Bracken

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Bracken
Pteridium aquilinum nf.jpg
Pteridium aquilinum [1]
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Plantae
Clade: Tracheophytes
Division: Polypodiophyta
Class: Polypodiopsida
Order: Polypodiales
Family: Dennstaedtiaceae
Genus: Pteridium
Gled. ex Scop. 1760 not Raf. 1814 (Pteridaceae)
Species

See text

Bracken (Pteridium) is a genus of large, coarse ferns in the family Dennstaedtiaceae. Ferns (Pteridophyta) are vascular plants that have alternating generations, large plants that produce spores and small plants that produce sex cells (eggs and sperm). Brackens are noted for their large, highly divided leaves. They are found on all continents except Antarctica and in all environments except deserts, though their typical habitat is moorland. The genus probably has the widest distribution of any fern in the world.

Contents

The word bracken is of Old Norse origin, related to Swedish bräken and Danish bregne, both meaning fern. In the past, the genus was commonly treated as having only one species, Pteridium aquilinum , but the recent trend is to subdivide it into about ten species.

Like other ferns, brackens do not have seeds or fruits, but the immature fronds, known as fiddleheads , are sometimes eaten, although some are thought to be carcinogenic.

Description

Sori (paler green) along outer edge on underside of leaves Pteridium leaf kz1.jpg
Sori (paler green) along outer edge on underside of leaves

Bracken is one of the oldest ferns, with fossil records over 55 million years old having been found. The plant sends up large, triangular fronds from a wide-creeping underground rootstock, and may form dense thickets. This rootstock may travel a meter or more underground between fronds. The fronds may grow up to 2.5 m (8 ft) long or longer with support, but typically are in the range of 0.6–2 m (2–6+12 ft) high. In cold environments, bracken is deciduous and, as it requires well-drained soil, is generally found growing on the sides of hills.

Fern spores are contained in structures found on the underside of the leaf called sori. The linear, leaf-edge pattern of these in bracken is different from that in most other ferns, where the sori are circular and occur towards the center of the leaf.

Species

[2]

  1. Pteridium aquilinum - nearly cosmopolitan
  2. Pteridium arachnoideum - Mexico, Central and South America, Galápagos
  3. Pteridium caudatum - Mexico, Central and South America, Florida, West Indies
  4. Pteridium centrali-africanum - Zaire, Zambia, Tanzania, Burundi
  5. Pteridium esculentum - China, Southeast Asia, Australia, New Zealand
  6. Pteridium falcatum - Guangxi
  7. Pteridium feei - Mexico, Central America
  8. Pteridium lineare - Yunnan
  9. Pteridium revolutum - China
  10. Pteridium tauricum - Caucasus
  11. Pteridium yunnanense - Yunnan

Distribution and habitat

Pteridium aquilinum (bracken or common bracken) is the most common species with a cosmopolitan distribution, occurring in temperate and subtropical regions throughout much of the world. It is a prolific and abundant plant in the moorlands of Ireland, where it is limited to altitudes of below 600 metres. It does not like poorly drained marshes or fen. It has been observed growing in soils from pH 2.8 to 8.6. Exposure to cold or high pH inhibits its growth. It causes such a problem in invading pasturelands that at one time the British government had an eradication programme. Special filters have even been used on some British water supplies to filter out the bracken spores. [3] [4]

Bracken is a characteristic moorland plant in Ireland which over the last decades has increasingly out-competed characteristic ground-cover plants such as moor grasses, cowberry, bilberry, and heathers, and now covers a considerable part of upland moorland. Once valued and gathered for use in animal bedding, tanning, soap and glass making, and as a fertiliser, bracken is now seen as a pernicious, invasive, and opportunistic plant, taking over from the plants traditionally associated with open moorland and reducing easy access by humans. It is toxic to cattle, dogs, sheep, pigs, and horses, and is also linked to cancers in humans. [5] It can harbour high levels of sheep ticks, which can pass on Lyme disease. Grazing provided some control by stock trampling, but this has almost ceased since the 2001 foot-and-mouth disease outbreak reduced commercial livestock production. Global climatic changes have also suited bracken well and contributed to its rapid increase in land coverage.

