Comparative study of Puccinia recondita influence on elements of productivity and protein contents in grain of soft wheat Triticum aestivum and its wild relative Brachypodium distachyon
Keywords:
Brachypodium distachyon, мягкая пшеница, бурая листовая ржавчина, устойчивость, элементы продуктивности,Abstract
Modern theories of plant diseases prediction are based on results of investigations on laws of pathogenesis and influence of environmental factors on it.
Study of genetic basis of plant resistance of soft wheat, search for resistance genes, creation of resistant varieties and their introduction into the breeding practice expands the possibility of preventing the spread of brown leaf rust, one of the most dangerous wheat diseases.
The aim of this work is to estimate the influence of brown leaf rust on the elements of productivity and protein content in grain of local varieties of soft wheat Kazakhstanskaya 19, Kazakhstanskaya early and new model object Brachypodium distachyon along with their correlation.
The results of the comparative study of the impact of biotic stress on the elements of productivity have shown that Puccinia reconditastatistically significantly reduces the productivity of all parameters in wheat varieties Kazakhstanskaya 19, Kazakhstanskaya early and model object Brachypodium distachyon. The protein content in the grain of wheat of local breeding varieties Kazakhstanskaya 19, Kazakhstanskaya early and wild cereal B.distachyon is not changed when infected with brown leaf rust.
References
Литература
1 Поисково-справочная система по экологии: ru-ecology.info.
2 Абиев С.А. Ржавчинные грибы злаковых растений Казахстана. - Алматы: НИЦ «Ғылым». – 2002. – 296 с.
3 Boyd L.A., Ridout Ch., O’Sullivan D.M., Leach J.E., Leung H. Plant-pathogen interactions: disease resistance in modern agriculture // Trends in Genetics. – 2013. – Vol. 29, No. 4. – P. 233-240.
4 Peraldi A., Goddard R., Nicholson P. Brachypodium distachyon provides insights into plant trade-offs between growth and stress tolerance // ISB news report. – 2015. – P. 6-10.
5 Ayliffe M., Singh D., Park R, Moscou M., Pryor T. Infection of Brachypodium with selected grass rust pathogens // Mol Plant Microbe Interact. – 2013. – Vol. 26, No. 8. – P. 946-957.
6 Peraldi A., Beccari G., Steed A, Nicholson P. Brachypodium distachyon: a new pathosystem to study Fusarium head blight and other Fusarium diseases of wheat // BMC Plant Biol. – 2011. – Vol. 11, No. 100. – P. 1-14.
7 O’Driscoll A., Doohan F., Mullins E. Exploring the utility of Brachypodium distachyon as a model pathosystem for the wheat pathogen Zymoseptoria tritici // BMC Res Notes. – 2015. – Vol. 8, No. 132. – P. 1-10.
8 Bluemke A., Sode B., Ellinger D., Voigt C. Reduced susceptibility to Fusarium head blight in Brachypodium distachyon through priming with the Fusarium mycotoxin deoxynivalenol: DON priming in pathogen resistance // Molecular Plant Pathology. – 2014. – Vol. 16, No. 5. – P. 472-483.
9 Garvin D.F. Investigating rust resistance with the model grass Brachypodium // Proceedings of the 2011 Borlaug Global Rust Initiative Technical Workshop. – USA, 2011. – P. 88-91.
10 Barbieri M., Marcel T.C., Niks R.E., Francia E., Pasquariello M., Mazzamurro V., Garvin D.F., Pecchioni N. QTLs for resistance to the false brome rust Puccinia brachypodii in the model grass Brachypodium distachyon L. // Genome. – 2012. – Vol. 55. – P. 152-163.
11 Mazzamurro V., Marcel T., Milc J., Francia E., Roncaglia E., Malagoli G., Bicciato S., Tagliafico E., Pecchioni N. Transcriptome analysis in the interaction Brachypodium – Puccinia brachypodii // 1st International Brachypodium Conference. – Italy, 2013. – Р. 73.
12 Bettgenhaeuser J., Gardiner M., Opanowicz M., Hubbard A., Bayles R., Doonan J., Wulff B.B.H., Moscou M.J. Deciphering the genetic basis of wheat stripe rust resistance in Brachypodium distachyon // 1st International Brachypodium Conference. – Italy, 2013. – P. 76.
