Ug99

Last updated

Contents

Puccinia graminis
Stem rust close up.jpg
Scientific classification
Kingdom:
Fungi
Phylum:
Basidiomycota
Class:
Pucciniomycetes
Subclass:
Incertae sedis
Order:
Pucciniales
Family:
Pucciniaceae
Genus:
Puccinia
Species:
P. graminis
Subspecies:
P. graminis tritici
Variety:
Ug99

Ug99 is a lineage of wheat stem rust (Puccinia graminis f. sp. tritici), which is present in wheat fields in several countries in Africa and the Middle East and is predicted to spread rapidly through these regions and possibly further afield, potentially causing a wheat production disaster that would affect food security worldwide. [1] In 2005 the noted green revolution pioneer Norman Borlaug brought great attention to the problem, and most subsequent efforts can be traced to his advocacy. [2] It can cause up to 100% crop losses and is virulent against many resistance genes which have previously protected wheat against stem rust.

Although Ug99-resistant varieties of wheat do exist, [2] a screen of 200,000 wheat varieties used in 22 African and Asian countries found that only 5-10% of the area of wheat grown in these countries consisted of varieties with adequate resistance. [1]

The original race of Ug99, which is designated as 'TTKSK' under the North American nomenclature system, was first detected in Uganda in 1998 [3] and first characterised in 1999 [3] (hence the name Ug99) and has since been detected in Kenya, Ethiopia, Eritrea, Sudan, Yemen, Iran, Tanzania, Mozambique, Zimbabwe, South Africa, [4] and Egypt. There are now 15 known races of Ug99. [5] They are all closely related and are believed to have evolved from a common ancestor, but differ in their virulence/avirulence profiles and the countries in which they have been detected. [1]

Genetics

Ug99 is the product of a type of somatic nuclear exchange event which has not been observed in other stem rust races. [6] During this event and thereafter the nuclei have not experienced recombination. [6]

Gene resistance

Ug99 and its variants differ from other strains of the Black Stem Rust (BSR) pathogen due to their ability to overcome resistance genes in wheat that have been durable against the BSR pathogen for decades. [7] These resistant Sr genes, of which 50 are known, give wheat different resistances to stem rust. [3] The virulence in Uganda was virulent against Sr31 and is specific to Ug99. [3] The massive losses of wheat that have occurred have been devastating, but in recent years the wheat rust epidemic has been effectively controlled through selection and breeding for additional Sr genes. [3] (In the decades since, however, Sr31-virulence has evolved in other strains in other locations. [8] Patpour et al., 2022 finds it in Spain and Siberia.) [8]

United States Department of Agriculture (USDA) researchers are testing genes to determine their Ug99 resistance, which will ultimately aid in the development of wheat varieties that will be able to fight off the rust. Resistance has been identified in a small number of spring wheat land races from North America - 23 out of 250 races with adult plant resistance, 27 out of 23,976 SNPs conveying APR, and only 9 races having seedling resistance. [9] This resistance was present without the Ug99 pathogen challenge being present in NA to drive its selection. [9] USDA has studied winter wheat land races where resistance is more probable. [10]

In addition to the research being conducted by the USDA, The United Kingdom’s Department for International Development (DFID) along with Bill & Melinda Gates Foundation, announced in February 2011 that they will be granting $40 million to a global project led by Cornell University to combat virulent strains of Ug99. [11] The five-year grant to the Durable Rust Resistance in Wheat (DRRW) project supported attempts to identify new resistance genes as well as reproduce and distribute rust resistant wheat seeds to farmers. [11]

There has been a continuous process of development of new resistant cultivars and failure of those cultivars. [12] This demonstrates the need for continuous improvement. [12]

As of 2020 modern molecular and molecular genetics techniques are identifying quantitative trait loci (QTLs), particular cellular structures, and individual R genes more efficiently than ever before. [13] These will be needed given the continuing severe, worldwide threat Ug99 poses. [13] [1]

Sr35 confers resistance to all other severe Pgt races and the original Ug99. [14] Salcedo et al., 2017 finds its Avr target, AvrSr35. [14] Races virulent on Sr35 benefit from nonfunctionalization of AvrSr35 by insertion of a mobile element. [14]

