Morphological characterization of pollen grains of Brazilian species of Bombacoideae (Malvaceae <i>s.l</i>.)

Saba, Marileide Dias; Esteves, Gerleni Lopes; Santos, Valdira de Jesus; Santos, Francisco de Assis Ribeiro dos

doi:10.1590/0102-33062019abb0234

ABSTRACT

The pollen grains of 15 species belonging to five genera (Ceiba Mill., Eriotheca Schott & Endl., Pachira Aubl., Pseudobombax Dugand, and Rhodognaphalopsis A. Robyns) of the subfamily Bombacoideae (Malvaceae s.l.) were acetolysed, measured, described and photomicrographed under light microscopy and scanning and transmission electron microscopy, in order to characterize the pollen morphology of species of the subfamily occurring in Brazil. The pollen characters studied were size, shape, exine constitution, and apertural type. Pollen grains were medium to large-sized and isopolar with a (sub)circular and (sub)triangular amb with flat, convex or concave sides; oblate to suboblate; 3(-4)-colp(or)ate or 4-5(-6)-colporate, planaperturate, sinuaperturate; equatorial calottes different or not; exine tectate or semitectate, perforate and microreticulate with or without supratectal spines. The results confirm the eurypalynous nature of the group with variation among the studied genera being mainly in the exine pattern.

Keywords:
Ceiba; Pachira; palynology; Pseudobombax; SEM; TEM

Introduction

Bombacoideae is one of nine recognized subfamilies of Malvaceae s.l. (Bayer et al. 1999Bayer C, Fay MF, Bruijn AY, et al. 1999. Support for an expanded family concept of Malvaceae within a recircunscribed order Malvales: a combined analysis of plastid atpB and rbcL DNA sequences. Botanical Journal of the Linnean Society 129: 267-303.). It comprises genera traditionally placed in the family Bombacaceae and, with the subfamily Malvoideae, forms a clade called Malvatheca (Alverson et al. 1999Alverson WS, Whitlock BA, Nyffeler R, Bayer C, Baum DA. 1999. Phylogeny of the core Malvales: evidence from ndhF sequence data. American Journal of Botany 86: 1474-1486.). Malvatheca is well-supported by mixed analyses, and includes representatives characterized by modified anthers with two or multiple sporangiate thecae. However, the compositions of Bombacoideae and Malvoideae are not easily determined by morphology, while molecular studies have presented conflicting results (Baum et al. 2004Baum DA, Smith SD, Yen A, et al. 2004. Phylogenetic relationships of Malvatheca (Bombacoideae and Malvoideae; Malvaceae sensu lato) as inferred from plastid DNA sequences. American Journal of Botany 91: 1863-1871.; Nyffeler et al. 2005Nyffeler R, Bayer C, Alverson WS. et al. 2005. Phylogenetic analysis of the Malvadendrina clade (Malvaceae s.l.) based on plastid DNA sequences. Organisms, Diversity & Evolution 5: 109-123.). Traditional works (Kunth 1821Kunth KS. 1821. Bombacaceae. In: Humbold A, Bonpland A, Kunth KS. (eds.) Nova genera et species plantarum. Vol. 5. Antverpiae, Ex officina Christophori Plantini. p. 294-308.; Candolle 1824Candolle AP. 1824. Bombacaceae. Prodromus Systematis Naturalis Regni Vegetabilis. Vol. 1. Paris, Caprelet.; Cronquist 1981Cronquist A. 1981. An integrated system of classification of flowering plants. New York, Columbia University Press. ) have always considered the taxa included in Malvoideae and Bombacoideae as being very closely related.

Bombacoideae includes about 17 genera and 160 species with a predominantly Neotropical distribution (Carvalho-Sobrinho et al. 2016Carvalho-Sobrinho JG, Alverson WS, Alcantara S, Queiroz LP, Mota AC, Baum D A. 2016. Revisiting the phylogeny of Bombacoideae (Malvaceae): Novel relationships, morphologically cohesive clades, and a new tribal classification based on multilocus phylogenetic analyses. Molecular Phylogenetics and Evolution 101: 56-74.). According to Stevens (2005Stevens PF. 2005. Angiosperm Phylogeny Website. Version 6. May 2005. http://www.mobot.org/MOBOT/research/APweb/. 26 Jul. 2018.
http://www.mobot.org/MOBOT/research/APwe... ), the subfamily is characterized by an often robust trunk with water storage in the parenchyma, fine bark, robust aculeus, usually fasciculate fillets, pollen grains with a triangular amb with more or less flat sides, staminode generally absent, pubescent endocarp and palmately compound leaves, the latter being considered a probable synapomorphy for the group (Alverson et al. 1999Alverson WS, Whitlock BA, Nyffeler R, Bayer C, Baum DA. 1999. Phylogeny of the core Malvales: evidence from ndhF sequence data. American Journal of Botany 86: 1474-1486.; Baum et al. 2004Baum DA, Smith SD, Yen A, et al. 2004. Phylogenetic relationships of Malvatheca (Bombacoideae and Malvoideae; Malvaceae sensu lato) as inferred from plastid DNA sequences. American Journal of Botany 91: 1863-1871.).

Several representatives of Bombacoideae have numerous uses and are of great economic importance. The light wood of species of Cavanillesia, Ceiba, Eriotheca and Pseudobombax is used in the manufacture of packaging, furniture structure, door, linings, toys, and model aircrafts. The kapok is used for filling mattresses, pillows, and furniture upholstery. Among other species, representatives of Bombax, Ceiba, and Pachira stand out as ornamental plants used in parks and gardens (Braga 1960Braga RP. 1960. Plantas do Nordeste, especialmente do Ceará. 4th. edn. Natal, Ed. Universitária UFRN. ; Lorenzi 2002Lorenzi H. 2002a. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Vol. 1. Nova Odessa, Ed. Plantarum. a; bLorenzi H. 2002b. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil . Vol. 2. Nova Odessa, Ed. Plantarum . ; Maia 2004Maia GN. 2004. Caatinga: árvores e arbustos e suas utilidades. São Paulo, D & Z Computação Gráfica e Editora. ).

Bombacoideae is considered a eurypalynous subfamily whose pollen grains vary mainly in apertural type and pattern of exine ornamentation. The use of pollen morphology for taxonomic differentiation is of particular importance for eurypalynous groups. Fuchs (1967Fuchs HP. 1967. Pollen morphology of the family Bombacaceae. Review of Palaeobotany and Palynology 3: 119-132.) emphasized the value of pollen characters for differentiating taxa of Bombacoideae. This is evidenced in the taxonomic study of Bombax s.l. (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.), which used pollen morphology along with macromorphological characters to delimit infrageneric taxa, and the classification of Cronquist (1981Cronquist A. 1981. An integrated system of classification of flowering plants. New York, Columbia University Press. ), which used pollen type as one of the characters to separate representatives included in Malvoideae and Bombacoideae.

One of the most significant contributions to the pollen morphology of representatives of Bombacoideae is that of Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.), who analyzed pollen grains of 29 genera of the subfamily using light and electron microscopy. These authors recognized eleven pollen types based mainly on exine ornamentation patterns and apertural types.

