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'''Биљни хормон''' ('''фитохормон''') је природно (ендогено) или вештачки синтетисано [[хемијско једињење|једињење]] које има изражен [[физиологија|физиолошки]] ефекат на [[биљке]]. Код биљака не постоје специјално диференцирани [[Орган (анатомија)|орган]]и за синтезу хормона, већ се они синтетишу у појединачним, локализованим или дифузно распоређеним [[ћелија (биологија)|ћелијама]]. Најчешће се синтетишу врло мале количине хормона, али оне имају велики ефекат на процесе [[метаболизам|метаболизма]], [[раст]]а, [[диференцијација|диференцијације]] и [[сенесценција|сенесценције]] (старења) биљака.
[[File:Auxin.jpg|thumb|250п|Lack of the plant hormone [[auxin]] can cause abnormal growth (right)|150px|right]]


'''Биљни хормон''' ('''фитохормон''') је природно (ендогено) или вештачки синтетисано [[хемијско једињење|једињење]] које има изражен [[физиологија|физиолошки]] ефекат на [[биљке]]. Код биљака не постоје специјално диференцирани [[Орган (анатомија)|орган]]и за синтезу хормона, већ се они синтетишу у појединачним, локализованим или дифузно распоређеним [[ћелија (биологија)|ћелијама]]. Најчешће се синтетишу врло мале количине хормона, али оне имају велики ефекат на процесе [[метаболизам|метаболизма]],<ref>{{cite journal | vauthors = Méndez-Hernández HA, Ledezma-Rodríguez M, Avilez-Montalvo RN, Juárez-Gómez YL, Skeete A, Avilez-Montalvo J, De-la-Peña C, Loyola-Vargas VM | display-authors = 6 | title = Signaling Overview of Plant Somatic Embryogenesis | journal = Frontiers in Plant Science | volume = 10 | pages = 77 | date = 2019 | pmid = 30792725 | pmc = 6375091 | doi = 10.3389/fpls.2019.00077 | doi-access = free }}</ref> [[раст]]а, [[диференцијација|диференцијације]] и [[сенесценција|сенесценције]] (старења) биљака. Биљни хормон такође учествују у одбрани од [[патоген]]а,<ref>{{cite journal | vauthors = Shigenaga AM, Argueso CT | title = No hormone to rule them all: Interactions of plant hormones during the responses of plants to pathogens | journal = Seminars in Cell & Developmental Biology | volume = 56 | pages = 174–189 | date = August 2016 | pmid = 27312082 | doi = 10.1016/j.semcdb.2016.06.005 }}</ref><ref>{{cite journal | vauthors = Bürger M, Chory J | title = Stressed Out About Hormones: How Plants Orchestrate Immunity | journal = Cell Host & Microbe | volume = 26 | issue = 2 | pages = 163–172 | date = August 2019 | pmid = 31415749 | doi = 10.1016/j.chom.2019.07.006 | pmc = 7228804 }}</ref> [[Stress (biology)|stress]] tolerance<ref>{{cite journal | vauthors = Ku YS, Sintaha M, Cheung MY, Lam HM | title = Plant Hormone Signaling Crosstalks between Biotic and Abiotic Stress Responses | journal = International Journal of Molecular Sciences | volume = 19 | issue = 10 | pages = 3206 | date = October 2018 | pmid = 30336563 | pmc = 6214094 | doi = 10.3390/ijms19103206 | doi-access = free }}</ref><ref>{{cite journal | vauthors = Ullah A, Manghwar H, Shaban M, Khan AH, Akbar A, Ali U, Ali E, Fahad S | display-authors = 6 | title = Phytohormones enhanced drought tolerance in plants: a coping strategy | journal = Environmental Science and Pollution Research International | volume = 25 | issue = 33 | pages = 33103–33118 | date = November 2018 | pmid = 30284160 | doi = 10.1007/s11356-018-3364-5 | s2cid = 52913388 }}</ref> and through to [[Reproduction|reproductive]] development.<ref>{{cite journal | vauthors = Pierre-Jerome E, Drapek C, Benfey PN | title = Regulation of Division and Differentiation of Plant Stem Cells | journal = Annual Review of Cell and Developmental Biology | volume = 34 | pages = 289–310 | date = October 2018 | pmid = 30134119 | pmc = 6556207 | doi = 10.1146/annurev-cellbio-100617-062459 }}</ref> Unlike in [[animal]]s (in which hormone production is restricted to specialized [[gland]]s) each plant cell is capable of producing hormones.<ref>{{cite web | title = Plant hormones | url = https://biology.tutorvista.com/biomolecules/plant-hormones.html | publisher = NCS Pearson }}</ref><ref>{{cite web | url= http://www.scienceindia.in/home/view_article/70 | title= Plant Hormones}}</ref> [[Frits Warmolt Went|Went]] and [[Thimann]] coined the term "phytohormone" and used it in the title of their 1937 book.<ref name="WentThimann">{{cite book | vauthors = Went FW, Thimann KV |date= 1937 |title= Phytohormones | url = https://archive.org/details/in.ernet.dli.2015.351314 |publisher= The Macmillan Company |location= New York }}</ref>
Биљни хормони обухватају следећа једињења или класе једињења:
* [[ауксин]]е,
* [[гиберелини|гиберелине]],
* [[цитокинин]]е,
* [[апсцисинска киселина|апсцисинску киселину]],
* [[етен]],
* [[брасиностероиди|брасиностероиде]],
* [[јасмонати|јасмонате]].


