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Wednesday, May 15, 2019

Chestnut tree

From Wikipedia, the free encyclopedia

Chestnut
Châtaignier 120807 1.jpg
Sweet chestnut Castanea sativa
Scientific classification
Kingdom: Plantae
Clade: Angiosperms
Clade: Eudicots
Clade: Rosids
Order: Fagales
Family: Fagaceae
Genus: Castanea
Mill.
Species

The chestnuts are a group of eight or nine species of deciduous trees and shrubs in the genus Castanea, in the beech family Fagaceae. They are native to temperate regions of the Northern Hemisphere.

The name also refers to the edible nuts they produce.

Species

Chestnuts belong to the family Fagaceae, which also includes oaks and beeches. The four main species groups are commonly known as American, European, Chinese, and Japanese chestnuts.
  • The two accepted species of American chestnuts are Castanea dentata (American chestnut – eastern states) and Castanea pumila (American or Allegheny chinkapin, also known as "dwarf chestnut" – southern and eastern states).
  • Asian chestnuts include Castanea mollissima (Chinese chestnut), Castanea henryi (Chinese chinkapin, also called Henry's chestnut – China), Castanea seguinii (also called Seguin's chestnut – China) and Castanea crenata (Japanese chestnut, Korean chestnut). A tropical version of chestnut trees can reach 20–30 m with fruits or seeds half the size of the Chinese version. It is edible and taste like C. mollissima. It is found in Malaysia and perhaps other Southeast Asian countries, as well. Perhaps because its seeds are relatively small, it is not commercially cultivated.
  • The European chestnut, Castanea sativa (sweet chestnut; also called "Spanish chestnut" in the US and the UK), is the only European species of chestnut, though it was successfully introduced to the Himalayas and other temperate parts of Asia.
Chestnuts should not be confused with horse chestnuts, in the genus Aesculus, which are not related to true chestnuts but are named for producing nuts of similar appearance that are mildly poisonous to humans. Nor should they be confused with water chestnuts, which are tubers of an aquatic herbaceous plant in the sedge family Cyperaceae. Other trees commonly mistaken for chestnut trees are the chestnut oak (Quercus prinus) and the American beech (Fagus grandifolia), both of which are also in the Fagaceae.

Etymology

Female chestnut flowers
 
Male chestnut flowers
 
The name "chestnut" is derived from an earlier English term "chesten nut", which descends from the Old French word chastain (Modern French, châtaigne). The French word in turn derives from Latin Castanea (also the scientific name of the tree), which traces to the Ancient Greek word κάστανον (sweet chestnut). A possible source of the Greek word is the ancient town of Kastanea in Thessaly; however, it is probable that the town took its name from the tree growing around it. In the Mediterranean climate zone, chestnut trees are rarer in Greece because the chalky soil is not conducive to the tree's growth. Kastania is located on one of the relatively few sedimentary or siliceous outcrops. They grow so abundantly there, their presence would have determined the place's name. Still others take the name as coming from the Greek name of Sardis glans (Sardis acorn) – Sardis being the capital of Lydia, Asia Minor, from where the fruit had spread.

The name is cited twice in the King James Version of the Bible. In one instance, Jacob puts peeled twigs in the water troughs to promote healthy offspring of his livestock. Although it may indicate another tree, it indicates the fruit was a local staple food in the early 17th century.

These synonyms are or have been in use: Fagus Castanea (used by Linnaeus in first edition of Species Plantarum, 1753), Sardian nut, Jupiter's nut, husked nut, and Spanish chestnut (U.S.).

Description

Chestnut trees are of moderate growth rate (for the Chinese chestnut tree) to fast-growing for American and European species. Their mature heights vary from the smallest species of chinkapins, often shrubby, to the giant of past American forests, C. dentata that could reach 60 m. Between these extremes are found the Japanese chestnut (C. crenata) at 10 m average; followed by the Chinese chestnut (C. mollissima) at about 15 m, then the European chestnut (C. sativa) around 30 m.

The Chinese and more so the Japanese chestnuts are both often multileadered and wide-spreading, whereas European and especially American species tend to grow very erect when planted among others, with little tapering of their columnar trunks, which are firmly set and massive. When standing on their own, they spread on the sides and develop broad, rounded, dense crowns at maturity. The latter two's foliage has striking yellow autumn coloring.

Bark - sweet chestnut (C. sativa)
 
Its bark is smooth when young, of a vinous maroon or red-brown color for the American chestnut, grey for the European chestnut. With age, American species' bark becomes grey and darker, thick, and deeply furrowed; the furrows run longitudinally, and tend to twist around the trunk as the tree ages; it sometimes reminds one of a large cable with twisted strands.

C. sativa male catkins (pale buff) and female catkins (green, spiny, partly hidden by leaves)
 
The leaves are simple, ovate or lanceolate, 10–30 cm long and 4–10 cm wide, with sharply pointed, widely spaced teeth, with shallow rounded sinuates between.

The flowers follow the leaves, appearing in late spring or early summer or into July. They are arranged in long catkins of two kinds, with both kinds being borne on every tree. Some catkins are made of only male flowers, which mature first. Each flower has eight stamens, or 10 to 12 for C. mollissima. The ripe pollen carries a heavy, sweet odor that some people find too sweet or unpleasant. Other catkins have these pollen-bearing flowers, but also carry near the twig from which these spring, small clusters of female or fruit-producing flowers. Two or three flowers together form a four-lobed prickly calybium, which ultimately grows completely together to make the brown hull, or husk, covering the fruits.

Chestnuts can be found on the ground around trees
 
Chestnut flowers are not self-compatible, so two trees are required for pollination. All Castanea species readily hybridize with each other. 

The fruit is contained in a spiny (very sharp) cupule 5–11 cm in diameter, also called "bur" or "burr". The burrs are often paired or clustered on the branch and contain one to seven nuts according to the different species, varieties, and cultivars. Around the time the fruits reach maturity, the burrs turn yellow-brown and split open in two or four sections. They can remain on the tree longer than they hold the fruit, but more often achieve complete opening and release the fruits only after having fallen on the ground; opening is partly due to soil humidity.

The chestnut fruit has a pointed end with a small tuft at its tip (called "flame" in Italian), and at the other end, a hilum – a pale brown attachment scar. In many varieties, the fruit is flattened on one or two sides. It has two skins. The first one is a hard, shiny, brown outer hull or husk, called the pericarpus; the industry calls this the "peel". Underneath the pericarpus is another, thinner skin, called the pellicle or episperm. The pellicle closely adheres to the seed itself, following the grooves usually present at the surface of the fruit. These grooves are of variable sizes and depths according to the species and variety. 

The fruit inside these shows two cotyledons with a creamy-white flesh throughout, except in some varieties which show only one cotyledon, and whose episperm is only slightly or not intruded at all. Usually, these varieties have only one large fruit per burr, well rounded (no flat face) and which is called "marron" (marron de Lyon in France, marron di Mugello in Italy, or paragon). 

Chestnut fruit have no epigeal dormancy and germinate right upon falling to the ground in the autumn, with the roots emerging from the seed right away and the leaves and stem the following spring. Because the seeds lack a coating or internal food supply, they lose viability soon after ripening and must be planted immediately. 

The superior fruiting varieties among European chestnuts have good size, sweet taste, and easy-to-remove inner skins. American chestnuts are usually very small (around 5 g), but sweet-tasting with easy-to-remove pellicles. Some Japanese varieties have very large nuts (around 40 g), with typically difficult-to-remove pellicles. Chinese chestnut pellicles are usually easy to remove, and their sizes vary greatly according to the varieties, although usually smaller than the Japanese chestnut.

History

Europe

The sweet chestnut was introduced into Europe from Sardis, in Asia Minor; the fruit was then called the Sardian nut. It has been a staple food in southern Europe, Turkey, and southwestern and eastern Asia for millennia, largely replacing cereals where these would not grow well, if at all, in mountainous Mediterranean areas. Evidence of its cultivation by man is found since around 2000 BC. Alexander the Great and the Romans planted chestnut trees across Europe while on their various campaigns. A Greek army is said to have survived their retreat from Asia Minor in 401–399 BC thanks to their stores of chestnuts. Ancient Greeks, such as Dioscorides and Galen, wrote of chestnuts to comment on their medicinal properties—and of the flatulence induced by eating too much of it. To the early Christians, chestnuts symbolized chastity. Until the introduction of the potato, whole forest-dwelling communities which had scarce access to wheat flour relied on chestnuts as their main source of carbohydrates. In some parts of Italy, a cake made of chestnuts is used as a substitute for potatoes. In 1583, Charles Estienne and Jean Liébault wrote, "an infinity of people live on nothing else but (the chestnut)". In 1802, an Italian agronomist said of Tuscany that "the fruit of the chestnut tree is practically the sole subsistence of our highlanders", while in 1879 it was said that it almost exclusively fed whole populations for half the year, as "a temporary but complete substitution for cereals".

