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The using of biotechnology in cultivar breeding of Cucurbita vegeteble species

Year 2017, Volume: 46 Issue: 2, 39 - 49, 08.01.2018

Abstract

Compared to conventional breeding methods, biotechnology is approved a more effective crop improvement technique, requiring only a short time to develop a new variety. Thus, biotechnogical breeding methods are distinguished in current breeding efforts. In view of this concept, this presented study aimed to provide an overview of biotechnology–based approaches in Cucurbita breeding programs. In this way, some biotechnological breeding methods (dihaploidization, interspecific hybridization, regeneration, protoplast culture, recombinant DNA technology, molecular techniques) and their applications were discussed. The results of study could provide a different perspective to Cucurbita breeders for the improvement of new varieties with desirable agronomic and economic traits.

References

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  • Aggour, A. R., L. A. Badr and M. M. Ashry, 1999. Biotechnological Studies on Interspecific Crosses among Some Cucurbita Species. First International Conference in Egypt, on Plant Tissue Culture and its Application 255–275.
  • Ananthakrishnan, G., X. Xia, C. Elman, S. Singer, H. S. Paris, A. Gal–on and V. Gaba, 2003. Shoot Production in Squash (Cucurbita pepo) by in vitro Organogenesis. Cell Biology and Morphogenesis.
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  • Balkaya, A., E. S. Kurtar, R. Yanmaz ve M. Ozbakır, 2005. Karadeniz Bölgesinde Kışlık Kabak Türlerinde (Kestane Kabağı, Cucurbita maxima Duchesne ve Balkabağı, Cucurbita moschata Duchesne) Gen Kaynaklarının Toplanması, Karakterizasyonu ve Değerlendirilmesi. TÜBİTAK 104O144 nolu Proje Sonuç Raporu 160s.
  • Baranek, M., G. Stift, J. Vollmann and T. Lelly, 2000. Genetic Diversity within and between the Species Cucurbita pepo, C. moschata and C. maxima as Revealed by Rapd Markers. Cucurbit Genetics Cooperative Report 23:73–77.
  • Berber, M., 2009. Kabuksuz Çekirdek Kabaklarında (Cucurbita pepo L. var. styriaca) Işınlanmış Polenle Tozlama Yöntemiyle Haploid Üretimi (Yüksek Lisans Tezi). Çukurova Üniversitesi Fen Bilimleri Enstitüsü Biyoteknoloji Anabilim Dalı, 62 s.
  • Blanca, J., J. Canizares, C. Roig, P. Ziarsolo, F. Nuez and B. Pico, 2011. Transcriptome Characterization and High Throughput SSRs and SNPs Discovery in Cucurbita pepo (Cucurbitaceae). BMC Genomics 12:1–15.
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  • Çağlar, G. ve S. Bağcı, 2004. Bazı Cucumis Türleri Arasındaki Melezlemelerde Embriyo Kurtarma Yoluyla in vitro Hibrit Bitki Regenerasyonu. Akdeniz Üniversitesi Ziraat Fakültesi Dergisi 17(2):175–182.
  • Dumas De Vaulx, R. and D. Chambonnet, 1986. Obtention of Embryos and Plants from in vitro Culture of Unfertilized Ovules of Cucurbita pepo. In: Genetic Manipulation in Plant Breeding. W. Horn, C. J. Jensen, W. Odenbach, O. Schieder (eds), Proc. International Symposium Eucarpia, 8–12 Sept. 1985, Berlin. 295–297.
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  • Ferriol, M., B. Pico and F. Nuez, 2003. Genetic Diversity of a Germplasm Collection of Cucurbita pepo using SRAP and AFLP Markers. Theoretical and Applied Genetics 107:271–282.
  • Ferriol, M., B. Pico, P. Fernandez and F. Nuez, 2004a. Molecular Diversity of a Germplasm Collection of Squash (Cucurbita moschata) Determined by SRAP and FLP Markers. Crop Science 44:653–664.
