Genetic variability studies for yield and yield components in sunflower (<i>Helianthus annuus</i> L.)

Supriya, S.M.; Kulkarni, Vikas; Goud, I. Shanker; Lokesha, R.; Govindappa, M.

doi:10.5958/0975-928x.2016.00096.x

Cited by 13 publications

(22 citation statements)

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“…Plant height exhibited highly significant positive correlation with head diameter (0.5555, 0.6419), test weight (0.4133, 0.4299), volume weight (0.4482, 0.4657) and seed yield per plant (0.6449, 0.7122) both at phenotypic and genotypic level (Tables 4 and 5). Similar findings were made by Vanisree et al, (1988), Chidambaram and Sundaresan (1990), Uttam et al, (2006), Kaya et al, (2007) and Supriya et al, (2016).…”

Section: Plant Height (Cm)supporting

confidence: 79%

Quantitative Analysis of Oil Yield and Its Components in Newly Developed Hybrids of Sunflower (Helianthus annuus L.)

Supriya¹,

Kulkarni²,

Ranganatha³

et al. 2017

Int.J.Curr.Microbiol.App.Sci

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Section: Plant Height (Cm)supporting

confidence: 79%

Quantitative Analysis of Oil Yield and Its Components in Newly Developed Hybrids of Sunflower (Helianthus annuus L.)

Supriya¹,

Kulkarni²,

Ranganatha³

et al. 2017

Int.J.Curr.Microbiol.App.Sci

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“…It is apparent from the pooled data in Table (4) that significant differences were detected among the ten tested sunflower genotypes for all studied traits, indicated that there is valuable genetic variation in these genotypes to warrant selection for improvement sunflower crop. Similar significant genotypic effects for all studied traits were reported by Supriya et al (2016), Neelima et al (2016) and Supriya et al (2017). Irrespective of pollination methods imposed, 'Sakha 53' (21.55 cm) followed by 'L120' (19.83 cm) behaved as the largest head diameter; 'L120' (534.95) followed by 'L880' (503.37) gave more filled seeds per head; 'L120' (80.07 %) followed by 'L92' (76.59 %) had the highest proportion of seed setting; 'L355' (6.76 g) followed by 'L167' (6.73 g) possessed the biggest mass of 100-seed; 'L355' (538.58 mg) followed by ''L880 (535.33 mg) had the biggest mass of kernel; 'L880' (199.71 mg) followed by 'L355' (198.61 mg) expressed the highest mass of hull; the highest proportion of hull was detected in 'L355' (1.07 %) followed by 'L167' (0.82 %); 'L120' (2.98 %, 37.28 g, 1022.95 kg and 42.86 %) followed by 'L92' (2.83 %, 33.83 g, 890.05 kg and 40.21 %) behaved as the largest ratio of Kernel to hull, seed mass per plant, seed yield per fed and seed oil content, respectively.…”

Section: Genotypic Effectssupporting

confidence: 84%

“…This indicated that tested sunflower genotypes significantly differed from pollination method to another for all studied traits, hence it was considered as important interaction to discussion. Similar significant interactive effect of pollination methods with sunflower genotypes were reported by Supriya et al (2016), Neelima et al (2016) and Supriya et al (2017).…”

Section: Analysis Of Variancesupporting

confidence: 81%

“…Successful sunflower breeding program depends on magnitude of genetic variability in the breeding material and knowledge of selection criteria would be effective in improving seed yield. In this respect, considerable amount of genetic variability might be affect days to first flowering, days to full flowering, plant height, stem diameter, autogamy percentage, self-compatibility percentage, head diameter, number of filled seeds per head, number of unfilled seeds per head, total number of seeds per head, seed setting percentage, 100-seed mass, kernel mass (mg), hull mass (mg), hull content (%), kernel to hull ratio, seed mass per plant, seed yield per fed and seed oil content as reported by Sameena (2003), Supriya et al (2016), Neelima et al (2016) and Supriya et al (2017). High heritability coupled with high percentage of genetic advance were observed for head diameter, seed mass per plant, 100-seed mass, pollen production per plant, plant height and percentage of hull mass as reported by by Khan and Muhammad (2007), Kalukhe et al (2010), Sudrik et al (2014) and Seyed et al (2014), Sheshaiah and Shankargoud (2015), Supriya et al (2016), Dudhe et al (2017) and Baraiya et al (2018).…”

