Anoxic Conditions From Everest to Europa: Swamps, Fossils, Naked Mole Rats, and the Hunt for Extraterrestrial Life

Above elevations of 6500 meters (21,300 feet), most climbers tend to start using supplemental oxygen.  At altitudes higher than this, oxygen is spread so thin that humans can have a very tough time breathing.  Even people who come from sea level to my hometown of Boulder, Colorado at an elevation of 1,655 meters (5,430 feet) often get altitude sickness, and there's still a whole lot of altitude to go before you even get to Everest Base Camp.  Most birds don't fly as high as the summit of Mt. Everest, because most birds have no reason to fly that high.  However, for the bar-headed goose, the Himalayas form an unfortunate, but not impassable, barrier between their winter feeding grounds in India and their Tibetan nesting grounds.  These geese have been reported flying over some of the highest Himalayan peaks, and they're not the only ones that fly this high.  On November 29th, 1973, a Rüppell's griffon, a type of Old World vulture, collided with an airplane at an altitude of 11280 meters (37,000 feet).  By comparison, oxygen cylinders are recommended for sailplane pilots flying over 3660 meters (12,000 feet)!

Here we have a beautiful (and extraordinarily neat) size comparison and altitude chart of a number of things covered in the post, including the altitude of Denver, the summit of Mt. Everest, the upper extent of the range of the snow leopard, and the height at which the Rüppells griffon got sucked into the jet engine.  I've also thrown in some other helpful and fun things for comparison as well.

Part of what helps birds survive at altitudes that could kill a human is a series of air sacs that allow air to flow in one direction through the body of the bird.  In humans, the air we breath in and out travels back and forth along the same tubes.  In birds, as well as some of their close dinosaurian cousins, these air sacs would have have allowed the air to flow more efficiently through their bodies.  While this is simply one of many adaptations that can help birds fly at incredibly high altitudes, other animals have evolved other adaptations to assist in high altitude living.  Scientists have determined that changes in the genes EGLN1 and EPAS1 are linked with animals living in oxygen impoverished environments, such as the snow leopard, humans native to Tibet, and naked mole rats.  Naked mole rats live in underground colonies of 20-300 individuals, and are one of two species of mammal that can be classified as "eusocial," meaning that their colonies display a caste system (similar to the social structure seen in ant and termite colonies).  These underground colonies are poorly ventilated, which means that as the mole rats inhale oxygen and exhale carbon dioxide, CO2 concentrations can increase to levels that would be unsafe for humans.  Fortunately, naked mole rats are well adapted to breathing very little oxygen, and their brains seem incapable of registering pain upon contact with acids, which is thought to help them in these CO2 rich confines.  They also demonstrate similar changes in the aforementioned genes as snow leopards and the Tibetan people, indicating another adaptation to these low oxygen (or hypoxic) conditions.

A group of naked mole rats all huddled together at the Cheyenne Mountain Zoo in Colorado Springs, Colorado.  Look at all of that eusociality!

Although hypoxic conditions can bode ill for human climbers and gregarious colonial rodents, low oxygen conditions can be great for paleontologists.  When oxygen levels drop to nearly zero, anoxic conditions prevail, and bacterial decomposition of organic material is greatly reduced.  This can be a major factor when it comes to soft-tissue preservation, such as feathers and skin.  A FEW WEEKS AGO, we talked about several famous fossil sites called Lagerstätten (a German term meaning "mother lode"), that are set apart from other fossil deposits due to the quality and/or quantity of the fossils discovered there.  One of the most famous examples is the Cambrian-aged Burgess Shale in British Columbia, Canada.  Abrupt burial of the 500 million year old organisms, coupled with the anoxic conditions that prevailed at the bottom of this body of water, ensured that these soft-bodied organisms would be preserved in exquisite detail.

