Jump to content

Orchid

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by 209.247.21.225 (talk) at 22:41, 30 May 2007 (Appearance and Structure). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

Orchids
Color plate from Ernst Haeckel's Kunstformen der Natur
Scientific classification
Kingdom:
Division:
Class:
Order:
Family:
Orchidaceae

Subfamilies

For genera, see list of Orchidaceae genera.

Orchids (Orchidaceae family) are the largest and most diverse of the flowering plant (Angiospermae) families, with over 800 described genera and 25,000 species. Some sources give 30,000 species, but the exact number is unknown since classification differs greatly in the academic world. There are another 100,000+ hybrids and cultivars produced by horticulturists, created since the introduction of tropical species in the 19th century. The Kew World Checklist of Orchids includes about 24,000 accepted species. About 800 new species are added each year. Orchids, through their interactions with pollinators and their symbiosis with orchid mycorrhizal fungi, are considered by some, along with the grasses, to be examples of the most advanced (derived) floral evolution known.

All orchid species are protected for the purposes of international commerce under CITES as potentially threatened or endangered in their natural habitat, with most species listed under Appendix II. A number of species and genera are afforded protection under Appendix I, including all Cypripedium, Mexipedium, Paphiopedilum, Phragmipedium, and Selenipedium species. Many other species are protected by both international and national legislation, and while hybrids are supposed to be specifically exempted, hybrid orchids are not allowed into the United States without a CITES permit. The reason that is given is that the authorities cannot distinguish the difference between hybrids and species.[citation needed]

Naming

The term 'orchid' derives from the Greek ορχις orchis, meaning "NUTS", from the appearance of subterranean steroids for the gouch Orchis. The word "orchis" was first used by ompalumpas Theophrastos (372/371287/286 BC), in his book "De historia plantarum" (The natural history of plants). He was a student of butttouchumsAristotle and is considered the father of botany and ecology.q

Appearance and Structure

Orchids, like the ones in my @$$ grasses and the palms, which they resemble in some ways which remides my of farting& for instance the form of their gas form leaves—are monocotyledons. They have one cotyledon, or very gasey leaf, in contrast to the two of most flowering plants.

Orchids are cosmopolitan in distribution, occurring in every habitat, except Antarctica and deserts. The great majority are to be found in the tropics, mostly Asia, South America and Central America. They are found above the Arctic Circle, in southern Patagonia and even on Macquarie Island, close to Antarctica.

The following list gives a rough overview of their distribution:

  • Eurasia: 40–60 genera
  • North America: 20–30 genera
  • tropical America: 300–350 genera
  • tropical Africa: 125–150 genera
  • tropical Asia: 250–300 genera
  • Oceania: 50–70 genera

Orchids can be grouped according to the way they retrieve nutrients:

  • A majority of species are perennial epiphytes; they are found in tropical moist broadleaf forests or mountains and subtropics. These are anchored on other plants, mostly trees, sometimes shrubs. However, they are not parasites.
  • A few are lithophytes, similar to epiphytes but growing naturally on rocks or on very rocky soil. They derive their nutrients from the atmosphere, rain water, litter, humus, and even their own dead tissue.
  • Others are terrestrial plants. They grow in the soil or in the loose substrate atop the ground and obtain their nutrients from the soil or the substrate. This group includes nearly all temperate orchids.
  • Some lack chlorophyll and are myco-heterotrophs (formerly incorrectly called saprophytes). These achlorophyllous orchids have an ectomycorrhizal relationship, i.e. they are completely dependent on soil fungi feeding on decaying plant matter (usually fallen leaves) to provide them with nutrients. Typical examples include the Bird's-nest Orchid (Neottia nidus-avis) and Spotted Coral-root (Corallorrhiza maculata).

