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. 2022 Jun 13;199:187–202. doi: 10.3897/phytokeys.199.79501

Pollen morphology of the genera Hidalgoa and Dahlia (Coreopsideae, Asteraceae): implications for taxonomy

Erandi Sánchez-Chávez 1,, Andrew Vovides 1, Victoria Sosa 1
PMCID: PMC9849023  PMID: 36761880

Abstract

Hidalgoa and Dahlia are two closely related genera in Asteraceae, tribe Coreopsideae whose limits need to be clarified. Pollen morphology has been useful for delimitation at the genus level in this family. To better define these genera, the morphology of pollen grains was observed and measured using light and scanning electron microscopy. The pollen grains of 25 species of Dahlia and Hidalgoa were acetolyzed and analyzed. Pollen is tricorporate in most of the species studied, although in a few species in Dahlia, grains were found to be hexacolporate. The most outstanding differentiating characters among species of Dahlia and Hidalgoa are colpus length (greater in Hidalgoa) and shape of spines (conical in Hidalgoa). In addition, lalongate ora are larger in Hidalgoa than in Dahlia. A PCA analysis of thirteen pollen characters, identified species of Hidalgoa in a discrete group and Dahliacuspidata as an outlier. These distinctive attributes in pollen morphology support the idea that pollen morphology is useful for delimitation at the generic level in the Dahlia clade. Further evidence from other sources, genetic or anatomical, might contribute to demarcating Dahlia and Hidalgoa, and provide insight into the family’s evolutionary history.

Keywords: Asteraceae, Dahlia , hexacolporate, Hidalgoa , pollen morphology, tricolporate

Introduction

Hidalgoa La Llave and Dahlia Cav. are two closely related genera in tribe Coreopsideae of the Asteraceae (Sørensen 1969; Turner 2010; Sánchez-Chávez et al. 2019). Hidalgoa comprises four accepted species (Panero 2007; Turner 2010), with H.ternata La Llave having the most widespread distribution, from Mexico to northern South America. The rest have restricted distributions. H.pentamera Sherff and H.uspanapa B.L. Turner are endemic to southeastern Mexico, and H.werklei Hook.f. is distributed in Costa Rica and in the Andean region of Colombia. Habitats for the species in Hidalgoa are cloud forests, mainly in microhabitats associated with rivers and very humid places. Remarkably, plants of Hidalgoa are vines, climbing onto vegetation by twisting petioles. The heads of Hidalgoa have five to twelve pistillate, fertile ray florets, and functionally staminate disc florets (Fig. 1A, B). Cypselae are compressed, with two apical lateral cusps (Panero 2007; Crawford et al. 2009; Turner 2010; Pruski and Robinson 2015).

Figure 1.

Figure 1.

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Morphological variation in Dahlia and Hidalgoa species AHidalgoapentameraBHidalgoauspanapaCDahliamooreiDDahliamixtecana. Photos by E. Sánchez-Chávez (A, C, D) and Andrés Ortiz (B).

Dahlia includes 40 species, of which 37 are endemic to Mexico (Villaseñor and Redonda-Martínez 2018; Carrasco-Ortiz et al. 2019; Reyes-Santiago et al. 2019), distributed mostly in pine and oak forests (Carrasco-Ortiz et al. 2019). Based on their chromosome numbers and morphological descriptors such as life form, size, shape, and segmentation of the compound leaves, four sections were recognized in Dahlia (Sørensen 1969): sect. Epiphytum with a single epiphytic species (D.macdougallii Sherff), sect. Pseudodendron with three suffrutescent species, sect. Entemophyllon with eight suffrutescent species with solid petioles, and sect. Dahlia with 28 herbaceous species with hollow petioles (Suppl. material 1: Table S1). With the exception of the epiphytic species, the rest possess tubers, and a few are rupicolous. Some of the species in sect. Entemophyllon that live for more than one season, have stems that become quite woody and give the full-grown plants a shrubby aspect. In Dahlia the ray florets can be neutral, pistillate fertile or sterile, while the disk florets are hermaphroditic, and vary in number from 15 to 170 (Fig. 1C, D) (Sørensen 1969; Pruski and Robinson 2015). Cypselae are compressed, linear to spatulate, sometimes shallowly tuberculate, with pappus absent or consisting of 2(5) small teeth, weak filiform, sometimes elongated to 1 mm caducous bristles (Sørensen 1969; Panero 2007; Pruski and Robinson 2015).

Hidalgoa was thought to be closely related to the genera Fitchia Hook. f, Moonia Arn., Oparanthus Sherff, and Petrobium R. Br., for sharing the character of functional male disc florets (Ryding and Bremer 1992). The similar floral morphology of Hidalgoa and Dahlia was suggested to be the result of a close relationship (Sørensen 1969; Turner 2010). Furthermore, a previous phylogenetic molecular study that included species of Dahlia and Hidalgoa found that the latter was embedded in a large clade with Dahlia; species of the two genera formed a well-supported monophyletic group (Sánchez-Chávez et al. 2019). However, taxonomic decisions will not be made until additional anatomical and palynological characters, as well as further molecular data, can be analyzed.