Boundary records compiled in the reign of John already showed the famous Tortworth Chestnut in South Gloucestershire, as a landmark; and it was also known by the same name of "Great Chestnut of Tortworth" in the days of Stephen. This tree measured over 50 feet (15 m) in circumference at 5 feet (1.5 m) from the ground in 1720. The Hundred Horse Chestnut in the chestnut forests on Mount Etna is the oldest living chestnut tree and is said to be even larger. Chestnut trees particularly flourish in the Mediterranean basin. In 1584, the governor of Genoa, which dominated Corsica, ordered all the farmers and landowners to plant four trees yearly, among which a chestnut tree – plus olive, fig and mulberry trees (this assumedly lasted until the end of Genoese rule over Corsica in 1729). Many communities owe their origin and former richness to the ensuing chestnut woods. In France, the marron glacé, a candied chestnut involving 16 different processes in a typically French cooking style, is always served at Christmas and New Year's time. In Modena, Italy, they are soaked in wine before roasting and serving, and are also traditionally eaten on Saint Simon's Day in Tuscany. In the Romagna region, roasted chestnuts are often served with a traditional wine, the Cagnina di Romagna. It is traditional to eat roasted chestnuts in Portugal on St. Martin's Day.

Their popularity declined during the last few centuries, partly due to their reputation of "food for poor people". Many people did not want to take chestnut bread as "bread" because chestnut flour does not rise. Some slandered chestnut products in such words as the bread which "gives a sallow complexion" written in 1770, or in 1841 "this kind of mortar which is called a soup". The last decades' worldwide renewal may have profited from the huge reforestation efforts started in the 1930s in the United States to establish varieties of C. sativa which may be resistant to chestnut blight, as well as to relieve the strain on cereal supplies. 

Chestnut output in 2005
 
The main region in Italy for chestnut production is the Mugello region; in 1996, the European Community granted the fruit Protected Geographic Indication (equivalent to the French Appellation d'Origine Contrôlée) status to the Mugello sweet chestnut. It is markedly sweet, peels easily, is not excessively floury or astringent, and has notes of vanilla, hazelnut, and, more subtly, fresh bread. There is no unpleasant aroma, such as yeast, fungus, mold or paper, which sometimes occur with other chestnuts. The main regions in France for chestnut production are the départements of Ardèche, with the famous "Châtaigne d'Ardèche" (A.O.C), of the Var (Eastern Provence), of the Cévennes (Gard and Lozère départements) and of the Lyon region. France annually produces over 1,000 metric tons, but still imports about 8,000 metric tons, mainly from Italy.

In Portugal's archipelago of Madeira, chestnut liquor is a traditional beverage, and it is gaining popularity with the tourists and in continental Portugal.

Asia

Always served as part of the New Year's menu in Japan, chestnuts represent both success and hard times—mastery and strength. The Japanese chestnut (kuri) was in cultivation before rice and the Chinese chestnut (C. mollissima) possibly for 2,000 to 6,000 years.

During British colonial rule in the mid-1700s to 1947, the sweet chestnut (C. sativa) was widely introduced in the temperate parts of the Indian subcontinent, mainly in the lower- to middle Himalayas. They are widely found in British-founded hill stations in northern India, and to a lesser extent in Bhutan and Nepal. They are mainly used as an ornamental tree and are found in almost all British-founded botanical gardens and official governmental compounds (such as larger official residences) in temperate parts of the Indian subcontinent. 

China has about 300 chestnut cultivars. Moreover, the 'Dandong chestnut' (belonging to the Japanese chestnut C. crenata) is a major cultivar in Liaoning Province.

North America

American Indians were eating the American chestnut species, mainly C. dentata and some others, long before European immigrants introduced their stock to America, and before the arrival of chestnut blight. In some places, such as the Appalachian Mountains, one-quarter of hardwoods were chestnuts. Mature trees often grew straight and branch-free for 50 feet (15 m), up to 100 feet, averaging up to 5 ft in diameter. For three centuries, most barns and homes east of the Mississippi River were made from it. In 1911, the food book The Grocer's Encyclopedia noted that a cannery in Holland included in its "vegetables-and-meat" ready-cooked combinations, a "chestnuts and sausages" casserole besides the more classic "beef and onions" and "green peas and veal". This celebrated the chestnut culture that would bring whole villages out in the woods for three weeks each autumn (and keep them busy all winter), and deplored the lack of food diversity in the United States's shop shelves.

Soon after that, though, the American chestnuts were nearly wiped out by chestnut blight. The discovery of the blight fungus on some Asian chestnut trees planted on Long Island, New York, was made public in 1904. Within 40 years, the nearly four billion-strong American chestnut population in North America was devastated; only a few clumps of trees remained in Michigan, Wisconsin, California and the Pacific Northwest. Due to disease, American chestnut wood almost disappeared from the market for decades, although quantities can still be obtained as reclaimed lumber. Today, they only survive as single trees separated from any others (very rare), and as living stumps, or "stools", with only a few growing enough shoots to produce seeds shortly before dying. This is just enough to preserve the genetic material used to engineer an American chestnut tree with the minimal necessary genetic input from any of the disease-immune Asiatic species. Efforts started in the 1930s are still ongoing to repopulate the country with these trees, in Massachusetts and many places elsewhere in the United States. In the 1970s, geneticist Charles Burnham began back-breeding Asian chestnut into American chestnut populations to confer blight resistance with the minimum difference in genes. In the 1950s, the Dunstan chestnut was developed in Greensboro, N.C., and constitutes the majority of blight-free chestnuts produced in the United States annually.

Today, the nut's demand outstrips supply. The United States imported 4,056 metric tons of European in-shell chestnuts worth $10 million in 2007. The U.S. chestnut industry is in its infancy, producing less than 1% of total world production. Since the mid-20th century, most of the US imports are from Southern Italy, with the large, meaty, and richly flavored Sicilian chestnuts being considered among the best quality for bulk sale and supermarket retail. Some imports come from Portugal and France. The next two largest sources of imports are China and South Korea. The French varieties of marrons are highly favored and sold at high prices in gourmet shops.

A study of the sector in 2005 found that US producers are mainly part-timers diversifying an existing agricultural business, or hobbyists. Another recent study indicates that investment in a new plantation takes 13 years to break even, at least within the current Australian market. Starting a small-scale operation requires a relatively low initial investment; this is a factor in the small size of the present production operations, with half of them being between 3 and 10 acres (12,000 and 40,000 m2). Another determining factor in the small productivity of the sector is that most orchards have been created less than 10 years ago, so have young trees which are as now barely entering commercial production. Assuming a 10 kg (22 lb) yield for a 10-year-old tree is a reliable conservative estimate, though some exceptional specimens of that age have yielded 100 kg (220 lb). So, most producers earn less than $5,000 per year, with a third of them not having sold anything so far.

Moreover, the plantings have so far been mostly of Chinese species, but the products are not readily available. The American Chestnut Foundation recommends waiting a while more before large-scale planting, because its associates (the American Chestnut Cooperators' Foundation and many others from education, research and industry sectors contributing to the program) and it are at the last stages of developing a variety that is as close as possible to the American chestnut, while having incorporated the blight-resistant gene of the Asiatic species. Considering the additional advantage that chestnut trees can be easily grown organically, and assuming the development of brands in the market and everything else being equal, home-grown products would reach higher prices than imports, the high volume of which indicates a market with expanding prospects. As of 2008, the price for chestnuts sold fresh in the shell ranges from $1.50/lb ($3.30/kg) wholesale to about $5/lb ($11/kg) retail, depending mainly on the size.

Australia, New Zealand

The Australian gold rush of the 1850s and 1860s led to the first recorded plantings of European chestnut trees, brought in from Europe by the first settlers. Along the years, most chestnut tree plantations were C. sativa stock, which is still the dominant species. Some of these are still standing today. Some trees in northern Victoria are around 120 years old and up to 60 m tall.

Chestnuts grow well in southwest Western Australia, which has cold winters and warm to hot summers. As of 2008, the country has just under 350 growers, annually producing around 1,200 metric tons of chestnuts, of which 80% come from northeast Victoria. The produce is mostly sold to the domestic fresh fruit market. Chestnuts are now slowly gaining popularity in Australia. A considerable increase in production is expected in the next 10 years, due to the increase in commercial plantings during the last 15 to 25 years. By far, the most common species in Australia is the European chestnut, but small numbers of the other species, as well as some hybrids have been planted.

The Japanese chestnut (C. crenata) does well in wet and humid weather and in hot summers (about 30 °C); and was introduced to New Zealand in the early 1900s, more so in the upper North Island region.

Nutrition

Chestnuts (raw, peeled)
Nutritional value per 100 g (3.5 oz)
Energy820 kJ (200 kcal)

44 g
Sugars11 g

1.3 g

1.6 g

VitaminsQuantity %DV
Vitamin A equiv.
0%
1 μg
Thiamine (B1)
13%
0.144 mg
Riboflavin (B2)
1%
0.016 mg
Niacin (B3)
7%
1.102 mg
Vitamin B6
27%
0.352 mg
Folate (B9)
15%
58 μg
Vitamin B12
0%
0 μg
Vitamin C
48%
40.2 mg

MineralsQuantity %DV
Calcium
2%
19 mg
Iron
7%
0.94 mg
Magnesium
8%
30 mg
Phosphorus
5%
38 mg
Potassium
10%
484 mg
Sodium
0%
2 mg
Zinc
5%
0.49 mg

Other constituentsQuantity
Water60.21 g
Percentages are roughly approximated using US recommendations for adults.
Source: USDA Nutrient Database

Chestnuts depart from the norm for culinary nuts in that they have very little protein or fat, their calories coming chiefly from carbohydrates. Fresh chestnut fruits have about 180 Cal or kcal (800 kJ) per 100 g of edible parts, which is much lower than walnuts, almonds, other nuts, and dried fruit (about 600 kcal/100 g). Chestnuts contain very little fat, mostly unsaturated, and no gluten.

