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Nectar-dwelling microbes of common tansy are attractive to its mosquito pollinator, Culex pipiens L.

A Correction to this article was published on 08 March 2021

This article has been updated

Abstract

Background

There is widespread interkingdom signalling between insects and microbes. For example, microbes found in floral nectar may modify its nutritional composition and produce odorants that alter the floral odor bouquet which may attract insect pollinators. Mosquitoes consume nectar and can pollinate flowers. We identified microbes isolated from nectar of common tansy, Tanacetum vulgare, elucidated the microbial odorants, and tested their ability to attract the common house mosquito, Culex pipiens.

Results

We collected 19 microbial isolates from T. vulgare nectar, representing at least 12 different taxa which we identified with 16S or 26S rDNA sequencing as well as by biochemical and physiological tests. Three microorganisms (Lachancea thermotolerans, Micrococcus lactis, Micrococcus luteus) were grown on culture medium and tested in bioassays. Only the yeast L. thermotolerans grown on nectar, malt extract agar, or in synthetic nectar broth significantly attracted Cx. pipiens females. The odorant profile produced by L. thermotolerans varied with the nutritional composition of the culture medium. All three microbes grown separately, but presented concurrently, attracted fewer Cx. pipiens females than L. thermotolerans by itself.

Conclusions

Floral nectar of T. vulgare contains various microbes whose odorants contribute to the odor profile of inflorescences. In addition, L. thermotolerans produced odorants that attract Cx. pipiens females. As the odor profile of L. thermotolerans varied with the composition of the culture medium, we hypothesize that microbe odorants inform nectar-foraging mosquitoes about the availability of certain macro-nutrients which, in turn, affect foraging decisions by mosquitoes.

Background

Chemical signalling between microbes and insects is widespread and occurs in a variety of contexts [1,2,3]. Plant odorants as well as visual displays of inflorescences play essential roles in attracting insect pollinators [4]. Floral nectar provides nutrition and habitat for myriad microorganisms [5,6,7,8,9,10] that may ultimately alter the composition of nectar [11] and produce odorants [8, 12, 13], thereby modifying the inflorescence odor bouquet [13,14,15]. These microbially-derived odorants may contribute to the plant-pollinator signalling system by serving as attractive semiochemicals (message-bearing chemicals) to pollinators [13, 16,17,18]. However, this type of signalling may be species-specific with respect to both the sender and the receiver of these semiochemicals because in other instances, microbe-derived odorants cause no behavioral response [19], or avoidance by pollinators [19, 20]. Furthermore, the overall odor bouquet produced by microbes varies with the composition of the microbe community [2, 21], likely modifying the insects’ behavioural responses.

Plant-derived nutrients (e.g., sugars) are fundamental dietary constituents for adult mosquitoes [22], providing energy for flight, mating, blood-feeding, egg-laying, and female overwintering [22,23,24,25]. Floral nectar is the dominant source of plant sugar for most mosquitoes but other sugar sources such as extra-floral nectar, aphid honeydew, and fruit juices are also consumed [22, 26]. Inflorescence semiochemicals [27] along with visual inflorescence displays [28] and CO2 [29] attract mosquitoes to various inflorescences [22, 29,30,31] that they distinguish by scent [32, 33] and may pollinate [34,35,36,37].

Microbe-derived odorants have not yet been implicated in mosquito nectar-foraging but are exploited by mosquitoes in a variety of other contexts. For example, the odor bouquet of microbe-inoculated or infested aphid honeydew is more attractive to the yellow fever mosquito, Aedes aegypti, than the odor bouquet of sterilized honeydew [38]. The volatile semiochemicals emitted by human skin microbes help attract host-seeking mosquitoes [39,40,41]. Carbon dioxide is another important vertebrate- and plant-host cue for mosquitoes [29, 42], which originates not only from potential hosts but also from their symbiotic microbes [43]. Moreover, microbe-derived semiochemicals indicate suitable oviposition sites for many mosquito species and attract gravid females [44,45,46]. Microbe-derived semiochemicals and CO2 may also play a role in mosquito attraction to floral nectar.

Common tansies, Tanacetum vulgare, are visited by many insect taxa [37, 47], including mosquitoes [37, 48] that respond to floral semiochemicals [29] and serve as pollinators [37]. Therefore, T. vulgare is a good model plant to investigate the role of nectar-dwelling microbes in the attraction of mosquitoes to floral nectar. Working with T. vulgare, and one of its mosquito pollinators, the common house mosquito, Culex pipiens [37], we tested the hypotheses (H) that: (1) nectar-colonizing microbes emit semiochemicals attractive to Cx. pipiens; (2) the attractiveness of these microbes is dependent upon their nutrient source; and (3) multiple species of nectar-colonizing microbes attract more mosquitoes than a single species.

Results

Identification of nectar-colonizing microbes

We collected nectar from nectaries of T. vulgare florets with a sterile glass microcapillary tube and identified 19 microbial isolates (Table 1) by sequencing the 16S or 26S rDNA genes, and by comparing the results to data in the National Center for Biotechnology Information GenBank using BLASTn (Bethesda, USA; http://www.ncbu.nlm.nih.gov/BLAST.cgi). We performed additional biochemical and physiological tests on select isolates to aid in their identification (Table 2). Sampling a total of 40 florets from 20 inflorescences (2 florets per inflorescence) from 4 plants (5 inflorescences per plant), we found the yeast L. thermotolerans in nectar from two separate florets on two separate plants. Bacillus spp. were present in six florets from three separate plants, and Micrococcus spp. were present in four florets from three separate plants. In five floret samples, more than one microbe was present.

Table 1 (i) List of microbes identified from Tanacetum vulgare nectar including information about the plant, inflorescence, and individual florets from which they were collected, (ii) the medium used to culture microbes, and iii the methods used for microbe identification
Table 2 Biochemical tests for the identification of microbes collected from the inflorescences of common tansy, Tanacetum vulgare

H1: Nectar-colonizing microbes emit odorants attractive to Cx pipiens

In two-choice laboratory experiments with a paired-trap design, we tested attraction of female Cx. pipiens to a synthetic nectar broth (10% w/v sucrose, 2% w/v yeast extract) (control stimulus) and the same broth inoculated with (i) L. thermotolerans (Exp. 1), (ii) M. luteus (Exp. 2), or (iii) M. lactis (Exp. 3). We captured more female Cx. pipiens when L. thermotolerans was the inoculum (z = 4.03, p < 0.0001; Fig. 1, Exp. 1) but not when either M. luteus or M. lactis was the inoculum (M. luteus: z = 1.44, p = 0.15; M. lactis: z = − 1.02, p = 0.31; Fig. 1, Exps. 2, 3), indicating an ability of the mosquitoes to discern among different microbes or their metabolites.

