Pinguicula

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iButterwort
Butterwort with prey (Pinguicula gigantea)
Butterwort with prey (Pinguicula gigantea)
Scientific classification
Kingdom: Plantae
Division: Magnoliophyta
Class: Magnoliopsida
Order: Lamiales
Family: Lentibulariaceae
Genus: Pinguicula
L.
Pinguicula distribution
Pinguicula distribution
Species

About 80, see separate list.

The butterworts are a group of carnivorous plants comprising the genus Pinguicula. Members of this genus use sticky, glandular leaves to lure, trap, and digest insects in order to supplement the poor mineral nutrition they obtain from the environments. Of the roughly 80 currently known species, 12 are native to Europe, 9 to North America, and the rest are found in northern Asia, South and Central America and southern Mexico.

The name Pinguicula is derived from a term coined by Conrad Gesner, who in his 1561 work entitled Horti Germaniae commented on the glistening leaves: "propter pinguia et tenera folia…" (lat. pinguis = fat). The common name "butterwort" reflects this characteristic.

Contents

[edit] Characteristics

The majority of Pinguicula are perennial plants. The only known annuals are P. sharpii, P. takakii, P. crenatiloba, and P. pumila. All species form stemless rosettes.

[edit] Habit

Winter rosette of Pinguicula cyclosecta  (non-carnivorous)
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Winter rosette of Pinguicula cyclosecta (non-carnivorous)
Summer rosette of Pinguicula cyclosecta  (carnivorous)
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Summer rosette of Pinguicula cyclosecta (carnivorous)

Butterworts can be divided roughly into two main groups based on the climate in which they grow; each group is the further subdivided based on morphological characteristics. Although these groupings are not cladistically supported by genetic studies,[1] these groupings are nonetheless convenient for horticultural purposes.

Tropical butterworts either form somewhat compact winter rosettes composed of fleshy leaves or retain carnivorous leaves year-round. Temperate species often form tight buds (called hibernacula) composed of scale-like leaves during a winter dormancy period. During this time the roots (with the exception of P. alpina) and carnivorous leaves wither.[2] Temperate species flower when they form their summer rosettes while tropical species flower at each rosette change.

Many butterworts cycle between rosettes composed of carnivorous and non-carnivorous leaves as the seasons change, so these two ecological groupings can be further divided according to their ability to produce different leaves during their growing season. If the growth in the summer is different in size or shape to that in the early spring (for temperate species) or in the winter (tropical species), then plants are considered heterophyllous; whereas uniform growth identifies a homophyllous species.

This results in four groupings:

  • Tropical butterworts: species which do not undergo a winter dormancy but continue to alternately bloom and form rosettes.
    • Heterophyllous tropical species: species that alternate between rosettes of carnivorous leaves during the warm season and compact rosettes of fleshy non-carnivorous leaves during the cool season. Examples include P. emarginata, P. gypsicola, and P. laxifolia.
    • Homophyllous tropical species: these species produce rosettes of carnivorous leaves of roughly uniform size throughout the year, such as P. acuminata.
  • Temperate butterworts: these plants are native to climate zones with cold winters. They produce a winter-resting bud (hibernacula) during the winter.
    • Heterophyllous temperate species: species where the vegetative and generative rosettes differ in shape and/or size, as seen in P. lutea and P. lusitanica.
    • Homophyllous temperate species: the vegetative and generative rosettes appear identical, as exhibited by P. alpina, P. grandiflora, and P. vulgaris.

[edit] Roots

The root system of Pinguicula species is relatively undeveloped. The thin, white roots serve mainly as an anchor for the plant and to absorb moisture (nutrients are absorbed through carnivory). In temperate species these roots wither (except in P. alpina) when the hibernaculum is formed. In the few epiphytic species (such as P. lignicola), the roots form anchoring suction cups.

[edit] Leaves and carnivory

A fly trapped on a Butterwort leaf.
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A fly trapped on a Butterwort leaf.

The leaf blade of a butterwort is smooth, rigid, and succulent, usually bright green or pinkish in colour. Depending on species, the leaves are between 2 and 30 cm.(1-12") long. The leaf shape depends on the species, but is usually roughly obovate, spatulate, or linear.

Like all members of the family Lentibulariaceae, butterworts are carnivorous. In order to catch and digest insects, the leaf of a butterwort uses two specialized glands which are scattered across the leaf surface (usually only on the upper surface, with the exception of P. gigantea and P. longifolia ssp. longifolia). One is termed a peduncular gland, and consists of a few secretory cells on top of a single stalk cell. These cells produce a mucilagenous secretion which forms visible droplets across the leaf surface. This wet appearance probably helps lure prey in search of water (a similar phenomena is observed in the sundews). The droplets secrete only limited enzymes and serve mainly to entrap insects. On contact with an insect, the peduncular glands release additional mucilage from special reservoir cells located at the base of their stalks.[2] The insect will begin to struggle, triggering more glands and encasing itself in mucilage. Some species can bend their leaf edges slightly by thigmotropism, bringing additional glands into contact with the trapped insect. The second type of gland found on butterwort leaves are sessile glands which lie flat on the leaf surface. Once the prey is entraped by the peduncular glands and digestion begins, the initial flow of nitrogen triggers enzyme release by the sessile glands.[2] These enzymes, which include amylase, esterase, phosphatase, protease, and ribonuclease break down the digestible components of the insect body. These fluids are then absorbed back into the leaf surface through cuticular holes, leaving only the chitin exoskeleton of the larger insects on the leaf surface.

