不同来源植物乳杆菌基因组结构和功能差异的比较研究

[目的] 本试验研究不同来源植物乳杆菌（Lactobacillus plantarum）基因特点以及在不同环境下其基因多样性,探究2株L.plantarum A8和P9在肠道生境及植物表面适应性的异同,为优良菌株的开发提供理论基础。[方法] 本研究对从动物肠道和植物表面分离获得的L.plantarum A8和L.plantarum P9的基因组进行分析,利用第二代测序技术（NextGeneration Sequencing,NGS）,基于Illumina NovaSeq测序平台,同时利用第三代单分子测序技术,基于PacBio Sequel测序平台,对L.plantarum A8和L.plantarum P9进行测序。采用Carbohydrate-active enzymes（CAZy）、Koyto encyclopedia of genes and genomes（KEGG）和Clusters of orthologous genes（COG）数据库对基因组进行功能注释;采用CGView软件绘制菌株的基因组环形图谱。应用比较基因组学与已经公开发表的其他L.plantarum基因组进行比较分析。[结果] 由研究可知L.plantarum A8和L.plantarum P9基因组大小存在差异,通过构建系统发育树发现2株菌与其他来源的L.plantarum分在同一分支,并且L.plantarum P9与母乳来源的L.plantarum WLPL04菌株距离最近,而L.plantarum A8与L.paraplantarum DSM10667距离最近。通过基因家族分析可知,2株菌共有基因为2643个,其中包括一些抗应激蛋白如热休克蛋白、冷休克蛋白。L.plantarum A8和P9独特基因分别为321和336个,L.plantarum A8中独特基因主要参与DNA复制、ABC转运系统（ABC transfer system）、PTS系统（phosphotransferase system）、磺酸盐转运系统、氨基酸生物合成等代谢通路;L.plantarum P9的独特基因以参与碳水化合物的运输和代谢基因居多,例如rpiA基因、lacZ基因、FruA基因等。[结论] 通过比较基因组学方法解析L.plantarum的基因组信息,发现动物肠道来源的L.plantarum具有较好的氨基酸转运能力,植物表面附着的L.plantarum菌株具有较好碳水化合物利用能力,从而为益生菌的开发与利用提供理论依据。     

全基因组测序揭示两株泡菜源植物乳杆菌基因型差异和潜在益生特性北大核心

【目的】为了探究植物乳杆菌(Lactiplantibacillus plantarum)基因型差异和潜在益生特性,采用全基因组测序技术对其进行测序并解析基因组序列及生物特性。【方法】本研究基于HiSeq和PacBio测序平台,对团队前期从四川多代泡菜中分离获得、体外益生特性评价良好的潜在益生菌菌株L.plantarum Eden-Star PC06和L.plantarum Eden-Star PC108的全基因组进行测序。利用相关生物信息学软件对原始数据进行组装及其后续的功能注释、分子进化、菌株安全性、次级代谢产物合成基因簇以及益生特性相关基因进行分析。【结果】通过基因组装得到了2株植物乳杆菌的全基因组信息,L.plantarum Eden-Star PC06和Eden-Star PC108基因组大小分别为3163902 bp和3205054 bp;GC含量分别为44.68%和44.67%;分别包含3161个和3197个DNA编码序列;功能基因数据库比对结果显示2株菌在碳水化合物利用、氨基酸利用和糖基转移酶等基因上得到大量注释;通过比对数据库,在2株植物乳杆菌全基因组上发现了4个与肠液耐受相关的胆盐水解酶基因、完整的植物乳杆菌细菌素合成相关基因簇和抵御多种胁迫的益生相关基因。【结论】本研究通过全基因组测序在基因水平上探究了L.plantarum Eden-Star PC06和Eden-Star PC108基因型差异和益生特性基因,证明L.plantarum Eden-Star PC06和Eden-Star PC108是2株有应用前景的益生菌菌株,以期为筛选优良益生菌菌株和评价其益生特性提供遗传学基础。     