A drawing of Opabinia, one of the many creatures that inhabited the Cambrian aged Burgess Shale in British Columbia, Canada.  Photo Credit: Sam Lippincott

Why do swamps often have that rotten egg smell?  Believe it or not, the answer is closely related to what we've already been talking about!  Under hypoxic or anoxic conditions, bacteria that use oxygen (O2) sometimes have to make do with sulfur (S).  If you look at a periodic table, you can see that sulfur (element #16) is directly below oxygen (element #8).  In the periodic table, each group (or column) of elements has very similar chemical properties, which means each element will react in a similar fashion.*  For the bacteria that can't get enough oxygen, they will sometimes turn to its close cousin sulfur instead.  Below is the chemical formula for cellular respiration, which is what these bacteria do, as well as some of the cells in humans.  On the left, we have the inputs: glucose (C6H12O6), and oxygen (O2).  When we breath in air, we are bringing oxygen into our lungs, and we can get glucose from the foods we eat.  On the right of the arrow, we have the outputs: water (H20), carbon dioxide (CO2), and energy.  Remember how we talked about the CO2 concentrations in naked mole rat burrows?  CO2 is one of the products of respiration, and one that can be harmful in large doses.  Energy is another product of respiration, which is the fuel that cells need to do their job.  In places where there is less oxygen input (such as at the top of Mt. Everest or in a naked mole rat burrow), the cells don't get as much energy output, and they can't do their job as well.

Now, instead of having oxygen as one of the inputs of cellular respiration, let's try sticking oxygen's close cousin, sulfur, into the equation to see what will happen.  As you can see below, the glucose on the left of the equation remains unaffected, as does the carbon dioxide output on the right of the equation.  But instead of having water (H2O) as another one of the outputs, we now see a molecule with the formula H2S.  Instead of forming water (hydrogen oxide), we have now formed a closely related molecule, hydrogen sulfide.  In swamps, large amounts of organic material leads to lots of bacteria and bacterial decomposition, which in turn can lead to lots of the oxygen being used up in the water.  That's when these bacteria start using sulfur to make their energy, producing hydrogen sulfide, with that characteristic rotten egg smell.  Even with this sulfur replacement, sometimes the bacteria just can't keep up with the amount of vegetation that is deposited in the swamp, and the organic material builds up.  If the rate at which the vegetation accumulates exceeds the rate which the bacteria can decompose the vegetation, then you have coal formation potential sometime in the future.

Let's take this one step further.  In normal respiration, where oxygen is one of the inputs and water (H2O) is one of the outputs, carbon dioxide (CO2) is another one of the outputs.  If animals and bacteria keep using up oxygen and turning it into carbon dioxide, why haven't we run out of oxygen?  Will we run out one day?  Fortunately, for the time being, plants have got our back, by undergoing a process called photosynthesis.  Photosynthesis is almost the exact opposite of respiration: carbon dioxide and water are the inputs, and glucose and oxygen are the outputs.  However, unlike respiration, light is one of the inputs of photosynthesis.  In the 1700s, a man named Joseph Priestly did experiments in which he sealed a mouse in a jar, and waited to see what happened.  The mouse, as you could probably predict, suffocated and died.  It used up its oxygen to create energy (as well as carbon dioxide), and eventually ran out of oxygen.  (This is why it's important not to put animals into completely sealed jars with no airflow, as they will suffocate.)  However, if he put a plant into the same jar as the mouse, the mouse didn't suffocate.  We now know that is because, as the mouse used up the oxygen, creating carbon dioxide, the plant would use the carbon dioxide, ultimately creating more oxygen.

As you probably know, plants need light to survive, and as we mentioned before, that's because light is one of the inputs of photosynthesis.  No light, no photosynthesis.  No photosynthesis, your plant dies.  For many years, scientists assumed that all life on Earth was directly dependent on the Sun for its energy.  That is, until 1977, when scientists discovered entire communities of biological organisms living thousands of meters beneath the surface of the ocean, too far from any sunlight to undergo photosynthesis.  So what was going on?  How were these communities able to survive without access to the sunlight?

