|Lacanobia subjuncta (Grote and Robinson)|
-- Mike Doerr and Jay F. Brunner
Lacanobia eggs (M. Doerr)
Lacanobia late instar larva in apple fruit (M. Doerr)
Larva:The larva is the most distinctive stage of L. subjuncta. Both its color and pattern change as it grows. Earlier instars resemble green fruitworms (green with a lateral stripe). The color of later instars ranges from bright green to tan to a light red or brick color. It is the mature larva that displays the characteristic herringbone pattern on its dorsal side. The last instar larva is large, nearly two inches in length.
Pupa: L. subjuncta pupates in the soil near the host plant. The pupa is dark brown and naked, that is, not found within a silken cocoon.
Adult: The L. subjuncta adult is about 1 inch (25 mm) long and 2 inches (50 mm) between the wing tips. L. subjuncta has a distinctive color pattern of scales on the wing that range from light brown to black. The reniform and orbicular spots are light brown with a black border. These spots can be easily seen and help to identify this species from other Noctuids
Lacanobia neonate on leaf (M. Doerr)
As larvae mature, the feeding is more typical of a fruitworm than a cutworm. The term "cutworm" refers to larvae that bite at the stems of plant tissue causing them to fall over. L. subjuncta larvae feed on leaf tissue first causing holes in the leaf interior then on the periphery and then eating the entire leaf. Fruit injury is incidental to foliage feeding but can be quite severe in orchards where the densities are high. More fruit damage can occur where clustered fruit is in close proximity to dense foliage or tall growing weeds, such as the lower center of apple trees. Larvae feed directly on fruit by excavating holes. These holes can be as large as a fingertip. As larvae grow they are very mobile within the canopy and feeding damage becomes evenly distributed.
Lacanobia feeding damage to leaves (M. Doerr)
The pheromone lure is very attractive and large numbers of moths may be captured in orchards containing few larvae. In order to limit the effect of outside populations biasing trap data, traps should be placed in the center of each orchard block of 10 acres or larger.
Bucket trap for Lacanobia fruitworm (M. Doerr)
Direct sampling of larvae using a limb tap/beating tray method requires a large number of samples to accurately measure populations. At least 25 beating tray samples spread throughout a large block is necessary to obtain an accurate measure of L. subjuncta density. Larvae are more likely to be dislodged where foliage is the densest; therefore, sampling should be concentrated in the lower interior of the trees. The beating tray sampling technique is biased towards younger larvae so this sample is most reliable when the majority of eggs have hatched and larvae are still in the early instars (see Degree-Day Model section below).
The most reliable measure of L. subjuncta density is a visual inspection of foliage feeding. In order to optimize pesticide programs, it is best to conduct this sample when egg hatch is nearly complete and before larvae become too large. Visual inspection also requires that a large number of trees be examined because larvae are not uniformly distributed throughout an orchard. Twenty shoots from 25 trees should be examined in a large block (10 to 20 acres) noting the percentage of shoots that show feeding damage.
Thresholds: There is not a good correlation between any measure of L. subjuncta density or foliage feeding activity and fruit injury. This is most likely because L. subjuncta only incidentally feed on fruit and horticulture factors like crop load, clustering of fruit, shoot growth, weed management and fruit maturity can all influence the amount of fruit damage that occurs.
Apple orchards can tolerate relatively high L. subjuncta densities before significant fruit injury occurs. Although the correlation between assessments of larval feeding activity and fruit injury are not strong, there are some general guidelines that can be followed. When 30-35% of shoots show feeding damage then about 1% fruit injury can be expected. This threshold is based on the amount of foliage feeding present at 100% egg hatch , a time that is a little too late for optimized insecticide applications that target young larvae. Therefore, treatment thresholds based on trap catch or beating trays are needed to predict either fruit injury or shoot infestations.
Peak trap catch provides an indicator of population level in an area and can serve as a presence/absence indicator. Typically, orchards with peak trap catch less than 150 moths/week did not have shoot injury that would exceed the 30-35% shoot feeding threshold. The main problem in using peak trap captures as a threshold is that some orchards will have very high peak trap catches but have low levels of foliage feeding. Therefore, a peak trap catch that exceeds 150/week should trigger a search for egg masses in late May-early June and/or use of beating tray samples and foliage inspection in mid-June to further assess L. subjuncta densities. If egg masses or larvae are not detected in-orchard then controls would not be required. A sample of neighboring blocks or areas containing weeds such as mallow, curly dock, dandelion, pigweed or lambs quarter may reveal the external source of moths. What constitutes a treatable population is one of the most important decisions for managing L. subjuncta. However, at this time there is no single density measure will provide an accurate and reliable prediction of the risk of fruit injury from this pest.
Degree-day Model: With little detailed information on a pest's phenology, sampling for larvae and timing insecticide applications is relegated to a a trial and error exercise. The result has often been an increase in rates and frequency of pesticide applications. This increases grower costs as well as the potential for negative impact on biological control activity in the system.
A degree-day model has been designed to identify important periods in L. subjuncta phenology through the growing season. The lower and upper thresholds for L. subjuncta are 44 and 90°F. A horizontal cutoff is used when calculating degree-days using maximum and minimum temperatures beginning March 1. A degree-day look-up table for L. subjuncta and a degree day development phenology table are available.
The detailed phenology descriptions presented here are expected to make the timing of insecticide applications more accurate and therefore more effective. For example, the ideal timing for the application of a "selective" pesticide with relatively short residual activity is when the majority of egg hatch is complete and most larvae are of a susceptible stage - third instar or earlier. First generation egg hatch is estimated to be 80% complete by approximately 1044 degree-days (see phenology table). During the interval of 1035-1170 degree-days, all larvae collected during model development were in the first through third instars. This time frame represents the best opportunity to control L. subjuncta with a single insecticide application. The 135 degree-day window equates to an average of 10 calendar days based on 30-year average temperatures in central Washington. This period provides sufficient time to apply an insecticide under acceptable climatic conditions. During the second generation, 80% egg hatch is estimated at 3042 degree-days. The best timing for an insecticide application against larvae of the second generation is between 2970-3105 degree-days. This represents a period of 7 calendar days based on 30-year average temperatures in central Washington.
Another use of the model is to provide growers and crop consultants with a tool to schedule a larval sampling activity just prior to the time for an optimum insecticide application. By sampling just prior to the windows discussed above an estimate of the number of larvae or percent shoot feeding can be made to ascertain the need to apply a control.