Ређе помињана као биљни хормони су и следећа једињења са физиолошким ефектом на биљке:
Биљни хормони обухватају следећа једињења или класе једињења: [[ауксин]]е, [[гиберелини|гиберелине]], [[цитокинин]]е, [[апсцисинска киселина|апсцисинску киселину]], [[етен]], [[брасиностероиди|брасиностероиде]], и [[јасмонати|јасмонате]]. Ређе помињана као биљни хормони су и следећа једињења са физиолошким ефектом на биљке: [[салицилна киселина]], [[азот моноксид]] и [[системин]].

* [[салицилна киселина]]
Phytohormones occur across the [[plant kingdom]], and even in [[algae]], where they have similar functions to those seen in [[Vascular plant|higher plants]].<ref>{{cite journal | vauthors = Tarakhovskaya ER, Maslov Y, Shishova MF | year = 2007 | title = Phytohormones in algae | journal = Russian Journal of Plant Physiology | volume = 54 | issue = 2| pages = 163–170 | doi= 10.1134/s1021443707020021| s2cid = 27373543 }}</ref> Some phytohormones also occur in [[microorganism]]s, such as unicellular [[fungus|fungi]] and [[bacteria]], however in these cases they do not play a hormonal role and can better be regarded as [[secondary metabolites]].<ref>
* [[азот моноксид]]
{{cite journal | doi= 10.1007/BF00029903 | volume= 15 | issue= 3 | title= Gibberellin formation in microorganisms | journal= Plant Growth Regulation | pages= 303–314| year= 1994 | vauthors = Rademacher W | s2cid= 33138732 }}
* [[системин]]
</ref>

== Карактеристике ==
[[File:Phyllody on Coneflower with aster yellows.jpg|thumb|250п|[[Phyllody]] on a [[purple coneflower]] (''Echinacea purpurea''), a plant development abnormality where leaf-like structures replace [[flower]] organs. It can be caused by hormonal imbalance, among other reasons.]]

The word hormone is derived from Greek, meaning ''set in motion''. Plant hormones affect [[gene expression]] and [[gene transcription|transcription]] levels, cellular division, and growth. They are naturally produced within plants, though very similar chemicals are produced by fungi and bacteria that can also affect plant growth.<ref>{{cite book | vauthors = Srivastava LM | title = Plant growth and development: hormones and environment |publisher=Academic Press |year=2002 |page=140 |isbn=978-0-12-660570-9 }}</ref> A large number of related [[chemical compound]]s are [[Chemical synthesis|synthesize]]d by humans. They are used to regulate the growth of [[Agriculture|cultivate]]d plants, [[weed]]s, and [[in vitro]]-grown plants and plant cells; these manmade compounds are called '''plant growth regulators''' ('''PGRs'''). Early in the study of plant hormones, "phytohormone" was the commonly used term, but its use is less widely applied now.