Hydrothermal vents are essentially underwater hot springs that form along tectonic boundaries thousands of meters beneath the surface of the ocean.  These underwater vents spew different compounds containing sulfur into the surrounding water, just like aboveground geysers do, too.  (If you have ever been to Yellowstone National Park, then you might even remember the rotten egg smell.)  Some bacteria that surround these vents are actually able to use these sulfur-containing compounds to create the energy needed to undergo a process similar to photosynthesis, called chemosynthesis (consult the equation below).  Chemosynthesis is very similar to photosynthesis, with a few key differences, the biggest difference being the sulfur reactions vs. sunlight as one of the inputs.  You can also see that, instead of having water (H2O) as an input like in photosynthesis, chemosynthesis instead uses hydrogen sulfide (H2S) as an input.  Then, instead of producing oxygen, the chemosynthetic organisms produce water and sulfur.  You can compare it to the oxygen-poor respiration equation that we talked about with the swamps, and see that it is similar to that equation as well, simply flipped around.

But that's not all.  Scientists have taken this idea a step (or rather, one giant leap) further.  The search for life on other planets thus far has yielded nothing, but that doesn't mean it's not there.  It is now realized that some of the factors that were once thought to limit the development of life, such as sunlight, might not be as crucial as we once thought, and the hydrothermal vent communities have been crucial in the maturation of these ideas.  Some scientists suspect that life could exist on Mars by using chemosynthesis, but a new candidate has been receiving an increasing amount of attention: one of Jupiter's moons, Europa.  Icier than the planet Hoth, Europa is now thought to have an ocean of liquid water up to 160 km (100 miles) deep surrounding the solid, rocky mantle, following the discovery of a magnetic field surrounding the moon, similar to the magnetic field that surrounds the Earth.

What keeps the liquid ocean of Europa from freezing solid?  Jupiter is pretty far from the Sun, and even Mars, which is much closer to both the Sun and the Earth than Jupiter is, has had its water frozen for millennia.  It's thought that the gravity exerted by the enormous mass of Jupiter continually pushes and pulls, or tidal stresses, on its moons, which keep the planets from becoming tectonically inactive, like Mars.  Io, another of Jupiter's moons slightly larger than our Moon, is the most geologically active body in our Solar System.  The tidal stresses from Jupiter exerted on Io apparently make Io's ground itself buckle up and down, similar to the tides we experience here on Earth, except that instead of water moving up and down 18 meters (60 feet), its solid ground moving up and down up to 100 meters (330 feet!)  It's these same tidal stresses that make Io so geologically and volcanically active that help keep Europa from freezing solid.  It has been hypothesized that the tidal flexing might also create hydrothermal vents on the bottom of Europa's oceans, and it shouldn't take too much thinking to realize what that might mean: the potential for extraterrestrial life!

*For example, we humans, as well as all known lifeforms, are carbon-based.  In science fiction, such as Star Trek and Transformers, you will often hear about "silicon-based lifeforms."  Why silicon, as opposed to any other element?  If you look at the periodic table, silicon is in the same group as carbon, and situated right beneath it, and therefore has very similar chemical properties as carbon.



Works Cited:

Baby Prairie Dogs and Birdwatching on the Bird of Prey Route!

Today, with the summer weather and the lack of school, I decided to take my car over to what I like to call the "Bird of Prey Route," a little dirt road in between Superior and Boulder about ten minutes from my house here in Colorado.  You can usually see at least one or two different types of raptors there, and there are a number of other awesome animals that I have spotted there, as well!  Today, I saw a lot of really cool birds, as well as some baby prairie dogs, as you can see below!

This particular species of prairie dog is the black-tailed prairie dog (Cynomys ludovicianus).  Like the other species of prairie dog, the black-tail is a highly social little rodent.  Below you can see two pups "kissing" each other, a type of interaction that members of the same family group will employ.  I think this is just to help solidify familial bonds, but I'm not sure if anybody knows for certain.

Today, the bird of prey route did not disappoint!  Perched in the tree in the picture below is the red-tailed hawk (Buteo jamaicensis), definitely the raptor that I see most often when on the route.

