CN106282198A - 拟南芥WRKY家族转录因子AtWRKY44基因,蛋白编码序列及其应用 - Google Patents
拟南芥WRKY家族转录因子AtWRKY44基因,蛋白编码序列及其应用 Download PDFInfo
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Abstract
本发明属于基因工程技术领域,具体涉及一种在拟南芥中表达的WRKY家族转录因子AtWRKY44基因,蛋白编码序列及其应用,包括核苷酸编码序列的克隆,表达载体构建,对拟南芥此基因内源的不同器官、组织的空间表达模式,长日照条件下此基因的表达模式变化进行分析鉴定所使用的方法,以及转化此基因于拟南芥内,进行分子鉴定和开花实验,检测其基因表达量变化及对开花调控的影响。本发明提供的拟南芥基因AtWRKY44可用于植物品种改良,如用于改变植物的开花时间,避开不利的非生物胁迫,最后提高作物产量。
Description
技术领域
本发明属于基因工程技术领域,具体涉及一种在拟南芥中表达的WRKY家族转录因子AtWRKY44基因,蛋白编码序列及其应用,包括核苷酸编码序列的克隆,表达载体构建,对拟南芥此基因内源的不同器官、组织的空间表达模式,长日照条件下此基因的表达模式变化进行分析鉴定所使用的方法,以及转化此基因于拟南芥(Columbia)内,进行分子鉴定和开花实验,检测其基因表达量变化及对开花调控的影响。
背景技术
转录因子又称反式作用因子,是指能与真核基因启动子区域中的顺式作用元件发生特异性结合,激活或抑制下游基因的转录,从而保证目的基因在特定的强度、在特定的时间与空间表达的蛋白质分子(刘蕾等,2008)。
WRKY蛋白N端是一个由60个氨基酸组成的保守结构域,其中WRKYGQK是N端绝对保守的7个氨基酸残基,也就是WRKY结构域。少数WRKY蛋白的WRKY结构域可以被WRRY,WSKY,WKRY,WVKY或WKKY取代(Rushton and Somssich et al., 2010)。在蛋白C是一个锌指结构域。根据WRKY结构域和锌指结构的特点,WRKY家族可以被分成3 类,家族I 含有2 个WRKY结构域; 家族II 多数只有1 个WRKY域,家族I和II包含相同的Cys2 - His2 锌指结构序列;家族III有1 个WRKY域,并包含着2 种不同的锌指结构序列,即Cys2 - His /Cys和Cys2- His2。这三类成员可以特异性结合到W box (T)(T)TGAC(C/T)上(ISHIGURO andNAKAMURA, 1994; Eulgem and Rushton et al., 2000)。
WRKY家族转录因子最初是由2位日本科学家从甜薯中克隆出来(ISHIGURO andNAKAMURA, 1994)。经过二十年的发展,WRKY家族成员在不断地丰富。据统计,WRKY家族在拟南芥和水稻中分别有70、100多个(Hu and Ye et al., 2015),大豆中约有197个成员(Schmutz and Cannon et al., 2010),棉花中已发现超过200多个成员(Dou and Zhanget al., 2014)。此外,还存在于油菜、玉米等其它植物中。WRKY家族已成为植物中最大的转录因子家族之一,并广泛参与植物多项生理过程,如响应生物与非生物胁(Huang andDuman, 2002; Rizhsky and Davletova et al., 2004; Zheng and Abu Qamar et al.,2006),调控叶片衰老(Miao and Laun et al., 2004),参与种皮发育(Johnson andKolevski et al., 2002)以及GA、ABA信号传导等(Zhang and Xie et al., 2004; Zhangand Shin et al., 2009),从而最终影响植物的新陈代谢,形态建成等。拟南芥AtWRKY44,又被称为 TRANSPARENT TESTA GLABRA2(TTG2),是WRKY家族中第一个确认参与植物形态建成的蛋白,参与拟南芥的表皮毛形成、种皮发育、响应干旱下的开花等(Johnson andKolevski et al., 2002; Han and Zhang et al., 2013)。
