小麦B-box基因家族全基因组鉴定与表达分析

doi:10.3724/SP.J.1006.2021.01077

Abstract

Abstract:

B-box (BBX) is a class of zinc finger proteins that contain one or two B-box domains and play important roles in plant growth and development. The number, gene structure and phylogenetic relationship of wheat B-box transcription factors, as well as their expression specificity in different tissues and response to abiotic stress were investigated. A total of 87 members of B-box gene family were identified from wheat genome and all contained the B-box domain. TaBBXs encoded 146 to 489 amino acids and the isoelectric points ranged from 4.32 to 10.42. Chromosome mapping showed that these genes were distributed on 18 wheat chromosomes except 1A, 1B, and 1D. Based on phylogenetic analysis, TaBBXs were divided into five subfamilies, with 0-4 introns. The members of the subfamily in the same phylogenetic tree branch in the same group had highly similar gene structures. The qRT-PCR revealed that the investigated 20 genes had different expression patterns, and most genes were highly expressed in leaves, and TaBBX10 and TaBBX39 were only highly expressed in leaves, while TaBBX74 was expressed in spikes, TaBBX43 was specifically expressed in roots. These genes showed different expression patterns under different stress. 11 genes were up-regulated after low temperature stress, 13 genes were down-regulated after ABA treatment, 10 genes were up-regulated after salt stress, and 7 genes were down-regulated after drought stress. TaBBX10, TaBBX39, TaBBX60, TaBBX67, and TaBBX74 were significantly up-regulated under two or more stresses.

Key words: wheat, genome-wide, B-box gene family, abiotic stress, gene expression

WANG Yan-Peng, LING Lei, ZHANG Wen-Rui, WANG Dan, GUO Chang-Hong. Genome-wide identification and expression analysis of B-box gene family in wheat[J].Acta Agronomica Sinica, 2021, 47(8): 1437-1449.

Figures/Tables 11

Table 1

Table S1

TaBBX genes information identified in the wheat genome"