I also saw a pair of American kestrels (Falco sparverius), the species of raptor that I see second most often.  I don't usually see the kestrels so close together, however, so perhaps this was a mated pair.  I did see one of them fly into a hollow in a tree, which might be where a nest is hidden away!

As I was watching the hollow in the tree where the American kestrel swooped off into, I noticed several European starlings (Sturnus vulgaris) flying into other hollows on the tree.  Then I realized that the angle of one of the hollows was just right, and that I could actually see the adult starling feed its young!  If you zoom in on the picture, you can see that the baby already looks pretty big, maybe even as big as the parent!

Black-billed magpies (Pica hudsonia) are especially abundant in the area, and I saw several of them as well.

This magpie looks like it is molting!

Now this particular tree presents a particularly provocative puzzle, as it is almost completely covered in some very sharp looking thorns.  A few weeks ago, I saw another tree, much larger than this one, along the banks of Boulder Creek that had some enormous thorns on its branches as well, some of them easily six inches long, and super sharp on the end!  I don't know for certain what kind of tree this, or the Boulder Creek tree, is, but a good candidate I think is the honey locust (Gleditsia triacanthos), or some other tree closely related to the honey locust.  Below is the picture of the tree that I took on the Bird of Prey Route.

Here is a picture of the thorns of the honey locust tree.

And here is the picture that I took on my iPhone at Boulder Creek of this tree.  The thorns look pretty similar to those of the honey locust, and I think that the trunk of the tree looks pretty similar, too.

Now why do these trees have such huge thorns?  That's a really good question.  I started answering (or at least trying to answer) the question here in this blog post, but everything rapidly started spiraling out of control and off focus as I started talking about giraffes, tiny squirrels, cheetahs, and extinct North American elephants.  For those of you who know me, it should come as no surprise that I spiraled so quickly off topic.  But regardless, what I had written ended up having enough material for at least three or more posts, so I have moved the answer to a different post, which I will hopefully be publishing soon.  Keep an eye out for that!  In the meantime, back to the future birds!  Here, we see a pair of barn swallows (Hirundo rustica) perched on a wire.

I'm not quite as sure about the identity of this particular bird.  Also a swallow, I am thinking that it might be a violet-green swallow (Tachycineta thalassina).

I believe this to be a vesper sparrow (Pooecetes gramineus).

A western kingbird (Tyrannus verticalis), another bird that I see all the time here, at least in the summer!

At last, we have one of the most exciting birds that I saw on the route today, the blue grosbeak (Passerina caerulea), a bird that I don't remember ever seeing before!

Remember to check back soon to learn all about those massively spiky trees!

Works Cited:

Robbins, C. S., Bruun, B., & Zim, H. S. (1983). Birds of North America. New York: Golden Press.

Stokes, D. W., & Stokes, L. Q. (2010). The Stokes field guide to the birds of North America. New York: Little, Brown.

Animal of the Day: Viscacha

Today's Animal of the Day is the viscacha and, in my opinion, the viscacha is one of the cutest animals in the world!  There are five species of extant (still living, opposite of extinct) viscacha, composing two genera.  The viscachas live in the South American Andes, with one species, the plains viscacha, inhabiting the Pampas of Argentina.  The plains viscacha can apparently live in warrens (groups of interconnected burrows) of up to around one hundred individuals!  

Now what exactly is the viscacha, anyways?  Except for the long tail, it sure looks like a rabbit, now, doesn't it?  Well, the rabbit-like features of the viscacha actually evolved through a fascinating biological process called convergent evolution, in which organisms evolve a similar adaptation to other organisms, but did not receive the adaptation from a common ancestor.  For example, the antlers of the elk and the moose are not an example of convergent evolution, as the common ancestor of the two animals both had antlers.  

However, the saber-teeth in the Chinese water deer and the musk deer DID evolve via convergent evolution, as their common ancestor did not have these features.  And yes, that picture of the Chinese water deer to the right is a real picture.  We'll talk about these fascinating animals at some point in the future.  

