fbpx
Wikipedia

Floral scent

December 15, 2023

Floral scent, or flower scent, is composed of all the volatile organic compounds (VOCs), or aroma compounds, emitted by floral tissue (e.g. flower petals). Other names for floral scent include, aroma, fragrance, floral odour or perfume. Flower scent of most flowering plant species encompasses a diversity of VOCs, sometimes up to several hundred different compounds.[1][2] The primary functions of floral scent are to deter herbivores and especially folivorous insects (see Plant defense against herbivory), and to attract pollinators. Floral scent is one of the most important communication channels mediating plant-pollinator interactions, along with visual cues (flower color, shape, etc.).[3]

Flowers of Lonicera japonica emit a sweet, subtle fragrance mainly composed of linalool.[4]

Biotic interactions edit

Perception by flower visitors edit

Flower visitors such as insects and bats detect floral scents thanks to chemoreceptors of variable specificity to a specific VOC. The fixation of a VOC on a chemoreceptor triggers the activation of an antennal glomerulus, further projecting on an olfactory receptor neuron and finally triggering a behavioral response after processing the information (see also Olfaction, Insect olfaction). The simultaneous perception of various VOCs may cause the activation of several glomeruli, but the output signal may not be additive due to synergistic or antagonistic mechanisms linked with inter-neuronal activity.[5] Therefore, the perception of a VOC within a floral blend may trigger a different behavioral response than when perceived isolated. Similarly, the output signal is not proportional to the amount of VOCs, with some VOCs in low amounts in the floral blend having major effects on pollinator behavior. A good characterization of floral scent, both qualitative and quantitative, is necessary to understand and potentially predict flower visitors' behavior.

Flower visitors use floral scents to detect, recognize and locate their host species and even discriminate among flowers of the same plant.[6] This is made possible by the high specificity of floral scent, where both diversity of VOCs and their relative amount may characterize the flowering species, an individual plant, a flower of the plant, and the distance of the plume from the source.

To make the best use of this specific information, flower visitors rely on long-term and short-term memory that allows them to efficiently choose their flowers.[7] They learn to associate the floral scent of a plant with a reward such as nectar and pollen,[8] and have different behavioral responses to known scents versus unknown ones.[9] They are also able to react similarly to slightly different odor blends.[10]

Mediated biotic interactions edit

 
Pollinators use both floral scent and floral colour to locate flowers of Antirrhinum majus spp. striatum.[11]

A primary function of floral scent is to attract pollinators and ensure the reproduction of animal-pollinated plants.

Some families of VOCs presented in floral scents have likely evolved as herbivore repellents.[12] However, these plant defenses are also used by herbivores themselves to locate a plant resource, similar to pollinators attracted by the floral scent.[13] Therefore, flower traits can be subject to antagonistic selection pressures (positive selection by pollinators and negative selection by herbivores).[14]

Plant-plant communications edit

Plants have an array of volatile compounds they can release to signal other plants. By unleashing these cues, plants learn more about their environment and sufficiently respond. However, there are still many factors about plant scents scientists are still trying to understand. Scientists have studied how many of the volatile compounds released by plants are from a floral source. A study concluded that floral cues are as important as other volatile compounds and are pertinent for plant-to-plant communication.[15] Further research found that plants who receive the floral volatiles have higher fitness than other volatile cues because floral cues are the only compounds released by plants that indicate their kind of mating environment.[16] Plants are able to respond to these mating cues and change adjustable floral phenotypes that can affect plant pollination and mating. Floral volatiles can ward off or attract pollinators/mates all at once. Depending on the number of floral signals released by a plant can control the level of attracting/repelling the plant wants. The composition of floral compounds and the rate of their release are the potential factors that control attraction/repellence. These two elements can be in response to ecological cues like high plant density and temperature.[17] For instance, in sexually deceptive orchids, floral scents emitted after pollination reduce the flower's attractiveness to pollinators. This mechanism acts as a signal to pollinators to visit unpollinated flowers.[18]

Environmental conditions can affect plant communication and signaling. Signal factors include temperature and plant density. Environmentally high temperatures increase the rate of releasing floral compounds, which can increase the amount of signal released and thus its ability to reach more plants.[17] When plant density increases, plant communication increases as well, since plants would be near each other and have signals reach many neighboring plants. This can also increase the signal's reliability and lowering the chance the signal will degrade before it can reach other plants.[17]

Biosynthesis of floral VOCs edit

Most floral VOCs belong to three main chemical classes.[2][6] VOCs in the same chemical class are synthesized from a shared precursor, but the biochemical pathway is specific for each VOC and often varies from one plant species to another.

Terpenoids (or isoprenoids) are derived from isoprene and synthesized via the mevalonate pathway or the erythritol phosphate pathway. They represent the majority of floral VOCs and are often the most abundant compounds in floral scent blends.[19]

The second chemical class is composed of the fatty acid derivatives synthesized from acetyl-CoA, most of which are known as green leaf volatiles, because they are also emitted by vegetative parts (i.e.: leaves and stems) of plants, and sometimes higher in abundance than from floral tissue.

The third chemical class is composed of benzenoids/phenylpropanoids, also known as aromatic compounds; they are synthesized from phenylalanine.