Most advanced orchids have these five basic features:

  • The presence of a column, also called gynostemium
  • The flower is bilaterally symmetric (zygomorphic)
  • The pollen are glued together into the pollinia, a mass of waxy pollen on filaments.
  • The seeds are microscopically small, lacking endosperm (food reserves) in the overall majority of the species. There are notable exceptions, such as Disa cardinalis, whose seeds may grow to a length of 1.1 mm. Seeds of Vanilla may weigh 20 times or more than that of other orchids.
  • The seeds can, under natural circumstances, only germinate in symbiosis with specialized fungi. Under artificial circumstances, however, germination is possible "in vitro" on sterile substrates of agar in specialized laboratories. Germinating seeds in agar, usually done in flasks, is an advanced technique, requiring sterility at all costs. It takes anywhere from one–up to five to ten years for an orchid seedling to mature. An alternative type artificial germination, however, is done by cultivating the fungus and sowing the seeds on them. This is called in-vitro symbiotic culture and is used most commonly for terrestrial orchids.

Leaves

This small orchid demonstrates a typical zygomorphic flower with three petal-like sepals (top, lower right, lower left), two normal petals on either side of the dorsal (upper) sepal, and the labellum, a modified lower petal in three parts surrounding and below the shiny column.

Orchids have simple leaves with parallel veins. Their shape is highly variable between species; ovate, lanceolate, or orbiculate. Their size and shape can be an aid in identifying the orchid, since it reflects the taxonomic position. The leaves can be enormous or minute, or they can even be lacking (as in the Ghost Orchid (Polyrrhiza lindenii), a mycoheterotrophic species, and Aphyllorchis and Taeniophyllum, which depend on their roots, which contain chlorophyll for photosynthesis).

The structure of the leaves corresponds to the specific habitat of the orchid. Species that typically bask in sunlight, or grow on sites which can be occasionally very dry, have thick, leathery leaves. The laminas are covered by a waxy cuticle. These retain their necessary water supply. Shade species, on the other hand, have tall, thin leaves. They cannot tolerate a drop in atmospheric humidity or exposure to direct sunlight. Between these two extremes, there is a whole range of intermediate forms.

The leaves of most orchids live on, attached to their pseudobulbs, for several years. Some species, especially those with plicate leaves, shed their aged leaves annually, through an articulation between the lamina and the petiole sheath, and develop new leaves together with new pseudobulbs (as in the genus Catasetum).

The leaves of some species can be most beautiful. The leaves of the Macodes sanderiana, a semiterrestrial or lithophyte, show a sparkling silver and gold veining on a light green background. The cordate leaves of Psychopsiella limminghei are light brownish green with maroon-puce markings, created by flower pigments. The attractive mottle of the leaves of Lady's Slippers from temperate zones (Paphiopedilum) is caused by uneven distribution of chlorophyll. Also Phalaenopsis schilleriana is a lovely pastel pink orchid with leaves spotted dark green and light green. The Jewel Orchid (Ludisia discolor) is grown more for its colorful leaves than its fairly inconspicuous white flowers.

Stem

The stem of an orchid determines the habit of the species. Each type of stem can grow in one of these two ways:

  • monopodial ("one-footed") growth. The new shoots grow upwards from a single stem, originating in the end bud of the old shoots. It then produces leaves and flowers along this stem. The stem of these orchids can reach a length of several meters (as in the genera Vanda and Vanilla).
  • sympodial ("many-footed") growth. The plant produces a series of adjacent shoots which grow to a certain size, bloom, then stop growing, to be replaced by the next growth. Plants of this type grow laterally rather than vertically, following the surface of their support. The growth continues by development of new leads (with their own leaves and roots) sprouting from or next to those of the previous year (as in the genus Cattleya). While this lead is developing, the rhizome may start its growth again, this time from an 'eye', or undeveloped bud, thereby causing the rhizome to branch.

Plant thallus and roots

Pseudobulbs of an epiphytic orchid

All orchids are perennial herbs, lacking any permanent woody structure.