Bracken is a well-adapted pioneer plant which can colonise land quickly, with the potential to extend its area by as much as 1%–3% per year. This ability to expand rapidly at the expense of other plants and wildlife can cause major problems for land users and managers. It colonises ground with an open vegetation structure, but is slow to colonise healthy, well managed heather stands.

Bracken presents a threat to biodiversity. Many plant species occur only on upland moorland, tied to unique features in the habitat. The loss and degradation of such areas due to the dominance of bracken has caused many species to become rare and isolated.[ citation needed ]

Ecology

Evolutionarily, bracken may be considered one of the most successful ferns. It is considered highly invasive, and can survive in acid soils. [6]

Fungal associations

Woodland fungi such as Mycena epipterygia can be found growing under the bracken canopy. Both Camarographium stephensii and Typhula quisquiliaris grow primarily from dead bracken stems.

Other plant associations

Young bracken fronds curled Curled bracken fronds.JPG
Young bracken fronds curled

Bracken is known to produce and release allelopathic chemicals, which is an important factor in its ability to dominate other vegetation, particularly in regrowth after fire. Its chemical emissions, shady canopy, and thick litter inhibit other plant species from establishing themselves – with the occasional exception of plants which support rare butterflies. Herb and tree seedling growth may be inhibited even after bracken is removed, apparently because active plant toxins remain in the soil.

Bracken substitutes the characteristics of a woodland canopy, and is important for giving shade to European plants such as common bluebell and wood anemone where the woodland does not exist. These plants are intolerant to stock trampling. Dead bracken provides a warm microclimate for development of the immature stages. Climbing corydalis, wild gladiolus, and chickweed wintergreen also seem to benefit from the conditions found under bracken stands.

The high humidity in the stands helps mosses survive underneath, including Campylopus flexuosus, Hypnum cupressiforme , Polytrichum commune , Pseudoscelopodium purum and Rhytidiadelphus squarrosus.

Uses

Dried bracken bundles (P. aquilinum) at a food market in South Korea Dried Eastern brakenfern.jpg
Dried bracken bundles (P. aquilinum) at a food market in South Korea

Food

Warabimochi bracken jelly, a traditional Japanese dessert. The darker jelly on the left is made from pure bracken powder, while the lighter jelly on the right uses other starches as well. Senjuan Yoshimune warabimochi.jpg
Warabimochi bracken jelly, a traditional Japanese dessert. The darker jelly on the left is made from pure bracken powder, while the lighter jelly on the right uses other starches as well.

Bracken fiddleheads have been eaten by many cultures throughout history, either fresh, cooked, or pickled. Pteridium aquilinum is especially common in East Asian cuisine.

In Korea, bracken (sometimes referred to as 'fernbrake' in Korean recipes) is known as gosari (고사리), and is a typical ingredient in bibimbap , a popular mixed rice dish. [7] Stir-fried bracken (gosari namul ) is also a common side dish ( banchan ) in Korea. [8]

In Japan, bracken is known as warabi (わらび), and is steamed, boiled, or cooked in soups. Warabimochi bracken jelly, named after its resemblance to mochi rice cakes, is a popular traditional dessert, although commercial variants are often made with cheaper potato starch instead. The fiddleheads are also preserved in salt, sake, or miso. [9]

In China, bracken is known as juecai (蕨菜), and is eaten like vegetables or preserved by drying. Also called "fernbrake", it is used as a vegetable in soups and stews. [10]

Bracken rhizomes can be ground into flour to make bread. In the Canary Islands, the rhizome was historically used to make a porridge called gofio. [9] Both fronds and rhizomes have been used to produce beer in Siberia, and among indigenous peoples of North America. [9] [11]

Bracken leaves are used in the Mediterranean region to filter sheep's milk, and to store freshly made ricotta cheese. [9]

