Comparative floral anatomy and evolutionary interpretations of cryptic dioecy in <i>Ocotea velloziana</i> (Lauraceae)

Silva, Sarah Juventina Barbosa da; Leme, Flávia Maria; Franco, Ana Paula Sales de Araujo; Arruda, Rosani do Carmo de Oliveira; Schönenberger, Jürg; Alves, Flávio Macedo

doi:10.1590/2175-7860202475016

Abstract

Ocotea velloziana (Lauraceae) is a species with cryptic dioecy. The staminate flowers of this species have a pistillode and pistillate flowers have staminodes, which often makes it difficult to describe circumscribe the reproductive system correctly. Therefore, to understand the evolution of dioecy in this species, the morphology of both floral morphotypes needs to be described. We apply traditional and modern approaches to describe the comparative floral anatomy of the two floral morphotypes in O. velloziana. We found that the pistillate flowers have fewer (three) vascular traces in the tepals (compared to five traces in the tepals of the staminate flowers). The pistillode and the staminodes in the flowers of O. velloziana are smaller and less vascularized than their homologous, fertile counterparts, the pistils and stamens. In addition, even though the nectaries are smaller in pistillate flowers, their basic morphology and vascularization are similar in the two floral morphotypes. Our results suggest androtepaly in O. velloziana, however future ontogenetic studies and investigation of the vascularization are necessary in other Lauraceae species to clarify this issue. The nectaries have originated from the hypanthium and may be characterized as nectar-secreting emergencies not homologous to the stamens.

Key words:
dicliny; floral vascularization; histochemistry; nectaries; perianth

Resumo

Em Ocotea velloziana (Lauraceae) ocorre a dioicia críptica, na qual flores estaminadas possuem pistilódios e flores pistiladas possuem estaminódios, muitas vezes difíceis de distinguir de estruturas funcionais. A descrição das características anatômicas e morfológicas das flores pistiladas e estaminadas é necessária para compreender completamente a evolução da dioicia nesta espécie. Neste estudo, aplicamos abordagens tradicionais e modernas para o estudo da anatomia floral comparativa dos dois morfotipos florais de O. velloziana. Os resultados mostraram que as flores pistiladas de O. velloziana possuem menos (três) traços vasculares nas tépalas (versus cinco traços nas tépalas das flores estaminadas). O pistilódio e os estaminódios nas flores de O. velloziana são menores e menos vascularizados do que suas contrapartes homólogas e férteis, ou seja, os pistilos e os estames. Além disso, embora os nectários sejam menores nas flores pistiladas, sua morfologia básica e vascularização são semelhantes nos dois morfotipos florais. Nossos resultados sugerem androtepalia em O. velloziana, porém futuros estudos ontogenéticos e investigação da vascularização são necessários em outras espécies de Lauraceae para esclarecer completamente esta questão. Os nectários originam-se do hipanto e podem ser caracterizados como emergências secretoras de néctar não homólogas aos estames.

Palavras-chave:
diclinia; vascularização floral; histoquímica; nectários; perianto

Introduction

Dioecy is characterized as a reproductive system that presents diclinous flowers on separate plant individuals (Sakai & Weller 1999Sakai AK & S Weller SG (1999) Gender and sexual dimorphism in flowering plants: a review of terminology, biogeographic patterns, ecological correlates, and phylogenetic Approaches. In: Geber MA, Dawson TE & LF Delph (eds.) Gender and sexual dimorphism in flowering plants. Springer-Verlag, Berlin , Heidelberg. Pp. 1-31.; Renner 2014Renner SS (2014) The relative and absolute frequencies of angiosperm sexual systems: dioecy, monoecy, gynodioecy, and an updated online database. American Journal of Botany 101: 1588-1596.; Cardoso et al. 2018Cardoso JCF, Viana ML, Matias R, Furtado MT, Caetano APDS, Consolaro H & Brito VLGD (2018) Towards a unified terminology for angiosperm reproductive systems. Acta Botanica Brasilica 32: 329-348.). The phenomenon is found in about 6% of angiosperm species around the world (Renner & Ricklefs 1995; Endress 1996Endress PK (1996) Diversity and evolutionary biology of tropical flowers. Cambridge University Press, Cambridge. 511p.). Avoiding self-fertilization by dioecy increases the efficiency of nutrient allocation for reproduction (Thomson & Brunet 1990Thomson JD & Brunet J (1990) Hypotheses for the evolution of dioecy in seed plants. Trends in Ecology & Evolution 5: 11-16.), maintaining genetic variability (Bawa 1980Bawa KS (1980) Evolution of dioecy in flowering plants. Annual Review ofEcology , Evolution, and Systematics 11: 15-39.) and can generate plants that produce more than twice as many seeds compared to species with perfect flowers, i.e., flowers that contain both fertile male and fertile female parts (Sakai & Weller 1991).

Cryptic dioecy is predominant in Neotropical dioecious Lauraceae, i.e., staminate flowers have a pistillode and pistillate flowers have staminodes (Mayer & Charlesworth 1991Mayer SS & Charlesworth D (1991) Cryptic dioecy in flowering plants. Trends in Ecology & Evolution 6: 320-325.). This often impedes fast identification of the sexual system (Penagos-Zuluaga et al. 2021). However, the total number of occurrences of dioecy within the family ultimately depends on verifying the fertility of the ovules in pollen-producing flowers (van der Werff 2017van der Werff H (2017) Studies in Andean Ocotea (Lauraceae) IV. Species with unisexual flowers and densely pubescent leaves, or with erect pubescence or domatia, occurring above 1000 m in altitude. Novon: A Journal for Botanical Nomenclature 25: 343-393.; Penagos-Zuluaga et al. 2021). Studying floral anatomy can help to identify floral morphotypes and to determine whether the flowers are perfect or if they are functionally only pistillate or staminate (see Leme et al. 2018Leme FM, Staedler YM, Schonenberger J & Teixeira SP (2018) Ontogeny and vascularization elucidate the atypical floral structure of Ampelocera glabra, a tropical species of Ulmaceae. International Journal of Plant Science 179: 461-476., 2021).

The taxonomy of Lauraceae has been mainly based on androecium composition (Rohwer 1993Rohwer JG (1993) Lauraceae. In the families and genera of vascular plants. In: Kubitzki K, Rohwer JR & Bittrich V (eds.) Vol. 2. Springer-Verlag, Berlin . Pp. 336-391. ). However, in recent phylogenies, several traditional groups have emerged as paraphyletic or polyphyletic (e.g., Chanderbali et al. 2001Chanderbali AS, Van Der Werff H & Renner SS (2001) Phylogeny and historical biogeography of Lauraceae: evidence from the chloroplast and nuclear genomes. Annals of the Missouri Botanical Garden 88: 104-134.; Rohwer & Rudolph 2005; Alves & Souza 2013Alves FM & Souza VC (2013) Phylogenetic analysis of the Neotropical genus Mezilaurus and reestablishment of Clinostemon (Lauraceae). Taxon 62: 281-290.; Trofimov et al. 2016Trofimov D, Rudolph B & Rohwer JG (2016) Phylogenetic study of the genus Nectandra (Lauraceae), and reinstatement of Damburneya. Taxon 65: 980-996.; Rohde et al. 2017Rohde R, Rudolph B, Ruthe K, Lorea-Hernández FG, Moraes PLR, Li J & Rohwer JG (2017) Neither Phoebe nor Cinnamomum - the tetrasporangiate species of Aiouea (Lauraceae). Taxon 66: 1085-1111.; Trofimov & Rohwer 2020; Penagos-Zuluaga et al. 2021). Therefore, new attributes need to be identified that could serve to delimit groups and help to understand the evolution of the family (Nishida & van der Werff 2007Nishida S & van der Werff H (2007) Are cuticular characters useful in solving generic relationships of problematic species of Lauraceae? Taxon 56: 1229-1237. , 2011; Trofimov et al. 2016; Zeng et al. 2017Zeng G, Liu B, Ferguson DK, Rohwer JG & Yang Y (2017) Floral structure and ontogeny of Syndiclis (Lauraceae). Plos One 12: e0186358.).

