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Plant cells can be electrically excitable and can display rapid electrical responses (]s) to environmental stimuli. These action potentials can influence processes such as ]-based cytoplasmic streaming, ], wound responses, respiration, ] and flowering.<ref>Wagner E, Lehner L, Normann J, Veit J, Albrechtova J (2006). Hydroelectrochemical integration of the higher plant—basis for electrogenic flower induction. pp 369–389 In: Balusˇka F, Mancuso S, Volkmann D (eds) Communication in plants: neuronal aspects of plant life. Springer, Berlin.</ref><ref>Fromm J, Lautner S. (2007). Electrical signals and their physiological significance in plants. Plant Cell Environ. 30(3):249-57. {{DOI|10.1111/j.1365-3040.2006.01614.x}} PMID 17263772</ref><ref>{{cite pmid|19129416}}</ref><ref>{{cite jstor|4353850}}</ref> | Plant cells can be electrically excitable and can display rapid electrical responses (]s) to environmental stimuli. These action potentials can influence processes such as ]-based cytoplasmic streaming, ], wound responses, respiration, ] and flowering.<ref>Wagner E, Lehner L, Normann J, Veit J, Albrechtova J (2006). Hydroelectrochemical integration of the higher plant—basis for electrogenic flower induction. pp 369–389 In: Balusˇka F, Mancuso S, Volkmann D (eds) Communication in plants: neuronal aspects of plant life. Springer, Berlin.</ref><ref>Fromm J, Lautner S. (2007). Electrical signals and their physiological significance in plants. Plant Cell Environ. 30(3):249-57. {{DOI|10.1111/j.1365-3040.2006.01614.x}} PMID 17263772</ref><ref>{{cite pmid|19129416}}</ref><ref>{{cite jstor|4353850}}</ref> | ||
==Plant perception== | |||
{{Main|Plant perception (physiology)}} | |||
Plants have many ]. For example, they can produce different toxins (]s) against invaders or they can induce rapid ] in invading cells to hinder the pests from spreading out. These strategies depend on quick and reliable recognition-systems. | |||
===Light=== | |||
{{Main|Photomorphogenesis|photoperiodism}} | |||
Plants also can detect harmful ultraviolet B-rays and then start producing pigments which filter out these rays.<ref>Åke Strid and Robert J. Porra. . Plant and Cell Physiology, 1992, Vol. 33, No. 7 1015-1023</ref> | |||
===Contact stimuli=== | |||
{{Main|Thigmotropism|Thigmomorphogenesis}} | |||
The mimosa plant ('']'') makes its thin leaves point down at the slightest touch and ]s such as the ] snap shut by the touch of insects. {{citation needed|date=November 2011}} | |||
] levels also increase rapidly in response to mechanical perturbations such as tendril coiling.<ref>{{cite doi|10.1007/BF00201050}}</ref> | |||
==Plant adaptation vs plant intelligence== | ==Plant adaptation vs plant intelligence== |
Revision as of 23:41, 3 September 2012
It has been suggested that this article be merged into Plant perception (physiology). (Discuss) Proposed since September 2012. |
In botany, plant intelligence is the ability of plants to sense the environment and adjust their morphology, physiology and phenotype accordingly.
Intelligence is an umbrella term describing abilities such as the capacities for abstract thought, understanding, communication, reasoning, learning, learning from past experiences, planning, and problem solving. Studies indicate plants are capable of problem solving and communication.
Problem solving
Plants adapt their behaviour in a variety of ways:
- Active foraging for light and nutrients. They do this by changing their architecture, physiology and phenotype.
- Leaves and branches are positioned and oriented in response to light source.
- Ability to detect soil volume and adapt growth accordingly independently of nutrient availability.
- Adaptively defend against herbivores.
Mechanisms
Main articles: Signal transduction, Plant neurobiology, and Plant hormoneIn plants, the mechanism responsible for adaptation is signal transduction. Plants do not have a brain or neuronal network, but reactions within signalling pathways may provide a biochemical basis for learning and memory. Controversially, the brain is used as a metaphor in plant intelligence to provide an integrated view of signalling, (see plant neurobiology).
Plant cells can be electrically excitable and can display rapid electrical responses (action potentials) to environmental stimuli. These action potentials can influence processes such as actin-based cytoplasmic streaming, plant organ movements, wound responses, respiration, photosynthesis and flowering.
Plant adaptation vs plant intelligence
It has been argued that although plants are capable of adaptation, it should not be called intelligence. "A bacterium can monitor its environment and instigate developmental processes appropriate to the prevailing circumstances, but is that intelligence? Such simple adaptation behaviour might be bacterial intelligence but is clearly not animal intelligence." However, plant intelligence fits with the definition of intelligence proposed by David Stenhouse in a book he wrote about evolution where he described it as "adaptively variable behaviour during the lifetime of the individual".
It is also argued that a plant cannot have goals because operational control of the plant's organs is devolved.
History
Charles Darwin studied the movement of plants and in 1880 published a book The Power of Movement in Plants. In the book he concludes:
It is hardly an exaggeration to say that the tip of the radicle thus endowed acts like the brain of one of the lower animals; the brain being situated within the anterior end of the body, receiving impressions from the sense-organs, and directing the several movements.
See also
References
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instead. - ^ De Kroon, H. and Hutchings, M.J. (1995) Morphological plasticity in clonal plants: the foraging concept reconsidered. J. Ecol. 83, 143–152
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instead. - Scheel, Dierk; Wasternack, C. (2002). Plant signal transduction. Oxford: Oxford University Press. ISBN 0-19-963879-9.
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instead. - Wagner E, Lehner L, Normann J, Veit J, Albrechtova J (2006). Hydroelectrochemical integration of the higher plant—basis for electrogenic flower induction. pp 369–389 In: Balusˇka F, Mancuso S, Volkmann D (eds) Communication in plants: neuronal aspects of plant life. Springer, Berlin.
- Fromm J, Lautner S. (2007). Electrical signals and their physiological significance in plants. Plant Cell Environ. 30(3):249-57. doi:10.1111/j.1365-3040.2006.01614.x PMID 17263772
- Attention: This template ({{cite pmid}}) is deprecated. To cite the publication identified by PMID 19129416, please use {{cite journal}} with
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instead. - http://www.newscientist.com/article/mg17523535.700-not-just-a-pretty-face.html