Today's Fossil Friday specimen comes from a location we've never before featured on this blog, Joshua Tree National Park.Joshua Tree is most famous for its eponymous trees and its spectacular granite formations, but there are also significant Pleistocene fossil deposits within the park. Over  a period of several years Kathleen Springer and Eric Scott (then at the San Bernardino County Museum) collected some of these remains under a NPS permit. Earlier this week Joshua Tree designated Western Science Center as the repository for that collection and transferred the specimens here.The Joshua Tree fauna is an contrast with other Southern California sites such as Diamond Valley Lake in that, like today, during the Pleistocene it was more mountainous and more arid than the inland valleys. While the fossils from Joshua Tree are almost all fragmentary and poorly preserved, studying the fauna from this site will help give us a more complete understanding of how California ecosystems worked during the Pleistocene.The particular fossil shown here is a Columbian mammoth lower left third molar, one of several mammoth remains in the collection. Mammoths seem to be one taxon that had a great deal of ecological flexibility, as they are found in almost every imaginable Pleistocene deposit.Thanks to Melanie Spoo of Joshua Tree National Park and Vincent Santucci of the National Park Service for arranging the move of the Joshua Tree fossils to WSC. 

Tomorrow is the Western Science Center's annual fundraiser, Science Under the Stars. That has our entire staff, including me, wrapped up in preparations for 500 guests and a massive benefit auction, so Fossil Friday will necessarily be brief.Above on the left is a partial molar from a Columbian mammoth, Mammuthus columbi, from Pleistocene deposits near Murrieta in Riverside County. As massive as the tooth is, it's incomplete, with the anterior part of the tooth having already worn away. Mammoth teeth (in fact, all the elephants) have enamel arranged in transverse plates that wear to enamel loops on the occlusal surface.The tooth on the right is a cast of a wooly mammoth (M. primigenius) from Alaska. While it's a little difficult to see on the black tooth, the enamel plates on the wooly mammoth are thinner and more numerous than on the Columbian mammoth. This general rule is often used to distinguish between the two species, but as so often seems to be the case, proboscideans are not good at following rules! There is considerable overlap in this character ("lamellar frequency") between Columbian and wooly mammoths. Moreover, it appears that the two species were regularly interbreeding where their ranges overlapped (the apparent hybrids were originally given a different species name, M. jeffersonii). And recent genetic evidence calls into question whether Columbian and wooly mammoths were in fact just different morphs of a single, highly variable species.

I missed last Fossil Friday while I was attending the Society of Vertebrate Paleontology in Calgary, which included posters on Diamond Valley Lake mastodon tusks and the Valley of the Mastodons Symposium and Exhibit. But I'm now back in Hemet, and ready for some more Fossil Friday posts!A few months ago I posted about a Columbian mammoth lower jaw from Merced County,  collected by PaleoResources during a Caltrans road project. There was actually quite a bit of material recovered during this project, and we're currently in the process of integrating it into the WSC collections. One of the other large pieces is the tusk shown above.This is a typical left tusk from a mammoth, with strong curvature in multiple planes resulting in an open spiral shape. Mastodon tusks, in contrast, tend to be thicker for a given length (at least in males), and curve more strongly in one plane than the other, so the tusk is more of an arc than a spiral. While it's difficult to see from this angle, the tusk shown here has a fairly prominent wear facet at the tip.When PaleoResources dropped off this collection, they indicated that they suspected the mammoth material represented more than one individual, even though there were no duplicate pieces (so that, technically, the minimum number of individuals = 1). I agree with PaleoResources' assessment; I don't see any way such a large tusk could have come from a mammoth as young as the one represented by the lower jaw in the same deposit.This tusk, along with the juvenile lower jaw and an associated mammoth pelvis, are currently on display at the Western Science Center.

