谷子基因组中SSR的偏态分布

doi:10.7668/hbnxb.20194516

摘要/Abstract

摘要：

为了研究谷子基因组中SSR的分布偏好,采用生物信息学方法搜索和分析了谷子基因组中SSR在基因座5'侧翼区、3'侧翼区、外显子区和内含子区的分布规律。结果发现,随着5'侧翼区与起始密码子间距离的增加,SSR在5'侧翼区的频率与其基因组频率的比值(相对频率)逐渐下降,在1~700 bp区域内相对频率远大于1.50,而在3'侧翼区、外显子区和内含子区中SSR的相对频率均接近1.00。进一步分析发现,随着5'侧翼区与起始密码子间距离的增加,不同单一SSR类型的相对频率的变化趋势各不相同,总体上,包括CCG、AG、AGG、AGGG、ACC和AGC在内的这6个SSR类型在5'侧翼区的频率和相对频率均较高,其中,AG在5'侧翼区相对频率大于1.5的区域最大(1~1 800 bp),而在CCG的区域最小(1~200 bp)。在外显子区,CCG、AGG、AGC、ACG和ACC这5个高C/G含量的三碱基SSR类型具有较高的频率和相对频率。综上,SSR在基因座5'侧翼区1~700 bp内特异性出现,其中,包括CCG、AG、AGG、AGGG、ACC和AGC在内的6个SSR类型为主要的特异性分布类型;而在基因座3'侧翼区、外显子区和内含子区中,SSR的分布与整个基因组无明显差别,但在外显子区,CCG、AGG、AGC、ACG和ACC这5个SSR类型具有明显的分布特异性。

关键词: 谷子, SSR, 分布偏好, 5'侧翼区, 外显子区

Abstract:

To reveal the distribution preferences of SSR in foxtail millet genome,the study analyzed distribution regularities of SSRs among the 5'-flanking regions,the 3'-flanking regions,the extron regions and the intron regions in gene locus from foxtail millet genome using bioinformatics methods.The results showed that the relative frequency,a ratio of the frequency of a type of SSR in a certain genomic region by the frequency of this SSR in whole genome,of SSRs decreased with increasing of the distance of 5'-flanking regions from start codon,and was more than 1.50 obviously in a range from 1 bp to 700 bp.However,the relative frequency of SSRs was close to 1.00 in each of other three regions.Furthermore,with increasing of the distance of 5'-flanking regions from start codon,the relative frequency of various SSR types revealed the various changing trends,and as a whole,6 SSR types,including CCG,AG,AGG,AGGG,ACC and AGC,showed both the high frequency and the high relative frequency,and of these 6 types,the distance range(1—1 800 bp)of AG,in which its relative frequency was more than 1.50,is the maximum while that of CCG is minimal(1—200 bp).Meanwhile,in the extron regions,5 SSR types with high C/G contents,including CCG,AGG,AGC,ACG and ACC,showed both a high frequency and a high relative frequency.It was concluded that SSRs distributed preferentially in a length range from about 1—700 bp of 5'-flanking regions with 6 main specific SSR types,including CCG,AG,AGG,AGGG,ACC and AGC;on the other hand,in 3'-flanking regions,the intron regions and the extron region,distribution of SSR is close to that in genome,and however,in the extron region,a total of 5 SSR types,including CCG,AGG,AGC,ACG and ACC,are obviously specifically distributed.

Key words: Foxtail millet, SSR, Distribution preference, 5'-flanking regions, Extron regions

高建明, 邱丽娜, 桂枝. 谷子基因组中SSR的偏态分布[J]. 华北农学报, 2024, 39(2): 19-26. doi: 10.7668/hbnxb.20194516.