Tangents aside, I never actually answered the question: what are the viscachas related to, if not rabbits?  Rabbits, along with hares and pikas, are members of the order Lagomorpha, or the lagomorphs, contrary to the belief of many people, who (understandably) think that the rabbits are actually rodents.  If you were to say that the viscacha was a rodent, however, then you would be correct!  The viscacha is indeed a member of the order Rodentia, and are fairly closely related to the chinchillas, one of which is pictured off to the left.  The chinchillas, just like the viscachas, are also native to the South American Andes.  The chinchillas, despite being a very popular pet (I remember my preschool had one when I went there), are not doing too hot in the wild: both extant species, the short- and long-tailed chinchilla, are labeled as "Critically Endangered" by the IUCN.  

This was the birthday post of Isabel Lippincott! Happy birthday, Isabel! If you have a birthday coming up, just email me the date at cuyvaldar123946@gmail.com with the date and your favorite animals, and I will do my best to get a post in! And if you like what you are reading, please feel free to follow us here or via Facebook!

Top Ten Most Interesting Arboreal Mammals (Part 1)

Today, in honor of the birthday of Charlie Bowers, we are going to be taking a "Top Ten" approach to some pretty cool arboreal mammals.  FYI, for those of you who don't know, arboreal means an animal that lives in the trees!  So let's dive right in!  For Part 2 of this duology, click HERE.

10.  Squirrel - Although a fairly common animal and really not that exciting at first glance, the squirrel is actually quite the exciting animal!  Incredibly acrobatic, the squirrel is superbly adapted for an arboreal lifestyle.  Need more proof?  Click the link right HERE to be amazed!

One of the koalas at the San Diego Zoo in California.  Photo Credit: Julie Neher

9.  Koala -  Other than the kangaroo, the koala is probably the most iconic Australian marsupial.  Many myths abound in regards to the koala.  For example, many people believe that the koala is constantly "adjusting its altitude," so to speak, due to something in the leaves of the eucalyptus trees that they consume.  While it seems quite likely that the koala is constantly baked due to its lackadaisical attitude, it's not actually true: the koala just spends a great deal of its day asleep in order to digest the tough vegetation that composes its diet.  As a matter of fact, the 20-22 hours a day the koala sleeps makes it the sleepiest  mammal!  (For more information about the koala and its digestion, click HERE). 

8.  Primates - Perhaps the order of mammals that is most superbly adapted to a life in the trees, the primates include everything from the aye-aye to the orangutan, from the tarsier to us humans!  Thought to have started evolving in North America or Asia around 65 MYA or so, before even the dinosaurs died out, today there are over 200 extant species, with new ones still being discovered, like the lesula monkey that was discovered in the Democratic Republic of the Congo in 2012 (pictured above).

7.  Binturong - Often called the "Bear-cat," the binturong is the largest of the strange group of animals known as the civets.  (For more about civets and their relatives, click HERE).  Native to southeastern Asia, the binturong is omnivorous, but seems to consume fruit the most in its diet, and is particularly partial to figs.  Although the binturong is labeled as "Critically Endangered" in China, the IUCN labels the species as a whole as merely "Vulnerable."

6.  Sloth - When you hear the word "sloth," you might think of someone or something being lazy.  There is a very good reason for that association: the sloth is quite sloth!  As David Attenborough says in the excellent BBC production "Life of Mammals," "The sloth moves as if it's powered by the wrong sort of batteries."  Sleeping around 20 hours a day, the sloth is the second sleepiest mammal, right after the koala.  While it sleeps, the sloth hangs upside down from tree branches.  Sounds like a lot of work, right?  Actually, it really isn't: the sloth simply hooks its claws over the tree branch, and relaxes all of its muscles.  If a human hunter shoots a sloth hanging from a tree, it will usually simply remain hanging from the tree branch, anchored by its claws!  Then the hunter actually has to physically climb up into the tree to retrieve its prize!

