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The Use of Genitors in Biotic Stress Resistant Radish Breeding Program

Year 2021, Volume: 11 Issue: özel sayı, 3429 - 3437, 30.12.2021
https://doi.org/10.21597/jist.1027945

Abstract

Radish (Raphanus sativus L.) is an important vegetable species in the Brassicaceae family. It is the oldest cultivated species among Brassicaceae vegetables. Radishes have a wide genetic variation in terms of shape and size characteristics. Today, yield and quality losses occur in radish cultivation due to biotic stress (diseases and pests etc.). The most common diseases in radish cultivation are white rust, Fusarium wilt, downy mildew and turnip mosaic virus. Also radishes are in danger of many pests such as cabbage worm, radish aphid, and root lesion nematode. Genetic resources, which are the basis of phenotypic variation, are one of the most important factors in the success of variety breeding. In addition, resistance genes that are not found in commercial radish varieties can be found in wild and different sub-varieties. In recent years, radish breeding studies have begun to focus on the selection of tolerant genotypes and tolerance mechanisms against diseases and pests by using new germplasm sources. In this review, use of genitors that are resistant to diseases and pests and development of new tolerant genotypes studies are presented in radish breeding programmes.

References

  • Anonim 2021. Tescilli ve Üretim İzinli Çeşitler Listesi. T.C. Gıda, Tarım ve Hayvancılık Bakanlığı, Tohumluk Tescil ve Sertifikasyon Merkez Müdürlüğü. http://www.ttsm.gov.tr/TR/belge/1-248/tescilli-cesitler-listesi.http://www.ttsm.gov.tr/TR/belge/1-247/uretimizinli-cesitler-istesi.html (Erişim Tarihi: 23.11.2021).
  • Baik SY, Kim JC, Jang KS, Choi, YH, Choi GJ, 2010. Development of Effective Screening Method and Evaluation of Radish Cultivars for Resistance to Fusarium oxysporum f. Sp. Raphani. The Korean Society of Plant Pathology, 16 (2):148-152.
  • Bayraktar K, 1981. Sebze Yetiştirme Cilt 3. Sebzelerde Tohum Üretimi. Ege Üniversitesi Ziraat Fakültesi Yayınları No. 244, İzmir-Türkiye.
  • Belesky DP, Walker JW, Cassida KA, Muir JP, 2020. Forbs and Browse Species. Forages: The Science of Grassland Agriculture, 2: 347-366.
  • Bünte R, Müller J, Friedt W, 1997. Genetic Variation and Response to Selection for Resistance to Root‐Knot Nematodes in Oil Radish (Raphanus sativus ssp. oleiferus). Plant Breeding, 116 (3):263-266.
  • Cheo TY, Guo RL, Lan YZ, Lou LL, Kuan KC, An ZX, 1987. Angiospermae, Dicotyledoneae, Cruciferae. In: Cheo TY, ed. Flora Reipublicae Popularis Sinicae, 33. Science Press, Beijing (China), pp. 1-483.
  • Coelho PS, Monteiro AA, 2018. Genetic and Histological Characterization of Downy Mildew Resistance at the Cotyledon Stage in Raphanus sativus L. Euphytica, 214 (11):1-14.
  • Crisp P, 1995. Radish, Raphanus Sativus (Cruciferae). In: J Smartt, NW Simmonds (editors.) Evolution of Crop Plants. Wiley-Blackwell, 2nd Edition, ISBN: 978-0-582-08643-2, pp. 86-89.
  • Diederichsen E, Frauen M, Linders EG, Hatakeyama K, Hirai M, 2009. Status and Perspectives of Clubroot Resistance Breeding in Crucifer Crops. Journal of Plant Growth Regulation, 28 (3):265-281.
  • Engels JMM, Arora RK, Guarino L, 1995. An introduction to Plant Germplasm Exploration and Collecting: Planning, Methods and Procedures, Follow-Up. Collecting Plant Genetic Diversity, Technical guidelines, CAB International, Wallingford, United Kingdom, 31-63.
  • Furusato K, Miyazawa A, 1958. Japanese Radish Cultivars from the Viewpoints of Horticultural Science. In: I Nishiyama (editor), The Radish in Japan, Gakujutsu Shinkokai, Tokyo,pp.138-161.
  • Gan C, Deng X, Cui L, Yu X, Yuan W, Dai Z, Yao M, Pang W, Ma Y, Yu X, Choi SY, Lim YP, Piao Z, 2019. Construction of a High-Density Genetic Linkage Map and Identification of Quantitative Trait Loci Associated with Clubroot Resistance in Radish (Raphanus sativus l.). Molecular Breeding, 39 (8): 1-12.