P. esculentum rhizomes were traditionally used by the Māori people of New Zealand as a staple food, and are known as aruhe. They were eaten by exploring or hunting groups away from permanent settlements. The plant was widely distributed across New Zealand as a result of prehistoric deforestation, and planting on rich soils, which produced the best rhizomes. The rhizomes were dried, and could be heated and softened with a pounder (patu aruhe), [12] after which the starch could be sucked from the fibers. Patu aruhe were important ritual items, and several distinct styles were developed. [13] [12]

Source of potash

Green bracken ferns average 25% potash and can contain as much as 55%. [14] It has advantages over other sources of plant ash, such as hardwood, due to its high potash yield as a percentage of both dry and fresh mass, abundance, growth rate, and ease of harvesting. [15] Bracken has been recognized as a source of potash since at least the 10th century AD, with numerous references in European texts, typically in relation to its use for soap and glass making. [15] The turn to mined sources of potash in the industrial age ended significant use of bracken as a source of potash, contributing to its status as a troublesome weed. [15]

Others

Bracken has traditionally been used for animal bedding, which later breaks down into a rich mulch that could be used as fertilizer. It is still used this way in Wales. [16] It is also used as a winter mulch, which has been shown to reduce the loss of potassium and nitrogen in the soil, and to lower soil pH. [16]

Toxicity

Bracken contains the carcinogenic compound ptaquiloside, which causes damage to DNA, thus leading to cancers of the digestive tract. [17] High stomach cancer rates are found in Japan and North Wales, where bracken is often eaten, but it is unclear whether bracken plays a role. [18] Consumption of ptaquiloside-contaminated milk is thought to contribute to human gastric cancer in the Andean states of Venezuela. [19] The spores have also been implicated as carcinogens.

However, ptaquiloside is water-soluble and destroyed in heat (by cooking) and alkaline conditions (by soaking). [20] Korean and Japanese cooks have traditionally soaked the shoots in water and ash to detoxify the plant before eating. [9] Ptaquiloside also degenerates at room temperature, and denatures almost completely at boiling temperature. [21] Despite this, moderation of consumption is still recommended to reduce chances of cancer formation. [21] The British Royal Horticultural Society recommends against consumption of bracken altogether, by both humans and livestock. [22]

Ptaquiloside has been shown to leach from wild bracken plants into the water supply, which has been implicated in high rates of stomach and oesophageal cancers in areas with high bracken growth, such as Wales and South America. [23]

Uncooked bracken also contains the enzyme thiaminase, which breaks down thiamine (vitamin B1). Excessive consumption of bracken can lead to vitamin B1 deficiency (beriberi), especially in animals with simple stomachs. Ruminants are less vulnerable because they synthesize thiamine. [24]

In animals

Ptaquiloside from bracken has been shown to be carcinogenic in some animals. [25] Animals may ingest the plant when other sources of food are unavailable, such as during droughts or after snowfalls.

In cattle, bracken poisoning can occur in acute and chronic forms, acute poisoning being the most common. Milk from cows that have eaten bracken may also contain ptaquiloside, which is especially concentrated in buttermilk. [23] In pigs and horses, bracken poisoning induces vitamin B1 deficiency. [26]

In insects

Hydrogen cyanide is released by the young fronds of bracken when eaten by mammals or insects. [27] Two major insect moulting hormones, alpha ecdysone and 20-hydroxyecdysone, are found in bracken. These cause uncontrollable, repeated moulting in insects ingesting the fronds, leading to rapid death. [28] Bracken is currently under investigation as a possible source of new insecticides. [29]

Archaeology

Bracken in Ireland with a linear pattern running across the hillside, a possible indication of past cultivation. Bleak hillside with bracken - geograph.org.uk - 1618991.jpg
Bracken in Ireland with a linear pattern running across the hillside, a possible indication of past cultivation.

Many sites have archaeological remains dating from the Neolithic and Bronze Ages through to the Industrial Revolution. The root systems of established bracken stands degrade archaeological sites by disrupting the strata and other physical evidence. These rhizomes may travel a metre or more underground between fronds and form 90% of the plant, with only the remainder being visible.

