Nutation (botany)

Last updated

Nutation refers to the bending movements of stems, roots, leaves and other plant organs caused by differences in growth in different parts of the organ. Circumnutation refers specifically to the circular movements often exhibited by the tips of growing plant stems, caused by repeating cycles of differences in growth around the sides of the elongating stem. [1] Nutational movements are usually distinguished from 'variational' movements caused by temporary differences in the water pressure inside plant cells (turgor).

Contents

Simple nutation occurs in flat leaves and flower petals, caused by unequal growth of the two sides of the surface. For example, in young leaf buds the outer surface of each leaflet grows faster, causing it to curve over its neighbors and form a compact bud. As the bud expands, growth becomes more rapid on the inner surface of the leaves, causing the bud to open and the leaves to flatten out. Similar inequality of growth, but more sharply localized, leads to the folding and rolling of the leaf in the bud, and to the changing shapes of flower petals.

A circumnutating plant stem Circumnutation.png
A circumnutating plant stem

Circumnutational movements are most obvious in growing seedlings, where the combination of circular movement and upward growth causes the tip to move up in a spiral path. The first detailed analysis of circumnutation was Charles Darwin's The Power of Movement in Plants; [2] [3] he concluded that most plant movements were modifications of circumnutation, but many counterexamples are now known. Circumnutation is not a direct response to gravity or the direction of illumination, but these factors and many physiological processes can influence its direction, timing and amplitude. [1]

Although the function of circumnutation in most plants is not known, many twining plants have adapted these movements to help them find and twine around vertical objects such as tree trunks, and to help tendrils find and wind around smaller supports. [4] [5] The growing tips of the vine or tendril initially swings in wide circles that maximize its chance of bumping into an obstacle (a potential support). Once the obstacle is encountered the circles tighten, causing the vine or tendril to wind around the support as it grows.

The possible theories for plant nutations

Over the last century, studies on plant nutations gave rise to three main theories about their origin: [1] [5]

New experiments in space showed that the presence of gravity involves and amplifies oscillations of plant shoots, while confirming the occurrence of reduced nutations. [11] [12] These findings support the "two-oscillator" hypothesis, which has been revisited to account for the effect of elastic deflections due to gravity loading, previously disregarded. [13] By means of a morphoelastic rod model, some studies showed that a Hopf-like bifurcation phenomenon occurs and elasticity plays an important role in determining the onset of oscillations. [14] [15] In particular, the plant shoot might undergo "exogenous" oscillations - which sum to the "endogenous" ones - as it reaches a critical length. [15]

Related Research Articles

<span class="mw-page-title-main">Vine</span> Plant with a growth habit of trailing or scandent stems or runners

A vine is any plant with a growth habit of trailing or scandent stems, lianas, or runners. The word vine can also refer to such stems or runners themselves, for instance, when used in wicker work.

<span class="mw-page-title-main">Apical dominance</span> Phenomenon where the central stem grows stronger than other stems

In botany, apical dominance is the phenomenon whereby the main, central stem of the plant is dominant over other side stems; on a branch the main stem of the branch is further dominant over its own side twigs.

<span class="mw-page-title-main">Tendril</span> Specialisation of plant parts used to climb or bind

In botany, a tendril is a specialized stem, leaf or petiole with a threadlike shape used by climbing plants for support and attachment, as well as cellular invasion by parasitic plants such as Cuscuta. There are many plants that have tendrils; including sweet peas, passionflower, grapes and the Chilean glory-flower. Tendrils respond to touch and to chemical factors by curling, twining, or adhering to suitable structures or hosts. Tendrils vary greatly in size from a few centimeters up to 27 inches for Nepenthes harryana The chestnut vine can have tendrils up to 20.5 inches in length. Normally there is only one simple or branched tendril at each node, but the aardvark cucumber can have as many as eight.

<span class="mw-page-title-main">Auxin</span> Plant hormone

Auxins are a class of plant hormones with some morphogen-like characteristics. Auxins play a cardinal role in coordination of many growth and behavioral processes in plant life cycles and are essential for plant body development. The Dutch biologist Frits Warmolt Went first described auxins and their role in plant growth in the 1920s. Kenneth V. Thimann became the first to isolate one of these phytohormones and to determine its chemical structure as indole-3-acetic acid (IAA). Went and Thimann co-authored a book on plant hormones, Phytohormones, in 1937.

