Hold your breath – Differential behavioral and sensory acuity of mosquitoes to acetone and carbon dioxide
Authors:
Majid Ghaninia aff001; Shahid Majeed aff003; Teun Dekker aff003; Sharon R. Hill aff003; Rickard Ignell aff003
Authors place of work:
School of Life Sciences, Arizona State University, Tempe, AZ, United States of America
aff001; Division of Entomology, Department of Plant Protection, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran
aff002; Disease Vector Group, Unit of Chemical Ecology, Department of Plant Protection Biology, Swedish University of Agricultural Sciences, Alnarp, Sweden
aff003
Published in the journal:
PLoS ONE 14(12)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0226815
Summary
Host seeking in the yellow fever mosquito, Aedes aegypti, and the African malaria mosquito, Anopheles coluzzii, relies on specific and generic host-derived odorants. Previous analyses indicate that the behavioral response of these species depends differentially on the presence of carbon dioxide (CO2) and other constituents in human breath for activation and attraction. In this study, we use a flight tube assay and electrophysiological analysis to assess the role of acetone, a major component of exhaled human breath, in modulating the behavioral and sensory neuronal response of these mosquito species, in the presence and absence of CO2. When presented alone at ecologically relevant concentrations, acetone increases attraction in Ae. aegypti, but not in An. coluzzii. Moreover, in combination with CO2, human breath-equivalents of acetone ranging between 0.1 and 10 ppm reproduces a behavioral response similar to that observed to human breath in host-seeking Ae. aegypti, but not in An. coluzzii. Acetone does, however, reduce attraction to CO2 in An. coluzzii, when presented at a higher concentration of 10 ppm. We identify the capitate peg A neuron of the maxillary palp of both species as a dual detector of CO2 and acetone. The sensory response to acetone, or binary blends of acetone and CO2, reflects the observed behavioral output in both Ae. aegypti and An. coluzzii. We conclude that host recognition is contextual and dependent on a combination of ecologically relevant odorants at naturally occurring concentrations that are encoded, in this case, by differences in the temporal structure of the neuronal response. This information should be considered when designing synthetic blends for that optimally attract mosquitoes for monitoring and control.
Keywords:
Behavior – Animal behavior – Carbon dioxide – Neurons – Acetones – Mosquitoes – Aedes aegypti – Sensory neurons
Introduction
The yellow fever mosquito, Aedes aegypti, and the African malaria mosquito, Anopheles coluzzii (formerly Anopheles gambiae molecular form M), exhibit a feeding preference for humans, making them efficient vectors of disease [1]. To identify new vector control measures to prevent the transmission of these diseases, the odor-mediated host-seeking behavior of mosquitoes has been put under scrutiny [2]. This behavior is heavily dependent on specific and generic host-derived volatile cues, which when presented in an accurate blend elicit a sequence of behaviors, including activation, attraction and landing [3–6]. Recognition of ´host´ differs across species, and is highly contextual and dependent on quantitative and qualitative differences in the odor blends [4, 5, 7]. Thus, an increased understanding of odor blend perception in mosquitoes is pertinent for the development of synthetic blends that support monitoring and control of host-seeking mosquitoes.
We, and others, have previously shown that sensory neurons in the maxillary palps of mosquitoes are tuned to constituents of vertebrate breath, including carbon dioxide (CO2) and (R)-1-octen-3-ol [4, 5, 8, 9], which are commonly used for the control and monitoring of mosquitoes. These studies show that interspecific variation in the behavioral response to volatile cues, when presented in ecologically relevant context and concentrations, can be explained by differential constraints on the olfactory system between mosquito species [4, 5]. To further analyze the behavioral and sensory response of Ae. aegypti and An. coluzzii to ecologically relevant odor blends, we here assess the role of another constituent of vertebrate breath, acetone, in the presence and absence of CO2.
Acetone is a by-product of fat metabolism and is a major component in exhaled breath, as well as in fresh urine and blood of humans and animals alike [10–14]. The concentration of acetone in human breath ranges from 0.5 to 2 ppm, but is greatly impacted by factors such as health, age and diet [12]. Similarly, acetone concentration in the breath of other animals, such as cattle, depends on the health of individual animals [10, 15, 16], and may reach concentrations of up to 40× higher than that of humans [11, 16].
Behavioral responses to acetone, either alone or in the presence of CO2, have been demonstrated for both An. gambiae [17, 18] and Ae. aegypti [19–21]. Besides enhancing the behavioral response to CO2, acetone, when presented at concentrations substantially higher than that found in human breath, affects the behavioral response to both complex host odors and individual constituents thereof [17, 19, 21, 22]. The behavioral response to acetone, however, differs among species. While acetone increases flight behavior in An. gambiae, it does not evoke landing and may even inhibit attraction to other host odorants [17, 19]. For Ae. aegypti, however, acetone, either alone or in combination with other host volatiles, increases attraction [20]. This suggests that acetone is differentially detected and encoded by the olfactory system of mosquitoes. As of yet, however, no studies have reported on which sensory neuron(s) in mosquitoes are responsible for the detection of acetone, or how this information is encoded.
