«Previous Article|Table of Contents|Next Article»

《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2023年24

Page:

16-23

Research Field:

Publishing date:

Info

Title:

Chloroplast Genome and Characteristics Analysis of Allium tuberosum

Author(s):

WANG Hongxia1; 2; 3; ZHENG Wenxia1

(1.College of Ecological Environment and Resources，Qinghai Minzu University，Xining,Qinghai 810000；2.Qinghai Provincial Key Laboratory of High Value Utilization of Characteristic Economic Plants，Xining，Qinghai 810000;3.Laboratory of Biotechnology and Analytical Testing，Xining，Qinghai 810000)

Keywords:

Allium tuberosum; chloroplast genome; codon preference; phylogenetic analysis

PACS:

S 633.3

DOI:

10.11937/bfyy.20231522

Abstract:

Taking the chloroplast genome of Allium tuberosum as the research object，the chloroplast genome was sequenced by Illumina NovaSep sequencing platform and the structure，codon preference，simple repeat sequence，comparison and phylogeny of chloroplast genome were studied，in order to provide reference for the molecular marker development，identification and exploitation of the germplasm resources studies of A.tuberosum. The results showed that the chloroplast genome of A.tuberosum was 154 056 bp in length with 133 genes annotated，including 38 tRNAs，8 rRNAs and 87 protein-coding genes.The codons in cpDNA of A.tuberosum tended to end with A or U，the frequency of Leu was the highest and that of Cys was the lowest.250 SSR loci were identified in the chloroplast genome sequence，with the highest number of single nucleotide repeats (164) and the lowest number of hexanucleotide repeats (one).There were no obvious expansion and contraction at the IR boundaries；phylogenetic analysis showed that A.tuberosum was most closely related to A.ramosum.

References:

［1］RONO P C，DONG X，YANG J X，et al.Initial complete chloroplast genomes of Alchemilla (Rosaceae):Comparative analysis and phylogenetic relationships［J］.Frontiers Genetics，2020,11：560368.［2］李佳文,刘强,张静文,等.濒危红树植物莲叶桐叶绿体基因组及其系统进化［J］.西北林学院学报,2020,35(5):54-61.［3］JANSEN R K，SASKI C，LEE S，et al.Complete plastid genome sequences of three rosids（Castanea,Prunus,Theobroma）:Evidence for at least two independent transfers of rpl22 to the nucleus［J］.Molecular Biology and Evolution，2011,28(1):835-847.［4］BOYNTON J E,GILLHAM N W，HARRIS E H,et al.Chloroplast transformationin Chlamydo monas with high veloeity mieroprojeetiles［J］.Science,1988,240(4858):1534-1538.［5］关云会，姚文燕，杨青淑，等.西藏凹乳芹叶绿体基因组密码子偏好性分析［J］.分子植物育种，2021,19(23):7771-7781.［6］张梦洁,杨秀瑶,尹拓,等.轮叶蒲桃叶绿体基因组特征及系统发育分析［J/OL］.广西植物,（2023-04-01)［2023-05-01］.https://kns.cnki.net/kcms/detail/45.1134.Q.20230411.1832.016.html.［7］TERADA R，URAWA H，INAGAKI Y，et al.Efficient gene targeting by homologous recombination in rice［J］.Nat Biotechnol,2002，20(10):1030-1034.［8］武亚红,赵青,王海平.葱属植物分类研究进展［J］.园艺学报，2021,48(7):1418-1428.［9］赵帮宏,宗义湘,乔立娟,等.2019年我国辛辣类蔬菜产业发展趋势与政策建议［J］.中国蔬菜,2019(6):1-5.［10］李同梅.无公害韭菜栽培关键技术研究［J］.世界热带农业信息,2023(6):13-15.［11］鞠丽萍,王远全,王爱民,等.万州区大棚韭菜栽培模式及高产栽培关键技术［J］.长江蔬菜,2020(3):21-22.［12］林莹,徐磊.福建省韭菜病虫害绿色高效防控技术［J］.福建热作科技,2022，47(4):55-56.［13］尹同萍.莱州市韭菜病虫害绿色防控及机械化防治技术模式研究［J］.中国农机监理,2022(4):36-38.［14］HUANG Y H，MAO Z C，XIE B Y.Chinese leek(Allium tuberosum Rottler ex Sprengel) reduced disease symptom caused by root-knot nematode［J］.Journal of Integrative Agriculture，2016,15(2):364-372.［15］焦子源,尹守恒,陈建华.韭菜种质资源花器官表型性状多样性分析［J］.中国蔬菜，2022(10):66-73.［16］李懋学,商树田,王志学.栽培韭和野韭的核型比较研究［J］.园艺学报，1982，9(3):31-36,73-74.［17］KOHN C V，KIELKOWSKA A，HAVEY M J.Sequencing and annotation of the chloroplast DNAs and identification of polymorphisms distinguishing normal male-fertile and male-sterile cytoplasms of onion［J］.Genome，2013,56(12):737-742.［18］BANKEVICH A，NURK S，ANTIPOV D，et al.SPAdes：A new genome assembly algorithm and its applications to single-cell sequencing［J］.Computational Biol，2012,19(5)：455-477.［19］LIU C，SHI L C，ZHU Y J，et al.CpGAVAS，an integrated web server for the annotation，visualization，analysis，and GenBank submission of completely sequenced chloroplast genome sequences［J］.BMC Genomics，2012，13(1)：715.［20］SHARP P M，LI W H.The codon adaptation index:A measure of directional synonymous codon usage bias，and its potential applications［J］.Nucleic Acids Research,1987,15(3)：1281-1295.［21］冯坤.棉属十个叶绿体基因组分析及其系统发育研究［D］.北京:中国农业科学院，2013.［22］FELSENSTEIN J.Confidence limits on phylogenies：An approach using the bootstrap［J］.Evolution,1985,39(4):783-791.［23］苏丹丹,刘玉萍,刘涛,等.苦马豆叶绿体基因组结构及其特征分析［J］.植物研究，2022，42(3):446-454.［24］邢少辰，CLARKE J H L.叶绿体基因组研究进展［J］.生物化学与生物物理进展，2008，35(1)：21-28.［25］王继玥,白禹,石登红,等.桑科植物叶绿体基因组研究进展［J］.北方园艺，2021(8):124-130.［26］莫冰棋,李艺,张骏骁,等.宽叶韭与峨眉韭系统发育及叶绿体基因组密码子偏好分析［J/OL］.分子植物育种,(2022-02-11)［2023-05-01］.https://kns.cnki.net/kcms/detail/46.1068.S.20220210.1602.004.html.［27］李豪,肖燕萍,许新锐,等.大花韭和粗根韭叶绿体全基因组的结构特征和遗传标记［J］.分子植物育种,2022,20(23):7847-7856.［28］曲桑卓玛,田甜,李文麒,等.青甘韭cpSSR序列特征分析［J/OL］.分子植物育种，(2022-11-04)［2023-05-01］.https://〖JP2〗kns.cnki.net/kcms/detail/46.1068.S.20221104.1542.005.html.［29］王宏霞,李文麒.蒙古韭叶绿体微卫星特征分析［J］.北方园艺，2023(3):1-7.［30］杨俏俏,姜梅,王立强,等.药食两用藠头叶绿体基因组解析、比较基因组学及系统发育研究［J］.药学学报，2019,54(1):173-181.［31］HUO Y M，GAO L M，LIU B J，et al.Complete chloroplast genome sequences of four Allium species:Comparative and phylogenetic analyses［J］.Scientific Reports,2019(9):1-14.［32］WEI L，HE J，JIA X，et al.Analysis of codon usage bias of mitochondrial genome in bombyx mori and its relation to evolution［J］.BMC Evol Biol,2014(14):262.［33］KAWABE A，MIYASHITA N T.Patterns of codon usage bias in three dicot and four monocot plant species［J］.Genes Genet Syst，2003,78(5)：343-352.［34］王媛媛，杨美青.蒙古韭叶绿体基因组密码子使用偏好性分析［J］.分子植物育种,2021，4(19):1084-1092.［35］YANG Y，JING Z B，RUAN X F，et al.Development of simple sequence repeat markers in persimmon(Diospyros L.) and their potential use in related species［J］.Genetics and Molecular Research，2015,14(1):609-618.［36］吴林世,廖菊阳,刘艳,等.基于高通量测序的羊踯躅叶绿体基因组及SSR序列分析［J］.经济林研究,2022,40(1):123-131.［37］任延靖,邵登魁.芜菁叶绿体基因组结构与进化关系分析［J］.种子,2022,41(2):59-64,75.［38］CUI Y X，NIE L P，SUN W,et al.Comparative and phylogenetic analyses of ginger (Zingiber officinale) in the family zingiberaceae based on the complete chloroplast genome［J］.Plants,2019，8(8)：283.［39］ZHANG J Q，LIU H C，XU W T，et al.Analysis of codon usage pattern in Lonicera×heckrottii ‘Gold Flame’ based on chloroplast genome［J］.Notulae Botanicae Horti Agrobotanici Cluj-Napoca，2022,50(1)：12535.［40］BORSCH T,QUANDT D.Mutational dynamics and phylogenetic utility of noncoding chloroplast DNA［J］.Plant Syst Evol，2009,282(3)：169-199.［41］赵祺,余佳兴,秦宇雯,等.基于高通量测序的菜头肾叶绿体基因组的组装及序列分析［J］.中草药,2021,52(6):1744-1750.［42］吴东洋,业宁,徐逸卿,等.狗枣猕猴桃叶绿体基因组微卫星特征分析［J］.北方园艺，2018(9)：30-35.［43］ZHANG J W，JIANG Z M，ZHAO H，et al.The complete chloroplast genome sequence of the endangered species Syringa pinnatifolia (Oleaceae)［J］.Nordic J Bot，2019,37(5):e02201.

Memo

Memo:

-

Common functions

Last Update: 2024-01-02