植物查尔酮合成酶超基因家族的分子进化

doi:10.3724/SP.J.1259.2015.00055

植物学报 ›› 2015, Vol. 50 ›› Issue (1): 55-71.DOI: 10.3724/SP.J.1259.2015.00055

植物查尔酮合成酶超基因家族的分子进化

包颖^1,^2,^*(), 郭昌锋¹, 陈少华¹, 刘梅¹

¹曲阜师范大学生命科学学院, 曲阜 273165
²中国科学院植物研究所系统与进化植物学国家重点实验室, 北京 100093

收稿日期:2013-11-04 接受日期:2014-02-23 出版日期:2015-01-01 发布日期:2015-04-09
通讯作者: 包颖
作者简介:
? 共同第一作者
基金资助:
山东自然科学基金(No.ZR2012CM024)和中国科学院系统与进化植物学国家重点实验室开放课题(No.LSEB201101)

Molecular Evolution of Chalcone Synthase Gene Superfamily in Plants

Ying Bao^{1, 2, *}, Changfeng Guo¹, Shaohua Chen¹, Mei Liu¹

¹School of Life of Sciences, Qufu Normal University, Qufu 273165, China
²State Key Laboratory of Systematic and Evolutionary Botany, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China

Received:2013-11-04 Accepted:2014-02-23 Online:2015-01-01 Published:2015-04-09
Contact: Bao Ying
About author:
? These authors contributed equally to this paper

摘要/Abstract

摘要： 查尔酮合成酶(CHS)超基因家族又称为植物类型III聚酮合酶超基因家族, 其编码酶通过催化和合成一系列结构多样及生理活性各异的次生代谢物, 在植物生长发育和适应环境的过程中扮演着重要角色。为全面了解CHS超基因家族在植物中的进化规律, 重建其进化历史, 该研究利用14种具有全基因组数据的代表植物, 通过生物信息学手段, 深入挖掘和分析了不同植物类群基因组中查尔酮合成酶超基因家族的成员构成, 推测了其可能的扩增机制和功能分歧, 并探讨了该超基因家族在植物中的总体进化趋势。结果共识别144条具有表达信息的同源序列, 它们全部来自9种陆生植物的基因组, 藻类植物基因组中没有发现相关序列。系统发育和进化分析表明, CHS超基因家族的起源古老, 它们可能为适应复杂的生态环境而出现在早期的陆生植物中, 之后在长期的进化过程中不断发生谱系的特异扩张和拷贝丢失, 最后通过功能分歧的形式在不同植物类群中被分别固定。此外, 进化检验也显示, 尽管CHS超基因家族内部发生了多样的遗传改变, 但整个超基因家族仍处于强烈的纯化选择之下, 并且个体基因中也无任何单氨基酸位点受到正向选择的影响。

Abstract: The chalcone synthase (CHS) gene superfamily, also known as plant-specific type III polyketide synthase gene superfamily, encodes many important enzymes that can catalyze and synthesize various plant secondary metabolites with diverse structures and different biological activities. These metabolites play key roles in plant growth, reproduction, and plant adaptation to the environment. To fully understand the basic evolutionary rules of the CHS gene superfamily in plants and reconstruct its evolutionary history, we performed bioinformatics analysis of CHS genes in 14 plant species with whole-genome data. We performed a BLAST search to identify the gene members of the CHS superfamily. The possible expansion mechanisms and functional divergences of the members were characterized, and the evolution- ary trend of the superfamily was explored. We identified 144 genes with expression information; all are expressed in 9 land plants but not 5 algae. Phylogenetic analysis revealed that the CHS gene superfamily had an ancient origin and complicated evolutionary history. It probably appeared in early terrestrial plants to adapt to the complex environment, then experienced lineage-specific expansions or gene loss during evolution, and finally was fixed in different plant taxa through functional divergences. In addition, evolutionary testing showed that despite diverse genetic differentiation within the CHS superfamily, the whole superfamily was still filtered by strong purifying selection and no single amino acid site within an individual gene was affected by positive selection.

包颖, 郭昌锋, 陈少华, 刘梅. 植物查尔酮合成酶超基因家族的分子进化. 植物学报, 2015, 50(1): 55-71.