GAO Jianming, QIU Lina, GUI Zhi. Preference Distribution of Simple Sequence Repeats in Foxtail Millet Genome[J]. Acta Agriculturae Boreali-Sinica, 2024, 39(2): 19-26. doi: 10.7668/hbnxb.20194516.

http://www.hbnxb.net/CN/Y2024/V39/I2/19

图/表 5

参考文献 33

[16]	Fan W L, Wang X L, Li Q, Yu Z J, Li G. Genetic analysis and primary localization of fruit length gene fl and sex expression gene a in melon(Cucumis melo L.)[J]. Xinjiang Agricultural Sciences, 2018, 55(10):1765-1774.
[17]	Delfino P, Zenoni S, Imanifard Z, Tornielli G B, Bellin D. Selection of candidate genes controlling veraison time in grapevine through integration of meta-QTL and transcriptomic data[J]. BMC Genomics, 2019, 20(1):739. doi: 10.1186/s12864-019-6124-0 pmid: 31615398
[18]	武博洋, 彭云玲, 赵小强, 方鹏. 玉米苗期在盐胁迫下耐盐相关QTL分析[J]. 分子植物育种, 2019, 17(1):154-160.doi:10.13271/j.mpb.017.000154.
	Wu B Y, Peng Y L, Zhao X Q, Fang P. Salt tolerance related QTL analysis in maize seedling stage under salt stress[J]. Molecular Plant Breeding, 2019, 17(1):154-160.
[19]	张素君, 周晓栋, 唐丽媛, 李兴河, 王海涛, 刘存敬, 蔡肖, 张香云, 张建宏. 杂交棉冀1518纤维品质性状的QTL定位及遗传分析[J]. 分子植物育种, 2021, 19(11):3627-3637.doi:10.13271/j.mpb.019.003627.
	Zhang S J, Zhou X D, Tang L Y, Li X H, Wang H T, Liu C J, Cai X, Zhang X Y, Zhang J H. QTL mapping and genetic analysis of fiber quality traits in hybrid cotton Ji1518[J]. Molecular Plant Breeding, 2021, 19(11):3627-3637.
[20]	伊六喜, 邬阳, 曹彦, 贾海滨, 斯钦巴特尔, 高凤云, 周宇, 贾霄云. 亚麻主要产量相关性状的SSR关联分析[J]. 华北农学报, 2022, 37(5):52-61.doi:10.7668/hbnxb.20192676.
[1]	Tautz D. Hypervariability of simple sequences as a general source for polymorphic DNA markers[J]. Nucleic Acids Research, 1989, 17(16):6463-6471.doi:10.1093/nar/17.16.6463. pmid: 2780284
[2]	Gur-Arie R, Cohen C J, Eitan Y, Shelef L, Hallerman E M, Kashi Y. Simple sequence repeats in Escherichia coli:abundance,distribution,composition,and polymorphism[J]. Genome Research, 2000, 10(1):62-71.doi:10.1101/gr.10.1.62. pmid: 10645951
[3]	Tóth G, Gáspári Z, Jurka J. Microsatellites in different eukaryotic genomes:survey and analysis[J]. Genome Research, 2000, 10(7):967-981.doi:10.1101/gr.10.7.967. pmid: 10899146
[4]	Li Y C, Korol A B, Fahima T, Beiles A, Nevo E. Microsatellites:genomic distribution,putative functions and mutational mechanisms:a review[J]. Molecular Ecology, 2002, 11(12):2453-2465.doi:10.1046/j.1365-294x.2002.01643.x.
[5]	Saveliev A, Everett C, Sharpe T, Webster Z, Festenstein R. DNA triplet repeats mediate heterochromatin-protein-1-sensitive variegated gene silencing[J]. Nature, 2003, 422(6934):909-913.doi:10.1038/nature01596. URL
[6]	Chistiakov D A, Hellemans B, Volckaert F A M. Microsatellites and their genomic distribution,evolution,function and applications:a review with special reference to fish genetics[J]. Aquaculture, 2006, 255(1/4):1-29.doi:10.1016/j.aquaculture.2005.11.031. URL
[7]	辛佳佳, 张南峰, 程华萍, 戴兴临, 张洋, 涂玉琴, 涂伟凤, 谷德平, 关峰, 汤洁. 江西省地方蚕豆种质资源遗传多样性分析及优异资源挖掘[J]. 江苏农业学报, 2022, 38(1):20-29.doi:10.3969/j.issn.1000-4440.2022.01.003.
	Xin J J, Zhang N F, Cheng H P, Dai X L, Zhang Y, Tu Y Q, Tu W F, Gu D P, Guan F, Tang J. Genetic diversity analysis and excellent resources mining of local broad bean germplasm resources in Jiangxi Province[J]. Jiangsu Journal of Agricultural Sciences, 2022, 38(1):20-29.