本发明通过克隆AtWRKY44基因,对其在长日照条件下的开花时间下相关mRNA节律性表达水平进行鉴定,并分析AtWRKY44参与光周期开花调控途径,发现在GI过表达和gi-2突变体中表达量均下调,同时WRKY44与miRNA172靶基因TOE1蛋白能在酵母内进行互作,说明GI、WRKY44和TOE1三者存在某种平衡。将该基因转入野生型拟南芥后,观察转基因株系在长日照下的开花时间以及干旱胁迫下的开花时间。这极大地丰富了WRKY家族转录因子生物学功能,为研究拟南芥如何调控开花打下基础,为最终提高产量提供基因来源和技术支持。
发明内容
本发明的目的在于丰富已有的拟南芥基因AtWRKY44的生物学功能,并提供该基因的应用。
本发明首先提供拟南芥WRKY家族转录因子基因,名为AtWRKY44,为具有特定序列的DNA分子,基因组全长2226bp,其中编码序列1290bp,具体如SEQ ID NO.1所示。
本发明还提供这种AtWRKY44的蛋白编码序列,有321个氨基酸残基,其氨基酸序列为SEQ ID NO.2所示。
本发明还提供用于调取获得拟南芥样品中基因AtWRKY44的一对核苷酸引物。该引物根据基因AtWRKY44设计,使用此对引物对拟南芥样品cDNA进行PCR扩增可获得长1290bp的基因片段。具体的引物序列为:
Forward primer 5'ATGGAGGTGAATGATGGTGAAAG3'(SEQ ID NO.3);
Reverse primer5'TCAAATTGTTTGCTTAGAAAG3' (SEQ ID NO.4)。
本发明还提供用于构建pSKM36- AtWRKY44-MYC载体的引物序列,根据所述基因AtWRKY44编码序列设计,含有AscI/SnaBI酶切位点:
Forward primer 5'GCGCGCATGGAGGTGAATGATGGTGAAAG3'(Asc I)(SEQ ID NO.5);
Reverse primer5'TACGTATCAAATTGTTTGCTTAGAAAG3'(SnaB I)(SEQ ID NO.6)。
本发明还提供构建pSKM36 -AtWRKY44表达载体的方法,其具体步骤如下:
(1)以pCRBlunt-AtWRKY44载体质粒为模板,利用引物SEQ ID NO.5和SEQ ID NO.6克隆出含有SEQ ID NO.1的序列;
(2)将上述序列构建到pSKM36载体中,酶切位点分别为5'- AscIⅠ,3' -SnaBⅠ。经转化,进行阳性克隆的PCR验证。
本发明还提供检测拟南芥基因AtWRKY44在长日照下mRNA表达量变化的方法,包括利用所述基因AtWRKY44的核苷酸序列作为设计引物的保守区段,调取其序列的引物:
Forward primer5'TTTCTTCGTTCCCTAACTCCT3'(SEQ ID NO.7);
Reverse primer5'CCACTCTTTCACCATCATTCAC3' (SEQ ID NO.8)。
本发明还提供检测拟南芥在长日照条件下,基因AtWRKY44表达含量变化的方法,具体步骤为:将拟南芥在长日照下培养至10天后,从开灯时间0小时开始,每隔4小时提取拟南芥的总RNA;利用反转录试剂盒将总RNA反转录成cDNA,利用引物SEQ ID NO.7和SEQ IDNO.8,进行定量PCR检测。
本发明还提供检测拟南芥GI过表达转基因株系中AtWRKY44基因启动子中不同区域的丰富程度所用的两对引物,即利用该基因启动子的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'AAATTGCAAGCTAACAAAGTAAC3' (SEQ ID NO.9);
Reverse primer5'AAATTCAGTCATCTTGTCCAATAC3'(SEQ ID NO.10);
Forward primer5'ATAAGTTGGTACAGTTCAGTTCAC3'(SEQ ID NO.11);
Reverse primer5'TTTAGTTGAAGACTACAGCGAC3'(SEQ ID NO.12)。
本发明还提供检测拟南芥基因FT的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'GGTGGAGAAGACCTCAGGAA3'( SEQ ID NO.13);
Reverse primer5'GGTTGCTAGGACTTGGAACATC3' (SEQ ID NO.14)。
本发明还提供检测拟南芥基因CO的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'ATTCTGCAAACCCACTTGCT3'(SEQ ID NO.15);
