生物技术通讯
生物技術通訊
생물기술통신
LETTERS IN BIOTECHNOLOGY
2013年
5期
631-635
,共5页
孟祥荣%苏山春%邓仲良%刘子中%杨瑞馥%韩延平%黄新祥
孟祥榮%囌山春%鄧仲良%劉子中%楊瑞馥%韓延平%黃新祥
맹상영%소산춘%산중량%류자중%양서복%한연평%황신상
鼠疫耶尔森菌%非编码小RNA%Hfq蛋白%RNA-蛋白免疫共沉淀
鼠疫耶爾森菌%非編碼小RNA%Hfq蛋白%RNA-蛋白免疫共沉澱
서역야이삼균%비편마소RNA%Hfq단백%RNA-단백면역공침정
Yersinia pestis%small non-coding RNA%Hfq protein%RNA-binding protein immmunoprecipitation
目的::建立RNA免疫共沉淀方法,为鼠疫耶尔森菌Hfq蛋白相关非编码小RNA(sRNA)提供体内验证方法。方法:首先在RNA结合蛋白Hfq下游加入Flag标签,用Flag标签抗体进行免疫共沉淀,获得蛋白-RNA复合物,然后从沉淀的蛋白-RNA复合物中分离得到纯化的RNA;通过Western印迹检测各步骤Hfq蛋白的表达,再利用Northern印迹检测目的sRNA--RyhB1和RyhB2。结果:构建了带有Flag标签的RNA结合蛋白Hfq的载体,此载体转导入hfq缺失株后与鼠疫菌野生株的生长曲线无明显差异;通过RNA-蛋白免疫共沉淀技术鉴定出已知与鼠疫菌Hfq蛋白结合的2个sRNA--RyhB1和RyhB2。结论:建立了利用RNA-蛋白免疫共沉淀鉴定与鼠疫菌Hfq蛋白结合的sRNA的技术,为细菌sRNA的验证、功能研究和体内蛋白质与RNA相互作用研究提供了有利工具。
目的::建立RNA免疫共沉澱方法,為鼠疫耶爾森菌Hfq蛋白相關非編碼小RNA(sRNA)提供體內驗證方法。方法:首先在RNA結閤蛋白Hfq下遊加入Flag標籤,用Flag標籤抗體進行免疫共沉澱,穫得蛋白-RNA複閤物,然後從沉澱的蛋白-RNA複閤物中分離得到純化的RNA;通過Western印跡檢測各步驟Hfq蛋白的錶達,再利用Northern印跡檢測目的sRNA--RyhB1和RyhB2。結果:構建瞭帶有Flag標籤的RNA結閤蛋白Hfq的載體,此載體轉導入hfq缺失株後與鼠疫菌野生株的生長麯線無明顯差異;通過RNA-蛋白免疫共沉澱技術鑒定齣已知與鼠疫菌Hfq蛋白結閤的2箇sRNA--RyhB1和RyhB2。結論:建立瞭利用RNA-蛋白免疫共沉澱鑒定與鼠疫菌Hfq蛋白結閤的sRNA的技術,為細菌sRNA的驗證、功能研究和體內蛋白質與RNA相互作用研究提供瞭有利工具。
목적::건립RNA면역공침정방법,위서역야이삼균Hfq단백상관비편마소RNA(sRNA)제공체내험증방법。방법:수선재RNA결합단백Hfq하유가입Flag표첨,용Flag표첨항체진행면역공침정,획득단백-RNA복합물,연후종침정적단백-RNA복합물중분리득도순화적RNA;통과Western인적검측각보취Hfq단백적표체,재이용Northern인적검측목적sRNA--RyhB1화RyhB2。결과:구건료대유Flag표첨적RNA결합단백Hfq적재체,차재체전도입hfq결실주후여서역균야생주적생장곡선무명현차이;통과RNA-단백면역공침정기술감정출이지여서역균Hfq단백결합적2개sRNA--RyhB1화RyhB2。결론:건립료이용RNA-단백면역공침정감정여서역균Hfq단백결합적sRNA적기술,위세균sRNA적험증、공능연구화체내단백질여RNA상호작용연구제공료유리공구。
Objective: To establish the RNA-binding immunoprecipitation(RIP) method for identification of Yer-sinia pestis small non-coding RNA(sRNA) associated with Hfq protein in vivo. Methods: The Flag peptide-coding gene was fused downstream of the hfq gene. These method involve immunoprecipitation of endogenously formed complexes of RNA-binding protein Hfq by the antibody of Flag and isolation of RNA associated with Hfq protein. Every part of Hfq protein was confirmed by Western blot, then the interest sRNA, RyhB1 and RyhB2, were detect-ed by Northern blot. Results: The plasmid of RNA-binding protein Hfq with the Flag was successfully construct-ed, this carrier transformed into hfq deletion mutant did not have any significant difference in the growth curve of wild-type Y.pestis. Two Hfq-binding sRNA, RyhB1 and RyhB2, were identified in Y.pestis by RNA-binding protein immmunoprecipitation. Conlusion: RNA-binding protein immmunoprec ipitation has been established for identifica-tion of Y.pestis sRNA-binding Hfq protein, which was a high sensitivity method and provided an powerful tool for validation of bacterial sRNA, function studies and protein interaction with RNA studies in vivo.