Control

Some small level of scattered cover can provide beneficial habitats for some wildlife, at least in the UK (as given above). However, on balance, removing bracken encourages primary habitats to re-establish, which are of greater importance for wildlife. Control is a complex question with complex answers, which need to form part of a wider approach. Management can be difficult and expensive; plans may need to be about cost-effective, practical limitation and control rather than give an expectation for eradication.

All methods need follow-up over time, starting with the advancing areas first. Given the decades elapsed to arrive at the current levels of coverage on many sites, slowing or reversing the process will be also of necessity long-term, with consistency and persistence from all parties being key.

Various techniques are recommended by Natural England and the RSPB to control bracken either individually or in combination RSPB Bracken management in the uplands.

Natural England recommends that only Asulam can be sprayed aerially, Glyphosate requires spot treatment, e.g. using a weedwiper or knapsack spray. The toxicity of Asulam is low and has been generally highly cost-effective but its use is now restricted by the EU after 2012, at least until specific registered uses can be defined.

Selective sprays like Starane, Access, Metsulfuron 600WG, etc. work well but only if sprayed in late autumn so the rhizomes store food for winter and hence absorb the poison.

On archaeological sites, chemical control is usually required as mechanical methods may cause damage.

Any bracken control programme must be completed, or bracken will re-establish.

A Bracken Control Group was established in 2012 to provide best-practice guidance for all bracken control techniques. The Group has also been responsible for submitting an application for an Emergency Authorisation to secure the continued availability of Asulam for bracken control, following the decision not to register the product under new regulations in the EU. Registration has been re-applied for but this will not be available until 2017 at the earliest. Until re-registration is approved the Group will aim to keep Asulam available under the emergency provisions. Bracken Control Group website

In culture

Bracken is commonly referred to by local populations in the north of England as 'Moorland Scrub'.[ citation needed ]

The creature ’Bracken’ from the 2023 video game Lethal Company is named after the plant.

See also

Related Research Articles

<span class="mw-page-title-main">Fern</span> Class of vascular plants

The ferns are a group of vascular plants that reproduce via spores and have neither seeds nor flowers. They differ from mosses by being vascular, i.e., having specialized tissues that conduct water and nutrients, and in having life cycles in which the branched sporophyte is the dominant phase.

Haumia-tiketike is the god of all uncultivated vegetative food in Māori mythology. He is particularly associated with the starchy rhizome of the Pteridium esculentum, which became a major element of the Māori diet in former times. He contrasts with Rongo, the god of kūmara and all cultivated food plants.

<span class="mw-page-title-main">Fiddlehead</span> Fronds of a young fern

Fiddleheads or fiddlehead greens are the furled fronds from a fledgling fern, harvested for use as a vegetable.

<i>Matteuccia</i> Species of fern in the family Onocleaceae

Matteuccia is a genus of ferns with one species: Matteuccia struthiopteris. The species epithet struthiopteris comes from Ancient Greek words στρουθίων (strouthíōn) "ostrich" and πτερίς (pterís) "fern".

<i>Platycerium</i> Genus of ferns

Platycerium is a genus of about 18 fern species in the polypod family, Polypodiaceae. Ferns in this genus are widely known as staghorn or elkhorn ferns due to their uniquely shaped fronds. This genus is epiphytic and is native to tropical and temperate areas of South America, Africa, Southeast Asia, Australia, and New Guinea.

<i>Dicksonia antarctica</i> Species of fern

Dicksonia antarctica, the soft tree fern or man fern, is a species of evergreen tree fern native to eastern Australia, ranging from south-east Queensland, coastal New South Wales and Victoria to Tasmania.

<i>Onoclea sensibilis</i> Species of fern

Onoclea sensibilis, the sensitive fern, also known as the bead fern, is a coarse-textured, medium to large-sized deciduous perennial fern. The name comes from its sensitivity to frost, the fronds dying quickly when first touched by it. It is sometimes treated as the only species in Onoclea, but some authors do not consider the genus monotypic.

<i>Pteridium aquilinum</i> Species of plant (fern)

Pteridium aquilinum, commonly called bracken, brake, pasture brake, common bracken, and also known as eagle fern, is a species of fern occurring in temperate and subtropical regions in both hemispheres. Originally native to Eurasia and North America, the extreme lightness of its spores has led to it achieving a cosmopolitan distribution.

