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– Pseudocercospora fuligena from leaf spots on Lycopersicon esculentum . 1 – 2 Lesions on host leaves (1. upper surface, 2. lower surface). 3 – 4 Stromata and conidiophores. 5 – 8 Conidia. 9 Culture. Bars 1, 2 = 10 mm, 3 – 8 = 10 μm, 9 = 10 mm. 

– Pseudocercospora fuligena from leaf spots on Lycopersicon esculentum . 1 – 2 Lesions on host leaves (1. upper surface, 2. lower surface). 3 – 4 Stromata and conidiophores. 5 – 8 Conidia. 9 Culture. Bars 1, 2 = 10 mm, 3 – 8 = 10 μm, 9 = 10 mm. 

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Fig. 1 – Leaf spots caused by Pseudocercospora fuligena . 
Fig. 2 – Pseudocercospora fuligena. 1 Stroma and conidiophores. 2...
Fig. 3 – Pseudocercospora fuligena from leaf spots on Lycopersicon...
Tropical phytopathogens 2: Pseudocercospora fuligena
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U 2012 – Tropical phytopathogens 2: Pseudocercospora fuligena. Plant Pathology & Quarantine 2(1), 57–62, doi 10.5943/ppq/2/1/8 Black leaf mold of tomato (Lycopersicon esculentum) is caused by Pseudocercospora fuligena, and the fungus and symptoms of the disease are illustrated and described. This cercosporoid disease causes leaf spots and spots on...
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... Com o desenvolvimento da doença, crescimento pulverulento escuro irá ocorrer nas duas superfícies das folhas que murcham e secam e, geralmente, permanecem presas à planta com uma aparência fuliginosa escura. As manchas podem ocorrer também em pecíolos, caules e pedúnculos dos frutos, mas não nos frutos(PHENGSINTHAM et al., 2012).Manejo: realizar adubação balanceada; fazer irrigação adequada; fazer rotação de cultivos; escolher cultivar com maior resistência(PHENGSINTHAM et al., 2012); e aplicar, se necessário, calda bordalesa (ver em receitas para tratar problemas fitossanitários).Figura 87. Sintomas de cercosporiose ou mancha de cercóspora (Pseudocercospora sp.) em folhas de tomate (A e B). ...
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First Draft Genome Resource for the Tomato Black Leaf Mold Pathogen Pseudocercospora fuligena
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  • MOL PLANT MICROBE IN
Pseudocercospora fuligena is a fungus that causes black leaf mold, an important disease of tomato in tropical and subtropical regions of the world. Despite its economic importance, genomic resources for this pathogen are scarce and no reference genome was available thus far. Here, we report a 50.6-Mb genome assembly for P. fuligena, consisting of 348 contigs with an N 50 value of 0.407 Mb. In total, 13,764 protein-coding genes were predicted with an estimated BUSCO completeness of 98%. Among the predicted genes there were 179 candidate effectors, 445 carbohydrate-active enzymes, and 30 secondary metabolite gene clusters. The resources presented in this study will allow genome-wide comparative analyses and population genomic studies of this pathogen, ultimately improving management strategies for black leaf mold of tomato.
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Pseudocercospora solanacea revisited and a survey of Pseudocercospora spp. on Solanum with a key to the species
Article
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Braun, U. 2017: Pseudocercospora solanacea revisited and a survey of Pseudocercospora spp. on Solanum with a key to the species. Schlechtendalia 32: 51–65. The nomenclature of Pseudocercospora solanacea is discussed in detail and a description, based on the re-examination of type material, is provided. The taxonomy of this species is discussed in the context of other Pseudocercospora species on hosts of the genus Solanum, and the species concerned are keyed out. Cercospora atromarginalis, C. rigospora, and C. solani-nigri are lectotypified. Cercospora fuligena ( Pseudocercospora fuligena), C. solani-nigri, Pseudocercospora solani-melongenicola are reduced to synonymy with Pseudocercospora atromarginalis.
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