[8]	Pei Z Y, Gao J M, Chen Q L, Wei J Z, Li Z F, Luo F, Shi L L, Ding B, Sun S J. Genetic diversity of elite sweet sorghum genotypes assessed by SSR markers[J]. Biologia Plantarum, 2010, 54(4):653-658.doi:10.1007/s10535-010-0116-x. URL
[9]	于金田, 常巍, 高雪芹, 伏兵哲. 无芒雀麦SSR-PCR反应体系优化及其遗传多样性分析[J]. 基因组学与应用生物学, 2021, 40(S4):3600-3609.doi:10.13417/j.gab.040.003600.
	Yu J T, Chang W, Gao X Q, Fu B Z. Optimization of SSR-PCR reaction system and analysis of genetic diversity of Bromus inermis[J]. Genomics and Applied Biology, 2021, 40(S4):3600-3609.
[10]	王齐, 周天华, 柏国清, 王佳, 贾芸, 陈尘, 王耀铭, 戴全华. 秦巴山区漆树的遗传多样性分析[J]. 基因组学与应用生物学, 2022, 41(5):1060-1066.doi:10.13417/j.gab.041.001060.
	Wang Q, Zhou T H, Bai G Q, Wang J, Jia Y, Chen C, Wang Y M, Dai Q H. Analysis on genetic diversity of Toxicodendron vernicifluum in Mts.Qinling-bashan area[J]. Genomics and Applied Biology, 2022, 41(5):1060-1066.
[11]	白志元, 张瑞军, 武国平, 连世超, 杨玉花, 卫保国. 基于SSR标记的杂交大豆主要亲本遗传多样性分析[J]. 华北农学报, 2018, 33(4):120-125.doi:10.7668/hbnxb.2018.04.017.
[20]	Yi L X, Wu Y, Cao Y, Jia H B, Siqin B, Gao F Y, Zhou Y, Jia X Y. SSR correlation analysis of main yield related traits in flax[J]. Acta Agriculturae Boreali-Sinica, 2022, 37(5):52-61.
[21]	Ashkani S, Rafii M Y, Rusli I, Sariah M, Abdullah S N A, Abdul Rahim H, Latif M A. SSRs for marker-assisted selection for blast resistance in rice(Oryza sativa L.)[J]. Plant Molecular Biology Reporter, 2012, 30(1):79-86.doi:10.1007/s11105-011-0315-4. URL
[22]	Gao J M, Xia B X, Luo F, Sun S J, Pei Z Y, Gui Z, Yuan Q H, Li X L. Marker-assisted breeding for Rf1,a nuclear gene controlling A1 CMS in sorghum(Sorghum bicolor L.Moench)[J]. Euphytica, 2013, 193(3):383-390.doi:10.1007/s10681-013-0939-6. URL
[23]	Zhang L D, Yuan D J, Yu S W, Li Z G, Cao Y F, Miao Z Q, Qian H M, Tang K X. Preference of simple sequence repeats in coding and non-coding regions of Arabidopsis thaliana[J]. Bioinformatics, 2004, 20(7):1081-1086.doi:10.1093/bioinformatics/bth043. pmid: 14764542
[24]	周勃, 任海龙, 张龑, 高强, 徐麟, 邹集文. 金花菜与苜蓿属主要物种基因组SSR分布特征的比较分析[J]. 新疆农业科学, 2022, 59(9):2217-2223.doi:10.6048/j.issn.1001-4330.2022.09.016.
	Zhou B, Ren H L, Zhang Y, Gao Q, Xu L, Zou J W. Characteristics and analysis of simple sequence repeats(SSR)in Medicago polymorpha and main Medicagospecies genome[J]. Xinjiang Agricultural Sciences, 2022, 59(9):2217-2223.
[11]	Bai Z Y, Zhang R J, Wu G P, Lian S C, Yang Y H, Wei B G. Genetic diversity analysis of main parents for hybrid soybean based on SSR markers[J]. Acta Agriculturae Boreali-Sinica, 2018, 33(4):120-125.
[12]	蔡海滨, 韩光煜, 涂敏, 汪智, 傅泳维, 官鑫, 王云月, 卢宝荣. 基于SSR荧光标记的江苏省杂草稻群体遗传多样性分析[J]. 分子植物育种, 2022, 20(21):7104-7115.doi:10.13271/j.mpb.020.007104.
	Cai H B, Han G Y, Tu M, Wang Z, Fu Y W, Guan X, Wang Y Y, Lu B R. Genetic diversity analysis of weedy rice populations in Jiangsu Province based on SSR fluorescent markers[J]. Molecular Plant Breeding, 2022, 20(21):7104-7115.
[13]	Liang Y S, Yan C, Qin X J, Nan W B, Zhang H M. Construction of three half-sib SSR linkage maps derived from overwintering cultivated rice and segregation distortion loci mapping[J]. Genome, 2020, 63(4):239-251.doi:10.1139/gen-2019-0160. pmid: 32053407
[14]	Meng Y S, Zheng C X, Li H, Li A X, Zhai H, Wang Q M, He S Z, Zhao N, Zhang H, Gao S P, Liu Q C. Development of a high-density SSR genetic linkage map in sweet potato[J]. The Crop Journal, 2021, 9(6):1367-1374.doi:10.1016/j.cj.2021.01.003. URL
