Assessing the biology of wheat-infecting Botryosphaeriaceae spp.
Abstract
In 1999, a novel wheat disease was observed in Queensland,
Australia. This disease induced grain shrivelling and was
described as white grain disorder (WGD). WGD is now a documented
disease across all mainland wheat-growing States. It was unknown
where the causal fungus originated, how it was able to infect
wheat, and whether there were any other non-grass hosts. Using
molecular techniques and morphological analyses to examine fungi
from infected grain, I determined that the causal agent of WGD
was three distinct species of fungi of the genus Eutiarosporella,
in the Botryosphaeriaceae family. I classified these as
Eutiarosporella darliae, E. pseudodarliae, and E.
tritici-australis.
The three species’ genomes were sequenced to gain a better
understanding of their lifestyle. My primary focus became
analysing secondary metabolite (SM) clusters, particularly
polyketide synthases (PKS) and non-ribosomal peptide synthases
(NRPS). I discovered that the WGD-Eutiarosporella spp. harbour
modular PKS genes (mPKSs). mPKSs have previously only been
observed in bacteria and protist species, not in fungi. Through
phylogenetic analyses, I concluded that these mPKSs were
horizontally acquired from an unknown species.
I also identified an SM cluster with three co-localised hybrid
PKS-NRPS genes in E. darliae and E. pseudodarliae, but absent in
E. tritici-australis. A comparison of syntenic genes among all
three species revealed that this cluster was once present in E.
tritici-australis, but was lost. Genes homologous to one of the
PKS-NRPSs are linked to disease in woody plants in other fungi.
Subsequent inoculation of Hakea leaves with E. darliae and E.
pseudodarliae induced necrotic disease symptoms,
9 whereas E. tritici-australis did not. I concluded that the
WGD-Eutiarosporella
species were likely once primarily woody plant pathogens and
speculate that such species may act as reservoirs for the fungi.
Another aspect of the life-style of the WGD-Eutiarosporella that
I sought to elucidate was a mechanism of sexual reproduction.
Sexual spores have been observed in the field for the
WGD-Eutiarosporella spp.. Consequently, I analysed their genomes
to determine the composition of mating type genes. E. darliae and
E. pseudodarliae each possessed a copy of each mating type gene,
MAT1-1-1 and MAT1-2-1, which indicates that these species are
homothallic (self-fertile). However, MAT1-1-1 was located distal
to the MAT-locus, within the middle of an unrelated gene. Only
MAT1-2-1 could be identified in the sequenced E. tritici-
australis isolate. However, additional screened isolates
harboured either MAT1-1-1 or MAT1-2-1, indicating that E.
tritici-australis is heterothallic (non-self-fertile). I
concluded that E. darliae and E. pseudodarliae’s ancestor
transitioned from heterothallism to homothallism via a cryptic
DNA integration event.
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