Their carbohydrate content compares with that of wheat and rice; chestnuts have twice as much starch as the potato on an as-is basis. In addition, chestnuts contain about 8% of various sugars, mainly sucrose, glucose, fructose, and, in a lesser amount, stachyose and raffinose, which are fermented in the lower gut, producing gas. In some areas, sweet chestnut trees are called "the bread tree". When chestnuts are just starting to ripen, the fruit is mostly starch and is very firm under finger pressure from the high water content. As the chestnuts ripen, the starch is slowly converted into sugars, and moisture content also starts decreasing. Upon pressing the chestnut, a slight 'give' can be felt; the hull is not so tense, and space occurs between it and the flesh of the fruit. They are the only "nuts" that contain vitamin C, with about 40 mg per 100 g of raw product, which is about 65% of the U.S. recommended daily intake. The amount of vitamin C decreases by about 40% after heating. Fresh chestnuts contain about 52% water by weight, which evaporates relatively quickly during storage; they can lose as much as 1% of weight in one day at 20 °C (68 °F) and 70% relative humidity.

Tannin is contained in the bark as well as in the wood, leaves, and seed husks. The husks contain 10–13% tannin.

Cultivation, pests, and diseases

Chestnuts

Climate, seasonal germination cycle

Chestnuts produce a better crop when subjected to chill temperatures during the dormant period. Frosts and snowfalls are beneficial rather than harmful to the trees. The dormant plant is very cold-hardy in Britain. Chestnut is hardy to zone 5, which is 22 °C (39.6 °F) lower in average minimal temperature than London in zone 9. The young growth in spring, even on mature plants, though, is frost-tender; bud-burst is later than most other fruit trees, so late frosts can be damaging to young buds.

Trees can be found at altitudes between 200 and 1000 m above sea level; some mention between 300 and 750 m altitude, while the famous Chestnut Tree of One Hundred Horses on Mount Etna stands at 1200 metres. They can tolerate maritime exposure, although growth is reduced.

Seeds germinate in late winter or early spring, but the life length is short. If kept moist, they can be stored in a cool place for a few months, but must be checked regularly for signs of germination. Low temperature prolongs dormancy. Sowing them as soon as ripe is better, either in cold frames or seedbeds outdoors, where they can be left in situ for 1 to 2 years before being planted in their permanent positions, or in pots, where the plants can be put out into their permanent positions in summer or autumn. They must be protected from the cold in their first winter, and also from mice and squirrels.

Chestnuts are considered self-sterile, so at least two trees are needed for pollination.

Soil requirements

Castanea grows best in a soil with good drainage and adequate moisture. The tree prefers sloping, deep soils; it does not like shallow or heavy soils with impermeable, clay subsoils. The Chinese chestnut prefers a fertile, well-drained soil, but it grows well in fairly dry, rocky, or poor soils.

Although Castanea can grow in very acid soil, and while these soils are reasonably well tolerated, the preferred range is from pH 5.5-6.0. It does not grow well on alkaline soils, such as chalk, but thrives on soils such as those derived from granite, sandstone, or schist. On alkaline soils, chestnut trees can be grown by grafting them onto oak rootstocks.

Recently cleared land is best avoided to help resist the root rot, Armillaria mellia.

Sun exposure

Castanea likes a full sun position. An experiment with C. dentata seedlings in Ohio confirmed the need for sun for optimal growth. The butt of the tree is sometimes painted with white paint to protect the tree from sunburn until it has developed enough canopy.

Wide spacing between the trees encourages low, broad crowns with maximum exposure to sunshine to increase fruit production. Where chestnut trees touch, virtually no fruit is produced. Current industrial planting spacings can range from 7 x 7 to 20 x 20 m. The closer plantings, which are more popular, mean quicker increases in short-term production, but heavy pruning or even tree removal is required later.

Watering

The optimum rainfall for chestnut trees is 800 mm (31 in) or more, ideally in even distribution throughout the year. Mulching during summer is recommended. Rainfall below 700 mm (28 in) per year needs be complemented with, for example, a drip irrigation system. This should water the soil at the outer half of the circle formed by the drip line to encourage root growth. 

Independently from annual rainfall, watering young trees is recommended at least during summer and early autumn. Once established, they resist droughts well.

Preservation

In addition to being consumed fresh, chestnuts can also be canned, pureed, or preserved in sugar or syrup (marrons glacés). Shelled and cooked nuts should be covered, refrigerated, and used within 3–4 days. Cooked chestnuts, either whole, chopped, or pureed, may be frozen in an airtight container and held up to 9 months. Because of their high water content, transpiration rates, and consequent loss weight, the nuts react as fresh fruits (not as nuts). They should be kept cool at all times, including in shops when on display for sale. To preserve their freshness for a few months with no artificial refrigeration, the chestnuts can be soaked in cold water for about 20 hours immediately after harvest, after which they are dried in the shade, then layered in dry sand.

Chestnuts behave similarly to seeds in that they produce very little ethylene, and their respiration rate is low, varying between 5 and 20 mg/(kg·h) depending on the temperature.

Pests

Mammals and birds

  • Grey squirrels strip bark, from when the tree is about 8 years old and onwards through the life of the tree.
  • Rabbits and wallabies can do great damage to young trees, which need guarding by some fence or by wrapping the tree trunk in sisal or other appropriate material. Deer and kangaroos can also be troublesome.
  • Cattle and horses may require temporary fencing to prevent them from damaging fallen chestnuts at harvest time.
  • The Sulphur-crested cockatoo can damage branches up to 10 mm in diameter by carrying out "beak maintenance" on young trees.
  • Rosellas can be troublesome at harvest time.

Insects

  • Dryocosmus kuriphilus, the oriental chestnut gall wasp, is native to China, but is an invasive pest elsewhere. It attacks and destroys the chestnut fruit. It is considered the world's worst pest of chestnuts.
  • The larvae of the polyfag moth (Phytomyza horticola) species are among those that do most damage to shoots and foliage.
  • The most frequently occurring pests are the winter moth (Operophtera brumata) and the mottled umber moth (Erannis defoliaria).
  • The oak roller weevil (Attelabus nitens) causes relatively less damage by rolling up the leaves into a barrel shape to shelter its eggs and developing larvae. The insects swarm from the end of April to mid-June, and damage the tree's flower buds during their feeding season.
  • The larvae of the oak-leaf-mining moth, also called the tischerid moth (Tischeria ekebladella), digs white, see-through mines in chestnut leaves. It lays its eggs in the leaves between May and June. The larvae cause white spots in the leaves by chewing them from the inside.
  • The oak aphid (Myzocallis castanicola) sucks on the apex of young shoots and leaves. Native to Europe and North America, it is, for example, active in Hungary. Leaves do not roll up, but their feeding delays the growth of shoots and damages young graft-shoot hosts. Commercial plantations and nurseries spray pesticides during the shoots' growth period to fight the damage. The chestnut mosaic virus is probably transmitted by M. castanicola aphids.
  • The chestnut weevil (Curculio elephas) most often damages the fruits. In Hungary, it swarms in chestnut orchards around August 20, particularly strongly around noon and in sunny weather. The eggs are laid into the cupules or around the peduncle joints. The larvae feed on the nuts and leave only nutchips and excrement within. While the chestnuts ripen, the larvae retreat into the ground after having chewed their way out of the nuts. The following July, they turn into pupae.
    The larvae of the chestnut weevil can only chew their way out of a fallen nut, so breeding occurs mostly where chestnuts lie on the ground for a sufficient length of time, or where the trees produce many small fruits which remain behind at the harvest. Timing the harvests to pick up the chestnuts as soon as they fall reduces the numbers of the overwintering larvae. Regular soil work is also unfavourable to its life habits. Small grafts are sprayed with chemicals. A warm, aerosol-based protection has been developed for older trees, by Sifter and Bürgés in 1971. Planting chestnut orchards beside turkey oak forests is not advised, because both trees are susceptible to the chestnut weevil (which also uses the turkey oak acorn to develop), and the tTurkey oak trees can pass it on to the chestnut trees.
  • In Hungary, the most common moth threatening chestnut trees is the acorn moth (Laspeyreisa splendana) and its subspecies. Its grayish-yellow larvae cause similar damage to that of the chestnut weevil, but they spin characteristic webs among the nutchips and larval excrement. This moth causes about 5–41% of the damage that occurs in western Hungary's plantations. Plantations need regular protection against these moths, the occurrence of which does not decrease.
  • In New Zealand, the grass grub beetle eats the soft, new-season foliage. They can entirely strip a young tree in the late spring, when they fly at dusk, often in huge numbers.

