Distant populations of a <i>Xanthosoma</i> (Araceae) species have different floral scents but the same cyclocephaline beetle pollinators

Gottsberger, Gerhard; Silberbauer-Gottsberger, Ilse; Dötterl, Stefan

doi:10.1590/0102-33062020abb0013

ABSTRACT

We report on the reproductive biology, pollinators, and thermogenesis of the widely distributed Araceae species, Xanthosoma striatipes. We analyzed the floral scent in one population and compared it to a previous study. Xanthosoma striatipes was studied at three sites in Brazil, São Paulo, Minas Gerais and Maranhão. The results showed constancy of the reproductive biology and main pollinator species across sites. The pollinators at all three sites sites were two species of cyclocephaline scarabs, Cyclocephala atricapilla and C. ohausiana. The scent composition of the strongly scented inflorescences of plants of a site in São Paulo differed from plants recently studied in Central Brazil. Of the 39 and 23 compounds detected, in the present and the previous study, respectively, only seven compounds, were in common. We discuss that the two main constituents identified in samples at both sites, the aromatic compound methyl salicylate and the terpenoid (E)-4,8-dimethyl-1,3,7-nonatriene, alone seem to be sufficient for the attraction of the beetles. However, it is also possible that different compounds are involved in attracting the same beetle species to plants of the different populations.

Keywords:
beetle behavior; cyclocephaline scarabs; floral scent; GCMS-analyses; thermogenesis

Introduction

The actual numbers of Araceae comprise 125 genera and 3525 species (Boyce &Croat 2016Boyce PC, Croat TB. 2016. The Überlist of Araceae. Totals of published and estimated number of species in Aroid genera. http://www.aroid.org/genera/160330uberlist.pdf.
http://www.aroid.org/genera/160330uberli... ). The Neotropical genus Xanthosoma Schott is part of the tribe Caladieae Schott (Mayo et al. 1997Mayo SJ, Bogner J, Boyce PC. 1997. The genera of Araceae. London, UK, Royal Botanic Gardens Kew. ), and its 140 described species (Boyce & Croat 2016Boyce PC, Croat TB. 2016. The Überlist of Araceae. Totals of published and estimated number of species in Aroid genera. http://www.aroid.org/genera/160330uberlist.pdf.
http://www.aroid.org/genera/160330uberli... ) are distributed from Mexico and the West Indies to northern Argentina.

The spadix of the inflorescence of Xanthosoma carries unisexual flowers distributed in zones, with basal pistillate and distal staminate flowers, separated by several rows of sterile staminate flowers. The whole spadix is covered by a large leafy bract, the spathe, which is constricted at the middle, forming an inflated chamber called tube or kettle, and a more expanded and boat-shaped apical portion called lamina. Pistillate and sterile staminate flowers are distributed within the tube. Among several genera of the Caladieae, including Xanthosoma, either nitidulids (Nitidulidae) or cyclocephaline scarab (Melolonthidae, Cyclocephalini) beetles act as key pollinators (Maia & Schlindwein 2006Maia ACD, Schlindwein C. 2006. Caladium bicolor (Araceae) and Cyclocephala celata (Coleoptera Dynastinae): a well-established pollination system in the northern Atlantic rainforest of Pernambuco, Brazil. Plant Biology 8: 529-534.; Chartier et al. 2014Chartier M, Gibernau M, Renner SS. 2014. The evolution of pollinator-plant interaction types in the Araceae. Evolution 68: 1533-1543.; Gibernau 2016Gibernau M. 2016. Pollinators and visitors of aroid inflorescences III - Phylogenetic & Chemical insights. Aroideana 39: 4-22.; Milet-Pinheiro et al. 2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ).

In spite of the existence of several studies on pollination and scent emission in tropical Araceae (Maia & Schlindwein 2006Maia ACD, Schlindwein C. 2006. Caladium bicolor (Araceae) and Cyclocephala celata (Coleoptera Dynastinae): a well-established pollination system in the northern Atlantic rainforest of Pernambuco, Brazil. Plant Biology 8: 529-534.; Maia et al. 2012Maia ACD, Dötterl S, Kaiser R, et al. 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.; Dötterl et al. 2012Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.; Maia et al. 2013aMaia ACD, Gibernau M, Carvalho AT, Gonçalves EG, Schlindwein C. 2013a. The cowl does not make the monk: scarab beetle pollination of the Neotropical aroid Taccarum ulei (Araceae, Spathicarpeae). Biological Journal of the Linnean Society 108: 22-34.; bMaia ACD, Gibernau M, Dötterl S, et al. 2013b. The floral scent of Taccarum ulei (Araceae): attraction of scarab beetle pollinators to an unusual aliphatic acyloin. Phytochemistry 93: 71-78.; Gottsberger et al. 2013Gottsberger G, Silberbauer-Gottsberger I, Dötterl S. 2013. Pollination and floral scent differentiation in species of the Philodendron bipinnatifidum complex (Araceae). Plant Systematics and Evolution 299: 793-809.; Pereira et al. 2014Pereira J, Schlindwein C, Antonini Y, et al. 2014. Philodendron adamantinum (Araceae) lures its single cyclocephaline scarab pollinator with specific dominant floral scent volatiles. Biological Journal of the Linnean Society 111: 679-691. ; Gibernau 2016Gibernau M. 2016. Pollinators and visitors of aroid inflorescences III - Phylogenetic & Chemical insights. Aroideana 39: 4-22.; Milet-Pinheiro et al. 2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ), we know little about the constancy of pollinating beetle species in different regions and whether floral scent emissions are similar among distant populations or not. To this end, the present paper presents data on pollinators and floral biology of the widely distributed species Xanthosoma striatipes from sites in the Brazilian states of São Paulo, Minas Gerais, and Maranhão. The distance between the southernmost study site in São Paulo and the northernmost in Maranhão is approximately 2,050 km. We also analyzed the floral scents of a population in São Paulo and compared it to a previous study performed in Central Brazil, in the Distrito Federal, about 750 km north, far away from the São Paulo site. Thus, the widely distributed South American species X. striatipes, with apparent native occurrences in Bolivia, North Brazil, Southeast Brazil, West-Central Brazil, Colombia, French Guiana, Guyana, Paraguay and Venezuela (Brummit 2001Brummit RK. 2001. World Geographic Scheme for Recording Plant Distributions. 2nd. edn. Pittsburgh, Hunt Institute for Botanical Documentation, Carnegie Mellon University.) is a suitable study species.