<span class="mw-page-title-main">Cytokinin</span> Class of plant hormones promoting cell division

Cytokinins (CK) are a class of plant hormones that promote cell division, or cytokinesis, in plant roots and shoots. They are involved primarily in cell growth and differentiation, but also affect apical dominance, axillary bud growth, and leaf senescence.

<span class="mw-page-title-main">Amyloplast</span> Type of plastid, double-enveloped organelles in plant cells

Amyloplasts are a type of plastid, double-enveloped organelles in plant cells that are involved in various biological pathways. Amyloplasts are specifically a type of leucoplast, a subcategory for colorless, non-pigment-containing plastids. Amyloplasts are found in roots and storage tissues, and they store and synthesize starch for the plant through the polymerization of glucose. Starch synthesis relies on the transportation of carbon from the cytosol, the mechanism by which is currently under debate.

<span class="mw-page-title-main">Abscisic acid</span> Plant hormone

Abscisic acid is a plant hormone. ABA functions in many plant developmental processes, including seed and bud dormancy, the control of organ size and stomatal closure. It is especially important for plants in the response to environmental stresses, including drought, soil salinity, cold tolerance, freezing tolerance, heat stress and heavy metal ion tolerance.

<span class="mw-page-title-main">Coleoptile</span> Protective sheath in certain plants

Coleoptile is the pointed protective sheath covering the emerging shoot in monocotyledons such as grasses in which few leaf primordia and shoot apex of monocot embryo remain enclosed. The coleoptile protects the first leaf as well as the growing stem in seedlings and eventually, allows the first leaf to emerge. Coleoptiles have two vascular bundles, one on either side. Unlike the flag leaves rolled up within, the pre-emergent coleoptile does not accumulate significant protochlorophyll or carotenoids, and so it is generally very pale. Some preemergent coleoptiles do, however, accumulate purple anthocyanin pigments.

<span class="mw-page-title-main">Callus (cell biology)</span> Growing mass of unorganized plant parenchyma cells

Plant callus is a growing mass of unorganized plant parenchyma cells. In living plants, callus cells are those cells that cover a plant wound. In biological research and biotechnology callus formation is induced from plant tissue samples (explants) after surface sterilization and plating onto tissue culture medium in vitro. The culture medium is supplemented with plant growth regulators, such as auxin, cytokinin, and gibberellin, to initiate callus formation or somatic embryogenesis. Callus initiation has been described for all major groups of land plants.

<span class="mw-page-title-main">Thigmotropism</span> Directed growth of plants in response to touch

In plant biology, thigmotropism is a directional growth movement which occurs as a mechanosensory response to a touch stimulus. Thigmotropism is typically found in twining plants and tendrils, however plant biologists have also found thigmotropic responses in flowering plants and fungi. This behavior occurs due to unilateral growth inhibition. That is, the growth rate on the side of the stem which is being touched is slower than on the side opposite the touch. The resultant growth pattern is to attach and sometimes curl around the object which is touching the plant. However, flowering plants have also been observed to move or grow their sex organs toward a pollinator that lands on the flower, as in Portulaca grandiflora.

<span class="mw-page-title-main">Heliotropism</span> Motion of flowers or leaves to face the Sun

Heliotropism, a form of tropism, is the diurnal or seasonal motion of plant parts in response to the direction of the Sun.

<span class="mw-page-title-main">Hydrotropism</span>

Hydrotropism is a plant's growth response in which the direction of growth is determined by a stimulus or gradient in water concentration. A common example is a plant root growing in humid air bending toward a higher relative humidity level.