  • Günay A, 1984. Özel Sebze Yetiştiriciliği. Cilt III, Çağ Matbaası, s. 312.
  • Haruta T, 1962. Studies on the Genetics of Self- and Cross-Incompatibility in Cruciferous Vegetable. Res Bull Takii Plant Breeding Exp Stn 2: 1-169.
  • Hasan F, Ansari MS, 2010. Effect of Different Cole Crops on the Biological Parameters of Pieris brassicae (l.) (Lepidoptera: Pieridae) under Laboratory Conditions. Journal of Crop Science and Biotechnology, 13 (3): 195-202.
  • IBPGR (1981). Genetic resources of Cruciferous Crops. IBPGR Secretariat Consultation on The Genetic Resources of Cruciferous Crops, 17-19 November 1980. International Board for Plant Genetic Resources, Rome-Italy, pp. 47.
  • Jouet A, Saunders DG, McMullan M, Ward B, Furzer O, Jupe F, Jones JD, 2019. Albugo candida Race Diversity, Ploidy and Host-Associated Microbes Revealed using DNA Sequence Capture on Diseased Plants in the Field. New Phytologist, 221 (3): 1529-1543.
  • Jugulam M, Walsh M, Hall JC, 2014. Introgression of Phenoxy Herbicide Resistance from Raphanus raphanistrum into Raphanus sativus. Plant Breeding, 133 (4): 489-492.
  • Kaneko Y, Matsuzawa Y, 1993. Radish: Raphanus sativus L. In: G Kalloo, BO Bergh (editors.) Genetic Improvement of Vegetable Crops, Pergamon, ISBN 0080408265, pp. 487-510.
  • Karaağaç O, Balkaya A, 2017. Türkiye’de Yerel Sebze Çeşitlerinin Mevcut Durumu ve Islah Programlarında Değerlendirilmesi. Türktob Dergisi, 23: 8-15.
  • Karaağaç O, Balkaya A, Abak K, 2021. Sebze Islahı, Cilt 1, Lahanagiller (Brassicaceae) Islahı, Bölüm:3 Turp Islahı, Gece Kitaplığı, 149-198, ISBN 978-625-7478-52-6.
  • Kargıoğlu M, Cenkci S, Serteser A, Konuk M, Vural G, 2010. Traditional Uses of Wild Plants in The Middle Aegean Region of Turkey. Human Ecology, 38 (3): 429-450.
  • Kaygısız H, 1989. Sebze Üreticisinin El Kitabı. Hasat Yayıncılık ve Reklamcılık, s. 55. İstanbul.
  • Li GS, Li XX, Shen D, Yang YG, Qiu Y, Wang HP, Gong HZ, 2010. Genetic Analysis of the Resistance to TUMV in Elite Radish Germplasm. Journal of Plant Genetic Resources, 11 (2): 152-156.
  • Li S, 1989. The Origin and Resources of Vegetable Crops in China. International Symposium on Horticultural Germplasm, Cultivated and Wild; Beijing, China, Sept. 1988. Chinese Society for Horticultural Science, International Academic Publishers, Beijing, pp. 197-202.
  • Liang XU, Jiang QW, Jian WU, Yan W, Gong, YQ, Wang XL, Limera C, Liu LW, 2014. Identification and Molecular Mapping of the Rsdmr Locus Conferring Resistance to Downy Mildew at Seedling Stage in Radish (Raphanus sativus l.). Journal of Integrative Agriculture, 13 (11): 2362-2369.
  • Matsuzawa Y, Kaneko Y, Sarashima M, 1985. Fertility in the Intergeneric Hybrid Plant, Raphanobrassica. Bulletin College Agriculture Utsunomiya University, 12: 31-39.
  • McCall AC, Murphy SJ, Venner C, Brown M, 2013. Florivores Prefer White Versus Pink Petal Color Morphs in Wild Radish, Raphanus sativus. Oecologia, 172(1):189-195.
  • Meena PD, Verma PR, Saharan GS, Hossein Borhan M, 2014. Historical Perspectives of White Rust Caused by Albugo Candida in Oilseed Brassica. Journal of Oilseed Brassica, 5: 1-41.
  • Niikura S, 2002. Self-Incompatibility in Vegetable Seed Breeding. Technical Bulletin, 157: 1-8.
  • Niikura S, 2017. F1 Hybrid Breeding Using Genome Information. In: Nishio T, Kitashiba H (editors.), The Radish Genome, Springer Int. Publishing, Cham. ISBN 978-3-319-59253-4, pp. 199-216.
  • Pan Y, Xu YY, Zhu XW, Zhe L, Liu Z, Gong YQ, Xu L, Gong MY, Liu LW 2014. Molecular Characterization and Expression Profiles of Myrosinase Gene (rsmyr2) in Radish (Raphanus sativus L.). Journal of Integrative Agriculture, 13 (9): 1877-1888.
  • Peterka H, Budahn H, Schrader O, Ahne R, Schütze W, 2004. Transfer of Resistance Against the Beet Cyst Nematode from Radish (Raphanus sativus) to Rape (Brassica napus) by Monosomic Chromosome Addition. Theoretical and Applied Genetics, 109 (1): 30-41.
  • Pistrick K, 1987. Untersuchungen Zur Systematik Der Gattung Raphanus. Kulturpflanze, 35: 224-321.
