黄瓜R2R3-MYB亚家族鉴定及生物信息学分析

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DOI:10.11833/j.issn.2095-0756.20230278

郭玉婷^1,,
杜长霞^{1, 2,,}

1.
浙江农林大学园艺科学学院浙江省山区农业高效绿色生产协同创新中心，浙江杭州 311300
2.
浙江农林大学农业农村部亚热带果品蔬菜质量安全控制重点实验室，浙江杭州 311300

基金项目:浙江省自然科学基金资助项目(LY23C150005)

详细信息

作者简介:郭玉婷(ORCID: 0009-0009-3497-8158)，从事蔬菜分子生物学研究。E-mail:623163988@qq.com

通信作者:杜长霞(ORCID: 0000-0002-0366-2224)，副教授，从事蔬菜逆境生物学研究。E-mail:changxiadu@zafu.edu.cn

中图分类号:S642.2

Identification and bioinformatics analysis of R2R3-MYB subfamily in cucumber

GUO Yuting^1,,
DU Changxia^{1, 2,,}

1.
Collaborative Innovation Center for Efficient and Green Production of Agriculture in Mountainous Areas of Zhejiang Province, College of Horticulture Science, Zhejiang A&F University, Hangzhou 311300, Zhejiang, China
2.
Key Laboratory of Quality and Safety Control for Subtropical Fruit and Vegetable, Ministry of Agriculture and Rural Affairs, Zhejiang A&F University, Hangzhou 311300, Zhejiang, China

摘要: 目的深入研究黄瓜 Cucumis sativusR2R3-MYB亚家族成员的相关功能。方法利用生物信息学手段分析黄瓜全基因组，鉴定R2R3-MYB亚家族成员，对其系统进化关系、蛋白理化性质、染色体定位、基因结构、保守基序、顺式作用元件、蛋白质互作进行分析。结果黄瓜全基因组中含99个具有典型结构域的R2R3-MYB转录因子，蛋白序列含195~552个氨基酸，有保守基序及氨基酸位点；基因在染色体上分布不均匀；大部分亚家族成员蛋白质的不稳定指数大于40，属于不稳定蛋白。顺式作用调控元件分析发现：大部分基因启动子区所含元件与激素调节、MYB结合位点、胁迫密切相关。结论通过黄瓜全基因组鉴定，获得黄瓜基因组99个R2R3-MYB家族成员，分为30个亚组，映射于7条染色体上，该家族成员的上游启动子区含逆境相关作用元件。图7表1参36
- 黄瓜/
- R2R3-MYB/
- 转录因子/
- 全基因组鉴定
Abstract: ObjectiveThis study is aimed to conduct an in-depth study of the functions associated with members of the R2R3-MYB subfamily in cucumber ( Cucumis sativus). MethodFirst, an analysis was conducted of the whole cucumber genome so as to identify R2R3-MYB subfamily members. Then, bioinformatics was employed to analyze their phylogenetic relationships, physicochemical properties of proteins, chromosomal localization, gene structure, conserved motifs, and cis-acting elements, as well as the protein interactions. ResultThe whole cucumber genome contained 99 R2R3-MYB transcription factors with typical structural domains, and the protein sequences contained amino acids ranging from 195 to 552, with conserved motifs and amino acid sites. They were unevenly distributed on chromosomes. They were unstable proteins with the instability index of most subfamily members being greater than 40. As was shown by the analysis of cis-acting regulatory elements, most of the elements contained in the promoter regions of genes were closely related to hormone regulation, MYB binding sites, and stress. ConclusionThe R2R3-MYB family members were obtained through whole cucumber genome identification, which were divided into 30 subgroups and mapped on 7 chromosomes and the upstream promoter region of this family members contained stress-related action elements. [Ch, 7 fig. 1 tab. 36 ref.]
- Cucumis sativus/
- R2R3-MYB/
- transcription factor/
- whole genome identification