<span class="mw-page-title-main">Gravitropism</span> Plant growth in reaction to gravity

Gravitropism is a coordinated process of differential growth by a plant in response to gravity pulling on it. It also occurs in fungi. Gravity can be either "artificial gravity" or natural gravity. It is a general feature of all higher and many lower plants as well as other organisms. Charles Darwin was one of the first to scientifically document that roots show positive gravitropism and stems show negative gravitropism. That is, roots grow in the direction of gravitational pull and stems grow in the opposite direction. This behavior can be easily demonstrated with any potted plant. When laid onto its side, the growing parts of the stem begin to display negative gravitropism, growing upwards. Herbaceous (non-woody) stems are capable of a degree of actual bending, but most of the redirected movement occurs as a consequence of root or stem growth outside. The mechanism is based on the Cholodny–Went model which was proposed in 1927, and has since been modified. Although the model has been criticized and continues to be refined, it has largely stood the test of time.

<i>The Power of Movement in Plants</i> Book about tropism published by Charles Darwin in 1880

The Power of Movement in Plants is a book by Charles Darwin on phototropism and other types of movement in plants. This book continues his work in producing evidence for his theory of natural selection. As it was one of his last books, followed only by the publication of The Formation of Vegetable Mould through the Action of Worms, he was assisted by his son Francis in conducting the necessary experiments and preparing the manuscript. The Power of Movement in Plants was published 6 November 1880, and 1500 copies were quickly sold by publisher John Murray.

<span class="mw-page-title-main">Shade tolerance</span>

In ecology, shade tolerance is a plant's ability to tolerate low light levels. The term is also used in horticulture and landscaping, although in this context its use is sometimes imprecise, especially in labeling of plants for sale in commercial nurseries.

<span class="mw-page-title-main">Plant perception (physiology)</span> Plants interaction to environment

Plant perception is the ability of plants to sense and respond to the environment by adjusting their morphology and physiology. Botanical research has revealed that plants are capable of reacting to a broad range of stimuli, including chemicals, gravity, light, moisture, infections, temperature, oxygen and carbon dioxide concentrations, parasite infestation, disease, physical disruption, sound, and touch. The scientific study of plant perception is informed by numerous disciplines, such as plant physiology, ecology, and molecular biology.

<span class="mw-page-title-main">Astrobotany</span> Study of plants grown in spacecraft

Astrobotany is an applied sub-discipline of botany that is the study of plants in space environments. It is a branch of astrobiology and botany.

Important structures in plant development are buds, shoots, roots, leaves, and flowers; plants produce these tissues and structures throughout their life from meristems located at the tips of organs, or between mature tissues. Thus, a living plant always has embryonic tissues. By contrast, an animal embryo will very early produce all of the body parts that it will ever have in its life. When the animal is born, it has all its body parts and from that point will only grow larger and more mature. However, both plants and animals pass through a phylotypic stage that evolved independently and that causes a developmental constraint limiting morphological diversification.

<span class="mw-page-title-main">Plants in space</span> Growth of plants in outer space

The growth of plants in outer space has elicited much scientific interest. In the late 20th and early 21st century, plants were often taken into space in low Earth orbit to be grown in a weightless but pressurized controlled environment, sometimes called space gardens. In the context of human spaceflight, they can be consumed as food and/or provide a refreshing atmosphere. Plants can metabolize carbon dioxide in the air to produce valuable oxygen, and can help control cabin humidity. Growing plants in space may provide a psychological benefit to human spaceflight crews. Usually the plants were part of studies or technical development to further develop space gardens or conduct science experiments. To date plants taken into space have had mostly scientific interest, with only limited contributions to the functionality of the spacecraft, however the Apollo Moon tree project was more or less forestry inspired mission and the trees are part of a country's bicentennial celebration.

Stacey Harmer is a chronobiologist whose work centers on the study of circadian rhythms in plants. Her research focuses on the molecular workings of the plant circadian clock and its influences on plant behaviors and physiology. She is a professor in the Department of Plant Biology at the University of California, Davis.