基因名 Gene name	基因登录号 Gene ID	染色体位点 Chromosome location	基因长度 Length (bp)	氨基酸长度 Length (aa)	等电点 Isoelectric point (pI)	分子量 Molecular weight (kD)	外显子个数 Exon number	分组 Group	结构域类型 Domain type
TaBBX01	TraesCS2A02G119600	2A:70102039-70104699	1149	382	5.73	40010.83	4	Ⅲ	1BBX + CCT
TaBBX02	TraesCS2A02G348900	2A:587750669-587751938	765	254	4.95	27209.52	2	Ⅳ	2BBX
TaBBX03	TraesCS2A02G353900	2A:594579959-594581671	951	316	5.56	33724.51	2	Ⅰ	2BBX+ CCT
TaBBX04	TraesCS2A02G366100	2A:610710308-610712939	789	262	4.79	28237.51	2	Ⅳ	2BBX
TaBBX05	TraesCS2A02G388500	2A:635722864-635724553	777	258	5.82	27357.5	3	Ⅳ	2BBX
TaBBX06	TraesCS2B02G140300	2B:106954443-106956656	1164	387	5.44	40384.32	4	Ⅲ	1BBX + CCT
TaBBX07	TraesCS2B02G367300	2B:523760095-523761742	774	257	4.89	27492.85	2	Ⅳ	2BBX
TaBBX08	TraesCS2B02G372000	2B:530306217-530307895	960	319	5.56	33908.66	2	Ⅰ	2BBX+ CCT
TaBBX09	TraesCS2B02G406600	2B:575903665-575905255	795	264	5.82	27823.99	3	Ⅳ	2BBX
TaBBX10	TraesCS2D02G121400	2D:70622968-70625567	1146	381	5.72	39968.91	4	Ⅲ	1BBX + CCT
TaBBX11	TraesCS2D02G347300	2D:445396017-445397519	777	258	4.81	27494.76	2	Ⅳ	2BBX
TaBBX12	TraesCS2D02G351900	2D:450234732-450236192	960	319	5.56	33936.74	2	Ⅰ	2BBX+ CCT
TaBBX13	TraesCS2D02G386300	2D:491429370-491431171	789	262	5.82	27600.81	3	Ⅳ	2BBX
TaBBX14	TraesCS3A02G139300	3A:117227850-117230216	1050	349	5.15	37168.47	3	Ⅳ	2BBX
TaBBX15	TraesCS3B02G156900	3B:150154692-150156947	1050	349	5.22	37477.8	3	Ⅳ	2BBX
TaBBX16	TraesCS3D02G139600	3D:99748881-99751184	1050	349	5.32	37482.8	3	Ⅳ	2BBX
TaBBX17	TraesCS4A02G140600	4A:216145053-216148012	1239	412	5.5	45256.44	5	Ⅲ	1BBX + CCT
TaBBX18	TraesCS4A02G268500	4A:580733925-580736107	1233	410	5.85	44829.19	2	Ⅱ	1BBX + CCT
TaBBX19	TraesCS4B02G045700	4B:32896523-32898695	1236	411	6.04	44870.33	2	Ⅱ	1BBX + CCT
TaBBX20	TraesCS4B02G155800	4B:281732350-281735921	1194	397	6.06	43627.8	3	Ⅲ	1BBX + CCT
TaBBX21	TraesCS4D02G046200	4D:21774703-21776886	1233	410	5.85	44816.25	2	Ⅱ	1BBX + CCT
TaBBX22	TraesCS4D02G167300	4D:288428472-288432595	1194	397	6.1	43454.51	3	Ⅲ	1BBX + CCT
TaBBX23	TraesCS5A02G166100	5A:355071283-355072804	981	326	5.78	35576.36	2	Ⅰ	1BBX + CCT
TaBBX24	TraesCS5A02G317100	5A:528110873-528114741	636	211	5.74	23146.7	5	Ⅳ	2BBX
TaBBX25	TraesCS5A02G336000	5A:545058736-545059411	540	179	5.29	19206.94	2	Ⅲ	1BBX
TaBBX26	TraesCS5A02G336100	5A:545073760-545074317	441	146	4.57	15371.44	2	Ⅲ	1BBX
TaBBX27	TraesCS5A02G339000	5A:546563819-546564523	705	234	9.27	24319.82	1	Ⅴ	1BBX
TaBBX28	TraesCS5A02G339100	5A:546575974-546576576	603	200	10.42	21432.56	1	Ⅴ	1BBX
TaBBX29	TraesCS5B02G163500	5B:302753429-302754975	978	325	5.96	35477.32	2	Ⅰ	1BBX + CCT
TaBBX30	TraesCS5B02G317700	5B:501954375-501958483	636	211	5.85	23088.66	5	Ⅳ	2BBX
TaBBX31	TraesCS5B02G335200	5B:518472466-518473347	468	155	5	16721.09	2	Ⅲ	1BBX
TaBBX32	TraesCS5B02G335300	5B:518481548-518484145	1107	368	6.23	39645.26	4	Ⅲ	1BBX + CCT
TaBBX33	TraesCS5B02G337400	5B:520970152-520970850	699	232	9.02	24101.56	1	Ⅴ	1BBX
TaBBX34	TraesCS5B02G337500	5B:521031958-521032572	615	204	9.65	21590.87	1	Ⅴ	1BBX
TaBBX35	TraesCS5D02G170700	5D:267762539-267764201	978	325	5.96	35519.42	2	1	1BBX + CCT
TaBBX36	TraesCS5D02G323400	5D:415613354-415617623	636	211	5.85	23084.67	5	Ⅳ	2BBX
TaBBX37	TraesCS5D02G341000	5D:429289528-429291886	1083	360	6.33	38690.35	4	Ⅲ	1BBX + CCT
TaBBX38	TraesCS5D02G343300	5D:431251824-431252543	720	239	9.03	25267.96	1	Ⅴ	1BBX
TaBBX39	TraesCS6A02G143900	6A:121616223-121619829	645	214	4.72	22147.27	2	Ⅳ	2BBX
TaBBX40	TraesCS6A02G150900	6A:134947729-134949478	1095	364	5.68	37982.35	3	Ⅰ	2BBX+ CCT
TaBBX41	TraesCS6A02G216400	6A:398252913-398254425	771	256	5.14	27782.32	2	Ⅳ	2BBX
TaBBX42	TraesCS6A02G218900	6A:405166583-405168134	966	321	5.24	33625.42	2	Ⅰ	2BBX+ CCT
TaBBX43	TraesCS6A02G239300	6A:449584187-449585880	711	236	5.77	25104.96	3	Ⅳ	2BBX