Over the past years, learning about the evolution of the reproductive system has also become an important matter in understanding the phylogeny of Lauraceae. The reproductive system has been historically used in generic delimitation (Kostermans 1957Kostermans AJGH (1957) Lauraceae. Reinwardtia 4: 193-256.; van der Werff 1991van der Werff H (1991) A key to the genera of Lauraceae in the new world. Annals of the Missouri Botanical Garden 78: 377-387.) and contains a phylogenetic signal in Ocotea (Penagos-Zuluaga et al. 2022; Trofimov et al. 2022Trofimov D, Cadar D, Schmidt-Chanasit J, Moraes PLR & Rohwer JG (2022) A comparative analysis of complete chloroplast genomes of seven Ocotea species (Lauraceae) confirms low sequence divergence within the Ocotea complex. Scientific Reports 12: 1120.). Ocotea is the largest Neotropical genus of Lauraceae with about 400 species and it contains species with dioecious, gynodioecious or perfect flowers (van der Werff 2017, 2022; Penagos-Zuluaga et al. 2021). According to the most widely accepted hypothesis, all dioecious Ocotea species belong to the same subclade within the genus and have evolved from a cosexual ancestor (Chanderbali et al. 2001Chanderbali AS, Van Der Werff H & Renner SS (2001) Phylogeny and historical biogeography of Lauraceae: evidence from the chloroplast and nuclear genomes. Annals of the Missouri Botanical Garden 88: 104-134.; van der Werff 2017). Cosexuality is a sexual system, in which individuals of a population present only perfect (cosexual, hermaphrodite, monoclinous or bisexual) flowers, with functional stamens and pistils in the same flower (Cardoso et al. 2018Cardoso JCF, Viana ML, Matias R, Furtado MT, Caetano APDS, Consolaro H & Brito VLGD (2018) Towards a unified terminology for angiosperm reproductive systems. Acta Botanica Brasilica 32: 329-348.).

Studying floral anatomy is important to elucidate Charles Darwin’s “abominable mystery” about the origin and evolution of flowers (Pennisi 2000Pennisi E (2000) On the origin of flowering plants. Science 324: 28-31.; Buggs 2017Buggs RJA (2017) The deepening of Darwin’s abominable mystery. Nature Ecology & Evolution 1: 0169.). Such studies provide data to answer questions about the origin and the identity of organs, floral developmental patterns, and organ homology within Lauraceae (Reece 1939Reece PC (1939) The floral anatomy of the avocado. American Journal of Botany 26: 429-433.; Sastri 1965; Buzgo et al. 2007Buzgo M, Chanderbali AS, Kim S, Zheng Z, Oppenheimer D, Soltis PS & Soltis DE (2007) Floral developmental morphology of Persea americana (avocado, Lauraceae): the oddities of male organ identity. International Journal of Plant Sciences 168: 261-284. ; Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.). Consequently, comparative anatomy plays a fundamental role in systematics (Rieppel 1988Rieppel O (1988) Fundamentals of comparative biology. Birkhauser, Basel. 202p.). However, few studies have been conducted in Lauraceae and they reached different conclusions with regard to the origin of the perianth, some suggesting bracteotepaly i.e., tepals originating from the bracts (Sajo et al. 2016; Ronse De Craene 2008Ronse De Craene LP (2008) Homology and evolution of petals in the core eudicots. Systematic Botany 33: 301-325.), others androtepaly, tepals originating from the stamens (Albert et al. 1998Albert VA, Gustafsson MHG & Di Laurenzio L (1998) Ontogenetic systematics, molecular developmental genetics, and the angiosperm petal. In: Soltis PS, Soltis DE & Doyle JJ (eds.) Molecular systematics of plants II. Kluwer Academic Publishers, Boston. Pp. 349-374.; Chanderbali et al. 2006Chanderbali AS, Kim S, Buzgo M, Zheng Z, Oppenheimer DG, Soltis DE & Soltis PS (2006) Genetic footprints of stamen ancestors guide perianth evolution in Persea (Lauraceae). International Journal of Plant Sciences 167: 1075-1089.; Soltis et al. 2009Soltis PS, Brockington SF, Mi-Jeong Y, Piedrahita A, Latvis M, Moore MJ, Chanderbali AS & DE Soltis (2009) Floral variation and floral genetics in basal Angiosperms. American Journal of Botany 96: 110-128.).

Furthermore, lack of knowledge about the anatomical background is limiting our understanding of dioecy at the functional level (Pätzold et al. 2023Pätzold J, Feyrer B, Saumweber J, Hilger HH & Gottschling M (2023) Observations on flower and fruit anatomy in dioecious species of Cordia (Cordiaceae, Boraginales) with evolutionary interpretations. Organisms Diversity & Evolution 23: 77-90.) and only a few studies have been published on dioecious Lauraceae species (Boyle 1980Boyle EM (1980) Vascular anatomy of the flower, seed and fruit of Lindera benzoin. Bulletin of the Torrey Botanical Club 107: 409-417.; Souza & Moscheta 1999Souza LA & Moscheta IS (1999) Morfo-anatomia da flor de Ocotea puberula (Rich.) Nees (Lauraceae). Acta Scientiarum. Biological Sciences 21: 343-348. ; Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.). Therefore, the objective of this work was to study the comparative floral anatomy associated with the morphological characteristics of staminate and pistillate flowers of Ocotea velloziana (Meisn.) Mez (Lauraceae), a species with cryptic dioecy. We aim to elucidate the evolution of dioecy in Ocotea velloziana by answering the following questions: 1) What are the morphological and anatomical differences between homologous floral (perianth, androecium, gynoecium) organs of staminate and pistillate flowers? 2) Are there differences between the paired nectaries of stamens and staminodes? and 3) Can the floral vascular system (i.e., the number and arrangement of vascular bundles) help us understand floral evolution in Ocotea velloziana?

Materials and Methods

Plant material

Specimens with staminate flowers (Saiefert T.M.O. & Alves F.M. 21 [CGMS 74455]) and pistillate flowers (E.J. Coutinho 01 [CGMS 84591]) were collected in Mato Grosso do Sul state, Brazil and were deposited in the CGMS Herbarium of the Federal University of Mato Grosso do Sul (INBIO/UFMS) (Thiers, continuously updated - <http://sweetgum.nybg.org/ih/>).

Flowers in anthesis and buds in several developmental stages were collected, fixed in buffered formalin or FAA (9:1:1 mixture of 70% ethanol, formalin, and acetic acid) for 48 hours, then dehydrated in or transferred to an ethanol series and, finally, stored in 70% ethanol (Kraus & Arduin 1997Kraus JE & Arduin M (1997) Manual básico de métodos em morfologia vegetal. Editora Universidade Rural, Rio de Janeiro. 198p.).

Herbarium samples were rehydrated for one week in a 1:1 glycerin-water mixture (Leme & Scremin-Dias 2014Leme FM & Scremin-Dias E (2014) Ecological interpretations of the leaf anatomy of amphibious species of Aeschynomene L. (Leguminosae - Papilionoideae). Brazilian Journal Biology 74: 41-51.), dehydrated in an increasing ethanol series that reached and stored in 70% ethanol.

Morphological analysis

Floral morphology was recorded using a Leica M205 C stereo microscope with a Leica DFC 420 Coupled camera. For Scanning Electron Microscopy (SEM), the samples stored in 70% ethanol were dried in the open air and mounted on metal stubs with carbon adhesive tape and sputtered with gold in a Denton Vacuum Desk III system. Electron micrographs were obtained using a Jeol JSM-6380LV scanning electron microscope (SEM).

Staminate flowers were measured in 50 flowers (five flowers from each of 10 individuals) and pistillate flowers were measured from 15 flowers (five flowers from each of three exsiccates).