In this study, we analyze the behavioral response of female Ae. aegypti and An. coluzzii to human breath and binary blends of acetone and CO2, as well as to acetone and CO2 alone, at ecologically relevant concentrations [5, 10–12, 15, 16, 23–25]. Physiological responses to these stimuli by the CO2-sensitive neuron on the maxillary palp of the two species reflect the species-specific differences in behavioral responses. We discuss our findings in relation to previous studies and place them in the context of development of attractants for disease-transmitting mosquitoes.
Materials and methods
Mosquitoes
Aedes aegypti (Rockefeller strain) and An. coluzzii (Suakoko strain; previously An. gambiae molecular form M) were reared at 27 ± 2°C, 70 ± 2% relative humidity (RH) under a 12 h : 12 h light : dark period, as previously described [26]. For all experiments, 6-day post-emergence female mosquitoes were used; these were provided water but deprived of their regular sugar source 24 h prior to experiments.
Flight tube bioassay
To analyze the behavioral response of Ae. aegypti and An. coluzzii to exhaled breath, as well as to acetone and CO2, presented alone or in binary blends, a flight tube bioassay was used (Fig 1A; [5]. The bioassay was illuminated from above with white light at 280 lux for the diurnal Ae. aegypti, while red light (40 lux) was used for the nocturnal An. coluzzii. Experiments were conducted during their period of peak host-seeking activity of each species [27, 28]. Charcoal-filtered humidified air (25 ± 2°C, RH 65 ± 2%) flowed through the flight tube at 30 cm s−1. To ensure a laminar flow and a homogeneous plume structure, the air passed through a series of stainless-steel mesh screens prior to entering the flight tube. Homogenous discrete stimulus pulses (1 s on and 1 s off) were introduced into the flight section using a stimulus controller (SEC-2/b, Syntech), which pumped stimulus-laden air from a 40 l Tedler gas sampling bag (Adtech Polymer Ltd, Stroud, UK) into a pulse generator, placed behind the mesh screens [24]. Stimuli were prepared in the following way: 1) breath was collected by a volunteer exhaling normally through a mouthpiece into the bag for 4 min prior to the experiment; 2) 30000 ppm CO2 was prepared by introducing synthetic air (Strandmöllen AB, Ljungby, Sweden) at 1.5 l min-1 and pure CO2 (Strandmöllen AB) at 0.2 l min-1 into the gas sampling bag, to obtain the concentration approximating the natural composition in exhaled breath [12]; 3) acetone (99.9%, Chromasolv, Sigma-Aldrich, Stockholm, Sweden) was diluted with distilled water and then pipetted into the bag, which was subsequently filled with synthetic air, to obtain concentrations of 0.1 ppm, 1 ppm and 10 ppm at the downwind end of the flight tube; 4) binary mixtures of 30000 ppm CO2 and the three concentrations of acetone; and 5) for the negative control experiments, the gas sampling bag was filled with synthetic air at an airflow of l.5 l min-1. The consistency in amplitude and the structure of the discrete pulsed stimuli was visualized using a mini-PID (Aurora Scientific, Aurora, Ontario, Canada) with known concentration of acetone with different flow rates as described by Majeed et al. [24]. In addition, the concentrations of acetone and CO2 were measured at the down-wind end of the flight tube using the mini-PID (Aurora Scientific, Aurora, Ontario, Canada) and a CO2 analyzer (LI-820, LICOR Biosciences, Lincoln, NE, USA), respectively. This revealed a concentration of 1200 ± 12 ppm CO2, as well as average concentrations of 0.1 ± 0.02 ppm, 1 ppm ± 0.01 and 10 ± 0.04 ppm acetone.
A. Behavior was assessed in a flight tube assay: (a) charcoal filtered and humidified air flowed through the assay, (b) pressurized air inlet, (c) stimulus inlet into which the stimulus was injected, (d) stainless-steel mesh plume diffusers, (e) glass flight tube, and (f) release chamber. The upper panels demonstrate that the pulsed stimuli (here shown as five cycles of 1 s on and 1 s off) maintain their amplitude and shape throughout the flight tube and at all tested flow rates. The upper right panel shows the consistent and distinct pulsed stimuli at ascending flow rates of known concentration of acetone in the flight tube. Discrete pulsed stimuli were measured in the center (in red) and at the lateral sides (in black) of the release chamber, at halfway and at the source. The upper left panel presents a graphical representation of the distinct pulsed stimuli, which shows the average amplitude of each of the five distinct pulses (N = 10) at different positions and the regression correlation coefficients (R2) that demonstrate the consistency of the stimulus amplitude at the different positions within the flight tube with increasing flow rates. Time to take off (B, C; top graphs) and source contact (B, C; bottom graphs) are differentially affected by human breath, acetone and by the binary blends in the two species. The number of mosquitoes responding is indicated as numbers inset in each bar. Different letters above the bars denote significant differences between treatments within species (ANOVA, p < 0.05). Vertical bars represent the standard error of means ± SE.
