花生DOFH10在细胞中可能通过小泡运输并在网格蛋白相关途径被专一地识别

doi:10.7668/hbnxb.2018.05.019

摘要/Abstract

摘要： 为对花生未知的DOFH10基因进行研究，根据DOF转录调控因子DOF （DNA binding with One Finger）GW391728的cDNA序列，采用引物对s162-a1469和引物s30-a1469用PCR方法在花生16个品种中进行克隆比较，并进一步对DOFH10在数据库进行序列比对，对其一级结构酶切位点、三维空间结构、蛋白质表达等进行研究。结果表明，用引物对s162-a1469在5个品种中克隆得到2类DOFH10基因A和B类。它们分别与野生花生染色体A03上的XM_016100960.2和野生花生染色体B03上的XM_016334585.2序列完全相同。用引物s30-a1469从所有16个品种中得到相同的B类DOFH10基因，包括6个多粒果实品种。A类基因在4个多粒果实品种和1个2粒果实品种中存在。序列比对表明，A和B类DOFH10基因是不同基因编码的，它们分别位于家培花生的A和B基因组。B类DOFH10在DOF保守序列区域与野生花生染色体B01上编码网格蛋白集装相关蛋白XP_016199412.2的一段基因剪辑后的RNA序列完全相同，DOFH10蛋白上多个肉豆蔻酰十四酰修饰位点的分布，这2个结果意味着该蛋白在细胞内的运输可能通过膜系统进行。蛋白质印迹分析表明，DOFH10在发育中子叶专一表达。花生DOFH10基因有A和B等2类，其中B类DOFH10存在于所有家培花生品种中，是必需基因，其蛋白可能通过Clathrin依赖的小泡运输途径运入细胞核。A类DOFH10更多存在于多粒家培花生品种中，可能与果实发育早期细胞分裂有关。

关键词: DOF, 转录因子, 花生, 网格蛋白相关, 果实发育

Abstract: Study unknown DOFH10 (DNA binding with one finger) genes in peanuts,cloning of DOFH10 genes with PCR methods according to cDNA of DOF transcription factor GW391728 with primers s162-a1469 and primers s30-a1469 from 16 different peanut cultivars of Arachis hypogaea L.,sequences comparison,analysis on enzyme site and 3D structure and Western Blot on DOFH10 proteins were conducted. Two types of DOFH10 genes were separated from genome DNA of 5 cultivars with primers s162-a1469,type A DOFH10 was only existed in four cultivars with multiple seeds per fruit and one cultivar with two seeds per fruit. They were identical to XM_016100960.2 from Arachis duranensis chromosome A03 and to XM_016334585.2 from Arachis ipaensis chromosome B03 respectively. With primers s30-a1469,only type B DOFH10 was cloned from all the 16 cultivars used including all the six cultivars with multiple seeds per fruit. Type B DOFH10 had identical RNA and protein sequences at DOF zinc finger region to that of putitive clathrin assembly protein XP_016199412.2 encoded by gene on chromosome B01 of Arachis ipaensis. Multiple possible myristoylation sites scattered on DOFH10 protein,both results suggested that transportation of DOFH10 was probable via vesicle membrane traffic related to clathrin. DOFH10 protein was specifically expressed in developing cotyledons displayed by Western Blot. A and B two types of DOFH10 genes existed in cultivated peanut. The type B was present in all 16 peanut cultivars,and was an essential gene,was possibly transported into nucleus through clathrin dependant vesicle pathway. The type A DOFH10 tended more appeared in cultivars with multiple seeds per fruit,probably related to cell division in early fruit development.

Key words: DOF, Transcription factor, Peanut, Clathrin related, Fruit development

中图分类号:

严海燕, 黄珍玲, 锁慧, 黄家权, 廖伯寿. 花生DOFH10在细胞中可能通过小泡运输并在网格蛋白相关途径被专一地识别[J]. 华北农学报, 2018, 33(5): 130-143. doi: 10.7668/hbnxb.2018.05.019.

YAN Haiyan, HUANG Zhenling, SUO Hui, HUANG Jiaquan, LIAO Boshou. Cell Transport of DOFH10 in Arachis hypogaea L. Is Possibly via Vesicle and Specifically Recognized in Clathrin Related Pathway[J]. ACTA AGRICULTURAE BOREALI-SINICA, 2018, 33(5): 130-143. doi: 10.7668/hbnxb.2018.05.019.

