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Biotic stress

February 16, 2024

Biotic stress is stress that occurs as a result of damage done to an organism by other living organisms, such as bacteria, viruses, fungi, parasites, beneficial and harmful insects, weeds, and cultivated or native plants.[1] It is different from abiotic stress, which is the negative impact of non-living factors on the organisms such as temperature, sunlight, wind, salinity, flooding and drought.[2] The types of biotic stresses imposed on an organism depend the climate where it lives as well as the species' ability to resist particular stresses. Biotic stress remains a broadly defined term and those who study it face many challenges, such as the greater difficulty in controlling biotic stresses in an experimental context compared to abiotic stress.

The damage caused by these various living and nonliving agents can appear very similar.[1] Even with close observation, accurate diagnosis can be difficult.[1] For example, browning of leaves on an oak tree caused by drought stress may appear similar to leaf browning caused by oak wilt, a serious vascular disease caused by a fungus, or the browning caused by anthracnose, a fairly minor leaf disease.

Agriculture edit

Biotic stressors are a major focus of agricultural research, due to the vast economic losses caused to cash crops. The relationship between biotic stress and plant yield affects economic decisions as well as practical development. The impact of biotic injury on crop yield impacts population dynamics, plant-stressor coevolution, and ecosystem nutrient cycling.[3]

Biotic stress also impacts horticultural plant health and natural habitats ecology. It also has dramatic changes in the host recipient. Plants are exposed to many stress factors, such as drought, high salinity or pathogens, which reduce the yield of the cultivated plants or affect the quality of the harvested products. Although there are many kinds of biotic stress, the majority of plant diseases are caused by fungi.[4] Arabidopsis thaliana is often used as a model plant to study the responses of plants to different sources of stress.[5]

In history edit

Biotic stresses have had huge repercussions for humanity; an example of this is the potato blight, an oomycete which caused widespread famine in England, Ireland and Belgium in the 1840s.[6] Another example is grape phylloxera coming from North America in the 19th century, which led to the Great French Wine Blight.[6]

Today edit

Losses to pests and disease in crop plants continue to pose a significant threat to agriculture and food security. During the latter half of the 20th century, agriculture became increasingly reliant on synthetic chemical pesticides to provide control of pests and diseases, especially within the intensive farming systems common in the developed world. However, in the 21st century, this reliance on chemical control is becoming unsustainable. Pesticides tend to have a limited lifespan due to the emergence of resistance in the target pests, and are increasingly recognised in many cases to have negative impacts on biodiversity, and on the health of agricultural workers and even consumers.[7]

Tomorrow edit

Due to the implications of climate change, it is suspected that plants will have increased susceptibility to pathogens.[8] Additionally, elevated threat of abiotic stresses (i.e. drought and heat) are likely to contribute to plant pathogen susceptibility.[8]

Effect on plant growth edit

Photosynthesis edit

Many biotic stresses affect photosynthesis, as chewing insects reduce leaf area and virus infections reduce the rate of photosynthesis per leaf area. Vascular-wilt fungi compromise the water transport and photosynthesis by inducing stomatal closure.[6][9]

Response to stress edit

Plants have co-evolved with their parasites for several hundred million years. This co-evolutionary process has resulted in the selection of a wide range of plant defences against microbial pathogens and herbivorous pests which act to minimise frequency and impact of attack. These defences include both physical and chemical adaptations, which may either be expressed constitutively, or in many cases, are activated only in response to attack. For example, utilization of high metal ion concentrations derived from the soil allow plants to reduce the harmful effects of biotic stressors (pathogens, herbivores etc.); meanwhile preventing the infliction of severe metal toxicity by way of safeguarding metal ion distribution throughout the plant with protective physiological pathways.[10] Such induced resistance provides a mechanism whereby the costs of defence are avoided until defense is beneficial to the plant. At the same time, successful pests and pathogens have evolved mechanisms to overcome both constitutive and induced resistance in their particular host species. In order to fully understand and manipulate plant biotic stress resistance, we require a detailed knowledge of these interactions at a wide range of scales, from the molecular to the community level.[7]

