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Autumn leaf color

December 01, 2023

Autumn leaf color is a phenomenon that affects the normally green leaves of many deciduous trees and shrubs by which they take on, during a few weeks in the autumn season, various shades of yellow, orange, red, purple, and brown.[1] The phenomenon is commonly called autumn colours[2] or autumn foliage[3] in British English and fall colors,[4] fall foliage, or simply foliage[5] in American English.

Japanese maple autumn leaves

In some areas of Canada and the United States, "leaf peeping" tourism is a major contribution to economic activity. This tourist activity occurs between the beginning of color changes and the onset of leaf fall, usually around September and October in the Northern Hemisphere and April to May in the Southern Hemisphere.

Chlorophyll and the green/yellow/orange colors edit

 
In this leaf, the veins are still green, while the other tissue is turning red. This produces a fractal-like pattern
 
A North American leaf with multiple colors across it
 
Cross-section of a leaf showing color changes

A green leaf is green because of the presence of a pigment known as chlorophyll, which is inside an organelle called a chloroplast. When abundant in the leaf's cells, as during the growing season, the chlorophyll's green color dominates and masks out the colors of any other pigments that may be present in the leaf. Thus, the leaves of summer are characteristically green.[6]

Chlorophyll has a vital function: it captures solar rays and uses the resulting energy in the manufacture of the plant's food – simple sugars which are produced from water and carbon dioxide. These sugars are the basis of the plant's nourishment – the sole source of the carbohydrates needed for growth and development. In their food-manufacturing process, the chlorophylls break down, thus are continually "used up". During the growing season, however, the plant replenishes the chlorophyll so that the supply remains high and the leaves stay green.

In late summer, with daylight hours shortening and temperatures cooling, the veins that carry fluids into and out of the leaf are gradually closed off as a layer of special cork cells forms at the base of each leaf. As this cork layer develops, water and mineral intake into the leaf is reduced, slowly at first, and then more rapidly. During this time, the amount of chlorophyll in the leaf begins to decrease. Often, the veins are still green after the tissues between them have almost completely changed color.

Chlorophyll is located in the thylakoid membrane of the chloroplast and it is composed of an apoprotein along with several ligands, the most important of which are chlorophylls a and b. In the autumn, this complex is broken down. Chlorophyll degradation is thought to occur first. Research suggests that the beginning of chlorophyll degradation is catalyzed by chlorophyll b reductase, which reduces chlorophyll b to 7‑hydroxymethyl chlorophyll a, which is then reduced to chlorophyll a.[7] This is believed to destabilize the complex, at which point breakdown of the apoprotein occurs. An important enzyme in the breakdown of the apoprotein is FtsH6, which belongs to the FtsH family of proteases.[8]

Chlorophylls degrade into colorless tetrapyrroles known as nonfluorescent chlorophyll catabolites.[9] As the chlorophylls degrade, the hidden pigments of yellow xanthophylls and orange beta-carotene are revealed.

Pigments that contribute to other colors edit

 
Autumn coloration at the Kalevanpuisto park in Pori, Finland.

Carotenoids edit

Carotenoids are present in the leaves throughout the year, but their orange-yellow colors are usually masked by green chlorophyll.[6] As autumn approaches, certain influences both inside and outside the plant cause the chlorophylls to be replaced at a slower rate than they are being used up. During this period, with the total supply of chlorophylls gradually dwindling, the "masking" effect slowly fades away. Then other pigments present (along with the chlorophylls) in the leaf's cells begin to show through.[6] These are carotenoids and they provide colorations of yellow, brown, orange, and the many hues in between.

The carotenoids occur, along with the chlorophyll pigments, in tiny structures called plastids, within the cells of leaves. Sometimes, they are in such abundance in the leaf that they give a plant a yellow-green color, even during the summer. Usually, however, they become prominent for the first time in autumn, when the leaves begin to lose their chlorophyll.

Carotenoids are common in many living things, giving characteristic color to carrots, corn, canaries, and daffodils, as well as egg yolks, rutabagas, buttercups, and bananas.

Their brilliant yellows and oranges tint the leaves of such hardwood species as hickories, ash, maple, yellow poplar, aspen, birch, black cherry, sycamore, cottonwood, sassafras, and alder. Carotenoids are the dominant pigment in coloration of about 15–30% of tree species.[6]

Anthocyanins edit

Main article: Anthocyanin

The reds, the purples, and their blended combinations that decorate autumn foliage come from another group of pigments in the cells called anthocyanins. Unlike the carotenoids, these pigments are not present in the leaf throughout the growing season, but are actively produced towards the end of summer.[6] They develop in late summer in the sap of the cells of the leaf, and this development is the result of complex interactions of many influences both inside and outside the plant. Their formation depends on the breakdown of sugars in the presence of bright light as the level of phosphate in the leaf is reduced.[10]

 
Autumn foliage at Blue Mountains, Australia in April 2022

During the summer growing season, phosphate is at a high level. It has a vital role in the breakdown of the sugars manufactured by chlorophyll, but in autumn, phosphate, along with the other chemicals and nutrients, moves out of the leaf into the stem of the plant. When this happens, the sugar-breakdown process changes, leading to the production of anthocyanin pigments. The brighter the light during this period, the greater the production of anthocyanins and the more brilliant the resulting color display. When the days of autumn are bright and cool, and the nights are chilly but not freezing, the brightest colorations usually develop.

