Friday, September 30, 2011

Reptile Fire

Ex-NFL Star's Snake Breeding Business Damaged in Fire

Former Pro Chad Brown loses all but seven snakes

September 27, 2011


Former NFL and University of Colorado football player Chad Brown appears to have lost nearly his entire collection of snakes in a fire at his reptile store, Pro Exotics, in Littleton Colorado. According to a report on FOX31 in Denver, the fire started at around 5:30 a.m. September 26 and destroyed two units of the reptile store and caused damage to surrounding businesses in the industrial park. "Bad things are going to happen to us in life,” Brown, co-owner of the store with business partner Robyn Markland, told FOX31. “It's what we do about them, not what has happened to us.”
Brown lost approximately 2,000 African ball pythons in the fire, and estimates his losses in the tens of thousands to hundreds of thousands of dollars, according to the report. Six rat snakes and a Boa constrictor (Boa constrictor imperator) survived the fire. Brown first became interested in snakes while attending the University of Colorado after a friend gave him a snake. He then obtained more snakes and started breeding them while in college. The fire, which was reported after a police officer responded to a burglary alarm at the office complex, is under investigation.



Thursday, September 29, 2011

Epomis Beetles Turn On Their Unsuspecting Amphibian Predators

Larvae of the genus Epomis eats amphibians

September 26, 2011



Research is just at a preliminary stage, with much still to be discovered, although it has been known previously from studies in Israel that adult Epomis beetles often occur alongside amphibians and will also prey on them. Image courtesy Tel Aviv University.
While it's usually the frog that catches the unsuspecting bug for a tasty snack, another potential outcome to this story has now emerged. In an unprecedented reversal of the usual role of prey and predator, a certain group of ground beetle larvae can deliberately lure would-be amphibian predators within reach and then consume them with a success rate of almost 100%. In a report just published, researchers describe for the first time how these larvae are able to pull off this feat.
Caught unawareAccording to the scientists, larvae of the genus Epomis combine a sit-and-wait strategy with unique movements of their antennae and mouthparts, in order to attract the attention of an hungry amphibian, such as a frog or toad. As the amphibian is attracted closer, thinking it has spotted potential prey, so the beetle larva increases the intensity of these enticing motions, reinforcing this impression.
Then, when the amphibian attacks, the larva almost always manages to avoid the predator's tongue. Instead, it uses its unique double-hooked mouthparts to attach itself to the amphibian's body and begin feeding in a particularly gory way. This can include both sucking out the amphibian's bodily fluids and also chewing its body tissues. The combined effect of this assault is usually fatal for its much larger adversary.
How this may have occurred"Interestingly, both adult beetles and larvae of species related to Epomis are commonly preyed upon by amphibians," says the senior author Gil Wizen. "It seems that instead of serving as food items for amphibians, Epomis larvae have evolved to specifically take advantage of amphibians as a food source. The amphibians themselves are unaware of this danger, and this makes them highly vulnerable."
These findings extend the perspective of co-evolution in the arms race between predator and prey and suggest that counterattack defense behavior has evolved into predator-prey role reversal. However, the mechanism of the larva's swift counterattack against the speedy amphibian is still unknown.
Research in this area is just at a preliminary stage, with much still to be discovered, although it has been known previously from studies in Israel that adult Epomis beetles often occur alongside amphibians and will also prey on them.
Got From: http://www.reptilechannel.com/reptile-news/2011/09/26/epomis-eats-frogs.aspx


Gila Monster

Wednesday, September 28, 2011

Gila Monster

Gila Monster  



The Gila Monster is a large, venomous lizard. This slow-moving predator was named for the Gila River Basin in the southwestern United States. The Gila Monster's scientific name is Heloderma suspectum (genus and species).
This solitary meat-eater is mostly nocturnal, most active during the night. The Gila Monster becomes dormant and stays in a burrow during the winter. This lizard can live for months without food; it lives off fat stores in its tail. Its life span is about 20 years.
Habitat: Gila Monsters live in the Mojave, Sonoran, and Chihuahuan deserts of Mexico and the USA. It is the only poisonous lizard found in North America.
Venom: The Gila Monster has a potent venom, a nerve toxin, that is produced in glands located in the lower jaw. When a Gila Monster bites an animal, the poison flows into the wound via grooved teeth. This poison only rarely kills people.
Diet: The Gila Monster is a carnivore (meat-eater). It eats small mammals (like rats and mice), birds, lizards, frogs, and eggs. It senses prey using its long, sensitive tongue.
Anatomy: The Gila Monster averages almost 18 to 22 inches (46-55 cm) long and weighs about 3 pounds (1.3 kg). The scaly, bead-like skin is pink, yellow, and black; there are dark bands on the tail. It has a large head, large jaws, a thick tail, four short legs, and five-toed feet with sharp claws.
Reproduction: The female Gila Monster digs a hole in sandy soil, lays 3 to 15 eggs, and then covers them up with sand. Hatchlings are from 3.5 to 4.5 inches (9-11 cm) long.
Got From: http://www.enchantedlearning.com/subjects/reptiles/lizard/Gilamonster.shtml

