Genome elimination during microsporogenesis in two pentaploid accessions of Brachiaria decumbens (Poaceae)

G.C.L. Ricci, M.S. Pagliarini and C.B. Valle
Published December 7, 2010
Genet. Mol. Res. 9 (4): 2364-2371 (2010)
DOI 10.4238/vol9-4gmr919

About the Authors
G.C.L. Ricci, M.S. Pagliarini and C.B. Valle

Corresponding author: 
M.S. Pagliarini
E-mail: mspagliarini@uem.br

ABSTRACT

Polyploidy is a prominent and significant force in plant evolution, taking place since ancient times and continuing until today. Recent cytogenetic studies in the genus Brachiaria using germplasm collected from wild African savannas in the 1980s revealed that most species and accessions within species are polyploid. Diploid, tetraploid, and pentaploid accessions have been found. We found asynchronous meiosis during microsporogenesis, followed by genome elimination, in two pentaploid (2n = 5x = 45) accessions (D53 and D71) of a hardy, invasive pasture grass, introduced from Africa to Brazil, Brachiaria decumbens. In these accessions, chromosomes paired as 18 bivalents and nine univalents during diakinesis, suggesting that these accessions resulted from a recent event of natural hybridization. The lack of chromosome associations in the genomes suggests that these accessions resulted from hybridization between two genotypes that are not closely related, with low genome affinity and with different meiotic rhythms. This supposition is reinforced by the meiotic behavior of the nine univalents, which were always laggard in relation to the other chromosomes and eliminated as micronuclei in microspores. The behavior of these accessions, which have an odd level of ploidy and confirmed genome elimination, supports the general assumption that a polyploid accession can undergo a new event of polyploidization by natural hybridization (neopolyploidyzation). This evidence for natural hybridization in Brachiaria shows that this is a wild genus in an ongoing evolutionary process.

Key words: Brachiaria decumbens; Natural hybridization; Polyploidy; Genome elimination; Microsporogenesis; Evolution.

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