Anthocyanins temporarily color the edges of some of the very young leaves as they unfold from the buds in early spring. They also give the familiar color to such common fruits as cranberries, red apples, blueberries, cherries, strawberries, and plums.

Anthocyanins are present in about 10% of tree species in temperate regions, although in certain areas – most famously northern New England – up to 70% of tree species may produce the pigment.[6] In autumn forests, they appear vivid in the maples, oaks, sourwood, sweetgums, dogwoods, tupelos, cherry trees, and persimmons. These same pigments often combine with the carotenoids' colors to create the deeper orange, fiery reds, and bronzes typical of many hardwood species.

Function of autumn colors edit

Deciduous plants were traditionally believed to shed their leaves in autumn primarily because the high costs involved in their maintenance would outweigh the benefits from photosynthesis during the winter period of low light availability and cold temperatures.[11] In many cases, this turned out to be oversimplistic – other factors involved include insect predation,[12] water loss, and damage from high winds or snowfall.

Anthocyanins, responsible for red-purple coloration, are actively produced in autumn, but not involved in leaf-drop. A number of hypotheses on the role of pigment production in leaf-drop have been proposed, and generally fall into two categories: interaction with animals, and protection from nonbiological factors.[6]

Photoprotection edit

According to the photoprotection theory, anthocyanins protect the leaf against the harmful effects of light at low temperatures.[13][14] The leaves are about to fall, so protection is not of extreme importance for the tree. Photo-oxidation and photoinhibition, however, especially at low temperatures, make the process of reabsorbing nutrients less efficient. By shielding the leaf with anthocyanins, according to photoprotection theory, the tree manages to reabsorb nutrients (especially nitrogen) more efficiently.

Coevolution edit

 
Fall foliage peak times in the United States

According to the coevolution theory,[15] the colors are warning signals to insects like aphids that use trees as a host for the winter. If the colors are linked to the amount of chemical defenses against insects, then the insects will avoid red leaves and increase their fitness; at the same time, trees with red leaves have an advantage because they reduce their parasite load. This has been shown in the case of apple trees where some domesticated apple varieties, unlike wild ones, lack red leaves in the autumn. A greater proportion of aphids that avoid apple trees with red leaves manage to grow and develop compared to those that do not.[16] A trade-off, moreover, exists between fruit size, leaf color, and aphids resistance as varieties with red leaves have smaller fruits, suggesting a cost to the production of red leaves linked to a greater need for reduced aphid infestation.[16]

Consistent with red-leaved trees providing reduced survival for aphids, tree species with bright leaves tend to select for more specialist aphid pests than do trees lacking bright leaves (autumn colors are useful only in those species coevolving with insect pests in autumn).[17] One study found that simulating insect herbivory (leaf-eating damage) on maple trees showed earlier red coloration than trees that were not damaged.[18]

The coevolution theory of autumn colors was proposed by W. D. Hamilton in 2001 as an example of evolutionary signalling theory.[17][a] With biological signals such as red leaves, it is argued that because they are costly to produce, they are usually honest, so signal the true quality of the signaller with low-quality individuals being unable to fake them and cheat. Autumn colors would be a signal if they were costly to produce, or be impossible to fake (for example if autumn pigments were produced by the same biochemical pathway that produces the chemical defenses against the insects).[citation needed]

The change of leaf colors prior to fall have also been suggested as adaptations that may help to undermine the camouflage of herbivores.[19]

See also: Deciduous and Plant defense against herbivory

Many plants with berries attract birds with especially visible berry and/or leaf color, particularly bright red. The birds get a meal, while the shrub, vine, or typically small tree gets undigested seeds carried off and deposited with the birds' manure. Poison ivy is particularly notable for having bright-red foliage drawing birds to its off-white seeds (which are edible for birds, but not most mammals).