Tuatara

Tuatara

Tuatara  



The Tuatara is an unusual reptile that lives on islands off the coast of New Zealand. This nocturnal (most active at night) animal sleeps in a burrow during the day and hunts at night. Although it looks like a lizard, it is not a lizard. The Tuatara has a life span of well over 60 years; it does not reach maturity until it is 20 years old.
Anatomy: Tuataras have dorsal crests along their back. They have a third pineal or parietal "eye" on their forehead; its purpose is unsure. These reptiles grow to be about 2 feet (60 cm) long. Unlike all other reptiles, the Tuatara's teeth are fused to the jaw bone.
Diet: Tuataras are carnivores (meat eaters). They eat insects (like the weta (a cricket), moths and beetles), reptiles (like lizards), worms, snails, eggs, baby birds and even other Tuataras.
Predators: Tuataras are eaten by rodents, pigs, and wild cats.
Habitat: Tuataras are native to chaparral habitats on islands off New Zealand. They went extinct on New Zealand itself in the late 1800's.
Reproduction: Tuataras hatch from leathery-skinned eggs. The female lays about a dozen eggs in a burrow; they take 1 to 1 1/4 years to hatch. There is no parental care.
Classification: Class Reptilia (reptiles), Order Rhynchocephalia (beak-headed reptiles), Family Sphenodontidae, Genus Sphenodon , Species punctatus and guntheri.
Got From: http://www.enchantedlearning.com/subjects/reptiles/tuatara/Tuataraprintout.shtml

Tuesday, September 27, 2011

Komodo Dragons

WARNING: This video contains Komodo dragons devouring a buffalo

Monday, September 26, 2011

The Komodo Dragon


http://www.pbs.org/
With its sheer strength and deadly, bacteria-ridden saliva, the Komodo dragon is the top predator in its range.


Komodo dragons have thrived in the harsh climate of Indonesia's Lesser Sunda Islands for millions of years, although amazingly, their existence was unknown to humans until about 100 years ago.
Reaching 10 feet (3 meters) in length and more than 300 pounds (136 kilograms), Komodo dragons are the heaviest lizards on Earth. They have long, flat heads with rounded snouts, scaly skin, bowed legs, and huge, muscular tails.
As the dominant predators on the handful of islands they inhabit, they will eat almost anything, including carrion, deer, pigs, smaller dragons, and even large water buffalo and humans. When hunting, Komodo dragons rely on camouflage and patience, lying in wait for passing prey. When a victim ambles by, the dragon springs, using its powerful legs, sharp claws and serrated, shark-like teeth to eviscerate its prey.
Animals that escape the jaws of a Komodo will only feel lucky briefly. Dragon saliva teems with over 50 strains of bacteria, and within 24 hours, the stricken creature usually dies of blood poisoning. Dragons calmly follow an escapee for miles as the bacteria takes effect, using their keen sense of smell to hone in on the corpse. A dragon can eat a whopping 80 percent of its body weight in a single feeding.
There is a stable population of about 3,000 to 5,000 Komodo dragons on the islands of Komodo, Gila Motang, Rinca, and Flores. However, a dearth of egg-laying females, poaching, human encroachment, and natural disasters has driven the species to endangered status.

Map

Map: Komodo dragon range
Komodo Dragon Range

Fast Facts

Type:
Reptile
Diet:
Carnivore
Average life span in the wild:
30 years+
Size:
10 ft (3 m)
Weight:
330 lbs (150 kg)
Protection status:
Endangered
Did you know?
Komodo dragons can run up to 11 mph (18 kph) in short bursts.
Size relative to a 6-ft (2-m) man:
Illustration: Komodo dragon compared with adult man
Got From: http://animals.nationalgeographic.com/animals/reptiles/komodo-dragon/

Thursday, September 22, 2011

Green Anole Care

Green Anole

First Reptile Genome Sequenced

Genetic map of the green anole produced for the first time

September 7, 2011

 
Anoles are rich in ecology and morphology and have just the right amount of diversity to make them interesting yet tractable to study. Photo credit: David E. Scott, Savannah River Ecology Laboratory, Aiken, SC, USA.

The green anole lizard (Anolis carolinensis) – a native of the southeastern United States – is the first reptile to have its genetic blueprint, known as a genome, sequenced and assembled. Broad Institute researchers have studied more than 20 mammalian genomes – including those of some of our closest relatives – but the genetic landscape of reptiles has remained relatively unexplored.
Lizards are more closely related to birds than to any of the other groups whose genomes have been sequenced in full. "People have been sequencing animals from different parts of the vertebrate tree, but lizards had not been previously sampled," explained Kerstin Lindblad-Toh, scientific director of vertebrate genome biology at the Broad who has been closely involved in the research. "This was an important branch to look at."
Amazing DiversityFour hundred species of anole lizards have fanned out across North America, Central America, the islands of the Caribbean and South America, making them an appealing model for studying evolution. Although much is known about their biology and behavior, genomic information may be a critical missing piece for understanding how the lizards have become so diverse.

"Anoles are rich in ecology and morphology and have just the right amount of diversity to make them interesting yet tractable to study," said Jonathan Losos, an author of the paper, professor at Harvard University, and author of the book Lizards in an Evolutionary Tree: Ecology and Adaptive Radiation of Anoles.
"But a big stumbling block in studying them has been that they have not been great organisms for classical genetic study. This genome is going to revolutionize our ability to study that aspect of their evolutionary diversification."
In addition to insights into human and mammalian genomes, the anole lizard’s genome also offers up clues about how lizard species evolved to populate islands in the Greater Antilles. Much like Darwin’s finches, anoles adapted to fill all of the ecological niches the islands have to offer.
Some lizards have short legs and can walk along narrow twigs; others are green in color with big toe pads suited for living high up in trees; others are yellow and brown and live in the grass. But unlike the finches, lizards on different islands have independently evolved diverse communities of these twig, canopy, and grass dwelling species – almost identical lizard species have evolved in parallel on the islands of Hispaniola, Puerto Rico, Cuba, and Jamaica.
"These lizards have been compared to Darwin’s finches and in many respects they are similar," said Losos. "They show the workings of natural selection as species adapted to different habitats. But the difference is in the case of the lizards, this evolution has happened four times, once on each of the different islands."
By sampling the genomes of more than 90 species, the researchers were able to make a preliminary map of how these species evolved to colonize the islands. "This is setting the stage for the research community to be able to look for signatures of adaptation in a very informative and coherent way," said Lindblad-Toh.
Color VisionThe researchers were also able to create a "parts list" of proteins found in green anole eggs, which they compared with those found in eggs from chickens and they discovered that both bird and lizard egg genes are evolving rapidly. They also mapped many genes in the anoles’ genome associated with color vision, which these lizards use to identify mates.
"Anoles have extremely good color vision – some species can even see in the ultraviolet range," said Losos. Other studies have shown that anoles can distinguish between similar colors and patterns. "It’s pretty clear that one function of the dewlap is to distinguish one species from others and that they use the dewlap - the skin fold under the chin - to determine whether a particular individual belongs to their species or not."
Reference: Alfoldi J et al. "The genome of the green anole lizard and a comparative analysis with birds and mammals." Nature August 31, 2011 doi:10.1038/nature10390