图 1黄瓜与拟南芥、杨梅R2R3-MYB亚家族成员的系统进化树构建

Figure 1Phylogenetic tree construction ofC. sativus,A. thalianaandM. rubraR2R3-MYB subfamily members

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图 2黄瓜R2R3-MYB亚家族染色体定位图

Figure 2Chromosome location map ofC. sativusR2R3-MYB subfamily

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图 3黄瓜R2R3-MYB亚家族与拟南芥共线性分析图

Figure 3Analysis of the collinearity betweenC. sativusR2R3-MYB subfamily andA. thaliana

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图 4黄瓜R2R3-MYB亚家族蛋白保守基序和基因结构

Figure 4Protein conservative motifs and gene structure of R2R3-MYB subfamily inC. sativus

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图 5黄瓜R2R3-MYB亚家族蛋白序列比对图

Figure 5Sequence comparison ofC. sativusR2R3-MYB subfamily proteins

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图 6黄瓜R2R3-MYB亚家族上游顺式元件预测

Figure 6Prediction of upstream homeopathic elements ofC. sativusR2R3-MYB subfamily

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图 7黄瓜R2R3-MYB亚家族成员蛋白的互作预测

Figure 7Prediction of protein interactions among R2R3-MYB subfamily members inC. sativus

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表 1黄瓜R2R3-MYB亚家族成员信息

Table 1.Cucumber R2R3-MYB subfamily member information

基因命名	氨基酸数量/个	分子量/kDa	等电点	不稳定指数	脂肪指数	染色体位置	基因命名	氨基酸数量/个	分子量/ kDa	等电点	不稳定指数	脂肪指数	染色体位置
Cs2RMYB1	360	40.91	6.44	52.41	57.17	Chr 1	Cs2RMYB51	268	30.01	8.59	54.65	64.40	Chr 3
Cs2RMYB2	471	54.88	5.91	42.84	66.43	Chr 1	Cs2RMYB52	217	25.13	7.21	55.75	65.21	Chr 3
Cs2RMYB3	367	41.94	5.83	59.22	75.50	Chr 1	Cs2RMYB53	195	22.67	8.37	72.59	73.54	Chr 3
Cs2RMYB4	331	37.60	9.02	65.15	61.90	Chr 1	Cs2RMYB54	355	39.21	6.25	54.46	82.96	Chr 3
Cs2RMYB5	277	31.19	5.90	78.88	66.21	Chr 1	Cs2RMYB55	305	34.19	6.19	45.79	74.52	Chr 3
Cs2RMYB6	232	26.59	8.83	57.26	66.51	Chr 1	Cs2RMYB56	253	28.52	9.10	49.09	65.53	Chr 3
Cs2RMYB7	326	36.76	6.42	53.91	67.94	Chr 1	Cs2RMYB57	313	35.05	4.97	68.24	75.97	Chr 4
Cs2RMYB8	288	32.50	6.31	71.30	64.03	Chr 1	Cs2RMYB58	314	36.06	6.10	62.98	58.06	Chr 4
Cs2RMYB9	377	42.09	6.46	50.23	66.71	Chr 1	Cs2RMYB59	322	35.68	6.14	54.46	67.55	Chr 4
Cs2RMYB10	337	37.92	5.74	45.24	71.19	Chr 1	Cs2RMYB60	377	40.50	5.41	39.90	73.24	Chr 4
Cs2RMYB11	299	33.99	9.17	58.17	61.64	Chr 1	Cs2RMYB61	353	39.81	6.22	60.28	59.92	Chr 4
Cs2RMYB12	372	42.33	6.12	54.32	67.63	Chr 1	Cs2RMYB62	229	25.19	9.29	58.90	61.70	Chr 4
Cs2RMYB13	277	32.11	5.83	63.46	79.96	Chr 1	Cs2RMYB63	263	29.14	8.34	61.14	67.15	Chr 4
Cs2RMYB14	337	38.24	8.66	52.38	59.08	Chr 1	Cs2RMYB64	280	31.51	8.92	59.53	72.11	Chr 4
Cs2RMYB15	370	41.15	6.13	51.97	61.95	Chr 1	Cs2RMYB65	260	28.84	5.00	38.86	76.54	Chr 5
Cs2RMYB16	364	41.75	9.54	55.58	69.81	Chr 1	Cs2RMYB66	323	36.41	6.00	53.24	72.45	Chr 5
Cs2RMYB17	327	37.06	7.68	62.31	69.48	Chr 2	Cs2RMYB67	258	29.46	5.84	45.28	67.67	Chr 5
