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Achieving Durable Disease Resistance in Cereals [Kietas viršelis]

Edited by (University of Nottingham), Contributions by , Contributions by , Contributions by , Contributions by , Contributions by , Contributions by (J), Contributions by (Institut National de Recherche pour lAgriculture, lalimentation et lEnvironnement (INRAE) (France)), Contributions by , Contributions by (Institut National de Recherche pour lAgriculture, lalimentation et lEnvironnement (INRAE) (France))
  • Formatas: Hardback, 970 pages, aukštis x plotis x storis: 229x152x51 mm, weight: 1456 g, Color tables, photos and figures
  • Serija: Burleigh Dodds Series in Agricultural Science 106
  • Išleidimo metai: 19-Oct-2021
  • Leidėjas: Burleigh Dodds Science Publishing Limited
  • ISBN-10: 1786766019
  • ISBN-13: 9781786766014
Kitos knygos pagal šią temą:
Achieving Durable Disease Resistance in CerealsDidesnis paveikslėlis
  • Formatas: Hardback, 970 pages, aukštis x plotis x storis: 229x152x51 mm, weight: 1456 g, Color tables, photos and figures
  • Serija: Burleigh Dodds Series in Agricultural Science 106
  • Išleidimo metai: 19-Oct-2021
  • Leidėjas: Burleigh Dodds Science Publishing Limited
  • ISBN-10: 1786766019
  • ISBN-13: 9781786766014
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781786766014.html
Raktažodžiai:
"This book is number 106 in the Burleigh Dodds Series in Agriculture Science and continues this excellent series of informative reviews in plant and animal agricultural production systems. This volume is a collection of chapters by experts in cereal diseases and disease management from around the world and contains some excellent detailed overviews on recent advances in our understanding of key cereal pathogens and advances in their management. It will be a valuable resource for wheat and barley focussed researchers, breeders and growers." (Professor Matt Dickinson, University of Nottingham, UK - Plant Pathology)

Its been estimated that up to 40% of crop yields are lost to pests and diseases worldwide, a problem exacerbated by increasing fungicide resistance. Given the continuous struggle between crops and the diseases which exploit them, achieving durable disease resistance remains a key challenge in ensuring global food security. A range of issues need to be addressed to meet this challenge for major diseases affecting cereal crops such as Fusarium, barley yellow dwarf virus (BYDV) and Septoria.

Achieving durable disease resistance in cereals provides an authoritative review of key advances, from better understanding of pathogen biology/epidemiology and plant-pathogen interactions, to identifying sources of resistance and advances in techniques for breeding new varieties. This collection offers a comprehensive review of research on achieving durable resistance to diseases such as Fusarium head blight, Septoria tritici blotch, Septoria nodorum blotch, tan spot, blast, BYDV and Ramularia.

Edited by Professor Richard Oliver, Curtin University, Australia, Achieving durable disease resistance in cereals will be an excellent reference for researchers in cereal science, arable farmers, government and private sector agencies supporting cereal production and companies supplying the cereals sector (e.g. seed companies). It complements Integrated disease management of wheat and barley, also edited by Professor Oliver, published by Burleigh Dodds Science in 2018.

