中国乳业 ›› 2023, Vol. 0 ›› Issue (10): 105-115.doi: 10.12377/1671-4393.23.10.19
银佳1,2, 冯立科2, 杨爱君2, 彭小霞2, 李理1,*
YIN Jia1,2, FENG Like2, YANG Aijun2, PENG Xiaoxia2, LI Li1,*
摘要: B族维生素是人体所必需的营养素之一,常作为辅酶参与机体多种生理代谢,已被证实与能量代谢、免疫调节、神经递质的合成、肠道健康等密切相关。缺乏B族维生素往往会导致机体氨基酸、碳水化合物和脂肪酸的合成与代谢紊乱、免疫功能受损、神经递质合成障碍、肠道内环境紊乱,甚至影响核酸生物合成,最终导致多种疾病,危害人体健康。因此,日常摄入充足的B族维生素对于机体健康稳态具有重要意义。已有研究表明,微生物具有合成B族维生素的能力,其合成的B族维生素可提供给机体吸收利用、调节机体肠道健康。此外,部分益生菌如双歧杆菌和乳杆菌,也被证实具有合成B族维生素的能力。因此筛选可高产B族维生素的益生菌并将其应用于食品当中,增强食品营养价值,为强化食品中的B族维生素提供新思路,对于功能性食品的开发具有重要的意义。本文概述常见B族维生素的生理功能、合成B族维生素微生物的研究进展以及可合成B族维生素的益生菌在食品中的应用。
[1] Peterson C T,Rodionov D A,Osterman A L,et al.B vitamins and their role in immune regulation and cancer[J]. Nutrients,2020,12(11):3380. [2] Mozaffari H,Askari M,Bellissimo N,et al.Associations between dietary intake of B vitamins and cardiovascular risk factors in elderly men:A cross-sectional study[J]. International Journal of Clinical Practice,2021,75(10):e14691. [3] Wu H H L,McDonnell T,Chinnadurai R. Physiological associations between vitamin B deficiency and diabetic kidney disease[J]. Biomedicines,2023,11(4):1153. [4] Lindschinger M,Tatzber F,Schimetta W,et al.Bioavailability of natural versus synthetic B vitamins and their effects on metabolic processes[J]. MMW Fortschritte der Medizin,2020,162(Suppl 4):17-27. [5] Liu J,Tan Y,Cheng H,et al.Functions of gut microbiota metabolites,current status and future perspectives[J]. Aging and Disease,2022,13(4):1106-1126. [6] Uebanso T,Shimohata T,Mawatari K,et al.Functional roles of B-vitamins in the gut and gut microbiome[J]. Molecular Nutrition & Food Research,2020,64(18):e2000426. [7] Rodionov D A,Arzamasov A A,Khoroshkin M S,et al.Micronutrient requirements and sharing capabilities of the human gut microbiome[J]. Frontiers in Microbiology,2019,10:1316. [8] Maldonado Galdeano C,Cazorla S I,Lemme Dumit J M,et al. Beneficial effects of probiotic consumption on the immune system[J]. Annals of Nutrition & Metabolism,2019,74(2):115-124. [9] Wang Y,Wu Y,Wang Y,et al.Antioxidant properties of probiotic bacteria[J]. Nutrients,2017,9(5):521. [10] LeBlanc J G,Chain F,Martin R,et al. Beneficial effects on host energy metabolism of short-chain fatty acids and vitamins produced by commensal and probiotic bacteria[J]. Microbial Cell Factories,2017,16:79. [11] Hrubsa M,Siatka T,Nejmanova I,et al.Biological properties of vitamins of the B-complex, part 1:vitamins B(1),B(2),B(3),and B(5)[J]. Nutrients,2022,14(3):484. [12] Yoshii K,Hosomi K,Sawane K,et al.Metabolism of dietary and microbial vitamin B family in the regulation of host immunity[J]. Frontiers in Nutrition,2019,6:48. [13] Lonsdale D.A review of the biochemistry,metabolism and clinical benefits of thiamin(e) and its derivatives[J]. Evidence-Based Complementary and Alternative Medicine,2006,3(1):49-59. [14] Mrowicka M,Mrowicki J,Dragan G,et al. The importance of thiamine(vitamin B1)in humans[J]. Bioscience Reports,2023,43(10):BSR20230374. [15] Soto-Martin E C,Warnke I,Farquharson F M,et al. Vitamin biosynthesis by human gut butyrate-producing bacteria and cross-feeding in synthetic microbial communities[J]. mBio,2020,11(4):e00886-20. [16] Magnusdottir S,Ravcheev D,de Crecy-Lagard