrence of a disulfide bond in the β-galactosidase structure. Additionally, the formation of this disulfide bond is supported by the analysis of a homology model of the protein that indicates that two cysteines located in the vicinity of the catalytic center are sufficiently close for disulfide bond formation.