为阐明茶叶籽水浆发酵微生物种类及其在发酵过程中的作用特性,对发酵5βh的茶叶籽水浆发酵液进行微生物分离与提纯,从中分离纯化出1株菌株。经形态观察、16βS rDNA及pheS基因测序与比对、系统发育树的构建与分析,确定该菌株为植物乳杆菌(Lactobacillus plantarum ssp. Plantarum);命名该菌株为茶叶籽乳杆菌(Lactobacillus plantarum ssp. plantarum JJZ21),菌种保藏号为CCTCC M 2016471。在茶叶籽水浆发酵过程中,发酵液中茶叶籽乳杆菌的数量在5βh之后逐渐快速增加,至12~15βh之间达到最大值,之后又逐渐降低,至22βh后,逐渐趋于稳定。伴随茶叶籽乳杆菌数量的增加,发酵液中的干物质含量、可溶性糖含量、可溶性蛋白含量及其pH均明显下降,呈极显著(P<0.01)负相关性。茶叶籽乳杆菌通过消耗发酵液中的可溶性糖及可溶性蛋白等物质,向发酵液中分泌乳酸等酸性有机物,导致发酵液pH逐渐降低,为发酵液中的油脂体上浮以及茶叶籽水浆发酵分层现象发生奠定了基础。
To clarify the fermentation properties of microorganisms in fermentation layering of tea-seed-water-milk (TSWM), identification and isolation of microorganism in 5βh fermented TSWM were conducted. Based on morphological observation, 16βS rDNA, pheS gene sequencing and comparison, and phylogenetic tree analysis, a bacterial strain isolated from the fermented TSWM was identified as a strain of Lactobacillus plantarum ssp. Plantarum and named as L. plantarum ssp. Plantarum JJZ21 (LPJJZ21). Its culture preservation number was CCTCC M 2016471. In the fermentation process of TSWM, the total number of LPJJZ21 was increased rapidly after 5βh, peaked at 12βh to 15βh, then gradually reduced until 22βh, finally stayed stable after 22βh. Accompanied by the increasing of LPJJZ21, the dry matter, soluble sugar, soluble protein contents and pH decreased significantly, with highly significant (P<0.01) and negative correlation. Through consuming the soluble protein, soluble sugar and other substances in fermented TSWM, JJZ21 secreted acidic organic matter (such as lactate acid and so on), leading to the gradual decrease of pH in fermented TSWM, which were the prerequisite for the floating up of fat bodies in fermented TSWM and fermentation layering of TSWM.
[1] Jiang J Z, Ren C J, Wang Z B, et al.New process for extracting oil and starch from tea seeds[J]. Journal of Food Science and Engineering, 2013, 3(12): 699-703.
[2] 姜金仲, 杨鹏鸣, 王超英, 等. 茶叶籽水浆发酵分层过程及其间总质量动态研究[J]. 中国粮油学报, 2017, 32(2): 104-108.
[3] 姜金仲, 王超英, 韩晗, 等. 茶叶籽仁水浆静置发酵分层生产茶叶籽油及淀粉[J]. 中国油脂, 2015, 40(3): 74-78.
[4] 姜金仲, 杨鹏鸣, 王兴春, 等. 茶叶籽酵母的分离鉴定及其发酵特性研究[J]. 食品工业科技, 2017, 38(21): 105-108.
[5] 鲁战会, 李里特, 李再贵, 等. 自然发酵对淀粉凝胶的改性机理及发酵菌株的筛选[J]. 食品与发酵工业, 2002, 28(4): 1-6.
[6] 吕加平. 酸奶中乳酸菌镜检涂片的特殊染色法[J]. 微生物学通报, 1999, 26(4): 281-282.
[7] 东秀珠, 蔡妙英. 常见细菌系统鉴定手册[M]. 北京: 北京科学出版社, 2001: 373-380.
[8] Frédéric Ampe, Edouard Miambi.Cluster analysis, richness and biodiversity indexes derived from denaturing gradient gel electrophoresis fingerprints of bacterial communities demonstrate that traditional maize fermentations are driven by the transformation process[J]. International Journal of Food Microbiology, 2000, 60(1): 91-97.
[9] 辛若竹, 丁梅, 孟宪志, 等. 活性酸乳中每种益生菌总数的同时计数法[J]. 食品科学, 2008, 29(4): 244-248.
[10] 金雷, 陈瑜, 严忠雍, 等. 邻苯二甲酸二丁酯高效降解菌H-2的分离鉴定及其降解特性[J]. 食品科学, 2014, 35(15): 202-206.
[11] 刘峨. 不同放线菌酮培养基配制方法的对比研究[J]. 啤酒科技, 2015, 206(2): 20-21.
[12] 黄婉玉, 曹炜, 李菁, 等. 考马斯亮蓝法测定果汁中蛋白质的含量[J]. 食品与发酵工业, 2009, 35(5): 160-162.
[13] 朱彩平, 张声华. 枸杞子水提物中多糖含量的测定[J]. 食品与发酵工业, 2005, 31(2): 111-113.
[14] 冯磊, 麻成金, 黄群, 等. 二次通用旋转组合设计法优化酶法提取茶叶籽蛋白工艺[J]. 食品工业科技, 2012, 33(17): 215-219.
[15] Seunggyu L, Yeonjung L, Minkyung K, et al.A study on the yogurt manufacture suitability and antimicrobial activity of lactobacillus plantarum lhb55 isolated from kimchi[J]. Journal of Animal Science & Technology, 2010, 52(2): 141-148.
[16] Erkkilä S, Petäjä E, Eerola S, et al.Flavor profiles of dry sausages fermented by selected novel meat starter cultures[J]. Meat Science, 2001, 58(2): 111-116.
[17] 周光燕, 张小平, 钟凯. 乳酸菌对泡菜发酵过程中亚硝酸盐含量变化及泡菜品质的影响研究[J]. 西南农业学报, 2006(2): 290-293.
[18] 郭翔, 艾连中, 吴艳, 等. 植物乳杆菌Lactobacillus plantarum GUO安全性研究[J]. 食品科学, 2009, 30(23): 436-438.
[19] 江和源, 张建勇, 高晴晴. 茶皂素的性质、制备与应用[J]. 中国茶叶, 2007(3): 14-15.
[20] 李国玉. 美拉德褐变型发酵乳饮料的研制[J]. 中国乳业, 2015(4): 64-66.
[21] 任晓镤, 许倩, 李明杨, 等. 酿酒酵母对乳杆菌生长与生物膜形成的影响[J]. 农业机械学报, 2016, 47(2): 264-269.
浙公网安备 33019902000101号 
