Identification and Expression Analysis of the ARF Gene Family in Cabbage under Abiotic Stress

doi:10.13560/j.cnki.biotech.bull.1985.2025-0265

Abstract

Abstract:

Objective To identify the members of the auxin response factor (ARF) gene family in cabbage, analyze the expression patterns of BoARF genes under various abiotic stresses in cabbage, and lay a foundation for clarifying the functions of the ARF gene family in cabbage. Method Bioinformatics approaches were used to identify 36 ARF gene family members in the cabbage genome. Comprehensive analyses were conducted, including phylogenetic tree construction, gene structure analysis, conserved motif identification, chromosomal localization, cis-acting element prediction, and collinearity relationship analysis. Additionally, real-time quantitative polymerase chain reaction (RT-qPCR) technology was applied to detect the expression patterns of selected BoARF genes in response to various abiotic stresses (low temperature, high temperature, drought, and salt stress). Result Phylogenetic analysis revealed that the 36 BoARF genes can be classified into four main clades, and these genes are distributed across the nine chromosomes of Brassica oleracea. All 36 BoARF genes contain the conserved Auxin_resp domain characteristic of the ARF family. With the exception of BoARF31, the remaining 35 members possess a B3-type DNA-binding domain. In terms of gene structure, most members contain 12-15 exons. Intraspecies collinearity analysis identified 17 pairs of collinear genes within the cabbage genome. Interspecies collinearity analysis revealed that the cabbage ARF gene family shares 27 collinear relationships with Arabidopsisthaliana and 30 collinear gene pairs with Brassica rapa. Promoter region analysis uncovered a variety of cis-acting elements related to light response, hormone response and abiotic stress response. The analysis of the expression patterns of BoARF genes under abiotic stresses found that BoARF genes responded to different degrees to treatments of low temperature, high temperature, salt, and drought stresses, indicating that the ARF gene family may be involved in the adaptive regulation of cabbage to abiotic stresses. Conclusion A total of 36 BoARF genes are identified in cabbage, which are localized on 9 chromosomes. The promoters of ARF genes contain cis-acting elements associated with abiotic stress. BoARF genes demonstrate distinct expression patterns under abiotic stress.

Key words: cabbage, auxin response factor (ARF), gene family, abiotic stress, chromosomal localization, phylogenetic analysis, cis-acting elements, expression analysis

QIN Wen-jun, XIONG Yan-jie, ZHAO Ran, MA Xiao-ran, YE Xiao-meng, SONG Jiang-hua. Identification and Expression Analysis of the ARF Gene Family in Cabbage under Abiotic Stress[J]. Biotechnology Bulletin, 2025, 41(10): 253-263.

Figures/Tables 8

References 35

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引物名称 Primer name	序列 Sequence （5′-3′）
BoActin-QF	CCTCCGTCTTGACCTTGC
BoActin-QR	GTCTCCATCTCCTGCTCGT
BoARF3-F	TACCACTAACCTCTCCTCTGGG
BoARF3-R	CTTAACTACCTCGGTGGCTGTT
BoARF18-F	CTCAGGGACACATCGAGCAG
BoARF18-R	CGGTATCAACCTCCGCCTTT
BoARF20-F	ATTTCGAGGAACTGAGGGTGTC
BoARF20-R	AAGCTGTTCTATGTGCCCTTGA
BoARF22-F	AGCAACGAAGCGACTAACGA
BoARF22-R	CCCGGTTATCCATGTCTTTCTCA
BoARF28-F	GTCTTCCCCTGTTGGATGTGT
BoARF28-R	CAAAAGAGTCTCCAGCAACCA
BoARF29-F	AACAGCTACAGCCACATAAGCT
BoARF29-R	GATGTTTGTTGTGCCTGATGCT
BoARF30-F	AGGAACAAACGACCGAGACC
BoARF30-R	GGATTTCCACACACCATCAGG
BoARF33-F	AATCCTCATCCTCATGAAGTTACA
BoARF33-R	AAGAGGACCAGCACAAGCAT