Recenzijos

"This book is number 106 in the Burleigh Dodds Series in Agriculture Science and continues this excellent series of informative reviews in plant and animal agricultural production systems. This volume is a collection of chapters by experts in cereal diseases and disease management from around the world and contains some excellent detailed overviews on recent advances in our understanding of key cereal pathogens and advances in their management. It will be a valuable resource for wheat and barley focussed researchers, breeders and growers." (Professor Matt Dickinson, University of Nottingham, UK - Plant Pathology)

Series list xvi
Introduction xxiii
1 Global patterns of cereal diseases and the impacts of breeding for host plant resistance
1(14)
Serge Savary
Laetitia Willocquet
1 Introduction
1(2)
2 The meaning of crop losses for plant breeding
3(4)
3 Paradigm 1: pathogen elimination and total control
7(1)
4 Paradigm 2: disease management
7(1)
5 Paradigm 3: ecological disease management
8(1)
6 Where to look for further information
9(1)
7 References
9(6)
Part 1 Fungal diseases of cereals: rusts
2 Advances in understanding the biology and epidemiology of rust diseases of cereals
15(24)
Vanessa Bueno-Sancho
Clare M. Lewis
Diane G. O. Saunders
1 Introduction
15(1)
2 The wheat rust pathogen lifecycle
16(3)
3 Epidemiology of the wheat rust pathogens
19(2)
4 Developing integrated disease forecasting for wheat rusts
21(1)
5 Mechanisms of wheat rust control
22(2)
6 Studying wheat rust pathogens in the genomic era
24(2)
7 Case study: field pathogenomics
26(3)
8 Conclusion and future trends
29(1)
9 Where to look for further information
29(1)
10 Acknowledgements
30(1)
11 References
30(9)
3 Advances in identifying stripe rust resistance genes in cereals
39(44)
Tianheng Ren
Zhi Li
Feiquan Tan
Cheng Jiang
Peigao Luo
1 Introduction
39(2)
2 Stripe rust resistance genes
41(8)
3 Traditional methods for identifying wheat resistance genes
49(2)
4 Molecular marker methods for identifying wheat resistance genes
51(7)
5 Application of sequence-based technology in Yr gene mapping
58(3)
6 Case study: application of stripe resistance genes in southwestern China
61(4)
7 Where to look for further information
65(1)
8 Acknowledgements
66(1)
9 References
66(17)
Part 2 Fungal diseases of cereals: Fusarium head blight
4 Advances in understanding the epidemiology of Fusarium in cereals
83(28)
Stephen N. Wegulo
1 Introduction
83(3)
2 Life cycle
86(6)
3 Mycotoxin production
92(1)
4 Influence of environmental factors on disease development
93(1)
5 Influence of management practices on disease risk
94(3)
6 Predicting Fusarium head blight epidemics
97(1)
7 Detection and identification
98(1)
8 Disease assessment
99(2)
9 Future trends in research
101(1)
10 Where to look for further information
101(1)
11 References
102(9)
5 Cereal-Fusar/um interactions: Improved fundamental insights into Fusarium pathogenomics and cereal host resistance reveals new ways to achieve durable disease control
111(80)
Claire Kanja
Ana K. Machado Wood
Laura Baggaley
Catherine Walker
Kim E. Hammond-Kosack
1 Introduction
111(8)
2 Infection biology, trichothecene mycotoxins and plasmodesmata function
119(10)
3 Fusarium genomes
129(5)
4 Transcriptome analysis of compatible interactions in multiple cereal species
134(4)
5 Virulence determinants, secondary metabolite clusters and effectors
138(16)
6 Plant defence pathways and resistance QTLs
154(3)
7 Crop improvements using genetic modification (GM), gene editing (GE) and host-induced gene silencing (HIGS) approaches
157(7)
8 Unanswered questions, future outlook and concluding remarks
164(5)
9 Acknowledgements
169(1)
10 References
169(22)
6 Advances in genetic improvement of durable resistance to Fusarium head blight in wheat
191(54)
Guihua Bai
1 Introduction
191(3)
2 Fusarium head blight resistance types
194(3)
3 Inoculation methods
197(3)
4 Fusarium head blight disease rating methods and the relationships among different types of resistance
200(3)
5 Preparation of Fusarium inoculum
203(1)
6 Sources of Fusarium head blight resistance
204(2)
7 Quantitative trait loci for wheat resistance to Fusarium head blight
206(12)
8 Resistance mechanisms
218(1)