Races

There are 15 races of Ug99, which (under the North American nomenclature system) have the designations TTKSK, TTKSF, TTKST, TTTSK, TTKSP, PTKSK, PTKST, TTKSF+, [4] TTKTT, TTKTK, TTHSK, PTKTK, TTHST, TTKTT+, and TTHTT. [5] They are all closely related and are believed to have evolved from a common ancestor. [1]

TTKSK

Also known as PTKS. [15] The first Ug99 race to be characterised. [16] [15] Like most Ug99 races, and unlike other stem rust varieties, it is virulent against the Sr gene Sr31 ; [16] [15] also virulent against Sr38 . [15] Avirulent against Sr24 . [16] [15] It was found in Uganda [15] in 1999, Kenya [16] in 2001, [5] Ethiopia in 2003, [5] Sudan and Yemen in 2006, [5] Iran in 2007, [5] and Tanzania [1] in 2009, [5] Eritrea in 2012, [5] and Rwanda and Egypt in 2014. [5]

TTKSF

First detected in South Africa in 2000, [5] Zimbabwe 2009, [5] and Uganda in 2012. [5] Avirulent on Sr31 . [5]

TTKST

Discovered in Kenya in 2006 [16] was the first Ug99 race found to be virulent against Sr gene Sr24 . [1] [16] TTKST is now the predominant stem rust race in Kenya. [1] Virulent on Sr31 . [5]

TTTSK

First detected in Kenya in 2007, [5] Tanzania in 2009, [5] Ethiopia in 2010, [5] Uganda in 2012, [5] and Rwanda in 2014. [5] Virulent on Sr31 and Sr36 . [5]

TTKSP

First detected by Visser et al., 2011 in South Africa in 2007. [17] [5] Avirulent on Sr31 and virulent on Sr24 . [5]

PTKSK

First detected in Ethiopia in 2007, [5] Kenya in 2009, [5] Yemen in 2009, [5] and South Africa in 2017. [5] [18] Virulent on Sr31 and avirulent on Sr21 . [5]

PTKST

First detected in Ethiopia in 2007, [5] Kenya in 2008, [5] South Africa in 2009 by Visser et al., 2011, [17] [5] Eritrea and Mozambique and Zimbabwe in 2010. [5] Virulent on Sr31 and Sr24 , but avirulent on Sr21 . [5]

TTKSF+

First detected in both South Africa and Zimbabwe in 2010. [5] Virulent against Sr9h . [19] [20] [21] Avirulent on Sr31 but virulent on Sr9h . [5]

TTKTT

First detected in Kenya in 2014. [5] Also detected in Iraq in 2019, the first such detection in the country. [5] Found in Nepal in 2023. [22] Virulent on Sr31 , Sr24 , and SrTmp . [5]

TTKTK

First detected in Kenya, [5] [23] Rwanda, [5] [23] Uganda, [5] [23] Eritrea, [5] and Egypt [5] [23] in 2014. Virulent on Sr31 and SrTmp . [5]

TTHSK

First detected in Kenya in 2014. [24] Differs from the original (TTKSK) by avirulence against Sr30. [24] Similar to TTHST. [24] Virulent on Sr31 but avirulent on Sr30 . [5]

PTKTK

First detected in Kenya in 2014. [24] Differs from PTKSK by virulence against SrTmp. [24] Differs from TTKTK by avirulence against Sr21. [24] Virulent on Sr31 and Sr24 , but avirulent on Sr21 . [5]

TTHST

First detected in Kenya in 2013. [5] Virulent on Sr31 and Sr24 , but avirulent on Sr30 . [5]

TTKTT+

First detected in Kenya in 2019. [5] Virulent to Sr31 , Sr24 , SrTmp , and Sr8155B1 . [5]

TTHTT

First detected in Kenya in 2020. [5] Virulent to Sr31 , Sr24 , and SrTmp , avirulent to Sr30 . [5]