References

  1. 1 2 3 Stolarz, Maria (28 October 2014). "Circumnutation as a visible plant action and reaction". Plant Signaling & Behavior. 4 (5): 380–387. doi:10.4161/psb.4.5.8293. PMC   2676747 . PMID   19816110. Circumnutation is a helical organ movement widespread among plants.
  2. 1 2 Darwin, Charles, 1809-1882, author. (2017). The power of movement in plants. ISBN   978-0-19-180518-9. OCLC   981425326.{{cite book}}: |last= has generic name (help)CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  3. Brown, Allan H. (September 28, 1992). "Circumnutations: From Darwin to Space Flights" (PDF). Plant Physiology. 101 (2): 345–348. doi:10.1104/pp.101.2.345. PMC   160577 . PMID   11537497.
  4. Fiorello, Isabella; Del Dottore, Emanuela; Tramacere, Francesca; Mazzolai, Barbara (2020-03-20). "Taking inspiration from climbing plants: methodologies and benchmarks—a review". Bioinspiration & Biomimetics. 15 (3): 031001. Bibcode:2020BiBi...15c1001F. doi: 10.1088/1748-3190/ab7416 . ISSN   1748-3190. PMID   32045368.
  5. 1 2 Mugnai, Sergio; Azzarello, Elisa; Masi, Elisa; Pandolfi, Camilla; Mancuso, Stefano (2015), Mancuso, Stefano; Shabala, Sergey (eds.), "Nutation in Plants", Rhythms in Plants: Dynamic Responses in a Dynamic Environment, Cham: Springer International Publishing, pp. 19–34, doi:10.1007/978-3-319-20517-5_2, ISBN   978-3-319-20517-5, S2CID   197438746 , retrieved 2021-03-02
  6. Gradmann, Hans (1927-04-01). "Die Kreisbewegungen der Ranken und der Windepflanzen". Naturwissenschaften (in German). 15 (15): 345–352. Bibcode:1927NW.....15..345G. doi:10.1007/BF01504773. ISSN   1432-1904. S2CID   22480027.
  7. Israelsson, D.; Johnsson, A. (1967). "A Theory for Circumnutations in Helianthus annuus". Physiologia Plantarum. 20 (4): 957–976. doi:10.1111/j.1399-3054.1967.tb08383.x. ISSN   1399-3054.
  8. Somolinos, Alfredo S. (1978). "Periodic solutions of the sunflower equation: 𝑥+(𝑎/𝑟)𝑥+(𝑏/𝑟)sin𝑥(𝑡-𝑟)=0". Quarterly of Applied Mathematics. 35 (4): 465–478. doi: 10.1090/qam/465265 . ISSN   0033-569X.
  9. "Scopus preview - Scopus - Welcome to Scopus". www.scopus.com. Retrieved 2021-03-02.
  10. "Google Scholar". scholar.google.com. Retrieved 2021-03-02.
  11. Johnsson, A.; Solheim, B. G. B.; Iversen, T.-H. (2009). "Gravity amplifies and microgravity decreases circumnutations in Arabidopsis thaliana stems: results from a space experiment". New Phytologist. 182 (3): 621–629. doi: 10.1111/j.1469-8137.2009.02777.x . ISSN   1469-8137. PMID   19320838.
  12. Kobayashi, Akie; Kim, Hye-Jeong; Tomita, Yuta; Miyazawa, Yutaka; Fujii, Nobuharu; Yano, Sachiko; Yamazaki, Chiaki; Kamada, Motoshi; Kasahara, Haruo; Miyabayashi, Sachiko; Shimazu, Toru (2019). "Circumnutational movement in rice coleoptiles involves the gravitropic response: analysis of an agravitropic mutant and space-grown seedlings". Physiologia Plantarum. 165 (3): 464–475. doi: 10.1111/ppl.12824 . ISSN   1399-3054. PMID   30159898. S2CID   52123435.
  13. Agostinelli, Daniele (2021-03-02). "The mystery of plant nutations: Is mathematics of any help?". Medium. Retrieved 2021-03-02.
  14. Agostinelli, Daniele; Lucantonio, Alessandro; Noselli, Giovanni; DeSimone, Antonio (March 2020). "Nutations in growing plant shoots: The role of elastic deformations due to gravity loading". Journal of the Mechanics and Physics of Solids. 136: 103702. Bibcode:2020JMPSo.13603702A. doi: 10.1016/j.jmps.2019.103702 .
  15. 1 2 Agostinelli, Daniele; DeSimone, Antonio; Noselli, Giovanni (2021). "Nutations in plant shoots: Endogenous and exogenous factors in the presence of mechanical deformations". Frontiers in Plant Science. 12: 608005. doi: 10.3389/fpls.2021.608005 . ISSN   1664-462X. PMC   8023405 . PMID   33833768.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.