生物素对发酵过程中MscCG外排L-谷氨酸的影响

doi:10.13560/j.cnki.biotech.bull.1985.2020-0003

摘要/Abstract

摘要：

谷氨酸棒杆菌发酵产生的谷氨酸主要是通过外排蛋白在细胞膜拉伸时打开通道从而将谷氨酸排至胞外。由于培养基中的生物素会影响细胞膜成分从而影响膜张力,因此生物素的浓度会间接影响谷氨酸外排蛋白的能力和胞外谷氨酸的积累量。研究表达谷氨酸外排蛋白 MscCG对谷氨酸棒杆菌发酵生产L-谷氨酸的影响,并利用 M2P BioLector微型生物反应器在线检测发酵过程中的生物量、溶氧及pH的变化。结果表明,生物素对MscCG外排谷氨酸影响很大,0.5 μg/L生物素是本实验条件下的亚适量,在此生物素浓度下外排蛋白 MscCG排出谷氨酸的量达到最高;低于亚适量,菌体生长速度缓慢从而谷氨酸产量降低;高于亚适量,菌体生长速度快但谷氨酸浓度低,发酵液中溶氧缺乏导致乳酸积累。因此,发酵过程中需综合考虑对生物素浓度、溶氧及pH值的动态控制,以期达到谷氨酸发酵的最高水平。

关键词: L-谷氨酸, 生物素, 外排蛋白MscCG, 发酵, 谷氨酸棒杆菌

Abstract:

The L-glutamate produced by the fermentation of Corynebacterium glutamicum is mainly released by the L-glutamate exporters’ opening the channel when the cell membrane is stretched. The biotin in medium can affect the components of cell membrane and thus affect the membrane tension,and the concentration of biotin can indirectly affect the capacity of L-glutamate exporter and the accumulation of extracellular L-glutamate in the fermentation broth. In this study,we investigated the effect of L-glutamate exporter MscCG on the L-glutamate production from the fermentation of C. glutamicum,and online monitored the changes of biomass,dissolved oxygen and pH in the fermentation process using the M2P BioLector micro-bioreactor. The results showed that biotin had a great influence on the efflux of L-glutamate by MscCG. 0.5 μg/L biotin was the suboptimal under the condition of this experiment,at which the amount of L-glutamate exported by MscCG reached the highest. When the concentration was lower than that,the growth rate of the bacteria was slow and the efflux of L-glutamate reduced. When the concentration was > 0.5 μg/L,the growth rate of bacteria was fast but the concentration of L-glutamate was low,and the lack of dissolved oxygen led to the accumulation of lactate. Therefore,the concentration of biotin,the dissolved oxygen and pH control should be adjusted in a combined way for maximum productivity of L-glutamate.

Key words: L-glutamate, biotin, MscCG, fermentation, Corynebacterium glutamicum

聂志华, 朱蕾蕾. 生物素对发酵过程中MscCG外排L-谷氨酸的影响[J]. 生物技术通报, 2020, 36(10): 150-155.

NIE Zhi-hua, ZHU Lei-lei. Effects of Biotin on L-Glutamate Efflux Mediated by MscCG in Fermentation Process[J]. Biotechnology Bulletin, 2020, 36(10): 150-155.

