Pinguicula moranensis: Difference between revisions
m Removed taxobox colour. See User:Eubot/Removing colours from taxoboxen. |
m spelling |
||
Line 50: | Line 50: | ||
The leaf blades of the summer rosettes of ''P. moranensis'' are smooth, rigid, and succulent, varying from bright yellow-green to maroon in colour. The [[leaf|laminae]] are generally [[Leaf shape|obovate]] to [[Leaf shape|orbicular]], between 5.5 and 13 centimeters (2–5 in.) long and supported by a 1 to 3.5 centimetre (⅜–1 ⅜ in.) [[petiole]].<ref name=Ruiz2001:158>Ruiz 2001, pg. 158</ref> |
The leaf blades of the summer rosettes of ''P. moranensis'' are smooth, rigid, and succulent, varying from bright yellow-green to maroon in colour. The [[leaf|laminae]] are generally [[Leaf shape|obovate]] to [[Leaf shape|orbicular]], between 5.5 and 13 centimeters (2–5 in.) long and supported by a 1 to 3.5 centimetre (⅜–1 ⅜ in.) [[petiole]].<ref name=Ruiz2001:158>Ruiz 2001, pg. 158</ref> |
||
As with all members of the genus, these leaf blades are densely covered by peduncular (stalked) [[mucilage]]nous [[gland]]s and [[sessile]] (flat) digestive glands. The peduncular glands consist of a few secretory cells on top of a single-celled stalk. 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 phenomenon is observed in the [[sundew]]s. 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. The insect struggles, triggering more glands and encasing itself in mucilage. ''P. moranensis'' can bend its leaf edges slightly by [[thigmotropism]], bringing additional glands into contact with the trapped insect. The sessile glands, which lie flat on the leaf surface, serve to digest the insect prey. Once the prey is |
As with all members of the genus, these leaf blades are densely covered by peduncular (stalked) [[mucilage]]nous [[gland]]s and [[sessile]] (flat) digestive glands. The peduncular glands consist of a few secretory cells on top of a single-celled stalk. 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 phenomenon is observed in the [[sundew]]s. 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. The insect struggles, triggering more glands and encasing itself in mucilage. ''P. moranensis'' can bend its leaf edges slightly by [[thigmotropism]], bringing additional glands into contact with the trapped insect. The sessile glands, which lie flat on the leaf surface, serve to digest the insect prey. Once the prey is entrapped by the peduncular glands and digestion begins, the initial flow of nitrogen triggers enzyme release by the sessile glands. 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 [[Plant cuticle|cuticular]] holes, leaving only the [[chitin]] [[exoskeleton]] of the larger insects on the leaf surface.<ref name=legendre2002>Legendre, L. 2000</ref> |
||
The holes in the [[Plant cuticle|cuticle]] which allow for this digestive mechanism pose a challenge for the plant, since they serve as breaks in the cuticle (waxy layer) that protects the plant from desiccation.<ref name=legendre2002 /> As a result, ''P. moranensis'' is usually found in relatively humid environments. The production of the stalked capture glands and sessile digestive glands is also costly. A recent study found that the density of these respective glands can be correlated to environmental gradients. For example, capture gland density was found to be highest where prey availability was low, whereas digestive glands density showed direct correlation to prey availability.<ref name=Alcala2005 /> These results suggest that the amount of investment in carnivorous features is an adaptation to the environmental gradients. |
The holes in the [[Plant cuticle|cuticle]] which allow for this digestive mechanism pose a challenge for the plant, since they serve as breaks in the cuticle (waxy layer) that protects the plant from desiccation.<ref name=legendre2002 /> As a result, ''P. moranensis'' is usually found in relatively humid environments. The production of the stalked capture glands and sessile digestive glands is also costly. A recent study found that the density of these respective glands can be correlated to environmental gradients. For example, capture gland density was found to be highest where prey availability was low, whereas digestive glands density showed direct correlation to prey availability.<ref name=Alcala2005 /> These results suggest that the amount of investment in carnivorous features is an adaptation to the environmental gradients. |
||
Line 85: | Line 85: | ||
====Twentieth century==== |
====Twentieth century==== |
||
When Barnhart revised the family [[Lentibulariaceae]] in 1916, he recognized six species in the section Orcheosanthus, admitting however that this number was likely to change as others studied the section in the future. Sprague in 1928 proposed that the species joined by Hemsley were probably distinct, but that they were likely so interrelated that distinguishing between them would require observing characteristics that were usually or always indistinct in dried specimens.<ref>The difficulty of basing |