Other important works on the pollen morphology of species of the subfamily include Erdtman (1952Erdtman G. 1952. Pollen morphology and plant taxonomy - angiosperms. Stockholm, Almqvist and Wiksell. ), who analyzed 90 species of 20 genera, including species of the Brazilian flora. Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.), as previously mentioned, used pollen characters in the taxonomic study of the genus Bombax, including species of Eriotheca, Pachira, Pseudobombax, Bombacopsis and Rhodognaphalopsis. Using scanning electron microscopy, Robyns (1971) Robyns A. 1971. On pollen morphology of Bombacaceae. Bulletin du Jardin Botanique National de Belgique 41: 451-456.recognized pollen types that differed with regard to apertures, amb and sexine stratification. Tsukada (1964Tsukada M. 1964. Pollen morphology and identification III. Modern and fossil tropical pollen with emphasis on Bombacaceae. Pollen et Spores 6: 393-462.) highlighted the importance of representatives of Bombacoideae in stratigraphic studies when analyzing the pollen morphology of fossil and extant species. Sowunmi (1973Sowunmi MA. 1973. Pollen grains of Nigerian plants. I. Woody species. Grana 13: 145-186.), Lozano-García & Hernández (1990Lozano-García MS, Hernández EM. 1990. Palinologia de la Estación de Biología Tropical Los Tuxtlas: Parte I - especies arbóreas. México, Instituto de Geologia, UNAM - Universidad Nacional Autónoma de México. ) and Palacios-Chávez et al. (1991Palacios-Chávez R, Ludlow-Wiechers B, Villanueva RG. 1991. Flora palinologica de la reserva de la biosfera de Sian Ka’an Quintana Roo, Mexico. Chetumal, Centro de Investigações de Quintana Roo. ) included morphological descriptions of the pollen of species of Bombacoideae in their works. Moncada & Sotolongo (1994Moncada M, Sotolongo L. 1994. Morfología de los granos de polen en géneros de Bombacaceae en Cuba. Acta Botánica Cubana 97: 1-7.) described four pollen types for the genera that occur in Cuba.

Brazilian works of significance include that of Salgado-Labouriau (1973)Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. , who recognized four pollen types for Cerrado species; Melhem & Bissa (1985Melhem TS, Bissa WM. 1985. Flora polínica da reserva do parque Estadual das Fontes do Ipiranga (São Paulo, Brasil). Famílias: 35-Dilleniaceae, 38-Theaceae e 46-Bombacaceae. Hoehnea 12: 5-9.), who analyzed the pollen morphology of Pseudobombax grandiflorum; Bove (1993Bove CP. 1993. Catálogo sistemático do pólen das plantas arbóreas do Brasil meridional - XXVII - Bombacaceae, Caprifoliaceae e Sytracaceae. Revista Brasileira de Biologia 53: 87-101.) who described the pollen grains of Pseudobombax, Bombacopsis, Pachira and Spirotheca, which occur in the state of Santa Catarina, grouping them into two pollen types and three pollen subtypes; Carreira et al. (1995Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.), who analyzed the pollen grains of species of Bombacoideae growing in the park of the Goeldi Museum and presented a pollen key based on apertural type and exine ornamentation; and Abreu et al. (2014Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.), who analyzed eleven species, separating them by a pollen key that considers the presence or absence of callote. It should be noted that most descriptions were made using light microscopy (LM), with scanning electron microscopy (SEM) being used only in the last three cited works.

The present work aimed to describe the pollen morphology of Brazilian species of Bombacoideae with the aim of expanding palynological knowledge of species of this subfamily.

Materials and methods

Pollen grains of 15 species belonging to five genera representative of Brazilian Bombacoideae were examined using light and electron microscopy. Anthers were removed from specimens deposited in the herbaria ALCB, EAC, HST, HUEFS, IPA, PEUFR, SP, SPF and TEPB, all acronyms according to Thiers (2017Thiers B. 2017. [continuously updated]. Index Herbariorum: a global directory of public herbaria and associated staff. New York Botanical Garden’s Virtual Herbarium. http://sweetgum.nybg.org/ih/. 15 Nov. 2018.
http://sweetgum.nybg.org/ih/... , continuously updated) (Tab. 1).

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Table 1
Species used in the morphological analysis of pollen grains of Bombacoideae. *Material used in photomicrographs and electromicrographs.

For light microscopy (LM), pollen material was acetolyzed (Erdtman 1960Erdtman G. 1960. The acetolysis method. A revised description. Svensk Botanisk Tidskrift 54: 561-564.), mounted on slides with glycerinated gelatin, sealed with paraffin and analyzed and photomicrographed using a Zeiss Axiostar microscope. The slides were deposited in the pollen collection of Laboratório de Micromorfologia Vegetal (LAMIV) of Universidade Estadual de Feira de Santana. Measurements of the main morphometric parameters (equatorial and polar diameters) were made on 25 pollen grains, whenever possible. Other parameters (diameter of apertures and thickness of exine, sexine and nexine) were measured for 10 randomly-chosen pollen grains. All exine measurements were taken in the mesocolpium region. Quantitative data were submitted statistical analyses adequate for the sample size. The arithmetic mean (x̄), standard deviation of the mean (Sx̄ ), 95 % confidence interval (CI) and coefficient of variation (CV) were calculated for all of the diameter measurements with a sample size of 25, while only the arithmetic mean was calculated for parameters with a sample size less than 25.

Principal component analysis (PCA) using PC-ORD 5.0 software (McCune & Mefford 2011McCune B, Mefford MJ. 2011. PC-ORD. Multivariate analysis of ecological data. Version 5. Gleneden Beach, MjM Software.) was used to identify the palynological variables that best contribute to the distinction of the studied species. This analysis used ten metric variables: polar diameter in equatorial view (P), equatorial diameter in polar view (E), equatorial diameter in equatorial view (Epv), shape (P/E), polar area index (AI), ectoaperture length (EcL), ectoaperture width (EcW), endoaperture height (Eh) and thickness of exine (Ex), nexine (Nex) and sexine (Sex). The results were observed in a biplot graph built from the two first principal components (PC1 and PC2) derived from the PCA.

For scanning electron microscopy (SEM), acetolyzed pollen grains were washed in distilled water, dehydrated in an ascending hydroethanolic series (50, 70, 80, 90 and 100 %), mounted on a SEM specimen holder, metallized with gold, and electron micrographed using a LEO 1430 VP Electron Microscope of the Departamento de Ciências Biológicas of the Universidade Estadual de Feira de Santana.

Ceiba erianthos (Cav.) K. Schum. was selected, because of the availability of material, for analysis using transmission electron microscopy (TEM). Closed anthers were fixed in glutaraldehyde (2.5 %) with 0.1 M sodium phosphate solution at pH 7.4, post-fixed in 1 % osmium tetroxide (OsO₄), dehydrated in an ascending acetone series (30, 50, 70, 90 and three baths at 100 % for 30 min each bath) and included in EPON resin. Sections made using an Ultracut E ultramicrotome equipped with a diamond razor were contrasted with 7 % aqueous uranyl acetate and lead citrate for observation using a Zeiss M 109 microscope of the Electron Microscopy Laboratory of the Gonçalo Moniz Research Center - Oswaldo Cruz Foundation.