TaBBX44	TraesCS6A02G286400	6A:518666410-518670650	972	323	6.65	35122.47	3	Ⅲ	2BBX+ CCT
TaBBX45	TraesCS6A02G289400	6A:521451709-521454099	1110	369	5.91	41051.82	2	Ⅰ	2BBX+ CCT
TaBBX46	TraesCS6A02G293200	6A:524718099-524720326	1281	426	6.81	46496.91	2	Ⅱ	1BBX + CCT
TaBBX47	TraesCS6B02G172300	6B:184884215-184886653	645	214	4.89	22154.35	2	Ⅳ	2BBX
TaBBX48	TraesCS6B02G179000	6B:198984566-198986312	1125	374	5.28	38846.14	3	Ⅰ	2BBX+ CCT
TaBBX49	TraesCS6B02G246500	6B:439021199-439022376	783	260	4.98	28026.56	2	Ⅳ	2BBX
TaBBX50	TraesCS6B02G248400	6B:445852206-445853977	966	321	5.34	33887.8	2	Ⅰ	2BBX+ CCT
TaBBX51	TraesCS6B02G285200	6B:514117744-514119320	717	238	6.04	25141.06	3	Ⅳ	2BBX
TaBBX52	TraesCS6B02G315400	6B:563320471-563324616	1173	390	4.96	42531.41	4	Ⅲ	2BBX+ CCT
TaBBX53	TraesCS6B02G319500	6B:567397520-567399497	1113	370	5.58	41154.91	2	Ⅰ	2BBX+ CCT
TaBBX54	TraesCS6B02G323400	6B:572391940-572393940	1287	428	6.4	46597.09	2	Ⅱ	1BBX + CCT
TaBBX55	TraesCS6D02G133100	6D:100871867-100874382	645	214	4.97	22054.19	2	Ⅳ	2BBX
TaBBX56	TraesCS6D02G140900	6D:110442898-110444721	1095	364	5.68	38019.41	3	Ⅰ	2BBX+ CCT
TaBBX57	TraesCS6D02G199200	6D:277099701-277101029	783	260	5.14	28221.83	2	Ⅳ	2BBX
TaBBX58	TraesCS6D02G202000	6D:284849813-284850866	954	317	5.17	33352.08	2	Ⅰ	2BBX+ CCT
TaBBX59	TraesCS6D02G221700	6D:312763126-312764854	717	238	5.77	25258.08	3	Ⅳ	2BBX
TaBBX60	TraesCS6D02G267100	6D:377220309-377224969	1179	392	4.79	43027.95	4	Ⅲ	2BBX+ CCT
TaBBX61	TraesCS6D02G269500	6D:379572086-379574125	1110	369	5.5	40998.72	2	Ⅰ	2BBX+ CCT
TaBBX62	TraesCS6D02G274100	6D:382588127-382590143	1305	434	6.12	47026.54	2	Ⅱ	1BBX + CCT
TaBBX63	TraesCS7A02G108400	7A:65969778-65975971	1080	359	5.1	38311.73	3	Ⅳ	2BBX
TaBBX64	TraesCS7A02G108700	7A:66173971-66174456	486	161	8.98	17172.82	1	Ⅴ	1BBX
TaBBX65	TraesCS7A02G132100	7A:85159979-85160728	750	249	7.65	25502.35	1	Ⅰ	1BBX + CCT
TaBBX66	TraesCS7A02G206200	7A:168812422-168813720	1299	432	5.32	47132.21	1	Ⅱ	1BBX + CCT
TaBBX67	TraesCS7A02G211300	7A:174203246-174205720	1158	385	6.06	42218.87	2	Ⅰ	2BBX+ CCT
TaBBX68	TraesCS7A02G218600	7A:185642724-185648145	1191	396	4.92	43615.36	4	Ⅲ	2BBX+ CCT
TaBBX69	TraesCS7A02G263500	7A:261221617-261225670	1473	490	6.1	52005.04	4	Ⅲ	1BBX + CCT
TaBBX70	TraesCS7A02G383400	7A:558402604-558404184	852	283	5.04	29956.59	3	Ⅳ	2BBX
TaBBX71	TraesCS7A02G497200	7A:686936894-686938479	1119	372	5.96	39566.55	2	Ⅰ	2BBX+ CCT
TaBBX72	TraesCS7B02G006400	7B:3684186-3689427	1017	338	4.83	36159.24	4	Ⅳ	2BBX
TaBBX73	TraesCS7B02G113400	7B:131376607-131378427	1299	432	5.3	47173.18	1	Ⅱ	1BBX + CCT
TaBBX74	TraesCS7B02G118300	7B:137793769-137796142	1152	383	6.24	42114.89	2	Ⅰ	2BBX+ CCT
TaBBX75	TraesCS7B02G125500	7B:146898679-146904866	1014	337	4.32	36449.17	3	Ⅲ	2BBX
TaBBX76	TraesCS7B02G161500	7B:220866464-220870459	1467	488	6.44	51810.89	4	Ⅲ	1BBX + CCT
TaBBX77	TraesCS7B02G286300	7B:521577849-521579171	936	311	5.69	33195.49	2	Ⅳ	2BBX
TaBBX78	TraesCS7B02G400600	7B:667070044-667071768	1119	372	5.9	39407.46	2	Ⅰ	2BBX+ CCT
TaBBX79	TraesCS7D02G103300	7D:63325536-63331403	1092	363	5.03	38772.21	3	Ⅳ	2BBX
TaBBX80	TraesCS7D02G131700	7D:83472836-83474058	753	250	6.09	25596.33	1	Ⅰ	1BBX + CCT
TaBBX81	TraesCS7D02G209000	7D:167228163-167229829	1299	432	5.26	47125.17	1	Ⅱ	1BBX + CCT
TaBBX82	TraesCS7D02G213000	7D:171311981-171314465	1119	372	6.31	41073.77	2	Ⅰ	2BBX+ CCT
TaBBX83	TraesCS7D02G220300	7D:180685905-180691434	1191	396	4.92	43609.35	4	Ⅲ	2BBX+ CCT
TaBBX84	TraesCS7D02G264300	7D:244952312-244956390	1470	489	6.21	51903.89	4	Ⅲ	1BBX + CCT
TaBBX85	TraesCS7D02G379900	7D:492148581-492150240	858	285	5.02	30133.81	3	Ⅳ	2BBX
TaBBX86	TraesCS7D02G484400	7D:594729348-594730950	1119	372	5.86	39527.57	2	Ⅰ	2BBX+ CCT
TaBBX87	TraesCSU02G091500	Un:81434193-81437118	1110	369	6.21	40011.43	4	Ⅲ	1BBX + CCT