13 Методы выявления ценных сортов зерновых культур среди интродуцированных селекционных материалов (методическая рекомендация) // Рсалиев Ш.С., Тилеубаева Ж.С., Рсалиев А.С., Агабаева А.Ч.. – пгт. Гвардейский, 2004. Инв. № 828. – 15 с.
14 Ахметова А.А, Зеленский Ю.И., Карабаев М.К., Моргунов А.И. Урожайность и устойчивость к ржавчине питомников КАСИБ // Материалы совещания Казахстанско-Сибирской сети по улучшению яровой пшеницы (КАСИБ). – Новосибирск, 2014. – С.3-8.
15 Доспехов Б.А. Методика полевого опыта. – М.: Колос, 1985. – 351 с.
16 Гешеле Э.Э. Основы фитопатологической оценки в селекции растений. – М.: Колос. – 1973. – 206 с.
17 Stakman E.C., Levine M.N. The determination of biologic forms of Puccinia graminis on Triticum cpp. // Minn.Agr.Exp. St.Technol.Bull. – 1922. – No. 8 – P. 38-41.
18 Рокицкий П.Ф. Биологическая статистика. – М.: Колос. – 1973. – 327 с.
19 Натрова З., Смочек Я. Продуктивность колоса зерновых культур. М.: Колос. – 1983. – 45 c.
20Calderini D.F., Dreccer M.F., Slafer G.A. Genetic improvement in wheat yield and associated traits. A re-examination of previous results and the latest trends // Plant Breed. – 1995. – Vol. 114. – P. 108-112.
21 Морозова З.А. Методология использования закономерностей морфогенеза колосовых злаков в селекции. М.: МАКС Пресс. – 2013. – 366 с.
References
1 Search and reference system on ecology at: ru-ecology.info
2 Abiyev SA (2002) Rust fungi of Kazakhstani cereal grains [Rzhavchinnye griby zlakovyh rastenij Kazahstana]. Gylym, Almaty, Kazakhstan, pp. 296 p. (in Russian)
3 Boyd LA, Ridout Ch, O'Sullivan DM, Leach JE, Leung H (2013) Plant-pathogen interactions: disease resistance in modern agriculture, Trends in Genetics, 29(4):233-240. DOI: 10.1016/j.tig.2012.10.011
4 Peraldi A, Goddard R, Nicholson P (2015) Brachypodium distachyon provides insights into plant trade-offs between growth and stress tolerance. ISB news report, USA. P. 6-10.
5 Ayliffe M, Singh D, Park R, Moscou M, Pryor T (2013) Infection of Brachypodium distachyon with selected grass rust pathogens, Mol Plant Microbe Interact, 26(8):6-957. DOI 10.1094/MPMI-01-13-0017-R
6 Peraldi A, Beccari G, Steed A, Nicholson P (2011) Brachypodium distachyon: a new pathosystem to study Fusarium head blight and other Fusarium diseases of wheat, BMC Plant Biol, 11(100). DOI: 10.1186/1471-2229-11-100
7 O'Driscoll A, Doohan F, Mullins E (2015) Exploring the utility of Brachypodium distachyon as a model pathosystem for the wheat pathogen Zymoseptoria tritici, BMC Res Notes, 8 (132). DOI: 10.1186/s13104-015-1097-9
8 Bluemke A, Sode B, Ellinger D, Voigt C (2014) Reduced susceptibility to Fusarium head blight in Brachypodium distachyon through priming with the Fusarium mycotoxin deoxynivalenol: DON priming in pathogen resistance, Molecular Plant Pathology, 16(5):472-483. DOI: 10.1111/mpp.12203
9 Garvin DF (2011) Investigating rust resistance with the model grass Brachypodium. Proceedings of the 2011 Borlaug Global Rust Initiative Technical Workshop, USA. P. 88-91.
10 Barbieri M, Marcel TC, Niks RE, Francia E, Pasquariello M, Mazzamurro V, Garvin DF, Pecchioni N (2012) QTLs for resistance to the false brome rust Puccinia brachypodii in the model grass Brachypodium distachyon L., Genome, 55:152-163. DOI: 10.1139/G2012-001
11 Mazzamurro V, Marcel TC, Milc J, Francia E, Roncaglia E, Malagoli G, Bicciato S, Tagliafico E, Pecchioni N (2013) Transcriptome analysis in the interaction Brachypodium – Puccinia brachypodii. 1st International Brachypodium Conference, Italy. Р. 73.