Got From: http://www.reptilechannel.com/reptile-news/2011/09/07/reptile-genome-sequenced.aspx

Wednesday, September 21, 2011

Bearded Dragon Care

Beardie Health

Bearded Dragon Basking Open Mouth

Why do bearded dragons bask with their mouth open?

By Margaret A. Wissman, DVM, DABVP

Q. I own three bearded dragons. One of my male bearded dragons sits under his basking lamp with his mouth wide open. None of my other bearded dragons do this and I am concerned. My friend told me that it is normal and it is how bearded dragons regulate their heat but I read somewhere that it can mean they have a respiratory illness. He has been doing it for a while but is still very active and seems normal. Any help would be appreciated. Thanks.
A. The good news is that this is a normal behavior for bearded dragons.  It seems that many owners don’t realize how warm these lizards should really be maintained, so they don’t see this behavior.  The key to keeping bearded dragons happy is to have a basking spotlight that allows them to raise their body temperature to 95 to 110 degrees Fahrenheit.  When a bearded dragon reaches its thermal maximum, it will often sit with its mouth open.  This behavior, called gaping, shows that the lizard is at its optimal temperature for basking.  This gaping will allow a bearded dragon to dissipate extra body heat.  Since lizards don’t sweat, this is an effective way for them to regulate their body temperature.  It is important that your bearded dragon habitat have a thermal gradient, so that your lizards can move to a cooler location, if they so desire, once they have reached their optimum body temperatures.
Open-mouth breathing is usually a sign of respiratory disease in other types of herps, and is an especially dangerous sign in snakes, however it can be normal in some lizards, including bearded dragons.
The good news is that you are keeping your bearded dragons at the correct temperature gradient, apparently, and you have nothing to worry about.
Margaret A. Wissman, DVM, DABVP has been an avian/exotic/herp animal veterinarian since 1981. She is a regular contributor to REPTILES magazine. Looking for a local herp vet? Click here>>

Got From: http://www.reptilechannel.com/lizards/lizard-care/bearded-dragon-basking.aspx

Tuesday, September 20, 2011

The Sandfish Lizard

How the Sandfish Lizard has Helped to Build a Machine

Reptile inspires rescuers

September 12, 2011


Click image to enlarge
Photo caption The inspiration sandfish (Scincus scincus), showing its distinctive head shape.
Credit: Wilfried Berns/Tiermotive.de
.
Machines able to navigate through the rubble of buildings in the aftermath of disasters such as earthquakes would be of great benefit to rescuers, saving vital time in the search for those trapped alive in the debris, but building effective machines is extremely challenging. Researchers at the Georgia Institute of Technology recently built a robot that can penetrate and 'swim' through granular material. They have now shown that varying the shape or adjusting the inclination of the robot's head affects the robot's movement in complex environments.
"We discovered that by changing the shape of the sand-swimming robot's head or by tilting its head up and down slightly, we could control the robot's vertical motion as it swam forward within a granular medium," explained Daniel Goldman, an assistant professor in the Georgia Tech School of Physics.
Desert reptile mechanics"The biological inspiration for our sand-swimming robot is the sandfish lizard, which inhabits the Sahara desert in Africa and rapidly buries into and swims within sand," explained Goldman. "We were intrigued by the sandfish lizard's wedge-shaped head that forms an angle of 140 degrees with the horizontal plane, and we thought its head might be responsible for or be contributing to the animal's ability to maneuver in complex environments."
For their experiments, the researchers attached a wedge-shaped block of wood to the head of their robot, which was built with seven connected segments, powered by servo motors, packed in a latex sock and wrapped in a spandex swimsuit. The doorstop-shaped head - resembling that of the sandfish - had a fixed lower length of approximately 4 inches, height of 2 inches and a tapered snout. The researchers examined whether the robot's vertical motion could be controlled simply by varying the inclination of the robot's head. Before each experimental run in a test chamber filled with plastic spheres which had a 0.25 inch diameter, the researchers submerged the robot a couple of inches into the granular medium and leveled the surface. Then they tracked the robot's position until it reached the end of the container or swam to the surface.
Effect of adjustments The researchers investigated the vertical movement of the robot when its head was placed at five different degrees of inclination. They found that when the sandfish-inspired head with a leading edge that formed an angle of 155 degrees with the horizontal plane was set flat, negative lift force was generated and the robot moved downward into the media. As the tip of the head was raised from zero to 7 degrees relative to the horizontal, the lift force increased until it became zero. At inclines above 7 degrees, the robot rose out of the medium. "The ability to control the vertical position of the robot by modulating its head inclination opens up avenues for further research into developing robots more capable of maneuvering in complex environments, like debris-filled areas produced by an earthquake or landslide," said Goldman. The robotics results matched the research team's findings from physics experiments and computational models designed to explore how head shape affects lift in granular media.
"While the lift forces of objects in air, such as airplanes, are well understood, our investigations into the lift forces of objects in granular media are some of the first ever," he added. Being able to precisely control the tilt of the head will allow the researchers to implement different strategies of head movement during burial and determine the best way to wiggle deep into sand. The researchers also plan to test the robot's ability to maneuver through material similar to the debris found after natural disasters and plan to examine whether the sandfish lizard adjusts its head inclination to ensure a straight motion as it dives into the sand.

