Apple Explained

An apple is a round, edible fruit produced by an apple tree (Malus spp., among them the domestic or orchard apple; Malus domestica). Apple trees are cultivated worldwide and are the most widely grown species in the genus Malus. The tree originated in Central Asia, where its wild ancestor, Malus sieversii, is still found. Apples have been grown for thousands of years in Eurasia and were introduced to North America by European colonists. Apples have religious and mythological significance in many cultures, including Norse, Greek, and European Christian tradition.

Apples grown from seed tend to be very different from those of their parents, and the resultant fruit frequently lacks desired characteristics. For commercial purposes, including botanical evaluation, apple cultivars are propagated by clonal grafting onto rootstocks. Apple trees grown without rootstocks tend to be larger and much slower to fruit after planting. Rootstocks are used to control the speed of growth and the size of the resulting tree, allowing for easier harvesting.

There are more than 7,500 cultivars of apples. Different cultivars are bred for various tastes and uses, including cooking, eating raw, and cider or apple juice production. Trees and fruit are prone to fungal, bacterial, and pest problems, which can be controlled by a number of organic and non-organic means. In 2010, the fruit's genome was sequenced as part of research on disease control and selective breeding in apple production.

Etymology

The word apple, whose Old English ancestor is English, Old (ca.450-1100);: æppel, is descended from the Proto-Germanic noun Germanic languages: *aplaz, descended in turn from Proto-Indo-European Indo-European languages: *h₂ébōl.[1]

As late as the 17th century, the word also functioned as a generic term for all fruit, including nuts. This can be compared to the 14th-century Middle English expression English, Middle (1100-1500);: appel of paradis, meaning a banana.[2]

Description

The apple is a deciduous tree, generally standing 6to tall in cultivation and up to in the wild, though more typically .[3] When cultivated, the size, shape and branch density are determined by rootstock selection and trimming method. Apple trees may naturally have a rounded to erect crown with a dense canopy of leaves. The bark of the trunk is dark gray or gray-brown, but young branches are reddish or dark-brown with a smooth texture. When young twigs are covered in very fine downy hairs and become hairless as they become older.[4]

The buds are egg shaped and dark red or purple in color and range in size from 3 to 5 millimeters, but usually less than 4 mm. The bud scales have very hairy edges. When emerging from the buds the leaves are, that is their edges overlap each other. The shape is ranges from simple ovals (elliptic) medium or wide in width, somewhat egg shaped with the wider portion toward their base (ovate) or even with sides that are more parallel to each other instead of curved (oblong) with a narrow pointed end. The edges have broadly angled teeth, but do not have lobes. The top surface of the leaves are, almost hairless, while the undersides are densely covered in fine hairs. The leaves are attached alternately by short leaf stems long.

Blossoms are produced in spring simultaneously with the budding of the leaves and are produced on spurs and some long shoots. When the flower buds first begin to open the petals are rose-pink and fade to white or light pink when fully open with each flower 3to in diameter. The five petaled flowers are group in an inflorescence consisting of a cyme with 4–6 flowers. The central flower of the inflorescence is called the "king bloom"; it opens first and can develop a larger fruit.[5]

Fruit

The fruit is a pome that matures in late summer or autumn. The true fruits or carpels are the harder interior chambers inside the apple's core. There are usually five carpels inside an apple, but there may be as few as three. Each of the chambers contains one or two seeds.[6] The edible flesh is formed from the receptacle at the base of the flower.[7]

The seeds are egg- to pear-shaped and may be colored from light brown or tan to a very dark brown, often with red shades or even purplish-black. They may have a blunt or sharp point.[8] The five sepals remain attached and stand out from the surface of the apple.[3]

The size of the fruit varies widely between cultivars, but generally has a diameter between .[4] The shape is quite variable and may be nearly round, elongated, conical, or short and wide.[9]

The groundcolor of ripe apples is yellow, green, yellow-green or whitish yellow. The overcolor of ripe apples can be orange-red, pink-red, red, purple-red or brown-red. The overcolor amount can be 0–100%.[10] The skin may be wholly or partly russeted, making it rough and brown. The skin is covered in a protective layer of epicuticular wax.[11] The skin may also be marked with scattered dots. The flesh is generally pale yellowish-white, though it can be pink, yellow or green.

Chemistry

Important volatile compounds in apples that contribute to their scent and flavour include acetaldehyde, ethyl acetate, 1-butanal, ethanol, 2-methylbutanal, 3-methylbutanal, ethyl propionate, ethyl 2-methylpropionate, ethyl butyrate, ethyl 2-methyl butyrate, hexanal, 1-butanol, 3-methylbutyl acetate, 2-methylbutyl acetate, 1-propyl butyrate, ethyl pentanoate, amyl acetate, 2-methyl-1-butanol, trans-2-hexenal, ethyl hexanoate, hexanol.[12] [13]

Taxonomy

The apple as a species has more than 100 alternative scientific names, or synonyms.[14] In modern times, Malus pumila and Malus domestica are the two main names in use. M. pumila is the older name, but M. domestica has become much more commonly used starting in the 21st century, especially in the western world. Two proposals were made to make M. domestica a conserved name: the earlier proposal was voted down by the Committee for Vascular Plants of the IAPT in 2014, but in April 2017 the Committee decided, with a narrow majority, that the newly popular name should be conserved.[15] The General Committee of the IAPT decided in June 2017 to approve this change, officially conserving M. domestica.[16] Nevertheless, some works published after 2017 still use M. pumila as the correct name, under an alternate taxonomy.[17]

When first classified by Linnaeus in 1753, the pears, apples, and quinces were combined into one genus that he named Pyrus and he named the apple as Pyrus malus. This was widely accepted, however the botanist Philip Miller published an alternate classification in The Gardeners Dictionary with the apple species separated from Pyrus in 1754. He did not clearly indicate that by Malus pumila he meant the domesticated apple. Nonetheless, it was used as such by many botanists. When Moritz Balthasar Borkhausen published his scientific description of the apple in 1803 it may have been a new combination of P. malus var. domestica, but this was not directly referenced by Borkhausen. The earliest use of var. domestica for the apple was by Georg Adolf Suckow in 1786.

Genome

Apples are diploid, with two sets of chromosomes per cell (though triploid cultivars, with three sets, are not uncommon), have 17 chromosomes and an estimated genome size of approximately 650 Mb. Several whole genome sequences have been completed and made available. The first one in 2010 was based on the diploid cultivar 'Golden Delicious'.[18] However, this first whole genome sequence contained several errors,[19] in part owing to the high degree of heterozygosity in diploid apples which, in combination with an ancient genome duplication, complicated the assembly. Recently, double- and trihaploid individuals have been sequenced, yielding whole genome sequences of higher quality.[20] [21]

The first whole genome assembly was estimated to contain around 57,000 genes,[18] though the more recent genome sequences support estimates between 42,000 and 44,700 protein-coding genes.[20] [21] The availability of whole genome sequences has provided evidence that the wild ancestor of the cultivated apple most likely is Malus sieversii. Re-sequencing of multiple accessions has supported this, while also suggesting extensive introgression from Malus sylvestris following domestication.

