Monday, February 12, 2024

Valenictus sheperdi and friends: Miocene-Pliocene tusked walruses from the Purisima Formation in Santa Cruz, California

I had very much intended to be writing a part 2 of my Xenorophus blog series right now but the Journal of Vertebrate Paleontology jumped the gun and published our walrus paper without letting us know a publication date - I assumed it would be in March sometime [heads up to anyone else 'attempting' to put together a press release for an upcoming paper in JVP - also, you will have to ask them if your paper has been chosen as a feature/cover article, because they will not tell you at present]. Without further ado, a summary of our most recent paper on odobenine walruses from the Purisima Formation.

 
Infographic I made a few years ago combining my skull line drawings with a composite phylogeny.
 

Introduction

Walruses have a surprisingly long fossil record - and as bizarre as the modern walrus is, it's of course only logical that it must have looked less weird in the past (we're going to flip this idea on its head here shortly). What I mean by this is that walruses are pinnipeds - closely related to seals and sea lions, within the order Carnivora. Pinnipeds, along with cetaceans and sirenians, are one of the three "main" groups of marine mammals. Sea otters, aquatic sloths, the polar bear, and a couple other weirdos like Kolponomos are geologically more ephemeral experiments with marine existence - but pinnipeds are one of the 'long haulers', so to speak. Because the walrus is a highly specialized and unusual pinniped, it stands to reason that ancestral walruses must have been much more seal or sea lion like in the past - and for most of the Miocene - roughly half of their evolutionary history (from about 17 to about 8-9 million years) - they would have looked pretty similar to a seal or sea lion externally, and even internally as their skulls are quite similar. By the late Miocene (~8-5 million years), walruses diverge into a few groups - a few late-surviving "imagotariine" walruses like Pontolis and Titanotaria, the dusignathines or double-tusked walruses (Dusignathus, Gomphotaria) - and the odobenines, or true tusked walruses. If you want a slightly dated* recap of all of this, see my blog series "The Evolutionary History of Walruses" - part 1, part 2, part 3, part 4, part 5.

*OH MY GOD I cannot believe I wrote that series ten years ago.


 Cast of the skull of Aivukus cedrosensis from the Almejas Formation of Baja California.

Odobenine walruses are surprisingly diverse compared to today. The oldest named species is Aivukus cedrosensis, thought to be about 6-8 million years old - from the Almejas Formation of Isla Cedros off the coast of Baja California. It has a long seal-like snout and lacks tusks, but has several cranial features of the odobenines and a reduced dentition. The age of this taxon is uncertain - there is no good maximum date for the Almejas Formation. However, during this study we realized that all of the teeth of great white sharks reported from this unit are Carcharodon carcharias, according to the faunal list of Barnes (2008) - rather than unserrated teeth of Carcharodon hastalis. It's possible that these teeth could represent the transitional great white Carcharodon hubbelli and were misidentified as C. carcharias - but no C. hastalis teeth are reported from these localities. This strongly suggests that the Almejas Formation is likely to be younger than the base of the Purisima Formation at Santa Cruz, where C. hastalis teeth occur in a few layers that are approximately 6.3-6.7 million years old.

The holotype and only known skull of Protodobenus japonicus.

A somewhat more derived species, Protodobenus japonicus from the early Pliocene of Japan (4-5 mya), has a short stubby snout and short stubby tusks. These tusks look like regular canines externally, but critically possess a core of globular dentine (see following paragraph).  Protodobenus is small - harbor seal sized - and very likely to be a juvenile. The erupted parts of the canines are minimal but also broken, and the true extent of what is erupted is unclear. However, if it is indeed a juvenile, longer tusks were very likely present in adult forms. Unlike Aivukus, Protodobenus has a very deep and foreshortened skull and an inflated 'muzzle' that houses those elongated canine roots - roots that seem to be open, and perhaps continuously growing.

Thick core of globular dentine in tusks of modern and fossil walruses - from Ray (1975).

 
Sparse globules of dentine in teeth of modern elephant seal (left) and sperm whale (middle, right) - from Ray (1975).

Globular dentine is a dental tissue unique to some mammals - it consists of little beads of dentine fused together and occurs sporadically in sperm whale teeth but as a large rod running down the middle of the tusk in some walruses. In 1994, Tom Deméré named the new tribe Odobenini - a smaller clade within the Odobeninae - based on the possession of globular dentine. Aside from the modern species, Odobenus rosmarus, three other walrus genera are present in this clade: the fragmentary Pliopedia (which we'll sort of ignore for a while), the "toothless" walrus Valenictus, and Ontocetus from the North Atlantic and Japan. 

