“Antirrhinum majus”的意思、由来-开放百科全书

Antirrhinum majus (common snapdragon; often - especially in horticulture - simply "snapdragon") is a species of flowering plant belonging to the genus Antirrhinum. The plant was placed in the Plantaginaceae family following a revision its prior classical family, Scrophulariaceae.^[2] It is native to the Mediterranean region, from Morocco and Portugal north to southern France, and east to Turkey and Syria.^[3]^[4] The common name "snapdragon", originates from the flowers' reaction to having their throats squeezed, which causes the "mouth" of the flower to snap open like a dragon's mouth.

Description

It is an herbaceous perennial plant, growing to 0.5–1 m tall, rarely up to 2 m. The leaves are spirally arranged, broadly lanceolate, 1–7 cm long and 2-2.5 cm broad. The flowers are produced on a tall spike, each flower is 3.5-4.5 cm long, zygomorphic, with two 'lips' closing the corolla tube; wild plants have pink to purple flowers, often with yellow lips. The fruit is an ovoid capsule 10–14 mm diameter, containing numerous small seeds.

^[5] The plants are pollinated by bumblebees, and the flowers close over the insects when they enter and deposit pollen on their bodies.

Taxonomy

Cultivation

Antirrhinum majus to some extent can survive frost as well as higher temperature, but does best at temperatures around 17–25 °C. Nighttime temperatures around 15–17 °C encourage growth in both the apical meristem and stem of A. majus.^[2] The species is able to grow well from seeds, flowering quickly in 3 to 4 months. It is also able to be grown through cutting.

Though perennial, the species is often cultivated as a biennial or annual plant, particularly in colder areas where it may not survive the winter. Numerous cultivars are available, including plants with lavender, orange, pink, yellow, or white flowers, and also plants with peloric flowers, where the normal flowering spike is topped with a single large, symmetrical flower.^[5]^[6] The cultivars ’Floral Showers Deep Bronze’^[7]

The trailing (creeping) variety is often referred to as A. majus pendula (syn. A. pendula, A. repens).

It often escapes from cultivation, and naturalised populations occur widely in Europe north of the native range,^[5] and elsewhere in temperate regions of the world.^[4]

Model research organism

In the laboratory it is a model organism,^[9] for example containing the gene DEFICIENS which provides the letter "D" in the acronym MADS-box for a family of genes which are important in plant development. Antirrhinum majus has been used as a model organism in biochemical and developmental genetics for nearly a century. Many of the characteristics of A. majus made it desirable as a model organism; these include its diploid inheritance, ease of cultivation (having a relatively short generation time of around 4 months), its ease of both self-pollination and cross-pollination, and A. majus's variation in morphology and flowering color. It also benefits from its divergence from Arabidopsis thaliana, with A. thaliana's use as a common eudicot model, it has been used to compare against A. majus in developmental studies.^[2]

Studies in A. majus have also been used to suggest that, at high temperatures, DNA methylation is not vital in suppressing the Tam3 transposon. Previously, it was suggested that DNA methylation was important in this process, this theory coming from comparisons of the degrees of methylation when transposition is active and inactive. However, A. majus's Tam3 transposon process did not completely support this. Its permission of transposition at 15 °C and strong suppression of transposition at temperatures around 25 °C showed that suppression of the transposition state was unlikely to be caused by the methylation state.^[10] It was shown that low temperature-dependent transposition was the cause of the methylation/demethylation of Tam3, not the other way around as previously believed. It was shown in a study that decreases in the methylation of Tam3 were found in tissue that was still developing at cooler temperatures, but not in tissue that was developed or grown in hotter temperatures.^[11]

Another role A. majus played in examining the relationship between pollinator and plant were in the studies of floral scents. Two of A. majus's enzymes, phenylpropanoids and isoprenoids, were used in the study of its floral scent production and the scent's effect on attracting pollinators.^[2]

Chemistry

Antirrhinin is an anthocyanin found in A. majus.^[13] It is the 3-rutinoside of cyanidin.

