Research Article
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Year 2019, Volume: 25 Issue: 1, 79 - 85, 13.03.2019
https://doi.org/10.15832/ankutbd.539005

Abstract

References

  • Ashri A (1998). Sesame breeding. Plant Breeding Reviews 16: 179-228
  • Ashri A (2007). Sesame (Sesamum indicum L.). In: R J Singh (Ed), Genetics Resources, Chromosome Engineering and Crop Improvement, Vol.4, Oilseed Crops, CRC Press, Boca Raton, pp. 231-289
  • Chowdhury S, Datta A K, Saha A, Sengupta S, Paul R, Maity S & Das A (2010). Traits influencing yield in sesame (Sesamum indicum L.) and multi locational trials of yield parameters in some desirable plant types. Indian Journal of Science and Technology 3: 163-166
  • Govidarasu R, Rathinam M & Sivasubramania P (1990). Genetic variability in sesamum (Sesamum indicum L.). The Madras Agricultural Journal 78: 450-452 Hahm T S, Park S J & Martin L Y (2009). Effects of germination on chemical composition and functional properties of sesame (Sesamum indicum L.) seeds. Bioresource Technology 100: 1643-1647
  • Harikumar K B, Sung B, Tharakan S T, Pandey M K, Joy B, Guha S, Krishnan S & Aggarwal B B (2010). Sesamin manifests chemopreventive effects through suppression of NF-KB-regulated cell survival, proliferation, invasion and angiogenic gene products. Molecular Cancer Research 8: 751-761
  • Hika G, Geleta N, Jaleta Z (2015). Genetic variability, heritability and genetic advance for the phenotypic traits in sesame (Sesamum indicum L.) populations from Ethiopia. Science, Technology and Arts Research Journal 4: 20–26
  • Hoballah A A (2001). Selection and agronomic evaluation of induced mutant lines of sesame. In: Van Zanten L. (ed.): Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Mtng. Vienna, IAEA: 137–149 IPGRI & NBPGR (2004). Descriptors for Sesame (Sesamum spp.), International Plant Genetic Resources Institute, Rome, Italy, and National Bureau of Plant Genetic Resources, New Delhi, India
  • Kang C W (2001). Breeding sesame for diseases and shatter resistant high yielding varieties with induced mutations. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 41-49
  • Khan N U, Marwat K B, Hassan B, Farhatullah G, Batool S, Makhdoom K, Ahmad W & Khan H U (2010). Genetic variation and heritability for cotton seed, fiber and oil traits in Gossypıum hirsutum L. Pakistan Journal of Botany 42: 615-625
  • Kumar S T (2010). Seed genetics in relation to seed yield sesame. In: D Bedigian (Ed), Sesame: The Genus Sesamum, Medicinal and Aromatic Plants-Industrial Profiles, CRC Press, Boca Raton, pp. 255-265
  • Langham D G (1946). Genetics of sesame, III. “Open sesame” and mottled leaf. Journal of Heredity 37: 149-152
  • Langham D R (2001). Shatter resistance in sesame. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 51-61
  • Langham D R & Wiemers T (2002). Progress in mechanizing sesame in the US through breeding. In: J Janickand & A Whipkey (Eds), Trends in New Crops and New Uses, American Society for Horticultural Science Press, Virginia, pp. 157-173
  • Mahmood T, Turner M, Stoddard F L & Javed M A (2004). Genetic analysis of quantitative traits in rice (Oryza sativa L.) exposed to salinity. Australian Journal of Agricultural Research 55: 1173-1181
  • Smith J D & Kinman M L (1965). The use of parent-offspring regression as an estimator of heritability. Crop Science 5: 595-596.
  • Steel R G D & Torrie J H (1980). Principles and procedures of statistics: A biometrical Approach. McGraw-Hill, New York
  • TSMS (2010). Turkish State Meteorological Service. http://www.dmi.gov.tr/en-US/forecast-cities.aspx?m=ANTALYA. (Erişim tarihi:10.10.2015)
  • Uzun B, Lee D, Donini P & Cagirgan M I (2003). Identification of a molecular marker linked to the closed capsule mutant trait in sesame using AFLP. Plant Breeding 122: 95–97
  • Uzun B, Ozbas M O, Canci H & Cagirgan M I (2004). Heterosis for agronomic traits in sesame hybrids of cultivars x closed capsule mutants. Acta Agriculturae Scandinavica, Section B - Soil and Plant Science 54: 108-112
  • Van Zanten L (2001). Sesame improvement by induced mutations: Results of the co-ordinated research project and recommendation for future studies. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 1-12
  • Weiss E A (1971). Castor, sesame and safflower. Barnes and Noble Inc, New York
  • Yol E, Karaman E, Furat S & Uzun B (2010). Assessment of selection criteria in sesame by using correlation coefficients, path and factor analyses. Australian Journal of Crop Science 4: 598-602.
  • Yol E, Toker C & Uzun B (2017). Inheritance of long and dense capsule characteristics in sesame. Turkish Journal of Field Crops 22: 8-13.