Early discoveries: Valenictus imperialensis (and a little about Pliopedia pacifica)

One of preeminent marine mammal paleontologist Remington Kellogg's earliest publications on any fossil marine mammal was a short paper naming a new "sea lion" which he called Pliopedia pacifica. He studied this specimen during a research visit to California with E.L. Furlong in 1920 and facilitated by the infamous ichthyologist David Starr Jordan of Stanford University. The holotype consisted of a handful of associated forelimb bone fragments - more on that later. 


The holotype humerus of Valenictus imperialensis from the lower Pliocene Deguynos Formation of Imperial County, California - just southwest of the Salton Sea and due east of San Diego. Sarah and I, and all three cats, will be driving by the type locality just off I-8 in a few months time when we make our cross-country trip back to the Pacific coast.

A complete humerus collected just after World War 2 from the desert in Imperial County near Plaster City - just a few miles from the US-Mexico border. This specimen was originally placed in the California Institute of Technology (CIT) collection and sometime before Ed Mitchell studied it, subsumed within LACM (Natural History Museum of Los Angeles County - formerly the Los Angeles County Museum). This incredibly stout and relatively small humerus was named as the holotype of Valenictus imperialensis by Ed Mitchell in 1961. Mitchell went to great lengths to defend his identification of the specimen as a new taxon, suggesting it may represent a new family but ultimately identifying it as a walrus - laying out many new observations on pinniped humeri. Chief among these is a tuberosity for the deltoid insertion that is separate from the deltopectoral crest of the humerus.


 A painted cast of the Burman walrus specimen on display at the Santa Cruz Museum of Natural History - recently described and identified as Valenictus sp., cf. V. chulavistensis.

Toothless walruses from Santa Cruz and San Diego, California

In the late 1980s Mr. Eric Burman was checking out some tidepools in Santa Cruz when he happened upon a large nodule with a skull inside. He brought the skull to my colleague Frank Perry, who recognized the specimen as a pinniped skull. It was sent to Larry Barnes at LACM, where it was prepared for study. Barnes reported it with Frank at the 1989 Marine Mammal Conference in Pacific Grove, California. They indicated that the specimen was similar to the modern walrus Odobenus rosmarus but completely lacked teeth aside from the sockets for the tusks, and that the skull was somewhat longer and sea lion like than the greatly foreshortened skull of Odobenus. Unfortunately, nothing aside from the conference abstract was ever published. A very nice painted cast of the skull is on display at the Santa Cruz Museum, which I saw during my very first research visit in 2005.


The fragmentary partial holotype skull of Valenictus chulavistensis -

Shortly thereafter - around 1990 I believe, but cannot recall the exact date - another toothless walrus was reported, this time from the contemporaneous (but slightly younger) San Diego Formation of southern California. This material included a partial skeleton of a large male (confirmed by a baculum), a juvenile male skull with both tusks, and some other isolated specimens including a juvenile maxilla and an isolated but complete adult tusk. This material formed a large component of the research material for Tom Deméré's Ph.D. dissertation - which was eventually published in 1994. At some point, hearing that another toothless walrus had appeared in Pliocene rocks of California, Barnes drove down to San Diego to check it out in person - and became convinced that they were not identical. In the mid-2000s, once I started finding difficult to identify Purisima Formation vertebrates in Santa Cruz and further north along the coast, I started meeting with Frank Perry at the Santa Cruz Museum of Natural History, who conveyed to me much of the history of these walrus fossils and explained the storied history of the cast of the spectacular skull in the SCMNH display that had, somehow, evaded formal published study for 16 years or so.

After a few more years of reading, I visited the San Diego Museum of Natural History for the first time in August 2007 - I had accumulated quite a collection of fossils from a couple of State Parks permits (all material now curated at UCMP Berkeley) and desperately needed to compare the marine mammals with other fossils - you see, virtually all of the anatomically informative specimens at UCMP had been taken on loan in the 1970s and 1980s to other institutions. I wanted to see many of these - on loan to LACM - and never heard back from anyone there despite repeated emails and phone calls. However, I did get a warm response from the SDNHM paleontology curator - and namer of Valenictus chulavistensis - Tom Deméré, who said if I can get myself down there and get a hotel I'd be welcome to spend as much time in collections as I wanted. He also reminded me that the famous San Diego Zoo was their neighbor, if I earmarked enough time to take an afternoon off from collections work. In addition to the permitted material I collected, I brought along many specimens from my then-private collection (obviously material all earmarked for donation to the Santa Cruz museum or to UCMP; they all mostly went to UCMP over the next couple of years). Tom was very generous with his time, and helped me identify many specimens - and he was particularly helpful with some of my baleen whale earbones and other specimens. This was foundationally important to me because up until this point, I had gotten a pretty prickly (read: outright hostile) response from other marine mammal paleontologists and then-Ph.D. students on the west coast, and was starting to doubt my chosen path.* Tom let me repeat something I did at UCMP: just open up every single cabinet and pull out specimens when they matched something I had, and see what the identification was. If he had a few minutes free, I'd ask him about the identification. In a few months' time, I'll be starting as the second Colclough postdoctoral researcher at the SDNHM, and I am very, very much looking forward to going drawer-by-drawer again and reacquainting myself with their collection - nearly 20 years later.