  • Randall C, 1980. Evaluation of Radish Cultivars for Resistance to Clubroot (Plasmodiophora brassicae) Race 6 for Midwestern United States. Plant Disease, 64(5):463.
  • Sarı N, Abak K, Paksoy M, 1995. Kadirli-Kozan Turplarının Seleksiyonla Islahı ve Geliştirilen Hatların Adana ve Şanlıurfa Koşullarındaki Verimleri. Türkiye II. Ulusal Bahçe Bitkileri Kongresi Bildirileri, 13-16 Ekim 1995, Cilt II, s. 341-345.
  • Sato E, Min YY, Toyota K, Takada A, 2009. Relationships Between the Damage to Radish Caused by the Root-Lesion Nematode Pratylenchus Penetrans, Its Density Prior to Cultivation and the Soil Nematode Community Structure Evaluated by Polymerase Chain Reaction-Denaturing Gradient Gel Electrophoresis. Soil Science and Plant Nutrition, 55 (4): 478-484.
  • Shoemaker JS, 1949. Vegetable Growing. John Wiley and Sons, New York, s. 506.
  • Smallegange RC, Van Loon JJA, Blatt SE, Harvey JA, Agerbirk N, Dicke M, 2007. Flower vs. Leaf feeding by Pieris Brassicae: Glucosinolate-Rich Flower Tissues are Preferred and Sustain Higher Growth Rate. Journal of Chemical Ecology, 33 (10): 1831-1844.
  • Şehirali S, Özgen M, 1988. Bitki Islahı. Ankara Üniversitesi Ziraat Fakültesi Yayınları: 1059, Ders Kitabı No: 310, s. 183-190.
  • Şeniz V, 1993. Bahçe Bitkileri Islahı. Uludağ Üniversitesi Ziraat Fakültesi Ders Notları No: 13, s. 15-25, Bursa-Türkiye.
  • Takabe T, 1944. Studies on the Hybrids Between Radish and Hama-Daikon. Japanese Society for Horticultural Science, 15: 74-77.
  • Van Andel A, 2011. Inbred Radish Line NIZ-AC2 U.S. Patent No: 8,063,271. Washington, DC: U.S. Patent and Trademark Office.
  • Voss A, Snowdon RJ, Lühs W, 2000. Intergeneric Transfer of Nematode Resistance from Raphanus sativus Into the Brassica napus Genome. In III International Symposium on Brassicas and XII Crucifer Genetics Workshop 539, pp. 129-134.
  • Vural H, Eşiyok D, Duman İ, 2000. Kültür Sebzeleri (Sebze Yetiştirme). Ege Üniversitesi Ziraat Fakültesi Bahçe Bitkileri Bölümü, ISBN 975-97190-0-2, s. 440.
  • Wada S, Toyota K, Takada A, 2011. Effects of the Nematicide Imicyafos on Soil Nematode Community Structure and Damage to Radish Caused by Pratylenchus Penetrans. Journal of Nematology, 43 (1): 1-6.
  • Wiersema JH, León B, 1999. World Economic Plants - A Standard Reference. CRC Press, USA.
  • Williams PH, Pound GS, 1963. Nature and Inheritance of Resistance to Albugo candida in Radish. Phytopathology, 53: 1150-1154.
  • Yamagishi H, Bhat SR, 2014. Cytoplasmic Male Sterility in Brassicaceae Crops. Breeding Science, 64 (1): 38-47.
  • Yamagishi H, Terachi T, 1997. Molecular and Biological Studies on Male-Sterile Cytoplasm in the cruciferae. IV. Ogura‐Type Cytoplasm Found in The Wild Radish, Raphanus raphanistrum. Plant Breeding, 116 (4): 323-329.
  • Yoon JY, Choi GS, Kim S, Choi SK, 2017. Resistance Evaluation of Radish (Raphanus sativus l.) Inbred Lines Against Turnip Mosaic Virus. Research in Plant Disease, 23 (1): 60-64.
  • Yoshii H, 1963. Studies on the Mosaic Virus of Radish. Special Bulletin. Kyushu Research Disease and Insect, 1: 1-26.
  • Yoshikawa H, 1976. Examination of Races of Clubroot in Cole Crops. Agriculture Horticulture, 51: 628-634.
  • Yoshikawa H, 1983. Breeding for Clubroot Resistance of Crucifer Crops in Japan. Japan Agricultural Research Quarterly, 17 (1): 6-11.
  • Yu X, Lu L, Ma Y, Chhapekar SS, Yi SY, Lim YP, Choi SR, 2020. Fine-Mapping of A Major Qtl (Fwr1) for Fusarium wilt Resistance in Radish. Theoretical and Applied Genetics, 133 (1): 329-340.
  • Yücel Ş, Balkaya A, Unlu AT, Kandemir D, Pala K, 2021. Yerel Turp Genetik Kaynaklarının Morfolojik ve Moleküler Karakterizasyonu ve Teksel Seleksiyon Islahı Yöntemi ile Ümitvar Genotiplerin Seçilmesi. TÜBİTAK TOVAG 2210172 No’lu Proje (Yürürlükte).
  • Zhong X, Zhou Q, Cui N, Cai D, Tang G, 2019. Bvczr3 and Bvhs1pro-1 Genes Pyramiding Enhanced Beet Cyst Nematode (Heterodera Schachtii Schm.) Resistance in Oilseed Rape (Brassica napus L.). International Journal of Molecular Sciences, 20 (7): 1-16.

Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler

Year 2021, Volume: 11 Issue: özel sayı, 3429 - 3437, 30.12.2021
https://doi.org/10.21597/jist.1027945

Abstract

Turp (Raphanus sativus L.), Brassicaceae (Lahanagiller) familyasının içinde yer alan önemli bir sebzedir.
Lahanagil grubu sebze türleri içerisinde kültüre alınan en eski türdür. Turplar şekil ve irilik özellikleri yönünden çok geniş bir genetik vasyasyona sahiptir. Günümüzde turp yetiştiriciliğinde biyotik stres (hastalık ve zararlı etmenleri vb.) faktörleri nedeniyle önemli düzeylerde verim ve kalite kayıpları meydana gelmektedir. Turp yetiştiriciliğinde en yaygın olarak gözlemlenen hastalıklar; beyaz pas, Fusarium solgunluğu, mildiyö ve şalgam mozaik virüsü olarak sıralanabilir. Ayrıca turplar; kök, gövde ve yaprakları ile beslenen lahana kurdu, turp afiti, kök lezyon nematodu gibi birçok zararlının da tehlikesi ve tehdidi altındadır. Genetik kaynaklar, çeşit ıslah çalışmalarının başarıya ulaşmasında en önemli faktörlerden birisi olan fenotipik varyasyonun temelini oluşturmaktadır. Ayrıca halihazırda ticareti yapılan turp çeşitlerinde bulunmayan dayanıklılık genleri, yabani ve farklı alt varyetelerde bulunabilmektedir. Son yıllarda turp bitkisinde mevcut genetik
kaynaklardan yararlanılarak hibrit çeşit ıslahı çalışmalarında hastalık ve zararlılara karşı tolerant yeni genotiplerin geliştirilmesi ve tolerantlıkta rol alan mekanizmaların belirlenmesine yönelik çalışmalara daha fazla önem verilmeye başlanmıştır. Bu derlemede turp ıslah programlarında dayanıklılık kaynağı olarak yararlanılan genitörler ve hastalık ve zararlılara karşı tolerant yeni genotiplerin geliştirilmesi konusunda yapılan ıslah çalışmaları derlenmiştir.