Inducible defense responses to insect herbivores edit

In order for a plant to defend itself against biotic stress, it must be able to differentiate between an abiotic and biotic stress. A plants response to herbivores starts with the recognition of certain chemicals that are abundant in the saliva of the herbivores. These compounds that trigger a response in plants are known as elicitors or herbivore-associated molecular patterns (HAMPs).[11] These HAMPs trigger signalling pathways throughout the plant, initiating its defence mechanism and allowing the plant to minimise damage to other regions. These HAMPs trigger signalling pathways throughout the plant, initiating its defence mechanism and allowing the plant to minimise damage to other regions. Phloem feeders, like aphids, do not cause a great deal of mechanical damage to plants, but they are still regarded as pests and can seriously harm crop yields. Plants have developed a defence mechanism using salicylic acid pathway, which is also used in infection stress, when defending itself against phloem feeders. Plants perform a more direct attack on an insects digestive system. The plants do this using proteinase inhibitors. These proteinase inhibitors prevent protein digestion and once in the digestive system of an insect, they bind tightly and specifically to the active site of protein hydrolysing enzymes such as trypsin and chymotrypsin.[11] This mechanism is most likely to have evolved in plants when dealing with insect attack.

Plants detect elicitors in the insects saliva. Once detected, a signal transduction network is activated. The presence of an elicitor causes an influx of Ca2+ ions to be released in to the cytosol. This increase in cytosolic concentration activates target proteins such as Calmodulin and other binding proteins. Downstream targets, such as phosphorylation and transcriptional activation of stimulus specific responses, are turned on by Ca2+ dependent protein kinases.[11] In Arabidopsis, over expression of the IQD1 calmodulin-binding transcriptional regulator leads to inhibitor of herbivore activity. The role of calcium ions in this signal transduction network is therefore important.

Calcium Ions also play a large role in activating a plants defensive response. When fatty acid amides are present in insect saliva, the mitogen-activated protein kinases (MAPKs) are activated. These genes when activated, play a role in the jasmonic acid pathway.[11] The jasmonic acid pathway is also referred to as the Octadecanoid pathway. This pathway is vital for the activation of defence genes in plants. The production of jasmonic acid, a phytohormone, is a result of the pathway. In an experiment using virus-induced gene silencing of two calcium-dependent protein kinases (CDPKs) in a wild tobacco (Nicotiana attenuata), it was discovered that the longer herbivory continued the higher the accumulation of jasmonic acid in wild-type plants and in silenced plants, the production of more defence metabolites was seen as well as the decrease in the growth rate of the herbivore used, the tobacco hornworm (Manduca sexta).[11] This example demonstrates the importance of MAP kinases in plant defence regulation.

Inducible defense responses to pathogens edit

Plants are capable of detecting invaders through the recognition of non-self signals despite the lack of a circulatory or immune system like those found in animals. Often a plant's first line of defense against microbes occurs at the plant cell surface and involves the detection of microorganism-associated molecular patterns (MAMPs).[12] MAMPs include nucleic acids common to viruses and endotoxins on bacterial cell membranes which can be detected by specialized pattern-recognition receptors.[13] Another method of detection involves the use of plant immune receptors to detect effector molecules released into plant cells by pathogens. Detection of these signals in infected cells leads to an activation of effector-triggered immunity (ETI), a type of innate immune response.[14]

Both the pattern recognition immunity (PTI) and effector-triggered immunity (ETI) result from the upregulation of multiple defense mechanisms including defensive chemical signaling compounds.[14] An increase in the production of salicylic acid (SA) has been shown to be induced by pathogenic infection. The increase in SA results in the production of pathogenesis related (PR) genes which ultimately increase plant resistance to biotrophic and hemibiotrophic pathogens. Increases in jasmonic acid (JA) synthesis near the sites of pathogen infection have also been described.[15][16] This physiological response to increase JA production has been implicated in the ubiquitination of jasmonate ZIM domains (JAZ) proteins, which inhibit JA signaling, leading to their degradation and a subsequent increase in JA activated defense genes.[15]