Anatomical and histochemical analysis

Both the fixed and the rehydrated material, stored in 70% ethanol, was dehydrated in an increasing ethanol series (two hours each in 80%, 90% and 95% solutions). For the preparation of the slides, the samples were infiltrated for two days in a pre-infiltration solution (Leica^® activated historesin + 95% ethanol, 1:1) and in activated historesin (Leica^®) according to the manufacturer’s protocol. Some flowers were infiltrated for over two weeks for better infiltration. Then the material was polymerized and sectioned at 5 μm thickness using Leica RM2145 rotary microtome, mounted on slides and stained with toluidine blue in pH 4.7 0.05 M sodium citrate buffer (modified from O’Brien et al. 1964O’Brien TP, Feder N & McCully ME (1964) Polychromatic staining of plant cell walls by toluidine blue O. Protoplasma 59: 368-373.). The histochemical analysis of the main compounds was conducted using Sudan IV to identify total lipids (Pearse 1985Pearse AGE (1985) Histochemistry: theoretical and applied. Vol. 2. 4th ed. C. Livingstone, Edinburgh. 391p.), Xylidine Ponceau for proteins (Vidal 1970Vidal BC (1970) Dichroism in collagen bundles stained with xylidine-Ponceau 2R. Annales d'histochimie 15: 289-296.), ferric chloride for phenolic compounds (Lillie 1965Lillie RD (1965) Histopathologic technic and practical histochemistry. McGraw-Hill, New York. 501p.), and Schiff‘s Reagent/Periodic Acid (PAS) for neutral polysaccharides (O’Brien & McCully 1981). The photomicrographs of the sections were taken using a Nikon Ci Eclipse microscope with a coupled digital camera.

Floral vascularization analysis

For vascularization analysis using high-resolution x-ray computed tomography (HRXCT), the flowers in 70% alcohol were treated in a 1% solution of phosphotungstic acid in 70% ethanol for one week (Staedler et al. 2013Staedler YM, Masson D & Schönenberger J (2013) Plant tissues in 3D via X-ray tomography: simple contrasting methods allow high resolution imaging. PLoS One 8: e75295., 2018). The samples were then mounted in tubes and scanned while immersed in 70% ethanol. Herbarium samples were rehydrated using a 10% ammonium hydroxide aqueous solution, then fixed with FAA (5% formalin, 5% acetic acid, and 90% solution of 70% ethanol; Espinosa & Castro 2018Espinosa F & Castro MP (2018) On the use of herbarium specimens for morphological and anatomical research. Botany Letters 165: 361-367.). Microtomography was performed using a MicroXCT-200 imaging system (Zeiss Microscopy) with an L9421-02 90kV Microfocus X-ray source (Hamamatsu Photonics, Iwata City, Japan). We used the XMReconstructor 8.1.6599 program (Zeiss Microscopy) for 3D reconstructions and the AMIRA-based XM3DViewer 1.1.6 program (Zeiss Microscopy) to view the generated data and to create 2D and 3D reconstructions.

Results

Floral organization

Ocotea velloziana is a tree with cryptic dioecy, with a raceme-type inflorescence in axillary position (Fig. 1a-b). The staminate and pistillate flowers are white greenish and pedicellate and the perianth is organized in two whorls of three tepals, classified in outer and inner tepals (Fig. 1c-d). The staminate flowers are larger than the pistillate flowers, but the size of the individual tepals is similar in both (Tab. 1). There are no differences between the inner and the outer tepals from the same morphotype.

The androecium of the staminate morphotype has nine fertile stamens, which are organized in three whorls of three stamens. The stamens of whorls I and II are introrse and the stamens of whorl III are latrorse (Fig. 1c). The stamens of whorl III have a pair of naturally yellow and globose nectaries arranged at the base of each filament (Fig. 1c). The pistillate morphotype has three whorls of staminodes (whorls I, II, and III). The staminodes of whorl III have a pair of naturally yellow and globose nectaries at the base of each filament, similar to those of the staminate morphotype (Fig. 1d). The stamens and staminodes of whorl I are located in front of the outer tepals, those of whorl II are located in front of the inner tepals, and those of the whorl III are located in front of the stamens/staminodes of whorl I (Fig. 1c). The stamens have anthers with four sporangia, arranged in two overlapping pairs and each sporangium releases its pollen through valvate dehiscence (Fig. 2a). There is a poorly developed pistillode in the center, lacking locule and ovule (Fig. 2b-c).

In the pistillate morphotype, the staminodes contain no pollen and the anthers do not dehiscence, although lines of dehiscence are visible on the anthers (Fig. 2d). The gynoecium is well developed, unicarpellate, unilocular, uniovulate and the ovule is pendant (apical placentation; Fig. 2e-f). Male floral organs are larger in staminate than in pistillate flowers, whereas female organs are substantially larger in pistillate flowers (Tab. 1).

Figure 1
a-d. Ocotea velloziana - a. flowering branch; b. fruiting branch; c. staminate flower showing the nine fertile stamens in three whorls (I, II and III) and the nectaries (n) at the base of whorl III; d. pistillate flower showing the staminodes of whorls I and II (I and II), nectaries (n) at the base of each filament of the staminodes of whorl III (III) and pistil in the center (black asterisk). Symbols: I = whorl I; II = whorl II; III = whorl III; IT = inner te.al; OT = outer tepal; n = nectary.

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Table 1
Comparative floral structure in staminate and pistillate flowers of Ocotea velloziana.

Floral anatomy

The pedicel epidermis is slightly papillose and has non-secreting unicellular trichomes in the staminate and the pistillate floral morphotypes (Fig. 3a-b). The pedicel cortex is constituted of a regular-type parenchyma with rounded cells (Fig. 3a-c). The pedicel has six main vascular bundles (Fig. 3a). In the receptacle, the traces branch towards the center to serve the pistillode or pistil in the staminate and pistillate flowers, respectively (Fig. 3b-c).

In both floral morphotypes, the tepals and the stamens/staminodes are inserted on a hypanthium. The epidermis of the hypanthium is simple and its adaxial surface contains more papillae and non-secreting unicellular trichomes than the abaxial side (Fig. 3c-f). The multi-stratified mesophyll is composed of homogeneous parenchyma tissue with oil-secreting idioblasts (Fig. 3e-h).

The outer and inner surfaces of the tepals possess papillose epidermis in both floral morphotypes (Fig. 4a-j), with trichomes on the abaxial and adaxial surfaces and stomata on the abaxial surface (Fig. 4c-d). The parenchymatous and homogeneous mesophyll (Fig. 4c-d) is four-to-ten cell layers thick and contains oil idioblasts. The tepals are vascularized by five vascular bundles in the staminate flowers and three vascular bundles in the pistillate flowers at the base (Fig. 4c-d).

The stamens and staminodes in both floral morphotypes possess filament with a papillose epidermis and a parenchymatous ground tissue surrounding the vascular tissue (Fig. 4e). The epidermis of the anthers of the staminate flowers has a simple layer with two subepidermal layers of regular parenchyma (Fig. 4f). The flaps of the anther consist of a layer of strongly lignified endothecial cells (Fig. 4f). The microsporangia contain pollen grains (Fig. 4f). In the pistillate flowers, the staminodes have a continuous epidermis around the entire anther, and a few layers of parenchyma in the subepidermal region (Fig. 4g-h). The anthers remain closed and consist of weakly lignified endothecium cells and inconspicuous locules with no pollen grains (Fig. 4h).

In the staminate flowers, the pistillode has papillose epidermis mainly in the apical region, which is filled with parenchymal tissue and a vascular bundle in the center (Fig. 4i). Locules and ovules are absent (Fig. 4i). In the pistillate flower, the epidermis of the pistil is cuticularized and the parenchymatous mesophyll is multi-stratified and homogeneous with evident ventral and dorsal bundles and 3-4 adjacent bundles on each side, as well as oil-secreting idioblasts (Fig. 4j). The ovary is unitegmic and contains a single ovule (Figs. 2f; 4j).