Allelopathy edit

The brilliant red autumn color of some species of maple is created by processes separate from those in chlorophyll breakdown. When the tree is struggling to cope with the energy demands of a changing and challenging season, maple trees are involved in an additional metabolic expenditure to create anthocyanins. These anthocyanins, which create the visual red hues, have been found to aid in interspecific competition by stunting the growth of nearby saplings (allelopathy).[20]

Tourism edit

See also: Leaf peeping
 
Autumn in Canberra, Australia

Although some autumn coloration occurs wherever deciduous trees are found, the most brightly colored autumn foliage is found in the northern hemisphere, including most of southern mainland Canada, some areas of the northern United States, Northern and Western Europe north of the Alps, the Caucasus region of Russia near the Black Sea, and Eastern Asia (including much of northern and eastern China, and as well as Korea and Japan).[21][22]

 
Harvard Yard showing Autumn leaf color

In the southern hemisphere, colorful autumn foliage can be observed in southern and central Argentina, the south and southeast regions of Brazil, eastern and southeastern Australia (including South Australia and Tasmania) and most of New Zealand, particularly the South Island.[23]

Climate influences edit

Compared to Western Europe (excluding Southern Europe), North America provides many more tree species (more than 800 species and about 70 oaks, compared to 51 and three, respectively, in Western Europe)[24] which adds many more different colors to the spectacle. The main reason is the different effect of the Ice ages – while in North America, species were protected in more southern regions along north–south ranging mountains, this was not the case in much of Europe.[25]

Global warming and rising carbon dioxide levels in the atmosphere may delay the usual autumn spectacle of changing colors and falling leaves in northern hardwood forests in the future, and increase forest productivity.[26] Specifically, higher autumn temperatures in the Northeastern United States is delaying the color change.[27] Experiments with poplar trees showed that they stayed greener longer with higher CO2 levels, independent of temperature changes.[26] However, the experiments over two years were too brief to indicate how mature forests may be affected over time. Other studies using 150 years of herbarium specimens found more than a one-month delay in the onset of autumn since the 19th century, and found that insect, viral, and drought stress can also affect the timing of fall coloration in maple trees.[27][28] Also, other factors, such as increasing ozone levels close to the ground (tropospheric ozone pollution), can negate the beneficial effects of elevated carbon dioxide.[29]

References edit

  This article incorporates public domain material from the USDA Forest Service.