Studies regarding the upregulation of defensive chemicals have confirmed the role of SA and JA in pathogen defense. In studies utilizing Arabidopsis mutants with the bacterial NahG gene, which inhibits the production and accumulation of SA, were shown to be more susceptible to pathogens than the wild-type plants. This was thought to result from the inability to produce critical defensive mechanisms including increased PR gene expression.[16][17] Other studies conducted by injecting tobacco plants and Arabidopsis with salicylic acid resulted in higher resistance of infection by the alfalfa and tobacco mosaic viruses, indicating a role for SA biosynthesis in reducing viral replication.[17][18] Additionally, studies performed using Arabidopsis with mutated jasmonic acid biosynthesis pathways have shown JA mutants to be at an increased risk of infection by soil pathogens.[16]

Along with SA and JA, other defensive chemicals have been implicated in plant viral pathogen defenses including abscisic acid (ABA), gibberellic acid (GA), auxin, and peptide hormones.[15] The use of hormones and innate immunity presents parallels between animal and plant defenses, though pattern-triggered immunity is thought to have arisen independently in each.[12]

Cross tolerance with abiotic stress edit

  • Evidence shows that a plant undergoing multiple stresses, both abiotic and biotic (usually pathogen or herbivore attack), can produce a positive effect on plant performance, by reducing their susceptibility to biotic stress compared to how they respond to individual stresses. The interaction leads to a crosstalk between their respective hormone signalling pathways which will either induce or antagonize another restructuring genes machinery to increase tolerance of defense reactions.[19]
  • Reactive oxygen species (ROS) are key signalling molecules produced in response to biotic and abiotic stress cross tolerance. ROS are produced in response to biotic stresses during the oxidative burst.[20]
  • Dual stress imposed by ozone (O3) and pathogen affects tolerance of crop and leads to altered host pathogen interaction (Fuhrer, 2003). Alteration in pathogenesis potential of pest due to O3 exposure is of ecological and economical importance.[21]
  • Tolerance to both biotic and abiotic stresses has been achieved. In maize, breeding programmes have led to plants which are tolerant to drought and have additional resistance to the parasitic weed Striga hermonthica.[22][23]

Remote sensing edit

The Agricultural Research Service (ARS) and various government agencies and private institutions have provided a great deal of fundamental information relating spectral reflectance and thermal emittance properties of soils and crops to their agronomic and biophysical characteristics. This knowledge has facilitated the development and use of various remote sensing methods for non-destructive monitoring of plant growth and development and for the detection of many environmental stresses that limit plant productivity. Coupled with rapid advances in computing and position locating technologies, remote sensing from ground-, air-, and space-based platforms is now capable of providing detailed spatial and temporal information on plant response to their local environment that is needed for site specific agricultural management approaches.[24] This is very important in today's society because with increasing pressure on global food productivity due to population increase, result in a demand for stress-tolerant crop varieties that has never been greater.