Diseases

  • Chestnut blight fungus (Cryphonectria parasitica) (formerly Endothia parasitica) affects chestnut trees. The Eastern Asian species have coevolved with this disease and are moderately to very resistant to it, while the European and North American species, not having been exposed to it in the past, have little or no resistance. Early in the 20th century, chestnut blight destroyed about four billion American chestnut trees, and reduced the most important tree throughout the East Coast to an insignificant presence. The American chinkapins are also very susceptible to chestnut blight. The European and West Asian chestnuts are susceptible, but less so than the American species. The resistant species (particularly Japanese and Chinese chestnut, but also Seguin's chestnut and Henry's chestnut) have been used in breeding programs in the U.S. to create hybrids with the American chestnut that are also disease-resistant.
    The bark miner Spulerina simploniella (Lepidoptera: Gracilariidae) was found in intensively managed chestnut coppices in Greece, but not in orchards. The larvae (and the rain) may be agents in the spread of the disease. They mine under the thin periderm of young trees up to 10 years old, while the stem bark is still smooth. Rain during the pupation period (around the last week of May and first two weeks of June), and the actions of the larvae, may collude for conidiospores to come into contact with the freshly exposed phloem, thus causing cankers.
  • Ink disease also appears in a number of other plants. The disease attacks the phloem tissue and the cambium of the roots and root collars about 10–20 cm above ground. Wet rot settles in as a result. It was named after the ink-black color of the tannic acid becoming (oxidized) after seeping out, but that symptom is not a characteristic of only that disease. The same ink-black color can appear following other types of decays and mechanical injuries that make liquids seep through; these liquids can also oxidize after contact with air. Moreover, with some phytophthoric diseases, no tannic acid is generated. With the ink disease, the leaves turn yellow and later fall off; the fruits remain small, and the nuts prematurely drop out of the burrs. These dry and remain on the trees throughout winter. In acute cases, root decay makes the trees dry out and wither away. It is caused by Phytophthora cambivora and Phytophthora cinnamomi.
  • Phytophthora disease is the longest-known chestnut tree disease leading to tree death. Of the two main pathogens for this disease, the one in European chestnuts is known since 1971 to be Phytophthora cambivora. Phytophthora cinnamoni was discovered in chestnut trees in the United States in 1932. Both trigger similar symptoms. Since then, it has also been shown to occur in most European chestnut-growing countries. Differentiating between the two pathogens is difficult. Chemicals seem of little effectiveness. Many countries impose strict prophylactic rules to prevent the spread of the disease.
  • Melanconis modonia can infect trees through injuries and induce "bark death". It was first reported in Hungary by Hausz in 1972. The damage is of little consequence in older or stronger trees, but it affects sapling graftings in nurseries. Coryneum perniciosum, one of the two conidium-like side forms of this fungus, occurs on all decayed, ligneous parts of a chestnut tree. The symptoms of infection on young, smooth trunks is similar to that of the chestnut blight fungus Cryphonectria. For this reason, it has persistently been wrongly thought of as the pathogen for ink disease. With Melanconis, the bark sinks in and takes on brownish-red tones, with black, lentil-like multicell conidium bodies and black cone-like stromata breaking through the bark. Unlike with Cryphonectria, though, no orange-colored fruiting bodies are seen. Prevention primarily includes keeping trees in good shape; some further protections against Cryphonectria also help prevent bark death caused by Melanconis.
  • Chestnut mosaic virus is probably transmitted by the oak aphid Myzocallis castanicola.
  • Root rot is caused by the honey fungus Armillaria mellia. When planting Castanea, recently cleared land is best avoided to help resist this fungus. The disease is more prevalent on heavier and poorly drained soil types.
  • Leaf spot is the most common disease for chestnut trees (Mycosphaerella maculiformis). It is known as cylindrosporium leaf spot disease, after its summer conidium form Cylindrosporium castaneae. The pathogens spend the winter in the white spots of the fallen leaves. At spring time, it reinfects the new leaves. In or near June, tiny white spots on the leaves appear, which grow and turn brown over time. At the end of the summer, the spots entirely cover the leaf, which turns yellow. In rainy and humid weather with large temperature fluctuation, the tree loses its leaves. If August is dry and warm, the infected leaves roll up, the arteries twist, and the dead leaves dry on the tree until defoliage. This recurs yearly, though the extent of the damage varies from year to year. Some species are more resistant than others.
  • Oak mildew is among several foliage diseases of smaller significance for European chestnut growing. It infects the most trees (Microsphaera alphitoides). Younger trees suffer most; their shoots become short-jointed, growth is delayed, and they develop sensitivity to frostbite. In older trees, the fungus usually infects only the tip of the shoots. The pathogens hibernate in the shoots and infect the leaves from there. The fungus grows on the top of the leaves, with the appearance of a coating only in midsummer. The infected leaves' development slows down or stops, the distance between their vessels shrinks, and the vessels themselves become curly.
  • In storage rot, breaking the tuft provides the most common entrance for fungal spores during storage. Cyboria, the most diffuse, turns the flesh black and spongy. Other fungi are known, such as Rhizopus, Fusarium, and Colletotrichum. In chestnuts, Colletotrichum disease symptoms may also be called blossom end rot. Browning of the chestnut burs at the blossom end may be a first sign in August. At harvest time, blackening of pointed end of the chestnut shell and kernel indicates infection. The extent of blackening can vary. It can range from a barely visible black tip of the kernel to the whole nut being black. Parts of the nut kernel with no color change remain edible.

Coppicing

Most chestnut wood production is done by coppice systems, cut on a 12-year rotation to provide small timber which does not split as badly as large logs. In southern England (particularly in Kent), sweet chestnut has traditionally been grown as coppices, being recut every 10 years or so on rotation for poles used for firewood, fencing (fence posts and chestnut paling), and especially to support the strings up when hops are grown.

Sustainable forest management

An excellent soil-enriching understory in pine forests, sustainable forest management incorporates more mixed plantings of proven efficiency, as opposed to monosylviculture. A study presented in 1997 has evaluated positively the potential increase in productivity with mixed stands and plantations, compared to plots of only one species. The relative yield total values of the mixed plantings steadily increase with time. C. sativa responds well to competitive pressure from Pseudotsuga menziesii, the latter also showing a higher productivity. C. dentata seedlings in Ohio reforestation efforts are best achieved by planting them in places with little or no arboreous land cover, because of the need for light.

Uses

A kestaneci or chestnut vendor in Istanbul
 
Roasted chestnuts in Melbourne, Australia

Culinary

A hot chestnut seller in Avignon, 1936
 
Dried chestnut in the South of Italy
 
The fruit can be peeled and eaten raw, but it can be somewhat astringent, especially if the pellicle is not removed.

Another method of eating the fruit involves roasting, which does not require peeling. Roasting requires scoring the fruit beforehand to prevent explosion of the fruit due to expansion. Once cooked, its texture is slightly similar to that of a baked potato, with a delicate, sweet, and nutty flavour. This method of preparation is popular in many countries, where the scored chestnuts may be cooked mixed with a little sugar.

Chestnuts can be dried and milled into flour, which can then be used to prepare breads, cakes, pies, pancakes, pastas, polenta (known in Corsica as pulenda), or used as thickener for stews, soups, and sauces. Chestnut cake may be prepared using chestnut flour. In Corsica, the flour is fried into doughnut-like fritters called fritelli and made into necci, pattoni, castagnacci, and cialdi. The flour can be light beige like that from Castagniccia, or darker in other regions. It is a good solution for long storage of a nutritious food. Chestnut bread can stay fresh as long as two weeks.

The nuts can also be eaten candied, boiled, steamed, deep-fried, grilled, or roasted in sweet or savory recipes. They can be used to stuff vegetables, poultry, fowl, and other edibles. They are available fresh, dried, ground, or canned (whole or in puree). 

Candied chestnuts (whole chestnuts candied in sugar syrup, then iced) are sold under the French name marrons glacés or Turkish name kestane şekeri ("sugared chestnuts"). They appeared in France in the 16th century. Towards the end of 19th century, Lyon went into a recession with the collapse of the textile market, notably silk. Clément Faugier, a civil engineer, was looking for a way to revitalize the regional economy. In 1882 at Privas, he invented the technology to make marrons glacés on an industrial scale (although a great number of the more than 20 necessary steps from harvest to the finished product are still accomplished manually). Chestnuts are picked in autumn, and candied from the start of the following summer for the ensuing Christmas. Thus, the marrons glacés eaten at Christmas are those picked the year before.

In Hungarian cuisine, cooked chestnuts are puréed, mixed with sugar (and usually rum), forced through a ricer, and topped with whipped cream to make a dessert called gesztenyepüré (chestnut purée). In Swiss cuisine, a similar dish made with kirsch and butter is called vermicelles. A French version is known as "Mont Blanc". 

A fine granular sugar can be obtained from the fermentation of the juice, as well as a beer; the roasted fruit provides a coffee substitute. Parmentier, who among other things was a famous potato promoter, extracted sugar from chestnuts and sent a chestnut sugarloaf weighing several pounds to the Academy of Lyon. The continental blockade following shortly after (1806–1814) increased the research into developing chestnuts as a source of sugar, but Napoleon chose beets instead.