V,et al. Systematic genome assessment of B-vitamin biosynthesis suggests co-operation among gut microbes[J]. Frontiers in Genetics,2015,6:148. [17] Khromova N Y,Epishkina J M,Karetkin B A,et al.The combination of in vitro assessment of stress tolerance ability,autoaggregation,and vitamin B-producing ability for new probiotic strain introduction[J]. Microorganisms,2022,10(2):470. [18] Odumosu B T,Bamidele T A,Ofem D W,et al.Screening,isolation and biotechnological potentials of foodborne Lactobacillus fermentum strains MT903311 and MT903312[J]. Heliyon,2023,9(4):e14959. [19] Allaart J G,van Asten A J,Vernooij J C,et al. Effect of Lactobacillus fermentum on beta2 toxin production by Clostridium perfringens[J]. Applied Environmental Microbiology,2011,77(13):4406-4411. [20] Park J,Hosomi K,Kawashima H,et al.Dietary vitamin B1 intake influences gut microbial community and the consequent production of short-chain fatty acids[J]. Nutrients,2022,14(10):2078. [21] Fawzi N Y,Abdelghani D Y,Abdel-azim M A,et al. The ability of probiotic lactic acid bacteria to ferment egyptian broken rice milk and produce rice-based yoghurt[J]. Annals of Agricultural Science,2022,67(1):107-118. [22] Hou J W,Yu R C,Chou C C.Changes in some components of soymilk during fermentation with bifidobacteria[J]. Food Research International,2000,33(5):393-397. [23] Li S,Chen C,Ji Y,et al.Improvement of nutritional value,bioactivity and volatile constituents of quinoa seeds by fermentation with Lactobacillus casei[J]. Journal of Cereal Science,2018,84:83-89. [24] Saedisomeolia A,Ashoori M.Riboflavin in human health:a review of current evidences[J]. Advances in Food and Nutrition Research,2018,83:57-81. [25] Mosegaard S,Dipace G,Bross P,et al.Riboflavin deficiency-implications for general human health and inborn errors of metabolism[J]. International Journal of Molecular Sciences,2020,21(11):3847. [26] Thakur K,Tomar S K,De S.Lactic acid bacteria as a cell factory for riboflavin production[J]. Microbial Biotechnology,2016,9(4):441-451. [27] Carrizo S L,Montes de Oca C E,Laino J E,et al. Ancestral andean grain quinoa as source of lactic acid bacteria capable to degrade phytate and produce B-group vitamins[J]. Food Research International,2016,89(Part 1):488-494. [28] Wan Z,Zheng J,Zhu Z,et al.Intermediate role of gut microbiota in vitamin B nutrition and its influences on human health[J]. Frontiers in Nutrition,2022,9:1031502. [29] Kim J-Y,Choi E-J,Lee J-H,et al.Probiotic potential of a novel vitamin B2-overproducing Lactobacillus plantarum Strain,HY7715,isolated from Kimchi[J]. Applied Sciences,2021,11(13):5765. [30] Solopova A,Bottacini F,Venturi Degli Esposti E,et al. Riboflavin biosynthesis and overproduction by a derivative of the human gut commensal Bifidobacterium longum subsp. infantis ATCC 15697[J]. Frontiers in Microbiology,2020,11:573335. [31] Llamas-Arriba M G,Hernandez-Alcantara A M,Mohedano M L,et al. Lactic acid bacteria isolated from fermented doughs in spain produce dextrans and riboflavin[J]. Foods,2021,10(9):2004. [32] Russo P,Capozzi V,Arena M P,et al.Riboflavin-overproducing strains of Lactobacillus fermentum for riboflavin-enriched bread[J]. Applied