  1. ^ . usna.usda.gov. United States National Arboretum. October 6, 2011. Archived from the original on January 11, 2018. Retrieved June 18, 2015.
  2. ^ Wade, Paul; Arnold, Kathy (September 16, 2014). "New England in the Fall: Trip of a Lifetime - Telegraph". telegraph.co.uk. The Daily Telegraph. Retrieved June 18, 2015.
  3. ^ "BBC - Gardening - How to be a gardener - The gardening year - Autumn's theme". bbc.co.uk. BBC. September 17, 2014. Retrieved June 18, 2015.
  4. ^ "US Forest Service - Caring for the land and serving people". fs.fed.us. United States Forest Service. 2014. Retrieved June 18, 2015.
  5. ^ "MaineFoliage.com - Maine's Official Fall Foliage Website". MaineFoliage.com. 2013. Retrieved June 18, 2015.
  6. ^ a b c d e f g Archetti, Marco; Döring, Thomas F.; Hagen, Snorre B.; Hughes, Nicole M.; Leather, Simon R.; Lee, David W.; Lev-Yadun, Simcha; Manetas, Yiannis; Ougham, Helen J. (2011). "Unravelling the evolution of autumn colours: an interdisciplinary approach". Trends in Ecology & Evolution. 24 (3): 166–73. doi:10.1016/j.tree.2008.10.006. PMID 19178979.
  7. ^ Horie, Y.; Ito, H.; Kusaba, M.; Tanaka, R.; Tanaka, A. (2009). "Participation of Chlorophyll b Reductase in the Initial Step of the Degradation of Light-harvesting Chlorophyll a/b-Protein Complexes in Arabidopsis". Journal of Biological Chemistry. 284 (26): 17449–56. doi:10.1074/jbc.M109.008912. PMC 2719385. PMID 19403948.
  8. ^ Zelisko, A.; Garcia-Lorenzo, M.; Jackowski, G.; Jansson, S.; Funk, C. (2005). "AtFtsH6 is involved in the degradation of the light-harvesting complex II during high-light acclimation and senescence". Proceedings of the National Academy of Sciences. 102 (38): 13699–704. Bibcode:2005PNAS..10213699Z. doi:10.1073/pnas.0503472102. PMC 1224624. PMID 16157880.
  9. ^ Hortensteiner, S. (2006). "Chlorophyll degradation during senescence". Annual Review of Plant Biology. 57: 55–77. doi:10.1146/annurev.arplant.57.032905.105212. PMID 16669755.
  10. ^ Davies, Kevin M. (2004). Plant pigments and their manipulation. Wiley-Blackwell. p. 6. ISBN 978-1-4051-1737-1.
  11. ^ Thomas, H; Stoddart, J L (1980). "Leaf Senescence". Annual Review of Plant Physiology. 31: 83–111. doi:10.1146/annurev.pp.31.060180.000503.
  12. ^ Labandeira, C. C.; Dilcher, DL; Davis, DR; Wagner, DL (1994). "Ninety-seven million years of angiosperm-insect association: paleobiological insights into the meaning of coevolution". Proceedings of the National Academy of Sciences. 91 (25): 12278–82. Bibcode:1994PNAS...9112278L. doi:10.1073/pnas.91.25.12278. PMC 45420. PMID 11607501.
  13. ^ Lee, David; Gould, Kevin (2002). "Why Leaves Turn Red". American Scientist. 90 (6): 524–531. Bibcode:2002AmSci..90..524L. doi:10.1511/2002.6.524. S2CID 209833569.
  14. ^ Lee, D; Gould, K (2002). "Anthocyanins in leaves and other vegetative organs: An introduction". Advances in Botanical Research. 37: 1–16. doi:10.1016/S0065-2296(02)37040-X. ISBN 978-0-12-005937-9.
  15. ^ Archetti, M; Brown, S. P. (June 2004). "The coevolution theory of autumn colours". Proc. Biol. Sci. 271 (1545): 1219–23. doi:10.1098/rspb.2004.2728. PMC 1691721. PMID 15306345.
  16. ^ a b Archetti, M. (2009). "Evidence from the domestication of apple for the maintenance of autumn colours by coevolution". Proceedings of the Royal Society B: Biological Sciences. 276 (1667): 2575–80. doi:10.1098/rspb.2009.0355. PMC 2684696. PMID 19369261.
  17. ^ a b Hamilton, W. D.; Brown, S. P. (2001). "Autumn tree colours as a handicap signal". Proceedings of the Royal Society B: Biological Sciences. 268 (1475): 1489–93. doi:10.1098/rspb.2001.1672. PMC 1088768. PMID 11454293.
  18. ^ Forkner, Rebecca E. (May 1, 2014). "Simulated herbivory advances autumn phenology in Acer rubrum". International Journal of Biometeorology. 58 (4): 499–507. Bibcode:2014IJBm...58..499F. doi:10.1007/s00484-013-0701-8. PMID 23832182. S2CID 24879283.
  19. ^ Lev-Yadun, Simcha; Dafni, Amots; Flaishman, Moshe A.; Inbar, Moshe; Izhaki, Ido; Katzir, Gadi; Ne'eman, Gidi (2004). "Plant coloration undermines herbivorous insect camouflage". BioEssays. 26 (10): 1126–30. doi:10.1002/bies.20112. PMID 15382135.
  20. ^ (Frey & Eldridge, 2005)[citation needed]
  21. ^ . South Dakota State University. August 30, 1998. Archived from the original on October 20, 2006. Retrieved November 28, 2006.
  22. ^ Altman, Daniel (November 8, 2006). "Fall foliage sets Japan ablaze". Taipei Times. Retrieved November 28, 2006.
  23. ^ Hutchinson, Carrie (March 2, 2019). "The 5 Best Places in Australia to See Autumn Colours". Qantas. Retrieved July 22, 2019.
  24. ^ Heinz Ellenberg, H. Ellenberg: Vegetation Mitteleuropas mit den Alpen: In ökologischer, dynamischer und historischer Sicht, UTB, Stuttgart; 5th edition, in German, ISBN 3-8252-8104-3, 1996[page needed]
  25. ^ (in German). University of Hamburg Biology Server. Archived from the original on October 6, 2014. Retrieved July 29, 2020.
  26. ^ a b Taylor, Gail; Tallis, Matthew J.; Giardina, Christian P.; Percy, Kevin E.; Miglietta, Franco; Gupta, Pooja S.; Gioli, Beniamino; Calfapietra, Carlo; Gielen, Birgit (2007). "Future atmospheric CO2 leads to delayed autumnal senescence". Global Change Biology. 14 (2): 264–75. Bibcode:2008GCBio..14..264T. CiteSeerX 10.1.1.384.1142. doi:10.1111/j.1365-2486.2007.01473.x. S2CID 86176515.
  27. ^ a b Gibbens, Sarah (November 24, 2021). . Environment. National Geographic. Archived from the original on November 24, 2021.
  28. ^ Garretson, Alexis; Forkner, Rebecca E. (2021). "Herbaria Reveal Herbivory and Pathogen Increases and Shifts in Senescence for Northeastern United States Maples Over 150 Years". Frontiers in Forests and Global Change. 4: 185. Bibcode:2021FrFGC...4.4763G. doi:10.3389/ffgc.2021.664763.
  29. ^ "Forests Could Benefit When Fall Color Comes Late". Newswise. Retrieved August 17, 2008.

Notes edit

  1. ^ Hamilton died in 2000. The paper was submitted by coauthor S.P. Brown in December of the same year and published in 2001.

Further reading edit

  • Guy, Robert D.; Krakowski, Jodie (2003). (PDF). Davidsonia. 14 (4): 111–20. Archived from the original (PDF) on October 19, 2013. Retrieved May 18, 2007.

