Symbionts provide pesticide detoxification.

S ymbiosis is the intimate “living together” of different organisms (1), and symbiotic relationships range from mutually beneficial to neutral or parasitic. Indeed, many microbial–host symbioses can vary between these states, depending upon circumstances. Recent years have seen an explosion of discoveries revealing novel microbial–host relationships and interactions. In addition to “classic” nutritional symbioses (in which the microbe provides a limiting nutrient not normally available in the host’s diet), studies have shown that microbes can alter the reproductive mode of their hosts (e.g., induce development of unfertilized eggs, change sex, or cause sperm–egg incompatibilities), affect mate choice, and provide protection from natural enemies, including viruses, protozoa, and parasitic insects (2–4). Kikuchi et al. (5) report an extension of this repertoire of effects— bacteria in the genus Burkholderia impart protection against organophosphorous pesticides in stinkbugs. Burkholderia is a genus of biologically diverse bacteria commonly found in soil and associated with plants (6). Although originally isolated as plant pathogens on onion, many Burkholderia are now known to provide benefits to plants, from involvement in nitrogen fixation to suppression of plant disease. Strains of Burkholderia cepacia can also cause chronic lung infections in cystic fibrosis patients. Stinkbug-associated Burkholderia are from a different group within the genus, and related strains are found both in soil and in the guts of stinkbugs (5). Organophosphorus (OP) compounds are extensively used in agriculture, accounting for ∼38% of total pesticide use (7). These compounds inhibit the activity of acetylcholine esterase, resulting in neurotoxic effects in both insects and mammals. Hence, OPs are common causes of poisoning in people and livestock. Because of their heavy use, OP compounds are also significant contaminants in terrestrial and aquatic ecosystems. Kikuchi et al. (5) bring together the findings of two different disciplines. For several decades researchers have been investigating how pesticides are degraded in the environment, discovering a major role of soil microorganisms, including bacteria in the genus Burkholderia (7, 8). Soil bacteria can metabolize OPs and use them as sources of carbon, phosphorus, or nitrogen, facilitating degradation of these compounds in the environment. Components of the genetic machinery for OP degradation have also been exchanged among diverse soil bacteria by lateral gene transfers. Motivation for the research includes possible use of soil microbes for environmental remediation of pesticides and application of the biochemical mechanisms to medical treatment of pesticide poisoning. A separate research community has been busy exploring the microbial symbioses of insects. The resurgence of symbiosis research from its original heyday in the early to mid-20th century (9) has been spurred by the advent of molecular tools for characterizing previously intractable bacteria, as well as the discoveries of amazing and diverse phenotypic effects of symbionts on their hosts (2–4). In previous work, Kikuchi et al. (10) found that Burkholderia are common gut bacteria in a wide range of stinkbugs and relatives, encompassing a significant fraction of the insect order Heteroptera, or “true bugs.” Many are major pests in agriculture; for example, the bean bug Riptortus pedestris described in the present study. Burkholderia normally impart a growth advantage to the bugs, although the precise benefit provided is not yet known. Careful study also revealed that the bugs acquire Burkholderia from the environment each generation as nymphs (11), rather than from the mother (e.g., either within or on the eggs) or infectiously from other stinkbugs (Fig. 1). The bacteria colonize specialized structures in the posterior midgut referred to as “crypts” and can achieve upward of 10 cells per adult. Consistent with environmental acquisition, their phylogeny based on 16S ribosomal sequence indicate no separation of soilvs. stinkbugassociated bacteria. Environmental acquisition of symbionts each generation has not been widely described in insects, although it occurs in some other systems, such as the squid–Vibrio (light organ), coral–algal (nutritional), and legume–rhizobium (nitrogen fixation) symbioses (12–14). In the present study, Kikuchi et al. (5) bring together their own observations on Burkholderia in stink bugs with the observations of Burkholderia involvement in pesticide degradation (7, 8) to develop the hypothesis that OP-degrading bacteria could impart pesticide resistance to the insects. Fenitrothion (FEN) is a commonly used OP pesticide, and FEN-degrading Burkholderia strains are found in soils where these pesticides are applied. Inoculating with FEN-degrading vs. nondegrading strains revealed that pesticidedegrading symbionts impart significant protection against the pesticide applied under laboratory conditions. Although FEN-degrading Burkholderia were uncommon in local bean fields, treatment of field soil brought to the laboratory with FEN greatly enhanced frequency of FENdegrading Burkholderia, and the stinkbugs reared on soybeans from these soils showed elevated levels of FEN-degrading activity. Finally, much higher levels of Fig. 1. Burkholderia bacteria are found in the soil, where some genotypes are capable of detoxifying OP pesticides. Stinkbugs acquire bacteria from the environment, and Burkholderia preferentially colonize specialized structures (crypts) in the insect midgut. When stinkbugs are experimentally infected with pesticide-degrading bacteria, they have significantly increased resistance to pesticide treatment. It is unclear whether any Burkholderia genotypes have established a routine transmission cycle between bean bugs and the environment, which would enhance coadaptation of pesticide resistance in microbes and host.