Brassica oleracea, also known as wild cabbage in its uncultivated form, is a plant of the family Brassicaceae. The species originated from feral populations of related plants in the Eastern Mediterranean, where it was most likely first cultivated. It has many common used as vegetables, including cabbage, broccoli, cauliflower, kale, Brussels sprout, collard, Savoy cabbage, kohlrabi, and gai lan.
Description
Wild
B. oleracea is a tall
biennial plant or
perennial plant
that forms a stout rosette of large
leaves in the first year. The grayish-green leaves are fleshy and thick,
helping the plant store water and nutrients in difficult environments. In its second year, a woody spike grows up to tall, from which branch off stems with long clusters of yellow four-petaled flowers.
Taxonomy
Origins
According to the Triangle of U theory,
B. oleracea is very closely related to five other species of the genus
Brassica.
A 2021 study suggests that
Brassica cretica, native to the Eastern Mediterranean, particularly Greece and the
Aegean Islands, was the closest living relative of cultivated
B. oleracea, thus supporting the view that its cultivation originated in the Eastern Mediterranean region, with later admixture from other
Brassica species.
Genetic analysis of nine wild populations on the French Atlantic coast indicated their common
feral origin, deriving from domesticated plants escaped from fields and gardens.
The cultivars of B. oleracea are grouped by developmental form into several major , of which the Acephala group remains most like the natural wild cabbage in appearance.
Etymology
'Brassica' was Pliny the Elder's name for several cabbage-like plants.
[Gledhill, David (2008). "The Names of Plants". Cambridge University Press. (hardback), (paperback). pp 76]
Its specific epithet oleracea means "vegetable/herbal" in Latin and is a form of (oleraceus).
Distribution and habitat
Although rarely abundant, wild cabbage is found on the coasts of Britain, France, Spain, and Italy.
Wild cabbage is a hardy plant with high tolerance for Sodium chloride and lime. Its intolerance of competition from other plants
Cultivation
B. oleracea has become established as an important human food
agriculture plant, used because of its large food reserves, which are stored over the winter in its leaves. It has been bred into a wide range of
, including cabbage, broccoli, cauliflower, brussels sprouts, collards, and kale, some of which are hardly recognizable as being members of the same genus, let alone species.
The historical genus of Crucifera, meaning "cross-bearing" in reference to the four-petaled flowers, may be the only unifying feature beyond taste.
B. oleracea is tolerant of a variety of soil conditions between pH 6.0 and 7.5, but grows particularly well in alkaline soils in full sunlight,
Researchers believe that B. oleracea has been cultivated for several thousand years, but its history as a domesticated plant is not clear before ancient Greece and ancient Rome times, when it was a well-established garden vegetable. Theophrastus mentions three kinds of (ῤάφανος):[Compare Theophrastus; raphanis (ραφανίς), "radish", also a Brassica.] a curly-leaved, a smooth-leaved, and a wild-type.[Theophrastus, Enquiry into Plants, IV.6.16; Deipnosophistae, I, noting the effects of cabbages on wine and wine-drinkers, also quotes Apollodorus of Carystus: "If they think that our calling it a , while you foreigners call it a Crambe, makes any difference to us women!" ( on-line English text).]
History
Through artificial selection for various phenotype traits, the emergence of variations of the plant with drastic differences in appearance occurred over centuries. Preference for leaves,
terminal buds,
lateral buds, stems, and
inflorescences resulted in selection of varieties of wild cabbage into the many forms known today. The wild plant (and its ancestors) originated in the eastern Mediterranean region of Europe. Estimated from
Sanskrit writings 4,000 years ago, as well as Greek writings from the sixth century BC, plant cultivation may have occurred.
Impact of preference
The preference for eating the leaves led to the selection of plants with larger leaves being harvested and their seeds planted for the next growth. Around the fifth century BC, the formation of what is now known as kale had developed.
Preference led to further artificial selection of kale plants with more tightly bunched leaves or terminal buds. Around the first century AD, the phenotype variation of
B. oleracea known as cabbage emerged. Phenotype selection preferences in Germany resulted in a new variation from the kale cultivar. By selecting for wider stems, the variant plant known as
kohlrabi emerged around the first century AD.
European preference emerged for eating immature buds, selecting for inflorescence. Early records in 15th century AD, indicate that early cauliflower and broccoli heading types were found throughout southern Italy and Sicily, although these types may not have been resolved into distinct cultivars until about 100 years later.