Selection of <Emphasis Type="Italic">Lactobacillus plantarum</Emphasis> TN627 as a new probiotic candidate based on <Emphasis Type="Italic">in vitro</Emphasis> functional properties

Nine lactobacilli previously selected for high antagonism against food borne bacterial pathogens were identified via 16S rRNA gene sequencing and screened for probiotic potential for use in poultry production. The lactobacilli were subjected to a subtractive in vitro analysis system using a certified probiotic as reference. This allowed for selection of a milk-derived Lactobacillus plantarum strain, termed TN627. This organic acid-producing bacterium was free of harmful enzymatic activity and sensitive to several antibiotics. It also showed good growth at pH 4 and in the presence of bile. L. plantarum TN627 also exhibited high efficacy of adhesion to chicken enterocytes, which correlated with detecting genes encoding the mucusbinding, adhesion-promoting proteins (Mub and MapA) and the adhesion-like factor EF-Tu, commonly involved in adherence of lactobacilli to mucosal surfaces. Taken together, our findings suggest that TN627 is a promising probiotic candidate with high potential for application as a supplement in the animal feed industry.     

Lactobacillus Plantarum 299v Changes miRNA Expression in the Intestines of Piglets and Leads to Downregulation of LITAF by Regulating ssc-miR-450a

Lactiplantibacillus plantarum subsp. plantarum 299v (L. plantarum 299v) is one of the most important probiotic strains in animal health, but the molecular mechanisms of how it exerts health benefits remain unclear. The purpose of this study was to explore the changes in miRNA expression profiles in the intestinal tissues of piglets by L. plantarum 299v and to explore its possible molecular regulatory mechanism in intestinal function. Neonatal piglets were orally administered L. plantarum 299v daily from 1 to 20 days old, and high-throughput sequencing was conducted to analyse the changes in miRNA expression in the jejunum and ileum. The results showed that 370 known porcine miRNAs were identified from eight libraries. Five miRNAs (ssc-miR-21-5p, -143-3p, -194b-5p, -192, and -126-3p) were highly expressed in the intestinal tissues. There were 15 differentially expressed miRNAs between the control group and the L. plantarum group, and only miR-450a was expressed differentially in both intestinal tissues. KEGG analysis revealed that the target genes of the 15 differentially expressed miRNAs were involved in 37 significantly enriched pathways (P < 0.01). Then, quantitative polymerase chain reaction confirmed that the miRNA expression was corresponded well with those from the sequencing. Luciferase reporter assays verified that lipopolysaccharide-induced TNF-α factor is a target of miR-450a. Our results also showed L. plantarum 299v could influence intestinal function by changing the levels of cytokines via miRNA expression. This is the first study to analyse differential expression miRNA profiles in intestinal tissue after L. plantarum 299v treatment and investigate the molecular regulatory mechanism of functional miRNA.

     

Next generation sequencing,biochemical characterization,metabolic pathway analysis of novel probiotic Pediococcus acidilactici NCDC 252 and it’s evolutionary relationship with other lactic acid bacteria

Pediococcus acidilactici NCDC 252 is a facultative anaerobe of dairy origin that possessed all studied in vitro probiotic attributes and several useful enzyme activities. Its whole genome was sequenced and analysed for its evolutionary relationship with other lactic acid bacteria (LAB). This is a novel sequence and first report of genome sequence of P. acidilactici of dairy origin. Its genome is relatively larger than other studied genomes of P. acidilactici and is comprised of 40 scaffolds that totals to 3,243,337 bases and 44.5% GC content. A total of 3054 coding sequences (CDS) were identified by RAST and DIAMOND servers. The genome also encoded different enzyme activities required for utilization of various carbohydrates. This was also confirmed by carbohydrate utilization studies. The genome also encoded genes for probiotics properties. The phylogenetic analysis of P. acidilactici NCDC 252 genome was done using Maximum Parsimony and Maximum Likelihood methods to study its evolution and relatedness to other LABs based upon their 16S rDNA sequences. The strain exhibited highest resemblance to Lactobacillus plantarum WCFS1 and is also much close to P. acidilactici based on similarity of ribosomal protein. The strain seems to have acquired some genes for its adaptation in dairy/environmental niche. This genome sequence is novel with genome more similar to L. plantarum and biochemical and phenotypic characteristics of P. acidilactici.