Sweet chestnuts are not easy to peel when cold. One kilogram of untainted chestnuts yields about 700 g of shelled chestnuts.

Animal fodder and litter

Chestnuts are often added to animal fodder. A first soak in limewater removes their bitter flavour, then they are ground and mixed with the ordinary provender. Other methods of preparation are also used. It is given to horses and cattle in the Orient, and to pigs in England, France and other places. The leaves are not as prone to be insect-eaten as those of the oak, and are also used for fodder.

Timber

Chestnut wood: Note the splitting at the top of the log.
 
Chestnut is of the same family as oak, and likewise its wood contains many tannins. This renders the wood very durable, gives it excellent natural outdoor resistance, and saves the need for other protection treatment. It also corrodes iron slowly, although copper, brass, or stainless metals are not affected.

Chestnut timber is decorative. Light brown in color, it is sometimes confused with oak wood. The two woods' textures are similar. When in a growing stage, with very little sap wood, a chestnut tree contains more timber of a durable quality than an oak of the same dimensions. Young chestnut wood has proved more durable than oak for woodwork that has to be partly in the ground, such as stakes and fences.

After most growth is achieved, older chestnut timber tends to split and warp when harvested. The timber becomes neither as hard nor as strong as oak. The American chestnut C. dentata served as an important source of lumber, because that species has long, unbranched trunks. In Britain, chestnut was formerly used indiscriminately with oak for the construction of houses, millwork, and household furniture. It grows so freely in Britain that it was long considered a truly native species, partly because the roof of Westminster Hall and the Parliament House of Edinburgh were mistakenly thought to be constructed of chestnut wood. Chestnut wood, though, loses much of its durability when the tree is more than 50 years old, and despite the local chestnut's quick growth rate, the timber used for these two buildings is considerably larger than a 50-year-old chestnut's girth. It has been proven that the roofs of these buildings are actually Durmast oak, which closely resembles chestnut in grain and color.

It is therefore uncommon to find large pieces of chestnut in building structures, but it has always been highly valued for small outdoor furniture pieces, fencing, cladding (shingles) for covering buildings, and pit-props, for which durability is an important factor. In Italy, chestnut is also used to make barrels used for aging balsamic vinegar and some alcoholic beverages, such as whisky or lambic beer. Of note, the famous 18th-century "berles" in the French Cévennes are cupboards cut directly from the hollowed trunk.

Fuel

Dry, chestnut firewood is best burned in a closed log-burner, because of its tendency to spit when on an open fire.

Wildlife

The tree is noted for attracting wildlife. The nuts are an important food for jays, pigeons, wild boar, deer, and squirrels. American and Chinese chinquapins (Castanea pumila and Castanea henryi) have very small nuts that are an important source of food for wildlife.

Leather

Chestnut wood is a useful source of natural tannin and was used for tanning leather before the introduction of synthetic tannins. On a 10% moisture basis, the bark contains 6.8% tannin and the wood 13.4%. The bark imparts a dark color to the tannin, and has a higher sugar content, which increases the percentage of soluble non-tans, or impurities, in the extract; so it was not employed in this use. Chestnut tannin is obtained by hot-water extraction of chipped wood. It is an ellagic tannin and its main constituents are identified by castalagin (14.2%) and vescalagin (16.2%). It has a naturally low pH value, relatively low salts content, and high acids content. This determines its astringency and its capability to fix raw hides. These properties make chestnut extract especially suitable for the tanning of heavy hides and to produce leather soles for high-quality shoes in particular. It is possible to obtain a leather with high yield in weight, which is compact, firm, flexible, and waterproof. Chestnut-tanned leathers are elastic, lightfast, resistant to traction and abrasion, and have warm color. Chestnut tannin is one of the pyrogallol class of tannins (also known as hydrolysable tannin). As it tends to give a brownish tone to the leather, it is most often used in combination with quebracho, mimosa, tara, myrabolans, and valonia.

The wood seems to reach its highest tannin content after the trees reach 30 years old. The southern European chestnut wood usually contains at least 10 to 13% more tannin than chestnut trees in northern climates.

Other uses

Fabric can be starched with chestnut meal. Linen cloth can be whitened with chestnut meal. The leaves and the skins (husk and pellicle) of the fruits provide a hair shampoo.

Hydrolysable chestnut tannins can be used for partial phenol substitution in phenolic resin adhesives production and also for direct use as resin.

Chestnut extracts were evaluated through several biochemical assays showing evident antioxidant properties.

Chestnut buds have been listed as one of the 38 substances used to prepare Bach flower remedies, a kind of alternative medicine promoted for its effect on health. However, according to Cancer Research UK, "there is no scientific evidence to prove that flower remedies can control, cure or prevent any type of disease, including cancer".

Artistic references

Still life with roasted chestnuts by Georg Flegel
  • In the film based on the novel by E. M. Forster, Howards End, Mrs. Ruth Wilcox (Vanessa Redgrave) tells of her childhood home, where superstitious farmers would place pigs' teeth in the bark of the chestnut trees and then chew on this bark to ease toothaches. In the novel, the tree is actually a Wych elm.
  • Longfellow's The Village Blacksmith begins "Under a spreading chestnut-tree / The village smithy stands; / The smith, a mighty man is he, / With large and sinewy hands; / And the muscles of his brawny arms / Are strong as iron bands. "
  • Under the Spreading Chestnut Tree is a set of variations, with fugue, for orchestra composed in 1939 by Jaromír Weinberger.
  • In George Orwell's 1984 the chestnut tree is used in poems recited throughout (modifying "The Chestnut Tree" by Glen Miller 1939: "Underneath the spreading chestnut tree / I loved him and he loved me / There I used to sit up on his knee / ´Neath the spreading chestnut tree."), referring to nature, modern life, and lines as in the saying: 'that old chestnut'.
  • In Honoré de Balzac's novel Père Goriot, Vautrin states that Eugène de Rastignac's family is living off of chestnuts; this symbolism is used to represent how impoverished Eugene's family is.
  • In Shakespeare's Macbeth one of the Wayward Sisters threatens to kill a woman's husband over a chestnut. This is meant to show the impassivity and comic relief of their characters.
  • "The Christmas Song" famously mentions chestnuts in its opening line, and is commonly subtitled "Chestnuts Roasting on an Open Fire."
  • "Dr. Evil", the villain from the Austin Powers film series mentioned that his eccentric father would, "... accuse chestnuts of being lazy." As a Belgian boulangerie owner, Dr. Evil's father may have encountered them in a culinary context.

Notable chestnut trees

  • Chestnut Tree of One Hundred Horses on Mount Etna, 57.9 m (190 ft) circumference in 1780, (64-meter circumference in 1883)
  • Tortworth Chestnut. 15.8-meter (52 ft) circumference in 1776, when it was described as "the largest tree in England"
  • Sacred Chestnut of Istán, 46-foot (14 m) circumference, estimated to be between 800 and 1,000 years old.

Whale meat

From Wikipedia, the free encyclopedia

Raw whale meat in Norway
 
Whale meat on sale at Tsukiji fish market in Tokyo in 2008
 
Whale meat on sale at the fish market in Bergen, Norway, in 2012
 
A beluga whale is flensed for its maktaaq which is an important source of vitamin C in the diet of some Inuit.
 
Whale meat, broadly speaking, may include all cetaceans (whales, dolphins, porpoises) and all parts of the animal: muscle (meat), organs (offal), and fat (blubber). There is relatively little demand for it, compared to farmed livestock, and commercial whaling, which has faced opposition for decades, continues today in very few countries (mainly Iceland, Japan, Norway), although whale meat used to be eaten across Western Europe and colonial America. However, wherever dolphin drive hunting and aboriginal whaling exist, marine mammals are eaten locally as part of the subsistence economy: in the Faroe Islands; in the circumpolar Arctic (the Inuit in Canada and Greenland, related peoples in Alaska, the Chukchi people of Siberia); other indigenous peoples of the United States (including the Makah people of the Pacific Northwest); in St. Vincent and the Grenadines (mainly on the island of Bequia); in a couple of villages in Indonesia; in certain South Pacific islands.

Like horse meat, for some cultures whale meat is taboo, or a food of last resort, e.g. in times of war, whereas in others it is a delicacy and a culinary centrepiece. Indigenous groups contend that whale meat represents their cultural survival. Its consumption has been denounced by detractors on wildlife conservation, toxicity, and animal rights grounds. Whale meat can be prepared in various ways, including salt-curing, which means that consumption is not necessarily restricted to coastal communities.

History

Native American whalers removing strips of flesh from a whale carcase at Neah Bay, Washington, 1910
 
Whales were hunted in European waters throughout the Middle Ages for their meat and oil. Under Catholicism, aquatic creatures were generally considered "fish"; therefore whale was deemed suitable for eating during Lent and other "lean periods". An alternative explanation is that the Church considered "hot meat" to raise the libido, making it unfit for holy days. Parts submerged in water, such as whale or beaver tails, were considered "cold meat."

Eating whale meat did not end with the Middle Ages in Europe, but rather, whale stock in nearby oceans collapsed due to overexploitation, especially the right whales around the Bay of Biscay. Thus European whalers (the Basques, especially, were known for their expertise) had to seek out the New World to catch whales. The Dutch (Flemish) were also active in the whaling commerce during the Middle Ages, and a number of records regarding the trafficking of whalemeat and taxation on it occur from historical Flanders (extending to cities like Arras or Calais in the département of Pas de Calais).

