Chrysopelea paradisi

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Paradise flying snake
Chrysopelea paradisi (6032067972).jpg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Order: Squamata
Suborder: Serpentes
Family: Colubridae
Subfamily: Ahaetuliinae
Genus: Chrysopelea
Species:
C. paradisi
Binomial name
Chrysopelea paradisi
Boie, 1827

Paradise tree snake or paradise flying snake (Chrysopelea paradisi) is a species of colubrid snake found in Southeast Asia. It can, like all species of its genus Chrysopelea , glide by stretching the body into a flattened strip using its ribs. It is mostly found in moist forests and can cover a horizontal distance of 10 meters or more [2] in a glide from the top of a tree. Slow motion photography shows an undulation of the snake's body in flight while the head remains relatively stable, suggesting controlled flight. They are mildly venomous with rear fangs and also can constrict their prey, which consists of mostly lizards and bats.

Contents

Paradise flying snake from Bukit Lawang, Indonesia Paradise flying snake (Chrysopelea paradisi).jpg
Paradise flying snake from Bukit Lawang, Indonesia

Etymology

The species name paradisi comes from either the Latin "paradisus" or Greek "paradeisos", which means park. It is assumed that the holotype from 1826 was found in a park. [3]

Taxonomy

Chrysopelea paradisi belongs to the genus Chrysopelea , which contains four other described species. [4]

Chrysopelea is one of five genera belonging to the vine snake subfamily Ahaetuliinae, of which Chrysopelea is most closely related to Dendrelaphis , as shown in the cladogram below: [5]

Ahaetuliinae
Paradise Flying Snake at the Children's Aquarium at Fair Park Paradise Flying Snake.jpg
Paradise Flying Snake at the Children's Aquarium at Fair Park

Distribution

It is found in Thailand, Indonesia, Brunei, India, Malaysia, Myanmar, Philippines, and Singapore. [3]

Behavior

It lives in forests and is fully arboreal, and glides between trees. It has oviparous reproduction. [3]

Similar to some other colubrid snakes, flying snakes possess enlarged posterior maxillary teeth, produce venom from Duvernoy's glands, and are believed to be mildly venomous. [6]

Because this snake is uncommon, arboreal, and prefers forests, encounters with humans are rare. However, there was a report of a 45-year-old woman who was bitten on her right thumb by a snake hanging to the window grill when she was trying to close the windowpanes of her bedroom. [6]

Gliding

The flying snake has a unique kinematic that is different compared to other animals with gliding or flight because they are cylindrical and do not have limbs such as legs or wings. [7] Although the flying snake does not display visible characteristics that contribute to its ability to glide, there are three aspects that have been studied and found to have great positive effects on this. Their form of takeoff which is most commonly the anchored J-loop take-off, [8] once airborne their cross sectional body is shaped into a triangle, [9] and their bodies use an aerial undulation to maximize the distance traveled. [10]

Related Research Articles

<span class="mw-page-title-main">Flying squirrel</span> Tribe of mammals

Flying squirrels are a tribe of 50 species of squirrels in the family Sciuridae. Despite their name, they are not in fact capable of full flight in the same way as birds or bats, but they are able to glide from one tree to another with the aid of a patagium, a furred skin membrane that stretches from wrist to ankle. Their long tails also provide stability as they glide. Anatomically they are very similar to other squirrels with a number of adaptations to suit their lifestyle; their limb bones are longer and their hand bones, foot bones, and distal vertebrae are shorter. Flying squirrels are able to steer and exert control over their glide path with their limbs and tail.

Constriction is a method used by several snake species to kill or subdue their prey. Although some species of venomous and mildly venomous snakes do use constriction to subdue their prey, most snakes which use constriction lack venom. The snake strikes at its prey and holds on, pulling the prey into its coils or, in the case of very large prey, pulling itself onto the prey. The snake then wraps one or two loops around the prey, forming a constriction coil. The snake monitors the prey's heartbeat to ascertain it is dead. This can be a physically demanding and potentially dangerous procedure for the snake, because its metabolism is accelerated up to sevenfold and it becomes vulnerable to attack by another predator.

Concertina movement is the method by which a snake or other organism anchors itself with sections of itself and pulls or pushes with other sections to move in the direction it wants to go. To spring forward a snake may require a rough surface to thrust back against. It is named after the concertina musical instrument.

Robot locomotion is the collective name for the various methods that robots use to transport themselves from place to place.

<span class="mw-page-title-main">Bird flight</span> Aerial locomotion in avian dinosaurs

Bird flight is the primary mode of locomotion used by most bird species in which birds take off and fly. Flight assists birds with feeding, breeding, avoiding predators, and migrating.