Cultivar groups
According to the Royal Botanic Gardens (Kew Species Profiles)
[ Accessed March 23, 2023 – see "Descriptions" subsection "According to Kew Species Profiles"] the species has eight
. Each cultivar group has many
, like 'Lacinato' kale or 'Belstar' broccoli.
-
Acephala group: non-heading cultivars (kale, collards, ornamental cabbage, ornamental kale, flowering kale, tree cabbage).
-
Alboglabra: Asian Cuisine cultivars (Chinese kale, Chinese broccoli, gai lan, kai lan).
-
Botrytis group: cultivars that form compact inflorescences (broccoli, cauliflower, broccoflower, calabrese broccoli, romanesco broccoli).
-
Capitata: cabbage and cabbage-like cultivars (cabbage, savoy cabbage, red cabbage).
-
Gemmifera: bud-producing cultivars (sprouts, Brussels sprouts)
-
Gongylodes: turnip-like cultivars (kohlrabi, knol-kohl)
-
Italica: sprouts (purple sprouting broccoli, sprouting broccoli). Edible inflorescences not compacted into a single head.
-
Tronchuda: low-growing annuals with spreading leaves (Portuguese cabbage, seakale cabbage (distinct from sea kale)).
A 2024 study compares 704 B. oleracea sequences and establishes a phylogenetic tree of cultivars. The authors find large-scale changes in gene expression and gene presence. Some genes are considered to be linked to certain traits such as arrested inflorescence (typical of cauliflower and broccoli).
|
|
| | Brassica oleracea var. oleracea |
| | Brassica oleracea var. capitata f. alba |
| | Brassica oleracea var. capitata f. sabauda |
| | Brassica oleracea var. capitata f. rubra |
| | Brassica oleracea var. capitata f. acuta |
| | Brassica oleracea var. alboglabra |
| | Brassica oleracea var. viridis |
| | Brassica oleracea var. longata |
| | Brassica oleracea var. acephala |
| | Brassica oleracea var. sabellica |
| | Brassica oleracea var. palmifolia |
| | Brassica oleracea var. ramosa |
| | Brassica oleracea var. viridis x gemmifera |
| | Brassica oleracea var. medullosa |
| | Brassica oleracea var. costata |
| | Brassica oleracea var. gemmifera |
| | Brassica oleracea var. gongylodes |
| | Botrytis group | Brassica oleracea var. italica |
| | Brassica oleracea var. botrytis |
| | Brassica oleracea var. botrytis |
| | Brassica oleracea var. botrytis |
| | Brassica oleracea var. botrytis |
| | Brassica oleracea var. botrytis × italica |
| | Brassica oleracea var. italica × alboglabra |
|
Uses
Human genetics in relation to taste
The TAS2R38 gene encodes a G protein-coupled receptor that functions as a taste receptor, mediated by ligands such as
propylthiouracil (PTU) and phenylthiocarbamide that bind to the receptor and initiate signaling that confers various degrees of taste perception. Vegetables in the brassica family, such as collard greens, kale, broccoli, cabbage, and Brussels sprouts, contain
and
, which resemble PTU, and therefore much of the perceived "bitterness" of these vegetables is mediated through TAS2R38. Bitter taste receptors in the TS2R family are also found in gut mucosal and pancreatic cells in humans and rodents. These receptors influence release of hormones involved in appetite regulation, such as peptide YY and glucagon-like peptide-1, and therefore may influence caloric intake and the development of obesity. Thus, bitter taste perception may affect dietary behaviors by influencing both taste preferences and metabolic hormonal regulation.
[ Text was copied from the preprint version, which is available under a Creative Commons Attribution 4.0 International License.]
Three variants in the TAS2R38 gene – rs713598, rs1726866, and rs10246939 – are in high linkage disequilibrium in most populations and result in amino acid coding changes that lead to a range of bitter taste perception phenotypes. The PAV haplotype is dominant; therefore, individuals with at least one copy of the PAV allele perceive molecules in vegetables that resemble PTU as tasting bitter, and consequently may develop an aversion to bitter vegetables. In contrast, individuals with two AVI haplotypes are bitter non-tasters. PAV and AVI haplotypes are the most common, though other haplotypes exist that confer intermediate bitter taste sensitivity (AAI, AAV, AVV, and PVI). This taste aversion may apply to vegetables in general.
Notes
Further reading
External links