Inheritance of Indehiscent Capsule Character, Heritability and Genetic Advance Analyses in the Segregation Generations of Dehiscent x Indehiscent Capsules in Sesame

Year 2019, Volume: 25 Issue: 1, 79 - 85, 13.03.2019
https://doi.org/10.15832/ankutbd.539005

Abstract

The investigation was made to estimate heritability and genetic advance and thus understand the genetic behavior of indehiscent capsule character in sesame with the field experiments during three consecutive years. Muganli-57 (♀) parent with dehiscent capsule was crossed with ACS 344 (♂), an introduction material, which had indehiscent capsule character. The results in the F1 generation indicated that dehiscent capsule character was dominant over indehiscent capsule. In F2, 3:1 segregation ratio was monitored and further confirmed in F3 showing indehiscent capsule character was controlled by a single recessive gene. Heritability was estimated by parent-offspring regression and the data were collected in F1, F2 and F3 generations derived from the cross between dehiscent and indehiscent capsule types. Heritability estimates in narrow sense for number of branches, number of capsules per plant, 1000 seed weight and seed yield were low in indehiscent capsule types of F2. Genetic advance had also low values except for number of branches (30.79%). Whilst low values obtained for indehiscent capsule, dehiscent capsule types in F2 indicated high heritability for the characters studied (70.52-92.84%). Stem height to the first capsule and plant height were of high heritabilities in both capsule types of F2 and F3. Although indehiscent capsule types had low means and heritabilities due to pleiotropic effects, mutant cross had heterotic effect on dehiscent types for all the characters. This positive shift could be explained by additive gene effect and this information presented in this investigation was therefore highly beneficial for the genetic improvement of sesame and reaching to high yielding types. This research also provides an example that bad parent may have a good progeny. C