     

基于比较基因组学揭示不同植物乳杆菌的遗传特征及菌株差异——以Lactobacillus plantarum P9和Lp-6研究为例

[目的]植物乳杆菌(Lactbacillus plantarum,L.plantarum)在食品、医药和动物养殖等多个领域均有应用。本文以L.plantarum P9和Lp-6为例,解析L.plantarum遗传背景和基因组特征,为其鉴定和开发奠定基础。[方法]本研究采用PacBio SMRT测序技术完成了L.plantarum P9和Lp-6全基因组测序,结合已公开的110株L.plantarum全基因组数据和1株模式菌株ATCC 14917T数据,通过比较基因组学方法探究L.plantarum基因组的差异。[结果]L.plantarum P9和Lp-6基因组大小分别为3314.1和3482.5 kb,GC含量(%)分别为44.38%和44.32%,二者分别含有8个和9个质粒。113株L.plantarum系统发育树结果显示,L.plantarum P9与L.plantarum ATCC 14917T遗传距离更近,L.plantarum Lp-6更接近祖先群体分支。与L.plantarum WCSF1相比,含有xerS等基因的22.0 kb基因组片段在L.planarum Lp-6上发生了倒位,在L.plantarum P9基因组中缺失;L.plantarum Lp-6染色体插入含tagF等基因的13.0 kb片段;包含gpmA等基因的14.4 kb基因片段插入到L.plantarum P9染色体中。[结论]通过比较基因组学方法解析L.plantarum P9和Lp-6遗传信息,发现不同L.plan tarum菌株的遗传特征存在差异。     

Genotypic adaptations associated with prolonged persistence of Lactobacillus plantarum in the murine digestive tract

Probiotic bacteria harbor effector molecules that confer health benefits, but also adaptation factors that enable them to persist in the gastrointestinal tract of the consumer. To study these adaptation factors, an antibiotic-resistant derivative of the probiotic model organism Lactobacillus plantarum WCFS1 was repeatedly exposed to the mouse digestive tract by three consecutive rounds of (re)feeding of the longest persisting colonies. This exposure to the murine intestine allowed the isolation of intestine-adapted derivatives of the original strain that displayed prolonged digestive tract residence time. Re-sequencing of the genomes of these adapted derivatives revealed single nucleotide polymorphisms as well as a single nucleotide insertion in comparison with the genome of the original WCFS1 strain. Detailed in silico analysis of the identified genomic modifications pinpointed that alterations in the coding regions of genes encoding cell envelope associated functions and energy metabolism appeared to be beneficial for the gastrointestinal tract survival of L. plantarum WCFS1. This work demonstrates the feasibility of experimental evolution for the enhancement of the gastrointestinal residence time of probiotic strains, while full-genome re-sequencing of the adapted isolates provided clues towards the bacterial functions involved. Enhanced gastrointestinal residence is industrially relevant because it enhances the efficacy of the delivery of viable probiotics in situ.     