The terminology adopted is in accordance with Punt et al. (2007Punt W, Hoen PP, Blackmore S, Nilson S, Thomas A. 2007. Glossary of pollen and spore terminology. Review of Palaeobotany and Palynology 143: 1-81.). The denomination ‘equatorial calotte’ is in agreement with the definition of Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.).

Results

Pollen grains of the studied species of Bombacoideae are characterized as medium to large in size, isopolar, oblate to suboblate with a (sub)circular and (sub)triangular amb (planaperturate) and a small to large polar area; 3-4-5(-6)-zonoaperturate, colpate, colporate, equatorial calottes different or not, exine tectate-perforate to microreticulate, reticulate with or without supratectal processes and sexine thicker than nexine.

Table 2 summarizes the quantitative pollen characters of the investigated specimens. Figures 1-5 illustrate morphopalynous characteristics.

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Table 2
Pollen morphometric characteristics and measurements (μm) for species of Bombacoideae (Malvaceae s.l.): polar axis (P), equatorial axis (E), equatorial axis in polar view (Epv), polar axis/equatorial axis (P/E), range (R), apocolpium index (AI), ectoaperture length x ectoaperture width (Ec), endoaberture height (Eh), sexine (Sex), nexine (Nex), * n < 25.

Ceiba erianthos (Cav.) K. Schum. (Fig. 1A-E); C. glaziovii (Kuntze) K. Schum. (Fig. 1F-K)

Figure 1
Pollen grains of species of Ceiba Mill. A-E. C. erianthos K. Schum. A. Optical section in polar view. B. LO-analysis. C. Optical section in equatorial view. D. Surface detail (SEM). E. Detail of murus structure in cross-section (SEM). F-L. C. glaziovii (Kuntze) K. Schum. F. Optical section in polar view. G. LO-analysis. H. Detail of aperture and surface. I. Polar view (SEM). J. Surface detail (SEM). K. Aperture detail (SEM). (t = tectum, c = columella, b = basal layer, i = intine)

Pollen grains large; oblate to suboblate; isopolar; amb circular; 4-5(-6)-zonocolporate. Ectoapertures long with sharp ends; endoapertures lalongate, circular or less frequent lalongate; membrane psilate-aperturate. Exine semitectate, reticulate, heterobrochate. Muri high, sinuous, simple to dupli-columellate. Sexine thicker than nexine.

In addition to the 4-5-aperturate pollen grains, 6-aperturate pollen grains (Fig. 1A) were recorded in the specimen Andrade-Lima 8145 of C. erianthos (ca. 6 %) and in the specimen Oliveira 258 of C. glaziovii (ca. 11 %). The endoaperture is difficult to visualize in C. erianthos; it was lolongate in most specimens analyzed but specimens with circular (Fig. 1H) or lalongate endapertures could also be found.

The lumina of the reticulum are irregular, gradually decreasing in size from the apocolpium to the mesocolpium; free bacula and granules could be identified using SEM (Fig. 1D; 1J). Branched muri of the reticulum supported by oblique columellae could also be observed using SEM (Fig. 1D, 1I, 1J).

The TEM analysis (Fig. 1E) of C. erianthos, which is the first for the species, revealed stratification of the exine consisting of a semitectum, which is as thick as the nexine (referring to the basal layer plus endexine, layers which were not discernible by the methodology used), supported by short columellae, and the intine, which is thicker and stratified under the apertures.

Eriotheca candolleana (K. Schum.) A. Robyns (Fig. 2A-E); E. macrophylla (K. Schum.) A. Robyns (Fig. 2F-H); E. gracilipes (K. Schum.) A. Robyns (Fig. 2I-J); E. obcordata A. Robyns (Fig 2K-L)

Figure 2
Pollen grains of species of Eriotheca Schott & Endl. A-E. E. candolleana (K. Schum.) A. Robyns- A. Optical section in polar view. B. LO-analysis. C. Aperture and surface in equatorial view. D. Polar view (SEM). E. Surface detail (SEM). F-H. E. macrophylla (K. Schum.) A. Robyns- F. Optical section in polar view. G. LO-analysis. H. Detail of aperture (SEM). I-J. E. gracilipes (K. Schum.) A. Robyns- I. Polar view (SEM). J. Surface detail (SEM). K-L. E. obcordata A. Robyns. K. Optical section in polar view. L. LO-analysis.

Pollen grains medium to large in size; oblate; isopolar; amb (sub)triangular with flat to convex sides; equatorial calottes undifferentiated; 3(-4)-colporate; planaperturate. Ectoapertures short and narrow with sharp ends; endoapertures lolongate and lalongate; membrane psilate-aperturate. Exine semitectate, reticulate, heterobrochate, lumina polyhedral with free granules in the interior; muri high, smooth and simplicolumellate. Sexine thicker than nexine.

The pollen grains of species of Eriotheca are uniform in size (Tab. 2). The largest pollen grains (52.5 μm) were observed for E. obcordata; however, the average size class was predominant among the analyzed specimens. The amb varied between subtriangular and triangular, with the latter predominating. The 4-aperturate pollen grains (Fig. 2F) had a subcircular amb. 4-aperturate pollen grains were recorded in one specimen of E. candolleana (Monteiro 23510) and for specimens of E. macrophylla; however, the specimen Lima 12632 had the most significant percentage of 4-aperturate pollen grains with 12.7 %, while other specimens had 2 % or less. All specimens analyzed of E. gracilipes had 3-aperturate pollen. The ectoapertures were short and narrow, sometimes hindering visualization of endoapertures under LM, which was characterized as lolongate in E. candolleana, E. gracilipes and E. macrophylla, and lalongate with straight to concave upper and inferior margins in E. obcordata. Using SEM, it was possible to detect the presence of heterogeneously-sized granules in the reticulum lumina of the specimens analyzed (Fig. 2J). The smooth surface of muri was also observed with SEM.

Pachira aquatica Aubl. (Fig. 3A-D); P. nervosa (Uitt.) Fernández-Alonso (Fig. 3E-F); P. retusa (Mart. &Zucc.) Fernández-Alonso (Fig. 3G-J); P. tocantina (Ducke) Fernández-Alonso (Fig. 3K-L)

Figure 3
Pollen grains of Pachira Aubl. A-D. P. aquatica Aubl.- A. Optical section in polar view. B. Optical section in equatorial view. C. Polar view (SEM). D. Detail of surface and aperture (SEM). E-F. P. nervosa (Uitt.) Fernández-Alonso- E. Polar view (SEM). F. Detail of aperture (SEM). G-J. P. retusa (Mart & Zucc.) Fernández-Alonso- G. Optical section in polar view. H. Optical section in equatorial view. I. Surface detail (SEM). J. Structure of exine with forked columella (arrow) (SEM). K-L. P. tocantina (Ducke) Fernández-Alonso- K. Polar view (SEM). L. Structure of exine with forked columellae (arrows) (SEM).