Microbiology And Biotechnology,2014,98(8):3691-3700. [33] Bhushan B,Kumkum C R,Kumari M,et al.Soymilk bio-enrichment by indigenously isolated riboflavin-producing strains of Lactobacillus plantarum[J]. LWT-Food Science and Technology,2020,119:108871. [34] Juarez del Valle M,Laino J E,Savoy de Giori G,et al. Riboflavin producing lactic acid bacteria as a biotechnological strategy to obtain bio-enriched soymilk[J]. Food Research International,2014,62:1015-1019. [35] Juarez Del Valle M,Laino J E,de Moreno de LeBlanc A,et al. Soyamilk fermented with riboflavin-producing Lactobacillus plantarum CRL 2130 reverts and prevents ariboflavinosis in murine models[J]. British Journal of Nutrition,2016,116(7):1229-1235. [36] Ge Y Y,Zhang J R,Corke H,et al.Screening and spontaneous mutation of pickle-derived Lactobacillus plantarum with overproduction of riboflavin,related mechanism,and food application[J]. Foods,2020,9(1):88. [37] Spacova I,Ahannach S,Breynaert A,et al.Spontaneous riboflavin-overproducing Limosilactobacillus reuteri for biofortification of fermented foods[J]. Frontiers in Nutrition,2022,9:9. [38] Williams P A,Harder J M,Foxworth N E,et al.Vitamin B(3)modulates mitochondrial vulnerability and prevents glaucoma in aged mice[J]. Science,2017,355(6326):756-760. [39] Lipszyc P S,Cremaschi G A,Zorrilla-Zubilete M,et al.Niacin modulates pro-inflammatory cytokine secretion. a potential mechanism involved in its anti-atherosclerotic effect[J]. The Open Cardiovascular Medicine Journal,2013,7:90-98. [40] Maslak E,Zloch M,Arendowski A,et al.Isolation and identification of Lactococcus lactis and Weissella cibaria strains from fermented beetroot and an investigation of their properties as potential starter cultures and probiotics[J]. Foods,2022,11(15):2257. [41] Tangyu M,Fritz M,Ye L,et al.Co-cultures of Propionibacterium freudenreichii and Bacillus amyloliquefaciens cooperatively upgrade sunflower seed milk to high levels of vitamin B(12) and multiple co-benefits[J]. Microbial Cell Factories,2022,21(1):48. [42] Jung M Y,Lee C,Seo M J,et al.Characterization of a potential probiotic bacterium Lactococcus raffinolactis WiKim0068 isolated from fermented vegetable using genomic and in vitro analyses[J]. BMC Microbiology,2020,20(1):136. [43] Palachum W,Choorit W,Chisti Y.Nutritionally enhanced probioticated whole pineapple juice[J]. Fermentation,2021,7(3):178. [44] Oguro Y,Nishiwaki T,Shinada R,et al.Metabolite profile of koji amazake and its lactic acid fermentation product by Lactobacillus sakei UONUMA[J]. Journal of Bioscience and Bioengineering,2017,124(2):178-183. [45] He W,Hu S,Du X,et al.Vitamin B5 reduces bacterial growth via regulating innate immunity and adaptive immunity in mice infected with Mycobacterium tuberculosis[J]. Frontiers in Immunology,2018,9:365. [46] Kuwaki S,Nakajima N,Tanaka H,et al.Plant-based paste fermented by lactic acid bacteria and yeast:functional analysis and possibility of application to functional foods[J]. Biochemistry Insights,2012,5:21-29. [47] Gaucheron F.Milk and dairy products:a unique micronutrient combination[J]. Journal of the American College of Nutrition,2011,30(5 Suppl 1):400S-409S. [48] Stach