Top Ten Mammals That Look Like Something They Aren't (Part 1)

Today, we are going to be taking a "Top Ten" look at some mammals that look a lot like something they aren't.  Sometimes, these two animals are fairly closely related: other times, they are quite far apart!  All of these examples will be results of a fascinating phenomenon known as "Convergent Evolution," which is where similar ecological and environmental factors cause two very different animals to evolve in a similar fashion.  So let's dive right in!  But first, this is the birthday post of Joseph Kleinkopf, happy birthday Joseph! (For Part 2, animals 5-1 of the countdown, click HERE.)

10.  Bear Dogs - As their name implies, the bear-dogs are a group of mammalian carnivores that greatly resemble both bears and dogs.  However, they are neither!  According to The Big Cats and their Fossil Relatives by Alan Turner, they are thought to be fairly closely related to dogs, and more distantly related to bears.  Their remains are most commonly found in North America, although they are also found in Europe, Asia, and Africa.  Temporally, these animals lived during the Miocene Epoch, and are though to have arisen about 15 MYA, and fallen into extinction around 12 million years ago (MYA).

9.  Entelodonts - The Entelodonts, frequently referred to as "Hell" or "Terminator Pigs" greatly resemble the extant (still around, opposite of extinct) pigs and peccaries.  However, they are in a separate family from both the pigs and the peccaries, the family Entelodontidae, but all three do reside in the order Artiodactyla.  Some paleontologists believe that these guys are more closely related to whales and their relatives than pigs, but their exact phylogenetic relationship is unclear.  They inhabited North America and Europe during the Oligocene Epoch, around 34-32 MYA. 

8.  Hyrax - This little guy looks like he would be a rodent, but his true relatives are actually much more surprising!  Weighing between about 5 and 10 pounds, the hyraxes are actually fairly closely related to the members of the family Proboscidea, or the elephants and their relatives!  The extant hyraxes have their own family, Hyracoidea, but their ancient ancestors are thought to have branched into the extant hyraxes, the elephants and kin, and most likely the manatee and its relatives!  Hyraxes are found exclusively in Africa and the Middle East.

7.  Red Panda - The red panda has a long history of uncertainty in regards to its phylogenetic relationship to other animals, as has its namesake, the giant panda.  However, now we know that the giant panda is in the family Ursidae, or the bear family, and the red panda is now classified in its own family, Ailuridae, closely related to the mustelids, raccoons, and more, distantly bears.  For more information about the red panda, click HERE.  For more information about the giant panda, click HERE.

6.  Rabbits and Pikas - Even up until just a few years ago, I had assumed that the rabbits and the pikas were both rodents.  They look a lot like them, and they share the trait of continually growing teeth.  However, the members of the order Lagomorpha, which is the order that includes the rabbits and the pikas, differs from the order Rodentia in that they possess four incisors, as opposed to two for the rodents.  Furthermore, most rodents are omnivorous, while the lagomorphs are almost entirely strictly herbivorous.

For Part 2, animals 5-1 of the countdown, click HERE.

And remember, if you have a birthday coming up, just email me the date at cuyvaldar123946@gmail.com with the date and your favorite animal, and I will do my best to get a post in! 

More Squirrel Prints, Plus Some Bird Ones, Too!

As I MENTIONED YESTERDAY, we got our first real snow yesterday, and there were some squirrel footprints in our driveway.  After I made the post, when I got home, my father pointed out some bird footprints on the back porch, and this morning I saw some more, better squirrel prints on our back stoop.  I decided to share these cool prints with you as well, since squirrels and birds are quite rare in North America!  (Sarcasm).  The first two picture are of the bird tracks, and then all of the rest are from the eastern fox squirrel.

Bird tracks

I forgot the flash for this one, but I thought that the bird footprints still looked pretty cool with the green light coming from our back-porch light!

Squirrel Footprints on Our Doorstep!