*The prior summer, I met Morgan Churchill while on a research visit at UCMP, then a master's student of Annalisa Berta, at San Diego State University - he was quite encouraging and we hit it off so well that he and I are still publishing together. He introduced me to Rachel Racicot, another master's student of Annalisa's at the time, and I finally realized that there were some very nice, rational and encouraging people in marine mammal paleontology. Now we all have our PhDs and are either professors or postdocs, still publishing together. And, matter of fact, Morgan coauthored the study that this blog post is summarizing! It's been a good ride so far. A little retrospective like this reminds me how far I've come.

One of the things I happened upon while rummaging through SDNHM collections was an unpainted cast of the Santa Cruz skull - labeled "Valenictus sp.". I asked Tom about this identification - and in his opinion, it was referable to Valenictus - and not very different at all from Valenictus chulavistensis in particular. I was amazed - and it clicked for me: of course there wouldn't be two different genera of toothless walruses in the California Pliocene. Occam's Razor and all that. 


 Composite skeleton of Valenictus chulavistensis on display at SDNHM.

A closer look at Valenictus chulavistensis

The discovery of Valenictus chulavistensis was significant for multiple reasons. First, it was one of the few named marine mammals from the Pliocene of California - anything new is a great window into the evolution of marine mammals before the record goes 'dark' during the Ice Age. Second, it clarified what the rest of Valenictus looked like: the humerus was very close in shape to the relatively smaller and more stout humerus of Valenictus imperialensis reported by Ed Mitchell three decades prior. Indeed, the specimen was in fact a walrus, and an odobenine in particular. Humeri are somewhat diagnostic in pinnipeds, but they can't tell you much about the paleoecology of the animal - not like good skull material can, anyway.

 
The paratype skull of Valenictus chulavistensis, an immature male. It's been foreshortened a little bit by burial compaction, making it falsely look like the skull of Odobenus. All other Valenictus skulls are elongated like a stubby sea lion.

Valenictus, as it turns out, is pretty interesting in a number of ways. The first is the toothless condition: there are no sockets for upper incisors, premolars, or molars - just the two upper canines - and no sockets for any lower teeth at all. Toothlessness might seem counterintuitive - you need teeth to eat stuff, right? Wrong, actually - it depends upon what you eat. The modern walrus doesn't have any incisors (typically), and has lost or reduced some of its postcanine (cheek) teeth - typically not possessing upper molars. Though rightfully assumed to use its teeth in feeding, Francis Fay reported detailed accounts of feeding experiments with modern walruses - and they don't bite or chew anything with their teeth. Mollusk shells don't enter the oral cavity at all - walruses will purse their enormous lips, position a clam shell within the lips, suck the meat right off of the shell, and let the empty shells fall to the seafloor. The teeth in the modern walrus are however used for 'percussive' communication - the jaw is closed rapidly and you can hear a loud hammering sound - it almost sounds like two 2x4s being banged together. What's very interesting here is that Valenictus chulavistensis is more highly specialized than Odobenus rosmarus is for suction feeding.


 Another view of the composite skeleton of Valenictus chulavistensis.