Cs2RMYB18	295	32.99	9.07	45.41	70.10	Chr 2	Cs2RMYB68	236	26.98	6.71	53.48	74.83	Chr 5
Cs2RMYB19	222	25.74	6.00	53.86	72.43	Chr 2	Cs2RMYB69	284	31.23	6.41	56.18	72.46	Chr 5
Cs2RMYB20	264	29.98	8.97	58.24	63.14	Chr 2	Cs2RMYB70	300	33.77	5.29	55.23	71.50	Chr 5
Cs2RMYB21	265	31.42	9.64	54.52	67.02	Chr 2	Cs2RMYB71	337	38.25	7.69	55.10	66.59	Chr 5
Cs2RMYB22	286	32.59	5.60	58.72	59.69	Chr 2	Cs2RMYB72	210	24.43	5.19	51.25	60.38	Chr 5
Cs2RMYB23	228	26.87	10.27	58.08	65.44	Chr 2	Cs2RMYB73	464	52.29	6.82	66.09	66.85	Chr 5
Cs2RMYB24	256	29.15	8.24	48.25	79.22	Chr 2	Cs2RMYB74	369	41.40	6.61	50.68	56.34	Chr 5
Cs2RMYB25	210	23.54	10.31	65.32	59.48	Chr 2	Cs2RMYB75	307	34.25	7.51	48.64	64.59	Chr 5
Cs2RMYB26	230	26.32	8.83	57.64	63.65	Chr 2	Cs2RMYB76	398	44.52	6.49	53.56	62.29	Chr 5
Cs2RMYB27	204	23.04	8.44	43.78	67.94	Chr 2	Cs2RMYB77	202	23.93	8.25	43.61	58.37	Chr 5
Cs2RMYB28	338	38.46	8.56	58.00	68.99	Chr 2	Cs2RMYB78	294	33.13	8.72	52.07	70.41	Chr 5
Cs2RMYB29	290	31.80	9.23	59.33	65.93	Chr 2	Cs2RMYB79	286	32.77	6.40	64.03	65.17	Chr 6
Cs2RMYB30	297	33.70	9.97	55.65	69.97	Chr 2	Cs2RMYB80	552	61.13	5.50	52.51	61.54	Chr 6
Cs2RMYB31	301	32.30	8.19	55.90	64.15	Chr 2	Cs2RMYB81	301	34.40	5.56	70.97	65.08	Chr 6
Cs2RMYB32	308	34.86	5.93	48.47	84.90	Chr 2	Cs2RMYB82	269	31.33	6.45	45.95	63.42	Chr 6
Cs2RMYB33	519	57.03	7.46	59.70	57.53	Chr 3	Cs2RMYB83	334	38.24	4.96	46.95	59.85	Chr 6
Cs2RMYB34	305	34.64	5.70	57.58	70.72	Chr 3	Cs2RMYB84	286	32.92	5.80	56.50	54.58	Chr 6
Cs2RMYB35	248	29.14	9.10	56.61	66.49	Chr 3	Cs2RMYB85	291	33.53	6.63	61.70	46.94	Chr 6
Cs2RMYB36	259	29.98	6.50	48.74	59.54	Chr 3	Cs2RMYB86	277	32.26	9.35	51.45	59.49	Chr 6
Cs2RMYB37	296	33.70	5.35	56.27	67.20	Chr 3	Cs2RMYB87	301	32.45	9.32	50.91	64.82	Chr 6
Cs2RMYB38	219	25.25	6.32	59.79	70.32	Chr 3	Cs2RMYB88	319	35.85	6.53	48.51	65.49	Chr 6
Cs2RMYB39	354	40.50	9.20	58.22	77.40	Chr 3	Cs2RMYB89	344	38.44	6.12	57.72	80.00	Chr 6
Cs2RMYB40	267	30.10	5.59	55.70	69.33	Chr 3	Cs2RMYB90	387	44.36	5.81	54.93	61.01	Chr 6
Cs2RMYB41	245	28.13	5.75	48.70	62.57	Chr 3	Cs2RMYB91	289	33.19	6.45	53.15	70.17	Chr 6
Cs2RMYB42	224	25.60	7.64	65.43	74.87	Chr 3	Cs2RMYB92	248	27.74	9.11	46.24	76.73	Chr 7
Cs2RMYB43	275	31.61	8.71	39.67	79.75	Chr 3	Cs2RMYB93	500	54.62	5.89	55.46	57.82	Chr 7
Cs2RMYB44	316	36.22	5.63	58.87	56.52	Chr 3	Cs2RMYB94	254	29.45	5.36	74.13	75.63	Chr 7
Cs2RMYB45	312	34.71	6.99	55.70	62.79	Chr 3	Cs2RMYB95	271	31.90	5.56	53.17	62.66	Chr 7
Cs2RMYB46	248	29.70	8.46	52.73	69.60	Chr 3	Cs2RMYB96	254	29.40	5.02	43.86	79.49	Chr 7
Cs2RMYB47	348	39.13	8.86	46.82	64.77	Chr 3	Cs2RMYB97	280	32.36	5.20	59.21	68.86	Chr 7
Cs2RMYB48	294	32.66	6.17	57.40	64.42	Chr 3	Cs2RMYB98	285	32.82	5.32	58.47	64.70	Chr 7
Cs2RMYB49	233	26.13	9.33	51.33	65.41	Chr 3	Cs2RMYB99	248	27.78	6.24	44.80	65.28	Scaffold 72
Cs2RMYB50	313	35.13	5.95	54.63	65.50	Chr 3
说明：Cs2RMYB48基因定位于叶绿体，其他基因定位于细胞核。