Regulation of emissions edit

Floral scent emissions of most flowering plants vary predictably throughout the day, following a circadian rhythm. This variation is controlled by light intensity.[20] Maximal emissions coincide with peaks of the highest activity of visiting pollinators. For instance, snapdragon flowers, mostly pollinated by bees, have the highest emissions at noon, whereas nocturnally-visited tobacco plants have the highest emissions at night.[21]

Floral scent emissions also vary along with floral development, with the highest emissions at anthesis,[22] i.e. when the flower is fecund (highly fertile), and reduced emissions after pollination, probably due to mechanisms linked with fecundation.[23] In tropical orchids, floral scent emission is terminated immediately following pollination, reducing the expenditure of energy on fragrance production.[24] In petunia flowers, ethylene is released to stop the synthesis of benzenoid floral volatiles after successful pollination.[25]

Abiotic factors, such as temperature, atmospheric CO2 concentration, hydric stress, and soil nutrient status also impact the regulation of floral scent.[26] For instance, increased temperatures in the environment can increase the emission of VOCs in flowers, potentially altering communication between plants and pollinators.[17]

Finally, biotic interactions may also affect the floral scent. Plant leaves attacked by herbivores emit new VOCs in response to the attack, the so-called herbivore-induced plant volatiles (HIPVs).[27] Similarly, damaged flowers have a modified floral scent compared to undamaged ones. Micro-organisms present in nectar may alter floral scent emissions as well.[28]

Measurement edit

Measuring floral scent both qualitatively (identification of VOCs) and quantitatively (absolute and/or relative emission of VOCs) requires the use of analytical chemistry techniques. It requires collecting floral VOCs, and then analyzing them.

VOCs sampling edit

The most popular methods rely on adsorbing floral VOCs on an adsorbent material such as SPME fibers or cartridges by pumping air sampled around inflorescences through the adsorbent material.

It is also possible to extract chemicals stocked in petals by immersing them in a solvent and then analyze the liquid residue. This is more adapted to the study of heavier organic compounds, and/or VOCs that are stored in floral tissue before being emitted into air.

Sample analysis edit

Desorption edit

Main article: Desorption
  • Thermal desorption: the adsorbent material is flash-heated so that all adsorbed VOCs are carried away from the adsorbent and injected into the separation system. This is how work injectors in gas chromatography machines, which literally volatilize introduced samples. For VOCs adsorbed on bigger amount of adsorbent material such as cartridges, thermal desorption may require the use of a specific machine, a thermal desorber, connected to the separation system.
  • Desorption by solvent: VOCs adsorbed on the adsorbent material are carried away by a small quantity of solvent which is volatilized and injected in the separation system. Most commonly used solvents are very volatile molecules, such as methanol, to avoid co-elution with slightly heavier VOCs

Separation edit

Gas chromatography (GC) is ideal to separate volatilized VOCs due to their low molecular weight. VOCs are carried by a gas vector (helium) through a chromatographic column (the solid phase) on which they have different affinities, which allows to separate them.

Liquid chromatography may be used for liquid extractions of floral tissue.

Detection and identification edit

Separation systems are coupled with a detector, that allows the detection and identification of VOCs based on their molecular weight and chemical properties. The most used system for the analysis of floral scent samples is GC-MS (gas chromatography coupled with mass spectrometry).

Quantification edit

Quantification of VOCs is based on the peak area measured on the chromatogram and compared to the peak area of a chemical standard:[29]

  • Internal calibration: a known quantity of a specific chemical standard is injected together with the VOCs, the measured area on the chromatogram is proportional to the injected quantity. Because the chemical properties of VOCs alter their affinity to the solid phase (the chromatographic column) and subsequently the peak area on the chromatogram, it is best to use several standards that reflect the best chemical diversity of the floral scent sample. This method allows a more robust comparison among samples.
  • External calibration: calibration curves (quantity vs. peak area) are established independently by the injection of a range of quantities of chemical standard. This method is best when the relative and absolute amount of VOCs in floral scent samples varies from sample to sample and from VOC to VOC and when the chemical diversity of VOCs in the sample is high. However, it is more time-consuming and may be a source of errors (e.g. matrix effects due to solvent or very abundant VOCs compared to trace VOCs[30]).

Specificity of floral scent analysis edit

Floral scent is often composed of hundreds of VOCs, in very variable proportions. The method used is a tradeoff between accurately detecting quantifying minor compounds and avoiding detector saturation by major compounds. For most analysis methods routinely used, the detection threshold of many VOCs is still higher than the perception threshold of insects,[31] which reduces our capacity to understand plant-insect interactions mediated by floral scent.