When Barnhart revised the family [[Lentibulariaceae]] in 1916, he recognized six species in the section Orcheosanthus, admitting however that this number was likely to change as others studied the section in the future. Sprague in 1928 proposed that the species joined by Hemsley were probably distinct, but that they were likely so interrelated that distinguishing between them would require observing characteristics that were usually or always indistinct in dried specimens.<ref>The difficulty of basing taxonomical work in the genus ''Pinguicula'' solely on dried specimens has been noted by several frustrated botanists. McVaugh & Mickel in their 1963 notes on the section ''Orcheosanthus'' noted that "Herbarium study of these plants is difficult and frustrating because the leaves and other vegetative and reproductive structures are so fragile that dried specimens are seldom adequately preserved. Usually but a single flower is found on a plant, and the extraordinarily fragile pressed flowers often lose their original color and shape to a very large extent. Often neither vegetative nor reproductive structures can be studied without severe damage to the specimen" (McVaugh, 1963). Barnhart (1916) had stated that "the range of variation is enormous, but how much is seasonal, how much individual, and how much of taxonomic importance, is (based on herbarium samples alone) at present mere guesswork" (Barnhart, 1916). This conclusion was echoed by Sprague (1928), Ernst (1961), and McVaugh (1963).</ref> Sprague recognized eight species in the section: ''P. moranensis'' <small>H.B.K</small>, ''P. caudata'' <small>Schltdl.</small>, ''P. oblongiloba'', ''P. flos-mulionis'', ''P. bakeriana'', a ''P. moranensis''-like '''''P. rosei''''' described by Watson in 1911, and the very distinct ''[[Pinguicula gypsicola|P. gypsicola]]''.<ref name=Ruiz2001 /> |
||
In 1966 [[Siegfried Jost Casper|Casper]] published the first ever monograph of the genus. He clearly defined his taxonomic organization according to a broad range of morphological and phenotypic characteristics. Casper considered ''P. caudata'', as well as various other taxa, to be a synonyms of ''P. moranensis''. He therefore recognized only 6 species for the section ''Orcheosanthus'': ''P. moranensis'', ''P. gypsicola'', ''P. macrophylla'' <small>H.B.K.</small>, ''P. oblongiloba'', and the two recently discovered species ''[[Pinguicula colimensis|P. colimensis]]'' and ''[[Pinguicula cyclosecta|P. cyclosecta]]''.<ref name=Casper1966 /> Since that time 14 additional species have been discovered and assigned to the section.<ref>Ruiz 2001, pg. 29</ref> When Zamudio redefined the section in 1999, however, he chose to include only 12 species, including all six of Casper's choices.<ref name=Ruiz2001 /> ''P. moranensis'', therefore, remains in the section ''Orcheosanthus'', along with over a dozen synonyms it has inherited in its 200-year taxonomic history. |
In 1966 [[Siegfried Jost Casper|Casper]] published the first ever monograph of the genus. He clearly defined his taxonomic organization according to a broad range of morphological and phenotypic characteristics. Casper considered ''P. caudata'', as well as various other taxa, to be a synonyms of ''P. moranensis''. He therefore recognized only 6 species for the section ''Orcheosanthus'': ''P. moranensis'', ''P. gypsicola'', ''P. macrophylla'' <small>H.B.K.</small>, ''P. oblongiloba'', and the two recently discovered species ''[[Pinguicula colimensis|P. colimensis]]'' and ''[[Pinguicula cyclosecta|P. cyclosecta]]''.<ref name=Casper1966 /> Since that time 14 additional species have been discovered and assigned to the section.<ref>Ruiz 2001, pg. 29</ref> When Zamudio redefined the section in 1999, however, he chose to include only 12 species, including all six of Casper's choices.<ref name=Ruiz2001 /> ''P. moranensis'', therefore, remains in the section ''Orcheosanthus'', along with over a dozen synonyms it has inherited in its 200-year taxonomic history. |
Revision as of 10:16, 22 March 2008
Pinguicula moranensis | |
---|---|
File:Dsc04852.jpg | |
In habitat in Oaxaca | |
Scientific classification | |
Kingdom: | |
Division: | |
Class: | |
Order: | |
Family: | |
Genus: | |
Species: | P. moranensis
|
Binomial name | |
Pinguicula moranensis | |
Varieties | |
P. moranensis var. moranensis | |
Synonyms | |
According to Ruiz (2001) unless otherwise noted.[1]
P. moranensis var. neovolcanica: |
Pinguicula moranensis (Template:PronEng) is a perennial rosette-forming insectivorous herb native to Mexico and Guatemala.[3] A species of butterwort, it forms summer rosettes of flat, succulent leaves up to 10 centimeters (4 in) long, which are covered in mucilagenous (sticky) glands that attract, trap, and digest arthropod prey. Nutrients derived from the prey are used to supplement the nutrient-poor substrate that the plant grows in. In the winter the plant forms a non-carnivorous rosette of small, fleshy leaves that conserves energy while food and moisture supplies are low. Single pink, purple, or violet flowers appear twice a year on upright stalks up to 25 centimeters long.