Cultivation

History

Central Asia is generally considered the center of origin for apples due to the genetic variability in specimens there.[22] The wild ancestor of Malus domestica was Malus sieversii, found growing wild in the mountains of Central Asia in southern Kazakhstan, Kyrgyzstan, Tajikistan, and northwestern China.[23] Cultivation of the species, most likely beginning on the forested flanks of the Tian Shan mountains, progressed over a long period of time and permitted secondary introgression of genes from other species into the open-pollinated seeds. Significant exchange with Malus sylvestris, the crabapple, resulted in populations of apples being more related to crabapples than to the more morphologically similar progenitor Malus sieversii. In strains without recent admixture the contribution of the latter predominates.[24] [25] [26]

The apple is thought to have been domesticated 4,000–10,000 years ago in the Tian Shan mountains, and then to have travelled along the Silk Road to Europe, with hybridization and introgression of wild crabapples from Siberia (M. baccata), the Caucasus (M. orientalis), and Europe (M. sylvestris). Only the M. sieversii trees growing on the western side of the Tian Shan mountains contributed genetically to the domesticated apple, not the isolated population on the eastern side.[27]

Chinese soft apples, such as M. asiatica and M. prunifolia, have been cultivated as dessert apples for more than 2,000 years in China. These are thought to be hybrids between M. baccata and M. sieversii in Kazakhstan.[27]

Among the traits selected for by human growers are size, fruit acidity, color, firmness, and soluble sugar. Unusually for domesticated fruits, the wild M. sieversii origin is only slightly smaller than the modern domesticated apple.[27]

At the Sammardenchia-Cueis site near Udine in Northeastern Italy, seeds from some form of apples have been found in material carbon dated to around 4000 BCE.[28] Genetic analysis has not yet been successfully used to determine whether such ancient apples were wild Malus sylvestris or Malus domesticus containing Malus sieversii ancestry. It is hard to distinguish in the archeological record between foraged wild apples and apple plantations.[29]

There is indirect evidence of apple cultivation in the third millennium BCE in the Middle East. There was substantial apple production in European classical antiquity, and grafting was certainly known then.[29] Grafting is an essential part of modern domesticated apple production, to be able to propagate the best cultivars; it is unclear when apple tree grafting was invented.[29]

The Roman writer Pliny the Elder describes a method of storage for apples from his time in the 1st Century. He says they should be placed in a room with good air circulation from a north facing window on a bed of straw, chaff, or mats with windfalls kept separately.[30] Though methods like this will extend the availabity of reasonably fresh apples, without refrigeration their lifespan is limited. Even sturdy winter apple varieties will only keep well until December in cool climates.[31] For longer storage medieval Europeans strung up cored and peeled apples to dry, either whole or sliced into rings.[32]

Of the many Old World plants that the Spanish introduced to Chiloé Archipelago in the 16th century, apple trees became particularly well adapted.[33] Apples were introduced to North America by colonists in the 17th century, and the first named apple cultivar was introduced in Boston by Reverend William Blaxton in 1640.[34] The only apples native to North America are crab apples.[35]

Apple cultivars brought as seed from Europe were spread along Native American trade routes, as well as being cultivated on colonial farms. An 1845 United States apples nursery catalogue sold 350 of the "best" cultivars, showing the proliferation of new North American cultivars by the early 19th century. In the 20th century, irrigation projects in Eastern Washington began and allowed the development of the multibillion-dollar fruit industry, of which the apple is the leading product.

Until the 20th century, farmers stored apples in frostproof cellars during the winter for their own use or for sale. Improved transportation of fresh apples by train and road replaced the necessity for storage.[36] [37] Controlled atmosphere facilities are used to keep apples fresh year-round. Controlled atmosphere facilities use high humidity, low oxygen, and controlled carbon dioxide levels to maintain fruit freshness. They were first researched at Cambridge University in the 1920s and first used in the United States in the 1950s.[38]

Breeding

See also: Fruit tree propagation and Malling series.

Many apples grow readily from seeds. However, apples must be propagated asexually to obtain the sweetness and other desirable characteristics of the parent. This is because seedling apples are "extreme heterozygotes". Rather than resembling their parents, seedlings are all different from each other and from their parents.[39] Triploid cultivars have an additional reproductive barrier in that three sets of chromosomes cannot be divided evenly during meiosis, yielding unequal segregation of the chromosomes (aneuploids). Even in the case when a triploid plant can produce a seed (apples are an example), it occurs infrequently, and seedlings rarely survive.[40]

Because apples are not true breeders when planted as seeds, grafting is usually used. The rootstock used for the bottom of the graft can be selected to produce trees of a large variety of sizes, as well as changing the winter hardiness, insect and disease resistance, and soil preference of the resulting tree. Dwarf rootstocks can be used to produce very small trees (less than 10feet high at maturity), which bear fruit many years earlier in their life cycle than full size trees, and are easier to harvest.[41]

Dwarf rootstocks for apple trees can be traced as far back as 300 BCE, to the area of Persia and Asia Minor. Alexander the Great sent samples of dwarf apple trees to Aristotle's Lyceum. Dwarf rootstocks became common by the 15th century and later went through several cycles of popularity and decline throughout the world.[42] The majority of the rootstocks used to control size in apples were developed in England in the early 1900s. The East Malling Research Station conducted extensive research into rootstocks, and their rootstocks are given an "M" prefix to designate their origin. Rootstocks marked with an "MM" prefix are Malling-series cultivars later crossed with trees of 'Northern Spy' in Merton, England.[43]

Most new apple cultivars originate as seedlings, which either arise by chance or are bred by deliberately crossing cultivars with promising characteristics.[44] The words "seedling", "pippin", and "kernel" in the name of an apple cultivar suggest that it originated as a seedling. Apples can also form bud sports (mutations on a single branch). Some bud sports turn out to be improved strains of the parent cultivar. Some differ sufficiently from the parent tree to be considered new cultivars.[45]

Apples have been acclimatized in Ecuador at very high altitudes, where they can often, with the needed factors, provide crops twice per year because of constant temperate conditions year-round.[46]

Pollination

See also: Fruit tree pollination.

Apples are self-incompatible; they must cross-pollinate to develop fruit. During the flowering each season, apple growers often utilize pollinators to carry pollen. Honey bees are most commonly used. Orchard mason bees are also used as supplemental pollinators in commercial orchards. Bumblebee queens are sometimes present in orchards, but not usually in sufficient number to be significant pollinators.[47]

Cultivars are sometimes classified by the day of peak bloom in the average 30-day blossom period, with pollinizers selected from cultivars within a 6-day overlap period. There are four to seven pollination groups in apples, depending on climate:

One cultivar can be pollinated by a compatible cultivar from the same group or close (A with A, or A with B, but not A with C or D).[48]

Maturation and harvest

See also: Fruit picking and Fruit tree pruning.

Cultivars vary in their yield and the ultimate size of the tree, even when grown on the same rootstock. Some cultivars, if left unpruned, grow very large—letting them bear more fruit, but making harvesting more difficult. Depending on tree density (number of trees planted per unit surface area), mature trees typically bear 40- of apples each year, though productivity can be close to zero in poor years. Apples are harvested using three-point ladders that are designed to fit amongst the branches. Trees grafted on dwarfing rootstocks bear about 10- of fruit per year.

Some farms with apple orchards open them to the public so consumers can pick their own apples.[49]

Crops ripen at different times of the year according to the cultivar. Cultivar that yield their crop in the summer include 'Gala', 'Sweet Bough', and 'Duchess'; fall producers include 'Fuji', 'Jonagold', 'Golden Delicious', 'Red Delicious', and 'Blenheim'; winter producers include 'Granny Smith', 'King', 'Swayzie', and 'Tolman Sweet'.

Storage

Commercially, apples can be stored for months in controlled atmosphere chambers. Apples are commonly stored in chambers with lowered concentrations of oxygen to reduce respiration and slow softening and other changes if the fruit is already fully ripe. The gas ethylene is used by plants as a hormone which promotes ripening, decreasing the time an apple can be stored. For storage longer than about six months the apples are picked earlier, before full ripeness, when ethylene production by the fruit is low. However, in many varieties this increases their sensitivity to carbon dioxide, which also must be controlled.[50]

For home storage, most cultivars of apple can be held for approximately two weeks when kept at the coolest part of the refrigerator (i.e. below 5 °C).[51] Some varieties of apples (e.g. 'Granny Smith' and 'Fuji') have more than three times the storage life of others.[52]

Non-organic apples may be sprayed with a substance 1-methylcyclopropene blocking the apples' ethylene receptors, temporarily preventing them from ripening.[53]

Pests and diseases

Apple trees are susceptible to fungal and bacterial diseases, and to damage by insect pests. Many commercial orchards pursue a program of chemical sprays to maintain high fruit quality, tree health, and high yields. These prohibit the use of synthetic pesticides, though some older pesticides are allowed. Organic methods include, for instance, introducing its natural predator to reduce the population of a particular pest.

A wide range of pests and diseases can affect the plant. Three of the more common diseases or pests are mildew, aphids, and apple scab.