Phenotypic and genomic diversity of Lactobacillus plantarum strains isolated from various environmental niches

Lactobacillus plantarum is a ubiquitous microorganism that is able to colonize several ecological niches, including vegetables, meat, dairy substrates and the gastro‐intestinal tract. An extensive phenotypic and genomic diversity analysis was conducted to elucidate the molecular basis of the high flexibility and versatility of this species. First, 185 isolates from diverse environments were phenotypically characterized by evaluating their fermentation and growth characteristics. Strains clustered largely together within their particular food niche, but human fecal isolates were scattered throughout the food clusters, suggesting that they originate from the food eaten by the individuals. Based on distinct phenotypic profiles, 24 strains were selected and, together with a further 18 strains from an earlier low‐resolution study, their genomic diversity was evaluated by comparative genome hybridization against the reference genome of L. plantarum WCFS1. Over 2000 genes were identified that constitute the core genome of the L. plantarum species, including 121 unique L. plantarum‐marker genes that have not been found in other lactic acid bacteria. Over 50 genes unique for the reference strain WCFS1 were identified that were absent in the other L. plantarum strains. Strains of the L. plantarum subspecies argentoratensis were found to lack a common set of 24 genes, organized in seven gene clusters/operons, supporting their classification as a separate subspecies. The results provide a detailed view on phenotypic and genomic diversity of L. plantarum and lead to a better comprehension of niche adaptation and functionality of the organism.     

Genome shuffling of Lactobacillus plantarum C88 improves adhesion

Genome shuffling is an important method for rapid improvement in microbial strains for desired phenotypes. In this study, ultraviolet irradiation and nitrosoguanidine were used as mutagens to enhance the adhesion of the wild-type Lactobacillus plantarum C88. Four strains with better property were screened after mutagenesis to develop a library of parent strains for three rounds of genome shuffling. Fusants F3-1, F3-2, F3-3, and F3-4 were screened as the improved strains. The in vivo and in vitro tests results indicated that the population after three rounds of genome shuffling exhibited improved adhesive property. Random Amplified Polymorphic DNA results showed significant differences between the parent strain and recombinant strains at DNA level. These results suggest that the adhesive property of L. plantarum C88 can be significantly improved by genome shuffling. Improvement in the adhesive property of bacterial cells by genome shuffling enhances the colonization of probiotic strains which further benefits to exist probiotic function.     

Identification of <Emphasis Type="Italic">Lactobacillus plantarum</Emphasis> genes modulating the cytokine response of human peripheral blood mononuclear cells

Background  

Modulation of the immune system is one of the most plausible mechanisms underlying the beneficial effects of probiotic bacteria on human health. Presently, the specific probiotic cell products responsible for immunomodulation are largely unknown. In this study, the genetic and phenotypic diversity of strains of the Lactobacillus plantarum species were investigated to identify genes of L. plantarum with the potential to influence the amounts of cytokines interleukin 10 (IL-10) and IL-12 and the ratio of IL-10/IL-12 produced by peripheral blood mononuclear cells (PBMCs).     

鸡源暹罗芽孢杆菌CML548的益生特性及全基因组分析

【背景】芽孢杆菌是用于动物微生态制剂的重要菌株之一。暹罗芽孢杆菌因具有较强的抑菌活性,近年来受到广泛关注。【目的】对实验室前期分离的鸡源暹罗芽孢杆菌CML548的益生特性进行评价,通过全基因组测序及生物信息学分析,探究其抑菌及潜在的益生机制。【方法】通过牛津杯法、稀释涂布平板法分别对菌株CML548的抑菌和产酶特性、酸和胆盐的耐受性进行研究。使用IlluminaHiSeq2500测序平台进行全基因组测序,并通过多种生物信息学工具和数据库对基因组进行注释和分析。【结果】体外实验表明该菌株具有优良的益生性状：能够有效抑制致病性大肠杆菌、鼠伤寒沙门氏菌、产气荚膜梭菌的生长;能够同时产生蛋白酶、淀粉酶和纤维素酶;具有较高的酸和胆盐耐受性。全基因组测序分析表明菌株CML548的基因组大小为4061741bp,GC含量为46.07%,预测到3 961个编码基因。分别有1 693、2 704、3 413、186、67、1、5个基因被GO、KEGG、COG、CAZy、DBAASP、CARD、VFDB数据库注释;通过antiSMASH预测到16个与次级代谢产物合成相关的基因簇。此外,还发现其含有抗菌活性...     