References

  • Anonim 2021. Tescilli ve Üretim İzinli Çeşitler Listesi. T.C. Gıda, Tarım ve Hayvancılık Bakanlığı, Tohumluk Tescil ve Sertifikasyon Merkez Müdürlüğü. http://www.ttsm.gov.tr/TR/belge/1-248/tescilli-cesitler-listesi.http://www.ttsm.gov.tr/TR/belge/1-247/uretimizinli-cesitler-istesi.html (Erişim Tarihi: 23.11.2021).
  • Baik SY, Kim JC, Jang KS, Choi, YH, Choi GJ, 2010. Development of Effective Screening Method and Evaluation of Radish Cultivars for Resistance to Fusarium oxysporum f. Sp. Raphani. The Korean Society of Plant Pathology, 16 (2):148-152.
  • Bayraktar K, 1981. Sebze Yetiştirme Cilt 3. Sebzelerde Tohum Üretimi. Ege Üniversitesi Ziraat Fakültesi Yayınları No. 244, İzmir-Türkiye.
  • Belesky DP, Walker JW, Cassida KA, Muir JP, 2020. Forbs and Browse Species. Forages: The Science of Grassland Agriculture, 2: 347-366.
  • Bünte R, Müller J, Friedt W, 1997. Genetic Variation and Response to Selection for Resistance to Root‐Knot Nematodes in Oil Radish (Raphanus sativus ssp. oleiferus). Plant Breeding, 116 (3):263-266.
  • Cheo TY, Guo RL, Lan YZ, Lou LL, Kuan KC, An ZX, 1987. Angiospermae, Dicotyledoneae, Cruciferae. In: Cheo TY, ed. Flora Reipublicae Popularis Sinicae, 33. Science Press, Beijing (China), pp. 1-483.
  • Coelho PS, Monteiro AA, 2018. Genetic and Histological Characterization of Downy Mildew Resistance at the Cotyledon Stage in Raphanus sativus L. Euphytica, 214 (11):1-14.
  • Crisp P, 1995. Radish, Raphanus Sativus (Cruciferae). In: J Smartt, NW Simmonds (editors.) Evolution of Crop Plants. Wiley-Blackwell, 2nd Edition, ISBN: 978-0-582-08643-2, pp. 86-89.
  • Diederichsen E, Frauen M, Linders EG, Hatakeyama K, Hirai M, 2009. Status and Perspectives of Clubroot Resistance Breeding in Crucifer Crops. Journal of Plant Growth Regulation, 28 (3):265-281.
  • Engels JMM, Arora RK, Guarino L, 1995. An introduction to Plant Germplasm Exploration and Collecting: Planning, Methods and Procedures, Follow-Up. Collecting Plant Genetic Diversity, Technical guidelines, CAB International, Wallingford, United Kingdom, 31-63.
  • Furusato K, Miyazawa A, 1958. Japanese Radish Cultivars from the Viewpoints of Horticultural Science. In: I Nishiyama (editor), The Radish in Japan, Gakujutsu Shinkokai, Tokyo,pp.138-161.
  • Gan C, Deng X, Cui L, Yu X, Yuan W, Dai Z, Yao M, Pang W, Ma Y, Yu X, Choi SY, Lim YP, Piao Z, 2019. Construction of a High-Density Genetic Linkage Map and Identification of Quantitative Trait Loci Associated with Clubroot Resistance in Radish (Raphanus sativus l.). Molecular Breeding, 39 (8): 1-12.
  • Günay A, 1984. Özel Sebze Yetiştiriciliği. Cilt III, Çağ Matbaası, s. 312.
  • Haruta T, 1962. Studies on the Genetics of Self- and Cross-Incompatibility in Cruciferous Vegetable. Res Bull Takii Plant Breeding Exp Stn 2: 1-169.
  • Hasan F, Ansari MS, 2010. Effect of Different Cole Crops on the Biological Parameters of Pieris brassicae (l.) (Lepidoptera: Pieridae) under Laboratory Conditions. Journal of Crop Science and Biotechnology, 13 (3): 195-202.
  • IBPGR (1981). Genetic resources of Cruciferous Crops. IBPGR Secretariat Consultation on The Genetic Resources of Cruciferous Crops, 17-19 November 1980. International Board for Plant Genetic Resources, Rome-Italy, pp. 47.