Most of the current collections growth at the Western Science Center comes in the form of mitigation projects, fossils and artifacts that are recovered during various construction projects. Most of the projects that have come to us are from Riverside County, but we're increasingly starting to bring in material from other areas.Earlier this week we received several Colombian mammoth bones from a Caltrans road project in Merced County, California. The fossils were recovered and beautifully prepared by PaleoResource Consultants. While it appears that all the bones are mammoth, they do not appear to all come from one individual.One of the best-preserved elements is a lower jaw, shown above in dorsal view. The tooth in place is quite small, and is apparently either the fourth premolar or the first molar (I'm leaning toward the 4th premolar, but I need to examine it further to be sure). That makes this a very young animal; if the tooth is the 4th premolar it was probably only about 3 years old, and if it's the 1st molar it would still only be about 13 years old. There are going to be lots of things to work on in this small but significant collection.Thanks to Caltrans and PaleoResources Consultants for bring us this exciting specimen, and to Pat Holroyd at the UC Berkeley Museum of Paleontology, who put us in touch with PaleoResources.

With the influence of Max Mastodon, Diamond Valley Lake mammoths sometimes get short shrift around here. But while DVL mammoths are not nearly as common as mastodons, there is still plenty of interesting mammoth material.The tooth shown above is an upper molar, probably the second molar, with the anterior end of the tooth to the right. This is the occlusal view showing the transverse enamel ridges that are typical of mammoths and other members of the family Elephantidae, including the modern elephants. (Mastodons are proboscideans, but not elephantids, which is reflected in their different tooth structure.) Below is a medial view, with anterior to the left:Because mammoths (like other advanced proboscideans) had horizontal tooth replacement, the anterior end of the tooth erupts first, with the upper teeth moving forward and down over time. That means the front of the tooth has seen more use than the back of the tooth, which is clear in medial view. The front of the tooth is very short because it has been almost completely worn away, while the back of the tooth is still tall, with very little wear.This specimen, which was associated with another tooth and several other cranial fragments, was recovered from near the East Dam of Diamond Valley Lake. Most of the dated sediments from that end of the lake are among the older DVL deposits, from about 35,000 to 45,000 years old.

Mastodons were the most common proboscideans in Diamond Valley, but they weren't the only ones there. Columbian mammoths (Mammuthus columbi) were also present, although in much smaller numbers. The most complete Columbian mammoth from DVL is Xena, whose partial skeleton is on permanent exhibit at the Western Science Center.Xena's remains include the left femur (thigh bone), shown above in anterior view with the proximal end on the left. As is typical of Columbian mammoths, the femur is relatively long and slender when compared to mastodons. While adult mammoths and mastodons were probably pretty comparable in terms of weight, mammoths were quite a bit taller because of their long legs, which were proportioned more like those of modern elephants than the relatively short, thick legs of mastodons. Xena was not particularly tall for a Columbian mammoth, but was at least as tall as Max, the biggest mastodon known from California.While Xena's femur is well preserved, it is missing both the proximal and distal ends.These were lost because they had not yet fused to the rest of the femur, indicating that Xena was still growing (even at 3 m tall!). This is also borne out by her teeth; Xena's 1st molars were in wear, but the 2nd molars were completely unerupted, suggesting that she was probably only about 18-20 years old.

After a few weeks of focusing on mastodon remains, it's worth remembering that there were two different species of proboscideans at Diamond Valley Lake. While mastodon remains are quite common, Columbian mammoths (Mammuthus columbi) were also present.This specimen is a lower left 1st or 2nd molar of M. columbi, discovered during the early years of the DVL excavations. Like the closely related Asian elephant, mammoths had enamel that is folded multiple times, wearing to produce a series of raised transverse enamel ridges in occlusal view. Like other advanced proboscideans mammoths replaced their teeth sequentially, so the front of the tooth (on the right in the image above) is more heavily worn that the back of the tooth. In fact, the last enamel ridge is essentially unworn, so this tooth had probably not quite completely erupted.A cast of this tooth is on permanent exhibit at the Western Science Center, as a touchable display allowing visitors to compare the very different occlusal surfaces of mammoth and mastodon teeth. As it happens, we're also auctioning off an additional cast of this tooth (below) tomorrow night at our annual Science Under the Stars fundraiser.