Fig. 1
figure 1

Mean proportion of Culex pipiens females captured in paired traps baited with a synthetic nectar broth inoculated, or not (control; light grey bars), with Micrococcus lactis (Exp. 1), Micrococcus luteus (Exp. 2), or Lachancea thermotolerans (Exp. 3). Numbers in white boxes represent the mean percentage of non-responding mosquitoes, and numbers within parentheses the total number of mosquitoes captured. The asterisk (*) in Exp. 3 indicates a significant preference for the treatment stimulus (binary logistic regression with a logit link function, P < 0.05)

Dose of microbes tested

We grew L. thermotolerans, M. luteus and M. lactis in the synthetic nectar broth for 48 h and these reached final mean concentrations of 3.85 × 107 cells/mL (N = 2), 1.13 × 105 cells/mL (N = 2), and 2.85 × 106 cells/mL (N = 2), respectively.

H2: The attractiveness of microbes is dependent upon their growth medium

To determine whether the attractiveness of L. thermotolerans is affected by its nutrient source, single colonies of L. thermotolerans were spread-plated onto synthetic nectar agar, malt extract agar or YEPD agar plates. In two-choice laboratory experiments, we then tested attraction of Cx. pipiens to paired traps baited with either one of the three types of inoculated agar (each with 40–60% microbial growth coverage) or an uninoculated control agar. Lachancea thermotolerans growing on synthetic nectar agar (Exp. 4) or malt extract agar (Exp. 5) attracted more female Cx. pipiens than corresponding agar controls but not when growing on YEPD agar (Exp. 6) (Exp. 4: z = 2.29, p = 0.02; Exp. 5: z = 2.47, p = 0.013; Exp. 6: z = -0.61, p = 0.54; Fig. 2). Thus, attraction of Cx. pipiens females to L. thermotolerans is contingent upon the nutrients available to this yeast.

Fig. 2
figure 2

Mean proportion of Culex pipiens females captured in paired traps baited with one of three types of media inoculated, or not (control; light grey bars), with Lachancea thermotolerans. Numbers in white boxes represent the mean percentage of non-responding mosquitoes, and numbers within the parentheses the total number of mosquitoes captured. The asterisk (*) in Exp. 4 and Exp. 6 indicates a significant preference for the treatment stimulus (binary logistic regression with a logit link function, P < 0.05)

H3: Multiple species of nectar-colonizing microbes attract more mosquitoes than single microbe species

We hypothesized that odorants from different microbes may have additive or synergistic effects on attraction of Cx. pipiens females; therefore, we investigated whether M. lactis, M. luteus and L. thermotolerans presented together are more attractive than each microbe on its own. We inoculated synthetic nectar in separate petri dishes with single colonies of M. lactis, M. luteus or L. thermotolerans, and in laboratory experiments tested attraction of female Cx. pipiens to paired traps baited with each species alone or in ternary combination. Surprisingly, the ternary combination was as attractive as M. lactis alone (z = − 1.08, p = 0.28; Fig. 3, Exp. 7) and M. luteus alone (z = − 0.33, p = 0.74; Fig. 3, Exp. 8), and even less attractive than L. thermotolerans alone (z = 1.96, p = 0.05; Fig. 3, Exp. 9). Hence, the attractiveness of L. thermotolerans was actually reduced when it was presented alongside the two bacterial species.

Fig. 3
figure 3

Mean proportion of Culex pipiens females captured in paired traps baited with one or three vessels containing synthetic nectar broth, each inoculated with one of three microbes: Micrococcus lactis, M. luteus and Lachancea thermotolerans. Numbers in white boxes represent the mean percentage of non-responding mosquitoes, and numbers within parentheses the total number of mosquitoes captured. The asterisk (*) in Exp. 9 indicates a significant preference for the L. thermotolerans test stimulus (binary logistic regression with a logit link function, P < 0.05)

Identification of microbe-derived volatiles

We used dynamic headspace aerations to capture the odorants emitted from L. thermotolerans and identified them by gas chromatography-mass spectrometry (GC–MS). In response to the nutrients provided by the three types of media, L. thermotolerans produced different odor blends (Fig. 4). The yeast grown on all three media generated 2-phenylethanol, and dimethyl trisulfide was detected in two media types. All microbe-produced compounds differed from those originating from the media themselves (Table 3).

Fig. 4
figure 4

Headspace odorants from plates of YEPD agar (a), malt extract agar (b), and synthetic nectar agar plates (c) that were inoculated with Lachancea thermotolerans and that were not present in the headspace of uninoculated control plates. Compounds produced by L. thermotolerans were 3-methyl-butanol (1); 2-methyl-butanol (2); unknown (3); dimethyl trisulfide (4); 2-phenylethanol (5); 2-acetyl furan (6); indole (7); geranyl acetone (8); hexanoic acid (9) and benzyl alcohol (10). Note: different retention times of the same compounds in panels A-C are due to different temperature programs run during gas chromatographic analyses (see “Methods” for details)

Table 3 Headspace odorants of YEPD agar, malt extract agar and synthetic nectar agar, each inoculated with Lachancea thermotolerans. Compounds in bold font were found in two or more samples

CO2 production from synthetic nectar

Over the course of 150 h, L. thermotolerans growing in synthetic nectar broth sealed with a 98% sulfuric acid vapour lock produced 343 mg of CO2 (Fig. 5).

Fig. 5
figure 5

Weight loss over time of synthetic nectar broth (25 mL) inoculated with Lachancea thermotolerans due to fermentation and CO2 emission by L. thermotolerans

Discussion

Our data show that diverse microbes including the yeast Lachancea thermotolerans colonize floral nectar of tansy. Lachancea thermotolerans growing on synthetic nectar or malt extract media produce odorants that attract female Culex pipiens. Furthermore, we show that L. thermotolerans grown in a synthetic nectar broth produces CO2 and that L. thermotolerans alone is more attractive to female Cx. pipiens than when presented along with two bacteria also isolated from the same inflorescences. Below we elaborate on our conclusions.

Our culture-based approach to isolate nectar-colonizing microbes from common tansy likely under-represents the microbial diversity present in nectaries [49]; nevertheless, our collection of 19 isolates representing at least 12 species of microbes compares favourably with results of other studies examining microbial diversity in floral nectar using culture methods [6,7,8]. We isolated Staphylococcus epidermidis which may have been a contaminant because this microbe is typically associated with human skin. However, other microbes, such as Candida albicans [50] (not isolated in our study) which are thought to be obligate commensals of animals, have also been isolated from the environment [51]. Although culture-independent methods such as metagenomic analysis can be used to examine microbial diversity without the selection pressures of culturing, only by obtaining live cultures of the colonizing microbes could we study the odor profiles of these isolates and test their ability to attract Cx. pipiens.