Among the most serious disease problems is a bacterial disease called fireblight, and three fungal diseases: Gymnosporangium rust, black spot,[58] and bitter rot.[59] Codling moths, and the apple maggots of fruit flies, cause serious damage to apple fruits, making them unsaleable. Young apple trees are also prone to mammal pests like mice and deer, which feed on the soft bark of the trees, especially in winter.[57] The larvae of the apple clearwing moth (red-belted clearwing) burrow through the bark and into the phloem of apple trees, potentially causing significant damage.[60]

Cultivars

See main article: List of apple cultivars.

There are more than 7,500 known cultivars (cultivated varieties) of apples.[61] Cultivars vary in their yield and the ultimate size of the tree, even when grown on the same rootstock. Different cultivars are available for temperate and subtropical climates. The UK's National Fruit Collection, which is the responsibility of the Department of Environment, Food, and Rural Affairs, includes a collection of over 2,000 cultivars of apple tree in Kent.[62] The University of Reading, which is responsible for developing the UK national collection database, provides access to search the national collection. The University of Reading's work is part of the European Cooperative Programme for Plant Genetic Resources of which there are 38 countries participating in the Malus/Pyrus work group.[63]

The UK's national fruit collection database contains much information on the characteristics and origin of many apples, including alternative names for what is essentially the same "genetic" apple cultivar. Most of these cultivars are bred for eating fresh (dessert apples), though some are cultivated specifically for cooking (cooking apples) or producing cider. Cider apples are typically too tart and astringent to eat fresh, but they give the beverage a rich flavor that dessert apples cannot.[64]

In the United States there are many apple breeding programs associated with universities. Cornell University has had a program operating since 1880 in Geneva, New York. Among their recent well known apples is the 'SnapDragon' cultivar released in 2013. In the west Washington State University started a program to support their apple industry in 1994 and released the 'Cosmic Crisp' cultivar in 2017. The third most grown apple cultivar in the United States is the 'Honeycrisp', released by the University of Minnesota program in 1991.[65] Unusually for a popular cultivar, the 'Honeycrisp' is not directly related to another popular apple cultivar but instead to two unsuccessful cultivars.[66] In Europe there are also many breeding programs such as the Julius Kühn-Institut, the German federal research center for cultivated plants.[67]

Commercially popular apple cultivars are soft but crisp. Other desirable qualities in modern commercial apple breeding are a colorful skin, absence of russeting, ease of shipping, lengthy storage ability, high yields, disease resistance, common apple shape, and developed flavor.[68] Modern apples are generally sweeter than older cultivars, as popular tastes in apples have varied over time. Most North Americans and Europeans favor sweet, subacid apples, but tart apples have a strong minority following. Extremely sweet apples with barely any acid flavor are popular in Asia,[69] especially the Indian subcontinent.

Old cultivars are often oddly shaped, russeted, and grow in a variety of textures and colors. Some find them to have better flavor than modern cultivars, but they may have other problems that make them commercially unviable—low yield, disease susceptibility, poor tolerance for storage or transport, or just being the "wrong" size.[70] A few old cultivars are still produced on a large scale, but many have been preserved by home gardeners and farmers that sell directly to local markets. Many unusual and locally important cultivars with their own unique taste and appearance exist; apple conservation campaigns have sprung up around the world to preserve such local cultivars from extinction. In the United Kingdom, old cultivars such as 'Cox's Orange Pippin' and 'Egremont Russet' are still commercially important even though by modern standards they are low yielding and susceptible to disease.[71]

Production

See main article: List of countries by apple production.

Apple production in 2022
CountryMillions of
tonnes
World
Source: FAOSTAT of the United Nations[72]

World production of apples in 2022 was 95 million tonnes, with China producing 50% of the total (table).[72] Secondary producers were the United States and Turkey.[72]

Toxicity

Amygdalin

Apple seeds contain small amounts of amygdalin, a sugar and cyanide compound known as a cyanogenic glycoside. Ingesting small amounts of apple seeds causes no ill effects, but consumption of extremely large doses can cause adverse reactions. It may take several hours before the poison takes effect, as cyanogenic glycosides must be hydrolyzed before the cyanide ion is released.[73] The U.S. National Library of Medicine's Hazardous Substances Data Bank records no cases of amygdalin poisoning from consuming apple seeds.[74]

Allergy

One form of apple allergy, often found in northern Europe, is called birch-apple syndrome and is found in people who are also allergic to birch pollen.[75] Allergic reactions are triggered by a protein in apples that is similar to birch pollen, and people affected by this protein can also develop allergies to other fruits, nuts, and vegetables. Reactions, which entail oral allergy syndrome (OAS), generally involve itching and inflammation of the mouth and throat, but in rare cases can also include life-threatening anaphylaxis.[76] This reaction only occurs when raw fruit is consumed—the allergen is neutralized in the cooking process. The variety of apple, maturity and storage conditions can change the amount of allergen present in individual fruits. Long storage times can increase the amount of proteins that cause birch-apple syndrome.[75]

In other areas, such as the Mediterranean, some individuals have adverse reactions to apples because of their similarity to peaches.[75] This form of apple allergy also includes OAS, but often has more severe symptoms, such as vomiting, abdominal pain and urticaria, and can be life-threatening. Individuals with this form of allergy can also develop reactions to other fruits and nuts. Cooking does not break down the protein causing this particular reaction, so affected individuals cannot eat raw or cooked apples. Freshly harvested, over-ripe fruits tend to have the highest levels of the protein that causes this reaction.[75]

Breeding efforts have yet to produce a hypoallergenic fruit suitable for either of the two forms of apple allergy.[75]

Uses

See also: Cooking apple and Cider apple.

Nutrition

A raw apple is 86% water and 14% carbohydrates, with negligible content of fat and protein (table). A reference serving of a raw apple with skin weighing 100 grams provides 52 calories and a moderate content of dietary fiber.[77] Otherwise, there is low content of micronutrients, with the Daily Values of all falling below 10%.[78]

Culinary

Apples varieties can be grouped as cooking apples, eating apples, and cider apples, the last so astringent as to be "almost inedible". Apples are consumed as juice, raw in salads, baked in pies, cooked into sauces and apple butter, or baked.[79] They are sometimes used as an ingredient in savory foods, such as sausage and stuffing.[80]

Several techniques are used to preserve apples and apple products. Traditional methods include drying and making apple butter. Juice and cider are produced commercially; cider is a significant industry in regions such as the West of England and Normandy.

A toffee apple (UK) or caramel apple (US) is a confection made by coating an apple in hot toffee or caramel candy respectively and allowing it to cool.[81] Apples and honey are a ritual food pairing eaten during the Jewish New Year of Rosh Hashanah.[82]

Apples are an important ingredient in many desserts, such as pies, crumbles, and cakes. When cooked, some apple cultivars easily form a puree known as apple sauce, which can be cooked down to form a preserve, apple butter. They are often baked or stewed, and are cooked in some meat dishes.[83]

Apples are milled or pressed to produce apple juice, which may be drunk unfiltered (called apple cider in North America), or filtered. Filtered juice is often concentrated and frozen, then reconstituted later and consumed. Apple juice can be fermented to make cider (called hard cider in North America), ciderkin, and vinegar. Through distillation, various alcoholic beverages can be produced, such as applejack, Calvados, and apfelwein.[84]

Organic production

Organic apples are commonly produced in the United States.[85] Due to infestations by key insects and diseases, organic production is difficult in Europe.[86] The use of pesticides containing chemicals, such as sulfur, copper, microorganisms, viruses, clay powders, or plant extracts (pyrethrum, neem) has been approved by the EU Organic Standing Committee to improve organic yield and quality.[86] A light coating of kaolin, which forms a physical barrier to some pests, also may help prevent apple sun scalding.

Non-browning apples

Apple skins and seeds contain polyphenols.[87] These are oxidised by the enzyme polyphenol oxidase, which causes browning in sliced or bruised apples, by catalyzing the oxidation of phenolic compounds to o-quinones, a browning factor.[88] Browning reduces apple taste, color, and food value. Arctic apples, a non-browning group of apples introduced to the United States market in 2019, have been genetically modified to silence the expression of polyphenol oxidase, thereby delaying a browning effect and improving apple eating quality.[89] [90] The US Food and Drug Administration in 2015, and Canadian Food Inspection Agency in 2017, determined that Arctic apples are as safe and nutritious as conventional apples.[91] [92]

Other products

Apple seed oil is obtained by pressing apple seeds for manufacturing cosmetics.[93]

In culture

See main article: Apple (symbolism).