"Xena" is the most complete Columbian mammoth specimen recovered from Diamond Valley Lake, including a nearly perfect skull and lots of postcranial material. Both of Xena's tusks were also recovered, and are on display with the rest of her skeleton at the Western Science Center.Elephants and their relatives (proboscideans) use their tusks in all kinds of ways, including fighting, stripping vegetation, and digging water holes. While the tusks are modified incisor teeth, they do not have enamel (some extinct lineages did, but that's another story), so tusks are typically heavily worn at the tips. The polished wear facets are easily visible in the image above.Another curious feature of proboscideans is that, in most individuals, one of the tusks tends to be more heavily worn that the other. In our mounted cast of Xena, you can see that her left tusk is more heavily worn that the right one, as it's blunter and somewhat shorter:Since proboscidean tusks are worn during behavioral activities, it's possible that the differential tusk wear is evidence for lateralization, or handedness. Most animals show a preference for using one side of their body over the other. This can be expressed in a variety of ways, including a preference for using a particular hand for detailed tasks in humans, or for using one side of the mouth in feeding in whales. For some unknown reason, in almost all species that show lateralization, right-handedness is more common. Modern elephants are also lateralized; an elephant will always tend to curl its trunk in the same direction when pulling up grass, for example. Differential tusk wear suggests that they also show handedness in behaviors that involve the tusks. In Xena's case, the more heavily worn left tusk suggests that she was left-handed.We recently produced a cast of Xena's left tusk, which will be auctioned off at the Western Science Center's annual Science Under the Stars fundraiser on September 12. If your in Southern California consider coming the the event to support the museum!

It's Fossil Friday, and in what I intend to be a regular feature we'll look at different specimens in the Western Science Center collection. To kick off, we'll examine a mammoth jaw to show that not not everything in the Valley of the Mastodons is a mastodon!The image above is an oblique view, with the front of the jaw to the left. Mammoths (and their close relatives, the elephants) have massive but remarkably short lower jaws. The example above is missing the condyles that articulate with the cranium, but is otherwise complete and has almost its entire length preserved. This particular specimen is from a Columbian mammoth (Mammuthus columbi), and was collected from Late Pleistocene deposits during the Diamond Valley Lake Project.Here's the same jaw from directly above (dorsal view), with the front of the jaw at the top: The two roughly oval patches with the ridges and grooves cutting across them are the teeth. Here's an oblique close-up of the right one:One thing that you may find a bit curious is that in this huge jaw there are only two teeth, one on each side (although, to be fair, each tooth is enormous). That is a function of the unique method of tooth replacement found in elephants and their relatives. Unlike most mammals, elephants grow in their teeth one at a time, and as each tooth wears down it gradually moves forward in the jaw and falls out. As this happens, the next tooth in line moves forward and becomes functional, so the teeth act as if they're on a conveyer belt. Because the new tooth starts to become functional before the older one falls out, at most points in its life an elephant will have approximately one and a half functional teeth in each half of its jaw at any one time.There are two points in an elephant's life cycle that are exceptions to this general rule. A very young elephant that has only just had its first tooth erupt has, of course, only one functional tooth instead of one and a half. Moreover, an elephant only ever grows a total of six teeth in each half of its jaw, three premolars and three molars (excluding the tusks in the upper jaw, which are also teeth). That means that an elderly elephant that has already lost its first five teeth will only have a single, very large tooth remaining in each half-jaw.That's exactly what we see in the mammoth jaw shown here. The enormous teeth on each side of the jaw are the lower 3rd molars, which had almost completely erupted but still had a lot of wear to go. The three premolars and the first two molars have already worn down and fallen out, making this a fully mature mammoth. We can even compare this to modern elephants to get an estimate of how old this mammoth was when it died. Assuming that mammoths and elephants grew and replaced their teeth at the same rate (and there's pretty good evidence that they did), and assuming that their diets were equally abrasive (less certain, but not unreasonable), the Diamond Valley Lake mammoth was probably at least 40 years old when it died.