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Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları

Year 2022, Volume: 51 Issue: (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu, 49 - 57, 19.12.2022

Abstract

Dünya genelinde açıkta ve örtüaltında geniş ekiliş alanı olan patlıcanın yetiştiriciliğini kısıtlayan en önemli faktörler toprak kökenli patojenlerdir. Bunlardan özellikle Fusarium oxysporum f.sp. melongenae ve Verticillium dahliae’nin neden olduğu solgunluk hastalıkları, verim kayıplarına yol açmaktadır. Hastalık etmenleri ile mücadelede çevre dostu ve en kalıcı yöntem, dayanıklı çeşit kullanmaktır. Ancak bu hastalıklara dayanıklı kültür formunda ticari çeşit geliştirme çalışmalarından henüz yeterli düzeyde çıktılara ulaşılamamıştır. Batı Akdeniz Tarımsal Araştırma Enstitüsü’nde 2015-2021 yılları arasında yürütülen araştırmalar kapsamında, heterozis ve geriye melezleme metodu kullanılarak bitki ve meyve özellikleri bakımından arzu edilen özelliklere sahip, aynı zamanda Fusarium ve Verticillium solgunluk etmenlerine dayanıklılık sağlayan genleri de bulunduran ıslah hatları geliştirilmiştir. Böylece birden fazla hastalığa dayanıklılık gösteren nitelikli ticari çeşit ıslahı için gen piramitlemesi tekniğinden yararlanma esasında çalışmalar yapılmaktadır. Çoklu dayanıklılık gösteren ıslah hatlarının çeşit geliştirme programlarında kullanılması ile birlikte kısa sürede ticari çeşitler geliştirmenin yolu açılmıştır.

References

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Gene Pyramiding Studies to Develop Multiple Resistances Against Soilborne Fungi in Eggplant

Year 2022, Volume: 51 Issue: (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu, 49 - 57, 19.12.2022

Abstract

Soil-borne pathogens are the most important factors limiting the cultivation of eggplant, which has a wide cultivation area in the open and under cover all over the world. Especially wilt diseases caused by Fusarium oxysporum f.sp. melongenae and Verticillium dahliae, leads to yield losses. The most environmentally friendly and most permanent method of combating disease agents is to use resistant varieties. However, sufficient outputs have not been reached yet from commercial cultivar development studies in the form of culture resistant to these diseases. Within the scope of the research carried out at the Batı Akdeniz Agricultural Research Institute between 2015-2021, breeding lines with the desired characteristics in terms of plant and fruit characteristics, as well as genes that provide resistance to Fusarium and Verticillium wilt fungi, were developed using the heterosis and backcross method. Thus, studies are carried out on the basis of utilizing the gene pyramiding technique for the breeding of qualified commercial varieties that are resistant to more than one disease. The use of breeding lines showing multiple resistance in cultivar development programs paved the way for developing commercial cultivars in a short time.