Pollen grains large; oblate to suboblate; isopolar; amb triangular, less frequently quadrangular, with flat to slightly convex sides; equatorial calottes separate, protrusions with rounded angles; planaperturate; 3-colp(or)ate, sometimes 4-colporate; costate and with differentiated margin. Ectoapertures short with sharp ends; endoapertures lolongate, sometimes difficult to visualize. Exine reticulate and heterobrochate in the polar and apertural regions, psilate-perforate, microreticulate in the equatorial calottes. Muri thin to wide, simplicolumellate to duplicolumellate, with simple and digitate columellae, anastomosed, with supratectal protrusions. Sexine thicker than nexine.

Morphologically, the pollen grains of the studied species of Pachira are similar. There was a predominance of 3-aperturate pollen grains; 4-colporate (7 %) pollen grains were found only in the examined specimen of P. nervosa. The aperture was well defined in P. aquatica, with a margin devoid of ornamentation (Fig. 3D); the aperture was difficult to visualize in the other species using LM, with continuous ornamentation up to the apertural region, without a differentiated margin. The endoapertures were lolongate with an irregular outline, and were difficult to visualize in some of the analyzed specimens. It was not possible to measure the endoaperture of all of the analyzed specimens of P. retusa, since most pollen grains were kneaded making it difficult to visualize the endoaperture (Fig. 3H). The surface of pollen grains had reticulate ornamentation in polar and apertural regions, with irregular lumina and ornate muri, but differing in the equatorial calottes where it was psilate-perforate (SEM). There were concentrated perforations towards the reticulate regions (Fig. 3C-D) in P. aquatica, and microreticulate in the other species (Fig. 3E).

The SEM examination revealed longitudinally-elongated supratectate protrusions, with predominantly rounded apices, starting from the point of intersection of the reticulate muri in P. aquatica (Fig. 3C, 3D), characterizing a "cristate reticulum" sensuHesse et al. (2009Hesse M, Halbritter H, Zetter R, et al. 2009. Pollen terminology: an illustrated handbook. Wien, Springer-Verlag.). In the other species, the branched columellae (Fig. 3J, L) fuse distally, forming supratectate structures of varied shapes (Fig. 3F, I). Granules were observed by SEM inside the lumina of P. nervosa (Fig. 3F). The sexine was thicker than the nexine in all specimens (Tab. 2), with the largest difference being for a specimen of P. tocantina, for which the sexine measured 2.3 μm and the nexine measured 0.6 μm.

Pseudobombax calcicola Carv.-Sobr. & Queiroz LP (Fig. 4A-E); Ps. marginatum (A. St.-Hil., A. Juss. & Cambess.) A. Robyns (Fig. 4F-I); Ps. minimum Carv.-Sobr. & LP Queiroz (Fig. 4J-N); Ps. simplicifolium A. Robyns (Fig. 4O-Q)

Figure 4
Pollen grains of species of Pseudobombax Dugand. A-E. Ps. calcicola Carv.-Sobr. & L.P. Queiroz - A. Optical section in polar view. B. LO-analysis C. Optical section in equatorial view. D. Polar view (SEM). E. Structure of exine (SEM). F-I. Ps. marginatum (A. St.-Hil., A. Juss. & Cambess.) A. Robyns- F. Optical section in polar view. G. Analysis of L.O. H. Aperture and surface in equatorial view. I. Detail of aperture (SEM). J-N. Ps. minimum Carv.-Sobr. & L.P. Queiroz - J. Optical section in polar view. K. LO-analysis L. Detail of aperture (SEM). M. Surface detail (SEM). N. Structure of exine (SEM). O-Q. Ps. simplicifolium A. Robyns- O. Optical section in equatorial view, detail of the aperture in the upper right corner (SEM). P. Polar view (SEM). Q. Surface detail (SEM).

Pollen grains large, oblate, isopolar; amb triangular with flat to slightly concave sides; equatorial calottes slightly to very evident, with rounded angles; 3-colp(or)ate; planaperturate; costate. Ectoapertures short and long with rounded ends; endoapertures lolongate when present. Exine reticulate, heterobrochate, with circular to elongated lumina in the polar region and around the apertures with granules in the interior, psilate, granulate and microreticulate in the mesocolpium region and colpus margin. Muri wide, smooth and perforated, single-, dupli- or less frequent pluricolumellate, with distinct columellae using optical (LM), and short and wide columellae using SEM. Sexine thicker than nexine.

The pollen grains of most of the analyzed species were homogeneous in shape, size and amb, with the exception of Ps. calcicola, which reached a size of up to 100 μm (Tab. 2).

As for apertures, colporate pollen grains were observed in Ps. marginatum, Ps. simplicifolium and Ps. minimum, but it was not possible to measure the endoapertures in any of the analyzed specimens of the latter two species. The endoaperture was characterized as circular or lolongate in most of the analyzed specimens, but difficult to visualize using light microscopy (Fig. 4H, 4O). A differentiated margin was noted using SEM (Fig. 4I). The pollen grains of specimen Figueiredo et al. 175 of Ps. marginatum and the analyzed specimen of Ps. calcicola were characterized as colpate.

The ornamentation of the exine is reticulate with circular to elongated lumina in the polar region and around the apertures. Using SEM, the exine was observed to be psilate in the equatorial calotte in Ps. Calcicola and Ps. Simplicifolium, finely granulate and irregularly perforate in Ps. Marginatum, and microreticulate in Ps. Minimum. The reticulum of Ps. minimum had comparatively smaller lumina, uniform up to the apertural region, without a differentiated margin (Fig. 4L).

With SEM it was possible to observe few and spaced perforations in the reticulum muri (Fig. 4L, M, Q). Figures 4E and 4N show how the tectum is supported by large and short columellae that form single rows, double rows or more rarely several rows (Fig. 4G) under the muri.

The sexine was much thicker than nexine in all the studied species. Using SEM, short columellae and the inner surface of the rough nexine could be observed for Ps. minimum (Fig. 4N) and an undulate nexine for Ps. calcicolate (Fig. 4E).

Rhodognaphalopsis faroensis (Ducke) A. Robyns (Fig. 5A-G)

Figure 5
A-G. Pollen grains of Rhodognaphalopsis faroensis (Ducke) A. Robyns- A. Optical section in polar view. B. LO-analysis C. Detail of aperture. D. Optical section of aperture. E. Polar view (SEM). F. Surface detail (SEM). G. Equatorial View (SEM).

Pollen grains large; oblate; isopolar; amb triangular with concave sides; 3-colporate; costate. Ectoapertures short with rounded ends; endoapertures lalongate with concave upper and lower margins. Exine microreticulate-echinate using LM, tectate-perforate with supratectate protrusions with cylindrical and conical shapes and heterogeneous sizes and diameters using SEM. Sexine thicker than nexine.

The ectoapertures were observed to be short, narrow, with a regular outline and rounded ends, and without a differentiated margin using LM and SEM (Fig. 5C, G). The endoaperture was lalongate with concave upper and lower margins while the extremeties were difficult to view. Figure 5D shows the costae of the pollen grains of the studied species.