Plant hormones are not [[nutrient]]s, but [[chemical]]s that in small amounts promote and influence the growth,<ref>{{cite book | vauthors = Öpik H, Rolfe SA, Willis JA, Street HE |title=The physiology of flowering plants |url=https://books.google.com/books?id=atZq3w6pOvQC&pg=PA191 |year=2005 |publisher=Cambridge University Press |isbn=978-0-521-66251-2 |page=191 |edition=4th}}
</ref> development, and differentiation of cells and [[tissue (biology)|tissues]]. The biosynthesis of plant hormones within plant tissues is often diffuse and not always localized. Plants lack glands to produce and store hormones, because, unlike animals—which have two circulatory systems ([[lymphatic]] and [[cardiovascular]]) powered by a [[heart]] that moves fluids around the body—plants use more passive means to move chemicals around their bodies. Plants utilize simple chemicals as hormones, which move more easily through their tissues. They are often produced and used on a local basis within the plant body. Plant cells produce hormones that affect even different regions of the cell producing the hormone.

Hormones are transported within the plant by utilizing four types of movements. For localized movement, [[cytoplasm]]ic streaming within cells and slow diffusion of [[ion]]s and [[molecule]]s between cells are utilized. Vascular tissues are used to move hormones from one part of the plant to another; these include [[sieve tube]]s or [[phloem]] that move [[sugar]]s from the leaves to the [[root]]s and flowers, and [[xylem]] that moves water and mineral solutes from the roots to the [[foliage]].

Not all plant cells respond to hormones, but those cells that do are programmed to respond at specific points in their growth cycle. The greatest effects occur at specific stages during the cell's life, with diminished effects occurring before or after this period. Plants need hormones at very specific times during plant growth and at specific locations. They also need to disengage the effects that hormones have when they are no longer needed. The production of hormones occurs very often at sites of active growth within the [[meristem]]s, before cells have fully differentiated. After production, they are sometimes moved to other parts of the plant, where they cause an immediate effect; or they can be stored in cells to be released later. Plants use different pathways to regulate internal hormone quantities and moderate their effects; they can regulate the amount of chemicals used to biosynthesize hormones. They can store them in cells, inactivate them, or cannibalise already-formed hormones by [[Conjugation (biochemistry)|conjugating]] them with [[carbohydrate]]s, [[amino acid]]s, or [[peptide]]s. Plants can also break down hormones chemically, effectively destroying them. Plant hormones frequently regulate the concentrations of other plant hormones.<ref>{{cite journal | vauthors = Swarup R, Perry P, Hagenbeek D, Van Der Straeten D, Beemster GT, Sandberg G, Bhalerao R, Ljung K, Bennett MJ | display-authors = 6 | title = Ethylene upregulates auxin biosynthesis in Arabidopsis seedlings to enhance inhibition of root cell elongation | journal = The Plant Cell | volume = 19 | issue = 7 | pages = 2186–96 | date = July 2007 | pmid = 17630275 | pmc = 1955695 | doi = 10.1105/tpc.107.052100 }}</ref> Plants also move hormones around the plant diluting their concentrations.

The concentration of hormones required for plant responses are very low (10<sup>−6</sup> to 10<sup>−5</sup> [[mole (unit)|mol]]/[[liter|L]]). Because of these low concentrations, it has been very difficult to study plant hormones, and only since the late 1970s have scientists been able to start piecing together their effects and relationships to plant physiology.<ref>{{harvnb|Srivastava|2002|p=143}}</ref> Much of the early work on plant hormones involved studying plants that were genetically deficient in one or involved the use of tissue-cultured plants grown ''[[in vitro]]'' that were subjected to differing ratios of hormones, and the resultant growth compared. The earliest scientific observation and study dates to the 1880s; the determination and observation of plant hormones and their identification was spread out over the next 70 years.