Timeline

1993

1998

2000

2001

2003

2006

2007

2008

2009

2010

2013

2014

2017

2019

2020

2023

Geographic spread

Because stem rust (as with many fungi) spreads its spores across long distances with the help of natural air currents, containment is difficult. [28] Advances in fluid mechanics which are commonly used for meteorology have also aided Ug99 dispersal prediction. [28] This is especially important for inter-continental, intermittent spread, such as from Eastern South Africa to Western Australia. [28]

China

Although Ug99 has not yet reached China, [29] other stem rust races already have, [29] and an effort is under way to marry resistance against present races with future needs for resistance against Ug99 whenever it arrives. [29]

Lebanon

Although Sr5, Sr21, Sr9e, Sr7b, Sr11, Sr6, Sr8a, Sr9g, Sr9b, Sr30, Sr17, Sr9a, Sr9d, Sr10, SrTmp, Sr38, and SrMcN are no longer effective in Lebanon, Sr11, Sr24, and Sr31 still are which is diagnostic for the absence of Ug99 from Lebanon. [30]

Iraq

Detected in Iraq in 2019. [5]

South Asia

Low-levels of TTKTT were detected in Nepal in 2023, but surveillance has not revealed any propagation in the region. [31] As of 2013 it was the US Director of National Intelligence's assessment that Ug99 would arrive in South Asia soon, in the following few years. This was expected to cause worldwide supply disruptions because, although productivity was growing in Eastern Europe and could theoretically fill that gap, governments worldwide had shown a readiness to forbid exports. [32]

See also

Related Research Articles

<span class="mw-page-title-main">Rust (fungus)</span> Order of fungi

Rusts are fungal plant pathogens of the order Pucciniales causing plant fungal diseases.

<span class="mw-page-title-main">Triticale</span> Hybrid wheat/rye crop

Triticale is a hybrid of wheat (Triticum) and rye (Secale) first bred in laboratories during the late 19th century in Scotland and Germany. Commercially available triticale is almost always a second-generation hybrid, i.e., a cross between two kinds of primary (first-cross) triticales. As a rule, triticale combines the yield potential and grain quality of wheat with the disease and environmental tolerance of rye. Only recently has it been developed into a commercially viable crop. Depending on the cultivar, triticale can more or less resemble either of its parents. It is grown mostly for forage or fodder, although some triticale-based foods can be purchased at health food stores and can be found in some breakfast cereals.

The cereal grain wheat is subject to numerous wheat diseases, including bacterial, viral and fungal diseases, as well as parasitic infestations.

<span class="mw-page-title-main">Stem rust</span> Fungus disease of cereal crops

Stem rust, also known as cereal rust, black rust, red rust or red dust, is caused by the fungus Puccinia graminis, which causes significant disease in cereal crops. Crop species that are affected by the disease include bread wheat, durum wheat, barley and triticale. These diseases have affected cereal farming throughout history. The annual recurrence of stem rust of wheat in North Indian plains was discovered by K.C. Mehta. Since the 1950s, wheat strains bred to be resistant to stem rust have become available. Fungicides effective against stem rust are available as well.

<span class="mw-page-title-main">Wheat leaf rust</span> Fungal disease of wheat, most prevalent

Wheat leaf rust is a fungal disease that affects wheat, barley, rye stems, leaves and grains. In temperate zones it is destructive on winter wheat because the pathogen overwinters. Infections can lead up to 20% yield loss. The pathogen is a Puccinia rust fungus. It is the most prevalent of all the wheat rust diseases, occurring in most wheat-growing regions. It causes serious epidemics in North America, Mexico and South America and is a devastating seasonal disease in India. P. triticina is heteroecious, requiring two distinct hosts.

<i>Blumeria graminis</i> Fungal pathogen of grasses

Blumeria graminis is a fungus that causes powdery mildew on grasses, including cereals. It is the only species in the genus Blumeria. It has also been called Erysiphe graminis and Oidium monilioides or Oidium tritici.

<span class="mw-page-title-main">Elvin Stakman</span> American mycologist (1885–1979)

Elvin Charles Stakman was an American plant pathologist who was a pioneer of methods of identifying and combatting disease in wheat. He became an internationally renowned phytopathologist for his studies of the genetics and epidemiology of stem rust. Stakman is credited with improving crop yields both in North America and worldwide as part of the Green Revolution.