See also edit

References edit

  1. ^ a b c Flynn 2003.
  2. ^ Yadav 2012.
  3. ^ Peterson & Higley 2001.
  4. ^ Carris, Little & Stiles 2012.
  5. ^ Karim 2007.
  6. ^ a b c Flexas, Loreto & Medrano 2012.
  7. ^ a b Roberts 2013.
  8. ^ a b Garrett et al. 2006.
  9. ^ Balachandran; et al. (1997). "Concepts of plant biotic stress. Some insights into the stress physiology of virus infected plants, from the perspective of photosynthesis". Physiologia Plantarum. 100 (2): 203–213. doi:10.1111/j.1399-3054.1997.tb04776.x.
  10. ^ Poschenrieder, Tolrà & Barceló 2006.
  11. ^ a b c d e Taiz, Lincoln; Zeiger, Eduardo; Møller, Ian Max; Murphy, Angus (2015). Plant Physiology and Development. USA: Sinauer Associations, Inc. p. 706. ISBN 9781605352558.
  12. ^ a b Spoel, Steven H.; Dong, Xinnian (2012). "How do plants achieve immunity? Defence without specialized immune cells". Nature Reviews Immunology. 12 (2): 89–100. doi:10.1038/nri3141. PMID 22273771. S2CID 205491561.
  13. ^ Boller, T; He, SY (2009). "Innate immunity in plants: an arms race between pattern recognition receptors in plants and effectors in microbial pathogens". Science. 324 (5928): 742–4. Bibcode:2009Sci...324..742B. doi:10.1126/science.1171647. PMC 2729760. PMID 19423812.
  14. ^ a b Tsuda, Kenichi; Katagiri, Fumiaki (2010). "Comparing signaling mechanisms engaged in pattern-triggered and effector-triggered immunity". Current Opinion in Plant Biology. 13 (4): 459–465. doi:10.1016/j.pbi.2010.04.006. PMID 20471306.
  15. ^ a b c Bari, Rajendra; Jones, Jonathan D. G. (2009). "Role of plant hormones in plant defence responses". Plant Molecular Biology. 69 (4): 473–488. doi:10.1007/s11103-008-9435-0. PMID 19083153. S2CID 28385498.
  16. ^ a b c Halim, V. A.; Vess, A.; Scheel, D.; Rosahl, S. (2006). "The Role of Salicylic Acid and Jasmonic Acid in Pathogen Defence". Plant Biology. 8 (3): 307–313. doi:10.1055/s-2006-924025. PMID 16807822. S2CID 28317435.
  17. ^ a b Vlot, A. Corina; Dempsey, D'Maris Amick; Klessig, Daniel F. (2009). "Salicylic Acid, a Multifaceted Hormone to Combat Disease". Annual Review of Phytopathology. 47: 177–206. doi:10.1146/annurev.phyto.050908.135202. PMID 19400653.
  18. ^ Van Huijsduijnen, R. A. M. H.; Alblas, S. W.; De Rijk, R. H.; Bol, J. F. (1986). "Induction by Salicylic Acid of Pathogenesis-related Proteins and Resistance to Alfalfa Mosaic Virus Infection in Various Plant Species". Journal of General Virology. 67 (10): 2135–2143. doi:10.1099/0022-1317-67-10-2135.
  19. ^ Rejeb, Pastor & Mauch-Mani 2014.
  20. ^ Perez & Brown 2014.
  21. ^ Raju et al. 2015.
  22. ^ Atkinson & Urwin 2012.
  23. ^ Fuller, Lilley & Urwin 2008.
  24. ^ Pinter et al. 2003.

Sources edit