The holes in the cuticle which allow for this digestive mechanism also pose a challenge for the plant, since they serve as breaks in the cuticle (waxy layer) that protects the plant from desiccation. As a result, most butterworts live in humid environments.

Flower of P. vulgaris
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Flower of P. vulgaris

Butterworts are usually only able to trap small insects and those with large wing surfaces. They can also digest pollen which lands on their leaf surface. The secretory system can only function a single time, so that a particular area of the leaf surface can only be used to digest insects once.[2]

[edit] Flowers

The flower of a hybrid butterwort
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The flower of a hybrid butterwort

As with almost all carnivorous plants, the flowers of butterworts are held far above the rest of the plant by a long stalk in order to reduce the probability of trapping potential pollinators. The single, long-lasting flowers are zygomorphic, with two lower lip petals characteristic of the bladderwort family, and a spur extending from the back of the flower. The calyx has five sepals, and the petals are arranged in a two-part lower lip and a three-part upper lip. Most butterwort flowers are blue, violet or white, often suffused with a yellow, greenish or reddish tint. P. laueana and the newly described P. caryophyllacea are unique in having a strikingly red flowers. Butterworts are often cultivated and hybridized primarily for their flowers.

The shape and colors of butterwort flowers are distinguishing characteristics which are used to divide the genus into subgenera and to distinguish individual species from one another.

[edit] Fruit and seed

The round to egg-shaped seed capsules open when dry into two halves, exposing numerous small (0.5-1 mm), brown seeds. If moisture is present the silique closes, protecting the seed and opening again upon dryness to allow for wind dispersal. Many species have a net-like pattern on their seed surface to allow them to land on water surfaces without sinking, since many non-epiphytic butterworts grow near water sources. The haploid chromosome number of butterworts is either n = 8 or n = 11, depending on species. The exception is P. lusitanica, whose chromosome count is n = 6.

[edit] Vegetative propagation

As well as sexual reproduction by seed, many butterworts can reproduce asexually by vegetative reproduction. Many members of the genus form offshoots during or shortly after flowering (e.g. P. vulgaris), which grow into new genetically identical adults. A few other species form new offshoots using stolons (e.g. P. calyptrata, P. vallisnerifolia) or form plantlets at the leaf margins (e.g. P. heterophylla, P. primuliflora).

[edit] Distribution

P. alpina
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P. alpina

Butterworts are distributed throughout the northern hemisphere (map). The greatest concentration of species, however, is in humid mountainous regions of Central America (including Mexico) and South America, where populations can be found as far south Tierra del Fuego. Australia is the only continent without any native butterworts.

Butterworts probably originated from modern day Central America, which is also the center of Pinguicula diversity; roughly 50% of butterwort species are found here. From there, the genus likely spread to Europe, before continental drift split the continents apart.

The great majority of Pinguicula species have a very limited distribution. The two butterwort species with the widest distribution - P. alpina and P. vulgaris - are found throughout much of Europe and North America. Other species found in the United States include P. caerulea, P.ionantha, P. lutea, P. macroceras, P. planifolia, P. primuliflora, P. pumila, and P. villosa.

[edit] Habitat

P. macroceras ssp. nortensis growing on a wet rock wall in northern California.
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P. macroceras ssp. nortensis growing on a wet rock wall in northern California.
P. leptoceras in a wet meadow in Südtirol, Italy
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P. leptoceras in a wet meadow in Südtirol, Italy

In general, butterworts grow in nutrient poor, alkaline soils. Some species have adapted to other soil types, such as acidic peat bogs (ex. P. vulgaris, P. calyptrata, P. lusitanica), soils composed of pure gypsum (P. gypsicola), or even vertical rock walls (P. ramosa, P. vallisnerifolia, and many of the Mexican species). A few species are epiphytes (P. casabitoana, P. lignicola). Pinguicula macrocera ssp. nortensis has even been observed growing on hanging dead grasses. Each of these environments is relatively nutrient poor, allowing butterworts to compete for space.

Butterworts need habitats that are almost constantly moist or wet, at least during their carnivorous growth stage. Many Mexican species lose their carnivorous leaves, and sprout succulent leaves, or die back to onion-like "bulbs to survive the winter drought, at which point the can survive in bone dry conditions. This moisture can be supplied by either a high groundwater table, or by high humidity or precipitation. Unlike many other carnivorous plants that require sunny locations, many butterworts thrive in part-sun or even shady conditions.