Further, the chemical diversity in floral scent samples is challenging. The time of analysis is proportional to the range in molecular weight of VOCs present in the sample, hence a high diversity will increase analysis time. Floral scent may also be composed of very similar molecules, such as isomers and especially enantiomers, which tend to co-elute and then to be very hardly separated. Unambiguously detecting and quantifying them is of importance though, as enantiomers may trigger very different responses in pollinators.[32]

References edit

  1. ^ Knudsen, Jette T.; Eriksson, Roger; Gershenzon, Jonathan; Ståhl, Bertil (March 2006). "Diversity and Distribution of Floral Scent". The Botanical Review. 72 (1): 1–120. doi:10.1663/0006-8101(2006)72[1:DADOFS]2.0.CO;2. S2CID 24559115.
  2. ^ a b Piechulla, B.; Effmert, U. (2010). "Biosynthesis and Regulation of Flower Scent". Plant Developmental Biology - Biotechnological Perspectives. Springer Berlin Heidelberg. pp. 189–205. doi:10.1007/978-3-642-04670-4_10. ISBN 9783642046698.
  3. ^ Raguso, Robert A. (December 2008). "Wake Up and Smell the Roses: The Ecology and Evolution of Floral Scent". Annual Review of Ecology, Evolution, and Systematics. 39 (1): 549–569. doi:10.1146/annurev.ecolsys.38.091206.095601.
  4. ^ El-Sayed, A. M.; Mitchell, V. J.; McLaren, G. F.; Manning, L. M.; Bunn, B.; Suckling, D. M. (15 May 2009). "Attraction of New Zealand Flower Thrips, Thrips obscuratus, to cis-Jasmone, a Volatile Identified from Japanese Honeysuckle Flowers". Journal of Chemical Ecology. 35 (6): 656–663. doi:10.1007/s10886-009-9619-3. PMID 19444522. S2CID 9504546.
  5. ^ Cunningham, J. P. (2012-02-01). "Can mechanism help explain insect host choice?" (PDF). Journal of Evolutionary Biology. 25 (2): 244–251. doi:10.1111/j.1420-9101.2011.02435.x. ISSN 1420-9101. PMID 22225990. S2CID 25567175.
  6. ^ a b Dudareva, Natalia; Negre, Florence; Nagegowda, Dinesh A.; Orlova, Irina (October 2006). "Plant Volatiles: Recent Advances and Future Perspectives". Critical Reviews in Plant Sciences. 25 (5): 417–440. doi:10.1080/07352680600899973. S2CID 84019949.
  7. ^ Chittka, Lars; Thomson, James D.; Waser, Nickolas M. (1999). "Flower Constancy, Insect Psychology, and Plant Evolution". Naturwissenschaften. 86 (8): 361–377. Bibcode:1999NW.....86..361C. doi:10.1007/s001140050636. ISSN 0028-1042. S2CID 27377784.
  8. ^ Giurfa, Martin (2007-07-17). "Behavioral and neural analysis of associative learning in the honeybee: a taste from the magic well". Journal of Comparative Physiology A. 193 (8): 801–824. doi:10.1007/s00359-007-0235-9. ISSN 0340-7594. PMID 17639413. S2CID 9164757.
  9. ^ Junker, Robert R.; Höcherl, Nicole; Blüthgen, Nico (2010-07-01). "Responses to olfactory signals reflect network structure of flower-visitor interactions". Journal of Animal Ecology. 79 (4): 818–823. doi:10.1111/j.1365-2656.2010.01698.x. ISSN 1365-2656. PMID 20412348.
  10. ^ Guerrieri, Fernando; Schubert, Marco; Sandoz, Jean-Christophe; Giurfa, Martin (2005-02-22). "Perceptual and Neural Olfactory Similarity in Honeybees". PLOS Biol. 3 (4): e60. doi:10.1371/journal.pbio.0030060. ISSN 1545-7885. PMC 1043859. PMID 15736975.
  11. ^ Jaworski, Coline C.; Andalo, Christophe; Raynaud, Christine; Simon, Valérie; Thébaud, Christophe; Chave, Jérôme; Huang, Shuang-Quan (11 August 2015). "The Influence of Prior Learning Experience on Pollinator Choice: An Experiment Using Bumblebees on Two Wild Floral Types of Antirrhinum majus". PLOS ONE. 10 (8): e0130225. Bibcode:2015PLoSO..1030225J. doi:10.1371/journal.pone.0130225. PMC 4532467. PMID 26263186.
  12. ^ Schiestl, Florian P. (2010-05-01). "The evolution of floral scent and insect chemical communication". Ecology Letters. 13 (5): 643–656. doi:10.1111/j.1461-0248.2010.01451.x. ISSN 1461-0248. PMID 20337694.
  13. ^ Theis, Nina; Adler, Lynn S. (2012-02-01). "Advertising to the enemy: enhanced floral fragrance increases beetle attraction and reduces plant reproduction". Ecology. 93 (2): 430–435. doi:10.1890/11-0825.1. ISSN 1939-9170. PMID 22624324.
  14. ^ Strauss, S., and J. Whittall. 2006. Non-pollinator agents of selection on floral traits. Pp. 120–138 in Ecology and evolution of flowers. OUP Oxford.
  15. ^ Caruso, Christina M.; Parachnowitsch, Amy L. (2016-01-01). "Do Plants Eavesdrop on Floral Scent Signals?". Trends in Plant Science. 21 (1): 9–15. doi:10.1016/j.tplants.2015.09.001. ISSN 1360-1385. PMID 26476624.
  16. ^ Harder, Lawrence D.; Johnson, Steven D. (August 2009). "Darwin's beautiful contrivances: evolutionary and functional evidence for floral adaptation". New Phytologist. 183 (3): 530–545. doi:10.1111/j.1469-8137.2009.02914.x. ISSN 0028-646X.