  • Atkinson, N. J.; Urwin, P. E. (2012). "The interaction of plant biotic and abiotic stresses: from genes to the field". Journal of Experimental Botany. 63 (10): 3523–3543. doi:10.1093/jxb/ers100. PMID 22467407.
  • Carris, L. M.; Little, C. R.; Stiles, C. M. (2012). . www.apsnet.org. doi:10.1094/PHI-I-2012-0426-01 (inactive 31 January 2024). Archived from the original on 2015-11-10. Retrieved 11 March 2016.{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  • Flexas, J.; Loreto, F.; Medrano, H., eds. (2012). Terrestrial Photosynthesis In A Changing Environment: A Molecular, Physiological, and Ecological Approach. CUP. ISBN 978-0521899413.
  • Flynn, P. (2003). "Biotic vs. Abiotic - Distinguishing Disease Problems from Environmental Stresses". ISU Entomology. Retrieved 16 May 2013.
  • Fuller, V. L.; Lilley, C. J.; Urwin, P. E. (2008). "Nematode resistance". New Phytologist. 180 (1): 27–44. doi:10.1111/j.1469-8137.2008.02508.x. PMID 18564304.
  • Garrett, K. A.; Dendy, S. P.; Frank, E. E.; Rouse, M. N.; Travers, S. E. (2006). "Climate Change Effects on Plant Disease: Genomes to Ecosystems" (PDF). Annual Review of Phytopathology. 44: 489–509. doi:10.1146/annurev.phyto.44.070505.143420. hdl:2097/2379. PMID 16722808.
  • Karim, S. (2007). Exploring plant tolerance to biotic and abiotic stresses (PDF) (Thesis). ISBN 978-9157673572.
  • Perez, I. B.; Brown, P. J. (2014). "The role of ROS signaling in cross-tolerance: from model to crop". Front. Plant Sci. 5: 754. doi:10.3389/fpls.2014.00754. PMC 4274871. PMID 25566313.
  • Peterson, R. K. D.; Higley, L. G., eds. (2001). Biotic Stress and Yield Loss. CRC Press. ISBN 978-0849311451.
  • Pinter, P. J.; Hatfield, J. L.; Schepers, J. S.; Barnes, E. M.; Moran, M. S.; Daughtry, C. S.T.; Upchurch, D. R. (2003). "Remote Sensing for Crop Management". Photogrammetric Engineering & Remote Sensing. 69 (6): 647–664. doi:10.14358/PERS.69.6.647.
  • Poschenrieder, C.; Tolrà, R.; Barceló, J. (2006). "Can metals defend plants against biotic stress?". Trends in Plant Science. 11 (6): 288–295. doi:10.1016/j.tplants.2006.04.007. PMID 16697693.
  • Raju, N. J.; Gossel, W.; Ramanathan, A.; Sudhakar, M., eds. (2015). Management of Water, Energy and Bio-resources in the Era of Climate Change: Emerging Issues and Challenges. doi:10.1007/978-3-319-05969-3. ISBN 978-3319059686. S2CID 132165592.
  • Rejeb, I. B.; Pastor, V.; Mauch-Mani, B. (2014). "Plant Responses to Simultaneous Biotic and Abiotic Stress: Molecular Mechanisms". Plants. 3 (4): 458–475. doi:10.3390/plants3040458. PMC 4844285. PMID 27135514.
  • Roberts, M. (2013). "Preface: Induced Resistance to biotic stress". Journal of Experimental Botany. 64 (5): 1235–1236. doi:10.1093/jxb/ert076. PMID 23616991.
  • Yadav, B. K. V. (2012). . forestrynepal.org. Archived from the original on 7 August 2016. Retrieved 3 December 2015.