Germanic paganism

In Norse mythology, the goddess Iðunn is portrayed in the Prose Edda (written in the 13th century by Snorri Sturluson) as providing apples to the gods that give them eternal youthfulness. The English scholar H. R. Ellis Davidson links apples to religious practices in Germanic paganism, from which Norse paganism developed. She points out that buckets of apples were found in the Oseberg ship burial site in Norway, that fruit and nuts (Iðunn having been described as being transformed into a nut in Skáldskaparmál) have been found in the early graves of the Germanic peoples in England and elsewhere on the continent of Europe, which may have had a symbolic meaning, and that nuts are still a recognized symbol of fertility in southwest England.[94]

Davidson notes a connection between apples and the Vanir, a tribe of gods associated with fertility in Norse mythology, citing an instance of eleven "golden apples" being given to woo the beautiful Gerðr by Skírnir, who was acting as messenger for the major Vanir god Freyr in stanzas 19 and 20 of Skírnismál. Davidson also notes a further connection between fertility and apples in Norse mythology in chapter 2 of the Völsunga saga: when the major goddess Frigg sends King Rerir an apple after he prays to Odin for a child, Frigg's messenger (in the guise of a crow) drops the apple in his lap as he sits atop a mound. Rerir's wife's consumption of the apple results in a six-year pregnancy and the birth (by Caesarean section) of their son—the hero Völsung.[95]

Further, Davidson points out the "strange" phrase "Apples of Hel" used in an 11th-century poem by the skald Thorbiorn Brúnarson. She states this may imply that the apple was thought of by Brúnarson as the food of the dead. Further, Davidson notes that the potentially Germanic goddess Nehalennia is sometimes depicted with apples and that parallels exist in early Irish stories. Davidson asserts that while cultivation of the apple in Northern Europe extends back to at least the time of the Roman Empire and came to Europe from the Near East, the native varieties of apple trees growing in Northern Europe are small and bitter. Davidson concludes that in the figure of Iðunn "we must have a dim reflection of an old symbol: that of the guardian goddess of the life-giving fruit of the other world."

Greek mythology

Apples appear in many religious traditions, often as a mystical or forbidden fruit. One of the problems identifying apples in religion, mythology and folktales is that the word "apple" was used as a generic term for all (foreign) fruit, other than berries, including nuts, as late as the 17th century.[96] For instance, in Greek mythology, the Greek hero Heracles, as a part of his Twelve Labours, was required to travel to the Garden of the Hesperides and pick the golden apples off the Tree of Life growing at its center.[97] [98]

The Greek goddess of discord, Eris, became disgruntled after she was excluded from the wedding of Peleus and Thetis.[99] In retaliation, she tossed a golden apple inscribed Καλλίστη (Kallistē, "For the most beautiful one"), into the wedding party. Three goddesses claimed the apple: Hera, Athena, and Aphrodite. Paris of Troy was appointed to select the recipient. After being bribed by both Hera and Athena, Aphrodite tempted him with the most beautiful woman in the world, Helen of Sparta. He awarded the apple to Aphrodite, thus indirectly causing the Trojan War.[100]

The apple was thus considered, in ancient Greece, sacred to Aphrodite. To throw an apple at someone was to symbolically declare one's love; and similarly, to catch it was to symbolically show one's acceptance of that love. An epigram claiming authorship by Plato states:[101]

Atalanta, also of Greek mythology, raced all her suitors in an attempt to avoid marriage. She outran all but Hippomenes (also known as Melanion, a name possibly derived from melon, the Greek word for both "apple" and fruit in general),[98] who defeated her by cunning, not speed. Hippomenes knew that he could not win in a fair race, so he used three golden apples (gifts of Aphrodite, the goddess of love) to distract Atalanta. It took all three apples and all of his speed, but Hippomenes was finally successful, winning the race and Atalanta's hand.[97]

Celtic mythology

In Celtic mythology, the otherworld has many names, including Emain Ablach, "Emain of the Apple-trees". A version of this is Avalon in Arthurian legend, or in Welsh Ynys Afallon, "Island of Apples".[102]

Christian art

Though the forbidden fruit of Eden in the Book of Genesis is not identified, popular Christian tradition has held that it was an apple that Eve coaxed Adam to share with her.[103] The origin of the popular identification with a fruit unknown in the Middle East in biblical times is found in wordplay with the Latin words mālum (an apple) and mălum (an evil), each of which is normally written malum.[104] The tree of the forbidden fruit is called "the tree of the knowledge of good and evil" in Genesis 2:17,[105] and the Latin for "good and evil" is bonum et malum.[106]

Renaissance painters may also have been influenced by the story of the golden apples in the Garden of Hesperides. As a result, in the story of Adam and Eve, the apple became a symbol for knowledge, immortality, temptation, the fall of man into sin, and sin itself. The larynx in the human throat has been called the "Adam's apple" because of a notion that it was caused by the forbidden fruit remaining in the throat of Adam. The apple as symbol of sexual seduction has been used to imply human sexuality, possibly in an ironic vein.[103]

Proverb

The proverb, "An apple a day keeps the doctor away", addressing the supposed health benefits of the fruit, has been traced to 19th-century Wales, where the original phrase was "Eat an apple on going to bed, and you'll keep the doctor from earning his bread".[107] In the 19th century and early 20th, the phrase evolved to "an apple a day, no doctor to pay" and "an apple a day sends the doctor away"; the phrasing now commonly used was first recorded in 1922.[108]