== Класе ==
Different hormones can be sorted into different classes, depending on their chemical structures. Within each class of hormone, chemical structures can vary, but all members of the same class have similar physiological effects. Initial research into plant hormones identified five major classes: abscisic acid, auxins, brassinosteroids, cytokinins and ethylene.<ref>{{cite journal |title=Botany: a brief introduction to plant biology |publisher=Wiley |location=New York |year=1979 |pages=[https://archive.org/details/botanybriefintro00rost/page/155 155–170] |isbn=978-0-471-02114-8 |url=https://archive.org/details/botanybriefintro00rost/page/155 }}</ref> This list was later expanded, and brassinosteroids, jasmonates, salicylic acid, and strigolactones are now also considered major plant hormones. Additionally there are several other compounds that serve functions similar to the major hormones, but their status as ''bone fide'' hormones is still debated.

===Abscisic acid===
[[File:Abscisic acid.svg|thumb|Abscisic acid]]
[[Abscisic acid]] (also called ABA) is one of the most important plant growth inhibitors. It was discovered and researched under two different names, ''dormin'' and ''abscicin II'', before its chemical properties were fully known. Once it was determined that the two compounds are the same, it was named abscisic acid. The name refers to the fact that it is found in high concentrations in newly [[abscission|abscissed]] or freshly fallen leaves.

This class of PGR is composed of one chemical compound normally produced in the leaves of plants, originating from [[chloroplast]]s, especially when plants are under stress. In general, it acts as an inhibitory chemical compound that affects [[bud]] growth, and seed and bud dormancy. It mediates changes within the [[apical meristem]], causing bud dormancy and the alteration of the last set of leaves into protective bud covers. Since it was found in freshly abscissed leaves, it was initially thought to play a role in the processes of natural leaf drop, but further research has disproven this. In plant species from temperate parts of the world, abscisic acid plays a role in leaf and seed dormancy by inhibiting growth, but, as it is dissipated from seeds or buds, growth begins. In other plants, as ABA levels decrease, growth then commences as [[gibberellin]] levels increase. Without ABA, buds and seeds would start to grow during warm periods in winter and would be killed when it froze again. Since ABA dissipates slowly from the tissues and its effects take time to be offset by other plant hormones, there is a delay in physiological pathways that provides some protection from premature growth. Abscisic acid accumulates within seeds during fruit maturation, preventing seed germination within the fruit or before winter. Abscisic acid's effects are degraded within plant tissues during cold temperatures or by its removal by water washing in and out of the tissues, releasing the seeds and buds from dormancy.<ref>{{cite journal | vauthors = Feurtado JA, Ambrose SJ, Cutler AJ, Ross AR, Abrams SR, Kermode AR | title = Dormancy termination of western white pine (Pinus monticola Dougl. Ex D. Don) seeds is associated with changes in abscisic acid metabolism | journal = Planta | volume = 218 | issue = 4 | pages = 630–9 | date = February 2004 | pmid = 14663585 | doi = 10.1007/s00425-003-1139-8 | s2cid = 25035678 }}</ref>

ABA exists in all parts of the plant, and its concentration within any tissue seems to mediate its effects and function as a hormone; its degradation, or more properly [[catabolism]], within the plant affects metabolic reactions and cellular growth and production of other hormones.<ref>{{cite journal |title=Role of Abscisic Acid in Seed Dormancy |journal=J Plant Growth Regul |volume=24 |issue=4 |pages=319–344 |date=December 2005 |doi=10.1007/s00344-005-0110-2 | vauthors = Kermode AR |doi-access=free }}</ref> Plants start life as a seed with high ABA levels. Just before the seed germinates, ABA levels decrease; during germination and early growth of the seedling, ABA levels decrease even more. As plants begin to produce shoots with fully functional leaves, ABA levels begin to increase again, slowing down cellular growth in more "mature" areas of the plant. Stress from water or predation affects ABA production and catabolism rates, mediating another cascade of effects that trigger specific responses from targeted cells. Scientists are still piecing together the complex interactions and effects of this and other phytohormones.