LO-analysis (Fig. 5B) revealed a tectum with a pattern similar to that of a microreticulum. Higher amplifications using SEM, however, revealed the presence of perforations of varied diameter and shape (spherical and elongated) concentrated in the polar region. The supratectate protrusions also varied in shape and diameter, with cylindrical protrusions with rounded ends and conical protrusions with a sharp end (Fig. 5E-G).

Principal component analysis

The first two axes of the PCA explained 85.43 % of the total variance (Fig. 6). The first axis (PC1) explained 75.66 % of the total variance with ectoaperture length (EcL) and width (EcW) being the most significant variables, followed equatorial diameter in polar view (E) (Tab. 3). The species of Pseudobombax (Ps. calc, Ps. simp, Ps. marg, Ps. mini) and Paquira aquatica (Pa. aqua) were grouped having the highest values for these variables of the first axis. In contrast, species of Eriotheca (Er. macr, Er. obco, Er. cand, Er. grac.) were grouped on the opposite side with lower values of E, EcL and EcW. The second axis (PC2) explained 9.77 % of the total variance, with sexine (Sex) and exine (Ex) being the most significant variables (Tab. 3). The variables polar area index (AI) and nexine (Nex) were correlated with the second axis. The taxa in the bottom left quadrant have lower values for AI (Fig. 6).

Figure 6
Principal component analysis performed with the pollen metrical variables of Brazilian species of Bombacoideae. Ce. eria = Ceiba erianthos, Ce glaz = C. glaziovii, Er. cand = Eriotheca candolleana, Er. grac = E. gracilipes, Er. macr = E. macrophylla, Er. obco = E. obcordata, Pa. aqua = Pachira aquatica, Pa. nerv = P. nervosa, Pa. retu = P. retusa, Pa. toca = P. tocantina, Ps. calc = Pseudobombax calcicola, Ps. marg = Ps. marginatum, Ps. mini = Ps. minimum, Ps. simp = Ps. simplicifolium, Rh. faro = Rhodognaphalopsis faroensis.

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Table 3
Pearson and Kendall correlation coefficients for pollen metrical variables of the first and the second axis of PCA ordination of species of Bombacoideae.

Discussion

Data reported in the literature for other species of Ceiba have revealed that, in addition to having a reticulum and gems and piles, sculptural elements such as the exine may also be present (Erdtman 1952Erdtman G. 1952. Pollen morphology and plant taxonomy - angiosperms. Stockholm, Almqvist and Wiksell. ; Palacios-Chavez et al. 1991Palacios-Chávez R, Ludlow-Wiechers B, Villanueva RG. 1991. Flora palinologica de la reserva de la biosfera de Sian Ka’an Quintana Roo, Mexico. Chetumal, Centro de Investigações de Quintana Roo. ). Using SEM, Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.) described for this genus the presence of clava or bacula-like processes in the reticulum lumina, in addition to ramified muri supported by oblique columellae, as was corroborated by the present study. Abreu et al. (2014Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.) also recorded elements of ornamentation in the lumina of C. erianthos.

The results obtained in this research regarding aperture type are in agreement with data found in the literature for this genus, except for the number of apertures. The 3-aperture condition cited by Erdtman (1952Erdtman G. 1952. Pollen morphology and plant taxonomy - angiosperms. Stockholm, Almqvist and Wiksell. ), Tsukada (1964Tsukada M. 1964. Pollen morphology and identification III. Modern and fossil tropical pollen with emphasis on Bombacaceae. Pollen et Spores 6: 393-462.), Sowunmi 1973Sowunmi MA. 1973. Pollen grains of Nigerian plants. I. Woody species. Grana 13: 145-186.), Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.), Palacios-Chavez et al. (1991Palacios-Chávez R, Ludlow-Wiechers B, Villanueva RG. 1991. Flora palinologica de la reserva de la biosfera de Sian Ka’an Quintana Roo, Mexico. Chetumal, Centro de Investigações de Quintana Roo. ), Moncada & Sotolongo (1994Moncada M, Sotolongo L. 1994. Morfología de los granos de polen en géneros de Bombacaceae en Cuba. Acta Botánica Cubana 97: 1-7.), Carreira et al. (1995Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.), and Abreu et al. (2014Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.) for other species of the genus, was not observed in any of the specimens analyzed here.

There are no data in the literature on the ultrastructure of pollen grains of other species of Bombacoideae. However, some of the data presented here for Ceiba erianthos (e.g., short columellae and thicker intine at the apertural region) are in agreement with those reported for other species of Malvaceae s.l. (Saba & Santos 2015Saba MD, Santos FAR. 2015. Pollen morphology and exine ultrastructure of selected species of Waltheria L. (Byttnerioideae-Malvaceae). Review of Palaeobotany and Palynology 221: 204-210.; Silveira-Júnior et al. 2015Silveira-Júnior CEA, Lima LLC, Saba MD. 2015. Palynological study of heterostylous species of Melochia L. (Byttinerioideae-Malvaceae) occurring in Bahia, Brazil. Review of Palaeobotany and Palynology 221: 192-203.; 2017Silveira-Júnior CEA, Lima LLC, Saba MD. 2017. Pollen morphology of Waltheria L. (Malvaceae-Byttnerioideae) from Bahia, Brazil. Acta Botanica Brasilica 31: 597-612.).

Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.) and Salgado-Labouriau (1973)Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. described the pollen grains of the species of Eriotheca studied here and reported similar pollen characteristics. However, these authors referred to duplicolumellate muri, rarely pluricolumellate, for E. candolleana (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.) and E. gracilipes (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.; Salgado-Labouriau 1973Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. ). Furthermore, the colpate pollen grains described by Robyns (1963)Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311. for E. macrophylla (crenulaticalyx) are not in accordance with the data presented here. Visualization of the endoaperture is very difficult by LM, but the SEM analysis of the present work was able to confirm its presence.

For Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.), species of Eriotheca, including the species studied here, along with species of the genera Aguiaria , Pachira (Bombacopsis), Pseudobombax and Spirotheca, comprise the Bombax pollen type. The data presented here are in agreement with those presented by these authors with the exception of the pattern of rugulate ornamentation of the exine, which was not observed in any of the species analyzed here. Abreu et al. (2014Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.) recorded perforations in the reticulum muri of E. pentaphylla, which were not observed in the present study. The other characteristics reported by Abreu et al. (2014)Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360. are consistent with the data presented here.

Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.) and Salgado-Labouriau (1973)Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. described the pollen grains of Pachira retusa and P. tocantina as colpate and colporate, respectively. These data differ from those presented here, which may be explained by the lolongate type of endoapertures, which was difficult to visualize in the analyzed species, and by the kneaded condition of the majority of pollen grains after acetolysis. The authors did not mention the presence of costae, as evidenced here for P. nervosa.

Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.) and Moncada & Sotolongo (1994Moncada M, Sotolongo L. 1994. Morfología de los granos de polen en géneros de Bombacaceae en Cuba. Acta Botánica Cubana 97: 1-7.) using LM, and Carreira et al. (1995Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.) using SEM, reported the presence of spines in equatorial calottes. Such elements were not observed in any of the specimens analyzed here. The equatorial calottes of the analyzed specimens of P. tocantina were less prominent than those of the other studied species.