External links edit

 
Wikimedia Commons has media related to Leaves in autumn.
  • Autumnal tints by Henry David Thoreau
  • Identifying Common trees in Autumn by their colors
  • Sanderson, Katharine (2007). "Why autumn leaves turn red". Nature. doi:10.1038/news.2007.202.

December 01, 2023
autumn, leaf, color, phenomenon, that, affects, normally, green, leaves, many, deciduous, trees, shrubs, which, they, take, during, weeks, autumn, season, various, shades, yellow, orange, purple, brown, phenomenon, commonly, called, autumn, colours, autumn, fo. Autumn leaf color is a phenomenon that affects the normally green leaves of many deciduous trees and shrubs by which they take on during a few weeks in the autumn season various shades of yellow orange red purple and brown 1 The phenomenon is commonly called autumn colours 2 or autumn foliage 3 in British English and fall colors 4 fall foliage or simply foliage 5 in American English Japanese maple autumn leavesIn some areas of Canada and the United States leaf peeping tourism is a major contribution to economic activity This tourist activity occurs between the beginning of color changes and the onset of leaf fall usually around September and October in the Northern Hemisphere and April to May in the Southern Hemisphere Contents 1 Chlorophyll and the green yellow orange colors 2 Pigments that contribute to other colors 2 1 Carotenoids 2 2 Anthocyanins 3 Function of autumn colors 3 1 Photoprotection 3 2 Coevolution 3 3 Allelopathy 4 Tourism 5 Climate influences 6 References 7 Notes 8 Further reading 9 External linksChlorophyll and the green yellow orange colors edit nbsp In this leaf the veins are still green while the other tissue is turning red This produces a fractal like pattern nbsp A North American leaf with multiple colors across it nbsp Cross section of a leaf showing color changes A green leaf is green because of the presence of a pigment known as chlorophyll which is inside an organelle called a chloroplast When abundant in the leaf s cells as during the growing season the chlorophyll s green color dominates and masks out the colors of any other pigments that may be present in the leaf Thus the leaves of summer are characteristically green 6 Chlorophyll has a vital function it captures solar rays and uses the resulting energy in the manufacture of the plant s food simple sugars which are produced from water and carbon dioxide These sugars are the basis of the plant s nourishment the sole source of the carbohydrates needed for growth and development In their food manufacturing process the chlorophylls break down thus are continually used up During the growing season however the plant replenishes the chlorophyll so that the supply remains high and the leaves stay green In late summer with daylight hours shortening and temperatures cooling the veins that carry fluids into and out of the leaf are gradually closed off as a layer of special cork cells forms at the base of each leaf As this cork layer develops water and mineral intake into the leaf is reduced slowly at first and then more rapidly During this time the amount of chlorophyll in the leaf begins to decrease Often the veins are still green after the tissues between them have almost completely changed color Chlorophyll is located in the thylakoid membrane of the chloroplast and it is composed of an apoprotein along with several ligands the most important of which are chlorophylls a and b In the autumn this complex is broken down Chlorophyll degradation is thought to occur first Research suggests that the beginning of chlorophyll degradation is catalyzed by chlorophyll b reductase which reduces chlorophyll b to 7 hydroxymethyl chlorophyll a which is then reduced to chlorophyll a 7 This is believed to destabilize the complex at which point breakdown of the apoprotein occurs An important enzyme in the breakdown of the apoprotein is FtsH6 which belongs to the FtsH family of proteases 8 Chlorophylls degrade into colorless tetrapyrroles known as nonfluorescent chlorophyll catabolites 9 As the chlorophylls degrade the hidden pigments of yellow xanthophylls and orange beta carotene are revealed Pigments that contribute to other colors edit nbsp Autumn coloration at the Kalevanpuisto park in Pori Finland Carotenoids edit Carotenoids are present in the leaves throughout the year but their orange yellow colors are usually masked by green chlorophyll 6 As autumn approaches certain influences both inside and outside the plant cause the chlorophylls to be replaced at a slower rate than they are being used up During this period with the total supply of chlorophylls gradually dwindling the masking effect slowly fades away Then other pigments present along with the chlorophylls in the leaf s cells begin to show through 6 These are carotenoids and they provide colorations of yellow brown orange and the many hues in between The carotenoids occur along with the chlorophyll pigments in tiny structures called plastids within the cells of leaves Sometimes they are in such abundance in the leaf that they give a plant a yellow green color even during the summer Usually however they become prominent for the first time in autumn when the leaves begin to lose their chlorophyll Carotenoids are common in many living things giving