In spite of the uniform pollen morphology in the genera of Asteraceae, some pollen characters have been shown to be useful for supporting recognition and delimitation in numerous genera (El-Ghazaly and Anderberg 1995). Some examples of differentiating characters in the taxa of this family are the polar diameter and dimensions of the colpus and endoaperture in Viguiera Kunth (Magenta et al. 2010) and in Xanthium L., the length and number of spines and the number of columellae (Coutinho et al. 2020). Sexine thickness, the type of aperture, and spine dimensions are the differentiating traits for species of Stilpnopappus and Strophopappus (Carrijo et al. 2013), as is pollen surface ornamentation in the complex Phaeostigma of the genus Ajania (Huang et al. 2017). Pollen type and pollen grain shape are taxonomically useful for distinguishing species and genera of the subtribe Lepidaploinae (Marques et al. 2021).

The pollen in tribe Coreopsideae is helianthoid (exine with columellae containing internal foramina and clearly caveate), predominantly spheroidal, tricolporate, echinate, with internal foramina, full cavea present, and endexine much thicker than the foot layer (Blackmore et al. 2009).

Pollen morphology has not been analyzed in detail for the species of Hidalgoa or Dahlia. Previous palynological research by Wodehouse (1929) on four Dahlia species identified the presence of six apertures (hexacolporate) in pollen grains. This attribute constitutes a notable exception within the family. Further studies examined and described the meiotic stages of the pollen mother cell in Dahlia to determine the development of these apertures (Wodehouse 1930).

The aims of this study are to compile and compare pollen morphology of the species of Hidalgoa and Dahlia to identify informative characters and understand the relationships and limits of these taxa.

Materials and methods

Twenty-five samples of pollen grains were obtained from herbarium specimens deposited in the IBUG (Instituto de Botánica de la Universidad de Guadalajara) and XAL (Instituto de Ecología, A. C.) herbaria. Vouchers of specimens are included in Table 1.

Table 1.

Studied species of Hidalgoa and Dahlia for analyzing pollen grains, indicating their voucher and the herbarium in which they were deposited. Herbarium acronyms are according to Index Herbariorum.

Species Locality Collector Herbarium
Dahliaatropurpurea P.D. Sørensen Guerrero A. Castro C. 2251 IBUG
Dahliaaustralis (Sherff) P.D. Sørensen Puebla A. Rodriguez C. 6491 IBUG
Dahliabarkerae Knowles & Westc. Jalisco A. Castro C. 2304 IBUG
Dahliabrevis P.D. Sørensen México A. Rodriguez C. 5869 IBUG
Dahliacampanulata Saar, P.D. Sørensen & Hjert. Oaxaca A. Rodriguez C. 6495 IBUG
Dahliacoccinea Cav. Jalisco A. Rodriguez C. 7490 IBUG
Dahliacordifolia (Sessé & Moc.) McVaugh Guerrero A. Rodriguez C. 5224 IBUG
Dahliacuspidata Saar, P.D. Sørensen & Hjert. Guanajuato E. Ventura 9581 IBUG
Dahliadissecta S. Watson A. Rodriguez C. 6412 IBUG
Dahliaimperialis Roezl ex Ortgies Chiapas A. Rodriguez C. 6983 IBUG
Dahlialinearis Sherff Guanajuato E. Ventura 6143 IBUG
Dahliamerckii Lehm. L. Gutierrez s/n IBUG
Dahliamollis P.D. Sørensen Hidalgo A. Rodriguez C. 6414 IBUG
Dahlianeglecta Saar Hidalgo A. Rodriguez C. 6466 IBUG
Dahliaparvibracteata Saar & P.D. Sørensen Guerrero A. Rodriguez C. 6092 IBUG
Dahliapugana Aarón Rodr. & Art. Castro Jalisco A. Rodriguez C. 7731 IBUG
Dahliarudis P.D. Sørensen A. Ma. Hernández 12 XAL
Dahliarupicola P.D. Sørensen Durango A. Rodriguez C. 6133 IBUG
Dahliascapigera Knowles & Westc. Queretaro E. Gonzalez P. 560 IBUG
Dahliasorensenii H.V. Hansen & Hjert. J. Suárez J. 584 IBUG
Dahliaspectabilis Saar & P.D. Sørensen San Luis Potosí A. Rodriguez C. 6352 IBUG
Dahliatenuicaulis P.D. Sørensen Jalisco M. Chazaro B. 5736 IBUG
Dahliawixarika Art. Castro, Carr.-Ortiz & Aarón Rodr. Jalisco A. Castro C. 2983 IBUG
Hidalgoapentamera Sherff Veracruz E. Sánchez-Chávez 28 XAL
Hidalgoaternata La Llave Veracruz T. B. Croat 25505 XAL
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Pollen grains were acetolyzed according to the methodology of Erdtman (1960), and for difficult material in which compounds formed thin coats on the grains that interfered during the scanning process, the suggestions of Fonnegra (1989) were implemented. The grains were immersed in glacial acetic acid for 24 hours before acetolysis and then transferred to the acetolysis mixture for 1 to 6 hours and the temperature of the water bath was raised to 96 °C. For light microscopy (LM), the pollen grains were mounted in glycerol jelly, sealed, and then examined with a Carl Zeiss Fomi III Optical Microscope, equipped with a Cannon Power Shot G9 digital camera. Permanent slides were deposited in the Palynological Laboratory of the Instituto de Ecología, A. C. The following pollen measurements were obtained from 25 grains per sample: polar axis, equatorial diameter, exine thickness, colpus length, colpus width, ora width, ora length, spinae length, spine width at base and number of apertures.