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MYB蛋白质家族成员数量庞大，功能多样，存在于绝大多数真核生物中。大多数MYB蛋白作为转录因子发挥作用，MYB结合域有结合DNA的能力^[1−2]，在植物生长发育、次生代谢及抗逆胁迫等方面具有重要作用^[3]。R2R3-MYB作为家族中成员最多的一类，对植物生长发育意义重大^[4−7]。

MYB基因家族根据MYB结构域的数量和类型分为4类：1R-MYB (或MYB相关)、2R-MYB (R2R3-MYB)、3R-MYB (R1R2R3-MYB)和4R-MYB^[8]。2R-MYB类是植物特有的，并且是最大的亚家族，已在许多植物中进行了全基因组注释。R2R3-MYB家族成员数量各不相同，拟南芥Arabidopsis thaliana^[9]有126个，水稻Oryza sativa^[10]有102个，葡萄Vitis vinifera^[11]有108个，甜橙Citrus sinensis^[12]有100个，苹果Malus domestica^[13]有222个，毛果杨Populus trichocarpa^[14]有192个，玉米Zea mays^[15]有200多个。LI等^[16]在黄瓜Cucumis sativus中仅鉴定出55个R2R3-MYB基因，而黄瓜基因组V2版本中鉴定出69个R2R3-MYB基因^[17]。通过最新版黄瓜基因组数据库可知：黄瓜基因组V3版本基因组数量为24 317个，较V2版本(23 248个)增多。鉴于此，本研究对黄瓜基因组数据库V3版本中的R2R3-MYB亚家族进行鉴定，分析黄瓜CsMYB基因家族成员，为研究黄瓜CsMYB家族功能提供参考。