characteristic color to carrots corn canaries and daffodils as well as egg yolks rutabagas buttercups and bananas Their brilliant yellows and oranges tint the leaves of such hardwood species as hickories ash maple yellow poplar aspen birch black cherry sycamore cottonwood sassafras and alder Carotenoids are the dominant pigment in coloration of about 15 30 of tree species 6 Anthocyanins edit Main article Anthocyanin The reds the purples and their blended combinations that decorate autumn foliage come from another group of pigments in the cells called anthocyanins Unlike the carotenoids these pigments are not present in the leaf throughout the growing season but are actively produced towards the end of summer 6 They develop in late summer in the sap of the cells of the leaf and this development is the result of complex interactions of many influences both inside and outside the plant Their formation depends on the breakdown of sugars in the presence of bright light as the level of phosphate in the leaf is reduced 10 nbsp Autumn foliage at Blue Mountains Australia in April 2022During the summer growing season phosphate is at a high level It has a vital role in the breakdown of the sugars manufactured by chlorophyll but in autumn phosphate along with the other chemicals and nutrients moves out of the leaf into the stem of the plant When this happens the sugar breakdown process changes leading to the production of anthocyanin pigments The brighter the light during this period the greater the production of anthocyanins and the more brilliant the resulting color display When the days of autumn are bright and cool and the nights are chilly but not freezing the brightest colorations usually develop Anthocyanins temporarily color the edges of some of the very young leaves as they unfold from the buds in early spring They also give the familiar color to such common fruits as cranberries red apples blueberries cherries strawberries and plums Anthocyanins are present in about 10 of tree species in temperate regions although in certain areas most famously northern New England up to 70 of tree species may produce the pigment 6 In autumn forests they appear vivid in the maples oaks sourwood sweetgums dogwoods tupelos cherry trees and persimmons These same pigments often combine with the carotenoids colors to create the deeper orange fiery reds and bronzes typical of many hardwood species Function of autumn colors editDeciduous plants were traditionally believed to shed their leaves in autumn primarily because the high costs involved in their maintenance would outweigh the benefits from photosynthesis during the winter period of low light availability and cold temperatures 11 In many cases this turned out to be oversimplistic other factors involved include insect predation 12 water loss and damage from high winds or snowfall Anthocyanins responsible for red purple coloration are actively produced in autumn but not involved in leaf drop A number of hypotheses on the role of pigment production in leaf drop have been proposed and generally fall into two categories interaction with animals and protection from nonbiological factors 6 Photoprotection edit According to the photoprotection theory anthocyanins protect the leaf against the harmful effects of light at low temperatures 13 14 The leaves are about to fall so protection is not of extreme importance for the tree Photo oxidation and photoinhibition however especially at low temperatures make the process of reabsorbing nutrients less efficient By shielding the leaf with anthocyanins according to photoprotection theory the tree manages to reabsorb nutrients especially nitrogen more efficiently Coevolution edit nbsp Fall foliage peak times in the United StatesAccording to the coevolution theory 15 the colors are warning signals to insects like aphids that use trees as a host for the winter If the colors are linked to the amount of chemical defenses against insects then the insects will avoid red leaves and increase their fitness at the same time trees with red leaves have an advantage because they reduce their parasite load This has been shown in the case of apple trees where some domesticated apple varieties unlike wild ones lack red leaves in the autumn A greater proportion of aphids that avoid apple trees with red leaves manage to grow and develop compared to those that do not 16 A trade off moreover exists between fruit size leaf color and aphids resistance as varieties with red leaves have smaller fruits suggesting a cost to the production of red leaves linked to a greater need for reduced aphid infestation 16 Consistent with red leaved trees providing reduced survival for aphids tree species with bright leaves tend to select for more specialist aphid pests than do trees lacking bright leaves autumn colors are useful only in those species coevolving with insect pests in autumn 17 One study found that simulating insect herbivory leaf eating damage on maple trees showed earlier red coloration than trees that were not damaged 18 The coevolution theory of autumn colors was proposed by W D Hamilton in 2001 as an example of evolutionary signalling theory 17 a With biological signals such as red leaves it is argued that because they are costly to produce they are usually