Table S1

Fig. 1

Fig. S1

Fig. 2

Fig. 3

Fig. S2

Fig. 4

Table 2

Fig. 5

Fig. 6

References 44

[1]	解松峰, 吉万全, 张耀元, 张俊杰, 胡卫国, 李俊, 王长有, 张宏, 陈春环. 小麦重要产量性状的主基因+多基因混合遗传分析. 作物学报, 2020,46:365-384.
	Xie S F, Ji W Q, Zhang Y Y, Zhang J J, Hu W G, Li J, Wang C Y, Zhang H, Chen C H. Genetic effects of important yield traits analyzed by mixture model of major gene plus polygene in wheat. Acta Agron Sin, 2020,46:365-384 (in Chinese with English abstract).
[2]	刘登才, 张连全, 郝明, 黄林, 甯顺腙, 袁中伟, 姜博, 颜泽洪, 伍碧华, 郑有良. 小麦族的基因组显性及其育种学意义. 作物学报, 2020,46:1465-1473.
	Liu D C, Zhang L Q, Hao M, Huang L, Ning S Z, Yuan Z W, Jiang B, Yan Z H, Wu B H, Zheng Y L. Genome dominance and the breeding significance in Triticeae. Acta Agron Sin, 2020,46:1465-1473 (in Chinese with English abstract).
[3]	Choulet F, Alberti A, Theil S, Glover N, Barbe V, Daron J, Pingault L, Sourdille P, Couloux A, Paux E, Leroy P, Mangenot S, Guilhot N, Le Gouis J, Balfourier F, Alaux m, Jamilloux V, Poulain J, Durand C, Bellec A, Gaspin C, Safar J, Dolezel J, Rogers J, Vandepoele K, Aury J M, Mayer K, Berges H, Quesneville H, Wincker P, Feuillet C. Structural and functional partitioning of bread wheat chromosome 3B. Science, 2014,345:1249721. doi: 10.1126/science.1249721
[4]	IWGSC. Shifting the limits in wheat research and breeding using a fully annotated reference genome. Science, 2018,361:eaar7191. doi: 10.1126/science.aar7191
[5]	茹京娜, 于太飞, 陈隽, 陈明, 周永斌, 马有志, 徐兆师, 闵东红. 小麦锌指转录因子TaDi19A对低温的响应及其互作蛋白的筛选. 中国农业科学, 2017,50:2411-2422.
	Ru J N, Yu T F, Chen J, Chen M, Zhou Y B, Ma Y Z, Xu Z S, Min D H. Response of wheat Zinc-Finger transcription factor TaDi19A to cold and its screening of interacting proteins. Sci Agric Sin, 2017,50:2411-2422 (in Chinese with English abstract).
[6]	Klug A, Schwabe J W. Protein motifs 5. Zinc fingers. FASEB J, 1995,9:597-604. pmid: 7768350
[7]	Putterill J, Robson F, Lee K, Simon R, Coupland G. The CONSTANS gene of Arabidopsis promotes flowering and encodes a protein showing similarities to zinc finger transcription factors. Cell, 1995,80:847. pmid: 7697715
[8]	Chang C S, Maloof J N, Wu S H. COP1-mediated degradation of BBX22/LZF1 optimizes seedling development in Arabidopsis. Plant Physiol, 2011, 156: 228-239. doi: 10.1104/pp.111.175042
[9]	Gonzalezschain N D, Diazmendoza M, Zurczak M, Suarezlopez P. Potato CONSTANS is involved in photoperiodic tuberization in a graft-transmissible manner. Plant J, 2012,70:678-690. doi: 10.1111/tpj.2012.70.issue-4
[10]	Crocco C D, Holm M, Yanovsky M J, Botto J F. Function of B-box under shade. Plant Signal Behav, 2011,6:101-104. doi: 10.4161/psb.6.1.14185
[11]	Wang Q, Tu X, Zhang J, Chen X, Rao L. Heat stress-induced BBX18 negatively regulates the thermotolerance in Arabidopsis. Mol Biol Rep, 2013,40:2679-2688. doi: 10.1007/s11033-012-2354-9
[12]	Fan X Y, Sun Y, Cao D M, Bai M Y, Luo X M, Yang H J, Wei C Q, Zhu S W, Sun Y, Chong K. BZS1, a B-box protein, promotes photomorphogenesis downstream of both Brassinosteroid and light signaling pathways. Mol Plant, 2012,5:591-600. doi: 10.1093/mp/sss041
[13]	Bai M J, Sun J J, Liu J Y, Ren H R, Wang K, Wang Y L, Wang C Q, Dehesh K. The B-box protein BBX19 suppresses seed germination via induction of ABI5. Plant J, 2019,99:1192-1202. doi: 10.1111/tpj.v99.6
[14]	Yadav A, Lingwan M, Yadukrishnan P, Masakapalli S K, Datta S. BBX31 promotes hypocotyl growth, primary root elongation and UV-B tolerance in Arabidopsis. Plant Signal Behav, 2019,14:e1588672. doi: 10.1080/15592324.2019.1588672
