Diplotaxis tenuifolia explained

Diplotaxis tenuifolia is a species of flowering plant in the mustard family known by the common name perennial wall-rocket. It is native to Europe and western Asia, where it grows on disturbed ground and roadsides, and it can now be found throughout much of the temperate world where it has naturalized. In recent years it has increasingly been cultivated to produce salad leaves, which are marketed as wild rocket in Britain or arugula in the US. It is easily confused with garden rocket, which has similar uses.

Description

Perennial wall-rocket is a glabrous herb with an erect or sprawling habit, that grows up to 1.3 m tall, with a solid, almost woody terete stem and spreading branches.The deeply pinnate leaves are up to 12 cm long and often rather fleshy, with a peppery taste and a musty smell.[1]

In the British Isles, it flowers from May to September[1] (or through October in a warm year).[2] In Spain, it can be seen flowering between April and December. The inflorescence is a branched raceme up to 30 cm long with up to 30 flowers, each of which has 4 free bright yellow petals up to 15 mm long, and 4 free yellow/brown sepals up to 7.5 mm long. Each flower has 6 stamens and a single style.[3] [4]

The fruit is a straight, flat silique (pod) up to five centimeters long. The pedicels are shorter than the fruits and ascend at an acute angle to the stem. Above the receptacle is a short (2 mm) stalk (or stipe) below the pod (a useful feature for separating this species from annual wall-rocket). The seeds are arranged in 2 rows, or staggered in a zigzag pattern, towards the centre of the pod, which in turn consists of 2 valves, so a cross-section of the fruit shows 4 seeds in total. This is a distinguishing feature of the genus Diplotaxis, although it is not always easy to see, as plants are not self-pollinating, so ripe seeds do not always develop.

Taxonomy

The original name (basionym) of perennial wall-rocket is Sisymbrium tenuifolium, published by Linnaeus in 1755,[5] but it was transferred to the new genus Diplotaxis by de Candolle in 1821. It has been given many other names (synonyms) over the years, within the diverse genera Arabis (rockcresses), Brassica (mustards), Crucifera, Eruca (rockets), Erysimum (wallflowers) and Sinapis (charlock), which reflects the complex history of crucifer taxonomy. A full list is maintained by the Catalogue of Life Partnership.

There is only one currently recognised subspecies: Diplotaxis tenuifolia subsp. cretacea (Kotov) Sobr.-Vesp., which was described in 1996 and which is restricted to Ukraine and western Russia.[6]

D. tenuifolia is assumed to have hybridised with D. viminea resulting in D. muralis. [7] It has also been hybridised with Raphanus sativus.[8]

The chromosome number is 2n = 22 (based on British material).

The generic name Diplotaxis comes from the Ancient Greek, διπλός (diplos) = twofold, or double; and τάσσω, τάσσειν (tasso, tassein), which means to put into order, or to draw up in a line (as with troops before a battle). It refers to the double row of seeds in each part of the fruit, which distinguishes this genus from others within the Brassicaceae. The specific epithet tenuifolia simply means "narrow-leafed".[9]

The common name "rocket" is a corruption of the Italian word ruchetta, which describes various cruciferous plants. This species is also sometimes called wild rocket, sand rocket, Lincoln weed (mainly in Australia) and white rocket; the seeds are sometimes marketed as "wild Italian arugula" or "sylvetta arugula".

Identification

In Britain it is most likely to be confused with annual wall-rocket, but it does not have a basal rosette, the leaves are divided more than halfway to the midrib, and the fruit has a short stalk (stipe) above the sepal scars.

The Diplotaxis species can be separated from most other crucifers by the double row of seeds in each valve of the fruit (although this is a difficult feature to see in unfertilised plants) and a seedless beak to the silique.[10]

Distribution

It is native to parts of Europe, reaching in the east to Turkey and Syria. It is extinct from Morocco and Algeria, but has been introduced in a number of regions: Cyprus, the Caucasus, Palestine, Yemen, Japan, Australia, New Zealand, New Caledonia, Canada (Ontario, Quebec and Nova Scotia), the United States, Costa Rica, Argentina and Uruguay.[11]