See also

Further reading

Notes and References

  1. News: Where the word 'apple' came from and why the apple was unlucky to be linked to the fall of man . 6 July 2021 . live . 2023-06-28 . . https://web.archive.org/web/20230628112156/https://www.scmp.com/magazines/post-magazine/article/3139890/where-word-apple-came-and-why-forbidden-fruit-was-unlucky . 28 June 2023 . en.
  2. Web site: Origin and meaning of "apple" by Online Etymology Dictionary . . 22 November 2019 . 21 December 2019 . https://web.archive.org/web/20191221020212/https://www.etymonline.com/word/apple . live .
  3. Web site: Dickson . Elizabeth E. . Malus domestica . . 27 July 2024 . 28 May 2021.
  4. Book: Heil . Kenneth D. . O'Kane, Jr. . Steve L. . Reeves . Linda Mary . Clifford . Arnold . Flora of the Four Corners Region: Vascular Plants of the San Juan River Drainage, Arizona, Colorado, New Mexico, and Utah . 2013 . . St. Louis, Missouri . 909 . 27 July 2024.
  5. Web site: Apples - Malus domestica . North Carolina Extension Gardener Plant Toolbox . . 31 July 2024 . https://web.archive.org/web/20240531122432/https://plants.ces.ncsu.edu/plants/malus-domestica/common-name/apples/ . 31 May 2024 . live.
  6. Book: Juniper . Barrie E. . Mabberley . David J. . Barrie Juniper . David Mabberley . The Story of the Apple . 2006 . . Portland, Oregon . 978-0-88192-784-9 . 27 . 1 August 2024.
  7. Web site: Fruit glossary . Royal Horticultural Society . 7 August 2024 . live . https://web.archive.org/web/20240807071550/https://schoolgardening.rhs.org.uk/Resources/Info-Sheet/Fruit-Glossary . 7 August 2024.
  8. Book: Burford . Tom . Tom Burford . Apples of North America : 192 Exceptional Varieties for Gardeners, Growers and Cooks . 2013 . Timber Press . Portland, Oregon . 978-1-60469-249-5 . 22, 50, 55, 122, 123, 137, 141, 147, 159, 245, 246 . First .
  9. Web site: Shape . Western Agricultural Research Center . . 30 July 2024 . live . https://web.archive.org/web/20240423183929/https://agresearch.montana.edu/warc/guides/apples/heritage_orchard_management_guide/heritage-fruit-id-guide/apple_id_characteristics/appleid_shape.html . 23 April 2024.
  10. Book: Janick . Jules . Cummins . James N. . Brown . Susan K. . Hemmat . Minou . Fruit Breeding, Volume I: Tree and Tropical Fruits . Jules Janick . James N. Moore . 978-0-471-31014-3 . 1996 . . http://www.hort.purdue.edu/newcrop/pri/chapter.pdf . 9, 48 . Chapter 1: Apples . live . https://web.archive.org/web/20130719085631/http://www.hort.purdue.edu/newcrop/pri/chapter.pdf . 19 July 2013 .
  11. Web site: Natural Waxes on Fruits . Postharvest.tfrec.wsu.edu . 29 October 2010 . 14 June 2013 . dead . https://web.archive.org/web/20130524130738/http://postharvest.tfrec.wsu.edu/pages/N2I2A . 24 May 2013 .
  12. Flath . R. A. . Black . D. R. . Forrey . R. R. . McDonald . G. M. . Mon . T. R. . Teranishi . R. . Volatiles in Gravenstein Apple Essence Identified by GC-Mass Spectrometry . Journal of Chromatographic Science . 1 August 1969 . 7 . 8 . 508 . 10.1093/CHROMSCI/7.8.508.
  13. Flath . Robert A. . Black . Dale Robert. . Guadagni . Dante G. . McFadden . William H. . Schultz . Thomas H. . Identification and organoleptic evaluation of compounds in Delicious apple essence . . January 1967 . 15 . 1 . 29 . 10.1021/jf60149a032.
  14. Qian . Guan-Ze . Liu . Lian-Fen . Tang . Geng-Guo . (1933) Proposal to conserve the name Malus domestica against M. pumila, M. communis, M. frutescens, and Pyrus dioica (Rosaceae) . . April 2010 . 59 . 2 . 650–652 . 10.1002/tax.592038 . en.
  15. Report of the Nomenclature Committee for Vascular Plants: 69 . 10.12705/662.17 . 2017 . Applequist . Wendy L. . . 66 . 2 . 500–513.
  16. Wilson . Karen L. . Report of the General Committee: 18 . Taxon . June 2017 . 66 . 3 . 742 . 10.12705/663.15 . free .
  17. 726282-1 . Malus domestica (Suckow) Borkh. . 31 July 2024.
  18. 2010 . The genome of the domesticated apple (Malus × domestica Borkh.) . Nature Genetics . 10.1038/ng.654 . 5 . Velasco . Riccardo. Zharkikh . Andrey . Affourtit . Jason . Dhingra . Amit . Cestaro . Alessandro . Kalyanaraman. Ananth . Fontana . Paolo . Bhatnagar . Satish K. . Troggio. Michela . Pruss . Dmitry . Salvi . Silvio . Pindo . Massimo. Baldi . Paolo . Castelletti . Sara . Cavaiuolo . Marina . Coppola . Giuseppina . Costa . Fabrizio . Cova . Valentina . Dal Ri. Antonio. Goremykin . Vadim . Komjanc . Matteo . Longhi. Sara . Magnago . Pierluigi . Malacarne . Giulia. Malnoy . Mickael . Micheletti . Diego . Moretto . Marco . Perazzolli . Michele . Si-Ammour. Azeddine . Vezzulli . Silvia . 42 . 10 . 833–839 . 20802477 . 14854514 . free.
  19. 2016. A high-density, multi-parental SNP genetic map on apple validates a new mapping approach for outcrossing species . 10.1038/hortres.2016.57. Di Pierro . Erica A.. Gianfranceschi . Luca . Di Guardo . Mario. Koehorst-Van Putten . Herma J.J. . Kruisselbrink. Johannes W.. Longhi . Sara. Troggio. Michela . Bianco . Luca. Muranty. Hélène . Pagliarani. Giulia. Tartarini . Stefano . Letschka. Thomas. Lozano Luis. Lidia. Garkava-Gustavsson . Larisa . Micheletti. Diego. Bink. Marco C.A.M. . Voorrips . Roeland E. . Aziz . Ebrahimi . Velasco . Riccardo . Laurens. François . Van De Weg . W. Eric . 5 . . 3 . 1 . 16057 . 27917289 . 5120355 . 2016HorR....316057D .
  20. 2017. High-quality de novo assembly of the apple genome and methylome dynamics of early fruit development. Nature Communications . 10.1038/ng.3886. Daccord. Nicolas . Celton . Jean-Marc . Linsmith . Gareth. Becker . Claude. Choisne . Nathalie . Schijlen . Elio. Van De Geest . Henri. Bianco . Luca. Micheletti . Diego . Velasco . Riccardo . Di Pierro . Erica Adele. Gouzy . Jérôme. Rees . D Jasper G.. Guérif . Philippe . Muranty . Hélène . Durel . Charles-Eric . Laurens . François . Lespinasse . Yves . Gaillard . Sylvain. Aubourg . Sébastien . Quesneville. Hadi . Weigel . Detlef . Van De Weg. Eric . Troggio . Michela . Bucher . Etienne . 3 . Nature Genetics . 49 . 7 . 1099–1106 . 28581499 . 24690391 . free . 10449/42064 . free.
  21. 2019 . A high-quality apple genome assembly reveals the association of a retrotransposon and red fruit colour . Nature Genetics . 10.1038/s41467-019-09518-x . 5 . Zhang . Liyi . Hu . Jiang . Han . Xiaolei . Li . Jingjing . Gao . Yuan . Richards . Christopher M. . Zhang . Caixia . Tian. Yi . Liu . Guiming . Gul . Hera . Wang. Dajiang . Tian . Yu . Yang . Chuanxin . Meng . Minghui . Yuan . Gaopeng . Kang. Guodong . Wu . Yonglong. Wang . Kun . Zhang . Hengtao . Wang . Depeng . Cong . Peihua . Nature Communications . 10 . 1 . 1494 . 30940818 . 6445120 . 2019NatCo..10.1494Z.
  22. Richards . Christopher M. . 5 . Volk, Gayle M. . Reilley, Ann A. . Henk, Adam D. . Lockwood, Dale R. . Reeves, Patrick A. . Forsline, Philip L. . Genetic diversity and population structure in Malus sieversii, a wild progenitor species of domesticated apple . Tree Genetics & Genomes . 5 . 2 . 339–347 . 2009 . 10.1007/s11295-008-0190-9 . 19847067.
  23. Lauri . Pierre-éric . Maguylo . Karen . Trottier . Catherine . Architecture and size relations: an essay on the apple (Malus × domestica, Rosaceae) tree . American Journal of Botany . March 2006 . 93 . 3 . 357–368 . 10.3732/ajb.93.3.357 . 27 July 2024.
