Abstract
Elms, especially Ulmus minor and U. americana, are carrying out a hard battle against Dutch elm disease (DED). This vascular wilt disease, caused by Ophiostoma ulmi and O. novo-ulmi, appeared in the twentieth century and killed millions of elms across North America and Europe. Elm breeding and conservation programmes have identified a reduced number of DED tolerant genotypes. In this study, three U. minor genotypes with contrasted levels of tolerance to DED were exposed to several biotic and abiotic stresses in order to (i) obtain a de novo assembled transcriptome of U. minor using 454 pyrosequencing, (ii) perform a functional annotation of the assembled transcriptome, (iii) identify genes potentially involved in the molecular response to environmental stress, and (iv) develop gene-based markers to support breeding programmes. A total of 58,429 putative unigenes were identified after assembly and filtering of the transcriptome. 32,152 of these unigenes showed homology with proteins identified in the genome from the most common plant model species. Well-known family proteins and transcription factors involved in abiotic, biotic or both stresses were identified after functional annotation. A total of 30,693 polymorphisms were identified in 7,125 isotigs, a large number of them corresponding to single nucleotide polymorphisms (SNPs; 27,359). In a subset randomly selected for validation, 87% of the SNPs were confirmed. The material generated may be valuable for future Ulmus gene expression, population genomics and association genetics studies, especially taking into account the scarce molecular information available for this genus and the great impact that DED has on elm populations.
Highlights
Owing to their long life cycles, forest tree species need to develop evolutionary mechanisms and processes to cope with different abiotic and biotic stresses
146 unique transcripts found a best blast hit with O. ulmi genome, 6 showed the highest homology with O. novo-ulmi, and the remaining 29 sequences aligned best with D. eschscholzii genome
The transcriptome collection represents the major genetic resource for U. minor focused on biotic and abiotic stress responses, including Dutch elm disease (DED). This wilt disease strongly affects Ulmus species causing the death of numerous adult trees, which could cause genetic impoverishment of elm populations
Summary
Owing to their long life cycles, forest tree species need to develop evolutionary mechanisms and processes to cope with different abiotic and biotic stresses. The results will depend on the timing, nature, and severity of each stress. Current climate change is drastically affecting Mediterranean regions and promoting the occurrence of numerous situations of combined environmental stresses. Climate change models predict an increase in temperature, aridity and extreme events throughout its natural distribution, composed mainly by central and southern Europe. DED is a wilt disease caused by two fungi, Ophiostoma ulmi (Buisman) Nannf. Two successive pandemics of DED that occurred during the twentieth century caused the death of most adult trees in many locations of Europe and North America, including those used as ornamental trees in urban areas (Brasier, 2000). The combined effects of climate change and DED, which is really difficult to control due to its high impact and fast expansion, will jeopardize the survival of the remaining elm forests during the decades
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