  • Some orchids are terrestrial, growing rooted in the soil. Terrestrial orchids may be rhizomatous, forming corms or tubers. These act as storage organs for food and water. The root caps of terrestrials are smooth and white. Terrestrials are mostly found in colder climates.
  • A great many orchids are epiphytes, which do not require soil and use trees for support. They occur in warmer regions. Epiphytic orchids have modified aerial roots and, in the older parts of the root, an epidermis modified into a spongy, water-absorbing velamen, which can have a silvery-gray, white or brown appearance. The cells of the root epidermis grow at a right angle to the axis of the root. This allows them to get a firm grasp on their support. These roots can sometimes be a few meters long, in order to take up as much moisture as possible. Nutrients mainly come from animal droppings on their supporting tree that are washed down when it rains. The aerial roots of epiphytes that lack leaves have an additional function. They contain chlorophyll and take up carbon dioxide.
  • Several species are lithophytes, especially in rocky mountain ranges in Australia and Tasmania, central Brazil and Africa.

The base of the stem of sympodial epiphytes, or in some species essentially the entire stem, may be thickened to form what is called a pseudobulb. These contain nutrients and water for drier periods. Pseudobulbs have a smooth surface with lengthwise grooves. They typically stay alive for five or six years. They look on the inside more like a corm than the embryonal stage of leaf sheaths. They have different sizes and shapes. They can be conical or oblong. In the Black Orchids (Bulbophyllum), the pseudobulbs are no longer than 2 mm. The largest orchid in the world, the Giant Orchid (Grammatophyllum speciosum), has pseudobulbs with lengths of 2–3 m. When the orchid has aged and the pseudobulb has shed its leaves, the pseudobulb becomes dormant and is called a backbulb. The next year's pseudobulb then takes over, exploiting the last reserves of the backbulb. Eventually, the backbulb also dies off, having given life to newer growths. At the end of the pseudobulb typically appear one or two leaves, though there may be up to a dozen or more. Some Dendrobium have long, canelike pseudobulbs with short, rounded leaves over the whole length. Some orchids have hidden or extremely small pseudobulbs hidden completely inside leaves.

Some sympodial terrestrials, such as Orchis and Ophrys, have two subterranean tubers (more like tuberous roots) between the roots. One is used as a food reserve for wintery periods, and provides for the development of the other pseudobulb, from which visible growth develops.

In warm and humid climates, many terrestrial orchids do not need pseudobulbs.

Orchid flowers

Calopogon orchid
Wild orchid from Sumatran Rainforest

There are many types of specializations within the Orchidaceae. Best known are the seemingly endless structural variations in the flowers that encourage pollination by particular species of insects, bats, or birds.

Most African orchids are white, while Asian orchids are often multicolored. Some orchids only grow one flower on each stem, others sometimes more than a hundred together on a single spike.

The typical orchid flower is zygomorphic, i.e. bilaterally symmetric. Notable exceptions are the genera Mormodes, Ludisia and Macodes.

The flowers grow on racemes or panicles. These can be :

  • basal (i.e. produced from the base of the pseudobulb, as in Cymbidium)
  • apical (i.e. produced from the apex of the orchid, as in Cattleya)
  • or axillary (i.e. coming from a node between the leaf axil and the plant axis, as in Vanda).

The basic orchid flower is composed of three sepals in the outer whorl, and three petals in the inner whorl. The medial petal is usually modified and enlarged (then called the labellum or lip), forming a platform for pollinators near the center of the corolla. Together, except the lip, they are called tepals.

Sepals form the exterior of the bud. They are green in this stage, but sometimes, if the orchid blossom is, for example, purple, the buds can show a purple tint. When the flower opens, the sepals become intensely colored. Sepals may mimic petals such as in some phalaenopsis or be completely distinct. In many orchids, the sepals are mutually different and generally resemble the petals. It is not always easy to distinguish sepals and petals. The normal form can be found in Cattleya, with three sepals forming a triangle. But in Venus Slippers (Paphiopedilum) the lower two sepals are concrescent (fused together into a synsepal), while the lip has taken the form of a slipper. In Masdevallia all the sepals are fused into a calyx. In an example like this the sepals are very prominent, especially in lycaste orchids, the actual petals become diminished and inconspicuous.

