Evolution of interspersed repetitive elements in Gossypium (Malvaceae)

Very little is known regarding how repetitive elements evolve in polyploid organisms. Here we address this subject by fluorescent in situ hybridization (FISH) of 20 interspersed repetitive elements to metaphase chromosomes of the cotton AD-genome tetraploid Gossypium hirsutum and its putative A- and...

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Published inAmerican journal of botany Vol. 85; no. 10; pp. 1364 - 1368
Main Authors Hanson, R.E. (Texas AandM University, College Station, TX.), Zhao, X.P, Islam-Faridi, M.N, Paterson, A.H, Zwick, M.S, Crane, C.F, McKnight, T.D, Stelly, D.M, Price, H.J
Format Journal Article
LanguageEnglish
Published Columbus American Botanical Society 01.10.1998
Botanical Society of America
Botanical Society of America, Inc
Subjects
ADN
ANALYTICAL METHODS
Botany
CHROMOSOME
CHROMOSOMES
Concerted evolution
CROMOSOMAS
Diploidy
DNA
DNA HYBRIDIZATION
EVOLUCION
EVOLUTION
Fish
Flowers & plants
fluorescence in situ hybridization
FLUORESCENT IN SITU HYBRIDIZATION
fluorescent in situ hybridization (FISH)
Gene conversion
Genetics
Genetics and Molecular Biology
GENOMAS
GENOME
GENOME ANALYSIS
GENOMES
genomics
GOSSYPIUM
GOSSYPIUM ARBOREUM
GOSSYPIUM HIRSUTUM
GOSSYPIUM RAIMONDII
HIBRIDACION DE ADN
HYBRIDATION D'ADN
interspersed repetitive element
Malvaceae
nucleic acid hybridization
Plants
POLIPLOIDIA
POLYPLOIDIE
POLYPLOIDY
REPETITIVE DNA
repetitive sequences
TECHNIQUE ANALYTIQUE
TECNICAS ANALITICAS
Tetraploidy
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Summary:Very little is known regarding how repetitive elements evolve in polyploid organisms. Here we address this subject by fluorescent in situ hybridization (FISH) of 20 interspersed repetitive elements to metaphase chromosomes of the cotton AD-genome tetraploid Gossypium hirsutum and its putative A- and D-genome diploid ancestors. These elements collectively represent an estimated 18% of the G. hirsutum genome, and constitute the majority of high-copy interspersed repetitive elements in G. hirsutum. Seventeen of the elements yielded FISH signals on chromosomes of both G. hirsutum subgenomes, while three were A-subgenome specific. Hybridization of eight selected elements, two of which were A-subgenome specific, to the A2 genome of G. arboreum yielded a signal distribution that was similar to that of the G. hirsutum A-subgenome. However, when hybridized to the D5 genome of G. raimondii, the putative diploid ancestor of the G. hirsutum D-subgenome, none of the probes, including elements that strongly hybridized to both G. hirsutum subgenomes, yielded detectable signal. The results suggest that the majority, although not all, G. hirsutum interspersed repetitive elements have undergone intergenomic concerted evolution following polyploidization and that this has involved colonization of the D-subgenome by A-subgenome elements and/or replacement of D-subgenome elements by elements of the A-subgenome type
Bibliography:1999004365
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monosom@tamu.edu
Current address: University of Michigan Medical Center, MRSB‐II, C568, Ann Arbor, Michigan 48109.
Author for correspondence (Ph: 409 845‐2745; FAX: 409 862‐4733; e‐mail
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ISSN:0002-9122
1537-2197
DOI:10.2307/2446394