Specialized literature includes references of pollen grains with spinous processes for the species studied here (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.; Tsukada 1964Tsukada M. 1964. Pollen morphology and identification III. Modern and fossil tropical pollen with emphasis on Bombacaceae. Pollen et Spores 6: 393-462.; Nilson & Robyns 1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.; Moncada & Sotolongo 1994Moncada M, Sotolongo L. 1994. Morfología de los granos de polen en géneros de Bombacaceae en Cuba. Acta Botánica Cubana 97: 1-7.) as well as for other species of Pachira (Salgado-Labouriau 1973Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. ; Nilson & Robyns 1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.; Bove 1993Bove CP. 1993. Catálogo sistemático do pólen das plantas arbóreas do Brasil meridional - XXVII - Bombacaceae, Caprifoliaceae e Sytracaceae. Revista Brasileira de Biologia 53: 87-101.). Supratectate protrusions were observed for the species studied here, but they were not considered spinous processes. Carreira et al. (1995Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.) did not refer to such structures.

The species of Pachira studied by Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.) were included in the Bombax pollen type, which is characterized as 3(-4)-colp(or)ate, rarely porate, reticulate, microreticulate to rarely tectate-perforated, equinate, and rarely rugulate. Most of the pollen traits presented by these authors were corroborated by the present study, with the exception of the presence of equinate and rugulate pollen grains, which was not observed in the specimens analyzed here.

The occurrence of colpate and colporate pollen grains in the same species of Pseudobombax was reported in the literature by Robyns (1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.) and Salgado-Labouriau (1973)Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. using LM. Considering the difficulty of visualizing the endoaperture using LM, identifications of apertural type in some of the descriptions presented for species of this genus may be mistaken.

According to Nilson & Robyns (1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.), in addition to the presence of a reticulum and microreticulum, rugulae can also be present as sculptural elements of pollen grains of species of Pseudobombax. Pollen data in the literature for Ps. simplicifolium and Ps. marginatum (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.; Salgado-Labouriau 1973Salgado-Labouriau ML. 1973. Contribuição à palinologia dos cerrados. Rio de Janeiro, Academia Brasileira de Ciências. ; Nilson & Robyns 1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.; Abreu et al. 2014Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.), and for other species of the genus (Tsukada 1964Tsukada M. 1964. Pollen morphology and identification III. Modern and fossil tropical pollen with emphasis on Bombacaceae. Pollen et Spores 6: 393-462.; Melhem & Bissa 1985Melhem TS, Bissa WM. 1985. Flora polínica da reserva do parque Estadual das Fontes do Ipiranga (São Paulo, Brasil). Famílias: 35-Dilleniaceae, 38-Theaceae e 46-Bombacaceae. Hoehnea 12: 5-9.; Bove 1993Bove CP. 1993. Catálogo sistemático do pólen das plantas arbóreas do Brasil meridional - XXVII - Bombacaceae, Caprifoliaceae e Sytracaceae. Revista Brasileira de Biologia 53: 87-101.; Moncada & Sotolongo 1994Moncada M, Sotolongo L. 1994. Morfología de los granos de polen en géneros de Bombacaceae en Cuba. Acta Botánica Cubana 97: 1-7.), were corroborated by the present study.

Data reported in the literature (Robyns 1963Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311.; Nilson & Robyns 1986Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59.) on the pollen morphology of Rhodognaphalopsis are consistent those of presented here for most morphopalynous characters. However, the 4-aperturate and colpate type of aperture described by Nilson & Robyns (1986)Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59., and the type of endoaperture observed by Robyns (1963)Robyns A. 1963. Essai de Monographie du genre Bombax L. s.l. (Bombacaceae). Bulletin du Jardin Botanique de l’État à Bruxelles 33: 1-311. and Nilson & Robyns (1986)Nilson S, Robyns A. 1986. Bombacaceae Kunth. World Pollen and Spore Flora 14:1-59., were not observed in any of the specimens analyzed here.

The data obtained in the present study confirmed the heterogeneous nature of the pollen of representatives of Bombacoideae. Ornamentation type was found to be an important character for recognizing the studied species of this subfamily. Rhodognaphalopsis differs by having perforate to microreticulate pollen grains with cylindrical and conical supratectate protrusions, while other genera have a foveolate sexine. Pseudobombax and Pachira both have pollen grains with differentiated equatorial calottes, as well as a triangular amb and a planaperture-type of aperture, however, the reticulum of the analyzed species of these genera differs. The ordering of species by PCA confirmed the separation of the studied species of Bombacoideae using only quantitative variables of the pollen grains. Some attributes show potential usefulness for characterizing species, such as equatorial diameter and sexine thickness. In conclusion, morphological and morphometric pollen data provided useful information for distinguishing the studied species, and can contribute substantially to understanding the diversity and relationships among genera and species of the subfamily Bombacoideae.

Acknowledgements

The authors would like to thank the curators of herbaria for authorizing the collection of botanical material; researchers Marcos André Vannier and Cláudio Pereira from the Centro de Pesquisa Gonçalo Muniz - Instituto Oswaldo Cruz (FIOCRUZ), for authorizing and assisting with SEM analysis; and CNPq for research support to FARS.

References

Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.
Alverson WS, Whitlock BA, Nyffeler R, Bayer C, Baum DA. 1999. Phylogeny of the core Malvales: evidence from ndhF sequence data. American Journal of Botany 86: 1474-1486.
Baum DA, Smith SD, Yen A, et al 2004. Phylogenetic relationships of Malvatheca (Bombacoideae and Malvoideae; Malvaceae sensu lato) as inferred from plastid DNA sequences. American Journal of Botany 91: 1863-1871.
Bayer C, Fay MF, Bruijn AY, et al 1999. Support for an expanded family concept of Malvaceae within a recircunscribed order Malvales: a combined analysis of plastid atpB and rbcL DNA sequences. Botanical Journal of the Linnean Society 129: 267-303.
Bove CP. 1993. Catálogo sistemático do pólen das plantas arbóreas do Brasil meridional - XXVII - Bombacaceae, Caprifoliaceae e Sytracaceae. Revista Brasileira de Biologia 53: 87-101.
Braga RP. 1960. Plantas do Nordeste, especialmente do Ceará. 4th. edn. Natal, Ed. Universitária UFRN.
Candolle AP. 1824. Bombacaceae. Prodromus Systematis Naturalis Regni Vegetabilis. Vol. 1. Paris, Caprelet.
Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.
Carvalho-Sobrinho JG, Alverson WS, Alcantara S, Queiroz LP, Mota AC, Baum D A. 2016. Revisiting the phylogeny of Bombacoideae (Malvaceae): Novel relationships, morphologically cohesive clades, and a new tribal classification based on multilocus phylogenetic analyses. Molecular Phylogenetics and Evolution 101: 56-74.
Cronquist A. 1981. An integrated system of classification of flowering plants. New York, Columbia University Press.
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Erdtman G. 1960. The acetolysis method. A revised description. Svensk Botanisk Tidskrift 54: 561-564.
Fuchs HP. 1967. Pollen morphology of the family Bombacaceae. Review of Palaeobotany and Palynology 3: 119-132.
Hesse M, Halbritter H, Zetter R, et al 2009. Pollen terminology: an illustrated handbook. Wien, Springer-Verlag.
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Publication Dates

Publication in this collection
20 Mar 2020
Date of issue
Jan-Mar 2020

History

Received
04 July 2019
Accepted
18 Sept 2019

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

[1] Abreu VHR, Mendonça CBF, Gonçalves-Esteves V. 2014. Pollen morphology of selected species of the subfamily Bombacoideae (Malvaceae sensu lato). Acta Botanica Brasilica 28: 352-360.

