The making of a new pathogen: insights from comparative population genomics of the domesticated wheat pathogen Mycosphaerella graminicola and its wild sister species.

The fungus Mycosphaerella graminicola emerged as a new pathogen of cultivated wheat during its domestication ~11,000 yr ago. We assembled 12 high-quality full genome sequences to investigate the genetic footprints of selection in this wheat pathogen and closely related sister species that infect wild grasses. We demonstrate a strong effect of natural selection in shaping the pathogen genomes with only ~3% of nonsynonymous mutations being effectively neutral. Forty percent of all fixed nonsynonymous substitutions, on the other hand, are driven by positive selection. Adaptive evolution has affected M. graminicola to the highest extent, consistent with recent host specialization. Positive selection has prominently altered genes encoding secreted proteins and putative pathogen effectors supporting the premise that molecular host-pathogen interaction is a strong driver of pathogen evolution. Recent divergence between pathogen sister species is attested by the high degree of incomplete lineage sorting (ILS) in their genomes. We exploit ILS to generate a genetic map of the species without any crossing data, document recent times of species divergence relative to genome divergence, and show that gene-rich regions or regions with low recombination experience stronger effects of natural selection on neutral diversity. Emergence of a new agricultural host selected a highly specialized and fast-evolving pathogen with unique evolutionary patterns compared with its wild relatives. The strong impact of natural selection, we document, is at odds with the small effective population sizes estimated and suggest that population sizes were historically large but likely unstable.

[1]  Paramvir S. Dehal,et al.  Finished Genome of the Fungal Wheat Pathogen Mycosphaerella graminicola Reveals Dispensome Structure, Chromosome Plasticity, and Stealth Pathogenesis , 2011, PLoS genetics.

[2]  P. Andolfatto,et al.  Effective Population Size and the Efficacy of Selection on the X Chromosomes of Two Closely Related Drosophila Species , 2010, Genome biology and evolution.

[3]  M. Schierup,et al.  Whole-Genome and Chromosome Evolution Associated with Host Adaptation and Speciation of the Wheat Pathogen Mycosphaerella graminicola , 2010, PLoS genetics.

[4]  Philipp W. Messer,et al.  Evidence that Adaptation in Drosophila Is Not Limited by Mutation at Single Sites , 2010, PLoS genetics.

[5]  J. Burdon,et al.  Diversity and evolution of effector loci in natural populations of the plant pathogen Melampsora lini. , 2009, Molecular biology and evolution.

[6]  J. Welch,et al.  Quantifying Adaptive Evolution in the Drosophila Immune System , 2009, PLoS genetics.

[7]  A. Hobolth,et al.  Ancestral Population Genomics: The Coalescent Hidden Markov Model Approach , 2009, Genetics.

[8]  Richard G. F. Visser,et al.  Meiosis Drives Extraordinary Genome Plasticity in the Haploid Fungal Plant Pathogen Mycosphaerella graminicola , 2009, PloS one.

[9]  A. Rokas The effect of domestication on the fungal proteome. , 2009, Trends in genetics : TIG.

[10]  M. Webster,et al.  The legacy of domestication: accumulation of deleterious mutations in the dog genome. , 2008, Molecular biology and evolution.

[11]  W. J. Dickinson,et al.  A genome-wide view of the spectrum of spontaneous mutations in yeast , 2008, Proceedings of the National Academy of Sciences.

[12]  S. Kamoun,et al.  Adaptive evolution has targeted the C-terminal domain of the RXLR effectors of plant pathogenic oomycetes , 2008, The Plant cell.

[13]  Ruiqiang Li,et al.  SOAP: short oligonucleotide alignment program , 2008, Bioinform..

[14]  G. Kema,et al.  Electrophoretic and cytological karyotyping of the foliar wheat pathogen Mycosphaerella graminicola reveals many chromosomes with a large size range. , 2007, Mycologia.

[15]  Ziheng Yang PAML 4: phylogenetic analysis by maximum likelihood. , 2007, Molecular biology and evolution.