To observe the pollen with a scanning electron microscope (SEM), acetolyzed pollen grains were washed in ethanol and later in water. Grains were sputter-coated with gold and observed using a Carl Zeiss EVO-50 scanning electron microscope. The terminology of Halbritter et al. (2018) was used, and for pollen structure the terminology of Erdtman (1969) was followed. Number of spines/100 μm2, colpus end, base of spine and pollen surface ornamentation were described for five grains per sample. Final morphological data are presented in Table 2.

Table 2.

Pollen attributes analyzed on the studied species of Hidalgoa and Dahlia. The values given in exine, colpus, ora, spine are averages. Cl colpus length, Cw colpus width, Ow Os width, Ol Os length, Swab Width at base.

Specie Polar axis (P)(μm) Equatorial diameter (E)(μm) P/E Pollen shape Number of apertures Exine (μm) Colpus (μm) Os (μm) Spine Number of spines/100 μm2 Base of spine
Min Max Mean Min Max Mean Cl Cw Copus ends Osl Ow Length (μm) Swab (μm)
Dahliaatropurpurea 28.18 32.70 30.43 28.85 32.46 30.92 0.98 Oblate-spheroidal Tricolporate 2.88 3.79 3.12 acute 2.28 2.55 7.80 5.99 7–8 distended
Dahliaaustralis 25.38 29.98 28.43 23.88 30.49 28.32 1.00 Spheroidal Tricolporate 2.63 3.01 3.08 acute 2.56 2.05 6.01 4.51 6–8 distended
Dahliabarkerae 30.62 36.15 33.78 30.86 34.82 33.34 1.01 Prolate-spheroidal Tricolporate 3.58 6.38 5.63 acute 2.20 3.09 7.55 7.21 4–5 distended
Dahliabrevis 26.41 32.33 29.04 25.53 32.58 29.41 0.99 Oblate-spheroidal Tricolporate 1.81 4.83 4.74 obtuse 2.06 2.93 7.37 5.79 7–10 distended
Dahliacampanulata 30.61 34.72 32.84 30.50 34.48 32.96 1.00 Spheroidal Tricolporate 2.24 4.34 1.54 obtuse 1.44 1.92 7.35 6.99 5–7 smooth
Dahliacoccinea 29.42 39.47 34.74 31.66 39.83 34.79 1.00 Spheroidal Tricolporate 3.05 5.42 4.53 obtuse 3.18 2.71 9.81 8.17 4–5 distended
Dahliacordifolia 27.80 32.03 29.64 28.00 33.46 30.61 0.97 Oblate-spheroidal Tricolporate 2.96 5.75 4.26 obtuse 2.32 2.74 7.87 6.64 6–7 smooth
Dahliacuspidata 31.21 35.48 33.16 31.63 37.05 34.44 0.96 Oblate-spheroidal Hexacolporate/ Tricolporate 1.64 8.61 6.22 obtuse 4.75 5.24 9.07 6.94 4–6 distended
Dahliadissecta 28.34 32.50 30.55 27.72 32.21 30.31 1.01 Prolate-spheroidal Hexacolporate/ Tricolporate 2.88 3.80 2.95 obtuse 2.18 2.35 7.33 6.57 5–7 smooth
Dahliaimperialis 25.95 30.64 28.04 25.78 31.50 28.94 0.97 Oblate-spheroidal Hexacolporate/ Tricolporate 1.98 3.85 2.93 obtuse 2.17 2.93 7.46 5.95 6–8 smooth
Dahlialinearis 29.83 33.79 31.82 29.85 34.99 32.68 0.97 Oblate-spheroidal Tricolporate 2.19 3.98 4.44 obtuse 2.42 3.70 5.29 5.59 8–10 smooth
Dahliamerckii 26.19 31.65 28.54 28.64 34.78 31.61 0.90 Oblate-spheroidal Hexacolporate/ Tricolporate 3.05 4.59 3.16 obtuse 1.45 2.75 6.97 6.25 7–8 distended
Dahliamollis 26.59 30.26 28.38 28.14 32.36 29.93 0.95 Oblate-spheroidal Tricolporate 1.88 4.14 2.42 obtuse 2.20 2.42 7.79 6.27 5–7 distended
Dahlianeglecta 32.72 37.48 35.06 30.75 37.77 35.77 0.98 Oblate-spheroidal Tricolporate 4.20 4.81 3.34 obtuse 2.35 3.03 6.82 6.80 4–5 distended
Dahliaparvibracteata 29.58 32.88 31.29 28.73 32.67 31.57 0.99 Oblate-spheroidal Hexacolporate/ Tricolporate 3.11 4.82 2.97 obtuse 2.05 2.97 8.97 6.86 6–7 distended
Dahliapugana 29.11 33.23 31.09 29.56 33.94 31.78 0.98 Oblate-spheroidal Tricolporate 3.42 4.41 4.08 obtuse 2.68 2.23 6.22 6.35 6–7 distended
Dahliarudis 30.08 35.73 33.29 33.40 36.78 34.94 0.95 Oblate-spheroidal Hexacolporate/ Tricolporate 3.06 4.19 2.50 acute 2.41 2.50 8.19 7.74 6–7 narrower
Dahliarupicola 28.20 35.37 31.16 26.92 32.40 30.08 1.04 Prolate-spheroidal Tricolporate 1.71 3.36 2.76 obtuse 2.41 2.76 8.36 5.99 6–7 distended
Dahliascapigera 26.68 32.66 30.56 27.01 31.57 29.38 1.04 Prolate-spheroidal Tricolporate 2.15 6.58 2.65 acute 2.68 2.65 7.90 6.09 4–5 narrower
Dahliasorensenii 28.87 34.80 31.90 30.73 36.42 33.90 0.94 Oblate-spheroidal Hexacolporate/ Tricolporate 1.68 5.17 2.40 obtuse 1.73 2.40 9.07 6.12 4–5 narrower
Dahliaspectabilis 27.71 34.07 30.33 25.20 32.12 30.11 1.01 Prolate-spheroidal Tricolporate 2.46 4.72 2.05 obtuse 1.54 2.05 8.57 6.00 6–8 distended
Dahliatenuicaulis 28.54 32.84 31.03 31.58 35.37 33.01 0.94 Oblate-spheroidal Tricolporate 2.82 4.19 4.94 obtuse 2.56 2.79 9.22 6.43 7 distended
Dahliawixarika 27.85 33.23 30.12 27.24 32.07 30.15 1.00 Spheroidal Tricolporate 2.42 3.36 2.63 obtuse 2.95 2.63 7.44 6.01 7–9 narrower
Hidalgoapentamera 25.73 30.35 27.97 25.10 30.27 26.94 1.04 Prolate-spheroidal Tricolporate 1.78 14.97 3.29 acute 2.06 9.98 5.47 6.09 4–5 narrower
Hidalgoaternata 28.01 34.07 30.36 26.45 32.08 29.63 1.02 Prolate-spheroidal Tricolporate 1.71 14.55 3.34 acute 2.89 8.21 5.80 4.63 4 narrower
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A matrix based on thirteen pollen characters was constructed. To estimate the quantitative variation within Dahlia and Hidalgoa, each character was measured and the average for each species was estimated. Qualitative characters were coded with the following states: number of apertures (tricolporate:0/ hexacolporate:1), colpus end (obtuse:0/ acute:1), base of spine (narrower:0/ distended:1) lalongate ora (absent:0/ present:1; present/absent:2) (Suppl. material 1: Table S2). A principal component analysis (PCA) was run in R (R Core Team. 2019) to evaluate the contribution of each pollen variable to the affiliation of species (Table 3). Graphical representation displayed distribution of thirteen pollen characters.