[15]	于肖夏, 南志标, 于卓, 杨东升, 谢锐, 石悦, 吴国芳. 基于SSR分子标记的高丹草遗传图谱构建及相关性状QTL定位[J]. 分子植物育种, 2018, 16(16):5347-5358.doi:10.13271/j.mpb.016.005347.
[25]	王宇, 唐冬梅, 仲伟敏, 马玉华, 张敏. 红阳猕猴桃全基因组SSR标记与基因密码子偏性分析[J]. 西南农业学报, 2020, 33(5):920-927.doi:10.16213/j.cnki.scjas.2020.5.004.
	Wang Y, Tang D M, Zhong W M, Ma Y H, Zhang M. Genome-wide analysis of SSR markers and codon bias of Actinidia chinensis cv.Hongyang[J]. Southwest China Journal of Agricultural Sciences, 2020, 33(5):920-927.
[26]	Grover A, Aishwarya V, Sharma P C. Biased distribution of microsatellite motifs in the rice genome[J]. Molecular Genetics and Genomics, 2007, 277(5):469-480.doi:10.1007/s00438-006-0204-y. pmid: 17237941
[27]	刁现民. 禾谷类杂粮作物耐逆和栽培技术研究新进展[J]. 中国农业科学, 2019, 52(22):3943-3949.doi:10.3864/j.issn.0578-1752.2019.22.001.
	Diao X M. Progresses in stress tolerance and field cultivation studies of orphan cereals in China[J]. Scientia Agricultura Sinica, 2019, 52(22):3943-3949. doi: 10.3864/j.issn.0578-1752.2019.22.001
[28]	Liu Z L, Bai G H, Zhang D D, Zhu C S, Xia X Y, Cheng R H, Shi Z G. Genetic diversity and population structure of elite foxtail millet(Setaria italica (L.) P.Beauv.)germplasm in China[J]. Crop Science, 2011, 51(4):1655-1663.doi:10.2135/cropsci2010.11.0643. URL
[29]	贾冠清, 刁现民. 谷子 (Setaria italica (L.)P.Beauv.)作为功能基因组研究模式植物的发展现状及趋势[J]. 生命科学, 2017, 29(3):292-301.doi:10.13376/j.cbls/2017039.
	Jia G Q, Diao X M. Current status and perspectives of researches on foxtail millet(Setaria italica (L.) P.Beauv.):a potential model of plant functional genomics studies[J]. Chinese Bulletin of Life Sciences, 2017, 29(3):292-301.
[30]	Diao X M, James S, Jeffrey L B, Li J Y. Initiation of Setaria as a model plant[J]. Frontiers of Agricultural Science and Engineering, 2014, 1(1):16.doi:10.15302/j-fase-2014011. URL
[31]	付楠, 刘金荣, 王素英, 刘海萍, 闫宏山, 宋中强. 谷子SSR标记的开发与应用研究进展[J]. 安徽农业科学, 2018, 46(25):26-28,35.doi:10.13989/j.cnki.0517-6611.2018.25.008.
	Fu N, Liu J R, Wang S Y, Liu H P, Yan H S, Song Z Q. Research progress on development and application of SSR markers in foxtail millet[J]. Journal of Anhui Agricultural Sciences, 2018, 46(25):26-28,35.
[32]	Bennetzen J L, Schmutz J, Wang H, Percifield R, Hawkins J, Pontaroli A C, Estep M, Feng L, Vaughn J N, Grimwood J, Jenkins J, Barry K, Lindquist E, Hellsten U, Deshpande S, Wang X W, Wu X M, Mitros T, Triplett J, Yang X H, Ye C Y, Mauro-Herrera M, Wang L, Li P H, Sharma M, Sharma R, Ronald P C, Panaud O, Kellogg E A, Brutnell T P, Doust A N, Tuskan G A, Rokhsar D, Devos K M. Reference genome sequence of the model plant Setaria[J]. Nature Biotechnology, 2012, 30(6):555-561.doi:10.1038/nbt.2196. pmid: 22580951
[33]	Jurka J, Pethiyagoda C. Simple repetitive DNA sequences from Primates:compilation and analysis[J]. Journal of Molecular Evolution, 1995, 40(2):120-126.doi:10.1007/BF00167107. pmid: 7699718
[15]	Yu X X, Nan Z B, Yu Z, Yang D S, Xie R, Shi Y, Wu G F. Construction of genetic linkage map base on SSR markers and identification of QTLs for main traits of Sorghum×Sudangrass[J]. Molecular Plant Breeding, 2018, 16(16):5347-5358.
[16]	范文林, 王贤磊, 李群, 俞志杰, 李冠. 甜瓜果长基因fl与性别表达基因a的遗传分析及定位[J]. 新疆农业科学, 2018, 55(10):1765-1774.doi:10.6048/j.issn.1001-4330.2018.10.001.

