Vibration detection and discrimination in the masked birch caterpillar (Drepana arcuata)

Guedes, Raul Narciso C.; Matheson, S. M.; Frei, Britta; Smith, Myron L.; Yack, Jayne E.

doi:10.1007/s00359-012-0711-8

Cited by 34 publications

(46 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Such freezing is presumed to be advantageous for detecting vibrations as well as visual and olfactory information necessary for recognizing conspecifics or predators. The freeze response has also been demonstrated in a territorial leafdwelling caterpillar, D. arcuata (Yack et al, 2001;Guedes et al, 2012); the caterpillars stop feeding and constructing shelters (i.e., freeze) in response to vibrations from approaching intruders and begin signaling as intruders approach (Guedes et al, 2012). Similar to caterpillars, beetles can receive vibrational information from approaching con-or heterospecifics and determine the next behavioral step, such as walking or flight for escape, preceding freeze and/or startle responses.…”

Section: Discussionmentioning

confidence: 93%

“…An increasing number of studies have shown that arthropods inhabiting plants detect approaching predators, prey, or conspecifics through substrate-borne vibrations (Ota and Č okl, 1991;Bacher et al, 1997;Djemai et al, 2001;Yack et al, 2001;Djemai et al, 2004;Castellanos and Barbosa, 2006;McNett et al, 2010;Eriksson et al, 2011;Guedes et al, 2012). Michelsen et al (1982) noted that plant stems and leaves serve as channels for transmitting and receiving vibrational information.…”

Section: Introductionmentioning

confidence: 98%

“…Such discrimination can be achieved by detecting differences in vibrational characteristics including frequency, amplitude, and temporal patterns. For example, the ability of a caterpillar (Drepana arcuata) to discriminate among vibrations allows it to respond selectively to conspecifics and predators (Guedes et al, 2012). Because responding to approaching predators or conspecific intruders is often costly (Ruxton et al, 2004), it is advantageous for insects to avoid responding to abiotic stimulation.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Substrate-Borne Vibrations Induce Behavioral Responses in the Leaf-Dwelling Cerambycid, Paraglenea fortunei

et al. 2014

View full text Add to dashboard Cite

Many insects utilize substrate-borne vibrations as a source of information for recognizing mates or predators. Among various substrates, plant leaves are commonly used for transmitting and receiving vibrational information. However, little is known about the utilization of vibrations by leaf-dwelling insects, especially coleopteran beetles. We conducted two experiments to examine the response of the leaf-dwelling cerambycid beetle, Paraglenea fortunei, to substrate-borne vibrations. We recorded and analyzed vibrations of host plant leaves from four different sources: wind (0.5 m/s), a beetle during landing, a walking beetle, and a beetle walking in the wind (0.5 m/s). We then measured the behavioral thresholds, the lowest amplitudes that induce behavioral responses, from beetles walking and resting on horizontal and vertical substrates with pulsed vibrations ranging from 20 Hz to 1 kHz. The vibrational characteristics of biotic and abiotic stimuli clearly differed. Beetle-generated vibrations (landing, walking, and walking in the wind) were broadly high in the low-frequency components above ∼30 Hz, while wind-generated vibrations showed a dominant peak at ∼30 Hz and a steep decrease thereafter. Among four situations, beetles walking on horizontal substrates showed lowest thresholds to vibrations of 75-500 Hz, which are characteristic of beetle-generated vibrations. Given that P. fortunei beetles are found on horizontal leaf surfaces of the host plant, vibrations transmitted though horizontal substrates may induce a strong freeze response in walking beetles to detect conspecifics or heterospecifics. Our findings provide evidence that leaf-dwelling beetles can discriminate among biotic and abiotic factors via differences in vibrational characteristics.

show abstract

Section: Discussionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Substrate-Borne Vibrations Induce Behavioral Responses in the Leaf-Dwelling Cerambycid, Paraglenea fortunei

et al. 2014

View full text Add to dashboard Cite

show abstract

“…In crickets or tettigoniid, species-specific vibratory signals can facilitate orientation in a complex 3D habitat, like bushes, toward conspecifics (Latimer and Schatral 1983;Stiedl and Kalmring 1989;Weidemann and Keuper 1987). Holometabolous caterpillars can detect and discriminate vibratory signals occurring on leaves with so far unidentified sense organs (Guedes et al 2012).These exemplary observations show the ability of various species to locate vibrational stimuli.…”

Section: Neural Network and Neuroethologymentioning

confidence: 95%

Functional Morphology and Evolutionary Diversity of Vibration Receptors in Insects

Lakes‐Harlan

Strauß

2014

Animal Signals and Communication

View full text Add to dashboard Cite

Vibratory signals of biotic and abiotic origin occur commonly in the environment of all living organisms. Many species deliberately produce such signals for communication purposes. Thus, it is not only useful but also advantageous and/or necessary to be able to detect and process vibratory signals with appropriate receptor organs. Mechanoreception is suggested to be evolutionarily ancient among animals (Kung 2005;Thurm 2001). Given the long evolutionary history, such receptors have very different anatomical structures and corresponding physiological properties. Responding to mechanical stress is a basic property of cells, even outside the nervous system. In the nervous system, specialized sensory cells and organs register mechanosensory signals and impart the information to higher centers. Structural and molecular adaptations in various mechanoreceptors can push these systems to a sensitivity at or near to the physical limits, e.g., with respect to the noise-stimuli relation. Here, we will deal with the vibratory receptor systems of insects, with a focus on the specialized scolopidial sensory organs from molecular mechanisms to systems analysis.

show abstract

“…It is known that natural sources of vibratory noise, such as those caused by rain, wind and animal songs, play important roles in modulating the aforementioned behaviours. Some organisms can discriminate between noise and 'biological' cues even when both contain overlapping spectra (Caldwell, McDaniel, & Warkentin, 2009Guedes, Matheson, Frei, Smith, & Yack, 2012). However, many other organisms are subject to vibratory noise interference.…”

mentioning

confidence: 99%

Vibratory noise in anthropogenic habitats and its effect on prey detection in a web-building spider

Elias

2014

Animal Behaviour

View full text Add to dashboard Cite

Vibration detection and discrimination in the masked birch caterpillar (Drepana arcuata)

Cited by 34 publications

References 20 publications

Substrate-Borne Vibrations Induce Behavioral Responses in the Leaf-Dwelling Cerambycid, Paraglenea fortunei

Substrate-Borne Vibrations Induce Behavioral Responses in the Leaf-Dwelling Cerambycid, Paraglenea fortunei

Functional Morphology and Evolutionary Diversity of Vibration Receptors in Insects

Vibratory noise in anthropogenic habitats and its effect on prey detection in a web-building spider

Contact Info

Product

Resources

About