References

  • Ashri A (1998). Sesame breeding. Plant Breeding Reviews 16: 179-228
  • Ashri A (2007). Sesame (Sesamum indicum L.). In: R J Singh (Ed), Genetics Resources, Chromosome Engineering and Crop Improvement, Vol.4, Oilseed Crops, CRC Press, Boca Raton, pp. 231-289
  • Chowdhury S, Datta A K, Saha A, Sengupta S, Paul R, Maity S & Das A (2010). Traits influencing yield in sesame (Sesamum indicum L.) and multi locational trials of yield parameters in some desirable plant types. Indian Journal of Science and Technology 3: 163-166
  • Govidarasu R, Rathinam M & Sivasubramania P (1990). Genetic variability in sesamum (Sesamum indicum L.). The Madras Agricultural Journal 78: 450-452 Hahm T S, Park S J & Martin L Y (2009). Effects of germination on chemical composition and functional properties of sesame (Sesamum indicum L.) seeds. Bioresource Technology 100: 1643-1647
  • Harikumar K B, Sung B, Tharakan S T, Pandey M K, Joy B, Guha S, Krishnan S & Aggarwal B B (2010). Sesamin manifests chemopreventive effects through suppression of NF-KB-regulated cell survival, proliferation, invasion and angiogenic gene products. Molecular Cancer Research 8: 751-761
  • Hika G, Geleta N, Jaleta Z (2015). Genetic variability, heritability and genetic advance for the phenotypic traits in sesame (Sesamum indicum L.) populations from Ethiopia. Science, Technology and Arts Research Journal 4: 20–26
  • Hoballah A A (2001). Selection and agronomic evaluation of induced mutant lines of sesame. In: Van Zanten L. (ed.): Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Mtng. Vienna, IAEA: 137–149 IPGRI & NBPGR (2004). Descriptors for Sesame (Sesamum spp.), International Plant Genetic Resources Institute, Rome, Italy, and National Bureau of Plant Genetic Resources, New Delhi, India
  • Kang C W (2001). Breeding sesame for diseases and shatter resistant high yielding varieties with induced mutations. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 41-49
  • Khan N U, Marwat K B, Hassan B, Farhatullah G, Batool S, Makhdoom K, Ahmad W & Khan H U (2010). Genetic variation and heritability for cotton seed, fiber and oil traits in Gossypıum hirsutum L. Pakistan Journal of Botany 42: 615-625
  • Kumar S T (2010). Seed genetics in relation to seed yield sesame. In: D Bedigian (Ed), Sesame: The Genus Sesamum, Medicinal and Aromatic Plants-Industrial Profiles, CRC Press, Boca Raton, pp. 255-265
  • Langham D G (1946). Genetics of sesame, III. “Open sesame” and mottled leaf. Journal of Heredity 37: 149-152
  • Langham D R (2001). Shatter resistance in sesame. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 51-61
  • Langham D R & Wiemers T (2002). Progress in mechanizing sesame in the US through breeding. In: J Janickand & A Whipkey (Eds), Trends in New Crops and New Uses, American Society for Horticultural Science Press, Virginia, pp. 157-173
  • Mahmood T, Turner M, Stoddard F L & Javed M A (2004). Genetic analysis of quantitative traits in rice (Oryza sativa L.) exposed to salinity. Australian Journal of Agricultural Research 55: 1173-1181
  • Smith J D & Kinman M L (1965). The use of parent-offspring regression as an estimator of heritability. Crop Science 5: 595-596.
  • Steel R G D & Torrie J H (1980). Principles and procedures of statistics: A biometrical Approach. McGraw-Hill, New York
  • TSMS (2010). Turkish State Meteorological Service. http://www.dmi.gov.tr/en-US/forecast-cities.aspx?m=ANTALYA. (Erişim tarihi:10.10.2015)
  • Uzun B, Lee D, Donini P & Cagirgan M I (2003). Identification of a molecular marker linked to the closed capsule mutant trait in sesame using AFLP. Plant Breeding 122: 95–97
  • Uzun B, Ozbas M O, Canci H & Cagirgan M I (2004). Heterosis for agronomic traits in sesame hybrids of cultivars x closed capsule mutants. Acta Agriculturae Scandinavica, Section B - Soil and Plant Science 54: 108-112
  • Van Zanten L (2001). Sesame improvement by induced mutations: Results of the co-ordinated research project and recommendation for future studies. In: L Van Zanten (Ed), Sesame Improvements by Induced Mutations, Proc. Final FAO/IAEA Co-ord. Res. Meeting, IAEA, Vienna, pp. 1-12
  • Weiss E A (1971). Castor, sesame and safflower. Barnes and Noble Inc, New York
  • Yol E, Karaman E, Furat S & Uzun B (2010). Assessment of selection criteria in sesame by using correlation coefficients, path and factor analyses. Australian Journal of Crop Science 4: 598-602.
  • Yol E, Toker C & Uzun B (2017). Inheritance of long and dense capsule characteristics in sesame. Turkish Journal of Field Crops 22: 8-13.
There are 23 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Makaleler
Authors

Engin Yol 0000-0002-3152-6078

Bulent Uzun 0000-0001-6228-9629

Publication Date March 13, 2019
Submission Date December 6, 2017
Acceptance Date March 20, 2018
Published in Issue Year 2019 Volume: 25 Issue: 1

Cite

APA Yol, E., & Uzun, B. (2019). Inheritance of Indehiscent Capsule Character, Heritability and Genetic Advance Analyses in the Segregation Generations of Dehiscent x Indehiscent Capsules in Sesame. Journal of Agricultural Sciences, 25(1), 79-85. https://doi.org/10.15832/ankutbd.539005

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