Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (22): 4851-4868.doi: 10.3864/j.issn.0578-1752.2021.22.012

• HORTICULTURE • Previous Articles     Next Articles

Genome-Wide Identification and Expression Analysis of ACA Gene Family in Brassica rapa

WANG Jie(),WU XiaoYu,YANG Liu,DUAN QiaoHong(),HUANG JiaBao()   

  1. College of Horticulture Science and Engineering, Shandong Agricultural University/State Key Laboratory of Crop Biology, Tai’an 270108, Shandong
  • Received:2021-01-25 Accepted:2021-06-01 Online:2021-11-16 Published:2021-11-19
  • Contact: QiaoHong DUAN,JiaBao HUANG E-mail:17835423101@163.com;duanqh@sdau.edu.cn;jbhuang2018@outlook.com

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Abstract:

【Objective】The aim of this study was to identify ACA genes family from Brassica rapa, and to analyze the commonness and characteristics of those genes, which provided data support for further revealing the evolutionary relationship of ACA family. At the same time, the expression of BraACAs after self-pollination under abiotic stress was investigated, which laid the foundation for further exploring how BraACAs as regulate calcium to perform some biological functions. 【Method】Based on Arabidopsis genome database, the ACA gene family of Brassica rapa was identified by homologous alignment. The molecular weight, theoretical isoelectric point and other physicochemical properties were predicted by online software Expasy. The MEGA 5.0 software was used to construct phylogenetic tree, and the online software GSDS 2.0 was employed to draw gene structure map. According to the family gene location information, chromosome mapping was carried out in TBtools. Then, McscanX software was used to carry out the collinearity analysis of ACA family genes in Arabidopsis and Brassica rapa, and the online software PlantCARE was used to predict and analyze the promoter elements of BraACAs. The protein conserved domains were analyzed by online tools Pfam and MEME. The expression of BraACAs gene in different tissues, abiotic stress and self-pollination were detected by qRT-PCR. 【Result】A total of 18 ACA genes were systematically identified from Brassica rapa, which were distributed on 10 chromosomes. According to the phylogenetic tree, four groups were classified, including 3, 4, 4 and 7 members. According to promoter element analysis, there were many light, abiotic stress and hormone response elements in the promoter of ACA family genes in Brassica rapa, which indicated that ACA family genes had potential biological function of resisting stress. According to the analysis of protein domains, most of the ACA gene family proteins in Brassica rapa had four functional domains unique to the ACA family, 13 of which had N-terminal autoinhibitory domains. The results of qRT-PCR showed that BraACAs were mainly expressed in flowers and pods, and the expression of Bra002762 and Bra035649 genes were up-regulated under chill stress, suggesting that Bra002762 and Bra035649 had potential biological functions in response to chill stress; the expression of Bra031701 gene was up-regulated under salt stress, suggesting that Bra031701 had potential biological functions in response to salt stress. There were significant differences in the expression of Bra003276 and Bra024117 genes between self-pollination and cross-pollination, suggesting that Bra003276 and Bra024117 responded to the self-incompatibility of Brassica rapa. The subcellular localizations of these five genes were all located in the plasma membrane to verify their function of balancing ion concentration on the membrane. 【Conclusion】BraACAs protein structures contained four highly conserved domains. The expression of BraACAs was specific in tissues, and five ACA family gene members encoded proteins located on the cell membrane, of which Bra0002762, Bra035649, Bra031701 were associated with chilling and salt stress response, while Bra003276 and Bra024117 were associated with self-incompatibility reaction.

Key words: ACA gene family, Ca2+-ATPase, chilling stress, salt stress, self-incompatibility, Brassica rapa

Table 1

The primers used in the qRT-PCR"

基因名称 Gene name 上游引物(5´-3´) Forward primer (5´-3´) 下游引物(5´-3´) Reverse primer (5´-3´)
Bra017841 AAAAGCTTCTGGGTGTTCGTAT GGTAGCTATCCCAACGATCAAA
Bra039940 ACCAGAATTTTGACGTTAAGGC GAGATAAATTGGAATGCGGCTT
Bra010605 GCTGTTGGTTCAGTCGATATTC GGCTCAACTTTCACCACTTTAC
Bra010917 GAAGCTTCAAGATGGTTCTCAC ATTGTCTCACAAGCAGCTAGAT
Bra023790 TCGACAAGCTTACTTCTTCGAT ATCGCTTTTCGTATTCTTTCCG
Bra033900 GTCTGCTACCACTATCTGTACC TTGATTCTAAACCGGACCAGAA
Bra023899 TCAAGCACTAAGGAAAAACGG ATATTTGCATACACAGAACGGC
Bra031259 AATAACGGTGATGGGTAGATCC ATATTTGCATACACAGAACGGC
Bra016926 ATCTCTGACGTCATTGAAGGTT AATCGCTTTAGCTGTGCTTATG
Bra003276 GCTGATGTGATCATAATGGACG ATACAAAGTTGATGATCAGCGC
Bra007319 GTATCCATCGTGAAAAACCGAG GTTTATATTCTGTCCGTGCACC
Bra019960 GTGATTCTGCTGATATTGGCTG GCTATATTTGCTTGGTAGGCAC
Bra031701 TTCTGTCACGCCATTGTCCT GGTCTATGGCAAGGCAAGGT
Bra002762 GAGAGTTCGGACATCATCATCT GTTAATGATAAGAGCAGCGACG
Bra035649 GTAGTATTTACGTCCCAGAGGG AGAATAGAAGACTGCGATCTGG
Bra011144 GCTCATAATACAACTGGCAGTG GCATCGAAATTCATGCCTAACT
Bra024117 CTTGTCGTCCGCTATTTTACTG TAGGCAAGAGTCAAGGTAACAG
Bra037404 CGGAGATAGGCAAGATACAGAG TGTAGTTGATGATCCAGACGAG
BraActin2 CGGTGTCATGGTTGGGAGA CGTGCTCGATGGGGTACTTC

