Sakr, H. (2009). COMBINING ABILITY AND TYPE OF GENE ACTION FOR GREEN FODDER YIELD AND IT'S COMPONENTS IN SOME TEOSINTE MAIZE HYBRIDS.. Journal of Agricultural Chemistry and Biotechnology, 34(12), 10825-10836. doi: 10.21608/jacb.2009.99337
H. O. Sakr. "COMBINING ABILITY AND TYPE OF GENE ACTION FOR GREEN FODDER YIELD AND IT'S COMPONENTS IN SOME TEOSINTE MAIZE HYBRIDS.". Journal of Agricultural Chemistry and Biotechnology, 34, 12, 2009, 10825-10836. doi: 10.21608/jacb.2009.99337
Sakr, H. (2009). 'COMBINING ABILITY AND TYPE OF GENE ACTION FOR GREEN FODDER YIELD AND IT'S COMPONENTS IN SOME TEOSINTE MAIZE HYBRIDS.', Journal of Agricultural Chemistry and Biotechnology, 34(12), pp. 10825-10836. doi: 10.21608/jacb.2009.99337
Sakr, H. COMBINING ABILITY AND TYPE OF GENE ACTION FOR GREEN FODDER YIELD AND IT'S COMPONENTS IN SOME TEOSINTE MAIZE HYBRIDS.. Journal of Agricultural Chemistry and Biotechnology, 2009; 34(12): 10825-10836. doi: 10.21608/jacb.2009.99337
COMBINING ABILITY AND TYPE OF GENE ACTION FOR GREEN FODDER YIELD AND IT'S COMPONENTS IN SOME TEOSINTE MAIZE HYBRIDS.
Although there are many forage crops valid in our country but the forage yield of maize (Zea mays L.) a fodder crop popular because of its earliness succulence and high yield. It could be increased if the tillering habit of teosinte (zea mexican) transferred to maize through hybridization breeding program. In this, investigation three lines of teosinte, which were derived from selection among segregating generations of three crosses. The three lines of teosinte were crossed by three genotypes of maize, inbred line 34 , inbred line 63, from National Maize Research Program and single cross 30k8 (commercial) to produce nine crosses at Serw Agricultural Research station in 2007 growing season. The nine crosses and their parents were evaluated during 2008 and 2009 seasons at Serw Agricultural Research. The studied traits were number of tillers per plant, number of leaves per plant, plant height, leaves weight to stems weight ratio, green fodder yield per plant, dry fodder yield per plant and digestible protein percentage. The data were subjected to biometrical analyses and the obtained results could be summarized in the following: Significant mean squares for crosses and tester (maize) for all studied traits were observed. Mean squares of line (teosinte) is not significant for all studied traits except for L/S ratio and green fodder yield in the first cut. In addition, mean squares of lines x testers interactions were significant and highly significant in most occasions for all studied traits except for number of tillers per plant and L/S ratio. Years, crosses by years, tester (maize) x years and L x T x Y interaction were significant in most occasions. There was no specific parents exhibited highest mean through the three cuts with respect to most of studied traits. However, line-3 of teosinte , was the best parent for number of tillers per plant , L/S ratio, numbers of leaves per plant , green fodder yield and dry fodder yield per plant through the three cuts. On the other hand, the cross L1xT1 followed by L3xT1 were the best combinations for green fodder yield per plant as a total of three cuts. In general, the over all means of crosses exceeded their parents except for number of tillers per plant and number of leaves per plant. The parental inbred lines that exhibited desirable general combining ability (GCA) effects were L1 for number of leaves per plant, L/S ratio and dry fodder yield per plant. In addition, L-2 for dry fodder yield per plant and digestible protein and L-3 for dry fodder yield per plant. Generally, these inbred lines could be recommended for advanced stage of evaluation by teosinte and teosinte x maize program. Line 34(tester-1) was good general combiner for green fodder yield per plant, dry fodder yield per plant and digestible protein percentage while line 63( tester-2) was a good general combiner for number of tillers per plant, number of leaves per plant, green fodder yield per plant, dry fodder yield per plant and digestible protein percentage. The highest SCA effects were observed in the crosses L1xT3, L2xT1, L2xT3 and L3xT1 for dry fodder yield per plant and L1xT1 and L2xT2 for digestible protein percentage. Estimation of general combining ability (σ2GCA) for maize (tester) higher in magnitude than those of (σ2GCA) for teosinte (line) for all studied traits. So that the contribution of maize were higher than the contribution of teosinte for all studied traits. General combining ability variance components (σ2GCA) was larger than that of specific combining ability variance (σ2SCA) for all studied traits indicating that additive genetic variance played Sakr, H. O. 10826 the major role than non-additive gene action in the inheritance of these traits. The variance of general combining ability interaction with years (σ2GCA x Y) was higher than the variance of specific combining ability interaction with years (σ2SCA x Y) for most traits these indicating that additive type of gene action was more affected by environmental conditions than non-additive effects. Significant positive correlations were observed among all studied traits. Therefore, the selection for one of these traits will be associated with the improvement of the other traits during the selection program. In conclusion, from the previous results, it could be recommended that, the best crosses with highest SCA effects should be used as started materials for selection breeding program to important fodder yield components.
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