Wiki: Arum - upcScavenger

Arum is a genus of flowering plants in the family Araceae. They are native to Europe, northern Africa, and western and central Asia, with the highest species diversity in the Mediterranean region.

(2025). 9781842460368, The Board of Trustees of the Royal Botanic Gardens, Kew. ISBN 9781842460368

Frequently called arum lilies, they are not closely related to the true lilies Lilium. Plants in the closely related genus Zantedeschia are also called 'arum lilies'.

They are rhizome, herbaceous perennial plants growing to 20–60 cm tall, with sagittate (arrowhead-shaped) leaves 10–55 cm long. The flowers are produced in a spadix, surrounded by a 10–40 cm long, distinctively coloured spathe, which may be white, yellow, brown, or purple. Some species are scented, others not. The fruit is a cluster of bright orange or red berries.

All parts of the plants, including the berries, are poisonous as they contain raphides of calcium oxalate. Nelson, L. et al. (2007) Handbook of Poisonous and Injurious Plants. New York Botanical Garden. In spite of this, the plant has a history of culinary use among Arab peasants in Palestine who leached the toxins from the plant before the leaves were consumed.

Nissim Ḳrispil (1985). 9789652640116, Cana Publishing House Ltd.. ISBN 9789652640116

, s.v. Arum palaestinum ()

(2025). 9789950385849, Dar Al Nasher. ISBN 9789950385849

(2025). 9789402406603, Dordrecht: Springer. ISBN 9789402406603

The genus name is the Latinized form of the Greek name for these plants, aron.

Inflorescence and pollination

The flowers are borne on a poker-shaped inflorescence called a spadix, which is partially enclosed in a spathe or leaf-like hood of varying colour. The flowers are hidden from sight, clustered at the base of the spadix with a ring of female flowers at the bottom and a ring of male flowers above them.

Above the male flowers is a ring of hairs forming an insect trap. The insects are trapped beneath the ring of hairs and are dusted with pollen by the male flowers before escaping and carrying the pollen to the spadices of other plants, where they pollinate the female flowers. Once the plant is pollinated, the small hairs wither away and the trapped insects are released.

After the inflorescence opens, the spadix heats up well above ambient temperature, due to a phenomenon called thermogenesis. This is caused by the rapid consumption of starch in cyanide insensitive respiration, which is biochemically different from the respiration normally found in plants. The heat is used to vaporize odour components, which in species with short "flower-stalks" cause a faecal smell. This in turn attracts the small flies and gnats that are to be trapped within the inflorescence. As the time required for successful pollination to occur can be several days, many of the small insects nevertheless die within the flower due to their short lifespan. Therefore, dead insects are frequently found within the inflorescence, when opened, sometimes leading the finder to believe it is a carnivorous plant – but that is not the case. No digestive enzymes or similar components are present; and in fact, once pollinated, the entire inflorescence starts withering except the central part, from which the berries later emerge.

Peter Boyce (1993). 9780112500858, HMSO. ISBN 9780112500858

pp. 35-40

Pollination-wise, the species of Arum can be split into two (or three) distinct groups. The "cryptic" species have the inflorescence on a relatively short stalk, and the odour released during the thermogenesis is recognizable to the human nose as distinctively faecal. These species are visited by insects with some relation to dung, such as owl-midges (Psychodidae) or fungus-gnats (Sciara). In northern Europe, only the cryptic-flowered species are found.

The other main group are called "flag" species, due to the inflorescence being on a long stalk. These species also exhibit thermogenesis, but if an odour is released it is not recognizable to the human nose, and it is debated if pollinators are attracted by a non-recognizable smell, the thermogenesis itself or visual attraction.

Finally the closely related A. idaeum and A. creticum does not seem to fit any of the two groups. A. creticum appears to be of the "flag" group but, as the only species, emits a pleasing lemony smell. The apparently "cryptic" A. idaeum does not emit a recognizable smell.

Species

, Plants of the World Online accepts the following 27 species and one hybrid:

Arum apulum - Italy (Apulia)
Arum besserianum - South Poland, Ukraine
Arum concinnatum - South Greece, Turkey
Arum creticum - Crete, Turkey
Arum cylindraceum - Central Europe, Iberian Peninsula, Italy, Balkans, Turkey, Cyprus
Arum cyrenaicum - Crete, Libya (Cyrenaica)
Arum dioscoridis - East Aegean, Cyprus, Turkey, Levant
Arum euxinum - Turkey (Bithynia)
Arum gratum - Lebanon, Syria
Arum hainesii - East Iraq
Arum hygrophilum - Turkey, Levant, Cyprus, Morocco
Arum idaeum - Crete
Arum italicum - Mediterranean Europe, Britain, Maghreb, Crimea, Caucasus, Turkey, Iraq
Arum jacquemontii - Iran, Afghanistan, South Central Asia, West Himalayas
Arum korolkowii - North Iran, Afghanistan, Central Asia
Arum lucanum - South Italy, Albania
Arum maculatum - Europe, Turkey, West Caucasus
Arum megobrebi - Transcaucasus, NE Turkey
Arum meryemianum - Turkey
Arum nigrum - Greece, Montenegro
Arum orientale - Carpathian Basin, Carpathians, Balkans, Crimea, Donbass, Caucasus, Turkey, Levant
Arum palaestinum - Levant
Arum pictum - Corsica, Sardinia, Balearics
Arum purpureospathum - Crete
Arum rupicola - Lesbos, Turkey, Transcaucasus, Iran, Levant, Iraq
Arum sintenisii - Cyprus, Turkey
Arum × sooi - Hungary, Spain
Arum taiwanianum - Taiwan

Formerly placed here:

Arum triphyllum – now Arisaema triphyllum
Arum dracunculus – now Dracunculus vulgaris

Distribution and habitat

Distribution maps for all species were published in a 2010 paper.

Taxonomy

Most literature on the genus Arum deals specifically with either A. maculatum or A. italicum. Among remaining species, A. dioscoridis is the most frequently mentioned.

Boyce published an overview of taxonomic classifications of Arum in 1989.

Classification of Boyce 1989 (with updates):

Subgenus Gymnomesium

A. pictum

Subgenus Arum

Section Arum

A. concinnatum
A. byzantinum
A. italicum
A. maculatum
A. megobrebi

Section Dioscoridea

Subsection Alpina

Arum alpinum ( A. cylindraceum)

Subsection Discroochiton

Arum orientale
A. apulum
Arum orientale
A. cyrenaicum
Arum orientale
A. besserianum
A. gratum
A. hainesii
Arum orientale
A. lucanum
A. nigrum
A. orientale
A. purpureospathum

Subsection Tenuifila

A. jacquemontii
A. korolkowii
A. rupicola

Subsection Hygrophila

A. euxinum
A. hygrophilum
A. sintenisii

Subsection Poeciloporphyrochiton

A. dioscoridis
A. palaestinum

Subsection Cretica

A. creticum
A. idaeum

Chloroplast classification (2010):

Subgenus Gymnomesium

A. pictum

Subgenus Arum

Section Arum

A. maculatum
Nigrum-Italicum subsection

A. nigrum
Italicum complex
A. concinnatum
A. byzantinum
A. italicum

Section Poeciloporphyrochiton

A. dioscoridis
A. palaestinum

Large section

A. creticum
A. idaeum
A. jacquemontii
A. korolkowii
A. rupicola
Subsection Hygrophila

A. euxinum
A. hygrophilum
A. sintenisii

Subsection Discroochiton

A. elongatum
Large series

A. gratum
Cylindraceum complex

A. apulum
A. balansanum
A. cylindraceum
A. cyrenaicum
A. euxinum
A. lucanum
A. purpureospathum

Combined chloroplast-ITS sequence classification (2010):

Subgenus Gymnomesium

A. pictum

Subgenus Arum

Section Arum

A. maculatum
Nigrum-Italicum subsection

A. nigrum
Italicum complex
A. concinnatum
A. byzantinum
A. italicum

Section Poeciloporphyrochiton

A. dioscoridis
A. palaestinum

Large section

Subsection Cretica

A. creticum
A. idaeum

Subsection Hygrophila

A. hygrophilum
A. sintenisii

Subsection Tenuifila

A. rupicola
Jacquemontii-Korolkowii complex

A. jacquemontii
A. korolkowii

Subsection Discroochiton

A. elongatum
Large series

A. gratum
Cylindraceum complex

A. apulum
A. balansanum
A. cylindraceum
A. cyrenaicum
A. euxinum
A. lucanum
A. purpureospathum

The ancestor of the genus is thought to have had dung/urine scented flowers for attracting flies and beetles, but over time several clades have moved to different pollinator attraction strategies. In an example of convergent evolution, A. gratum, A. palaestinum and A. sintenisii produce a fruity scent, to attract Drosophila species and others. Apparent scentlessness has evolved in Subsection Tenuifila, A. cylindraceum, A. hygrophilum, A. euxinum and A. lucanum. Subsection Cretica has evolved a sweet scent to attract bees and other insects.

Uses

Despite the presence of irritant , which act together with unverified proteinaceous toxins, most parts of all species have been used as food, and continue to be used today. Use is uncommon because of the duration required to reduce aroid raphides to safe levels.

==Gallery==

===Leaves===