Present state of lactic acid bacteria phage taxonomy

Recent developments in molecular taxonomy of bacteriophages of lactobacilli and lactic streptococci are presented. DNA homology appears to be the most valid criterion in studying phage taxonomy. For each bacterial species, phages can be classified in a few families according to this criterion. A fair correspondence is observed between the groups differentiated by DNA-DNA hybridization and those differenciated by protein composition. In 2 bacterial species, a close relatedness between some virulent and temperate phages has been demonstrated. The presence of homologous sequences in the genome of various phages may play an important role in their evolution. For future taxonomic studies, some phages representative of DNA homology groups are proposed as reference phages.     

The genomics of lactic acid bacteria

The lactic acid bacteria (LAB) are one of the most industrially important groups of bacteria. These organisms are used in a variety of ways, including food production, health improvement and production of macromolecules, enzymes and metabolites. The genome sequencing of 20 LAB provides an expanded view of their genetic and metabolic capacities and enables researchers to perform functional and comparative genomic studies. This review highlights some of the findings from these analyses in the context of the numerous roles the LAB play.     

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.     

乳酸菌基因组学研究进展

乳酸菌广泛应用于食品发酵工业中,其中有些菌种是重要的益生菌。目前,对乳酸菌的研究已从最初的形态学研究进入到了分子水平的研究。乳酸菌全基因组测序研究已在全球展开。乳酸菌基因组研究有助于揭示乳酸菌的遗传和代谢机制,加速重要益生功能基因的挖掘,同时为乳酸菌的应用提供众多可能性。本文就乳酸菌基因组研究的概况、重要乳酸菌基因组、乳酸菌的功能基因组以及比较基因组进行了综述。     

Molecular taxonomy and phylogenetic position of lactic acid bacteria

Lactic acid bacteria, important in food technology, are Gram-positive organisms exhibiting a DNA G + C content of less than 50 mol%. Phylogenetically they are members of the Clostridium-Bacillus subdivision of Gram-positive eubacteria. Lactobacillus and streptococci together with related facultatively anaerobic taxa evolved as individual lines of descent about 1.5-2 billion years ago when the earth passed from an anaerobic to an aerobic environment. In contrast to the traditional, morphology-based classification, the genus Lactobacillus is intermixed with strains of Pediococcus and Leuconostoc. Similarly, the physiology-based clustering of lactobacilli into Thermo-, Strepto- and Betabacterium does not agree with their phylogenetic relationships. On the other hand, the phenotypically defined genus Streptococcus is not a phylogenetic coherent genus but its members fall into at least 3 moderately related genera, i.e. Streptococcus, Lactococcus and Enterococcus. The genus Bifidobacterium, frequently grouped with the lactobacilli, is the most ancient group of the second, the Actinomycetes subdivision of the Gram-positive eubacteria. In addition, propionibacteria, microbacteria and brevibacteria belong to this subdivision but the latter organisms appear as offshoots of non-lactic acid bacteria.     

Comparative genomics of lactic acid bacteria reveals a niche-specific gene set

Background  

The recently sequenced genome of Lactobacillus helveticus DPC4571 [1] revealed a dairy organism with significant homology (75% of genes are homologous) to a probiotic bacteria Lb. acidophilus NCFM [2]. This led us to hypothesise that a group of genes could be determined which could define an organism's niche.     

Functional genomics of lactic acid bacteria: from food to health

Genome analysis using next generation sequencing technologies has revolutionized the characterization of lactic acid bacteria and complete genomes of all major groups are now available. Comparative genomics has provided new insights into the natural and laboratory evolution of lactic acid bacteria and their environmental interactions. Moreover, functional genomics approaches have been used to understand the response of lactic acid bacteria to their environment. The results have been instrumental in understanding the adaptation of lactic acid bacteria in artisanal and industrial food fermentations as well as their interactions with the human host. Collectively, this has led to a detailed analysis of genes involved in colonization, persistence, interaction and signaling towards to the human host and its health. Finally, massive parallel genome re-sequencing has provided new opportunities in applied genomics, specifically in the characterization of novel non-GMO strains that have potential to be used in the food industry. Here, we provide an overview of the state of the art of these functional genomics approaches and their impact in understanding, applying and designing lactic acid bacteria for food and health.     

Understanding the industrial application potential of lactic acid bacteria through genomics

Lactic acid bacteria (LAB) are a heterogeneous group of bacteria contributing to various industrial applications, ranging from food and beverage fermentation, bulk and fine chemicals production to pharmaceuticals manufacturing. Genome sequencing is booming; hitherto, 25 genomes of LAB have been published and many more are in progress. Based on genomic content of LAB, this review highlights some findings related to applications revealed by genomics and functional genomics analyses. Finally, this review summarizes mathematical modeling strategies of LAB in the context of genomics, to further our understanding of industrial related features.     