The reproductive organs in the center (stamens and pistil) have adapted to become a cylindrical structure called the column or gynandrium. On top of the column lies the stigma, the vestiges of stamens and the pollinia, a mass of waxy pollen on filaments. These filaments can be a caudicle (as in Habenaria) or a stipe (as in Vanda). These filaments hold the pollinia to the viscidium (sticky pad). The pollen are held together by the alkaloid viscine. This viscidium adheres to the body of a visiting insect. The type of pollinia is useful in determining the genus. On top of the pollinia is the anther cap, preventing self-pollination. At the upper edge of the stigma of single-anthered orchids, in front of the anther cap, is the rostellum, a slender beaklike extension.

Reproduction

Bumblebee Orchid (Ophrys bombyliflora)

It is in the variety and the refinement of their reproductive methods that orchids truly amaze. On many orchids, the lip (labellum) serves as a landing pad for flying insects. The labellum is sometimes adapted to have a color and shape which attracts particular male insects via mimicry of a receptive female insect. Some orchids are reliant solely on this deception for pollination. After pollination, the epigynous ovary starts developing and produces a many-seeded capsule.

  • The Lady's Slipper (Paphiopedilum) has a deep pocket that traps visiting insects, with just one exit. Passage through this exit leads to pollinia being deposited on the insect.
  • Many neotropical orchids are pollinated by male orchid bees, which visit the flowers to gather volatile chemicals they require to synthesize pheromonal attractants. Each type of orchid places the pollinia on a different body part of a different species of bee, so as to enforce proper cross-pollination.
  • A Eurasian genus Ophrys has some species that look and smell so much like female bumblebees that male bees flying nearby are irresistibly drawn in and attempt to mate with the flower, such as with the Bumblebee Orchid (Ophrys bombyliflora). The viscidium, and thus pollinia, stick to the head or the abdomen of the bumblebee. On visiting another orchid of the same species, the bumblebee pollinates the sticky stigma with the pollinia. The filaments of the pollinia have, during transport, taken such position that the waxy pollen are able to stick in the second orchid to the stigma, just below the rostellum. Such is the refinement of the reproduction. If the filaments had not taken the new position on the bee, the pollinia could not have pollinated the original orchid. Other species of Ophrys are mimics of different bees or wasps, and are also pollinated by males attempting to mate with the flowers, and other orchid genera practice similar deception.
  • An underground orchid in Australia, Rhizanthella slateri, never sees the light of day, but depends on ants and other terrestrial insects to pollinate it.
  • Many Bulbophyllum species stink like rotting carcasses, and the flies they attract assist their reproduction.
  • Catasetum saccatum, a species discussed briefly by Darwin actually launches its viscid pollen sacs with explosive force, when an insect touches a seta. He was ridiculed for reporting this by the naturalist Thomas Huxley.
  • Some Phalaenopsis species in Malaysia are known to use subtle weather cues to coordinate mass flowering.
  • Some Phalaenopsis, Dendrobium and Vanda species produce keiki, offshoots or plantlets formed from one of the nodes along the stem, through the accumulation of growth hormones at that point.

The filaments of the pollinia of some orchids dry up if they haven’t been visited by an insect. This way, the waxy pollen falls on the stigma causing the orchid to self-fertilize.

  • Holcoglossum amesianum, native to China's Yunnan province, reproduces in a hermaphroditic manner, fertilizing itself by rotating its anther and insert it into the flower's stigma cavity. This mode of pollination is likely due to the lack of wind and insects in the region where this species grows. The Bee orchid uses a similar method of selfpollination.

