Results 11 to 20 of about 26,834 (193)

Marker-Assisted Pyramiding of Multiple Disease Resistance Genes in Coffee Genotypes (Coffea arabica) [PDF]

Agronomy, 2021
The use of resistant cultivars is the most effective strategy for controlling coffee leaf rust caused by the fungus Hemileia vastatrix. To assist the development of such cultivars, amplified fragment-length polymorphism (AFLP) markers linked to two loci ...
Dênia Pires de Almeida, Eveline Teixeira Caixeta, Karoliny Ferreira Moreira, Antonio Carlos Baião de Oliveira, Kátia Nogueira Pestana de Freitas, Antônio Alves Pereira, Renato Domiciano Silva Rosado, Laércio Zambolim, Cosme Damião Cruz   +8 more
doaj   +3 more sources

Coffee resistance to the main diseases : leaf rust and coffee berry disease [PDF]

Brazilian Journal of Plant Physiology, 2006
Sucesso considerável tem sido obtido no uso do melhoramento clássico para o controle de doenças de plantas economicamente importantes, tais como a ferrugem alaranjada das folhas e a antracnose dos frutos do cafeeiro (CBD).
Adejumo TO, Agrios GN, Alvarado GA, Alvarez ME, Amaral JF, Ameha A, Anne-Sophie Petitot, Azinheira HG, Azinheira HG, Bailey JA, Bailey JA, Baker CJ, Benac R, Benhamou N, Benoit Bertrand, Bestwick CS, Bettencourt AJ, Bettencourt AJ, Bettencourt AJ, Bettencourt AJ, Beynon SM, Bieysse D, Bogdanove AJ, Bowell GP, Bradley DJ, Caño-Delgado A, Century KS, Chagas CM, Chen Z, Chen Z, Chen Z, Chen ZJ, Chittoor JM, Chong J, Christensen AB, Clough SJ, Cohen Y, Collins TJ, Costet L, Coutinho TA, Croft KPC, D'Oliveira B, D'Oliveira B, D'Oliveira B, Dangl JL, De Lima JEO, De Wit PJGM, Deising H, Delledonne M, Diana Fernandez, Dixon RA, Dixon RA, Diéguez-Uribeondo J, Do HM, Dong J, Dorey S, Du L, Ebel J, Eskes AB, Esquerré-Tugayé M-T, Fagioli SLG, Fernandez D, Firman ID, Firman ID, Flor HH, Fritig B, Garcia I, Garcia I, Geiser DM, Gibs JN, Gichuru EK, Gichuru EK, Gichuru EK, Goodman RN, Gouveia MMC, Grant M, Guerra-Guimarães L, Guerra-Guimarães L, Guest DI, Hammerschmidt R, Hammerschmidt R, Hammond-Kosack KE, Harrison MJ, He ZH, Heath MC, Heath MC, Heath MC, Heath MC, Heath MC, Heath MC, Heath MC, Helena Gil Azinheira, Heslop-Harrison J, Hindorf H, Holguin MF, Huang C, Jalloul A, Johnson R, Jonak C, Kanzaki H, Keen NT, Kibani THM, Klessig DF, Koga H, Kushalappa AC, Laloi C, Lampard JF, Latunde-Dada AO, Latunde-Dada AO, Latunde-Dada AO, Latunde-Dada AO, Lawrence CB, Leguizamon JC, Leite Jr. RP, Leonor Guerra-Guimarães, Li W-B, Lin KC, Lindhout P, Littlefield LJ, Livak KJ, Loureiro A, Loureiro A, Manga B, Manga B, Mansfield J, Maria do Céu Silva, Marques DV, Martins EMF, Martins EMF, Masaba DM, Masaba DM, Masaba DM, Masaba DM, Masaba DM, Mauch-Mani B, Maxemiuc-Naccache V, Maxemiuc-Naccache V, Mayne WW, McDonald J, Mendgen K, Mendgen K, Michel Nicole, Montillet JL, Morris E, Mould MJ, Mould MJR, Nandris D, Neill S, Niks RE, Noronha-Wagner H, Nutman JF, O'Connell RJ, O'Connell RJ, O'Connell RJ, O'Connell RJ, Omondi CO, Omondi CO, Parlevliet JE, Parlevliet JE, Peck SC, Peng M, Perfect SE, Philippe Lashermes, Pilling E, Pink DAC, Pontier D, Pring RJ, Prusky D, Rasmussen JB, Rayner RW, Richael C, Rijkenberg FHJ, Rijo L, Rijo L, Rijo L, Rijo L, Rijo L, Robinson RA, Rodrigues Jr CJ, Rodrigues Jr. CJ, Rodrigues Jr. CJ, Rodrigues Jr. CJ, Rodrigues Jr. CJ, Rodrigues Jr. CJ, Rojas ML, Romeis T, Rostoks N, Ryan CA, Ryerson DE, Saccas AM, Santos P, Scheideler M, Schlumbaum A, Schulze-Lefert P, Silva DM, Silva MC, Silva MC, Silva MC, Silva MC, Silva MC, Silva MC, Silva MC, Silva MC, Silva MC, Simmonds NW, Skalamera D, Skipp RA, Somssich IE, Sreenivasaprasad S, Staskawicz B, Steiner KG, Teri JM, Thordal-Christensen H, Tiburzy R, Torregrosa C, Trevorrow PR, Turner JG, Tuzun S, Vale FXR, Van der Graaff NA, Van der Graaff NA, Van der Plank JE, Van der Vossen HAM, Van der Vossen HAM, Van der Vossen HAM, Van der Vossen HAM, Van Loon LC, Van Loon LC, Van Loon LC, Victor Várzea, Voegele RT, Várzea VMP, Várzea VMP, Várzea VMP, Várzea VMP, Várzea VMP, Várzea VMP, Várzea VMP, Várzea VMP, Waller JM, Waller JM, Walyaro DJ, Way HM, Wellman FL, Wells JM, Wen YT, White O, Wiethölter N, Wrigley G, Yamaguchi T, Zhou FS, Zhou N, Ülker B   +252 more
core   +5 more sources