Evaluation of the probiotic potential and effect of encapsulation on survival for <Emphasis Type="Italic">Lactobacillus plantarum</Emphasis> ST16Pa isolated from papaya

Capability to produce antilisterial bacteriocins by lactic acid bacteria (LAB) can be explored by the food industry as a tool to increase the safety of foods. Furthermore, probiotic activity of bacteriogenic LAB brings extra advantages to these strains, as they can confer health benefits to the consumer. Beneficial effects depend on the ability of the probiotic strains to maintain viability in the food during shelf-life and to survive the natural defenses of the host and multiply in the gastrointestinal tract (GIT). This study evaluated the probiotic potential of a bacteriocinogenic Lactobacillus plantarum strain (Lb. plantarum ST16Pa) isolated from papaya fruit and studied the effect of encapsulation in alginate on survival in conditions simulating the human GIT. Good growth of Lb. plantarum ST16Pa was recorded in MRS broth with initial pH values between 5.0 and 9.0 and good capability to survive in pH 4.0, 11.0 and 13.0. Lb. plantarum ST16Pa grew well in the presence of oxbile at concentrations ranging from 0.2 to 3.0%. The level of auto-aggregation was 37%, and various degrees of co-aggregation were observed with different strains of Lb. plantarum, Enterococcus spp., Lb. sakei and Listeria, which are important features for probiotic activity. Growth was affected negatively by several medicaments used for human therapy, mainly anti-inflammatory drugs and antibiotics. Adhesion to Caco-2 cells was within the range reported for other probiotic strains, and PCR analysis indicated that the strain harbored the adhesion genes mapA, mub and EF-Tu. Encapsulation in 2, 3 and 4% alginate protected the cells from exposure to 1 or 2% oxbile added to MRS broth. Studies in a model simulating the transit through the GIT indicated that encapsulated cells were protected from the acidic conditions in the stomach but were less resistant when in conditions simulating the duodenum, jejunum, ileum and first section of the colon. To our knowledge, this is the first report on a bacteriocinogenic LAB isolated from papaya that presents application in food biopreservation and may be beneficial to the consumer health due to its potential probiotic characteristics.     

Biological characteristics and whole-genome analysis of the potential probiotic,Lactobacillus reuteri S5

Lactic acid bacteria are micro-organisms used for probiotic purposes and form major parts of human and mammalian intestinal microbiota, exerting important health-promoting effects on the host. Here, we evaluated Lactobacillus reuteri strain S5 isolated from the intestines of healthy white feather broilers. Lactobacillus reuteri S5 grew best after 20 h of incubation in MRS medium. Lactic acid production was 1·42 mmol l⁻¹ at 24 h, which was well tolerated. Activities of T-AOC, GSH-Px and T-SOD in the cell-free fermentation supernatant of L. reuteri S5 were higher than those in the bacteria, and the strain showed good hydrophobicity in vitro. The dominant carbon and nitrogen sources of L. reuteri S5 were glucose and soybean meal. A high-quality complete genome map of L. reuteri S5 was obtained using a Pacbio nanopore third-generation sequencing platform. The results showed that L. reuteri S5 possesses a complete primary metabolic pathway, encoding the main functional enzymes of the glycolysis pathway and pentose phosphate pathway. The genome contains genes encoding antioxidants and conferring tolerance to inorganic salt ions, acids and bile salts. This study shows that L. reuteri S5 is a probiotic strain with excellent probiotic characteristics and has great potential for the development of feed additives to promote animal health.     

