Molecular cloning of the lactose-metabolizing genes from Streptococcus lactis

Genetics of lactose utilization in lactic acid bacteria

Lactose utilization is the primary function of lactic acid bacteria used in industrial dairy fermentations. The mechanism by which lactose is transported determines largely the pathway for the hydrolysis of the internalized disaccharide and the fate of the glucose and galactose moieties. Biochemical and genetic studies have indicated that lactose can be transported via phosphotransferase systems, transport systems dependent on ATP binding cassette proteins, or secondary transport systems including proton symport and lactose-galactose antiport systems. The genetic determinants for the group translocation and secondary transport systems have been identified in lactic acid bacteria and are reviewed here. In many cases the lactose genes are organized into operons or operon-like structures with a modular organization, in which the genes encoding lactose transport are tightly linked to those for lactose hydrolysis. In addition, in some cases the genes involved in the galactose metabolism are linked to or co-transcribed with the lactose genes, suggesting a common evolutionary pathway. The lactose genes show characteristic configurations and very high sequence identity in some phylogenetically distant lactic acid bacteria such as Leuconostoc and Lactobacillus or Lactococcus and Lactobacillus. The significance of these results for the adaptation of lactic acid bacteria to the industrial milk environment in which lactose is the sole energy source is discussed.

RepR protein expression on plasmid pIP501 is controlled by an antisense RNA-mediated transcription attenuation mechanism

Expression of the rate-limiting initiator protein RepR of plasmid pIP501 is controlled by the antisense RNAIII. Mutational alteration of individual G residues within the single-stranded loops of RNAIII led to an increase in copy number. In contrast to the G-rich single-stranded loops, two smaller AT-rich loops of RNAIII were found to be dispensable for its inhibitory function. Reciprocal mutations in the same loop compensated for each other's effect, and a destabilization of the major stem structure of RNAIII also resulted in an increased copy number. These data were consistent with the idea that the interaction of RNAIII with its target starts with the formation of a kissing complex between the single-stranded loops of both molecules. The repR mRNA leader sequence, which includes the target of RNAIII, is able to assume two alternative structures due to the presence of two inverted repeats the individual sequences of which are mutually complementary. In the presence of the antisense RNAIII, one of these inverted repeats (IR2) is forced to fold into a transcriptional terminator structure that prevents transcription of the repR gene. In the absence of RNAIII, formation of the transcriptional terminator is prevented and expression of the essential repR gene can proceed normally. This antisense RNA-driven transcriptional attenuation mechanism was supported by extensive deletional analysis and direct evidence that IR2 functions as a transcriptional terminator.

Characterization of the minimal origin required for replication of the streptococcal plasmid pIP501 in Bacillus subtilis

By using deletional analysis the origin of replication, oriR, of the streptococcal plasmid pIP501 in Bacillus subtilis has been mapped at a position immediately downstream of the repR gene. Determination of both the right and left border of oriR allowed the definition of a sequence of a maximum of 52 nucleotides which theoretically constitutes the minimal origin of replication. Recently, the start point of leading-strand synthesis of the closely related plasmid pAM beta 1 has been mapped at a position which is located exactly in the middle of this sequence (Bruand et al., 1991). The function of oriR did not depend on its location downstream of the repR gene. Translocation of oriR-containing fragments to other regions of the plasmid proved to be possible. The smallest translocated fragment that still reconstituted autonomous replication was 72bp in size. This fragment was also active in directing the replication of an Escherichia coli plasmid in B. subtilis when the RepR protein was supplied in trans from a repR gene integrated into the host chromosome. The transformation efficiency of plasmids carrying translocated oriR fragments showed a certain dependence on the fragment length and orientation. The DNA sequence of oriR included an inverted repeat, both branches of which appeared to be essential for oriR function. The repeats of oriR shared sequence similarity with a repeat located upstream of promoter pII, which has been suggested to be involved in autoregulation of repR expression.

In vitro expression of Lac-PTS and tagatose 1,6-bisphosphate aldolase genes from Lactococcus lactis subsp. cremoris plasmid pDI-21

A 4.4-kb EcoR1-EcoR1 DNA fragment from the Lactococcus lactis subsp. cremoris plasmid pDI-21 encoded the tagatose 1,6-bisphosphate (TBP) aldolase gene and the Lac-PTS genes. In vitro transcription-translation using Escherichia coli S30 extract showed the synthesis of 41,000-, 23,000- and 12,000-dalton proteins which correspond to the TBP-aldolase, Lac-PTS enzyme II, and factor III proteins respectively.