Ying Bao, Changfeng Guo, Shaohua Chen, Mei Liu. Molecular Evolution of Chalcone Synthase Gene Superfamily in Plants. Chinese Bulletin of Botany, 2015, 50(1): 55-71.

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链接本文: https://www.chinbullbotany.com/CN/10.3724/SP.J.1259.2015.00055

https://www.chinbullbotany.com/CN/Y2015/V50/I1/55

图/表 4

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Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
Arabidopsis thaliana	1	AT1G02050	-	1
	2	AT4G00040	+	4
	3	AT4G34850	+	4
	4	AT5G13930	+	5
Medicago truncatula	1	MT1G097900	+	1	Tandem
	2	MT1G097910	+	1	Tandem
	3	MT1G098140	+	1	Tandem
	4	MT1G098150	+	1	Tandem
	5	MT2G058470	-	2
	6	MT3G083910	-	3	Tandem and block
	7	MT3G083920	-	3	Tandem and block
	8	MT3G086260	+	3
	9	MT4G078730	+	4
	10	MT5G007720	+	5	Tandem
	11	MT5G007730	+	5	Tandem
	12	MT5G007740	+	5	Tandem
	13	MT5G007760	+	5	Tandem
	14	MT5G007770	+	5	Tandem
	15	MT7G016700	+	7	Tandem
	16	MT7G016720	-	7	Tandem
	17	MT7G016780	+	7	Tandem
	18	MT7G016800	+	7	Tandem
	19	MT7G016820	+	7	Tandem
	20	MT7G084300	-	7
	21	MT8G085200	+	8	Block
Populus trichocarpa	1	PT00G02200	-	Scaffold_955
	2	PT01G06410	+	Scaffold_1	Block
	3	PT01G14120	+	Scaffold_1	Tandem and block
	4	PT01G14130	+	Scaffold_1	Tandem and block
	5	PT02G14050	-	Scaffold_2	Block
	6	PT03G16580	+	Scaffold_3	Tandem and block
	7	PT03G16590	+	Scaffold_3	Tandem and block
	8	PT03G16600	+	Scaffold_3	Tandem and block
	9	PT04G16510	+	Scaffold_4	Block
	10	PT05G15150	-	Scaffold_5	Tandem
	11	PT09G12950	+	Scaffold_9	Block
	12	PT12G12680	+	Scaffold_12	Block
	13	PT14G05350	-	Scaffold_14	Block
	14	PT14G14010	-	Scaffold_14
Vitis vinifera	1	VV03G05390	+	3
	2	VV05G00090	+	5
	3	VV10G06850	+	10	Tandem
	4	VV10G06860	+	10	Tandem
	5	VV14G13530	+	14
	6	VV15G00770	-	15
	7	VV16G00180	-	16	Tandem
	8	VV16G00200	-	16	Tandem
表1 (续) Table 1 (continued)
Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
	9	VV16G00220	-	16	Tandem
	10	VV16G00240	-	16	Tandem
	11	VV16G00260	-	16	Tandem
	12	VV16G00280	+	16	Tandem
	13	VV16G00290	-	16	Tandem
	14	VV16G00310	-	16	Tandem
	15	VV16G00320	-	16	Tandem
	16	VV16G00330	-	16	Tandem
	17	VV16G00340	-	16	Tandem
	18	VV16G00350	-	16	Tandem
	19	VV16G00360	-	16	Tandem
	20	VV16G00370	-	16	Tandem
	21	VV16G00380	+	16	Tandem
	22	VV16G00390	+	16	Tandem
