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Cycadeoidea

Cycadeoidea is an extinct genus of gymnospermous seed plants within the order Bennettitales, characterized by short, stout, unbranched or rarely branched trunks up to 1 meter in diameter, helically arranged persistent leaf bases, and pinnate leaves resembling those of modern cycads.^[1] These plants bore bisporangiate (bisexual) cones embedded in the axils of leaf bases, featuring flower-like structures with a central ovulate receptacle surrounded by interseminal scales, stalked ovules, and microsporophylls bearing synangia.^[2] The cones remained closed at maturity, with orthotropous ovules and pollen grains that were small (≤25 μm), bilaterally symmetrical, and sulcate.^[3] Flourishing during the Mesozoic Era, Cycadeoidea first appeared in the Late Triassic and persisted until the Late Cretaceous, with peak diversity in the Jurassic and Lower Cretaceous.^[1] Fossils, often permineralized and anatomically preserved, have been documented worldwide, including notable occurrences in North America (e.g., Black Hills, South Dakota; Vancouver Island, British Columbia), Europe, and Asia.^[4] The genus was established in 1829 by William Buckland based on silicified trunks from the Isle of Portland, England, initially mistaken for cycad remains due to superficial similarities.^[3] Anatomically, Cycadeoidea trunks exhibited secondary xylem up to 11 mm wide and secondary phloem up to 6 mm wide, with distinctive tangential bands of fibers and sieve elements in the phloem, uniseriate rays, and vascular tissues supporting the embedded cones.^[1] Seeds featured a multilayered integument (endotesta, sclerotesta, sarcotesta) and a vascularized nucellus, lacking a pollen chamber, which provides key evidence for Bennettitales reproductive biology.^[3] These plants are significant in paleobotany for their potential role in seed plant evolution, particularly as models for understanding the origins of angiosperm-like flowers, and evidence suggests possible insect-mediated pollination or self-pollination mechanisms.^[2] Their decline in the Late Cretaceous coincides with the rise of flowering plants, highlighting shifts in Mesozoic ecosystems.^[3]

Taxonomy and Classification

Taxonomic History

The genus Cycadeoidea was first recognized from silicified trunks unearthed in the oolite quarries of the Isle of Portland, England, which were described by geologist William Buckland in 1828 as resembling modern cycads in their stout, columnar form and leaf scars. These fossils, preserved in Jurassic sediments, prompted Buckland to propose the name Cycadeoidea (initially as a subfamily "Cycadeoideae") to highlight their cycad-like external appearance, though internal anatomy later revealed distinct differences. The type species, C. megalophylla, was designated based on the largest and most complete specimens, which featured prominent leaf bases and armored stems. Although Buckland's 1828 description did not fully comply with nomenclatural requirements for valid publication (lacking a detailed diagnosis), the genus name was formally validated by John Lindley and William Hutton in 1832, who also recognized C. microphylla as a second species from the same locality. During the late 19th and early 20th centuries, prominent paleobotanists including Joseph Dalton Hooker and Albert C. Seward advanced the taxonomy through detailed anatomical studies, distinguishing Cycadeoidea from true cycads and contributing to debates on its placement within the emerging order Bennettitales, characterized by bisporangiate strobili unlike cycad pollen cones. Seward, in particular, emphasized the reproductive structures in his comprehensive works, helping to clarify affinities amid initial confusions with other Mesozoic gymnosperms. Classification proved challenging due to the fragmented preservation of fossils, often limited to isolated trunks or partial stems, which led to the description of over 30 species by the early 1900s, many based on minor variations in leaf scar patterns or stem diameter. Subsequent discoveries of more complete specimens, particularly from North American sites, allowed for consolidation, with numerous names synonymized as variants of a few core species like C. dacotensis and C. reichenbachiana. This over-description reflected broader issues in early paleobotany, where incomplete material obscured true diversity.^[5] Nomenclatural stability was further tested in 2016 when the genus's legitimacy was questioned due to priority conflicts with the earlier name Mantellia (proposed in 1828 for similar fossils), rendering Cycadeoidea technically superfluous. However, proposals to conserve Cycadeoidea were endorsed by the International Code of Nomenclature for algae, fungi, and plants, citing its entrenched use in over a century of paleobotanical literature and its role as the type genus for Cycadeoidaceae, ensuring retention despite the technical illegitimacy.

Current Placement and Synonyms

Cycadeoidea is classified within the kingdom Plantae, clade Tracheophytes, division Cycadeoideopsida, order Bennettitales (synonym Cycadeoideales), family Cycadeoideaceae, and genus Cycadeoidea.^[6]^[7] The type species is Cycadeoidea megalophylla (Buckland, 1828), originally described from Jurassic fossils in England.^[8] Accepted synonyms include Mantellia Brongniart (1828), Cylindropodium Saporta (1872), Bennettites Carruthers (1870), Zodites Oldham and Morris (1863), Pseudocycas Ward (1900), Bucklandia Brown (1840), and Paralycopodites Dawson (1862); these have been suppressed in favor of Cycadeoidea due to nomenclatural priority conflicts, taxonomic redundancy, and the genus's widespread use in paleobotany despite its initial illegitimacy.^[8]^[9] Within Bennettitales, Cycadeoidea serves as a core genus of the family Cycadeoideaceae, characterized by stout, unbranched trunks and bisporangiate cones, distinguishing it from related families like Williamsoniaceae.^[7] Despite morphological similarities to early angiosperms, such as flower-like reproductive structures, Cycadeoidea is not considered an ancestor to flowering plants, as it lacks key angiosperm traits like cupules, pollen chambers, and integumentary tracheids.^[7] Recent phylogenetic analyses post-2000, including those reevaluating seed cone anatomy, have affirmed the monophyly of Cycadeoideaceae based on shared traits such as radial seed orientation and vascularized nucelli, supporting its distinct position within Bennettitales as a monophyletic clade of Mesozoic gymnosperms.^[7]^[10]

Morphology and Anatomy

Vegetative Features

Cycadeoidea exhibited a distinctive vegetative body plan dominated by a short, barrel-shaped trunk that typically reached heights of 1-2 meters, often preserved in silicified form with an armored exterior composed of persistent leaf bases forming a ramentum of helically arranged scales. These trunks were generally unbranched or rarely branched, cylindrical to columnar in shape, and up to 1 meter in diameter, featuring a large central pith surrounded by an endarch eustele with secondary xylem and phloem. The secondary phloem was well-developed, consisting of alternating tangential bands of fibers and sieve elements, with fibers exceeding 1200 μm in length and 26-34 μm in diameter, exhibiting slit-like apertures on their lateral walls.^[2]^[11]^[11] The vascular anatomy of the trunk included manoxylic wood, a loose arrangement of secondary xylem filled with abundant parenchyma, which provided structural support but contrasted with the denser, compact pycnoxylic wood typical of conifers. Leaf traces were C-shaped, sometimes developing secondary xylem, and contributed to the overall eustele configuration. Immature leaves displayed circinate vernation, a coiling pattern observed in many fern-like and cycad-like plants.^[11]^[2]^[2] A crown of pinnate leaves, up to 1-2 meters long, topped the trunk, with wedge-shaped leaflets showing dichotomous venation and morphological similarity to those of modern cycads, though distinguishable by syndetocheilic stomata in the leaf cuticle. The root system was likely adventitious, emerging from the base of the trunk, as inferred from fossil specimens preserving root attachments and showing parenchymatous cells with microbial interactions.^[12]^[13]^[2] While Cycadeoidea shared a superficial cycad-like habit with living cycads, including stout trunks and pinnate foliage, key differences included the absence of girdling leaf traces, distinct stomatal morphology, and variations in stele structure, underscoring their placement within the Bennettitales rather than Cycadales.^[2]^[12]

Reproductive Structures

Cycadeoidea exhibits distinctive bisexual strobili, or cones, that are embedded deeply within the axils of the stem amid persistent leaf bases, remaining closed at maturity. These structures typically measure 3–8 cm in diameter and consist of a short peduncle supporting a central axis from which whorls of sterile bracts, microsporophylls, and megasporophylls arise in a compact, flower-like arrangement. The bracts subtend the fertile organs, providing structural support, while the overall bisporangiate configuration integrates both micro- and megasporangiate elements on a single receptacle.^[2]^[12] Microsporophylls are pinnate and recurved, with distal tips often fused, bearing clusters of microsporangia organized into synangia—fused pollen sacs that are reniform and multiloculate, containing 8-20 tubular sporangia each. Pollen grains produced within these synangia are boat-shaped, ranging from elliptic to prolate, approximately 25 μm long and 12 μm wide, and feature a single elongated sulcus, rendering them monosulcate with punctate to psilate exine ornamentation. This pollen morphology underscores the advanced reproductive adaptations of Bennettitales.^[2]^[14] The megasporangiate portion centers on a dome-shaped receptacle bearing stalked, orthotropous ovules, each enclosed in a cupule-like structure formed by 5-6 surrounding interseminal scales, with typically a single ovule per unit. Seeds develop from these ovules, featuring a three-layered integument comprising endotesta, sclerotesta, and sarcotesta, along with a prominent micropylar tube and two cotyledons in the embryo. The inflorescence's compact, bisexual design, comparable to the Williamsonia-type, has fueled hypotheses regarding Bennettitales' role in angiosperm evolution through shared floral-like traits.^[2]^[3] Anatomically, vascular traces originating from the stem's leaf traces extend into the reproductive units, forming a cylindrical bundle in the cortex that supplies the cone peduncle and fertile organs. Resin canals permeate the bracts and adjacent tissues, contributing to the plant's defensive architecture. These features highlight the integrated morphology distinguishing Cycadeoidea's reproduction from that of modern cycads.^[2]^[12]

Paleobiology and Ecology

Growth and Habitat

Cycadeoidea exhibited a perennial growth habit, typically forming short, barrel-like or columnar trunks that could reach heights of up to 2 meters and diameters of 60 cm, suggesting an arborescent or shrub-like form suited to the understory of Mesozoic forests.^[15] These plants were unbranched or sparingly branched in maturity, with persistent leaf bases forming an armored cortex, and their vascular system consisted of a eustele featuring a large central pith surrounded by a ring of secondary xylem and phloem.^[16] Evidence from preserved wood indicates secondary growth via a cambium, with some species displaying distinct growth rings—up to approximately 25 in certain trunks—implying an estimated lifespan of decades under favorable conditions.^[15] Fossil evidence points to habitat preferences in coastal, fluvial, or lacustrine environments of the Mesozoic, particularly in low, warm, and moist settings such as the fluviatile deposits of the Early Cretaceous Utrillas Formation or the Portland 'dirt bed' in England.^[17]^[15] Cycadeoidea tolerated seasonal wetness, as inferred from their occurrence in freshwater-influenced sediments, and co-occurred with ferns, conifers, ginkgos, and equisetums in these assemblages, indicating adaptation to humid, subtropical forest understories potentially disturbed by large herbivores like dinosaurs.^[18]^[15] In paleoecological terms, Cycadeoidea likely occupied a mid-successional niche, contributing to forest structure by providing shade for smaller flora through their dense frond crowns and persistent trunks, while their loose, parenchyma-rich wood—despite enabling larger sizes—reflected adaptation to warm, high-CO₂ atmospheres of the Jurassic and Cretaceous that supported rapid vegetative expansion.^[18]^[16] Their role as dominant seed plants in these ecosystems waned with the rise of angiosperms, but preserved trunks show no direct evidence of extensive herbivory, suggesting resilience in competitive, dynamic habitats.^[15]

Reproduction and Pollination

Cycadeoidea, as a representative of the Bennettitales, possessed bisporangiate cones that bore both microsporangia and megasporangia on a single axis, facilitating a reproductive strategy dominated by self-pollination. These cones remained closed at maturity, with pollen maturing prior to ovules, allowing pollen from synangia to contact the ovulate receptacle through developmental disintegration of the cone tissues.^[14]^[4] While self-pollination was likely the primary mode, evidence suggests potential for anemophily or entomophily as secondary mechanisms. The monosulcate pollen grains, elliptic to prolate in shape and measuring approximately 25–26 μm in length with a punctate-psilate exine, exhibit features compatible with wind dispersal, though the enclosed cone structure argues against it as dominant. Insect pollination is inferred from beetle borings and tunnels in the reproductive tissues, indicating possible incidental transfer during herbivory, but coprolites from these insects contain plant fragments without pollen, supporting limited pollinator efficiency.^[14]^[4] Fertilization in Cycadeoidea proceeded via pollen tube growth through the nucellus to the archegonium, without double fertilization, consistent with gymnosperm patterns and differing from angiosperms. This process likely involved slow pollen tube extension and possible dormancy, enabling ovule development post-pollination, as observed in related Bennettitales.^[14] Seed dispersal was constrained by the persistent, closed cones, primarily occurring through gravity upon cone decay or disintegration, with limited evidence for animal-mediated transport; inferences of winged or fleshy seeds remain speculative based on broader Bennettitales morphology. Fossil evidence from permineralized Early Cretaceous specimens in North America reveals in situ pollen and ovules within trunks, demonstrating a maturation sequence where microsporangia precede megasporangia, reinforcing selfing.^[14]^[4] The bisexual cone organization of Cycadeoidea holds evolutionary significance as a potential precursor trait in debates on the gymnosperm-angiosperm transition, with "flower-like" structures suggesting parallels to early angiosperm bisexuality, though recent phylogenies position Bennettitales outside the angiosperm clade.^[19]

Fossil Record

Geological Distribution

Cycadeoidea occurs from the Late Triassic to the Late Cretaceous, approximately 237 to 94 million years ago, with peak diversity in the Jurassic and Early Cretaceous.^[1]^[20] The genus is emblematic of Mesozoic gymnosperm diversification, flourishing alongside non-avian dinosaurs and the earliest birds during a period of dynamic terrestrial ecosystems.^[21] Abundance peaked in the Jurassic and Barremian and Aptian stages of the Early Cretaceous, when Cycadeoidea contributed significantly to coastal plain and fluvial floras across Laurasia and Gondwana.^[22] The genus declined in the Late Cretaceous, with fossils becoming rarer as environmental shifts favored other plant groups. This downturn is linked to competitive pressures from rising angiosperms, which disrupted established gymnosperm-dominated forest structures through superior resource acquisition and reproductive strategies.^[23] Stratigraphically, Cycadeoidea serves as a key marker in Mesozoic sequences, notably within the Wealden Group of southern England and the Potomac Group of eastern North America, where permineralized trunks and cones preserve details of its anatomy.^[24]^[25] These associations underscore its role in dating non-marine deposits from Triassic to Cretaceous systems.

Major Fossil Sites

Fossils of Cycadeoidea have been documented from several key localities worldwide, spanning the Mesozoic. In Europe, primarily in southern England, the Isle of Portland in Dorset yielded the earliest known specimens, consisting of silicified trunks from the Purbeck Group (Late Jurassic), which provided the basis for the genus description in 1828.^[24]^[26] On the Isle of Wight, permineralized material has been recovered from the Wealden Group (Early Cretaceous), including trunks that reveal detailed anatomical features through recent excavations.^[24] In North America, Triassic occurrences include C. marylandica from the Newark Supergroup in Maryland.^[27] The Black Hills region of South Dakota represents a major Jurassic site, where large silicified trunks were extensively collected from the Morrison Formation along the eastern rim, contributing to early systematic studies.^[28] On Vancouver Island, British Columbia, anatomically preserved cones and compressed specimens occur in Upper Cretaceous (Campanian) shales at localities such as Brannen Lake, offering insights into reproductive structures.^[3] Compressed remains are also noted from the Queen Charlotte Islands (now Haida Gwaii), though less abundant.^[25] Occurrences in Asia are less common but include trunk fragments from Cretaceous sediments in northeastern China, such as the Songliao Basin, and petrified material in Gondwanan deposits of India, like the Rajmahal Hills (Early Cretaceous).^[29] Silicification is the predominant mode of preservation for Cycadeoidea fossils, particularly in trunks, allowing for exceptional anatomical detail through permineralization in cherts and limestones.^[1] Rarer compressions in shales, as seen in some North American and Asian sites, preserve external morphology but limit internal study.^[3] Notable collections stem from 19th-century excavations, with the Yale Peabody Museum housing the largest assemblage of over a thousand American trunks from the Black Hills, amassed through efforts like those of G.R. Wieland.^[1] The Natural History Museum in London holds significant European specimens, including type material from Portland acquired in the late 1800s.^[30] These Mesozoic sites underscore the genus's widespread distribution from the Late Triassic to Late Cretaceous.

Diversity and Species

The genus Cycadeoidea encompasses approximately 7–10 accepted species, a marked reduction from more than 30 historically proposed taxa through extensive synonymy and taxonomic revisions in the 20th century.^[8]^[31] Among the key species is the type C. megalophylla Buckland ex P. Martin, distinguished by its large, pinnate leaves up to 1 m long with broad pinnae.^[32] C. microphylla (Ward) Wieland features smaller cones with fruits measuring 2–3 cm in diameter, reflecting more compact reproductive structures. C. etrusca (Gozzadini) Scott, known from silicified trunks found near an Etruscan tomb at Marzabotto, Italy, exhibits robust, unbranched stems up to 30 cm in diameter with persistent leaf bases.^[33] In North America, C. maccafferyi Rothwell, Stockey et C. P. Osborne is characterized by permineralized cones up to 7.8 cm long, containing radially arranged seeds 12–19 mm in length.^[3] Species within Cycadeoidea vary notably in trunk diameter (10–100 cm), leaf length (20 cm to over 1 m), and cone morphology, including differences in seed arrangement and bisporangiate structure.^[3]^[24]^[2] Delimiting species remains challenging due to the disarticulated nature of most fossils, where leaves, trunks, and reproductive organs are rarely found in organic connection, necessitating ongoing taxonomic revisions; no fully intact plants have been documented.^[3]^[24] The genus exhibits greater diversity in the Northern Hemisphere (Laurasia), though with occurrences in Gondwana, consistent with a predominantly Laurasian paleogeographic distribution during the Mesozoic.^[34]

References

[1]
Secondary phloem anatomy of Cycadeoidea (Bennettitales)
May 1, 2007 · The Bennettitales are a group of fossil seed plants known from the Triassic to the Cretaceous, with a worldwide distribution. Bennettitalean ...
[2]
Bennettitales - an overview | ScienceDirect Topics
Bennettitales was a group of seed plants with complex flower-like reproductive structures and either stocky cycad-like or thin divaricate-branching stems.Cycadeoidaceae · Williamsoniaceae · Ovulate Structures
[3]
Anatomically preserved Cycadeoidea (Cycadeoidaceae), with a ...
Sep 1, 2002 · Cycadeoids are an important extinct clade of Mesozoic seed plants also known as Bennettitales (Watson and Sincock, 1992). For nearly a century ...
[4]
(PDF) Pollen and coprolite structure in Cycadeoidea (Bennettitales)
The Mesozoic seed plant group Bennettitales is most comprehensively known from permineralized fossils of Cycadeoidea from the Lower Cretaceous of North ...
[5]
[PDF] Elaboration of the Fossil Cycads in the Yale Museum
As the Mantellianidi- formis of Brongniart is the Cycadeoidea megalophylla of Buckland, it is evident that Dr. Mantell supposed the speci- men to belong to ...
[6]
Cycadeoideales - IRMNG
Mar 15, 2018 · Cycadeoideales † ; Plantae (Kingdom) ; Tracheophyta (Phylum) ; Spermatophytina (Subdivision) ; Gymnospermae (Superclass) ; Cycadopsida (Class) ...Missing: hierarchy | Show results with:hierarchy
[7]
(PDF) Anatomically preserved Cycadeoidea (Cycadeoidaceae) With ...
Aug 5, 2025 · Superb preservation of the British Columbia cones confirms that Bennettitales lack a cupule, have radial seeds, and have a vascularized nucellus ...
[8]
The nomenclature of Cycadeoidea (fossil Spermatophyta
Aug 9, 2025 · The confused nomenclatural history of Mantellia (≡ Cycadeoidea) is summarized and corrected with new bibliographic and historical data. Since ...
[9]
A nomenclatural note on Monanthesia and Bennettites - ScienceDirect
Bennettites is the most important synonym of Cycadeoidea. •. We here designate B. gibsonianus as lectotype for Bennettites. Abstract.
[10]
Is the anthophyte hypothesis alive and well? New evidence from the ...
Jan 1, 2009 · Bennettitales is an extinct group of seed plants with reproductive structures that are similar in some respects to both Gnetales and angiosperms ...
[11]
(PDF) Secondary phloem anatomy of Cycadeoidea (Bennettitales)
Aug 5, 2025 · Fibers are long, more than 1200 μm, approximately 26.6-34.2 μm in diameter, and have slit-like apertures on the lateral walls. Sieve elements ...
[12]
Introduction to the Bennettitales
Bennettitaleans first appear in the Triassic and became extinct toward the end of the Cretaceous. Two major groups are recognized: the cycadeoids with stout ...<|control11|><|separator|>
[13]
1. Trunk and cone morphology, Cycadeoidea. (A) Transverse section...
Some parenchymatous bennettitalean root cells show interactions with chytrid fungi and bacteria; the remains of other fungi and fungi-like organisms are ...
[14]
[PDF] 3-Osborn-and-Taylor-2010.pdf
The Mesozoic seed plant group Bennettitales is most comprehensively known from permineralized fossils of Cycadeoidea from the Lower Cre- taceous of North ...
[15]
None
Below is a merged summary of all provided segments about *Cycadeoidea* from *American Fossil Cycads* and related sources. To retain all information in a dense and organized manner, I will use a table in CSV format for key details, followed by a narrative summary that consolidates additional context, such as paleoecology, climate, and co-occurring plants, which are not easily tabularized. The table will cover growth habit, habitat, trunk size, wood characteristics, growth rings, lifespan, and herbivory, while the narrative will address the remaining details.
[16]
[PDF] The Anatomy of Arborescent Plant Life through Time
In cross-section cycad and cycadeoid stems are eusteles, consisting of a large pith surrounded by a ring of vascular tissue, Figure 26. Figure 26. Cycadeoidea ...
[17]
Cycadeoidea marylandica (Bennettitales) from the late Albian of ...
The single specimen consists of a trunk fragment found in the late Albian deposits of the Utrillas Formation, near the village of Gargallo (NE Spain).
[18]
[PDF] Dark and disturbed: a new image of early angiosperm ecology
Plants were grown for 18 months under three light environments— 100%, 30%, and 5% full sunlight—before mea- surements were taken. Six ecological and ...
[19]
Defining the limits of flowers - PubMed Central - NIH
2009); similar condensation is believed to have led via strobili to cone formation in the ginkgos, cycads, pentoxyls and bennettites.
[20]
[PDF] Cretaceous Plants from Southwestern Colorado
This many-named conifer, or a very closely related species, is common in Lower Cretaceous strata in Vir- ginia, South Dakota, Montana, and California. With ...<|control11|><|separator|>
[21]
On Cycadeoidea gigantea, a new Cycadean Stem from the Purbeck ...
On Cycadeoidea gigantea, a new Cycadean Stem from the Purbeck Beds of Portland. Author: A. C. Seward, M.A., F.G.S.Authors Info & Affiliations. Publication ...
[22]
an aptian cycadeoid from the budden canyon formation, ono ... - jstor
We describe a cycadeoid trunk from the Aptian Chickabally Member, Budden Canyon Formation in Ono, California. Our diagnosis of the specimen as a cycadeoid ...
[23]
The Angiosperm Terrestrial Revolution and the origins of modern ...
Oct 26, 2021 · The rise of angiosperms triggered a macroecological revolution on land and drove modern biodiversity in a secular, prolonged shift to new, high levels.
[24]
The bennettitalean trunk genera Cycadeoidea and Monanthesia in ...
Large, silicified, bennettitalean trunks from the Mesozoic are perhaps the earliest fossil plants known to Man. They have been recovered from an Etruscan tomb ...
[25]
[PDF] GEOLOGICAL SURVEY - USGS Publications Warehouse
Descriptions of the species of Cycadeoidea, or fossil cycadean trunks, thus far discovered in the iron-ore belt, Potomac for- mation of Maryland. Proc. Biol ...
[26]
the songliao Basin of Northeast china, showing fossil locality (a)...
Well‐preserved Cretaceous trunk fragments of Cycadeoidea (Cycadeoidaceae) were recently found in Keshan County, Heilongjiang Province, Northeast China. These ...
[27]
Conserve Cycadeoidea and C. megalophylla - Wiley Online Library
Cycadeoidea with two intended species names, C. megalophylla and C. microphylla, first appeared in a brief report by Buckland (in. Proc. Geol. Soc. London 1: 80 ...
[28]
https://www.facebook.com/tatemuseum/posts/970533731748124
[29]
[PDF] LF Ward-Famous Fossil Cycad. - ART. VII.
of Cycadeoidea etrusca lay upon an Etruscan tomb at Marza- botto before it was discovered by Count Gozzadini in 1867 and found its way in 1878 to the ...
[30]
[PDF] pollination in the Bennettitales revisited - Verlag Berger
Apr 21, 2023 · Focusing on bisexual bennettitaleans, especially Cycadeoidea, we propose a novel explanation of how pollination occurred. Pollination was ...