基序 Motif	基因组 Genome	外显子区 Extron	内含子区 Intron	基序 Motif	基因组 Genome	外显子区 Extron	内含子区 Intron
CCG	44.34	189.23(4.27)	14.03(0.32)	AAT	3.19	0.44(0.14)	5.15(1.61)
AGG	19.78	48.45(2.45)	7.85(0.40)	AATC	3.06	0.22(0.07)	3.13(1.02)
AG	15.04	0.91(0.06)	13.13(0.87)	AAGC	2.80	1.07(0.38)	3.51(1.26)
AAG	12.78	12.59(0.98)	7.85(0.61)	ACGC	2.59	0.16(0.06)	2.33(0.90)
AGC	12.13	41.34(3.41)	6.85(0.56)	AGCT	2.57	0.08(0.03)	2.33(0.90)
C	11.54	0.30(0.03)	22.46(1.95)	AGGC	2.47	0.49(0.20)	1.77(0.72)
A	9.85	0.16(0.02)	16.09(1.63)	AAAAG	2.44	0.14(0.06)	3.04(1.24)
AAAG	8.59	1.46(0.17)	10.38(1.21)	AGCC	2.31	0.66(0.29)	1.81(0.79)
AT	8.38	0.06(0.01)	8.14(0.97)	ACT	2.14	1.13(0.53)	2.30(1.08)
AGGG	8.36	1.37(0.16)	7.29(0.87)	AGCG	2.13	0.38(0.18)	1.23(0.58)
ACC	8.30	19.32(2.33)	4.32(0.52)	AATT	2.11	0.03(0.01)	2.30(1.09)
ACG	7.71	29.46(3.82)	2.82(0.37)	CG	2.07	1.98(0.96)	1.41(0.68)
ATC	7.11	10.09(1.42)	4.03(0.57)	ATCG	2.04	0.06(0.03)	2.28(1.12)
AC	6.94	0.14(0.02)	10.05(1.45)	AATG	1.84	0.30(0.16)	2.93(1.60)
AAAT	6.68	0.11(0.02)	11.81(1.77)	AACC	1.73	0.63(0.37)	2.44(1.41)
CCGG	4.99	2.25(0.45)	2.26(0.45)	ACCC	1.68	0.33(0.20)	2.01(1.20)
AAC	4.98	2.94(0.59)	7.34(1.47)	AGAT	1.48	0.08(0.06)	1.63(1.11)
ATGC	4.63	0.16(0.04)	5.46(1.18)	AAAAT	1.20	0.03(0.02)	1.99(1.66)
CCCG	3.93	3.11(0.79)	1.95(0.50)	AGGGG	1.12	0.16(0.15)	0.87(0.78)
ACAT	3.86	0.25(0.06)	3.13(0.81)	CCGCG	1.04	2.23(2.15)	0.31(0.30)
ATCC	3.83	0.74(0.19)	3.60(0.94)	AGAGG	1.04	0.16(0.16)	0.65(0.63)
AAAC	3.80	0.52(0.14)	7.38(1.94)	总计All	299.53	410.92(1.37)	257.99(0.86)
AAGG	3.21	0.96(0.30)	1.83(0.57)