K,Stach W,Augoff K.Vitamin B6 in health and disease[J]. Nutrients,2021,13(9):3229. [49] Toriumi K,Miyashita M,Suzuki K,et al.Vitamin B6 deficiency hyperactivates the noradrenergic system,leading to social deficits and cognitive impairment[J].Translational Psychiatry,2021,11(1):262. [50] Qian B,Shen S,Zhang J,et al.Effects of vitamin B6 deficiency on the composition and functional potential of T cell populations[J]. Journal of Immunology Research,2017,2017:2197975. [51] Szutowska J,Gwiazdowska D,Rybicka I,et al.Controlled fermentation of curly kale juice with the use of autochthonous starter cultures[J]. Food Research International,2021,149:110674. [52] Li H,Yan L,Wang J,et al.Fermentation characteristics of six probiotic strains in soymilk[J]. Annals of Microbiology,2012,62(4):1473-1483. [53] Belda E, Voland L, Tremaroli V, et al.Impairment of gut microbial biotin metabolism and host biotin status in severe obesity:effect of biotin and prebiotic supplementation on improved metabolism[J]. GUT,2022,71(12):2463-2480. [54] Skupsky J,Sabui S,Hwang M,et al.Biotin supplementation ameliorates murine colitis by preventing NF-kappa B activation[J]. Cellular and Molecular Gastroenterology and Hepatology,2020,9(4):557-567. [55] Hanna M,Jaqua E,Nguyen V,et al.B vitamins:functions and uses in medicine[J]. The Permanente Journal,2022,26(2):89-97. [56] Courtemanche C,Elson-Schwab I,Mashiyama S T,et al.Folate deficiency inhibits the proliferation of primary human CD8+ T lymphocytes in vitro[J]. Journal of Immunology,2004,173(5):3186-3192. [57] Zhang X H,Bao G Y,Liu D B,et al.The association between folate and Alzheimer's Disease:a systematic review and meta-analysis[J]. Frontiers in Neuroscience,2021,15:661198. [58] Albano C,Silvetti T,Brasca M. Screening of lactic acid bacteria producing folate and their potential use as adjunct cultures for cheese bio-enrichment[J]. FEMS Microbiology Letters,2020,367(9):fnaa059. [59] Hossain K S,Amarasena S,Mayengbam S.B vitamins and their roles in gut health[J]. Microorganisms,2022,10(6):1168. [60] Sugahara H,Odamaki T,Hashikura N,et al.Differences in folate production by bifidobacteria of different origins[J]. Bioscience of Microbiota Food and Health,2015,34(4):87-93. [61] Liu M,Chen Q,Sun Y,et al.Probiotic potential of a folate-producing strain Latilactobacillus sakei LZ217 and its modulation effects on human gut microbiota[J]. Foods,2022,11(2):234. [62] Tamene A,Baye K,Kariluoto S,et al.Lactobacillus plantarum P2R3FA isolated from traditional cereal-based fermented food increase folate status in deficient rats[J]. Nutrients,2019,11(11):2819. [63] Wu Z,Wu J,Cao P,et al.Characterization of probiotic bacteria involved in fermented milk processing enriched with folic acid[J]. Journal of Dairy Science,2017,100(6):4223-4229. [64] Albano C,Silvetti T,Brasca M. Screening of lactic acid bacteria producing folate and their potential use as adjunct cultures for cheese bio-enrichment[J]. FEMS Microbiology Letters,2020,367(9):fnaa059. [65] Tamene A,Baye K,Humblot C.Folate content of a staple food increased by fermentation of a cereal using selected folate-producing microorganisms[J]. Heliyon,2022,8(5):e09526. [66] Tamura