  • Ferriol, M., B. Pico and F. Nuez, 2004b. Morphological and Molecular Diversity of a Collection of Cucurbita maxima Landraces. Journal of the American Society for Horticultural Science 129(1):60–69.
  • Gajdova J., A. Lebeda and B. Navrátilová, 2004. Protoplast Cultures of Cucumis and Cucurbita spp. In: Lebeda A., Paris H. S. (eds), Progress in Cucurbit Genetics and Breeding Research. Proceedings of Cucurbitaceae 2004, the 8th Eucarpia Meeting on Cucurbit Genetics and Breeding. Palacký University in Olomouc, Olomouc: 441–454.
  • Gajdova, J., B. Navrátilová, J. Smolná and A. Lebeda, 2007. Effect of Genotype, Source of Protoplasts and Media Composition on Cucumis and Cucurbita Protoplast Isolation and Regeneration. Acta Horticulturae 731:89–94.
  • Gémes Juhász, A., G. Venczel and P. Balogh, 1997. Haploid Plant Induction in Zucchini (Cucurbita pepo L. convar. giromontiina Duch) and in Cucumber (Cucumis sativus L.) Lines Through in vitro Gynogenesis. Acta Horticulturae 447:623–625.
  • Gemesne, J. A. and G. Venczel, 1996. in vitro Gynogenesis Induction in Zucchini (Cucurbita pepo L. convar. giromontiina Duch) Lines. Proceedeings of the VI. Eucarpia Meeting on Cucurbit Genetics and Breeding (1996) pp: 200–201.
  • Gong, L., G. Stift, R. Kofler, M. Pachner and T. Lelley, 2008a. Microsatellites for the Genus Cucurbita and an SSR–based Genetic Linkage Map of Cucurbita pepo L. Theoretical and Applied Genetics 117:37–48.
  • Gong, L., M. Pachner, K. Kalai and T. Lelley, 2008b. SSR–based Genetic Linkage Map of Cucurbita moschata and its Synteny with Cucurbita pepo. Genome 51:878–887.
  • Jarl, C. I., G. S. Bokelmann and J. M. De Haas, 1995. Protoplast Regeneration and Fusion in Cucumis: melon × cucumber. Plant Cell Tissue and Organ Culture 43:259–265.
  • Kathiravan, K., G. Vengedesan, S. Singer, B. Steinitz, H. S. Paris and V. Gaba, 2006. Adventitious Regeneration in vitro Occurs Across a wide Spectrum of Squash (Cucurbita pepo) genotypes. Plant Cell Tissue and Organ Culture 85:285–295.
  • Kintzios, S., E. Sereti, P. Bluchos, J. B. Drossopoulos, C. K. Kitsaki and A. Liopa–Tsakalidis, 2002. Growth Regulator Pretreatment Improves Somatic Embryogenesis from Leaves of Squash (Cucurbita pepo L.) and Melon (Cucumis melo L.). Plant Cell Reports 21:1–8.
  • Kiss–Baba, E., S. Panczel, K. Simonyi and G. D. Bisztray, 2010. Investigations on the Regeneration Ability of Squash Cultivars. Acta Agronomica Hungarica 58(2):159–166.
  • Klas, F. E., M. Fuchs and D. Gonsalves, 2011. Fruit Yield of Virus–Resistant Transgenic Summer Squash in Simulated Commercial Plantings under Conditions of High Disease Pressure. Journal of Horticulture and Forestry 3(2):46–52.
  • Kurtar, E. S., N. Sarı ve K. Abak, 2000. Kabakta Bazı Cucurbita Türleri ile Tozlamanın Haploid Embriyo Uyartımına Etkileri. OMÜ Ziraat Fakültesi Dergisi 15(2):43–47.
  • Kurtar, E. S., N. Sarı and K. Abak, 2002. Obtention of Haploid Embryos and Plants through Irradiated Pollen Technique in Squash (Cucurbita pepo L.). Euphytica 127:335–344.
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  • Kurtar, E. S. and A. Balkaya, 2010. Production of in vitro haploid Plants from in Situ Induced Haploid Embryos in Winter Squash (Cucurbita maxima Duchesne ex Lam.) Via Irradiated Pollen. Plant Cell Tissue and Organ Culture 102(3):267–277.
  • Kurtar, E. S., A. Balkaya and D. Kandemir, 2016. Evaluation of Haploidization Efficiency in Winter Squash (Cucurbita maxima Duch.) and Pumpkin (Cucurbita moschata Duch.) Through Anther Culture. Plant Cell Tissue and Organ Culture 127:497–511.
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Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı

Year 2017, Volume: 46 Issue: 2, 39 - 49, 08.01.2018

Abstract

Yeni bir çeşidin geliştirilmesinde biyoteknoloji, konvansiyonel ıslah metotlarıyla karşılaştırıldığında etkili bir ürün geliştirme tekniği olarak kabul görmektedir. Bu sebeple günümüz ıslah çalışmalarında biyoteknolojik ıslah metotları daha fazla ön plana çıkmaktadır. Sunulan bu derleme çalışmasında, Cucurbita türlerinin çeşit ıslah programlarında bazı biyoteknolojik ıslah metotları (dihaploidizasyon, türler arası melezlemeler ve embriyo kültürü, rejenerasyon, protoplast kültürü, rekombinant DNA teknolojisi, moleküler teknikler) ve bunların uygulamaları tartışılmıştır. Çalışmanın sonuçları, Cucurbita türlerinde çalışan ıslahçılara istenilen agronomik ve ekonomik özelliklere sahip yeni çeşitlerin geliştirilmesinde farklı bir bakış açısı sunabilecektir.


References

  • Abrie, A. L. and J. Van Staden, 2001. Micropropagation of the Endangered Aloe polyphylla. Plant Growth Regulation 33(1): 19–23.
  • Aggour, A. R., L. A. Badr and M. M. Ashry, 1999. Biotechnological Studies on Interspecific Crosses among Some Cucurbita Species. First International Conference in Egypt, on Plant Tissue Culture and its Application 255–275.
  • Ananthakrishnan, G., X. Xia, C. Elman, S. Singer, H. S. Paris, A. Gal–on and V. Gaba, 2003. Shoot Production in Squash (Cucurbita pepo) by in vitro Organogenesis. Cell Biology and Morphogenesis.
  • Andres, T. C. and R. W. Robinson, 2002. Cucurbita Ecuadorensis, an Ancient Semi–Domesticate With Multiple Disease Resistance and Tolerance to Some Adverse Growing Conditions. In: D. N. Maynard (ed.). Cucurbitaceae 2002. ASHS Press, Alexandria, Va. p. 95–99.
  • Baktemur, G., N. K. Yücel, H. Taşkın, S. Çömlekçioğlu ve S. Büyükalaca, 2014. Effects of Different Genotypes and Gamma Ray Doses on Haploidization Using Irradiated Pollen Technique in Squash. Turkis Journal of Biology 38:318–327.
  • Balkaya, A., E. S. Kurtar, R. Yanmaz ve M. Ozbakır, 2005. Karadeniz Bölgesinde Kışlık Kabak Türlerinde (Kestane Kabağı, Cucurbita maxima Duchesne ve Balkabağı, Cucurbita moschata Duchesne) Gen Kaynaklarının Toplanması, Karakterizasyonu ve Değerlendirilmesi. TÜBİTAK 104O144 nolu Proje Sonuç Raporu 160s.
  • Baranek, M., G. Stift, J. Vollmann and T. Lelly, 2000. Genetic Diversity within and between the Species Cucurbita pepo, C. moschata and C. maxima as Revealed by Rapd Markers. Cucurbit Genetics Cooperative Report 23:73–77.
  • Berber, M., 2009. Kabuksuz Çekirdek Kabaklarında (Cucurbita pepo L. var. styriaca) Işınlanmış Polenle Tozlama Yöntemiyle Haploid Üretimi (Yüksek Lisans Tezi). Çukurova Üniversitesi Fen Bilimleri Enstitüsü Biyoteknoloji Anabilim Dalı, 62 s.
  • Blanca, J., J. Canizares, C. Roig, P. Ziarsolo, F. Nuez and B. Pico, 2011. Transcriptome Characterization and High Throughput SSRs and SNPs Discovery in Cucurbita pepo (Cucurbitaceae). BMC Genomics 12:1–15.
  • Bordas, M., L. Gonzáles–Candelas, M. Dabauza, D. Ramón and V. Moreno, 1998. Somatic Hybridization between an Albino Cucumis melo L. Mutant and Cucumis myriocarpus Naud. Plant Science 132:179–190.
  • Chambonnet, D. and R. Dumas De Vaulx, 1985. Obtention of Embryos and Plants from in vitro Culture of Unfertilized Ovules of Cucurbita Pepo. Cucurbit Genetics Cooperative Report 8:66.
  • Çağlar, G. ve S. Bağcı, 2004. Bazı Cucumis Türleri Arasındaki Melezlemelerde Embriyo Kurtarma Yoluyla in vitro Hibrit Bitki Regenerasyonu. Akdeniz Üniversitesi Ziraat Fakültesi Dergisi 17(2):175–182.
  • Dumas De Vaulx, R. and D. Chambonnet, 1986. Obtention of Embryos and Plants from in vitro Culture of Unfertilized Ovules of Cucurbita pepo. In: Genetic Manipulation in Plant Breeding. W. Horn, C. J. Jensen, W. Odenbach, O. Schieder (eds), Proc. International Symposium Eucarpia, 8–12 Sept. 1985, Berlin. 295–297.
  • Esteras, C., P. Gomez and A. J. Monforte, 2012. High–Throughput SNP Genotyping in Cucurbita pepo for Map Construction and Quantitative Trait Loci Mapping. BMC Genomics 13:1–21.
  • Ferriol, M., B. Pico and F. Nuez, 2003. Genetic Diversity of a Germplasm Collection of Cucurbita pepo using SRAP and AFLP Markers. Theoretical and Applied Genetics 107:271–282.