[15]	Gangappa S N, Crocco C D, Johansson H, Datta S, Hettiarachchi C, Holm M, Botto J F. The Arabidopsis B-box protein BBX25 interacts with HY5, negatively regulating BBX22 expression to suppress seedling photomorphogenesis. Plant Cell, 2013,25:1243-1257. doi: 10.1105/tpc.113.109751
[16]	An J P, Wang X F, Espley R V, Lin W K, Bi S Q, You C X, Hao Y J. An apple B-box protein MdBBX37 modulates anthocyanin biosynthesis and hypocotyl elongation synergistically with MdMYBs and MdHY5. Plant Cell Physiol, 2020,61:130-143. doi: 10.1093/pcp/pcz185
[17]	Lippuner V, Cyert M S, Gasser C S. Two classes of plant cDNA clones differentially complement yeast calcineurin mutants and increase salt tolerance of wild-type yeast. J Biol Chem, 1996,271:12859-12866. pmid: 8662738
[18]	Nagaoka S, Takano T. Salt tolerance-related protein STO binds to a MYB transcription factor homologue and confers salt tolerance in Arabidopsis. J Exp Bot, 2003,54:2231-2237. doi: 10.1093/jxb/erg241
[19]	Min J H, Chung J S, Lee K H, Kim C S. The CONSTANS-like 4 transcription factor, AtCOL4, positively regulates abiotic stress tolerance through an abscisic acid-dependent manner in Arabidopsis. J Integr Plant Biol, 2015,57:313-324. doi: 10.1111/jipb.12246
[20]	Liu X, Li R, Dai Y Q, Yuan L, Sun Q H, Zhang S Z, Wang X Y. A B-box zinc finger protein, MdBBX10, enhanced salt and drought stresses tolerance in Arabidopsis. Plant Mol Biol, 2019,99:437-447. doi: 10.1007/s11103-019-00828-8
[21]	Liu X, Dai Y Q, Li R, Yuan L, Chen X S, Wang X Y. Members of B-box protein family from Malus domestica enhanced abiotic stresses tolerance in Escherichia coli. Mol Biotechnol, 2019,61:421-426. doi: 10.1007/s12033-019-00172-8
[22]	王日红, 宋敏燕, 王然, 杨英杰. 山梨B-box基因PuBBX24表达特性及其在童期调控中的功能分析. 园艺学报, 2019,46:1458-1472.
	Wang R H, Song M Y, Wang R, Yang Y J. Expression characteristics of B-box gene PuBBX24 and its function in juvenile regulation. Acta Hortic Sin, 2019,46:1458-1472 (in Chinese with English abstract).
[23]	Khanna R, Wu S H. The Arabidopsis B-box zinc finger family. Plant Cell, 2009,21:3416. doi: 10.1105/tpc.109.069088
[24]	Huang J Y, Zhao X B, Weng X Y, Wang L, Xie W B. The rice B-box zinc finger gene family: genomic identification, characterization, expression profiling and diurnal analysis. PLoS One, 2012,7:e48242. doi: 10.1371/journal.pone.0048242
[25]	Gangappa S N, Botto J F. The BBX family of plant transcription factors. Trends Plant Sci, 2014,19:460-470. doi: 10.1016/j.tplants.2014.01.010
[26]	Chu Z, Wang X, Li Y, Yu H, Li J, Lu Y, Li H, Ouyang B. Genomic organization, phylogenetic and expression analysis of the B-box gene family in tomato. Front Plant Sci, 2016,7:1552.
[27]	Talar U, Kiełbowicz-Matuk A, Czarnecka J, Rorat T. Genome- wide survey of B-box proteins in potato (Solanum tuberosum)—Identification, characterization and expression patterns during diurnal cycle, etiolation and de-etiolation. PLoS One, 2017,12:e0177471. doi: 10.1371/journal.pone.0177471
[28]	Shalmani A, Fan S, Jia P, Li G, Muhammad I, Li Y, Sharif R, Dong F, Zuo X, Li K. Genome identification of B-box gene family members in seven rosacea species and their expression analysis in response to flower induction in Malus domestica. Molecules, 2018,23:1763. doi: 10.3390/molecules23071763