<span class="mw-page-title-main">Take-all</span> Fungal plant disease

Take-all is a plant disease affecting the roots of grass and cereal plants in temperate climates caused by the fungus Gaeumannomyces tritici. All varieties of wheat and barley are susceptible. It is an important disease in winter wheat in Western Europe particularly, and is favoured by conditions of intensive production and monoculture.

Leaf rust is a fungal disease of barley caused by Puccinia hordei. It is also known as brown rust and it is the most important rust disease on barley.

<i>Puccinia hordei</i> Species of fungus

Puccinia hordei is a species of rust fungus. A plant pathogen, it can cause leaf rust of barley, also known as brown rust of barley. It was originally found on the dry leaves of Hordeum vulgare in Germany.

Puccinia striiformis is a fungal species and plant pathogen. It causes stripe rust on wheat, but has other hosts as well. The species is common in Europe and in more recent years has become a problem in Australia. Crop infections can cause losses of up to 40%, and the fungus will infect both winter wheat and spring wheat.

<span class="mw-page-title-main">Plant disease resistance</span> Ability of a plant to stand up to trouble

Plant disease resistance protects plants from pathogens in two ways: by pre-formed structures and chemicals, and by infection-induced responses of the immune system. Relative to a susceptible plant, disease resistance is the reduction of pathogen growth on or in the plant, while the term disease tolerance describes plants that exhibit little disease damage despite substantial pathogen levels. Disease outcome is determined by the three-way interaction of the pathogen, the plant and the environmental conditions.

<span class="mw-page-title-main">Wheat yellow rust</span> Fungal disease of wheat

Wheat yellow rust, also known as wheat stripe rust, is one of the three major wheat rust diseases, along with stem rust of wheat and leaf rust.

<i>Dasypyrum villosum</i> Species of grass

Dasypyrum villosum is a species of annual grass in the family Poaceae. It is native to eastern and southern Europe and Western Asia from the Balearic Islands to Turkmenistan, including in the Mediterranean and the Caucasus regions.

<span class="mw-page-title-main">Telium</span> Structure produced by rust fungi as part of the reproductive cycle

Telium, plural telia, are structures produced by rust fungi as part of the reproductive cycle. They are typically yellow or orange drying to brown or black and are exclusively a mechanism for the release of teliospores which are released by wind or water to infect the alternate host in the rust life-cycle. The telial stage provides an overwintering strategy in the life cycle of a parasitic heteroecious fungus by producing teliospores; this occurs on cedar trees. A primary aecial stage is spent parasitizing a separate host plant which is a precursor in the life cycle of heteroecious fungi. Teliospores are released from the telia in the spring. The spores can spread many kilometers through the air, however most are spread near the host plant.

Ruth Florence Allen (1879–1963) was an American botanist and plant pathologist and the first woman to earn her Ph.D. in botany from the University of Wisconsin. Her doctorate research focused on the reproduction and cell biology of ferns, particularly the phenomenon of apogamy. Later in her career, Allen shifted her focus to plant pathology. Her major contribution to the field of mycology was furthering the understanding of rust fungi, a group of economically important plant pathogens. Allen completed many studies on Puccinia graminis, once considered a catastrophically damaging disease-causing agent in cereal crops before the discovery of current management measures.

<span class="mw-page-title-main">Agriculture in Finland</span>

Agriculture in Finland is characterized by the northern climate and self-sufficiency in most major agricultural products. Its economic role is declining in terms of GNP and employment in primary production, but together with the food industry and forestry with which it is linked, it forms a significant part of the Finnish economy. The number of farms has steadily declined for the last decades. Between 2000 and 2012 their number fell from almost 80,000 in 2000 to about 60,000, while the amount of arable land has slightly increased to a total of almost 2.3 million hectares. Agriculture employed 125,000 people in 2010, which is a drop of 30 percent from 2000.

<span class="mw-page-title-main">Margaret Newton</span> Phytopathologist and mycologist

Margaret Brown Newton was a Canadian plant pathologist and mycologist internationally renowned for her pioneering research in stem rust Puccinia graminis, particularly for its effect on the staple Canadian agricultural product wheat.