Individual mosquitoes were kept in glass release chambers (7 × 2.6 cm i.d.), covered with stainless steel mesh on one side and a cotton plug on the other, in the bioassay room for 24 h prior to the experiments [5]. Following the opening of the release chamber, the time to take off (flight activation) and the time to source contact were recorded. The maximum experimental time was 120 s. Thirty individuals of each species were observed for all treatments. To minimize the effect of daily variation in baseline activity and responses to odors, an equal number of test and control individuals were observed each day. For both species, to compare the time to take off and the time to source contact in response to the various treatments (human breath, CO2 and acetone alone, binary blends and synthetic air), an ANOVA followed by Tukey’s HSD post hoc test was used (GraphPad Prism, v. 7; GraphPad software, La Jolla, CA, USA). The total number of mosquitoes making source contact was analyzed with nominal logistic regression, comparing presence and absence of CO2 and dose of acetone for each species (JMP Pro v. 14, SAS Institute Inc., Cary, NC, 1989–2019).
Electrophysiology
Initial screening of all previously characterized functional types of sensilla on the antennae of Ae. aegypti and An. coluzzii [26, 29–32] revealed that the sensory neurons sensitive to acetone are found on the maxillary palps. Specifically, the type of sensory neuron responding to acetone is the same as the one responding to CO2, the capitate peg A (cpA) neuron [5]. Electrophysiological recordings from this sensillum type were made and analyzed as previously described [5].
A continuous humidified stream of synthetic air (Strandmöllen AB), lacking CO2, was passed over the maxillary palp (2 l min−1) via a glass tube (7 mm i.d.). Stimuli, consisting of CO2, acetone or binary mixture thereof, were introduced into the air stream through a hole (2 mm i.d.) in the glass tube, 11 cm upstream of the maxillary palps. Delivery of CO2 was regulated by a two-way Teflon solenoid valve (Teddington, Skogås, Sweden), controlled via the digital output of an IDAC-4 (Syntech, Germany). The valve was connected to a separate gas cylinder containing 1200 ppm CO2 and oxygen (20%), balanced by nitrogen (Strandmöllen AB). Acetone, dissolved in distilled water, at concentrations ranging from 0.1 to 100000 ppm, were loaded (15 μl) onto a piece of filter paper (5 × 20 mm), placed inside a Pasteur pipette. The pipettes were sealed using Parafilm™ after loading and used once within 5 min to limit the variation due to evaporation. For the dose-response analysis, stimuli were presented in increasing concentrations from 0.1 to 100000 ppm. To test binary mixtures of CO2 and acetone, pipettes loaded with 0.1, 1 and 10 ppm acetone were gently, yet rapidly, filled with 1200 ppm CO2, after establishing a stable contact with a capitate peg sensillum. The rationale for selecting 1200 ppm CO2 for the binary blends was that this concentration corresponds with the natural level associated with proximity to a host [23, 25] and has previously been shown to elicit behavioral response in both mosquito species [5, 24]. Stimuli were presented in the following order: CO2 (1200 ppm), 0.1 ppm acetone, 0.1 ppm acetone + CO2, 1 ppm acetone, 1 ppm acetone + CO2, 10 ppm acetone, 10 ppm acetone + CO2. For all experiments, distilled water was used as a control. The entire panel of stimuli was used once per specimen. The time between stimuli was 10 s. Extracellular spike activity of the A neuron was analyzed by counting the number of spikes 0.5 s before stimulus onset and subtracting this from that of the 0.5 s period following stimulus delivery. Results are presented as spikes s-1. To further analyze the neural response to the binary mixtures, the temporal characteristics were analyzed by plotting frequency histograms (spikes s-1) during 100 ms bins over a period of 2s (500 ms before to 1500 ms after the response onset).
To compare the sensitivity of the capitate peg A neurons of the two species to acetone and the binary blends, a repeated measures two-way ANOVA followed by Tukey’s multiple comparison test was used (GraphPad Prism, v. 8.2.1). The kinetic curve fits were generated using a non-linear regression association/dissociation model (association then dissociation model constrained at HotNM = 12 and Time0 = 0.2; GraphPad Prism, www.graphpad.com/guides/prism/8/curve-fitting/reg_equaton_association_then_disso.htm).
Results
Reliance on acetone for the behavioral response to human breath
The behavioral response of Ae. aegypti and An. coluzzii was differentially affected by acetone and the binary blends (Take off: F(8,261) = 9.93, P < 0.0001 and F(8,261) = 4.43, P < 0.0001, respectively; Source contact: F(8,190) = 15.2, P < 0.0001 and F(8,150) = 7.22, P < 0.0001, respectively) (Fig 1). Compared to synthetic air, acetone alone did not affect the time to take off in either species, but significantly reduced the time to source contact in Ae. aegypti (Fig 1B and 1C). When presented together with CO2, on the other hand, acetone significantly reduced the time to take off in Ae. aegypti, but not in An. coluzzii (Fig 1B and 1C; top). Combinations of acetone and CO2 did not influence the time to source contact in Ae. aegypti (Fig 1B; bottom), but the time to source contact increased at the highest dose tested in An. coluzzii (Fig 1C; bottom). For both species, the number of insects that made source contact was higher in the presence of CO2 but was not affected by the dose of acetone (Ae. aegypti χ2 = 1.32, p = 0.52, parameter estimates: intercept = 0.036, acetone = 0.63; An. coluzzii χ2 = 1.51, p = 0.93, parameter estimates: intercept = 0.031, acetone = 0.46).
