植物DnaJ蛋白的研究进展
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摘要
逆境胁迫严重影响作物的生长发育,是目前农业生产面临的主要问题之一。其中高温胁迫对作物的影响尤为严重。热激蛋白是植物在长期进化过程产生的响应热胁迫的一类蛋白。Dna J蛋白作为热激蛋白家族中的一类,是广泛存在于植物细胞中的胁迫响应因子,在许多生物及非生物胁迫响应中都扮演着重要的角色。本综述主要介绍植物Dna J蛋白的发现、结构分类、作用机制和生物学功能,并提出今后的发展方向。
Biotic and abiotic stresses have serious effect on the growth and development of crop plants. In the long-term evolution, plants have evolved a complicated mechanism to respond to adverse stress conditions.Previous researches had reported that heat shock response(HSR), which was defined as sum total of cellular high temperature-related defense activities, was induced in many plant species under high temperature stress condition.Among them, a great deal of ubiquitous and evolutionary-conserved proteins, identified as heat shock proteins, was one of the main products of the HSR. The Hsp40 s, also known as Dna J proteins or J-proteins, is one of heat shock proteins. In recent years, it has been found that plant J-proteins played important roles in both biotic and abiotic stresses. This research would be significant for understanding the mechanism of heat response in plants and provide a comprehensive basis for further analyzing the function of Dna J members.
Biotic and abiotic stresses have serious effect on the growth and development of crop plants. In the long-term evolution, plants have evolved a complicated mechanism to respond to adverse stress conditions.Previous researches had reported that heat shock response(HSR), which was defined as sum total of cellular high temperature-related defense activities, was induced in many plant species under high temperature stress condition.Among them, a great deal of ubiquitous and evolutionary-conserved proteins, identified as heat shock proteins, was one of the main products of the HSR. The Hsp40 s, also known as Dna J proteins or J-proteins, is one of heat shock proteins. In recent years, it has been found that plant J-proteins played important roles in both biotic and abiotic stresses. This research would be significant for understanding the mechanism of heat response in plants and provide a comprehensive basis for further analyzing the function of Dna J members.
引文
Albrecht V.,Ingenfeld A.,and Apel K.,2008,Snowy cotyledon2:the identification of a zinc finger domain protein essentia for chloroplast development in cotyledons but not in true leaves,Plant Molecular Biology,66(6):599-608
Balsera M.,Goetze T.A.,Kovács-Bogdán E.,Schürmann P.,Wagner R.,Buchanan B.B.,Soll J.,and B觟lter B.,2009,Characterization of Tic110,a channel-forming protein at the inner envelope membrane of chloroplasts,unveils a response to Ca2+and a stromal regulatory disulfide bridge,J.Biol.Chem.,284(5):2603-2616
Bekh-Ochir D.,Shimada S.,Yamagami A.,Kanda S.,Ogawa K.,Nakazawa M.,Matsui M.,Sakuta M.,Osada H.,Asami T.,and Nakano T.,2013,A novel mitochondrial Dna J/Hsp40family protein BIL2 promotes plant growth and resistance against environmental stress in brassinosteroid signaling,Planta,237(6):1509-1525