2Blades is an agricultural phytopathology non-profit which performs research to improve durable genetic resistance in crops, and funds other researchers to do the same. 2Blades was co-founded by Dr. Roger Freedman and Dr. Diana Horvath in 2004.

Diane G. O. Saunders is a British biologist and group leader at the John Innes Centre and an Honorary Professor in the School of Biological Sciences at the University of East Anglia. Her research investigates plant pathogens that pose a threat to agriculture. She was awarded the Rosalind Franklin Award by the Royal Society in 2022.

References

  1. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Singh, Ravi P.; Hodson, David P.; Huerta-Espino, Julio; Jin, Yue; Bhavani, Sridhar; Njau, Peter; Herrera-Foessel, Sybil; Singh, Pawan K.; Singh, Sukhwinder; Govindan, Velu (8 September 2011). "The Emergence of Ug99 Races of the Stem Rust Fungus is a Threat to World Wheat Production". Annual Review of Phytopathology . 49 (1). Annual Reviews: 465–481. doi:10.1146/annurev-phyto-072910-095423. ISSN   0066-4286. PMID   21568701. S2CID   24770327.
  2. 1 2 3 4 Gross, Michael (2013). "Pests on the move". Current Biology . 23 (19). Cell Press: R855–R857. doi: 10.1016/j.cub.2013.09.034 . ISSN   0960-9822. PMID   24251330. S2CID   15559913.
  3. 1 2 3 4 5
  4. 1 2 3 4 5 6 7 8 Hodson, D. P.; Grønbech-Hansen, J.; Lassen, P.; Alemayehu, Y.; Arista, J.; Sonder, K.; Kosina, P.; Moncada, P.; Nazari, K.; Park, R. F.; Pretorius, Z. A.; Szabo, L. J.; Fetch, T.; Jin, Y. "Tracking the Wheat Rust Pathogens" (PDF). 2012 Borlaug Global Rust Initiative Technical Workshop Proceedings. Borlaug Global Rust Initiative. Archived (PDF) from the original on October 5, 2019. Retrieved 28 November 2012.
  5. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 "Pathotype Tracker – Where is Ug99?". The International Maize and Wheat Improvement Center.
  6. 1 2 Li, Feng; Upadhyaya, Narayana M.; Sperschneider, Jana; Matny, Oadi; Nguyen-Phuc, Hoa; Mago, Rohit; Raley, Castle; Miller, Marisa E.; Silverstein, Kevin A. T.; Henningsen, Eva; Hirsch, Cory D.; Visser, Botma; Pretorius, Zacharias A.; Steffenson, Brian J.; Schwessinger, Benjamin; Dodds, Peter N.; Figueroa, Melania (2019-11-07). "Emergence of the Ug99 lineage of the wheat stem rust pathogen through somatic hybridisation". Nature Communications . 10 (1). Nature Portfolio: 5068. Bibcode:2019NatCo..10.5068L. doi:10.1038/s41467-019-12927-7. ISSN   2041-1723. PMC   6838127 . PMID   31699975. S2CID   207916981.
  7. "USDA Coordinated Approach to Address Pgt-Ug99". ARS (USDA Agricultural Research Service). September 20, 2017.
  8. 1 2
  9. 1 2
  10. USDA Agricultural Research Service (2007). Action Plan to Minimize Impact of Ug99 Stem Rust in the United States (PDF) (Report) (1.01 ed.). USDA Agricultural Research Service. pp. 1–27. Archived from the original (PDF) on 2022-10-20.
  11. 1 2 McCandless, Linda (February 27, 2011). "$40M grant to fight wheat pathogen that threatens global food security". Cornell Chronicle . Retrieved October 5, 2019.
  12. 1 2
