Lactose- and galactose-utilizing strains of poly(hydroxyalkanoic acid)-accumulating Alcaligenes eutrophus and Pseudomonas saccharophila obtained by recombinant DNA technology

Summary Transposon Tn 951-encoded -galactosidase was expressed in Pseudomonas saccharophila and enabled this bacterium to grow on lactose as sole carbon source. In contrast, -galactosidase was not expressed in Alcaligenes eutrophus even if the lacZ gene of Tn 951 was separated from the lacI gene. However, -galactosidase was expressed in A. eutrophus, if a DNA fragment, which was suspected to harbour the promoter of the A. eutrophus poly(3-hydroxybutyric acid)-synthetic genes, was ligated to the promoter probe vector pMC1403, which employs lac Z, Y as reporter genes. Plasmid pPL76, which harboured one of the promoter-lac fusions, enabled A. eutrophus not only to express -galactosidase but also to grow slowly on lactose (doubling time = 25–30 h). Subsequently, the promoter-lac fusion was ligated to Tn5 in pSUP5011 and was inserted into the genome of A. eutrophus H16 and of the glucose-utilizing mutant H16-G⁺1 by applying the suicide plasmid technique. Two recombinant strains, H16-cPL and H16-G⁺1-cPL, which grow with a doubling time of 16–23 h on lactose, were investigated in detail. The cells only utilized the glucose residue of lactose as a carbon source for grouth and excreted galactose into the medium. Only after the Escherichia coli gal operon had been cloned in vector pVK101 and had been mobilized to H16-cPL or H16-G⁺1-cPL, was lactose completely utilized; no galactose was detected in the medium and the growth yields increased twofold. Depending on the orientation of the gal operon in pVK101, the expression of galactokinase seems to be dependent either on the promoter of aminoglycoside phosphotransferase gene (kan) or on the promoter of the tetR gene. Offprint requests to: A. Steinbüchel     

Galactose Metabolism by Streptococcus mutans

The galK gene, encoding galactokinase of the Leloir pathway, was insertionally inactivated in Streptococcus mutans UA159. The galK knockout strain displayed only marginal growth on galactose, but growth on glucose or lactose was not affected. In strain UA159, the sugar phosphotransferase system (PTS) for lactose and the PTS for galactose were induced by growth in lactose and galactose, although galactose PTS activity was very low, suggesting that S. mutans does not have a galactose-specific PTS and that the lactose PTS may transport galactose, albeit poorly. To determine if the galactose growth defect of the galK mutant could be overcome by enhancing lactose PTS activity, the gene encoding a putative repressor of the operon for lactose PTS and phospho-β-galactosidase, lacR, was insertionally inactivated. A galK and lacR mutant still could not grow on galactose, although the strain had constitutively elevated lactose PTS activity. The glucose PTS activity of lacR mutants grown in glucose was lower than in the wild-type strain, revealing an influence of LacR or the lactose PTS on the regulation of the glucose PTS. Mutation of the lacA gene of the tagatose pathway caused impaired growth in lactose and galactose, suggesting that galactose can only be efficiently utilized when both the Leloir and tagatose pathways are functional. A mutation of the permease in the multiple sugar metabolism operon did not affect growth on galactose. Thus, the galactose permease of S. mutans is not present in the gal, lac, or msm operons.     

The gal Genes for the Leloir Pathway of Lactobacillus casei 64H

The gal genes from the chromosome of Lactobacillus casei 64H were cloned by complementation of the galK2 mutation of Escherichia coli HB101. The pUC19 derivative pKBL1 in one complementation-positive clone contained a 5.8-kb DNA HindIII fragment. Detailed studies with other E. coli K-12 strains indicated that plasmid pKBL1 contains the genes coding for a galactokinase (GalK), a galactose 1-phosphate-uridyltransferase (GalT), and a UDP-galactose 4-epimerase (GalE). In vitro assays demonstrated that the three enzymatic activities are expressed from pKBL1. Sequence analysis revealed that pKBL1 contained two additional genes, one coding for a repressor protein of the LacI-GalR-family and the other coding for an aldose 1-epimerase (mutarotase). The gene order of the L. casei gal operon is galKETRM. Because parts of the gene for the mutarotase as well as the promoter region upstream of galK were not cloned on pKBL1, the regions flanking the HindIII fragment of pKBL1 were amplified by inverse PCR. Northern blot analysis showed that the gal genes constitute an operon that is transcribed from two promoters. The galKp promoter is inducible by galactose in the medium, while galEp constitutes a semiconstitutive promoter located in galK.     

Use of lac operon fusions to isolate Escherichia coli mutants with altered expression of the fumarate reductase system in response to substrate and respiratory controls.

