Transfer of genes between plant species has played an important role in crop improvement for many decades. Useful traits such as resistance to disease, insects, and stress have been transferred to crop varieties from noncultivated plants. Recombinant DNA methods greatly extend (even outside the plant kingdom) the sources from which genetic information can be obtained for crop improvement. Gene transfer systems based on recombinant DNA are available for several crop species and are under development for others. The concerted use of traditional and more recent methods for plant genetic manipulation will contribute to crop improvement.
Three weedy amaranths (Amarantkus hybridus, A. retroflexus and A. powellii) from nine California sites, three domesticated species (A. caudatus, A. hypochondriacus and A. cruentus) from the USDA plant inventory as well as other sources and a naturally-occurring crop-weed hybrid were studied for numerical taxonomy using morphological and allozyme variation data. The crop and weedy species groups were easily separated and the hybrid populations were found to be intermediate. Surprisingly, very little intraspecific variation was present. Crop, weed and hybrid amaranths were also compared for their yielding ability, harvest index, seed efficiency of grain production and protein, popping quality and other agronomic traits. Although field plot yields were similar among the three groups of species (700 Kg/ha seed without fertilizer treatment and water, ranging to 3000 Kg/ha with fertilizer applications of 170 Kg N/ha, and abundant water), the harvest index of the weedy group was much higher (25-40%) than the domesticated species (10-15%). The allocation of biomass to seed production is positively correlated with seed yield in the domesticated but not in the weedy types, whereas the percentages of biomass as stem material and as seeds are negatively correlated. Several weedy and crop characteristics together should provide the basis of new improved cultivars through genetic recombination and selection.
The genetic control of breeding system in a population of grain amaranth is described here by the estimates of outcrossing rate variation among individuals and their response to mass selection. In the first generation (So), a single morphological marker locus (R/r) controlling plant pigmentation was used for the estimation of outcrossing rate. A mixture ofgenotypes RR (red) and rr (green) mixed in equal proportions was grown and all rr plants were progeny-tested for estimating the outcrossing rate (t), using the relationship t = H / p, where H = proportion of heterozygotes (Rr) in the progeny, and p = frequency of alleleR. A full range (0 to 100%) of outcrossing rates was found in the first generation, with [ = 0.31, 6t = 0.25, and the distribution was significantly skewed toward high outcrossing.A bidirectional mass selection experiment was initiated for high and low outcrossing rates. In the Hi and Lo lines (Generation $1), the rate of outcrossing was estimated using the R locus in addition to two other completely dominant morphological markers (B, GI). Reidtive sex ratios in the monoecious inflorescences of selected lines were estimated by the number of male flowers per glomerule. Outcrossing rate was significantly different between the Hi and Lo lines, and Lo line exhibited much higher male fertility than the Hi line. Such a response to selection indicated a polygenic control of sex expression, and consequently, of the potential for outcrossing in this population. In the second generation ($2), selection was based on the number of male flowers/glomerule as an index of outcrossing ability. Differences in sex expression between the Hi and Lo lines in $2 generation had 1.0 male flower/ glomerule, while the Hi selection individuals had more or less rectangular distribution from 0.1 to 1.0 male flowers/glomerule. Thus, breeding system in amaranth, as represented by the sex ratios within glomerules and the outcrossing rate parameters, responded to bidirectional selection. Such a genetic component of variation in breeding system has significant implications in the evolution of amaranth species and landraces under domestication.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.