honest so signal the true quality of the signaller with low quality individuals being unable to fake them and cheat Autumn colors would be a signal if they were costly to produce or be impossible to fake for example if autumn pigments were produced by the same biochemical pathway that produces the chemical defenses against the insects citation needed The change of leaf colors prior to fall have also been suggested as adaptations that may help to undermine the camouflage of herbivores 19 See also Deciduous and Plant defense against herbivory Many plants with berries attract birds with especially visible berry and or leaf color particularly bright red The birds get a meal while the shrub vine or typically small tree gets undigested seeds carried off and deposited with the birds manure Poison ivy is particularly notable for having bright red foliage drawing birds to its off white seeds which are edible for birds but not most mammals Allelopathy edit The brilliant red autumn color of some species of maple is created by processes separate from those in chlorophyll breakdown When the tree is struggling to cope with the energy demands of a changing and challenging season maple trees are involved in an additional metabolic expenditure to create anthocyanins These anthocyanins which create the visual red hues have been found to aid in interspecific competition by stunting the growth of nearby saplings allelopathy 20 Tourism editSee also Leaf peeping nbsp Autumn in Canberra AustraliaAlthough some autumn coloration occurs wherever deciduous trees are found the most brightly colored autumn foliage is found in the northern hemisphere including most of southern mainland Canada some areas of the northern United States Northern and Western Europe north of the Alps the Caucasus region of Russia near the Black Sea and Eastern Asia including much of northern and eastern China and as well as Korea and Japan 21 22 nbsp Harvard Yard showing Autumn leaf colorIn the southern hemisphere colorful autumn foliage can be observed in southern and central Argentina the south and southeast regions of Brazil eastern and southeastern Australia including South Australia and Tasmania and most of New Zealand particularly the South Island 23 Climate influences editCompared to Western Europe excluding Southern Europe North America provides many more tree species more than 800 species and about 70 oaks compared to 51 and three respectively in Western Europe 24 which adds many more different colors to the spectacle The main reason is the different effect of the Ice ages while in North America species were protected in more southern regions along north south ranging mountains this was not the case in much of Europe 25 Global warming and rising carbon dioxide levels in the atmosphere may delay the usual autumn spectacle of changing colors and falling leaves in northern hardwood forests in the future and increase forest productivity 26 Specifically higher autumn temperatures in the Northeastern United States is delaying the color change 27 Experiments with poplar trees showed that they stayed greener longer with higher CO2 levels independent of temperature changes 26 However the experiments over two years were too brief to indicate how mature forests may be affected over time Other studies using 150 years of herbarium specimens found more than a one month delay in the onset of autumn since the 19th century and found that insect viral and drought stress can also affect the timing of fall coloration in maple trees 27 28 Also other factors such as increasing ozone levels close to the ground tropospheric ozone pollution can negate the beneficial effects of elevated carbon dioxide 29 nbsp Typical fall foliage in red maple country in the Adirondack Mountains of Upstate New York nbsp English country lane in the autumn nbsp Autumn leaf color and Mount Fuji with snow seen from Lake Kawaguchi Japan nbsp Autumn in Arrowtown New Zealand nbsp Autumn coloration at Karasawa of the Hodaka Mountains in Japan nbsp Autumn orange colors in Heinola Finland in October 2018 nbsp The town of Stirling South Australia located in the Adelaide Hills attracts many tourists during autumn nbsp A variety of colors around Tōfuku ji temple in Kyoto Japan nbsp Some trees such as this American sweetgum at Keokea Maui develop bold fall colors in subtropical or tropical areas nbsp Webster s Falls Ontario CanadaReferences edit nbsp This article incorporates public domain material from the USDA Forest Service The Science of Color in Autumn Leaves usna usda gov United States National Arboretum October 6 2011 Archived from the original on January 11 2018 Retrieved June 18 2015 Wade Paul Arnold Kathy September 16 2014 New England in the Fall Trip of a Lifetime Telegraph telegraph co uk The Daily Telegraph Retrieved June 18 2015 BBC Gardening How to be a gardener The gardening year Autumn s theme bbc co uk BBC September 17 2014 Retrieved June 18 2015 US Forest Service Caring for the land and serving people fs fed us United States Forest Service 2014 Retrieved June 18 2015 MaineFoliage com Maine s Official Fall Foliage Website MaineFoliage com 2013 Retrieved June 18 2015 a b c d e f g Archetti Marco Doring Thomas F Hagen Snorre B Hughes Nicole M Leather Simon R Lee David W Lev Yadun Simcha Manetas