  13. 1 2 Deng, Yiwen; Ning, Yuese; Yang, Dong-Lei; Zhai, Keran; Wang, Guo-Liang; He, Zuhua (2020-10-05). "Molecular Basis of Disease Resistance and Perspectives on Breeding Strategies for Resistance Improvement in Crops". Molecular Plant . 13 (10). Cell Press: 1402–1419. doi:10.1016/j.molp.2020.09.018. ISSN   1674-2052. PMID   32979566. S2CID   221955936.
  14. 1 2 3
    Li, Feng; Upadhyaya, Narayana; Sperschneider, Jana; Matny, Oadi; Nguyen-Phuc, Hoa; Mago, Rohit; Raley, Castle; Miller, Marisa; Silverstein, Kevin; Henningsen, Eva; Hirsch, Cory; Visser, Botma; Pretorius, Zacharias; Steffenson, Brian; Schwessinger, Benjamin; Dodds, Peter; Figueroa, Melania (2019). "Emergence of the Ug99 lineage of the wheat stem rust pathogen through somatic hybridisation". Nature Communications . 10 (1). Nature Portfolio: 5068. Bibcode:2019NatCo..10.5068L. doi:10.1038/s41467-019-12927-7. ISSN   2041-1723. PMC   6838127 . PMID   31699975. S2CID   207916981. (FL ORCID   0000-0001-8528-4249.) (NMU ORCID   0000-0002-3052-0416.) (OM ORCID   0000-0002-8447-2886.) (HNP ORCID   0000-0001-9329-4287.) (KATS ORCID   0000-0002-4955-3218.) (EH ORCID   0000-0001-9619-3705.) (CDH ORCID   0000-0002-3409-758X.) (BJS ORCID   0000-0001-7961-5363.) (PND ORCID   0000-0003-0620-5923. GS N3w9QUUAAAAJ. RID D-1181-2009.) (MF ORCID   0000-0003-2636-661X. (RID R-7696-2017).
    This review cites this research.
    Salcedo, Andres; Rutter, William; Wang, Shichen; Akhunova, Alina; Bolus, Stephen; Chao, Shiaoman; Anderson, Nickolas; De Soto, Monica; Rouse, Matthew; Szabo, Les; Bowden, Robert; Dubcovsky, Jorge; Akhunov, Eduard (2017). "Variation in the AvrSr35 gene determines Sr35 resistance against wheat stem rust race Ug99". Science . 358 (6370). American Association for the Advancement of Science (AAAS): 1604–1606. doi:10.1126/science.aao7294. ISSN   0036-8075. PMC   6518949 . PMID   29269474. S2CID   206664159.
  15. 1 2 3 4 5 6 Nagarajan, Subrahmaniam; Kogel, Hans J.; Zadoks, Jan C. (2012). "Epidemiology of Puccinia graminis f.sp. tritici-Ug99 in the Rift Valley "Flyway" from Uganda-Kenya to Yemen". Plant Health Progress . 13 (1). American Phytopathological Society: 31. doi:10.1094/php-2012-1114-01-rv. ISSN   1535-1025. S2CID   88243732.
  16. 1 2 3 4 5 6
  17. 1 2 3 4 This review... Singh, Ravi P.; Hodson, David P.; Huerta-Espino, Julio; Jin, Yue; Bhavani, Sridhar; Njau, Peter; Herrera-Foessel, Sybil; Singh, Pawan K.; Singh, Sukhwinder; Govindan, Velu (8 September 2011). "The Emergence of Ug99 Races of the Stem Rust Fungus is a Threat to World Wheat Production". Annual Review of Phytopathology . 49 (1). Annual Reviews: 465–481. doi:10.1146/annurev-phyto-072910-095423. ISSN   0066-4286. PMID   21568701. S2CID   24770327. ...cites this study: Visser, B; Herselman, L; Park, RF; Karaoglu, H; Bender, CM; Pretorius, Z (2010). "Characterization of two new Puccinia graminis f. sp. tritici races within the Ug99 lineage in South Africa". Euphytica . 179: 119–127. doi:10.1007/s10681-010-0269-x. S2CID   6176783.
  18. Terefe, T.; Pretorius, Z. A.; Visser, B.; Boshoff, W. H. P. (2019). "First Report of Puccinia graminis f. sp. tritici Race PTKSK, a Variant of Wheat Stem Rust Race Ug99, in South Africa". Plant Disease . 103 (6). American Phytopathological Society: 1421. doi: 10.1094/pdis-11-18-1911-pdn . ISSN   0191-2917.