The second curious aspect is the postcranial skeleton of Valenictus. The bones of Valenictus chulavistensis are very dense - like sea cow bones. This condition is called osteosclerosis, which is technically defined as the internal 'inflation' of the bony cortex (wall) by reduction of the marrow cavity. The bones of the modern walrus are indeed heavy, and the skull of modern Odobenus should probably be described as osteosclerotic as well, but the limb bones of Valenictus are quite a bit more dense (though this has never been quantified, to be honest). Some of them are also inflated externally - what is called pachyostosis. Increasing bone density is typically acknowledged as an adaptation for having 'bone ballast' - a way to help a marine tetrapod sink down to the seafloor. This is particularly important for any species of marine tetrapods that feed on the seafloor or need to dive shallowly, or have enormous buoyant guts that need to be counter-weighted. Sea cows (Sirenia) both feed on the seafloor and have enormous buoyant guts, and as a result have incredibly dense pachyosteosclerotic bones.* Walruses feed on the seafloor and are pretty hefty animals, so a bit of bone ballast helps. The dense skull, along with the heavy tusks, might help the modern walrus stay oriented in a stable orientation with the head down along the seafloor in order to efficiently cruise along and find mollusks. In the case of Valenictus, something else may have been going on given that modern walruses don't need such a high degree of bone ballast. Fossils of Valenictus have also been found in the proto-gulf of California/Sea of Cortez - V. imperialensis is one such example of this. There is evidence of hypersaline conditions in the proto-gulf - and perhaps V. chulavistensis inhabited subtropical embayments undergoing rapid evaporation causing hypersalinity. Hypersaline conditions make you more buoyant, and so perhaps the extra bone ballast in Valenictus is an adaptation against this.

*However, the recently extinct Hydrodamalis gigas - Steller's sea cow - fed on kelp at the surface and was apparently incapable of diving and its back stuck out of the water most of the time, according to the observations of Steller himself.

The third curious aspect of Valenictus chulavistensis is nothing anatomical, but rather its geographic location: San Diego, California, is not normally what comes to mind when you picture where walruses live. The modern species is chiefly Arctic in distribution, rarely straying south of the Alaska Peninsula or the Aleutians in the North Pacific, and in the Atlantic, rarely further south than the southern tip of Greenland. These are latitudes approximately 60*N - San Diego, on the other hand, is approximately the same latitude as Charleston, South Carolina, where I am typing from right now - 32*N. As alluded to earlier, walruses were formerly much more diverse and cosmopolitan in their past distribution. Adaptation for boreal seas and sea ice is apparently a very recent development in walrus evolution.

 
A photo of the skull taken by Forrest Sheperd shortly after lugging the 70 lb concretion off the beach. This is the photo sent to my MSU email account in early 2011.

A new fossil walrus from Santa Cruz - the discovery and laborious preparation of Valenictus sheperdi

In January 2011, a young fossil collector I had met a couple of times - 13-year-old Forrest Sheperd - was looking for fossils in Santa Cruz and happened upon a 70 lb sandstone concretion with bone sticking out. He recognized that a skull was presered inside the nodule, and that most of it remained entombed within the rock. After I saw some photos Forrest emailed me, I realized it was a walrus skull. I had already visited SDNHM and taken quick snapshots for future reference of many Valenictus skull specimens (three or four new skulls had surfaced in the 15 years since it was published) - and though I couldn't see the palate, the top of the skull and its size looked like a good match. I asked Forrest if he would be willing to donate the specimen, and so during my last semester of graduate school - March 2011 - I drove out to California from Bozeman Montana to visit family, do a little coastal fieldwork, and meet with Forrest. I also took the opportunity to drop off a carload of fossils at UCMP at Berkeley. I met with Forrest, felt immediately intimidated by the massive weight of the concretion, confirmed it was a walrus, and a few days later started the drive back to Montana. I spent a few months at Museum of the Rockies reducing the size of the concretion and a bit of airscribing to reveal some of the more shallowly covered parts of the skull. The late Bob Harmon dug out a tool he had been talking about for several years - a pneumatic scaler, which is a polite way of describing a handheld jack hammer. Now, I usually use that description for an airscribe, which is fair. However, a pneumatic scaler really is a handheld jack hammer - it packs a serious punch, and can chip off silver dollar sized chunks of the hardest, toughest sandstone I've ever encountered (which, actually, happens to be the rock the concretion around Forrest's walrus was enveloped by). By May 2011, I had successfully defended my Master's thesis and submitted my edits, had them approved, and Sarah and I started preparing to move out - we were ready to move on from Bozeman and start the next chapter of our lives down under.


 I just dug up this photo from March 2017 of me chipping away at the concretion out back behind "the old place". Given the upcoming, imminent move I am making to my next position, me wearing a "Property of San Diego Natural History Museum" is pretty hilarious and prophetic. Cosmic irony.