9 Breeding strategies
219(7)
10 Conclusion and future trends
226(1)
11 Where to look for further information
226(1)
12 Acknowledgements
227(1)
13 References
227(18)
Part 3 Fungal diseases of cereals: Septoria tritici blotch
7 Advances in understanding the epidemiology of Septoria tritici blotch in cereals
245(18)
Stephen B. Goodwin
1 Introduction
245(2)
2 What's in a name: taxonomy of Z. tritici
247(2)
3 Life cycle of Z. tritici
249(2)
4 Mode of nutrition
251(2)
5 Epidemiology
253(2)
6 Diagnostics
255(1)
7 Conclusion and future trends
256(1)
8 Where to look for further information
256(1)
9 References
257(6)
8 Understanding plant-pathogen interactions in Septoria tritici blotch infection of cereals
263(40)
Y. Petit-Houdenot
M.-H. Lebrun
G. Scalliet
1 Introduction
263(2)
2 Z. tritici genomics
265(3)
3 Molecular and biological tools available in Z. tritici
268(1)
4 Molecular biology of infection
269(8)
5 S. tritici blotch disease management
277(5)
6 Conclusion
282(3)
7 Acknowledgements
285(1)
8 Where to look for further information
285(1)
9 References
286(17)
9 Advances in breeding techniques for durable Septoria tritici blotch (STB) resistance in cereals
303(56)
Harsh Raman
1 Introduction
303(2)
2 Challenges in achieving durable resistance: qualitative and quantitative resistance
305(2)
3 Molecular marker technologies for genetic mapping of Septoria tritici blotch resistance genes
307(4)
4 Ways of increasing durability of resistance: planting of varietal mixtures
311(19)
5 Ways of increasing durability of resistance: deployment of qualitative resistance genes
330(2)
6 Ways of increasing durability of resistance: pyramiding of qualitative and quantitative resistance genes
332(2)
7 Ways to increase durability of resistance: manipulation of plant architecture genes and deployment of multiple resistance loci
334(1)
8 Marker-assisted selection (MAS) and genomic selection (GS) for Septoria tritici blotch resistance breeding
335(3)
9 The use of genetic transformation and gene editing techniques
338(1)
10 Conclusion and future trends
339(1)
11 References
340(19)
Part 4 Fungal diseases of cereals: Septoria nodorum blotch and spot blotch
10 Understanding the plant-pathogen interaction associated with Septoria nodorum blotch of wheat
359(34)
Gayan K. Kariyawasam
Timothy L. Friesen
Edward T. Schafer
1 Introduction
359(3)
2 Necrotrophic effector-host sensitivity gene interactions in the wheat-R nodorum system
362(15)
3 Genetic relationship between NE-sensitivity gene interactions
377(2)
4 Importance of NE-sensitivity gene interactions in the field
379(2)
5 Additional QTL associated with susceptibility/resistance to P. nodorum
381(1)
6 Impact of genome sequencing in characterizing NE-sensitivity gene interactions
381(2)
7 Where to look for further information
383(1)
8 References
384(9)
11 Advances in genetic mapping of Septoria nodorum blotch resistance in wheat and applications in resistance breeding
393(42)
Min Lin
Morten Lillemo
1 Introduction
393(1)
2 Pathogen
394(3)
3 Agricultural importance and management of Septoria nodorum blotch (SNB)
397(1)
4 Methods used in genetic studies of Septoria nodorum blotch (SNB)
398(7)
5 Case study: Septoria nodorum blotch (SNB) resistance in wheat in Norway
405(13)
6 Future trends
418(2)
7 Conclusion
420(1)
8 Where to look for further information
421(1)
9 Acknowledgements
421(1)
10 References
422(13)
12 Advances in breeding techniques for durable resistance to spot blotch in cereals
435(42)
Ramesh Chand
Sudhir Navathe
Sandeep Sharma
1 Introduction
435(2)
2 Spread, economic importance and disease cycle
437(1)
3 Diversity of the pathogen and physiological specialization
438(1)
4 Identification of resistance sources
439(7)
5 Histological, biochemical and morphological components of resistance
446(5)
6 Molecular approaches for the resistance breeding: an account of quantitative trait loci (QTL) and genome-wide association studies (GWAS)
451(6)
7 Resistance genes and their possible deployment
457(1)
8 Low molecular weight toxins and their possible role in pathogenicity
457(1)
9 Necrotrophic effector triggered susceptibility (NETS)-associated genes and breeding for the spot blotch resistance in wheat
458(1)