February 16, 2024
biotic, stress, stress, that, occurs, result, damage, done, organism, other, living, organisms, such, bacteria, viruses, fungi, parasites, beneficial, harmful, insects, weeds, cultivated, native, plants, different, from, abiotic, stress, which, negative, impac. Biotic stress is stress that occurs as a result of damage done to an organism by other living organisms such as bacteria viruses fungi parasites beneficial and harmful insects weeds and cultivated or native plants 1 It is different from abiotic stress which is the negative impact of non living factors on the organisms such as temperature sunlight wind salinity flooding and drought 2 The types of biotic stresses imposed on an organism depend the climate where it lives as well as the species ability to resist particular stresses Biotic stress remains a broadly defined term and those who study it face many challenges such as the greater difficulty in controlling biotic stresses in an experimental context compared to abiotic stress The damage caused by these various living and nonliving agents can appear very similar 1 Even with close observation accurate diagnosis can be difficult 1 For example browning of leaves on an oak tree caused by drought stress may appear similar to leaf browning caused by oak wilt a serious vascular disease caused by a fungus or the browning caused by anthracnose a fairly minor leaf disease Contents 1 Agriculture 1 1 In history 1 2 Today 1 3 Tomorrow 2 Effect on plant growth 2 1 Photosynthesis 3 Response to stress 3 1 Inducible defense responses to insect herbivores 3 2 Inducible defense responses to pathogens 3 3 Cross tolerance with abiotic stress 4 Remote sensing 5 See also 6 References 7 SourcesAgriculture editBiotic stressors are a major focus of agricultural research due to the vast economic losses caused to cash crops The relationship between biotic stress and plant yield affects economic decisions as well as practical development The impact of biotic injury on crop yield impacts population dynamics plant stressor coevolution and ecosystem nutrient cycling 3 Biotic stress also impacts horticultural plant health and natural habitats ecology It also has dramatic changes in the host recipient Plants are exposed to many stress factors such as drought high salinity or pathogens which reduce the yield of the cultivated plants or affect the quality of the harvested products Although there are many kinds of biotic stress the majority of plant diseases are caused by fungi 4 Arabidopsis thaliana is often used as a model plant to study the responses of plants to different sources of stress 5 In history edit Biotic stresses have had huge repercussions for humanity an example of this is the potato blight an oomycete which caused widespread famine in England Ireland and Belgium in the 1840s 6 Another example is grape phylloxera coming from North America in the 19th century which led to the Great French Wine Blight 6 Today edit Losses to pests and disease in crop plants continue to pose a significant threat to agriculture and food security During the latter half of the 20th century agriculture became increasingly reliant on synthetic chemical pesticides to provide control of pests and diseases especially within the intensive farming systems common in the developed world However in the 21st century this reliance on chemical control is becoming unsustainable Pesticides tend to have a limited lifespan due to the emergence of resistance in the target pests and are increasingly recognised in many cases to have negative impacts on biodiversity and on the health of agricultural workers and even consumers 7 Tomorrow edit Due to the implications of climate change it is suspected that plants will have increased susceptibility to pathogens 8 Additionally elevated threat of abiotic stresses i e drought and heat are likely to contribute to plant pathogen susceptibility 8 Effect on plant growth editPhotosynthesis edit Many biotic stresses affect photosynthesis as chewing insects reduce leaf area and virus infections reduce the rate of photosynthesis per leaf area Vascular wilt fungi compromise the water transport and photosynthesis by inducing stomatal closure 6 9 Response to stress editPlants have co evolved with their parasites for several hundred million years This co evolutionary process has resulted in the selection of a wide range of plant defences against microbial pathogens and herbivorous pests which act to minimise frequency and impact of attack These defences include both physical and chemical adaptations which may either be expressed constitutively or in many cases are activated only in response to attack For example utilization of high metal ion concentrations derived from the soil allow plants to reduce the harmful effects of biotic stressors pathogens herbivores etc meanwhile preventing the infliction of severe metal toxicity by way of safeguarding metal ion distribution throughout the plant with protective physiological pathways 10 Such induced resistance provides a mechanism whereby the costs of defence are avoided until defense is beneficial to the plant At the same time successful pests and pathogens have evolved mechanisms to overcome both constitutive and induced resistance in their particular host species In order to fully understand and manipulate plant biotic stress resistance we require a detailed knowledge of these interactions at a wide range of scales from the molecular to the community level 7 Inducible defense responses to insect herbivores edit In order for a plant to defend itself against biotic stress it must be able to differentiate between an abiotic and biotic stress A plants response to herbivores starts with the recognition