Wheat yellow rust

History

As R.P. Singh, J. Huerta-Espino, and A.P. Roelfs say in their 2002 comprehensive review of literature on the wheat rusts for UN FAO:

A stripe rust outbreak in northwest Syria contributed to the beginning of the Syrian Civil War by increasing food prices.

Life cycle

Other cereal rust fungi have macrocyclic, heteroecious life cycles, involving five spore stages and two phylogenetically unrelated hosts. P. striiformis was thought to be microcyclic for centuries until 2009, when a team of scientists at the USDA-ARS Cereal Disease Lab led by Yue Jin confirmed that barberry (Berberis and Mahonia spp.) is an alternate host. Barberry was known as an alternate host of the closely related stem rust (Puccinia graminis) and for many years, when infection was observed on barberry, it was assumed to be stem rust.{{Cite book|title=The black stem rust and the barberry|last=Stakman|first=Elvin C.|author-link=Elvin C. Stakman

Symptoms

Yellow rust, or stripe rust, takes its name from the appearance of yellow-colored stripes produced parallel along the venations of each leaf blade. These yellow stripes are actually characteristic of uredinia that produce yellow-colored urediniospores. Primary hosts of yellow rust of wheat are Triticum aestivum (bread wheat), Triticum turgidum (durum wheat), triticale, and a few Hordeum vulgare (barley) cultivars. Berberris serves as its alternative host.

The disease usually occurs early in the growth season, when temperature ranges between 2 and; but it may occur to a maximum of 23 C. High humidity and rainfall are favorable conditions for increasing the infection on both leaf blade and leaf sheath, even on spikes when in epidemic form. Symptoms are stunted and weakened plants, shriveled grains, fewer spikes, loss in number of grains per spike and grain weight. Losses can be 50%, but in severe situations 100% is vulnerable. Since yellow rust can occur whenever the wheat plants in green and the environmental condition conducive for the spore infection, yellow rust is a severe problem in the wheat-producing regions worldwide. Temperatures during the time of winter wheat emergence and the coldest period of the year are crucial for epidemic development in winter-habit wheat crops.

Worldwide population structure

Both the spatial genetic structure and the spatial dissemination of this disease have been investigated. Population genetic analyses indicate a strong regional heterogeneity in levels of recombination, with clear signatures of recombination in the Himalayan and near-Himalayan regions and a predominant clonal population structure in other regions. The existence of a high genotypic diversity, recombinant population structure, high sexual reproduction ability, and the abundance of the alternate host (Berberis spp.) in the Himalayan and neighboring regions suggest the region as a plausible Pst center of origin or at least very close to its centre of origin. However, further exploration may be useful from Central Asia to East Asian regions.

Disease management

Breeding of resistant varieties is the most cost-effective method to control this rust. Fungicides are available but vary in availability depending on their registration restrictions by national or state governments. Development of varieties resistant to the disease is always an important objective in wheat breeding programs for crop improvement. This has been done in the past, however as normal, these resistance genes became ineffective due to the acquisition of virulence to that particular resistance gene rendering the variety susceptible - necessitating ongoing variety development. |This book... | {{ Cite book | language=en| year=2017| publisher=Springer Netherlands| publication-place=Dordrecht| pages=vii+719| first2=Xianming| last2=Chen| first1=Zhensheng| last1=Kang| editor-first1=Xianming| editor-first2=Zhensheng| editor-last1=Chen| editor-last2=Kang| s2cid=30527470| oclc=1006649931| lccn=2017943111| id=978-94-024-1111-9. 978-94-024-1491-2. 978-94-024-1109-6| doi=10.1007/978-94-024-1111-9| title=Stripe Rust| isbn=978-94-024-1109-6}} | |...cites this study: |

Resistance

Resistance genes

These genes are most often abbreviated Yr and Yr1, Yr24, etc.

QYr.niab-2D.1 is a quantitative trait locus (QTL) for adult plant resistance (APR). This allele comes from the Claire variety. Bouvet et al., 2021 discovered it when investigating unknown resistance in the UK 2015 and 2016 seasons. It has since broken down however. language=en| year=2021| publisher=Springer Science and Business Media LLC| issue=3| volume=135| journal=Theoretical and Applied Genetics| issn=0040-5752| first6=James| first5=Ian| first4=Jane| first3=Lucy| first2=Sarah| first1=Laura| last6=Cockram| last5=Mackay| last4=Thomas| last3=James| last2=Holdgate| last1=Bouvet| pages=741–753| title=The evolving battle between yellow rust and wheat: implications for global food security| doi=10.1007/s00122-021-03983-z| s2cid=236275608| pmc=8942934| pmid=34821981| id=JC }}

Lebanon

Although Yr6, Yr7, Yr8, Yr9, Yr10, Yr17, Yr24, Yr25, and Yr27 are no longer effective in Lebanon, Yr1, Yr3, Yr4, Yr5, Yr15 are still effective against yellow rust pathotypes prevalent there.

References

• Ali S. (2012) Population biology and invasion history of Puccinia striiformis f.sp. tritici at worldwide and local scale, Ph.D. dissertation. Université Paris-Sud 11.
• Chen, X. M. 2005. Epidemiology and control of stripe rust [Puccinia striiformis f. sp. tritici] on wheat. Can. J. Plant Pathol. 27:314-337.
• Doodson, J.K., Manners, J.G. and Myers, A. (1964). Some effects of yellow rust (Puccinia striiformis) on the growth and yield of spring wheat. Ann. Bot. 28: 459–472.
• Eriksson, J. and E. Henning. 1896. Die Getreideroste. Ihre Geschichte und Natur sowie Massregein gegen dieselben. P. A. Norstedt and Soner, Stockholm. 463 pp.
• Hogg, W.H., Hounam, C.E., Malik, A.K., and Zadoks, J.C. 1969. Meteorological factors affecting the epidemiology of wheat rusts. WMO Tech Note 99. 143 pp.
• Hovmøller, M. S., Sørensen, C. K., Walter, S., Justesen, A. F. (2011) Diversity of Puccinia striiformis on cereals and grasses. Annual Review of Phytopathology 49, 197–217.
• Hylander, N., I. Jorstad and J.A. Nannfeldt. 1953. Enumeratio uredionearum Scandinavicarum. Opera Bot. 1:1-102.
• Jin, Y., Szabo, L.J., and Carson, M. 2010. Century-old mystery of Puccinia striiformis life history solved with the identification of Berberis as an alternate host. Phytopathology 100:432-435.
• Poehlman J.M. and D.A. Sleper. 1995. Breeding Field Crops. 4th Ed. Iowa State Press/Ames, Iowa 50014.
• Robbelen, G. and Sharp, E. L., 1978. Mode of inheritance, interaction and application of genes conditioning resistance to yellow rust. Adv. Plant Breeding, 9, 88 pp.
• Saari, E. E. and Prescott, J. M., 1985. World distribution in relation to economic losses. Pages 259–298, in: The Cereal Rusts Vol. II: Diseases, distribution, epidemiology and control, A. P. Roelfs and W. R. Bushnell eds., Academic Press, Orlando, Fl.
• Stubbs, R. W., 1985. Stripe rust. Pages 61–101 in: The Cereal Rusts Vol. II: Diseases, distribution, epidemiology and control, A. P. Roelfs and W. R. Bushnell eds., Academic Press, Orlando, Fl. Zadoks, J. C. and Bouwman, J. J., 1985. Epidemiology in Europe. Pages 329–369 in: The Cereal Rusts Volume II: Diseases, distribution, epidemiology and control, A. P. Roelfs and W. R. Bushnell eds., Academic Press, Orlando, Fl.

References

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