Larry L. McKay

Discovering lactic acid bacteria by genomics

This review summarizes a collection of lactic acid bacteria that are now undergoing genomic sequencing and analysis. Summaries are presented on twenty different species, with each overview discussing the organisms fundamental and practical significance, nvironmental habitat, and its role in fermentation, bioprocessing, or probiotics. For those projects where genome sequence data were available by March 2002, summaries include a listing of key statistics and interesting genomic features. These efforts will revolutionize our molecular view of Gram–positive bacteria, as up to 15 genomes from the low GC content lactic acid bacteria are expected to be available in the public domain by the end of 2003. Our collective view of the lactic acid bacteria will be fundamentally changed as we rediscover the relationships and capabilities of these organisms through genomics.

The role of autolysis of lactic acid bacteria in the ripening of cheese

Abstract The importance of autolysis of lactic acid bacteria in cheese ripening is evident from the literature. However, the mechanisms and the consequences still require investigation. The consequences of autolysis of mesophilic starters in Cheddar cheese are discussed and highlights from current physiological and genetic studies on starter autolysis are presented. The relative merits of measuring starter autolysis in cheese by viable starter cell densities, electron microscopic observations and assay of cell-free cytoplasmic enzymes are discussed for cheese studies using different starter strains and added phage to achieve different levels of autolysis. The balance of both the intact and autolysed starter cells in young curd appear to be important in cheese ripening. The intact cells are necessary for physiological reactions such as lactose fermentation and oxygen removal and possibly for a number of flavour reactions. In contrast, the main consequence of autolysed cells in cheese is to accelerate the peptidolytic reactions. The possible influences of autolysis of adventitious lactic acid bacteria during cheese ripening are discussed.

Comparative Genome Analysis of Lactobacillus reuteri and Lactobacillus fermentum Reveal a Genomic Island for Reuterin and Cobalamin Production

Lactobacillus reuteri is a heterofermentative lactic acid bacterium that naturally inhabits the gut of humans and other animals. The probiotic effects of L. reuteri have been proposed to be largely associated with the production of the broad-spectrum antimicrobial compound reuterin during anaerobic metabolism of glycerol. We determined the complete genome sequences of the reuterin-producing L. reuteri JCM 1112T and its closely related species Lactobacillus fermentum IFO 3956. Both are in the same phylogenetic group within the genus Lactobacillus. Comparative genome analysis revealed that L. reuteri JCM 1112T has a unique cluster of 58 genes for the biosynthesis of reuterin and cobalamin (vitamin B12). The 58-gene cluster has a lower GC content and is apparently inserted into the conserved region, suggesting that the cluster represents a genomic island acquired from an anomalous source. Two-dimensional nuclear magnetic resonance (2D-NMR) with 13C3-glycerol demonstrated that L. reuteri JCM 1112T could convert glycerol to reuterin in vivo, substantiating the potential of L. reuteri JCM 1112T to produce reuterin in the intestine. Given that glycerol is shown to be naturally present in feces, the acquired ability to produce reuterin and cobalamin is an adaptive evolutionary response that likely contributes to the probiotic properties of L. reuteri.

Functional properties of plasmids in lactic streptococci

Plasmid biology has become an important area of investigation in dairy starter cultures since it now appears that some properties, vital for successful milk fermentations, are coded by genes located on plasmid DNA. Some of these metabolic properties observed in lactic streptococci have been clearly established as being plasmid-mediated. Examples would be lactose utilization and in Streptococcus lactis subsp. diacetylactis the ability to produce a bacteriocin-like substance. Phenotypic and physical evidence for plasmid linkage has been obtained for other traits such as citrate, sucrose, galactose, glucose, mannose, and xylose utilization, proteinase activity, modification/restriction systems, as well as for nisin production. Further genetic evidence is now needed to confirm plasmid association to these properties. For some characteristics the association with plasmids is highly speculative and is solely based on the phenotypic loss of a metabolic property. In this category would be sensitivity to agglutinins, sensitivity to the lactoperoxidase-thiocyanate-hydrogen peroxide inhibitory system, arginine hydrolysis, and slime production. Other properties which appear plasmid-mediated in lactic streptococci and which will be discussed include inorganic ion resistance, drug resistance, and diplococcin production.

Identification of bacilysin, chlorotetaine, and iturin a produced by Bacillus sp. strain CS93 isolated from pozol, a Mexican fermented maize dough.

ABSTRACT Three antimicrobial compounds produced by Bacillus sp. strain CS93 isolated from pozol were identified by using high-performance liquid chromatography and mass spectrometry. The three compounds were iturin, bacilysin, and chlorotetaine. Production of these compounds by CS93 could account for the medicinal properties attributed to pozol.

Cloning, Sequencing, and Expression of the Pyruvate Carboxylase Gene in Lactococcus lactis subsp. lactis C2

ABSTRACT A functional pyc gene was isolated fromLactococcus lactis subsp. lactis C2 and was found to complement a Pyc defect in L. lactis KB4. The deduced lactococcal Pyc protein was highly homologous to Pyc sequences of other bacteria. The pyc gene was also detected inLactococcus lactis subsp. cremoris and L. lactis subsp. lactis bv. diacetylactis strains.