Table 2

Partial cloned gene primer sequence"

引物名称 Primer name 正向引物(5´-3´) Forward primer(5´-3´) 反向引物(5´-3´) Reverse primer(5´-3´)
Bra002762-pCAMBIA1300-GFP ATGACCAGTCCCTTCAAGCCA GAGTGAACCTTCTCCAGAAGATTTTT
Bra035649-pCAMBIA1300-GFP ATGACTAGCCTCTTCAAGCAATCTC CAAGGCTTCAAAAGTTTGTTGTTT
Bra031701-pCAMBIA1300-GFP ATGGAAGACGCTTACGCCAG CGCCGGTCCTTGGGGAGT
Bra024117-pCAMBIA1300-GFP ATGAGTGGTGGACAAGGACAGTT ACCTGATGAATTCCTTCTCCATCG
Bra003276-pCAMBIA1300-GFP ATGTCTAATCTCCTCAAGGATTTTCA GGCAGAGTCAGATGGACCAGAA

Table 3

Information about ACA gene family members of Brassica rapa"

基因ID
Gene ID		 理论等电点
pI		 分子量
Molecular weight (Da)		 CDS长度
CDS length (bp)		 氨基酸
No. of amino acids (aa)		 亚细胞定位
Subcellular location		 跨膜结构数量
Number of membrane spanning domain		 拟南芥对应ID
Arabidopsis corresponds ID
Bra017841 5.58 110370.20 3045 1015 细胞质膜Plas 8 AT4G37640
Bra039940 5.65 110609.40 3045 1015 细胞质膜Plas 8 AT2G22950
Bra010605 5.45 112318.20 3093 1031 细胞质膜Plas 8 AT4G37640
Bra010917 5.40 110689.40 3054 1017 细胞质膜Plas 8 AT1G27770
Bra023790 8.75 112419.20 3054 1018 细胞质膜Plas 8 AT3G22910
Bra033900 8.28 112171.60 3048 1016 细胞质膜Plas 8 AT3G22910
Bra023899 6.16 119249.50 3291 1097 细胞质膜Plas 10 AT3G21180
Bra031259 6.09 119273.50 3288 1096 细胞质膜Plas 8 AT3G21180
Bra016926 5.43 112256.90 3099 1033 细胞质膜Plas 8 AT2G41560
Bra003276 6.08 111847.50 3078 1026 细胞质膜Plas 8 AT3G57330
Bra007319 5.84 111456.90 3066 1022 细胞质膜Plas 8 AT3G57330
Bra019960 5.06 113187.20 3138 1046 细胞质膜Plas 7 AT1G10130
Bra031701 5.26 118294.80 3256 1086 细胞质膜Plas 8 AT1G10130
Bra002762 8.03 116025.10 3222 1074 细胞质膜Plas 7 AT5G57110
Bra035649 7.81 116661.70 3231 1077 细胞质膜Plas 7 AT5G57110
Bra011144 6.48 116775.40 3210 1070 细胞质膜Plas 8 AT5G57110
Bra024117 6.39 115856.20 3186 1062 细胞质膜Plas 8 AT4G29900
Bra037404 5.31 115615.30 3165 1055 细胞质膜Plas 8 AT4G00900
平均数 Average 6.28 114171.00 3142 1047 \ \ \

Fig. 1

Phylogenetic tree and gene structure of ACA gene family in Brassica rapa"

Fig. 2

Synteny analysis and gene duplication events ACA genes between Brassica rapa and Arabidopsis"

Fig. 3

Analysis of cis-elements in promoter of ACA family genes in Brassica rapa"

Fig. 4

Characterization conserve domains within the Brassica rapa ACA family protein"

Fig. 5

Alignment of conserved motifs of the Brassica rapa ACA family"

Fig. 6

Expression of BraACAs in different organs of Brassica rapa"

Fig. 7

Expression analysis of BraACAs under cold stress at different time points"

Fig. 8

Alignment of the amino acid sequences Bra0002762, Bra035649 and AT5G57110"

Fig. 9

Expression analysis of BraACAs under salt stress at different time points"

Fig. 10

Alignment of the amino acid sequences Bra031701 and AT1G10130"

Fig. 11

Expression levels of BraACAs in stigmas of Brassica rapa at matures stage FPKM values of BraACAs were extracted from stigma RNA-seq data for drawing"

Fig. 12

Expression level of BraACA genes under un-pollination (UP), self-pollination (SI) and cross-pollination (SC)"

Fig. 13

Agarose gel electrophoresis of BraACAs"

Fig. 14

Subcellular localization of BraACAs CK: Vector free injection of tobacco leaves; GFP: Expression of 35s-GFP/pCAMBIA1300 empty vector in tobacco leaves. Scale bar=10 μm"

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doi: 10.1007/s11103-014-0220-y
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