Strains of $\text{E}\text{.}\text{coli}$ with fusions between the $\text{lac}$ structural genes and the promoter region of the fumarate reductase system were constructed from a parental strain deleted in the native $\text{lac}$ operon. Like fumarate reductase in wild-type cells, β-galactosidase in these fusion strains is inducible by fumarate, but only under anaerobic conditions. From one of these strains, three classes of mutants altered in the expression of the hybrid operon were isolated. By anaerobic selection for growth on lactose in the absence of fumarate, mutants that synthesize β-galactosidase constitutively both aerobically and anaerobically were obtained. By aerobic selection for growth on lactose in the presence of fumarate, mutants that are inducible in the enzyme both aerobically and anaerobically and mutants that are inducible in the enzyme only aerobically were obtained. The regulatory behaviors of the mutants studied suggest that substrate and respiratory control of the expression of the fumarate reductase complex are mechanistically connected.     

Use of the Mud(Ap,lac) bacteriophage to study the regulation of L-proline biosynthetic genes inEscherichia coli K-12

One operon fusion to the promoter of either theproA orproB genes of the proline biosynthetic pathway was obtained by the use of the Mud(Ap,lac) bacteriophage. This operon fusion was further stabilized by transformation with the plasmid pGW600 containing the wild type Mu repressor gene. The level of β-galactosidase in this strain was not affected by the presence of high concentrations of NaCl in the growth medium. Mutations affecting the regulation of thispro-lac genetic fusion were generated by the insertion of Tn5; β-galactosidase levels in these mutants were higher than in the parental strain when proline was present at a high level. In some of these mutants we observed either repression or maintenance of β-galactosidase levels whenpro-lac (F′proAB ⁺) merodiploids were constructed.     

Construction and analysis of in vivo activity of E. coli promoter hybrids and promoter mutants that alter the -35 to -10 spacing

A series of promoter hybrids has been constructed by exchanging the ? 35 and ? 10 regions of lacUV5, tet, and trp promoters. These three promoters and the six hybrid promoters constructed from them have been inserted into a pKO plasmid which places galactokinase expression under the control of the inserted promoter. Additionally, promoter mutants were prepared which had altered the spacing between the ? 35 and ? 10 regions of the promoter. Derivatives of the tet promoter with one or two extra base pairs in this spacer region and constructions of the lac:: tet hybrid promoter with two different spacings have been inserted into the galactokinase expression plasmid. Measurements of galactokinase levels in strains harboring these plasmids permited the comparison of in vivo activities of the promoters. The strongest of the hybrid promoters (order: ? 35, ? 10) were trp:: lac and trp:: tet suggesting a high efficiency for the ? 35 region of the trp promoter. The weakest promoters were tet:: trp, lac:: trp and lac::tet indicating a weak ? 10 region for the trp promoter and the importance of ? 35 to ? 10 spacing. Analysis of activity of related promoters with differences in spacing indicated that a distance of 19 bp yields a very weak promoter, and that 18 bp is less active than the 17-bp spacing, which is the most frequently found spacing in promoters.     

Tuning the Expression Level of a Gene Located on a Bacterial Chromosome

A new method of constructing a set of bacterial cell clones varying in the strength of a promoter upstream of the gene of interest was developed with the use of Escherichia coli MG1655 and lacZ as a reporter. The gist of it lies in constructing a set of DNA fragments with tac-like promoters by means of PCR with the consensus promoter P _tac and primers ensuring randomization of the four central nucleotides in the ?35 region. DNA fragments containing the tac-like promoters and a selective marker (Cm ^R) were used to replace lacI and the regulatory region of the lactose operon in E. coli MG1655. Direct LacZ activity assays with independent integrant clones revealed 14 new promoters (out of 4⁴ = 256 possible variants), whose strength varied by two orders of magnitude: LacZ activity in the corresponding strains gradually varied from 10² Miller units with the weakest promoter to 10⁴ Miller units with consensus P _tac Sequencing of the modified promoters showed that randomization of three positions in the ?35 region is sufficient for generating a representative promoter library, which reduces the number of possible variants from 256 to 64. The method of constructing a set of clones varying in expression of the gene or operon of interest is promising for modern metabolic engineering.     

Immediate stoichiometric appearance of β-galactosidase products in the medium of Escherichia coli cells incubated with lactose

Products of β-galactosidase action on lactose by intact E. coli cells appeared in the medium as soon as lactose was added and the amount of product was equal to the lactose used. No detectable levels of β-galactosidase were found in the medium and lactose was not significantly broken down unless lac permease was present. The appearance did not depend upon the presence of any of the commonly known galactose or glucose permease systems. The Km of product appearance from whole cells was equal to the K_t for lactose transport by lac permease. When the cells were broken the Km became the normal β-galactosidase Km.     

