OxyR tightly regulates catalase expression in Neisseria meningitidis through both repression and activation mechanisms

Loading...
Thumbnail Image
File version
Author(s)
Ieva, Raffaele
Roncarati, Davide
Metruccio, Matteo ME
Seib, Kate L
Scarlato, Vincenzo
Delany, Isabel
Griffith University Author(s)
Primary Supervisor
Other Supervisors
Editor(s)
Date
2008
Size

1631865 bytes

File type(s)

application/pdf

Location
License
Abstract

Mechanisms for coping with oxidative stress (OS) are crucial for the survival of pathogenic Neisseria spp. in the human host. In this study we investigate the mechanism by which OxyR finely regulates the catalase gene (kat) in Neisseria meningitidis. Detailed transcriptional analyses show that catalase is transcribed from a single promoter that is induced by H2O2 in an OxyR-dependent manner and two key cysteine residues are essential for this. OxyR also represses the kat promoter: kat expression in the null mutant is at a constitutive intermediary level higher than uninduced, but lower than H2O2-induced levels in the wild type. Our data are consistent with a model in which OxyR binds to the kat promoter and exerts: (i) repression of transcription in the absence of OS signal and (ii) activation of the promoter in response to OS signal. This direct double-edged mechanism may ensure tight regulatory control of kat expression ensuring catalase is synthesized only when needed. In addition, our results provide an explanation for the altered OS resistance phenotypes seen in Neisseria mutant strains where, paradoxically, the oxyR mutants are more resistant than the wild type in oxidative killing assays.

Journal Title

Molecular Microbiology

Conference Title
Book Title
Edition
Volume

70

Issue

5

Thesis Type
Degree Program
School
Publisher link
Patent number
Funder(s)
Grant identifier(s)
Rights Statement
Rights Statement

© 2008 Blackwell Publishing Ltd. This is the pre-peer reviewed version of the following article: OxyR tightly regulates catalase expression in Neisseria meningitidis through both repression and activation mechanisms , Molecular Microbiology, Vol. 70(5), 2008, pp. 1152-1165, which has been published in final form at http://dx.doi.org/10.1111/j.1365-2958.2008.06468.x.

Item Access Status
Note
Access the data
Related item(s)
Subject

Biological sciences

Bacteriology

Agricultural, veterinary and food sciences

Biomedical and clinical sciences

Persistent link to this record
Citation
Collections