[2] Alverson WS, Whitlock BA, Nyffeler R, Bayer C, Baum DA. 1999. Phylogeny of the core Malvales: evidence from ndhF sequence data. American Journal of Botany 86: 1474-1486.

[3] Baum DA, Smith SD, Yen A, et al 2004. Phylogenetic relationships of Malvatheca (Bombacoideae and Malvoideae; Malvaceae sensu lato) as inferred from plastid DNA sequences. American Journal of Botany 91: 1863-1871.

[4] Bayer C, Fay MF, Bruijn AY, et al 1999. Support for an expanded family concept of Malvaceae within a recircunscribed order Malvales: a combined analysis of plastid atpB and rbcL DNA sequences. Botanical Journal of the Linnean Society 129: 267-303.

[5] Bove CP. 1993. Catálogo sistemático do pólen das plantas arbóreas do Brasil meridional - XXVII - Bombacaceae, Caprifoliaceae e Sytracaceae. Revista Brasileira de Biologia 53: 87-101.

[6] Braga RP. 1960. Plantas do Nordeste, especialmente do Ceará. 4th. edn. Natal, Ed. Universitária UFRN.

[7] Candolle AP. 1824. Bombacaceae. Prodromus Systematis Naturalis Regni Vegetabilis. Vol. 1. Paris, Caprelet.

[8] Carreira LMM, Raposo RCO, Lobato ESP. 1995. Morfologia polínica de plantas cultivadas no Parque do Museu Goeldi. VII - Família Bombacaceae. Boletim do Museu Paraense Emílio Goeldi, Série Botânica 11: 275-293.

[9] Carvalho-Sobrinho JG, Alverson WS, Alcantara S, Queiroz LP, Mota AC, Baum D A. 2016. Revisiting the phylogeny of Bombacoideae (Malvaceae): Novel relationships, morphologically cohesive clades, and a new tribal classification based on multilocus phylogenetic analyses. Molecular Phylogenetics and Evolution 101: 56-74.

[10] Cronquist A. 1981. An integrated system of classification of flowering plants. New York, Columbia University Press.

[11] Erdtman G. 1952. Pollen morphology and plant taxonomy - angiosperms. Stockholm, Almqvist and Wiksell.

[12] Erdtman G. 1960. The acetolysis method. A revised description. Svensk Botanisk Tidskrift 54: 561-564.

[13] Fuchs HP. 1967. Pollen morphology of the family Bombacaceae. Review of Palaeobotany and Palynology 3: 119-132.

[14] Hesse M, Halbritter H, Zetter R, et al 2009. Pollen terminology: an illustrated handbook. Wien, Springer-Verlag.

[15] Kunth KS. 1821. Bombacaceae. In: Humbold A, Bonpland A, Kunth KS. (eds.) Nova genera et species plantarum. Vol. 5. Antverpiae, Ex officina Christophori Plantini. p. 294-308.

[16] Lorenzi H. 2002a. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Vol. 1. Nova Odessa, Ed. Plantarum.

[17] Lorenzi H. 2002b. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil . Vol. 2. Nova Odessa, Ed. Plantarum .

[18] Lozano-García MS, Hernández EM. 1990. Palinologia de la Estación de Biología Tropical Los Tuxtlas: Parte I - especies arbóreas. México, Instituto de Geologia, UNAM - Universidad Nacional Autónoma de México.

[19] Maia GN. 2004. Caatinga: árvores e arbustos e suas utilidades. São Paulo, D & Z Computação Gráfica e Editora.

[20] McCune B, Mefford MJ. 2011. PC-ORD. Multivariate analysis of ecological data. Version 5. Gleneden Beach, MjM Software.

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Species	Voucher	Herbarium
Ceiba erianthos K. Schum	Andrade-Lima 8145, Harley & Giulietti 54045, Guedes & Eudes 4839	IPA*, HUEFS, ALCB
C. glaziovii (Kuntze) K. Schum.	Queiroz et al. 997, Oliveira 258, Lyra-Lemos et al. 7030	HUEFS, HUEFS, HUEFS*
Eriotheca candolleana (K. Schum.) A. Robyns	Monteiro 23510, Pirani et al. 4356	PEUFR*, SPF
E. gracilipes (K. Schum.) A. Robyns	Andrade-Lima 5491	IPA*
E. macrophylla (K. Schum.) A. Robyns	Lima 12632, Ducke & Lima 65	HST*, IPA
E. obcordata A. Robyns	Silva et al. 107	HUEFS
Pachira aquatica Aubl.	Miranda 72, Fróes 26.629, Alunos de Taxonomia da FUFPI s.n.	HUEFS, SP*, TEPB 450
P. nervosa (Uitt.) A. Robyns	Esteves et al. 02	SP*
P. retusa (Mart. & Zucc.) Fern Alonso	Freire-Fierro et al. s.n., Queiroz et al. 9634, Junqueira et al. 142	SPF 106500*, HUEFS, HUEFS
P. tocantina (Ducke) Fern. Alonso	Fróes 23378	SP*
Pseudobombax calcicola Carv.-Sobr. & L.P.Queiroz	Carvalho-Sobrinho & Queiroz 573	HUEFS
Ps. marginatum (A. St.-Hil., A. Juss. & Cambess.) A Robyns	Castro s.n., Figueiredo et al. 175, Du Bocage 267	EAC 32129, EAC, IPA*
Ps. minimum Carv.-Sobr. & L.P.Queiroz	Forzza et al. 1591	HUEFS
Ps. simplicifolium A. Robyns	Queiroz & Nascimento 4628, Queiroz et al. 7361, Du Bocage 274	HUEFS, HUEFS*, IPA
Rhodognaphalopsis faroensis (Ducke) A. Robyns	Ribeiro & Pereira 1704, Esteves & Assunção 07	SP*, SP