  • Jouet A, Saunders DG, McMullan M, Ward B, Furzer O, Jupe F, Jones JD, 2019. Albugo candida Race Diversity, Ploidy and Host-Associated Microbes Revealed using DNA Sequence Capture on Diseased Plants in the Field. New Phytologist, 221 (3): 1529-1543.
  • Jugulam M, Walsh M, Hall JC, 2014. Introgression of Phenoxy Herbicide Resistance from Raphanus raphanistrum into Raphanus sativus. Plant Breeding, 133 (4): 489-492.
  • Kaneko Y, Matsuzawa Y, 1993. Radish: Raphanus sativus L. In: G Kalloo, BO Bergh (editors.) Genetic Improvement of Vegetable Crops, Pergamon, ISBN 0080408265, pp. 487-510.
  • Karaağaç O, Balkaya A, 2017. Türkiye’de Yerel Sebze Çeşitlerinin Mevcut Durumu ve Islah Programlarında Değerlendirilmesi. Türktob Dergisi, 23: 8-15.
  • Karaağaç O, Balkaya A, Abak K, 2021. Sebze Islahı, Cilt 1, Lahanagiller (Brassicaceae) Islahı, Bölüm:3 Turp Islahı, Gece Kitaplığı, 149-198, ISBN 978-625-7478-52-6.
  • Kargıoğlu M, Cenkci S, Serteser A, Konuk M, Vural G, 2010. Traditional Uses of Wild Plants in The Middle Aegean Region of Turkey. Human Ecology, 38 (3): 429-450.
  • Kaygısız H, 1989. Sebze Üreticisinin El Kitabı. Hasat Yayıncılık ve Reklamcılık, s. 55. İstanbul.
  • Li GS, Li XX, Shen D, Yang YG, Qiu Y, Wang HP, Gong HZ, 2010. Genetic Analysis of the Resistance to TUMV in Elite Radish Germplasm. Journal of Plant Genetic Resources, 11 (2): 152-156.
  • Li S, 1989. The Origin and Resources of Vegetable Crops in China. International Symposium on Horticultural Germplasm, Cultivated and Wild; Beijing, China, Sept. 1988. Chinese Society for Horticultural Science, International Academic Publishers, Beijing, pp. 197-202.
  • Liang XU, Jiang QW, Jian WU, Yan W, Gong, YQ, Wang XL, Limera C, Liu LW, 2014. Identification and Molecular Mapping of the Rsdmr Locus Conferring Resistance to Downy Mildew at Seedling Stage in Radish (Raphanus sativus l.). Journal of Integrative Agriculture, 13 (11): 2362-2369.
  • Matsuzawa Y, Kaneko Y, Sarashima M, 1985. Fertility in the Intergeneric Hybrid Plant, Raphanobrassica. Bulletin College Agriculture Utsunomiya University, 12: 31-39.
  • McCall AC, Murphy SJ, Venner C, Brown M, 2013. Florivores Prefer White Versus Pink Petal Color Morphs in Wild Radish, Raphanus sativus. Oecologia, 172(1):189-195.
  • Meena PD, Verma PR, Saharan GS, Hossein Borhan M, 2014. Historical Perspectives of White Rust Caused by Albugo Candida in Oilseed Brassica. Journal of Oilseed Brassica, 5: 1-41.
  • Niikura S, 2002. Self-Incompatibility in Vegetable Seed Breeding. Technical Bulletin, 157: 1-8.
  • Niikura S, 2017. F1 Hybrid Breeding Using Genome Information. In: Nishio T, Kitashiba H (editors.), The Radish Genome, Springer Int. Publishing, Cham. ISBN 978-3-319-59253-4, pp. 199-216.
  • Pan Y, Xu YY, Zhu XW, Zhe L, Liu Z, Gong YQ, Xu L, Gong MY, Liu LW 2014. Molecular Characterization and Expression Profiles of Myrosinase Gene (rsmyr2) in Radish (Raphanus sativus L.). Journal of Integrative Agriculture, 13 (9): 1877-1888.