引物名称 Primer name	序列 Sequence （5′-3′）
BoActin-QF	CCTCCGTCTTGACCTTGC
BoActin-QR	GTCTCCATCTCCTGCTCGT
BoARF3-F	TACCACTAACCTCTCCTCTGGG
BoARF3-R	CTTAACTACCTCGGTGGCTGTT
BoARF18-F	CTCAGGGACACATCGAGCAG
BoARF18-R	CGGTATCAACCTCCGCCTTT
BoARF20-F	ATTTCGAGGAACTGAGGGTGTC
BoARF20-R	AAGCTGTTCTATGTGCCCTTGA
BoARF22-F	AGCAACGAAGCGACTAACGA
BoARF22-R	CCCGGTTATCCATGTCTTTCTCA
BoARF28-F	GTCTTCCCCTGTTGGATGTGT
BoARF28-R	CAAAAGAGTCTCCAGCAACCA
BoARF29-F	AACAGCTACAGCCACATAAGCT
BoARF29-R	GATGTTTGTTGTGCCTGATGCT
BoARF30-F	AGGAACAAACGACCGAGACC
BoARF30-R	GGATTTCCACACACCATCAGG
BoARF33-F	AATCCTCATCCTCATGAAGTTACA
BoARF33-R	AAGAGGACCAGCACAAGCAT

基因 Gene	序列号 Sequence ID	氨基酸 Amino acid (aa)	分子质量 Molecular weight (kD)	等电点 Isoelectric point	亚细胞定位 Prediction of subcellular localization
BoARF1	Bo2g161810.1	832	92.897 96	6.12	Nucleus
BoARF2	Bo9g076090.1	509	57.927 90	8.61	Nucleus
BoARF3	Bo6g081980.1	543	59.727 75	5.26	Nucleus
BoARF4	Bo7g114200.1	724	80.341 36	8.10	Nucleus
BoARF5	Bo8g097320.1	561	62.937 75	6.02	Nucleus
BoARF6	Bo4g136370.1	820	90.502 65	5.96	Nucleus
BoARF7	Bo8g068380.1	1 020	113.085 42	6.20	Nucleus
BoARF8	Bo2g023110.1	1 174	129.795 23	6.36	Nucleus
BoARF9	Bo8g069820.1	846	93.808 66	5.60	Nucleus
BoARF10	Bo7g109250.1	631	71.227 49	6.15	Nucleus
BoARF11	Bo6g099440.1	777	87.012 40	5.92	Nucleus
BoARF12	Bo5g062810.1	900	99.001 81	5.87	Nucleus
BoARF13	Bo1g037360.1	609	69.110 45	5.95	Nucleus
BoARF14	Bo1g090350.1	662	73.478 58	5.97	Nucleus
BoARF15	Bo3g108130.1	848	94.489 99	6.43	Nucleus
BoARF16	Bo6g121520.1	557	60.514 57	5.41	Mitochondrion， nucleus
BoARF17	Bo7g067390.1	543	62.129 71	6.69	Nucleus
BoARF18	Bo9g014770.1	829	92.567 60	6.34	Nucleus
BoARF19	Bo3g039330.1	563	63.229 87	6.07	Nucleus
BoARF20	Bo9g007780.1	491	56.626 32	6.98	Nucleus
BoARF21	Bo1g014600.1	651	71.906 42	7.59	Nucleus
BoARF22	Bo4g071620.1	703	77.829 81	6.56	Nucleus
BoARF23	Bo9g143570.1	769	85.178 70	6.29	Nucleus
BoARF24	Bo4g008150.1	583	65.667 65	6.88	Nucleus
BoARF25	Bo5g027930.1	880	97.244 45	5.84	Nucleus
BoARF26	Bo4g182310.1	594	65.639 33	6.73	Nucleus
BoARF27	Bo4g041340.1	608	66.607 46	6.52	Nucleus
BoARF28	Bo9g055750.1	480	54.965 61	6.41	Nucleus
BoARF29	Bo9g151530.1	1 174	129.754 34	6.63	Nucleus
BoARF30	Bo4g083590.1	682	76.161 90	6.29	Nucleus
BoARF31	Bo3g135810.1	630	70.641 54	5.85	Nucleus
BoARF32	Bo7g062090.1	860	95.380 51	5.71	Nucleus
BoARF33	Bo3g148950.1	849	93.716 25	6.11	Nucleus
BoARF34	Bo5g027250.1	1052	116.626 96	6.19	Nucleus
BoARF35	Bo2g024860.1	606	68.317 08	9.51	Nucleus
BoARF36	Bo4g039540.1	548	62.465 99	6.01	Nucleus

