ABSTRACT
The F2 generations from two maize crosses were used to compare the ability of RAPD and RFLP marker systems to create a genetic linkage map. Both RFLPs and RAPDs were shown to provide Mendelian-type markers. Most of the RFLPs (80%) could be placed with a good level of certainty (LOD>4) on the genetic linkage map. However, because of their dominant nature, only between 37% and 59% of the RAPDs could be placed with such a LOD score. The use of combined data from RFLPs and RAPDs increases the level of information provided by RAPDs and allows the creation of a combined RFLP/RAPD genetic linkage map. Thus, the RAPD technique was found to be a powerful method to provide improved probes coverage on a previously created RFLP map and to locate markers linked to chromosomal regions of interest.
ABSTRACT
In order to map the genes conditioning the induction of embryos during our anther culture process, we evaluated F2 plants from three different crosses for their anther culture ability and also performed RFLP analysis on these plants. The results showed that six chromosomal regions appear to be associated with the ability to induce embryo-like structures from maize microspores. These regions are located on chromosomes 1 (two regions), 3, 5, 7, and 8. Some of these chromosomes are identical to those found in previous studies and we have localized the regions more precisely. Notably, all chromosome regions identified, except one, are near viviparous mutant loci. Since the viviparous mutations are known to involve the plant hormone abscisic acid (ABA), these results suggest that ABA or its antagonist, gibberellic acid (GA3), might somehow be related to anther culture ability. We also propose some combinations of probes to screen for anther culture ability in the three genotypes studied.
ABSTRACT
Anther-derived calli of corn were treated with 10 µM pronamide for 2, 3 and 4 days. The ploidy level of the calli was then evaluated using flow cytometry, at different times after the treatment. Untreated haploid calli did not change in ploidy level for 97 days but by 466 days, there were up to 50% diploid or higher ploidy cells thus showing that spontaneous doubling may occur during corn calli subculture with this genotype. Pronamide treatment did increase the percentage of diploid and tetraploid cells and by 466 days, all of the lines showed an additional change toward higher ploidy levels. This change may be due to spontaneous chromosome doubling or to differential cell cycle times of cells with different ploidy levels. The ploidy level of plants regenerated from the cultures was determined by counting the guard cell chloroplast numbers and the correlation with the ploidy level of the cultures was r(2)=0.84. These studies show that pronamide treatments can increase haploid maize callus chromosome numbers and that spontaneous chromosome doubling can occur with time in maize callus.