Boston R.S.,Viitanen P.V.,and Vierling E.,1996,Molecular chaperones and protein folding in plants,In:Filipowicz W.,and Hohn T.(eds.),Post-transcriptional control of gene expression in plants,Springer Netherlands,Dordrecht,pp.191-222
Bukau B.,and Horwich A.L.,1998,The Hsp70 and Hsp60chaperone machines,Cell,92(3):351-366
Caplan A.J.,Cyr D.M.,and Douglas M.G.,1993,Eukaryotic homologues of Escherichia coli Dna J:a diverse protein family that functions with hsp70 stress proteins,Molecular Biology of the Cell,4(6):555-563
Cheetham M.E.,and Caplan A.J.,1998,Structure,function and evolu tion of Dna J:conservation and adaptation of chaperone function,Cell Stress and Chaperones,3(1):28-36
Chen K.M.,Holmstr觟m M.,Raksajit W.,Suorsa M.,Piippo M.,Aro E.M.,2010,Small chloroplast-targeted Dna J proteins are involved in optimization of photosynthetic reactions in Arabidopsis thaliana,BMC Plant Biology,10(1):43
Chiu C.C.,Chen L.J.,and Li H.M.,2010,Pea chloroplast Dna J-J8 and Toc12 are encoded by the same gene and localized in the stroma,Plant Physiol.,154(3):1172-1182
Corsi A.K.,and Schekman R.,1997,The lumenal domain of Sec63p stimulates the ATPase activity of Bi P and mediates Bi P recruitment to the translocon in Saccharomyces cerevisiae,The Journal of Cell Biology,137(7):1483-1493
Craig E.A.,Huang P.,Aron R.,and Andrew A.,2006,The diverse roles of J-proteins,the obligate Hsp70 co-chaperone,In:Amara S.G.,Bamberg E.,Grinstein S.,Hebert S.C.,Jahn R.,Lederer W.J.,Lill R.,Miyajima A.,Murer H.,Offermanns S.,Schultz G.,and Schweiger M.(eds.),Reviews of physiology,biochemistry and pharmacology,Springer,Berlin Heidelberg,pp.1-21
Cunnea P.M.,Miranda-Vizuete A.,Bertoli G.,Simmen T.,Damdimopoulos A.E.,Hermann S.,Leinonen S.,Huikko M.P.,Gustafsson J.A.,Sitia R.,and Spyrou G.,2003,ERdj5,an endoplasmic reticulum(ER)-resident protein containing Dna J and thioredoxin domains,is expressed in secretory cells or following ER stress,J.Biol.Chem.,278(2):1059-1066
Cyr D.M.,Lu X.,and Douglas M.G.,1992,Regulation of Hsp70function by a eukaryotic Dna J homolog,J.Biol.Chem.,267(29):20927-20931
Dorn K.V.,Willmund F.,Schwarz C.,Henselmann C.,Pohl T.Hess B.,Veyel D.,Usadel B.,Friedrich T.,Nickelsen J.,and Schroda M.,2010,Chloroplast Dna J-like proteins 3 and 4(CDJ3/4)from Chlamydomonas reinhardtii contain redoxactive Fe-S clusters and interact with stromal HSP70BBiochem.J.,427(2):205-215
Georgopoulos C.P.,Lam B.,Lundquist-Heil A.,Rudolph C.F.Yochem J.,and Feiss M.,1979,Identification of the E.col dna K(gro PC756)gene product,Molecular and General Genetics,172(2):143-149
Goffin L.,and Georgopoulos C.,1998,Genetic and biochemica characterization of mutations affecting the carboxy-termina domain of the Escherichia coli molecular chaperone Dna JMolecular Microbiology,30(2):329-340
Hosoda A.,Kimata Y.,Tsuru A.and Kohno K.,2003,JPDI,a novel endoplasmic reticulum-resident protein containing both a Bi P-interacting J-domain and thioredoxin-like motifs J.Biol.Chem.,278(4):2669-2676
Jin G.L.,Wang X.S.,and Zhu J.,2005,Bioinformatic analysis o the 14-3-3 gene family in rice,Yichuan Xuebao(Acta Genetica Sinica),32(7):726-732(金谷雷,汪旭升,朱军,2005,水稻14-3-3蛋白家族的生物信息学分析,遗传学报,32(7)726-732)
