Chromosome pairing and chiasma frequency were studied in bread wheat euhaploids (2n = 3x = 21; ABD genomes) with and without the major pairing regulatorPh1. This constitutes the first report of chromosome pairing relationships among the A, B, and D genomes of wheat without the influence of an alien genome. AllPh1 euhaploids had very little pairing, with 0.62-1.05 rod bivalents per cell; ring bivalents were virtually absent and mean arm-binding frequency (c) values ranged from 0.050 to 0.086. In contrast, theph1b euhaploids had extensive homoeologous pairing, with chiasma frequency 7.5-11.6 times higher than that in thePh1 euhaploids. They had 0.53-1.16 trivalents, 1.53-1.74 ring bivalents, and 2.90-3.57 rod bivalents, withc from 0.580 to 0.629. N-banding of meiotic chromosomes showed strongly preferential pairing between chromosomes of the A and D genomes; 80% of the pairing was between these genomes, especially in the presence of theph1b allele. The application of mathematical models to unmarked chromosomes also supported a 2∶1 genomic structure of theph1b euhaploids. Numerical modeling suggested that about 80% of the metaphase I association was between the two most related genomes in the presence ofph1b, but that pairing under Ph1 was considerably more random. The data demonstrate that the A and D genomes are much more closely related to each other than either is to B. These results may have phylogenetic significance and hence breeding implications.
The relationship between tillering in space‐planted early generation populations and in close‐planted commercial‐type stands of wheat (Triticum aestivum L.) was investigated over a 5‐year period. The primary objective was to determine if this relationship is strong enough to justify selection for tillering type in spaced populations. Secondary objectives were to examine tillering‐ yield relationships and possible differences in tiller survival among wheat genotypes. Four winter and two spring wheat cultivars with known tillering differences in densely‐seeded stands maintained their relative rankings when grown in spaced plantings. However, when F5 plants selected for high or low tillering in spaced populations were subsequently grown in densely‐sown F6 plant‐rows, little relationship was observed between tillering characteristics in the two planting densities. In attempting to explain the divergent results it is theorized that tillering differences among the cultivars, which had exhibited these differences over many years and environments, were largely genetic and would, therefore, likely persist regardless of planting density. Conversely, we suspect that much of the tillering variation observed among the spaced F5 plants was non genetic and would lack consistency under dense seeding. The relationship between tillering in spaced and close plantings appears to be further complicated by the differential ability of genotypes to mature spike‐bearing tillers, as a percentage of total tillers initiated. The cultivars we studied veried widely in the efficiency with which they matured fertile tillers in dense plantings. In only two of eight crosses did we observe a significant association between degree of tillering in space‐planted F5's and in their densely‐seeded F6 plant‐rows. Consequently, tillering differences in space‐planted early generation wheat populations do not appear to provide a reliable selection criterion. We observed no consistency between grain yield and degree of tillering. Other yield components largely compensated for variation in tiller number, with kernels per spike having a greater effect than kernel weight.
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