A modified recombineering protocol for the genetic manipulation of gene clusters in Aspergillus fumigatus

Genomic analyses of fungal genome structure have revealed the presence of physically-linked groups of genes, termed gene clusters, where collective functionality of encoded gene products serves a common biosynthetic purpose. In multiple fungal pathogens of humans and plants gene clusters have been s...

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Bibliographic Details
Published in:PloS one 2014-11, Vol.9 (11), p.e111875
Main Authors: Alcazar-Fuoli, Laura, Cairns, Timothy, Lopez, Jordi F, Zonja, Bozo, Pérez, Sandra, Barceló, Damià, Igarashi, Yasuhiro, Bowyer, Paul, Bignell, Elaine
Format: Article
Language:English
Subjects:
Alleles
Animals
Aspergillus
Aspergillus fumigatus
Aspergillus fumigatus - genetics
Aspergillus fumigatus - immunology
Bacteria
Bacterial artificial chromosomes
Biology and Life Sciences
Biosynthesis
Cassettes
Cell Line
Chromosome deletion
Chromosomes
Chromosomes, Artificial, Bacterial
Clonal deletion
Cloning
Cloning, Molecular
Deoxyribonucleic acid
DNA
Epigenetics
Fungal infections
Fungi
Gene clusters
Gene deletion
Gene Order
Genes
Genes, Fungal
Genetic engineering
Genetic Engineering - methods
Genetic research
Genomes
Genomic analysis
Genomics
Health aspects
Host-Pathogen Interactions - genetics
Host-Pathogen Interactions - immunology
Hypoxia
Infection
Inflammation
Insects
Laboratories
Macrophages - immunology
Macrophages - microbiology
Medicine
Metabolites
Methodology
Mice
Multigene Family
Municipalities
Mycoses
Pathogenicity
Pathogens
Peptides
Phages
Physiological aspects
Plant genetics
Plant metabolites
Plants (botany)
Recombination
Science
Secondary metabolites
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Summary:Genomic analyses of fungal genome structure have revealed the presence of physically-linked groups of genes, termed gene clusters, where collective functionality of encoded gene products serves a common biosynthetic purpose. In multiple fungal pathogens of humans and plants gene clusters have been shown to encode pathways for biosynthesis of secondary metabolites including metabolites required for pathogenicity. In the major mould pathogen of humans Aspergillus fumigatus, multiple clusters of co-ordinately upregulated genes were identified as having heightened transcript abundances, relative to laboratory cultured equivalents, during the early stages of murine infection. The aim of this study was to develop and optimise a methodology for manipulation of gene cluster architecture, thereby providing the means to assess their relevance to fungal pathogenicity. To this end we adapted a recombineering methodology which exploits lambda phage-mediated recombination of DNA in bacteria, for the generation of gene cluster deletion cassettes. By exploiting a pre-existing bacterial artificial chromosome (BAC) library of A. fumigatus genomic clones we were able to implement single or multiple intra-cluster gene replacement events at both subtelomeric and telomere distal chromosomal locations, in both wild type and highly recombinogenic A. fumigatus isolates. We then applied the methodology to address the boundaries of a gene cluster producing a nematocidal secondary metabolite, pseurotin A, and to address the role of this secondary metabolite in insect and mammalian responses to A. fumigatus challenge.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0111875