Kampinga H.H.,and Craig E.A.,2010,The HSP70 chaperone machine ry:J proteins as drivers of functional specificity Nat.Rev.Mol.Cell Biol.,11(8):579-592
Kelley W.L.,1998,The J-domain family and the recruitment o chaperone power,Trends Biochem.Sci.,23(6):222-227
Kong F.,Deng Y.,Wang G.,Wang J.,Liang X.,and Meng Q.2014a,Le CDJ1,a chloroplast Dna J protein,facilitates hea tolerance in transgenic tomatoes,Journal of Integrative Plan Biology,56(1):63-74
Kong F.,Deng Y.,Zhou B.,Wang G.,Wang Y.,and Meng Q.2014b,A chloroplast-targeted Dna J protein contributes to maintenance of photosystem II under chilling stress,J.Exp Bot.,65(1):143-158
Kong F.Y.,2014,Functiona l analysis of a tomato chloroplas Dna J protein Le CDJ l,Dissertation for Ph.D.,Shandong A-gricultural University,Supervisor:Meng Q.W.,pp.10-11(孔凡英,2014,番茄叶绿体Dna J蛋白Le CDJ1功能分析,博士学位论文,山东农业大学,导师:孟庆伟,pp.10-11)
Kroczynska B.,and Blond S.Y.,2001,Cloning and characterization of a new soluble murine J-domain protein that stimulates Bi P,Hsc70 and Dna K ATPase activity with different efficiencies,Gene,273(2):267-274
Kroczynska B.,Zhou R.,Wood C.,and Miernyk J.A.,1996,At J1,a mitochondrial homologue of the Escherichia coli Dna J protein,Plant Biochem.Sci.,31(3):619-629
Kushnir S.,Babiychuk E.,Kampfenkel K.,Belles-Boix E.,Mon gatu M.V.and InzéD.,1995,Characterization of Arabidopsis thaliana c DNAs that render yeasts tolerant toward the thiol-oxidizing drug diamide,Proc.Nat I.Acad.Sci.USA,92(23):10580-10584
Liberek K.,Marszalek J.,Ang D.,Georgopoulos C.,and Zylicz M.,1991,Escherichia coli Dna J and Grp E heat shock proteins jointly stimulate ATPase activity of Dna K,Proc.Nati.Acad.Sci.USA,88(7):2874-2878
Martinez-Yamout M.,Legge G.B.,Zhang O.,Wright P.E.,and Dyson H.J.,2000,Solution structure of the cysteine-rich domain of the Escherichia coli chaperone protein Dna J,J.Mol.Biol.,300(4):805-818
Miernyk J.A.,1999,Protein folding in the plant cell,Plant Physiol.,121(3):695-703
Miernyk J.A.,2001,The J-domain proteins of Arabidopsis thaliana:an unexpectedly large and diverse family of chaperones,Cell Stress and Chaperones,6(3):209-218
Qbadou S.,Becker T.,Bionda T.,Reger K.,Ruprecht M.,Soll J.,and Schleiff E.,2007,Toc64-a preprotein-receptor at the outer membrane with bipartide function,JJ.Mol.Biol.,367(5):1330-1346
Qiu X.B.,Shao Y.M.,Miao S.,and Wang L.,2006,The diversity of the Dna J/Hsp40 family,the crucial partners for Hsp70chaperones,Cell.Mol.Life Sci.,63(22):2560-2570
Rajan V.B.,and D?Silva P.,2009,Arabidopsis thaliana J-class heat shock proteins:cellular stress sensors,Funct.Integr.Genomics,9(4):433-446
Shimada H.,Mochizuki M.,Ogura K.,Froehlich J.E.,Osteryoung K.W.,Shirano Y.,Shibata D.,Masuda S.,Mori K.,and Takamiya K.,2007,Arabidopsis cotyledon-specific chloroplast biogenesis factor CYO1 is a protein disulfide isomerase,Plant Cell,19(10):3157-3169
Silver P.A.,and Way J.C.,1993,Eukaryotic Dna J homologs and the specificity of Hsp70 activity,Cell,74(1):5-6
Su P.H.,and Li H.M.,2010,Stromal Hsp70 is important for protein translocation into pea and Arabidopsis chloroplasts,Plant Cell,22(5):1516-1531
