Liu, X.; Wingen, L. U.; Sotiropoulos, A. G.; Balotf, S.; Kiss, L.; Schiestl, B.; Schmitt, V.; Scheikl, D.; Dunemann, S.; Sargheini, N.; Huettel, B.; Sakhteman, A.; Abele, M.; Ludwig, C.; Tellier, A.; Mueller, M. C.; Hueckelhoven, R.

Some filamentous plant-pathogenic fungi have comparably large genome sizes within the fungal kingdom due to the proliferation of transposable elements (TEs). Blumeria hordei (Bh), the causal agent of the powdery mildew disease on barley, is a filamentous obligate biotrophic fungus. Compared to other ascomycetes, it contains a low number of genes but a high genomic TE content of approximately 75%. Yet, a comprehensive understanding of the contribution of TEs to the RNA and protein landscape of Bh is lacking. Here, we use Bh as a model to study transcripts and proteins derived from genes and individual TEs. Therefore , we created two high-quality genome assemblies of the German Bh isolate TUM1 and the Australian Bh isolate AUS1. We applied deep proteomics with mass spectrometry, long-read and short-read sequencing on both DNA and RNA. Based on these multi-omic resources, we completed nearly gapless genome assemblies, new gene and TE annotations, and effector predictions. Using long-read RNA sequencing, we detected extensive co-transcription of TEs and genes as TE-gene chimeric transcripts. We identified previously unpredicted splice variants or genes, partially supported by proteomics. The intergenic and TE genomic space of Bh TUM1 gives rise to thousands of transcripts and several novel TE-derived proteins that lack from previous TE protein predictions. Together, this supports an existing potential for expression of novel transcripts and proteins from highly abundant TEs in the Bh genome.