[29]	Liu X, Li R, Dai Y Q, Chen X S, Wang X Y. Genome-wide identification and expression analysis of the B-box gene family in the apple (Malus domestica Borkh.) genome. Mol Genet Genome, 2017,293:1-13. doi: 10.1007/s00438-017-1370-9
[30]	Cao Y, Han Y, Meng D, Li D, Jiao C, Jin Q, Lin Y, Cai Y. B-box genes: genome-wide identification, evolution and their contribution to pollen growth in pear (Pyrus bretschneideri Rehd.). BMC Plant Biol, 2017,17:156. doi: 10.1186/s12870-017-1105-4
[31]	Wei H R, Wang P P, Chen J Q, Li C J, Wang Y Z, Yuan Y B, Fang J G, Leng X P. Genome-wide identification and analysis of B-box gene family in grapevine reveal its potential functions in berry development. BMC Plant Biol, 2020,20:72. doi: 10.1186/s12870-020-2239-3
[32]	Crocco C D, Botto J F. BBX proteins in green plants: insights into their evolution, structure, feature and functional diversification. Gene, 2013,531:44-52. doi: 10.1016/j.gene.2013.08.037
[33]	Zou Z Y, Wang R H, Wang R, Yang S L, Yang Y J. Genome-wide identification, phylogenetic analysis, and expression profiling of the BBX family genes in pear. J Hortic Sci Biotechnol, 2017,93:37-50. doi: 10.1080/14620316.2017.1338927
[34]	Magadum S, Banerjee U, Murugan P, Gangapur D, Ravikesavan R. Gene duplication as a major force in evolution. J Genet, 2013,92:155-161. doi: 10.1007/s12041-013-0212-8
[35]	Cannon S B, Mitra A, Baumgarten A, Young N D, May G. The roles of segmental and tandem gene duplication in the evolution of large gene families in Arabidopsis thaliana. BMC Plant Biol, 2004,4:10. doi: 10.1186/1471-2229-4-10
[36]	Moore R C, Purugganan M D. The early stages of duplicate gene evolution. Proc Natl Acad Sci USA, 2003,100:15682-15687. doi: 10.1073/pnas.2535513100
[37]	Abdullah S, Jing X Q, Shi Y, Izhar M, Zhou M R, Wei X Y, Chen Q Q, Li W Q, Liu W T, Chen K M. Characterization of B-box gene family and their expression profiles under hormonal, abiotic and metal stresses in Poaceae plant. BMC Genome, 2019,20:27. doi: 10.1186/s12864-018-5336-z
[38]	Hassidim M, Harir Y, Yakir E, Kron I, Green R M. Over- expression of CONSTANS-LIKE 5 can induce flowering in short-day grown Arabidopsis. Planta, 2009,230:481-491. doi: 10.1007/s00425-009-0958-7 pmid: 19504268
[39]	Cheng X F, Wang Z Y. Overexpression of COL9, a CONSTANS-LIKE gene, delays flowering by reducing expression of CO and FT in Arabidopsis thaliana. Plant J, 2005,43:758-768. doi: 10.1111/tpj.2005.43.issue-5
[40]	Li W, Wang J, Sun Q, Li W, Yu Y, Zhao M, Meng Z. Expression analysis of genes encoding double B-box zinc finger proteins in maize. Funct Integr Genome, 2017,17:653-666.
[41]	Rengasamy P. World salinization with emphasis on Australia. J Exp Bot, 2006,57:1017-1023. pmid: 16510516
[42]	Cramer G R, Urano K, Delrot S, Pezzotti M, Shinozaki K. Effects of abiotic stress on plants: a systems biology perspective. BMC Plant Biol, 2011,11:163. doi: 10.1186/1471-2229-11-163 pmid: 22094046
[43]	Yang Y, Ma C, Xu Y, Wei Q, Imtiaz M, Lan H, Gao S, Cheng L, Wang M, Fei Z. A zinc finger protein regulates flowering time and abiotic stress tolerance in chrysanthemum by modulating gibberellin biosynthesis. Plant Cell, 2014,26:2038-2354. doi: 10.1105/tpc.114.124867
[44]	刘焱, 邢立静, 李俊华, 戴绍军. 水稻含有B-box锌指结构域的OsBBX25蛋白参与植物对非生物胁迫的响应. 植物学报, 2012,47:366-378. doi: 10.3724/SP.J.1259.2012.00366
	Liu Y, Xing L J, Li J H, Dai S J. Rice B-box zinc finger protein OsBBX25 is involved in the abiotic response. Chin Bull Bot, 2012,47:366-378 (in Chinese with English abstract).