http://www.hbnxb.net/CN/Y2018/V33/I5/130

参考文献

[1] Yan H,Huang J,Liao B,et al. DOF transcription factors in developing peanut(Arachis Hypogaea)seeds[J]. Ameri J Mol Biol,2012,2:60-71.
[2] Jung S,Tate P L,Horn R,et al. The phylogenetic relationship of possible progenitors of the cultivated peanut[J]. The Journal of Heredity,2003,94(4):334-340.
[3] Chopra R,Burow G,Farmer A,et al. Comparisons of de novo transcriptome assemblers in diploid and polyploid species using peanut (Arachis spp.) RNA-Seq data[J]. PLoS One,2014,9(12):e0115055.
[4] Vicente-Carbajosa J,Moose S P,Parsons R L,et al. A maize zinc-finger protein binds the prolamin box in zein gene promoters and interacts with the basic leucine zipper transcriptional activator Opaque2[J]. Proceedings of the National Academy of Sciences of the United States of America,1997,94(14):7685-7690.
[5] Diaz I,Vicente-Carbajosa J,Abraham Z,et al. The GAMYB protein from barley interacts with the DOF transcription factor BPBF and activate endosperm-specific genes during seed germination[J]. Plant Journal,2002,29(4):453-464.
[6] Vicente-Carbajosa J,O n ate L,Lara P,et al. Barley BLZ1:a bZIP transcriptional activator that interacts with endosperm-specific gene promoters[J]. The Plant Journal,1998,13(5):629-640.
[7] Wang H W,Zhang B,Hao Y J,et al. The soybean Dof-type transcription factor genes, GmDof4 and GmDof11,enhance lipid content in the seeds of transgenic Arabidopsis plants[J]. The Plant Journal,2007,52(4):716-729.
[8] Stanke M,Diekhans M,Baertsch R,et al. Using native and syntenically mapped cDNA alignments to improve de novo gene finding[J]. Bioinformatics,2008,24(5):637-644.
[9] Roy A,Kucukural A,Zhang Y. I-TASSER:a unified platform for automated protein structure and function prediction[J]. Nature Protocols,2010,5(4):725-738.
[10] Zhang Y. I-TASSER server for protein 3D structure prediction[J]. BMC Bioinformatics,2008,9:40.
[11] Panchy N,Lehti-Shiu M,Shiu S H. Evolution of gene duplication in plants[J]. Plant Physiology,2016,171(4):2294-2316.
[12] Desmeules P,Penney S E,Desbat B,et al. Determination of the contribution of the myristoyl group and hydrophobic amino acids of recoverin on its dynamics of binding to lipid monolayers[J]. Biophysical Journal,2007,93(6):2069-2082.
[13] Colombo S,Longhi R,Alcaro S,et al. N-myristoylation determines dual targeting of mammalian NADH-cytochrome b5 reductase to ER and mitochondrial outer membranes by a mechanism of kinetic partitioning[J]. The Journal of Cell Biology,2005,168(5):735-745.
[14] Liu Y,Kahn R A,Prestegard J H. Structure and membrane interaction of myristoylated ARF1[J]. Structure,2009,17(1):79-87.
[15] Zouhar J,Sauer M. Helping hands for budding prospects:ENTH/ANTH/VHS accessory proteins in endocytosis,vacuolar transport,and secretion[J]. The Plant Cell,2014,26(11):4232-4244.
[16] Yan H,Zong C,Shan S. Vesicle trafficking patterns in developing peanut fruits related to Aspergillus flavus resistancy and development[J]. Chinese J Cell Biol,2014,36(8):1092-1103.
[17] Hosy E,Martinière A,Choquet D,et al. Super-resolved and dynamic imaging of membrane proteins in plant cells reveal contrasting kinetic profiles and multiple confinement mechanisms[J]. Molecular plant,2014,8(2):339-342.
[18] Langowski L,Wabnik K,Li H,et al. Cellular mechanisms for cargo delivery and polarity maintenance at different polar domains in plant cells[J]. Cell Discov,2016,2:16018.
[19] Langowski C,Wabnik K,Li H,et al. Cellular mechanisms for cargo delivery and polarity maintenance at different polar domains in plant cells[J].Cell Discov,2016,2:16018.
[20] Mcmichael C M,Reynolds G D,Koch L M,et al. Mediation of clathrin-dependent trafficking during cytokinesis and cell expansion by Arabidopsis stomatal cytokinesis defective proteins[J]. The Plant Cell,2013,25(10):3910-3925.
[21] Sutimantanapi D,Pater D,Smith L G. Divergent roles for maize Pan1 and Pan2 receptor-like proteins in cytokinesis and cell morphogenesis[J]. Plant Physiology,2014,164(4):1905-1917.
[22] Bradford M K,Whitworth K,Wendland B. Pan1 regulates transitions between stages of clathrin-mediated endocytosis[J]. Molecular Biology of the Cell,2015,26(7):1371-1385.
[23] Rosquete M R,Davis D J,Drakakaki G. The plant Trans-Golgi network:not just a matter of distinction[J]. Plant Physiology,2018,176(1):187-198.
[24] Liu Y,Li P,Fan L,et al. The nuclear transportation routes of membrane-bound transcription factors[J].Cell Commun Siqnal,2018,16(1):12.

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