41 research outputs found
Inheritance and relationships of flowering time and seed size in kabuli chickpea
Flowering time and seed size are the important traits for adaptation in chickpea. Early phenology (time of flowering, podding and maturity) enhance chickpea adaptation to short season environments. Along with a trait of consumer preference, seed size has also been considered as an important factor for subsequent plant growth parameters including germination, seedling vigour and seedling mass. Small seeded kabuli genotype ICC 16644 was crossed with four genotypes (JGK 2, KAK 2, KRIPA and ICC 17109) to study inheritance of flowering time and seed size. The relationships of phenology with seed size, grain yield and its component traits were studied. The study included parents, F1, F2 and F3 of four crosses. The segregation data of F2 indicated flowering time in chickpea was governed by two genes with duplicate recessive epistasis and lateness was dominant to earliness. Two genes were controlling 100-seed weight where small seed size was dominant over large seed size. Early phenology had significant negative or no association (ICC 16644 × ICC 17109) with 100-seed weight. Yield per plant had significant positive association with number of seeds per plant, number of pods per plant, biological yield per plant, 100-seed weight, harvest index and plant height and hence could be considered as factors for seed yield improvement. Phenology had no correlation with yield per se (seed yield per plant) in any of the crosses studied. Thus, present study shows that in certain genetic background it might be possible to breed early flowering genotypes with large seed size in chickpea and selection of early flowering genotypes may not essentially have a yield penalty
Allelic relationships of flowering time genes in chickpea
Flowering time and crop duration are the most important traits for adaptation of chickpea (Cicer arietinum L.) to different agro-climatic conditions. Early flowering and early maturity enhance adaptation of chickpea to short season environments. This study was conducted to establish allelic relationships of the early flowering genes of ICC 16641, ICC 16644 and ICCV 96029 with three known early flowering genes, efl-1 (ICCV 2), ppd or efl-2 (ICC 5810), and efl-3 (BGD 132). In all cases, late flowering was dominant to early-flowering. The results indicated that the efl-1 gene identified from ICCV 2 was also present in ICCV 96029, which has ICCV 2 as one of the parents in its pedigree. ICC 16641 and ICC 16644 had a common early flowering gene which was not allelic to other reported early flowering genes. The new early flowering gene was designated efl-4. In most of the crosses, days to flowering was positively correlated with days to maturity, number of pods per plant, number of seeds per plant and seed yield per plant and negatively correlated or had no correlation with 100-seed weight. The double-pod trait improved grain yield per plant in the crosses where it delayed maturity. The information on allelic relationships of early flowering genes and their effects on yield and yield components will be useful in chickpea breeding for desired phenology
A DATA BASE FOR PREDICTING SOYBEAN PHENOLOGY
The quest for a better soybean phenology model continues, phenological behavior being a necessary part of any crop growth and yield simulation model. New and published data for soybean strains from different maturity groups sown at different dates and locations were analyzed for temperature and photoperiod effects on mainstem node appearance rates and on flowering, early pod fill, and maturity dates. Degree days were calculated from maximum and minimum weather station temperatures using 10℃ as the base temperature. When the maximum temperature exceeded 28℃, the difference between it and 28 was subtracted from the 24h degree day calculation. Photoperiods at floral initiation were estimated as those values that occurred 290 degree days before the first open flower, but those that occurred before the longest day of the year were set to the longest photoperiod for the latitude. Such methods for calculating degree days and photoperiods were arrived at from analyses of the literature and by trial and error. Numerous equations and plots are given for predicting the effects of photoperiod and temperature on soybean phenology of Maturity Groups 000-VII. Such information will be used in soybean management models and in planning further phenological research