In plants under water stress, ABA plays a role in closing the [[stomata]]. Soon after plants are water-stressed and the roots are deficient in water, a signal moves up to the leaves, causing the formation of ABA precursors there, which then move to the roots. The roots then release ABA, which is translocated to the foliage through the vascular system<ref>{{cite journal | vauthors = Ren H, Gao Z, Chen L, Wei K, Liu J, Fan Y, Davies WJ, Jia W, Zhang J | display-authors = 6 | title = Dynamic analysis of ABA accumulation in relation to the rate of ABA catabolism in maize tissues under water deficit | journal = Journal of Experimental Botany | volume = 58 | issue = 2 | pages = 211–9 | year = 2007 | pmid = 16982652 | doi = 10.1093/jxb/erl117 | doi-access = free }}</ref> and modulates potassium and sodium uptake within the [[guard cell]]s, which then lose [[turgid]]ity, closing the stomata.<ref>{{cite journal | vauthors = Else MA, Coupland D, Dutton L, Jackson MB |title=Decreased root hydraulic conductivity reduces leaf water potential, initiates stomatal closure, and slows leaf expansion in flooded plants of castor oil (''Ricinus communis'') despite diminished delivery of ABA from the roots to shoots in xylem sap |journal=Physiologia Plantarum |volume=111 |issue=1 |pages=46–54 |date=January 2001 |doi= 10.1034/j.1399-3054.2001.1110107.x}}</ref><ref>{{cite journal | vauthors = Yan J, Tsuichihara N, Etoh T, Iwai S | title = Reactive oxygen species and nitric oxide are involved in ABA inhibition of stomatal opening | journal = Plant, Cell & Environment | volume = 30 | issue = 10 | pages = 1320–5 | date = October 2007 | pmid = 17727421 | doi = 10.1111/j.1365-3040.2007.01711.x }}</ref>

== Референце ==
{{Reflist|}}


{{клица-биљке}}
==Спољашње везе==
==Спољашње везе==
{{Commons category|Plant hormones}}
* [http://www.bionet-skola.com/w/Biljni_hormoni БиоНет школа]
*[https://web.archive.org/web/20030908034154/http://www.sidwell.edu/sidwell.resources/bio/virtuallb/plant/hormone.html Simple plant hormone table] with location of synthesis and effects of application — this is the format used in the descriptions at the ends of the Wikipedia articles on individual plant hormones.
*[https://web.archive.org/web/20040427231955/http://www.umanitoba.ca/faculties/afs/plant_science/courses/39_768/l18/l18.1.html Hormonal Regulation of Gene Expression and Development] — Detailed introduction to plant hormones, including genetic information.


{{нормативна контрола}}
{{нормативна контрола}}

Верзија на датум 20. март 2022. у 22:04

Lack of the plant hormone auxin can cause abnormal growth (right)

Биљни хормон (фитохормон) је природно (ендогено) или вештачки синтетисано једињење које има изражен физиолошки ефекат на биљке. Код биљака не постоје специјално диференцирани органи за синтезу хормона, већ се они синтетишу у појединачним, локализованим или дифузно распоређеним ћелијама. Најчешће се синтетишу врло мале количине хормона, али оне имају велики ефекат на процесе метаболизма,[1] раста, диференцијације и сенесценције (старења) биљака. Биљни хормон такође учествују у одбрани од патогена,[2][3] stress tolerance[4][5] and through to reproductive development.[6] Unlike in animals (in which hormone production is restricted to specialized glands) each plant cell is capable of producing hormones.[7][8] Went and Thimann coined the term "phytohormone" and used it in the title of their 1937 book.[9]

Биљни хормони обухватају следећа једињења или класе једињења: ауксине, гиберелине, цитокинине, апсцисинску киселину, етен, брасиностероиде, и јасмонате. Ређе помињана као биљни хормони су и следећа једињења са физиолошким ефектом на биљке: салицилна киселина, азот моноксид и системин.