This morning we woke up to a fresh blanket of snow, the first (real) snow of the year for us!  Naturally this means that I must do all of my first snow traditions, including watching the Battle of Hoth scene from Star Wars Episode V: The Empire Strikes Back, and wearing my Mammoth and Mastodon Madness t-shirt from the Denver Museum of Nature and Science.  Anyways, on my way over to school, I saw a few footprints.  I took a few pictures on my phone so they aren't very good looking, but I believe them to be from the eastern fox squirrel, the type of squirrel that is just so common around here in Boulder, Colorado!  If anyone knows otherwise please let me know, but I am 99.99% sure that this is what we are looking at!  The first two pictures are the ones that I took with my phone.  The first picture has an impression of my right index finger in the snow next to the footprints for scale.  The third picture is a picture that someone else took of some eastern fox squirrel footprints in the snow too!

23-Fact Tuesdays: Polar Bear Celebrations, Eccentric Artists, and Unicorn Horns!

Welcome to our third "23-Fact Tuesday" which are never on Tuesdays.  I believe that this one is actually closer to a Tuesday than we ever have been before, however, so that's got to count for something!  I'd also like to thank Mona Kamath for her help on this post!  Enjoy!

1.  Despite the fact that polar bears are generally solitary, they gather annually in places like the city of Churchill in Manitoba, Canada, where they congregate together prior to the freezing of the sea ice.  When they gather in groups like this, the group is called a "Celebration." 

2.  The eccentric and incredibly odd (though undeniably gifted) artist Salvador Dalí had a pet ocelot named Babou.  He also had a pretty righteous mustache, if I do say so myself.

3.  In 1663, the German scientist Otto von Guericke "reconstructed" the mythical unicorn using the fossilized bones of a mammoth, a woolly rhinoceros, and the horn of a narwhal.  This reconstruction managed to legitimately fool some people, including Gottfriend Wilhelm Leibniz, the famous German philosopher and mathematician, who reportedly was dubious about the existence of the unicorn prior to this "reconstruction," but was convinced by Guericke's "fossil."  

4.  From wing tip to wing tip, Hatzegopteryx measured an astonishing 46 feet!

5.  Gasosaurus, a dinosaur that was described in the year 1985, was named "Gas-Lizard" because it was discovered by a Chinese gas-mining company.

6.  In order to hover and move in any direction, the hummingbird, often nick-named "nature's helicopter" moves its wings in a figure-eight pattern, as opposed to the up-and-down motion typical of other birds.

7.  Cotylorhynchus, one of the largest pelycosaurs, is quite possibly the funniest-looking extinct animal I have ever, ever seen.  It was also discovered by my 9th grade Language Arts teacher's great great uncle, J. Willis Stovall, a famous paleontologist. 

8.  One of the elephants at the Cheyenne Mountain Zoo is named Kimba, which means "Poop" (I used the nicer term for what the word actually means there) or "Corpse" in Swahili.

9.  Speaking of poop, fossil poop is known as a "coprolite."

10.  The acrobatic margay can rotate its ankles 180 degrees, which allows it to descend tree trunks head-first and hold on to branches with either their front or back paws.

11.  The white-tailed deer is named for the white patch on its rump and tail, while the mule deer is named for the fact that its face resembles that of a mules.

12.  About a third of the extant mammalian species are rodents.

13.  Hopping, the method of locomotion preferred by the kangaroos, is actually much more efficient than walking.  Of course, this is only the case if you have evolved in that fashion.  It wouldn't just be more energy efficient if we started hopping around everywhere.  

14.  Although you often hear people mention the "saber-toothed tigers," this is actually a bit of a misnomer, due to the fact that the saber-toothed cats to which they are referring to are not actually tigers, and are simply just cats.  

15.  The sweat of the Hippopotamus, is red or pink, leading people to aptly refer to it as "blood-sweat."

16.  Despite the fact that the polar bear has white fur, the color of its skin is the complete opposite: jet-black.  Talk about Yin/Yang right there.

17.  Island dwarfism is suspected to have occurred in one of our human relatives, Homo floresiensis, who inhabited the island of Flores in Indonesia up until around 12,000 years ago.  The nick-name for this ancient human is "The Hobbit." 

