Physical Maps and Recombination Frequency of Six Rice Chromosomes

Overview

Journal Plant J

Specialties Biology
Cell Biology
Molecular Biology

Date 2003 Nov 18

PMID 14617072

Citations 67

Authors

Jianzhong Wu

Hiroshi Mizuno

Mika Hayashi-Tsugane

Yukiyo Ito

Yoshino Chiden

Masaki Fujisawa

Satoshi Katagiri

Shoko Saji

Shoji Yoshiki

Wataru Karasawa

Rie Yoshihara

Akiko Hayashi

Harumi Kobayashi

Kazue Ito

Masao Hamada

Masako Okamoto

Maiko Ikeno

Yoko Ichikawa

Yuichi Katayose

Masahiro Yano

Takashi Matsumoto

Takuji Sasaki

Affiliations

Soon will be listed here.

Abstract

We constructed physical maps of rice chromosomes 1, 2, and 6-9 with P1-derived artificial chromosome (PAC) and bacterial artificial chromosome (BAC) clones. These maps, with only 20 gaps, cover more than 97% of the predicted length of the six chromosomes. We submitted a total of 193 Mbp of non-overlapping sequences to public databases. We analyzed the DNA sequences of 1316 genetic markers and six centromere-specific repeats to facilitate characterization of chromosomal recombination frequency and of the genomic composition and structure of the centromeric regions. We found marked changes in the relative recombination rate along the length of each chromosome. Chromosomal recombination at the centromere core and surrounding regions on the six chromosomes was completely suppressed. These regions have a total physical length of about 23 Mbp, corresponding to 11.4% of the entire size of the six chromosomes. Chromosome 6 has the longest quiescent region, with about 5.6 Mbp, followed by chromosome 8, with quiescent region about half this size. Repetitive sequences accounted for at least 40% of the total genomic sequence on the partly sequenced centromeric region of chromosome 1. Rice CentO satellite DNA is arrayed in clusters and is closely associated with the presence of Centromeric Retrotransposon of Rice (CRR)- and RIce RetroElement 7 (RIRE7)-like retroelement sequences. We also detected relatively small coldspot regions outside the centromeric region; their repetitive content and gene density were similar to those of regions with normal recombination rates. Sequence analysis of these regions suggests that either the amount or the organization patterns of repetitive sequences may play a role in the inactivation of recombination.

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