Monday, September 19, 2011

Reptile Vocabulary

Reptilia cladogram
http://www.enchantedlearning.com/subjects/reptiles/printouts.shtml

Ar·cho·sau·ria

noun pl \ˌär-kə-ˈsr-ē-ə\
 
Definition of ARCHOSAURIA
: a large subclass of Reptilia comprising the dinosaurs, pterosaurs, and crocodilians all distinguished by possessing temporal openings separated from each other by a postorbitosquamosal arch
ar·cho·sau·ri·an \¦ar-kə-¦sr-ē-ən\archos02 adjective or noun

Origin of ARCHOSAURIA

NL, fr. archo- (fr. Gk archōn) + -sauria

Browse

Next Word in the Dictionary: arch–poet
Previous Word in the Dictionary: archosaur
All Words Near: Archosauria

GOT FROM: http://www.merriam-webster.com/dictionary/archosauria

Oklahoma Reptiles

Oklahoma is rich in reptiles and amphibians, ranking third of all fifty states in number of species. Eighty species are represented, including one alligator, seventeen turtle, eighteen lizard, and forty-six snake species; and fifty-one species of amphibians are also present, including twenty-three salamander and twenty-eight frog and toad species. The state reptile is the collared lizard (Crotaphytus collaris, also called mountain boomer, although it is mute).This large lizard, which can run on its hind legs, reaches a total length of fourteen inches and is found on sunny, rocky outcrops statewide. The American alligator (Alligator mississippiensis) is rare in Oklahoma, found only in the extreme southeastern corner of the state. It is the only Oklahoma reptile with current state and federal conservation protection.

Of the turtles, one of the most interesting is the alligator snapping turtle (Macrochelys temminckii). This is the largest freshwater turtle in North America, with males reaching 250 pounds or more. Found in the eastern part of Oklahoma, it is rarely seen because it spends its entire life at the bottom of slow-moving rivers and creeks, except for females, who briefly leave the water to lay eggs. This turtle has a pink, fleshy protuberance in its mouth, which it wriggles while its mouth is held open. Curious fish approach this "worm" mimic and are captured by the turtle's jaws, strong enough to break a man's arm. The common snapping turtle (Chelydra serpentina), is also quite large, commonly reaching thirty-five pounds. Oklahoma's other turtles are much smaller and mostly aquatic, except for two species of terrestrial box turtles (Terrapene carolina and Terrapene ornata).

Noteworthy Oklahoma lizards (other than the state reptile mentioned above) include the Texas horned lizard (Phrynosoma cornutum), or horny toad, which is not a toad at all. This species has declined drastically in the last fifty to eighty years. It is a flattened, pancake sort of lizard, with sharp spines along its sides and stout horns projecting from the back of its head. It eats mostly ants and relies on its cryptic coloration to blend into its surroundings to escape predation. If severely disturbed by a dog or coyote, though, the horny toad is capable of spurting blood from the suborbital sinuses of its eyes, blood that apparently contains a substance that drives off the would-be predator. In southeastern Oklahoma lives the green anole (Anolis carolinensis), the popular "chameleon" sold in pet stores. This delicate lizard is arboreal and, like the true Old World chameleons (but not to the same extent), can change color from a drab brown to a bright emerald green.

Other lizards are long-tailed, actively foraging racerunners or whiptails (Teiidae), and smooth-scaled, shiny skinks (Scincidae). The slender glass lizard (Ophisaurus attenuatus) has no legs and is more tail than body. It is a lizard, though, as it has moveable eyelids and external ear openings. The Mediterranean house gecko (Hemidactylus turcicus) has been introduced from Texas (where it was introduced from the Mediterranean) to buildings on the campus of the University of Oklahoma and perhaps elsewhere in the southern part of the state. It is nocturnal, and the undersides of its toes have special microscopic, hairlike structures that allow it to climb on walls. It is the only species of lizard in Oklahoma that vocalizes. This, and some of the other lizards of Oklahoma (especially the skinks), can actively shed its tail (autotomy) if a predator grabs it, so as to be able to escape with its life. The tail can then regenerate.

Oklahoma sports more species of snakes than any other kind of reptile. There are blind snakes, hog-nosed snakes, wormsnakes, flat-headed snakes, groundsnakes, rough greensnakes, coachwhips, racers, ratsnakes, kingsnakes, milksnakes, bullsnakes, brownsnakes, earthsnakes, lined snakes, ribbonsnakes, gartersnakes, crayfish snakes, and watersnakes, among others. Probably the most common snake in Oklahoma is the small, gray ring-necked snake (Diadophis punctatus), usually found under rocks and logs. Although it is harmless to humans, this species can exude from its mouth a noxious fluid. When confronted by a potential predator, the snake will tightly coil its tail and flash its underside, which has a series of bright red and black bands, to warn or startle the molester.