[edit] Environmental status

The environmental threats faced by various Pinguicula species depend on their location and on how widespread their distribution is. Most greatly endangered are the species which are endemic to small areas, such as P. ramosa, P. casabitoana, and P. fiorii. These populations are threatened primarily by habitat destruction. Wetland destruction has threatened several US species. Most of these are federally listed as either threatened or endangered, and P. ionantha is listed on CITES appendix I, giving it additional protection.

[edit] Botanical history

Pinguicula vulgaris, illustration
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Pinguicula vulgaris, illustration

The first mention of butterworts in botanical literature is an entry entitled Zitroch chrawt oder smalz chrawt (trans: "zitroch" herb or lard herb) by Vitus Auslasser in his 1479 work on medicinal herbs entitled Macer de Herbarium. The name "Zittrochkraut" is still used for butterworts in Tirol, Austria.

In 1583, Clusius already distinguished between two forms in his Historia stirpium rariorum per Pannoniam, Austriam: a blue-flowered form (P. vulgaris) and a white-flowered form (Pinguicula alpina). Linnaeus added P. villosa and P. lusitanica when he published his Species Plantarum in 1753. The number of known species rose sharply with the exploration of the new continents in the 19th century; in 1844, 32 species were known.

It was only in 1875 that the carnivory of this genus was first studied. A friend of Charles Darwin by the name of W. Marshall pointed out to him the insects which got caught on butterwort leaves. Darwin studied these plants extensively and determined them to be insectivorous.[3] S. J. Casper's large 1966 monograph of the genus[4] included 46 species, a number which has almost doubled since then. Many exciting discoveries have been made in recent years, especially in Mexico. Another important development in the history of butterworts is the formation of the International Pinguicula Study Group, an organization dedicated to furthering the knowledge of this genus and promoting its popularity in cultivation, in the 1990s.

[edit] Uses

Butterworts are widely cultivated by carnivorous plant enthusiasts. The temperate species and many of the Mexican butterworts are relatively easy to grow and have therefore gained relative popularity. Two of the most widely grown plants are the hybrid cultivars Pinguicula × 'Sethos' and Pinguicula × 'Weser'. Both are crosses of Pinguicula ehlersiae and Pinguicula moranensis, and are employed by commercial orchid nurseries to combat pests.

Butterworts also produce a strong bactericide which prevents insects from rotting while they are being digested. According to Linnaeus, this property has long been known by northern Europeans, who applied butterwort leaves to the sores of cattle to promote healing.[5] Additionally, butterwort leaves were used to curdle goat's milk and form a yogurt-like cheese called Filmjölk.

[edit] Classification

For a list of species, see the separate article List of Pinguicula species.

Pinguicula belong to the Bladderwort family (Lentibulariaceae), along with Utricularia and Genlisea. Siegfried Jost Casper systematically divided them into three subgenera with 15 sections.[4]

A detailed study of the phylogenetics of butterworts by Cieslak et al. (2005)[1] found that all of the currently accepted subgenera and many of the sections were polyphyletic. The diagram below gives a more accurate representation of the correct cladogram. Polyphyletic sections are marked with an *.

                  ┌────Clade I (Sections Temnoceras *, Orcheosanthus *, Longitubus, 
                  │             Heterophyllum *, Agnata *, Isoloba *, Crassifolia)   
                  │   
              ┌───┤ 
              │   │
              │   │
       ┌──────┤   └────Clade II (Section Micranthus * = P. alpina)
       │      │   
       │      │   
   ┌───┤      └────────Clade III (Sections Micranthus *, Nana)
   │   │ 
   │   │ 
───┤   └───────────────Clade IV (Section Pinguicula) 
   │                        
   │   
   └───────────────────Clade V (Sections Isoloba *, Ampullipalatum, Cardiophyllum)

[edit] Gallery

[edit] References

Much of the content of this article comes from the equivalent German-language wikipedia article (retrieved March 29, 2006).

  1. ^ a b Cieslak T, Polepalli JS, White A, Müller K, Borsch T, Barthlott W, Steiger J, Marchant A, Legendre L (2005). "Phylogenetic analysis of Pinguicula (Lentibulariaceae): chloroplast DNA sequences and morphology support several geographically distinct radiations". American Journal of Botany 92: 1723-1736.
  2. ^ a b c d Legendre L (2002). "The genus Pinguicula L. (Lentibulariaceae): an overview". Acta Botanica Gallica 141 (1): 77-95.
  3. ^ Darwin C (1875). Insectivorous plants. London: John Murray.
  4. ^ a b Casper SJ (1966). Monographie der Gattung Pinguicula L. (Heft 127/128, Vol 31). Stuttgart: Bibliotheca Botanica.
  5. ^ D'Amato P (1988). The savage garden: cultivating carnivorous plants. Ten Speed Press.

[edit] Further reading

  • Barthlott W, Porembski S, Seine R, Theisen I (2004). Karnivoren. Stuttgart: Verlag Eugen Ulmer.
  • Müller K, Borsch T, Legendre L, Porembski S, Theisen I, Barthlott W (2004). "Evolution of carnivory in Lamiales". Plant Biology 6: 1-14.

[edit] External links

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