Microbe-derived semiochemicals have been shown to guide foraging behavior of mosquitoes in a variety of contexts. Semiochemicals emitted from human skin microbiota, including S. epidermidis, Corynebacterium minutissimum and Brevibacterium epidermidis, attract mosquitoes to human hosts [39, 41, 52, 53]. Moreover, semiochemicals from Psychrobacter immobilis, Sphingobacterium multivorum, Bacillus spp., Pseudomonas spp., Klebsiella spp., and others help mosquitoes locate suitable oviposition sites [44, 46]. Finally, semiochemicals emitted from microbes colonizing aphid honeydew [38], or present in floral nectar [this study], attract sugar-foraging mosquitoes.

Microbes could also inform mosquitoes about the prospect of obtaining a sugar meal. The odor profiles of inflorescences differ not only between plant species [54] but also within the same species due, in part, to microbe-specific odorants [17]. These odorants may enable mosquitoes to discern inflorescences with sugar-rich and sugar-poor rewards, analogous to mosquitoes selecting human hosts based, in part, on their skin microbiota [40, 41]. Emission of microbe-semiochemicals from nectaries could inform mosquitoes about the presence of nectar-dwelling microbes which, in turn, would signal sugar or amino acid metabolism and thus the availability of sugar or amino acids. Alternatively, microbe odorants could indicate microbe presence stemming from a previous insect floral visit that may have temporarily depleted the sugar resource. Mosquitoes themselves are capable of microbe phoresis, as shown with floral nectar surrogates [55], as are many other insects visiting inflorescences or obtaining floral nectar [56, 57].

The informative value of microbe-derived odorants to foraging mosquitoes became evident when we grew L. thermotolerans in/on different nutrient sources. The nutrients available to L. thermotolerans not only affected the odorants it produced (Fig. 4) but also their attractiveness to foraging mosquitoes. This implies that the presence and composition of specific microbial odorants could inform mosquitoes about the availability of particular nutrients such as carbohydrates and amino acids. Lachancea thermotolerans grown in synthetic nectar broth produced appreciable amounts of CO2 which—while only weakly attractive on its own [42]—synergistically enhances the attractiveness of floral and host semiochemicals to both nectar- and host-foraging mosquitoes [38, 42].

Lachancea thermotolerans and its odor bouquet, respectively, also attract several species of North American yellowjackets (Hymenoptera: Vespidae) [58, 59] and the green lacewing, Chrysoperla comanche (Stephens) [60]. When grown and aerated on grape juice agar, L. thermotolerans produced 20 odorants which, when field-tested as a synthetic blend, attracted Western yellowjackets, Vespula pensylvanica [58]. Two of the odorants in this blend, 2-phentylethanol and 2-acetylfuran, were also found in this study. Lachancea thermotolerans is frequently isolated from fruit or fruit-related resources [61, 62] and is used in wine fermentations to generate ethanol and lactic acid [63].

Most studies investigating relationships between nectar-dwelling microbes and floral visitation by insects have focussed on hymenopterans (but see [64]), yet dipterans are also frequent visitors and important pollinators of flowers [65,66,67,68], and they interact with microbes [3, 69]. Our results suggest microbe-mediated, or at least modulated, inflorescence visitation by mosquitoes. This concept has been suggested for some hymenopteran pollinators including the European honey bee, Apis mellifera [13], and several species of bumble bees, Bombus spp. [17, 18], that preferentially visit inflorescences with nectar-dwelling yeasts, primarily Metschnikowia reukaufii. Conversely, both honey bees and bumble bees avoid inflorescences with certain nectar-dwelling bacteria [19, 20]. The combined information indicates that microbes can alter the floral scent [15], thereby prompting attraction or avoidance of specific floral visitors.

In follow-up studies, the sample size, while adequate, could be increased and the complete visitation history of plants could be tracked, thereby revealing the insect vectors of any microbe inoculum. Moreover, to determine the amount of inoculum and the resulting odor intensity needed to attract mosquitoes, a dose–response experiment could be run with one test stimulus reflecting the odor intensity of a representative tansy inflorescence. We tested 10 ml of synthetic nectar in our laboratory bioassays. This took into account that (i) each common tansy possesses multiple inflorescences, (ii) each inflorescence comprises dozens of composite flowers, and (iii) each composite flower contains up to 300 florets, each of which can produce up to ~ 1 µL of nectar (D. P. Pers. Obs.). Therefore, the volume of synthetic nectar we bioassayed approximates the volume of nectar produced by a common tansy or a group of common tansies. Similarly, the amount of synthetic nectar odorants we assayed resembled that of odorants produced by nectar-dwelling microbes and which would be encountered by foraging mosquitoes in field settings.

Conclusion

We demonstrate that floral nectar of common tansies contains various microbes, and we identified 19 to genus level or further. Of the three species tested in behavioral bioassays, only the yeast L. thermotolerans had a significant effect on the attraction of female Cx. pipiens, which was diminished, rather than improved, by admixture with two bacterial species. The attractiveness of L. thermotolerans to Cx. pipiens females was dependent upon its nutrient source and linked to a distinct odorant profile, although a causal relationship was not tested. We propose that specific components of the odor blend signal the availability of certain macro-nutrients such as sugar and amino acids which, in turn, inform foraging decisions by mosquitoes. It would now be interesting to determine the key odorant(s) in the microbe odorant blend that mediate(s) the attraction of mosquitoes.