References

  • Alam, I., M. Salimullah, 2021. Genetic engineering of eggplant (Solanum melongena L.):progress, controversy and potential. Horticulturae 7(4):78.
  • Aldrich, C., C.A. Cullis, 1993. CTAB DNA extraction from plant tissues. Plant Molecular Biology Reporter 11(2):128-141.
  • Altınok, H.H., C. Can, 2010. Characterization of Fusarium oxysporum f.sp. melongenae isolates from eggplant in Turkey by pathogenicity, VCG and RAPD analysis. Phytoparasitica 38(2):149-157.
  • Altınok, H.H., H.F. Boyacı, V. Topçu, 2012. Antalya, Mersin ve Samsun illeri örtü altı patlıcan üretim alanlarında Fusarium ve Verticillium solgunluklarının yaygınlığı ve izolatların virülensliklerinin coğrafi dağılımı. Atatürk Üniversitesi Ziraat Fakültesi Dergisi 43(2):107-115.
  • Barchi, L., L. Toppino, D. Valentino, L. Bassolino, E. Portis, S. Lanteri, G.L. Rotino, 2018. QTL analysis reveals new eggplant loci involved in resistance to fungal wilts. Euphytica 214(2):1-15.
  • Boyacı, H.F. 2007. Patlıcanlarda Fusarium solgunluğuna dayanıklılık kaynakları ve dayanıklılığın kalıtımı (Doktora Tezi). Çukurova Üniversitesi Fen Bilimleri Enstitüsü, Adana 96s.
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  • Collonnier, C., I. Fock, V. Kashyap, G.L. Rotino, M.C. Daunay, Y. Lian, I.K. Mariska, M.V. Rajam, A. Servaes, G. Ducreux, D. Sihachakr, 2001. Applications of biotechnology in eggplant. Plant Cell, Tissue and Organ Culture 65(2):91-107.
  • Daunay, M.C., J. Salinier, X. Aubriot, 2019. Crossability and diversity of eggplants and their wild relatives. In The Eggplant Genome. Springer, Cham. pp:135-191.
  • Deketelaere, S., L. Tyvaert, S.C. França, M. Höfte, 2017. Desirable traits of a good biocontrol agent against Verticillium wilt. Frontiers in microbiology 8:1186.
  • Dervis, S., H. Yetisir, H. Yıldırım, F.M. Tok, S. Kurt, F. Karaca, 2009. Genetic and pathogenic characterization of Verticillium dahliae isolates from eggplant in Turkey. Phytoparasitica 37:467-476.
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  • Gaion, L.A., L.T. Braz, R.F. Carvalho, 2018. Grafting in vegetable crops:A great technique for agriculture. International Journal of Vegetable Science 24(1):85-102.
  • Garibaldi, A., A. Minuto, M.L. Gullino, 2005. Verticillium wilt incited by Verticillium dahliae in eggplant grafted on Solanum torvum in Italy. Plant Disease 89:777.
  • Gebeloğlu, N., Ş.Ş. Ellialtıoğlu, 2022. Patlıcan ıslahı. K., Abak, A. Balkaya, Ş.Ş. Ellialtıoğlu ve E. Düzyaman (Ed):Sebze Islahı Cilt-3 Solanaceae (Patlıcangiller). Gece Kitaplığı s:319-412. ISBN:978-625-430-116-2.
  • Gramazio, P., J. Prohens, S. Vilanova, 2021. Genomic resources in the eggplant wild genepool. In the wild solanums, Genomes Springer, Cham. pp:189-200.
  • Gümrükcü, E., A. Ünlü, H.F. Boyacı, V. Topçu, N. Karatekin, 2014. Verticillium solgunluk hastalığına (Verticillium dahliae Kleb.) karşı patlıcan hatlarının reaksiyonlarının belirlenmesi. Türkiye 5. Bitki Koruma Kongresi, 3-5 Şubat 2014, Antalya.
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  • Kashyap, V., S.V. Kumar, C. Collonnier, F. Fusari, R. Haicour, G.L. Rotino, D. Sihachakr, M.V. Rajam, 2003. Biotechnology of eggplant. Scientia Horticulturae 97(1):1-25.
  • Kefalogianni, I., D. Gkizi, E. Pappa, L. Dulaj, S.E. Tjamos and I. Chatzipavlidis, 2017. Combined use of biocontrol agents and zeolite as a management strategy against Fusarium and Verticillium wilt. BioControl 62(2):139-150.
  • Kim, S.K., W.K. Kim, W.E. Park, S.S. Hong, 2000. Occurrence of eggplant wilt caused by Verticillium dahliae. Plant Pathology Journal 16 (3):156-161.
  • Miller, A.S., C.R. Rowe, M.R. Riedel, 1996. Fusarium and Verticillium wilts of tomato, potato, pepper and eggplant. The Ohio State University Extension Plant Pathology, HGY-3122-96. 2021 Cofey Road. Columbus, OH 432101087.
  • Miyatake, K., T. Saito, S. Negoro, H. Yamaguchi, T. Nunome, A. Ohyama, H. Fukuoka, 2016. Detailed mapping of a resistance locus against Fusarium wilt in cultivated eggplant (Solanum melongena). Theoretical and Applied Genetics 129(2):357-367.
  • Mochizuki, H., Y. Sakata, K. Yamakawa, T. Nishio, S. Komochi, T. Nariakawa, S. Monma, 1997. Eggplant parental line 1’ and eggplant breeding line resistant to Fusarium wilt. Bulletin of the National Research Institute of Vegetables, Ornamental Plants and Tea. Series A:Vegetables and Ornamental Plants 12:85-90.
  • Monma, S., I. Sato, H. Matsunaga, 1996. Evaluation of resistance to bacterial, Fusarium and Verticillium in eggplant and eggplant-related species collected in Ghana. Capsicum and Eggplant Newsletter 15:71-72.
  • Mutlu, N., F.H. Boyaci, M. Göçmen, K. Abak, 2008. Development of SRAP, SRAPRGA, RAPD and SCAR markers linked with a Fusarium wilt resistance gene in eggplant. Theoretical and Applied Genetics 117:1303-1312.
  • Panth, M., S.C. Hassler, F. Baysal-Gurel, 2020. Methods for management of soilborne diseases in crop production. Agriculture 10(1):16.
  • Pegg, G.F., 1981. Biochemistry and physiology of pathogenesis. In:E.M. Mace, A.A. Bell, C.H. Beckman (Eds):Fungal wilt disease of plants. Academic Press Inc. London, ISBN:0-12-464450-3.
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There are 54 citations in total.