Materials and methods

We studied Xanthosoma striatipes (Kunth & C.D. Bouché) Madison at different sites (Fig. 1). The first site was in the surroundings of the city of Botucatu in the state of São Paulo (city coordinates 22°53’9” S, 48°26’42” W, alt. 756-920 m, approximately 230 km northwest of the city of São Paulo). In the years 1978, 1980, 1981 and 2007, we always observed six individuals in a population of about 25 individuals. The plants were growing in a marshy field between a gallery forest (called Mata de Pinheirinho, because of the presence of the gymnosperm Podocarpus sellowii) and a Campo Cerrado. The scent samples presented in this publication are from this site.

Figure 1
Location of the study sites of Xanthosoma striatipes in Brazil in the States São Paulo (Botucatu), Minas Gerais (Indianópolis) and Maranhão (Codó) used in the present study as well as in the Distrito Federal (Guará) and Tocantins (Arraias) used in the study by Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ). The distance between the southernmost site, Botucatu, and the northernmost site, Codó, is approximately 2,050 km. The dotted lines on the map indicate major rivers.

The second site was a private property called “Fazenda Bela Tanda” (coordinates 19°3’ S, 47°57” W) in the municipality of Indianópolis, approximately 40 km southeast of the city of Uberlândia, and approximately 370 km south of the federal capital Brasília, in the state of Minas Gerais (Fig. 1). The population there consisted of about 30 individuals, which grew in marshy places along a river. We also observed six individuals, from December 4 to 13, 1986.

Our third study site was in the state of Maranhão, Northeastern Brazil, in the surroundings of Codó, approximately 220 km southeast of São Luís, the capital city of this state, also in a private property, “Fazenda Canto da Roça” (4°30’ S, 43°54’ W) (Fig. 1). The population was growing in a swamp extended in an area of approximately 10 x 30 m (Fig. 2). On February 20-21, 1982, we registered 147 fertile individuals in various stages, from flowering to fruiting, and studied 6 inflorescences.

Figure 2
The large X. striatipes population in Codó, State of Maranhão, growing in a swamp.

Further information about visiting beetles and scent analyses of X. striatipes is from the publication of Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ). Their collection sites were in Guará, close to Brasília in the Distrito Federal (city coordinates 15°49’53” S, 47°58’48” W), and another one in Arraias in the state of Tocantins (city coordinates 12°55’51” S, 46°56’16” W), approximately 340 km northeast of Brasília (Fig. 1). We compare the data of Milet-Pinheiro et al. (2017) with our data in the discussion section.

Plant voucher specimens are deposited in the herbaria of Botucatu (BOTU), Brasília (UB) and Ulm (ULM).

Characteristics of inflorescences, flowering, anthesis and beetle visitation

Although the population sizes of Xanthosoma varied, at each site we observed six inflorescences, their flowering, and their opening and closing in the pistillate and staminate stages. We assessed the functionality of pistils (pistillate = female stage) by the production of stigmatic exudates, and the effective function of stamens (staminate = male stage) by the release of pollen and its accessibility to insect visitors. We also observed the behavior of the visiting beetles, distinguishing their sex, and collected a total of 15 individuals for identification.

Warming rhythm of inflorescences

To study the increase in temperature (thermogenesis) we used temperature loggers and recorded the temperature of the inflorescences in relation to ambient temperature. We inserted the thermocouples into the upper staminate part of the inflorescences, which is the region of the spadices with the highest temperatures (based on previous tests). As a control, a second probe hung freely at approximately the same height and pointed away from the spadix, to record ambient temperatures. We protected the inflorescences and equipment from rain and direct sunlight. Inflorescence and ambient sensors were fully cross-calibrated to ensure data consistency. We used a Bioblock Scientific 16200 equipment (Portugal) for measurements. In addition, temperature of the inflorescences and the ambient air were measured continuously or discontinuously during the night and day with a NiCr-Ni temperature sensor (Therm 2256-1, Ahlborn Meß- und Regeltechnik, Germany).

