In their natural habitat, bacteria are consumed by bacterivorous nematodes; however, they are not simply passive preys. Here we report a defensive mechanism used by certain bacteria to mobilize nematode-trapping fungi to kill nematodes. These bacteria release urea, which triggers a lifestyle switch in the fungus Arthrobotrys oligospora from saprophytic to nematode–predatory form; this predacious form is characterized by formation of specialized cellular structures or ‘traps’. The bacteria significantly promote the elimination of nematodes by A. oligospora. Disruption of genes involved in urea transport and metabolism in A. oligospora abolishes the urea-induced trap formation. Furthermore, the urea metabolite ammonia functions as a signal molecule in the fungus to initiate the lifestyle switch to form trap structures. Our findings highlight the importance of multiple predator–prey interactions in prey defense mechanisms.
Background
Reaumuria soongorica is an extreme xerophyte shrub widely distributed in the desert regions including sand dune, Gobi and marginal loess of central Asia which plays a crucial role to sustain and restore fragile desert ecosystems. However, due to the lacking of the genomic sequences, studies on R. soongorica had mainly limited in physiological responses to drought stress. Here, a deep transcriptomic sequencing of R. soongorica will facilitate molecular functional studies and pave the path to understand drought adaptation for a desert plant.Methodology/Principal FindingsA total of 53,193,660 clean paired-end reads was generated from the Illumina HiSeq™ 2000 platform. By assembly with Trinity, we got 173,700 contigs and 77,647 unigenes with mean length of 677 bp and N50 of 1109 bp. Over 55% (43,054) unigenes were successfully annotated based on sequence similarity against public databases as well as Rfam and Pfam database. Local BLAST and Kyoto Encyclopedia of Genes and Genomes (KEGG) maps were used to further exhausting seek for candidate genes related to drought adaptation and a set of 123 putative candidate genes were identified. Moreover, all the C4 photosynthesis genes existed and were active in R. soongorica, which has been regarded as a typical C3 plant.Conclusion/SignificanceThe assembled unigenes in present work provide abundant genomic information for the functional assignments in an extreme xerophyte R. soongorica, and will help us exploit the genetic basis of how desert plants adapt to drought environment in the near future.
BackgroundSand rice (Agriophyllum squarrosum) is an annual desert plant adapted to
mobile sand dunes in arid and semi-arid regions of Central Asia. The sand rice
seeds have excellent nutrition value and have been historically consumed by local
populations in the desert regions of northwest China. Sand rice is a potential
food crop resilient to ongoing climate change; however, partly due to the scarcity
of genetic information, this species has undergone only little agronomic
modifications through classical breeding during recent years.ResultsWe generated a deep transcriptomic sequencing of sand rice, which uncovers 67,741
unigenes. Phylogenetic analysis based on 221 single-copy genes showed close
relationship between sand rice and the recently domesticated crop sugar beet.
Transcriptomic comparisons also showed a high level of global sequence
conservation between these two species. Conservation of sand rice and sugar beet
orthologs assigned to response to salt stress gene ontology term suggests that
sand rice is also a potential salt tolerant plant. Furthermore, sand rice is far
more tolerant to high temperature. A set of genes likely relevant for resistance
to heat stress, was functionally annotated according to expression levels,
sequence annotation, and comparisons corresponding transcriptome profiling results
in Arabidopsis.ConclusionsThe present work provides abundant genomic information for functional dissection
of the important traits in sand rice. Future screening the genetic variation among
different ecotypes and constructing a draft genome sequence will further
facilitate agronomic trait improvement and final domestication of sand rice.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-872) contains supplementary material, which is available to authorized users.
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