The species was first collected by Humboldt and Bonpland on the outskirts of Mina de Morán in the Sierra de Pachuca of the modern-day Mexican state of Hidalgo on their Latin American expedition of 1799–1804.[4] Based on these collections, Humboldt, Bonpland and Carl Sigismund Kunth described this species in Nova Genera et Species Plantarum in 1817. The extremely variable species has been redefined at least twice since,[4][5][6] while several new species have been segregated from it based on various geographical or morphological distinctions, although the legitimacy of some of these is still debated.[7] P. moranensis remains the most common and most widely distributed member of the Section Orcheosanthus.[4] It has long been cultivated for its carnivorous nature and attractive flowers, and is one of the most common butterworts in cultivation.
The generic name Pinguicula is derived from the Latin pinguis (meaning "fat") due to the buttery texture of the surface of the carnivorous leaves. The specific epithet moranensis refers to its type location, Mina de Moran.
Plant characteristics
Habit
P. moranensis is seasonally dimorphic, in that it undergoes two distinct growth habits throughout the year. During the summer when rain and insect prey are most plentiful, the plant forms a ground hugging rosette composed of 6–8 generally obovate leaves, each up to 95 millimeters (3¾ in) long.[8] These leaves are carnivorous, having a large surface area densely covered with stalked mucilagenous glands with which they attract, trap, and digest arthropod prey, most commonly flies. These so-called "summer leaves" are replaced by "winter rosettes" of small, glandless succulent leaves with the onset of the dry season in October. This protective winter rosette allows the plant to undergo winter dormancy until the first rains begin in May.[8] Flowers born singly on upright 10–25 centimeters (4–10 in.) peduncles emerge twice during the year (from the summer rosette and again from the winter rosette), a feature rare among the Mexican species.[9][10][11] In the summer these appear in June, peak in August and September, and disappear with the return to the winter rosette in October or November.[4]
Leaves and carnivory
The leaf blades of the summer rosettes of P. moranensis are smooth, rigid, and succulent, varying from bright yellow-green to maroon in colour. The laminae are generally obovate to orbicular, between 5.5 and 13 centimeters (2–5 in.) long and supported by a 1 to 3.5 centimetre (⅜–1 ⅜ in.) petiole.[12]
As with all members of the genus, these leaf blades are densely covered by peduncular (stalked) mucilagenous glands and sessile (flat) digestive glands. The peduncular glands consist of a few secretory cells on top of a single-celled stalk. 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 phenomenon 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. The insect struggles, triggering more glands and encasing itself in mucilage. P. moranensis can bend its leaf edges slightly by thigmotropism, bringing additional glands into contact with the trapped insect. The sessile glands, which lie flat on the leaf surface, serve to digest the insect prey. Once the prey is entrapped by the peduncular glands and digestion begins, the initial flow of nitrogen triggers enzyme release by the sessile glands. 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.[13]
The holes in the cuticle which allow for this digestive mechanism pose a challenge for the plant, since they serve as breaks in the cuticle (waxy layer) that protects the plant from desiccation.[13] As a result, P. moranensis is usually found in relatively humid environments. The production of the stalked capture glands and sessile digestive glands is also costly. A recent study found that the density of these respective glands can be correlated to environmental gradients. For example, capture gland density was found to be highest where prey availability was low, whereas digestive glands density showed direct correlation to prey availability.[8] These results suggest that the amount of investment in carnivorous features is an adaptation to the environmental gradients.