Data Mining of the Coffee Rust Genome [PDF]

Mathematical Modelling of Natural Phenomena, 2012
The genomes of nine isolates of _Hemileia vastatrix_, the causal agent of coffee leaf rust were sequenced by Illumina and 454. Quality control, cleaning and _de novo_ assemblies of data were performed.
Alvaro Gaitan, David Octavio Botero-Rozo, Diego M. Riañ, Marco Cristancho, Silvia Restrepo, William Giraldo   +5 more
core   +5 more sources

INCIDENCE AND SEVERITY OF COFFEE LEAF RUST, CERCOSPORIOSIS AND COFFEE LEAF MINER IN COFFEE PROGENIES [PDF]

Coffee Science, 2018
Coffee leaf rust is the main disease of this crop, however cercosporiosis and coffee leaf miner can also cause significant damage when they reach high levels of infestation.
Castro, Elisa de Melo, da Silva, Fabiano França, de Carvalho, Alex Mendonça, de Carvalho, Samuel Pereira, Júnior, Sebastião de Lima, Lima, Amador Eduardo de, Sampaio Junior, Hudinilson Gilberto   +6 more
core   +3 more sources

Influence of Environmental Conditions and Genetic Background of Arabica Coffee (C. arabica L) on Leaf Rust (Hemileia vastatrix) Pathogenesis

Frontiers in Plant Science, 2017
Global warming is a major threat to agriculture worldwide. Between 2008 and 2013, some coffee producing countries in South and Central America suffered from severe epidemics of coffee leaf rust (CLR), resulting in high economic losses with social ...
Lucile Toniutti, Lucile Toniutti, Jean-Christophe Breitler, Hervé Etienne, Claudine Campa, Sylvie Doulbeau, Laurent Urban, Charles Lambot, Juan-Carlos H. Pinilla, Benoît Bertrand   +9 more
doaj   +3 more sources

Interactive effects of altitude, microclimate and shading system on coffee leaf rust [PDF]

Journal of Plant Interactions, 2019
Shade effects on coffee diseases are ambiguous because they vary depending on the season and environment. Using Coffee Leaf Rust (CLR) as an example, we demonstrate relationships between the environment and shading systems and their effects on disease ...
Avelino, Jacques, Liebig, Theresa, Läderach, Peter, Poehling, Hans-Michael, Ribeyre, Fabienne, Van Asten, Piet J.A.   +5 more
core   +5 more sources

High-density genetic mapping for coffee leaf rust resistance. [PDF]

Tree Genetics & Genomes, 2016
Coffee leaf rust caused by the fungus Hemileia vastatrix causes considerable economic losses for coffee producers. Although agrochemical products can provide sufficient disease control, the use of resistant cultivars is a safer alternative.
BRITO, G. G. de, CAIXETA, E. T., DIOLA, V., LOUREIRO, M. E., MACIEL-ZAMBOLIM, E., SAKIYAMA, N. S.   +5 more
core   +3 more sources

Shade and leaf retention: an aspect of effective Coffee Leaf Rust management [PDF]

, 2019
Coffee Leaf Rust (CLR) has been reported in over 50 coffee growing countries causing significant economic losses in Arabica coffee. The aim of this study was to determine the effect of shade on leaf life span in relation to severity of coffee leaf rust ...
Alwora, G., Gichuru, E.K., Miano, Douglas W., Mutitu, E.W., Pinard, Fabrice   +4 more
core   +1 more source

Incidence of Coffee Leaf Rust in Vietnam, Possible Original Sources and Subsequent Pathways of Migration. [PDF]

Front Plant Sci, 2022
Le CTM, Okane I, Ono Y, Tsuda Y, Yamaoka Y.   +4 more
europepmc   +2 more sources

Contrasting coffee leaf rust epidemics between forest coffee and semi-forest coffee agroforestry systems in SW-Ethiopia. [PDF]

Heliyon, 2022
Ethiopian Arabica coffee is produced in different agroforestry systems which differ in forest management intensity. In forest coffee systems (FC), coffee shrubs grow naturally in the understory of Afromontane forests with little human intervention, whereas in semi-forest coffee systems (SFC) thinning of the canopy and removal of the understory is ...
Daba G, Berecha G, Lievens B, Hundera K, Helsen K, Honnay O.   +5 more
europepmc   +4 more sources