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

基因 Gene	正向引物 Forward primer (5′-3′)	反向引物 Reverse primer (5′-3′)
TaBBX01	AACGGGGGAGTGTTACTTCT	AGTTGGAGCAGAGGAACCGA
TaBBX06	AACTCGCCAAGTCGGAGGA	AGCTGCTGATACGGAGGTACA
TaBBX08	TACCGCCGACGTGTTCTT	TCAGAGGAGGATACGCTGTG
TaBBX10	CTCGCATCGTCCTCTCCAA	TCTGCTGGCATGAAGGTACA
TaBBX12	CACAGCGTATCGTCGTCTGA	ATCTCCTCGTGCTCCTCCAT
TaBBX13	TCGAACAAGCCGTATCAGCA	AGAAGGAGGAGCCGAGAGAC
TaBBX14	AGCCGGAGGTAATCAAAGCC	GAGGAGGACGACAACGATCC
TaBBX18	GGGTTCTCCGGGTTCGAC	CCTCTAACTCTTGCTCCGGC
TaBBX35	TGACATTGAAAGGCTGCGT	TGACATTGAAAGGCTGCGT
TaBBX39	ACCGCCGATTCCTCATCAC	CCAATGTCGTCTTCTCCTCCT
TaBBX43	CTCCGAGTACCTCACCAAGAC	CAATGCTCCTGCCTCATCCA
TaBBX46	CACGCGGTACATGGCACG	CCGGTGCGCTTGACGAAG
TaBBX52	CCGAACTGCGAGGAAGGAATA	GCTGGCTGATGTGTAGGAAGT
TaBBX60	GCCGAACTGTGAGGAAGGAA	AGGCTGATGCGTAGGAAGTG
TaBBX62	CACGACGGGCGGGTAAAG	GGCTCCTTTTCAAGAACTGCG
TaBBX67	GAGAAGGAAGGGAGCGAGTG	GCTGGACTGGACCGTATTGT
TaBBX74	GCAACCAAGAGCAGTATGTGAT	TGTTGACGGAATCTGTGTAAGC
TaBBX76	AGGTAAGCTCATGCACCTCG	CGTCTCGCTGTCGATCCTTG
TaBBX77	GACGAGCCCATTCACAGCG	GGCAGATGTTGGTGAGGTAGTC
TaBBX86	AGGGCGGGAAGATGGACTAC	ATGAGGAGCTGTAGGTCTGC
TaActin	TACTCCCTCACAACAACCG	AGAACCTCCACTGAGAACAA

顺式作用元件 cis-elements	基因数目 Number of genes	顺式作用元件的功能 Functions of cis-elements
CAAT-box	87	Common cis-acting element in promoter and enhancer regions
TATA-box	87	Core promoter element around -30 of transcription start
CGTCA-motif	75	cis-acting regulatory element involved in the MeJA-responsiveness
TGACG-motif	75	cis-acting regulatory element involved in the MeJA-responsiveness
ABRE	84	cis-acting element involved in the abscisic acid responsiveness
ARE	67	cis-acting regulatory element essential for the anaerobic induction
MBS	49	MYB binding site involved in drought-inducibility
LTR	57	cis-acting element involved in low-temperature responsiveness
W box	51	Wounding and pathogen responsiveness.
TGA-element	42	Auxin-responsive element
GC-motif	51	Enhancer-like element involved in anoxic specific inducibility
CCAAT-box	24	MYBHv1 binding site
TCA-element	30	cis-acting element involved in salicylic acid responsiveness
P-box	31	Gibberellin-responsive element
WUN-motif	20	Wound-responsive element
ERE	18	Ethylene-responsive element
GARE-motif	23	Gibberellin-responsive element
TC-rich repeats	27	cis-acting element involved in defense and stress responsiveness
AuxRR-core	18	cis-acting regulatory element involved in auxin responsiveness