1. 材料与方法

1.1. 数据来源

全基因组序列来源于黄瓜基因组数据库( http://www.cucurbitgenomics.org/organism/20 )。序列中的MYB结合域(PF00249)使用PFam数据库( http://pfam.xfam.org/ )的隐马尔可夫模型(HMM)配置文件进行识别和确认，该配置文件用作对先前注释的黄瓜MYB序列的查询，通过HMMER SEARCH进一步识别并使用默认参数手动筛选(目标序列的期望值E≤1.2×10⁻⁸)^[17]。应用HMMER SEARCH建立黄瓜MYB (CsMYB)基因家族特异性模型^[18]，使用黄瓜MYB特异性HMM选择E低于0.001的所有黄瓜MYB蛋白。CsMYB家族的候选基因根据黄瓜特异性MYB HMM确定。以上最初获得的所有候选CsMYB基因均通过保守域数据库(conserved domain database，CDD)^[19]和简单模块化架构研究工具(simplemodular architecture research tool，SMART)使用默认参数E≤0.010^[20]。根据MYB序列内的特征性保守结构域，分离黄瓜R2R3-MYB基因。

1.2. 黄瓜R2R3-MYB基因家族系统进化分析

通过ClustalW对模式植物拟南芥、木本植物杨梅Morella rubra^[21]和草本植物黄瓜^[1]的R2R3-MYB序列进行比对，采用MEGA-11软件的邻接法(neighbor-joining，NJ)，设置自展法系数(bootstrap)为1 000次，其余参数按系统默认构建进化树^[22]。

1.3. 黄瓜R2R3-MYB家族成员的基本性质及定位分析

通过筛选结果得到的黄瓜R2R3-MYB基因的序列信息，利用TBtools将其定位于染色体上。采用ExPASy-ProtParam ( https://www.expasy.org/resources/protparam )在线预测黄瓜R2R3-MYB蛋白的氨基酸数量、分子量、理论等电点、不稳定指数及脂肪系数；使用Plant-mPLoc 2.0 ( http://www.csbio.sjtu.edu.cn/bioinf/plant-multi/ )预测亚细胞定位。

1.4. 黄瓜R2R3-MYB家族成员的染色体定位及共线性分析

利用TBtools中的Gene Location Visualize功能绘制黄瓜R2R3-MYB家族成员的染色体定位图，并通过MCscanX将黄瓜R2R3-MYB亚家族成员基因与拟南芥同源基因进行共线性分析。

1.5. 黄瓜R2R3-MYB亚家族成员的基因结构及基序分析

利用TBtools对黄瓜R2R3-MYB亚家族成员的基因结构进行可视化分析，并对其蛋白的保守基序进行分析，限值为15，绘制结果图。

1.6. 黄瓜R2R3-MYB亚家族上游的顺式元件预测

利用TBtools提取黄瓜R2R3-MYB亚家族成员上游1 500 bp的序列，通过PlantCARE 数据库( http://bioinformatics.psb.ugent.be/webtools/plantcare/html/ )获得启动子顺式作用元件，利用Excel筛选结果，再利用TBtools对其最终结果进行可视化。

1.7. 黄瓜R2R3-MYB亚家族蛋白成员的互作预测

通过网站STRING ( https://www.string-db.org/ )对黄瓜R2R3-MYB蛋白成员之间进行互作预测分析，研究黄瓜R2R3-MYB蛋白成员之间的作用关系。