Detection of acetone
Electrophysiological recordings from the capitate peg sensilla of Ae. aegypti and An. coluzzii (Fig 2A) revealed a dose-dependent response of the overall rate of firing of the cpA neuron to acetone at concentrations exceeding 1000 ppm (Dose: F(6, 196) = 62.34, p < 0.0001), with Ae. aegypti being significantly more sensitive than An. coluzzii (Species: F(3, 196) = 121.3, p < 0.0001) (Fig 2B–2D). Interestingly, even at low, and ecologically relevant, concentrations (0.1–100 ppm), acetone elicited a higher response than the control (synthetic air) for both Ae. aegypti (p = 0.0097) and An. coluzzii (p = 0.0047) (Fig 2B–2D). Taken together, these results demonstrate that both species are capable of sensing low, ecologically relevant, concentrations of acetone, however assessing the effect of the dose requires higher resolution analysis.
A. Sample trace from a capitate peg sensillum of Ae. aegypti, displaying the firing frequency of the three neurons (cpA, B, and C). Dose-dependent response of the cpA neuron in Ae. aegypti and An. coluzzii to increasing concentrations of acetone (B-D). Note the significant increased response, above the control, to low concentrations of acetone (D). At higher concentrations, acetone elicits a significantly higher response in the cpA neuron of Ae. aegypti than of An. coluzzii, indicated by different letter designations (two-way repeated-measures ANOVA, Tukey’s multiple comparison test, uppercase, Ae. aegypti; lowercase, An. coluzzii) (D). “ns” indicates no significant difference among the doses for each species control.
Detection of binary blends of acetone and CO2
The response of the cpA neuron, when analyzed at high temporal resolution, to either acetone or CO2 alone, was significantly different from that to the binary blends for both Ae. aegypti (F(1,10) = 70.84, p < 0.0001) and An. coluzzii (F(1,10) = 53.04, p < 0.0001) (Fig 3A–3D). In Ae. aegypti, the cpA response to acetone was significantly higher than that to the control, in both the presence and absence of CO2 (F(3,30) = 30.04, p < 0.0001) (Fig 3E; Table 1). In contrast, in An. coluzzii, the only significant change in cpA activity was to acetone in the absence of CO2 (F(3,30) = 6.47, p = 0.0017) (Fig 3F; Table 1).
Physiological response of the cpA neuron in Ae. aegypti (A, B) and An. coluzzii (C, D) to increasing concentrations of acetone, CO2, and binary blends thereof. E and F show, in high temporal resolution, the differential increase in response of the cpA neuron of Ae. aegypti (nrecording = 6, Nindividual = 6) and An. coluzzii (nrecording = 6, Nindividual = 6) to acetone in the presence or absence of CO2 (two-way repeated-measures ANOVA, Tukey’s multiple comparison test; ** p < 0.01; *** p < 0.001).
The temporal pattern of response to acetone and CO2 alone, as well as binary blends thereof, was phasic-tonic for both Ae. aegypti and An. coluzzii (Fig 2B and 2C and Fig 3C, A,C In Ae. aegypti, the cpA activity in response to CO2 and the three binary blends of acetone and CO2 could be modeled by a single, shared association/dissociation curve (F(12,306) = 1.509, p = 0.1194; dotted line in Fig 3E), revealing a consistently higher kinetic response to increasing concentrations of acetone in combination with CO2 compared to acetone alone (Fig 3E). In contrast, a model of the activity of the Ae. aegypti cpA neuron to acetone alone revealed that each concentration could be represented by distinct association/dissociation curves (F(8,240) = 4.551, p < 0.0001; solid lines in Fig 3E), demonstrating that the response kinetics of this neuron is influenced by acetone concentration (Fig 3E). The reverse was observed for An. coluzzii, in which the cpA response to acetone alone could be modeled by a single, shared curve (F(2,204) = 1.566, p = 0.1367; dotted line in Fig 3F), while the response to CO2 and the blends were modeled individually (F(12,272) = 4.198, p < 0.0001; solid lines in Fig 3F). This demonstrates that the response kinetics of this neuron is influenced by acetone concentration only in the presence of CO2 (Fig 3F).