Tsai J.,and Douglas M.G.,1996,A conserved HPD sequence of the J-domain is necessary for YDJ1 stimulation of Hsp70ATPase activity at a site distinct from substrate binding,J.Biol.Chem.,271(16):9347-9354
Vitha S.,Froehlich J.E.,Koksharova O.,Pyke K.A.,Erp H.V.,and Osteryoung K.W.,2003,ARC6 is a J-domain plastid division protein and an evolutionary descendant of the cyanobacterial cell division protein Ftn2,Plant Cell,15(8)1918-1933
Walsh P.,Bursac D.,Law Y.C.,Cyr D.,and Lithgow T.,2004The J-protein family:modulating protein assembly,disassembly and translocation,EMBO Rep.,5(6):567-571
Wang A.R.,Liu X.G.,Zhao X.,and Lu G.D.,2009,Analysis of rice nitrilase family by bioinformatic methods,Zhongguo Nongxue Tongbao(Chinese Agricultural Science Bulletin)25(23):52-57(王爱荣,刘向国,赵旭,鲁国东,2009,水稻腈水解酶家族的生物信息学分析,中国农学通报,25(23)52-57)
Wang G.,Kong F.,Zhang S.,Meng X.,Wang Y.,and Meng Q.2015,A tomato chloroplast-targeted Dna J protein protects Rubisco activity under heat stress,J.Exp.Bot.,66(11):3027
Wang M.Q.,and Zhang D.Y.,2015,Research advance of hea shock protein 70 gene family and its biological functions in plant,Jiyinzuxue Yu Yingyong Shengwuxue(Genomics and Applied Biology),34(2):421-428(王明强,张道远,2015植物热激蛋白70基因家族及其生物学功能研究进展,基因组学与应用生物学,34(2):421-428)
Wang Y.W.,Chen S.M.,Wang W.J.,Huang X.Q.,Zhou C.F.Zhuang Z.,and Lu S.,2016,The Dna J-Like zinc finger domain protein PSA2 affects light acclimation and chloroplas developmentin Arabidopsis thaliana,Front.Plant Sci.,7:360
Xing Y.,and Zhang Q.,2010,Genetic and molecular bases of rice yield,Annu.Rev.Plant Biol.,61(1):421-442
Yang K.Z.,Xia C.,Liu X.L.,Dou X.Y.,Wang W.,Chen L.Q.,Zhang X.Q.,Xie L.F.,He L.,Ma X.,and Ye D.,2009,Amutation in thermosensitive male sterile 1,encoding a heat shock protein with Dna J and PDI domains,leads to thermosensitive gametophytic male sterility in Arabidopsis,Plant J.,57(5):870-882
Zhao X.,Liu X.G.,and Wang A.R.,2011,Bioinformatic analysis of the Dna J protein family in rice,Yaredai Nongye Yanjiu(Subtropical Agriculture Research),7(3):206-211(赵旭,刘向国,王爱荣,2011,水稻Dna J蛋白的生物信息学分析,亚热带农业研究,7(3):206-211)
Zhou R.G.,Kroczynska B.,Hayman G.T.,and Miernyk J.,1995,At J2,an Arabidopsis homolog of Escherichia coli Dna J.,Plant Physiol.,108(2):821
Zhou W.,Zhou T.,Li M.X.,Zhao C.L.,Jia N.,Wang X.X.,Sun Y.Z.,Li G.L.,Xu M.,Zhou R.G.and Li B.,2012,The Arabidopsis J-protein At D B1 facilitates thermotolerance by protecting cells against heat-induced oxidative damage,New Phytol.,194(2):364-378
Zhu J.K.,Shi J.,Bressan R.A.,and Hasegawa P.M.,1993,Expression of an Atriplex nummularia gene encoding a protein homologous to the bacterial molecular chaperone,Plant Cell,5(3):341-349
Zhu X.,Liang S.,Yin J.,Yuan C.,Wang J.,Li W.,He M.,Wang J.,Chen W.,Ma B.,Wang Y.,Qin P.,Li S.,and Chen X.,2015,The Dna J Os Dj A7/8 is essential for chloroplast development in rice(Oryza sativa),Gene,574(1):11-19
Balsera M.,Goetze T.A.,Kovács-Bogdán E.,Schürmann P.,Wagner R.,Buchanan B.B.,Soll J.,and B觟lter B.,2009,Characterization of Tic110,a channel-forming protein at the inner envelope membrane of chloroplasts,unveils a response to Ca2+and a stromal regulatory disulfide bridge,J.Biol.Chem.,284(5):2603-2616