  17. ^ a b c d Farré-Armengol, Gerard; Filella, Iolanda; Llusià, Joan; Niinemets, Ülo; Peñuelas, Josep (December 2014). "Changes in floral bouquets from compound-specific responses to increasing temperatures". Global Change Biology. 20 (12): 3660–3669. doi:10.1111/gcb.12628. PMC 5788256. PMID 24817412.
  18. ^ Schiestl, Florian P.; Ayasse, Manfred (2001-02-01). "Post-pollination emission of a repellent compound in a sexually deceptive orchid: a new mechanism for maximising reproductive success?". Oecologia. 126 (4): 531–534. doi:10.1007/s004420000552. ISSN 1432-1939. PMID 28547238. S2CID 5035741.
  19. ^ Gershenzon, Jonathan; Dudareva, Natalia (18 June 2007). "The function of terpene natural products in the natural world". Nature Chemical Biology. 3 (7): 408–414. doi:10.1038/nchembio.2007.5. PMID 17576428.
  20. ^ Harmer, Stacey L.; Hogenesch, John B.; Straume, Marty; Chang, Hur-Song; Han, Bin; Zhu, Tong; Wang, Xun; Kreps, Joel A.; Kay, Steve A. (2000-12-15). "Orchestrated Transcription of Key Pathways in Arabidopsis by the Circadian Clock". Science. 290 (5499): 2110–2113. Bibcode:2000Sci...290.2110H. doi:10.1126/science.290.5499.2110. ISSN 0036-8075. PMID 11118138. S2CID 8920347.
  21. ^ Kolosova, Natalia; Gorenstein, Nina; Kish, Christine M.; Dudareva, Natalia (2001-10-01). "Regulation of Circadian Methyl Benzoate Emission in Diurnally and Nocturnally Emitting Plants". The Plant Cell. 13 (10): 2333–2347. doi:10.1105/tpc.010162. ISSN 1532-298X. PMC 139162. PMID 11595805.
  22. ^ Dudareva, Natalia; Murfitt, Lisa M.; Mann, Craig J.; Gorenstein, Nina; Kolosova, Natalia; Kish, Christine M.; Bonham, Connie; Wood, Karl (2000-06-01). "Developmental Regulation of Methyl Benzoate Biosynthesis and Emission in Snapdragon Flowers". The Plant Cell. 12 (6): 949–961. doi:10.1105/tpc.12.6.949. ISSN 1532-298X. PMC 149095. PMID 10852939.
  23. ^ Negre, Florence; Kish, Christine M.; Boatright, Jennifer; Underwood, Beverly; Shibuya, Kenichi; Wagner, Conrad; Clark, David G.; Dudareva, Natalia (2003-12-01). "Regulation of Methylbenzoate Emission after Pollination in Snapdragon and Petunia Flowers". The Plant Cell. 15 (12): 2992–3006. doi:10.1105/tpc.016766. ISSN 1532-298X. PMC 282847. PMID 14630969.
  24. ^ Arditti, Joseph (1980). "Aspects of the Physiology of Orchids". Advances in Botanical Research Volume 7. Vol. 7. pp. 421–655. doi:10.1016/s0065-2296(08)60091-9. ISBN 9780120059072.
  25. ^ Schuurink, Robert C.; Haring, Michel A.; Clark, David G. (2006). "Regulation of volatile benzenoid biosynthesis in petunia flowers". Trends in Plant Science. 11 (1): 20–25. doi:10.1016/j.tplants.2005.09.009. PMID 16226052.
  26. ^ Piechulla, B.; Effmert, U. (2010-01-01). "Biosynthesis and Regulation of Flower Scent". In Pua, Eng Chong; Davey, Michael R. (eds.). Plant Developmental Biology - Biotechnological Perspectives. Springer Berlin Heidelberg. pp. 189–205. doi:10.1007/978-3-642-04670-4_10. ISBN 9783642046698.
  27. ^ Arimura, Gen-ichiro; Matsui, Kenji; Takabayashi, Junji (2009-05-01). "Chemical and Molecular Ecology of Herbivore-Induced Plant Volatiles: Proximate Factors and Their Ultimate Functions". Plant and Cell Physiology. 50 (5): 911–923. doi:10.1093/pcp/pcp030. ISSN 0032-0781. PMID 19246460.
  28. ^ Peñuelas, Josep; Farré-Armengol, Gerard; Llusia, Joan; Gargallo-Garriga, Albert; Rico, Laura; Sardans, Jordi; Terradas, Jaume; Filella, Iolanda (2014-10-22). "Removal of floral microbiota reduces floral terpene emissions". Scientific Reports. 4: 6727. Bibcode:2014NatSR...4E6727P. doi:10.1038/srep06727. ISSN 2045-2322. PMC 4205883. PMID 25335793.
  29. ^ Tholl, Dorothea; Boland, Wilhelm; Hansel, Armin; Loreto, Francesco; Röse, Ursula S.R.; Schnitzler, Jörg-Peter (2006-02-01). "Practical approaches to plant volatile analysis". The Plant Journal. 45 (4): 540–560. doi:10.1111/j.1365-313X.2005.02612.x. ISSN 1365-313X. PMID 16441348.
  30. ^ Kim, Ki-Hyun; Kim, Yong-Hyun; Brown, Richard J. C. (2013-08-02). "Conditions for the optimal analysis of volatile organic compounds in air with sorbent tube sampling and liquid standard calibration: demonstration of solvent effect". Analytical and Bioanalytical Chemistry. 405 (26): 8397–8408. doi:10.1007/s00216-013-7263-9. ISSN 1618-2642. PMID 23907690. S2CID 25005504.
  31. ^ Macel, Mirka; Van DAM, Nicole M.; Keurentjes, Joost J. B. (2010-07-01). "Metabolomics: the chemistry between ecology and genetics". Molecular Ecology Resources. 10 (4): 583–593. doi:10.1111/j.1755-0998.2010.02854.x. ISSN 1755-0998. PMID 21565063. S2CID 11608830.
  32. ^ Parachnowitsch, Amy; Burdon, Rosalie C. F.; Raguso, Robert A.; Kessler, André (2013-01-01). "Natural selection on floral volatile production in Penstemon digitalis: Highlighting the role of linalool". Plant Signaling & Behavior. 8 (1): e22704. doi:10.4161/psb.22704. PMC 3745574. PMID 23221753.