  19. Randhawa, Mandeep S.; Singh, Ravi P.; Dreisigacker, Susanne; Bhavani, Sridhar; Huerta-Espino, Julio; Rouse, Matthew N.; Nirmala, Jayaveeramuthu; Sandoval-Sanchez, Maricarmen (2018-11-30). "Identification and Validation of a Common Stem Rust Resistance Locus in Two Bi-parental Populations". Frontiers in Plant Science . 9. Frontiers Media: 1788. doi: 10.3389/fpls.2018.01788 . ISSN   1664-462X. PMC   6283910 . PMID   30555507.
  20. Pretorius, Z. A.; Szabo, Les J.; Boshoff, W. H. P.; Herselman, L.; Visser, B. (2012). "First Report of a New TTKSF Race of Wheat Stem Rust (Puccinia graminis f. sp. tritici) in South Africa and Zimbabwe". Plant Disease . 96 (4). American Phytopathological Society: 590. doi: 10.1094/pdis-12-11-1027-pdn . ISSN   0191-2917. PMID   30727416.
  21. Rouse, Matthew N.; Nirmala, Jayaveeramuthu; Jin, Yue; Chao, Shiaoman; Fetch, Thomas G.; Pretorius, Zacharias A.; Hiebert, Colin W. (2014-06-10). "Characterization of Sr9h, a wheat stem rust resistance allele effective to Ug99". Theoretical and Applied Genetics . 127 (8). Springer Science+Business Media: 1681–1688. doi:10.1007/s00122-014-2330-y. ISSN   0040-5752. PMID   24913360. S2CID   2598581.
  22. "Successful surveillance results in early first detection of Ug99 in South Asia". Grainews. Retrieved 2024-04-22.
  23. 1 2 3 4
  24. 1 2 3 4 5 6 7 8 9
  25. 1 2 3 4 Singh, Ravi P.; Hodson, David; Huerta-Espino, Julio; Jin, Yue; Njau, Peter; Wanyera, Ruth; Herrera-Foessel, Sybil; Ward, Richard W. (2008). "Will Stem Rust Destroy The World's Wheat Crop?". Advances in Agronomy . 98. Elsevier B. V.: 272–309. doi:10.1016/S0065-2113(08)00205-8. ISBN   9780123743558. Archived from the original on 2020-11-08. Retrieved 2018-12-29.
  26. 1 2 3
  27. "Successful surveillance results in early first detection of Ug99 in South Asia". Grainews. Retrieved 2024-04-22.
  28. 1 2 3 Schmale, David; Ross, Shane (2015). "Highways in the Sky: Scales of Atmospheric Transport of Plant Pathogens". Annual Review of Phytopathology . 53 (1). Annual Reviews: 591–611. doi:10.1146/annurev-phyto-080614-115942. PMID   26047561.
  29. 1 2 3 Wu, Xian Xin; Lin, Qiu Jun; Ni, Xin Yu; Sun, Qian; Chen, Rong Zhen; Xu, Xiao Feng; Qiu, Yong Chun; Li, Tian Ya (2020). "Characterization of Wheat Monogenic Lines with Known Sr Genes and Wheat Lines with Resistance to the Ug99 Race Group for Resistance to Prevalent Races of Puccinia graminis f. sp. tritici in China". Plant Disease . 104 (7). American Phytopathological Society: 1939–1943. doi: 10.1094/pdis-12-19-2736-re . ISSN   0191-2917. PMID   32396054.
  30. Kumari, Safaa (2020-11-09). El Amil, Rola (ed.). (DAY 2) - Phytosanitary Safety for Transboundary pest prevention - Yellow and Black rust population variability. CGIAR Germplasm Health Webinar series. Vol. Phytosanitary Awareness Week. International Institute of Tropical Agriculture + CGIAR. Slide at 00:44:37. Archived from the original on 2021-12-15.
  31. "Successful surveillance results in early first detection of Ug99 in South Asia". Grainews. Retrieved 2024-04-22.
  32. Clapper, James (March 12, 2013). "Statement for the Record" (PDF). Director of National Intelligence . Senate Select Committee on Intelligence.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.