Methods

Microbe collection

We collected 40 T. vulgare florets, from 20 inflorescences (2 florets per inflorescence), from 4 plants (5 inflorescences per plant) during September, 2017, in Delta, BC (Canada), wearing latex gloves (VWR International, Radnor, USA) and a surgical mask (Acklands Ltd., Wawa, Canada). All plants were collected within a 3-m2 patch of tansy beside a secondary road in a rural farming area. Immediately prior to sample collections, DP observed an adult female mosquito (likely Aedes dorsalis) visiting this tansy patch. We immediately placed inflorescences into sterile Ziploc bags (S.C. Johnson, Racine, USA) and stored them on ice for transport to the lab. Using ethanol and flame-sterilized scissors, we removed the tops of florets and inserted an autoclaved glass micro-capillary, prepared with a micropipette puller (Model P-1000, Sutter Instrument Co., Novato, USA), into the nectary to draw nectar via capillary action. Each draw yielded a maximum of ~ 1 µL of nectar. We repeated this twice on the same composite flower, using only one composite flower per inflorescence. We then inserted, and subsequently shattered, the micro-capillary into a sterile microcentrifuge tube (1.5 mL; ThermoFisher Scientific Inc., Waltham, USA) containing autoclaved distilled water (400 μL). We pipetted a 100-μL aliquot of this solution onto yeast extract peptone dextrose agar (YEPD) plates (20 g/L bacteriological peptone, 10 g/L yeast extract, 20 g/L glucose, 15 g/L agar) (Sigma Aldrich, St. Louis, USA) and Luria–Bertani agar (LB) plates (10 g/L tryptone, 5 g/L yeast extract, 5 g/L NaCl, 15 g/L agar) (Sigma Aldrich, St. Louis, USA), spread it with a sterile glass rod, and then incubated plates for 48–72 h at 30 °C. We subsequently re-streaked morphologically distinct colonies onto new plates to obtain pure colonies. Working cultures were maintained at 4 °C. Storage cultures of each isolate were prepared with 20% glycerol and stored at − 80 °C.

Microbe identification

Cells from a single colony were picked and grown in liquid YEPD or LB media for 24 h at 30 °C, and DNA was extracted according to Rose et al. 1990 [70]. DNA concentrations were estimated using a NanoDrop UV/Vis 2000 spectrophotometer (ThermoFisher Scientific Inc., Waltham, USA). To identify bacteria, we used Taq DNA polymerase (Applied Biological Materials, Richmond, Canada) to amplify the V3-V4 loop of the 16S rDNA gene with the Universal Forward Primer (UniF)—5′-CCTACGGGRBGCASCAG-3′ and the Universal Reverse Primer (UniR)—5′-GGACTACNNGGGTATCTAAT-3′ [71], and to amplify the 26S rDNA gene of yeast, we used the NL1 primer—5′-GCATATCAATAAGCGGAGGAAAAG-3′—and NL4 primer—5′-GGTCCGTGTTTCAAGACGG-3′ [72]. The identity of the colony found to be L. thermotolerans was confirmed using the specific primers INT2F (5′-TGGTTTTATTGAAGCCAAAGG-3′) and INT2R (5′-GGGGACCCGGAGATTAATAG-3′) [73]. PCR amplicons were pooled and concentrated using the NucleoSpin Gel and PCR Clean-up kit (Machery-Nagel, Duren, Germany). We sequenced amplicons (Genewiz, South Plainfield, USA) and used the Basic Local Alignment Search Tool (BLAST) [74] to compare the sequenced region of individual isolates with known sequences. A species or genus was determined to be a match if there was at least 95% coverage and 99% identity using BLAST with the sequenced isolate. In addition, we ran biochemical and physiological tests on select isolates (see Table 1) and Gram-tested bacterial colonies on select plates using KOH (Table 2). Biochemical tests were carried out according to established procedures [75, 76]. We determined the ability of isolates to grow at 7% NaCl and 10% NaCl in liquid media, and we tested isolate growth at various temperatures. For unknown Bacillus and Epidermidis isolates, catalase and oxidase enzyme production tests as well as sucrose, starch, L-alanine, glucose, mannitol, galactose, lactose, and fructose fermentation tests were run. For Micrococcus isolates, nitrate reduction, hydrolysis, and assimilation tests were run. We identified test isolates by comparing biochemical test results with data from the bioMérieux api® 50 CHB/E test kit (bioMérieux SA, Lyon, France) and reference papers [77,78,79,80,81].

Rearing of experimental mosquitoes

We reared Cx. pipiens at 23–26 °C, 40–60% RH, and a photoperiod of 14L:10D. We kept mixed groups of males and females in mesh cages (30 × 30 × 46 cm high) and provisioned them with a 10-% sucrose solution ad libitum. The primary author (DP) blood-fed females once per week. For oviposition, gravid females were given access to water in circular glass dishes (10 cm diameter × 5 cm high). We transferred eggs to water-filled trays (45 × 25 × 7 cm high) and sustained larvae with NutriFin Basix tropical fish food (Rolf C. Hagen Inc., Baie-D'Urfe, Canada). We transferred pupae via a 7-mL plastic pipette (VWR International, Radnor, USA) to water-containing 354-mL Solo cups covered with a mesh lid. Using an aspirator, we collected emergent adults and placed them in similar cups, along with a cotton ball soaked in a 10-% sucrose solution.

Behavioural bioassays

We ran all behavioral bioassays in mesh cages (77 × 78 × 104 cm) which were wrapped in black fabric except for the top, thereby allowing ambient fluorescent light illumination. During bioassays, we kept cages at 23–26 °C, 40–60% RH and a photoperiod of 14L:10D. For each 24-h bioassay, we released 50 virgin Cx. pipiens females, 1- to 3-day-old, 24-h sugar-deprived into a cage fitted with adhesive-coated (The Tanglefoot Comp., Grand Rapids, USA) paired delta traps (9 cm × 15 cm) on burette stands spaced 30 cm apart. For each bioassay which ran for about 24 h, treatment and control stimuli were randomly assigned to these traps. At the end of each bioassay the number of mosquitoes in each trap was counted.

Growth conditions for nectar-derived microorganisms

We grew microbes on YEPD agar plates, malt extract agar plates (3% w/v malt extract, 0.2% w/v peptone, 1.5% w/v agar), and synthetic nectar agar or nectar broth (10% w/v sucrose, 2% w/v yeast extract). All agar plates were 92-mm diam Petri dishes (Sarstedt Inc., Nümbrecht, Germany). The synthetic nectar broth was prepared in an autoclaved 2-L Erlenmeyer flask. After streaking single colonies onto plates or inoculating broth, we incubated cultures for approximately 48–72 h at 23–26 °C and 40–60% RH. We used plates with microbial growth covering 40–60% of the surface area for behavioural bioassays.

Attractiveness of microbes in synthetic nectar

In two-choice laboratory experiments with a paired-trap design, we tested attraction of female Cx. pipiens to microbe-derived odorants. We pipetted 10 mL of the treatment stimulus [synthetic nectar broth inoculated with L. thermotolerans, M. lactis or M. luteus and incubated as described above] into a sterile 92-mm diam Petri dish which we placed into a randomly assigned delta trap. The paired control stimulus consisted of a sterile synthetic nectar broth (10 mL) presented the same way. We bioassayed the response of female Cx. pipiens as described above in “behavioural bioassays”.

