IRD, UMR NUTRIPASS, IRD/Montpellier2/Montpellier1, F-34394 Montpellier, France.
CNRS-UMR 8030 and Commissariat à l'Energie Atomique et aux Energies Alternatives CEA/DSV/IG/Genoscope LABGeM, Evry, France.
Int J Food Microbiol. 2018 Feb 2;266:346-354. doi: 10.1016/j.ijfoodmicro.2017.10.011. Epub 2017 Oct 6.
The objective of this work was to investigate the nutritional potential of Lactobacillus plantarum A6 in a food matrix using next generation sequencing. To this end, we characterized the genome of the A6 strain for a complete overview of its potential. We then compared its transcriptome when grown in a food matrix made from pearl millet to and its transcriptome when cultivated in a laboratory medium. Genomic comparison of the strain L. plantarum A6 with the strains WCFS1, ST-III, JDM1 and ATCC14917 led to the identification of five regions of genomic plasticity. More specifically, 362 coding sequences, mostly annotated as coding for proteins of unknown functions, were specific to L. plantarum A6. A total of 1201 genes were significantly differentially expressed in laboratory medium and food matrix. Among them, 821 genes were up-regulated in the food matrix compared to the laboratory medium, representing 23% of whole genomic objects. In the laboratory medium, the expression of 380 genes, representing 11% of the all genomic objects was at least double than in the food matrix. Genes encoding important functions for the nutritional quality of the food were identified. Considering its efficiency as an amylolytic strain, we investigated all genes involved in carbohydrate metabolism, paying particular attention to starch metabolism. An extracellular alpha amylase, a neopullulanase and maltodextrin transporters were identified, all of which were highly expressed in the food matrix. In addition, genes involved in alpha-galactoside metabolism were identified but only two of them were induced in food matrix than in laboratory medium. This may be because alpha galactosides were already eliminated during soaking. Different biosynthetic pathways involved in the synthesis of vitamin B (folate, riboflavin, and cobalamin) were identified. They allowed the identification of a potential of vitamin synthesis, which should be confirmed through biochemical analysis in further work. Surprisingly, some genes involved in metabolism and bioaccessibility of iron were identified. They were related directly to the use of transport of iron, or indirectly to metabolism of polyphenols, responsible of iron chelation in the food. The combination of genomics and transcriptomics not only revealed previously undocumented nutritional properties of L. plantarum A6, but also documented the behaviour of this bacterium in food.
本工作旨在利用下一代测序技术研究植物乳杆菌 A6 在食品基质中的营养潜力。为此,我们对 A6 菌株的基因组进行了特征描述,以全面了解其潜在特性。然后,我们比较了其在珍珠粟制成的食品基质中生长时的转录组和在实验室培养基中生长时的转录组。对菌株 L. plantarum A6 与 WCFS1、ST-III、JDM1 和 ATCC14917 的基因组比较导致了五个基因组可塑性区域的鉴定。具体来说,362 个编码序列,主要注释为未知功能的蛋白质编码,是 L. plantarum A6 特有的。在实验室培养基和食品基质中,有 1201 个基因的表达存在显著差异。其中,821 个基因在食品基质中上调,与实验室培养基相比,占整个基因组对象的 23%。在实验室培养基中,380 个基因的表达至少是食品基质的两倍,占所有基因组对象的 11%。鉴定了对食品营养质量具有重要功能的基因。考虑到其作为淀粉分解菌的效率,我们研究了所有参与碳水化合物代谢的基因,特别关注淀粉代谢。鉴定了一种细胞外α-淀粉酶、一种新普鲁兰酶和麦芽糖转运蛋白,它们在食品基质中均高度表达。此外,还鉴定了参与α-半乳糖苷代谢的基因,但只有其中两个在食品基质中的诱导作用强于在实验室培养基中的诱导作用。这可能是因为α-半乳糖苷在浸泡过程中已经被消除。鉴定了不同的维生素 B(叶酸、核黄素和钴胺素)合成途径。它们允许鉴定出合成维生素的潜力,这需要在进一步的工作中通过生化分析来证实。令人惊讶的是,还鉴定了一些与铁的代谢和生物利用度相关的基因。它们直接与铁的运输有关,或者间接与多酚的代谢有关,多酚在食品中负责铁的螯合。基因组学和转录组学的结合不仅揭示了植物乳杆菌 A6 以前未记录的营养特性,还记录了该细菌在食品中的行为。