A few months later, I was accepted into the Ph.D. program at University of Otago to study with Ewan Fordyce. In retrospect, I probably could have taken the specimen with me - it was the only fossil I had considered bringing along - but another 50 lbs would have costed us several hundred additional dollars in overweight baggage fees, and we had to fit everything into 12 suitcases. I very easily could have prepared the specimen in Ewan's lab, but it would have stolen precious time away from my already brief three year program. The specimen had to wait back in California. Eventually, after graduating with my Ph.D. and getting more confident with acid preparation after getting hired at the Mace Brown Museum of Natural History, the fossil was sent to me on the east coast and I did a little bit of chiseling to reduce the volume of the concretion. I also did a bit more airscribing, but decided that I would just bathe the entire thing in a large acid bath - typically about 10 liters of 10% acetic acid. Thanks to the generosity of Jim Goedert, I was able to not only have the acid paid for by his donations, but also working on his fossils for nearly two years gave me the confidence I needed to try something so large. I generally had to replenish the acid once every three weeks, and I would fill up nearly every 4 liter acid bottle I had - for reference, this is about a half hour job. Not bad, but mixing that much acid down from glacial acetic acid - which, by the way, is 100% acetic acid - is a bit nerve wracking and relies a steady hand and focus. I've never burned myself with 100% acetic, but I have had my sinuses cleaned out a couple times and gotten a few drops onto my labcoat (which is why I was wearing a labcoat) and a couple spills up to a few milliliters (tablespoon size). 


 Progress photos of acid preparation, which took place from March 2017 to September 2018 or so.

For whatever reason, the reaction of Forrest's walrus to acid was quite slow; for Pysht Formation calcareous siltstone nodules from the Olympic Peninsula (donated by Goedert), I find that a once per week replenishment with fresh acid is best. You don't want to replenish too early and waste some of the potency of the acid, so I tend to drop a piece of one of Goedert's concretions - always the same piece - and see how reactive it is after a minute or so. If there are scarce bubbles, then it's time. Mother of vinegar also tends to accumulate on the surface, and in the case of some fossil sites, enough iron is freed and oxidized that the acid takes on a "lovely"  rusty hue right when it is just about spent. It's like taking a limit in Calculus - and I imagine that the acid potency curve is an exponential decay curve, like for calculating the age of a rock using ratios of radioactive isotopes. The line indicating 'spent acid' is going to be pretty close to flat at some point; the sooner you can replenish acid, the fossil will be subjected to stronger acidity for a greater proportion of the bath - thereby shortening preparation time. However, acid is sort of cheap - and I'm certainly 'cheaper' than the acid, so to speak - so at what point on the curve do you say "good enough, let's mix up a new batch"? It's a bit of a guessing game. If time is not of the essence, two weeks for anything in the ~1-3 kg size range is enough. Also recall that it's related to surface area. A sphere or cube will have the lowest surface area to volume ratio; however, many of these Olympic Peninsula concretions are all burrowed and have incredible nooks and crannies that dramatically increase the rate at which dissolution occurs because the surface area is much larger. For the walrus, it was sort of pill-shaped a low surface area. The tough matrix took about 18 months or so to come completely clean. Making matters worse was that the very center of the concretion seemed to be dolomitized: it no longer reacted to acid, and the matrix on the inside of the skull started to dissolve. So, I called off acid prep and started airscribing the remaining bits of stubborn matrix - you now see a pale oval 'tongue' in the middle of the palate, the permanent stain of this other rock type in the middle of the concretion. 

The holotype skull of Valenictus sheperdi in dorsal view.
 
The holotype skull of Valenictus sheperdi in lateral view.

Tusked walruses, and including the new species, from the Purisima Formation: what's new?

 We'll start with Valenictus sheperdi, because that's the most exciting material from the paper. The holotype specimen, UCMP 219091, is quite a bit larger (36 cm long) than the female skulls of Valenictus chulavistensis. We know that there are two morphotypes of V. chulavistensis - one with relatively narrow, dainty canines and skulls approximately 30 cm in length, and a robust canine morphotype with skulls pushing 35-40 cm and circular tusk cross-sections. This morphotype is confirmed to be male owing to the preservation of the baculum (penis bone) with the holotype. Generally speaking, bacula are nice, but it's generally uncontroversial to identify pinniped skulls with proportionally small canines and low muscle attachments as female - given how extremely sexually dimorphic pinnipeds are. Given that the V. sheperdi holotype skull is from a female, and it is about 18-24% larger than V. chulavistensis females, this suggests that V. sheperdi is a much larger walrus - perhaps close in size to modern walrus. There are a few anatomical distinctions as well. The paroccipital process of the squamosal has a sharp muscle attachment crest, whereas it is blunt in V. chulavistensis. There is a sharp, long crest along the maxilla below the orbit and behind the tusk socket - such a crest is not present in V. chulavistensis. Lastly, and perhaps most critically, the space between the canines is narrower in V. sheperdi - approximately 65-75% of the distance relative to the condition in V. chulavistensis. And, by the way, this is a comparison made only between females - so it's not caused by sexual dimorphism. We also report a titanic partial femur, collected by David Landes, that is a bit larger than the femora from the San Diego Formation; the width at the 'knee' end is about 160 mm, as compared to 120mm in the largest known San Diego Formation femora. The specimen is from just a few meters upsection relative to the holotype, so we identify it as Valenictus sp., cf. V. sheperdi. Also tentatively referred to the species is an astragalus that I reported back in 2017, collected by Wayne Thompson.