18.  The word "Mona" means "monkey" in Spanish.  Sure would suck if that was your name now wouldn't it!

19.  In Hindu culture, owls are a sign of bad luck.  That double sucks if you are Hindi and terrified of birds.

20.  Speaking of owls, due to the fact that they have binocular, or stereoscopic, vision (unlike other birds of prey, who have an eye on each side of its head), they have evolved the ability to turn their heads around 270 degrees in either direction.  Must be tough for them to crack their necks.

21.  Despite the fact that the creature in the picture below looks like a raccoon, it is not: that, my friends, is the raccoon dog!

22.  The tusks of the elephants are actually greatly elongated incisor teeth.  For reference, tap your front two teeth on the top or bottom of your mouth, it doesn't matter which, they are the same.  Those are your incisor teeth, you have two on each side of your mouth, eight all together.  

23.  In the narwhal, however, the tusk is their canine teeth, which (at least in our mouths) are the teeth right next to our incisors, towards the outside of our mouths. 

The Animals of Estes and Rocky Mountain National Park

As I mentioned earlier today, my family and I stayed at Estes Park a few nights ago.  During the day, we hit up the nearby Rocky Mountain National Park.  We saw a few different animals, a few of which I unfortunately was unable to get pictures of!  Here I will tell you all about the animals that we saw there!

First off, we went over to Lake Estes.  Despite the cold and the wind, probably a hundred or so geese, ducks, crows, and ravens were all scavenging around in the shallow water and the muddy areas.  We also saw a bald eagle, but unfortunately it was too far away for us to get any pictures.  Right before that, though, we spotted a muskrat (a little, water-loving rodent) swimming through the water!  It was really super cool, as it was an incredibly powerful swimmer!  We were walking along next to it, taking a ton of pictures and videos, but the muskrat was easily keeping pace with us!  It was swimming against the current, as well as against the wind, but somehow this rat-sized creature was able to forge ahead!

The muskrat swimming!

This is how far the muskrat swam!  It was certainly more than 100 yards, all keeping up with us!  CRAZINESS!

When I ran out in front of the muskrat to get pictures of it up close, it ducked into its burrow.  We were able to pinpoint the entrance because right out in front was a whole pile of what looked like chewed off crayfish pincers! 

The pile of chewed crayfish parts outside of the muskrat burrow

Some chewed parts on top of a rock

Here is a video of the muskrat swimming:

Muskrat Swimming Against The Current

We also saw a lot of elk, as we have talked about before.  Here are some more pictures that my mother took in the morning, around the same time that my Primos Truth Cam was picking them up, too!

The elk drinking on our first morning there!

An elk drinking on the first morning

 

When we first saw the elk right next to our cabin, a male mule deer walked right next to my mother and I, no more than ten feet from us while we were next to the river!  It was really cool, but a little sad to see how comfortable these animals are around humans.  Made for a good photo op, though!

The mule deer

That's our cabin, right there!

A male elk on the first night there, around the time that we saw the mule deer from above.  It was eating from a bird feeder!

While we were on our walk around Lake Estes, we passed by a male elk with a harem of four females on the golf course.  Here are some of those pictures!

The harem of female elk off to the left, while the male is grazing on the right

The male elk

The female elk

Another shot with the female elk off to the left and the male elk off to the right

And finally, a herd of elk in Rocky Mountain National Park!

Finally, although no one but my father saw it and we got no pictures of it, while we were driving in Rocky Mountain National Park at around 4:00 or so in the afternoon/evening, we almost ran over an ermine (also known as a stoat or a short-tailed weasel)!  Apparently it was adorned in its winter fur which, much like the arctic fox, changes with the seasons to blend in with its environment!  The ermine, along with otters, badgers, other weasels, and the wolverine, is a member of the family Mustelidae, colloquially referred to as the "mustelids."  The mustelids, in turn, are members of the superfamily Musteloidea, which we have discussed in the past.  It is within this superfamily that you will find coatis, raccoons, skunks, and red pandas. 

Estes Park on Dwellable