Scent sampling and GC-MS analyses

In Botucatu, we collected the scent of one inflorescence per plant of two different individuals. As the inflorescences of X. striatipes, like in other species, heat up more during the receptive pistillate (female) stage, we conducted the sampling at this stage through dynamic headspace extraction, for which we used freshly cut inflorescences kept in water. This cutting does not seem to influence the scents emitted from aroid inflorescences (Milet-Pinheiro et al. 2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. , and references therein). We enclosed the two inflorescences separately in PET film oven bags (Bratschlauch, Melitta GmbH, Germany) for nearly one hour (19:00 to 19:55 h) to enrich the scents. Afterwards the scented air inside the bags with the inflorescences was drawn for 60 min (from 20:00 to 21:00 h, sample one) and 120 min (from 20:00 to 22:00 h, sample two) by a membrane pump (Rietschle Thomas, Puchheim, Germany) at a constant flow rate of 200 mL min^-1. The air enriched with scent compounds was trapped in glass tubes containing adsorbent polymer (500 mg), consisting of a 1:1 mixture of Tenax^TM TA (80/100 mesh, Supelco, USA) and Carbopack^TM X (20/40 mesh, Supelco, USA). Samples were stored in a freezer until analysis. The tubes were eluted with 1 ml of high-grade acetone (Merck, Germany), and obtained samples were stored in a freezer until analysis (-20 °C).

Chemical analysis

The inflorescence scent samples were analyzed on a Varian Saturn 2000 mass spectrometer coupled to a Varian 3800 gas chromatograph equipped with a 1079 injector (Varian Inc.), which had been fitted with the ChromatoProbe kit, following Dötterl et al. (2006Dötterl S, Jürgens A, Seifert K, Laube T, Weißbecker B, Schütz S. 2006. Nursery pollination by a moth in Silene latifolia: The role of odours in eliciting antennal and behavioural responses. New Phytologist 169: 707-718.). 1µl of each sample was placed in a quartz vial, which was then injected in the GC by means of the ChromatoProbe (Dötterl et al. 2005Dötterl S, Wolfe L, Jürgens A. 2005. Qualitative and quantitative analyses of flower scent in Silene latifolia. Phytochemistry 66: 203-213.). The injector split vent was opened and the injector was heated to 40 °C to flush any air from the system. The split vent was closed after 2 min. The injector was heated at 200 °C min^-1, then held at 200 °C for 4.2 min, after which the split vent was opened and the injector cooled down. Separations were achieved with a fused silica column ZB-5 (5 % phenylpolysiloxane; 60 m long, inner diameter 0.25 mm, film thickness 0.25 µm; Phenomenex, Torrance, CA, USA). Electronic flow control was used to maintain a constant helium carrier gas flow of 1.0 ml min^-1. The GC oven temperature was held for 7 min at 40 °C, and then increased by 6 °C min^-1 to 250 °C and held for 1 min. The MS interface worked at 260 °C and the ion trap at 175 °C. Mass spectra were taken at 70 eV (in EI mode) with a scanning speed of 1 scan s^-1 from m/z 30 to 350. GC/MS data were processed using the Saturn Software package 5.2.1.

Identification of the components was carried out using the mass spectral libraries Wiley 9, Nist 2011, FFNSC 2, and Adams (2007Adams RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Mass Spectrometry. 4th. edn. Carol Stream, Illinois, Allured Publishing Corporation.), as well as the database available in MassFinder 3. Some of the compounds were confirmed by comparing their mass spectra and retention times with those of standard components available in the reference collection of the Plant Ecology Laboratory of the University of Salzburg. Samples from ambient air were used to discriminate between contaminants and inflorescence scents.

Results

Population sites, characteristics of inflorescences, flowering, and anthesis

The populations in Botucatu and Indianópolis had 25-30 individuals, while the population in Codó consisted of 147 individuals. At all sites, X. striatipes flowered during the rainy season. The inflorescence had a long peduncle, longer than the fertile part of the inflorescences. The spathe and the spadix had the same length of 13 to 17 cm each. The external basal part of the spathe was greenish and changed to light yellowish at the top. The internal part of the spathe and the spadix were also greenish at the base and became whitish, sometimes with a yellowish tinge in the upper part. The stigmata of the pistillate flowers were yellow. Xanthosoma striatipes had a two-night protogynous reproductive rhythm.

Warming rhythm of inflorescences

We measured the increase in temperature of inflorescences of X. striatipes in Botucatu (São Paulo state) and Bela Tanda (Minas Gerais state; Fig. 3A-B). At both sites, the temperature of the spadix was somewhat higher in the pistillate than the staminate stage. The peak temperature of a pistillate stage inflorescence in Botucatu was at 20:15 h, the staminate stage peak was already at 19:30 h. Measurements of inflorescences at Bela Tanda revealed that the temperature peak of the pistillate stage coincided with the temperature peak of the staminate stage. In Botucatu, in the measured inflorescence, the maximum temperature reached 33.6 °C (7.9 °C above ambient air temperature) in the pistillate stage and 27.8 °C (6.7 °C above ambient air temperature) in the staminate stage. The four measured inflorescences in Bela Tanda, reached at maximum 36.8 °C in the pistillate stage (20.5 and 19.5 °C above ambient air temperature, respectively), and 31.8 °C (14.5 °C above ambient air temperature) in the staminate stage. The peak heating temperatures of inflorescences and the timing at the two sites were thus slightly different, whereas the differences in temperatures between the spadix and the ambient air were twice as high in Bela Tanda than in Botucatu.