Winter rosette
The "winter" or "resting" rosette of P. moranensis is two to three (maximum five) centimeters (¾–2 in.) in diameter and consists of 60 to 100 or more small, fleshy, non-glandular leaves. These are each 10 to 30 millimeters (⅜–1 ¼ in.) long and three to eight millimeters (⅛–5⁄16 in.) wide, generally spatulate or oblong-spatulate, and densely covered with fine hairs. The rosette is either open or compact and bulb-like, depending on variety (see below).[14]
Flowers
P. moranensis produces one to seven flowers during each flowering period. These are borne singly on upright flower stalks which are green to brown-green in color and usually, like the upper surface of the carnivorous leaves, are densely covered in glandular hairs; the peduncles do, in fact, trap insect prey. The peduncles are 10 to 25 centimeters (4–10 in.) long and taper from two to three millimeters (⅛ in.) at the base to one millimeter (1⁄16 in.) at the top.[12]
The flowers themselves are composed of five petals which are fused at one end. The throat, the portion of the flower near the attachment point which holds the reproductive organs, is funnel shaped, and the petals flare out from there into a five-lobed zygomorphic corolla. The flowers 30 to 50 millimeters (1 ¼–2 in.) long. Below the attachment point to the stem the petals are fused into a 15–30 millimeter long spur which protrudes backwards roughly perpendicular to the rest of the flower.[12][15]
The ovary and attached pistil protrude from the top of the floral tube near its opening, with the receptive stigma surface toward the front. Two 1 millimeter anthers hang from recurved, 2 millimeter filaments behind the pistil.[16] Pollinators exiting after collecting nectar from the spur brush against the anther, transferring pollen to the stigma of the next flower they visit. The flowers can last up to 10 days but will wilt once they are pollinated.[17] Pollinated ovaries ripen into 5 millimeter (3⁄16 in.) dehiscent seed capsules containing numerous 1 millimeter long seeds.[16] The chromosome count for this species is 2n=44.[18]
The color and morphology of the flowers of this species is extremely variable, a source of delight to the horticulturist and headache to the taxonomist. Some generalizations, however, can be made.
The corolla flares open into five lobes, two upper lobes and three lower lobes. The upper lobes are 7–16 millimeters (¼–⅜ in.) long by 4–9 millimeters (5⁄32–⅜ in.) wide and generally oblong, obovate, or cuneate. The lower lobes are similarly shaped and are 7–20 millimeters (¼–¾ in.) long by 4–18 millimeters (5⁄32–¾ in.) wide. The central lower lobe is usually slightly longer than its neighbors. All of the petal lobes have rounded ends. The floral tube that houses the reproductive organs and is visible at the base of corolla lobes is white or lilac in color and 4–6 millimeters (5⁄32–¼ in.) long. The white color of the floral tube can extend to a variable distance onto the corolla lobes, particularly in a stripe on the lower middle lobe.[12] The color of the corolla lobes generally varies from pink to purple, but has been described by collectors as being "purple, scarlet, rosy-lavender to bluish-purple, dark pink to lavender, pinkish-purple, deep violet-purple, dark purple, bright mauve-pink, bright purple-pink, magenta with [white eye], [and] reddish pale with white eye."[19] A rare white-flowered form is also known.[19]
Taxonomy
Sergio Zamudio Ruiz, in his 2001 revision of the section Orcheosanthus, called the identity and exact delimitation of P. moranensis "perhaps the most difficult problem to solve within the genus".[20] This difficulty is due mainly to the high variability and large geographic distribution of the species, which has given rise to the description of many synonyms since the species was first described nearly 200 years ago. Botanists have attempted to delimitate the species through various morphological, ecological and genetic methods, though to this date some debate remains as to the placement and description of P. moranensis and its relationship to the species to which it is closely related.
Botanical history
Prior to Alexander von Humboldt and Aimé Bonpland's Latin American expedition in 1799–1804, only 8 Pinguicula species were known to science — 5 from Europe, 2 from North America and P. involuta from Peru. From 1803–1805, three additional species from Europe and North America were described, bringing the total of known species to 11.[2] In 1817 Humboldt, Bonpland and Carl Sigismund Kunth described 3 new species from their Latin American expedition: The Peruvian P. calyptrata and the first known Mexican species: P. macrophylla and P. moranensis.[21] At this point no infrageneric classification had yet been suggested.