Figure 2
a-f. Androecium and gynoecium of Ocotea velloziana, in SEM - a-c. staminate flower - a. fertile stamens; b. pistillode; c. detail of the ovary region in longitudinal section without ovule; d-f. pistillate flower - d. staminodes with valve remains (black arrow); e. pistil; f. detail of the ovary in longitudinal section showing the single ovule and placenta region (black arrow).

Figure 3
a-h. Comparative anatomy and vasculature of the flower of Ocotea velloziana in cross section (a-f. toluidine blue; g-h. sudan III). a, c, e, g. staminate flower. b, d, f, h. pistillate flower - a. pedicel of the staminate flower; b. receptacle of the pistillate flower; c. floral receptacle, bundles diverging to the pistillode; d-f. hypanthium at base of the ovary in the center and detail of the no secretory trichome; e. hypanthium with pistillode in the center; f. hypanthium with ovary and ovule; g-h. oil-secreting idioblasts in the hypanthium and in the ovary. Note the stomata in the epidermis (black arrow).

Figure 4
a-j. Comparative anatomy of the flower of Ocotea velloziana. a, b: 2D tomography reconstructions of transverse sections; c-e, g-j: cross sections; f: longitudinal section; c-j: toluidine blue. a, c, e, f, i. Staminate flower. b, d, g, h, j. Pistillate flower - a-b. cross sections in the middle of the flower, note all the floral organs separated; c. outer tepal highlighting the five vascular bundles (red circles); d. inner tepal emphasizing the three vascular bundles (red circles); e. filament of the stamen of whorl III; f. anther with endothecium in the flaps; g. filament of a staminode of whorl III; h. anther of a staminode, without locule and nor pollen; i. pistillode anatomy; j. ovary anatomy with an ovule in the center. Symbols: Ov = ovule.

Floral vascularization

In the staminate and pistillate flowers (Fig. 5a-b), the pedicel has six main vascular bundles represented by green color that remain in the floral base and in the hypanthium (Fig. 5a-d). Some traces are oriented from the vascular bundles of the floral base towards the floral center to supply the gynoecium. The initial vascularization of the hypanthium consists of six vascular traces, which are distributed in two complexes. Each complex vascularizes one whorl of the perianth and one or two whorls of stamens, forming two distinct and alternating vascular complexes (Fig. 5a-b). In the staminate flowers, the gynoecium traces serve the pistillode and in the pistillate flowers, these vascular traces divide into approximately ten vascular traces that supply the pistil (Fig. 3e-f).

Vascular complex 1 gives rise to the vascular traces of the outer tepals, the lateral vascular traces of the internal tepals, the vascular traces of whorl I and III of stamens/staminodes and the nectaries. Vascular complex 2, on the other hand, gives rise to the central traces of the inner tepals and the vascular traces of the stamens/staminode of whorl II (Fig. 5a-d).

Among the vascular traces derived from complex 1, the first vascular trace that splits off vascularizes the stamens/staminodes of whorl III, the innermost whorl of stamens (Fig. 5a-d). Complex 1 is similar in both floral morphotypes, but in staminate flowers the splitting off of the trace leading to whorl III is proximal, located close to the floral base, while in pistillate flower it is located higher up in the distal hypanthium region (Fig. 5a-d). The next branch forms the central trace of the outer tepals (Fig. 5c-d) and the vascular trace of the stamens/staminodes of whorl I (Fig. 5c-d).

The three other vascular traces of the hypanthium (derived from complex 2) branch out and form the central traces of the inner tepals and the vascular traces of the stamens/staminodes of whorl II (Fig. 5c-d).

The vascularization of the tepals differs between staminate and pistillate floral morphotypes. In the staminate flowers, the tepals are vascularized by five vascular bundles at the base in each organ (Fig. 4c). In the pistillate flowers, the tepals are vascularized by three vascular bundles at the base (Fig. 4d). However, the vascularization complex of the two floral morphotypes is similar, the lateral vascular bundles of each tepal (outer tepals + inner tepals) depart from the same vascular trace of the hypanthium, derived from complex 1 (Fig. 5c-f).

In staminate flowers, the lateral vascular traces of each tepal divide again and form two vascular bundles each in the outer and the inner tepals (Fig. 5e). In pistillate flowers, the lateral traces do not divide, forming only one vascular bundle at the lateral side of each tepal (Fig. 5f).

After vascular traces separate, vascular traces split off higher up in the hypanthium and supply the nectaries (Fig. 6a-b). The nectary vascular traces are formed from complex 1 of the hypanthium vascular traces and are vascularized by several vascular bundles (Fig. 6c-d).

In staminate flowers, the stamens of whorl III are vascularized by two additional lateral traces, which are derived from of the vascular traces of the nectaries, arising further up in the hypanthium (Fig. 6a,c).

When fully developed, the outer and inner tepals of the staminate flower have five vascular bundles and the outer and inner tepals of the pistillate flowers have three vascular bundles (Fig. 6e-f). In staminate flowers, stamens of whorls I and II have one vascular bundle, and stamens of whorl III have three vascular bundles at their base, but the two lateral bundles end close to the base of the filament (Fig. 6a,c,e). On the other hand, staminodes in pistillate flowers only have one vascular bundle (Fig. 6b,d,f). The nectaries have more than ten vascular bundles (Fig. 6a-d).

Nectaries

Nectaries have similar structure and are proportional to the size of the flowers in both staminate and pistillate floral morphotypes (Tab. 1). The surface of these round nectaries is covered by papillae epidermis with unicellular secretory trichomes (Fig. 7a-d). Near the base of the nectaries, the epidermis is slightly papillose and produces phenolic compounds (Fig. 7c). The subepidermal region consists of nectary parenchyma containing cells with dense cytoplasm and a large nucleus, which react positively to lipids (Fig. 7d), proteins (Fig. 7e) and neutral polysaccharides (Fig. 7f). The subnectary parenchyma is abundantly vascularized (Fig. 7a-b).

Discussion

Ocotea velloziana has diclinous flowers and both floral morphotypes are superficially similar to perfect flowers. However, the functionally staminate and pistillate flowers have distinct anatomies and considerably different sizes. The main differences between the floral morphotypes are the size of the floral structures, the presence or absence of a female gametophyte (embryo sac) or male gametophyte (pollen grains), and the different number of vascular bundles in the tepals, stamens/staminodes and pistil/pistillode. The histology of the nectary is similar in both floral morphotypes. This is the first study describing the histochemistry and structure of the nectary of Lauraceae species, in particular nectary emergence, that is, the presence of a nectary with its own vascularization derived from the hypanthium that produces nectar.

Previous studies on floral anatomy have shown a great diversity in the number of vascular traces in floral structures in Lauraceae (e.g., Reece 1939Reece PC (1939) The floral anatomy of the avocado. American Journal of Botany 26: 429-433.; Kasapligil 1951Kasapligil B (1951) Morphological and ontogenetic studies of Umbellularia californica Nutt. and Laurus nobilis L. University of California Publications in Botany 25: 115-240.; Sastri 1952Sastri RLN (1952) Studies in the Lauraceae I. Floral anatomy of Cinnamomum iners Reinw. and Cassytha filiformis L. Journal of the Indian Botanical Society 31: 240-246.; Boyle 1980Boyle EM (1980) Vascular anatomy of the flower, seed and fruit of Lindera benzoin. Bulletin of the Torrey Botanical Club 107: 409-417.; Souza & Moscheta 1999Souza LA & Moscheta IS (1999) Morfo-anatomia da flor de Ocotea puberula (Rich.) Nees (Lauraceae). Acta Scientiarum. Biological Sciences 21: 343-348. , 2000; Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.). Although in most Lauraceae species both tepal whorls (inner and outer tepals) are vascularized by the same number of bundles (i.e., Souza & Moscheta 1999; Sajo et al. 2016), there may be species with more bundles in the outer tepals compared to the inner tepals (Sastri 1952, 1965; Kasapligil 1951). The same number of vascular bundles in the inner and outer tepals is a pattern present in many Lauraceae species. At the same time, the number of vascular bundles per tepal may differ between staminate and pistillate flowers of the same species (Boyle 1980; Souza & Moscheta 1999). Our results corroborate this observation, as we found that each morphotype had the same number of vascular bundles in each tepal, even though the numbers differed between floral morphotypes.

