BIOLOGY AND CONTROL OF THE APPLE MEALYBUG PHENACOCCUS ACERIS (SIGNORET) IN BELGIUM.

Although in general very rare, some outbreaks of the apple mealybug Phenococcus aceris (Signoret) (Hemiptera: Pseudococcidae) were reported in the Belgian fruit growing area recently. This insect is known to be geographically widespread, to have a broad host range and to infest apple trees. Damage at harvest is considerable when sooty molds, a consequence of the pest's honeydew production, cover the fruits. Indirect damage of an infection is caused in cherry cultivation through transmission of the Little cherry virus (LChV2). Efficacy trials were executed in infested apple orchards in the Belgian fruit growing area and the life cycle of the pest on apple was studied more into detail. Apple mealybugs are univoltine, overwinter as 2nd instar nymphs inside a white cocoon on the tree (under the bark, in crevices) and leave their overwintering site in early spring (mid March). On sunny days the nymphs become active, move around and attach to start feeding (mid April). After a final moult into the adult form, females lay eggs in a cocoon-like white structure (from flowering on). Following hatching (end May), massive numbers of young nymphs spread out on the underside of the leaves (mid June) where they feed through suction. In order to manage this pest the efficacy of several plant protection products was tested in two infested apple orchards. Results indicated that mortality was high after an application of compounds belonging to the neonicotinoid insecticides. Different application timings and control strategies are possible, with active nymphs being the most vulnerable life stage. The observed degree of parasitation in our trial orchards also indicates a biological control contribution of parasitic wasps that should be taken into account. A decent IPM-strategy based on our results solved the problem in both apple orchards.

Control of sawflies in apple and pear in Belgium.

In the Belgian fruit growing area, sawflies are generally common but minor pests in pome fruit. Though, intensity and frequency of sawfly damage in apple and pear is increasing the last years in IPM and especially in organic orchards. The main species are apple sawfly (Hoplocampa testudinea Klug) and pear sawfly (Hoplocaompa brevis Klug) and recently also pear shoot sawfly (Janus compressus Fabricius). Here we report efficacy results on all three sawfly species fromtrial of three consecutive years (2011, 2012, and 2013). Flights and embryonic development were monitored and small plot efficacy trials were executed. Control of apple sawfly was complete (97.6% Abbott -trial 2011) when thiacloprid at 120 g/ha LWA was applied at the moment embryos are visible in the sawfly eggs. In 2012, a trial was executed on pear sawfly. Applications with thiacloprid were executed when the embryo was visible in the pear sawfly eggs and earlier at the start of egg laying. At both application timings, 100% Abbott efficacy was reached. A number of other active ingredients were tested at the moment embryos are visible in the sawfly eggs and very interesting efficacy results were reached for thiofanate-methyl, indoxacarb, spinosad, pyrethrins + piperonyl butoxide (PBO) and acetamiprid. In 2013, a preflowering application with pyrethrins + PBO reached the highest control against this pest. The most effective active ingredients of the pear sawfly trial were applied also in a trial on pear shoot sawfly. Efficacies were low or lacking, except for thiacloprid. Thiacloprid is in pear growing in Belgium only registered before flowering and after harvest. Therefore further research is needed to test the effect of earlier applications against this pest. This is a valuable efficacy study on occasionally occurring pests that are able to cause considerable economic losses.

Biological efficacy evaluation of mating disruption against the grape berry moth, Lobesia botrana, in grape in glasshouses.

The grape berry moth, Lobesia botrana, is an important pest of grapes. In Belgium, severe losses of production appeared due to the presence of L. botrona in grapes commercially grown in glasshouses. In 2010 mating disruption became a key pest management tactic in Flemish pip fruit orchards after being tested for several years. In other (European) countries, mating disruption is already applied in grapes but there is no registration in Belgium for use in grapes. Searching for an interesting residue free technique for application in small glasshouses, we evaluated the effect of mating disruption for control of L. botrana under protected conditions (glasshouse trials) during three consecutive years (2010-2012). A prerequisite for successful mating disruption is the treatment of large contiguous areas, as the pheromone product will not remain in sufficient quantities on narrow sites and, moreover, a larger portion of the crop remains at risk from migrating mated females. The glasshouses are rather small, however, we hypothesized that these so called border effects are not present due to the secluded spaces of the glasshouses. Pheromone dispensers were deployed and flights of L botrano moths were monitored (pheromone traps/UV-traps) during the whole time period of the trials. In the mating disrupted glasshouses hardly any moth was caught anymore in pheromone traps, in contrast to UV-traps or catches by pheromone traps in comparable non-mating disrupted glasshouse compartments. This indicates the incapability of the males to localize sex pheromone sources, and hence, the inability of finding females for mating. In line with these flight monitoring data, the nearly absence or strongly decreased L. botrana caused damage symptoms in the mating disrupted glasshouses demonstrates the benefits of the mating disruption technique under protected conditions of grape growing in glasshouses.

Consistent codling moth population decline by two years of mating disruption in apple: a Flemish case study.