Details

Primary Language Turkish
Subjects Agricultural Engineering (Other)
Journal Section Makaleler
Authors

Hatice Filiz Boyacı

Emine Gümrükçü This is me

Esra Cebeci

Volkan Topçu

Aytül Yıldırım

Şeküre Şebnem Ellialtıoğlu

Publication Date December 19, 2022
Submission Date January 1, 2022
Acceptance Date January 31, 2022
Published in Issue Year 2022 Volume: 51 Issue: (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu

Cite

APA Boyacı, H. F., Gümrükçü, E., Cebeci, E., … Topçu, V. (2022). Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları. Bahçe, 51((Özel Sayı 1) 13. Sebze Tarımı Sempozyumu), 49-57.
AMA Boyacı HF, Gümrükçü E, Cebeci E, Topçu V, Yıldırım A, Ellialtıoğlu ŞŞ. Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları. Bahçe. December 2022;51((Özel Sayı 1) 13. Sebze Tarımı Sempozyumu):49-57.
Chicago Boyacı, Hatice Filiz, Emine Gümrükçü, Esra Cebeci, Volkan Topçu, Aytül Yıldırım, and Şeküre Şebnem Ellialtıoğlu. “Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları”. Bahçe 51, no. (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu (December 2022): 49-57.
EndNote Boyacı HF, Gümrükçü E, Cebeci E, Topçu V, Yıldırım A, Ellialtıoğlu ŞŞ (December 1, 2022) Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları. Bahçe 51 (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu 49–57.
IEEE H. F. Boyacı, E. Gümrükçü, E. Cebeci, V. Topçu, A. Yıldırım, and Ş. Ş. Ellialtıoğlu, “Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları”, Bahçe, vol. 51, no. (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu, pp. 49–57, 2022.
ISNAD Boyacı, Hatice Filiz et al. “Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları”. Bahçe 51/(Özel Sayı 1) 13. Sebze Tarımı Sempozyumu (December2022), 49-57.
JAMA Boyacı HF, Gümrükçü E, Cebeci E, Topçu V, Yıldırım A, Ellialtıoğlu ŞŞ. Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları. Bahçe. 2022;51:49–57.
MLA Boyacı, Hatice Filiz et al. “Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları”. Bahçe, vol. 51, no. (Özel Sayı 1) 13. Sebze Tarımı Sempozyumu, 2022, pp. 49-57.
Vancouver Boyacı HF, Gümrükçü E, Cebeci E, Topçu V, Yıldırım A, Ellialtıoğlu ŞŞ. Patlıcanda Toprak Kökenli Fungal Etmenlere Karşı Çoklu Dayanıklılık Geliştirmek İçin Gen Piramitleme Çalışmaları. Bahçe. 2022;51((Özel Sayı 1) 13. Sebze Tarımı Sempozyumu):49-57.

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