French surgeon Ambroise Paré (died 1590) wrote that "the flesh has no value, but the tongue is soft and delicious and therefore salted; likewise, the blubber, which is distributed across many provinces, and eaten with peas during Lent". This blubber, known as craspois or lard de carême was food for the poorer strata on the continent. The whaling industry in North America may have supplied rendered fat, partly for consumption in Europe.

In early America, whalemen may have eaten blubber after rendering, which they termed "cracklings" or "fritters", said to be crunchy like toast; these were certainly reused as fuel chips to boil down the fat. Colonial America also more commonly consumed the meat and other portions of the "blackfish" (or pilot whale). However, by the beginning of large-scale commercial whaling, whale meat was not consumed by the general American public, as it was not seen as fit for consumption by so-called civilized peoples.

Species hunted

Minke whale is one of the most common species still hunted in substantial numbers.[citation needed] Baleen whales other than the minke are endangered, though they are taken in numbers by indigenous peoples who traditionally hunt them, and more lately, the whaling nations have resumed hunting larger baleen whales openly.

In 1998-1999, Harvard researchers published their DNA identifications of samples of whalemeat they obtained in the Japanese market, and found that mingled among the presumably legal (i.e. minke whale meat) was a sizeable proportion of dolphin and porpoise meats, and instances of endangered species such as fin whale and humpback whale. (Blue whale DNA was also detected in the study, but researchers have attributed those findings to crossbreeding with fin whales, and that view has since been strengthened.)

In recent years Japan has resumed taking North Pacific fin whale and sei whales in their "research whaling". The fin whales are highly desired because they yield arguably the best quality of tail meat (onomi). Japanese research vessels refer to the harvested whale meat as incidental byproducts which have resulted from study.

In Japan, the research whale meat was sold at officially published prices, but since 2011 an auction bid system has been adopted and actual realized prices have not been posted. 

Cut of whale meat for sale 1998 (minke whale)
official prices
(converted to yen/kg)
2011 (Bryde's whale)
reference price
for bidding (yen/kg)
Special selection red meat n/a 7000
Special grade red meat 4640 4500
1st grade red meat 3270 1700
2nd grade red meat 140 n/a
1st grade unesu (baleen whale underbelly, used for bacon) 5860 3000
2nd grade unesu 4380 2600

The channels through which premium cuts such as fin whale tail meat are sold remain opaque. A report by one of the Greenpeace Japan activists who intercepted whale meat package deliveries got no further than the sentiment by one restaurateur that it would take Nagatachō (i.e. high government) connections to get it.

Regions

In places such as Norway, Iceland, and Alaska, whale meat may be served without seasoning. However, it can also be cured or marinated, or made into jerky.

Norway

In Norway, whale meat was a cheap and common food until the 80s. It could be used in many ways but was often cooked in a pot with lid in a little water so that broth was created and then served with potatoes and vegetables, often with flatbrød at the side.

Greenland

The consumption of whale meat by the Inuit people in Greenland is part of their culture. However, in 2010, tourists also have begun to consume the meat. A Whale and Dolphin Conservation Society (WDCS) investigation has documented the practice of commercial wholesalers commissioning subsistence whalers to supply the demand by supermarkets. Whale products in Greenland are sold in 4-star hotels.

Japan

Sashimi of whale meat
 
The fluke (oba) which are thinly sliced and rinsed (sarashi kujira). Topped with vinegar-miso sauce
 
Whale bacon
 
Icelandic fin whale meat on sale in Japan in 2010
 
Whales have been hunted for meat in Japan since before 800 AD. After World War II, due to damage to Japan's infrastructure, whale meat became an important source of proteins.

In modern-day Japan, two cuts of whale meat are usually created: the belly meat and the tail meat. In the early 19th century, 70 different cuts were known. People still call the belly and tail cuts by their special whalemeat names, and also, different parts of the body such as the tongue retain their jargon names (see below). The tail meat is not the same as the fluke (tail flipper), and they go by different names. 

As previously mentioned, different cuts of whale meat have specialised names. The belly meat, in the striped bellows-like underbelly of baleen whales "from the lower jaw to the navel", is called unesu (ウネス(畝須)) and is known for being made into whale bacon.

The prized tail meat, called onomi (尾の身) or oniku (尾肉) are two strips of muscle that run from the dorsal to the base of the fluke. The tail meat is regarded as marbled, and is eaten as sashimi or tataki. Even Masanori Hata (aka Mutsugorō) a zoologist author and animal shelter operator has extolled the delicacy of the tail meat. It can only be derived from larger baleen whales, and the fin whale's meat has been considered superior. When the ban on this species was in place and Japan ostensibly complied, what was claimed to be genuine fin whale was still available, and legitimized as "grandfathered" goods, i.e., frozen stock from animals caught when still legal. In the past when blue whale hunting was still conducted by all nations, its tail fin was served in Japan.

The other portions are labelled lean, or "red meat" (赤肉 akaniku) and command much lower prices than the tail.

The fluke or tail flipper is referred to as either oba (尾羽) or obake (尾羽毛). After being cured in salt it is thinly sliced, scalded with hot water and rinsed, and served as sarashi kujira (pictured).

The tongue, called saezuri (さえずり) is often processed and used in high-end oden. The fried skin after the blubber is called koro, and analogous to "fritter/crackling". 

The Japanese article under 鯨肉 provides a more extensive list, which includes the intestines, sex organs, and other offal.
  • Harihari-nabe is a hot pot dish, consisting of whalemeat boiled with mizuna.
  • Sashimi of Abura-sunoko is striped layers of meat made from the root of the flippers.
  • Udemono, consists of innards that have been boiled and sliced.
Some other dishes are: cubed and grilled blubber, cartilage salads, and whale skin stew.

As of 2006, in Japan, 5,560 tons of whale meat worth ¥5.5 billion is sold in every year. The Japanese market has declined in recent years, with prices falling to $26 per kilogram in 2004, down $6 per kilogram from 1999. Fluke meat can sell for over $200 per kilogram, over three times the price of belly meat.

Greenpeace has alleged that some of the meat on sale is illegally sourced. They have claimed that it has been illegally smuggled from crew members of research ships and that more meat is caught than can be consumed by humans, with up to 20% of 2004's catch going unsold.

Native Alaskan communities

For thousands of years, Native Alaskans of the Arctic have depended on whale meat. The meat is harvested from legal, non-commercial hunts that occur twice a year in the spring and autumn. The meat is stored and eaten throughout the winter.

Tikiġaġmiut, Iñupiat living on the coast of Alaska, divided their catch into 10 sections. The fatty tail, considered to be the best part, went to the captain of the conquering vessel, while the less-desired sections were given to his crew and others that assisted with the kill.

The skin and blubber, known as muktuk, taken from the bowhead, beluga, or narwhal is also valued, and is eaten raw or cooked. Mikigaq is the fermented whale meat.

Faroe Islands

Whaling in the Faroe Islands in the North Atlantic has been practiced since about the time of the first Norse settlements on the islands. Around 1000 Long-finned Pilot Whales (Globicephala melaena) are killed annually, mainly during the summer. The hunts, called "grindadráp" in Faroese, are organized on a community level. 

Both the meat and blubber are stored and prepared in various ways, including Tvøst og spik. When fresh, the meat is often boiled. It can also be served as steak (grindabúffur). This dish comprises meat and blubber, which is salted and then boiled for an hour, served with potatoes. The meat can also be hung out to dry and then served in thin slivers. At parties some choose to serve "kalt borð" (cold table), which means a variety of cold food, which can include dried whale meat, dried blubber or blubber which is preserved in water with much salt in it, dried fish, dried sheep meat, etc. Traditionally, whale meat was preserved by hanging salted pieces (called "likkjur") outdoors under a roof to be dried in the wind. This method is still used today, particularly in villages. Today, both meat and blubber can also be stored in freezers.

In 2008, Faroe Islands Chief Medical Officer Høgni Debes Joensen and Pál Weihe of the Department of Public and Occupational Health recommended that pilot whales no longer be considered fit for human consumption due to the presence of DDT derivatives, PCBs and mercury in the meat. Their recommendation was based on research suggesting a correlation between mercury intake and the high rate of Parkinson's disease on the islands. As of 1 June 2011, the Faroese Food and Veterinary Authority has advised Faroe Islanders not to eat the kidney or liver of pilot whales, not to consume more than one serving per month, and, for women and girls, to refrain from eating blubber if they plan to have children and to refrain from whale meat entirely if they are breastfeeding, pregnant or planning to conceive in the following three months.

United Kingdom

During World War II the British Minister of Food introduced food rationing but allowed whale meat to be distributed 'off ration', i.e. without restriction. It was not popular because of the smell whilst cooking was deemed 'unpleasant', and the taste was considered 'bland' even when spiced.

During the post-World War II period, corned whale meat was available as an unrationed alternative to other meats. Sold under the name "whacon", the meat was described as "corned whalemeat with its fishy flavour removed", and was almost identical to corned beef, except "brownish instead of red". The Food Ministry emphasised its high nutritional value.