In 1844 a French-Swiss botanist by the name of Alphonse Pyrame de Candolle (who created the first Code of Botanical Nomenclature) proposed a division of the genus into three sections based on floral morphology. He placed in the section Orcheosanthus those species with purple, deeply bilabiate corollas with 5 sub-equal lobes, a short floral tube, and a large spur not protruding past this tube. He included four species in this section, all of them from Mexico: P. oblongiloba, P. orchidioides, P. caudata and P. moranensis. He excluded P. macrophylla H.B.K. on the grounds that it was a "dubious species".[22]
The section Orcheosanthus grew as Charles Morren described P. flos-mulionis in 1872, Eugene Fournier added P. sodalium in 1873 and Sander proposed P. bakeriana in 1881.[2] In 1879–1888, however, a botanist by the name of William Hemsley, after studying multiple specimens in herbariums and in culture, came to the conclusion that all the taxa placed in the section Orcheosanthus up to that point belonged to the same single species. Due to doubts as to the identity of the original two species described by H.B.K., Hemsley decided to use the name P. caudata Schltdl. for his conglomerate species. This name has been "indiscriminately" applied to members of the complex ever since.[23]
Twentieth century
When Barnhart revised the family Lentibulariaceae in 1916, he recognized six species in the section Orcheosanthus, admitting however that this number was likely to change as others studied the section in the future. Sprague in 1928 proposed that the species joined by Hemsley were probably distinct, but that they were likely so interrelated that distinguishing between them would require observing characteristics that were usually or always indistinct in dried specimens.[24] Sprague recognized eight species in the section: P. moranensis H.B.K, P. caudata Schltdl., P. oblongiloba, P. flos-mulionis, P. bakeriana, a P. moranensis-like P. rosei described by Watson in 1911, and the very distinct P. gypsicola.[6]
In 1966 Casper published the first ever monograph of the genus. He clearly defined his taxonomic organization according to a broad range of morphological and phenotypic characteristics. Casper considered P. caudata, as well as various other taxa, to be a synonyms of P. moranensis. He therefore recognized only 6 species for the section Orcheosanthus: P. moranensis, P. gypsicola, P. macrophylla H.B.K., P. oblongiloba, and the two recently discovered species P. colimensis and P. cyclosecta.[5] Since that time 14 additional species have been discovered and assigned to the section.[25] When Zamudio redefined the section in 1999, however, he chose to include only 12 species, including all six of Casper's choices.[6] P. moranensis, therefore, remains in the section Orcheosanthus, along with over a dozen synonyms it has inherited in its 200-year taxonomic history.
Phylogenetics
The varying importance which different authors have placed on various morphological characteristics when determining the taxonomy of the genus has long made the resulting subdivision of the genus a subject of controversy.[11] Ruiz (2001) supported his revision of the section Orcheosanthus with a phylogenetic analysis, using 20 morphological and phenological characteristics.[6] In 2005, Cieslak et al. conducted the first comprehensive phylogenetic analysis of the entire genus Pinguicula. Using molecular data, they were able to isolate those morphological characteristics that were synapomorphies for various groups, providing evidence for a genetically-based taxonomic structure. Their overall results did not support the placement of P. moranensis in the section Orcheosanthus, rather indicating that it should be placed in the section Longitubus along with P. laueana.[11]
In further disagreement with Ruiz's 2001 revision of the section Orcheosanthus, Cieslak et al.'s phylogenetic data indicated that P. rectifolia and several unnamed taxa that had been treated as synonyms of P. moranensis are in fact a distinct complex. They isolated several morphological characteristics that could be used to differentiate between the complexes, including floral spur length (longer in P. moranensis), flower color (never with a blue tinge in P. moranensis), and the shape of the lateral corolla lobe (exhibiting a twist in P. rectifolia).[11] A more thorough study analyzing numerous P. moranensis populations and other members of closely related taxa is needed to resolve this complex.
Varieties
After extensively studying P. moranensis in habitat, Ruiz (1999) came to the conclusion that the species could be divided into two distinct varieties, mainly on the basis of the shape of the leaves composing their winter (resting) rosettes:[4]
This variety has open winter rosettes composed of leaves which are spatulate in shape and have an obtuse or rounded end. It tends to grow in limestone-based substrates.