The holotype skull of Valenictus sheperdi in ventral view, showing that incredible toothless palate.

The holotype skull of Valenictus sheperdi in anterior and anterolateral view.

 


 A couple of postcranial bones we reported as Valenictus sp., cf. V. sheperdi - from just above the V. sheperdi type horizon; a big ass partial femur, and an astragalus I reported in 2017. Collected and donated by Dave Landes and Wayne Thompson (respectively).

Speaking of isolated postcrania - one of the reviewers asked "could Valenictus sheperdi be conspecific with V. imperialensis?" Indeed, an excellent question. The fossils are from different basins, so the thought hadn't crossed my mind - but the bigger clue is what had really initially separated the two: Valenictus sheperdi is larger than V. chulavistensis, and V. imperialensis is quite a bit smaller than V. chulavistensis. So I thought - exactly how different in size were V. sheperdi and V. imperialensis? The former is known only from a skull and the latter only from a humerus. Luckily, the holotype skeleton of V. chulavistensis is known from a fragmentary skull with an approximate length of 40 cm and a humerus measuring 31 cm long; this ratio suggests a humeral length of 27 cm, compared with the 24 cm long humerus of V. imperialensis. Add to this the fact that the V. imperialensis holotype is so robust it is likely to be a male - making V. imperialensis a decidedly small odobenine. Further, the predicted skull size of V. imperialensis is 32 cm. However, we really need more material of V. imperialensis to be sure!

Skull of Valenictus sp., cf. V. chulavistensis, the Burman specimen originally reported in a conference abstract by Barnes and Perry.

Higher up in the Purisima Formation, we also reported the skull originally studied by Barnes and Perry - and identified it as Valenictus sp., cf. chulavistensis - as we could not identify any features that distinguished it from the San Diego fossils. It is also a female, but not quite as well preserved - and a bit smaller in size, more like V. chulavistensis. Geochronologically, this also makes sense - this specimen is younger, and dated to about 4.89-3.59 Ma, which overlaps in time with the lower parts of the San Diego Formation. This suggests that this species lived along much of the Pacific coastline, as these localites are 700 km apart (a little added to reconstruct shortening by the San Andreas fault). 

The oldest well-dated record of Odobeninae, a first metacarpal from the left flipper of a walrus collected by yours truly in 2007, I believe.
 

In addition to the skulls, we also reported a couple of more partial specimens that nonetheless preserve some key features and are quite old. The first is a 'metacarpal I' collected from quite low down in the Purisima Formation, and is roughly 6-7 million years in age, likely close to about 6.9 Ma. This bone is somewhat diagnostic in pinnipeds - metacarpals are the largest bones in your hands, and the first metacarpal is the bone that connects your thumb to your wrist; the remaining metacarpals are in your palm (digit 1 = thumb, 2= index finger, 5= pinky). Since walruses are pinnipeds, all of the metacarpals and phalanges are embedded in the flipper. This specimen is massively inflated and also bent laterally - a feature only seen in odobenine walruses like Odobenus and Valenictus. However, it is grossly more inflated than any named walrus - but almost certainly represents an odobenine; dusignathines and all earlier "imagotariine" walruses have somewhat long, narrow metacarpals that really can't be confused with specimens like this. What's interesting is that this specimen has an older and better age determination than the previously oldest known odobenine, Aivukus cedrosensis from the Almejas Formation of Baja California.

The oldest well-dated record of the long tusked walruses, Odobenini - a tusk fragment with obvious globular dentine, collected by F.A. Perry.

The last specimen that is noteworthy is a hefty chunk of a large canine tusk collected from a stratum dating to about the Miocene-Pliocene boundary, roughly 6-5.2 Ma, but likely to be at the younger end and around 5.3 Ma. This specimen was collected in 1978 by my friend and colleague Frank Perry, and preserves a large core of globular dentine. This feature indicates that the specimen represents the Odobenini - long tusked walruses. It is possibly Valenictus, as it is only slightly older than Valenictus sheperdi - but ultimately we don't know, since isolated tusk fragments are not really diagnostic. But, that's fine! Because this specimen happens to be the oldest well-dated record of Odobenini anywhere. The previously oldest specimens were tusks from the early Pliocene Horokaoshirarika Formation of Japan - which now seems to be a bit younger than previously estimated, with a currently proposed maximum age of 4.5 Ma. What's further surprising is that this is entirely younger than the entire age control for Valenictus sheperdi, really underscoring how old such a specialized walrus is. This canine fragment indicates that the Odobenini already evolved prior to the Miocene-Pliocene boundary.