10 Breeding for the spot blotch resistance in barley
459(2)
11 Farmers participatory research in the release of spot blotch resistant variety
461(1)
12 Challenges and future prospects
462(1)
13 Where to look for further information
462(1)
14 References
463(14)
Part 5 Fungal diseases of cereals: net blotch
13 Advances in understanding the epidemiology, molecular biology and control of net blotch and the net blotch barley interaction
477(48)
Anke Martin
Barsha Poudel
Buddhika Amarasinghe Dahanayaka
Mark S. McLean
Lisle Snyman
`Francisco J. Lopez-Ruiz
1 Introduction
477(3)
2 Hybrids
480(1)
3 Molecular markers to accurately diagnose P. feres isolates
481(2)
4 Genetic variation and population genetics of P. teres
483(4)
5 Pathogenic variation and changes in virulence
487(4)
6 Differential sets
491(1)
7 The P. teres genome
492(4)
8 Identification of genes associated with virulence/avirulence by QTL and association mapping
496(7)
9 Managing the net blotches
503(9)
10 Conclusion and future trends
512(1)
11 Where to look for further information
513(1)
12 Acknowledgements
513(1)
13 References
514(11)
14 Understanding plant-pathogen interactions in net blotch infection of cereals
525(42)
Karl M. Effertz
Shaun J. Clare
Sarah M. Harkins
Robert S. Brueggeman
1 Introduction
525(1)
2 Host
526(3)
3 Pathogen
529(3)
4 Pyrenophora teres-barley pathosystem
532(13)
5 Downstream responses of barley to Pyrenophora teres infection
545(4)
6 Conclusion and future trends
549(1)
7 Where to look for further information
550(1)
8 Acknowledgements
551(1)
9 References
551(16)
15 Breeding barley for durable resistance to net and spot forms of net blotch
567(22)
Jerome D. Franckowiak
Gregory J. Platz
1 Introduction
567(1)
2 Net form net blotch caused by Pyrenophora teres f. teres
568(2)
3 Molecular markers for reactions to net form net blotch
570(2)
4 Population dynamics of barley-P teres f. teres interactions
572(2)
5 Durable resistance to net form net blotch
574(2)
6 Spot form net blotch caused by P. teres f. maculata
576(1)
7 Molecular markers for reactions to spot form net blotch
577(2)
8 Deployment of durable resistances
579(1)
9 Where to look for further information
580(1)
10 References
581(8)
Part 6 Fungal diseases of cereals: tan spot, blast and Ramularia
16 Tan spot disease under the lenses of plant pathologists
589(34)
Reem Aboukhaddour
Mohamed Hafez
Stephen E. Strelkov
Myriam R. Fernandez
1 Introduction
589(2)
2 Pyrenophora tritici-repentis: the fungus
591(2)
3 Pyrenophora tritici-repentis: the pathogen
593(3)
4 Tan spot on the prairies: a case study
596(15)
5 Conclusion and future trends
611(2)
6 References
613(10)
17 Towards an early warning system for wheat blast: epidemiological basis and model development
623(20)
J. M. Fernandes
E. M. Del Ponte
J. P. Ascari
T. J. Krupnik
W. Pavan
F. Vargas
T. Berton
1 Introduction
623(3)
2 Epidemiology and pathogen ecology
626(1)
3 Inoculum sources and survival
626(1)
4 Production, release and aerial transport of inoculum
627(1)
5 Infection and colonization
628(1)
6 Modelling wheat blast epidemics
629(2)
7 Early warning system for wheat blast
631(4)
8 Model uses and future developments
635(1)
9 References
636(7)
18 Investigating the biology of rice blast disease and prospects for durable resistance
643(38)
Vincent M. Were
Nicholas J. Talbot
1 Introduction
643(1)
2 Cell biology of appressorium formation
644(3)
3 The biology of invasive growth and effector secretion
647(1)
4 Two distinct mechanisms of effector secretion
648(1)
5 Understanding the plant-pathogen interface
649(2)
6 PAMP-triggered immunity modulation by secreted effectors
651(1)
7 Effector-triggered immunity and blast resistance genes
652(1)
8 Use of major resistance genes against rice blast
653(9)
9 Wheat blast as an emerging threat to global food security
662(2)
10 CRISPR-Cas9 mutagenesis of dominant S-genes
664(2)
11 Conclusion and future trends
666(1)
12 Where to look for further information
667(1)
13 References
667(14)
19 Ramularia leaf spot in barley
681(28)
Neil Havis
1 Introduction
681(1)
2 Diagnosis of plant disease
681(1)
3 Global distribution of disease
682(1)
4 Life cycle of the fungus
683(4)
5 Environmental effects on disease expression
687(1)