This variety has a closed, bulb-like rosette of winter leaves which are acicular (pointy) at the tip. It tends to grow on igneous substrates.
Ruiz also noted that these subspecies differed in their preference of soil substrate. He first noted this while attempting to find the population of plants from which Humboldt and Bonpland had collected their type specimens in 1803. Although Ruiz was able to find many populations of the species growing in the areas that Humboldt and Bonpland had visited in the vicinity if Mina de Moran, only one population, the only one growing on limestone, matched H.B.K.'s description and their type and isotype specimens now housed in the herbarium of the French national museum of natural history. The other populations in the area grew on substrate of igneous origin and more closely matched Hooker's 1846 description of P. orchidioides.[26] These latter plants then became the new variety, P. moranensis ssp. neovolcanica.[4]
Distribution and habitat
P. moranensis is the most widely distributed member of the Section Orcheosanthus.[4] It is also the most common and widely distributed Pinguicula species in Mexico, being found in all the major mountain ranges except Sierra Madre Occidental and Baja California.[16] Locations are known from the Mexican states of Tamaulipas, Guanajuato, Nuevo León, Campeche, Chiapas, Oaxaca, Puebla, Distrito Federal, Veracruz, Estado de México, Querétaro, San Luis Potosí, Morelos, Hidalgo, Guerrero, Zacatecas, Tlaxcala, Quintana Roo, and Michoacán and the Guatemalan departments of Huehuetenango, Quiché, San Marcos, Quetzaltenango, Totonicapan, Solola, Chimaltenango, Baja Verapaz, Guatemala and El Progreso.[6] Here it grows in mountainous regions between 800 and 3200 meters (2600–10500 ft) in altitude. Generally, the species tends to follow sedimentary outcrops of the Cretaceous period. P. moranensis var. neovolcanica, however, tends to grow on igneous rocks of the Eje Volcánico Transversal.[16]
P. moranensis most often grows in oak, pine-oak, or temperate montane woodlands. However, its distribution penetrates into tropical forests and xerophytic shrublands, as well as in gorges and canyon walls with high environmental humidity. P. moranensis prefers humid and shady environments, such as slopes by streams, gullies, or road cuts, or among leaf litter in sandy soil high in organic matter. Its ability to gather nutrients from the arthropod prey it catches allows it to grow in low-nutrient environments where other plants would usually out-compete it. As a result, it is often found in disturbed areas or on steep cliffs or hillsides. Since its roots do little more than provide anchorage, the plant requires little or no soil, and dense clusters can be found clinging onto boulders, moss or crags in rock faces, or even epiphytically on tree trunks. Common companion plants include mosses, Selaginella, ferns and other herbaceous plants, as well as a canopy trees such as pines and oaks.[16]
Cultivation
P. moranensis is one of the most popular and commonly cultivated Pinguicula,[27] in part due to its large size, large and pretty flowers, and the ease with which it can be grown as a container plant. Most growers use an open soil mix composed of some combination of washed sand, perlite, vermiculite, peat moss, gypsum and/or decomposed granite. Soil should be kept well drained, but watered regularly with distilled water in the summer and only very rarely once the plant enters its winter rosette. The species grows readily on well-lit windowsills, under fluorescent lights, or in warm to hot greenhouses.[27]
Hybrids and cultivars
Although no natural hybrids involving P. moranensis have been reported, the species is known to hybridize quite readily in cultivation. As a result, a number of cultivars involving the species have been registered and are recognized by the International Carnivorous Plant Society:[28]
cultivar name | parentage | description |
---|---|---|
Pinguicula 'George Sargent' Hort. Slack | P. moranensis × gypsicola | Lilac flowers, strap-shaped leaves, large winter rosettes. |