Codling moth (Cydia pomonella) is one of the most important pests in apple and pear. In 2010 mating disruption became a key pest management tactic in Flemish pip fruit orchards, largely due to a government subsidy and demonstrating projects aiming to widen the area treated by pheromones as large as possible. As a consequence, the mating disruption strategy was applied at approximately 7.500 ha, or half of the pip fruit area, in 2010 and 2011. The sudden large-scale implementation of this technique changed the codling moth management landscape. Here we present a case study of a commercially managed orchard that suffered from high codling moth pressures for many years, as did the surrounding area. The RAK3 mating disruption system was introduced at this location in 2010, and was continued in 2011. Systematic detailed codling moth flight data for this location are available for many years. In addition, comprehensive data on damage levels of chemically untreated windows spread all over the test orchard in a randomized block design were obtained in successive years, enabling us to thoroughly evaluate the effect of the changed codling moth management strategy. Data from 2011 included damage levels in chemically treated windows when the entire orchard was applied once at the flight peak of Cydia pomonella. In 2009, before introduction of mating disruption, a mean of 8.25 +/- 5.54% of the fruits were infested at harvest when assessed in completely untreated windows. After two years of mating disruption, supported with a full chemical support in 2010, except for the untreated assessment windows, and only one application on the flight peak of 2011, damage was reduced to less than 0.03% at harvest. This is a valuable case study to demonstrate the benefits of the mating disruption approach.

Optimal profit of the parasitation by Aphelinus mali in an IPM complementary strategy for the control of Eriosoma lanigerum.

During summer the parasitoid Aphelinus mali may certainly reduce the infestation of woolly apple aphid (Eriosoma lanigerum), but studies on the single interaction rarely indicate sufficient biological control in the period May-June. In this period chemical control by spirotetramat or pirimicarb remains indispensable in order to anticipate on dense migration waves and subsequent colonization of extension shoots by E. lanigerum. The limited parasitation by A. mali around flowering is linked with a delayed emergence from diapause and with a slower reproduction rate than its host. In 2010 and 2011 the first adult flights monitored on yellow sticky traps corresponded perfectly with the currently used prediction models for A. mali. Further accurate monitoring all along the season enabled also to determine a well defined endo-parasitic phase of A. mali occurring after the small peak observed around flowering. During this endo-parasitic phase A. mali larvae reside inside their mummified host. Compounds with higher acute toxicity on A. mali adults, like chloronicotinyl insecticides (CNI's), are preferably positioned here. Selectivity in the time can then be claimed. Respecting this principle, the further parasitation potential of A. mali in summer is not hampered. Preservation of the first peak of flights of A. mali in the pre-flowering period is essential for an exponential flight increase. This is essential for the parasitation of E. lanigerum in summer, which constitutes a valuable complement in the integrated control strategy.

Integrated management of phytoplasma diseases in pome fruit: an overview of efficacy results of IPM insecticides against pear Psylla (Cacopsylla pyri).

Phytoplasmas are plant pathogenic mollicutes that cause devastating diseases in various crops worldwide. The closely related pome fruit tree phytoplasmas Candidatus Phytoplasma mali and Candidatus Phytoplasma pyri are the causal agents of apple proliferation and pear decline, respectively. They can be transmitted from tree to tree by Psyllidae. As pear suckers (Cacopsylla pyri) are widely considered to be the most important pest in pear orchards, a good control of this insect vector is a key element for limiting the natural spread of pear decline. Efficient control relies on a perfect tuning of treatment schedules, taking into account efficacies of (at preferably) low-impact insecticides and side-(repellent)-effects of alternative products (e.g. kaolin, mineral oils and fungicides), the optimal positioning of these crop protection agents, and the best possible presence of beneficial predators. The department of Zoology of the pcfruit vzw research institute (Belgium) has a long tradition of executing insecticide field trials according to EPPO guidelines. Here, we present an overview of the results of a selection of IPM-compatible insecticides (abamectin, spirotetramat, thiacloprid, spinosad, spirodiclofen), tested in efficacy trials against pear Psylla on different life stages during the last decade. Based on these results and monitoring data of pest and beneficial biology, we additionally propose optimal pear Psylla control schedules which allow to reduce the number of (phytoplasma harbouring) psyllids in integrated systems to a minimum.

The selectivity in the time of thiacloprid (Calypso 480 SC) applied at preblossom on the further Anthocoris nemoralis population build up in pears.

Predatory bugs (Anthocoris sp.) are key predators of the pear sucker (Psyllo pyri) in pear orchards. In order to enhance biological control it is important to verify if crop protection products applied against Psylla pyri display potential short- or long-term detrimental effects on Anthocoris populations. This study focuses on the impact of thiacloprid (Calypso 480 SC), applied at preblossom for the control of the first generation pear sucker Psylla pyri, on subsequent population build up of Anthocoris nemoralis later in the season. Hereto, five large-scale trials on pear Conference were conducted. Two types of orchards were selected: the first type is surrounded by abundant vegetation from which Anthocorids easily can fly in when attracted by the presence of prey (Psylla pyri); the second type has no "reservoir" vegetation around the orchard and here it is considered that mostly the residential population of Anthocorids constitutes the predation. In all five trials positioning of thiacloprid preblossom did not prevent the normal population build up of the predatory Anthocoris sp. population later in the season. As both in orchards with surrounding vegetation and in orchards without adjacent vegetation a regular build up of the Anthocoris sp. population was observed, the outcomes of this study indicate that a preblossom application of Calypso 480 SC can be considered as "selective in time" for further Anthocoridae dynamics.