6 Genetics of disease resistance
688(4)
7 Pathogen variability
692(2)
8 Control of Ramularia leaf spot by fungicides
694(3)
9 Future prospects
697(1)
10 Where to look for further information
697(1)
11 References
698(11)
Part 7 Barley yellow dwarf virus
20 Advances in understanding the biology and epidemiology of barley yellow dwarf virus (BYDV)
709(38)
Douglas Lau
Carlos Diego Ribeiro dos Santos
Eduardo Engel
Paulo Roberto do Valle da Silva Pereira
1 Introduction
709(7)
2 Components of the pathosystem: host plants, viruses and aphid vectors
716(5)
3 Virus-aphid interactions
721(3)
4 Virus-host interactions
724(2)
5 Natural enemies of aphids
726(2)
6 Case study: biological control of cereal aphids and BYDV management in Brazil
728(8)
7 Conclusions and future trends
736(1)
8 Where to look for further information
737(1)
9 References
737(10)
21 Resistance breeding in barley against Barley yellow dwarf virus (BYDV): avoiding negative impacts on anatomy and physiology
747(32)
Torsten Will
1 Introduction
747(6)
2 The impact of Barley yellow dwarf virus (BYDV) on host and vector and the benefit of resistance
753(4)
3 Barley yellow dwarf virus control
757(7)
4 Conclusion and future trends
764(1)
5 Where to look for further information
765(1)
6 References
765(14)
Part 8 Fungal diseases of cereals: Regional strategies
22 Key challenges in breeding durable disease-resistant cereals: North America
779(1)
Christina Cowger
1 Introduction
779(1)
2 Key challenge 1: diversity of production settings
780(4)
3 Key challenge 2: structure of North American cereal breeding
784(2)
4 Key challenge 3: evolution of principal disease threats to small-grains cereals
786(2)
5 Specific disease challenges: Fusarium head blight
788(2)
6 Specific disease challenges: stripe rust, leaf rust, and stem rust
790(8)
7 Specific disease challenges: wheat powdery mildew
798(1)
8 Specific disease challenges: leaf blotch diseases
799(2)
9 Specific disease challenges: insect- and mite-related diseases
801(4)
10 Specific disease challenges: bacterial leaf streak and black chaff
805(1)
11 Conclusion
806(1)
12 Where to look for further information
807(1)
13 Acknowledgments
807(1)
14 References
807(18)
23 Achievements in breeding cereals with durable disease resistance in Northwest Europe
825(48)
James K. M. Brown
1 Progress in breeding for effective, durable resistance
825(2)
2 Sources of information about breeding for resistance
827(1)
3 Release and recommendation of cereal varieties
828(2)
4 Demand for disease resistance in cereals
830(3)
5 Breeding elite cereal varieties with resistance to multiple diseases
833(4)
6 Durable and non-durable resistance
837(4)
7 Resistance to biotrophic fungal diseases
841(11)
8 Resistance to non-biotrophic fungal diseases of wheat
852(4)
9 Resistance to non-biotrophic fungal diseases of barley
856(2)
10 Resistance to viral diseases
858(1)
11 Resistance to insects
859(1)
12 Mitigating trade-offs of disease resistance
860(2)
13 Future threats
862(1)
14 Acknowledgements
863(1)
15 Where to look for further information
864(1)
16 References
864(9)
24 Key challenges in breeding durable disease-resistant cereals: North Africa and West Asia
873(48)
Sarrah Ben M'Barek
Seyed Mahmoud Tabib Ghaffary
1 Introduction
873(4)
2 Cereal production in the West Asia and Northern Africa (WANA) region
877(6)
3 Breeding for durable disease resistance: key challenges
883(5)
4 Challenges in breeding durable resistance in wheat: rust diseases in Iran
888(8)
5 Challenges in breeding durable resistance in wheat: Septoria in North Africa
896(10)
6 Conclusion and future trends
906(1)
7 Where to look for further information
907(1)
8 References
907(14)
Index 921
Professor Richard Oliver has recently retired from his position as John Curtin Distinguished Professor in the Centre for Crop Disease Management at Curtin University, Australia. Amongst other honours, Professor Oliver is an Honorary Fellow of the National Institute of Agricultural Botany (NIAB), Honorary Professor at Nottingham Universities and was previously a Fellow at Rothamsted Research in the UK and a Visiting Professor at Wageningen University, The Netherlands. He is also a past President of the British Society for Plant Pathology.

