Current status, likely migration and strategies to mitigate the threat to wheat production from race UG99 (TTKS) of stem rust pathogen

Authors: SINGH, RAVI - CIMMYT; HODSON, DAVID - CIMMYT; Jin, Yue; HUERTA-ESPINO, JULIO - INIFAP-CEVAMEX; KINYUA, MIRIAM - KARI; WANYERA, RUTH - KARI; NJAU, PETER - KARI; WARD, RICK - CIMMYT

Submitted to: CAB International United Kingdom
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 10/26/2006
Publication Date: 1/8/2007
Citation: Singh, R.P., Hodson, D.P., Jin, Y., Huerta-Espino, J., Kinyua, M., Wanyera, R., Njau, P., Ward, R.W. 2007. Current status, likely migration and strategies to mitigate the threat to wheat production from race UG99 (TTKS) of stem rust pathogen. CAB Reviews: Perspective in Agriculture, Veterinary Science and Natural Resources. CAB International United Kingdom. 54:1-13.

Interpretive Summary: Stem or black rust, caused by Puccinia graminis tritici, is an important disease of wheat and barley, and has historically caused severe losses to wheat production worldwide. Successful control of the disease for over three decades through the use of genetic resistance has resulted in a sharp decline in research activity in recent years. Detection and spread in East Africa of race TTKS, commonly known as Ug99, is of high significance as most wheat cultivars currently grown in its likely migration path, i.e. to North Africa through Arabian Peninsula and then to Middle East and Asia, are highly susceptible to this race and the environment is conducive to disease epidemics. Identifying/developing adapted resistant cultivars in a relatively short time and replacing the susceptible cultivars before rust migrates out of East Africa is the strategy to mitigate potential losses. Although several alien genes will provide resistance to this race, the long-term strategy should focus on rebuilding the "Sr2-complex" (combination of slow rusting gene Sr2 with other unknown additive genes of similar nature) to achieve long-term durability. A Global Rust Initiative has been launched to monitor the further migration of this race, facilitate field testing in Kenya or Ethiopia of wheat cultivars and germplasm developed by wheat breeding programs worldwide, understand the genetic basis of resistance especially the durable type, carry out targeted breeding to incorporate diverse resistance genes into key cultivars and germplasm, and enhance the capacity of national programs. A few wheat genotypes that combine stem rust resistance with high yield potential and other necessary traits have been identified but need rigorous field testing to determine their adaptation in target areas.

Technical Abstract: Stem or black rust, caused by Puccinia graminis tritici, has historically caused severe losses to wheat (Triticum aestivum) production worldwide. Successful control of the disease for over three decades through the use of genetic resistance has resulted in a sharp decline in research activity in recent years. Detection and spread in East Africa of race TTKS, commonly known as Ug99, is of high significance as most wheat cultivars currently grown in its likely migration path, i.e. to North Africa through Arabian Peninsula and then to Middle East and Asia, are highly susceptible to this race and the environment is conducive to disease epidemics. Identifying/developing adapted resistant cultivars in a relatively short time and replacing the susceptible cultivars before rust migrates out of East Africa is the strategy to mitigate potential losses. Although several alien genes will provide resistance to this race, the long-term strategy should focus on rebuilding the "Sr2-complex" (combination of slow rusting gene Sr2 with other unknown additive genes of similar nature) to achieve long-term durability. A Global Rust Initiative has been launched to monitor the further migration of this race, facilitate field testing in Kenya or Ethiopia of wheat cultivars and germplasm developed by wheat breeding programs worldwide, understand the genetic basis of resistance especially the durable type, carry out targeted breeding to incorporate diverse resistance genes into key cultivars and germplasm, and enhance the capacity of national programs. A few wheat genotypes that combine stem rust resistance with high yield potential and other necessary traits have been identified but need rigorous field testing to determine their adaptation in target areas.