 
Phylogenetic analysis of walrus relationships from our new study.

Implications for the Relationships of Tusked Walruses

Any time a new pinniped taxon it's a good idea to revisit phylogeny - and in our case, Morgan and I published our walrus phylogenetic matrix 11 years ago and it's been tinkered with and added to by a few different papers since. At the time, we were describing a new specimen of Pelagiarctos, and trying to demonstrate the identification in an ironclad fashion, and needed a ton of dental characters. That matrix was never intended to be the primary walrus matrix in circulation, though that's certainly what happened; within a year or so we started adding additional taxa and more cranial and postcranial characters, and also simplified and streamlined some of the perhaps overly-parsed dental characters. We incorporated most of the new walruses named since then, including Archaeodobenus, Osodobenus, Pontolis kohnoi and Pontolis barroni, and Titanotaria orangensis - along with some proposed coding changes from earlier studies. Our matrix went from about 90 in the prior version to 143 - a dramatic 63% increase in the amount of character data. We also fixed some issues in character ordering and used a large number of ordered characters (n=46).

So, what did we learn from this new analysis? Surprisingly, the phylogeny didn't really change much from earlier work - either from our 2013 analysis, or from recent studies by Magallanes et al. (2018) and Biewer et al. (2020). We confirmed dusignathine monophyly - which of course will be investigated further with the reporting of many new unpublished dusignathine specimens from California. The dusignathine + odobenine clade, Neodobenia, is again very well supported and all the relationships within it are further well-supported. Support for many of the early branches within the "imagotariine" part of the tree are quite poorly supported - and I don't quite know how to proceed there, except perhaps to include additional outgroup taxa. We found decent support for a Valenictus + Pliopedia clade (see more below), though within this did not recover a subclade for just Valenictus - likely driven by the incompleteness of Pliopedia. Curiously, we did not find a sister taxon relationship between the Ontocetus sp. skull reported from Japan and Ontocetus emmonsi from the North Sea. Like Deméré (1994A), we found a sister taxon relationship between the modern walrus Odobenus and Valenictus (with Pliopedia in there as well). With that in mind, it seems as though every odobenine lineage has a North Pacific origin sometime in the Pliocene. 

The Kettleman Hills specimen of Pliopedia pacifica, from Repenning and Tedford (1977).

We further also included Pliopedia pacifica into our phylogenetic analysis. There are two main specimens - the holotype, originally reported by Kellogg (1921), and a partial skeleton including a well-preserved forelimb with complete humerus, radius, and ulna, and a skull cap reported by Repenning and Tedford (1977) from the lower Pliocene Etchegoin Formation of Kettleman Hills near Coalinga. The humerus is similar to Odobenus and Ontocetus in some respects, and the braincase is quite similar to Valenictus. Deméré (1994A) indicated that the flattened nuchal crest of the braincase and the deltoid insertion on the humerus identify this specimen to the Odobeninae. Barnes and Raschke (1991) cast doubt on the Kettleman Hills specimen belonging to Pliopedia pacifica, and restricted the species to the type specimen. We went a step further and coded this specimen into our phylogenetic analysis - all of the codings for features preserved in both specimens were identical, and most of the other informative codings were based on the Kettleman Hills specimen. Though the humerus is very different from Valenictus, the braincase has paired sulci on the midline, like Valenictus - a possible synapomorphy for these two genera. Regardless of the assignment of the Kettleman Hills specimen to Pliopedia, it, along with a couple specimens from the younger San Diego Formation, indicate that at least a second genus of odobenine was present in the Pliocene of California.

The last Valenictus - a giant molluskivore finds itself increasingly out of its element as embayments dry up and kelp forests proliferate, creating a perfect environment for sea otters to evolve into a million or two years later - but unfriendly to walruses. I had originally intended this to showcase some of the fauna known from the Purisima, but it's largely a softbottom depositional setting. Marine specialists will identify some unlikely associations - such as giant green anemones and California mussels this far down in the water column. Nevertheless, I wanted to underscore the occurrence of this fossil associated with many species found both in the Purisima as well as the modern Monterey bay.


The Extinction of Valenictus and Friends

We took a look at the biogeography faunal succession of Miocene-Pliocene walruses along the Pacific coast in the context of ecological change, climate change, and geographic change. 