Table 3.

Palynological characters used in the multivariate analysis of Hidalgoa and Dahlia species. The contribution of every character for Axis 1 and Axis 2 is indicated (see Fig. 4).

Character Axis 1 Axis 2
1 Pa Polar axis (μm) 1.63 23.53
2 Et Exine thickness (μm) 6.59 2.30
3 Cl Colpus length (μm) 25.18 1.19
4 Cw Colpus width (μm) 8.88 10.75
5 Ow Os width (μm) 22.82 1.34
6 Ol Os length(μm) 3.75 11.48
7 Sl Spinae length (μm) 7.98 10.97
8 Swab Spine width at base (μm) 5.48 20.32
9 Na Number of apertures 1.06 2.37
10 Ns Number of spines/100 μm2 4.49 11.70
11 Ce Colpus ends 8.81 0.25
12 Sb Base of spine 3.14 1.55
13 Osl Os lalongate 0.20 2.23
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Results

Pollen grains from a total of 25 species belonging to Dahlia (23 species) and Hidalgoa (2 species) were analyzed. Table 2 summarizes measurements and character states and Figs 2, 3 and 4 show the diversity in their pollen morphology.

Figure 2.

Figure 2.

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Pollen grains of Dahlia and Hidalgoa observed with light microscopy (LM) AD.australisBD.barkeraeCD.brevisDcampanulataED.coccineaFD.cordifoliaGD.cuspidataHD.dissectaID.imperialisJD.linearisKD.merckiiLD.mollisMD.neglectaND.parvibracteataOD.puganaPD.rudisQD.rupicolaRD.scapigeraSD.sorenseniiTD.spectabilisUD.rudis, pollen grain hexacolporate with three apertures on one hemisphere and three on the other hemisphere VH.ternataWH.pentamera. Scale bars: 10 μm.

Figure 3.

Figure 3.

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Scanning Electron Microscope (SEM) images of Dahlia and Hidalgoa pollen grains A–CHidalgoaternataA equatorial view B detail of colpus C detail of spine D–FDahliaaustralisD polar view E detail of colpus F detail of spine G–IDahliacuspidataG equatorial view H detail of colpus I detail of spine J–LDahlianeglectaJ equatorial view K detail of colpus L detail of spine M–ODahliacoccineaM equatorial view N detail of colpus O detail of spine.

Figure 4.

Figure 4.

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Scanning Electron Microscope (SEM) images of Dahlia and Hidalgoa pollen grains A, BDahliaatropurpureaCDahliabarkeraeD, EDahliabrevisFDahliadissectaHDahliaimperialisIDahlialinearisJDahliamerckiiKDahliascapigeraLDahliatenuicaulisMDahliawixarikaN–OHidalgoapentamera.