<i>Chrysopelea</i> Genus of snakes

Chrysopelea, commonly known as the flying snake or gliding snake, is a genus of snakes that belongs to the family Colubridae. They are found in Southeast Asia, and are known for their ability to glide between trees. Flying snakes are mildly venomous, though the venom is dangerous only to their small prey. There are five species within the genus.

<i>Chrysopelea ornata</i> Species of snake

Chrysopelea ornata is a mildly venomous opisthoglyphous (rear-fanged) colubrid snake found in both South and Southeast Asia. It is commonly known as the golden tree snake, ornate flying snake, and golden flying snake. Along with the other species in the Chrysopelea genus, the golden tree snake is very unusual, as it is capable of a type of gliding "flight" —mainly utilised during the pursuit of prey animals—from tree-to-tree. This action is also used to great effect for the snake to flee its own potential predators. Currently, three subspecies are recognised. The snake's striking looks, and potential for gliding, have made it a coveted choice for captivity.

<i>Dendrelaphis cyanochloris</i> Species of snake

Dendrelaphis cyanochloris, commonly known as Wall's bronzeback or the blue bronzeback, is a species of colubrid snake found in Southeast Asia.

<i>Dendrelaphis tristis</i> Species of snake

Dendrelaphis tristis is a species of colubrid tree-snake found in South Asia.

<i>Dendrelaphis caudolineatus</i> Species of snake

Dendrelaphis caudolineatus, commonly known as the striped bronzeback or grey bronzeback, is a species of colubrid snake found in Southeast Asia.

<i>Ahaetulla</i> Genus of snakes

Ahaetulla, commonly referred to as Asian vine snakes or Asian whip snakes, is a genus of colubrid snakes distributed throughout tropical Asia. They are considered by some scientists to be mildly venomous and are what is commonly termed as 'rear-fanged' or more appropriately, opisthoglyphous, meaning their enlarged teeth or fangs, intended to aid in venom delivery, are located in the back of the upper jaw, instead of in the front as they are in vipers or cobras. As colubrids, Ahaetulla do not possess a true venom gland or a sophisticated venom delivery system. The Duvernoy's gland of this genus, homologous to the venom gland of true venomous snakes, produces a secretion which, though not well studied, is considered not to be medically significant to humans.

<span class="mw-page-title-main">Flying and gliding animals</span> Animals that have evolved aerial locomotion

A number of animals are capable of aerial locomotion, either by powered flight or by gliding. This trait has appeared by evolution many times, without any single common ancestor. Flight has evolved at least four times in separate animals: insects, pterosaurs, birds, and bats. Gliding has evolved on many more occasions. Usually the development is to aid canopy animals in getting from tree to tree, although there are other possibilities. Gliding, in particular, has evolved among rainforest animals, especially in the rainforests in Asia where the trees are tall and widely spaced. Several species of aquatic animals, and a few amphibians and reptiles have also evolved this gliding flight ability, typically as a means of evading predators.

<span class="mw-page-title-main">Origin of avian flight</span> Evolution of birds from non-flying ancestors

Around 350 BCE, Aristotle and other philosophers of the time attempted to explain the aerodynamics of avian flight. Even after the discovery of the ancestral bird Archaeopteryx which lived over 150 million years ago, debates still persist regarding the evolution of flight. There are three leading hypotheses pertaining to avian flight: Pouncing Proavis model, Cursorial model, and Arboreal model.

Gliding flight is heavier-than-air flight without the use of thrust; the term volplaning also refers to this mode of flight in animals. It is employed by gliding animals and by aircraft such as gliders. This mode of flight involves flying a significant distance horizontally compared to its descent and therefore can be distinguished from a mostly straight downward descent like a round parachute.

<span class="mw-page-title-main">Arboreal locomotion</span> Movement of animals through trees

Arboreal locomotion is the locomotion of animals in trees. In habitats in which trees are present, animals have evolved to move in them. Some animals may scale trees only occasionally, but others are exclusively arboreal. The habitats pose numerous mechanical challenges to animals moving through them and lead to a variety of anatomical, behavioral and ecological consequences as well as variations throughout different species. Furthermore, many of these same principles may be applied to climbing without trees, such as on rock piles or mountains.

<span class="mw-page-title-main">Banded flying snake</span> Species of snake

The twin-barred tree snake is a species of colubrid snake found in Southeast Asia. It is also called the banded flying snake. It can glide, as with all species of its genus Chrysopelea, by stretching the body into a flattened strip using its ribs. It is fully arboreal, mostly found in moist forests, and can cover a horizontal distance of about 100 metres in a glide from the top of a tree. It is an oviparous snake.