December 15, 2023
floral, scent, flower, scent, composed, volatile, organic, compounds, vocs, aroma, compounds, emitted, floral, tissue, flower, petals, other, names, floral, scent, include, aroma, fragrance, floral, odour, perfume, flower, scent, most, flowering, plant, specie. Floral scent or flower scent is composed of all the volatile organic compounds VOCs or aroma compounds emitted by floral tissue e g flower petals Other names for floral scent include aroma fragrance floral odour or perfume Flower scent of most flowering plant species encompasses a diversity of VOCs sometimes up to several hundred different compounds 1 2 The primary functions of floral scent are to deter herbivores and especially folivorous insects see Plant defense against herbivory and to attract pollinators Floral scent is one of the most important communication channels mediating plant pollinator interactions along with visual cues flower color shape etc 3 Flowers of Lonicera japonica emit a sweet subtle fragrance mainly composed of linalool 4 Contents 1 Biotic interactions 1 1 Perception by flower visitors 1 2 Mediated biotic interactions 1 3 Plant plant communications 2 Biosynthesis of floral VOCs 3 Regulation of emissions 4 Measurement 4 1 VOCs sampling 4 2 Sample analysis 4 2 1 Desorption 4 2 2 Separation 4 2 3 Detection and identification 4 2 4 Quantification 4 3 Specificity of floral scent analysis 5 ReferencesBiotic interactions editPerception by flower visitors edit Flower visitors such as insects and bats detect floral scents thanks to chemoreceptors of variable specificity to a specific VOC The fixation of a VOC on a chemoreceptor triggers the activation of an antennal glomerulus further projecting on an olfactory receptor neuron and finally triggering a behavioral response after processing the information see also Olfaction Insect olfaction The simultaneous perception of various VOCs may cause the activation of several glomeruli but the output signal may not be additive due to synergistic or antagonistic mechanisms linked with inter neuronal activity 5 Therefore the perception of a VOC within a floral blend may trigger a different behavioral response than when perceived isolated Similarly the output signal is not proportional to the amount of VOCs with some VOCs in low amounts in the floral blend having major effects on pollinator behavior A good characterization of floral scent both qualitative and quantitative is necessary to understand and potentially predict flower visitors behavior Flower visitors use floral scents to detect recognize and locate their host species and even discriminate among flowers of the same plant 6 This is made possible by the high specificity of floral scent where both diversity of VOCs and their relative amount may characterize the flowering species an individual plant a flower of the plant and the distance of the plume from the source To make the best use of this specific information flower visitors rely on long term and short term memory that allows them to efficiently choose their flowers 7 They learn to associate the floral scent of a plant with a reward such as nectar and pollen 8 and have different behavioral responses to known scents versus unknown ones 9 They are also able to react similarly to slightly different odor blends 10 Mediated biotic interactions edit nbsp Pollinators use both floral scent and floral colour to locate flowers of Antirrhinum majus spp striatum 11 A primary function of floral scent is to attract pollinators and ensure the reproduction of animal pollinated plants Some families of VOCs presented in floral scents have likely evolved as herbivore repellents 12 However these plant defenses are also used by herbivores themselves to locate a plant resource similar to pollinators attracted by the floral scent 13 Therefore flower traits can be subject to antagonistic selection pressures positive selection by pollinators and negative selection by herbivores 14 Plant plant communications edit Plants have an array of volatile compounds they can release to signal other plants By unleashing these cues plants learn more about their environment and sufficiently respond However there are still many factors about plant scents scientists are still trying to understand Scientists have studied how many of the volatile compounds released by plants are from a floral source A study concluded that floral cues are as important as other volatile compounds and are pertinent for plant to plant communication 15 Further research found that plants who receive the floral volatiles have higher fitness than other volatile cues because floral cues are the only compounds released by plants that indicate their kind of mating environment 16 Plants are able to respond to these mating cues and change adjustable floral phenotypes that can affect plant pollination and mating Floral volatiles can ward off or attract pollinators mates all at once Depending on the number of floral signals released by a plant can control the level of attracting repelling the plant wants The composition of floral compounds and the rate of their release are the potential factors that control attraction repellence These two elements can be in response to ecological cues like high plant density and temperature 