The majority of species analyzed in Dahlia are tricoloporate. However, two out of ten pollen grains are hexacolporate in D.cuspidata, D.dissecta, D.imperialis, D.merckii, D.parvibracteata, D.rudis and D.sorensenii, with three apertures on one hemisphere and three on the other hemisphere (Fig. 2U). The shape is spheroidal-oblate, spheroidal or spheroidal-prolate (P/E = 0.90–1.04) and radially symmetric. Pollen size is P = 25.3 (31) 39.4 μm, E = 23.8 (31.6) 39.8 μm (Fig. 6A), and corresponds to a medium grain (Erdtman 1969). The ora are rarely lalongate, and situated distally from the equator, length 1.04 (2.51) 5.41 μm, and width 1.27 (3.60) 8.61 μm (Figs 2B, 2F, 6B), rarely acute. Colpus usually short, almost equal to ora length, more or less oval to oblong, length 2.24 (4.81) 9.2 μm, and width 1.27 (2.85) 5.89 μm (Figs 3E, 3H, 3K, 3N, 4I, 4M, 6C), apices obtuse to acute. Exine thickness thin, excluding spines, ranging from 1.1 (2.59) to 5.6 μm (Fig. 2). Ornamentation echinate; spines 4 (6–7) 10/100 μm2, spine length from 4.2 (7.75) to 12.26 μm, and width at base from 3.06 (6.40) to 10.35 μm, shape of spines more deltate than conical (Fig. 6D), with a distended or narrower base and with acuminate apex (Figs 3, 4). Tectum with the base of the spine always microperforate.

Figure 6.

Figure 6.

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Comparison of Dahlia and Hidalgoa pollen grains A box plot of Polar diameter B os length/width C colpus length/width D spine length/width at base. 1Dahliaatropurpurea. 2Dahliaaustralis. 3Dahliabarkerae. 4Dahliabrevis. 5Dahliacampanulata. 6Dahliacoccinea. 7Dahliacordifolia. 8Dahliacuspidata. 9Dahliadissecta. 10Dahliaimperialis. 11Dahlialinearis. 12Dahliamerckii. 13Dahliamollis. 14Dahlianeglecta. 15Dahliaparvibracteata. 16Dahliapugana. 17Dahliarudis. 18Dahliarupicola. 19Dahliascapigera. 20Dahliasorensenii. 21Dahliaspectabilis. 22Dahliatenuicaulis. 23Dahliawixarika. 24Hidalgoapentamera. 25Hidalgoaternata.

Pollen grains in the species of Hidalgoa analyzed are tricolporate and spheroidal-prolate (P/E = 1.02–1.04), radially symmetric. Pollen size is P = 25.7 (29.1) 34 μm, E = 25.1 (28.5) 32 μm (Fig. 6A), and corresponds to a medium grain (Erdtman 1969). The lalongate ora length 1.71 (2.47) to 4.87 μm, and width 6.32 (9.39) to 13.02 μm (Figs 2W, 6B), usually wider than longer and with acute apices. The colpus is elliptical, length 11.28 (14.76) to 16.83 μm, and width 2.69 (3.31) to 4.21 μm (Fig. 6C), apex always acute (Figs 3A, 3B, 4N). Exine is thinner, 1.12 (1.74) 2.95 μm excluding the spines. Ornamentation is echinate; spines 4–5/100 μm2, spine length ranging from 4 (5.6) to 6.77 μm and width at base 3.6 (5.3) to 7.3 μm, shape of spines conical (Figs 3C, 4O, 6D), with apex acute. Tectum with base of spine always microperforate. Palynological characters of the two studied species of Hidalgoa are similar, only a slight variation in pollen grain size was detected.

Results of the PCA indicate that the first two components explain 46.04% of the observed variation (see Table 3 to for the contribution of each variable to Dim 1 and Dim 2). A bidimensional projection of the axes of the two first components is displayed in Fig. 5. The first principal component explains 25.19% of the variation and is associated with colpus length (Cl) and os width (Ow). The second principal component explains 20.85% and variables that contributed the most are polar axis (Pa), spine width at base (Swab), spine length (Sl), colpus width (Cw), os length (Ol), number of spines/100 μm2 (Ns). Length of arrows in Fig. 5 suggests adequate sampling for all characters, except for lalongate os (Osl), number of apertures (Ap) and base of spine (Sb).

Figure 5.

Figure 5.

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Principal Components Analysis graph showing contribution of the thirteen attributes to explain variation in pollen grains of the studied Dahlia and Hidalgoa species. Pa Polar axis, Et Exine thickness, Cl Colpus length, Cw Colpus width, Ol Os length, Ow Os width, Sl Spine length, Swab Spine width at base, Na Number of apertures, Ns Number of spines/100 μm2, Ce Colpus ends, Sb Base of spine, Osl Os lalongate.