[16]  S. Kamoun Groovy times: filamentous pathogen effectors revealed. , 2007, Current opinion in plant biology.

[17]  S. Glémin,et al.  Grinding up wheat: a massive loss of nucleotide diversity since domestication. , 2007, Molecular biology and evolution.

[18]  E. Stukenbrock,et al.  Geographical variation and positive diversifying selection in the host-specific toxin SnToxA. , 2007, Molecular plant pathology.

[19]  S. Brunak,et al.  Locating proteins in the cell using TargetP, SignalP and related tools , 2007, Nature Protocols.

[20]  A. Hobolth,et al.  Genomic Relationships and Speciation Times of Human, Chimpanzee, and Gorilla Inferred from a Coalescent Hidden Markov Model , 2006, PLoS genetics.

[21]  E. Stukenbrock,et al.  Origin and domestication of the fungal wheat pathogen Mycosphaerella graminicola via sympatric speciation. , 2006, Molecular biology and evolution.

[22]  Adam Eyre-Walker,et al.  The genomic rate of adaptive evolution. , 2006, Trends in ecology & evolution.

[23]  John J Welch,et al.  Estimating the Genomewide Rate of Adaptive Protein Evolution in Drosophila , 2006, Genetics.

[24]  G. Larson,et al.  Genetics and animal domestication: new windows on an elusive process , 2006 .

[25]  Jian Lu,et al.  The accumulation of deleterious mutations in rice genomes: a hypothesis on the cost of domestication. , 2006, Trends in genetics : TIG.

[26]  P. Andolfatto Adaptive evolution of non-coding DNA in Drosophila , 2005, Nature.

[27]  S. Banke,et al.  Migration patterns among global populations of the pathogenic fungus Mycosphaerella graminicola , 2005, Molecular ecology.

[28]  Lars M Steinmetz,et al.  Elevated evolutionary rates in the laboratory strain of Saccharomyces cerevisiae. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[29]  J. Dangl,et al.  Diverse Evolutionary Mechanisms Shape the Type III Effector Virulence Factor Repertoire in the Plant Pathogen Pseudomonas syringae , 2004, Genetics.

[30]  B. McDonald,et al.  The interaction among evolutionary forces in the pathogenic fungus Mycosphaerella graminicola. , 2004, Fungal genetics and biology : FG & B.

[31]  S. Banke,et al.  Phylogenetic analysis of globally distributed Mycosphaerella graminicola populations based on three DNA sequence loci. , 2004, Fungal genetics and biology : FG & B.

[32]  Xavier Messeguer,et al.  DnaSP, DNA polymorphism analyses by the coalescent and other methods , 2003, Bioinform..

[33]  B. McDonald,et al.  Distribution of mating type alleles in the wheat pathogen Mycosphaerella graminicola over spatial scales from lesions to continents. , 2002, Fungal genetics and biology : FG & B.

[34]  G. Kema,et al.  Isolation and characterization of the mating-type idiomorphs from the wheat septoria leaf blotch fungus Mycosphaerella graminicola. , 2002, Fungal genetics and biology : FG & B.

[35]  R. Nielsen,et al.  Distinguishing migration from isolation: a Markov chain Monte Carlo approach. , 2001, Genetics.

[36]  M. Nei,et al.  Molecular Evolution and Phylogenetics , 2000 .

[37]  Jody Hey,et al.  The limits of selection during maize domestication , 1999, Nature.

[38]  M. Kreitman,et al.  Adaptive protein evolution at the Adh locus in Drosophila , 1991, Nature.

[39]  M. Nei,et al.  Simple methods for estimating the numbers of synonymous and nonsynonymous nucleotide substitutions. , 1986, Molecular biology and evolution.

[40]  R. Zare,et al.  Studies on the host range of Septoria species on cereals and some wild grasses in Iran , 2009 .

[41]  D. Haussler,et al.  Human-mouse alignments with BLASTZ. , 2003, Genome research.

[42]  Z. Yang,et al.  Estimating synonymous and nonsynonymous substitution rates under realistic evolutionary models. , 2000, Molecular biology and evolution.