17 For instance in sexually deceptive orchids floral scents emitted after pollination reduce the flower s attractiveness to pollinators This mechanism acts as a signal to pollinators to visit unpollinated flowers 18 Environmental conditions can affect plant communication and signaling Signal factors include temperature and plant density Environmentally high temperatures increase the rate of releasing floral compounds which can increase the amount of signal released and thus its ability to reach more plants 17 When plant density increases plant communication increases as well since plants would be near each other and have signals reach many neighboring plants This can also increase the signal s reliability and lowering the chance the signal will degrade before it can reach other plants 17 Biosynthesis of floral VOCs editMost floral VOCs belong to three main chemical classes 2 6 VOCs in the same chemical class are synthesized from a shared precursor but the biochemical pathway is specific for each VOC and often varies from one plant species to another Terpenoids or isoprenoids are derived from isoprene and synthesized via the mevalonate pathway or the erythritol phosphate pathway They represent the majority of floral VOCs and are often the most abundant compounds in floral scent blends 19 The second chemical class is composed of the fatty acid derivatives synthesized from acetyl CoA most of which are known as green leaf volatiles because they are also emitted by vegetative parts i e leaves and stems of plants and sometimes higher in abundance than from floral tissue The third chemical class is composed of benzenoids phenylpropanoids also known as aromatic compounds they are synthesized from phenylalanine Regulation of emissions editFloral scent emissions of most flowering plants vary predictably throughout the day following a circadian rhythm This variation is controlled by light intensity 20 Maximal emissions coincide with peaks of the highest activity of visiting pollinators For instance snapdragon flowers mostly pollinated by bees have the highest emissions at noon whereas nocturnally visited tobacco plants have the highest emissions at night 21 Floral scent emissions also vary along with floral development with the highest emissions at anthesis 22 i e when the flower is fecund highly fertile and reduced emissions after pollination probably due to mechanisms linked with fecundation 23 In tropical orchids floral scent emission is terminated immediately following pollination reducing the expenditure of energy on fragrance production 24 In petunia flowers ethylene is released to stop the synthesis of benzenoid floral volatiles after successful pollination 25 Abiotic factors such as temperature atmospheric CO2 concentration hydric stress and soil nutrient status also impact the regulation of floral scent 26 For instance increased temperatures in the environment can increase the emission of VOCs in flowers potentially altering communication between plants and pollinators 17 Finally biotic interactions may also affect the floral scent Plant leaves attacked by herbivores emit new VOCs in response to the attack the so called herbivore induced plant volatiles HIPVs 27 Similarly damaged flowers have a modified floral scent compared to undamaged ones Micro organisms present in nectar may alter floral scent emissions as well 28 Measurement editMeasuring floral scent both qualitatively identification of VOCs and quantitatively absolute and or relative emission of VOCs requires the use of analytical chemistry techniques It requires collecting floral VOCs and then analyzing them VOCs sampling edit The most popular methods rely on adsorbing floral VOCs on an adsorbent material such as SPME fibers or cartridges by pumping air sampled around inflorescences through the adsorbent material It is also possible to extract chemicals stocked in petals by immersing them in a solvent and then analyze the liquid residue This is more adapted to the study of heavier organic compounds and or VOCs that are stored in floral tissue before being emitted into air Sample analysis edit Desorption edit Main article Desorption Thermal desorption the adsorbent material is flash heated so that all adsorbed VOCs are carried away from the adsorbent and injected into the separation system This is how work injectors in gas chromatography machines which literally volatilize introduced samples For VOCs adsorbed on bigger amount of adsorbent material such as cartridges thermal desorption may require the use of a specific machine a thermal desorber connected to the separation system Desorption by solvent VOCs adsorbed on the adsorbent material are carried away by a small quantity of solvent which is volatilized and injected in the separation system Most commonly used solvents are very volatile molecules such as methanol to avoid co elution with slightly heavier VOCsSeparation edit Gas chromatography GC is ideal to separate volatilized VOCs due to their low molecular weight VOCs are carried by a gas vector helium through a chromatographic column the solid phase on which they have different affinities which allows to separate them Liquid chromatography may be used for liquid extractions of floral tissue Detection and identification edit Separation