Discussion

The pollen grains of the 25 species of Dahlia and Hidalgoa we studied share the pollen type common to tribe Coreopsideae: more or less spheroidal, round in both views, tricolporate, ora lalongate, tectum microperforate, echinate, spines irregularly distributed, conical to long-pointed and smooth or distended bases with perforations (Blackmore et al 2009). The pollen of the species studied is quite homogeneous, with little variation in size and shape. Pollen grains size ranges from 25.3 to 39.4 μm in Dahlia and 25.7 to 34 μm in Hidalgoa, and the ratio of polar axis and equatorial diameter is 0.90–1.04 (Dahlia: 0.90–1.04, Hidalgoa: 1.02–1.04). The largest grains were observed in D.neglecta and the smallest in D.australis and H.pentamera. Based on the classification proposed by Erdtman (1969), the pollen of both genera corresponds to medium-sized grains (25–50 μm), like those described by Tellería (2017) for tribe Coreopsideae. Pollen grains in Dahlia and Hidalgoa are radially symmetrical, isopolar, and mostly spheroidal, similar to those described in Coreopsis (Tadesse et al. 1995).

Apertures are the most variable attribute between Dahlia and Hidalgoa, but not within the genera. Pollen in Hidalgoa is always tricolporate, while in pollen grains of Dahlia, the aperture varies from tricolporate to hexacolporate. Hexacolporate species observed here were: D.cuspidata, D.dissecta, D.imperialis, D.merckii, D.parvibracteata, D.rudis and D.sorensenii. Wodehouse (1930) recognized the same pattern in D.brevis, D.coccinea, D.pinnata and D.imperialis. However, Wodehouse (1930) described these six apertures as uniform in all pollen grains; the observations were made on species belonging to the San Francisco Dahlia Society, plants that are probably of hybrid origin. The specimens collected from the herbariums for this study do not display characters of hybrid origin. Furthermore, hexacolporate grains have been indeed reported in Old World Vernonieae and Adenanthemum (Blackmore et al 2009). Other members of Coreopsideae such as Bidens also vary in the number of colpi from 3–4 (Tadesse et al. 1995) or polypentoporate (Younis et al. 2020).

The os and colpus displayed more variation in Dahlia than in Hidalgoa. In Hidalgoa the os is lalongate, the widest is up to 13 μm width, and the longest colpus is approximately 17 μm, with apices always acute. These traits of Hidalgoa are similar to those observed in Bidens (Tadesse et al. 1995). In Dahlia the ora are either lalongate or lolongate. The os is slightly wider than larger and apices are obtuse, rarely acute. The widest and largest colpus was observed in D.cuspidata (5.89 μm and 9.2 μm respectively) and D.scapigera (ca. 7 μm), and the smallest in D.australis (2.9 μm). Variation in the apertures like those of Dahlia has not been reported in other genera of the tribe Coreopsideae (Blackmore et al. 2009).

Spines are variable between Dahlia and Hidalgoa. In Hidalgoa they are conical and smaller (4.08 to 6.77 μm) while in Dahlia they are deltate and larger (4.29 to 12.26 μm), with exception of D.linearis (smaller). Spines in Dahlia varied more in shape and size. They are commonly triangular or deltate with a broadened base (distended base), as described by Tellería (2017) for tribe Coreopsideae. Sometimes spines emerge abruptly from the exine surface, e.g. D.campanulata, D.imperialis, D.parvibracteata, D.scapigera. These spines are similar to those described in Coreopsis (Tadesse et al. 1995). The transition between the microperforate basal portion of the spine and the unperforated apical portion is abrupt in almost all species, except in D.cordifolia, D.linearis and D.sorensenii. Exine thickness did not vary among Hidalgoa and Dahlia species. The thinnest was observed in D.cuspidata and D.sorensenii (1.6 μm) and the thickest in D.neglecta (4.2 μm).

Multivariate analyses did not reveal a clear clustering among species of Dahlia according to the sections proposed by Sørensen (1969), based mainly on life form and in the phylogeny of Saar et al. (2003). Nevertheless, D.cuspidata and the Hidalgoa species are significantly different from the other Dahlia species included in this study. Hidalgoa species have long colpi and wide ora, and D.cuspidata has long ora. Dahliacuspidata possesses unusual morphological characters such as large involucral outer bracts and cuspidate leaf shape. Thus, further research might decide the position of this species.

The most recent phylogeny that included Dahlia and Hidalgoa (Sánchez-Chávez et al. 2019) identified Hidalgoa within the Dahlia clade. However, both genera are morphologically complex (Sørensen 1969; Turner 2010), and contrasting characters such as life form, number and arrangement of fertile and sterile flowers have been used to separate these two groups. A further phylogeny, including all species, may help us to better understand pollen evolution in the genus.

Conclusions

The palynological descriptions for Hidalgoa presented here are the first, and despite the similarities in its floral morphology to that of Dahlia, its pollen is remarkably different, mostly in colpus length and shape of their spines. Hidalgoa has pollen grains with large colpi and small, conical spines. In addition, the length of the lalongate ora differ. Hexacolporate grains with a distended base, were found in a number of Dahlia species but have not been identified in Hidalgoa. Likewise, morphological characters such as pistillate fertile ray florets, cypselae with two apical lateral cusps and twisting petioles in Hidalgoa contrast with the ray florets, which can be fertile, pistillate or sterile, cypselae with pappus absent or present with 2(5) small teeth or of two weak filiform, caducous bristles of Dahlia; characters that have been utilized to tell these two genera apart. The results obtained in this palynological study support the idea that pollen morphology is useful for delimitation at the generic level in the Dahlia clade. These differentiating attributes in pollen morphology in the species of Dahlia and Hidalgoa indicate that they should be recognized as separate genera. However, as indicated above, additional anatomical and molecular characters are needed to make the taxonomic decision and help us understand evolution in the genera, and their relationship to other genera in Coreopsideae.