Attractiveness of L. thermotolerans growing on different media

In two-choice laboratory experiments with a paired-trap design, we tested attraction of female Cx. pipiens to L. thermotolerans with 40–60% surface area coverage cultured on YEPD agar, malt extract agar, or synthetic nectar agar prepared as described above. In each bioassay, the corresponding uninoculated agar media served as the paired control stimulus.

Comparative attractiveness of single- vs multiple-species of microbes

In two-choice laboratory experiments with paired traps, we compared attraction of female Cx. pipiens to L. thermotolerans, M. lactis, and M. luteus presented singly or in ternary combination in the same trap. We cultured each microbe separately in synthetic nectar broth as described above, and pipetted 3.3 mL of each broth into a separate sterile 35-mm Petri dish (Sarstedt Inc., Nümbrecht, Germany). As a result, paired traps were baited with either one or three Petri dishes in each bioassay, the design of which is as described in the “Behavioural bioassay” section.

Dose of microbes tested

We determined the concentration of microbes used in experiments by performing serial dilutions of microbe-inoculated synthetic nectar broth after incubation at 25 °C for 48 h. Cell density was determined using a hemacytometer.

Measurement of CO2 production by L. thermotolerans

We inoculated sterile synthetic nectar broth (25 mL) with a single colony-forming unit of L. thermotolerans previously grown on YEPD agar, and then incubated the broth at 30 °C for 5 days. We added an aliquot (10 μL) of this broth to 100 mL of sterile synthetic nectar broth in a 250-mL Erlenmeyer flask, attached a vapour lock (5 mL of 98% sulfuric acid) to maintain vapour pressure and prevent water loss, and obtained the starting weight. We incubated the entire assembly in a water bath kept at 30 °C in the fume hood and monitored weight loss as a proxy for CO2 emission [82].

Dynamic headspace odorant collections

We placed 12 plates with L. thermotolerans grown for 48–72 h at 23–26 °C on YEPD, malt agar, or SN media into a Pyrex® glass chamber (34 cm high × 12.5 cm wide). A mechanical pump drew charcoal-filtered air at a flow of 1 L min−1 for 24–72 h through the chamber and through a glass column (6 mm outer diameter × 150 mm) containing 200 mg of Porapak-Q™ adsorbent. We desorbed odorants captured on Porapak with 0.5 mL each of pentane and ether. We analyzed 2-µl aliquots of Porapak-Q™ extract by gas chromatography-mass spectrometry (GC–MS), operating a Saturn 2000 Ion Trap GC–MS fitted with a DB-5 GC–MS column (30 m × 0.25 mm i.d.; Agilent Technologies Inc., Santa Clara, USA) in full-scan electron impact mode. To chromatograph the odorants of L. thermotolerans on malt extract agar and on synthetic nectar agar, we used a flow of helium (35 cm s−1) as the carrier gas with the following temperature program: 50 °C (5 min), 10 °C min−1 to 280 °C (held for 10 min). The temperature of the injector port was 250 °C and the ion trap was set to 200 °C. To analyze the odorants of L. thermotolerans on YEPD agar, and to reveal very volatile compounds that may have eluded detection using the above temperature program, we retained the same helium flow (35 cm s−1) but lowered the initial temperature, running the following temperature program: 40 °C (5 min), 10 °C min−1 to 280 °C (held for 10 min). Aliquots of headspace odorant extracts were injected in split mode with a 1:1 split ratio, and the temperature of the injector port and the ion trap were set to 250 °C and 200 °C, respectively. We identified odorants in headspace odorant extracts by comparing their retention indices (RI; relative to n-alkane standards) [83] and their mass spectra with those reported in the literature and with those of authentic standards.

Statistical analyses

We used SAS software version 9.4 (SAS Institute Inc., Cary, USA) to analyze data, excluding from analyses all experimental replicates with no mosquitoes captured in traps. We used a binary logistic regression model with a logit link function to compare mean proportions of responders between test stimuli, and used back-transformed data to attain means and confidence intervals.

Availability of data and materials

The datasets generated and or analysed during the current study are available in the Dryad repository [https://0-doi-org.brum.beds.ac.uk/10.5061/dryad.j6q573ncw], and the genetic sequences are available from the National Center for Biotechnology Information GenBank [https://0-www-ncbi-nlm-nih-gov.brum.beds.ac.uk/genbank] (see Table 1 for accession numbers).

Change history

Abbreviations

GC–MS:

Gas chromatography–mass spectrometry

LB:

Luria–Bertani medium

PCR:

Polymerase chain reaction

RH:

Relative humidity

RI:

Retention index

YEPD:

Yeast extract peptone dextrose medium

References

  1. Douglas AE. Multiorganismal insects: diversity and function of resident microorganisms. Annu Rev Entomol. 2015;60:17–34.

    CAS  PubMed  Google Scholar 

  2. Davis TS, Crippen TL, Hofstetter RW, Tomberlin JK. Microbial volatile emissions as insect semiochemicals. J Chem Ecol. 2013;39:840–59.

    CAS  PubMed  Google Scholar 

  3. Uriel Y, Gries R, Tu L, Carroll C, Zhai H, Moore M, et al. The fly factor phenomenon is mediated by inter-kingdom signalling between bacterial symbionts and their blow fly hosts. Insect Sci. 2020;27:256–65.

    CAS  PubMed  Google Scholar 

  4. Knudsen JT, Eriksson R, Gershenzon J, Ståhl B. Diversity and distribution of floral scent. Bot Rev. 2006;72:1–120.

    Google Scholar 

  5. Herrera CM, Pozo MI. Nectar yeasts warm the flowers of a winter-blooming plant. Proc R Soc B Biol Sci. 2010;277:1827–34.

    Google Scholar 

  6. Pozo MI, Herrera CM, Bazaga P. Species richness of yeast communities in floral nectar of southern Spanish plants. Microb Ecol. 2011;61:82–91.

    PubMed  Google Scholar 

  7. Fridman S, Izhaki I, Gerchman Y, Halpern M. Bacterial communities in floral nectar. Environ Microbiol Rep. 2012;4:97–104.

    PubMed  Google Scholar 

  8. Álvarez-Pérez S, Herrera CM, de Vega C. Zooming-in on floral nectar: a first exploration of nectar-associated bacteria in wild plant communities. FEMS Microbiol Ecol. 2012;80:591–602.

    PubMed  Google Scholar 

  9. Herrera CM, de Vega C, Canto A, Pozo MI. Yeasts in floral nectar: a quantitative survey. Ann Bot. 2009;103:1415–23.

    PubMed Central  PubMed  Google Scholar 

  10. Canto A, Herrera CM. Micro-organisms behind the pollination scenes: microbial imprint on floral nectar sugar variation in a tropical plant community. Ann Bot. 2012;110:1173–83.