systems are coupled with a detector that allows the detection and identification of VOCs based on their molecular weight and chemical properties The most used system for the analysis of floral scent samples is GC MS gas chromatography coupled with mass spectrometry Quantification edit Quantification of VOCs is based on the peak area measured on the chromatogram and compared to the peak area of a chemical standard 29 Internal calibration a known quantity of a specific chemical standard is injected together with the VOCs the measured area on the chromatogram is proportional to the injected quantity Because the chemical properties of VOCs alter their affinity to the solid phase the chromatographic column and subsequently the peak area on the chromatogram it is best to use several standards that reflect the best chemical diversity of the floral scent sample This method allows a more robust comparison among samples External calibration calibration curves quantity vs peak area are established independently by the injection of a range of quantities of chemical standard This method is best when the relative and absolute amount of VOCs in floral scent samples varies from sample to sample and from VOC to VOC and when the chemical diversity of VOCs in the sample is high However it is more time consuming and may be a source of errors e g matrix effects due to solvent or very abundant VOCs compared to trace VOCs 30 Specificity of floral scent analysis edit Floral scent is often composed of hundreds of VOCs in very variable proportions The method used is a tradeoff between accurately detecting quantifying minor compounds and avoiding detector saturation by major compounds For most analysis methods routinely used the detection threshold of many VOCs is still higher than the perception threshold of insects 31 which reduces our capacity to understand plant insect interactions mediated by floral scent Further the chemical diversity in floral scent samples is challenging The time of analysis is proportional to the range in molecular weight of VOCs present in the sample hence a high diversity will increase analysis time Floral scent may also be composed of very similar molecules such as isomers and especially enantiomers which tend to co elute and then to be very hardly separated Unambiguously detecting and quantifying them is of importance though as enantiomers may trigger very different responses in pollinators 32 References edit Knudsen Jette T Eriksson Roger Gershenzon Jonathan Stahl Bertil March 2006 Diversity and Distribution of Floral Scent The Botanical Review 72 1 1 120 doi 10 1663 0006 8101 2006 72 1 DADOFS 2 0 CO 2 S2CID 24559115 a b Piechulla B Effmert U 2010 Biosynthesis and Regulation of Flower Scent Plant Developmental Biology Biotechnological Perspectives Springer Berlin Heidelberg pp 189 205 doi 10 1007 978 3 642 04670 4 10 ISBN 9783642046698 Raguso Robert A December 2008 Wake Up and Smell the Roses The Ecology and Evolution of Floral Scent Annual Review of Ecology Evolution and Systematics 39 1 549 569 doi 10 1146 annurev ecolsys 38 091206 095601 El Sayed A M Mitchell V J McLaren G F Manning L M Bunn B Suckling D M 15 May 2009 Attraction of New Zealand Flower Thrips Thrips obscuratus to cis Jasmone a Volatile Identified from Japanese Honeysuckle Flowers Journal of Chemical Ecology 35 6 656 663 doi 10 1007 s10886 009 9619 3 PMID 19444522 S2CID 9504546 Cunningham J P 2012 02 01 Can mechanism help explain insect host choice PDF Journal of Evolutionary Biology 25 2 244 251 doi 10 1111 j 1420 9101 2011 02435 x ISSN 1420 9101 PMID 22225990 S2CID 25567175 a b Dudareva Natalia Negre Florence Nagegowda Dinesh A Orlova Irina October 2006 Plant Volatiles Recent Advances and Future Perspectives Critical Reviews in Plant Sciences 25 5 417 440 doi 10 1080 07352680600899973 S2CID 84019949 Chittka Lars Thomson James D Waser Nickolas M 1999 Flower Constancy Insect Psychology and Plant Evolution Naturwissenschaften 86 8 361 377 Bibcode 1999NW 86 361C doi 10 1007 s001140050636 ISSN 0028 1042 S2CID 27377784 Giurfa Martin 2007 07 17 Behavioral and neural analysis of associative learning in the honeybee a taste from the magic well Journal of Comparative Physiology A 193 8 801 824 doi 10 1007 s00359 007 0235 9 ISSN 0340 7594 PMID 17639413 S2CID 9164757 Junker Robert R Hocherl Nicole Bluthgen Nico 2010 07 01 Responses to olfactory signals reflect network structure of flower visitor interactions Journal of Animal Ecology 79 4 818 823 doi 10 1111 j 1365 2656 2010 01698 x ISSN 1365 2656 PMID 20412348 Guerrieri Fernando Schubert Marco Sandoz Jean Christophe Giurfa Martin 2005 02 22 Perceptual and Neural Olfactory Similarity in Honeybees PLOS Biol 3 4 e60 doi 10 1371 journal pbio 0030060 ISSN 1545 7885 PMC 1043859 PMID 15736975 Jaworski Coline C Andalo Christophe Raynaud Christine Simon Valerie Thebaud Christophe Chave Jerome Huang Shuang Quan 11 August 2015 The Influence of Prior Learning Experience on Pollinator Choice An Experiment Using Bumblebees on Two Wild Floral Types of Antirrhinum majus PLOS ONE 10 8 e0130225 Bibcode 2015PLoSO 1030225J doi 10 1371 journal pone 0130225 PMC 4532467 PMID 26263186 Schiestl Florian P 2010 05 01 The evolution of floral scent and insect chemical communication Ecology Letters 13 5 