Fruits and seeds

cross-section of an orchid capsule, showing 3 or 6 longitudinal slits

The orchid ovary is always inferior (located behind the flower), three-carpelate and one or three-partitioned, with parietal placentation (but axile in the Apostasioideae).

If pollination was successful, the sepals and petals fade and wilt but they remain attached to the ovary. The epigynous ovary typically develops into a capsule that is dehiscent by 3 or 6 longitudinal slits, while remaining closed at both ends. The ripening of a capsule can take 2–18 months. The microscopic seeds are very numerous (over a million per capsule in most species). They blow off after ripening like dust particles or spores, barely visible to the human eye. Since they lack endosperm, they must enter symbiotic relationship with mycorrhizal fungi to germinate. These fungi provide the necessary nutrients to the seeds.

File:Random 010e.jpg
An orchid seed capsule

All orchid species are reliant upon mycorrhizal associations with various basidiomyceteous fungi to complete their lifecycle. Although all orchids are mycoheterotrophic during germination, some achlorophyllous (lacking chlorophyll) species are entirely dependent upon these fungi for nutrients. In general, orchid mycorrhizal fungi decompose organic matter and subsequently translocate the obtained nutrients via their hyphae to the orchid. Because most orchid seeds are extremely tiny with no food reserves (endosperm lacking), they will not germinate without such a symbiont to supply nutrients in the wild. Some fungi continue to live in the roots of the adult orchid. This enables an orchid such as Neottia nidus-avis to function without chlorophyll. The chance for a seed to meet a fitting fungus is very small. Of all the seeds released, only a minute fraction grow into new orchids. This process can take years; in some cases up to fifteen years.

Horticultural techniques have been devised for germinating seeds on a nutrient-containing gel, eliminating the requirement of the fungus for germination, and greatly aiding the propagation of rare and endangered species.

Orchids in commerce

Phalaenopsis hybrid

One orchid genus, Vanilla, is commercially important, used as a foodstuff flavoring, the source of vanilla. The underground tubers of terrestrial orchids are ground to a powder and used for cooking, such as in the hot beverage salep or the so-called "fox-testicle ice cream" salepi dondurma. The scent of orchids is frequently used by perfumists (using Gas-liquid chromatography) to identify potential fragrance chemicals. With these exceptions, orchids have virtually no commercial value other than for the enjoyment of the flowers (see also Botanical orchids).

There are a great number of tropical and subtropical orchids, and these are the most commonly known, as they are available at nurseries and through orchid clubs across the world. There are also quite a few orchids which grow in colder climates, although these are less often seen on the market. Temperate species available at nurseries include Ophrys apifera (bee orchid), Gymnadenia conopsea (fragrant orchid), Anacamptis pyramidalis (pyramidal orchid) and Dactylorhiza fuchsii (common spotted orchid).

The family of orchids is remarkably diverse. The plants found in "casual" culture, such as Phalaenopsis, Cattleya, Dendrobium, and so forth, represent a tiny fraction of the thousands of species of orchids. Also within the Orchidaceae are "leafless" orchids, which often appear as nothing more than masses of roots, achlorophyllous orchids that are entirely reliant upon their mycorrhizal symbiont for their nutrition, "jewel" orchids with foliage that is as pretty as their flowers, and so many others that are capable of affecting the most dedicated of growers very deeply. Ranging in size from tiny moss-like Pleurothallis species to massive (7 m) Grammatophyllum species in New Guinea, their beauty and sophistication have captivated many.

The National Orchid Garden in the Singapore Botanic Gardens is considered by some to be among the finest collections of orchids in cultivation open to the public. In 2004, Taiwan established the Taiwan Orchid Plantation, a science-based industrial park, to develop its commercial orchid exports in the future. See also botanical orchids.

Orchids, like tulips, have become a major market throughout the world. Buyers now bid hundreds of dollars on new hybrids or improved ones. Because of their apparent ease in hybridization, they are now becoming one of the most popular cut-flowers on the market. Though orchid hybridization has been happening for many years, only recently has new technology made it into what it is.