Oryza sativa	1	OS01G41834	-	1
	2	OS04G01354	-	4
	3	OS04G23940	-	4
	4	OS05G12180	-	5	Tandem
	5	OS05G12190	-	5	Tandem
	6	OS05G12210	-	5	Tandem
	7	OS05G12240	-	5	Tandem
	8	OS05G41645	+	5
	9	OS07G11440	-	7
	10	OS07G17010	+	7
	11	OS07G22850	-	7
	12	OS07G31750	-	7	Tandem
	13	OS07G31770	-	7	Tandem
	14	OS07G34140	-	7	Tandem
	15	OS07G34190	-	7	Tandem
	16	OS07G34260	-	7	Tandem
	17	OS10G07040	+	10
	18	OS10G07616	+	10
	19	OS10G08620	+	10	Tandem
	20	OS10G08670	+	10	Tandem
	21	OS10G08710	+	10	Tandem
	22	OS10G09860	-	10
	23	OS10G34360	+	10
	24	OS11G32540	-	11	Tandem
	25	OS11G32580	-	11	Tandem
	26	OS11G32610	+	11	Tandem
	27	OS11G32620	-	11	Tandem
	28	OS11G32650	-	11	Tandem
	29	OS11G35930	+	11
	30	OS12G07690	-	12
Zea mays	1	ZM01G41780	-	1	Block
	2	ZM02G42820	-	2	Tandem and block
	3	ZM02G42850	-	2	Tandem and block
	4	ZM02G45550	+	2
表1 (续) Table 1 (continued)
Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
	5	ZM03G09860	+	3	Tandem
	6	ZM03G09890	-	3	Tandem
	7	ZM03G09930	-	3	Tandem
	8	ZM04G30630	+	4	Tandem and block
	9	ZM04G30650	+	4	Tandem and block
	10	ZM04G32440	-	4
	11	ZM05G09820	+	5	Block
	12	ZM05G24850	+	5
	13	ZM07G22450	-	7	Block
Physcomitrella patens	1	PP00001G00030	-	Scaffold_1
	2	PP00020G01360	-	Scaffold_20
	3	PP00022G00030	+	Scaffold_22
	4	PP00025G01920	+	Scaffold_25	Tandem
	5	PP00025G01930	-	Scaffold_25	Tandem
	6	PP00034G01040	+	Scaffold_34
	7	PP00038G00030	-	Scaffold_38
	8	PP00039G01610	-	Scaffold_39
	9	PP00061G00280	-	Scaffold_61
	10	PP00076G01020	+	Scaffold_76
	11	PP00228G00140	-	Scaffold_228	Tandem
	12	PP00292G00010	-	Scaffold_292
	13	PP00303G00060	-	Scaffold_303	Tandem
	14	PP00303G00070	+	Scaffold_303	Tandem
	15	PP00304G00340	-	Scaffold_304
	16	PP00365G00100	-	Scaffold_365	Tandem
	17	PP00365G00120	+	Scaffold_365	Tandem
	18	PP00425G00060	-	Scaffold_425	Tandem
	19	PP00426G00290	-	Scaffold_426
	20	PP00463G00060	-	Scaffold_463	Tandem
	21	PP00463G00070	+	Scaffold_463	Tandem
	22	PP00463G00100	-	Scaffold_463	Tandem
	23	PP00500G00030	-	Scaffold_500
Selaginella moellendorffii	1	SM00001G06800	-	Scaffold_1
	2	SM00017G03910	-	Scaffold_17
	3	SM00007G01560	-	Scaffold_7
	4	SM00068G00810	-	Scaffold_68
Ostreococcus lucimarinus	-	-	-	-	-
O. tauri	-	-	-	-	-
Micromonas sp. RCC299	-	-	-	-	-
Volvox carteri	-	-	-	-	-
Chlamydomonas reinhardtii	-	-	-	-	-

Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
Arabidopsis thaliana	1	AT1G02050	-	1
	2	AT4G00040	+	4
	3	AT4G34850	+	4
	4	AT5G13930	+	5
Medicago truncatula	1	MT1G097900	+	1	Tandem
	2	MT1G097910	+	1	Tandem
	3	MT1G098140	+	1	Tandem
	4	MT1G098150	+	1	Tandem
	5	MT2G058470	-	2
	6	MT3G083910	-	3	Tandem and block
	7	MT3G083920	-	3	Tandem and block
	8	MT3G086260	+	3
	9	MT4G078730	+	4
	10	MT5G007720	+	5	Tandem
	11	MT5G007730	+	5	Tandem
	12	MT5G007740	+	5	Tandem
	13	MT5G007760	+	5	Tandem
	14	MT5G007770	+	5	Tandem
	15	MT7G016700	+	7	Tandem
	16	MT7G016720	-	7	Tandem
	17	MT7G016780	+	7	Tandem
	18	MT7G016800	+	7	Tandem
	19	MT7G016820	+	7	Tandem
	20	MT7G084300	-	7
	21	MT8G085200	+	8	Block
Populus trichocarpa	1	PT00G02200	-	Scaffold_955
	2	PT01G06410	+	Scaffold_1	Block
	3	PT01G14120	+	Scaffold_1	Tandem and block
	4	PT01G14130	+	Scaffold_1	Tandem and block
	5	PT02G14050	-	Scaffold_2	Block
	6	PT03G16580	+	Scaffold_3	Tandem and block
	7	PT03G16590	+	Scaffold_3	Tandem and block
	8	PT03G16600	+	Scaffold_3	Tandem and block
	9	PT04G16510	+	Scaffold_4	Block
	10	PT05G15150	-	Scaffold_5	Tandem
	11	PT09G12950	+	Scaffold_9	Block
	12	PT12G12680	+	Scaffold_12	Block
	13	PT14G05350	-	Scaffold_14	Block
	14	PT14G14010	-	Scaffold_14
Vitis vinifera	1	VV03G05390	+	3
	2	VV05G00090	+	5
	3	VV10G06850	+	10	Tandem
	4	VV10G06860	+	10	Tandem
	5	VV14G13530	+	14
	6	VV15G00770	-	15
	7	VV16G00180	-	16	Tandem
	8	VV16G00200	-	16	Tandem
表1 (续) Table 1 (continued)
Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
	9	VV16G00220	-	16	Tandem
	10	VV16G00240	-	16	Tandem
	11	VV16G00260	-	16	Tandem
	12	VV16G00280	+	16	Tandem
	13	VV16G00290	-	16	Tandem
	14	VV16G00310	-	16	Tandem
	15	VV16G00320	-	16	Tandem
	16	VV16G00330	-	16	Tandem
	17	VV16G00340	-	16	Tandem
	18	VV16G00350	-	16	Tandem
	19	VV16G00360	-	16	Tandem
	20	VV16G00370	-	16	Tandem
	21	VV16G00380	+	16	Tandem
	22	VV16G00390	+	16	Tandem
Oryza sativa	1	OS01G41834	-	1
	2	OS04G01354	-	4
	3	OS04G23940	-	4
	4	OS05G12180	-	5	Tandem
	5	OS05G12190	-	5	Tandem
	6	OS05G12210	-	5	Tandem
	7	OS05G12240	-	5	Tandem
	8	OS05G41645	+	5
	9	OS07G11440	-	7