Lactobacillus plantarum 24, Isolated From the Marula Fruit (Sclerocarya birrea), has Probiotic Properties and Harbors Genes Encoding the Production of Three Bacteriocins

Lactobacillus plantarum 24, isolated from marula fruit grows at pH 4.0 and tolerates acid levels and bile concentrations normally present in the human gastro-intestinal tract. Wistar rats that have been administered L. plantarum 24 showed no signs of discomfort or abnormal behavior. Tissue samples from the liver, spleen and intestine appeared normal. Furthermore, strain 24 harbors the genes encoding plantaricins A, F, and NC8α, a gene encoding immunity to plantaricin, and an ABC transporter similar in sequence to that reported for plantaricin G. At least one antimicrobial peptide within the size range of plantaricins A, F, and NC8α has been detected on a tricine-SDS–PAGE gel. Little is known about the microbial population in marula. This is the first report of a L. plantarum strain from marula fruit with bacteriocin genes and probiotic properties.     

Genome of a virulent bacteriophage Lb338-1 that lyses the probiotic Lactobacillus paracasei cheese strain

There is a lack of fundamental knowledge about the influence of bacteriophage on probiotic bacteria and other commensals in the gut. Here, we present the isolation and morphological and genetic characterization of a virulent narrow-host-range bacteriophage, φLb338-1. This phage was isolated from fresh sewage and was shown to infect the probiotic cheese strain Lactobacillus paracasei NFBC 338. Electron microscopy studies revealed that φLb338-1 is a member of the Myoviridae family, with an isometric head, a medium-sized contractile tail, and a complex base plate. Genome sequencing revealed a 142-kb genome with 199 open reading frames. Putative functions could be assigned to 22% of the open reading frames; these had significant homology to genes found in the broad-host-range SPO1-like group of phages which includes the Enterococcus faecalis phage φEF24C, Listeria phage A511, and Lactobacillus plantarum phage LP65. Interestingly, no significant genomic similarity was observed between the phage and the probiotic host strain. Future studies will determine if the presence of bacteriophage φLb338-1 or others in the human or animal gut plays an antagonistic role against the probiotic effect of beneficial bacteria.     

The effects of a vegetable‐derived probiotic lactic acid bacterium on the immune response

The objective of this study was to investigate the probiotic properties of the fermented vegetable derived lactic acid bacterium, L. plantarum. L. plantarum 10hk2 showed antibacterial activity against pathogenic bacteria and immunomodulating effects on murine macrophage cell lines. RAW 264.7 cells stimulated with viable cells of this probiotic strain increased the amounts of pro‐inflammatory mediators such as IL‐1β, IL‐6 and TNF‐α, as well as the anti‐inflammatory mediator, IL‐10. ICR mice fed with viable cells of L. plantarum 10hk2 had reduced numbers of enteric Salmonella and Shigella species in comparison to controls from 2 weeks after supplementation, and this effect was observed for up to 4 weeks. The findings of this study suggest that this specific lactic acid bacterial strain, which is derived from vegetable fermentation, holds great promise for use in probiotics and as a food additive since it can reduce the number of some pathogenic bacteria through production of lactic acids.     

Genomic Analysis for Antioxidant Property of Lactobacillus plantarum FLPL05 from Chinese Longevity People

Antioxidant activity is one of the important probiotic characteristics for lactic acid bacteria including Lactobacillus plantarum, which is used for food fermentation or as a probiotic supplement. L. plantarum FLPL05 is a novel strain originally isolated from a healthy elderly individual of longevity. The organism has been demonstrated to exhibit high antioxidant property. However, there are limited genomic insights into the antioxidant properties of this organism. In this study, we performed whole-genome analysis regarding its antioxidant property. L. plantarum FLPL05 exhibited higher antioxidant activity compared with that of L. plantarum strains ATCC14917, ATCC8014, and WCFS1. The antioxidant capacity of L. plantarum FLPL05 was genetically linked to its antioxidant system, i.e., glutathione and thioredoxin involved in global regulation of defense against hydrogen peroxide challenge. L. plantarum FLPL05 was further examined for its antioxidant potential in d-Gal-induced aging mice and exhibited a significant increase in the activity of serum glutathione peroxidase (GSH-PX) and a decrease in the level of malondialdehyde (MDA). Moreover, our analyses exhibited a complete gene cluster including plnA, plnB, plnC, plnD, plnE, plnF, plnG, plnH, plnI, plnJ, plnK, plnM, plnN, plnO, plnP, plnQ, plnST, plnU, plnV, plnW, plnX, and plnY for production of bacteriocin. Our results suggest that L. plantarum FLPL05 could be a probiotic candidate.