Phytohormones occur across the plant kingdom, and even in algae, where they have similar functions to those seen in higher plants.[10] Some phytohormones also occur in microorganisms, such as unicellular fungi and bacteria, however in these cases they do not play a hormonal role and can better be regarded as secondary metabolites.[11]

Карактеристике

Phyllody on a purple coneflower (Echinacea purpurea), a plant development abnormality where leaf-like structures replace flower organs. It can be caused by hormonal imbalance, among other reasons.

The word hormone is derived from Greek, meaning set in motion. Plant hormones affect gene expression and transcription levels, cellular division, and growth. They are naturally produced within plants, though very similar chemicals are produced by fungi and bacteria that can also affect plant growth.[12] A large number of related chemical compounds are synthesized by humans. They are used to regulate the growth of cultivated plants, weeds, and in vitro-grown plants and plant cells; these manmade compounds are called plant growth regulators (PGRs). Early in the study of plant hormones, "phytohormone" was the commonly used term, but its use is less widely applied now.

Plant hormones are not nutrients, but chemicals that in small amounts promote and influence the growth,[13] development, and differentiation of cells and tissues. The biosynthesis of plant hormones within plant tissues is often diffuse and not always localized. Plants lack glands to produce and store hormones, because, unlike animals—which have two circulatory systems (lymphatic and cardiovascular) powered by a heart that moves fluids around the body—plants use more passive means to move chemicals around their bodies. Plants utilize simple chemicals as hormones, which move more easily through their tissues. They are often produced and used on a local basis within the plant body. Plant cells produce hormones that affect even different regions of the cell producing the hormone.

Hormones are transported within the plant by utilizing four types of movements. For localized movement, cytoplasmic streaming within cells and slow diffusion of ions and molecules between cells are utilized. Vascular tissues are used to move hormones from one part of the plant to another; these include sieve tubes or phloem that move sugars from the leaves to the roots and flowers, and xylem that moves water and mineral solutes from the roots to the foliage.

Not all plant cells respond to hormones, but those cells that do are programmed to respond at specific points in their growth cycle. The greatest effects occur at specific stages during the cell's life, with diminished effects occurring before or after this period. Plants need hormones at very specific times during plant growth and at specific locations. They also need to disengage the effects that hormones have when they are no longer needed. The production of hormones occurs very often at sites of active growth within the meristems, before cells have fully differentiated. After production, they are sometimes moved to other parts of the plant, where they cause an immediate effect; or they can be stored in cells to be released later. Plants use different pathways to regulate internal hormone quantities and moderate their effects; they can regulate the amount of chemicals used to biosynthesize hormones. They can store them in cells, inactivate them, or cannibalise already-formed hormones by conjugating them with carbohydrates, amino acids, or peptides. Plants can also break down hormones chemically, effectively destroying them. Plant hormones frequently regulate the concentrations of other plant hormones.[14] Plants also move hormones around the plant diluting their concentrations.

The concentration of hormones required for plant responses are very low (10−6 to 10−5 mol/L). Because of these low concentrations, it has been very difficult to study plant hormones, and only since the late 1970s have scientists been able to start piecing together their effects and relationships to plant physiology.[15] Much of the early work on plant hormones involved studying plants that were genetically deficient in one or involved the use of tissue-cultured plants grown in vitro that were subjected to differing ratios of hormones, and the resultant growth compared. The earliest scientific observation and study dates to the 1880s; the determination and observation of plant hormones and their identification was spread out over the next 70 years.

Класе

Different hormones can be sorted into different classes, depending on their chemical structures. Within each class of hormone, chemical structures can vary, but all members of the same class have similar physiological effects. Initial research into plant hormones identified five major classes: abscisic acid, auxins, brassinosteroids, cytokinins and ethylene.[16] This list was later expanded, and brassinosteroids, jasmonates, salicylic acid, and strigolactones are now also considered major plant hormones. Additionally there are several other compounds that serve functions similar to the major hormones, but their status as bone fide hormones is still debated.

Abscisic acid

Abscisic acid

Abscisic acid (also called ABA) is one of the most important plant growth inhibitors. It was discovered and researched under two different names, dormin and abscicin II, before its chemical properties were fully known. Once it was determined that the two compounds are the same, it was named abscisic acid. The name refers to the fact that it is found in high concentrations in newly abscissed or freshly fallen leaves.