Figure 5
a-f. Floral vascularization of Ocotea velloziana (HRXCT, 3D reconstructions and 2D reconstructions in transverse sections). a, c, e. Staminate flowers. b, d, f. Pistillate flowers - a-b. flowers seen from the side, with the vasculature of the hypanthium and part of the floral organs shown in different colors; c-d. floral vasculature as seen from above; in the center, note that the first vascular traces that split off from the main traces (green) are those of the stamens/staminodes of whorl III, one vascular trace (dark blue) for each stamen/staminode; e-f. the vascular bundles of the hypanthium of the complex one branch higher and give rise to traces of the outer tepals (red) and stamens/staminodes of whorl I (white). The vascular bundles of the hypanthium of the complex two branch and rise to traces of the inner tepals (yellow) and of the stamens/staminodes of whorls II (royal blue). Note that the lateral bundles of the tepals split off higher up in the hypanthium vascular bundles of the complex one. Vasculature colors: green = hypanthium, C1 = complex 1, C2 = complex 2, red = outer tepals, yellow = inner tepals, white = stamens/staminodes of whorl I, royal blue = stamens/staminodes of whorl II, dark blue = stamens/staminodes of whorl III.

Figure 6
a-f. Floral vascularization of Ocotea velloziana (HRXCT, 3D reconstructions and 2D reconstructions in transverse sections). a, c, e. Staminate flowers. b, d, f. Pistillate flowers - a-b. nectaries vascular bundles (pink) close to vascular bundles of the stamens/staminodes of whorl III (dark blue) - a. in the staminate flower, split off two lateral vascular traces in the hypanthium that extend to the base of the stamens of whorl III (dark blue); c-d. numerous vascular bundles of the nectaries; e. staminate flowers with five vascular bundles in the tepals; f. pistillate flower with three vascular bundles in the tepals. Vasculature colors: green = hypanthium, red = outer tepals, yellow = inner tepals, white = stamens/staminodes of whorl I, royal blue = stamens/staminodes of whorl II, dark blue = stamens/staminodes of whorl III, pink = nectaries.

Figure 7
a-f. Anatomy and histochemical analyses of the floral nectary of Ocotea velloziana (nectary of the floral staminate morphotype) - a-b. longitudinal (a) and transverse (b) sections of the nectary, stained with Toluidine Blue; c. nectary with phenolic compounds in the epidermal cells, positive reaction with ferric chloride; d. positive reaction of the papillose cells of the epidermis for lipids with Sudan Black; e. epidermis and nectary parenchyma with positive reaction to proteins (stain: Xylidine ponceau); f. nectary parenchyma with positive reaction to neutral polysaccharides (stain: Schiff reagent). EP = epidermis; Np = nectary parenchyma; Sp = subnectary parenchyma.

Compared to pistillate flowers, which terminate in three traces, staminate flowers, have an additional branching in the lateral trace of the tepals, thereby terminating in five traces (Figs. 5; 6). Compared to functional organs (stamens and pistils), in non-functional floral organs (i.e., staminodes and pistillode) of Ocotea velloziana, there is also a reduction in vascularity. This is similar to what was described for another dioecious species, Ocotea puberula (Rich.) Nees (Souza & Moscheta 1999Souza LA & Moscheta IS (1999) Morfo-anatomia da flor de Ocotea puberula (Rich.) Nees (Lauraceae). Acta Scientiarum. Biological Sciences 21: 343-348. ). Therefore, the reduction of floral structures (pistillode and staminodes) is linked to a decrease in vascularization and lower allocation of resources to these structures generating tissue atrophy (e.g., Schmid 1972aSchmid R (1972a) Floral anatomy of Myrtaceae. I. Syzygium s.1. Botanische Jahrbücher 92: 336-363. , b).

Nutritional conflicts between the male and female functions within a flower can express selective forces that maintain male and female sterility genes in the morphotypes and drive the evolution to floral dicliny (Gibson & Diggle 1997Gibson JP & Diggle PK (1997) Structural analysis of female and hermaphroditic flowers of a gynodioecious tree, Ocotea tenera (Lauraceae). American Journal of Botany 84: 298-307.). While hermaphrodite species have a high investment in resources for pollen and ovules, plants dioecious with pistillate flowers are liberated from the cost of the male function and can reallocate resources from pollen to seed formation and vice-versa (Darwin 1877Darwin C (1877) The different forms of flowers on plants of the same species. Ed. John Murray, London. 352p.; Ashman 1994Ashman T-L (1994) Reproductive allocation in hermaphrodite and female plants of Sidalcea oregana ssp. spicata (Malvaceae) using four currencies. American Journal of Botany 81: 433-438.). This strengthen the reprodution, since the exclusion of self-fertilization achieved by dioecy increases the efficiency of nutrient allocation for reproduction (Freeman et al. 1997Freeman DC, Doust JL, El-Keblawi A, Miglia KJ & McArthur ED (1997) Sexual specialization and inbreeding avoidance in the evolution of dioecy. Botanical Review 63: 65-92.; Thomson & Brunet 1990Thomson JD & Brunet J (1990) Hypotheses for the evolution of dioecy in seed plants. Trends in Ecology & Evolution 5: 11-16.), maintaining genetic variability (Bawa 1980Bawa KS (1980) Evolution of dioecy in flowering plants. Annual Review ofEcology , Evolution, and Systematics 11: 15-39.) and generating plants that produce more than twice as many seeds as cosexual species (Sakai & Weller 1991Sakai AK & Weller SG (1991) Ecological aspects of sex expression in subdioecious Schiedea globosa (Caryophylaceae). American Journal of Botany 78: 1280-1288.). The allocation of resources for reproduction and the division of these resources among reproductive structures are of central importance to theories of the evolution of the reproductive system and the stability of hermaphroditism in plants (e.g., Charlesworth & Charlesworth 1978Charlesworth B & Charlesworth D (1978) A model for the evolution of dioecy and gynodioecy. American Naturalist 112: 975-997., 1981; Lloyd & Bawa 1984Lloyd DG & Bawa KS (1984) Modification of the gender of seed plants in varying conditions. Evolution ary Biology 17: 255-338.; Charlesworth 1989; Ashman 1994).

In general, the reproductive success of specimens with staminate flowers is limited by access to female gametes, whereas the success of specimens with pistillate flowers is limited by the resources available for ovule production. Consequently, males tend to optimize mating quantity (higher pollen production), while females optimize ovary and ovule quality (Bawa 1980Bawa KS (1980) Evolution of dioecy in flowering plants. Annual Review ofEcology , Evolution, and Systematics 11: 15-39.). Pistillate flowers produce smaller flowers (Gibson & Diggle 1997Gibson JP & Diggle PK (1997) Structural analysis of female and hermaphroditic flowers of a gynodioecious tree, Ocotea tenera (Lauraceae). American Journal of Botany 84: 298-307.) and less nectar (Ashman & Stanton 1991Ashman T-L & Stanton M (1991) Seasonal variation in pollination dynamics of sexually dimorphic Sidalcea oregana ssp. spicata (Malvaceae). Ecology 72: 993-1003.; Eckhart 1992Eckhart VM (1992) Resource compensation and the evolution of gynodioecy in Phacelia linearis (Hydrophyllaceae). Evolution 46: 1313-1328. ) compared to staminate flowers (Ashman 1994).

