Frequent Variations and Phylogenetic Relationships Within the Genus Identified by ND-FISH According to the Genome-wide Universal Oligonucleotides Chromosome Probes

Overview

Journal Front Plant Sci

Date 2024 Dec 27

PMID 39726427

Authors

Zhi Li

Zixin Sun

Tianheng Ren

Affiliations

Soon will be listed here.

Abstract

Introduction: Rye ( L.) played a very important role in wheat genetic improvement and forage production worldwide. However, since rye is a kind of cross-pollinated plant, high levels of genetic heterozygosity and heterogeneity existed in the genome. Genome-wide variation in repeat sequences is one of the most important reasons for chromosome evolution in rye. High-precision cytological identification can effectively identify the heterochromatin or repeat sequence variations in the rye genome, and the relationship between different rye varieties can be identified while obtaining the FISH-karyotype of different rye varieties. The evolution of rye chromosomes can be analyzed by the variation degree of different probes on rye chromosomes.

Methods: All materials were identified by non-denaturing fluorescence hybridization (ND-FISH). Five probes, (AAC), Oligo-pSc119.2-1, Oligo-pTa71A-2, Oligo-pSc200, and Oligo-pSc250 were used to identify rye chromosomes.

Results: 15 rye varieties including (cultivated rye and weedy rye), (wild rye), (wild rye), and (wild rye) were examined by five oligonucleotides probes. 92 signal sites and 2074 signal patterns were observed, suggesting that high polymorphisms exist in the different rye genomes. The karyotypes of 15 rye varieties were obtained, the frequency of different signal types at each signal site was calculated and the model diagrams of probes (AAC), Oligo-pSc119.2-1, Oligo-pTa71A-2, Oligo-pSc200 + Oligo-pSc250 were drawn. The results showed that the rate of variation of different chromosomes of rye was not consistent. 1R, 6R, and 7R have higher variation and genetic diversity, while 2R and 3R have lower variation and are more conserved relative to other chromosomes. The results also indicated that has a far genetic distance from other rye species, and might be one of the ancestors of Chinese rye varieties.

Discussion: Results from this study confirmed rapid chromosome change and high levels of chromosome diversity in rye.

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