This class of PGR is composed of one chemical compound normally produced in the leaves of plants, originating from chloroplasts, especially when plants are under stress. In general, it acts as an inhibitory chemical compound that affects bud growth, and seed and bud dormancy. It mediates changes within the apical meristem, causing bud dormancy and the alteration of the last set of leaves into protective bud covers. Since it was found in freshly abscissed leaves, it was initially thought to play a role in the processes of natural leaf drop, but further research has disproven this. In plant species from temperate parts of the world, abscisic acid plays a role in leaf and seed dormancy by inhibiting growth, but, as it is dissipated from seeds or buds, growth begins. In other plants, as ABA levels decrease, growth then commences as gibberellin levels increase. Without ABA, buds and seeds would start to grow during warm periods in winter and would be killed when it froze again. Since ABA dissipates slowly from the tissues and its effects take time to be offset by other plant hormones, there is a delay in physiological pathways that provides some protection from premature growth. Abscisic acid accumulates within seeds during fruit maturation, preventing seed germination within the fruit or before winter. Abscisic acid's effects are degraded within plant tissues during cold temperatures or by its removal by water washing in and out of the tissues, releasing the seeds and buds from dormancy.[17]

ABA exists in all parts of the plant, and its concentration within any tissue seems to mediate its effects and function as a hormone; its degradation, or more properly catabolism, within the plant affects metabolic reactions and cellular growth and production of other hormones.[18] Plants start life as a seed with high ABA levels. Just before the seed germinates, ABA levels decrease; during germination and early growth of the seedling, ABA levels decrease even more. As plants begin to produce shoots with fully functional leaves, ABA levels begin to increase again, slowing down cellular growth in more "mature" areas of the plant. Stress from water or predation affects ABA production and catabolism rates, mediating another cascade of effects that trigger specific responses from targeted cells. Scientists are still piecing together the complex interactions and effects of this and other phytohormones.

In plants under water stress, ABA plays a role in closing the stomata. Soon after plants are water-stressed and the roots are deficient in water, a signal moves up to the leaves, causing the formation of ABA precursors there, which then move to the roots. The roots then release ABA, which is translocated to the foliage through the vascular system[19] and modulates potassium and sodium uptake within the guard cells, which then lose turgidity, closing the stomata.[20][21]