J,Kubota K,Murakami H,et al.Immunomodulation by vitamin B12: augmentation of CD8+ T lymphocytes and natural killer (NK) cell activity in vitamin B12-deficient patients by methyl-B12 treatment[J]. Clinical and Experimental Immunology,1999,116(1):28-32. [67] Partearroyo T,Ubeda N,Montero A,et al.Vitamin B(12)and folic acid imbalance modifies NK cytotoxicity,lymphocytes B and lymphoprolipheration in aged rats[J]. Nutrients,2013,5(12):4836-4848. [68] Guy LeBlanc J,Milani C,Savoy de Giori G,et al. Bacteria as vitamin suppliers to their host: a gut microbiota perspective[J]. Current Opinion in Biotechnology,2013,24(2):160-168. [69] Li P GuQ,YangS etal Characterization of extracellular vitamin B12 Producing Lactobacillus plantarum strains and assessment of probiotic potentials[J]. Food chomistry,2017,234:494-501. [70] Vogel R F,Pavlovic M,Ehrmann M A,et al. Genomic analysis reveals Lactobacillus sanfranciscensis as stable element in traditional sourdoughs[J].Microbial Cell Factories,2011,10 (Supp11):S6.+ [71] Kumari M,Bhushan B,Kokkiligadda A,et al.Vitamin B12 biofortification of soymilk through optimized fermentation with extracellular B12 producing Lactobacillus isolates of human fecal origin[J]. Current Research in Food Science,2021,4:646-654. [72] Thompson H O,Onning G,Holmgren K,et al.Fermentation of cauliflower and white beans with Lactobacillus plantarum-impact on levels of riboflavin,folate,vitamin B(12),and amino acid composition[J]. Plant Foods for Human Nutrition,2020,75(2):236-242. [73] Hossain M N,Ranadheera C S,Fang Z,et al.Production of short chain fatty acids and vitamin B-12 during the in-vitro digestion and fermentation of probiotic chocolate[J]. Food Bioscience,2022,47:101682. [74] Xie C,Coda R,Chamlagain B,et al.Fermentation of cereal,pseudo-cereal and legume materials with Propionibacterium freudenreichii and Levilactobacillus brevis for vitamin B12 fortification[J]. LWT-Food Science and Technology,2021,137:110431. |
[1] | 孙潇慧, 泮秋立, 霍胜楠, 钟立霞, 程祥龙, 李文婷, 孟静. 微生物法检测特殊医学用途婴儿配方食品中叶酸含量的研究[J]. 中国乳业, 2023, 0(6): 68-72. |
[2] | 肖沙, 赵格, 赵建梅, 张喜悦, 刘娜, 徐莹, 王君玮. 生鲜乳中致病微生物污染来源、危害与消减措施[J]. 中国乳业, 2023, 0(5): 65-70. |
[3] | 蔡云阁. 益生菌治疗奶牛乳腺炎的研究进展[J]. 中国乳业, 2023, 0(4): 67-71. |
[4] | 刘洋乐, 孟毅, 魏勇, 李智星, 彭夏雨. 牛粪可再生垫料(RMS)的安全制备[J]. 中国乳业, 2023, 0(2): 34-39. |
[5] | 黄思, 吴晓春, 余智瑾, 赵存朝, 彭磊. 乳饼副产物乳清液制备乳清粉的工艺研究[J]. 中国乳业, 2022, 0(9): 102-107. |
[6] | 杨露. 益生菌对奶牛产奶量、乳成分及瘤胃微生物区系的影响[J]. 中国乳业, 2022, 0(8): 15-18. |
[7] | 高雁, 杨胜春, 曾军, 霍向东, 孙建, 林青. 益生菌对断奶后犊牛生长性能及血清指标的影响[J]. 中国乳业, 2022, 0(8): 19-23. |
[8] | 刘宝华, 徐庆利, 巴宁宁, 杜玲玲. 特殊医学用途全营养配方食品干法混合工序的工艺验证[J]. 中国乳业, 2022, 0(6): 75-80. |
[9] | 巴宁宁. 特殊医学用途婴儿配方食品冲调温度的研究分析[J]. 中国乳业, 2022, 0(5): 84-88. |
[10] | 刘宝华. 特殊医学用途配方食品干法工艺中混合机最佳参数的试验研究[J]. 中国乳业, 2022, 0(4): 87-93. |
[11] | 王亚利, 胡师齐, 李启明, 刘绒梅, 曹珺. 预包装食品标签审核关键要素及对策[J]. 中国乳业, 2022, 0(3): 71-75. |
[12] | 金佳佳, 严家俊, 綦艳, 姚丽锋, 张娟, 黄翠莉, 吴思敏, 庄艺协. 基质辅助激光解吸电离飞行时间质谱在乳品微生物中的应用进展[J]. 中国乳业, 2022, 0(12): 89-94. |
[13] | 杨纯佳, 蒋轩, 张娟, 黄翠莉. 基质辅助激光解吸电离飞行时间质谱法在婴幼儿食品蜡样芽胞杆菌检测中的应用[J]. 中国乳业, 2022, 0(11): 81-84. |
[14] | 邢益俊, 何瑛, 林木娣, 赖书莹, 曹学思, 杨爱君, 纪坤发. Soleris微生物快速检测系统在巴氏杀菌乳中的应用验证[J]. 中国乳业, 2022, 0(11): 85-89. |
[15] | 闫刘芹. 乳品质量安全法律监管的问题及对策从麦趣尔丙二醇事件切入[J]. 中国乳业, 2022, 0(10): 10-14. |
|