  • Peterka H, Budahn H, Schrader O, Ahne R, Schütze W, 2004. Transfer of Resistance Against the Beet Cyst Nematode from Radish (Raphanus sativus) to Rape (Brassica napus) by Monosomic Chromosome Addition. Theoretical and Applied Genetics, 109 (1): 30-41.
  • Pistrick K, 1987. Untersuchungen Zur Systematik Der Gattung Raphanus. Kulturpflanze, 35: 224-321.
  • Randall C, 1980. Evaluation of Radish Cultivars for Resistance to Clubroot (Plasmodiophora brassicae) Race 6 for Midwestern United States. Plant Disease, 64(5):463.
  • Sarı N, Abak K, Paksoy M, 1995. Kadirli-Kozan Turplarının Seleksiyonla Islahı ve Geliştirilen Hatların Adana ve Şanlıurfa Koşullarındaki Verimleri. Türkiye II. Ulusal Bahçe Bitkileri Kongresi Bildirileri, 13-16 Ekim 1995, Cilt II, s. 341-345.
  • Sato E, Min YY, Toyota K, Takada A, 2009. Relationships Between the Damage to Radish Caused by the Root-Lesion Nematode Pratylenchus Penetrans, Its Density Prior to Cultivation and the Soil Nematode Community Structure Evaluated by Polymerase Chain Reaction-Denaturing Gradient Gel Electrophoresis. Soil Science and Plant Nutrition, 55 (4): 478-484.
  • Shoemaker JS, 1949. Vegetable Growing. John Wiley and Sons, New York, s. 506.
  • Smallegange RC, Van Loon JJA, Blatt SE, Harvey JA, Agerbirk N, Dicke M, 2007. Flower vs. Leaf feeding by Pieris Brassicae: Glucosinolate-Rich Flower Tissues are Preferred and Sustain Higher Growth Rate. Journal of Chemical Ecology, 33 (10): 1831-1844.
  • Şehirali S, Özgen M, 1988. Bitki Islahı. Ankara Üniversitesi Ziraat Fakültesi Yayınları: 1059, Ders Kitabı No: 310, s. 183-190.
  • Şeniz V, 1993. Bahçe Bitkileri Islahı. Uludağ Üniversitesi Ziraat Fakültesi Ders Notları No: 13, s. 15-25, Bursa-Türkiye.
  • Takabe T, 1944. Studies on the Hybrids Between Radish and Hama-Daikon. Japanese Society for Horticultural Science, 15: 74-77.
  • Van Andel A, 2011. Inbred Radish Line NIZ-AC2 U.S. Patent No: 8,063,271. Washington, DC: U.S. Patent and Trademark Office.
  • Voss A, Snowdon RJ, Lühs W, 2000. Intergeneric Transfer of Nematode Resistance from Raphanus sativus Into the Brassica napus Genome. In III International Symposium on Brassicas and XII Crucifer Genetics Workshop 539, pp. 129-134.
  • Vural H, Eşiyok D, Duman İ, 2000. Kültür Sebzeleri (Sebze Yetiştirme). Ege Üniversitesi Ziraat Fakültesi Bahçe Bitkileri Bölümü, ISBN 975-97190-0-2, s. 440.
  • Wada S, Toyota K, Takada A, 2011. Effects of the Nematicide Imicyafos on Soil Nematode Community Structure and Damage to Radish Caused by Pratylenchus Penetrans. Journal of Nematology, 43 (1): 1-6.
  • Wiersema JH, León B, 1999. World Economic Plants - A Standard Reference. CRC Press, USA.
  • Williams PH, Pound GS, 1963. Nature and Inheritance of Resistance to Albugo candida in Radish. Phytopathology, 53: 1150-1154.
  • Yamagishi H, Bhat SR, 2014. Cytoplasmic Male Sterility in Brassicaceae Crops. Breeding Science, 64 (1): 38-47.
  • Yamagishi H, Terachi T, 1997. Molecular and Biological Studies on Male-Sterile Cytoplasm in the cruciferae. IV. Ogura‐Type Cytoplasm Found in The Wild Radish, Raphanus raphanistrum. Plant Breeding, 116 (4): 323-329.
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There are 57 citations in total.