Pinguicula 'Hameln' Hort. Studnicka | P. gypsicola × moranensis | Wider, P. moranensis like foliage. |
Pinguicula 'John Rizzi' Hort. D'Amato | P. moranensis × ? | Large, full flowers; oval, marginless undulating leaves. |
Pinguicula 'L'Hautil' Hort. L.Legendre & S.Lavayssiere | P. (ehlersiae × moranensis) × moranensis | Two forms ("Grande" and "Petite"). P. 'Sethos' × P. 'Huahuapan' |
Pinguicula 'Mitla' Hort. Studnicka[29] | P. gypsicola × moranensis | Wider, P. moranensis like foliage. |
Pinguicula 'Pirouette' Hort. J.Brittnacher, B.Meyers-Rice & L.Song | P. agnata × (moranensis × ehlersiae) | Hardy clone, attractive rosettes of pink leaves. |
Pinguicula 'Sethos' Hort. Slack | P. ehlersiae × moranensis | Large flowers with a white star-like center. |
Pinguicula 'Weser' Hort. Slack | P. moranensis × ehlersiae | Large flowers with single white streak down central lower lobe and dark veins. |
Additionally, three clones of P. moranensis have been registered as cultivars:[2]
cultivar name | origin | description |
---|---|---|
Pinguicula 'Huahuapan' Hort. Slack | Huajuapan de León, Oaxaca, Mexico | Lilac-pink flowers with crimson touches at their base. |
Pinguicula 'Libelulita' Hort. Rice & Salvia | southern Mexico | Square-tipped petals, pale purple at edges darkening to deep velvet-red near base, heavily veined, white center. |
Pinguicula 'Vera Cruz' Hort. Slack | Veracruz, Mexico | Deep rose with basal markings. |
Notes
- ^ Ruiz 2001, pgs. 160–161, 182
- ^ a b c d e f g Schlauer, Jan: Carnivorous Plant Database, version November 15 2005, 16:25.
- ^ Ruiz 2001, pg. 153; Casper (1966) included San Salvador in the range of the species. Those populations south and east of Guatemala, however, have since been assigned to P. mesophytica Zamudio.
- ^ a b c d e f g Zamudio, S. 1999
- ^ a b Casper, S.J. 1966
- ^ a b c d e Ruiz, S.J. 2001
- ^ As an example, see Speta 1989. Of the three species described by Speta & Fuchs, two (P. rectifolia and P. potosiensis) were rejected as synonyms by Zamudio 2001, while P. rectifolia was supported by Ciezlak et al.'s phylogenetic study in 2005.
- ^ a b c Alcala, R.E. & Dominguez, C.A. 2005
- ^ Peduncle length: Ruiz 2001, pg. 158
- ^ According to Cieslak et al. 2005, P. moctezumae, P. moranensis, P. emarginata, P. species ‘Huahuapan’ and P. rectifolia all share this trait.
- ^ a b c d Cieslak et al., 2005
- ^ a b c d Ruiz 2001, pg. 158
- ^ a b Legendre, L. 2000
- ^ Ruiz 2001, pg. 161
- ^ According to Cieslak (2005), the spur length is a diagnostic feature when differentiating this species from P. recitoflia. Cieslak asserts that in P. moranensis the spur is more than 50% longer than the rest of the corolla.
- ^ a b c d e Ruiz 2001, pg. 159
- ^ Legendre, L. Pollination of Pinguicula flowers. Retrieved on January 2, 2007.
- ^ Ruiz 2001, pg. 60
- ^ a b Ruiz 2001, pg. 184
- ^ Ruiz 2001, pg. 26; "La identidad de Pinguicula moranensis y su delimitación precisa es quizás el problema más difÍcil de resolver dentro del género."
- ^ From Ruiz, S.J. 2001, orig. Humboldt, A., A. Bonpland & C.S. Kunth. 1817
- ^ From Ruiz, S.J. 2001, orig. Candolle, A.P. De. 1844
- ^ Ruiz 2001, pg. 26
- ^ The difficulty of basing taxonomical work in the genus Pinguicula solely on dried specimens has been noted by several frustrated botanists. McVaugh & Mickel in their 1963 notes on the section Orcheosanthus noted that "Herbarium study of these plants is difficult and frustrating because the leaves and other vegetative and reproductive structures are so fragile that dried specimens are seldom adequately preserved. Usually but a single flower is found on a plant, and the extraordinarily fragile pressed flowers often lose their original color and shape to a very large extent. Often neither vegetative nor reproductive structures can be studied without severe damage to the specimen" (McVaugh, 1963). Barnhart (1916) had stated that "the range of variation is enormous, but how much is seasonal, how much individual, and how much of taxonomic importance, is (based on herbarium samples alone) at present mere guesswork" (Barnhart, 1916). This conclusion was echoed by Sprague (1928), Ernst (1961), and McVaugh (1963).