     

Probiotic characterization of Lactiplantibacillus plantarum HOM3204 and its restoration effect on antibiotic-induced dysbiosis in mice

The purpose of this study was to evaluate the probiotic characteristics of Lactiplantibacillus plantarum HOM3204 isolated from homemade pickled cabbage and to examine its restoration effect on antibiotic-induced dysbiosis in mice. Lact. plantarum HOM3204 tolerated simulated gastric and intestinal juices with a 99·38% survival rate. It also showed strong adhesion ability (3·45%) to Caco-2 cells and excellent antimicrobial activity against foodborne pathogens in vitro. For safety (antibiotic susceptibility) of this strain, it was susceptible to all the tested seven antibiotics. Lact. plantarum HOM3204 had good stability during storage, especially in cold and frozen conditions. Furthermore, Lact. plantarum HOM3204 significantly restored the gut microbiota composition by increasing the abundance of Lactobacilli and Bifidobacteria and decreasing Enterococci, and improved antioxidative function by raising the concentrations of glutathione peroxidase (GSH-Px) and superoxide dismutase (SOD) in serum of antibiotic-induced dysbiosis in mice. These results suggest that Lact. plantarum HOM3204 could be a potential probiotic as a functional food ingredient.     

Complete Genome Sequence of Lactobacillus plantarum JDM1

Lactobacillus plantarum is a lactic acid bacterium (LAB) species commonly used as a probiotic. We have sequenced the genome of Lactobacillus plantarum JDM1, which is a Chinese commercial LAB with several probiotic functions, using a GS 20 system. We recommend that each commercial probiotic strain should undergo complete genome sequencing to ensure safety and stability.Lactic acid bacteria (LAB) play a prominent role in the world food supply, performing the main bioconversions in fermented food, and are also used as probiotic supplements in dairy products and other foods. Lactobacillus plantarum is a LAB species commonly used as a probiotic. We have sequenced the genome of Lactobacillus plantarum JDM1, which is a widely used Chinese commercial LAB with several probiotic functions, using a GS 20 system (454 Life Science Corporation) (11). Two hundred thirty-six thousand, five hundred sixty-three high-quality reads were assembled with the 454 assembly tool, which had an average depth of 18.6-fold coverage of the genome and yielded 367 contigs. Among these, 225 large contigs represented 99.17% of the draft sequence. In the finishing process, the order of the selected large contigs was determined by BLAST analysis with the originally published genome sequence of strain WCFS1 (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"AL935263","term_id":"342240345","term_text":"AL935263"}}AL935263) (8). Physical gaps were filled through sequencing of PCR products that spanned these regions using ABI 3730 xl DNA sequencers. Sequence assembly was accomplished by using the Phred/Phrap/Consed software package (4, 7). To ensure final accuracy, the errors in homopolymer sites that arose from the pyrosequencing method were solved via comparison with the corresponding sites on WCFS1 and then resequencing of the ambiguous bases using the ABI 3730 xl DNA sequencer.The complete genome of Lactobacillus plantarum JDM1 contains a single, circular chromosome of 3,197,759 bp and two plasmids (pLP2000 [2,062 bp] and pLP9000 [9,254 bp]). The two plasmids have been sequenced and published, with GenBank accession numbers {"type":"entrez-nucleotide","attrs":{"text":"AY096004","term_id":"20853777","term_text":"AY096004"}}AY096004 and {"type":"entrez-nucleotide","attrs":{"text":"AY096005","term_id":"20853804","term_text":"AY096005"}}AY096005 (3). The overall GC content of the chromosome is 44.66%, whereas the plasmids have a GC content slightly lower than that of the chromosome. The entire genome of JDM1 contains 2,948 protein-coding genes, 62 tRNA-encoding genes, and 16 rRNA-encoding genes. Several repeated sequences, designated ISP2, were found in the chromosome