A major ongoing research effort seeks to understand the behavior, ecology and control of the spotted lanternfly (SLF) (Lycorma delicatula), a highly invasive pest in the U.S. and South Korea. These insects undergo four nymphal stages (instars) before reaching adulthood, and appear to shift host plant preferences, feeding, dispersal and survival patterns, anti-predator behaviors, and response to traps and chemical controls with each stage. However, categorizing SLF life stage is challenging for the first three instars, which have the same coloration and shape. Here we present a dataset of body mass and length for SLF nymphs throughout two growing seasons and compare our results with previously-published ranges of instar body lengths. An analysis using two clustering methods revealed that 1st-3rd instar body mass and length fell into distinct clusters consistently between years, supporting using these metrics to stage nymphs during a single growing season. The length ranges for 2nd-4th instars agreed between years in our study, but differed from those reported by earlier studies for diverse locations, indicating that it is important to obtain these metrics relevant to a study’s region for most accurate staging. We also used these data to explore the scaling of SLF instar bodies during growth. SLF nymph body mass scaled with body length varied between isometry (constant shape) and growing somewhat faster than predicted by isometry in the two years studied. Using previously published data, we also found that SLF nymph adhesive footpad area varies in direct proportion to weight, suggesting that footpad adhesion is independent of nymphal stage, while their tarsal claws display positive allometry and hence disproportionately increasing grasp (mechanical adhesion). By contrast, mouthpart dimensions are weakly correlated with body length, consistent with predictions that these features should reflect preferred host plant characteristics rather than body size. We recommend future studies use the body mass vs length growth curve as a fitness benchmark to study how SLF instar development depends on factors such as hatch date, host plant, temperature, and geographic location, to further understanding of life history patterns that help prevent further spread of this invasive insect.
A major ongoing research effort seeks to understand the behavior, ecology and control of the spotted lanternfly (SLF) (Lycorma delicatula), a highly-invasive pest in the U.S. and South Korea. These insects undergo four nymphal stages (instars) before reaching adulthood, and appear to shift host plant preferences, feeding, dispersal and survival patterns, anti-predator behaviors, and response to traps and chemical controls, with each stage. However, categorizing SLF lifestage is challenging for the first three instars, which have the same coloration and shape, because no comprehensive allometric datasets exist. We present a dataset of body mass and length for SLF nymphs throughout a growing season and compare our results with published ranges of instar body lengths based on small samples. An ontogenetic allometric analysis found that SLF nymph body mass scales isometrically with body length (exponent c = 3.05 [2.95,3.15]). An analysis using two clustering methods also revealed that first through third instar body mass and length fell into distinct clusters (Dyar’s rule), supporting using these two metrics to stage nymphs during a single growing season. The ranges for 2nd and 3rd instars were not consistent between our results and those from earlier studies for diverse locations. Using previously-published data, we also found that tarsal claw and arolia (adhesive footpad) dimensions scale in proportion to body length and mass, respectively, indicating that adhesive ability does not decrease with age, as posited in some previous studies. Conversely, mouthpart dimensions do not correlate with body length, consistent with predictions that these features should reflect preferred host plant characteristics rather than body size. We suggest extending these methods to study how SLF instar development depends on factors such as hatch date, host plant, temperature, and geographic location, using citizen scientist networks to collect morphometric data for a wide range of locations and environmental conditions.
The ability to upright quickly and efficiently when overturned on the ground (terrestrial self-righting) is crucial for living organisms and robots. The emerging field of terradynamics seeks to understand how and why different animals use diverse self-righting strategies. We studied this behavior using high speed multiangle video in nymphs of the invasive spotted lanternfly (SLF, Lycorma delicatula), an insect that must frequently recover from falling in its native habitat. While most insect species previously studied can use wing opening to facilitate overturning, nymphs, like most robots, are wingless. SLFs were highly successful at self-righting (>92% of trials) with no significant difference in the time or number of attempts required for three substrates with varying friction and roughness. These nymphs seldom overturned using the pitching and rolling strategies observed for other insect species, instead primarily flipping upright by rotating around a diagonal body axis. To understand these motions, we used video, photogrammetry and Blender rendering software to create novel, highly realistic 3D models of SLF body poses during each strategy. These models were analyzed using the energy landscape theory of self-righting, which posits that animals use methods that minimize energy barriers to overturning, and inertial morphing, which proposes the animal adjusts its body pose to minimize the rotational inertia during overturning, a theory which has not been applied to self-righting. A combination of both theories was found to explain the observed preferred strategies of this species, indicating the value of using 3D renderings with mechanical modeling for terradynamics and biomimetic applications.
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