  24. Cornille . Amandine . New Insight into the History of Domesticated Apple: Secondary Contribution of the European Wild Apple to the Genome of Cultivated Varieties. PLOS Genetics . 10.1371/journal.pgen.1002703 . 2012 . Mauricio . Rodney . Gladieux . Pierre . Smulders . Marinus J. M. . Roldán-Ruiz . Isabel . Laurens . François . Le Cam . Bruno . Nersesyan . Anush . Clavel . Joanne . Olonova . Marina . 8 . 5 . e1002703 . 22589740 . 3349737 . 5 . free .
  25. Web site: Kean . Sam . ScienceShot: The Secret History of the Domesticated Apple . 17 May 2012 . live . https://web.archive.org/web/20160611184017/http://www.sciencemag.org/news/2012/05/scienceshot-secret-history-domesticated-apple . 11 June 2016.
  26. Coart . E. . Van Glabeke . S. . De Loose . M. . Larsen . A.S. . Roldán-Ruiz . I. . 2006 . Chloroplast diversity in the genus Malus: new insights into the relationship between the European wild apple (Malus sylvestris (L.) Mill.) and the domesticated apple (Malus domestica Borkh.) . Mol. Ecol. . 15 . 8 . 2171–2182 . 10.1111/j.1365-294x.2006.02924.x . 16780433. 2006MolEc..15.2171C . 31481730 .
  27. Genome re-sequencing reveals the history of apple and supports a two-stage model for fruit enlargement . 10.1038/s41467-017-00336-7. 28811498. 5557836 . Nature Communications . 2017 . Duan . Naibin . Bai . Yang . Sun . Honghe . Wang . Nan . Ma . Yumin . Li . Mingjun . Wang . Xin . Jiao. Chen . Legall . Noah . Mao . Linyong . Wan . Sibao . Wang . Kun . He . Tianming . Feng . Shouqian . Zhang . Zongying . Mao . Zhiquan . Shen . Xiang . Chen . Xiaoliu . Jiang. Yuanmao . Wu . Shujing . Yin . Chengmiao . Ge . Shunfeng . Yang. Long . Jiang . Shenghui . Xu . Haifeng . Liu . Jingxuan . Wang . Deyun . Qu . Changzhi . Wang . Yicheng . Zuo . Weifang . 5 . 8 . 1 . 249 . 2017NatCo...8..249D.
  28. Book: The Origins and Spread of Domestic Plants in Southwest Asia and Europe . Colledge, Sue . Conolly, James . 2016-06-16 . . 9781598749885.
  29. Schlumbaum . Angela . van Glabeke . Sabine . Roldan-Ruiz . Isabel . Towards the onset of fruit tree growing north of the Alps: Ancient DNA from waterlogged apple (Malus sp.) seed fragments . Annals of Anatomy - Anatomischer Anzeiger . January 2012 . 194 . 1 . 157–162 . 10.1016/j.aanat.2011.03.004 . 21501956 . en.
  30. Book: Plinius . Gaius Secundus . Pliny the Elder . Bostock . John . John Bostock (physician) . Riley . Henry T. . Henry Thomas Riley . The Natural History of Pliny . 1855 . Henry G. Bohn . London . 303 . 3 August 2024 . III.
  31. Book: Martin . Alice A. . All about apples . 1976 . . Boston, Massachusetts . 978-0-395-20724-6 . 64–65 . First . 3 August 2024.
  32. Book: Adamson . Melitta Weiss . Food in Medieval Times . 2004 . Greenwood Press . Westport, Connecticut . 978-0-313-32147-4 . 19–20 . en.
  33. Torrejón . Fernando . Cisternas . Marco . Araneda . Alberto . 2004 . Efectos ambientales de la colonización española desde el río Maullín al archipiélago de Chiloé, sur de Chile . Environmental effects of the spanish colonization from de Maullín river to the Chiloé archipelago, southern Chile . . 77 . 4 . 661–677 . 10.4067/s0716-078x2004000400009 . es . free .
  34. Book: Smith . Archibald William . A Gardener's Handbook of Plant Names: Their Meanings and Origins . 1963 . . New York . 40 . First . 10 August 2024 . en.
  35. Book: Poole . Mike . Lawrence . James . The Harrowsmith Reader Volume II . 1980 . . Camden East, Ontario . 978-0-920656-11-2 . 122 . 10 August 2024 . en . Heirloom Apples.
  36. Book: Van Valen . James M. . History of Bergen County, New Jersey . 1900 . New Jersey Publishing and Engraving Company . New York . 33–34 . 9 August 2024 . en.
  37. Book: Brox . Jane . Jane Brox . Five Thousand Days Like This One . 1999 . Beacon Press . Boston, Massachusetts . 978-0-8070-2106-4 . 150–151 . 9 August 2024 . en.
  38. Web site: Cohen . Rachel D. . Thanks To Science, You Can Eat An Apple Every Day . The Salt . . 1 August 2024 . https://web.archive.org/web/20240618003023/https://www.npr.org/sections/thesalt/2018/11/26/668256349/thanks-to-science-you-can-eat-an-apple-every-day . 18 June 2024 . 26 November 2018 . live.
  39. Web site: The Heirloom Apple Orchard . The Jentsch Lab . . 9 August 2024 . https://web.archive.org/web/20240730203237/https://blogs.cornell.edu/jentsch/the-heirloom-orchard/ . 30 July 2024 . live.
  40. Ranney . Thomas G. . Polyploidy: From Evolution to Landscape Plant Improvement . 11th Metropolitan Tree Improvement Alliance Conference held in Gresham, Oregon, August 23–24, 2000 . METRIA . https://web.archive.org/web/20100723170402/http://www.ces.ncsu.edu/fletcher/programs/nursery/metria/metria11/ranney/index.html . 23 July 2010 . 7 November 2010 . https://www.ces.ncsu.edu/fletcher/programs/nursery/metria/metria11/index.html . Proceedings of the 11th Metropolitan Tree Improvement Alliance (METRIA) Conference . METRIA (NCSU.edu) . dead.
  41. Web site: Lord . William G. . Ouellette . Amy . February 2010 . Dwarf Rootstocks for Apple Trees in the Home Garden . dead . https://web.archive.org/web/20130930151829/http://extension.unh.edu/resources/files/Resource000583_Rep605.pdf . 30 September 2013 . 1 September 2013 . University of New Hampshire.
  42. Fallahi . Esmaeil . Colt . W. Michael . Fallahi . Bahar . Chun . Ik-Jo . The Importance of Apple Rootstocks on Tree Growth, Yield, Fruit Quality, Leaf Nutrition, and Photosynthesis with an Emphasis on `Fuji' . HortTechnology . January 2002 . 12 . 1 . 38–44 . 10.21273/HORTTECH.12.1.38 . 9 August 2024 . live . https://web.archive.org/web/20140211173706/http://horttech.ashspublications.org/content/12/1/38.full.pdf . 11 February 2014 . en.
  43. Web site: Parker . M.L. . Apple Rootstocks and Tree Spacing . North Carolina Cooperative Extension Service . 1 September 2013 . https://web.archive.org/web/20130911051127/http://www.ces.ncsu.edu/hil/hil-300-a.html . 11 September 2013 . en . September 1993 . dead.
  44. Book: Ferree . David Curtis . Warrington . Ian J. . Apples: Botany, Production, and Uses . 2003 . Centre for Agriculture and Bioscience International . New York . 978-0851995922 . 33–35 . en . 133167834.
  45. Web site: Polomski . Bob . Reighard . Greg . Apple HGIC 1350 . Home & Garden Information Center . . 22 January 2008 . https://web.archive.org/web/20080228131352/http://hgic.clemson.edu/factsheets/HGIC1350.htm . 28 February 2008 . dead.
  46. Barahona . M. . Adaptation of Apple Varieties in Ecuador . Acta Horticulturae . 1992 . 310 . 135–142 . 10.17660/ActaHortic.1992.310.17.
  47. Adamson . Nancy Lee . 2011 . An Assessment of Non-Apis Bees as Fruit and Vegetable Crop Pollinators in Southwest Virginia . Doctor of Philosophy in Entomology . . 15 October 2015 . https://web.archive.org/web/20151120230411/http://www.step-project.net/NPDOCS/Adamson_NL_D_2011.pdf . 20 November 2015 . live .
  48. Book: Powell . L.E. . Proceedings of the Fifth International Symposium on Growth Regulators in Fruit Production: Bologna-Rimini, 2 - 6 September 1985 . 1986 . . Wageningen . 978-90-6605-182-9 . 129–140 . The Chilling Requirement in Apple and Its Role in Regulating Time of Flowering in Spring in Cold-Winter Climate . 10.17660/ActaHortic.1986.179.10.
