姬芳玲
Associate Professor Supervisor of Doctorate Candidates Supervisor of Master's Candidates
Gender:Female
Alma Mater:大连理工大学
Degree:Doctoral Degree
School/Department:生物工程学院
Discipline:Bioengineering
Business Address:生物工程学院547房间
E-Mail:fanglingji@dlut.edu.cn
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Indexed by:期刊论文
Date of Publication:2014-11-01
Journal:JOURNAL OF MOLECULAR CATALYSIS B-ENZYMATIC
Included Journals:SCIE、EI
Volume:109
Page Number:184-190
ISSN No.:1381-1177
Key Words:meso-2,3-Butanediol dehydrogenase; Bacillus subtilis; ITC; Trypsin digestion
Abstract:meso-2,3-Butanediol dehydrogenase (BDH) catalyzes the redox reaction between (R)-acetoin and meso-2,3-butanediol (meso-BD). The BDHs isolated from bacteria are generally characterized as homotetramers. In the present work, an isolated and identified high acetoin (AC)-yielding (41.63 g/L) bacteria strain belonging to Bacillus subtilis but without 2,3-butanediol (BD) byproduct during its fermentation was selected. To understand the characteristics of BDH activity from this high AC-yielding strain, we cloned, purified and compared the BDH from Enterobacter aerogenes (CICC10293) (E. a-BDH) with the BDH from this high AC-yielding strain B. subtilis. Sequence alignments indicate a non-conservative amino acid substitution from Asp to Gly at site 194 on the B. s-BDH compared to that of E. a-BDH. Enzymatic analysis of E. a-BDH and D194G B. s-BDH shows D194G B. s-BDH has almost lost its entire enzymatic activity. Moreover, Isothermal titration calorimetry (ITC) measurements detected the substrate binding for the D194G B. s-BDH but no reaction was detected. Circular dicroism (CD) spectroscopy characterization revealed an identical secondary structure of E. a-BDH and D194G B. s-BDH. Remarkably, D194G B. s-BDH is highly susceptible to protease digestion, suggesting that the aspartic acid to glycine substitution might cause the proteolytic susceptibility of D194G B. s-BDH. Furthermore, by homology modeling with meso-2,3-butanediol dehydrogenase from Klebsiella pneumoniae (K. p-BDH) as a template, Gly194 seems to lose the hydrogen bond interactions with the surrounding residues (Gly206, Gly207 and Thr209), resulting in a putative conformational changes of D194G B. s-BDH which might be responsible for the loss of activity. (C) 2014 Elsevier B.V. All rights reserved.
诚邀有志于探索生命科学前沿的优秀学子,携手推动相关领域的科学研究与创新!
本团队现面向对生物工程、生物医用材料、免疫学、生物信息学、生物学及医学研究等领域感兴趣、热爱科学研究的同学,招收硕士和博士研究生。
姬芳玲,工学博士,副教授,博士生导师,国际磁共振学会会员,美国化学会ACS会员,中国生物材料学会血液净化材料分会委员。研究方向为重大疾病(自身免疫性疾病)发生发展机制、(纳米)抗体的结构与功能、淋巴细胞分离及细胞异质性研究。主持国家自然科学基金2项,省部级基金1项,参加国家重点项目1项。研究成果发表在Angew. Chem.、Analytical Chemistry、Acta Biomaterialia 及Bioconjugate Chemistry等国际一流期刊。已授权中国发明专利3项。
2006年本科毕业于大连理工大学,获生物工程工学学士学位。2013年研究生毕业于大连理工大学,获生物化工工学博士学位。攻读博士学位期间,获得国家留学基金委资助,前往美国匹兹堡大学医学部结构生物学系进行博士联合培养,联合培养博士导师:美国国家科学院院士、英国皇家化学学会会士Angela M. Gronenborn 教授。2013年12月入职大连理工大学生命科学与技术学院。荣获2020年全国高校生命科学类微课教学比赛三等奖。辽宁省普通高等教育(本科)教学成果奖二等奖(排名第六)、大连理工大学优秀教育教学成果一等奖(排名第六)。2022年入选辽宁省首届优秀研究生导师团队成员。主译并由高等教育出版社出版Damien Nevoltris和Patrick Chames编著的《抗体工程》(第三版)。指导本科生荣获全国大学生生命科学竞赛二等奖、指导“大学生创新创业训练计划”国家级、省级和校级等项目。
工作及教育经历
2022/12至今,大连理工大学,生物工程学院,博士生导师
2018/12至今,大连理工大学,生物工程学院,副教授
2013/12-2018/11,大连理工大学,生命科学与技术学院,讲师
2013/08-2013/11,大连理工大学,生命科学与技术学院,师资博士后
2010/09-2012/10,美国匹兹堡大学医学部结构生物学系,联合培养博士
2006/09-2013/07,大连理工大学,生物化工专业,博士学位(保研)
2002/09-2006/07,大连理工大学,生物工程专业,学士学位
