The Asymmetric Meiosis in Pentaploid Dogroses (Rosa Sect. Caninae) is Associated with a Skewed Distribution of RRNA Gene Families in the Gametes

Overview

Journal Heredity (Edinb)

Specialty Genetics

Date 2008 Jul 24

PMID 18648391

Citations 15

Authors

A Kovarik

G Werlemark

A R Leitch

K Souckova-Skalicka

Y K Lim

L Khaitova

B Koukalova

H Nybom

Affiliations

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Abstract

In pentaploid dogroses, Rosa section Caninae (2n=5x=35), the pollen transmits one basic genome (x=7) derived from the seven segregating bivalents, whereas the egg transmits four basic genomes (4x=28) one set derived from the segregation of seven bivalents and three sets of univalent-forming chromosomes. Chromosomes from all five genomes carry 18-5.8-26S nuclear ribosomal DNA (rDNA) sites. This mode of sexual reproduction, known as permanent odd polyploidy, can potentially lead to the independent evolution of rDNA on bivalent- and univalent-forming chromosomes. To test this hypothesis, we analyzed rRNA gene families in pollen and somatic leaf tissue of R. canina, R. rubiginosa and R. dumalis. Six major rRNA gene families (alpha, beta, beta' gamma, delta and epsilon) were identified based on several highly polymorphic sites in the internal transcribed spacers (ITSs). At least two of the major rRNA gene families were found in each species indicating that rDNAs have not been homogenized across subgenomes. A comparison of ITS1 sequences from leaf and pollen showed differences: the shared beta rRNA gene family was more abundant among pollen clones compared to leaf clones and must constitute a major part of the rDNA loci on bivalent-forming chromosomes. The gamma and delta families were underrepresented in pollen genomes and are probably located predominantly (or solely) on the univalents. The results support the hypothesis that pentaploid dogroses inherited a bivalent-forming genome from a common proto-canina ancestor, a likely donor of the beta rDNA family. Allopolyploidy with distantly related species is likely to have driven evolution of Rosa section Caninae.

Citing Articles

Epigenetic histone H3 phosphorylation marks discriminate between univalent- and bivalent-forming chromosomes during canina asymmetrical meiosis.

Kalfusova R, Herklotz V, Kumke K, Houben A, Kovarik A, Ritz C Ann Bot. 2023; 133(3):435-446.

PMID: 38127060 PMC: 11006542. DOI: 10.1093/aob/mcad198.

Ancient Origin of Two 5S rDNA Families Dominating in the Genus and Their Behavior in the Canina-Type Meiosis.

Vozarova R, Herklotz V, Kovarik A, Tynkevich Y, Volkov R, Ritz C Front Plant Sci. 2021; 12:643548.

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The love life of a rose. A commentary on: 'Asymmetrical canina meiosis is accompanied by the expansion of a pericentric satellite in non-recombining univalent chromosomes'.

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Asymmetrical canina meiosis is accompanied by the expansion of a pericentromeric satellite in non-recombining univalent chromosomes in the genus Rosa.

Lunerova J, Herklotz V, Laudien M, Vozarova R, Groth M, Kovarik A Ann Bot. 2020; 125(7):1025-1038.

PMID: 32095807 PMC: 7262465. DOI: 10.1093/aob/mcaa028.