Figure 3
A. Warming of one inflorescence of X. striatipes in Botucatu, State of São Paulo, during the pistillate and the staminate stage in two subsequent days (November 18 and 19, 2007). B. Warming of four inflorescences of different individuals of X. striatipes, one in the staminate and the other three in the pistillate stage during one day (Indianópolis, State of Minas Gerais (December 12, 1986).

Behavior of pollinating beetles

During the scent emitting pistillate stage of X. striatipes at all sites, the beetles of the two species Cyclocephala atricapilla (Mannerheim) and C. ohausiana Höhne visited the inflorescences (Figs. 4, (5). They approached the inflorescences between 20:15 and 20:45 h (Fig. 3B). After arriving and settling on the spathe or spadix (Fig. 4A), they crawled down into the tube to the receptive, sticky pistillate flowers (Fig. 4B). In the next morning, the beetles were still actively eating from the sterile staminate flowers and some of them were mating. Between 18:45 and 19:00 h of the second evening, the beetles started to feed on pollen, while crawling up the spadix (Fig. 5A-B). At 20:00 h, the first beetles flew away, while others were still feeding on pollen, leaving the inflorescences as late as 20:30 h (Fig. 3B). When leaving, the pollen-covered beetles crawled up to the top of the spadix, from where they flew away.

Figure 4
Xanthosoma striatipes at Indianópolis, State of Minas Gerais. A. One individual of Cyclocephala ohausiana (left) and an individual of C. atricapilla (right) have approached a warm and smelling spadix in the pistillate stage. B. An opened inflorescence in the pistillate stage. Several individuals of C. ohausiana and probably also of C. atricapilla in the basal tube are contacting the receptive stigmas and gnawing on sterile staminate flowers. The length of the beetles is ca. 1.8 cm.

Figure 5
An inflorescence in the second night in the staminate stage, with male flowers producing pollen grains in form of chains, which are eaten by beetles coming out of the tube and crawling upwards. A. Probably, a C. ohausiana beetle eating pollen. B. Several C. ohausiana individuals in search of remnants of pollen shortly before flying away. The length of the beetles is ca. 1.8 cm.

As visitors of X. striatipes at the Botucatu site, we registered 56 individuals of C. ohausiana and four individuals of C. atricapilla, during three observation days. At the Indianópolis site, during four observation days, 19 individuals of C. atricapilla, and 12 individuals of C. ohausiana were registered. In Codó, in one observation day, only two C. atricapilla and one C. ohausiana were verified. The numerical proportion of the two beetle species varied among observation days. For example, in the Botucatu population, on December 1, 1978, we counted four C. atricapilla and 11 C. ohausiana, and on January 20, 1980, only 20 C. ohausiana were registered. The representation of the two sexes also differed between the two beetle species. For example, in Botucatu, out of 56 C. ohausiana individuals, 42 were males and 14 females, while out of four registered C. atricapilla individuals, two were males and two females. At all three sites, a common number of beetles on one inflorescence was two-six individuals.

In the large Codó population in Maranhão, we could see that the visiting beetles were essential for fruit production. Inflorescences without signs of previous beetle visitation, such as gnawing marks or remnants of their feces, did not produce fruits (46 individuals), while those inflorescences, which apparently had been visited by beetles (26 individuals), set fruits.

Floral scents

At the time when beetles were attracted, the inflorescences released a strong fruity odor. Scent was much weaker, and somewhat stinking at the staminate stage. The analyses of the two scent samples collected during the pistillate stage from plants of the Botucatu site revealed in total 39 compounds, including 11 unknown compounds, and overall a very similar scent composition (Tab. 1). Most of the compounds occurred only in low amounts, with only seven compounds contributing at least 2 % to the total scent in any of the two samples. The most prominent compounds in both samples were the aromatics methyl salicylate, methyl o-anisate and 1,3,5-trimethoxybenzene, the cyclic compound methyl jasmonate, the terpenoids (E)- and (Z)-4,8-dimethyl-1,3,7-nonatriene, and the S-containing 4-methyl-5-vinylthiazole.

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Table 1
Relative amount of scent compounds (%) detected in the two scent samples of Xanthosoma striatipes analysed in the present study and in the two samples of this species analysed by Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ). The samples of the present study were collected in Botucatu, São Paulo, those of Milet-Pinheiro et al. (2017) Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. in Guará, Distrito Federal und Arraias, Tocantins. tr: < 0.05 %. Compounds are ordered according to chemical classes and within classes according to retention time. The identification of the compounds marked with an asterisk is based on synthetic reference compounds. Compounds printed in italics were only detected in the study of Milet-Pinheiro et al. (2017)Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. , and underlined compounds were found both in the present and the previous study.