Vascular bundles are responsible for controlling the size and shape of floral structures with large organs having a higher number of bundles and a more branched vascular structure, while small organs have fewer bundles and less branching (Schmid 1972aSchmid R (1972a) Floral anatomy of Myrtaceae. I. Syzygium s.1. Botanische Jahrbücher 92: 336-363. , b). Therefore, the bundles are functional structures resulting from physiological and fundamental factors as relics exposing the evolutionary loss of organs (Carlquist 1969Carlquist S (1969) Toward acceptable evolutionary interpretations of floral anatomy. Phytomorphology 19: 332-362.; Stebbins 1967Stebbins GL Jr (1967) Adaptive radiation and trends of evolution in higher plants. In: Dobzhansky T, Hecht M & Steere WC (eds.) Evolution ary biology. Vol. I. Appleton-Century-Crofts, Meredith Publishing Co. , New York. Pp. 101-142.).

Some authors have argued that gynodioecy is a common evolutionary pathway from hermaphroditism to dioecism in angiosperms (Bawa 1980Bawa KS (1980) Evolution of dioecy in flowering plants. Annual Review ofEcology , Evolution, and Systematics 11: 15-39.; Dufay et al. 2014Dufay M, Champelovier P, Kafer J, Henry JP, Mousset S & Marais GAB (2014) An angiosperm wide analys is of the gynodioecy-dioecy pathway. Annals of Botany 114: 539-548. ). In contrast, recent phylogenetic studies indicate a hermaphroditic ancestry for all dioecious origins in Ocotea (Chanderbali et al. 2001Chanderbali AS, Van Der Werff H & Renner SS (2001) Phylogeny and historical biogeography of Lauraceae: evidence from the chloroplast and nuclear genomes. Annals of the Missouri Botanical Garden 88: 104-134.; Trofimov et al. 2019Trofimov D, Moraes PL & Rohwer JG (2019) Towards a phylogenetic classification of the Ocotea complex (Lauraceae): classification principles and reinstatement of Mespilodaphne. Botanical Journal of the Linnean Society 190: 25-50.; Penagos-Zuluaga et al. 2021). Dioecy would not have arisen as a selection mechanism to avoid inbreeding, but from the differential allocation of resources (Darwin 1877Darwin C (1877) The different forms of flowers on plants of the same species. Ed. John Murray, London. 352p.; Bawa 1980; Rohwer 1986Rohwer J (1986) Some aspects of dioecy in Ocotea (Lauraceae). Plant Systematics and Evolution 152: 47-48.). The basic mode of reproduction in Lauraceae is dichogamy (protogyny), a mechanism that avoids self-fertilization (Kubitzki & Kurz 1984Kubitzki K & Kurz H (1984) Synchronized dichogamy and dioecy in neotropical Lauraceae. Plant Systematics and Evolution 147: 253-266.; Kubitzki et al. 1993).

Lauraceae can have two kinds of glandular organs, i.e., pairs of nectaries usually at the base or along the filament of each stamen/staminode of whorl III and a glandular head at the tip of the staminodes usually of the whorl IV (Rohwer 2009Rohwer JG (2009) The timing of nectar secretion in staminal and staminodial glands in Lauraceae . Plant Biology 11: 490-492.). Most Lauraceae species have nectaries in whorl III (Kostermans 1957Kostermans AJGH (1957) Lauraceae. Reinwardtia 4: 193-256.; van der Werff 1991van der Werff H (1991) A key to the genera of Lauraceae in the new world. Annals of the Missouri Botanical Garden 78: 377-387.), although they can also be present in all stamens, as in Chlorocardium, Phyllostemonodaphne and Urbanodendron (Rohwer 1993) or be completely absent, as in Anaueria, Mezilaurus and Williamodendron (Rohwer 1993; Alves & Souza 2013Alves FM & Souza VC (2013) Phylogenetic analysis of the Neotropical genus Mezilaurus and reestablishment of Clinostemon (Lauraceae). Taxon 62: 281-290.). These structures have been interpreted as reduced stamens (Sastri 1965), independent structures (Rohwer 1994), nectar-secreting emergencies not homologous with any organ (Rohwer 1993) or only an attribute of the third whorl (Kasapligil 1951Kasapligil B (1951) Morphological and ontogenetic studies of Umbellularia californica Nutt. and Laurus nobilis L. University of California Publications in Botany 25: 115-240.; Buzgo et al. 2007Buzgo M, Chanderbali AS, Kim S, Zheng Z, Oppenheimer D, Soltis PS & Soltis DE (2007) Floral developmental morphology of Persea americana (avocado, Lauraceae): the oddities of male organ identity. International Journal of Plant Sciences 168: 261-284. ).

Nectary vascularization originates in the hypanthium in both floral morphotypes of Ocotea velloziana, a fact that supports the interpretation that they are nectar-secreting emergences not homologous with any organ (Kasapligil 1951Kasapligil B (1951) Morphological and ontogenetic studies of Umbellularia californica Nutt. and Laurus nobilis L. University of California Publications in Botany 25: 115-240.; Rohwer 1993Rohwer JG (1993) Lauraceae. In the families and genera of vascular plants. In: Kubitzki K, Rohwer JR & Bittrich V (eds.) Vol. 2. Springer-Verlag, Berlin . Pp. 336-391. , 1994; Takahashi et al. 2014Takahashi M, Herendeen PS, Xiao X & Crane PR (2014) Lauraceous fossil flowers from the Kamikitaba assemblage (Coniacian, Late Cretaceous) of northeastern Japan (Lauraceae). Systematic Botany 39: 715-724.). Their homology with stamens could be refuted by the facts that 1) nectaries have their own vascularization, 2) the lack of transitional forms in living or fossil taxa, 3) stamen initiation occurs earlier in the ontogeny than nectary formation (e.g., Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.; Buzgo et al. 2007Buzgo M, Chanderbali AS, Kim S, Zheng Z, Oppenheimer D, Soltis PS & Soltis DE (2007) Floral developmental morphology of Persea americana (avocado, Lauraceae): the oddities of male organ identity. International Journal of Plant Sciences 168: 261-284. ), and that 4) similar structures are occasionally found in the outermost stamens and tepals (Chanderbali et al. 2006Chanderbali AS, Kim S, Buzgo M, Zheng Z, Oppenheimer DG, Soltis DE & Soltis PS (2006) Genetic footprints of stamen ancestors guide perianth evolution in Persea (Lauraceae). International Journal of Plant Sciences 167: 1075-1089.; Buzgo et al. 2007). Moreover, even though pistillate flowers have a reduced size and lost the functionality of the androecium, the nectaries are associated with whorl III staminodes, remain active, showing vascular independence to nutrient reception.

In spite of the reduced size and lost androecium functionality of the pistillate flower, the nectaries, associated with whorl III staminodes, remain functional indicating that these structures still play an important role in attracting pollinators for reproduction.

We believe that maintaining nectaries in pistillate flowers is likely to be fundamental to flower selection in the synchronization process with staminate flowers and to reward pollinators. Cosexual Lauraceae species present a heterodichogamous protogynous cycle with nectar secretion, i.e., in the female phase by the staminodes of whorl IV (glandular head) and in the male phase by the pairs of nectaries at the base of the filaments in stamens of whorl III (Kubitzki & Kurz 1984Kubitzki K & Kurz H (1984) Synchronized dichogamy and dioecy in neotropical Lauraceae. Plant Systematics and Evolution 147: 253-266.; Rohwer 1993Rohwer JG (1993) Lauraceae. In the families and genera of vascular plants. In: Kubitzki K, Rohwer JR & Bittrich V (eds.) Vol. 2. Springer-Verlag, Berlin . Pp. 336-391. ; Rohwer 2009). However, dioecious species generally lack staminodes of whorl IV (glandular head) as well as a heterodichogamous cycle (Kubitzki & Kurz 1984) and the stamens and pistils of different flowers need to mature concurrently. Therefore, the fertility of the pistils in pistillate flowers needs to be synchronized with the pair of glands at the base of the staminodes of whorl III in the same flower, which in turn are already synchronized with the fertility of the stamens in staminate flowers. Consequently, we believe that staminate flowers lost whorl IV given the lack of an active gynoecium, while pistillate flowers lost whorl IV because their pistils had been synchronized with the pair of glands at the base of staminodes of whorl III, making these structures obsolete in both flowers. Therefore, nectaries were responsible for selecting pistillate flowers in synchrony with their nectar secretion. The loss of staminodes of whorl IV, might be due to the fact that their function as nectar-secreting organs during the female flowering phase of heterodichogamous species (Rohwer 2009) became obsolete with dioecy. On the other hand, cosexual species, such as Persea americana, have both functional secretory structures (Buzgo et al. 2007Buzgo M, Chanderbali AS, Kim S, Zheng Z, Oppenheimer D, Soltis PS & Soltis DE (2007) Floral developmental morphology of Persea americana (avocado, Lauraceae): the oddities of male organ identity. International Journal of Plant Sciences 168: 261-284. ).

In Ocotea velloziana, vascularization of the lateral traces of the stamens of whorl III arises from the nectary vascularization, displaying vasculature complex 1. Unlike in other species, the traces serve different organs, i.e., the tepals and the stamens, reinforcing the role of the nectary as an independent structure. In Persea americana, nectaries have been described as emergences, but from stamens (partial homology) (Buzgo et al. 2007Buzgo M, Chanderbali AS, Kim S, Zheng Z, Oppenheimer D, Soltis PS & Soltis DE (2007) Floral developmental morphology of Persea americana (avocado, Lauraceae): the oddities of male organ identity. International Journal of Plant Sciences 168: 261-284. ), while in Ocotea prolifera (Nees & Mart.) Mez and Cryptocarya moschata Nees & Mart. the lateral bundles of the staminode and those supplying the nectaries (stamen appendages of the inner androecial whorl) have a common origin in the floral cup (Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.). Nevertheless, as the precise origin of the nectary cannot always be determined with certainty (Rohwer 1993Rohwer JG (1993) Lauraceae. In the families and genera of vascular plants. In: Kubitzki K, Rohwer JR & Bittrich V (eds.) Vol. 2. Springer-Verlag, Berlin . Pp. 336-391. ), more studies are necessary on the vascularization of nectaries in other Lauraceae species.

The highly different vascularization between the floral morphotypes complicates the interpretation of the origin of the tepals (androtepaly or bracteotepaly). However, in staminate flowers, only the gynoecium displays structural reduction with fewer bundles in the pistillode compared to the pistil of pistillate flowers. On the other hand, in pistillate flowers, the structure of the androecium is reduced, and also (or consequently), the vascularization of the tepals. This indicates a strong relationship between stamens and tepals, reinforcing the hypothesis of androtepaly (Albert et al. 1998Albert VA, Gustafsson MHG & Di Laurenzio L (1998) Ontogenetic systematics, molecular developmental genetics, and the angiosperm petal. In: Soltis PS, Soltis DE & Doyle JJ (eds.) Molecular systematics of plants II. Kluwer Academic Publishers, Boston. Pp. 349-374.; Chanderbali et al. 2001Chanderbali AS, Van Der Werff H & Renner SS (2001) Phylogeny and historical biogeography of Lauraceae: evidence from the chloroplast and nuclear genomes. Annals of the Missouri Botanical Garden 88: 104-134., 2006; Soltis et al. 2009Soltis PS, Brockington SF, Mi-Jeong Y, Piedrahita A, Latvis M, Moore MJ, Chanderbali AS & DE Soltis (2009) Floral variation and floral genetics in basal Angiosperms. American Journal of Botany 96: 110-128.), as opposed to bracteotepaly (Sajo et al. 2016Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.; Ronse De Craene 2008Ronse De Craene LP (2008) Homology and evolution of petals in the core eudicots. Systematic Botany 33: 301-325.; Takhtajan 1991Takhtajan A (1991) Evolution ary trends in flowering plants Columbia University Press, New York. 241p.; Warner et al. 2009Warner KA, PJ Rudall & Frohlich MW (2009) Environmental control of sepalness and petalness in perianth organs of waterlilies - a new mosaic theory on the evolutionary origin of a differentiated perianth. Journal of Experimental Botany 60: 3559-3574.). Thus, our results point androtepaly in O. velloziana, as suggested by ABC model whose B and C function and floral genes expressed in Persea (Chanderbali et al. 2006, 2008; Soltis et al. 2009), but we suggest that future ontogenetic, expression of floral genes studies, and vascularization work are necessary in other Lauraceae species to confirm this pattern.

Acknowledgements

The authors thank CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico), for the financial support of a scientific initiation scholarship; and to the CGMS Herbarium, for the loan of material. We are also grateful to Luiz Felipe Plaça Vargas (MULTILAM/INFI/UFMS) and Susanne Pamperl (UNIVIE), for technical assistance.

Data availability statement

In accordance with Open Science communication practices, the authors inform that all data are available within the manuscript.