	10	OS07G17010	+	7
	11	OS07G22850	-	7
	12	OS07G31750	-	7	Tandem
	13	OS07G31770	-	7	Tandem
	14	OS07G34140	-	7	Tandem
	15	OS07G34190	-	7	Tandem
	16	OS07G34260	-	7	Tandem
	17	OS10G07040	+	10
	18	OS10G07616	+	10
	19	OS10G08620	+	10	Tandem
	20	OS10G08670	+	10	Tandem
	21	OS10G08710	+	10	Tandem
	22	OS10G09860	-	10
	23	OS10G34360	+	10
	24	OS11G32540	-	11	Tandem
	25	OS11G32580	-	11	Tandem
	26	OS11G32610	+	11	Tandem
	27	OS11G32620	-	11	Tandem
	28	OS11G32650	-	11	Tandem
	29	OS11G35930	+	11
	30	OS12G07690	-	12
Zea mays	1	ZM01G41780	-	1	Block
	2	ZM02G42820	-	2	Tandem and block
	3	ZM02G42850	-	2	Tandem and block
	4	ZM02G45550	+	2
表1 (续) Table 1 (continued)
Species	Locus No.	Gene ID	Strand	Chromosome	Duplication pattern
	5	ZM03G09860	+	3	Tandem
	6	ZM03G09890	-	3	Tandem
	7	ZM03G09930	-	3	Tandem
	8	ZM04G30630	+	4	Tandem and block
	9	ZM04G30650	+	4	Tandem and block
	10	ZM04G32440	-	4
	11	ZM05G09820	+	5	Block
	12	ZM05G24850	+	5
	13	ZM07G22450	-	7	Block
Physcomitrella patens	1	PP00001G00030	-	Scaffold_1
	2	PP00020G01360	-	Scaffold_20
	3	PP00022G00030	+	Scaffold_22
	4	PP00025G01920	+	Scaffold_25	Tandem
	5	PP00025G01930	-	Scaffold_25	Tandem
	6	PP00034G01040	+	Scaffold_34
	7	PP00038G00030	-	Scaffold_38
	8	PP00039G01610	-	Scaffold_39
	9	PP00061G00280	-	Scaffold_61
	10	PP00076G01020	+	Scaffold_76
	11	PP00228G00140	-	Scaffold_228	Tandem
	12	PP00292G00010	-	Scaffold_292
	13	PP00303G00060	-	Scaffold_303	Tandem
	14	PP00303G00070	+	Scaffold_303	Tandem
	15	PP00304G00340	-	Scaffold_304
	16	PP00365G00100	-	Scaffold_365	Tandem
	17	PP00365G00120	+	Scaffold_365	Tandem
	18	PP00425G00060	-	Scaffold_425	Tandem
	19	PP00426G00290	-	Scaffold_426
	20	PP00463G00060	-	Scaffold_463	Tandem
	21	PP00463G00070	+	Scaffold_463	Tandem
	22	PP00463G00100	-	Scaffold_463	Tandem
	23	PP00500G00030	-	Scaffold_500
Selaginella moellendorffii	1	SM00001G06800	-	Scaffold_1
	2	SM00017G03910	-	Scaffold_17
	3	SM00007G01560	-	Scaffold_7
	4	SM00068G00810	-	Scaffold_68
Ostreococcus lucimarinus	-	-	-	-	-
O. tauri	-	-	-	-	-
Micromonas sp. RCC299	-	-	-	-	-
Volvox carteri	-	-	-	-	-
Chlamydomonas reinhardtii	-	-	-	-	-