基因命名	氨基酸数量/个	分子量/kDa	等电点	不稳定指数	脂肪指数	染色体位置	基因命名	氨基酸数量/个	分子量/ kDa	等电点	不稳定指数	脂肪指数	染色体位置
Cs2RMYB1	360	40.91	6.44	52.41	57.17	Chr 1	Cs2RMYB51	268	30.01	8.59	54.65	64.40	Chr 3
Cs2RMYB2	471	54.88	5.91	42.84	66.43	Chr 1	Cs2RMYB52	217	25.13	7.21	55.75	65.21	Chr 3
Cs2RMYB3	367	41.94	5.83	59.22	75.50	Chr 1	Cs2RMYB53	195	22.67	8.37	72.59	73.54	Chr 3
Cs2RMYB4	331	37.60	9.02	65.15	61.90	Chr 1	Cs2RMYB54	355	39.21	6.25	54.46	82.96	Chr 3
Cs2RMYB5	277	31.19	5.90	78.88	66.21	Chr 1	Cs2RMYB55	305	34.19	6.19	45.79	74.52	Chr 3
Cs2RMYB6	232	26.59	8.83	57.26	66.51	Chr 1	Cs2RMYB56	253	28.52	9.10	49.09	65.53	Chr 3
Cs2RMYB7	326	36.76	6.42	53.91	67.94	Chr 1	Cs2RMYB57	313	35.05	4.97	68.24	75.97	Chr 4
Cs2RMYB8	288	32.50	6.31	71.30	64.03	Chr 1	Cs2RMYB58	314	36.06	6.10	62.98	58.06	Chr 4
Cs2RMYB9	377	42.09	6.46	50.23	66.71	Chr 1	Cs2RMYB59	322	35.68	6.14	54.46	67.55	Chr 4
Cs2RMYB10	337	37.92	5.74	45.24	71.19	Chr 1	Cs2RMYB60	377	40.50	5.41	39.90	73.24	Chr 4
Cs2RMYB11	299	33.99	9.17	58.17	61.64	Chr 1	Cs2RMYB61	353	39.81	6.22	60.28	59.92	Chr 4
Cs2RMYB12	372	42.33	6.12	54.32	67.63	Chr 1	Cs2RMYB62	229	25.19	9.29	58.90	61.70	Chr 4
Cs2RMYB13	277	32.11	5.83	63.46	79.96	Chr 1	Cs2RMYB63	263	29.14	8.34	61.14	67.15	Chr 4
Cs2RMYB14	337	38.24	8.66	52.38	59.08	Chr 1	Cs2RMYB64	280	31.51	8.92	59.53	72.11	Chr 4
Cs2RMYB15	370	41.15	6.13	51.97	61.95	Chr 1	Cs2RMYB65	260	28.84	5.00	38.86	76.54	Chr 5
Cs2RMYB16	364	41.75	9.54	55.58	69.81	Chr 1	Cs2RMYB66	323	36.41	6.00	53.24	72.45	Chr 5
Cs2RMYB17	327	37.06	7.68	62.31	69.48	Chr 2	Cs2RMYB67	258	29.46	5.84	45.28	67.67	Chr 5
Cs2RMYB18	295	32.99	9.07	45.41	70.10	Chr 2	Cs2RMYB68	236	26.98	6.71	53.48	74.83	Chr 5
Cs2RMYB19	222	25.74	6.00	53.86	72.43	Chr 2	Cs2RMYB69	284	31.23	6.41	56.18	72.46	Chr 5
Cs2RMYB20	264	29.98	8.97	58.24	63.14	Chr 2	Cs2RMYB70	300	33.77	5.29	55.23	71.50	Chr 5
Cs2RMYB21	265	31.42	9.64	54.52	67.02	Chr 2	Cs2RMYB71	337	38.25	7.69	55.10	66.59	Chr 5
Cs2RMYB22	286	32.59	5.60	58.72	59.69	Chr 2	Cs2RMYB72	210	24.43	5.19	51.25	60.38	Chr 5
Cs2RMYB23	228	26.87	10.27	58.08	65.44	Chr 2	Cs2RMYB73	464	52.29	6.82	66.09	66.85	Chr 5
Cs2RMYB24	256	29.15	8.24	48.25	79.22	Chr 2	Cs2RMYB74	369	41.40	6.61	50.68	56.34	Chr 5
Cs2RMYB25	210	23.54	10.31	65.32	59.48	Chr 2	Cs2RMYB75	307	34.25	7.51	48.64	64.59	Chr 5