Reverse primer5'TTCCAGAAATTGGTAGAATTGGA3'(SEQ ID NO.16)。
本发明还提供检测拟南芥基因TOE1的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'GCGTGGAGTTAGCTTGAGGA3'(SEQ ID NO.17);
Reverse primer5'TCCAGTAAAGGCGATGATCC3'(SEQ ID NO.18)。
本发明还提供检测拟南芥基因TOE2的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'CCTCCGCATAACTCAAGGTT3'(SEQ ID NO.19);
Reverse primer5'GAATTCAGCGTCGTTTTGG3'(SEQ ID NO.20)。
本发明还提供检测拟南芥基因TOE3的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'GGAAGCAAGTGTACTTAGGTGGA3'(SEQ ID NO.21);
Reverse primer5'TAATCGCCGCTCGATCATA3'(SEQ ID NO.22)。
本发明还提供检测拟南芥基因SMZ的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'GGATGATTATAGGCATGACATCG3'(SEQ ID NO.23);
Reverse primer5'TCTCGCCTAAGTGTTTGCAC3'(SEQ ID NO.24)。
本发明还提供检测拟南芥基因SNZ的mRNA表达水平的一对引物,即利用该基因的核苷酸序列作为设计引物的保守区段,调取其序列的引物序列:
Forward primer5'GGCCGTTGGGAATCTCAT3'(SEQ ID NO.25);
Reverse primer5'GTACGCTCTTGCGGCTGT3'(SEQ ID NO.26)。
本发明还提供检测拟南芥在转入AtWRKY44基因后,对FT,CO,TOE1及其同源基因的转录水平的影响的方法,即利用引物序列SEQ ID NO.13,SEQ ID NO.14,SEQ ID NO.15,SEQID NO.16,SEQ ID NO.17,SEQ ID NO.18,SEQ ID NO.19,SEQ ID NO.20,SEQ ID NO.21,SEQID NO.22,SEQ ID NO.23,SEQ ID NO.24,SEQ ID NO.25,SEQ ID NO.26进行定量PCR检测。
本发明对拟南芥cDNA样品进行Real-timePCR, 然后检测该基因在长日照下的节律性表达;样品为拟南芥的RNA 经过逆转录后所得cDNA,其具体步骤如下:
(1)提取拟南芥器官的总RNA(Trizol,市售);
(2)利用反转录试剂盒(市售)将总RNA反转录成cDNA,根据SEQ ID NO.1,跨越两个外显子的131bp作为PCR产物,进行实时定量PCR检测。
本发明还提供检测拟南芥哥伦比亚在转入基因AtWRKY44后,拟南芥开花时间和FT基因表达量的变化的方法,具体是利用反转录试剂盒将总RNA反转录成cDNA,利用引物SEQID NO.13和SEQ ID NO.14,进行定量PCR检测。结果显示:转入基因AtWRKY44后,与野生型对照组相比,拟南芥延迟开花,FT表达量下调。
本发明中,可选用本领域已经知道的各种载体,如市售的载体以及质粒。
本发明研究了长日照下AtWRKY4不同转基因株系的mRNA水平和开花时间。AtWRKY44与光周期调控途径中基因GIGANTEA(简写为GI),TARGET OF EAT1(简写为TOE1)以及成花素FLOWER LOCUS T(简写为FT)的关系。长日照下,wrky44突变体开花时间提前,并且AtWRKY44在拟南芥哥伦比亚(Columbia,简写为Col)中的mRNA表达上具有节律性。Real-time PCR检测结果显示:AtWRKY44在植物的各个器官中均有表达,其中在叶和种皮表达量最高。GI蛋白可以特异地结合在AtWRKY44基因启动子中两个位点上。酵母双杂交实验显示AtWRKY44能与miRNA172的靶基因TOE1蛋白结合,并且TOE1及其同源基因的mRNA水平在wrky44突变体中有所上调。同时,FT的mRNA水平在wrky44突变体中显著高于野生型Col。FTmRNA的积累有助于拟南芥提前开花,AtWRKY44基因对开花时间的调控,可用于植物育种增产等。