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Pätzold J, Feyrer B, Saumweber J, Hilger HH & Gottschling M (2023) Observations on flower and fruit anatomy in dioecious species of Cordia (Cordiaceae, Boraginales) with evolutionary interpretations. Organisms Diversity & Evolution 23: 77-90.
Pearse AGE (1985) Histochemistry: theoretical and applied. Vol. 2. 4^th ed. C. Livingstone, Edinburgh. 391p.
Penago-Zuluaga JC, van der Werff H, Park B, Eaton DA, Comita LS, Queenborough SA & Donoghue MJ (2021) Resolved phylogenetic relationships in the Ocotea complex (Supraocotea) facilitate phylogenetic classification and studies of character evolution. American Journal of Botany 108: 664-679.
Reece PC (1939) The floral anatomy of the avocado. American Journal of Botany 26: 429-433.
Renner SS & Ricklefs RE (1995) Dioecy and its correlates in the flowering plants. American Journal of Botany 82: 596-606.
Renner SS (2014) The relative and absolute frequencies of angiosperm sexual systems: dioecy, monoecy, gynodioecy, and an updated online database. American Journal of Botany 101: 1588-1596.
Rieppel O (1988) Fundamentals of comparative biology. Birkhauser, Basel. 202p.
Rohwer J (1986) Some aspects of dioecy in Ocotea (Lauraceae). Plant Systematics and Evolution 152: 47-48.
Rohwer JG (1993) Lauraceae. In the families and genera of vascular plants. In: Kubitzki K, Rohwer JR & Bittrich V (eds.) Vol. 2. Springer-Verlag, Berlin . Pp. 336-391.
Rohwer JG (1994) A note on the evolution of the stamens in the Laurales, with emphasis on the Lauraceae . Botanica Acta 107: 103-110.
Rohwer JG (2009) The timing of nectar secretion in staminal and staminodial glands in Lauraceae . Plant Biology 11: 490-492.
Rohwer JG & Rudolph B (2005) Jumping genera: the phylogenetic positions of Cassytha, Hypodaphnis, and Neocinnamomum (Lauraceae) based on different analyses of trnK intron sequences. Annals of the Missouri Botanical Garden 92: 153-178.
Rohde R, Rudolph B, Ruthe K, Lorea-Hernández FG, Moraes PLR, Li J & Rohwer JG (2017) Neither Phoebe nor Cinnamomum - the tetrasporangiate species of Aiouea (Lauraceae). Taxon 66: 1085-1111.
Ronse De Craene LP (2008) Homology and evolution of petals in the core eudicots. Systematic Botany 33: 301-325.
Sajo MG, Moraes PLR, Assis LCS & Rudall PJ (2016) Comparative floral anatomy and development in neotropical Lauraceae. International Journal of Plant Sciences177: 579-589.
Sakai AK & Weller SG (1991) Ecological aspects of sex expression in subdioecious Schiedea globosa (Caryophylaceae). American Journal of Botany 78: 1280-1288.
Sakai AK & S Weller SG (1999) Gender and sexual dimorphism in flowering plants: a review of terminology, biogeographic patterns, ecological correlates, and phylogenetic Approaches. In: Geber MA, Dawson TE & LF Delph (eds.) Gender and sexual dimorphism in flowering plants. Springer-Verlag, Berlin , Heidelberg. Pp. 1-31.
Sastri RLN (1952) Studies in the Lauraceae I. Floral anatomy of Cinnamomum iners Reinw. and Cassytha filiformis L. Journal of the Indian Botanical Society 31: 240-246.
Sastri RLN (1965) Studies in the Lauraceae : V. comparative morphology of the flower. Annals of Botany 29: 39-44.
Staedler YM, Masson D & Schönenberger J (2013) Plant tissues in 3D via X-ray tomography: simple contrasting methods allow high resolution imaging. PLoS One 8: e75295.
Staedler YM, Kreisberger T, Manafzadeh S, Chartier M, Handschuh S, Pamperl S & Schönenberger J (2018) Novel computed tomography-based tools reliably quantify plant reproductive investment. Journal of Experimental Botany 69: 525-535.
Schmid R (1972a) Floral anatomy of Myrtaceae. I. Syzygium s.1. Botanische Jahrbücher 92: 336-363.
Schmid R (1972b) A resolution of the Eugenia-Syzygium controversy (Myrtaceae). American Journal of Botany 59: 423-436.
Soltis PS, Brockington SF, Mi-Jeong Y, Piedrahita A, Latvis M, Moore MJ, Chanderbali AS & DE Soltis (2009) Floral variation and floral genetics in basal Angiosperms. American Journal of Botany 96: 110-128.
Souza LA & Moscheta IS (1999) Morfo-anatomia da flor de Ocotea puberula (Rich.) Nees (Lauraceae). Acta Scientiarum. Biological Sciences 21: 343-348.
Souza LA & Moscheta IS (2000) Morfo-anatomia e aspectos da biologia floral de Nectandra megapotamica (Spreng.) Mez (Lauraceae). Acta Botanica Brasilica 14: 15-25.
Stebbins GL Jr (1967) Adaptive radiation and trends of evolution in higher plants. In: Dobzhansky T, Hecht M & Steere WC (eds.) Evolution ary biology. Vol. I. Appleton-Century-Crofts, Meredith Publishing Co. , New York. Pp. 101-142.
Takhtajan A (1991) Evolution ary trends in flowering plants Columbia University Press, New York. 241p.
Takahashi M, Herendeen PS, Xiao X & Crane PR (2014) Lauraceous fossil flowers from the Kamikitaba assemblage (Coniacian, Late Cretaceous) of northeastern Japan (Lauraceae). Systematic Botany 39: 715-724.
Thomson JD & Brunet J (1990) Hypotheses for the evolution of dioecy in seed plants. Trends in Ecology & Evolution 5: 11-16.
Trofimov D, Cadar D, Schmidt-Chanasit J, Moraes PLR & Rohwer JG (2022) A comparative analysis of complete chloroplast genomes of seven Ocotea species (Lauraceae) confirms low sequence divergence within the Ocotea complex. Scientific Reports 12: 1120.
Trofimov D, Moraes PL & Rohwer JG (2019) Towards a phylogenetic classification of the Ocotea complex (Lauraceae): classification principles and reinstatement of Mespilodaphne. Botanical Journal of the Linnean Society 190: 25-50.
Trofimov D & Rohwer JG (2020) Towards a phylogenetic classification of the Ocotea complex (Lauraceae): an analysis with emphasis on the Old World taxa and description of the new genus Kuloa. Botanical Journal of the Linnean Society 202: 35-44.
Trofimov D, Rudolph B & Rohwer JG (2016) Phylogenetic study of the genus Nectandra (Lauraceae), and reinstatement of Damburneya. Taxon 65: 980-996.
Vidal BC (1970) Dichroism in collagen bundles stained with xylidine-Ponceau 2R. Annales d'histochimie 15: 289-296.
van der Werff H (1991) A key to the genera of Lauraceae in the new world. Annals of the Missouri Botanical Garden 78: 377-387.
van der Werff H (2017) Studies in Andean Ocotea (Lauraceae) IV. Species with unisexual flowers and densely pubescent leaves, or with erect pubescence or domatia, occurring above 1000 m in altitude. Novon: A Journal for Botanical Nomenclature 25: 343-393.
van der Werff H (2022) Andea, a new genus of Neotropical Lauraceae. Annals of the Missouri Botanical Garden 107: 422-431.
Warner KA, PJ Rudall & Frohlich MW (2009) Environmental control of sepalness and petalness in perianth organs of waterlilies - a new mosaic theory on the evolutionary origin of a differentiated perianth. Journal of Experimental Botany 60: 3559-3574.
Zeng G, Liu B, Ferguson DK, Rohwer JG & Yang Y (2017) Floral structure and ontogeny of Syndiclis (Lauraceae). Plos One 12: e0186358.

Edited by

Area Editor:

Dr. João Paulo Basso-Alves

Publication Dates

Publication in this collection
29 Apr 2024
Date of issue
2024

History

Received
08 Sept 2023
Accepted
16 Feb 2024

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

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[62] Soltis PS, Brockington SF, Mi-Jeong Y, Piedrahita A, Latvis M, Moore MJ, Chanderbali AS & DE Soltis (2009) Floral variation and floral genetics in basal Angiosperms. American Journal of Botany 96: 110-128.

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[71] Trofimov D & Rohwer JG (2020) Towards a phylogenetic classification of the Ocotea complex (Lauraceae): an analysis with emphasis on the Old World taxa and description of the new genus Kuloa. Botanical Journal of the Linnean Society 202: 35-44.

[72] Trofimov D, Rudolph B & Rohwer JG (2016) Phylogenetic study of the genus Nectandra (Lauraceae), and reinstatement of Damburneya. Taxon 65: 980-996.

[73] Vidal BC (1970) Dichroism in collagen bundles stained with xylidine-Ponceau 2R. Annales d'histochimie 15: 289-296.

[74] van der Werff H (1991) A key to the genera of Lauraceae in the new world. Annals of the Missouri Botanical Garden 78: 377-387.

[75] van der Werff H (2017) Studies in Andean Ocotea (Lauraceae) IV. Species with unisexual flowers and densely pubescent leaves, or with erect pubescence or domatia, occurring above 1000 m in altitude. Novon: A Journal for Botanical Nomenclature 25: 343-393.

[76] van der Werff H (2022) Andea, a new genus of Neotropical Lauraceae. Annals of the Missouri Botanical Garden 107: 422-431.

[77] Warner KA, PJ Rudall & Frohlich MW (2009) Environmental control of sepalness and petalness in perianth organs of waterlilies - a new mosaic theory on the evolutionary origin of a differentiated perianth. Journal of Experimental Botany 60: 3559-3574.

[78] Zeng G, Liu B, Ferguson DK, Rohwer JG & Yang Y (2017) Floral structure and ontogeny of Syndiclis (Lauraceae). Plos One 12: e0186358.

Floral structure
	staminate	pistillate
Floral diameter	3.5-5.5 mm	2.5-3.5 mm
Floral length	4-4.5 mm	3-3.5 mm
Tepals	3-3.5 mm	3-3.5 mm
Stamens/staminodes (whorls I and II)	1.8-2.2 mm	0.8-0.9 mm
Anther	0.9-1 mm	0.3-0.4 mm
Filament	0.5-0.6 mm	0.4-0.5 mm
% of anther in stamen	65%	40%
Stamens/staminodios (whorl III)	1.8-3 mm	0.9-1.4 mm
Nectaries (base of stamens/staminodes of whorl III)	0.8-1 mm	0.4-0.5 mm
Pistillode/pistil	1.5-2 mm	2.2-3 mm
Ovary width	0.4-0.5 mm	0.8-1 mm
Ovary length	0.5-0,7 mm	0.8-1.2 mm
Stigma	0.2-0.3 mm	0.5-0.6 mm
% of style in pistil	75%	50%
Number of vascular bundles
	staminate	pistillate
Pedicel	6	6
Outer tepals	5	3
Inner tepals	5	3
Stamen S1/staminode S1	1	1
Stamen S2/staminode S2	1	1
Stamen S3/staminode S3	3	1
Nectaries	numerous	numerous
Pistillode/pistil	1	10

Brasil