Cs2RMYB26	230	26.32	8.83	57.64	63.65	Chr 2	Cs2RMYB76	398	44.52	6.49	53.56	62.29	Chr 5
Cs2RMYB27	204	23.04	8.44	43.78	67.94	Chr 2	Cs2RMYB77	202	23.93	8.25	43.61	58.37	Chr 5
Cs2RMYB28	338	38.46	8.56	58.00	68.99	Chr 2	Cs2RMYB78	294	33.13	8.72	52.07	70.41	Chr 5
Cs2RMYB29	290	31.80	9.23	59.33	65.93	Chr 2	Cs2RMYB79	286	32.77	6.40	64.03	65.17	Chr 6
Cs2RMYB30	297	33.70	9.97	55.65	69.97	Chr 2	Cs2RMYB80	552	61.13	5.50	52.51	61.54	Chr 6
Cs2RMYB31	301	32.30	8.19	55.90	64.15	Chr 2	Cs2RMYB81	301	34.40	5.56	70.97	65.08	Chr 6
Cs2RMYB32	308	34.86	5.93	48.47	84.90	Chr 2	Cs2RMYB82	269	31.33	6.45	45.95	63.42	Chr 6
Cs2RMYB33	519	57.03	7.46	59.70	57.53	Chr 3	Cs2RMYB83	334	38.24	4.96	46.95	59.85	Chr 6
Cs2RMYB34	305	34.64	5.70	57.58	70.72	Chr 3	Cs2RMYB84	286	32.92	5.80	56.50	54.58	Chr 6
Cs2RMYB35	248	29.14	9.10	56.61	66.49	Chr 3	Cs2RMYB85	291	33.53	6.63	61.70	46.94	Chr 6
Cs2RMYB36	259	29.98	6.50	48.74	59.54	Chr 3	Cs2RMYB86	277	32.26	9.35	51.45	59.49	Chr 6
Cs2RMYB37	296	33.70	5.35	56.27	67.20	Chr 3	Cs2RMYB87	301	32.45	9.32	50.91	64.82	Chr 6
Cs2RMYB38	219	25.25	6.32	59.79	70.32	Chr 3	Cs2RMYB88	319	35.85	6.53	48.51	65.49	Chr 6
Cs2RMYB39	354	40.50	9.20	58.22	77.40	Chr 3	Cs2RMYB89	344	38.44	6.12	57.72	80.00	Chr 6
Cs2RMYB40	267	30.10	5.59	55.70	69.33	Chr 3	Cs2RMYB90	387	44.36	5.81	54.93	61.01	Chr 6
Cs2RMYB41	245	28.13	5.75	48.70	62.57	Chr 3	Cs2RMYB91	289	33.19	6.45	53.15	70.17	Chr 6
Cs2RMYB42	224	25.60	7.64	65.43	74.87	Chr 3	Cs2RMYB92	248	27.74	9.11	46.24	76.73	Chr 7
Cs2RMYB43	275	31.61	8.71	39.67	79.75	Chr 3	Cs2RMYB93	500	54.62	5.89	55.46	57.82	Chr 7
Cs2RMYB44	316	36.22	5.63	58.87	56.52	Chr 3	Cs2RMYB94	254	29.45	5.36	74.13	75.63	Chr 7
Cs2RMYB45	312	34.71	6.99	55.70	62.79	Chr 3	Cs2RMYB95	271	31.90	5.56	53.17	62.66	Chr 7
Cs2RMYB46	248	29.70	8.46	52.73	69.60	Chr 3	Cs2RMYB96	254	29.40	5.02	43.86	79.49	Chr 7
Cs2RMYB47	348	39.13	8.86	46.82	64.77	Chr 3	Cs2RMYB97	280	32.36	5.20	59.21	68.86	Chr 7
Cs2RMYB48	294	32.66	6.17	57.40	64.42	Chr 3	Cs2RMYB98	285	32.82	5.32	58.47	64.70	Chr 7
Cs2RMYB49	233	26.13	9.33	51.33	65.41	Chr 3	Cs2RMYB99	248	27.78	6.24	44.80	65.28	Scaffold 72
Cs2RMYB50	313	35.13	5.95	54.63	65.50	Chr 3
说明：Cs2RMYB48基因定位于叶绿体，其他基因定位于细胞核。