可见,本发明提供的拟南芥基因AtWRKY44可用于植物品种改良,如用于改变植物的开花时间,避开不利的非生物胁迫,最后提高作物产量。
附图说明
图1拟南芥中WRKY44基因的节律性表达。
图2 WRKY44转基因株系中FT和CO的节律性表达。WRKY44转基因株系中TOE1及其同源基因TOE2,TOE3,SMZ和SNZ的节律性表达。
图3 WRKY44与TOE1蛋白的酵母双杂交分析。
图4染色质免疫共沉淀(CHIP)分析。
具体实施方式
下面结合具体实施实例进一步阐释本发明。应理解,这些实施例仅以用于说明本发明而不用于限制本发明的范围。下列实施例中未注明具体的实验方法,均可按照常规方法进行。如Sambrook等分子克隆:实验手册(New York: Cold Spring Harbor LaboratoryPress, 1989)中所述条件,或按照制造生产厂商的使用说明。
实施例1,拟南芥基因AtWRKY44的克隆
1. 拟南芥品种Col在温室中培养:生长条件为光周期16h /8h (L/D),23℃;
2. RNA提取,取100毫克左右新鲜的拟南芥植物组织材料,液氮充分研磨。加1 mlTrizol试剂,涡旋15 s后室温放置5 min。加0.2 ml氯仿,去蛋白,12000rpm离心10min后上清转移至新的离心管,加等体积异丙醇,充分混匀,室温放置10 min,12000 rpm离心10min,弃上清,用DEPC处理过的水配制的75%乙醇1 ml洗涤沉淀,重复一次。室温干燥5-10 min,溶于20 μl DEPC水中,测OD值,电泳检测;
3. 基因的克隆。通过对应的拟南芥的AtWKY44基因进行生信分析,设计引物。以逆转录的拟南芥cDNA第一链为模板,利用正向引物和反向引物进行PCR,获得基因全长,具体序列信息参见SEQ ID NO.1。
实施例2,拟南芥中WRKY44基因的节律性表达分析
提取拟南芥总RNA,利用反转录试剂盒将RNA反转录出cDNA,利用引物SEQ ID NO.7和SEQ ID NO.8,进行实时荧光定量PCR检测。结果显示该基因具有光周期相关的节律性表达(图1)。
实施例3 ,WRKY44转基因株系中FT,CO和TOE1及其同源基因的节律性表达分析
分别提取各转基因株系拟南芥总RNA,利用反转录试剂盒将RNA反转录出cDNA,利用引物SEQ ID NO.13-SEQ ID NO.26,进行实时荧光定量PCR检测。结果显示这些基因的转录水平在WRKY44转基因各株系有不同程度的变化(图2)。FT基因在wrky44, OXs株系中的表达模式基本不变,但是表达水平有所变化。在ZT8、ZT16时,FT在突变体中的mRNA水平高于col。过表达OX3中FT含量低于col。CO在col中的表达量在ZT16时达到峰值,但是在WRKY44-OX中在ZT12,ZT20达到峰值。wrky44突变体中CO表达量一直处于比较低的水平。TOE1基因的mRNA水平在wrky44突变体中上调,在WRKY44过表达株系中下调,TOE2在四个株系中的表达量没有明显的变化,col中TOE3含量均低于wrky44和WRKY44-OXs,OX7和col,wrky44和OX3中具有相似的表达水平和表达模式,SNZ在wrky44突变体中表达量上调,在过表达中表达量下调,表明WRKY44不仅能与TOE1在蛋白水平上互作,在转录水平上也能调控TOE1及其同源基因的表达。
实施例4, WRKY44与TOE1蛋白的酵母双杂
1、分别在YPDA平板上复苏酵母Y187和AH109两种菌株,挑取单克隆各一个,于5mlYPDA液体培养基中,30℃摇床过夜;
2、在50ml YPDA中扩大培养,至OD值为0.4-0.6;
3、在1.5ml灭菌的离心管中收菌,1000rpm离心5min,常温;
4、去上清,用无菌水重悬,1000rpm离心5min;
5、去上清,用1.1XLiAc/TE重悬酵母,5000rpm离心30s;
6、去上清,加入50ml1.1XLiAc/TE,分别在AH109和Y187菌株中加入相应的质粒各2μl,95℃预变性的鲑鱼精DNA 5μl,最后加入500μl 40%的PEG,30℃摇床30min;
7、42℃ 15min,每5min摇晃一次。5000rpm离心15s,去上清,加入100μl 无菌水,涂板,置于30℃培养箱;
8、约2-3d后,挑取将AH109和Y187菌株上的单克隆,用无菌水混匀后,在2XYPDA平板上点样,于30℃培养箱结合 4h;
9、将结合后的克隆再点样在含有X-gal和Aureobasidin A(AbA)的二缺平板上。然后观察酵母生长状态。携带AD-44和BD-TOE1的酵母能够在平板上生长(图3),说明WRKY44与TOE1蛋白能再酵母内互作。