Numerical taxonomy of psychrotrophic lactic acid bacteria from prepacked meat and meat products

Ninety-four strains of lactic acid bateria isolated from refrigerated, prepacked meat and meat products were together with 59 reference strains of Brochothrix, Lactobacillus, Leuconostoc, Pediococcus and Streptococcus phenotypically classfied, using 96 unit characters. Data were examined using Simple Matching (S_SM) or Jaccard coefficient (S_J), and unweighted pair group algorithm with arithmetic averages. Twenty-three clusters with two or more members were defined at the 84% S_SM-similarity level which corresponded to the S_J-similarity level of 61%. Based on S_SM, most field strains were included in nine clusters, and with three unsignificant exceptions these contained no reference strains. The field clusters were designated Carnobacterium piscicola (cluster 1; 5% of field isolates), Carnobacterium divergens(cluster 2; 9% of field isolates), Leuconostoc (cluster 9; 18% of field isolates) and Lactobacillus (cluster 4, 10, 11, 12, 13 and 14; together 60% of field isolates). The Lactobacillus clusters had many features in common with cluster II of Shaw & Harding (1984). Phenotypical characteristics of major clusters are given. The S_SM and S_J based classifications basically coincided for the field strains; the exception was cluster 4 which now were split in two parts. Fourteen clusters were made up of mainly reference strains (S_SM). Most of them included more than one type strain on species level; exceptions were Brochothrix thermosphacta (cluster 3), Lactobacillus salivarius (cluster 17) and Leuconostoc mesenteroides (cluster 18). Several rearrangements were seen amongst the clusters of the reference strains when S_J, instead of S_SM, was used for clustering.     

Numerical taxonomy and identification of lactic acid bacteria from spoiled, vacuum-packaged vienna sausages

Sixty-one lactic acid bacteria from spoiled vacuum-packaged vienna sausages and 15 reference strains were tested for 72 phenotypic characteristics. An identification key and a computer data base, both specific for lactic acid bacteria from meat sources, were used for identification and the results were compared. There was a high correlation (86.9%) between the two procedures in the identification of strains to genus level. However, only a 54.8% correlation was obtained in identifying strains to the species level. With numerical taxonomy ( S _sm matching coefficient with average linkage clustering) 60 strains were recovered in six clusters at the 89% similarity level. While most Leuconostoc strains clustered separately from the Lactobacillus strains, the identity of many leuconostocs was not clarified. The presence of a heterogeneous cluster containing typical and 'atypical' strains of the Lactobacillus saké/curvatus group and a separate homogeneous Lact. curvatus cluster was noted. Closer examination of the data suggested that the 'atypical' lactobacilli were all strains of Lact. saké.     

乳酸菌对微囊藻毒素的清除

【目的】研究唾液乳杆菌(Lactobacillus salivarius BBE09-18)、发酵乳杆菌(L.fermentum BBE09-29)以及干酪乳杆菌(L.casei Zhang)对藻毒素的清除能力以及影响乳酸菌清除藻毒素的主要因素,以期为进一步解析乳酸菌清除藻毒素的作用机制提供理论基础,并为去除食品体系中的藻毒素提供新的思路。【方法】研究乳酸菌细胞的不同生理状态(活细胞与死细胞)对藻毒素清除能力的影响,考察菌浓差异、起始藻毒素浓度差异、葡萄糖的供给等对乳酸菌清除藻毒素效能的影响。【结果】3株实验乳酸菌均具有清除藻毒素的能力,其中,L.casei Zhang的藻毒素清除能力最强,当藻毒素初始浓度为150μg/L时,24h后残留藻毒素浓度为85.5μg/L,清除率可达43%。此外,研究还发现乳酸菌活细胞的清除能力显著高于热失活后的死细胞。添加外源物质葡萄糖能显著提高实验菌株清除藻毒素的效率,在初始浓度为1800μg/L的藻毒素溶液中,当添加5%(w/v)葡萄糖后,L.casei Zhang经24h可清除92%的藻毒素。【结论】3株乳酸菌均具有藻毒素清除能力;同时,菌体浓度以及菌体自身的生理状态对藻毒素的清除效率具有重要影响,乳酸菌对藻毒素的清除可能与菌体的代谢活性相关。     

Comparative studies of lactic acid dehydrogenases in lactic acid bacteria

The stability, pH-dependence and kinetic properties of the Mn²⁺ and FDP-activated NAD-dependent lactic acid dehydrogenases from Lactobacillus casei ssp. casei (ATCC 393) and L. curvatus (DSM) 20010) were studied after the enzymes were purified to homogeneity by affinity chromatography. Both enzymes are virtually unidirectional, catalysing efficiently only the reduction of pyruvate. They are similar with respect to the effector requirement and pH-optimum. They differ, however, in their electrophoretic mobility, heat stability, pH-dependence of the Mn²⁺ requirement and several kinetic properties. It is suggested that most of these differences are caused by differences of the negative charges in the vicinity of the FDP-binding site or the site responsible for the interaction of the subunits of the enzymatically active oligomeres.Abbreviations l-LDH l-Lactic acid dehydrogenase - FDP Fructose-1,6-bisphosphate - DTE Dithioerythrol AddendumIn the case of the L. casei-LDH the shape of the NADH saturation curve is not changed by omitting the effectors FDP and Mn 2⁺. The K _M under these conditions is 3 fold higher (10.10 ^–5 M).