of certain chemicals that are abundant in the saliva of the herbivores These compounds that trigger a response in plants are known as elicitors or herbivore associated molecular patterns HAMPs 11 These HAMPs trigger signalling pathways throughout the plant initiating its defence mechanism and allowing the plant to minimise damage to other regions These HAMPs trigger signalling pathways throughout the plant initiating its defence mechanism and allowing the plant to minimise damage to other regions Phloem feeders like aphids do not cause a great deal of mechanical damage to plants but they are still regarded as pests and can seriously harm crop yields Plants have developed a defence mechanism using salicylic acid pathway which is also used in infection stress when defending itself against phloem feeders Plants perform a more direct attack on an insects digestive system The plants do this using proteinase inhibitors These proteinase inhibitors prevent protein digestion and once in the digestive system of an insect they bind tightly and specifically to the active site of protein hydrolysing enzymes such as trypsin and chymotrypsin 11 This mechanism is most likely to have evolved in plants when dealing with insect attack Plants detect elicitors in the insects saliva Once detected a signal transduction network is activated The presence of an elicitor causes an influx of Ca2 ions to be released in to the cytosol This increase in cytosolic concentration activates target proteins such as Calmodulin and other binding proteins Downstream targets such as phosphorylation and transcriptional activation of stimulus specific responses are turned on by Ca2 dependent protein kinases 11 In Arabidopsis over expression of the IQD1 calmodulin binding transcriptional regulator leads to inhibitor of herbivore activity The role of calcium ions in this signal transduction network is therefore important Calcium Ions also play a large role in activating a plants defensive response When fatty acid amides are present in insect saliva the mitogen activated protein kinases MAPKs are activated These genes when activated play a role in the jasmonic acid pathway 11 The jasmonic acid pathway is also referred to as the Octadecanoid pathway This pathway is vital for the activation of defence genes in plants The production of jasmonic acid a phytohormone is a result of the pathway In an experiment using virus induced gene silencing of two calcium dependent protein kinases CDPKs in a wild tobacco Nicotiana attenuata it was discovered that the longer herbivory continued the higher the accumulation of jasmonic acid in wild type plants and in silenced plants the production of more defence metabolites was seen as well as the decrease in the growth rate of the herbivore used the tobacco hornworm Manduca sexta 11 This example demonstrates the importance of MAP kinases in plant defence regulation Inducible defense responses to pathogens edit Plants are capable of detecting invaders through the recognition of non self signals despite the lack of a circulatory or immune system like those found in animals Often a plant s first line of defense against microbes occurs at the plant cell surface and involves the detection of microorganism associated molecular patterns MAMPs 12 MAMPs include nucleic acids common to viruses and endotoxins on bacterial cell membranes which can be detected by specialized pattern recognition receptors 13 Another method of detection involves the use of plant immune receptors to detect effector molecules released into plant cells by pathogens Detection of these signals in infected cells leads to an activation of effector triggered immunity ETI a type of innate immune response 14 Both the pattern recognition immunity PTI and effector triggered immunity ETI result from the upregulation of multiple defense mechanisms including defensive chemical signaling compounds 14 An increase in the production of salicylic acid SA has been shown to be induced by pathogenic infection The increase in SA results in the production of pathogenesis related PR genes which ultimately increase plant resistance to biotrophic and hemibiotrophic pathogens Increases in jasmonic acid JA synthesis near the sites of pathogen infection have also been described 15 16 This physiological response to increase JA production has been implicated in the ubiquitination of jasmonate ZIM domains JAZ proteins which inhibit JA signaling leading to their degradation and a subsequent increase in JA activated defense genes 15 Studies regarding the upregulation of defensive chemicals have confirmed the role of SA and JA in pathogen defense In studies utilizing Arabidopsis mutants with the bacterial NahG gene which inhibits the production and accumulation of SA were shown to be more susceptible to pathogens than the wild type plants This was thought to result from the inability to produce critical defensive mechanisms including increased PR gene expression 16 17 Other studies conducted by injecting tobacco plants and Arabidopsis with salicylic acid resulted in higher resistance of infection by the alfalfa and tobacco mosaic viruses indicating a role for SA biosynthesis in reducing viral replication 17 18 Additionally studies performed using Arabidopsis with mutated jasmonic acid biosynthesis pathways have shown JA mutants to be at an increased risk of infection by soil pathogens 16 Along with SA and JA other defensive chemicals have been implicated in plant viral pathogen defenses including abscisic acid ABA gibberellic acid GA auxin and peptide hormones 15 The use of hormones and innate immunity presents parallels between animal and plant defenses though pattern triggered immunity is thought to have arisen independently