实施例5,染色质免疫共沉淀(CHIP)分析
利用小鼠单克隆MYC抗体,将培养合适的拟南芥幼苗通过染色质免疫沉淀,提取符合要求的DNA。并在WRKY44启动子区域上设计18对引物,进行实时荧光定量PCR,寻找GI在WRKY44启动子上可能的结合位点(图4)。结果显示,第11和13片段具有较高的富集,说明该位点正是GI在WRKY44启动子上的结合位点。
参考文献
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<110> 复旦大学
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Claims (10)
1. 一种分离出的DNA分子,其特征在于,为从拟南芥中克隆出的基因AtWRKY44,基因组全长2226bp,其中编码序列1290bp,其核苷酸序列如SEQ ID NO.1所示。
2. 一种基因AtWRKY44编码的蛋白质分子,其特征在于,序列编码430个氨基酸残基,分子量47.15kDa,其氨基酸序列为SEQ ID NO.2所示。
3. 一对用于调取获得拟南芥样品基因AtWRKY44的引物序列,其特征在于,根据权利要求1所述基因AtWRKY44设计,序列如SEQ ID NO.3和SEQ ID NO.4所示。
4. 一对用于构建pSKM36- AtWRKY44-MYC载体的引物序列,其特征在于,根据权利要求1所述基因AtWRKY44编码序列,含有AscI/SnaBI酶切位点,序列如SEQ ID NO.5和SEQ IDNO.6所示。
5. 一种检测拟南芥在长日照条件下,基因AtWRKY44表达含量变化的方法,其特征在于,具体步骤为:将拟南芥在长日照下培养至10天后,从开灯时间0小时开始,每隔4小时提取拟南芥的总RNA;利用反转录试剂盒将总RNA反转录成cDNA,利用引物SEQ ID NO.7和SEQID NO.8进行定量PCR检测。
6. 一种检测GI过表达转基因株系中,AtWRKY44基因启动子中不同区域的丰富程度的方法,其具体步骤为:培养col与GI过表达株系后,利用鼠MYC单抗免疫共沉淀与GI-MYC蛋白结合的DNA片段,利用引物序列SEQ ID NO.9, SEQ ID NO.10,SEQ ID NO.11和SEQ IDNO.12,进行定量PCR检测。
7. 一种检测拟南芥哥伦比亚在转入基因AtWRKY44后,拟南芥开花时间和FT基因表达量的变化的方法,其特征在于,利用反转录试剂盒将总RNA反转录成cDNA,利用引物SEQ IDNO.13和SEQ ID NO.14,进行定量PCR检测;结果显示:转入基因AtWRKY44后,与野生型对照组相比,拟南芥延迟开花,FT表达量下调。
8.一种检测TOE1和AtWRKY44蛋白互作的方法—酵母双杂交实验,结果显示,两种蛋白转入酵母后存在互作。
9. 一种检测拟南芥在转入AtWRKY44基因后,对FT,CO,TOE1及其同源基因的转录水平的影响的方法,其特征在于,利用引物序列SEQ ID NO.13,SEQ ID NO.14,SEQ ID NO.15,SEQ ID NO.16,SEQ ID NO.17,SEQ ID NO.18,SEQ ID NO.19,SEQ ID NO.20,SEQ IDNO.21,SEQ ID NO.22,SEQ ID NO.23,SEQ ID NO.24,SEQ ID NO.25,SEQ ID NO.26进行定量PCR检测。
10.一种如权利要求1所述的拟南芥基因AtWRKY44在植物品种改良中的应用,包括用于改变植物的开花时间,避开不利的非生物胁迫,提高作物产量。
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| CN109825510A (zh) * | 2019-03-19 | 2019-05-31 | 长江师范学院 | 一种岷江百合LrWRKY2基因及应用 |
| CN112239493A (zh) * | 2020-11-17 | 2021-01-19 | 西南大学 | 蜡梅CpWRI-L4基因及其编码的蛋白与应用 |
| CN113444735A (zh) * | 2021-08-23 | 2021-09-28 | 中国农业科学院棉花研究所 | GhWRKY75基因在调控植物开花中的应用 |
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