Microbial Glycosylated Components in Plant Disease

Max Dow; Antonio Molinaro; Richard M. Cooper; Mari Anne Newman

doi:10.1016/B978-0-12-374546-0.00040-7

Microbial Glycosylated Components in Plant Disease

Max Dow^*, Antonio Molinaro, Richard M. Cooper, Mari Anne Newman

^*Corresponding author af dette arbejde

Publikation: Bidrag til bog/antologi/rapport › Bidrag til bog/antologi › Forskning › peer review

5 Citationer (Scopus)

Abstract

In order to be successful, a plant pathogen must be able to tolerate the host environment, evade or overcome preformed defenses and suppress or fail to elicit induced defenses. Components such as lipopolysaccharides, peptidoglycan, chitin, and glucan are considered to be microbe-associated molecular patterns, molecules that comprise (relatively) invariant structural moieties and that are indispensable to the pathogen, but which are recognized by plants to elicit defense responses. In phytopathogenic bacteria, extracellular polysaccharides and extracellular cyclic glucan have been implicated in suppression of particular defense responses. It is evident that microbial glycosylated components can play important, and sometimes opposing, roles in plant-microbe interactions. Roles such as elicitation of plant defenses are of benefit to the host. Conversely, other roles such as promotion of colonization of plant surfaces, suppression of basal defense responses and increasing microbial tolerance to the host environment, are of benefit to the pathogen. Bacterial polysaccharides can also have additional roles in other aspects of pathogen behavior that may include colonization of plant surfaces, biofilm formation, and tolerance to the host environment.

Originalsprog	Engelsk
Titel	Microbial Glycobiology
Antal sider	18
Forlag	Elsevier Science Inc.
Publikationsdato	2010
Sider	803-820
ISBN (Trykt)	9780123745460
DOI	https://doi.org/10.1016/B978-0-12-374546-0.00040-7
Status	Udgivet - 2010

Bibliografisk note

Funding Information:
M.D. acknowledges funding by the Science Foundation of Ireland through Principal Investigator Awards 03/IN3/B373 and 07/IN.1/B955. The work at the Università di Napoli (A.M.) is supported by MIUR, Rome (Progetti di Ricerca di Interesse Nazionale). Work at the University of Bath (R.M.C) was funded by a grant from the Leverhulme Trust. Work at the University of Copenhagen (M.-A. N) is supported by grants from The Danish Council for Technology and Innovation (Copenhagen, Denmark). M.-A. N. also acknowledges financial support from Købmand Sven Hansen and Hustru Ina Hansens Fond, Sorø, Denmark and grants from the Danish Agricultural and Veterinary Research Council and by the Carlsbergfondet (Copenhagen, Denmark).

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10.1016/B978-0-12-374546-0.00040-7

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Link to publication in Scopus

Citationsformater

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title = "Microbial Glycosylated Components in Plant Disease",

abstract = "In order to be successful, a plant pathogen must be able to tolerate the host environment, evade or overcome preformed defenses and suppress or fail to elicit induced defenses. Components such as lipopolysaccharides, peptidoglycan, chitin, and glucan are considered to be microbe-associated molecular patterns, molecules that comprise (relatively) invariant structural moieties and that are indispensable to the pathogen, but which are recognized by plants to elicit defense responses. In phytopathogenic bacteria, extracellular polysaccharides and extracellular cyclic glucan have been implicated in suppression of particular defense responses. It is evident that microbial glycosylated components can play important, and sometimes opposing, roles in plant-microbe interactions. Roles such as elicitation of plant defenses are of benefit to the host. Conversely, other roles such as promotion of colonization of plant surfaces, suppression of basal defense responses and increasing microbial tolerance to the host environment, are of benefit to the pathogen. Bacterial polysaccharides can also have additional roles in other aspects of pathogen behavior that may include colonization of plant surfaces, biofilm formation, and tolerance to the host environment.",

author = "Max Dow and Antonio Molinaro and Cooper, {Richard M.} and Newman, {Mari Anne}",

note = "Funding Information: M.D. acknowledges funding by the Science Foundation of Ireland through Principal Investigator Awards 03/IN3/B373 and 07/IN.1/B955. The work at the Universit{\`a} di Napoli (A.M.) is supported by MIUR, Rome (Progetti di Ricerca di Interesse Nazionale). Work at the University of Bath (R.M.C) was funded by a grant from the Leverhulme Trust. Work at the University of Copenhagen (M.-A. N) is supported by grants from The Danish Council for Technology and Innovation (Copenhagen, Denmark). M.-A. N. also acknowledges financial support from K{\o}bmand Sven Hansen and Hustru Ina Hansens Fond, Sor{\o}, Denmark and grants from the Danish Agricultural and Veterinary Research Council and by the Carlsbergfondet (Copenhagen, Denmark).",

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N2 - In order to be successful, a plant pathogen must be able to tolerate the host environment, evade or overcome preformed defenses and suppress or fail to elicit induced defenses. Components such as lipopolysaccharides, peptidoglycan, chitin, and glucan are considered to be microbe-associated molecular patterns, molecules that comprise (relatively) invariant structural moieties and that are indispensable to the pathogen, but which are recognized by plants to elicit defense responses. In phytopathogenic bacteria, extracellular polysaccharides and extracellular cyclic glucan have been implicated in suppression of particular defense responses. It is evident that microbial glycosylated components can play important, and sometimes opposing, roles in plant-microbe interactions. Roles such as elicitation of plant defenses are of benefit to the host. Conversely, other roles such as promotion of colonization of plant surfaces, suppression of basal defense responses and increasing microbial tolerance to the host environment, are of benefit to the pathogen. Bacterial polysaccharides can also have additional roles in other aspects of pathogen behavior that may include colonization of plant surfaces, biofilm formation, and tolerance to the host environment.

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