A new class of promoter mutations in the lactose operon of Escherichia coli

The isolation and genetic characterization of a number of mutations that are located in the promoter region of the lac2 operon are described. These mutations have reduced levels of lac operon expression in a wild, type (crp⁺cya⁺) genetic background. Three of the mutations also have lower levels of lac operon expression than lacP⁺ in a crp^?cya^? genetic background, that is in the absence of the catabolite activator protein and 3′,5′-adenosine cyclic monophosphate. These three mutations are located nearest to the lac operator. They define a second essential site in the promoter region.     

The separation of phage promoter from bacterial lac promoter for beta-galactosidase expression in transducing phage lambda plac5.

The replication defective transducing phage λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 carries a portion of the $\text{E.}\text{coli}\text{lac}$ operon in the $\text{b}$2 region of the lambda phage. This $\text{lac}$ operon segment contains the $\text{lac}$ promoter, the $\text{lac}$ operator, and the β-galactosidase $\text{z}$ gene, but does not contain the $\text{lac}$ repressor $\text{i}$ gene. The $\text{z}$ gene can be expressed from both the inserted $\text{lac}$ promoter and the phage promoter. When $\text{E.}\text{coli}$ strain 594 ($\text{z}$^?, $\text{i}$⁺) or JC6256 (Δ$\text{lac}$) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the absence of additional cyclic AMP, β-galactosidase synthesis is shown to be expressed from the phage promoter. When 594 (λ⁺) or JC6256 (λ⁺) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the presence of additional cyclic AMP and IPTG, β-galactosidase synthesis is shown to be expressed from the inserted $\text{lac}$ promoter.The ability to separate the phage promoter from the inserted $\text{lac}$ promoter for β-galactosidase expression will simplify the interpretation whenever λp$\text{lac}$5 is used.     

The Effect of the lacY Gene on the Induction of IPTG Inducible Promoters, Studied in Escherichia coli and Pseudomonas fluorescens

The role of the Escherichia coli lacY gene product (the lactose permease) in the induction of isopropyl-β-D-thiogalactopyranoside (IPTG) inducible promoters was studied in E. coli and P. fluorescens. This was done by comparing strains containing a lacIPOZYA chromosomal insert with newly constructed strains containing inserts without the lacY gene (lacIPOZ). The lactose operon inserts were introduced as single-copy chromosomal inserts to eliminate differences in expression caused by differences in copy number. Comparison between the two types of inserts showed that the lactose permease was essential to allow growth on lactose by both bacteria and that the lactose permease plays an important role in transporting the inducer IPTG across the membrane of P. fluorescens. The use of a functional lactose permease allows expression of β-galactosidase to increase more than fivefold from a wild-type lac promoter in P. fluorescens SS1001. We suggest that an increase in the rate of protein synthesis from lac-type promoters could be enhanced if an active lactose permease is present as well. Received: 29 October 1997 / Accepted: 8 December 1997     

Molecular and Biochemical Analysis of the Galactose Phenotype of Dairy Streptococcus thermophilus Strains Reveals Four Different Fermentation Profiles

Lactose-limited fermentations of 49 dairy Streptococcus thermophilus strains revealed four distinct fermentation profiles with respect to galactose consumption after lactose depletion. All the strains excreted galactose into the medium during growth on lactose, except for strain IMDOST40, which also displayed extremely high galactokinase (GalK) activity. Among this strain collection eight galactose-positive phenotypes sensu stricto were found and their fermentation characteristics and Leloir enzyme activities were measured. As the gal promoter seems to play an important role in the galactose phenotype, the galR-galK intergenic region was sequenced for all strains yielding eight different nucleotide sequences (NS1 to NS8). The gal promoter played an important role in the Gal-positive phenotype but did not determine it exclusively. Although GalT and GalE activities were detected for all Gal-positive strains, GalK activity could only be detected for two out of eight Gal-positive strains. This finding suggests that the other six S. thermophilus strains metabolize galactose via an alternative route. For each type of fermentation profile obtained, a representative strain was chosen and four complete Leloir gene clusters were sequenced. It turned out that Gal-positive strains contained more amino acid differences within their gal genes than Gal-negative strains. Finally, the biodiversity regarding lactose-galactose utilization among the different S. thermophilus strains used in this study was shown by RAPD-PCR. Five Gal-positive strains that contain nucleotide sequence NS2 in their galR-galK intergenic region were closely related.     

Fermentation of lactose by Zymomonas mobilis carrying a Lac+ recombinant plasmid

Lac⁺ recombinant plasmids encoding a β-galactosidase fused protein and lactose permease of Escherichia coli were introduced Zymomonas mobilis. The fused protein was expressed with 450 to 5,860 Miller units of β-galactosidase activity, and functioned as lactase. Raffinose uptake by Z. mobilis CP4 was enhanced in the plasmid-carrying strain over the plasmid-free strain, suggesting that the lactose permease was functioning in the organism. Z. mobilis carrying the plasmid could produce ethanol from lactose and whey, but could not grow on lactose as the sole carbon source. It was found that the growth of the organism was inhibited by either galactose of the galactose liberated from lactose.