  49. Web site: Romano . Andrea . 20 Best Places to Go Apple Picking in the United States . Travel + Leisure . 2 August 2024 . https://web.archive.org/web/20240421140207/https://www.travelandleisure.com/trip-ideas/fall-vacations/best-orchards-for-apple-picking . 21 April 2024 . 10 September 2023 . live.
  50. Web site: Graziano . Jack . Farcuh . Macarena . Controlled Atmosphere Storage of Apples . University of Maryland Extension . 2 August 2024 . https://web.archive.org/web/20230324131954/https://extension.umd.edu/resource/controlled-atmosphere-storage-apples . 24 March 2023 . 10 September 2021 . live.
  51. Book: Yepsen, Roger . Apples . W.W. Norton & Co. . 1994 . 978-0-393-03690-9 . New York.
  52. Web site: 25 May 2007 . Refrigerated storage of perishable foods . 26 February 2015 . . dead . https://web.archive.org/web/20150315033439/http://www.csiro.au/en/Research/Health/Food-safety/Refrigerating-foods . 15 March 2015 .
  53. News: Karp . David . 25 October 2006 . Puff the Magic Preservative: Lasting Crunch, but Less Scent . . live . 26 July 2017 . https://web.archive.org/web/20110803082104/http://www.nytimes.com/2006/10/25/dining/25fruit.html . 3 August 2011.
  54. Book: Jackson . H.S. . Lowther . Granville . Worthington . William . The Encyclopedia of Practical Horticulture: A Reference System of Commercial Horticulture, Covering the Practical and Scientific Phases of Horticulture, with Special Reference to Fruits and Vegetables . 1914 . The Encyclopedia of Horticulture Corporation . North Yakima, Washington . 475–476 . https://archive.org/details/CUbiodiversity628875-8748/page/475 . 1 August 2024 . I . Powdery Mildew.
  55. Book: Lowther . Granville . Worthington . William . The Encyclopedia of Practical Horticulture: A Reference System of Commercial Horticulture, Covering the Practical and Scientific Phases of Horticulture, with Special Reference to Fruits and Vegetables . 1914 . The Encyclopedia of Horticulture Corporation . North Yakima, Washington . 45–51 . 1 August 2024 . I .
  56. Book: Coli . William M. . Los . Lorraine M. . 2003 . Insect Pests . https://web.archive.org/web/20070221120428/http://www.umass.edu/fruitadvisor/NEAPMG/28-46.pdf . 2003-2004 New England Apple Pest Management Guide . en . . 28–29 . 3 March 2008 .
  57. Book: Atthowe . Helen . Gilkeson . Linda A. . Kite . L. Patricia . Michalak . Patricia S. . Pleasant . Barbara . Reich . Lee . Scheider . Alfred F. . Bradley . Fern Marshall . Ellis . Bardara W. . Martin . Deborah L. . The Organic Gardener's Handbook of Natural Pest and Disease Control . 2009 . . 978-1-60529-677-7 . 32–34 . en.
  58. Book: Coli . William M. . Berkett . Lorraine P. . Spitko . Robin . 2003 . Other Apple Diseases . https://web.archive.org/web/20070221120311/http://www.umass.edu/fruitadvisor/NEAPMG/19-27.pdf . 2003-2004 New England Apple Pest Management Guide . en . . 19–27 . 3 March 2008 .
  59. Martin . Phillip L. . Krawczyk . Teresa . Khodadadi . Fatemeh . Aćimović . Srđan G. . Peter . Kari A. . 2021 . Bitter Rot of Apple in the Mid-Atlantic United States: Causal Species and Evaluation of the Impacts of Regional Weather Patterns and Cultivar Susceptibility . . 111 . 6 . 966–981 . 10.1094/PHYTO-09-20-0432-R . 0031-949X . 33487025 . 231701083 . free.
  60. Erler . Fedai . 1 January 2010 . Efficacy of tree trunk coating materials in the control of the apple clearwing, Synanthedon myopaeformis . Journal of Insect Science . 10 . 1 . 63 . 10.1673/031.010.6301 . 3014806 . 20672979.
  61. Book: Elzebroek, A.T.G. . Wind, K. . Guide to Cultivated Plants . Centre for Agriculture and Bioscience International . Wallingford . 2008 . 27 . 978-1-84593-356-2 . 6 October 2020 . 20 October 2020 . https://web.archive.org/web/20201020231604/https://books.google.com/books?id=YvU1XnUVxFQC&q=apple%20cultivars%207,500&pg=PT39 . live .
  62. Web site: Home. . 2 December 2012 . live . https://web.archive.org/web/20120615145659/http://www.nationalfruitcollection.org.uk/index.php . 15 June 2012 .
  63. Web site: ECPGR Malus/Pyrus Working Group Members . Ecpgr.cgiar.org . 22 July 2002 . 25 August 2014 . dead . https://web.archive.org/web/20140826114504/http://www.ecpgr.cgiar.org/index.php?id=2501&tx_wfqbe_pi1[uid& . 26 August 2014 .
  64. Web site: Autumn Apple Musings . https://web.archive.org/web/20070811154017/http://casfs.ucsc.edu/publications/news%20and%20notes/Fall_06_N%26N.pdf . dead . 11 August 2007 . 24 January 2008 . 1–2 . Tarjan, Sue . News & Notes of the UCSC Farm & Garden, Center for Agroecology & Sustainable Food Systems . Fall 2006 .
  65. News: Beck . Kellen . How breeders bring out the best in new apples . 31 July 2024 . Mashable . 17 October 2020.
  66. News: Migicovsky . Zoë . How a few good apples spawned today's top varieties — and why breeders must branch out . 31 July 2024 . The Conversation . 22 August 2021.
  67. Peil . A. . Dunemann . F. . Richter . K. . Hoefer . M. . Király . I. . Flachowsky . H. . Hanke . M.-V. . Resistance Breeding in Apple at Dresden-Pillnitz . Ecofruit - 13th International Conference on Cultivation Technique and Phytopathological Problems in Organic Fruit-Growing: Proceedings to the Conference from 18thFebruary to 20th February 2008 at Weinsberg/Germany . 2008 . 220–225 . 31 July 2024 . de.
  68. Web site: Apple – Malus domestica . 22 January 2008 . . https://web.archive.org/web/20080512000735/http://www.plantpress.com/wildlife/o523-apple.php . 12 May 2008.
  69. Web site: World apple situation . 24 January 2008 . https://web.archive.org/web/20080211120700/http://www.fas.usda.gov/htp2/circular/1998/98-03/applefea.html . 11 February 2008 . dead .
  70. Weaver . Sue . June–July 2003 . Crops & Gardening – Apples of Antiquity . Hobby Farms Magazine . live . https://web.archive.org/web/20170219090902/http://www.hobbyfarms.com/apples-of-antiquity-3/ . 19 February 2017 .
  71. Web site: Rieger . Mark . Apple - Malus domestica . HORT 3020: Intro Fruit Crops . 22 January 2008 . . https://web.archive.org/web/20080121045236/http://www.uga.edu/fruit/apple.html . 21 January 2008 . dead.
  72. Web site: 2024 . Apple production in 2022; from pick lists: Crops/World Regions/Production Quantity . 18 June 2024 . FAOSTAT, UN Food and Agriculture Organization, Statistics Division.
  73. Book: Nelson, Lewis S. . Handbook of poisonous and injurious plants . Shih, Richard D. . Balick, Michael J. . . 2007 . 978-0-387-33817-0 . 211–212 . 13 April 2013 . https://web.archive.org/web/20130509140843/http://books.google.com/books?id=-J-YxItyrHEC&pg=PA211 . 9 May 2013 . live.
  74. Web site: Amygdalin . live . https://web.archive.org/web/20170421094516/https://toxnet.nlm.nih.gov/cgi-bin/sis/search/a?dbs+hsdb:@term+@DOCNO+3559 . 21 April 2017 . 20 April 2017 . Toxnet, US Library of Medicine.
  75. Web site: General Information – Apple . https://web.archive.org/web/20120723201454/http://foodallergens.ifr.ac.uk/food.lasso?selected_food=2 . 23 July 2012 . 17 October 2011 . Informall.
  76. Landau, Elizabeth, Oral allergy syndrome may explain mysterious reactions, 8 April 2009, CNN Health, accessed 17 October 2011
  77. Web site: 2018 . Nutrition Facts, Apples, raw, with skin [Includes USDA commodity food A343]. 100 gram amount ]. live . https://web.archive.org/web/20121228030614/http://nutritiondata.self.com/facts/fruits-and-fruit-juices/1809/2 . 28 December 2012 . 11 January 2020 . Nutritiondata.com, Conde Nast from USDA version SR-21.