  • Ferriol, M., B. Pico, P. Fernandez and F. Nuez, 2004a. Molecular Diversity of a Germplasm Collection of Squash (Cucurbita moschata) Determined by SRAP and FLP Markers. Crop Science 44:653–664.
  • Ferriol, M., B. Pico and F. Nuez, 2004b. Morphological and Molecular Diversity of a Collection of Cucurbita maxima Landraces. Journal of the American Society for Horticultural Science 129(1):60–69.
  • Gajdova J., A. Lebeda and B. Navrátilová, 2004. Protoplast Cultures of Cucumis and Cucurbita spp. In: Lebeda A., Paris H. S. (eds), Progress in Cucurbit Genetics and Breeding Research. Proceedings of Cucurbitaceae 2004, the 8th Eucarpia Meeting on Cucurbit Genetics and Breeding. Palacký University in Olomouc, Olomouc: 441–454.
  • Gajdova, J., B. Navrátilová, J. Smolná and A. Lebeda, 2007. Effect of Genotype, Source of Protoplasts and Media Composition on Cucumis and Cucurbita Protoplast Isolation and Regeneration. Acta Horticulturae 731:89–94.
  • Gémes Juhász, A., G. Venczel and P. Balogh, 1997. Haploid Plant Induction in Zucchini (Cucurbita pepo L. convar. giromontiina Duch) and in Cucumber (Cucumis sativus L.) Lines Through in vitro Gynogenesis. Acta Horticulturae 447:623–625.
  • Gemesne, J. A. and G. Venczel, 1996. in vitro Gynogenesis Induction in Zucchini (Cucurbita pepo L. convar. giromontiina Duch) Lines. Proceedeings of the VI. Eucarpia Meeting on Cucurbit Genetics and Breeding (1996) pp: 200–201.
  • Gong, L., G. Stift, R. Kofler, M. Pachner and T. Lelley, 2008a. Microsatellites for the Genus Cucurbita and an SSR–based Genetic Linkage Map of Cucurbita pepo L. Theoretical and Applied Genetics 117:37–48.
  • Gong, L., M. Pachner, K. Kalai and T. Lelley, 2008b. SSR–based Genetic Linkage Map of Cucurbita moschata and its Synteny with Cucurbita pepo. Genome 51:878–887.
  • Jarl, C. I., G. S. Bokelmann and J. M. De Haas, 1995. Protoplast Regeneration and Fusion in Cucumis: melon × cucumber. Plant Cell Tissue and Organ Culture 43:259–265.
  • Kathiravan, K., G. Vengedesan, S. Singer, B. Steinitz, H. S. Paris and V. Gaba, 2006. Adventitious Regeneration in vitro Occurs Across a wide Spectrum of Squash (Cucurbita pepo) genotypes. Plant Cell Tissue and Organ Culture 85:285–295.
  • Kintzios, S., E. Sereti, P. Bluchos, J. B. Drossopoulos, C. K. Kitsaki and A. Liopa–Tsakalidis, 2002. Growth Regulator Pretreatment Improves Somatic Embryogenesis from Leaves of Squash (Cucurbita pepo L.) and Melon (Cucumis melo L.). Plant Cell Reports 21:1–8.
  • Kiss–Baba, E., S. Panczel, K. Simonyi and G. D. Bisztray, 2010. Investigations on the Regeneration Ability of Squash Cultivars. Acta Agronomica Hungarica 58(2):159–166.
  • Klas, F. E., M. Fuchs and D. Gonsalves, 2011. Fruit Yield of Virus–Resistant Transgenic Summer Squash in Simulated Commercial Plantings under Conditions of High Disease Pressure. Journal of Horticulture and Forestry 3(2):46–52.
  • Kurtar, E. S., N. Sarı ve K. Abak, 2000. Kabakta Bazı Cucurbita Türleri ile Tozlamanın Haploid Embriyo Uyartımına Etkileri. OMÜ Ziraat Fakültesi Dergisi 15(2):43–47.
  • Kurtar, E. S., N. Sarı and K. Abak, 2002. Obtention of Haploid Embryos and Plants through Irradiated Pollen Technique in Squash (Cucurbita pepo L.). Euphytica 127:335–344.
  • Kurtar, E. S., A. Balkaya, M. Özbakır and T. Ofluoğlu, 2009. Induction of Haploid Embryo and Plant Regeneration via Irradiated Pollen Technique in Pumpkin (Cucurbita moschata Duchesne ex. Poir). African Journal of Biotechnology 8(21):5944–5951.
  • Kurtar, E. S. and A. Balkaya, 2010. Production of in vitro haploid Plants from in Situ Induced Haploid Embryos in Winter Squash (Cucurbita maxima Duchesne ex Lam.) Via Irradiated Pollen. Plant Cell Tissue and Organ Culture 102(3):267–277.
  • Kurtar, E. S., A. Balkaya and D. Kandemir, 2016. Evaluation of Haploidization Efficiency in Winter Squash (Cucurbita maxima Duch.) and Pumpkin (Cucurbita moschata Duch.) Through Anther Culture. Plant Cell Tissue and Organ Culture 127:497–511.
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There are 63 citations in total.