Oklahoma has seven species of truly venomous snakes: the copperhead (Agkistrodon contortrix), cottonmouth or water moccasin (A. piscivorous), and five species of rattlesnakes, the Massasauga (Sistrurus catenatus), western pigmy (S. miliarius), timber (Crotalus horridus), western diamondback (C. atrox), and prairie rattler (C. viridis). All of these species are pit vipers, that is, between the eye and the nostril they have a heat-sensitive gland that is used to detect warm prey. The timber and diamondback rattlesnakes can grow especially large, over six feet long. Their rattles emit a loud, menacing warning sound, whereas the rattle of the much smaller Massasauga and western pygmy rattlesnake is nearly inaudible.

Turning to the amphibians, most of the salamanders require moist habitats and are found only in the eastern part of the state. They range in size from the diminutive, two-inch to three-inch Oklahoma salamander (Eurycea tynerensis), which reproduces in its gilled larval form, to the eighteen- to thirty-inch, three-toed amphiuma (Amphiuma tridactylium), which is aquatic and has extremely tiny limbs that cannot support its weight. One species, the central newt (Notophthalmus viridescens), has a complex life cycle in which it hatches from aquatic eggs into gilled larvae that live in small, fishless ponds. These larvae metamorphose into lunged efts, living on land for a few years, eventually returning to their natal ponds to take up an aquatic life again as gill-less newts. Here they reproduce. This species has highly toxic skin secretions and, especially the eft form, is bright red to warn potential predators. Most salamanders lay aquatic larvae that hatch into gilled larvae, but one genus (Plethodon) lays terrestrial eggs, in moist forest litter, moss, under logs, and so forth, that hatch into miniature, terrestrial adults. Interestingly, these adults lack both gills and lungs, "breathing" through their skin.

Of the frogs and toads, the most common and widespread species is the tiny cricket frog (Acris crepitans), which is often found along the shoreline of lakes and ponds. Unlike salamanders, frogs and toads vocalize; males sing to attract females for breeding. The call of the cricket frog sounds like two marbles repeatedly struck together. In contrast, the call of the also-abundant American toad (Bufo americanus) is a high-pitched trill lasting six to thirty seconds. This species, and its relatives, has a rough, warty skin containing irritating toxins that repel potential predators. On the back, just behind the head, are a pair of prominent parotid glands that deliver copious amounts of this chemical. Other frogs and toads of Oklahoma include treefrogs, with suction-cup toe tips to help them climb; narrowmouth toads, which often live together with tarantulas in their burrows; spadefoot toads, which live in more arid parts of the state and breed only after heavy summer rains; and true frogs, which include the largest frog of the state, the bullfrog (Rana catesbeiana). All of the state's species lay aquatic eggs that hatch into aquatic larvae (tadpoles) that later metamorphose into adults.

BIBLIOGRAPHY: Jeffrey H. Black and Gregory Sievert, A Field Guide to Amphibians of Oklahoma (Oklahoma City, Okla.: Oklahoma Department of Wildlife Conservation, 1989). Charles C. Carpenter and James J. Krupa, Oklahoma Herpetology: An Annotated Bibliography (Norman: University of Oklahoma Press, 1989). Roger Conant and Joseph T. Collins, Reptiles and Amphibians of Eastern/Central North America, Peterson Field Guide Series (3rd ed.; Boston: Houghton Mifflin, 1998). F. Harvey Pough, et al., Herpetology (2nd ed.; Upper Saddle River, N. J.: Prentice-Hall, 2001). George R. Zug, Laurie J. Vitt, and Janalee P. Caldwell, Herpetology: An Introductory Biology of Amphibians and Reptiles (2nd ed.; San Diego, Calif.: Academic Press, 2001).

Stanley F. Fox

GOT FROM: http://digital.library.okstate.edu/encyclopedia/entries/R/RE029.html

Friday, September 16, 2011

Kansas Reptiles

Click on each animal to go to their list for Kansas!

Are Vertebrate animals. They have an internal bony skeleton.
Are cold-blooded. They cannot maintain their body temperature by internal means.
Have a dry, scaly skin or a shell.
Lay eggs with a tough outer shell, or have live birth. The eggs have an internal membrane called the amnion, which helps protect the developing embryo from injury and drying out. In some species of snakes, the eggs hatch internally and the young are born live.
Lay their eggs on land.

Have claws on their toes (excepting snakes).

Currently, there are about 6,500 recognized species of reptiles in the world, divided into 5 living orders. Within Kansas 67 species are recorded from 16 families in 2 orders.

Classification of living organisms has undergone a profound revolution within the last thirty years due to the advent of DNA analysis and the new taxonomic discipline of cladistics, which does not necessarily use the classical Linnean hierarchy (Kingdom-Phylum-Class-Order-Family-Genus-Species) to sort out how creatures are related to each other. The position of turtles, for instance, is a contentious issue currently. For more information, see the link to the Tree of Life website in the resource list.

The species list below is based on "A Checklist of the Vertebrate Animals of Kansas", 3rd edition, 2005, by George Potts and Joseph Collins. This publication is available from the Kansas University Natural History Museum, 1345 Jayhawk Blvd., Lawrence, KS 66045-7163.

For a pdf version of the Kansas list, click here Kansas turtles & reptiles list.
(On a Windows system, download the file by right clicking on the link and choose "Save Target As" to save it to your hard drive, then open it from there. You will need Acrobat Reader to view this file. If you don't have that software already, you can get it for free from Adobe.)
In this list, the scientific name of each species follows the common name and is written in italics.

There is a species portrait page done for the Ornate Box Turtle.
Range maps and population status for the seven reptile species on the Kansas Threatened & Endangered Species list may be found in the Kansas Wildlife Refuge.
Basic information on all Kansas snakes may be found within the Snake's Burrow!


