Dynamic Properties of Antennal Responses to Pheromone in Two Moth Species

Justus, Kristine A.; Cardé, Ring T.; French, Andrew S.

doi:10.1152/jn.00888.2004

Cited by 38 publications

(32 citation statements)

References 24 publications

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“…provides a tool to measure the ORNs' temporal resolution (15,16). We identified the antennae's temporal resolution as the maximum stimulus frequencies at which the coherence between the EAG response and the TiCl 4 smoke signal was significant at the 5 sigma level (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Olfactory transduction speed has never been measured directly, and estimates range from 10 to 30 ms (8)(9)(10)(11). Previous studies suggest that the maximum pulse tracking frequency of ORNs is species specific and ranges from 5 to 50 Hz (12)(13)(14)(15)(16)(17)(18)(19). However, these numbers do not match the high temporal resolution observed in behavioral studies (2)(3)(4)(5)(6)(7).…”

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confidence: 99%

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High-speed odor transduction and pulse tracking by insect olfactory receptor neurons

Szyszka

Gerkin

Galizia

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

111

101

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Sensory systems encode both the static quality of a stimulus (e.g., color or shape) and its kinetics (e.g., speed and direction). The limits with which stimulus kinetics can be resolved are well understood in vision, audition, and somatosensation. However, the maximum temporal resolution of olfactory systems has not been accurately determined. Here, we probe the limits of temporal resolution in insect olfaction by delivering high frequency odor pulses and measuring sensory responses in the antennae. We show that transduction times and pulse tracking capabilities of olfactory receptor neurons are faster than previously reported. Once an odorant arrives at the boundary layer of the antenna, odor transduction can occur within less than 2 ms and fluctuating odor stimuli can be resolved at frequencies more than 100 Hz. Thus, insect olfactory receptor neurons can track stimuli of very short duration, as occur when their antennae encounter narrow filaments in an odor plume. These results provide a new upper bound to the kinetics of odor tracking in insect olfactory receptor neurons and to the latency of initial transduction events in olfaction.olfaction | olfactory receptor neurons | odor transduction | temporal resolution | insect O dors carried in air plumes quickly break up into thin filaments that spread out across short distances from an odor source (1). The ability to track the temporal structure of filaments in an odor plume is essential for insects to segregate concurrent odors that arise from different sources (2-6). However, it is not clear whether signal transduction times and tracking rates of olfactory receptor neurons (ORNs) are fast enough to allow animals to use the higher frequency components of information present in odor plumes. Insect odor-guided behavior is remarkably robust against the spatial and temporal variability inherent in olfactory stimuli. For example, moths and beetles use temporal stimulus cues to segregate concurrent odors from closely spaced sources (2-5), and honey bees can detect 6-ms asynchrony in the onset of concurrent odor stimuli and use this onset asynchrony to segregate concurrent odors (6, 7). These observations of fast temporal resolution challenge the frequent notion that olfaction has slow integration times relative to other senses. Olfactory transduction speed has never been measured directly, and estimates range from 10 to 30 ms (8-11). Previous studies suggest that the maximum pulse tracking frequency of ORNs is species specific and ranges from 5 to 50 Hz (12-19). However, these numbers do not match the high temporal resolution observed in behavioral studies (2-7).We tested the limits of olfactory transduction speed and pulse tracking in five different insect species by measuring ORN population responses using electroantennogram (EAG) recordings. The amplitude and dynamics of EAG signals are proportional to the number of sensilla stimulated (20). They are also affected by receptor current amplitude, positions of the neurons relative to the recording electrode, and elec...

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

High-speed odor transduction and pulse tracking by insect olfactory receptor neurons

Szyszka

Gerkin

Galizia

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

111

101

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“…Thus the model fly's olfactory input signal can be taken as a scalar value. Olfactory receptor neurons are known to have low-pass (Justus et al, 2004;Schuckel et al, 2008) as well as high-pass (i.e. adaptation) characteristics (Störtkuhl et al, 1999).…”

Section: Olfactory Responsementioning

confidence: 99%

A model of visual–olfactory integration for odour localisation in free-flying fruit flies

Stewart

Baker

Webb

2010

Journal of Experimental Biology

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. Although rather less is known about flight responses to olfactory stimuli, it has been established that the sudden onset of an attractive odour results in increased forward velocity and a suppression of turning (Frye and Dickinson, Accepted 21 February 2010 SUMMARY Flying fruit flies (Drosophila melanogaster) locate a concealed appetitive odour source most accurately in environments containing vertical visual contrasts. To investigate how visuomotor and olfactory responses may be integrated, we examine the free-flight behaviour of flies in three visual conditions, with and without food odour present. While odour localisation is facilitated by uniformly distributed vertical contrast as compared with purely horizontal contrast, localised vertical contrast also facilitates odour localisation, but only if the odour source is situated close to it. We implement a model of visuomotor control consisting of three parallel subsystems: an optomotor response stabilising the model fly's yaw orientation; a collision avoidance system to saccade away from looming obstacles; and a speed regulation system. This model reproduces many of the behaviours we observe in flies, including visually mediated 'rebound' turns following saccades. Using recordings of real odour plumes, we simulate the presence of an odorant in the arena, and investigate ways in which the olfactory input could modulate visuomotor control. We reproduce the experimental results by using the change in odour intensity to regulate the sensitivity of collision avoidance, resulting in visually mediated chemokinesis. Additionally, it is necessary to amplify the optomotor response whenever odour is present, increasing the model fly's tendency to steer towards features of the visual environment. We conclude that visual and olfactory responses of Drosophila are not independent, but that relatively simple interaction between these modalities can account for the observed visual dependence of odour source localisation. Supplementary material available online at

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“…The bursts of firing by antennule olfactory receptor neurons of P. argus adapt selectively to odor pulses at frequencies of 0.5-0.1Hz (Marschall and Ache, 1989). Moth antennal receptor cells can resolve odor pulses at 2-5Hz (Rumbo and Kaissling, 1989) but show flicker fusion at 10Hz (Justus and Cardé, 2002), while electroantennograms show that odor pulses of 5-33Hz can be resolved, depending on the type of odorant and species of moth (Bau et al, 2002;Bau et al, 2005;Justus et al, 2005;Tripathy et al, 2010). The output of the moth olfactory antennal lobe, where local field potentials can track pulses up to 30Hz (Tripathy et al, 2010), also varies with the frequency of signal input (Vickers et al, 2001).…”

Section: A Reidenbach and M A R Koehlmentioning

confidence: 99%

The spatial and temporal patterns of odors sampled by lobsters and crabs in a turbulent plume

Reidenbach

Koehl

2011

Journal of Experimental Biology

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Dynamic Properties of Antennal Responses to Pheromone in Two Moth Species

Cited by 38 publications

References 24 publications

High-speed odor transduction and pulse tracking by insect olfactory receptor neurons

High-speed odor transduction and pulse tracking by insect olfactory receptor neurons

A model of visual–olfactory integration for odour localisation in free-flying fruit flies

The spatial and temporal patterns of odors sampled by lobsters and crabs in a turbulent plume

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