Species / specimens	P		E		Epv		P/E	AI	Ec	Eh	Sex	Nex
Species / specimens	x̄±S_x̄	R	x̄±S_x̄	R	x̄±S_x̄	R	P/E	AI	Ec	Eh	Sex	Nex
Ceiba eriantdos
Guedes & Eudes 4839 (ALCB)	46.1*	43.5-52.5	55.5*	46.5-63.0	57.6±1.1	46.5-67.5	0.83	0.44	23.6x1.0	─	2.1	1.7
Harley & Giulietti 54045 (HUEFS)	42.1*	39.0-45.0	60.5*	55.5-64.5	57.8*	52.5-64.5	0.70	0.46	21.9x4.1	7.8	2.0	1.2
Andrade-Lima 8145 (IPA)	38.6*	36.0-43.5	52.9*	51.0-54.0	64.4*	52.5-70.5	0.73	0.42	15.5x4.8	─	1.7	0.7
C. glaziovii
Queiroz et al. 997 (HUEFS)	47.8*	42.5-51.3	58.8*	53.8-63.8	56.0*	50.0-66.3	0.81	0.47	14.9x2.7	5.0	2.7	0.8
Lyra-Lemos et al. 7030 (HUEFS)	44.8*	42.0-49.5	57.8*	54.0-63.8	56.9*	52.5-61.5	0.77	0.53	16.9x4.2	5.3	2.5	0.9
Oliveira 258 (HUEFS)	46.5*	43.5-48.0	57.5*	55.5-60.0	58.6±0.5	52.5-63.0	0.81	0.47	16.7x3.6	7.1	3.2	1.0
Eriotheca candolleana
Monteiro 23510 (PEUFR)	28.8±0.4	25.0-32.5	43.7±0.6	40.0-50.0	41.5±0.6	37.5-47.5	0.66	0.65	10.9x2.3	4.0	1.7	0.6
Pirani et al .4356 (SPF)	24.0*	20.0-27.5	34.5*	32.5-36.2	33.1±0.5	32.1-34.0	0.69	0.59	7.2x1.0	2.5	1.7	0.7
E. gracilipes
Andrade-Lima 5491 (IPA)	27.8±0.3	25.5-30.0	38.0±0.4	31.5-42.0	36.7±0.4	31.5-40.5	0.73	0.55	12.3x1.5	4.7	1.6	0.9
E. macrophylla
Lima 12632 (HST) (3-apert)	22.0±1.0	18.0-27.0	41.3±1.8	39.0-46.5	42.7±0.5	39.0-49.5	0.53	0.57	9.8x2.4	4.3	1.5	0.6
Lima 12632(HST) (4-apert)	─	─	─	─	42.1±0.4	39.0-45.0	─	0.55	─	─	1.4	0.6
Ducke & Lima 65 (IPA)	28.6*	25.0-33.8	41.5*	33.8-45.0	36.8±1.6	33.8-45.0	0.69	0.64	9.0x2.4	4.5	1.1	0.6
E. obcordata
Silva et al. 107 (HUEFS)	30.1±0.5	27.0-33.0	44.2±0.6	40.5-52.5	42.7±0.6	37.5-48.0	0.68	0.60	11.9x2.0	5.4	1.4	0.7
Pachira aquatica
Fróes 26629 (SP)	56.3±0.4	52.5-60.0	69.1±0.5	63.0-73.5	66.0±0.8	57.0-70.5	0.81	0.62	17.9x3.5	7.9	1.8	1.2
Alunos Taxonomia da FUFPI s.n. (TEPB450)	─	─	─	─	61.2*	58.5-63.0	─	0.61	14.2x3.3	6.2	1.4	1.0
Miranda 72 (HUEFS)	49.0*	40.5-55.5	60.6*	52.5-67.5	59.1±0.7	52.5-67.5	0.81	0.65	20.9x5.4	10.5	1.2	1.1
P. nervosa
Esteves et al. 02 (SP)	38.2*	33.0-43.5	62.2*	60.0-66.0	57.8±0.5	52.5-63.0	0.61	0.54	13.9x3.1	5.3	1.8	0.6
P. retusa
Freire-Fierro et al. s.n. (SPF106500)	46.6*	42.0-51.0	64.0*	60.0-70.5	58.2*	48.0-63.0	0.73	0.56	14.7x4.1	7.8	1.5	0.6
Junqueira et al. 142 (HUEFS)	48.3*	45.0-52.5	66.3*	60.0-72.0	61.4±1.0	49.5-75.0	0.73	0.56	13.2x3.4	─	1.1	0.6
Queiroz et al. 9634 (HUEFS)	46.0*	45.0-46.5	64.5*	63.0-67.5	60.2*	54.0-64.5	0.71	0.60	17.4x2.4	─	1.1	0.6
P. tocantina
Fróes 23378 (SP)	45.3*	39.0-52.5	64.6*	57.0-70.5	60.7±0.8	49.5-69.0	0.70	0.56	12.6x2.2	─	2.3	0.6
Pseudobombax calcicola
Carvalho-Sobrinho & Queiroz 573 (HUEFS)	52.9±0.9	45.0-65.0	90.8±0.7	82.5-100.0	79.9±0.8	70.0-87.5	0.58	0.51	23.3x4.7	─	1.7	1.2
Ps. marginatum
Castro s.n. (EAC32129)	─	─	─	─	62.4*	58.5-66.0	─	0.57	17.8x2.0	7.0	1.7	0.8
Du Bocage 267 (IPA)	41.0*	37.5-45.0	64.0*	63.0-64.5	62.5*	55.5-70.5	0.64	0.54	24.0x6.0	15.6	1.6	0.9
Figueiredo et al. 175 (EAC)	39.0*	37.5-40.5	73.5*	67.5-79.5	63.4*	54.0-76.5	0.53	0.53	18.5x3.4	─	1.6	0.7
Ps. minimum
Forzza et al. 1591 (HUEFS)	42.4±0.8	32.5-50.0	61.3±0.5	57.5-67.5	57.2±0.7	52.5-67.5	0.69	0.53	20.1x3.1	─	1.5	0.7
Ps. simplicifolium
Queiroz & Nascimento 4628 (HUEFS)	38.8*	34.5-45.0	62.5*	58.5-67.5	61.2±1.1	48.0-69.0	0.62	0.42	20.6x5.4	─	1.9	0.6
Du Bocage 274 (IPA)	42.1*	30.0-50.0	65.4*	56.3-78.8	61.8±1.1	50.0-71.3	0.64	0.40	22.4x2.4	─	1.9	0.6
Queiroz et al. 7361 (HUEFS)	39.0±0.5	33.0-43.5	61.0±0.9	49.5-70.5	57.0±0.8	48.0-63.0	0.64	0.47	22.1x5.3	─	1.7	0.6
Rhodognaphalopsis faroensis
Ribeiro & Pereira 1704 (SP)	42.1±0.4	39.0-45.0	58.9±0.6	48.0-63.0	53.8±0.6	46.5-60.0	0.71	0.62	13.0x2.2	4.7	1.3	0.9
Esteves & Assunção 07 (SP)	─	─	─	─	38.6±0.8	33.0-48.0	─	0.60	─	─	1.4	0.6

Variables	Principal components
Variables	Axis 1	Axis 2
P	-0.4097	-0.0667
E	-0.4249	0.1661
Epv	-0.4106	0.0164
P/E	0.0032	-0.0982
AI	0.0400	0.0757
EcL	-0.4951	0.0199
EcW	-0.4555	0.1916
Ex	-0.1122	-0.6455
Sex	-0.0712	-0.6666
Nex	-0.1054	-0.2328

Brasil

Brasil

Morphological characterization of pollen grains of Brazilian species of Bombacoideae (Malvaceae s.l.)

ABSTRACT

Introduction

Materials and methods

Results

Discussion

Acknowledgements

References

Publication Dates

History