Референце

  1. ^ Méndez-Hernández HA, Ledezma-Rodríguez M, Avilez-Montalvo RN, Juárez-Gómez YL, Skeete A, Avilez-Montalvo J, et al. (2019). „Signaling Overview of Plant Somatic Embryogenesis”. Frontiers in Plant Science. 10: 77. PMC 6375091Слободан приступ. PMID 30792725. doi:10.3389/fpls.2019.00077Слободан приступ. 
  2. ^ Shigenaga AM, Argueso CT (август 2016). „No hormone to rule them all: Interactions of plant hormones during the responses of plants to pathogens”. Seminars in Cell & Developmental Biology. 56: 174—189. PMID 27312082. doi:10.1016/j.semcdb.2016.06.005. 
  3. ^ Bürger M, Chory J (август 2019). „Stressed Out About Hormones: How Plants Orchestrate Immunity”. Cell Host & Microbe. 26 (2): 163—172. PMC 7228804Слободан приступ. PMID 31415749. doi:10.1016/j.chom.2019.07.006. 
  4. ^ Ku YS, Sintaha M, Cheung MY, Lam HM (октобар 2018). „Plant Hormone Signaling Crosstalks between Biotic and Abiotic Stress Responses”. International Journal of Molecular Sciences. 19 (10): 3206. PMC 6214094Слободан приступ. PMID 30336563. doi:10.3390/ijms19103206Слободан приступ. 
  5. ^ Ullah A, Manghwar H, Shaban M, Khan AH, Akbar A, Ali U, et al. (новембар 2018). „Phytohormones enhanced drought tolerance in plants: a coping strategy”. Environmental Science and Pollution Research International. 25 (33): 33103—33118. PMID 30284160. S2CID 52913388. doi:10.1007/s11356-018-3364-5. 
  6. ^ Pierre-Jerome E, Drapek C, Benfey PN (октобар 2018). „Regulation of Division and Differentiation of Plant Stem Cells”. Annual Review of Cell and Developmental Biology. 34: 289—310. PMC 6556207Слободан приступ. PMID 30134119. doi:10.1146/annurev-cellbio-100617-062459. 
  7. ^ „Plant hormones”. NCS Pearson. 
  8. ^ „Plant Hormones”. 
  9. ^ Went FW, Thimann KV (1937). Phytohormones. New York: The Macmillan Company. 
  10. ^ Tarakhovskaya ER, Maslov Y, Shishova MF (2007). „Phytohormones in algae”. Russian Journal of Plant Physiology. 54 (2): 163—170. S2CID 27373543. doi:10.1134/s1021443707020021. 
  11. ^ Rademacher W (1994). „Gibberellin formation in microorganisms”. Plant Growth Regulation. 15 (3): 303—314. S2CID 33138732. doi:10.1007/BF00029903. 
  12. ^ Srivastava LM (2002). Plant growth and development: hormones and environment. Academic Press. стр. 140. ISBN 978-0-12-660570-9. 
  13. ^ Öpik H, Rolfe SA, Willis JA, Street HE (2005). The physiology of flowering plants (4th изд.). Cambridge University Press. стр. 191. ISBN 978-0-521-66251-2. 
  14. ^ Swarup R, Perry P, Hagenbeek D, Van Der Straeten D, Beemster GT, Sandberg G, et al. (јул 2007). „Ethylene upregulates auxin biosynthesis in Arabidopsis seedlings to enhance inhibition of root cell elongation”. The Plant Cell. 19 (7): 2186—96. PMC 1955695Слободан приступ. PMID 17630275. doi:10.1105/tpc.107.052100. 
  15. ^ Srivastava 2002, стр. 143
  16. ^ „Botany: a brief introduction to plant biology”. New York: Wiley. 1979: 155–170. ISBN 978-0-471-02114-8. 
  17. ^ Feurtado JA, Ambrose SJ, Cutler AJ, Ross AR, Abrams SR, Kermode AR (фебруар 2004). „Dormancy termination of western white pine (Pinus monticola Dougl. Ex D. Don) seeds is associated with changes in abscisic acid metabolism”. Planta. 218 (4): 630—9. PMID 14663585. S2CID 25035678. doi:10.1007/s00425-003-1139-8. 
  18. ^ Kermode AR (децембар 2005). „Role of Abscisic Acid in Seed Dormancy”. J Plant Growth Regul. 24 (4): 319—344. doi:10.1007/s00344-005-0110-2Слободан приступ. 
  19. ^ Ren H, Gao Z, Chen L, Wei K, Liu J, Fan Y, et al. (2007). „Dynamic analysis of ABA accumulation in relation to the rate of ABA catabolism in maize tissues under water deficit”. Journal of Experimental Botany. 58 (2): 211—9. PMID 16982652. doi:10.1093/jxb/erl117Слободан приступ. 
  20. ^ Else MA, Coupland D, Dutton L, Jackson MB (јануар 2001). „Decreased root hydraulic conductivity reduces leaf water potential, initiates stomatal closure, and slows leaf expansion in flooded plants of castor oil (Ricinus communis) despite diminished delivery of ABA from the roots to shoots in xylem sap”. Physiologia Plantarum. 111 (1): 46—54. doi:10.1034/j.1399-3054.2001.1110107.x. 
  21. ^ Yan J, Tsuichihara N, Etoh T, Iwai S (октобар 2007). „Reactive oxygen species and nitric oxide are involved in ABA inhibition of stomatal opening”. Plant, Cell & Environment. 30 (10): 1320—5. PMID 17727421. doi:10.1111/j.1365-3040.2007.01711.x. 

Спољашње везе

Биљни хормон на Викимедијиној остави.
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