    CAS  PubMed Central  PubMed  Google Scholar 

  11. Herrera CM, García IM, Pérez R. Invisible floral larcenies: Microbial communities degrade floral nectar of bumble bee-pollinated plants. Ecology. 2008;89:2369–76.

    PubMed  Google Scholar 

  12. Canto A, Herrera CM, Medrano M, Pérez R, Garcia IM. Pollinator foraging modifies nectar sugar composition in Hellebrous foetidus (Ranunculaceae): an experimental test. Am J Bot. 2008;95:315–20.

    PubMed  Google Scholar 

  13. Rering CC, Beck JJ, Hall GW, McCartney MM, Vannette RL. Nectar-inhabiting microorganisms influence nectar volatile composition and attractiveness to a generalist pollinator. New Phytol. 2018;220:750–9.

    CAS  PubMed  Google Scholar 

  14. Schaeffer RN, Irwin RE. Yeasts in nectar enhance male fitness in a montane perennial herb. Ecology. 2014;95:1792–8.

    PubMed  Google Scholar 

  15. Golonka AM, Johnson BO, Freeman J, Hinson DW. Impact of nectarivorous yeasts on Silene caroliniana’s scent. East Biol. 2014;3:1–26.

    Google Scholar 

  16. Bruce TJA, Wadhams LJ, Woodcock CM. Insect host location: a volatile situation. Trends Plant Sci. 2005;10:269–74.

    CAS  PubMed  Google Scholar 

  17. Yang M, Deng G-C, Gong Y-B, Huang S-Q. Nectar yeasts enhance the interaction between Clematis akebioides and its bumblebee pollinator. Plant Biol. 2019;21:732–7.

    CAS  PubMed  Google Scholar 

  18. Herrera CM, Pozo MI, Medrano M. Yeasts in nectar of an early-blooming herb: Sought by bumble bees, detrimental to plant fecundity. Ecology. 2013;94:273–9.

    PubMed  Google Scholar 

  19. Good AP, Gauthier MPL, Vannette RL, Fukami T. Honey bees avoid nectar colonized by three bacterial species, but not by a yeast species, isolated from the bee gut. PLoS ONE. 2014;9:e86494.

    PubMed Central  PubMed  Google Scholar 

  20. Junker RR, Romeike T, Keller A, Langen D. Density-dependent negative responses by bumblebees to bacteria isolated from flowers. Apidologie. 2014;45:467–77.

    CAS  Google Scholar 

  21. Raza W, Wang J, Jousset A, Friman V-P, Mei X, Wang S, et al. Bacterial community richness shifts the balance between volatile organic compound-mediated microbe–pathogen and microbe–plant interactions. Proc R Soc B Biol Sci. 2020;287:20200403.

    CAS  Google Scholar 

  22. Foster WA. Mosquito sugar feeding and reproductive energetics. Annu Rev Entomol. 1995;40:443–74.

    CAS  PubMed  Google Scholar 

  23. Clements A. The sources of energy for flight in mosquitoes. Exp Biol. 1955;32:547–54.

    CAS  Google Scholar 

  24. Manda H, Gouagna LC, Foster WA, Jackson RR, Beier JC, Githure JI, et al. Effect of discriminative plant-sugar feeding on the survival and fecundity of Anopheles gambiae. Malar J. 2007;6:1–11.

    Google Scholar 

  25. Nayar JK, Sauerman DM. Physiological effects of carbohydrates on survival, metabolism, and flight potential of female Aedes taeniorhynchus. J Insect Physiol. 1971;17:2221–33.

    CAS  PubMed  Google Scholar 

  26. Clements A. The biology of mosquitoes, volume 2: sensory reception and behaviour. Wallingford: CABI Publishing; 1999.

    Google Scholar 

  27. Peach DAH, Gries G. Mosquito phytophagy—sources exploited, ecological function, and evolutionary transition to haematophagy. Entomol Exp Appl. 2020;168:120–36.

    Google Scholar 

  28. Peach DAH, Ko E, Blake AJ, Gries G. Ultraviolet inflorescence cues enhance attractiveness of inflorescence odour to Culex pipiens mosquitoes. PLoS ONE. 2019;14:e0217484.

    CAS  PubMed Central  PubMed  Google Scholar 

  29. Peach DAH, Gries R, Zhai H, Young N, Gries G. Multimodal floral cues guide mosquitoes to tansy inflorescences. Sci Rep. 2019;9:3908.

    PubMed Central  PubMed  Google Scholar 

  30. Foster WA. Phytochemicals as population sampling lures. J Am Mosq Control Assoc. 2008;24:138–46.

    CAS  PubMed  Google Scholar 

  31. Nyasembe V, Torto B. Volatile phytochemicals as mosquito semiochemicals. Phytochem Lett. 2014;8:196–201.

    CAS  PubMed Central  PubMed  Google Scholar 

  32. Müller GC, Xue R, Schlein Y. Differential attraction of Aedes albopictus in the field to flowers, fruits and honeydew. Acta Trop. 2011;118:45–9.

    PubMed  Google Scholar 

  33. Yu B, Huang S, Ding Y, Fouad H, Li H, Mo JC. Laboratory evaluation of differential attraction of Culex pipiens pallens to the volatiles of flowers, fruits, and seed pods. J Asia-Pac Entomol. 2017;20:1372–6.

    Google Scholar 

  34. Stoutamire W. Mosquito pollination of Habenaria obtusata. Mich Bot. 1968;7:203–12.

    Google Scholar 

  35. Thien L. Mosquito pollination of Habenaria obtusata (Orchidaceae). Am J Bot. 1969;56:232–7.

    Google Scholar 

  36. Brantjes NBM, Leemans JAAM. Silene otites (Caryophyllaceae) pollinated by nocturnal lepidoptera and mosquitoes. Acta Bot Neerlandica. 1976;25:281–95.

    Google Scholar 

  37. Peach DAH, Gries G. Nectar thieves or invited pollinators? A case study of tansy flowers and common house mosquitoes. Arthropod-Plant Interact. 2016;10:497–506.

    Google Scholar 

  38. Peach DAH, Gries R, Young N, Lakes R, Galloway E, Alamsetti SK, et al. Attraction of female Aedes aegypti (L.) to aphid honeydew. Insects. 2019;10:43.

