Early attempts to apply the SIT on the olive fly, Bactrocera oleae, were unsuccessful, mainly due to the low competitiveness of the sterile mass‐reared males compared with the wild ones. Recently, new efforts are underway in Israel to develop a vigorous and efficient mass‐reared olive fly laboratory strain. To understand the genetics of the adaptation process and possibly link the corresponding loss of competitiveness to genetic markers, we followed the fluctuation of genotypic frequencies of ten microsatellite markers during the course of 22 generations of the colonization of a wild Israeli population in laboratory conditions. Effective and observed allele number is halved after 11 generations, so is mean heterozygosity. Practically, there is very little change between F0 and F1, there are substantial changes between F1 and F2–F5, and there is a virtual complete adaptation to the new laboratory environment by F11, because no more changes are observed between F11 and F22. If we assume that the loss of allele number and heterozygosity also reflects the loss of the ‘wild’ character of the colonized strain and, possibly, the loss of a substantial part of its natural vigour, our results indicate that there is an apparent need to refresh a mass‐reared colony with wild material at about every five to eight generations. Furthermore, simulation models indicated that while most of the observed allele frequency fluctuations were due to random drift, some alleles were probably under selection.
The citrus rust mite (CRM), Phyllocoptruta oleivora (Acari: Eriophyidae) is a cosmopolitan key pest of citrus, inflicting severe economic damage if not controlled. In Israel, CRM damages all citrus cultivars. International regulation and increasing control failures of CRM led growers to seek sustainable biological control solutions such as acarine biological control agents. Laboratory studies conducted in Israel have indicated that the indigenous predator species Amblyseius swirskii, Iphiseius degenerans, Typhlodromus athiasae and Euseius scutalis (all Acari: Phytoseiidae) can potentially control CRM. Our general objective in the present study was to bridge the gap of knowledge between laboratory studies and the lack of control efficacy of these species in commercial orchards. Predator augmentation in the field showed that although predator populations increased immediately following releases they later decreased and did not affect CRM populations. When A. swirskii augmentation was combined with a series of maize pollen applications, A. swirskii populations were enhanced substantially and continuously but again CRM populations were not affected. Growth chamber studies with CRM-infested seedlings, with or without a maize pollen supplement, indicated that pollen provisioning led to population increase of E. scutalis and A. swirskii but only E. scutalis significantly lowered CRM populations. Control with E. scutalis was confirmed in the field on CRM infested seedlings with pollen provisioned by adjacent flowering Rhodes grass. While experiments in mature citrus orchard showed that pollen supplement usually increased predator populations they also indicated that other factors such as intraguild interactions and pesticide treatments should be taken into account when devising CRM biological control programs.
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