Within Europe, its native range covers much of France, the Low Countries, Italy, the Pannonian Basin and the western Balkans up to Macedonia, with generally more thinly scattered populations in northern Greece, Bulgaria, Romania, Crimea, Sicilly, Malta, Sardinia, Corsica and parts of Spain.[12] It has extensively been introduced further north from its native range. In the British Isles the plant is an archaeophyte, with industrial regions and ports still at the centre of the distribution. It is established especially in parts of England and Wales (some believing the plant could even be native to the south-east). Its range has been expanding to the west since the 19th century, but it is still very rare in Scotland and Ireland.[13] It has also been introduced into much of Central Europe: throughout Switzerland, Austria, Germany and Poland, with more scattered instances on the southern shores of Norway and Sweden (where it is found in fewer areas that in the recent past), the Baltic States, Belarus and a few locations further east in Ukraine and European Russia. It has also been introduced on Menorca and near Lisbon in Portugal.[12]

Ecology

It is a ruderal plant of roadsides and waste ground.[1] It generally grows in places where there is full sunlight and requires moderately damp soils with a slightly alkaline reaction and moderately fertile conditions. It is tolerant of occasional salinity, which allows it to grow on the upper part of beaches and along salt-treated road verges. The Ellenberg values in Britain are L = 8, F = 5, R = 7, N = 6, and S = 1.[14] In Spain, it can be found at elevations of up to 800m.[15]

There are 11 species of insect that are known to feed on perennial wall-rocket in Britain.[16] Five of these are weevils (Curculionidae): Ceutorhynchus contractus (Marsham) (the cabbage leaf weevil), Ceutorhynchus picitarsis Gyllenhal, C. timidus Weise (= C. chalibaeus Germar, 1824),[17] Otiorhynchus ligneus (Olivier) and O. ovatus (L.).

Ceutorhynchus contractus and C. picitarsis adults consume the leaves and stems of this plant, whereas the larvae of C. chalibaeus make galls 1-2 cm long in the petioles. The two broad-nosed weevils (Otiorhynchus ligneus and O. ovatus) feed on the roots. All five species are polyphagous and widespread. [18]

Four of the phytophagous insects are Diptera (flies). The midge Contarinia nasturtii (Kieffer) has larvae that infest the stems, leaves and flowerheads, causing distortion and sterility. Dasineura brassicae (Winnertz) (previously D. napi (Loew)) is the brassica pod midge, an invasive non-native pest in Britain which causes damage to the developing seedpods. It is particularly of importance on rapeseed crops, but it can also infest wild plants of perennial wall-rocket.[19] Gephyraulus raphanistri (Kieffer) is a gall midge that destroys the flowerheads.[20] None of these species is restricted to wall-rocket and most are quite common, although the NBN Atlas has no records of brassica pod midge on wild plants in Britain as of 2022.

Finally, three species of Lepidoptera (butterflies and moths) are listed. Pieris brassicae (L.) is the common cabbage white butterfly, whose larvae eat the leaves and stems of this and many other species of Brassicaceae; Evergestis extimalis (Scopoli) is a micromoth whose larvae feed in the flowerheads; and Sitochroa verticalis (L.) (the lesser pearl) is also a micromoth, the larvae of which are found on a wide variety of plants.

Uses

Baby leaf rocket is cultivated worldwide as a salad leaf. In addition to D. tenuifolia, the annual Eruca sativa is grown and marketed under the same common names. These leaves are usually mixed with other baby leaf crops to form a mesclun-style salad. These crops have become popular due to their distinctive taste and texture in salads.

Leaves preserved at 5 °C show a loss of ascorbic acid and glucosinolates and an increase in polyphenols (then preservation after harvesting may be nutritionally good, since for example sinapic acid and ferulic acid have anti-cancer effects and umbelliferone is an anti-oxidant).

Wild rocket is high in ascorbic acid, carotenoids, polyphenols and glucosinolates (above all glucosativin and glucoerucin, which are the cause of the pungent flavour). When the leaves are chewed glucosinolates, through the enzyme myrosinase, are metabolized in isothiocyanates[21] and indoles.[22]

One of Trotula's works, Treatments for Women mentions "wild rocket cooked in wine" in a remedy for sanious flux in women.[23]