643 656 doi 10 1111 j 1461 0248 2010 01451 x ISSN 1461 0248 PMID 20337694 Theis Nina Adler Lynn S 2012 02 01 Advertising to the enemy enhanced floral fragrance increases beetle attraction and reduces plant reproduction Ecology 93 2 430 435 doi 10 1890 11 0825 1 ISSN 1939 9170 PMID 22624324 Strauss S and J Whittall 2006 Non pollinator agents of selection on floral traits Pp 120 138 in Ecology and evolution of flowers OUP Oxford Caruso Christina M Parachnowitsch Amy L 2016 01 01 Do Plants Eavesdrop on Floral Scent Signals Trends in Plant Science 21 1 9 15 doi 10 1016 j tplants 2015 09 001 ISSN 1360 1385 PMID 26476624 Harder Lawrence D Johnson Steven D August 2009 Darwin s beautiful contrivances evolutionary and functional evidence for floral adaptation New Phytologist 183 3 530 545 doi 10 1111 j 1469 8137 2009 02914 x ISSN 0028 646X a b c d Farre Armengol Gerard Filella Iolanda Llusia Joan Niinemets Ulo Penuelas Josep December 2014 Changes in floral bouquets from compound specific responses to increasing temperatures Global Change Biology 20 12 3660 3669 doi 10 1111 gcb 12628 PMC 5788256 PMID 24817412 Schiestl Florian P Ayasse Manfred 2001 02 01 Post pollination emission of a repellent compound in a sexually deceptive orchid a new mechanism for maximising reproductive success Oecologia 126 4 531 534 doi 10 1007 s004420000552 ISSN 1432 1939 PMID 28547238 S2CID 5035741 Gershenzon Jonathan Dudareva Natalia 18 June 2007 The function of terpene natural products in the natural world Nature Chemical Biology 3 7 408 414 doi 10 1038 nchembio 2007 5 PMID 17576428 Harmer Stacey L Hogenesch John B Straume Marty Chang Hur Song Han Bin Zhu Tong Wang Xun Kreps Joel A Kay Steve A 2000 12 15 Orchestrated Transcription of Key Pathways in Arabidopsis by the Circadian Clock Science 290 5499 2110 2113 Bibcode 2000Sci 290 2110H doi 10 1126 science 290 5499 2110 ISSN 0036 8075 PMID 11118138 S2CID 8920347 Kolosova Natalia Gorenstein Nina Kish Christine M Dudareva Natalia 2001 10 01 Regulation of Circadian Methyl Benzoate Emission in Diurnally and Nocturnally Emitting Plants The Plant Cell 13 10 2333 2347 doi 10 1105 tpc 010162 ISSN 1532 298X PMC 139162 PMID 11595805 Dudareva Natalia Murfitt Lisa M Mann Craig J Gorenstein Nina Kolosova Natalia Kish Christine M Bonham Connie Wood Karl 2000 06 01 Developmental Regulation of Methyl Benzoate Biosynthesis and Emission in Snapdragon Flowers The Plant Cell 12 6 949 961 doi 10 1105 tpc 12 6 949 ISSN 1532 298X PMC 149095 PMID 10852939 Negre Florence Kish Christine M Boatright Jennifer Underwood Beverly Shibuya Kenichi Wagner Conrad Clark David G Dudareva Natalia 2003 12 01 Regulation of Methylbenzoate Emission after Pollination in Snapdragon and Petunia Flowers The Plant Cell 15 12 2992 3006 doi 10 1105 tpc 016766 ISSN 1532 298X PMC 282847 PMID 14630969 Arditti Joseph 1980 Aspects of the Physiology of Orchids Advances in Botanical Research Volume 7 Vol 7 pp 421 655 doi 10 1016 s0065 2296 08 60091 9 ISBN 9780120059072 Schuurink Robert C Haring Michel A Clark David G 2006 Regulation of volatile benzenoid biosynthesis in petunia flowers Trends in Plant Science 11 1 20 25 doi 10 1016 j tplants 2005 09 009 PMID 16226052 Piechulla B Effmert U 2010 01 01 Biosynthesis and Regulation of Flower Scent In Pua Eng Chong Davey Michael R eds Plant Developmental Biology Biotechnological Perspectives Springer Berlin Heidelberg pp 189 205 doi 10 1007 978 3 642 04670 4 10 ISBN 9783642046698 Arimura Gen ichiro Matsui Kenji Takabayashi Junji 2009 05 01 Chemical and Molecular Ecology of Herbivore Induced Plant Volatiles Proximate Factors and Their Ultimate Functions Plant and Cell Physiology 50 5 911 923 doi 10 1093 pcp pcp030 ISSN 0032 0781 PMID 19246460 Penuelas Josep Farre Armengol Gerard Llusia Joan Gargallo Garriga Albert Rico Laura Sardans Jordi Terradas Jaume Filella Iolanda 2014 10 22 Removal of floral microbiota reduces floral terpene emissions Scientific Reports 4 6727 Bibcode 2014NatSR 4E6727P doi 10 1038 srep06727 ISSN 2045 2322 PMC 4205883 PMID 25335793 Tholl Dorothea Boland Wilhelm Hansel Armin Loreto Francesco Rose Ursula S R Schnitzler Jorg Peter 2006 02 01 Practical approaches to plant volatile analysis The Plant Journal 45 4 540 560 doi 10 1111 j 1365 313X 2005 02612 x ISSN 1365 313X PMID 16441348 Kim Ki Hyun Kim Yong Hyun Brown Richard J C 2013 08 02 Conditions for the optimal analysis of volatile organic compounds in air with sorbent tube sampling and liquid standard calibration demonstration of solvent effect Analytical and Bioanalytical Chemistry 405 26 8397 8408 doi 10 1007 s00216 013 7263 9 ISSN 1618 2642 PMID 23907690 S2CID 25005504 Macel Mirka Van DAM Nicole M Keurentjes Joost J B 2010 07 01 Metabolomics the chemistry between ecology and genetics Molecular Ecology Resources 10 4 583 593 doi 10 1111 j 1755 0998 2010 02854 x ISSN 1755 0998 PMID 21565063 S2CID 11608830 Parachnowitsch Amy Burdon Rosalie C F Raguso Robert A Kessler Andre 2013 01 01 Natural selection on floral volatile production in Penstemon digitalis Highlighting the role of linalool Plant Signaling amp Behavior 8 1 e22704 doi 10 4161 psb 22704 PMC 3745574 PMID 23221753 Retrieved from https en wikipedia org w index php title Floral scent amp oldid 1188059304, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.