3. 讨论

本研究共鉴定出99个黄瓜R2R3-MYB亚家族成员，约占黄瓜总MYB数的60%，数量多于西瓜(89个)^[4]，少于拟南芥(126个)^[9]、水稻(102个)^[10]和玉米(200个)^[15]。黄瓜的基因组大小为224.8~251.1 Mb^[24]，而拟南芥、水稻、玉米和西瓜的基因组大小分别为125.0、430.0、2 300.0和365.1 Mb^[25−28]，R2R3-MYB亚家族成员数量与植物的基因组大小并没有直接的相关性。

作为MYB家族最大的亚家族，R2R3-MYB家族成员具有典型的模式结构，在植物发育、新陈代谢、信号转导及响应生物和非生物胁迫中起着非常重要的作用^[29]。为了研究黄瓜基因组进化过程中功能保守的R2R3-MYB基因功能，构建其系统进化树并进行分析，结果表明：黄瓜Cs2RMYB30个亚组中大多数包含来自拟南芥和杨梅R2R3-MYB成员，然而，C28亚组仅拥有黄瓜和拟南芥R2R3-MYB成员，表明它们可能来自共同的祖先。同时，外显子和内含子的结构分析有利于研究基因家族内部的进化关系，通过分组可以初步推测其功能，聚类较近的基因存在功能相似性，如在C30亚组中，拟南芥AtMYB42和AtMYB85被证明参与木质素生物合成代谢调控^[30]，黄瓜Cs2RMYB72和Cs2RMYB73与其表现出较近的亲缘关系，可能与木质素生物合成代谢有关；在C15亚组中，AtMYB75、AtMYB90、AtMYB113和AtMYB114过量表达会促进植物花青素的积累^[31]，与黄瓜Cs2RMYB19同属于C15亚组；在C22亚组中，AtMYB93是其分支上唯一一个影响拟南芥侧根发育的负调控因子^[32]，而黄瓜Cs2RMYB89与AtMYB93进化关系最近；宫思宇等^[33]研究表明：AtMYB94通过调节拟南芥表皮的蜡质含量提高植株耐旱性，而C22亚组中的Cs2RMYB48是其同源基因，可能具有类似功能，同一分支亚家族转录因子可能存在功能相似性^[23,34]。

基序分析结果发现：所有的CsR2R3-MYB基因都有共同的保守基序，但也有独特的基序，这为CsR2R3-MYB亚家族成员的分类提供参考，且可能与CsR2R3-MYB基因的功能分化相关。此外，启动子序列上的顺式作用元件是转录因子识别并发挥转录调控作用的重要识别位点^[35]。本研究发现：黄瓜CsR2R3-MYB亚家族成员启动子上的顺式作用元件种类繁多，绝大多数CsR2R3-MYB基因家族成员基因启动子区都含有ERE元件，暗示其可能参与黄瓜性别分化等生长发育过程；富含ABRE和CGTCA等激素响应顺式作用元件，表明CsR2R3-MYB基因家族在黄瓜应答逆境胁迫中发挥重要作用。由于CsR2R3-MYB基因调控元件的不同功能，启动子区域中这些高度多样化的顺式调控元件也可能反映了转录水平上的功能分歧^[36]。本研究初步预测了MYB家族CsR2R3-MYB基因与植物生长发育及逆境胁迫响应相关，可为后续该亚家族成员基因功能深入研究提供参考。

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