Discussion
The behavioral response of Ae. aegypti and An. coluzzii to human breath relies on the presence of CO2 [18, 33, this study] and is differentially modulated by acetone. While acetone enhances the behavioral response of Ae. aegypti, in both the presence and absence of CO2, it decreases the behavioral response of An. coluzzii in the presence of CO2. This demonstrates that blend perception of generic volatile compounds in human breath plays a role in host attraction for these species. The observed differences in behavioral attraction correlate with the different mode of encoding CO2 and acetone, as well as the binary blends, by the cpA neurons of the two species. The data provided here, together with our previous studies [4, 5], clearly emphasize that generic host volatiles, when presented in ecologically relevant concentrations, may provide reliable cues for host attraction and recognition for mosquitoes.
When presented at ecologically relevant concentrations, acetone, in combination with CO2, reproduces a behavioral response similar to that observed to human breath of host-seeking Ae. aegypti, but not of An. coluzzii. This is in line with previous observations demonstrating that activation of host-seeking Ae. aegypti and An. gambiae differentially relies on human breath constituents other than CO2 [18, 33]. Acetone, when presented alone at concentrations of 1–10 ppm, significantly decreased the time to source contact in Ae. aegypti when compared with synthetic air. A similar observation was made by Venkatesh and Sen [20], albeit at concentrations of acetone >100,000× higher than that used in the current study, demonstrating that acetone may substitute for CO2, as suggested by Bernier et al. [21]. A plausible explanation for the observed behaviour at these extreme concentrations may be a result of the intense activation of the CO2 sensitive, cpA, neurons, demonstrated here. When presented in combination with CO2, 1 ppm acetone, an equivalent concentration of that found in human breath (0.5–2 ppm), significantly decreased the time to take off in Ae. aegypti compared to that of CO2 alone, to a level similar to that observed to human breath. Acetone has previously been shown to enhance the behavioral response of Ae. aegypti to other host volatiles, in the presence of CO2 [21, 22], verifying that acetone may act additively or synergistically to enhance activation and attraction. In contrast, acetone, whether in the presence or absence of CO2, did not significantly affect time to take off and source contact for An. coluzzii. The only exception to this was an observed increase in time to source contact, when acetone was presented at 10 ppm together with CO2. A similar inhibition of the behavioural response to high concentrations of acetone has been reported by Takken et al. [19] and Qiu et al. [17]. We conclude that Ae. aegypti and An. coluzzii appear differentially constrained in their capacity to respond behaviorally to binary blends of acetone and CO2.
The observed differential behavioral response of Ae. aegypti and An. coluzzii to acetone and CO2, and binary blends thereof, is reflected in the sensory response of the cpA neurons to these stimuli. While we cannot rule out the existence of rare types of acetone-sensitive neurons on the antennae or differences in higher order processing of either species, this study suggests that the CO2-sensitive neuron in mosquitoes, far from being a labelled line for CO2, is capable of encoding breath-related blends. While acetone is a novel ligand for the cpA neuron, other odorants are known to be agonists of the cpA neuron in Ae. aegypti, An. gambiae and in the southern house mosquito, Culex quinquefasciatus, when presented at high concentrations [34–36]. Our physiological analysis, however, reveals that the cpA neuron of both Ae. aegypti and An. coluzzii demonstrate a high sensitivity to ecologically relevant concentrations of acetone alone, which in Ae. aegypti correlates with behavior. A correlation is also found between the behavior of both Ae. aegypti and An. coluzzii and the sensory response of their cpA neurons to the binary blends. In Ae. aegypti, stimulation with both acetone and CO2 significantly increased the response of the cpA neuron, without altering the response kinetics, whereas the opposite was found for An. coluzzii. The observed differences in sensory response of the two species to acetone, either alone or in combination with CO2, is intriguing. Agonists of the CO2-sensitive neuron in both mosquitoes [34–36] and Drosophila melanogaster [35, 37] have been shown to be detected by gustatory receptors (Grs) expressed in the cpA neuron. Whether structural or stoichiometric differences of the Grs in the two mosquito species [8, 38, 39] account for the demonstrated differences in sensory response remain to be analyzed.
Previous studies indicate that behavioral responses to complex host odors in mosquitoes are more robust than to single host volatiles [3, 6, 17, 40, 41]. While host discrimination and selection by anthropophilic mosquitoes may be regulated by species-specific host volatiles [42, 43], recent research suggests that these behaviors also rely on a number of generic host volatiles and their relative proportions [3, 4, 41, 44–48]. In most of these studies, these host volatiles have been shown to be detected by sensory neurons on the antennae, and readily synergize with CO2 in eliciting host-related behaviors. In this study, we identify acetone as a host volatile, detected by sensory neurons on the maxillary palps, that differentially modulates both the physiological and behavioral responses in Ae. aegypti and An. coluzzii. Behaviorally, Ae. aegypti is activated by the presence of CO2 and acetone at ecologically relevant concentrations, whereas the activation of An. coluzzii is independent of the presence of acetone. This is reflected in the firing rates of the cpA sensory neuron of each species. In contrast, source contact is mediated in Ae. aegypti by CO2, with or without acetone, while this is not the case in An. coluzzii. Moreover, An. coluzzii tolerates only a limited concentration of acetone, less than 10 ppm, above which the time to source contract increases. This differential response to the presence of acetone correlates with the change in temporal kinetics seen in the cpA neuron in An. coluzzii. This suggests both that other stimuli are involved in attraction to the host in An. coluzzii [18], and that acetone is acting as a host discrimination cue in this species, but not in Ae. aegypti. In Ae. aegypti, acetone, together with CO2, is acting as an activator, similar to human breath, and may be the missing component in human breath that was proposed by Khan and Maibach [33] to be responsible for the observed greater human attraction.