Acknowledgements

We thank Tadesse Mesfin, Arturo Castro-Castro and an anonymous reviewer for comments and suggestions that greatly improved this manuscript. We thank the curators of the IBUG and XAL herbaria for kindly allowing us to sample the pollen of Hidalgoa and Dahlia. We are grateful to Bianca Delfosse for editing our English. Sonia Galicia provided invaluable help in the anatomy lab and with optical microscopy, and Ana Lucía Tovar Álvarez produced the SEM photomicrographs of LANIVEG-QRO. E. Sánchez-Chávez was supported by a Doctorate in Science scholarship from CONACyT, Mexico (780481).

Citation

Sánchez-Chávez E, Vovides A, Sosa V (2022) Pollen morphology of the genera Hidalgoa and Dahlia (Coreopsideae, Asteraceae): implications for taxonomy. PhytoKeys 199: 187–202. https://doi.org/10.3897/phytokeys.199.79501

Funding Statement

Instituto de Ecología A.C.

Supplementary materials

Supplementary material 1

Tables S1, S2

This dataset is made available under the Open Database License (http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this Dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited.

Erandi Sánchez-Chávez, Andrew Vovides, Victoria Sosa

Data type

Tables (docx. file)

Explanation note

Table S1. Dahlia diversity. Sections proposed by Sorensen (1969). Table S2. Data matrix showing the values found for the 13 characters (columns) in the 25 species (rows) of Hidalgoa and Dahlia included in this study. (Characters designated according to Table 3).