Lizards
(15 Species in Kansas)


Family Crotaphytidae - Collared Lizards Eastern Collared Lizard - Crotaphytus collaris

Family Phrynosomatidae - Prairie, Earless & Horned Lizards Lesser Earless Lizard - Holbrookia maculata
Texas Horned Lizard - Phrynosoma cornutum
Prairie Lizard - Sceloporus consobrinus

Family Scincidae - Skinks Coal Skink - Eumeces anthracinus
Five-lined Skink - Eumeces fasciatus
Broadhead Skink - Eumeces laticeps
Great Plains Skink - Eumeces obsoletus Southern Prairie Skink - Eumeces obtusirostris
Northern Prairie Skink - Eumeces septentrionalis
Ground Skink - Scincella lateralis

Family Lacertidae - Wall Lizards Western Green Lacerta - Lacerta bilineata
Italian Wall Lizard - Podarcis sicula

Family Teiidae - Whiptails Six-lined Racerunner - Aspidoscelis sexlineata

Family Anguidae - Glass Lizards Western Slender Glass Lizard - Ophisaurus attenuatus

Snakes(38 Species in Kansas)

Family Leptotyphlopidae - Slender Blind Snakes New Mexico Blind Snake - Leptotyphlops dissectis

Family Colubridae - Harmless Egg-laying Snakes Eastern Glossy Snake - Arizona elegans
Eastern Racer - Coluber constrictor
Prairie Kingsnake - Lampropeltis calligaster
Common Kingsnake - Lampropeltis getula
Milk Snake - Lampropeltis triangulum
Coachwhip - Masticophis flagellum
Rough Green Snake - Opheodrys aestivus
Great Plains Rat Snake - Pantherophis emoryi
Western Rat Snake - Pantherophis obsoletus
Gopher Snake - Pituophis catenifer
Longnose Snake - Rhinocheilus lecontei
Ground Snake - Sonora semiannulata
Flathead Snake - Tantilla gracilis
Plains Blackhead Snake - Tantilla nigriceps

Family Dipsadidae - Slender Rear-fanged Snakes Western Worm Snake - Carphophis vermis
Ringneck Snake - Diadophis punctatus Night Snake - Hypsiglena torquata

Family Natricidae - Harmless Live-bearing Snakes
Plainbelly Water Snake - Nerodia erythrogaster
Diamondback Water Snake - Nerodia rhombifer
Northern Water Snake - Nerodia sipedon Graham's Crayfish Snake - Regina grahamii
Brown Snake - Storeria dekayi
Redbelly Snake - Storeria occipitomaculata
Checkered Garter Snake - Thamnophis marcianus
Western Ribbon Snake - Thamnophis proximus
Plains Garter Snake - Thamnophis radix
Common Garter Snake - Thamnophis sirtalis
Lined Snake - Tropidoclonion lineatum
Rough Earth Snake - Virginia striatula
Smooth Earth Snake - Virginia valeriae

Family Xenodontidae - Robust Rear-fanged Snakes
Western Hognose Snake - Heterodon nasicus
Eastern Hognose Snake - Heterodon platirhinos

Family Crotalidae - Pit Vipers Copperhead - Agkistrodon contortrix
Cottonmouth - Agkistrodon piscivorus
Timber Rattlesnake - Crotalus horridus
Prairie Rattlesnake - Crotalus viridis
Massasauga - Sistrurus catenatus

Turtles
(15 Species in Kansas)


Family Chelydridae - Snapping Turtles
Common Snapping Turtle Chelydra serpentina
Alligator Snapping Turtle - Macrochelys temminckii

Family Kinosternidae - Mud & Musk Turtles Yellow Mud Turtle - Kinosternon flavescens
Common Musk Turtle - Sternotherus odoratus

Family Emydidae - Box & Basking Turtles
Northern Painted Turtle - Chrysemys picta
Common Map Turtle - Graptemys geographica
Ouachita Map Turtle - Graptemys ouachitensis
False Map Turtle - Graptemys pseudogeographica
River Cooter - Pseudemys concinna
Eastern Box Turtle - Terrapene carolina
Ornate Box Turtle - Terrapene ornata
Pond Slider - Trachemys scripta

Family Trionychidae - Softshell Turtles Smooth Softshell - Apalone mutica
Spiny Softshell - Apalone spinifera


For more information on reptiles, see these resources:


For detailed information on the distribution of reptiles in Kansas,
visit the Kansas Herpetofaunal Atlas.
If you have a strong interest in Great Plains reptiles, you may wish to join
the Kansas Herpetological Society.
An alternate taxonomy for Kansas reptiles may be found in the "Scientific and Standard English Names of Amphibians and Reptiles of North America North of Mexico" by the Society for the Study of Amphibians and Reptiles. This paper is available for download here.
Visit the Tree of Life website to see how cladistic analysis presents the classification of animals.

A Kansas Reptile Trip

This video was made by J. Kobylka Reptiles. Hope you enjoy!

Thursday, September 15, 2011

Burning Down the Forest to Restore the Collared Lizard

The introduction of firefighting after WWII to the Ozark Glades diminished collared lizard populations