No.	Contig	Length (bp)	Score bits	Strand	Identities	E-value	Sequence information
1	Ctg7180044571087	2 448	1 564	-	1 134/1 301 (87%)	0	Complete
2	Ctg7180044837494	4 493	1 535	-	1 119/1 301 (86%)	0	Complete
3	Ctg7180046059388	2 761	1 736	-	1 185/1 328 (89%)	0	Complete
4	Ctg7180055825794	3 986	1 000; 241	- -	821/999 (82%); 180/211 (85%)	0 7e-60	Complete
5	Ctg7180056125030	4 720	1 476; 378	- -	976/1 077 (91%); 226/237 (95%)	0 4e-101	Complete
6	Ctg7180057362889	39 003	1 893	-	1 265/1 402 (90%)	0	Complete
7	Jtg7180055651041f_7180057409216f	5 769	1 337; 309	- -	891/991 (90%); 215/244 (88%)	0 2e-80	Complete
8	Jtg7180057127125f_7180046406791r	10 190	1 577	-	1 123/1 284 (87%)	0	Complete
9	Ctg7180057114010	6 665	1 342	+	1 077/1 298 (83%)	0	Complete
10	Ctg7180057423160	15 081	1 471	+	1 087/1 271 (86%)	0	Complete
11	Jtg7180046403543f_7180056907730f	6 806	2 006	+	1 288/1 401 (92%)	0	Complete
12	Jtg7180043014796r_7180045416866r	5 549	717; 149	+ +	762/1 001 (76%); 141/180 (78%)	0 3e-32	Complete
13	Ctg7180057238333	10 113	1 712; 342	- -	966/977 (99%); 194/197 (98%)	0 2e-90	Complete
14	Ctg7180055304970	1 885	1 265	-	911/1 039 (88%)	0	Fragment
15	Ctg7180044078159	1 566	1 209	-	875/1 000 (88%)	0	Fragment
16	Ctg7180054149681	1 521	951	+	646/724 (89%)	0	Fragment
17	Ctg7180040742080	576	872	-	539/576 (94%)	0	Fragment
18	Ctg7180055755024	954	805	+	537/596 (90%)	0	Fragment
19	Ctg7180054149682	656	792	+	507/552 (92%)	0	Fragment
20	Ctg7180057090732	1 429	735	-	766/1 001 (77%)	0	Fragment
21	Ctg7180056804266	2 400	735	+	766/1 001 (77%)	0	Fragment
22	Ctg7180055304969	1 187	726	-	476/524 (91%)	0	Fragment
23	Deg7180050331267	530	704	+	474/530 (89%)	0	Fragment
24	Ctg7180047225082	2 089	704	+	756/998 (76%)	0	Fragment
25	Ctg7180057563133	1 376	675	+	753/1 002 (75%)	0	Fragment
26	Deg7180049910668	707	659	-	574/706 (81%)	0	Fragment
27	Ctg7180040473811	2 084	650	+	734/981 (75%)	0	Fragment
28	Deg7180050301638	1 145	623	+	510/616 (83%)	6e-175	Fragment
29	Ctg7180046407516	2 023	600	+	736/1 002 (73%)	6e-168	Fragment
30	Ctg7180056729621	1 548	583	+	654/871 (75%)	5e-163	Fragment
31	Ctg7180055812743	7 348	583	-	730/999 (73%)	5e-163	Fragment
32	Ctg7180056199763	7 255	574	+	722/987 (73%)	3e-160	Fragment
33	Ctg7180055845812	12 473	563	-	667/900 (74%)	5e-157	Fragment
34	Ctg7180053679462	1 148	554	-	659/891 (74%)	2e-154	Fragment
35	Ctg7180050291419	893	554	+	609/806 (76%)	2e-154	Fragment
36	Ctg7180040305101	946	553	+	623/833 (75%)	8e-154	Fragment
37	Ctg7180056889828	1 745	545	+	622/831 (75%)	1e-151	Fragment
38	Ctg7180040359262	801	544	+	536/691 (78%)	4e-151	Fragment
39	Ctg7180038459346	430	533	-	376/430 (87%)	8e-148	Fragment
40	Ctg7180038501054	559	522	-	453/555 (82%)	1e-144	Fragment
41	Ctg7180050814991	1 172	509	+	600/808 (74%)	9e-141	Fragment
42	Ctg7180057409908	1 097	508	+	343/384 (89%)	3e-140	Fragment
表2 (续) Table 2 (continued)
No.	Contig	Length (bp)	Score bits	Strand	Identities	E-value	Sequence information
43	Ctg7180056950914	6 228	1 357	+	1 092/1 318 (83%)	0	Nonsense mutation
44	Ctg7180056550739	18 693	1 342	-	1 076/1 293 (83%)	0	Nonsense mutation
45	Jtg7180056551170f_7180056551171f	9 504	1 198	-	1 060/1 326 (80%)	0	Nonsense mutation
46	Ctg7180039529527	1 759	677	+	754/1 001 (75%)	0	Nonsense mutation
47	Jtg7180057668388f_7180057668389f	5 289	661	+	734/975 (75%)	0	Nonsense mutation
48	Ctg7180044573223	1 796	650	-	747/1 001 (75%)	0	Nonsense mutation
49	Ctg7180056441624	5 881	600	+	739/1 002 (74%)	6e-168	Nonsense mutation
50	Jtg7180056265080f_7180046063071r	7 390	513	+	714/992 (72%)	7e-142	Nonsense mutation
51	Jtg7180057409910f_7180057409911f	20 052	1 393	+	1 080/1 281 (84%)	0	Frame shift