  78. Web site: 11 March 2020 . How to understand and use the nutrition facts label . live . https://web.archive.org/web/20220107165838/https://www.fda.gov/food/new-nutrition-facts-label/how-understand-and-use-nutrition-facts-label . 7 January 2022 . 9 September 2020 . US Food and Drug Administration.
  79. Book: Traverso . Amy . The Apple Lover's Cookbook . 2011 . . New York . 978-0-393-06599-2 . 16, 32, 35, 45, 92, 137, 262–263, 275 . First .
  80. Web site: Kellogg . Kristi . 15 January 2015 . 81 Best Apple Recipes: Dinners, Desserts, Salads, and More . live . https://web.archive.org/web/20201018215038/https://www.epicurious.com/ingredients/apple-of-my-eye-gallery . 18 October 2020 . 17 October 2020 . Epicurious.
  81. Book: Davidson, Alan . Alan Davidson (food writer) . Toffee apple . Jaine . Tom . . 3rd . Oxford . . 2014 . 978-0-19-967733-7 . 824.
  82. Web site: Shurpin . Yehuda . Why All the Symbolic Rosh Hashanah Foods? "בולבול" . Chabad.org . 21 March 2023 . 21 March 2023 . https://web.archive.org/web/20230321154816/https://www.chabad.org/library/article_cdo/aid/3053586/jewish/Why-All-the-Symbolic-Rosh-Hashanah-Foods.htm . live .
  83. Book: Davidson, Alan . Alan Davidson (food writer) . Apple . Jaine . Tom . . 3rd . Oxford . . 2014 . 978-0-19-967733-7 . 27–31.
  84. Book: Lim, T. K. . Edible Medicinal And Non-Medicinal Plants . 4, Fruits . 2012 . . 978-940074053-2 .
  85. Web site: Organic apples . 23 February 2017 . USDA Agricultural Marketing Service . February 2016 . dead . https://web.archive.org/web/20170224052612/http://www.agmrc.org/commodities-products/fruits/apples/organic-apples/ . 24 February 2017 .
  86. Web site: European Organic Apple Production Demonstrates the Value of Pesticides . December 2011 . CropLife Foundation, Washington, DC . 23 February 2017 . live . https://web.archive.org/web/20170224054210/https://croplife.org/wp-content/uploads/pdf_files/European-Organic-apple-production-demonstrates-the-value-of-pesticides.pdf . 24 February 2017 .
  87. Ribeiro . Flávia A.P. . Gomes de Moura . Carolina F. . Aguiar . Odair . de Oliveira . Flavia . Spadari . Regina C. . Oliveira . Nara R.C. . Oshima . Celina T.F. . Ribeiro . Daniel A. . The chemopreventive activity of apple against carcinogenesis: antioxidant activity and cell cycle control . European Journal of Cancer Prevention . 23 . 5 . 477–480 . September 2014 . 24366437 . 10.1097/CEJ.0000000000000005 . 23026644 . Review.
  88. Nicolas . J. J. . Richard-Forget . F. C. . Goupy . P. M. . Amiot . M. J. . Aubert . S. Y. . 1 January 1994 . Enzymatic browning reactions in apple and apple products . Critical Reviews in Food Science and Nutrition . 34 . 2 . 109–157 . 10.1080/10408399409527653 . 8011143.
  89. Web site: PPO silencing . Okanagan Specialty Fruits . 2019 . 14 November 2019 . live . 27 April 2021 . https://web.archive.org/web/20210427083033/https://www.okspecialtyfruits.com/our-science/ppo-silencing/ .
  90. Web site: United States: GM non-browning Arctic apple expands into foodservice . Fresh Fruit Portal . 14 November 2019 . 13 August 2019 . https://web.archive.org/web/20210627220702/https://www.freshfruitportal.com/news/2019/08/13/u-s-gm-non-browning-arctic-apple-expands-into-foodservice/ . live . 27 June 2021.
  91. Web site: Okanagan Specialty Fruits: Biotechnology Consultation Agency Response Letter BNF 000132 . U.S. Food and Drug Administration . March 20, 2015 . 14 November 2019 . live . 31 October 2017 . https://wayback.archive-it.org/7993/20171031091829/https://www.fda.gov/Food/IngredientsPackagingLabeling/GEPlants/Submissions/ucm436163.htm.
  92. Web site: Questions and answers: Arctic Apple . Canadian Food Inspection Agency, Government of Canada . 14 November 2019. 8 September 2017 . live . 19 September 2018 . https://web.archive.org/web/20180919152434/http://www.inspection.gc.ca/plants/plants-with-novel-traits/general-public/questions-and-answers-arctic-apple/eng/1426884802194/1426884861294.
  93. 10.2202/1556-3758.1283 . Proximate Composition of the Apple Seed and Characterization of Its Oil . 2007 . Yu . Xiuzhu . Van De Voort . Frederick R. . Li . Zhixi . Yue . Tianli . International Journal of Food Engineering . 3 . 5. 98590230 .
  94. Book: Davidson, Hilda Roderick Ellis . Hilda Ellis Davidson . Gods and Myths of Northern Europe . 1990 . . London . 0-14-013627-4 . 165–166.
  95. Book: Davidson, Hilda Ellis . Hilda Ellis Davidson . Roles of the Northern Goddess . 1998 . . London ; New York . 0-415-13610-5 . 146–147.
  96. Book: Sauer . Jonathan D. . Historical Geography of Crop Plants: A Select Roster . 1993 . . Boca Raton . 978-0-8493-8901-6 . 109.
  97. Book: Wasson, R. Gordon . Soma: Divine Mushroom of Immortality . Harcourt Brace Jovanovich . 1968 . 978-0-15-683800-9 . 128 . R. Gordon Wasson.
  98. Book: Ruck . Carl . Carl Ruck . Staples . Blaise Daniel . Blaise Daniel Staples . The Apples of Apollo, Pagan and Christian Mysteries of the Eucharist . . 2001 . 978-0-89089-924-3 . Durham . 64–70.
  99. Book: Hyginus . Fabulae . Theoi Project . Mary Grant . 92 . 7 December 2017 . http://www.theoi.com/Text/HyginusFabulae2.html#92 . https://web.archive.org/web/20130209204358/http://www.theoi.com/Text/HyginusFabulae2.html . 9 February 2013 . live.
  100. Book: Lucian . Dialogues of the Gods . Theoi Project . H. W. Fowler . F. G. Fowler . The Judgement of Paris . 7 December 2017 . http://www.theoi.com/Text/LucianDialoguesGods1.html#0 . https://web.archive.org/web/20170902094738/http://www.theoi.com/Text/LucianDialoguesGods1.html . 2 September 2017 . live.
  101. Book: Edmonds, J.M. . Plato: Complete Works . Indianapolis . . 1997 . 9780872203495 . Cooper . John M. . 1997 . 1744 . Epigrams . 10 September 2020 . Hutchinson . D.S. . https://books.google.com/books?id=Fv9AKY_DBVYC&pg=PR5 . https://web.archive.org/web/20210113180159/https://books.google.com/books?id=Fv9AKY_DBVYC&pg=PR5 . 13 January 2021 . live.
  102. Book: Flieger, Verlyn . Verlyn Flieger . The Otherworld . . . Kent, Ohio . 2005 . 978-0-87338-824-5 . 122–123.
  103. Book: Macrone . Michael . Brush up your Bible! . 1998 . . New York . 978-0-517-20189-3 . 38270894 . 15–16, 340–341 . 31 July 2024.
  104. Book: Kissling, Paul J . Genesis . 2004 . College Press . 978-0-89900875-2 . 1 . 193 . 6 October 2020 . https://web.archive.org/web/20210126053142/https://books.google.com/books?id=lotBnvqdmeQC&q=Genesis+apple&pg=PA193 . 26 January 2021 . live.
  105. Genesis 2:17
  106. Book: Hendel, Ronald . The Book of Genesis: A Biography . 2012 . . 978-0-69114012-4 . 114 . 6 October 2020 . https://web.archive.org/web/20220129224931/https://www.google.com/books/edition/The_Book_of_Genesis/xBPpIHwcZMUC?hl=en&gbpv=1&bsq=Genesis+apple+malum&pg=PA114&printsec=frontcover . 29 January 2022 . live.
  107. Book: Mieder, Wolfgang . A Dictionary of American Proverbs . . 1992 . 978-0-19-505399-9 . 54– . 9 January 2021 . https://web.archive.org/web/20220129224931/https://books.google.com/books?id=AbJ1tVGmiTgC&pg=PR54 . 29 January 2022 . live.
  108. Book: Pollan . Michael . Michael Pollan . The Botany of Desire: A Plant's-Eye View of the World . 2001 . . New York . 978-0-375-50129-6 . 9, 22, 50 . First .