<i>Chrysopelea taprobanica</i> Species of snake

Chrysopelea taprobanica, the Sri Lankan flying snake or Indian flying snake, is a species of gliding colubrid snake distributed in India and Sri Lanka. It can glide, as with all species of its genus Chrysopelea, by stretching the body into a flattened strip using its ribs. The snake is known as "dangara dandaa - දඟරදන්ඩා" in Sinhala, due to its folding postures.

<i>Ahaetulla mycterizans</i> Species of snake

Ahaetulla mycterizans, the Malayan green whipsnake or Malayan vine snake, is a slender arboreal colubrid vine snake found in Southeast Asia.

<span class="mw-page-title-main">Ahaetuliinae</span> Subfamily of snakes

The Ahaetuliinae are a subfamily of vine snakes within the family Colubridae that was erected in 2016. They are found from South and Southeast Asia through to Australia.

Batoids are a superorder of cartilaginous fish consisting of skates, rays and other fish all characterized by dorsoventrally flattened bodies and large pectoral fins fused to the head. This distinctive morphology has resulted in several unique forms of locomotion. Most Batoids exhibit median paired fin swimming, utilizing their enlarged pectoral fins. Batoids that exhibit median paired fin swimming fall somewhere along a spectrum of swimming modes from mobuliform to rajiform based on the number of waves present on their fin at once. Of the four orders of Batoidae this holds truest for the Myliobatiformes (rays) and the Rajiformes (skates). The two other orders: Rhinopristiformes and Torpediniformes exhibit a greater degree of body caudal fin swimming.

References

  1. Vogel, G.; Wogan, G.; Diesmos, A.C.; Gonzalez, J.C.; Inger, R.F. (2014). "Chrysopelea paradisi". IUCN Red List of Threatened Species . 2014: e.T183189A1732041. doi: 10.2305/IUCN.UK.2014-1.RLTS.T183189A1732041.en . Retrieved 20 November 2021.
  2. "Here's how flying snakes stay aloft". Science News. 2020-06-29. Retrieved 2021-01-14.
  3. 1 2 3 Chrysopelea paradisi at the Reptarium.cz Reptile Database . Accessed 26 June 2024.
  4. Genus Chrysopelea at The Reptile Database.
  5. Mallik, Ashok Kumar; Achyuthan, N. Srikanthan; Ganesh, Sumaithangi R.; Pal, Saunak P.; Vijayakumar, S. P.; Shanker, Kartik (27 July 2019). "Discovery of a deeply divergent new lineage of vine snake (Colubridae: Ahaetuliinae: Proahaetulla gen. nov.) from the southern Western Ghats of Peninsular India with a revised key for Ahaetuliinae". PLOS ONE . 14 (7): e0218851. Bibcode:2019PLoSO..1418851M. doi: 10.1371/journal.pone.0218851 . ISSN   1932-6203. PMC   6636718 . PMID   31314800.
  6. 1 2 Silva, Anjana; Weerawansa, Prasanna; Pilapitiya, Senaka; Maduwage, Thilina; Siribaddana, Sisira (September 2013). "First Authenticated Case of Sri Lankan Flying Snake ( Chrysopelea taprobanica ) Bite". Wilderness & Environmental Medicine. 24 (3): 273–276. doi:10.1016/j.wem.2013.01.008. ISSN   1080-6032.
  7. Socha, J. J. (2011, August 3). Gliding flight in Chrysopelea: Turning a snake into a wing. OUP Academic. Retrieved October 28, 2022, from https://academic.oup.com/icb/article/51/6/969/616152?login=true
  8. Socha, J. J. (1 September 2006). "Becoming airborne without legs: the kinematics of take-off in a flying snake, Chrysopelea paradisi". Journal of Experimental Biology. 209 (17): 3358–3369. doi: 10.1242/jeb.02381 . PMID   16916972.
  9. Holden, D.; Socha, J. J.; Cardwell, N. D.; Vlachos, P. P. (29 January 2014). "Aerodynamics of the flying snake Chrysopelea paradisi: how a bluff body cross-sectional shape contributes to gliding performance". Journal of Experimental Biology. 217 (3): 382–394. doi: 10.1242/jeb.090902 . PMID   24477611.
  10. Socha, J. J. (15 May 2005). "A 3-D kinematic analysis of gliding in a flying snake, Chrysopelea paradisi". Journal of Experimental Biology. 208 (10): 1817–1833. doi: 10.1242/jeb.01579 . PMID   15879063.

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