Discussion

As in other Araceae species, for instance in Philodendron selloum (Gottsberger & Silberbauer-Gottsberger 1991Gottsberger G, Silberbauer-Gottsberger I. 1991. Olfactory and visual attraction of Erioscelis emarginata (Cyclocephalini, Dynastinae) to the inflorescences of Philodendron selloum (Araceae). Biotropica 23: 23-28.), the beetles in Xanthosoma striatipes, are also attracted by the whitish-yellowish spathe together with the strong scent of the inflorescences. Xanthosoma striatipes also presents thermogenesis, which is certainly important and decisive for the successful attraction of the cyclocephaline scarab beetles. As known from previous studies of other cyclocephaline pollination systems in regions with a well-defined rainy and dry season, such as the Brazilian uplands and/or Cerrado, flowering of Xanthosoma also occurred in the rainy season (Dötterl et al. 2012Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.; Gottsberger et al. 2012Gottsberger G, Silberbauer-Gottsberger I, Seymour RS, Dötterl S. 2012. Pollination ecology of Magnolia ovata may explain the overall large flower size of the genus. Flora 207: 107-118.; 2013Gottsberger G, Silberbauer-Gottsberger I, Dötterl S. 2013. Pollination and floral scent differentiation in species of the Philodendron bipinnatifidum complex (Araceae). Plant Systematics and Evolution 299: 793-809.).

Contrary to most other pollinators, beetles are often stationary flower visitors, remaining in flowers or inflorescences for many hours (Gottsberger 2016Gottsberger G. 2016. Generalist and specialist pollination in basal angiosperms (ANITA grade, basal monocots, magnoliids, Chloranthaceae and Ceratophyllaceae): what we know now. Plant Diversity and Evolution 131: 263-362. ). The protogynous flowering rhythm is adequate for efficient pollen transfer in beetle pollination. In inflorescences, such as that of Xanthosoma, beetles find mating partners, feed on the sterile nutritious staminate flowers, and, just before leaving the inflorescence, they eat enormous amounts of pollen grains. Additionally, the increased temperature warms them up and facilitates their eventual flight to a pistillate stage inflorescence (Gottsberger 2016Gottsberger G. 2016. Generalist and specialist pollination in basal angiosperms (ANITA grade, basal monocots, magnoliids, Chloranthaceae and Ceratophyllaceae): what we know now. Plant Diversity and Evolution 131: 263-362. ).

In the states of São Paulo, Minas Gerais and Maranhão, along a south-north distribution, the beetle species Cyclocephala atricapilla and C. ohausiana are the constant pollinators of X. striatipes. Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ) also mention those two beetle species visiting X. striatipes at their study sites, and additionally C. celata Dechambre, 1980 and Erioscelis emarginata Endrödi, 1966.

In contrast to the two scent samples analyzed in the present study, which were quite similar (Tab. 1), the two samples of X. striatipes analyzed by Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ) strongly differed between each other. Further, there were marked differences in the scent samples in the present study compared to the previous one. Our analyses revealed 39 compounds, while Milet-Pinheiro et al. (2017)Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. detected 23 compounds in their samples, with only seven components common to both studies. Of the seven compounds that contributed at least 2 % to the total scent in any of the two samples analyzed in the present study, only two, (methyl salicylate and (E)-4,8-dimethyl-1,3,7-nonatriene) occurred also in the samples of Milet-Pinheiro et al. (2017)Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. . Beside these two compounds, Milet-Pinheiro et al. (2017)Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. found another four compounds that contributed in one of their samples at least 2 % to the total scent discharge: butan-2-yl acetate, (Z)-jasmone, dihydro-β-ionone, and two unknown compounds (Milet-Pinheiro et al. 2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ). Based on retention index and mass spectral information given by these authors, and recently published papers on novel scents in cyclocephaline pollinated plants (Maia et al. 2019Maia ACD, Grimm C, Schubert M, et al. 2019a. Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 204-213.a; bMaia ACD, Grimm C, Schubert M, et al. 2019b. Correction to: Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 214-215.) and in floral chemistry of Cyclanthaceae (Teichert et al. 2018Teichert H, Dötterl S, Gottsberger G. 2018. Scent emissions and floral nutrients of Carludovicoideae (Cyclanthaceae) and their importance for associated beetles. Plant Systematics and Evolution 304: 831-839.), these unknown compounds are isojasmol and dehydrojasmone. None of these compounds were detected in our samples (Tab. 1). This high overall intraspecific variation in scent was unexpected given that within-species variation in scent is limited in other species pollinated by cyclocephaline beetles (e.g., Gottsberger et al 2012Gottsberger G, Silberbauer-Gottsberger I, Seymour RS, Dötterl S. 2012. Pollination ecology of Magnolia ovata may explain the overall large flower size of the genus. Flora 207: 107-118.; 2013Gottsberger G, Silberbauer-Gottsberger I, Dötterl S. 2013. Pollination and floral scent differentiation in species of the Philodendron bipinnatifidum complex (Araceae). Plant Systematics and Evolution 299: 793-809.; Maia et al. 2013bMaia ACD, Gibernau M, Dötterl S, et al. 2013b. The floral scent of Taccarum ulei (Araceae): attraction of scarab beetle pollinators to an unusual aliphatic acyloin. Phytochemistry 93: 71-78.; 2019aMaia ACD, Grimm C, Schubert M, et al. 2019a. Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 204-213.).

