Properties of BsMany mosquitocidal

Properties of Bs
Many mosquitocidal strains of B. sphaericus have been isolated over the past 30•years, and the most toxic of these, including strains 1593 and especially 2362, belong to flagellar serotype 5a5b (Charles et al., 1996; Delécluse et al., 2000). The principal toxin in these strains is the Bin toxin, which is
composed of two proteins, a 51.4-kDa binding domain and a 41.9-kDa toxin domain, that co-crystallize into a single small parasporal body. Strain 2362 has an LC50 of 18•ng•ml–1 against the fourth instar of Culex mosquitoes (Baumann et al., 1991). After ingestion by a mosquito larva, the 51.4-kDa and 41.9-
kDa proteins are cleaved by proteases, yielding peptides of 43•kDa and 39•kDa, respectively, that form the active toxin (Baumann et al., 1991; Charles et al., 1996). These associate, bind to the receptor, an a-glucosidase on the midgut microvilli (Darboux et al., 2001), and cause lysis of midgut cells after
internalization (Davidson, 1988).
Fig.•3. Binding of Bin and Cyt1A to midgut epithelial cells of Binresistant fourth instars of Culex quinquefasciatus five hours after treatment. (A) Phase-contrast micrograph of a posterior midgut
epithelial cell of a Bin-resistant larva fed only Bin labeled with Oregon Green. (B) The same cell as in A viewed with an Oregon Green filter, showing that little or no Bin bound to the microvilli or
entered the cell. (C–F) Micrographs of a single posterior midgut epithelial cell from a Bin-resistant larva fed a 1:1 mixture of Bin and Cyt1A. Bin was labeled with Oregon Green, and Cyt1A with Rhodamine Red-X. (C) Phase contrast without filter; (D) superimposed micrographs taken with Oregon Green and Rhodamine Red-X filters; (E) micrograph of the cell using Oregon Green filter showing Bin throughout the cytoplasm, with no Bin detectable bound to the microvilli. (F) Micrograph of the cell taken using
Rhodamine Red-X filter showing Bin bound primarily to the microvilli. N, nucleus; bb, microvilli of the brush border. In addition to the binary toxin, many strains of Bs produce other mosquitocidal toxins during vegetative growth that are referred to as Mtx toxins. Two of these have been well studied
– Mtx (100•kDa) and Mtx2 (30.8•kDa) – but are not as toxic as the Bin toxin (Delécluse et al., 2000).
The target spectrum of Bs is more limited than that of Bti, being restricted to mosquitoes, and its highest activity is against Culex and certain Anopheles species (Delécluse et al., 2000). Some important species of Aedes, such as A. aegypti, are not very sensitive to Bs, whereas others, for example, Aedes atropalpus and Aedes nigromaculis, appear to be quite sensitive (Delécluse et al., 2000). Moreover, although strain
2362 was isolated from a blackfly (Simulium damnosum) adult, Bs strains have little or no activity against nematoceran flies other than mosquitoes. Nevertheless, Bs does appear to have better initial and residual activity than Bti against mosquitoes in polluted waters. As a result, a commercial formulation, VectoLex® (Abbott Laboratories), based on strain 2362 is marketed in many countries, especially to control Culex larvae in polluted waters. A disadvantage of Bs strains is that the Bin toxin is, in essence, a single toxin. Laboratory studies have shown that it is much more likely to result in resistance than Bti. In fact, resistance to Bs has already been reported in field populations of Culex mosquitoes in Brazil, China, France and India (Sinègre et al., 1994; Rao et al., 1995; Silva-Filha et al., 1995; Yuan et al., 2000), with resistance levels in some areas of China reported as >20•000-fold.