No.	Contig	Length (bp)	Score bits	Strand	Identities	E-value	Sequence information
1	Ctg7180044571087	2 448	1 564	-	1 134/1 301 (87%)	0	Complete
2	Ctg7180044837494	4 493	1 535	-	1 119/1 301 (86%)	0	Complete
3	Ctg7180046059388	2 761	1 736	-	1 185/1 328 (89%)	0	Complete
4	Ctg7180055825794	3 986	1 000; 241	- -	821/999 (82%); 180/211 (85%)	0 7e-60	Complete
5	Ctg7180056125030	4 720	1 476; 378	- -	976/1 077 (91%); 226/237 (95%)	0 4e-101	Complete
6	Ctg7180057362889	39 003	1 893	-	1 265/1 402 (90%)	0	Complete
7	Jtg7180055651041f_7180057409216f	5 769	1 337; 309	- -	891/991 (90%); 215/244 (88%)	0 2e-80	Complete
8	Jtg7180057127125f_7180046406791r	10 190	1 577	-	1 123/1 284 (87%)	0	Complete
9	Ctg7180057114010	6 665	1 342	+	1 077/1 298 (83%)	0	Complete
10	Ctg7180057423160	15 081	1 471	+	1 087/1 271 (86%)	0	Complete
11	Jtg7180046403543f_7180056907730f	6 806	2 006	+	1 288/1 401 (92%)	0	Complete
12	Jtg7180043014796r_7180045416866r	5 549	717; 149	+ +	762/1 001 (76%); 141/180 (78%)	0 3e-32	Complete
13	Ctg7180057238333	10 113	1 712; 342	- -	966/977 (99%); 194/197 (98%)	0 2e-90	Complete
14	Ctg7180055304970	1 885	1 265	-	911/1 039 (88%)	0	Fragment
15	Ctg7180044078159	1 566	1 209	-	875/1 000 (88%)	0	Fragment
16	Ctg7180054149681	1 521	951	+	646/724 (89%)	0	Fragment
17	Ctg7180040742080	576	872	-	539/576 (94%)	0	Fragment
18	Ctg7180055755024	954	805	+	537/596 (90%)	0	Fragment
19	Ctg7180054149682	656	792	+	507/552 (92%)	0	Fragment
20	Ctg7180057090732	1 429	735	-	766/1 001 (77%)	0	Fragment
21	Ctg7180056804266	2 400	735	+	766/1 001 (77%)	0	Fragment
22	Ctg7180055304969	1 187	726	-	476/524 (91%)	0	Fragment
23	Deg7180050331267	530	704	+	474/530 (89%)	0	Fragment
24	Ctg7180047225082	2 089	704	+	756/998 (76%)	0	Fragment
25	Ctg7180057563133	1 376	675	+	753/1 002 (75%)	0	Fragment
26	Deg7180049910668	707	659	-	574/706 (81%)	0	Fragment
27	Ctg7180040473811	2 084	650	+	734/981 (75%)	0	Fragment
28	Deg7180050301638	1 145	623	+	510/616 (83%)	6e-175	Fragment
29	Ctg7180046407516	2 023	600	+	736/1 002 (73%)	6e-168	Fragment
30	Ctg7180056729621	1 548	583	+	654/871 (75%)	5e-163	Fragment
31	Ctg7180055812743	7 348	583	-	730/999 (73%)	5e-163	Fragment
32	Ctg7180056199763	7 255	574	+	722/987 (73%)	3e-160	Fragment
33	Ctg7180055845812	12 473	563	-	667/900 (74%)	5e-157	Fragment
34	Ctg7180053679462	1 148	554	-	659/891 (74%)	2e-154	Fragment
35	Ctg7180050291419	893	554	+	609/806 (76%)	2e-154	Fragment
36	Ctg7180040305101	946	553	+	623/833 (75%)	8e-154	Fragment
37	Ctg7180056889828	1 745	545	+	622/831 (75%)	1e-151	Fragment
38	Ctg7180040359262	801	544	+	536/691 (78%)	4e-151	Fragment
39	Ctg7180038459346	430	533	-	376/430 (87%)	8e-148	Fragment
40	Ctg7180038501054	559	522	-	453/555 (82%)	1e-144	Fragment
41	Ctg7180050814991	1 172	509	+	600/808 (74%)	9e-141	Fragment
42	Ctg7180057409908	1 097	508	+	343/384 (89%)	3e-140	Fragment
表2 (续) Table 2 (continued)
No.	Contig	Length (bp)	Score bits	Strand	Identities	E-value	Sequence information
43	Ctg7180056950914	6 228	1 357	+	1 092/1 318 (83%)	0	Nonsense mutation
44	Ctg7180056550739	18 693	1 342	-	1 076/1 293 (83%)	0	Nonsense mutation
45	Jtg7180056551170f_7180056551171f	9 504	1 198	-	1 060/1 326 (80%)	0	Nonsense mutation
46	Ctg7180039529527	1 759	677	+	754/1 001 (75%)	0	Nonsense mutation
47	Jtg7180057668388f_7180057668389f	5 289	661	+	734/975 (75%)	0	Nonsense mutation
48	Ctg7180044573223	1 796	650	-	747/1 001 (75%)	0	Nonsense mutation
49	Ctg7180056441624	5 881	600	+	739/1 002 (74%)	6e-168	Nonsense mutation
50	Jtg7180056265080f_7180046063071r	7 390	513	+	714/992 (72%)	7e-142	Nonsense mutation
51	Jtg7180057409910f_7180057409911f	20 052	1 393	+	1 080/1 281 (84%)	0	Frame shift

植物查尔酮合成酶超基因家族的分子进化

Molecular Evolution of Chalcone Synthase Gene Superfamily in Plants

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