    PubMed Central  Google Scholar 

  39. Verhulst NO, Beijleveld H, Knols BG, Takken W, Schraa G, Bouwmeester HJ, et al. Cultured skin microbiota attracts malaria mosquitoes. Malar J. 2009;8:1–12.

    Google Scholar 

  40. Verhulst NO, Qiu YT, Beijleveld H, Maliepaard C, Knights D, Schulz S, et al. Composition of human skin microbiota affects attractiveness to malaria mosquitoes. PLoS ONE. 2011;6:e28991.

    CAS  PubMed Central  PubMed  Google Scholar 

  41. Busula AO, Takken W, de Boer JG, Mukabana WR, Verhulst NO. Variation in host preferences of malaria mosquitoes is mediated by skin bacterial volatiles. Med Vet Entomol. 2017;31:320–6.

    CAS  PubMed  Google Scholar 

  42. Gillies M. The role of carbon dioxide in host-finding by mosquitoes. Bull Entomol Res. 1980;70:525–32.

    Google Scholar 

  43. Schreck CE, James J. Broth cultures of bacteria that attract female mosquitoes. Mosq News. 1968;28:33–8.

    Google Scholar 

  44. Trexler JD, Apperson CS, Zurek L, Gemeno C, Schal C, Kaufman M, et al. Role of bacteria in mediating the oviposition responses of Aedes albopictus (Diptera: Culicidae). J Med Entomol. 2003;40:841–8.

    PubMed  Google Scholar 

  45. Lindh JM, Borg-karlson A, Faye I. Transstadial and horizontal transfer of bacteria within a colony of Anopheles gambiae (Diptera: Culicidae) and oviposition response to bacteria-containing water. Acta Trop. 2008;107:242–50.

    CAS  PubMed  Google Scholar 

  46. Ponnusamy L, Xu N, Nojima S, Wesson DM, Schal C, Apperson CS. Identification of bacteria and bacteria-associated chemical cues that mediate oviposition site preferences by Aedes aegypti. PNAS. 2008;105:9262–7.

    CAS  PubMed Central  PubMed  Google Scholar 

  47. Müller H. Die Befruchtung der Blumen durch Insekten. Leipzig: Wilhelm Engelmann; 1873.

    Google Scholar 

  48. Andersson IH, Jaenson TG. Nectar feeding by mosquitoes in Sweden, with special reference to Culex pipiens and Cx torrentium. Med Vet Entomol. 1987;1:59–64.

    CAS  PubMed  Google Scholar 

  49. Staley JT, Konopka A. Measurement of in situ activities of nonphotosynthetic microorganisms in aquatic and terrestrial habitats. Annu Rev Microbiol. 1985;39:321–46.

    CAS  PubMed  Google Scholar 

  50. Barnett JA. A history of research on yeasts 12: medical yeasts part 1 Candida albicans. Yeast. 2008;25:385–417.

    CAS  PubMed  Google Scholar 

  51. Bensasson D, Dicks J, Ludwig JM, Bond CJ, Elliston A, Roberts IN, et al. Diverse lineages of Candida albicans live on old oaks. Genetics. 2019;211:277–88.

    CAS  PubMed  Google Scholar 

  52. Braks MAH, Takken W. Incubated human sweat but not fresh sweat attracts the malaria mosquito Anopheles gambiae sensu stricto. J Chem Ecol. 1999;25:663–72.

    CAS  Google Scholar 

  53. Takken W, Verhulst NO. Chemical signaling in mosquito–host interactions: the role of human skin microbiota. Curr Opin Insect Sci. 2017;20:68–74.

    PubMed  Google Scholar 

  54. Galen C, Kaczorowski R, Todd SL, Geib J, Raguso RA. Dosage-dependent impacts of a floral volatile compound on pollinators, larcenists, and the potential for floral evolution in the Alpine Skypilot Polemonium viscosum. Am Nat. 2011;177:258–72.

    PubMed  Google Scholar 

  55. Kenney A, Cusick A, Payne J, Gaughenbaugh A, Renshaw A, Wright J, et al. The potential for flower nectar to allow mosquito to mosquito transmission of Francisella tularensis. PLoS ONE. 2017;12:1–12.

    Google Scholar 

  56. Belisle M, Peay KG, Fukami T. Flowers as islands: spatial distribution of nectar-inhabiting microfungi among plants of Mimulus aurantiacus, a hummingbird-pollinated shrub. Microb Ecol. 2012;63:711–8.

    PubMed  Google Scholar 

  57. Ushio M, Yamasaki E, Takasu H, Nagano AJ, Fujinaga S, Honjo MN, et al. Microbial communities on flower surfaces act as signatures of pollinator visitation. Sci Rep. 2015;5:1–7.

    Google Scholar 

  58. Babcock T, Borden JH, Gries R, Carroll C, Lafontaine JP, Moore M, et al. Inter-kingdom signalling—symbiotic yeasts produce semiochemicals that attract their yellowjacket hosts. Entomol Exp Appl. 2019;167:220–30.

    CAS  Google Scholar 

  59. Babcock T, Borden J, Gries R, Carroll C, Moore M, Gries G. Lachancea thermotolerans, a yeast symbiont of yellowjackets, enhances attraction of three yellowjacket species (Hymenoptera: Vespidae) to fruit powder. Environ Entomol. 2018. https://0-doi-org.brum.beds.ac.uk/10.1093/ee/nvy139.

    Article  PubMed  Google Scholar 

  60. Vitanović E, Aldrich JR, Winterton SL, Boundy-Mills K, Lopez JM, Zalom FG. Attraction of the green lacewing Chrysoperla comanche (Neuroptera: Chrysopidae) to yeast. J Chem Ecol. 2019;45:388–91.

    PubMed  Google Scholar 

  61. Hranilovic A, Bely M, Masneuf-Pomarede I, Jiranek V, Albertin W. The evolution of Lachancea thermotolerans is driven by geographical determination, anthropisation and flux between different ecosystems. PLoS ONE. 2017;12:e0184652.

    PubMed Central  PubMed  Google Scholar 

  62. Santo DE, Galego L, Gonçalves T, Quintas C. Yeast diversity in the Mediterranean strawberry tree (Arbutus unedo L.) fruits’ fermentations. Food Res Int. 2012;47:45–50.

    CAS  Google Scholar 

  63. Hranilovic A, Gambetta JM, Schmidtke L, Boss PK, Grbin PR, Masneuf-Pomarede I, et al. Oenological traits of Lachancea thermotolerans show signs of domestication and allopatric differentiation. Sci Rep. 2018;8:14812.

