TY - JOUR
T1 - Temperature modulates the secretome of the phytopathogenic fungus Lasiodiplodia theobromae
AU - Félix, Carina
AU - Duarte, Ana S.
AU - Vitorino, Rui
AU - Guerreiro, Ana C.L.
AU - Domingues, Pedro
AU - Correia, António C.M.
AU - Alves, Artur
AU - Esteves, Ana C.
N1 - Funding Information:
Recently, there has been considerable interest in the decay D + --'11' n + ~1 due to conflicting measurements of the branching ratio relative to the decay D~--. 0n + \[1 -4\]. A precise measurement of this decay rate is of interest since a large D~+ -,q'n + branching ratio poses problems for current models, which predict values of BR(D~ + ~'n +)/BR(D + ~0n +) of less than 2 \[5 ,6 \]. Among the mechanisms offered as possible explanations for larger values are final-state interactions and even the presence of a nearby scalar resonance \[5 ,7 \]. Several experiments have searched for evidence of the decay D~+ ~l\]'n +. An indication for a signal was reported by Mark II \[1 \], with a value of 4.8 + 2.1 for the ratio BR(D + --,Tl'n +)/BR(D + --.0n +). Subsequently, NA14' also claimed evidence for this channel, with a value of 5.0 + 1.8 + 1.2 for the same ratio \[3\]. However, in considerable disagreement with these results are the upper limits reported by Mark III and E691. These experiments have determined BR(D + ~l\]'n + )/BR(D + ~0n + ) to be less than 1.9 \[2\] and less than 1.7 \[4\] respectively, both at the t Supported by the German Bundesministerium f'tir Forschung und Technologie, under contract number 054DO51P. 2 Supported by the German Bundesministerium f'tir Forschung und Technologie, under contract number 054ER 12P. 3 Supported by the German Bundesministerium f'tir Forschung und Technologie, under contract number 054HD24P. 4 McGill University, Montreal, Quebec, Canada H3C 3J7. 5 University of Toronto, Toronto, Ontario, Canada M5S IA7. 6 Carleton University, Ottawa, Ontario, Canada K1S 5B6. 7 Supported by the Natural Sciences and Engineering Research Council, Canada. 8 Supported by the German Bundesministerium f'dr Forschung und Technologie, under contract number 054KA 17P. 9 Supported by Alexander yon Humboldt Stiftung, Bonn, FRG. 1o Supported by Raziskovalna skupnost Slovenije and the Inter-nationales Biiro KfA, Jiilich. 11 Supported by the Swedish Research Council. 12 Supported by the US Department of Energy, under contract DE-AS09-80ER 10690. at References in this paper to a specific charged state are to be interpreted as implying the charge-conjugate state also.
Publisher Copyright:
© 2016 Félix, Duarte, Vitorino, Guerreiro, Domingues, Correia, Alves and Esteves.
PY - 2016/8/3
Y1 - 2016/8/3
N2 - Environmental alterations modulate host-microorganism interactions. Little is known about how climate changes can trigger pathogenic features on symbiont or mutualistic microorganisms. Current climate models predict increased environmental temperatures. The exposing of phytopathogens to these changing conditions can have particularly relevant consequences for economically important species and for humans. The impact on pathogen/host interaction and the shift on their biogeographical range can induce different levels of virulence in new hosts, allowing massive losses in agricultural and health fields. Lasiodiplodia theobromae is a phytopathogenic fungus responsible for a number of diseases in various plants. It has also been described as an opportunist pathogen in humans, causing infections with different levels of severity. L. theobromae has a high capacity of adaptation to different environments, such as woody plants, moist argillaceous soils, or even humans, being able to grow and infect hosts in a wide range of temperatures (9-39°C). Nonetheless, the effect of an increase of temperature, as predicted in climate change models, on L. theobromae is unknown. Here we explore the effect of temperature on two strains of L. theobromae - an environmental strain, CAA019, and a clinical strain, CBS339.90. We show that both strains are cytotoxic to mammalian cells but while the environmental strain is cytotoxic mainly at 25°C, the clinical strain is cytotoxic mainly at 30 and 37°C. Extracellular gelatinolytic, xylanolytic, amylolytic, and cellulolytic activities at 25 and 37°C were characterized by zymography and the secretome of both strains grown at 25, 30, and 37°C were characterized by electrophoresis and by Orbitrap LC-MS/MS. More than 75% of the proteins were identified, mostly enzymes (glycosyl hydrolases and proteases). The strains showed different protein profiles, which were affected by growth temperature. Also, strain specific proteins were identified, such as a putative f5/8 type c domain protein - known for being involved in pathogenesis - by strain CAA019 and a putative tripeptidyl- peptidase 1 protein, by strain CBS339.90. We showed that temperature modulates the secretome of L. theobromae. This modulation may be associated with host-specificity requirements. We show that the study of abiotic factors, such as temperature, is crucial to understand host/pathogen interactions and its impact on disease.
AB - Environmental alterations modulate host-microorganism interactions. Little is known about how climate changes can trigger pathogenic features on symbiont or mutualistic microorganisms. Current climate models predict increased environmental temperatures. The exposing of phytopathogens to these changing conditions can have particularly relevant consequences for economically important species and for humans. The impact on pathogen/host interaction and the shift on their biogeographical range can induce different levels of virulence in new hosts, allowing massive losses in agricultural and health fields. Lasiodiplodia theobromae is a phytopathogenic fungus responsible for a number of diseases in various plants. It has also been described as an opportunist pathogen in humans, causing infections with different levels of severity. L. theobromae has a high capacity of adaptation to different environments, such as woody plants, moist argillaceous soils, or even humans, being able to grow and infect hosts in a wide range of temperatures (9-39°C). Nonetheless, the effect of an increase of temperature, as predicted in climate change models, on L. theobromae is unknown. Here we explore the effect of temperature on two strains of L. theobromae - an environmental strain, CAA019, and a clinical strain, CBS339.90. We show that both strains are cytotoxic to mammalian cells but while the environmental strain is cytotoxic mainly at 25°C, the clinical strain is cytotoxic mainly at 30 and 37°C. Extracellular gelatinolytic, xylanolytic, amylolytic, and cellulolytic activities at 25 and 37°C were characterized by zymography and the secretome of both strains grown at 25, 30, and 37°C were characterized by electrophoresis and by Orbitrap LC-MS/MS. More than 75% of the proteins were identified, mostly enzymes (glycosyl hydrolases and proteases). The strains showed different protein profiles, which were affected by growth temperature. Also, strain specific proteins were identified, such as a putative f5/8 type c domain protein - known for being involved in pathogenesis - by strain CAA019 and a putative tripeptidyl- peptidase 1 protein, by strain CBS339.90. We showed that temperature modulates the secretome of L. theobromae. This modulation may be associated with host-specificity requirements. We show that the study of abiotic factors, such as temperature, is crucial to understand host/pathogen interactions and its impact on disease.
KW - Cytotoxicity
KW - Extracellular enzymes
KW - Global changes
KW - Phytopathogenic fungi
KW - Secretome
UR - http://www.scopus.com/inward/record.url?scp=84984656891&partnerID=8YFLogxK
U2 - 10.3389/fpls.2016.01096
DO - 10.3389/fpls.2016.01096
M3 - Article
AN - SCOPUS:84984656891
SN - 1664-462X
VL - 7
JO - Frontiers in Plant Science
JF - Frontiers in Plant Science
IS - AUG2016
M1 - 1096
ER -