In their comparative study of floral scent chemistry of 13 Xanthosoma species (including X. striatipes), Milet-Pinheiro et al. (2017Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. ) mentioned that some of the species had only a small number of compounds. This phenomenon occurs not only in Araceae, but also in other plants pollinated by cyclocephalini beetles, among them Annonaceae and Magnoliaceae (Dötterl et al. 2012Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.; Gottsberger et al. 2012Gottsberger G, Silberbauer-Gottsberger I, Seymour RS, Dötterl S. 2012. Pollination ecology of Magnolia ovata may explain the overall large flower size of the genus. Flora 207: 107-118.; Maia et al. 2012Maia ACD, Dötterl S, Kaiser R, et al. 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.; 2013aMaia ACD, Gibernau M, Carvalho AT, Gonçalves EG, Schlindwein C. 2013a. The cowl does not make the monk: scarab beetle pollination of the Neotropical aroid Taccarum ulei (Araceae, Spathicarpeae). Biological Journal of the Linnean Society 108: 22-34.; Pereira et al. 2014Pereira J, Schlindwein C, Antonini Y, et al. 2014. Philodendron adamantinum (Araceae) lures its single cyclocephaline scarab pollinator with specific dominant floral scent volatiles. Biological Journal of the Linnean Society 111: 679-691. ). Apparently, a few prominent compounds suffice to attract the beetles, as demonstrated in some previous studies (Pereira et al. 2014Pereira J, Schlindwein C, Antonini Y, et al. 2014. Philodendron adamantinum (Araceae) lures its single cyclocephaline scarab pollinator with specific dominant floral scent volatiles. Biological Journal of the Linnean Society 111: 679-691. , and references therein). Given that C. atricapilla and C. ohausiana visit X. striatipes over its large distribution range, we expected that dominant compounds commonly present at different sites are responsible for attraction of these two beetle species, i.e. methyl salicylate and (E)-4,8-dimethyl-1,3,7-nonatriene. However, it also seems possible that different scent compounds are involved in attracting these insects at different sites. One of these compounds might be (Z)-jasmone, which was the most common (12 of the 13 species), and in some of the species (including one sample of X. striatipes) also the most abundant compound in the Xanthosoma species studied by Milet-Pinheiro et al. (2017)Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10. . Indeed, this compound increases the attractiveness of another compound in another cyclocephaline, Erioscelis emarginata (Dötterl et al. 2012Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.). Another compound responsible for attracting C. atricapilla and C. ohausiana to inflorescences of X. striatipes might be 4-methyl-5-vinylthiazole, which was only detected in the present study. This compound was highly attractive to a few cyclocephaline species, among them C. atricapilla (Maia et al. 2012Maia ACD, Dötterl S, Kaiser R, et al. 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.). 4-Methyl-5-vinylthiazole also attracts Cyclocephala celata (Maia et al. 2012Maia ACD, Dötterl S, Kaiser R, et al. 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.). Its absence at our sites might be associated with the natural distribution of Cyclocephala celata, or the seasonality of local populations of the insects.

Overall, despite the availability of just a few scent samples of Xanthosoma striatipes, the variation among them was higher than the intraspecific variation recorded in other cyclocephaline pollinated plant species. Further, our study shows that C. atricapilla and C. ohausiana are constant visitors of this species despite these variations in scents. This finding can be explained by either a rather specific olfactory search image of the beetles that relies on the few compounds commonly present, or by a less specialized olfactory search image, in case beetles would be attracted to plants at different sites by different compounds.

Acknowledgements

We are grateful to the late S. Endrödi and B. Ratcliffe for identification of the beetles, to E.G. Gonçalves for identification of the plants, to K. Gross for comments on an earlier version of the manuscript, and to E. Wild and anonymous reviewers for suggestions and improvements regarding the manuscript. Thanks to the owners of the sites in Indianópolis and Codó for the permission to work there. Graciela Hintze has kindly prepared the photo tables.