    PubMed Central  PubMed  Google Scholar 

  64. Vannette RL, Gauthier M-PL, Fukami T. Nectar bacteria, but not yeast, weaken a plant-pollinator mutualism. Proc R Soc B Biol Sci. 2012;280:20122601.

    Google Scholar 

  65. Orford KA, Vaughan IP, Memmott J. The forgotten flies: the importance of non-syrphid Diptera as pollinators. Proc R Soc B Biol Sci. 2015;282:20142934–20142934.

    Google Scholar 

  66. Rader R, Bartomeus I, Garibaldi LA, Garratt MPD, Howlett BG, Winfree R, et al. Non-bee insects are important contributors to global crop pollination. Proc Natl Acad Sci. 2016;113:146–51.

    CAS  PubMed  Google Scholar 

  67. Klecka J, Hadrava J, Biella P, Akter A. Flower visitation by hoverflies (Diptera: Syrphidae) in a temperate plant-pollinator network. PeerJ. 2018;6:e6025.

    PubMed Central  PubMed  Google Scholar 

  68. Ssymank A, Kearns CA, Pape T, Thompson FC. Pollinating flies (Diptera): a major contribution to plant diversity and agricultural production. Biodiversity. 2008;9:86–9.

    Google Scholar 

  69. Davis TS, Landolt PJ. A survey of insect assemblages responding to volatiles from a ubiquitous fungus in an agricultural landscape. J Chem Ecol. 2013;39:860–8.

    CAS  PubMed  Google Scholar 

  70. Rose MD, Winston F, Hieter P. Methods in yeast genetics. New York: Cold Spring Harbor Laboratory Press; 1990.

    Google Scholar 

  71. Takai K, Horikoshi K. Rapid detection and quantification of members of the Archaeal community by quantitative PCR using fluorogenic probes. Appl Environ Microbiol. 2000;66:5066–72.

    CAS  PubMed Central  PubMed  Google Scholar 

  72. Kurtzman CP, Robnett CJ. Identification of clinically important ascomycetous yeasts based on nucleotide divergence in the 5J end of the large-subunit (26S) ribosomal DNA gene. J Clin Microbiol. 1997;35:1216–23.

    CAS  PubMed Central  PubMed  Google Scholar 

  73. Zara G, Ciani M, Domizio P, Zara S, Budroni M, Carboni A, et al. A culture-independent PCR-based method for the detection of Lachancea thermotolerans in wine. Ann Microbiol. 2014;64:403–6.

    CAS  Google Scholar 

  74. Altschul S, Gish W, Myers E, Lipman D. Basic local alignment search tool. J Mol Biol. 1990;215:403–10.

    CAS  PubMed  Google Scholar 

  75. Claus D, Berkeley RCW. Genus Bacillus. In: Sneath PHA, Mair NS, Sharpe ME, Holt JG, editors. Manual of systematics bacteriology. Baltimore: Williams and Wilkins; 1986. p. 1104–39.

    Google Scholar 

  76. Priest FG. Systematics and Ecology of Bacillus. In: Sonenshein A, Hoch J, Losick R (eds) Bacillus subtilis and other gram-positive bacteria. American Society of Microbiology; 1993. p. 3–16. doi:https://0-doi-org.brum.beds.ac.uk/10.1128/9781555818388.ch1.

  77. Senses-Ergul S, Ágoston R, Belák Á, Deák T. Characterization of some yeasts isolated from foods by traditional and molecular tests. Int J Food Microbiol. 2006;108:120–4.

    CAS  PubMed  Google Scholar 

  78. Aruwa C, Olatope S. Characterization of Bacillus species from convenience foods with conventional and API kit method: a comparative analysis. J Appl Life Sci Int. 2015;3:42–8.

    Google Scholar 

  79. Welker NE, Campbell LL. Unrelatedness of Bacillus amyloliquefaciens and Bacillus subtilis. J Bacteriol. 1967;94:7.

    Google Scholar 

  80. Venkateswaran K. Bacillus nealsonii sp. nov., isolated from a spacecraft-assembly facility, whose spores are gamma-radiation resistant. Int J Syst Evol Microbiol. 2003;53:165–72.

    CAS  PubMed  Google Scholar 

  81. Chittpurna, Singh PK, Verma D, Pinnaka AK, Mayilraj S, Korpole S. Micrococcus lactis sp. nov., isolated from dairy industry waste. Int J Syst Evol Microbiol. 2011;61:2832–6.

  82. Vaughan-Martini A, Martini A. Determination of ethanol production. In: The yeasts. Fourth. Elsevier, Amsterdam; 1998. p. 107. doi:https://0-doi-org.brum.beds.ac.uk/10.1016/B978-044481312-1/50017-4.

  83. Adams R. Identification of essential oils by ion trap mass spectroscopy. San Diego: Academic Press; 1989.

    Google Scholar 

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Acknowledgements

We thank Martin Duckhorn for his volunteer assistance in the project.

Funding

The research was supported by scholarships to DP (Natural Sciences and Engineering Research Council of Canada [NSERC; https://www.canada.ca/en/science-engineering-research.html] PGSD; SFU Provost’s Prize of Distinction [https://www.sfu.ca/dean-gradstudies/awards/entrance-scholarships/provost-awards/ppd.html]; John H Borden Scholarship [http://esc-sec.ca/student/student-awards/#toggle-id-5]), scholarships to NY and EG (NSERC—Undergraduate Student Research Award), and by an NSERC—Industrial Research Chair to GG, with Scotts Canada Ltd. as the industrial sponsor. These funding bodies had no role in the design of the study, the collection, analysis, and interpretation of data, nor writing of this manuscript.

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DP, GG, MM, and CL designed the study. DP collected the microbe samples. DP, CC, HC, NY, SG, SM, AB, and EG identified the microbes. RG identified the microbial odorants. DP, EG, SM, and YU ran the bioassays. DP, EG, and YU analyzed data statistically. DP and GG wrote the manuscript. All authors read and approved the final manuscript.

Corresponding author

Correspondence to D. A. H. Peach.

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The authors declare that their industrial sponsor, Scotts Canada Ltd., had no role in the study design, data collection, analysis, and interpretation, drafting the paper, or the decision to submit the manuscript for publication. The authors also declare that their relationship with Scotts Canada Ltd. does not alter their adherence to BMC policies on data and material sharing. The authors further declare that they have no financial or non-financial competing interests.

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Peach, D.A.H., Carroll, C., Meraj, S. et al. Nectar-dwelling microbes of common tansy are attractive to its mosquito pollinator, Culex pipiens L.. BMC Ecol Evo 21, 29 (2021). https://0-doi-org.brum.beds.ac.uk/10.1186/s12862-021-01761-5

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