Literature DB >> 15231256

Strategies used by bacterial pathogens to suppress plant defenses.

Robert B Abramovitch1, Gregory B Martin.   

Abstract

Plant immune systems effectively prevent infections caused by the majority of microbial pathogens that are encountered by plants. However, successful pathogens have evolved specialized strategies to suppress plant defense responses and induce disease susceptibility in otherwise resistant hosts. Recent advances reveal that phytopathogenic bacteria use type III effector proteins, toxins, and other factors to inhibit host defenses. Host processes that are targeted by bacteria include programmed cell death, cell wall-based defense, hormone signaling, the expression of defense genes, and other basal defenses. The discovery of plant defenses that are vulnerable to pathogen attack has provided new insights into mechanisms that are essential for both bacterial pathogenesis and plant disease resistance.

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Year:  2004        PMID: 15231256     DOI: 10.1016/j.pbi.2004.05.002

Source DB:  PubMed          Journal:  Curr Opin Plant Biol        ISSN: 1369-5266            Impact factor:   7.834


  56 in total

1.  Tobacco calmodulin-like protein provides secondary defense by binding to and directing degradation of virus RNA silencing suppressors.

Authors:  Kenji S Nakahara; Chikara Masuta; Syouta Yamada; Hanako Shimura; Yukiko Kashihara; Tomoko S Wada; Ayano Meguro; Kazunori Goto; Kazuki Tadamura; Kae Sueda; Toru Sekiguchi; Jun Shao; Noriko Itchoda; Takeshi Matsumura; Manabu Igarashi; Kimihito Ito; Richard W Carthew; Ichiro Uyeda
Journal:  Proc Natl Acad Sci U S A       Date:  2012-06-04       Impact factor: 11.205

2.  Diverse AvrPtoB homologs from several Pseudomonas syringae pathovars elicit Pto-dependent resistance and have similar virulence activities.

Authors:  Nai-Chun Lin; Robert B Abramovitch; Young Jin Kim; Gregory B Martin
Journal:  Appl Environ Microbiol       Date:  2006-01       Impact factor: 4.792

3.  Direct protein interaction underlies gene-for-gene specificity and coevolution of the flax resistance genes and flax rust avirulence genes.

Authors:  Peter N Dodds; Gregory J Lawrence; Ann-Maree Catanzariti; Trazel Teh; Ching-I A Wang; Michael A Ayliffe; Bostjan Kobe; Jeffrey G Ellis
Journal:  Proc Natl Acad Sci U S A       Date:  2006-05-26       Impact factor: 11.205

4.  Insights into nonhost disease resistance: can they assist disease control in agriculture?

Authors:  Jeff Ellis
Journal:  Plant Cell       Date:  2006-03       Impact factor: 11.277

Review 5.  Molecular mechanisms of host-pathogen interactions and their potential for the discovery of new drug targets.

Authors:  Volker Briken
Journal:  Curr Drug Targets       Date:  2008-02       Impact factor: 3.465

6.  Xanthomonas axonopodis pv. citri uses a plant natriuretic peptide-like protein to modify host homeostasis.

Authors:  Natalia Gottig; Betiana S Garavaglia; Lucas D Daurelio; Alex Valentine; Chris Gehring; Elena G Orellano; Jorgelina Ottado
Journal:  Proc Natl Acad Sci U S A       Date:  2008-11-17       Impact factor: 11.205

7.  The N-terminal region of Pseudomonas type III effector AvrPtoB elicits Pto-dependent immunity and has two distinct virulence determinants.

Authors:  Fangming Xiao; Ping He; Robert B Abramovitch; Jennifer E Dawson; Linda K Nicholson; Jen Sheen; Gregory B Martin
Journal:  Plant J       Date:  2007-08-31       Impact factor: 6.417

8.  Pseudomonas syringae type III effector AvrPtoB is phosphorylated in plant cells on serine 258, promoting its virulence activity.

Authors:  Fangming Xiao; Patrick Giavalisco; Gregory B Martin
Journal:  J Biol Chem       Date:  2007-08-20       Impact factor: 5.157

9.  ARGONAUTE4 is required for resistance to Pseudomonas syringae in Arabidopsis.

Authors:  Astrid Agorio; Pablo Vera
Journal:  Plant Cell       Date:  2007-11-09       Impact factor: 11.277

10.  Quantitative proteomics of tomato defense against Pseudomonas syringae infection.

Authors:  Jennifer Parker; Jin Koh; Mi-Jeong Yoo; Ning Zhu; Michelle Feole; Sarah Yi; Sixue Chen
Journal:  Proteomics       Date:  2013-04-27       Impact factor: 3.984
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