Genome-wide identification and expression analysis of B-box gene family in wheat

RichHTML386

PDF

Abstract

Cite this article

share this article

Figures/Tables 11

References 44

Related Articles 15

Metrics

Comments

Recommended 0

[1]	HU Wen-Jing, LI Dong-Sheng, YI Xin, ZHANG Chun-Mei, ZHANG Yong. Molecular mapping and validation of quantitative trait loci for spike-related traits and plant height in wheat [J]. Acta Agronomica Sinica, 2022, 48(6): 1346-1356.
[2]	LI Hai-Fen, WEI Hao, WEN Shi-Jie, LU Qing, LIU Hao, LI Shao-Xiong, HONG Yan-Bin, CHEN Xiao-Ping, LIANG Xuan-Qiang. Cloning and expression analysis of voltage dependent anion channel (AhVDAC) gene in the geotropism response of the peanut gynophores [J]. Acta Agronomica Sinica, 2022, 48(6): 1558-1565.
[3]	GUO Xing-Yu, LIU Peng-Zhao, WANG Rui, WANG Xiao-Li, LI Jun. Response of winter wheat yield, nitrogen use efficiency and soil nitrogen balance to rainfall types and nitrogen application rate in dryland [J]. Acta Agronomica Sinica, 2022, 48(5): 1262-1272.
[4]	LEI Xin-Hui, WAN Chen-Xi, TAO Jin-Cai, LENG Jia-Jun, WU Yi-Xin, WANG Jia-Le, WANG Peng-Ke, YANG Qing-Hua, FENG Bai-Li, GAO Jin-Feng. Effects of soaking seeds with MT and EBR on germination and seedling growth in buckwheat under salt stress [J]. Acta Agronomica Sinica, 2022, 48(5): 1210-1221.
[5]	FU Mei-Yu, XIONG Hong-Chun, ZHOU Chun-Yun, GUO Hui-Jun, XIE Yong-Dun, ZHAO Lin-Shu, GU Jia-Yu, ZHAO Shi-Rong, DING Yu-Ping, XU Yan-Hao, LIU Lu-Xiang. Genetic analysis of wheat dwarf mutant je0098 and molecular mapping of dwarfing gene [J]. Acta Agronomica Sinica, 2022, 48(3): 580-589.
[6]	JIN Rong, JIANG Wei, LIU Ming, ZHAO Peng, ZHANG Qiang-Qiang, LI Tie-Xin, WANG Dan-Feng, FAN Wen-Jing, ZHANG Ai-Jun, TANG Zhong-Hou. Genome-wide characterization and expression analysis of Dof family genes in sweetpotato [J]. Acta Agronomica Sinica, 2022, 48(3): 608-623.
[7]	FENG Jian-Chao, XU Bei-Ming, JIANG Xue-Li, HU Hai-Zhou, MA Ying, WANG Chen-Yang, WANG Yong-Hua, MA Dong-Yun. Distribution of phenolic compounds and antioxidant activities in layered grinding wheat flour and the regulation effect of nitrogen fertilizer application [J]. Acta Agronomica Sinica, 2022, 48(3): 704-715.
[8]	LIU Yun-Jing, ZHENG Fei-Na, ZHANG Xiu, CHU Jin-Peng, YU Hai-Tao, DAI Xing-Long, HE Ming-Rong. Effects of wide range sowing on grain yield, quality, and nitrogen use of strong gluten wheat [J]. Acta Agronomica Sinica, 2022, 48(3): 716-725.
[9]	WU Yan-Fei, HU Qin, ZHOU Qi, DU Xue-Zhu, SHENG Feng. Genome-wide identification and expression analysis of Elongator complex family genes in response to abiotic stresses in rice [J]. Acta Agronomica Sinica, 2022, 48(3): 644-655.
[10]	YAN Yan, ZHANG Yu-Shi, LIU Chu-Rong, REN Dan-Yang, LIU Hong-Run, LIU Xue-Qing, ZHANG Ming-Cai, LI Zhao-Hu. Variety matching and resource use efficiency of the winter wheat-summer maize “double late” cropping system [J]. Acta Agronomica Sinica, 2022, 48(2): 423-436.
[11]	WANG Yang-Yang, HE Li, REN De-Chao, DUAN Jian-Zhao, HU Xin, LIU Wan-Dai, GU Tian-Cai, WANG Yong-Hua, FENG Wei. Evaluations of winter wheat late frost damage under different water based on principal component-cluster analysis [J]. Acta Agronomica Sinica, 2022, 48(2): 448-462.
[12]	CHEN Xin-Yi, SONG Yu-Hang, ZHANG Meng-Han, LI Xiao-Yan, LI Hua, WANG Yue-Xia, QI Xue-Li. Effects of water deficit on physiology and biochemistry of seedlings of different wheat varieties and the alleviation effect of exogenous application of 5-aminolevulinic acid [J]. Acta Agronomica Sinica, 2022, 48(2): 478-487.
[13]	QU Jian-Zhou, FENG Wen-Hao, ZHANG Xing-Hua, XU Shu-Tu, XUE Ji-Quan. Dissecting the genetic architecture of maize kernel size based on genome-wide association study [J]. Acta Agronomica Sinica, 2022, 48(2): 304-319.
[14]	XU Long-Long, YIN Wen, HU Fa-Long, FAN Hong, FAN Zhi-Long, ZHAO Cai, YU Ai-Zhong, CHAI Qiang. Effect of water and nitrogen reduction on main photosynthetic physiological parameters of film-mulched maize no-tillage rotation wheat [J]. Acta Agronomica Sinica, 2022, 48(2): 437-447.
[15]	MA Bo-Wen, LI Qing, CAI Jian, ZHOU Qin, HUANG Mei, DAI Ting-Bo, WANG Xiao, JIANG Dong. Physiological mechanisms of pre-anthesis waterlogging priming on waterlogging stress tolerance under post-anthesis in wheat [J]. Acta Agronomica Sinica, 2022, 48(1): 151-164.