We used paleogeographic maps to estimate the additional shelf space present in California during the late Miocene (5-8 Ma) and Pliocene (5-2 Ma). Many large embayments, including the enormous shallow embayment in the southern San Joaquin Valley (occasionally but informally called the "Temblor Sea") resulted in some 33,000 square kilometers of additional shelf, along with 27,000 km2 for the modern shelf, for about 60,000 km2 in total. This was reduced to about 48,000 km2 in the Pliocene, and to 27,000 km2 in the Holocene. Why is this important? Walruses only feed in shallow marine settings, well above 100 meters depth. Walruses are not pelagic, and are tied to eating mollusks on the seafloor. Gray whales have a similar ecology in that they suction feed in shallow settings - not for mollusks, but for amphipods and other small crustaceans in dense benthic (seafloor) communities. It's no coincidence that both gray whales and modern walruses graze in the same region - the Bering Sea - and both have close ancestors that inhabited a very different looking Pacific coast in just a few million years ago. These shallow marine embayments contrast strongly with the current California coast, which is dominated instead by rugged, rocky shorelines and thick, highly productive kelp forests - admittedly today, these kelp forests are considerably diminished relative to what they were prior to 18th-19th century Russian otter hunting.

Paleogeographic maps of California from the late Miocene to early Pliocene, late Pliocene, and Pleistocene, and changing marine carnivore diversity from each time slice.

These embayments hosted a bizarre cast of marine vertebrate species including low-latitude belugas (Monodontidae), the river dolphin-like Parapontoporia, the bizarre 'half beaked' porpoise Semirostrum and a host of other true porpoises taking up niche space now occupied by delphinids, the gigantic sea cow Hydrodamalis cuestae, double tusked walruses (Dusignathinae), several species of smallish rorquals (Balaenopteridae), dwarf right whales (?Balaenula), early gray whales (Eschrichtiidae), an early minke whale (Balaenoptera bertae), and the dwarf suction-feeding whale Herpetocetus. Notably absent from this list are sea otters (Enhydra), sea lions (Zalophus, Eumetopias), elephant seals (Mirounga), harbor seals (Phoca), killer whales (Orcinus), pilot whales (Globicephala), diverse delphinids (Delphinidae), and humpback whales (Megaptera) - these taxa either probably hadn't evolved yet or have fossils in other regions and likely invaded the eastern North Pacific sometime during the Pleistocene.

Pliocene marine vertebrate fauna from the Purisima Formation - from my 2013 marine mammal assemblage paper.

What happened to all of these shallow marine embayments - and this fauna? Uplift of the California Coast Ranges either directly lifted these embayments out of the Pacific Ocean, resulting in the large broad plains like the LA basin, San Diego, Salinas Valley, and others in San Luis Obispo, Marin, Sonoma, and Humboldt counties. In the case of the "Priest Valley Strait" - the body of water that connected the San Joaquin embayment to the proto-Monterey Bay - this shallow strait was sheared by movement of the San Andreas Fault, uplifted, and eventually completely pinched dry above sea level, turning the San Joaquin embayment into an inland sea. Within a million years, it turned into a freshwater lake, which eventually continued to dry out. Sometime after being stranded in the basin, the long-snouted Parapontoporia continued to inhabit freshwater environments. Uplift of the Sierra Nevada spelled further doom for the biggest of these embayments. As the Sierras were uplifted, they eroded and shed an incredible volume of sediment into the San Joaquin embayment. A one-two punch killed the basin: its connection to the Pacific was choked by the uplift of the Coast Ranges, and filled with sediment by the Sierras.

When did Valenictus go extinct? The youngest known specimens seem to date to strata within the San Diego Formation that are around 2.6 Ma, a bit younger than the youngest known specimens from the Purisima Formation; this, ironically, is actually about the time that the Purisima basins dry up and transition to nonmarine sediments. This coincides with the beginning of the estimated period of extinction in which many of these other strange Pliocene marine mammals went extinct - sadly, a minimum date is not yet available, since the early Pleistocene marine mammal record just sort of doesn't exist. By the middle Pleistocene (~1-0.7 Ma), most of the marine mammals belong to extant taxa.

What about climate change? Climate was certainly cooling, and while cooling seas may not be terribly critical to walrus distribution, it can greatly affect their prey. During the late Pliocene, rapid expansion and contraction of the newly formed northern hemisphere ice cap also began causing rapid 'glacioeustatic' changes in sea level. Ice cap volume increases, sea level decreases - and vice versa. This resulted in loss of embayment space, but more critically - fluctuating salinity in places like the San Joaquin embayment. