Equisetopsida

Equisetopsida

▪ plant class
Introduction

      (division Pteridophyta), class of primitive spore-bearing vascular plants. Most members of the group are extinct and known only from their fossilized remains. The sole living genus, Equisetum (horsetail), order Equisetales, is made up of 15 species of very ancient herbaceous plants, the horsetails and scouring rushes. Extinct members of the division, some of which have been traced back as far as the Devonian Period (416 to 359 million years ago), include many herbaceous Equisetales, shrubby Hyeniales, vinelike Sphenophyllales, and trees of the family Calamitaceae.

General features
      Sphenophytes, fossil and living, characteristically have whorled leaves and branches and conspicuously jointed stems (stem), which in many cases are also ribbed. Reproductive structures are present in the form of greatly compressed stems called cones (cone), or strobili, which form at the ends of branches.

      The giant extinct horsetails ( Calamites) were trees up to 1 metre (3 feet) in diameter and 30 metres (100 feet) in height. Their leaves—like those of extant horsetails—were arranged in spokelike whorls at regular intervals along the jointed stems. In the Sphenophyllales, an extinct order of scrambling sphenophytes, the leaves were wedge-shaped, with a repeatedly forking (dichotomous) venation system (sphenophylls). The order Hyeniales included shrublike plants with inconspicuous leaves arranged in rather indistinct whorls.

      The living species of Equisetum are distributed worldwide except for Australia, New Zealand, and Antarctica. Most of them are less than one metre (three feet) tall. There are reports of specimens of E. giganteum, from the American tropics, that attain a height of about 10 metres with a stem diameter of only 4 centimetres (1.6 inches); support is apparently provided by their habit of growing in dense stands and by surrounding vegetation in their natural environment. The majority of Equisetum species are found in wet or damp habitats, often in shaded locations along streams, ditches, and canals; some species, however, have become adapted to drier and sunnier conditions.

      The extant sphenophytes have little economic importance, although some species are cultivated in marshy areas as pond plants. The extinct giant types contributed to the coal beds formed in the Carboniferous Period (359 to 299 million years ago). Living horsetails have been used as scouring agents, their cleansing value being attributed to the abrasive action of the silica-laden walls of certain of their cells. Silica is only one of several minerals that horsetails selectively accumulate in their bodies. Gold is another—up to 0.15 gram per kilogram (4.5 ounces per ton) of plants—not economically feasible to mine but a certain indication of the availability of such ore deposits in the soil. Horses foraging on stands of Equisetum have been known to die from severe intestinal inflammation.

Life cycle
      Horsetails, like other vascular plants, display an alternation of generations: (alternation of generations) an asexual phase, represented by a sporophyte (the horsetail plant), and a sexual phase, the gametophyte, an inconspicuous, delicate, green plant. Each year, many gametophytes are initiated from spores, but apparently very few produce sporophytes in nature. Horsetails apparently survive mainly by vegetative reproduction rather than by a regular dependence on the sexual cycle.

      Some horsetails carry terminal cones (strobili) on green aerial branches. Other species, however, have separate upright, aerial branches for vegetative and for reproductive shoots. In these species the strobilate branches appear first, and, after the spores are shed, the green vegetative shoots develop. The fertile components of the strobilus are called sporangiophores; each consists of a stalk bearing a flattened disk at its apex, on the lower edge of which is a ring of 5 to 10 sporangia, each one opening and shedding spores by a longitudinal slit on its inner side. The Carboniferous treelike horsetails and their smaller allies are believed to have possessed the most elaborate reproductive strobili known among the vascular plants.

      Sphenophytes are homosporous, producing only one kind of spore. The spores have four bands, or elaters, which coil and uncoil in response to changes in humidity, assisting in the dispersal of the spores. Under low light intensity and high humidity, the spores germinate to form small, flattened, green gametophytes. After a period of development, these gametophytes come to resemble miniature green pincushions up to 3 centimetres (1.2 inches) in diameter. Eggs are produced in archegonia, at the bases of upright lobes on the gametophytes, and sperm are produced in antheridia, present on the lobes. The egg is fertilized in the archegonium by a sperm, forming a zygote which, by continued divisions, develops an embryo within the archegonium. The embryo (young sporophyte) is nourished by the gametophyte until it develops its own shoot and roots. One gametophyte may support two or more young sporophytes before it ultimately dies and decays.

Form and function
      The sporophyte of a typical sphenophyte consists of stem, leaves, and roots. The underground part of the stem (the rhizome) and the aerial part show the same basic organization. They consist of distinct segments united end to end at the nodes, which are the origins of the roots and leaves. (This jointed structure is the source of the alternative name Articulatae, which was applied to Equisetopsida by some earlier authorities.)

      The slender, herbaceous stems of Equisetum have hollow internodes. The whorled leaves are greatly reduced and nonphotosynthetic and are united laterally at each node to form a toothed sheath around the stem. Each toothlike leaf has a single, unbranched midvein. Secondary growth, by which girth increases annually, was characteristic of the extinct Calamitaceae and Sphenophyllales. In Equisetum the vascular strands are small and round, surrounding a large pith cavity. In the majority of species, the cell walls of the outer cell layer (epidermis) are thick and contain silica deposits. Branch buds are initiated at the nodes, but their subsequent development is dependent on the growth characteristics of the particular species. In relatively unbranched species, bud growth remains inhibited.

      Spores develop in spore cases (sporangia), which are borne on sporangiophores. These are organized into strobili, which may be associated with sterile bracts (much reduced leaves)—as in Sphenophyllales and Calamitaceae—or may be without them (Hyeniales, Equisetaceae). Each sporangiophore in Equisetum has 5 to 10 sporangia. The entire sporangiophore may have arisen as a condensed, dichotomous branch system, with each sporangium occupying the end of a branch but lying parallel to the stalk of the sporangiophore.

Cytogenetics
      Chromosome numbers in Equisetum are uniformly x = 108. Several hybrids are known, but all are sterile as there is no doubling of the chromosome number to allow chromosome pairing and consequent production of viable spores.

Evolution and classification

Evolutionary development
      Certain Equisetopsida flourished as trees (e.g., Calamites species) during the coal-forming Carboniferous Period, but the earliest sphenophytes appeared as early as the Devonian. In its fossil history the class constituted a much larger portion of the flora of the Earth than it does at the present time.

      Equisetum, which may also have been present during the Carboniferous, is perhaps one of the oldest living genera of vascular plants. The more primitive species have perennial, green shoots. The advanced species have annual, green, branched, vegetative shoots and often nongreen, unbranched, fertile shoots. Intermediate combinations of these features occur in some species.

Annotated classification
      Botanists recognize four to six different orders in the class. Only one order, Equisetales, has both living and extinct species; all others comprise extinct sphenophytes. The latter are indicated by a dagger (†) in the listing below.

Division Pteridophyta (lower vascular plant) (ferns and fern allies, pteridophytes)
 
      Class Equisetopsida (horsetails)
 Extinct and living primitive, seedless, homosporous vascular plants with jointed, ribbed stems and whorls of leaves at regular intervals along the stem.

      †Order Hyeniales (Protoarticulatae)
 Extinct shrublike plants, with short, forked leaves in whorls; 1 family: Hyeniaceae (now placed with the Polypodiopsida—true ferns—by some paleobotanists).

      †Order Pseudoborniales
 One family, Pseudoborniaceae, with a single extinct species, Pseudobornia ursina; 15 to 20 metres (50 to 65 feet) tall.

      †Order Sphenophyllales
 Extinct scrambling or vinelike understory plants, 1 metre (3 feet) tall, with small, wedge-shape leaves; 2 families: Sphenophyllaceae and Cheirostrobaceae.

      Order Equisetales
 Two families: Calamitaceae, extinct tree horsetails; and Equisetaceae, herbaceous living horsetails and fossil allies with needlelike leaves in whorls along the stem; 15 extant species in the genus Equisetum and several extinct species in the genus Equisetites.

Critical appraisal
      The extant genus Equisetum is a small remnant of a once diverse and dominant plant group. Although the genus includes two rather distinct groups, modern botanists recognize but a single genus.

Ernest M. Gifford John T. Mickel

Additional Reading
A comprehensive summary of paleobotanical knowledge is provided in Thomas N. Taylor and Edith L. Taylor, The Biology and Evolution of Fossil Plants (1993). Current research in the field is assembled by the American Fern Society in its publications American Fern Journal (quarterly) and Fiddlehead Forum (bimonthly); and by the British Pteridological Society in The Fern Gazette (annual) and Pteridologist (annual).John T. Mickel, How to Know the Ferns and Fern Allies (1979), with keys, brief descriptions, and illustrations, is the first manual to cover all of North America. Flora of North America Editorial Committee (ed.), Flora of North America, North of Mexico, vol. 2, Pteridophytes and Gymnosperms (1993); and Rolla M. Tryon, Alice F. Tryon, and Walter H. Hodge, Ferns and Allied Plants (1982), are good summaries of the genera of tropical American pteridophytes with descriptions, maps, discussions, and many illustrations. John T. Mickel and Joseph M. Beitel, Pteridophyte Flora of Oaxaca, Mexico (1988), provides a well-illustrated and informative pteridophyte manual for a region in Latin America.Life cycle and habitats are discussed in A.F. Dyer and Christopher N. Page (eds.), Biology of Pteridophytes (1985), a collection of symposium papers on a broad range of topics; Barbara Joe Hoshizaki, Fern Growers Manual, rev. and expanded ed. (2001), a good introduction to horticulture with encyclopaedic information on the species in cultivation; and Christopher N. Page, Ferns: Their Habitats in the British and Irish Landscape (1988), with excellent illustrations of habitats and ecology.Studies of form and function include K.R. Sporne, The Morphology of Pteridophytes: The Structure of Ferns and Allied Plants, 4th ed. (1975), a concise summary of ideas on fern structure; John T. Mickel, Ferns for American Gardens (1994, reissued 2003), a useful compilation of information on fern morphology, diversity, and cultivation; and Lenore W. May, “The Economic Uses and Associated Folklore of Ferns and Fern Allies,” The Botanical Review, 44(4):491–528 (October 1978), a summary of the diverse uses to which ferns have been put.The origin and evolution of ferns and fern allies is detailed in I. Manton, Problems of Cytology and Evolution in the Pteridophyta (1950), a milestone in the biology of ferns containing, for the first time, accurate data on chromosomes in relation to evolution and systematics; and J.D. Lovis, “Evolutionary Patterns and Processes in Ferns,” Advances in Botanical Research, 4:229–439 (1977), an outstanding summary of the knowledge of fern phylogeny and classification. Also useful are appropriate sections of Robert F. Scagel et al., An Evolutionary Survey of the Plant Kingdom (1965); Ernest M. Gifford and Adriance S. Foster, Morphology and Evolution of Vascular Plants, 3rd ed. (1989); and David W. Bierhorst, Morphology of Vascular Plants (1971), which provides detailed treatments of vascular plants together with theory and interpretation. Paul Kenrick and Peter R. Crane, The Origin and Early Diversification of Land Plants (1997), summarizes modern views on the evolution of the major lineages of land plants.Nomenclature for the taxonomy of sphenophytes is provided in R.L. Hauke, “The Taxonomy of Equisetum: An Overview,” New Botanist, 1:89–95 (1974); K.U. Kramer and P.S. Green, Pteridophytes and Gymnosperms (1990); and J.A. Crabbe, A.C. Jermy, and John T. Mickel, “A New Generic Sequence for the Pteridophyte Herbarium,” The Fern Gazette, 11(2/3):141–162 (1975), a list of pteridophyte genera in a phylogenetic sequence.Warren H. Wagner, Jr. Ernest M. Gifford John T. Mickel

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