Abstract
The relationship between xylophagous termites and the protists resident in their hindguts is a textbook example of symbiosis. The essential steps of lignocellulose degradation handled by these protists allow the host termites to thrive on a wood diet. There has never been a comprehensive analysis of lignocellulose degradation by protists, however, as it has proven difficult to establish these symbionts in pure culture. The trends in lignocellulose degradation during the evolution of the host lineage are also largely unknown. To clarify these points without any cultivation technique, we performed meta-expressed sequence tag (EST) analysis of cDNA libraries originating from symbiotic protistan communities in four termite species and a wood-feeding cockroach. Our results reveal the establishment of a degradation system with multiple enzymes at the ancestral stage of termite-protistan symbiosis, especially GHF5 and 7. According to our phylogenetic analyses, the enzymes comprising the protistan lignocellulose degradation system are coded not only by genes innate to the protists, but also genes acquired by the protists via lateral transfer from bacteria. This gives us a fresh perspective from which to understand the evolutionary dynamics of symbiosis.
Highlights
Cellulosic biomass is regarded as a very exciting candidate source for bio-fuel
We investigated the trends in lignocellulose degradation during the evolution of the host lineage using four representative termite species from four families of wood-feeding termites (Reticulitermes speratus (Rhinotermitidae), Hodotermopsis sjostedti (Termopsidae), Neotermes koshunensis (Kalotermitidae), and Mastotermes darwiniensis (Mastotermitidae)) and Cryptocercus punctulatus, a wood-feeding cockroach that is a member of a genus thought to be in a sister clade to the termite lineage [17]
We obtained 910 clones (R. speratus), 920 clones (H. sjostedti), 1056 clones (N. koshunensis), 1021 clones (M. darwiniensis), and 868 clones (C. punctulatus) as expressed sequence tag (EST) from the cDNA libraries constructed from the symbiotic protistan communities of the host insects
Summary
Cellulosic biomass is regarded as a very exciting candidate source for bio-fuel. Currently, the use of ethanol as fuel incurs a cost to the food supply, as ethanol production requires both starch and sucrose. If we can comprehensively obtain the cellulase genes from a whole symbiotic protistan community in the termite gut and reconstruct the evolutional trail of the cellulolytic system along the termite lineage, we may be able to identify the actual core components of termite systems for the efficient degradation of cellulose.
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