Prof Kim Hammond-Kosack is a molecular plant pathologist and geneticist whos current research focuses on fungal pathogens which infect hexaploid wheat. Since 1998, her group has investigated the Fusarium-wheat interaction, first in industry (1998-2002) and then at Rothamsted Research (since 2002). She discovered the symptomless phase of floral infection which is crucial for disease formation. Her group has played a major role in completing the full assembly and annotation of the reference genomes for F. graminearum, F. culmorum and F. venenatum genomes. She has published over 160 peer reviewed publications, 7 patents and is presently an associate editor at Plant Physiology. Since 2017, she has been the deputy head of the Department of Biointeractions and Crop Protection at Rothamsted Research. Dr Stephen B. Goodwin is a Research Plant Pathologist with the Agricultural Research Service of the U.S. Department of Agriculture, with a current focus on Septoria tritici blotch of wheat plus tar spot of maize. Dr. Marc-Henri Lebrun is a research director at the French CNRS (National Centre for Scientific Research) and currently head of the EGIP team at BIOGER INRAE-AgroParisTech Paris-Saclay University Institute dedicated to the study of fungal plant pathogens in Thiverval-Grignon, France. He is also President of the foundation for European Conferences on Fungal Genetics. He has served in editorial board of Fungal Genetic and Biology for 10 years, and he is currently Editor for Frontiers in Microbiology. He has supervised 12 PhD, and he has been director of UMR BIOGER (100 scientists/technicians/students) for 10 years (2005-2014). Dr Francisco J. Lopez-Ruiz leads the Fungicide Resistance Group at the Centre for Crop and Disease Management (CCDM). Based in the School of Molecular and Life Sciences at Curtin University, Australia, the Fungicide Resistance Group has made major contributions towards the management of fungicide resistance in several key plant pathogens. Dr Lopez-Ruiz has published widely on the molecular mechanisms of fungicide resistance and its detection.

Dr. Franckowiak has studied barley breeding and genetics for over 40 years with research programs at North Dakota State University, Fargo, ND, USA; Department of Agriculture and Fisheries at the Hermitage Research Facility, Warwick, Queensland, Australia; and the University of Minnesota. In corporation with Dr. Udda Lundqvist, Dr. Franckowiak prepared many new and revised Barley Genetic Stock (BGS) descriptions for the Barley Genetics Newsletter (BGN). Professor Frank Ordon is President of the Julius Kühn-Institute (JKI), the Federal Research Centre for Cultivated Plants in Germany. He is Honorary Professor for Molecular Resistance Breeding at the Martin-Luther University of Halle-Wittenberg, Editor-in-Chief of Plant Breeding, a member of the editorial board of several other journals and Chair of the Wheat Initiative Research Committee. He has published widely on molecular markers and improving resistance to biotic and abiotic stress especially in cereals.

Dr. Christina Cowger is a small grains pathologist with the Agricultural Research Service of the U.S. Department of Agriculture (USDA), and a professor in the Department of Entomology and Plant Pathology at North Carolina State University in Raleigh, North Carolina. Her research focuses on the epidemiology and sustainable management of diseases of wheat and barley, especially powdery mildew, Fusarium head blight, Septoria nodorum blotch (SNB), and barley yellow dwarf virus. Dr. Cowger has contributed to the identification of numerous sources of resistance to cereal diseases, as well as illuminating the etiology of those diseases and the population dynamics of the pathogens. She coordinates the USDA SNB screening nursery and is active in the US Wheat & Barley Scab Initiative.