苹果LRR-RLK基因家族鉴定和表达分析

doi:10.3864/j.issn.0578-1752.2021.14.015

摘要/Abstract

摘要：

【目的】从苹果全基因组中鉴定LRR-RLK家族蛋白成员,并进行生物信息学和表达模式分析,为研究苹果LRR-RLK的潜在功能提供理论基础。【方法】利用BLASTp基于GDR数据库鉴定苹果LRR-RLK家族成员,通过ExPASy Proteomics Server、Cell-PLoc、CD-Search Tool、MEGAX、MG2C等软件分析LRR-RLK蛋白序列基本信息、亚细胞定位情况、结构域组成、系统进化关系以及染色体定位情况。利用实时荧光定量PCR技术检测苹果12个LRR-RLK的组织表达和诱导表达特性。【结果】苹果LRR-RLK基因家族包含378个成员,这些LRR-RLK蛋白包括318—1 827个不等的氨基酸残基,等电点分布在5.16—9.75。亚细胞定位结果显示LRR-RLK蛋白均定位在细胞膜。系统进化分析可将其分为15类,各亚家族基因数量分布在1—111。染色体定位结果显示,LRR-RLK在苹果17条染色体上均有分布,其中第7条染色体数量最多,为40个。LRR-RLK家族基因具有2个特定的保守结构域,分别是LRR结构和蛋白激酶结构。蛋白二级结构以无规则卷曲为主,其次是α-螺旋,β-转角所占比例最小。通过定量检测发现筛选的12个家族成员在各组织中均有表达（除MD00G1105400外）,且多数基因在茎中表达水平相对较高。低温条件下,7个基因上调表达,其中MD09G1153800上调最明显,最高为对照的6.8倍,而MD06G1170200和MD05G1061600均下调表达;在干旱条件下,8个基因上调表达,其中MD00G1105400上调最明显,最高为对照的9.6倍;在盐胁迫条件下,MD04G1150400、MD13G1108000和MD02G1071800始终处于上调表达状态,其中MD02G1071800上调最明显,最高为对照的14.9倍。苹果新梢接种轮纹病菌后,12个LRR-RLK家族基因表达基本上呈先上升后下降的趋势。并且在‘望山红’中,1 d时表达水平较高,而在‘鸡冠’中,3 d时表达水平较高。MD09G1153800和 MD05G1065800在‘鸡冠’响应轮纹病菌侵染过程中显著上调表达,而在‘望山红’中无响应,可作为进一步开展抗病研究和功能分析的候选基因。【结论】苹果LRR-RLK基因家族包含378个成员,进化上可分为15组,在17条染色体上均有分布,多数基因具有在茎中高表达的组织表达特征,多数基因受逆境和轮纹病菌调控。

关键词: 苹果, LRR-RLK, 基因家族, 鉴定, 表达分析

Abstract:

【Objective】 The study was carried out to explore the whole genome characteristics and expression patterns ofLRR-RLKs in apple, to reveal the expression specificity of family members in different tissues and their responses to biological and abiotic stress, and further understand its biological function in apple. 【Method】 The members of LRR-RLK gene family in the whole genome of apple were identified based on the local BLAST database and Pfam database. The LRR-RLK amino acid sequence prediction, subcellular localization prediction, domain analysis, phylogenetic tree and chromosome localization were completed by software of ExPASy Proteomics Server, Cell-PLoc, CD-Search Tool, MEGAX and MG2C. In addition, the expression pattern of 12 LRR-RLK genes in different tissues and stress were analyzed by real-time fluorescent quantitative PCR (qRT-PCR).【Result】 A total of 378 LRR-RLKgenes were identified from apple genome. TheseLRR-RLKgenes encoded proteins containing 318-1 827 amino acid, and the theoretical isoelectric point ranged from 6.14 to 9.01. The prediction subcellular localization of apple LRR-RLK proteins was all distributed in the cell membrane. The gene family could be divided into 15 subgroups, containing 1-111 genes. The 378 genes in this family were distributed on all 17 chromosomes of the apple, and the chromosome 7 contained 40 genes. The LRR-RLK gene family had two conserved domains, namely the leucine-rich repeat structure and the protein kinase domain. Irregular curl and α-helix was the main secondary structure in the LRR-RLK gene family, and the rotation of β-turn was very small. It was found that the 12 selected family members were expressed in all tissues (except MD00G1105400), and most genes were expressed at relatively high levels in stem. Seven genes were up-regulated under low temperature conditions, and the expression of MD09G1153800 was the most obvious. The expression of MD09G1153800 was raised to 6.8 times of that under the control. While MD06G1170200 and MD05G1061600 were both down-regulated. Eight genes were up-regulated under drought conditions, and MD00G1105400 was the most obvious one. The expression of MD00G1105400 was raised to 9.6 times of that under the control; under salt conditions, MD04G1150400, MD13G1108000 and MD02G1071800 were always up-regulated. Among them, MD02G1071800 had the highest expression after 24 hours of salt stress treatment, which was 14.9 times of that under the control. After inoculating Botryosphaeria dothidea, the expression of 12 LRR-RLKgenes increased first and then decreased. After inoculating, the expression level of Wangshanhong was higher on the first day, however the expression level of Jiguan was higher on the third day. The expression of MD09G1153800 and MD05G1065800 were up-regulated significantly in Jiguan, in relative to have no change in Wangshanhong, suggesting that these twoLRR-RLKscould serve as candidate genes for further functional characterization. 【Conclusion】 A total of 378 LRR-RLK members were identified from apple whole genome sequences, which could be divided into 15 groups and distributed on 17 chromosomes, and the most of LRR-RLK genes were responsive to stress stimulus and Botryosphaeria dothidea.

