4 research outputs found
Response of elite Kenyan finger millet (Eleusine coracana, L. Gaertn) genotypes to Ethrel application
Finger millet is a staple food crop of many communities in Africa. The crop is highly nutritious and has incredible grain storage quality. Limited research investment in finger millet in the past has resulted in poor yields and there are currently no commercial hybrids. We investigated the response of different finger millet genotypes (Okhale-1, Gulu-E, KACCIMMI-72, IE 2872, IE 4115 and U-15) to the application of a plant growth regulator hormone (Ethrel). Six elite Kenyan finger millet varieties with contrasting agronomic traits were crossed in a 6 x 6 diallel pattern. To enhance male sterility across female parents, we subjected the plants to Ethrel at concentrations of 1,500ppm, 1,750ppm and 2,000ppm against a 0ppm check. Dwarfing of sprayed plants that resulted in less lodging and ultimately higher yields were observed among plants sprayed with Ethrel at different concentrations. Ethrel application at 2,000ppm had the most dwarfing effect on plants while spraying plants with 1,500ppm of Ethrel resulted in increased grain weight. Although our results demonstrate overall positive effect of Ethrel on finger millet production, the optimum concentrations for more efficient hybridization will still need to be determined
Cheprot et Al_PHYSIOLOGICAL CHARACTERIZATION OF KENYAN SORGHUM LINES.pdf
Eighty nine Kenyan sorghum lines were screened for tolerance to aluminium toxicity in nutrient
solution. Relative net root growth; root tip aluminium content and variation in organic acid
exudation were used to determine the tolerance or sensitivity of the sorghum lines at 148 μM Al for
six days. The lines showed variable reduction in root growth under the Al stress. On the basis of
the relative net root growths, three lines were tolerant, nineteen were moderately tolerant and sixty
seven were sensitive to the Al stress. The tolerant lines secreted up to five times more citrate
compared to sensitive lines under the Al treatment. All the lines secreted extremely low quantities
of malate under aluminium stress despite a significant positive regression (R 2 = 0.83) between
malate secretion and relative net root growth. There was a negative regression between relative
net root growth and root aluminium concentration (R2 = -0.79) among the selected sorghum lines,
and the sensitive lines accumulated up to three times the amount of Al compared to the tolerant
lines.. The Al tolerant sorghum lines were selected for improved sorghum production in acid soil.
The objectives of this study were to (i) identify Al tolerant Kenyan sorghum lines, (ii) investigate
tolerance mechanisms employed by Kenyan sorghum lines against Al stress
Genetic Diversity and Population Structure of Acacia senegal (L) Willd. in Kenya
The level of genetic diversity and population structure of Acacia senegal variety kerensis in Kenya was examined using seven polymorphic nuclear microsatellite loci and two chloroplast microsatellite loci. In both chloroplast and nuclear datasets, high levels of genetic diversity were found within all populations and genetic differentiation among populations was low, indicating extensive gene flow. Analysis of population structure provided support for the presence of two groups of populations, although all individuals had mixed ancestry. Groups reflected the influence of geography on gene flow, with one representing Rift Valley populations whilst the other represented populations from Eastern Kenya. The similarities between estimates derived from nuclear and chloroplast data suggest highly effective gene dispersal by both pollen and seed in this species, although population structure appears to have been influenced by distributional changes in the past. The few contrasts between the spatial patterns for nuclear and chloroplast data provided additional support for the idea that, having fragmented in the past, groups are now thoroughly mixed as a result of extensive gene flow. For the purposes of conservation and in situ management of genetic resources, sampling could target a few, large populations ideally distributed among the spatial groups identified. This should ensure the majority of extant variation is preserved, and facilitate the investigation of variation in important phenotypic traits and development of breeding populations