which were almost the same as those in WCSF1, identified as a class of transposase-encoding regions representing mobile genetic elements. The other repeated sequence, ISP1 of WCSF1, was absent in JDM1.The entire genomic sequence of L. plantarum JDM1 was a little shorter than that of L. plantarum WCSF1 (3.3 Mb). The two genomes were highly similar (>90% by BLASTN analysis) with respect to genome structure and gene order. Intraspecies diversity may be required for successful adaptation in a complex ecological habitat (2). L. plantarum JDM1 has been grown as a probiotic in rich nutritional medium for so long that the genome may have gradually contracted. As supporting evidence, many sugar transport and metabolism genes in WCFS1 were absent in JDM1.The prophage sequences and locations of JDM1 and WCFS1 are highly variable. L. plantarum JDM1 contains three prophage elements in its genome. R-Pg1, representing a short prophage remnant, is about 14 kb in size, which is similar to R-Lp3 in WCFS1. Pg2 and Pg3 are two ∼39-kb-long prophages that are closely related to Listeria phage B025 (accession no. {"type":"entrez-nucleotide","attrs":{"text":"DQ003639","term_id":"66733223","term_text":"DQ003639"}}DQ003639) and the phage Pediococcus pentosaceus ATCC 25745 (accession no. {"type":"entrez-nucleotide","attrs":{"text":"CP000422","term_id":"116101968","term_text":"CP000422"}}CP000422), respectively.The genomes of LAB evolve actively to adapt to nutritionally rich environments. Even for two strains of the same species, differences obviously exist. The degradation of the genome appears to be an ongoing process not only in all species of Lactobacillus (10) but also in different strains of the same species(2).With the development of better living conditions, the biosafety of food and medicine has received more attention. Lactobacillus bacteria have been supposed to have a “generally accepted as safe” status, but they still have been associated with negative reports (1, 6, 9). More about the functional mechanisms of JDM1 and potential side effects would be explored by complete genome sequencing and data mining. Furthermore, comparative genomics analysis could be carried out with Chinese and European strains. We believe the complete genome of each probiotic strain should be sequenced to ensure safety and stability. At the end of the day, we will get what we pay for in terms of microbial genome sequencing projects (5).     

Manufacture of Cheddar cheese using probiotic Lactobacillus plantarum K25 and its cholesterol-lowering effects in a mice model

The probiotic adjunct Lactobacillus plantarum K25 was inoculated into milk to produce probiotic cheese. The effect of Lb. plantarum K25 on cheese composition, microbiological growth and survival during the manufacturing and ripening period, primary and secondary proteolysis during cheese ripening, and the in vivo cholesterol-lowering ability of the probiotic cheese were investigated. The results showed that the use of adjunct Lb. plantarum K25 in Cheddar cheese did not affect the cheese components including moisture, protein, fat, salt content and the pH value of cheese. During the whole ripening period, the probiotic adjunct maintained its viability, suggesting the effectiveness of Cheddar cheese as a vehicle for delivery of probiotic bacteria. No significant differences were observed in water-soluble nitrogen, 70?% ethanol-soluble nitrogen, 5?% phosphotungstic acid-soluble nitrogen, free amino acids and urea-PAGE patterns between the control and probiotic cheeses. Assessment of the in vivo cholesterol-lowering property of cheese with Lb. plantarum K25 showed that the levels of serum total cholesterol, low-density lipoprotein cholesterol and triglycerides decreased significantly, and the level of serum high-density lipoprotein cholesterol increased in mice fed with the probiotic cheese. The results indicated the potential function as a dietary item of the probiotic cheese with Lb. plantarum K25 to reduce the risk of cardiovascular diseases.