References

  1. Blackmore S, Wortley AH, Skvarla JJ, Robinson H. (2009) Evolution of pollen in Compositae. In: Funk VA, Susanna A, Stuessy TF, Bayer RJ. (Eds) Systematics, evolution and biogeography of Compositae.International Association for Plant Taxonomy, Vienna, 101–130.
  2. Carrasco-Ortiz M, Munguía-Lino G, Castro-Castro A, Vargas-Amado G, Harker M, Rodríguez A. (2019) Riqueza, distribución geográfica y estado de conservación del género Dahlia (Asteraceae) en México. Acta Botánica Mexicana 126: 1–24. 10.21829/abm126.2019.1354 [DOI] [Google Scholar]
  3. Carrijo TT, Garbin ML, Picanço Leite W, Mendonça CBF, Esteves RL, Gonçalves-Esteves V. (2013) Pollen morphology of some related genera of Vernonieae (Asteraceae) and its taxonomic significance. Plant Systematics and Evolution 299(7): 1275–1283. 10.1007/s00606-013-0795-9 [DOI] [Google Scholar]
  4. Coutinho AP, Silveira P, Pita C, Santos MJ, Saraiva C, Perpétuo NC. (2020) Pollen morphology of Xanthium L. (s.l.) (Asteraceae, Asteroideae, Heliantheae, Ambrosiinae) in the Iberian Peninsula – a palynotaxonomic approach to a poisonous, allergenic and invasive genus. Grana 60(1): 35–56. 10.1080/00173134.2020.1737729 [DOI] [Google Scholar]
  5. Crawford DJ, Tadesse M, Mort M, Kimball RT, Randle CP. (2009) Coreopsideae. In: Funk VA, Susanna A, Stuessy TF, Bayer RJ. (Eds) Systematics, evolution and biogeography of Compositae.International Association for Plant Taxonomy, Vienna, 713–727.
  6. El-Ghazaly G, Anderberg AA. (1995) Pollen morphology of Phagnalon and Aliella (Asteraceae, Gnaphalieae) and its taxonomical implications. Grana 34(2): 89–99. 10.1080/00173139509429999 [DOI] [Google Scholar]
  7. Erdtman G. (1960) The acetolysis method, a revised description. Svensk Botanisk Tidskrift 54(4): 561–564. [Google Scholar]
  8. Erdtman G. (1969) Handbook of palynology: morphology, taxonomy, ecology; an introduction to the study of pollen grains and spores. Munksgaard, 486 pp.
  9. Fonnegra R. (1989) Métodos de Estudio Palinológico. Centro de Investigaciones de la Facultad de Ciencias Naturales y Exactas Universidad de Antioquia, Medellín, 57 pp. [Google Scholar]
  10. Halbritter H, Ulrich S, Grímsson F, Weber M, Zetter R, Hesse M, Buchner R, Svojtka M, Frosch-Radivo A. (2018) Illustrated Pollen Terminology. Illustrated Pollen Terminology. Springer International Publishing, 487 pp. 10.1007/978-3-319-71365-6 [DOI]
  11. Huang Y, An YM, Meng SY, Guo YP, Rao GY. (2017) Taxonomic status and phylogenetic position of Phaeostigma in the subtribe Artemisiinae (Asteraceae). Journal of Systematics and Evolution 55(5): 426–436. 10.1111/jse.12257 [DOI] [Google Scholar]
  12. Magenta MG, Nunes ADD, Mendonça CBF, Gonçalves-Esteves V. (2010) Palynotaxonomy of Brazilian Viguiera (Asteraceae) species. Boletín de La Sociedad Argentina de Bátanica 45(3–4): 285–299. [Google Scholar]
  13. Marques D, do Pico GMV, Nakajima JN, Dematteis M. (2021) Pollen morphology and its systematic value to southern South American species of Lepidaploa (Vernonieae: Asteraceae). Rodriguésia 72: 1–18. 10.1590/2175-7860202172017 [DOI] [Google Scholar]
  14. Panero JL. (2007) Coreopsideae. In: Kadereit JW, Jeffrey C. (Eds) The families and genera of vascular plants VIII.Flowering Plants. Eudicots, Asterales. The families and genera of vascular plants. Springer, Berlin, 406–428.
  15. Pruski JF, Robinson H. (2015) Asteraceae. In: Davidse G, Sousa-Sánchez M (Eds) Flora Mesoamericana 5(2): 1–1362. [Google Scholar]
  16. R Core Team (2019) R: A language and environment for statistical computing. R Foundation for Statistical Computing. https://www.r-project.org/
  17. Reyes-Santiago J, Islas-Luna MA, Munguía-Lino G, Castro-Castro A. (2019) Dahliamixtecana (Asteraceae, Coreopsideae), a striking new species from Oaxaca, Mexico. Phytotaxa 394(3): 209–218. 10.11646/phytotaxa.394.3.2 [DOI] [Google Scholar]
  18. Ryding O, Bremer K. (1992) Phylogeny, distribution, and classification of the Coreopsideae (Asteraceae). Systematic Botany 17(4): 649–659. 10.2307/2419733 [DOI] [Google Scholar]
  19. Saar DE, Polans NO, Sørensen PD. (2003) A phylogenetic analysis of the genus Dahlia (Asteraceae) based on internal and external transcribed spacer regions of nuclear ribosomal DNA. Systematic Botany 28(3): 627–639. http://www.jstor.org/stable/25063902 [Google Scholar]
  20. Sánchez-Chávez E, Rodríguez A, Castro-Castro A, Pérez-Farrera MA, Sosa V. (2019) Spatio-temporal evolution of climbing habit in the Dahlia-Hidalgoa group (Coreopsideae, Asteraceae). Molecular Phylogenetics and Evolution 135: 166–176. 10.1016/j.ympev.2019.03.012 [DOI] [PubMed] [Google Scholar]
  21. Sherff EE. (1947) Addition to the genera Scalesia Arn and Hidalgoa Llave and Lex. Publications of the Field Museum of Natural History. Botanical Series 23(7): 334–335. [Google Scholar]
  22. Sørensen PD. (1969) Revision of the genus Dahlia (Compositae, Heliantheae– Coreopsidinae). Rhodora 71: 309–365. [Google Scholar]
  23. Tadesse M, Crawford DJ, Smith EB. (1995) Pollen morphology of North American Coreopsis (Compositae – Heliantheae). Grana 34(1): 21–27. 10.1080/00173139509429029 [DOI] [Google Scholar]
  24. Tellería MC. (2017) Spines vs. microspines: An overview of the sculpture exine in selected basal and derived Asteraceae with focus on Asteroideae. Journal of Plant Research 130(6): 1023–1033. 10.1007/s10265-017-0956-y [DOI] [PubMed] [Google Scholar]
  25. Turner BL. (2010) The Comps of Mexico. A systematic account of the family Asteraceae (Chapter 10: Subfamily Coreopsideae). Phytologia Memoirs 1: 1–224. [Google Scholar]
  26. Villaseñor JL, Redonda-Martínez R. (2018) A new species of Dahlia (Asteraceae, Coreopsideae) from the state of Oaxaca, Mexico. Phytotaxa 362(2): 239–243. 10.11646/phytotaxa.362.2.11 [DOI] [Google Scholar]
  27. Wodehouse RP. (1929) The origin of symmetry patterns of pollen grains. Bulletin of the Torrey Botanical Club 56(7): 339–350. 10.2307/2480750 [DOI] [Google Scholar]
  28. Wodehouse RP. (1930) The origin of the six-furrowed configuration of Dahlia pollen grains. Bulletin of the Torrey Botanical Club 57(6): 371–380. 10.2307/2480640 [DOI] [Google Scholar]
  29. Younis S, Shaheen S, Harun N, Abbas M, Ahmad M, Hussain K, Khan F. (2020) Application of multimicroscopic techniques (LM and SEM) in comparative palynological study of Asteroideae members, inhabited in Pakistan. Microscopy Research and Technique 84(5): 1063–1077. 10.1002/jemt.23667 [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary material 1

Tables S1, S2

This dataset is made available under the Open Database License (http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this Dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited.

Erandi Sánchez-Chávez, Andrew Vovides, Victoria Sosa

Data type

Tables (docx. file)

Explanation note

Table S1. Dahlia diversity. Sections proposed by Sorensen (1969). Table S2. Data matrix showing the values found for the 13 characters (columns) in the 25 species (rows) of Hidalgoa and Dahlia included in this study. (Characters designated according to Table 3).

phytokeys-199-187_article-79501__-s001.docx (14.9KB, docx)

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