Identification of repetitive DNA sequences in the Chrysanthemum boreale genome

被引：7

作者：

Won, So Youn ^{[1
]}

Hwang, Yoon-Jung ^{[2
]}

Jung, Jae-A ^{[3
]}

Kim, Jung Sun ^{[1
]}

Kang, Sang-Ho ^{[1
]}

Sohn, Seong-Han ^{[1
]}

机构：

[1] Rural Dev Adm, Natl Inst Agr Sci, Jeonju 54874, South Korea

[2] Sahmyook Univ, Dept Life Sci, Seoul 01795, South Korea

[3] Rural Dev Adm, Natl Inst Hort & Herbal Sci, Wonju 55365, South Korea

来源：

SCIENTIA HORTICULTURAE | 2018年 / 236卷

关键词：

Asteraceae; Chrysanthemum; Fluorescence in situ hybridization; Repeat; Satellite; Transposon; ANNUUS L. GENOME; TRANSPOSABLE ELEMENTS; EVOLUTION; PLANT; RETROTRANSPOSONS; INSIGHTS; FISH;

D O I：

10.1016/j.scienta.2018.03.055

中图分类号：

S6 [园艺];

学科分类号：

0902 ;

摘要：

We previously revealed that the Chrysanthemum boreale genome is highly repetitive; however, the types and nucleotide sequences of repetitive DNA in this diploid wild chrysanthemum are not known. Here, we characterized repetitive DNA sequences in the C. boreale genome by analysing genomic sequences obtained by Illumina sequencing and confirmed their repetitive nature by conducting fluorescence in situ hybridization (FISH) analyses. Annotation of the obtained DNA sequences revealed that microsatellite-containing genomic sequences exhibited similarity with genomic sequences in Chrysanthemum morifolium, indicating sequence conservation of repetitive DNA sequences between the two Chrysanthemum species. Two superfamilies of repetitive DNA, Copia and Gypsy, belonging to the long-terminal repeat (LTR) class of retrotransposons, are abundant in the C. boreale genome. We propose that Copia and Gypsy retroelements contribute to the current genome architecture of C. boreale. Whole genome sequencing, which is currently in progress, will reveal the extent to which these repetitive DNA sequences contribute.

引用

页码：238 / 243

页数：6

共 50 条

[21] REPETITIVE DNA-SEQUENCES OF THE HUMAN GENOME USED AS CHROMOSOME MARKER
VOGT, P
CREMER, T
SCHARDIN, M
JOURNAL OF CLINICAL CHEMISTRY AND CLINICAL BIOCHEMISTRY, 1987, 25 (03): : 137 - 137
[22] A new cytotoxic guaianolide from Chrysanthemum boreale
Park, Ki Hun
Yang, Min Suk
Park, Moon Ki
Kim, Sang Chan
Yang, Chae Ha
Park, Sook Jahr
Lee, Jong Rok
FITOTERAPIA, 2009, 80 (01) : 54 - 56
[23] LENGTH AND INTERSPERSION OF REPETITIVE AND NON REPETITIVE DNA SEQUENCES IN 4 AMPHIBIAN SPECIES WITH DIFFERENT GENOME SIZES
BALDARI, CT
AMALDI, F
CHROMOSOMA, 1977, 61 (04) : 359 - 368
[24] Genome size and identification of repetitive DNA sequences using low coverage sequencing in Hancornia speciosa Gomes (Apocynaceae: Gentianales)
Santos, Vanessa
da Silva, Edson Ferreira
Almeida, Cicero
GENETICS AND MOLECULAR BIOLOGY, 2020, 43 (04)
[25] CONSTITUENTS OF ESSENTIAL OILS FROM CHRYSANTHEMUM-BOREALE AND CHRYSANTHEMUM-MAKINOI
MATSUO, A
UCHIO, Y
NAKAYAMA, M
HAYASHI, S
NIPPON KAGAKU KAISHI, 1975, (12) : 2188 - 2191
[26] ANALYSIS OF THE REPETITIVE DNA-SEQUENCES IN THE GENOME OF FISH LYMPHOCYSTIS DISEASE VIRUS
SCHNITZLER, P
DELIUS, H
SCHOLZ, J
TOURAY, M
DARAI, G
ZENTRALBLATT FUR BAKTERIOLOGIE MIKROBIOLOGIE UND HYGIENE SERIES A-MEDICAL MICROBIOLOGY INFECTIOUS DISEASES VIROLOGY PARASITOLOGY, 1987, 267 (01): : 158 - 158
[27] Tools and databases for solving problems in detection and identification of repetitive DNA sequences
Satovic, Eva
Cvitanic, Monika Tunjic
Plohl, Miroslav
PERIODICUM BIOLOGORUM, 2020, 121 (1-2) : 7 - 14
[28] Computational Approaches and Tools Used in Identification of Dispersed Repetitive DNA Sequences
Surya Saha
Susan Bridges
Zenaida V. Magbanua
Daniel G. Peterson
Tropical Plant Biology, 2008, 1 (1) : 85 - 96
[29] Censor - A program for identification and elimination of repetitive elements from DNA sequences
Jurka, J
Klonowski, P
Dagman, V
Pelton, P
COMPUTERS & CHEMISTRY, 1996, 20 (01): : 119 - 121
[30] REPETITIVE DNA OF GRAPEVINE - CLASSES PRESENT AND SEQUENCES SUITABLE FOR CULTIVAR IDENTIFICATION
THOMAS, MR
MATSUMOTO, S
CAIN, P
SCOTT, NS
THEORETICAL AND APPLIED GENETICS, 1993, 86 (2-3) : 173 - 180

← 1 2 3 4 5 →