Bekh-Ochir D.,Shimada S.,Yamagami A.,Kanda S.,Ogawa K.,Nakazawa M.,Matsui M.,Sakuta M.,Osada H.,Asami T.,and Nakano T.,2013,A novel mitochondrial Dna J/Hsp40family protein BIL2 promotes plant growth and resistance against environmental stress in brassinosteroid signaling,Planta,237(6):1509-1525
Boston R.S.,Viitanen P.V.,and Vierling E.,1996,Molecular chaperones and protein folding in plants,In:Filipowicz W.,and Hohn T.(eds.),Post-transcriptional control of gene expression in plants,Springer Netherlands,Dordrecht,pp.191-222
Bukau B.,and Horwich A.L.,1998,The Hsp70 and Hsp60chaperone machines,Cell,92(3):351-366
Caplan A.J.,Cyr D.M.,and Douglas M.G.,1993,Eukaryotic homologues of Escherichia coli Dna J:a diverse protein family that functions with hsp70 stress proteins,Molecular Biology of the Cell,4(6):555-563
Cheetham M.E.,and Caplan A.J.,1998,Structure,function and evolu tion of Dna J:conservation and adaptation of chaperone function,Cell Stress and Chaperones,3(1):28-36
Chen K.M.,Holmstr觟m M.,Raksajit W.,Suorsa M.,Piippo M.,Aro E.M.,2010,Small chloroplast-targeted Dna J proteins are involved in optimization of photosynthetic reactions in Arabidopsis thaliana,BMC Plant Biology,10(1):43
Chiu C.C.,Chen L.J.,and Li H.M.,2010,Pea chloroplast Dna J-J8 and Toc12 are encoded by the same gene and localized in the stroma,Plant Physiol.,154(3):1172-1182
Corsi A.K.,and Schekman R.,1997,The lumenal domain of Sec63p stimulates the ATPase activity of Bi P and mediates Bi P recruitment to the translocon in Saccharomyces cerevisiae,The Journal of Cell Biology,137(7):1483-1493
Craig E.A.,Huang P.,Aron R.,and Andrew A.,2006,The diverse roles of J-proteins,the obligate Hsp70 co-chaperone,In:Amara S.G.,Bamberg E.,Grinstein S.,Hebert S.C.,Jahn R.,Lederer W.J.,Lill R.,Miyajima A.,Murer H.,Offermanns S.,Schultz G.,and Schweiger M.(eds.),Reviews of physiology,biochemistry and pharmacology,Springer,Berlin Heidelberg,pp.1-21
Cunnea P.M.,Miranda-Vizuete A.,Bertoli G.,Simmen T.,Damdimopoulos A.E.,Hermann S.,Leinonen S.,Huikko M.P.,Gustafsson J.A.,Sitia R.,and Spyrou G.,2003,ERdj5,an endoplasmic reticulum(ER)-resident protein containing Dna J and thioredoxin domains,is expressed in secretory cells or following ER stress,J.Biol.Chem.,278(2):1059-1066
Cyr D.M.,Lu X.,and Douglas M.G.,1992,Regulation of Hsp70function by a eukaryotic Dna J homolog,J.Biol.Chem.,267(29):20927-20931
Dorn K.V.,Willmund F.,Schwarz C.,Henselmann C.,Pohl T.Hess B.,Veyel D.,Usadel B.,Friedrich T.,Nickelsen J.,and Schroda M.,2010,Chloroplast Dna J-like proteins 3 and 4(CDJ3/4)from Chlamydomonas reinhardtii contain redoxactive Fe-S clusters and interact with stromal HSP70BBiochem.J.,427(2):205-215
Georgopoulos C.P.,Lam B.,Lundquist-Heil A.,Rudolph C.F.Yochem J.,and Feiss M.,1979,Identification of the E.col dna K(gro PC756)gene product,Molecular and General Genetics,172(2):143-149
Goffin L.,and Georgopoulos C.,1998,Genetic and biochemica characterization of mutations affecting the carboxy-termina domain of the Escherichia coli molecular chaperone Dna JMolecular Microbiology,30(2):329-340
Hosoda A.,Kimata Y.,Tsuru A.and Kohno K.,2003,JPDI,a novel endoplasmic reticulum-resident protein containing both a Bi P-interacting J-domain and thioredoxin-like motifs J.Biol.Chem.,278(4):2669-2676