基序 Motif	基因组 Genome	外显子区 Extron	内含子区 Intron	基序 Motif	基因组 Genome	外显子区 Extron	内含子区 Intron
CCG	44.34	189.23(4.27)	14.03(0.32)	AAT	3.19	0.44(0.14)	5.15(1.61)
AGG	19.78	48.45(2.45)	7.85(0.40)	AATC	3.06	0.22(0.07)	3.13(1.02)
AG	15.04	0.91(0.06)	13.13(0.87)	AAGC	2.80	1.07(0.38)	3.51(1.26)
AAG	12.78	12.59(0.98)	7.85(0.61)	ACGC	2.59	0.16(0.06)	2.33(0.90)
AGC	12.13	41.34(3.41)	6.85(0.56)	AGCT	2.57	0.08(0.03)	2.33(0.90)
C	11.54	0.30(0.03)	22.46(1.95)	AGGC	2.47	0.49(0.20)	1.77(0.72)
A	9.85	0.16(0.02)	16.09(1.63)	AAAAG	2.44	0.14(0.06)	3.04(1.24)
AAAG	8.59	1.46(0.17)	10.38(1.21)	AGCC	2.31	0.66(0.29)	1.81(0.79)
AT	8.38	0.06(0.01)	8.14(0.97)	ACT	2.14	1.13(0.53)	2.30(1.08)
AGGG	8.36	1.37(0.16)	7.29(0.87)	AGCG	2.13	0.38(0.18)	1.23(0.58)
ACC	8.30	19.32(2.33)	4.32(0.52)	AATT	2.11	0.03(0.01)	2.30(1.09)
ACG	7.71	29.46(3.82)	2.82(0.37)	CG	2.07	1.98(0.96)	1.41(0.68)
ATC	7.11	10.09(1.42)	4.03(0.57)	ATCG	2.04	0.06(0.03)	2.28(1.12)
AC	6.94	0.14(0.02)	10.05(1.45)	AATG	1.84	0.30(0.16)	2.93(1.60)
AAAT	6.68	0.11(0.02)	11.81(1.77)	AACC	1.73	0.63(0.37)	2.44(1.41)
CCGG	4.99	2.25(0.45)	2.26(0.45)	ACCC	1.68	0.33(0.20)	2.01(1.20)
AAC	4.98	2.94(0.59)	7.34(1.47)	AGAT	1.48	0.08(0.06)	1.63(1.11)
ATGC	4.63	0.16(0.04)	5.46(1.18)	AAAAT	1.20	0.03(0.02)	1.99(1.66)
CCCG	3.93	3.11(0.79)	1.95(0.50)	AGGGG	1.12	0.16(0.15)	0.87(0.78)
ACAT	3.86	0.25(0.06)	3.13(0.81)	CCGCG	1.04	2.23(2.15)	0.31(0.30)
ATCC	3.83	0.74(0.19)	3.60(0.94)	AGAGG	1.04	0.16(0.16)	0.65(0.63)
AAAC	3.80	0.52(0.14)	7.38(1.94)	总计All	299.53	410.92(1.37)	257.99(0.86)
AAGG	3.21	0.96(0.30)	1.83(0.57)