12 Bettgenhaeuser J, Gardiner M, Opanowicz M, Hubbard A, Bayles R, Doonan J, Wulff BBH, Moscou MJ (2013) Deciphering the genetic basis of wheat stripe rust resistance in Brachypodium distachyon. 1st International Brachypodium Conference, Italy. Р. 76.
13 Rsaliev SS, Tileubaeva ZS, Rsaliev AS, Agabaeva Ach (2004) Methods for detection of valuable varieties of crops among introduced breeding materials (methodical recommendations) [Metody vyjavlenija cennyh sortov zernovyh kul'tur sredi introducirovannyh selekcionnyh materialov.Metodicheskaja rekomendacija]. Inv. № 828, pp.15.
14 Akhmetov AA, Zelensky YI, Karabaev MK, Morgunov AI (2014) Productivity and resistance to rust at KASIB nurceries. Proceedings of the Kazakhstan-Siberia Network Meeting on the Advancement of spring wheat (KASIB) [Urozhajnost' i ustojchivost' k rzhavchine pitomnikov KASIB. Materialy soveshhanija Kazahstansko-Sibirskoj seti po uluchsheniju jarovoj pshenicy]. Novosibirsk, pp.3-8.
15 Dospehov BA (1985) Methods of field experiment [Metodika polevogo opyta]. Kolos, Moscow, Russia, pp. 351 (in Russian)
16 Geshele EE (1973) Bases of phytopathological evaluation in plant breeding [Osnovy fitopatologicheskoj ocenki v selekcii rastenij]. – Kolos, Moscow, Russia, pp. 206 (in Russian)
17 Stakman E.C., Levine M.N. (1922) The determination of biologic forms of Puccinia graminis on Triticum cpp. Minn.Agr.Exp.St.Technol.Bull, USA. P. 38-41.
18 Rokitsky PF (1973) Biological Statistics [Biologicheskaja statistika]. – Kolos, Moscow, Russia, pp. 327 (in Russian)
19 Natrova Z, Smochek Y. (1983) Productivity of spikes of grain cultures [Produktivnost' kolosa zernovyh kul'tur]. – Kolos, Moscow, Russia, pp. 45 (in Russian)
20 Calderini DF, Dreccer MF, Slafer GA (1995) Genetic improvement in wheat yield and associated traits. A re-examination of previous results and the latest trends, Plant Breed, 114:108-112. DOI: 10.1111/j.1439-0523.1995.tb00772.x
21 Morozova ZA (2013) Methodology for laws of spiked cereals morphogenesis application in breeding [Metodologija ispol'zovanija zakonomernostej morfogeneza koloso.vyh zlakov v selekcii]. – Max Press, Moscow, Russia, pp. 366 (in Russian).
1 Поисково-справочная система по экологии: ru-ecology.info.
2 Абиев С.А. Ржавчинные грибы злаковых растений Казахстана. - Алматы: НИЦ «Ғылым». – 2002. – 296 с.
3 Boyd L.A., Ridout Ch., O’Sullivan D.M., Leach J.E., Leung H. Plant-pathogen interactions: disease resistance in modern agriculture // Trends in Genetics. – 2013. – Vol. 29, No. 4. – P. 233-240.
4 Peraldi A., Goddard R., Nicholson P. Brachypodium distachyon provides insights into plant trade-offs between growth and stress tolerance // ISB news report. – 2015. – P. 6-10.
5 Ayliffe M., Singh D., Park R, Moscou M., Pryor T. Infection of Brachypodium with selected grass rust pathogens // Mol Plant Microbe Interact. – 2013. – Vol. 26, No. 8. – P. 946-957.
6 Peraldi A., Beccari G., Steed A, Nicholson P. Brachypodium distachyon: a new pathosystem to study Fusarium head blight and other Fusarium diseases of wheat // BMC Plant Biol. – 2011. – Vol. 11, No. 100. – P. 1-14.
7 O’Driscoll A., Doohan F., Mullins E. Exploring the utility of Brachypodium distachyon as a model pathosystem for the wheat pathogen Zymoseptoria tritici // BMC Res Notes. – 2015. – Vol. 8, No. 132. – P. 1-10.