Jin G.L.,Wang X.S.,and Zhu J.,2005,Bioinformatic analysis o the 14-3-3 gene family in rice,Yichuan Xuebao(Acta Genetica Sinica),32(7):726-732(金谷雷,汪旭升,朱军,2005,水稻14-3-3蛋白家族的生物信息学分析,遗传学报,32(7)726-732)
Kampinga H.H.,and Craig E.A.,2010,The HSP70 chaperone machine ry:J proteins as drivers of functional specificity Nat.Rev.Mol.Cell Biol.,11(8):579-592
Kelley W.L.,1998,The J-domain family and the recruitment o chaperone power,Trends Biochem.Sci.,23(6):222-227
Kong F.,Deng Y.,Wang G.,Wang J.,Liang X.,and Meng Q.2014a,Le CDJ1,a chloroplast Dna J protein,facilitates hea tolerance in transgenic tomatoes,Journal of Integrative Plan Biology,56(1):63-74
Kong F.,Deng Y.,Zhou B.,Wang G.,Wang Y.,and Meng Q.2014b,A chloroplast-targeted Dna J protein contributes to maintenance of photosystem II under chilling stress,J.Exp Bot.,65(1):143-158
Kong F.Y.,2014,Functiona l analysis of a tomato chloroplas Dna J protein Le CDJ l,Dissertation for Ph.D.,Shandong A-gricultural University,Supervisor:Meng Q.W.,pp.10-11(孔凡英,2014,番茄叶绿体Dna J蛋白Le CDJ1功能分析,博士学位论文,山东农业大学,导师:孟庆伟,pp.10-11)
Kroczynska B.,and Blond S.Y.,2001,Cloning and characterization of a new soluble murine J-domain protein that stimulates Bi P,Hsc70 and Dna K ATPase activity with different efficiencies,Gene,273(2):267-274
Kroczynska B.,Zhou R.,Wood C.,and Miernyk J.A.,1996,At J1,a mitochondrial homologue of the Escherichia coli Dna J protein,Plant Biochem.Sci.,31(3):619-629
Kushnir S.,Babiychuk E.,Kampfenkel K.,Belles-Boix E.,Mon gatu M.V.and InzéD.,1995,Characterization of Arabidopsis thaliana c DNAs that render yeasts tolerant toward the thiol-oxidizing drug diamide,Proc.Nat I.Acad.Sci.USA,92(23):10580-10584
Liberek K.,Marszalek J.,Ang D.,Georgopoulos C.,and Zylicz M.,1991,Escherichia coli Dna J and Grp E heat shock proteins jointly stimulate ATPase activity of Dna K,Proc.Nati.Acad.Sci.USA,88(7):2874-2878
Martinez-Yamout M.,Legge G.B.,Zhang O.,Wright P.E.,and Dyson H.J.,2000,Solution structure of the cysteine-rich domain of the Escherichia coli chaperone protein Dna J,J.Mol.Biol.,300(4):805-818
Miernyk J.A.,1999,Protein folding in the plant cell,Plant Physiol.,121(3):695-703
Miernyk J.A.,2001,The J-domain proteins of Arabidopsis thaliana:an unexpectedly large and diverse family of chaperones,Cell Stress and Chaperones,6(3):209-218
Qbadou S.,Becker T.,Bionda T.,Reger K.,Ruprecht M.,Soll J.,and Schleiff E.,2007,Toc64-a preprotein-receptor at the outer membrane with bipartide function,JJ.Mol.Biol.,367(5):1330-1346
Qiu X.B.,Shao Y.M.,Miao S.,and Wang L.,2006,The diversity of the Dna J/Hsp40 family,the crucial partners for Hsp70chaperones,Cell.Mol.Life Sci.,63(22):2560-2570
Rajan V.B.,and D?Silva P.,2009,Arabidopsis thaliana J-class heat shock proteins:cellular stress sensors,Funct.Integr.Genomics,9(4):433-446
Shimada H.,Mochizuki M.,Ogura K.,Froehlich J.E.,Osteryoung K.W.,Shirano Y.,Shibata D.,Masuda S.,Mori K.,and Takamiya K.,2007,Arabidopsis cotyledon-specific chloroplast biogenesis factor CYO1 is a protein disulfide isomerase,Plant Cell,19(10):3157-3169
