Affiliation:
1. N.I. Vavilov All-Russian Institute of Plant Genetic Resources
2. N.I. Vavilov All-Russian Institute of Plant Genetic Resources
3. N.I. Vavilov All-Russian Institute of Plant Genetic Resources, Dagestan Experimental Station of VIR
Abstract
The search for new, effective methods for broadening the genetic polymorphism of the original breeding material remains one of important problems of hybrid maize breeding. Globally, breeding of commercial maize varieties and hybrids is carried out using diploid genotypes, whereas tetraploid sources of initial material and wild relatives of maize are poorly involved in the breeding process. The direct heteroploid crosses between diploid and tetraploid genotypes lead to the formation of weakly fertile or completely sterile triploid hybrids, which are cytologically unstable in subsequent generations. Tetraploid maize (2n=40), as well as some wild relatives with tetraploid genome, such as Zea perennis Hitchk. (2n=40) and Tripsacum dactiloides (L.) L. (2n=72), are attractive to breeders as sources for improving economically valuable traits. The attractiveness of resynthesized diploid lines is explained by the fact that unequal crossing over between homologous chromosomes forming polyvalent associations of chromosomes, more chromosomal rearrangements occur in tetraploids than in diploid genotypes, the chromosomes of which form bivalents. Synthetic tetraploid populations of maize and its tetraploid wild relatives have great potential of variability for improving diploid maize. The authors proposed a direct method for the resynthesis of doubled haploid lines using haploid induction and an indirect method for obtaining diploid lines by heteroploid crossing and subsequent segregation of a triploid hybrid in the progeny. The method of resynthesizing the tetraploid maize genome to diploid serves as an ideal model for studying the processes of crossing over in meiosis between multivalent associations of homologous chromosomes; it is promising for obtaining diploid lines with an increased frequency of recombination between the homologous chromosomes of different genomes, combined into a common one, and can serve as a source for obtaining aneuploid series.
Publisher
FSBSI FRC N.I. Vavilov All-Russian Institute of Plant Genetic Resources
Reference21 articles.
1. Bennett M.D., Leitch I.J. Plant DNA C-values database (release 2.0, Jan. 2003). Available from: www.rbgkew.org.uk/cval/homepage.html [accessed Jan. 10, 2023].
2. De Storme N., Mason A. Plant speciation through chromosome instability and ploidy change: Cellular mechanisms, molecular factors and evolutionary relevance. Current Plant Biology. 2014;1:10-33. DOI: 10.1016/j.cpb.2014.09.002
3. Deimling S., Röber F., Geiger H.H. Methodik und Genetik der in-vivo-Haploideninduktion bei Mais. Vorträge für Pflanzenzüchtung. 1997;38:203-204. [in German]
4. Food and Agriculture Organization of the United Nations (FAO): [website]. URL: https://www.fao.org [accessed Jan. 10, 2023].
5. Kellogg E.A., Bennetzen J.L. The evolution of nuclear genome structure in seed plants. American Journal of Botany. 2004;91(10):1709-1725. DOI: jstor.org/stable/4123862