By John B. Virata
September 1, 2011


Click image for infographic
The collared lizard grows to 10-16 inches in length. Its range includes Mexico and the southwestern U.S. and extends into the midwestern U.S.
A 20 year study led by a professor of biology in Arts & Sciences at Washington University in St. Louis concludes that the Eastern collared lizard (Crotaphytus collaris collaris) can restore its populations with little help from biologists after a burn technique called landscape-level burning on Ozark glades, its natural habitat. The study by Alan R. Templeton, PhD, states that the collared lizard undertakes an expanded restoration on its own after a burn that also benefits other species, including the fen orchid and fen dragonfly, with little assistance from biologists.
In 1982, Templeton and colleagues did a survey of the Ozarks and concluded that 75 percent of the lizard populations were gone, and in other areas the lizard was known to populate, it was extinct. The scientists determined that the introduction of firefighting after World War II led to an explosion of the Eastern red cedar tree, a species that was confined to the bluffs and cliffs of the Ozarks prior to the advent of forest firefighting. When man decided to fight forest fires in the area, the red cedar grew unabated, affecting the habitat of the collared lizard by effectively shading out the areas in which the lizard lived, turning what was once a sunny and sparse, hot, desert-like micro-climate to an area thick with vegetation.
In the mid 1980s, Templeton worked on restoring areas of the Ozark glades, which involved removing the red cedar trees and burning the areas. The restoration was a success and the plants that were native to the areas prior to the invasion of the giant tree canopies returned. He reintroduced the lizard over the course of several years in the mid to late 1980s, but in 1993 determined that the lizard was not faring well and the small populations would collapse due to dense underbrush that hampered the lizard’s ability to travel. To the dismay of foresters and environmentalists, a landscape level burn was recommended, and after two years of heated discussions, the burn took place.
“We did the burn and to tell the truth, I wasn’t really very optimistic about it,” Templeton told the Washington University in St. Louis newspaper. “I thought it was more really to reduce the fuel load, but I was stunned by what it did. Just one burn totally changed the environment. All of us were just shocked at how beneficial it was. “The fire mainly got rid of the woody understory and thick mats of leaf litter, but it didn’t destroy the canopy trees. In fact, with the woody understory gone, the canopy trees grew better, so the forestry people were happy. “The woody understory was mostly exotics, little shrubby trees that came from elsewhere. Once they were gone, the nutrients were released into the soil, and the soil was exposed to more sunlight, the endemics came back. All these endemic herbaceous plants came out of the forest floor and with them came a very abundant insect community. So the environmentalists were happy, too."
The burn essentially gave the lizard the opportunity to move about. Templeton introduced the lizards on three glades in the Ozarks, and on their own, they've populated 140 more glades. While glade size important, equally important is orientation, as the lizards fare better in a glade facing southwest. "Our glade sizes varied from 498 square meters to 45,373 m^2," Templeton told ReptileChannel.  "Our paper gives the details on dispersal distances, with adult females generally going to the nearest glade, with an average of moving 147 meters. In contrast, hatchlings moved an average of 647 meters when they dispersed."  The population of the lizard on the glades varied, from 1 to 58 lizards, not counting hatchlings, with 12 lizards being the average.
The collared lizard grows to 10-16 inches in length. Its range includes Mexico and the southwestern U.S. and extends into the midwestern U.S. In addition to the glades of the Ozarks, it can be found in a range of conditions, from grassy meadows and hillsides to rocky outcroppings and deserts.

http://www.reptilechannel.com/reptile-news/2011/09/01/collared-lizard-restored-by-fire.aspx

Wednesday, September 14, 2011

How to Become a Herpetologist

 I hope you enjoy the video! By the way this is not me!

Tuesday, September 13, 2011

Reptile Vocabulary

Reptilia cladogramhttp://www.enchantedlearning.com/subjects/reptiles/printouts.shtml

 Diapsid  n. Any of various reptiles having a skull with two pairs of temporal openings and including the lizards, snakes, crocodiles, dinosaurs, and pterosaurs.



Read more: http://www.answers.com/topic/diapsid#ixzz1Xrb3ZUNE

http://www.mun.ca/biology/scarr/Diapsida_phylogeny.gif

Baby Collared Lizards

Here is a video that follows up on the post yesterday. Hope you enjoy!

Monday, September 12, 2011

The Collared Lizard

Common collared lizard

From Wikipedia, the free encyclopedia
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Common collared lizard
A common collared lizard in Black Canyon of the Gunnison National Park
Scientific classification
Kingdom:Animalia
Phylum:Chordata
Class:Reptilia
Order:Squamata
Suborder:Iguania
Family:Crotaphytidae
Genus:Crotaphytus
Species:C. collaris
Binomial name
Crotaphytus collaris
(Say, 1823)
The Common collared lizard, Oklahoma collared lizard or collared lizard, Crotaphytus collaris, is a North American lizard that can reach a foot (30 cm) long in length (including the tail), with a large head and powerful jaws. They are well known for the ability to run on their hind legs, looking like small dinosaurs. The collared lizard is the state reptile of the United States state of Oklahoma, where it is known as the Mountain Boomer. The name "collared lizard" comes from the lizards' distinct coloration, which includes bands of black around the neck and shoulders that look like a collar. It is a member of the collared lizard family.
These reptiles are often tamed and kept as pets. When born in captivity, they are quite docile and tolerant of interaction with humans. They are very active and predatory lizards, requiring a large amount of space to run. They prefer high temperatures, up to 105-110°F (40-43°C) at their basking spot and 80°F (26°C) elsewhere in their habitat during the day. Some collared lizards eat small amounts of fruit or vegetables, but most prefer a diet of insects. They will also consume vertebrate prey, including small mammals and other lizards. Like many reptiles, in captivity they must be provided a diet supplemented with extra calcium and a light source with a UVB radiation to reduce the risk of bone disorders.

Collared lizard in Zion National Park, Utah

The origin of the name "mountain boomer" is not clear, but it may date back to settlers travelling west during the Gold Rush. One theory is that settlers mistook the sound of wind in canyons for the call of an animal in an area where the collared lizard was abundant. In reality, collared lizards are silent.
Like many other lizards, including the frilled lizard and basilisk, collared lizards can run on their hind legs, and are relatively fast sprinters. Record speeds have been around 16 miles/hour (26 km/h), much slower than the world record for lizards (21.5 miles/h or 34.6 km/h) attained by the larger-bodied Costa Rica spiny-tailed iguana, Ctenosaura similis.
Male Collared Lizard with blue-green body and yellow-brown head.
Male Common Collared Lizard at the Wichita Mountains Wildlife Refuge near Lawton, Oklahoma.

