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Internal anatomy of the snake
“Arms and legs gone, no ears, only one functional lung, voiceless, eyelids missing…a human being under these conditions would be institutionalized and under constant care…” James A. Peters, Encyclopedia Britannica 15th edition
The internal anatomy of snakes shows their obvious relation to other vertebrates; their organs, tissues, and germ cell layers are all very similar to those of other scaled reptiles (order Squamata), and even to other vertebral species (subphylum Vertebrata).
However, their differences from other vertebrates are even more distinct than their similarities. The body of a snake is long and elongated, like a tube, and certain adaptations have been made along the evolutionary chain in order to fit their organs into this form.
Other adaptations have also been developed in the evolutionary history of the suborder Serpentes, with the result of this highly specialized carnivore. Here are a few of those adaptations:
Lungs: All snakes are essentially one-lunged. Their left lung is usually vestigial, sometimes completely absent, and their right lung is enlarged and elongated, and has much less cartilage in it than other vertebrates. In aquatic snakes, the left lung’s anterior portion still functions, albeit not for gas exchange. It works as buoyancy organ during swimming.
Jaws: The lower jaw of snakes is loosely attached, with ligaments connecting the anterior left and right halves of the mandible. The left and right halves are generally also connected with a relatively loose ligament, allowing separation and movement of both halves. When the snake ingests a large meal, the jaw easily pops out of its hinge, to allow food to enter the esophagus. After swallowing its prey, the snake will “yawn” widely, and snap its mandible back into place.
Spine: Snakes generally have between 200 and 400 vertebrae. The “tail” vertebrae usually make up less than 20% of the total, and are the only vertebrae without ribs attached. The ribs and vertebral column of the snake provide solid anchoring points for the strong muscles required for limbless locomotion, and are necessary much farther down the torso than in other vertebrates.
Skin: It’s not slimy, for one! Despite some snakes looking like they have a sheen to their scales, no snakes secrete “slime” or mucous to coat their skin. Only amphibians and worm-type creatures do that. Snake skin is incredibly flexible, to accommodate the large meals that are consumed, and is comprised of scales, which are a protective extension of the epidermis. Scales also allow snakes to grip the ground or trees they’re climbing. Snake eyes are covered in clear scales, allowing them to be protected without eyelids.
Ears: Obviously, snakes have no external ears. However, they still have inner ears. When soundwaves hit their skin, the vibration is transferred through the muscle and bone, and into the inner ear, where it’s processed. Though the ability to sense directional vibration in snakes is generally highly developed, the sense of “hearing” as humans know it is relatively poor.
Sight: This is one trait that varies widely between snake species. Some are nearly blind, sensing only light and dark, while some can spot prey from far away. No snakes can see in color, but some snakes (the pythons, pit vipers, and some boas) can see infrared images - that is, they can sense the heat radiating from warm-blooded animals, allowing them to hunt prey at night.
Tongues: Snakes do not have a sense of taste, in the way that humans think of “taste”. Instead, their tongues “test” the air for certain compounds, bringing the air particles back into their mouth, into their vomeronasal (Jacobson’s) organ, which can tell if there are predators or prey in the area. Some snakes that live in aquatic environments, such as sea kraits and boas, can also use this sense underwater.
All images: Brehms Tierleben, Allgemeine Kunde des Tierreichs. Dr. Otto zur Strassen, 1913.
Snake info from: Snakes: In Question. Carl H. Ernst, George R. Zug, 1996.
#Staphylinidae #Coleoptera #Biology #student
Water bears, known to scientists as tardigrades, are famously adorable microscopic creatures who can survive anything: freezing, total dehydration, radiation bombardment, and even the vacuum of deep space. Now scientists have sequenced a tardigrade genome, and are very surprised by the results.
Water bears, known to scientists as tardigrades, are famously adorable microscopic creatures who can survive anything: freezing, total dehydration, radiation bombardment, and even the vacuum of deep space. Now scientists have sequenced a tardigrade genome, and are very surprised by the results.
Yesterday a group of researchers led by University of North Carolina at Chapel Hill biologist Thomas Boothby published their analysis of the tardigrade genome in the Proceedings of the National Academy of Sciences. What they found was that 17.5% of the tardigrade genome actually comes from other organisms, including plants, fungi, bacteria, and viruses. These genes entered tardigrade DNA in a process known as horizontal gene transfer, which is quite common among single-celled organisms but rare among animals. The closest comparison with the tardigrade is a microscopic form of plankton called a rotifer, which has about 9% of its DNA from other organisms.
The researchers reached the 17.5% number by isolating non-animal genes in the tardigrade sequence, and then comparing those non-animal genes with those of other sequenced organisms. About 17.5% of tardigrade genes closely resembled genes from non-animal organisms like plants and bacteria. This is the first time scientists have ever found an animal with 1/6 of its genome coming from non-animal sources.
Biologist Bob Goldstein, who worked with Boothby on the paper, told Gizmodo via email that they can’t be sure of the exact species that donated DNA to the tardigrade, partly because some of the species’ genomes may not have been sequenced yet.
The real question is, how did the tardigrade become such a genetic hodgepodge? Boothby and his colleagues speculate that it has to do with the animal’s response to stress. Tardigrades live in wet moss, and one of the common forms of peril they must endure is desiccation, or drying out. When tardigrades are desiccated, their DNA breaks into pieces. Any organisms around them will also suffer the same fate. But when water returns to the tardigrade’s environment, they re-hydrate and return to life. As they re-hydrate, their cell walls become porous and leaky, and fragments of DNA from the desiccated organisms around them can flow inside and merge with the animal’s rejuvenating DNA.
Tardigrades: Nature’s Doomsday?
Read the full scientific paper at PNAS.
’The Tardigrada of the Scottish lochs’ by James Murrary. Published 1905
3 Waterbears by *Banvivirie
Tardigrades are represented by more than 1000 different species, and here are just three. They are distinguished mainly by the shape of their pharynx and the shapes of their claws.
The central waterbear is the “standard”, most widely recognized tardigrade, and not many people are aware of the different forms that this creature can take.
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COMPARATIVE MAMMALIAN ANATOMY - 1860
Benjamin Waterhouse Hawkins A comparative view of the human and animal frame Chapman and Hall, 1860 ________________________________
Ten plates with brief explanatory text intended ’to give a comparative view of the variation in form of the bony skeleton or framework of those animals most frequently required by the artist, designer, or ornamentist.“
It appears that Waterhouse Hawkins, who is best known for his work with dinosaurs (here and here), wanted to make the illustrations as realistic as possible. All are depicted next to Homo sapiens, who is posed in ways the illustrator apparently felt were natural: a man leads a horse, gives a treat to his camel, shows off his elephant, and [perhaps] supplicates a king attended by the king of beasts.
The textual explanations of variation in animal form did not yet reflect the influence of Charles Darwin’s evolutionary theory, but the detailed illustrations added much to the understanding of mammalian anatomy.
(Images and text [revised here] via University of Wisconsin Digital Collections) ________________________________
Benjamin Waterhouse Hawkins in Wikipedia Wikipedia on history of dinosaur study
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