Costs of resistance to fungal pathogens in genetically modified wheat

doi:10.1093/jpe/rts013

Abstract

Abstract: Aims Many resistance genes against fungal pathogens show costs of resistance. Genetically modified (GM) plants that differ in only one or a few resistance genes from control plants present ideal systems for measuring these costs in the absence of pathogens.
Methods To assess the ecological relevance of costs of pathogen resistance, we grew individual plants of four transgenic spring wheat lines in a field trial with three pathogen levels and varied the genetic diversity of the crop.
Important findings We found that two lines with a Pm3b transgene were more resistant to powdery mildew than their sister lines of the variety Bobwhite, whereas lines with chitinase (A9) or chitinase and glucanase (A13) transgenes were not more resistant than their mother variety Frisal. Nevertheless, in the absence of the pathogen, both the GM lines of Bobwhite as well as those of Frisal performed significantly worse than their controls, i.e. Pm3b #1 and Pm3b #2 had 39% or 53% and A9 and A13 had 14% or 23% lower yields. In the presence of the pathogen, all GM lines except Pm3b #2 could increase their yields and other fitness-related traits, reaching the performance levels of the control lines. Line Pm3b #2 seemed to have lost its phenotypic plasticity and had low performance in all environments. This may have been caused by very high transgene expression. No synergistic effects of mixing different GM lines with each other were detected. This might have been due to high transgene expression or the similarity between the lines regarding their resistance genes. We conclude that costs of resistance can be high for transgenic plants with constitutive transgene expression and that this can occur even in cases where the non-transgenic control lines are already relatively resistant, such as in our variety Frisal. Transgenic plants could only compete with conventional varieties in environments with high pathogen pressure. Furthermore, the large variability among the GM lines, which may be due to unpredictable transgene expression, suggests that case-by-case assessments are necessary to evaluate costs of resistance.

Key words: powdery mildew, resistance genes, transgene expression, transgene stacking, yield

摘要：
Aims Many resistance genes against fungal pathogens show costs of resistance. Genetically modified (GM) plants that differ in only one or a few resistance genes from control plants present ideal systems for measuring these costs in the absence of pathogens.
Methods To assess the ecological relevance of costs of pathogen resistance, we grew individual plants of four transgenic spring wheat lines in a field trial with three pathogen levels and varied the genetic diversity of the crop.
Important findings We found that two lines with a Pm3b transgene were more resistant to powdery mildew than their sister lines of the variety Bobwhite, whereas lines with chitinase (A9) or chitinase and glucanase (A13) transgenes were not more resistant than their mother variety Frisal. Nevertheless, in the absence of the pathogen, both the GM lines of Bobwhite as well as those of Frisal performed significantly worse than their controls, i.e. Pm3b #1 and Pm3b #2 had 39% or 53% and A9 and A13 had 14% or 23% lower yields. In the presence of the pathogen, all GM lines except Pm3b #2 could increase their yields and other fitness-related traits, reaching the performance levels of the control lines. Line Pm3b #2 seemed to have lost its phenotypic plasticity and had low performance in all environments. This may have been caused by very high transgene expression. No synergistic effects of mixing different GM lines with each other were detected. This might have been due to high transgene expression or the similarity between the lines regarding their resistance genes. We conclude that costs of resistance can be high for transgenic plants with constitutive transgene expression and that this can occur even in cases where the non-transgenic control lines are already relatively resistant, such as in our variety Frisal. Transgenic plants could only compete with conventional varieties in environments with high pathogen pressure. Furthermore, the large variability among the GM lines, which may be due to unpredictable transgene expression, suggests that case-by-case assessments are necessary to evaluate costs of resistance.

Simon L. Zeller, Olena Kalinina, Bernhard Schmid. Costs of resistance to fungal pathogens in genetically modified wheat[J]. J Plant Ecol, 2013, 6(1): 92-100.