8 Bluemke A., Sode B., Ellinger D., Voigt C. Reduced susceptibility to Fusarium head blight in Brachypodium distachyon through priming with the Fusarium mycotoxin deoxynivalenol: DON priming in pathogen resistance // Molecular Plant Pathology. – 2014. – Vol. 16, No. 5. – P. 472-483.
9 Garvin D.F. Investigating rust resistance with the model grass Brachypodium // Proceedings of the 2011 Borlaug Global Rust Initiative Technical Workshop. – USA, 2011. – P. 88-91.
10 Barbieri M., Marcel T.C., Niks R.E., Francia E., Pasquariello M., Mazzamurro V., Garvin D.F., Pecchioni N. QTLs for resistance to the false brome rust Puccinia brachypodii in the model grass Brachypodium distachyon L. // Genome. – 2012. – Vol. 55. – P. 152-163.
11 Mazzamurro V., Marcel T., Milc J., Francia E., Roncaglia E., Malagoli G., Bicciato S., Tagliafico E., Pecchioni N. Transcriptome analysis in the interaction Brachypodium – Puccinia brachypodii // 1st International Brachypodium Conference. – Italy, 2013. – Р. 73.
12 Bettgenhaeuser J., Gardiner M., Opanowicz M., Hubbard A., Bayles R., Doonan J., Wulff B.B.H., Moscou M.J. Deciphering the genetic basis of wheat stripe rust resistance in Brachypodium distachyon // 1st International Brachypodium Conference. – Italy, 2013. – P. 76.
13 Методы выявления ценных сортов зерновых культур среди интродуцированных селекционных материалов (методическая рекомендация) // Рсалиев Ш.С., Тилеубаева Ж.С., Рсалиев А.С., Агабаева А.Ч.. – пгт. Гвардейский, 2004. Инв. № 828. – 15 с.
14 Ахметова А.А, Зеленский Ю.И., Карабаев М.К., Моргунов А.И. Урожайность и устойчивость к ржавчине питомников КАСИБ // Материалы совещания Казахстанско-Сибирской сети по улучшению яровой пшеницы (КАСИБ). – Новосибирск, 2014. – С.3-8.
15 Доспехов Б.А. Методика полевого опыта. – М.: Колос, 1985. – 351 с.
16 Гешеле Э.Э. Основы фитопатологической оценки в селекции растений. – М.: Колос. – 1973. – 206 с.
17 Stakman E.C., Levine M.N. The determination of biologic forms of Puccinia graminis on Triticum cpp. // Minn.Agr.Exp. St.Technol.Bull. – 1922. – No. 8 – P. 38-41.
18 Рокицкий П.Ф. Биологическая статистика. – М.: Колос. – 1973. – 327 с.
19 Натрова З., Смочек Я. Продуктивность колоса зерновых культур. М.: Колос. – 1983. – 45 c.
20Calderini D.F., Dreccer M.F., Slafer G.A. Genetic improvement in wheat yield and associated traits. A re-examination of previous results and the latest trends // Plant Breed. – 1995. – Vol. 114. – P. 108-112.
21 Морозова З.А. Методология использования закономерностей морфогенеза колосовых злаков в селекции. М.: МАКС Пресс. – 2013. – 366 с.
References
1 Search and reference system on ecology at: ru-ecology.info
2 Abiyev SA (2002) Rust fungi of Kazakhstani cereal grains [Rzhavchinnye griby zlakovyh rastenij Kazahstana]. Gylym, Almaty, Kazakhstan, pp. 296 p. (in Russian)
3 Boyd LA, Ridout Ch, O'Sullivan DM, Leach JE, Leung H (2013) Plant-pathogen interactions: disease resistance in modern agriculture, Trends in Genetics, 29(4):233-240. DOI: 10.1016/j.tig.2012.10.011
4 Peraldi A, Goddard R, Nicholson P (2015) Brachypodium distachyon provides insights into plant trade-offs between growth and stress tolerance. ISB news report, USA. P. 6-10.