Vanilla

Vanilla fruit

Vanilla (Vanilla planifolia and two other Vanilla species less commonly grown), is one of the rare examples of orchids used for food. Vanilla seeds and their surrounding pulp within the seed pod are used in the food industry to make the extremely popular flavoring "vanilla extract".

Vanilla was first cultivated in Central America where it was used, like today, as a flavoring. Vanilla cultivation was introduced to other parts of the world in the 1800s and it is now an important crop in much of the tropics. Madagascar is the leading producer, producing in 2005, 3 million metric tons (of a world total of 7.3 million metric tons). The Coca-Cola Company is the world's largest user of vanilla. Besides its use as a flavoring, it is also used in fragrances and perfumes.

Vanilla is a very labor intensive crop since the flowers have to be pollinated by hand. It is considered as one of the most profitable enterprises for small family farms. [1]

Taxonomy

The taxonomy of this family is in constant flux, as DNA studies give new information. An in-depth treatment of the taxonomy is given in Taxonomy of the Orchid family.

The following genera have been described (for a full list, see List of Orchidaceae genera with more than 800 genera and many pictures):

Aa; Abdominea; Acampe; Acanthephippium; Aceratorchis; Acianthus; Acineta; Acrorchis; Ada; Aerangis; Aeranthes; Aerides; Aganisia; Agrostophyllum; Amitostigma; Anacamptis; Ancistrochilus; Angraecum; Anguloa; Ansellia; Aorchis; Aplectrum; Arethusa; Armodorum; Ascocenda; Ascocentrum; Ascoglossum; Australorchis; Auxopus; Baptistonia; Barbrodia; Barkeria; Barlia; Bartholina; Beloglottis; Biermannia; Bletilla; Brassavola; Brassia; Bulbophyllum; Calypso; Catasetum; Cattleya; Cirrhopetalum; Cleisostoma; Clowesia; Coelogyne; Coryanthes; Cymbidium; Cyrtopodium; Cypripedium; Dactylorhiza; Dendrobium; Disa; Dracula; Encyclia; Epidendrum; Epipactis; Eria; Eulophia; Gongora; Goodyera; Grammatophyllum; Gymnadenia; Habenaria; Herschelia; Laelia; Lepanthes; Liparis; Ludisia; Lycaste; Masdevallia; Maxillaria; Mexipedium; Miltonia; Mormodes; Odontoglossum; Oncidium; Ophrys; Orchis; Paphiopedilum; Paraphalaenopsis; Peristeria; Phaius; Phalaenopsis; Pholidota; Phragmipedium; Platanthera; Pleione; Pleurothallis; Promenaea; Pterostylis; Renanthera; Renantherella; Restrepia; Restrepiella; Rhynchostylis; Saccolabium; Sarcochilus; Satyrium; Selenipedium; Serapias; Sophronitis; Spiranthes; Stanhopea; Stelis; Thrixspermum; Trias; Trichocentrum; Trichoglottis; Vanda; Vanilla; Zeuxine; Zygopetalum.

See also

References

  • Batygina, T. B., Bragina, E. A., and Vasilyeva, E. 2003. The reproductive system and germination in orchids. Acta Biol. Cracov. ser. Bot. 45: 21-34.
  • Berg Pana, H. 2005. Handbuch der Orchideen-Namen. Dictionary of Orchid Names. Dizionario dei nomi delle orchidee. Ulmer, Stuttgart
  • Kreutz, C. A. J. 2004. Kompendium der Europaischen Orchideen. Catalogue of European Orchids. Kreutz Publishers, Landgraaf, Netherlands
  • D. Lee Taylor and Thomas D. Bruns : Ectomycorrhizal mutualism by two nonphotosynthetic orchids; Proc. Natl. Acad. Sci. USA; Vol. 94, pp. 4510-4515, April 1997 (on line).

Template:Link FA Template:Link FA