Details

Primary Language Turkish
Journal Section Derlemeler
Authors

Ertan Sait Kurtar This is me

Ahmet Balkaya

Publication Date January 8, 2018
Submission Date April 5, 2017
Acceptance Date August 14, 2017
Published in Issue Year 2017 Volume: 46 Issue: 2

Cite

APA Kurtar, E. S., & Balkaya, A. (2018). Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı. Bahçe, 46(2), 39-49.
AMA Kurtar ES, Balkaya A. Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı. Bahçe. January 2018;46(2):39-49.
Chicago Kurtar, Ertan Sait, and Ahmet Balkaya. “Kabak türlerinin çeşit ıslahında Biyoteknolojinin kullanımı”. Bahçe 46, no. 2 (January 2018): 39-49.
EndNote Kurtar ES, Balkaya A (January 1, 2018) Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı. Bahçe 46 2 39–49.
IEEE E. S. Kurtar and A. Balkaya, “Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı”, Bahçe, vol. 46, no. 2, pp. 39–49, 2018.
ISNAD Kurtar, Ertan Sait - Balkaya, Ahmet. “Kabak türlerinin çeşit ıslahında Biyoteknolojinin kullanımı”. Bahçe 46/2 (January 2018), 39-49.
JAMA Kurtar ES, Balkaya A. Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı. Bahçe. 2018;46:39–49.
MLA Kurtar, Ertan Sait and Ahmet Balkaya. “Kabak türlerinin çeşit ıslahında Biyoteknolojinin kullanımı”. Bahçe, vol. 46, no. 2, 2018, pp. 39-49.
Vancouver Kurtar ES, Balkaya A. Kabak türlerinin çeşit ıslahında biyoteknolojinin kullanımı. Bahçe. 2018;46(2):39-4.

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