References

Adams RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Mass Spectrometry. 4th. edn. Carol Stream, Illinois, Allured Publishing Corporation.
Boyce PC, Croat TB. 2016. The Überlist of Araceae. Totals of published and estimated number of species in Aroid genera. http://www.aroid.org/genera/160330uberlist.pdf
» http://www.aroid.org/genera/160330uberlist.pdf
Brummit RK. 2001. World Geographic Scheme for Recording Plant Distributions. 2nd. edn. Pittsburgh, Hunt Institute for Botanical Documentation, Carnegie Mellon University.
Chartier M, Gibernau M, Renner SS. 2014. The evolution of pollinator-plant interaction types in the Araceae. Evolution 68: 1533-1543.
Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.
Dötterl S, Jürgens A, Seifert K, Laube T, Weißbecker B, Schütz S. 2006. Nursery pollination by a moth in Silene latifolia: The role of odours in eliciting antennal and behavioural responses. New Phytologist 169: 707-718.
Dötterl S, Wolfe L, Jürgens A. 2005. Qualitative and quantitative analyses of flower scent in Silene latifolia Phytochemistry 66: 203-213.
Gibernau M. 2016. Pollinators and visitors of aroid inflorescences III - Phylogenetic & Chemical insights. Aroideana 39: 4-22.
Gottsberger G, Silberbauer-Gottsberger I, Dötterl S. 2013. Pollination and floral scent differentiation in species of the Philodendron bipinnatifidum complex (Araceae). Plant Systematics and Evolution 299: 793-809.
Gottsberger G, Silberbauer-Gottsberger I, Seymour RS, Dötterl S. 2012. Pollination ecology of Magnolia ovata may explain the overall large flower size of the genus. Flora 207: 107-118.
Gottsberger G, Silberbauer-Gottsberger I. 1991. Olfactory and visual attraction of Erioscelis emarginata (Cyclocephalini, Dynastinae) to the inflorescences of Philodendron selloum (Araceae). Biotropica 23: 23-28.
Gottsberger G. 2016. Generalist and specialist pollination in basal angiosperms (ANITA grade, basal monocots, magnoliids, Chloranthaceae and Ceratophyllaceae): what we know now. Plant Diversity and Evolution 131: 263-362.
Maia ACD, Dötterl S, Kaiser R, et al 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.
Maia ACD, Gibernau M, Carvalho AT, Gonçalves EG, Schlindwein C. 2013a. The cowl does not make the monk: scarab beetle pollination of the Neotropical aroid Taccarum ulei (Araceae, Spathicarpeae). Biological Journal of the Linnean Society 108: 22-34.
Maia ACD, Gibernau M, Dötterl S, et al 2013b. The floral scent of Taccarum ulei (Araceae): attraction of scarab beetle pollinators to an unusual aliphatic acyloin. Phytochemistry 93: 71-78.
Maia ACD, Grimm C, Schubert M, et al 2019a. Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 204-213.
Maia ACD, Grimm C, Schubert M, et al 2019b. Correction to: Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 214-215.
Maia ACD, Schlindwein C. 2006. Caladium bicolor (Araceae) and Cyclocephala celata (Coleoptera Dynastinae): a well-established pollination system in the northern Atlantic rainforest of Pernambuco, Brazil. Plant Biology 8: 529-534.
Mayo SJ, Bogner J, Boyce PC. 1997. The genera of Araceae. London, UK, Royal Botanic Gardens Kew.
Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10.
Pereira J, Schlindwein C, Antonini Y, et al 2014. Philodendron adamantinum (Araceae) lures its single cyclocephaline scarab pollinator with specific dominant floral scent volatiles. Biological Journal of the Linnean Society 111: 679-691.
Teichert H, Dötterl S, Gottsberger G. 2018. Scent emissions and floral nutrients of Carludovicoideae (Cyclanthaceae) and their importance for associated beetles. Plant Systematics and Evolution 304: 831-839.

Publication Dates

Publication in this collection
16 Oct 2020
Date of issue
Jul-Sep 2020

History

Received
20 Jan 2020
Accepted
26 June 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Adams RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Mass Spectrometry. 4th. edn. Carol Stream, Illinois, Allured Publishing Corporation.

[2] Boyce PC, Croat TB. 2016. The Überlist of Araceae. Totals of published and estimated number of species in Aroid genera. http://www.aroid.org/genera/160330uberlist.pdf
» http://www.aroid.org/genera/160330uberlist.pdf

[3] Brummit RK. 2001. World Geographic Scheme for Recording Plant Distributions. 2nd. edn. Pittsburgh, Hunt Institute for Botanical Documentation, Carnegie Mellon University.

[4] Chartier M, Gibernau M, Renner SS. 2014. The evolution of pollinator-plant interaction types in the Araceae. Evolution 68: 1533-1543.

[5] Dötterl S, David A, Boland W, Silberbauer-Gottsberger I, Gottsberger G. 2012. Evidence of behavioral attractiveness of methoxylated aromatics in a dynastid scarab beetle-pollinated Araceae. Journal Chemical Ecology 38: 1539-1543.

[6] Dötterl S, Jürgens A, Seifert K, Laube T, Weißbecker B, Schütz S. 2006. Nursery pollination by a moth in Silene latifolia: The role of odours in eliciting antennal and behavioural responses. New Phytologist 169: 707-718.

[7] Dötterl S, Wolfe L, Jürgens A. 2005. Qualitative and quantitative analyses of flower scent in Silene latifolia Phytochemistry 66: 203-213.

[8] Gibernau M. 2016. Pollinators and visitors of aroid inflorescences III - Phylogenetic & Chemical insights. Aroideana 39: 4-22.

[9] Gottsberger G, Silberbauer-Gottsberger I, Dötterl S. 2013. Pollination and floral scent differentiation in species of the Philodendron bipinnatifidum complex (Araceae). Plant Systematics and Evolution 299: 793-809.

[10] Gottsberger G, Silberbauer-Gottsberger I, Seymour RS, Dötterl S. 2012. Pollination ecology of Magnolia ovata may explain the overall large flower size of the genus. Flora 207: 107-118.

[11] Gottsberger G, Silberbauer-Gottsberger I. 1991. Olfactory and visual attraction of Erioscelis emarginata (Cyclocephalini, Dynastinae) to the inflorescences of Philodendron selloum (Araceae). Biotropica 23: 23-28.

[12] Gottsberger G. 2016. Generalist and specialist pollination in basal angiosperms (ANITA grade, basal monocots, magnoliids, Chloranthaceae and Ceratophyllaceae): what we know now. Plant Diversity and Evolution 131: 263-362.

