Chromosome-level genome assembly and manually-curated proteome of model necrotroph Parastagonospora nodorum Sn15 reveals a genome-wide trove of candidate effector homologs, and redundancy of virulence-related functions within an accessory chromosome

Background The fungus Parastagonospora nodorum causes septoria nodorum blotch (SNB) of wheat (Triticum aestivum) and is a model species for necrotrophic plant pathogens. The genome assembly of reference isolate Sn15 was first reported in 2007. P. nodorum infection is promoted by its production of proteinaceous necrotrophic effectors, three of which are characterised – ToxA, Tox1 and Tox3. Results A chromosome-scale genome assembly of P. nodorum Australian reference isolate Sn15, which combined long read sequencing, optical mapping and manual curation, produced 23 chromosomes with 21 chromosomes possessing both telomeres. New transcriptome data were combined with fungal-specific gene prediction techniques and manual curation to produce a high-quality predicted gene annotation dataset, which comprises 13,869 high confidence genes, and an additional 2534 lower confidence genes retained to assist pathogenicity effector discovery. Comparison to a panel of 31 internationally-sourced isolates identified multiple hotspots within the Sn15 genome for mutation or presence-absence variation, which was used to enhance subsequent effector prediction. Effector prediction resulted in 257 candidates, of which 98 higher-ranked candidates were selected for in-depth analysis and revealed a wealth of functions related to pathogenicity. Additionally, 11 out of the 98 candidates also exhibited orthology conservation patterns that suggested lateral gene transfer with other cereal-pathogenic fungal species. Analysis of the pan-genome indicated the smallest chromosome of 0.4 Mbp length to be an accessory chromosome (AC23). AC23 was notably absent from an avirulent isolate and is predominated by mutation hotspots with an increase in non-synonymous mutations relative to other chromosomes. Surprisingly, AC23 was deficient in effector candidates, but contained several predicted genes with redundant pathogenicity-related functions. Conclusions We present an updated series of genomic resources for P. nodorum Sn15 – an important reference isolate and model necrotroph – with a comprehensive survey of its predicted pathogenicity content.

Accessory Chromosome-Acquired Secondary Metabolism in Plant Pathogenic Fungi: The Evolution of Biotrophs Into Host-Specific Pathogens

Accessory chromosomes are strain- or pathotype-specific chromosomes that exist in addition to the core chromosomes of a species and are generally not considered essential to the survival of the organism. Among pathogenic fungal species, accessory chromosomes harbor pathogenicity or virulence factor genes, several of which are known to encode for secondary metabolites that are involved in plant tissue invasion. Accessory chromosomes are of particular interest due to their capacity for horizontal transfer between strains and their dynamic “crosstalk” with core chromosomes. This review focuses exclusively on secondary metabolism (including mycotoxin biosynthesis) associated with accessory chromosomes in filamentous fungi and the role accessory chromosomes play in the evolution of secondary metabolite gene clusters. Untargeted metabolomics profiling in conjunction with genome sequencing provides an effective means of linking secondary metabolite products with their respective biosynthetic gene clusters that reside on accessory chromosomes. While the majority of literature describing accessory chromosome-associated toxin biosynthesis comes from studies ofAlternariapathotypes, the recent discovery of accessory chromosome-associated biosynthetic genes inFusariumspecies offer fresh insights into the evolution of biosynthetic enzymes such as non-ribosomal peptide synthetases (NRPSs), polyketide synthases (PKSs) and regulatory mechanisms governing their expression.

A partial pathogenicity chromosome in Fusarium oxysporum is sufficient to cause disease and can be horizontally transferred

During host colonization, plant pathogenic fungi secrete proteins, called effectors, to facilitate infection. Collectively, effectors may defeat the plant immune system, but usually not all effectors are equally important for infecting a particular host plant. In Fusarium oxysporum f.sp. lycopersici, all known effector genes – also called SIX genes – are located on a single accessory chromosome which is required for pathogenicity and can also be horizontally transferred to another strain. To narrow down the minimal region required for virulence, we selected partial pathogenicity chromosome deletion strains by fluorescence-assisted cell sorting of a strain in which the two arms of the pathogenicity chromosome were labelled with GFP and RFP, respectively. By testing the virulence of these deletion mutants, we show that the complete long arm and part of the short arm of the pathogenicity chromosome are not required for virulence. In addition, we demonstrate that smaller versions of the pathogenicity chromosome can also be transferred to a non-pathogenic strain and they are sufficient to turn the non-pathogen into a pathogen. Surprisingly, originally non-pathogenic strains that had received a smaller version of the pathogenicity chromosome were much more aggressive than recipients with a complete pathogenicity chromosome. Whole genome sequencing analysis revealed that partial deletions of the pathogenicity chromosome occurred mainly close to repeats, and that spontaneous duplication of sequences in accessory regions is frequent both in chromosome deletion strains and in horizontal transfer (recipient) strains.Author SummaryFungal genomes can often be divided into a core genome, which is essential for growth, and an accessory genome which is dispensable. The accessory genome in fungi can be beneficial under some conditions. For example, in some plant-pathogenic fungi, virulence genes are present in the accessory genome, which enable these fungi to cause disease on certain hosts. In Fusarium oxysporum f.sp. lycopersici, which infects tomato, all host-specific virulence genes are located on a single accessory chromosome. This ‘pathogenicity chromosome’ can be horizontally transferred between strains. Here, we found that many suspected virulence genes are in fact not required for virulence because strains without a large part of the pathogenicity chromosome, including these genes, showed no reduced virulence. In addition, we demonstrate that partial pathogenicity chromosomes can be horizontally transferred to a non-pathogen. Surprisingly, originally non-pathogenic strains that had received a partial pathogenicity chromosome were more virulent than strains that had received the complete pathogenicity chromosome.

FRAGMENTS WITH ACCESSORY CHROMOSOME CHARACTERISTICS IN CULTIVATED BARLEY (HORDEUM VULGARE)

A number of fragment chromosomes were isolated from the progeny of barley triploids and their trisomic derivatives. They were smaller than normal barley telocentrics, with a globular appearance, and some carried a small satellite. Their number per cell varied in both somatic and germinal tissue. At meiosis, pairing was observed between fragments, but pairing with the normal chromosomes was virtually absent. Unlike normal chromosomes when univalent, the fragments were always positioned on the equatorial plate at MI. Paired fragments behaved normally, but univalent ones divided precociously, rarely lagging at MI. At second division, lagging occurred frequently, with micronuclei forming at the quartet stage. Fertility was reduced substantially only in plants carrying more than one fragment. The behavior of these fragments in general conformed to that of "accessory chromosomes." They were assumed to have arisen from normal chromosomes which had lost their pairing arms, and/or from fragmentation of satellited telocentrics.