Collared lizards in the wild have been the subject of a number of studies of sexual selection. In captivity if two males are placed in the same cage they will fight to the death. This is not only in captivity though for it will fight if any other male is in its presence. Females will not fight though because just like many other animals in the animal kingdom the males fight to get the females' attention. Then they will try to kill the other male to win the female over. Males have a blue-green body with a light brown head. Females have a light brown head and body.

[edit] References

  • Bonine, K. E., and T. Garland, Jr. 1999. Sprint performance of phrynosomatid lizards, measured on a high-speed treadmill, correlates with hindlimb length. Journal of Zoology, London 248:255-265. PDF
  • Garland, T., Jr. 1984. Physiological correlates of locomotory performance in a lizard: an allometric approach. Am. J. Physiol. 247 (Regulatory Integrative Comp. Physiol. 16):R806-R815. PDF
  • Husak, J. F., and S. F. Fox. 2006. Field use of maximal sprint speed by collared lizards (Crotaphytus collaris): compensation and sexual selection. Evolution 60:1888-1895.
  • Husak, J. F., Fox, S. F, Lovern, M. B., and Van Den Bussche, R. A. 2006. Faster lizards sire more offspring: sexual selection on whole-animal performance. Evolution 60:2122-2130.
  • Lappin, A. K., Y. Brandt, J. F. Husak, J. M. Macedonia, and D. J. Kemp. 2005. Gaping displays reveal and amplify a mechanically based index of weapon performance. American Naturalist 168:100-113.
  • Snyder, R. C. 1962. Adaptations for bipedal locomotion of lizards. Am. Zool. 2:191-203.
  • Drake E.C. 1999 Information on the Collared Lizard.
GOT FROM: http://en.wikipedia.org/wiki/Common_Collared_Lizard

Thursday, September 8, 2011

Audubon Iphone App

If you have an Iphone I would totally recommend this app. Here is the photo that shows what the app photo looks like.    
  Got from:http://www.google.com/imgres?q=audubon+reptiles+app&um=1&hl=en&sa=N&tbm=isch&tbnid=7JtbCasBwV3czM:&imgrefurl=http://www.appolicious.com/tech/apps/214527-audubon-reptiles-and-amphibians-a-field-guide-to-north-american-reptiles-and-amphibians-green-mountain-digital&docid=mm12cdSlhH-9xM&itg=1&w=100&h=100&ei=PxppTuepLomesQKk-9H9DQ&zoom=1&biw=1366&bih=648&iact=rc&dur=264&page=1&tbnh=80&tbnw=80&start=0&ndsp=21&ved=1t:429,r:6,s:0&tx=27&ty=48&surl=1

My Leopard Gecko

My Leopard Gecko's name is Tiger and he is a giant leopard gecko. He is ten inches long and is very curious! Tiger loves to bask under the heat lamp and lay on top of his log. He eats crickets every other day and then transitions to mealworms. I use a hollowed out butter tub with vermictulite inside to help him shed. Currently he lives in a twenty gallon tank and what I use for the substrate inside the tank is paper towels. If you have suggestions on leopard gecko care please comment. Thanks!

Wednesday, September 7, 2011

Reptile Vocabulary

Reptilia cladogramhttp://www.enchantedlearning.com/subjects/reptiles/printouts.shtml

http://www.thefreedictionary.com/Reptilia
Noun 1. ReptiliaReptilia - class of cold-blooded air-breathing vertebrates with completely ossified skeleton and a body usually covered with scales or horny plates; once the dominant land animals

Tuesday, September 6, 2011

Black Mamba

Black mambas are fast, nervous, lethally venomous, and when threatened, highly aggressive. They have been blamed for numerous human deaths, and African myths exaggerate their capabilities to legendary proportions. For these reasons, the black mamba is widely considered the world’s deadliest snake.
Black mambas live in the savannas and rocky hills of southern and eastern Africa. They are Africa’s longest venomous snake, reaching up to 14 feet (4.5 meters) in length, although 8.2 feet (2.5 meters) is more the average. They are also among the fastest snakes in the world, slithering at speeds of up to 12.5 miles per hour (20 kilometers per hour).
They get their name not from their skin color, which tends to be olive to gray, but rather from the blue-black color of the inside of their mouth, which they display when threatened.
Black mambas are shy and will almost always seek to escape when confronted. However, when cornered, these snakes will raise their heads, sometimes with a third of their body off the ground, spread their cobra-like neck-flap, open their black mouths and hiss. If an attacker persists, the mamba will strike not once, but repeatedly, injecting large amounts of potent neuro- and cardiotoxin with each strike.
Before the advent of black mamba antivenin, a bite from this fearsome serpent was 100 percent fatal, usually within about 20 minutes. Unfortunately, antivenin is still not widely available in the rural parts of the mamba’s range, and mamba-related deaths remain frequent.
The black mamba has no special conservation status. However, encroachment on its territory is not only putting pressure on the species but contributes to more potentially dangerous human contact with these snakes.

 GOT FROM: http://animals.nationalgeographic.com/animals/reptiles/black-mamba/

http://imageshack.us/photo/my-images/204/7blackmambasnake.jpg/sr=1

http://www.johanmarais.co.za/DavidMaguire01/blackmamba.jpg

Thursday, September 1, 2011

Reptile Shows

The best way to meet people that love reptiles is to go to a reptile show! Find one near you!
Here is a link for a calendar showing the dates of reptile shows all over the country: http://www.reptilechannel.com/reptile-events/reptile-events.aspx