Properties of Lactose Plasmid pLY101 in Lactobacillus casei

A starter strain, Lactobacillus casei C257, was found to carry a lactose plasmid, pLY101. Restriction mapping showed that pLY101 DNA was 68.2 kilobases long. Since a non-lactose-utilizing variant of C257, MSK248, lost phospho-β-galactosidase (P-β-gal) activity and pLY101 DNA had a sequence(s) homologous to the streptococcal fragment including a P-β-gal gene, pLY101 is likely to encode a P-β-gal gene required for lactose metabolism in C257. MSK248 grew in galactose medium at a rate identical to that of C257 and retained phosphoenolpyruvate-dependent phosphotransferase system activity for lactose similar to that of C257. Therefore, the C257 chromosome appears to encode a complete set of genes for the lactose-phosphotransferase system and the predominant galactose metabolic pathway in C257. pLY101 DNA had a sequence homologous to a lactobacillus insertion sequence, ISL 1 , which mapped more than 12 kilobases from the sequence homologous to the streptococcal P-β-gal fragment.

Nucleotide and deduced amino acid sequences of the Staphylococcus aureus phospho-beta-galactosidase gene

We sequenced the Staphylococcus aureus phospho-beta-galactosidase gene. The protein product of this gene consisted of 470 amino acids, giving a molecular weight of 54,557. This gene appears to be transcribed as the terminal sequence on a polycistronic message.

Molecular and genetic characterization of lactose-metabolic genes of Streptococcus cremoris

Lac+ plasmid DNA from Streptococcus cremoris H2 was subcloned with an Escherichia coli vector on a 3.5-kilobase-pair PstI-AvaI fragment. Genetic analysis of the cloned DNA was possible because linear Lac+ DNA fragments were productive in the S. sanguis transformation system. Complementation of S. sanguis Lac-mutants showed that the 3.5-kilobase-pair fragment included the structural gene for 6-phospho-beta-D-galactosidase and either enzyme II-lac or factor III-lac of the lactose-specific phosphoenolpyruvate-dependent phosphotransferase system. Expression of the S. cremoris-like 40,000-dalton 6-phospho-beta-D-galactosidase in S. sanguis Lac+ transformants, rather than the 52,000-dalton wild-type S. sanguis enzyme, demonstrated the occurrence of gene replacement and not gene repair. The evidence supports chromosomal integration as the mechanism by which S. sanguis Lac- recipients are converted to a Lac+ phenotype after transformation with Lac+ DNA. Southern blot data suggest that the Lac+ DNA does not reside on a transposon, but that integration always occurs within a specific HincII fragment of the recipient chromosome. Hybridization experiments demonstrate homology between the S. cremoris Lac+ DNA and cellular DNA from Lac+ strains of Streptococcus lactis, S. mutans, S. faecalis, and S. sanguis.

High-efficiency transformation of Streptococcus lactis protoplasts by plasmid DNA

Streptococcus lactis IL1403 protoplasts were transformed by plasmid pIL204 (5.5 kilobases), which conferred erythromycin resistance with an average efficiency of 5 X 10(6) transformants per microgram of supercoiled DNA. The procedure used and transformation efficiencies obtained were close to those described for Bacillus subtilis (G. Chang and S. N. Cohen, Mol. Gen. Genet. 168:111-115, 1979).

Lactose metabolism in Streptococcus lactis: studies with a mutant lacking glucokinase and mannose-phosphotransferase activities

A mutant of Streptococcus lactis 133 has been isolated that lacks both glucokinase and phosphoenolpyruvate-dependent mannose-phosphotransferase (mannose-PTS) activities. The double mutant S. lactis 133 mannose-PTSd GK- is unable to utilize either exogenously supplied or intracellularly generated glucose for growth. Fluorographic analyses of metabolites formed during the metabolism of [14C]lactose labeled specifically in the glucose or galactosyl moiety established that the cells were unable to phosphorylate intracellular glucose. However, cells of S. lactis 133 mannose-PTSd GK- readily metabolized intracellular glucose 6-phosphate, and the growth rates and cell yield of the mutant and parental strains on sucrose were the same. During growth on lactose, S. lactis 133 mannose-PTSd GK- fermented only the galactose moiety of the disaccharide, and 1 mol of glucose was generated per mol of lactose consumed. For an equivalent concentration of lactose, the cell yield of the mutant was 50% that of the wild type. The specific rate of lactose utilization by growing cells of S. lactis 133 mannose-PTSd GK- was ca. 50% greater than that of the wild type, but the cell doubling times were 70 and 47 min, respectively. High-resolution 31P nuclear magnetic resonance studies of lactose transport by starved cells of S. lactis 133 and S. lactis 133 mannose-PTSd GK- showed that the latter cells contained elevated lactose-PTS activity. Throughout exponential growth on lactose, the mutant maintained an intracellular steady-state glucose concentration of 100 mM. We conclude from our data that phosphorylation of glucose by S. lactis 133 can be mediated by only two mechanisms: (i) via ATP-dependent glucokinase, and (ii) by the phosphoenolpyruvate-dependent mannose-PTS system.