Pests and Diseases

Pests

Diseases

References

1. ^{{cite journal | year = 2006 | title = Review of the systematics of Scrophulariaceae s.l. and their current disposition | journal = Australian Systematic Botany | volume = 19 | issue = 4 | pages = 289–307 | doi = 10.1071/SB05009 | last1 = Tank | first1 = David C. | last2 = Beardsley | first2 = Paul M. | last3 = Kelchner | first3 = Scot A. | last4 = Olmstead | first4 = Richard G.}}
2. ^¹²³⁴⁵⁶{{Cite journal|last=Hudson|first=Andrew|last2=Critchley|first2=Joanna|last3=Erasmus|first3=Yvette|date=2008-10-01|title=The Genus Antirrhinum (Snapdragon): A Flowering Plant Model for Evolution and Development|journal=Cold Spring Harbor Protocols|language=en|volume=2008|issue=10|pages=pdb.emo100|doi=10.1101/pdb.emo100|issn=1940-3402|pmid=21356683}}
3. ^¹Flora Europaea: Antirrhinum majus
4. ^¹²{{GRIN | accessdate = 24 December 2017}}
5. ^¹²{{Cite book|author1=Blamey, M. |author2=Grey-Wilson, C. |year=1989|title=Flora of Britain and Northern Europe|isbn= 978-0-340-40170-5}}
6. ^{{Cite book|editor=Huxley, A|year=1992|title=New RHS Dictionary of Gardening|isbn= 978-0-333-47494-5}}
7. ^{{cite web | url= https://www.rhs.org.uk/Plants/233162/i-Antirrhinum-majus-i-Floral-Showers-Deep-Bronze-(Floral-Showers-Series)/Details|title = RHS Plantfinder - Antirrhinum majus 'Floral Showers Deep Bronze'| accessdate=12 January 2018}}
8. ^{{cite web | url= https://www.rhs.org.uk/Plants/233137/i-Antirrhinum-majus-i-Montego-Pink-(Montego-Series)/Details| title = RHS Plantfinder - Antirrhinum majus ' Montego Pink'| accessdate=13 January 2018}}
9. ^{{cite journal|last2=Baum|first2=D. A.|year=2004|title=Phylogenetic relationships of North American Antirrhinum (Veronicaceae)|journal=American Journal of Botany|volume=91|issue=6|pages=918–25|doi=10.3732/ajb.91.6.918|pmid=21653448|last1=Oyama|first1=R. K.}}
10. ^{{Cite journal|last=Hashida|first=Shin-nosuke|last2=Kishima|first2=Yuji|last3=Mikami|first3=Tetsuo|date=2005-11-01|title=DNA methylation is not necessary for the inactivation of the Tam3 transposon at non-permissive temperature in Antirrhinum|journal=Journal of Plant Physiology|volume=162|issue=11|pages=1292–1296|doi=10.1016/j.jplph.2005.03.003|issn=0176-1617|pmid=16323282}}
11. ^{{Cite journal|last=Hashida|first=Shin-Nosuke|last2=Uchiyama|first2=Takako|last3=Martin|first3=Cathie|last4=Kishima|first4=Yuji|last5=Sano|first5=Yoshio|last6=Mikami|first6=Tetsuo|date=2017-04-21|title=The Temperature-Dependent Change in Methylation of the Antirrhinum Transposon Tam3 Is Controlled by the Activity of Its Transposase|journal=The Plant Cell|volume=18|issue=1|pages=104–118|doi=10.1105/tpc.105.037655|issn=1040-4651|pmc=1323487|pmid=16326924}}
12. ^{{Cite journal|last=Glover|first=Beverley J.|last2=Martin|first2=Cathie|date=1998-06-01|title=The role of petal cell shape and pigmentation in pollination success in Antirrhinum majus|journal=Heredity|language=en|volume=80|issue=6|pages=778–784|doi=10.1046/j.1365-2540.1998.00345.x|issn=0018-067X}}
13. ^{{Cite journal|year=1930|title=Natural anthocyanin pigments: The magenta flower pigment of Antirrhinum majus|journal=Biochemical Journal|volume=24|issue=3|pages=753–766|pmc=1254517|pmid=16744416|last1=Scott-Moncrieff|first1=R|doi=10.1042/bj0240753}}
14. ^¹²³⁴{{Cite web|url=http://edis.ifas.ufl.edu/fp044|title=Antirrhinum majus Snapdragon|last=Gilman|first=Edward F.|date=2015-05-18|website=edis.ifas.ufl.edu|language=en|access-date=2017-04-17}}