5 Ayliffe M, Singh D, Park R, Moscou M, Pryor T (2013) Infection of Brachypodium distachyon with selected grass rust pathogens, Mol Plant Microbe Interact, 26(8):6-957. DOI 10.1094/MPMI-01-13-0017-R
6 Peraldi A, Beccari G, Steed A, Nicholson P (2011) Brachypodium distachyon: a new pathosystem to study Fusarium head blight and other Fusarium diseases of wheat, BMC Plant Biol, 11(100). DOI: 10.1186/1471-2229-11-100
7 O'Driscoll A, Doohan F, Mullins E (2015) Exploring the utility of Brachypodium distachyon as a model pathosystem for the wheat pathogen Zymoseptoria tritici, BMC Res Notes, 8 (132). DOI: 10.1186/s13104-015-1097-9
8 Bluemke A, Sode B, Ellinger D, Voigt C (2014) Reduced susceptibility to Fusarium head blight in Brachypodium distachyon through priming with the Fusarium mycotoxin deoxynivalenol: DON priming in pathogen resistance, Molecular Plant Pathology, 16(5):472-483. DOI: 10.1111/mpp.12203
9 Garvin DF (2011) Investigating rust resistance with the model grass Brachypodium. Proceedings of the 2011 Borlaug Global Rust Initiative Technical Workshop, USA. P. 88-91.
10 Barbieri M, Marcel TC, Niks RE, Francia E, Pasquariello M, Mazzamurro V, Garvin DF, Pecchioni N (2012) QTLs for resistance to the false brome rust Puccinia brachypodii in the model grass Brachypodium distachyon L., Genome, 55:152-163. DOI: 10.1139/G2012-001
11 Mazzamurro V, Marcel TC, Milc J, Francia E, Roncaglia E, Malagoli G, Bicciato S, Tagliafico E, Pecchioni N (2013) Transcriptome analysis in the interaction Brachypodium – Puccinia brachypodii. 1st International Brachypodium Conference, Italy. Р. 73.
12 Bettgenhaeuser J, Gardiner M, Opanowicz M, Hubbard A, Bayles R, Doonan J, Wulff BBH, Moscou MJ (2013) Deciphering the genetic basis of wheat stripe rust resistance in Brachypodium distachyon. 1st International Brachypodium Conference, Italy. Р. 76.
13 Rsaliev SS, Tileubaeva ZS, Rsaliev AS, Agabaeva Ach (2004) Methods for detection of valuable varieties of crops among introduced breeding materials (methodical recommendations) [Metody vyjavlenija cennyh sortov zernovyh kul'tur sredi introducirovannyh selekcionnyh materialov.Metodicheskaja rekomendacija]. Inv. № 828, pp.15.
14 Akhmetov AA, Zelensky YI, Karabaev MK, Morgunov AI (2014) Productivity and resistance to rust at KASIB nurceries. Proceedings of the Kazakhstan-Siberia Network Meeting on the Advancement of spring wheat (KASIB) [Urozhajnost' i ustojchivost' k rzhavchine pitomnikov KASIB. Materialy soveshhanija Kazahstansko-Sibirskoj seti po uluchsheniju jarovoj pshenicy]. Novosibirsk, pp.3-8.
15 Dospehov BA (1985) Methods of field experiment [Metodika polevogo opyta]. Kolos, Moscow, Russia, pp. 351 (in Russian)
16 Geshele EE (1973) Bases of phytopathological evaluation in plant breeding [Osnovy fitopatologicheskoj ocenki v selekcii rastenij]. – Kolos, Moscow, Russia, pp. 206 (in Russian)
17 Stakman E.C., Levine M.N. (1922) The determination of biologic forms of Puccinia graminis on Triticum cpp. Minn.Agr.Exp.St.Technol.Bull, USA. P. 38-41.
18 Rokitsky PF (1973) Biological Statistics [Biologicheskaja statistika]. – Kolos, Moscow, Russia, pp. 327 (in Russian)
19 Natrova Z, Smochek Y. (1983) Productivity of spikes of grain cultures [Produktivnost' kolosa zernovyh kul'tur]. – Kolos, Moscow, Russia, pp. 45 (in Russian)
20 Calderini DF, Dreccer MF, Slafer GA (1995) Genetic improvement in wheat yield and associated traits. A re-examination of previous results and the latest trends, Plant Breed, 114:108-112. DOI: 10.1111/j.1439-0523.1995.tb00772.x
21 Morozova ZA (2013) Methodology for laws of spiked cereals morphogenesis application in breeding [Metodologija ispol'zovanija zakonomernostej morfogeneza koloso.vyh zlakov v selekcii]. – Max Press, Moscow, Russia, pp. 366 (in Russian).
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