Key words: apple, LRR-RLK, gene family, identification, expression analysis

黄金凤,吕天星,王寻,王颖达,王冬梅,闫忠业,刘志. 苹果LRR-RLK基因家族鉴定和表达分析[J]. 中国农业科学, 2021, 54(14): 3097-3112.

HUANG JinFeng,LÜ TianXing,WANG Xu,WANG YingDa,WANG DongMei,YAN ZhongYe,LIU Zhi. Genome-Wide Identification and Expression Pattern Analysis of LRR-RLK Gene Family in Apple[J]. Scientia Agricultura Sinica, 2021, 54(14): 3097-3112.

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登录号 Gene number	上游引物 Forward primer (5′-3′)	下游引物 Reverse primer (5′-3′)
MdActin	TGACCGAATGAGCAAGGAAATTACT	TACTCAGCTTTGGCAATCCACATC
MD09G1153800	TCTTCTTGAGCCATCTCC	CGTCGGTCAGTATGTTTT
MD04G1150400	ACCGTTCATTGCTCCTTG	GCGAGCCCTATTTCCATC
MD03G1138500	GAAGCCAACAGACGAGAT	GGATAATAAGCAAACCCT
MD06G1170200	CCAGTGGACCCATCATTC	GCTTGGAGCATTTCTTGTAT
MD03G1036900	GGAAAGGAGGAGCAGATT	CAGGACCCAACAGAACAT
MD05G1061600	AGATGTCTACAGCTATGGGATA	TGGTTAGTTCGCCTTTGA
MD13G1108000	TTCCCATAGACAGCAAGA	GTGGCATCCAAGTAAAGC
MD05G1261100	GTCGAAACCAAGCTATTT	TAGTTGAGGCGAACATTA
MD00G1105400	GACTGATAGGTTGGCACTG	GACCCTCTGACTATGTCG
MD02G1071800	GAATCCATCATAGAAACT	ATTAGCCATGTACTCGTA
MD05G1065800	TTCAATACCTCCGCAACT	AAATCCCACTCAGCAAAT
MD15G1288500	GCCTTGAGGATGGCAGAT	GTACCCTAACTTGAACAACGAC

亚家族 Subclade	基因数量 No.of genes	氨基酸数目 Number of amino acids	范围Range
亚家族 Subclade	基因数量 No.of genes	氨基酸数目 Number of amino acids	等电点 Isoelectric point	分子量 Molecular weight (Kd)	LRR数量 No. of LRRs
I-1	10	697-1022	5.34-8.39	78.68-111.91	1-11
II	39	595-1054	5.16-8.49	66.69-116.19	1-6
III	50	400-1063	5.61-9.66	43.51-115.39	2-9
IV	5	681-683	6.16-7.76	73.96-74.16	3-5
V	12	551-801	5.57-9.39	60.88-86.53	2-6
VI-1	10	700-794	7.61-9.46	77.79-87.25	2-8
VI-2	5	655-716	5.50-5.92	71.84-78.63	1-3
VII-1	7	886-1010	5.28-6.26	96.77-110.12	5-12
VII-2	2	861-862	5.8-6.15	94.58-94.84	7
VII-3	3	1141-1146	5.61-7.56	106.07-123.50	11-16
VIII	9	794-964	5.84-7.24	87.52-105.10	3-7
IX	8	851-977	5.62-8.63	93.01-103.52	5-9
Xa	4	601-627	6.14-8.09	66.09-124.65	1-4
Xb-1	12	1021-1301	5.42-6.74	122.83-141.35	9-19
Xb-2	2	1071-1090	5.76-6.80	117.55-119.70	6
XI	74	614-1258	5.28-9.09	67.92-138.67	4-20
XII	111	318-1827	5.22-9.75	34.95-199.33	2-19
XIII-a	5	532-606	5.44-6.15	58.27-67.22	2-3
XIII-b	1	989	6.05	108.91	8
XIV	4	899-911	6.50-8.10	97.60-98.43	5-9
XV	5	441-1145	6.15-8.37	47.94-125.05	6-10

登录号 Gene number	α-螺旋 α-helix (%)	β-转角 β-turn (%)	无规则卷曲 Random coil (%)	延长链 Extended strand (%)
MD04G1019100	34.88	5.98	43.74	15.39
MD04G1079600	36.80	4.25	44.13	14.81
MD04G1150400	36.25	4.86	43.83	15.06
MD04G1174900	37.82	2.18	45.39	14.61
MD05G1065800	37.14	3.85	46.92	12.09
MD05G1153300	32.27	3.67	45.21	18.85
MD05G1261100	33.66	2.41	52.14	11.79
MD05G1299200	41.63	5.44	41.63	11.30
MD06G1198600	34.16	2.39	49.86	13.59
MD07G1259500	39.01	3.34	45.90	11.75
MD08G1017800	36.67	2.28	47.46	13.60
MD09G1014600	33.97	3.30	46.26	16.48
MD09G1153800	40.07	5.08	39.35	15.50
MD09G1168400	38.16	7.75	38.59	15.49
MD11G1047400	37.23	1.91	48.42	12.44
MD12G1192800	28.75	4.62	52.26	14.38
MD13G1108000	26.88	4.21	49.43	19.48
MD15G1152400	33.84	2.79	51.05	12.33
MD15G1288500	29.64	5.73	50.00	14.63
MD16G1288500	39.36	4.33	42.37	13.94
MD17G1060000	33.74	1.80	51.47	12.99