Yiannis Ougham Helen J 2011 Unravelling the evolution of autumn colours an interdisciplinary approach Trends in Ecology amp Evolution 24 3 166 73 doi 10 1016 j tree 2008 10 006 PMID 19178979 Horie Y Ito H Kusaba M Tanaka R Tanaka A 2009 Participation of Chlorophyll b Reductase in the Initial Step of the Degradation of Light harvesting Chlorophyll a b Protein Complexes in Arabidopsis Journal of Biological Chemistry 284 26 17449 56 doi 10 1074 jbc M109 008912 PMC 2719385 PMID 19403948 Zelisko A Garcia Lorenzo M Jackowski G Jansson S Funk C 2005 AtFtsH6 is involved in the degradation of the light harvesting complex II during high light acclimation and senescence Proceedings of the National Academy of Sciences 102 38 13699 704 Bibcode 2005PNAS 10213699Z doi 10 1073 pnas 0503472102 PMC 1224624 PMID 16157880 Hortensteiner S 2006 Chlorophyll degradation during senescence Annual Review of Plant Biology 57 55 77 doi 10 1146 annurev arplant 57 032905 105212 PMID 16669755 Davies Kevin M 2004 Plant pigments and their manipulation Wiley Blackwell p 6 ISBN 978 1 4051 1737 1 Thomas H Stoddart J L 1980 Leaf Senescence Annual Review of Plant Physiology 31 83 111 doi 10 1146 annurev pp 31 060180 000503 Labandeira C C Dilcher DL Davis DR Wagner DL 1994 Ninety seven million years of angiosperm insect association paleobiological insights into the meaning of coevolution Proceedings of the National Academy of Sciences 91 25 12278 82 Bibcode 1994PNAS 9112278L doi 10 1073 pnas 91 25 12278 PMC 45420 PMID 11607501 Lee David Gould Kevin 2002 Why Leaves Turn Red American Scientist 90 6 524 531 Bibcode 2002AmSci 90 524L doi 10 1511 2002 6 524 S2CID 209833569 Lee D Gould K 2002 Anthocyanins in leaves and other vegetative organs An introduction Advances in Botanical Research 37 1 16 doi 10 1016 S0065 2296 02 37040 X ISBN 978 0 12 005937 9 Archetti M Brown S P June 2004 The coevolution theory of autumn colours Proc Biol Sci 271 1545 1219 23 doi 10 1098 rspb 2004 2728 PMC 1691721 PMID 15306345 a b Archetti M 2009 Evidence from the domestication of apple for the maintenance of autumn colours by coevolution Proceedings of the Royal Society B Biological Sciences 276 1667 2575 80 doi 10 1098 rspb 2009 0355 PMC 2684696 PMID 19369261 a b Hamilton W D Brown S P 2001 Autumn tree colours as a handicap signal Proceedings of the Royal Society B Biological Sciences 268 1475 1489 93 doi 10 1098 rspb 2001 1672 PMC 1088768 PMID 11454293 Forkner Rebecca E May 1 2014 Simulated herbivory advances autumn phenology in Acer rubrum International Journal of Biometeorology 58 4 499 507 Bibcode 2014IJBm 58 499F doi 10 1007 s00484 013 0701 8 PMID 23832182 S2CID 24879283 Lev Yadun Simcha Dafni Amots Flaishman Moshe A Inbar Moshe Izhaki Ido Katzir Gadi Ne eman Gidi 2004 Plant coloration undermines herbivorous insect camouflage BioEssays 26 10 1126 30 doi 10 1002 bies 20112 PMID 15382135 Frey amp Eldridge 2005 citation needed Pest Alert South Dakota State University August 30 1998 Archived from the original on October 20 2006 Retrieved November 28 2006 Altman Daniel November 8 2006 Fall foliage sets Japan ablaze Taipei Times Retrieved November 28 2006 Hutchinson Carrie March 2 2019 The 5 Best Places in Australia to See Autumn Colours Qantas Retrieved July 22 2019 Heinz Ellenberg H Ellenberg Vegetation Mitteleuropas mit den Alpen In okologischer dynamischer und historischer Sicht UTB Stuttgart 5th edition in German ISBN 3 8252 8104 3 1996 page needed Botanik online Pflanzengesellschaften Sommergrune Laub und Mischlaubwalder in German University of Hamburg Biology Server Archived from the original on October 6 2014 Retrieved July 29 2020 a b Taylor Gail Tallis Matthew J Giardina Christian P Percy Kevin E Miglietta Franco Gupta Pooja S Gioli Beniamino Calfapietra Carlo Gielen Birgit 2007 Future atmospheric CO2 leads to delayed autumnal senescence Global Change Biology 14 2 264 75 Bibcode 2008GCBio 14 264T CiteSeerX 10 1 1 384 1142 doi 10 1111 j 1365 2486 2007 01473 x S2CID 86176515 a b Gibbens Sarah November 24 2021 Fall foliage was disrupted by climate change It might be the new normal Environment National Geographic Archived from the original on November 24 2021 Garretson Alexis Forkner Rebecca E 2021 Herbaria Reveal Herbivory and Pathogen Increases and Shifts in Senescence for Northeastern United States Maples Over 150 Years Frontiers in Forests and Global Change 4 185 Bibcode 2021FrFGC 4 4763G doi 10 3389 ffgc 2021 664763 Forests Could Benefit When Fall Color Comes Late Newswise Retrieved August 17 2008 Notes edit Hamilton died in 2000 The paper was submitted by coauthor S P Brown in December of the same year and published in 2001 Further reading editGuy Robert D Krakowski Jodie 2003 Autumn Colours Nature s Canvas is a Silk Parasol PDF Davidsonia 14 4 111 20 Archived from the original PDF on October 19 2013 Retrieved May 18 2007 External links edit nbsp Wikimedia Commons has media related to Leaves in autumn Autumnal tints by Henry David Thoreau Identifying Common trees in Autumn by their colors Sanderson Katharine 2007 Why autumn leaves turn red Nature doi 10 1038 news 2007 202 Retrieved from https en wikipedia org w index php title Autumn leaf color amp oldid 1186565297, wikipedia, wiki, book, books, library,

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