Phylogenetic and physiological traits of oomycetes originally identified as Lagenidium giganteum from fly and mosquito larvae.

We studied phylogenetic and taxonomic features of isolates identified as Lagenidium giganteum recovered from six different species of mosquito larvae. The isolates grew vigorously at 25 C, moderately at 30 C, and not at all at 37 C and developed submerged, white colonies with few short, hyaline, aerial hyphae. Cultures displayed phenotypic plasticity, with broad, hyaline hyphae strongly constricted at septa that developed oval, spherical, or amorphous segments. These developed into sporangia producing one or two exit tubes, from which evanescent gelatinous vesicles containing zoospores developed. Three isolates developed oogonia consistent with features previously described for L. giganteum. Phylogenetic analysis of nuc rDNA internal transcribed spacer (ITS1-5.8S-ITS = ITS) and cytochrome c oxidase subunit II (COXII) sequences of L. giganteum consistently grouped into eight clusters. Four of the investigated isolates grouped with sequences of an unnamed Lagenidium species infecting nematodes. Based on phenotypic and phylogenetic data, we describe the latter isolates as L. juracyae, sp. nov. In addition, we also investigated a species of Paralagenidium from a dog with lagenidiosis and describe it as new, Paralagenidium ajellopsis, sp. nov.

Oomycetes: Lagenidium giganteum.

Lagenidium giganteum is a facultative parasite of mosquito larvae that initiates infection by production of biflagellate zoospores that selectively recognize and attach to larval cuticle. Following penetration of the cuticle, the parasite proliferates within the host, killing it within 24-60 h. Under optimum conditions the mycelia differentiate to produce asexual and/or sexual reproductive structures that produce zoospores within hours (asexual stage) to amplify the initial infection, or remain dormant for days, months or years (sexual stage), until conditions are conducive to mosquito breeding and spore germination. Recycling following a single application has been documented for up to 8-10 years. Environmental conditions that reduce or eliminate zoospore production, including temperature extremes (less than 16 degrees C or greater than 32 degrees C) and moderate levels of salinity and organic load, preclude use of the parasite for operational mosquito control. Three formulations of L. giganteum have been registered with the USEPA. Widespread use of the parasite will be possible when yields of the sexual stage in liquid culture are increased by a factor of ca. 10(2).

Evaluation of various control agents against mosquito larvae in rice paddies in Taiwan.

A field test was conducted in rice paddies adjacent to Wufeng, Taichung County in Central Taiwan to evaluate the efficacy of control agents against mosquito larvae. The agents included Bacillus thuringienesis israelensis (Bti), two Lagenidium giganteum products (Lg product A and T), and temephos. The major mosquito species found in the rice paddies were Culex tritaeniorhynchus/vishnui and Anopheles sinensis. Compared to controls, a 7-day treatment with Bti or Lg products A and T caused overall reductions in the number of immatures (larvae and pupae) of Cx. tritaeniorhynchus/vishnui of 77.5%, 49.7%, and 21.9%, respectively, whereas temephos caused an increase of 66.9%. The overall reductions in An. sinensis were 85.4%, 8.6%, 44.6%, and 92.1%, respectively. There was no significant reduction in the number of mosquito larvae following 42 days of treatment with these agents. In summary, 1-week treatments with both biological control agents produced moderate overall reductions in mosquito larvae in rice paddies. The insecticide temephos, on the other hand, was very effective at suppressing the larvae of An. sinensis but significantly increased the number of Cx. tritaeniorhynchus/vishnui larvae in temephos-treated plots.