Details

Primary Language Turkish
Subjects Horticultural Production
Journal Section Bahçe Bitkileri / Horticulture
Authors

Kübra Pala 0000-0001-5005-4304

Onur Karaağaç 0000-0002-8794-2556

Ahmet Balkaya 0000-0001-9114-615X

Early Pub Date December 29, 2021
Publication Date December 30, 2021
Submission Date November 24, 2021
Acceptance Date December 9, 2021
Published in Issue Year 2021 Volume: 11 Issue: özel sayı

Cite

APA Pala, K., Karaağaç, O., & Balkaya, A. (2021). Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler. Journal of the Institute of Science and Technology, 11(özel sayı), 3429-3437. https://doi.org/10.21597/jist.1027945
AMA Pala K, Karaağaç O, Balkaya A. Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler. J. Inst. Sci. and Tech. December 2021;11(özel sayı):3429-3437. doi:10.21597/jist.1027945
Chicago Pala, Kübra, Onur Karaağaç, and Ahmet Balkaya. “Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler”. Journal of the Institute of Science and Technology 11, no. özel sayı (December 2021): 3429-37. https://doi.org/10.21597/jist.1027945.
EndNote Pala K, Karaağaç O, Balkaya A (December 1, 2021) Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler. Journal of the Institute of Science and Technology 11 özel sayı 3429–3437.
IEEE K. Pala, O. Karaağaç, and A. Balkaya, “Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler”, J. Inst. Sci. and Tech., vol. 11, no. özel sayı, pp. 3429–3437, 2021, doi: 10.21597/jist.1027945.
ISNAD Pala, Kübra et al. “Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler”. Journal of the Institute of Science and Technology 11/özel sayı (December 2021), 3429-3437. https://doi.org/10.21597/jist.1027945.
JAMA Pala K, Karaağaç O, Balkaya A. Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler. J. Inst. Sci. and Tech. 2021;11:3429–3437.
MLA Pala, Kübra et al. “Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler”. Journal of the Institute of Science and Technology, vol. 11, no. özel sayı, 2021, pp. 3429-37, doi:10.21597/jist.1027945.
Vancouver Pala K, Karaağaç O, Balkaya A. Biyotik Stres Koşullarına Dayanıklı Turp Islah Programında Kullanılan Genitörler. J. Inst. Sci. and Tech. 2021;11(özel sayı):3429-37.