While the role of CO2 in activating, sensitizing and attracting mosquitoes to potential hosts is well characterized [3, 5, 49, and references therein], this study reveals that another major component of exhaled breath, acetone, is able to modulate this behavioral response. When presented in binary blends together with CO2, acetone, within the natural concentrations found in the exhaled breath of potential hosts, enhances both the sensory and behavioral response of Ae. aegypti. For An. coluzzii, which is highly anthropophilic, the sensory and behavioral response is decreased at higher concentrations of acetone, indicating that acetone may act as a recognition cue to discriminate among hosts. From a vector control perspective, additional identification of ecologically relevant odorants and their naturally occurring concentrations, and how these factors affect vector-host interaction, can aid in optimizing synthetic blends for monitoring and control of mosquito populations.
Zdroje
1. Takken W, Verhulst NO. Host preferences of blood-feeding mosquitoes. Annual Review of Entomology. 2013;58:433–53. doi: 10.1146/annurev-ento-120811-153618 23020619
2. Potter CJ. Stop the biting: targeting a mosquito’s sense of smell. Cell. 2014;156(5):878–81. doi: 10.1016/j.cell.2014.02.003 24581489
3. Cardé RT. Multi-cue integration: how female mosquitoes locate a human host. Current Biology. 2015;25(18):R793–R5. doi: 10.1016/j.cub.2015.07.057 26394099
4. Majeed S, Hill SR, Birgersson G, Ignell R. Detection and perception of generic host volatiles by mosquitoes modulate host preference: context dependence of (R)-1-octen-3-ol. Royal Society Open Science. 2016;3(11):160467. doi: 10.1098/rsos.160467 28018630
5. Majeed S, Hill SR, Dekker T, Ignell R. Detection and perception of generic host volatiles by mosquitoes: responses to CO2 constrains host-seeking behaviour. Royal Society Open Science. 2017;4(5):170189. doi: 10.1098/rsos.170189 28573028
6. Okumu FO, Killeen GF, Ogoma S, Biswaro L, Smallegange RC, Mbeyela E, et al. Development and field evaluation of a synthetic mosquito lure that is more attractive than humans. PloS One. 2010;5(1):e8951. doi: 10.1371/journal.pone.0008951 20126628
7. Bruce TJ, Pickett JA. Perception of plant volatile blends by herbivorous insects–finding the right mix. Phytochemistry. 2011;72(13):1605–11. doi: 10.1016/j.phytochem.2011.04.011 21596403
8. Lu T, Qiu YT, Wang G, Kwon JY, Rutzler M, Kwon H-W, et al. Odor coding in the maxillary palp of the malaria vector mosquito Anopheles gambiae. Current Biology. 2007;17(18):1533–44. doi: 10.1016/j.cub.2007.07.062 17764944
9. Syed Z, Leal WS. Maxillary palps are broad spectrum odorant detectors in Culex quinquefasciatus. Chemical Senses. 2007;32(8):727–38. doi: 10.1093/chemse/bjm040 17569743
10. Dobbelaar P, Mottram T, Nyabadza C, Hobbs P, Elliott-Martin R, Schukken Y. Detection of ketosis in dairy cows by analysis of exhaled breath. Veterinary Quarterly. 1996;18(4):151–2. 8972064
11. Elliott-Martin R, Mottram T, Gardner J, Hobbs P, Bartlett P. Preliminary investigation of breath sampling as a monitor of health in dairy cattle. Journal of Agricultural Engineering Research. 1997;67(4):267–75.
12. Fenske JD, Paulson SE. Human breath emissions of VOCs. Journal of the Air & Waste Management Association. 1999;49(5):594–8.
13. Wahl HG, Hoffmann A, Luft D, Liebich HM. Analysis of volatile organic compounds in human urine by headspace gas chromatography–mass spectrometry with a multipurpose sampler. Journal of Chromatography A. 1999;847(1–2):117–25. doi: 10.1016/s0021-9673(99)00017-5 10431355
14. Knodt C, Shaw J, White G. Studies on ketosis in dairy cattle. I. Effect of stall and pasture feeding upon the concentration of blood and urinary acetone bodies of dairy cattle1. Journal of Dairy Science. 1942;25(10):837–49.
15. Vale G, Hall D. The role of 1-octen-3-ol, acetone and carbon dioxide in the attraction of tsetse flies, Glossina spp. (Diptera: Glossinidae), to ox odour. Bulletin of Entomological Research. 1985;75(2):209–18.