External links

Notes and References

  1. Book: Rich, T.C.G.. 1991. Crucifers of Great Britain and Ireland . London. Botanical Society of the British Isles. 0901158208. 100.
  2. Web site: Not a Horticulturist . Tag: Diplotaxis Tenuifolia . 15 October 2022.
  3. Book: Rose . Francis . The Wild Flower Key . 2006 . Frederick Warne . London. 978-0-7232-5175-0.
  4. Book: Stace . C.A. . New Flora of the British Isles . 2019 . Suffolk . 978-1-5272-2630-2.
  5. Web site: Global Biodiversity Information Facility . Diplotaxis tenuifolia (L.) DC. . 6 October 2022.
  6. Web site: Global Biodiversity Information Facility . Diplotaxis tenuifolia subsp. cretacea (Kotov) Sobr.-Vesp. . 6 October 2022.
  7. Ueno . O. . Wada . Y. . Wakai . M. . Bang . S. W. . March 2006 . Evidence from Photosynthetic Characteristics for the Hybrid Origin of Diplotaxis muralis from a C 3 ‐C 4 Intermediate and a C 3 Species . Plant Biology . en . 8 . 2 . 253–259 . 10.1055/s-2005-873050 . 16547870 . 2006PlBio...8..253U . 260250600 . 1435-8603.
  8. 10.1104/pp.103.021329 . 167093 . 12857835 . Structural and Biochemical Dissection of Photorespiration in Hybrids Differing in Genome Constitution between Diplotaxis tenuifolia (C3-C4) and Radish (C3) . 2003 . Ueno . Osamu . Bang . Sang Woo . Wada . Yoshiharu . Kondo . Ayumu . Ishihara . Kuni . Kaneko . Yukio . Matsuzawa . Yasuo . Plant Physiology . 132 . 3 . 1550–1559 .
  9. Book: Stearn . William T. . Botanical Latin: History, Grammar, Syntax, Terminology and Vocabulary . 1980 . David & Charles . Newton Abbot . 0-7153-5645-3.
  10. Caruso . G.. Parrella . G. . Giorgini . M. . Nicoletti . R. . Crop Systems, Quality and Protection of Diplotaxis tenuifolia . Agriculture . 2018 . 8 . 4 . 55 . 10.3390/agriculture8040055. free .
  11. 1028648-2. Diplotaxis tenuifolia (L.) DC. . 17 June 2022.
  12. Book: Jalas. J.. Suominen. J.. Lampinen. R.. 1996. Atlas Florae Europaeae. Distribution of Vascular Plants in Europe. 11. Cruciferae (Ricotia to Raphanus). The Committee for Mapping the Flora of Europe & Societas Biologica Fennica Vanamo. Helsinki. 951-9108-11-4. 231.
  13. Web site: Diplotaxis tenuifolia. Online Atlas of the British and Irish Flora. 17 June 2022.
  14. Book: Hill. M.O.. Mountford. J.O.. Roy. D.B.. Bunce. R.G.H.. Ellenberg's indicator values for British plants. ECOFACT Volume 2. Technical Annex. 1999. Institute of Terrestrial Ecology. 1870393481. 29 May 2017.
  15. Book: Martínez Laborde, J.B.. Diplotaxis L.. Flora iberica. 4. Cruciferae-Monotropaceae. 1993. http://www.floraiberica.es/floraiberica/texto/pdfs/04_072_57_Diplotaxis.pdf. 349.
  16. Web site: Biological Records Centre . Insects and their food plants .
  17. Web site: Plant Parasites of Europe . Ceutorhynchus chalibaeus . 16 October 2022.
  18. Web site: National Biodiversity Network . Atlas . 16 October 2022.
  19. Web site: CABI . Invasive Species Compendium: Dasineura brassicae datasheet . 16 October 2022.
  20. Web site: Plant Parasites of Europe . Gephyraulus raphanistri (Kieffer, 1886) . 16 October 2022.
  21. Spadafora ND, Amaro AL, Pereira MJ, Müller CT, Pintado M, Rogers HJ . 15 November 2016 . Multi-trait analysis of post-harvest storage in rocket salad (Diplotaxis tenuifolia) links sensorial, volatile and nutritional data . Food Chem . 211 . 114–123 . 10.1016/j.foodchem.2016.04.107 . 27283614 . free .
  22. Bell L, Oruna-Concha MJ, Wagstaff C. 1 April 2015. Identification and quantification of glucosinolate and flavonol compounds in rocket salad (Eruca sativa, Eruca vesicaria and Diplotaxis tenuifolia) by LC-MS: highlighting the potential for improving nutritional value of rocket crops. . Food Chem . 172 . 852–861 . 10.1016/j.foodchem.2014.09.116 . 25442630. 4245720.
  23. Book: Green, Monica H.. The Trotula : an English translation of the medieval compendium of women's medicine. 2002. University of Pennsylvania Press. Philadelphia. 978-0812218084. 97.