in each 12 Cross tolerance with abiotic stress edit Evidence shows that a plant undergoing multiple stresses both abiotic and biotic usually pathogen or herbivore attack can produce a positive effect on plant performance by reducing their susceptibility to biotic stress compared to how they respond to individual stresses The interaction leads to a crosstalk between their respective hormone signalling pathways which will either induce or antagonize another restructuring genes machinery to increase tolerance of defense reactions 19 Reactive oxygen species ROS are key signalling molecules produced in response to biotic and abiotic stress cross tolerance ROS are produced in response to biotic stresses during the oxidative burst 20 Dual stress imposed by ozone O3 and pathogen affects tolerance of crop and leads to altered host pathogen interaction Fuhrer 2003 Alteration in pathogenesis potential of pest due to O3 exposure is of ecological and economical importance 21 Tolerance to both biotic and abiotic stresses has been achieved In maize breeding programmes have led to plants which are tolerant to drought and have additional resistance to the parasitic weed Striga hermonthica 22 23 Remote sensing editThe Agricultural Research Service ARS and various government agencies and private institutions have provided a great deal of fundamental information relating spectral reflectance and thermal emittance properties of soils and crops to their agronomic and biophysical characteristics This knowledge has facilitated the development and use of various remote sensing methods for non destructive monitoring of plant growth and development and for the detection of many environmental stresses that limit plant productivity Coupled with rapid advances in computing and position locating technologies remote sensing from ground air and space based platforms is now capable of providing detailed spatial and temporal information on plant response to their local environment that is needed for site specific agricultural management approaches 24 This is very important in today s society because with increasing pressure on global food productivity due to population increase result in a demand for stress tolerant crop varieties that has never been greater See also editAbiotic stress Stress on organisms caused by nonliving factors Biotic component Community of living organisms together with the nonliving components of their environmentPages displaying short descriptions of redirect targets List of beneficial weedsReferences edit a b c Flynn 2003 Yadav 2012 Peterson amp Higley 2001 Carris Little amp Stiles 2012 Karim 2007 a b c Flexas Loreto amp Medrano 2012 a b Roberts 2013 a b Garrett et al 2006 Balachandran et al 1997 Concepts of plant biotic stress Some insights into the stress physiology of virus infected plants from the perspective of photosynthesis Physiologia Plantarum 100 2 203 213 doi 10 1111 j 1399 3054 1997 tb04776 x Poschenrieder Tolra amp Barcelo 2006 a b c d e Taiz Lincoln Zeiger Eduardo Moller Ian Max Murphy Angus 2015 Plant Physiology and Development USA Sinauer Associations Inc p 706 ISBN 9781605352558 a b Spoel Steven H Dong Xinnian 2012 How do plants achieve immunity Defence without specialized immune cells Nature Reviews Immunology 12 2 89 100 doi 10 1038 nri3141 PMID 22273771 S2CID 205491561 Boller T He SY 2009 Innate immunity in plants an arms race between pattern recognition receptors in plants and effectors in microbial pathogens Science 324 5928 742 4 Bibcode 2009Sci 324 742B doi 10 1126 science 1171647 PMC 2729760 PMID 19423812 a b Tsuda Kenichi Katagiri Fumiaki 2010 Comparing signaling mechanisms engaged in pattern triggered and effector triggered immunity Current Opinion in Plant Biology 13 4 459 465 doi 10 1016 j pbi 2010 04 006 PMID 20471306 a b c Bari Rajendra Jones Jonathan D G 2009 Role of plant hormones in plant defence responses Plant Molecular Biology 69 4 473 488 doi 10 1007 s11103 008 9435 0 PMID 19083153 S2CID 28385498 a b c Halim V A Vess A Scheel D Rosahl S 2006 The Role of Salicylic Acid and Jasmonic Acid in Pathogen Defence Plant Biology 8 3 307 313 doi 10 1055 s 2006 924025 PMID 16807822 S2CID 28317435 a b Vlot A Corina Dempsey D Maris Amick Klessig Daniel F 2009 Salicylic Acid a Multifaceted Hormone to Combat Disease Annual Review of Phytopathology 47 177 206 doi 10 1146 annurev phyto 050908 135202 PMID 19400653 Van Huijsduijnen R A M H Alblas S W De Rijk R H Bol J F 1986 Induction by Salicylic Acid of Pathogenesis related Proteins and Resistance to Alfalfa Mosaic Virus Infection in Various Plant Species Journal of General Virology 67 10 2135 2143 doi 10 1099 0022 1317 67 10 2135 Rejeb Pastor amp Mauch Mani 2014 Perez amp Brown 2014 Raju et al 2015 Atkinson amp Urwin 2012 Fuller Lilley amp Urwin 2008 Pinter et al 2003 Sources editAtkinson N J Urwin P E 2012 The interaction of plant biotic and abiotic stresses from genes to the field Journal of Experimental Botany 63 10 3523 3543 doi 10 1093 jxb ers100 PMID 22467407 Carris L M Little C R Stiles C M 2012 Introduction to Fungi www apsnet org doi 10 1094 PHI I 2012 0426 01 inactive 31 January 2024 Archived from the original on 2015 11 10 Retrieved 11 March 2016 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of January 2024 link Flexas J Loreto F Medrano H eds 2012 Terrestrial Photosynthesis In A Changing Environment A Molecular Physiological and Ecological Approach CUP ISBN 978 0521899413 Flynn P 2003 Biotic vs Abiotic Distinguishing Disease Problems from Environmental Stresses ISU Entomology Retrieved 16 May 2013 Fuller V L Lilley C J Urwin P E 2008 Nematode resistance New Phytologist 180 1 27 44 doi 10 1111 j 1469 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