Toxicity

Tests have revealed that in whale meat sold in Japan, high levels of mercury and other toxins are present. A research study was conducted by Tetsuya Endo, Koichi Haraguchi and Masakatsu Sakata at the University of Hokkaido found high levels of mercury in the organs of whales, particularly the liver. They stated that "Acute intoxication could result from a single ingestion" of liver. The study found that liver samples for sale in Japan contained, on average, 370 micrograms of mercury per gram of meat, 900 times the government's limit. Levels detected in kidneys and lungs were approximately 100 times higher than the limit. The effect is due to the animal's trophic level, however, rather than its size. This means that there is a significant difference between the mercury levels in toothed whales and baleen whales, the former having a much higher concentration.

Environmental impact

Norwegian-based High North Alliance, has suggested that the carbon footprint resulting from eating whale meat is substantially lower than that of beef. Greenpeace has responded that, "The survival of a species is more important than lower greenhouse gas emissions from eating it." Many organizations, including Greenpeace and the Sea Shepherd Conservation Society, have criticised the whale trade for preying on endangered species, as studies have shown an alarming decrease in whale populations, which may significantly affect oceans and its foodchains, therefore it may affect lives in a foreseable future.

Anti-whaling efforts

Groups such as the Sea Shepherd Conservation Society have attempted to disrupt commercial whaling with varying degrees of success.

Habitat fragmentation

From Wikipedia, the free encyclopedia

Fragmentation and destruction of Great Ape habitat in Central Africa, from the GLOBIO and GRASP projects. Areas shown in black and red delineate areas of severe and moderate habitat loss, respectively.
 
Habitat fragmentation describes the emergence of discontinuities (fragmentation) in an organism's preferred environment (habitat), causing population fragmentation and ecosystem decay. Causes of habitat fragmentation include geological processes that slowly alter the layout of the physical environment (suspected of being one of the major causes of speciation),and human activity such as land conversion, which can alter the environment much faster and causes the extinction of many species. 

Deforestation and increased road-building in the Amazon Rainforest are a significant concern because of increased human encroachment upon wild areas, increased resource-extraction and further threats to biodiversity.

Definition

The term habitat fragmentation includes five discrete phenomena:
  • Reduction in the total area of the habitat
  • Decrease of the interior: edge ratio
  • Isolation of one habitat fragment from other areas of habitat
  • Breaking up of one patch of habitat into several smaller patches
  • Decrease in the average size of each patch of habitat
"fragmentation ... not only causes loss of the amount of habitat, but by creating small, isolated patches it also changes the properties of the remaining habitat" (van den Berg et al. 2001). Habitat fragmentation is the landscape level of the phenomenon, and patch level process. Thus meaning, it covers; the patch areas, edge effects, and patch shape complexity.

In scientific literature, there is some debate whether the term "habitat fragmentation" applies in cases of habitat loss, or whether the term primarily applies to the phenomenon of habitat being cut into smaller pieces without significant reduction in habitat area. Scientists who use the stricter definition of "habitat fragmentation" per se would refer to loss of habitat area as "habitat loss" and explicitly mention both terms if describing a situation where the habitat becomes less connected and there is less overall habitat.

Causes

Natural causes

Evidence of habitat destruction through natural processes such as volcanism, fire, and climate change is found in the fossil record. For example, habitat fragmentation of tropical rainforests in Euramerica 300 million years ago led to a great loss of amphibian diversity, but simultaneously the drier climate spurred on a burst of diversity among reptiles.

Human causes

Habitat fragmentation is frequently caused by humans when native plants is cleared for human activities such as agriculture, rural development, urbanization and the creation of hydroelectric reservoirs. Habitats which were once continuous become divided into separate fragments. After intensive clearing, the separate fragments tend to be very small islands isolated from each other by cropland, pasture, pavement, or even barren land. The latter is often the result of slash and burn farming in tropical forests. In the wheat belt of central western New South Wales, Australia, 90% of the native vegetation has been cleared and over 99% of the tall grass prairie of North America has been cleared, resulting in extreme habitat fragmentation.

Endogenous vs. exogenous

There are two types of processes that can lead to habitat fragmentation. There are exogenous processes and endogenous processes. Endogenous are process that develop as a part of a species biology so they typically include changes in biology, behavior and interactions within or between species. Endogenous threats can result in changes to breeding patterns or migration patterns and are often triggered by exogenous processes. Exogenous processes are independent of species biology and can include habitat degradation, habitat subdivision or habitat isolation. These processes can have a substantial impact on endogenous processes by fundamentally altering species behavior. Habitat subdivision or isolation can lead to changes in dispersal or movement of species including changes to seasonal migration. These changes can lead to decrease in a density of species, increased competition or even increased predation.

Implications

Habitat Loss and Biodiversity

One of the major ways that habitat fragmentation affects biodiversity is by reducing the amount of suitable habitat available for organisms. Habitat fragmentation often involves both habitat destruction and the subdivision of previously continuous habitat. Plants and other sessile organisms are disproportionately affected by some types of habitat fragmentation because they cannot respond quickly to the altered spatial configuration of the habitat.

Habitat loss, which can occur through the process of habitat fragmentation, is considered to be the greatest threat to species. But, the effect of the configuration of habitat patches within the landscape, independent of the effect of the amount of habitat within the landscape (referred to as fragmentation per se), has been suggested to be small. A review of empirical studies found that, of the 381 reported significant effect of habitat fragmentation per se on species occurrences, abundances or diversity in the scientific literature, 76% were positive whereas 24% were negative. Despite these results, the scientific literature tends to emphasize negative effects more than positive effects. Positive effects of habitat fragmentation per se imply that several small patches of habitat can have higher conservation value than a single large patch of equivalent size. Land sharing strategies could therefore have more positive impacts on species than land sparing strategies.

Habitat fragmented by numerous roads near the Indiana Dunes National Lakeshore.
 
Area is the primary determinant of the number of species in a fragment and the relative contributions of demographic and genetic processes to the risk of global population extinction depend on habitat configuration, stochastic environmental variation and species features. Minor fluctuations in climate, resources, or other factors that would be unremarkable and quickly corrected in large populations can be catastrophic in small, isolated populations. Thus fragmentation of habitat is an important cause of species extinction. Population dynamics of subdivided populations tend to vary asynchronously. In an unfragmented landscape a declining population can be "rescued" by immigration from a nearby expanding population. In fragmented landscapes, the distance between fragments may prevent this from happening. Additionally, unoccupied fragments of habitat that are separated from a source of immigrants by some barrier are less likely to be repopulated than adjoining fragments. Even small species such as the Columbia spotted frog are reliant on the rescue effect. Studies showed 25% of juveniles travel a distance over 200m compared to 4% of adults. Of these, 95% remain in their new locale, demonstrating that this journey is necessary for survival.

Additionally, habitat fragmentation leads to edge effects. Microclimatic changes in light, temperature and wind can alter the ecology around the fragment, and in the interior and exterior portions of the fragment. Fires become more likely in the area as humidity drops and temperature and wind levels rise. Exotic and pest species may establish themselves easily in such disturbed environments, and the proximity of domestic animals often upsets the natural ecology. Also, habitat along the edge of a fragment has a different climate and favours different species from the interior habitat. Small fragments are therefore unfavourable for species which require interior habitat. The percentage preservation of contiguous habitats is closely related to both genetic and species biodiversity preservation. Generally a 10% remnant contiguous habitat will result in a 50% biodiversity loss.

Informed Conservation

Habitat fragmentation is often a cause of species becoming threatened or endangered. The existence of viable habitat is critical to the survival of any species, and in many cases the fragmentation of any remaining habitat can lead to difficult decisions for conservation biologists. Given a limited amount of resources available for conservation is it preferable to protect the existing isolated patches of habitat or to buy back land to get the largest possible continuous piece of land. In rare cases a conservation reliant species may gain some measure of disease protection by being distributed in isolated habitats. This ongoing debate is often referred to as SLOSS (Single Large or Several Small).
One solution to the problem of habitat fragmentation is to link the fragments by preserving or planting corridors of native vegetation. In some cases, a bridge or underpass may be enough to join two fragments. This has the potential to mitigate the problem of isolation but not the loss of interior habitat. 

Another mitigation measure is the enlargement of small remnants in order to increase the amount of interior habitat. This may be impractical since developed land is often more expensive and could require significant time and effort to restore. 

The best solution is generally dependent on the particular species or ecosystem that is being considered. More mobile species, like most birds, do not need connected habitat while some smaller animals, like rodents, may be more exposed to predation in open land. These questions generally fall under the headings of metapopulations island biogeography.

Genetic Risks

As the remaining habitat patches are smaller, they tend to support smaller populations of fewer species. Small populations are at an increased risk of a variety of genetic consequences that influence their long-term survival. Remnant populations often contain only a subset of the genetic diversity found in the previously continuous habitat. In these cases, processes that act upon underlying genetic diversity, such as adaptation, have a smaller pool of fitness-maintaining alleles to survive in the face of environmental change. However in some scenarios, where subsets of genetic diversity are partitioned among multiple habitat fragments, almost all original genetic diversity can be maintained despite each individual fragment displaying a reduced subset of diversity.