Characterization of AbiR, a novel multicomponent abortive infection mechanism encoded by plasmid pKR223 of Lactococcus lactis subsp. lactis KR2

ABSTRACT The native lactococcal plasmid pKR223 encodes two distinct phage resistance mechanisms, a restriction and modification (R/M) system designated LlaKR2I and an abortive infection mechanism (Abi) which affects prolate-headed-phage proliferation. The nucleotide sequence of a 16,174-bp segment of pKR223 encompassing both the R/M and Abi determinants has been determined, and sequence analysis has validated the novelty of the Abi system, which has now been designated AbiR. Analysis of deletion and insertion clones demonstrated that AbiR was encoded by two genetic loci, separated by the LlaKR2I R/M genes. Mechanistic studies on the AbiR phenotype indicated that it was heat sensitive and that it impeded phage DNA replication. These data indicated that AbiR is a novel multicomponent, heat-sensitive, “early”-functioning Abi system and is the first lactococcal Abi system described which is encoded by two separated genetic loci.

Conjugal transfer of genetic material by Lactococcus lactis subsp. lactis 11007

Conjugal transfer of genetic material by Lactococcus lactis subsp. lactis 11007 was examined. A plasmid of 88 MDa (pJS88) was identified in addition to the previously reported conjugally transferred plasmids of 32 (pKB32) and 4.8 MDa. Proteinase activity, reduced bacteriophage sensitivity, bacteriocin resistance, and conjugal transfer ability were encoded by pJS88. The ability to metabolize lactose (Lac+) was encoded by pKB32, and the 4.8-MDa plasmid was cryptic. When a strain containing both pKB32 and pJS88 was mated with a recipient deficient in host-mediated homologous recombination (Rec-), a plasmid of 40 MDa (pJS40) was observed in approximately 50% of the Lac+ transconjugants. DNA-DNA hybridization results indicated that pJS40 contained homology with both pKB32 and pJS88. These results indicated that pKB32 was conjugally transferred via conduction and suggested that pJS40 is a deletion derivative of a pKB32::pJS88 cointegrate. A Rec- strain containing pKB32 and pJS88 mediated Lac+ conjugal transfer, suggesting that the pKB32::pJS88 cointegrate could form via a rec-independent event. Resolution of the pKB32::pJS88 cointegrate was observed in both Rec- and Rec+ hosts. Cointegrate formation and resolution via rec-independent mechanisms suggest the involvement of a transposable element in the Tn3 family.

Intracellular pH and the role of D-lactate dehydrogenase in the production of metabolic end products by Leuconostoc lactis

The kinetics of lactate dehydrogenase from Leuconostoc lactis NCW1 were studied. The pH optimum for the enzyme depended on the concentration of pyruvate used in the assay and the enzyme displayed an ordered mechanism with respect to substrate binding. The Km for pyruvate and NADH and the Vmax of the enzyme decreased 20-, 30- and 6-fold respectively as the pH decreased from 8.0 to 5.0. No activators were found and none of the intermediates of the phosphoketolase pathway tested inhibited the enzyme. ATP, ADP, GTP and NAD+ were inhibitory. The intracellular volume (Vol(in)) and intracellular pH (pH(in)) decreased as the extracellular pH (pH(ex)) decreased. Co-metabolism of citrate and glucose affected the Vol(in) but did not affect the pH(in), which decreased by 0.6 units per unit change in pH(ex); at pH 7.0, the pH(in) and pH(ex) were equal. The results suggest that pH(in) may play a role in determining the production of diacetyl and acetoin at low pH by Leuconostoc.

Group II introns and expression of conjugative transfer functions in lactic acid bacteria

The homologous lactococcal conjugative elements pRS01 and the sex factor of Lactococcus lactis strain 712 both contain a Group II intron within a gene believed to encode a conjugative relaxase enzyme. This enzyme is responsible for nicking of DNA at the origin of transfer (oriT) sequence of the sex factor DNA to initiate the strand transfer process. Group II introns have been studied in eukaryotes, and several of these elements in yeast mitochondrial genes have received considerable attention. These introns are relatively large in size and generally encode a protein within the intron sequence. In addition to splicing activity, Group II introns are mobile genetic elements. The intron-encoded proteins (IEPs) contain endonuclease and reverse transcriptase domains believed to play an enzymatic role in genetic mobility reactions, while a putative maturase domain is thought to promote splicing by stabilizing the folding of the intron RNA into an active ribozyme structure which carrie s out the splicing reaction. The lactococcal introns represent the first examples of Group II introns shown to be functional in vivo in prokaryotes. Because of the advantages of a bacterial system for genetic and molecular studies, the Ll.ltrB intron from pRS01 has attracted the attention of several laboratories interested in Group II intron biology. Recently, it has been shown that the system can be adapted to function in Escherichia coli (although at somewhat reduced efficiency). In addition, it has been recently proven that the best studied form of mobility, the homing of the intron into an intronless allele of the cognate exon gene, occurs via an RNA intermediate and does not require DNA homology or generalized host recombination functions. Current efforts are analysis of the role Ll.ltrB splicing in regulating expression of pRS01 conjugation functions. The lactococcal Group II introns represent the first demonstrated genetically mobile prokaryotic retroelements, and they also have considerable potential as genetic engineering tools for Lactic Acid Bacteria (LAB) and other organisms.