[1]	Emanuel B. Kopp, Pascal A. Niklaus, Samuel E. Wuest. Ecological principles to guide the development of crop variety mixtures [J]. J Plant Ecol, 2023, 16(6): 0-rtad017.
[2]	Christian Schöb, Nadine Engbersen, Jesús López-Angulo, Anja Schmutz, Laura Stefan. Crop Diversity Experiment: towards a mechanistic understanding of the benefits of species diversity in annual crop systems [J]. J Plant Ecol, 2023, 16(6): 0-rtad016.
[3]	Zi-Jun Ji, Lu-Feng Zhao, Tao-Jie Zhang, Ran-Xin Dai, Jian-Jun Tang, Liang-Liang Hu, Xin Chen. Coculturing rice with aquatic animals promotes ecological intensification of paddy ecosystem [J]. J Plant Ecol, 2023, 16(6): 0-rtad014.
[4]	Zheng-Bing Yan, Di Tian, Han-Yue Huang, Yuan-Feng Sun, Xing-Hui Hou, Wen-Xuan Han, Ya-Long Guo, Jing-Yun Fang. Interactive effects of plant density and nitrogen availability on the biomass production and leaf stoichiometry of Arabidopsis thaliana [J]. J Plant Ecol, 2023, 16(3): 0-rtac101.
[5]	Susanna Vain, Iris Gielen, Jaan Liira, and Kristjan Zobel. Population-level performance of Arabidopsis thaliana (L.) Heynh in dense monocultures [J]. J Plant Ecol, 2020, 13(2): 241-246.
[6]	Thomas P. McKenna, Brian J. Darby and Kathryn A. Yurkonis. Effects of monoculture-conditioned soils on common tallgrass prairie species productivity [J]. J Plant Ecol, 2019, 12(3): 474-484.
[7]	Zhenkai Sun, Xiaojuan Liu, Bernhard Schmid, Helge Bruelheide, Wensheng Bu, Keping Ma. Positive effects of tree species richness on fine-root production in a subtropical forest in SE-China [J]. J Plant Ecol, 2017, 10(1): 146-157.
[8]	Siyi Peng, Bernhard Schmid, Josephine Haase, Pascal A. Niklaus. Leaf area increases with species richness in young experimental stands of subtropical trees [J]. J Plant Ecol, 2017, 10(1): 128-135.
[9]	Zhenzhong Sun, Anping Chen, Junhua Ma, Chune He, Zhu Ouyang, Zhenrong Tian. Fertilization regulates the response of wheat yield to interannual temperature variation in North China [J]. J Plant Ecol, 2015, 8(5): 523-529.
[10]	Shujuan Zhang, Li Wang, Fang Ma, Keith J. Bloomfield, Jixian Yang, Owen K. Atkin. Is resource allocation and grain yield of rice altered by inoculation with arbuscular mycorrhizal fungi? [J]. J Plant Ecol, 2015, 8(4): 436-448.
[11]	Emiru Birhane, Frank J. Sterck, Frans Bongers, Thomas W. Kuyper. Arbuscular mycorrhizal impacts on competitive interactions between Acacia etbaica and Boswellia papyrifera seedlings under drought stress [J]. J Plant Ecol, 2014, 7(3): 298-308.
[12]	Terezie Stachová, Pavel Fibich, Jan Lepš. Plant density affects measures of biodiversity effects [J]. J Plant Ecol, 2013, 6(1): 1-11.
[13]	Xinming Chen, Jay Dhungel, Surya P. Bhattarai, Manouchehr Torabi, Lance Pendergast, David J. Midmore. Impact of oxygation on soil respiration, yield and water use efficiency of three crop species [J]. J Plant Ecol, 2011, 4(4): 236-248.
[14]	Zakaria M. Sawan, Mahmoud H. Mahmoud, Amal H. El-Guibali. Influence of potassium fertilization and foliar application of zinc and phosphorus on growth, yield components, yield and fiber properties of Egyptian cotton (Gossypium barbadense L.) [J]. J Plant Ecol, 2008, 1(4): 259-270.
[15]	Bernhard Schmid, Andy Hector, Prasenjit Saha, Michel Loreau. Biodiversity effects and transgressive overyielding [J]. J Plant Ecol, 2008, 1(2): 95-102.