[13] Maia ACD, Dötterl S, Kaiser R, et al 2012. The key role of 4-methyl-5-vinylthiazole in the attraction of scarab beetle pollinators: a unique olfactory floral signal shared by Annonaceae and Araceae. Journal Chemical Ecology 38: 1072-1080.

[14] Maia ACD, Gibernau M, Carvalho AT, Gonçalves EG, Schlindwein C. 2013a. The cowl does not make the monk: scarab beetle pollination of the Neotropical aroid Taccarum ulei (Araceae, Spathicarpeae). Biological Journal of the Linnean Society 108: 22-34.

[15] Maia ACD, Gibernau M, Dötterl S, et al 2013b. The floral scent of Taccarum ulei (Araceae): attraction of scarab beetle pollinators to an unusual aliphatic acyloin. Phytochemistry 93: 71-78.

[16] Maia ACD, Grimm C, Schubert M, et al 2019a. Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 204-213.

[17] Maia ACD, Grimm C, Schubert M, et al 2019b. Correction to: Novel floral scent compounds from night-blooming Araceae pollinated by cyclocephaline scarabs (Melolonthidae, Cyclocephalini). Journal Chemical Ecology 45: 214-215.

[18] Maia ACD, Schlindwein C. 2006. Caladium bicolor (Araceae) and Cyclocephala celata (Coleoptera Dynastinae): a well-established pollination system in the northern Atlantic rainforest of Pernambuco, Brazil. Plant Biology 8: 529-534.

[19] Mayo SJ, Bogner J, Boyce PC. 1997. The genera of Araceae. London, UK, Royal Botanic Gardens Kew.

[20] Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10.

[21] Pereira J, Schlindwein C, Antonini Y, et al 2014. Philodendron adamantinum (Araceae) lures its single cyclocephaline scarab pollinator with specific dominant floral scent volatiles. Biological Journal of the Linnean Society 111: 679-691.

[22] Teichert H, Dötterl S, Gottsberger G. 2018. Scent emissions and floral nutrients of Carludovicoideae (Cyclanthaceae) and their importance for associated beetles. Plant Systematics and Evolution 304: 831-839.

	Sample 1	Sample 2	Data of *Milet-Pinheiro et al. 2017*Milet-Pinheiro P, Gonçalves EG, Navarro DMA, Nuñez-Avellaneda LA, Maia ACD. 2017. Floral scent chemistry and pollination in the Neotropical aroid genus Xanthosoma (Araceae). Flora 231: 1-10.
Aliphatics
Butan-2-yl acetate			4.1^c
Pent-1-en-3-yl acetate			0.1^c
Aromatics			tr^c
Methyl benzoate			tr^c
1,2-Dimethoxybenzene*	tr	tr	tr^c
1,4-Dimethoxybenzene*	tr	tr
Methyl salicylate*	32.7	23.8	4.9-6.5
Isobutyl benzoate	0.1	0.2
Methyl o-anisate*	19.0	16.3
1,2,4-Trimethoxybenzene*	0.1	0.1
1,3,5-Trimethoxybenzene*	17.2	17.7
a Tetramethoxybenzene	0.1	0.2
C5-branched chain compounds
Methyl 2-methylbutyrate*	tr	1.1
Miscellaneous cyclic compounds
Isojasmol ^a			21.6^c
Dehydrojasmone ^b			16.9^c
(E)-Jasmone			tr^c
(Z)-Jasmone			0.1-51.2
Dihydro- β -ionone			8.0^c
7,8-Dihydro- β -ionol			0.1^c
Methyl jasmonate*	17.2	18.1
S-containing compounds
4-Methyl-5-vinylthiazole*	1.7	2.2
4-Methyl-5-formylthiazole	tr	tr
Terpenoids
Sabinene*	tr	0.1
β-Myrcene*	tr	0.1	0.2^c
Limonene			tr^c
Eucalyptol*	0.1	0.8	tr^c
(Z)-β-Ocimene			tr^c
(E)-β-Ocimene*	0.1	0.4	0.2-0.9
γ-Terpinene*	tr	tr
(E)-Linalool oxide furanoid* + Terpinolene*	tr	0.1
(Z)-4,8-Dimethyl-1,3,7-nonatriene*	0.4	2.1
Linalool*	0.3	0.2
(E)-4,8-Dimethyl-1,3,7-nonatriene*	9.9	14.6	0.5-82.4
α-Terpineol*	0.3	1
(E)-4,8-Dimethylnona-1,3,7-trien-5-yl acetate*	tr	tr
Theaspirane isomer 1			0.1^c
Theaspirane isomer 2			tr^c
β-Caryophyllene*	0.1	0.2	tr^c
(E)-β-Farnesene*	tr	tr
(E)-8(9)-dehydro4(5)-dihydrotheaspirone	tr	tr
α-Caryophyllene*	tr	0.0
Unknowns
Sum unknowns^{11 pooled}	0.5	0.6
unknown mw 91, 119, 105, 40, 77			0.9^c
unknown mw 79, 69, 41, 81, 93			0.1^c
unknown mw 117, 91, 94, 95, 79			1.1^c

Brasil