Gene Flow and Inbreeding

Gene flow occurs when individuals of the same species exchange genetic information through reproduction. Populations can maintain genetic diversity through migration. When a habitat becomes fragmented and reduced in area, gene flow and migration is typically reduced. Fewer individuals will migrate into the remaining fragments, and small disconnected populations that may have once been part of a single large population will become reproductively isolated. Scientific evidence that gene flow is reduced due to fragmentation depends on the study species. While trees that have long-range pollination and dispersal mechanisms may not experience reduced gene flow following fragmentation, most species are at risk of reduced gene flow following habitat fragmentation.

Reduced gene flow, and reproductive isolation can result in inbreeding between related individuals. Inbreeding does not always result in negative fitness consequences, but when inbreeding is associated with fitness reduction it is called inbreeding depression. Inbreeding becomes of increasing concern as the level of homozygosity increases, facilitating the expression of deleterious alleles that reduce the fitness. Habitat fragmentation can lead to inbreeding depression for many species due to reduced gene flow. Inbreeding depression is associated with conservation risks, like local extinction.

Genetic Drift

Small populations are more susceptible to genetic drift. Genetic drift is random changes to the genetic make up of populations and always leads to reductions in genetic diversity. The smaller the population is, the more likely genetic drift will be a driving force of evolution rather than natural selection. Because genetic drift is a random process, it does not allow species to become more adapted to their environment. Habitat fragmentation is associated with increases to genetic drift in small populations which can have negative consequences for the genetic diversity of the populations. However, research suggests that some tree species may be resilient to the negative consequences of genetic drift until population size is as small as ten individuals or less.

Adaptation

In order for populations to evolve in response to natural selection, they must be large enough that natural selection is a stronger evolutionary force than genetic drift. Recent studies on the impacts of habitat fragmentation on adaptation in some plant species have suggested that organisms in fragmented landscapes may be able to adapt to fragmentation. However, there are also many cases where fragmentation reduces adaptation capacity because of small population size.

Examples of Impacted Species

Some species that have experienced genetic consequences due to habitat fragmentation are listed below:

Macquarie perch
  • Macquaria australasica
  • Fagus sylvatica 
  • Betula nana
  • Rhinella ornata 
  • Ochotona princeps
  • Uta stansburiana
  • Plestiodon skiltonianus
  • Sceloporus occidentalis
  • Chamaea fasciata

Effect on Animal Behaviours

Although the way habitat fragmentation affects the genetics and extinction rates of species has been heavily studied, fragmentation has also been shown to affect species' behaviours and cultures as well. This is important because social interactions have the ability to determine and have an effect on a species' fitness and survival. Habitat fragmentation alters the resources available and the structure of habitats, as a result alters the behaviours of species and the dynamics between differing species. Behaviours affected can be within a species such as reproduction, mating, foraging, species dispersal, communication and movement patterns or can be behaviours between species such as predator prey relationships.

Predation Behaviours

Habitat fragmentation due to anthropogenic activities has been shown to greatly affect the predator-prey dynamics of many species by altering the amount of species and the members of those species. This affects the natural predator-prey relationships between animals in a given community and forces them to alter their behaviours and interactions, therefore resetting the so called "behavioral space race". The way in which fragmentation changes and re-shapes these interactions can occur in many different forms. Most prey species have patches of land that are refuge from their predators, allowing them the safety to reproduce and raise their young. Human introduced structures such as roads and pipelines alter these areas by facilitating predator activity in these refuges, increasing predator-prey overlap. The opposite could also occur in the favour of prey, increasing prey refuge and subsequently decreasing predation rates. Fragmentation may also increase predator abundance or predator efficiency and therefore increase predation rates in this manner. Several other factors can also increase or decrease the extent to which the shifting predator-prey dynamics affect certain species, including how diverse a predators diet is and how flexible habitat requirements are for predators and prey. Depending on which species are affected and these other factors, fragmentation and its resulting effects on predator-prey dynamics may contribute to a species extinction. In response to these new environmental pressures, new adaptive behaviours may be developed. Prey species may adapt to increased risk of predation with strategies such as altering mating tactics or changing behaviours and activities related to food and foraging.
Boreal Woodland Caribous
In the boreal woodland caribous of British Columbia the effects of fragmentation are clearly demonstrated. The species refuge area is peatland bog which has been interrupted by linear features such as roads and pipelines. These features have allowed their natural predators, the wolf and the black bear to more efficiently travel over landscapes and between patches of land. Since their predators can more easily access the caribous' refuge, the females of the species attempt to avoid the area, affecting their reproductive behaviours and offspring produced.

Communication Behaviours

Fragmentation affecting the communication behaviours of birds has been well studied in Dupont's Lark. The Larks primarily reside in regions of Spain and are a small passerine bird which use songs as a means of cultural transmission between members of the species. The Larks have two distinct vocalizations, the song and the territorial call. The territorial call is used by males to defend and signal territory from other male Larks and is shared between neighbouring territories when males respond to a rivals song. Occasionally it is used as a threat signal to signify an impending attack on territory. A large song repertoire can enhance a males ability to survive and reproduce as he has a greater ability to defend his territory from other males, and a larger number of males in the species means a larger variety of songs being transmitted. Fragmentation of the Dupont's Lark territory from agriculture, forestry and urbanization appears to have a large effect on their communication structures. Males only perceive territories of a certain distance to be rivals and so isolation of territory from others due to fragmentation leads to a decrease in territorial calls as the males no longer have any reason to use it or have any songs to match.

Forest fragmentation

Forest fragmentation is a form of habitat fragmentation where forests are reduced (either naturally or man-made) to relatively small, isolated patches of forest known as forest fragments or forest remnants. The intervening matrix that separates the remaining woodland patches can be natural open areas, farmland, or developed areas. Following the principles of island biogeography, remnant woodlands act like islands of forest in a sea of pastures, fields, subdivisions, shopping malls, etc. These fragments will then begin to undergo the process of ecosystem decay

Forest fragmentation also includes less subtle forms of discontinuities such as utility right-of-ways (ROWs). Utility ROWs are of ecological interest because they have become pervasive in many forest communities, spanning areas as large as 5 million acres in the United States. Utility ROWs include electricity transmission ROWs, gas pipeline and telecommunication ROWs. Electricity transmission ROWs are created to prevent vegetation interference with transmission lines. Some studies have shown that electricity transmission ROWs harbor more plant species than adjoining forest areas, due to alterations in the microclimate in and around the corridor. Discontinuities in forest areas associated with utility right-of-ways can serve as biodiversity havens for native bees and grassland species, as the right-of-ways are preserved in an early successional stage.

Implications

Forest fragmentation is one of the greatest threats to biodiversity in forests, especially in the tropics. The problem of habitat destruction that caused the fragmentation in the first place is compounded by
  • the inability of individual forest fragments to support viable populations, especially of large vertebrates
  • the local extinction of species that do not have at least one fragment capable of supporting a viable population
  • edge effects that alter the conditions of the outer areas of the fragment, greatly reducing the amount of true forest interior habitat.
The effect of fragmentation on the flora and fauna of a forest patch depends on a) the size of the patch, and b) its degree of isolation. Isolation depends on the distance to the nearest similar patch, and the contrast with the surrounding areas. For example, if a cleared area is reforested or allowed to regenerate, the increasing structural diversity of the vegetation will lessen the isolation of the forest fragments. However, when formerly forested lands are converted permanently to pastures, agricultural fields, or human-inhabited developed areas, the remaining forest fragments, and the biota within them, are often highly isolated.

Forest patches that are smaller or more isolated will lose species faster than those that are larger or less isolated. A large number of small forest "islands" typically cannot support the same biodiversity that a single contiguous forest would hold, even if their combined area is much greater than the single forest. However, forest islands in rural landscapes greatly increase their biodiversity.

Approaches to understanding habitat fragmentation

Two approaches that are typically used to understand habitat fragmentation and its ecological impacts.

Species-oriented approach

The species-oriented approach focuses specifically on individual species and how they each respond to their environment and habitat changes with in it. This approach can be limited because it does only focus on individual species and does not allow for a broad view of the impacts of habitat fragmentation across species.

Pattern-oriented approach

The pattern-oriented approach is based on land cover and its patterning in correlation with species occurrences. One model of study for landscape patterning is the patch-matrix-corridor model developed by Richard Forman The pattern-oriented approach focuses on land cover defined by human means and activities. This model has stemmed from island biogeography and tries to infer causal relationships between the defined landscapes and the occurrence of species or groups of species within them. The approach has limitations in its collective assumptions across species or landscapes which may not account for variations amongst them.

Variegation Model

The other model is the variegation model. Variegated landscapes retain much of their natural vegetation but are intermixed with gradients of modified habitat.  This model of habitat fragmentation typically applies to landscapes that are modified by agriculture. In contrast to the fragmentation model that is denoted by isolated patches of habitat surrounded by unsuitable landscape environments, the variegation model applies to landscapes modified by agriculture where small patches of habitat remain near the remnant original habitat. In between these patches are a matrix of grassland that are often modified versions of the original habitat. These areas do not present as much of a barrier to native species.

Lie group

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Lie_group In mathematics , a Lie gro...