- ^ Ruiz 2001, pg. 29
- ^ Ruiz 2001, pg. 177; The modern day P. orchidioides was described two years earlier (in 1844) by A. De Candolle. Hooker described a plant he saw growing at Kew Botanical Gardens and, thinking it to be similar to Candolle's P. orhidioides, applied that name.
- ^ a b D'Amato P. 1998, pg. 203–205
- ^ International Carnivorous Plant Society, Registered Cultivar Names — Pinguicula. Retrieved on January 2, 2007.
- ^ An illegitimate homonym of this cultivar exists. Peter D'Amato describes a P. moranensis clone under this name in The Savage Garden (1998).
References
- Alcala, R.E. & Dominguez, C.A. 2005 Differential Selection for Carnivory Traits Along an Environmental Gradient in Pinguicula moranensis; Ecology, 86(10), 2005, pp. 2652–2660
- Casper, S.J. 1966. Monographie der Gattung Pinguicula L. Heft 127/128, Vol 31. Stuttgart: Bibliotheca Botanica
- Cieslak, T., Polepalli, J.S., 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. 2005;92:1723–1736.
- Candonelle, A.P. De. 1844. Prodromus systematis naturalis regni vegetabilis; Tomo VIII. Paris. pp. 26–32.
- D'Amato, P. 1998. The Savage Garden — Cultivating Carnivorous Plants. Berkley, California: Ten Speed Press. ISBN 0-898-15915-6
- Ernst, A. 1961 Revision der Gattung Pinguicula Bot. Jahrb. Syst. 80(2): 145–194
- Hemsley, W.B. 1879–1888. Botany. In: Godwin, F.D. & O. Salvin, Biologia Centrali-Americana. R.H.Porter, London. 5 vol.
- Hooker, J.D. 1846 P. orchidioides. Botanical Magazine. 72: tab. 4231
- Humboldt, A., A. Bonpland & C.S. Kunth. 1817. Nova genera et species plantarum. II: pp. 225–226
- Legendre L (2000). "The genus Pinguicula L. (Lentibulariaceae): an overview". Acta Botanica Gallica 141 (1): 77–95.
- Mc Vaugh, R. & J.T.Mickel 1963. Notes on Pinguicula, sec. Orcheosanthus. Brittonia, Vol. 15, Issue 2 (apr. 15, 1963), p. 134–140
- Morren, E. 1872. Notice sure le Pinguicula flos-Mulionis Ed. Mn. ou Grassette Fleur de Muletier, Fig. Pl. XXVII. Belgique Hort. 22:371–374
- Ruiz, S.Z. 2001 Revision de la seccion Orcheosanthus del Genero Pinguicula (Lentibulariaceae) Universidad Nacional Autónoma de México.
- Sessé, M. & J. M. Mociño. 1893. Plantae Novae Hispaniae. 2a. Ed. México. Oficina Tipográfica de la Secretaria de Fomento, México, D.F. 175 pp.
- Speta, F. & F. Fuchs 1989 Drei neue Pinguicula-Arten der Sektion Orcheosanthus DC. aus Mexiko; Phyton (Austria), vol. 29, fasc. 1, pp. 93–103
- Sprague, T.A. 1928. The orchid-flowered butterworts. Kew Bull. 6: 230–234
- Watson, W. 1911. Pinguicula rosei. Gard. Chron. ser. 3, 29: 82.
- Zamudio, S. 1999 Notas sobre la identidad de Pinguicula moranensis H.B.K., con la description de una variedad nueva, Acta Botanica Mexicana, 1999, vol.49, pages 23–34
External links
- A World of Pinguicula — Articles, photos, taxanomic and horticultural information
- Carnivorous Plant Photo Finder: Pinguicula
- International Carnivorous Plant Society
- Pinguicula Discussion Forum
- Carnivorous plants of North America
- Flora of Chiapas
- Flora of Guerrero
- Flora of Hidalgo
- Flora of the State of Mexico
- Flora of Michoacán
- Flora of Morelos
- Flora of Oaxaca
- Flora of Puebla
- Flora of Querétaro
- Flora of San Luis Potosí
- Flora of Tlaxcala
- Flora of the Yucatán
- Flora of Zacatecas
- Flora of Campeche
- Flora of Quintana Roo
- Flora of Yucatán
- Pinguicula