Silver P.A.,and Way J.C.,1993,Eukaryotic Dna J homologs and the specificity of Hsp70 activity,Cell,74(1):5-6
Su P.H.,and Li H.M.,2010,Stromal Hsp70 is important for protein translocation into pea and Arabidopsis chloroplasts,Plant Cell,22(5):1516-1531
Tsai J.,and Douglas M.G.,1996,A conserved HPD sequence of the J-domain is necessary for YDJ1 stimulation of Hsp70ATPase activity at a site distinct from substrate binding,J.Biol.Chem.,271(16):9347-9354
Vitha S.,Froehlich J.E.,Koksharova O.,Pyke K.A.,Erp H.V.,and Osteryoung K.W.,2003,ARC6 is a J-domain plastid division protein and an evolutionary descendant of the cyanobacterial cell division protein Ftn2,Plant Cell,15(8)1918-1933
Walsh P.,Bursac D.,Law Y.C.,Cyr D.,and Lithgow T.,2004The J-protein family:modulating protein assembly,disassembly and translocation,EMBO Rep.,5(6):567-571
Wang A.R.,Liu X.G.,Zhao X.,and Lu G.D.,2009,Analysis of rice nitrilase family by bioinformatic methods,Zhongguo Nongxue Tongbao(Chinese Agricultural Science Bulletin)25(23):52-57(王爱荣,刘向国,赵旭,鲁国东,2009,水稻腈水解酶家族的生物信息学分析,中国农学通报,25(23)52-57)
Wang G.,Kong F.,Zhang S.,Meng X.,Wang Y.,and Meng Q.2015,A tomato chloroplast-targeted Dna J protein protects Rubisco activity under heat stress,J.Exp.Bot.,66(11):3027
Wang M.Q.,and Zhang D.Y.,2015,Research advance of hea shock protein 70 gene family and its biological functions in plant,Jiyinzuxue Yu Yingyong Shengwuxue(Genomics and Applied Biology),34(2):421-428(王明强,张道远,2015植物热激蛋白70基因家族及其生物学功能研究进展,基因组学与应用生物学,34(2):421-428)
Wang Y.W.,Chen S.M.,Wang W.J.,Huang X.Q.,Zhou C.F.Zhuang Z.,and Lu S.,2016,The Dna J-Like zinc finger domain protein PSA2 affects light acclimation and chloroplas developmentin Arabidopsis thaliana,Front.Plant Sci.,7:360
Xing Y.,and Zhang Q.,2010,Genetic and molecular bases of rice yield,Annu.Rev.Plant Biol.,61(1):421-442
Yang K.Z.,Xia C.,Liu X.L.,Dou X.Y.,Wang W.,Chen L.Q.,Zhang X.Q.,Xie L.F.,He L.,Ma X.,and Ye D.,2009,Amutation in thermosensitive male sterile 1,encoding a heat shock protein with Dna J and PDI domains,leads to thermosensitive gametophytic male sterility in Arabidopsis,Plant J.,57(5):870-882
Zhao X.,Liu X.G.,and Wang A.R.,2011,Bioinformatic analysis of the Dna J protein family in rice,Yaredai Nongye Yanjiu(Subtropical Agriculture Research),7(3):206-211(赵旭,刘向国,王爱荣,2011,水稻Dna J蛋白的生物信息学分析,亚热带农业研究,7(3):206-211)
Zhou R.G.,Kroczynska B.,Hayman G.T.,and Miernyk J.,1995,At J2,an Arabidopsis homolog of Escherichia coli Dna J.,Plant Physiol.,108(2):821
Zhou W.,Zhou T.,Li M.X.,Zhao C.L.,Jia N.,Wang X.X.,Sun Y.Z.,Li G.L.,Xu M.,Zhou R.G.and Li B.,2012,The Arabidopsis J-protein At D B1 facilitates thermotolerance by protecting cells against heat-induced oxidative damage,New Phytol.,194(2):364-378
Zhu J.K.,Shi J.,Bressan R.A.,and Hasegawa P.M.,1993,Expression of an Atriplex nummularia gene encoding a protein homologous to the bacterial molecular chaperone,Plant Cell,5(3):341-349
Zhu X.,Liang S.,Yin J.,Yuan C.,Wang J.,Li W.,He M.,Wang J.,Chen W.,Ma B.,Wang Y.,Qin P.,Li S.,and Chen X.,2015,The Dna J Os Dj A7/8 is essential for chloroplast development in rice(Oryza sativa),Gene,574(1):11-19