基因 Gene	序列号 Sequence ID	氨基酸 Amino acid (aa)	分子质量 Molecular weight (kD)	等电点 Isoelectric point	亚细胞定位 Prediction of subcellular localization
BoARF1	Bo2g161810.1	832	92.897 96	6.12	Nucleus
BoARF2	Bo9g076090.1	509	57.927 90	8.61	Nucleus
BoARF3	Bo6g081980.1	543	59.727 75	5.26	Nucleus
BoARF4	Bo7g114200.1	724	80.341 36	8.10	Nucleus
BoARF5	Bo8g097320.1	561	62.937 75	6.02	Nucleus
BoARF6	Bo4g136370.1	820	90.502 65	5.96	Nucleus
BoARF7	Bo8g068380.1	1 020	113.085 42	6.20	Nucleus
BoARF8	Bo2g023110.1	1 174	129.795 23	6.36	Nucleus
BoARF9	Bo8g069820.1	846	93.808 66	5.60	Nucleus
BoARF10	Bo7g109250.1	631	71.227 49	6.15	Nucleus
BoARF11	Bo6g099440.1	777	87.012 40	5.92	Nucleus
BoARF12	Bo5g062810.1	900	99.001 81	5.87	Nucleus
BoARF13	Bo1g037360.1	609	69.110 45	5.95	Nucleus
BoARF14	Bo1g090350.1	662	73.478 58	5.97	Nucleus
BoARF15	Bo3g108130.1	848	94.489 99	6.43	Nucleus
BoARF16	Bo6g121520.1	557	60.514 57	5.41	Mitochondrion， nucleus
BoARF17	Bo7g067390.1	543	62.129 71	6.69	Nucleus
BoARF18	Bo9g014770.1	829	92.567 60	6.34	Nucleus
BoARF19	Bo3g039330.1	563	63.229 87	6.07	Nucleus
BoARF20	Bo9g007780.1	491	56.626 32	6.98	Nucleus
BoARF21	Bo1g014600.1	651	71.906 42	7.59	Nucleus
BoARF22	Bo4g071620.1	703	77.829 81	6.56	Nucleus
BoARF23	Bo9g143570.1	769	85.178 70	6.29	Nucleus
BoARF24	Bo4g008150.1	583	65.667 65	6.88	Nucleus
BoARF25	Bo5g027930.1	880	97.244 45	5.84	Nucleus
BoARF26	Bo4g182310.1	594	65.639 33	6.73	Nucleus
BoARF27	Bo4g041340.1	608	66.607 46	6.52	Nucleus
BoARF28	Bo9g055750.1	480	54.965 61	6.41	Nucleus
BoARF29	Bo9g151530.1	1 174	129.754 34	6.63	Nucleus
BoARF30	Bo4g083590.1	682	76.161 90	6.29	Nucleus
BoARF31	Bo3g135810.1	630	70.641 54	5.85	Nucleus
BoARF32	Bo7g062090.1	860	95.380 51	5.71	Nucleus
BoARF33	Bo3g148950.1	849	93.716 25	6.11	Nucleus
BoARF34	Bo5g027250.1	1052	116.626 96	6.19	Nucleus
BoARF35	Bo2g024860.1	606	68.317 08	9.51	Nucleus
BoARF36	Bo4g039540.1	548	62.465 99	6.01	Nucleus