<span class="mw-page-title-main">Dennstaedtiaceae</span> Family of ferns

Dennstaedtiaceae is one of fifteen families in the order Polypodiales, the most derived families within monilophytes (ferns). It comprises 10 genera with ca 240 known species, including one of the world's most abundant ferns, Pteridium aquilinum (bracken). Members of the order generally have large, highly divided leaves and have either small, round intramarginal sori with cup-shaped indusia or linear marginal sori with a false indusium formed from the reflexed leaf margin. The morphological diversity among members of the order has confused past taxonomy, but recent molecular studies have supported the monophyly of the order and the family. The reclassification of Dennstaedtiaceae and the rest of the monilophytes was published in 2006, so most of the available literature is not updated.

<i>Osmundastrum</i> Species of fern

Osmundastrum is genus of leptosporangiate ferns in the family Osmundaceae with one living species, Osmundastrum cinnamomeum, the cinnamon fern. It is native to the Americas and eastern Asia, growing in swamps, bogs and moist woodlands.

<i>Osmunda japonica</i> Species of fern

Osmunda japonica, also called Asian royal fern or fiddlehead, is a fern in the genus Osmunda native to east Asia, including Japan, China, Korea, Taiwan, and the far east of Russia on the island of Sakhalin. It is called gobi in Korean, zenmai in Japanese, and zǐqí or juécài in Chinese.

<i>Ceratopteris thalictroides</i> Species of aquatic plant

Ceratopteris thalictroides is a fern species belonging to the genus Ceratopteris, one of only two genera of the subfamily Parkerioideae of the family Pteridaceae.

<span class="mw-page-title-main">Ptaquiloside</span> Chemical compound

Ptaquiloside is a norsesquiterpene glucoside produced by bracken ferns during metabolism. It is identified to be the main carcinogen of the ferns and to be responsible for their biological effects, such as haemorrhagic disease and bright blindness in livestock and oesophageal, gastric cancer in humans. Ptaquiloside has an unstable chemical structure and acts as a DNA alkylating agent under physiological conditions. It was first isolated and characterized by Yamada and co-workers in 1983.

<i>Diplazium australe</i> Species of fern

Diplazium australe, commonly known as the Austral lady fern, is a small fern occurring in eastern Australia, New Zealand and Norfolk Island. The habitat is moist shaded areas, often occurring in rainforest.

<i>Pteridium esculentum</i> Species of plant

Pteridium esculentum, commonly known as bracken fern, Austral bracken or simply bracken, is a species of the bracken genus native to a number of countries in the Southern Hemisphere. Esculentum means edible. First described as Pteris esculenta by German botanist Georg Forster in 1786, it gained its current binomial name in 1908. The Eora people of the Sydney region knew it as gurgi.

<i>Calochlaena dubia</i> Species of fern

Calochlaena dubia, commonly known as soft bracken, false bracken, common ground fern or rainbow fern, is a small Australian fern in the treefern family Dicksoniaceae. It is very common within its range, and often seen growing under eucalyptus forest, often on the poorer quality soils. It is an easy plant to grow in the garden.

<i>Polystichum vestitum</i> Species of fern

Polystichum vestitum, commonly known as the prickly shield fern or pūnui (Māori), is a hardy, evergreen or semi-evergreen ground fern.

<i>Musotima nitidalis</i> Species of moth

Musotima nitidalis, also known as the golden brown fern moth, is a species of moth of the family Crambidae. This species was described by Francis Walker in 1866. It is native to Australia and New Zealand and was first found in Europe in 2009.

<i>Rhizomarasmius undatus</i> Species of fungus

Rhizomarasmius undatus is a small mushroom which grows on fern rhizomes.

Antheridiogens are a class of chemicals secreted by fern gametophytes that have "been shown to influence production of male gametangia and thus mating systems in a large number of terrestrial fern species". Antheridiogens are only observed in homosporous fern species, as all gametophytes are potentially bisexual.

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