Section: Introductionmentioning

confidence: 99%

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Genetic variability and selection criteria of some sunflower genotypes under different pollination methods

Abdelsatar

Ahmed

Ibrahim

2020

AAS

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<p>To determinate self-compatible genotypes for increasing autogamy yielded, the ten sunflower genotypes were sown under four pollination methods i.e., open-, self-, hand- and sib-pollinations in a randomized complete block design replicated thrice at Kafr-El-Hamam Agricultural research Station, Sharkia Governorate, Agricultural Research Center, Egypt during 2018 and 2019 summer seasons. Significant variation existed for different pollination treatments, genotypes and their interactions for all studied traits. Among the treatments, open pollination followed by sibbing one was regarded as the best pollination treatment for head diameter, number of filled seeds per head, percentage of seed setting , kernel to hull ratio, seed mass per plant, seed yield per fed and seed oil content. Autogamy studies revealed that ‘L120’ followed by ‘L92’ and ‘L880’ recorded higher proportion of autogamy and self-compatibility. Preferred improvement of seed mass per plant may be achieved through selecting genotypes having the largest head diameter, bigger number of filled seeds per head, the highest proportion of seed setting and the heaviest seed, kernel and hull mass as proven by high phenotypic and genotypic coefficient of variation and high heritability coupled with high genetic advance (as % of mean) as well as correlation and path analyses at both phenotypic and genotypic levels.</p>

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“…The heritability estimates help in determining the relative amount of heritable portion in variation and thus help a plant breeder in selecting the elite inbreds from a diverse population. Heritability estimates in conjunction with genetic advance are more helpful in predicting the genetic gain under selection than heritability alone (Supriya et al 2016). Therefore, an attempt was made in the present investigation to assess the variability, heritability and genetic advance studies in twenty four hybrids and ten parents for eighteen characters.…”

mentioning

confidence: 99%

Genetic variability studies for yield and its component traits in newly developed sunflower (Helianthus annuusL.) hybrids

Varalakshmi

Neelima²,

Reddy³

et al. 2020

EJPB

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The present study was conducted in order to estimate the genetic variability and variability parameters among the parental lines and crosses for 18 characters in sunflower. The investigation was carried out at Regional Agricultural Research Station, Nandyal during rabi, 2018-19, in a Randomized block design with two replications. ANOVA studies reported highly significant differences for all the traits. High GCV and PCV recorded for oil yield, leaf area index, seed yield, autogamy per cent, number of seeds per head and specific leaf area indicating more variability of these traits and less influence of environment. High heritability and genetic advance noted for the traits viz., leaf area index, plant height, specific leaf area, the number of leaves per plant, oil yield, seed set per cent, seed yield, 100 seed weight, the number of seeds per head, head diameter and autogamy per cent indicates these traits were governed by additive gene action and selection will be rewarding for the crop improvement. The traits days to 50 per cent flowering, oil content, volume weight, SPAD chlorophyll meter reading and hull content reported high heritability coupled with moderate genetic advance indicating the role of both additive and non-additive gene action and population improvement by reciprocal recurrent selection can be useful.

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Genetic variability studies for yield and yield components in sunflower (Helianthus annuus L.)

Cited by 13 publications

References 0 publications

Quantitative Analysis of Oil Yield and Its Components in Newly Developed Hybrids of Sunflower (Helianthus annuus L.)

Quantitative Analysis of Oil Yield and Its Components in Newly Developed Hybrids of Sunflower (Helianthus annuus L.)

Genetic variability and selection criteria of some sunflower genotypes under different pollination methods

Genetic variability studies for yield and its component traits in newly developed sunflower (Helianthus annuusL.) hybrids

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