图/表 5

参考文献 22

[1]	Brosnan JT, Brosnan ME. Glutamate:a truly functional amino acid[J]. Amino Acids, 2013,45:413-418. URL pmid: 22526238
[2]	Jinap S, Hajeb P, Glutamate. Its applications in food and contribution to health[J]. Appetite, 2010,55(1):1-10. URL pmid: 20470841
[3]	Becker J, Wittmann C. Systems and synthetic metabolic engineering for amino acid production—the heartbeat of industrial strain development[J]. Curr Opin Biotechnol, 2012,23:718-726. URL pmid: 22244788
[4]	Wen J, Xiao Y, Liu T, et al. Rich biotin content inlignocellulose biomass plays the key role in determining cellulosic glutamic acid accumulation by Corynebacterium glutamicum[J]. Biotechnology for Biofuels, 2018,11(1):132-143.
[5]	Shiio I, Otsuka SI, Katsuya N. Effect of biotin on the bacterial formation of glutamic acid. II. Metabolism of glucose[J]. Journal of Biochemistry, 1962,52(1):108-116.
[6]	Eggelling L, Krumbach K, Sahm H. L-glutamate efflux with Corynebacterium glutamicum:why is penicillin treatment or Tween addition doing the same[J]. Journal of Molecular Microbiology ＆ Biotechnology, 2001,3(1):67-68.
[7]	Clement Y, Laneelle G. Glutamate excretion mechanism in Corynebacterium glutamicum triggering by biotin starvation or by surfactant addition[J]. Journal of General Microbiology, 1986,132(4):925-929.
[8]	Eggeling L. Exporters for production of amino acids and other small molecules[J]. Advances in Biochemical Engineering-Biotechnology, 2017,159:199-225.
[9]	Marin K, Kramer R. Amino acid transport systems in biotechnolo-gically relevant bacteria[C]// Wendisch VF, Amino acid biosyn-confproc-pathways, regulation and metabolic engineering[C]. Berlin:Springer, 2005: 289-325.
[10]	Park JH, Lee SY. Towards systems metabolic engineering of microorganisms for amino acid production[J]. Current Opinion in Biotechnology, 2008,19:454-460. URL pmid: 18760356
[11]	Nakamura J, Hirano S, Wachi M. Mutations of the Corynebacterium glutamicum NCgl1221 gene, encoding a mechanosensitive channel homolog, induce L-glutamic acid production[J]. Applied and Environmental Microbiology, 2007,73(14):4491-4498. URL pmid: 17513583
[12]	Wang Y, Cao GQ, Xu DY, et al. A Novel Corynebacterium glutamicum l-glutamate exporter[J]. Applied and Environmental Microbiology, 2018,84(6):1-17.
[13]	Becker M, Krämer R. MscCG from Corynebacterium glutamicum:functional significance of the C-terminal domain[J]. Eur Biophys J, 2015,44(7):577-588. URL pmid: 26033538
[14]	Nakayama Y, Komazawa K, Bavi N, et al. Evolutionary specializa-tion of MscCG, an MscS-like mechanosensitive channel, in amino acid transport in Corynebac-terium glutamicum[J]. Sci Rep, 2018,8(1):12893. URL pmid: 30150671
[15]	Bavi N, Cortes DM, Cox CD, et al. The role of MscL amphipathic N terminus indicates a blueprint for bilayer mediated gating of mechanosensitive channels[J]. Nat Commun, 2016,7:11984.
[16]	Levina N, Totemeyer S, Stokes NR, et al. Protection of Escherichia coli cells against extreme turgor by activation of MscS and MscL mechanosensitive channels:identification of genes required for MscS activity[J]. EMBO Journal, 1999,18(7):1730-1737.
[17]	Nakamura J, Hirano S, Ito H, et al. Mutations of the Corynebacterium glutamicum NCgl1221 gene, encoding a mechanosensitive channel homolog, induce l-glutamic acid production[J]. Appl Environ Microbiol, 2007,73(14):4491-4498. URL pmid: 17513583
[18]	Jansen RP, Beuck C, Moch M, et al. A closer look at Aspergillus:online monitoring via scattered light enables reproducible phenotyping[J]. Fungal Biotechnol, 2019,6:11.
[19]	林灯. 谈谈谷氨酸发酵中生物素问题[J]. 发酵科技通讯, 2003(1):25-26.
	Lin D. Problems of biotin in glutamate fermentation process[J]. Bulletin of Fermentation Science and Technology, 2003(1):25-26.
[20]	刘树涛, 王文风. 生物素与谷氨酸发酵[J]. 山东食品发酵, 2009(4):11-14.
	Liu ST, Wang WF. Biotin and glutamate fermentation[J]. Bulletin of Fermentation Science and Technology, 2009(4):11-14.
[21]	张克旭, 邱志成, 林瑾琳, 等. 控制生物素亚适量在谷氨酸发酵中的本质作用是什么[J]. 发酵科技通讯, 2009,2:23.
	Zhang KX, Qiu ZC, Lin JL, et al. What is the essential role of controlling the optimum amount of biotin in glutamate fermentation process[J]. Bulletin of Fermentation Science and Technology, 2009,38(2):23.
[22]	张克旭, 邱志成, 林瑾琳, 等. 谷氨酸发酵过程中pH值过高或过低有什么不好[J]. 发酵科技通讯, 2009,38(3):47.
	Zhang KX, Qiu ZC, Lin JL, et al. The effect of high or low pH in glutamate fermentation process[J]. Bulletin of Fermentation Science and Technology, 2009,38(3):47.

仪器名称	生产厂家
SBA-40D生物传感分析仪	山东省科学院生物研究所
Biolector 微型生物反应器	德国M2P Labs
全自动高压灭菌锅	山东博科科学仪器有限公司
恒温培养摇床	上海知楚仪器有限公司
培养箱	上海和呈仪器制造有限公司
紫外超净工作台	苏州安泰空气技术有限公司
紫外分光光度计	上海奥析科学仪器有限公司
电子天平	上海精密仪器仪表有限公司
精密pH 计	上海般特仪器有限公司
电转仪	Eppendorf 公司
恒温自动水浴锅	江苏金怡仪器科技有限公司

仪器名称	生产厂家
SBA-40D生物传感分析仪	山东省科学院生物研究所
Biolector 微型生物反应器	德国M2P Labs
全自动高压灭菌锅	山东博科科学仪器有限公司
恒温培养摇床	上海知楚仪器有限公司
培养箱	上海和呈仪器制造有限公司
紫外超净工作台	苏州安泰空气技术有限公司
紫外分光光度计	上海奥析科学仪器有限公司
电子天平	上海精密仪器仪表有限公司
精密pH 计	上海般特仪器有限公司
电转仪	Eppendorf 公司
恒温自动水浴锅	江苏金怡仪器科技有限公司