16. Torr S, Hall D, Smith J. Responses of tsetse flies (Diptera: Glossinidae) to natural and synthetic ox odours. Bulletin of Entomological Research. 1995;85(1):157–66.
17. Qiu Y, Smallegange R, Van Loon J, Takken W. Behavioural responses of Anopheles gambiae sensu stricto to components of human breath, sweat and urine depend on mixture composition and concentration. Medical and Veterinary Entomology. 2011;25(3):247–55. doi: 10.1111/j.1365-2915.2010.00924.x 21108650
18. Healy T, Copland M. Activation of Anopheles gambiae mosquitoes by carbon dioxide and human breath. Medical and Veterinary Entomology. 1995;9(3):331–6. doi: 10.1111/j.1365-2915.1995.tb00143.x 7548953
19. Takken W, Dekker T, Wijnholds Y. Odor-mediated flight behavior of Anopheles gambiae giles Sensu Stricto and An. stephensi liston in response to CO 2, acetone, and 1-octen-3-ol (Diptera: Culicidae). Journal of Insect Behavior. 1997;10(3):395–407.
20. Venkatesh P, Sen A. Laboratory evaluation of synthetic blends of l-(+)-lactic acid, ammonia, and ketones as potential attractants for Aedes aegypti. Journal of the American Mosquito Control Association. 2017;33(4):301–8. doi: 10.2987/16-6599.1 29369028
21. Bernier UR, Kline DL, Posey KH, Booth MM, Yost RA, Barnard DR. Synergistic attraction of Aedes aegypti (L.) to binary blends of L-lactic acid and acetone, dichloromethane, or dimethyl disulfide. Journal of Medical Entomology. 2003;40(5):653–6. doi: 10.1603/0022-2585-40.5.653 14596278
22. Bernier UR, Kline DL, Allan SA, Barnard DR. Laboratory comparison of Aedes aegypti attraction to human odors and to synthetic human odor compounds and blends. Journal of the American Mosquito Control Association. 2007;23(3):288–93. doi: 10.2987/8756-971X(2007)23[288:LCOAAA]2.0.CO;2 17939508
23. Grant A, Aghajanian J, O'Connell R, Wigton B. Electrophysiological responses of receptor neurons in mosquito maxillary palp sensilla to carbon dioxide. Journal of Comparative Physiology A. 1995;177(4):389–96.
24. Majeed S, Hill SR, Ignell R. Impact of elevated CO2 background levels on the host-seeking behaviour of Aedes aegypti. Journal of Experimental Biology. 2014;217(4):598–604.
25. Mboera L, Knols B, Takken W, Della Torre A. The response of Anopheles gambiae sl and A. funestus (Diptera: Culicidae) to tents baited with human odour or carbon dioxide in Tanzania. Bulletin of Entomological Research. 1997;87(2):173–8.
26. Ghaninia M, Ignell R, Hansson BS. Functional classification and central nervous projections of olfactory receptor neurons housed in antennal trichoid sensilla of female yellow fever mosquitoes, Aedes aegypti. European Journal of Neuroscience. 2007;26(6):1611–23. doi: 10.1111/j.1460-9568.2007.05786.x 17880395
27. Jones M, Gubbins S, Cubbin C. Circadian flight activity in four sibling species of the Anopheles gambiae complex (Diptera, Culicidae). Bulletin of Entomological Research. 1974;64(2):241–6.
28. Yee WL, Foster WA. Diel sugar-feeding and host-seeking rhythms in mosquitoes (Diptera: Culicidae) under laboratory conditions. Journal of Medical Entomology. 1992;29(5):784–91. doi: 10.1093/jmedent/29.5.784 1357175
29. Ghaninia M. Olfaction in mosquitoes: Neuroanatomy and electrophysiology of the olfactory system [Doctoral dissertation]: Swedish University of Agricultural Sciences, SE.; 2007.
30. Ghaninia M, Larsson M, Hansson BS, Ignell R. Natural odor ligands for olfactory receptor neurons of the female mosquito Aedes aegypti: use of gas chromatography-linked single sensillum recordings. Journal of Experimental Biology. 2008;211(18):3020–7.
31. Qiu YT, Van Loon JJ, Takken W, Meijerink J, Smid HM. Olfactory coding in antennal neurons of the malaria mosquito, Anopheles gambiae. Chemical Senses. 2006;31(9):845–63. doi: 10.1093/chemse/bjl027 16963500
32. Suer RA. Unravelling the malaria mosquito's sense of smell: neural and behavioural responses to human-derived compounds [Doctoral dissertation]: Wageningen University, NL.; 2011.
