'', a tuberous sundew, beginning its winter growth Sundews are
perennial (or rarely
annual)
herbaceous plants, typically forming prostrate or upright rosettes between in height, depending on the species. Climbing species form scrambling stems which can reach much longer lengths, up to in the case of
D. erythrogyne. Sundews have been shown to be able to achieve a lifespan of 50 years. The genus is specialised for
nutrient uptake through its carnivorous behaviour, for example the pygmy sundew is missing the
enzymes (
nitrate reductase, in particular) that plants normally use for the uptake of earth-bound nitrates.
Growth form The genus can be divided into several
habits, or growth forms: • Temperate sundews: These species form a tight cluster of unfurled leaves called a
hibernaculum in a winter dormancy period (=
Hemicryptophyte). All of the northern Asian, European, and North American species belong to this group.
Drosera arcturi from Australia (including Tasmania) and New Zealand is another temperate species that dies back to a horn-shaped hibernaculum. • Subtropical sundews: These species maintain vegetative growth year-round under uniform or nearly uniform climatic conditions. • Pygmy sundews: A group of roughly 40 Australian species, they are distinguished by miniature growth, the formation of
gemmae for
asexual reproduction, and dense formation of hairs in the crown centre. These hairs serve to protect the plants from Australia's intense summer sun. Pygmy sundews form the subgenus
Bryastrum. • Tuberous sundews: These nearly 50 Australian species form an underground
tuber to survive the extremely dry summers of their habitat, re-emerging in the autumn. These so-called tuberous sundews can be further divided into two groups, those that form rosettes and those that form climbing or scrambling stems. Tuberous sundews comprise the subgenus
Ergaleium. '', from the petiolaris complex • The
Drosera petiolaris complex: A group of tropical Australian species, they live in constantly warm but sometimes wet conditions. Several of the 14 species that comprise this group have developed special strategies to cope with the alternately drier conditions. Many species, for example, have
petioles densely covered in
trichomes, which maintain a sufficiently humid environment and serve as an increased
condensation surface for morning dew. The
D. petiolaris complex comprises the section
Lasiocephala. Although they do not form a single strictly defined growth form, a number of species are often put together in a further group: • Queensland sundews: A small group of three species (
D. adelae,
D. schizandra and
D. prolifera), all are native to highly humid habitats in the dim understories of the Australian rainforest.
Leaves and carnivory '' Sundews are characterised by the glandular tentacles, topped with sticky secretions, that cover their
leaves. The trapping and digestion mechanism usually employs two types of glands: stalked glands that secrete sweet mucilage to attract and ensnare insects and enzymes to digest them, and
sessile glands that absorb the resulting nutrient soup (the latter glands are missing in some species, such as
D. erythrorhiza). Small prey, mainly consisting of insects, are attracted by the sweet secretions of the peduncular glands. Upon touching these, the prey become entrapped by sticky mucilage which prevents their progress or escape. Eventually, the prey either succumb to death through exhaustion or through asphyxiation as the mucilage envelops them and clogs their
spiracles. Death usually occurs within 15 minutes. The plant meanwhile secretes
esterase,
peroxidase,
phosphatase and
protease enzymes. In addition to tentacle movement, some species are able to bend their leaves to various degrees to maximise contact with the prey. Of these,
D. capensis exhibits what is probably the most dramatic movement, curling its leaf completely around prey in 30 minutes. Some species, such as
D. filiformis, are unable to bend their leaves in response to prey. '' A further type of (mostly strong red and yellow) leaf coloration has recently been discovered in a few Australian species (
D. hartmeyerorum,
D. indica). Their function is not known yet, although they may help in attracting prey. The leaf morphology of the species within the genus is extremely varied, ranging from the sessile
ovate leaves of
D. erythrorhiza to the bipinnately divided
acicular leaves of
D. binata. The leaves of some
Western Australian species are very small, down to a leafblade or
lamina of just 1 mm diameter in the instance of
Drosera occidentalis. While the exact physiological mechanism of the sundew's carnivorous response is not yet known, some studies have begun to shed light on how the plant is able to move in response to mechanical and chemical stimulation to envelop and digest prey. Individual tentacles, when mechanically stimulated, fire action potentials that terminate near the base of the tentacle, resulting in rapid movement of the tentacle towards the centre of the leaf. This response is more prominent when marginal tentacles further away from the leaf centre are stimulated. The tentacle movement response is achieved through auxin-mediated
acid growth. When action potentials reach their target cells, the plant hormone
auxin causes protons (H+ ions) to be pumped out of the plasma membrane into the cell wall, thereby reducing the pH and making the cell wall more acidic. The resulting reduction in pH causes the relaxation of the cell wall protein, expansin, and allows for an increase in cell volume via osmosis and turgor. As a result of differential cell growth rates, the sundew tentacles are able to achieve movement towards prey and the leaf centre through the bending caused by expanding cells. Among some
Drosera species, a second bending response occurs in which non-local, distant tentacles bend towards prey as well as the bending of the entire leaf blade to maximise contact with prey. While mechanical stimulation is sufficient to achieve a localised tentacle bend response, both mechanical and chemical stimuli are required for the secondary bending response to occur.
Flowers and fruit '' The flowers of sundews, as with nearly all carnivorous plants, are held far above the leaves by a long stem. This physical isolation of the flower from the traps is commonly thought to be an adaptation meant to avoid trapping potential
pollinators. The mostly unforked
inflorescences are
spikes, whose flowers open one at a time and usually only remain open for a short period. Flowers open in response to light intensity (often opening only in direct sunlight), and the entire inflorescence is also
heliotropic, moving in response to the sun's position in the sky. The
radially symmetrical (
actinomorphic) flowers are always
perfect and have five parts (the exceptions to this rule are the four-petaled
D. pygmaea and the eight to 12-petaled
D. heterophylla). Most of the species have small flowers (<1.5 cm or 0.6 in). A few species, however, such as
D. regia and
D. cistiflora, have flowers or more in diameter. They are relatively useless for nutrient uptake, and they serve mainly to absorb water and to anchor the plant to the ground; they have long
hairs. they also host fungi like
endophytes to collect nutrients when they grow in poor soil and form
symbiotic relationships. == Reproduction ==