Extraordinary preservation in amber of the Miocene termite Mastotermes electrodominicus has led to the discovery of fossil symbiotic microbes. Spirochete bacteria and wood-digesting protists were identified in the intestinal tissue of the insect. Fossil wood (xylem: developing vessel-element cells, fibers, pit connections), protists (most likely xylophagic amitochondriates), an endospore (probably of the filamentous intestinal bacterium Arthromitus ؍ Bacillus), and large spirochetes were seen in thin section by light and transmission electron microscopy. The intestinal microbiota of the living termite Mastotermes darwiniensis, a genus now restricted to northern Australia, markedly resembles that preserved in amber. This is a direct observation of a 20-million-year-old xylophagus termite fossil microbial community.
Mastotermes, a genus of large tropical wood-ingesting termites, is of evolutionary importance for two reasons: (i) they harbor Mixotricha paradoxa and other amitochondriate many-genomed protists considered key to the early history of nucleated cells, and (ii) they are phylogenetically proximal to cockroaches (1). Both morphological and molecular features consistently place the single extant species (Mastotermes darwiniensis, family Mastotermitidae) as an early taxon ancestral to other termites. For example, Mastotermes is the only termite that, like cockroaches, oviposits an ootheca (egg case), although it is rudimentary (2). Numerous mastotermitid fossil specimens, corresponding to four extinct genera and about 20 species, occur from the Eocene [40 million years ago (mya)] to the Miocene (20-5 mya) of Australia, Brazil, the Caribbean, Central America, and especially Europe (3, 4). The two finest preserved fossil species, extremely similar to M. darwiniensis, occur in Oligocene and Miocene amber from southern Mexico (Mastotermes electromexicus) (5) and the Dominican Republic (Mastotermes electrodominicus) (6). The notoriously polyphagous ''living fossil'' M. darwiniensis is limited to northern Australia.Termites exhibit a complex and unique symbiosis with prokaryotic (eubacterial and archaebacterial) and eukaryotic microorganisms that live in their hindgut. The symbiotic microbiota digest cellulose to sugars and acetate and produce hydrogen, methane, and carbon dioxide (7). In addition to Mixotricha paradoxa, a giant trichomonad motile by means of a unique set of attached surface spirochetes (8, 9), M. darwiniensis harbors other Archaeprotista (class Parabasalia, those with distinctive parabasal bodies, a type of Golgi apparatus), including the two hypermastigote genera (Koruga and Deltotrichonympha), a devescovinid (Metadevescovina extranea), and a trichomonad (Pentatrichomonoides scroa) that harbors endosymbiotic methanogenic bacteria (10).Where and when did this symbiosis evolve? Here we use the remarkable preservative properties of termites in amber to seek direct paleontological evidence for the evolution of termite intestinal symbionts. Cellular and subcellular structures of amber-preserved tis...