33. Khan A, Maibach HI. Effect of human breath on mosquito attraction to man. Mosquito News. 1972;32(1):11–5.
34. Turner SL, Li N, Guda T, Githure J, Cardé RT, Ray A. Ultra-prolonged activation of CO 2-sensing neurons disorients mosquitoes. Nature. 2011;474(7349):87. doi: 10.1038/nature10081 21637258
35. Tauxe GM, MacWilliam D, Boyle SM, Guda T, Ray A. Targeting a dual detector of skin and CO2 to modify mosquito host seeking. Cell. 2013;155(6):1365–79. doi: 10.1016/j.cell.2013.11.013 24315103
36. Coutinho-Abreu IV, Sharma K, Cui L, Yan G, Ray A. Odorant ligands for the CO 2 receptor in two Anopheles vectors of malaria. Scientific Reports. 2019;9(1):2549. doi: 10.1038/s41598-019-39099-0 30796292
37. MacWilliam D, Kowalewski J, Kumar A, Pontrello C, Ray A. Signaling mode of the broad-spectrum conserved CO2 receptor is one of the important determinants of odor valence in Drosophila. Neuron. 2018;97(5):1153–67. e4. doi: 10.1016/j.neuron.2018.01.028 29429938
38. Erdelyan C, Mahood T, Bader T, Whyard S. Functional validation of the carbon dioxide receptor genes in Aedes aegypti mosquitoes using RNA interference. Insect Molecular Biology. 2012;21(1):119–27. doi: 10.1111/j.1365-2583.2011.01120.x 22122783
39. McMeniman CJ, Corfas RA, Matthews BJ, Ritchie SA, Vosshall LB. Multimodal integration of carbon dioxide and other sensory cues drives mosquito attraction to humans. Cell. 2014;156(5):1060–71. doi: 10.1016/j.cell.2013.12.044 24581501
40. Smallegange RC, Takken W. Host-seeking behaviour of mosquitoes: responses to olfactory stimuli in the laboratory. Olfaction in vector-host interactions: Wageningen Academic Publishers; 2010. p. 143–80.
41. Takken W, Knols BG. Odor-mediated behavior of Afrotropical malaria mosquitoes. Annual Review of Entomology. 1999;44(1):131–57.
42. Mukabana WR, Takken W, Coe R, Knols BG. Host-specific cues cause differential attractiveness of Kenyan men to the African malaria vector Anopheles gambiae. Malaria Journal. 2002;1(1):17.
43. Smallegange RC, Bukovinszkiné-Kiss G, Otieno B, Mbadi PA, Takken W, Mukabana WR, et al. Identification of candidate volatiles that affect the behavioural response of the malaria mosquito Anopheles gambiae sensu stricto to an active kairomone blend: laboratory and semi‐field assays. Physiological Entomology. 2012;37(1):60–71.
44. Omondi A, Ghaninia M, Dawit M, Svensson T, Ignell R. Age-dependent regulation of host seeking in Anopheles coluzzii. Scientific Reports. 2019;9(1):9699. doi: 10.1038/s41598-019-46220-w 31273284
45. Geier M, Bosch OJ, Boeckh J. Influence of odour plume structure on upwind flight of mosquitoes towards hosts. Journal of Experimental Biology. 1999;202(12):1639–48.
46. Smallegange RC, Qiu YT, Bukovinszkiné-Kiss G, Van Loon JJ, Takken W. The effect of aliphatic carboxylic acids on olfaction-based host-seeking of the malaria mosquito Anopheles gambiae sensu stricto. Journal of Chemical Ecology. 2009;35(8):933. doi: 10.1007/s10886-009-9668-7 19626371
47. Smallegange RC, Qiu YT, van Loon JJ, Takken W. Synergism between ammonia, lactic acid and carboxylic acids as kairomones in the host-seeking behaviour of the malaria mosquito Anopheles gambiae sensu stricto (Diptera: Culicidae). Chemical Senses. 2005;30(2):145–52. doi: 10.1093/chemse/bji010 15703334
48. Verhulst NO, Mukabana WR, Takken W, Smallegange RC. Human skin microbiota and their volatiles as odour baits for the malaria mosquito Anopheles gambiae ss. Entomologia Experimentalis et Applicata. 2011;139(2):170–9.
49. Dekker T, Geier M, Cardé RT. Carbon dioxide instantly sensitizes female yellow fever mosquitoes to human skin odours. Journal of Experimental Biology. 2005;208(15):2963–72.
Článek vyšel v časopise
PLOS One
2019 Číslo 12
- Případ Bulovka: Jak postupují jiné nemocnice, aby podobným tragédiím zabránily?
- Jak často se u masových střelců vyskytují duševní choroby?
- FDA varuje před selfmonitoringem cukru pomocí chytrých hodinek. Jak je to v Česku?
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
- Není statin jako statin aneb praktický přehled rozdílů jednotlivých molekul
Nejčtenější v tomto čísle
- Methylsulfonylmethane increases osteogenesis and regulates the mineralization of the matrix by transglutaminase 2 in SHED cells
- Oregano powder reduces Streptococcus and increases SCFA concentration in a mixed bacterial culture assay
- Parametric CAD modeling for open source scientific hardware: Comparing OpenSCAD and FreeCAD Python scripts
- The characteristic of patulous eustachian tube patients diagnosed by the JOS diagnostic criteria