类型 Type	基因组 Genome	外显子 Extron	内含子 Intron	5'侧翼区 5'-flanking regions	3'侧翼区 3'-flanking regions
单核苷酸 Mononucleotide	8 584(7.14%)	17(0.11%)	1 729(14.93%)	891(6.75%)	67(5.82%)
二核苷酸 Dinucleotide	13 011(10.82%)	112(0.75%)	1 468(12.67%)	1 619(12.27%)	101(8.77%)
三核苷酸 Trinucleotide	49 139(40.88%)	12 922(86.38%)	2 813(24.28%)	4 346(32.94%)	318(27.60%)
四核苷酸 Tetranucleotide	35 138(29.23%)	607(4.06%)	4 156(35.88%)	4 103(31.10%)	532(46.18%)
五核苷酸 Pentanucleotide	9 285(7.72%)	166(1.11%)	1 089(9.40%)	1 665(12.62%)	97(8.42%)
六核苷酸 Hexanucleotide	5 043(4.20%)	1 135(7.59%)	329(2.84%)	571(4.33%)	37(3.21%)
总计All	120 200	14 959	11 584	13 195	1 152

类型 Type	基因组 Genome	外显子 Extron	内含子 Intron	5'侧翼区 5'-flanking regions	3'侧翼区 3'-flanking regions
单核苷酸 Mononucleotide	8 584(7.14%)	17(0.11%)	1 729(14.93%)	891(6.75%)	67(5.82%)
二核苷酸 Dinucleotide	13 011(10.82%)	112(0.75%)	1 468(12.67%)	1 619(12.27%)	101(8.77%)
三核苷酸 Trinucleotide	49 139(40.88%)	12 922(86.38%)	2 813(24.28%)	4 346(32.94%)	318(27.60%)
四核苷酸 Tetranucleotide	35 138(29.23%)	607(4.06%)	4 156(35.88%)	4 103(31.10%)	532(46.18%)
五核苷酸 Pentanucleotide	9 285(7.72%)	166(1.11%)	1 089(9.40%)	1 665(12.62%)	97(8.42%)
六核苷酸 Hexanucleotide	5 043(4.20%)	1 135(7.59%)	329(2.84%)	571(4.33%)	37(3.21%)
总计All	120 200	14 959	11 584	13 195	1 152

基序 Motif	基因组频率 Genome frequency	5'范围/bp 5'-range	5'频率/ (个/Mb) 5'-frequency	5'相对频率 5'-relative frequency	3'范围/bp 3'-range	3'频率/ (个/Mb) 3'-frequency	3'相对频率 3'-relative frequency
AGCG	2.13	1~800	26.43~3.44	12.43~1.61	—	—	—
CCCG	3.93	1~2 200	30.01~6.84	7.63~1.73	—	—	—
AGGG	8.34	1~1 600	61.35~14.24	7.34~1.70	—	—	—
AG	15.04	1~1 800	92.30~24.00	6.14~1.60	—	—	—
ACC	8.30	1~400	49.08~16.74	5.91~2.01	—	—	—
CCG	44.34	1~200	214.43	4.84	—	—	—
AGG	19.78	1~400	92.68~30.56	4.69~1.54	—	—	—
AGC	12.13	1~400	48.32~21.99	3.98~1.81	1~100	21.24	1.75
A	9.85	1~2 000	33.48~15.39	3.40~1.56	100~900	31.08~21.29	3.15~1.70
ACG	7.71	1~400	20.20~12.07	2.62~1.57	—	—	—
AAG	12.78	1~200	26.05	2.04	—	—	—
C	11.54	1~2 000	22.59~17.37	1.96~1.50—	—	—	—

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