Palynological analysis of Sphaeropteris gardneri (Cyatheaceae, Pteridophyta)

Marquez, Gonzalo J.; Morbelli, Marta A.; Giudice, Gabriela E.

doi:10.1590/S0001-37652010000200012

Abstracts

The spore morphology and wall ultrastructure of Sphaeropteris gardneri (Hook.) R.M. Tryon from Brazil were analyzed with LM, SEM and TEM. The spores are trilete with an ornamentation formed of short low ridges with spines in their margins. The exospore is 2.5μm thick, two- layered in section and single or branched channels are present. The perispore is 1.2μm thick and two-layered. The inner layer has three strata: the inner stratum is formed of a network of branched and fused threads, the middle stratum has threads with a radial orientation and in the outer stratum thin, dark fibres are immersed in a less dense contrasted matrix. The outer layer of the perispore is the one that forms the echinate-ridges and is constituted of threads arranged in a compact way. Globules of different sizes are observed on the surface. The differences found in the perispore ornamentation and ultrastructure in Alsophila, which was previously studied, and those of Sphaeropteris, show a tendency to wall complexity.

Sphaeropteris; spores; morphology; ultrastructure

A morfologia dos esporos e a ultraestrutura da parede de Sphaeropteris gardneri (Hook.) R.M. Tryon, Brasil, foram analisadas com MO, MEV e MET. Os esporos são trilete com uma ornamentação formada por cristas curtas e baixas e com espinhos em suas margens. O exosporo possui 2,5μm de espessura, duas camadas em secção e estão presentes canais simples ou ramificados. A camada interna possui três estratos: o estrato interno é formado por uma rede de filamentos ramificados e fusionados, o estrato médio tem fios com uma orientação radial e no estrato externo fino, fibras escuras estão imersas em uma matrix menos densa. A outra camada do perisporo é a que forma as cristas equinatas e é constituída de filamentos dispostos em um arranjo compacto. Glóbulos de diferentes tamanhos são observados na superfície. As diferenças encontradas na ornamentação do perisporo e na ultraestrutura do Alsophila estudado previamente e aqueles de Sphaeropteris mostram uma tendência à complexidade da parede.

Sphaeropteris; esporos; morfologia; ultra-estrutura

BIOLOGICAL SCIENCES

Palynological analysis of Sphaeropteris gardneri (Cyatheaceae, Pteridophyta)

Gonzalo J. Marquez^I; Marta A. Morbelli^I; Gabriela E. Giudice^II

^ICátedra de Palinología, Facultad de Ciencias Naturales y Museo, UNLP Paseo Del Bosque s/n, 1900 La Plata Argentina

^IICátedra de Morfología Vegetal, Facultad de Ciencias Naturales y Museo, UNLP Paseo Del Bosque s/n, 1900 La Plata Argentina

^{Correspondence} Correspondence to: Gonzalo Marquez E-mail: cosme@fcnym.unlp.edu.ar

ABSTRACT

The spore morphology and wall ultrastructure of Sphaeropteris gardneri (Hook.) R.M. Tryon from Brazil were analyzed with LM, SEM and TEM. The spores are trilete with an ornamentation formed of short low ridges with spines in their margins. The exospore is 2.5μm thick, two- layered in section and single or branched channels are present. The perispore is 1.2μm thick and two-layered. The inner layer has three strata: the inner stratum is formed of a network of branched and fused threads, the middle stratum has threads with a radial orientation and in the outer stratum thin, dark fibres are immersed in a less dense contrasted matrix. The outer layer of the perispore is the one that forms the echinate-ridges and is constituted of threads arranged in a compact way. Globules of different sizes are observed on the surface. The differences found in the perispore ornamentation and ultrastructure in Alsophila, which was previously studied, and those of Sphaeropteris, show a tendency to wall complexity.

Key words:Sphaeropteris, spores, morphology, ultrastructure.

RESUMO

A morfologia dos esporos e a ultraestrutura da parede de Sphaeropteris gardneri (Hook.) R.M. Tryon, Brasil, foram analisadas com MO, MEV e MET. Os esporos são trilete com uma ornamentação formada por cristas curtas e baixas e com espinhos em suas margens. O exosporo possui 2,5μm de espessura, duas camadas em secção e estão presentes canais simples ou ramificados. A camada interna possui três estratos: o estrato interno é formado por uma rede de filamentos ramificados e fusionados, o estrato médio tem fios com uma orientação radial e no estrato externo fino, fibras escuras estão imersas em uma matrix menos densa. A outra camada do perisporo é a que forma as cristas equinatas e é constituída de filamentos dispostos em um arranjo compacto. Glóbulos de diferentes tamanhos são observados na superfície. As diferenças encontradas na ornamentação do perisporo e na ultraestrutura do Alsophila estudado previamente e aqueles de Sphaeropteris mostram uma tendência à complexidade da parede.

Palavras-chave:Sphaeropteris, esporos, morfologia, ultra-estrutura.

INTRODUCTION

The Sphaeropteris genus includes about 120 species (Tryon and Tryon 1982), most of them are distributed in Asia and Oceania. Six species (Tryon 1971, Windisch 1977) were reported in America: S. Brunei (Christ) Tryon, S. cuatrecasasii Tryon, S. Gardneri (Hook.) Tryon, S. horrida (Liebm.) Tryon, S. Insignis (D.C. Eaton) Tryon and S. quinduiensis (Karst.) Tryon. The distinctive characteristics to differentiate this genus from the rest of the Cyatheaceae is the presence of conform scales at the bases of the petioles (Tryon 1970) and spores with echinate perispore (Korall et al. 2007).

The former classification of the Cyatheaceae was proposed by Holttum (1963). This author takes the kind of scale at the base of the petioles as a diagnostic characteristic. Within Cyathea subg. Sphaeropteris, it includes the species that have settiferous scales. Tryon (1970) built later a new classification of the Cyatheaceae and proposed the Sphaeropteris genus to gather the species with conform scales (= settiferous) at the petiole bases.

In 1987, Lellinger differentiated four genera in the Cyatheaceae: Cyathea, Alsophila, Cnemidaria and Sphaeropteris. Within Sphaeropteris, the author included the species of the Old World, and the six species that constitute the "neotropical group S. horrida".

Recent works about phylogeny of the Cyatheaceae, including morphologic, molecular and paleontologic data, have supported Lellinger criteria regarding the origin of Sphaeropteris genus (Conant et al. 1994, 1995, 1996, Korall et al. 2006, 2007). In these works, Conant et al. (1996) and Korall et al. (2007) used the spore morphology in order to support the phylogenetic hypothesis.

Sphaeropteris gardneri (Hook.) R.M. Tryon is an endemic species from South Brazil and the only species of this genus in Southern South erica. It is characterized by having sphaeropteroids indusia, the abaxial surface of the costulae covered with abundant simple or ramified trichomes, and small scales and scamules on the abaxial surfaces of pinnae (Tryon 1971, Fernandes 1997). Its distribution area comprises Rio de Janeiro, Minas Gerais, São Paulo and Santa Catarina States.

Regarding the palynological antecedents on the genus, Erdtman and Sorsa (1971) described with LM Sphaeropteris cooperi (under Cyathea) spores. Gastony and Tryon (1976) analyzed Sphaeropteris spores with SEM and noticed a significant variability in their ornamentation.

In 1976, Liew and Wuang worked with SEM on Cyatheaceae spores from Taiwan and gave a key for species determination, taking into account the palynological characteristics. The authors characterized the spores of Sphaeropteris and those of some Alsophila species as echinulate and established relationships based on the spore morphology.

Tryon and Tryon (1982) made a distinction of the species of Sphaeropteris from America and considered three spore types based on the perispore characteristics. Based on observations with LM and SEM, Braggins and Large (1990) described the Sphaeropteris medullaris spores (under Cyathea medullaris) as having narrow, rare or absent proximally and abundant distally echinae.

The works of Lugardon (1971, 1974) were the first to describe the wall ultrastructure in these spores. This author illustrated with TEM the Sphaeropteris cooperi spores, native species from Australia, and S. medulla-ris, from New Zealand and Fiji. The author described a blechnoide exospore and a two-layered perispore, with a deep layer composed of three strata. In 1991, Tryon and Lugardon described and illustrated, with scanning and transmission electron microscopes, the spores of the Cyatheaceae. The spores of Sphaeropteris subgenus Sphaeropteris were characterized by having echinae on low ridges and with TEM, showed a complex three-layered perispore.

The aim of this work is to analyze the spore morphology and wall ultrastructure in Sphaeropteris gardneri with LM, SEM and TEM. The results obtained were compared with those published for other taxa of the genus and with spore of Alsophila species from the study area. In this way we hope to complete the knowledge on this species, contribute to works about conservation in the area and give new data to phylogenetic studies that other authors have carried out.

This work is included in the Project about spore morphology and ultrastructure of the Cyatheaceae that grows in Southern South America. Previous contributions related to this project, regarding the spore analysis in the Alsophila genus, were those of (Marquez et al. 2005, 2006, 2007, 2009).

METHODOLOGY

Spores were obtained from herbarium specimens from the Instituto Anchietano de Pesquisas (PACA). Spores of different specimens were studied by using light microscopy (LM), scanning electron microscopy (SEM) and transmission electron microscopy (TEM). For LM, untreated spores were studied.

On the basis of LM observations and measurements (25 spores for each sample), values of polar diameter, equatorial diameter, exospore and perispore thickness were obtained.

For SEM, the material was treated with hot 3% sodium carbonate, washed, dehydrated, suspended in 96% ethanol and, then, transferred to acetate plates. After drying, they were coated with gold.

All the observations were performed with an Olympus BH2 light microscope and a JEOL JSMT-100 SEM.

For studies with TEM, dry material from herbarium specimens was hydrated following the technique proposed by Rowley and Nilsson (1972) that consists on the use of a buffer plus alcian blue (AB); then, the material was fixed with 1% glutaraldehyde (GA) + 1% AB in phosphate buffer for 12 h, and postfixed with 1% OsO4 in water plus 1% AB.

The spores were dehydrated in an acetone series and, then, embedded in Spurr soft mixture. 3μm thick sections were stained with toluidine blue and observed with LM. Ultra-thin sections were stained with 1% uranyl acetate for 15 min, followed by lead citrate for 3 min. The observations were made with a Zeiss M-10 TEM.

The terms proposed by Lugardon (1981) and Tryon and Lugardon (1991) were used for describing globules, spore surface and structure.

STUDIED MATERIAL

Brazil: Santa Catarina, Mun. Papanduva, Serra do Espigão, 20/04/1962, Reitz and Klein 12656 (PACA); Biguaçu, Antinha, 04/03/1943, Reitz 232 (PACA); Ilhota, Morro de Baú, 21/01/1953, Reitz 5170 (PACA).

RESULTS

The spores of Sphaeropteris gardneri are trilete, triangular in polar view, with straight to slightly concave sides and rounded angles (Fig. 1A-B), and convex-hemispheric in equatorial view (Fig. 1C). The equatorial diameter is 42.3 (45.6) 49μm and the polar diameter is 34 (36.5) 39.8μm. The apertural folds are straight and reach the equator.

Short low ridges, parallel to the spore sides, are observed with SEM. The ridge margin bears conic spines 1.2-1.9μm high, which are abundant in the distal hemisphere, and are few or absent on apertural folds. In some cases, the spines could be fused by their bases (Fig. 1D-E).

With SEM, spheroids of different sizes are observed on the surface (Fig. 1E).

As seen with LM, the exospore is light brown, 2.5μm thick. With TEM, two layers are evident: a thin inner layer and a highly contrasted thick outer layer. Single or branched channels are present at the apertural fold sides and base (Figs. 1G, 2B).

The perispore is 0.7-2.1 μm thick and dark brown under LM. Using TEM, two layers can be differentiated. The inner layer (IP) is composed of three strata: the outer stratum (o) is 150-200 nm thick, with dark fibres immerse in a less dense contrasted matrix. The middle stratum (m) is 100-200 nm thick. It is composed of an amorphous substance traversed throughout by threads with channels running along its whole length, with a mainly radial orientation. This complex system is branched, forming a network of threads in the inner stratum (i) that is 90-150 nm thick.

The outer layer of the perispore (OP) is 0.8-1.5μm thick and forms the echinate-ridges. In section and at an ultrastructural level, this layer is constituted of interwoven threads in a compact arrangement (Figs. 1F-G, 2A-C).

In TEM sections, spheroids of different sizes are seen on the surface, with a low electro dense core. In some cases, these elements can be fused to one another and to the perispore (Fig. 2A).

DISCUSSION AND CONCLUSIONS

The spores of Sphaeropteris gardneri have a surface formed of short low ridges with high spines in their margins. These results are similar to those observed by other authors for other taxa of the genus (Tryon 1971, Erdt-man and Sorsa 1971, Gastony and Tryon 1976, Liew and Wuang 1976, Braggins and Large 1990, Tryon and Lugardon 1991, Conant et al. 1996, Korall et al. 2007).

The spines are higher and ore abundant in the distal hemisphere, and few on the apertural folds. Braggins and Large (1990) observed similar characteristics in Sphaeropteris medullaris.

The spore surface is smooth and with spheroids of different sizes. When analyzed under TEM, the spheroids have a low electro-dense center similar to that ofthe exospore, and a contrasted coat with similar structure to that of the perispore. Based on these ultrastructural characteristics, it can be inferred that the spheroids are "globules", according to Lugardon's definition (1981).

At the ultrastructural level, we recognized an exo-spore with two layers. The outer layer is thicker than the inner layer and has a deep stratum with many channels and cavities. This kind of exospores was defined by Lugardon (1974) as "blechnoid".

The perispore is composed of two layers, an inner layer with three strata and an outer one with a massive structure. This stratification coincides with the observations by Lugardon (1971, 1974) in Sphaeropteris coope-ri and S. medullaris. Our interpretation differs in some aspects referring to the perispore from that offered by Lugardon (l.c.). Thus, our observations showed that the inner perispore layer is formed of threads, that are arranged according to different patterns. Based on the spatial distribution and the frequency of fusion of these elements, each stratum has a different aspect. Nerverless, Lugardon (l.c.) observed that the strata were formed of a lumpy substance, in which dark lumps are fused.

In the present contribution, the outer perispore layer is interpreted as formed of densely packed threads. This particular arrangement of the elements and their chemical nature, make difficult its contrast with the usual fixatives and stains in electron microscopy. That would probably be the reason why some authors interpreted the outer part of the perispore as homogenous (i.e. Tryon and Lugardon 1991). Recently, Marquez et al. (2009) studied the spores of Alsophila species (Cyatheaceae) of Southern South America and found a strong similitude between this structure and that of Sphaeropteris. Differences were observed in the perispore ultraestructure and ornamentation, which is echinate-ridged in Sphaeropte-ris and cristate-ridged in Alsophila. In Sphaeropteris, the threads that form the outer perispore layer are densely packed, and give it a homogeneous aspect. In Alsophila,the threads of the perispore are loosely interwoven and, in some cases, they form bunches.

Thus, it can be suggested that the differences found between the perispore of Alsophila and that of Sphaeropteris show a tendency to wall complexity. These data support the conclusions of Liew and Wuang (1976) concerning the primitive character of the echinate ornamentation within the family, and would reinforce the phylogenetic hypotesis that proposes Sphaeropteris as a basal group within the Cyatheaceae (Tryon 1970, Korall et al. 2006).

An intermediate structural and morphologic type between both genera is observed in Alsophila capensis, which grows in Southern Brazil and West Africa. The spores of this species have ridges with slender spines on the margin (Marquez et al. 2009). The observations made in this study are related to spore ornamentation and would give information for a better understanding of the identity of A. capensis that, according to the recent phylogenetic analysis by Korall et al. (2007), would form a group differentiated from Alsophila and Sphaeropteris.

These studies make evident the high complexity of the spore wall of some groups of ferns. Further studies would increase our knowledge about the spores in this group and, particularly, about perispore development and the probable function of each of its structural components.

ACKNOWLEDGMENTS

This study was possible thanks to grants from the National Agency of Promotion of Science and Technology, PICT 12758, and for Project 451 from La Plata University. The authors thank the Instituto Anchietano de Pesquisas (PACA) for the material supplied for this study.

Manuscript received on January 12, 2009; accepted for publication on November 16, 2009

BRAGGINS JE AND LARGE MF. 1990. Spore morphology as a taxonomic data source in Cyathea J.E. Smith and Asplenium L. Rev Palaebot Palynol 64: 149-158.
CONANT DS, STEIN DB, VALINSKI AEC, SUDARSANAM P AND AHEARN ME. 1994. Phylogenetic Implications of chloroplast DNA variation in the Cyatheaceae. I Syst Bot 19: 60-72.
CONANT DS, RAUBESON LA, ATTWOOD DK AND STEIN DB. 1995. The relationships of Papuasian Cyatheaceae to New World Tree Ferns. Amer Fern J 85: 328-340.
CONANT DS, RAUBESON LA, ATTWOOD DK, PERERA S, ZIMMER EA, SWEERE JA AND STEIN DB. 1996. Phylogenetic and evolutionary implications ofcombinedanalysis of DNA and morphology in the Cyatheaceae. Proceeding of the Holttum Memorial Pteridophyte Symposium. Royal Botanic Gardens, Kew, p. 231-247.
ERDTMAN G AND SORSA P. 1971. Pollen and spore morphology/plant taxonomy. Pteridophyta (test and additional illustrations). Almqvist and Wiksell, Stockholm, 302 p.
FERNADES I. 1997. Taxonomia e Fitogeografia de Cyatheaceae e Dicksoniaceae nas Regiões Sul e Sudeste do Brasil. Tese de Doutorado, universidade de São Paulo, 435 p.
GASTONY GJ AND TRYON R. 1976. Spore morphology in the Cyatheaceae, 2. The genera Lophosoria, Metaxia, Sphaeropteris, Alsophila and Nephelea. Amer J Bot 63: 738-758.
HOLTTUM RE. 1963. Cyatheaceae. Fl. Males. Bull. Ser. II. Pteridophyta 1(2): 65-176.
KORALL P, PRYER KM, METZGAR JS, SCHNEIDER H AND CONANT DS. 2006. Tree ferns: Monophyletic groups and their relationships as revealed by four protein-coding plastid loci. MolPhylogenetEvol39: 830-845.
KORALL P, CONANT DS, METZGAR JS, SCHNEIDER H AND PRYER KM. 2007. A molecular phylogeny of scaly Tree Ferns (Cyatheaceae). Amer J Bot 94: 873-886.
LELLINGER DB. 1987. The disposition of Trichopteris (Cyatheaceae). Amer Fern J 77: 90-94.
LIEW FS AND WANG SC. 1976. Scanning electron microscopical studies on the spores of Pteridophytes. VIII. The tree fern faily (Cyatheaceae) and its allied species found in Taiwan. Taiwania 21: 251-267.
LUGARDON B. 1971. Contribution à la connaissance de la morphogenèse et de la structure des parois sporales chez les Filicinées isosporées. Thèse Univ. Paul Sabatier Toulouse, 257 p., 51pl. h.t.
LUGARDON B. 1974. La structure fine de l'exospore et de la périspore des Filicinées isosporées. Pollen Spores 16: 161-226.
LUGARDON B. 1981. Les globules des Filicinées homologues des corps d'Ubisch des Spermatophytes. Pollen Spores 16: 161-226.
MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2005. Análisis Palinológico en Alsophila incana (H. Karst.) D.S. Conant (Cyatheaceae) de Argentina. Bol Soc Arg Bot40(Supl): 187.
MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2006. Estudio Palinológico de las especies de Alsophila (Cyatheaceae) que crecen en Argentina. Actas del XIII Simposio Argentino de Palinología y Paleobotánica. Bahía Blanca, Argentina.
MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2007. Morfología y ultraestructura de las esporas de Alsophila (Cyatheaceae) del Cono Sur. Bol Soc Arg Bot 42(Supl): 123.
MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2009. Spore comparative analysis of Alsophila (Cyatheaceae) species from Southern South America. Rev Paleobot Palynol 156: 165-176.
ROWLEY JR AND NILSSON S. 1972. Structural stabilization for electron microscopy of pollen from herbarium specimens. Grana 12: 23-30.
TRYON AF AND LUGARDON B. 1991. Spores of the Pteri-dophyta. Surface, wall structure and diversity based on electron microscope studies. Springer, New York, NY, 648 p.
TRYON RM. 1970. The classification of the Cyatheaceae. Contr Gray Herb 200: 3-53.
TRYON RM. 1971. The American tree ferns allied to Sphaeropteris horrida. Rhodora 73: 1-19. Tryon RM and Tryon AF. 1982. Ferns and allied plants with special reference to tropical America. Springer, New York, NY, 857 p.
WINDISCH PG. 1977. Synopsis of the genus Sphaeropteris (Cyatheaceae) with a revision of the neotropical exindusiate species. Bot Jahrb Syst 98: 176-198.

Correspondence to:

Gonzalo Marquez

E-mail:

cosme@fcnym.unlp.edu.ar

Publication Dates

Publication in this collection
11 June 2010
Date of issue
June 2010

History

Received
12 Jan 2009
Accepted
16 Nov 2009

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] BRAGGINS JE AND LARGE MF. 1990. Spore morphology as a taxonomic data source in Cyathea J.E. Smith and Asplenium L. Rev Palaebot Palynol 64: 149-158.

[2] CONANT DS, STEIN DB, VALINSKI AEC, SUDARSANAM P AND AHEARN ME. 1994. Phylogenetic Implications of chloroplast DNA variation in the Cyatheaceae. I Syst Bot 19: 60-72.

[3] CONANT DS, RAUBESON LA, ATTWOOD DK AND STEIN DB. 1995. The relationships of Papuasian Cyatheaceae to New World Tree Ferns. Amer Fern J 85: 328-340.

[4] CONANT DS, RAUBESON LA, ATTWOOD DK, PERERA S, ZIMMER EA, SWEERE JA AND STEIN DB. 1996. Phylogenetic and evolutionary implications ofcombinedanalysis of DNA and morphology in the Cyatheaceae. Proceeding of the Holttum Memorial Pteridophyte Symposium. Royal Botanic Gardens, Kew, p. 231-247.

[5] ERDTMAN G AND SORSA P. 1971. Pollen and spore morphology/plant taxonomy. Pteridophyta (test and additional illustrations). Almqvist and Wiksell, Stockholm, 302 p.

[6] FERNADES I. 1997. Taxonomia e Fitogeografia de Cyatheaceae e Dicksoniaceae nas Regiões Sul e Sudeste do Brasil. Tese de Doutorado, universidade de São Paulo, 435 p.

[7] GASTONY GJ AND TRYON R. 1976. Spore morphology in the Cyatheaceae, 2. The genera Lophosoria, Metaxia, Sphaeropteris, Alsophila and Nephelea. Amer J Bot 63: 738-758.

[8] HOLTTUM RE. 1963. Cyatheaceae. Fl. Males. Bull. Ser. II. Pteridophyta 1(2): 65-176.

[9] KORALL P, PRYER KM, METZGAR JS, SCHNEIDER H AND CONANT DS. 2006. Tree ferns: Monophyletic groups and their relationships as revealed by four protein-coding plastid loci. MolPhylogenetEvol39: 830-845.

[10] KORALL P, CONANT DS, METZGAR JS, SCHNEIDER H AND PRYER KM. 2007. A molecular phylogeny of scaly Tree Ferns (Cyatheaceae). Amer J Bot 94: 873-886.

[11] LELLINGER DB. 1987. The disposition of Trichopteris (Cyatheaceae). Amer Fern J 77: 90-94.

[12] LIEW FS AND WANG SC. 1976. Scanning electron microscopical studies on the spores of Pteridophytes. VIII. The tree fern faily (Cyatheaceae) and its allied species found in Taiwan. Taiwania 21: 251-267.

[13] LUGARDON B. 1971. Contribution à la connaissance de la morphogenèse et de la structure des parois sporales chez les Filicinées isosporées. Thèse Univ. Paul Sabatier Toulouse, 257 p., 51pl. h.t.

[14] LUGARDON B. 1974. La structure fine de l'exospore et de la périspore des Filicinées isosporées. Pollen Spores 16: 161-226.

[15] LUGARDON B. 1981. Les globules des Filicinées homologues des corps d'Ubisch des Spermatophytes. Pollen Spores 16: 161-226.

[16] MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2005. Análisis Palinológico en Alsophila incana (H. Karst.) D.S. Conant (Cyatheaceae) de Argentina. Bol Soc Arg Bot40(Supl): 187.

[17] MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2006. Estudio Palinológico de las especies de Alsophila (Cyatheaceae) que crecen en Argentina. Actas del XIII Simposio Argentino de Palinología y Paleobotánica. Bahía Blanca, Argentina.

[18] MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2007. Morfología y ultraestructura de las esporas de Alsophila (Cyatheaceae) del Cono Sur. Bol Soc Arg Bot 42(Supl): 123.

[19] MARQUEZ GJ, MORBELLI MA AND GIUDICE GE. 2009. Spore comparative analysis of Alsophila (Cyatheaceae) species from Southern South America. Rev Paleobot Palynol 156: 165-176.

[20] ROWLEY JR AND NILSSON S. 1972. Structural stabilization for electron microscopy of pollen from herbarium specimens. Grana 12: 23-30.

[21] TRYON AF AND LUGARDON B. 1991. Spores of the Pteri-dophyta. Surface, wall structure and diversity based on electron microscope studies. Springer, New York, NY, 648 p.

[22] TRYON RM. 1970. The classification of the Cyatheaceae. Contr Gray Herb 200: 3-53.

[23] TRYON RM. 1971. The American tree ferns allied to Sphaeropteris horrida. Rhodora 73: 1-19. Tryon RM and Tryon AF. 1982. Ferns and allied plants with special reference to tropical America. Springer, New York, NY, 857 p.

[24] WINDISCH PG. 1977. Synopsis of the genus Sphaeropteris (Cyatheaceae) with a revision of the neotropical exindusiate species. Bot Jahrb Syst 98: 176-198.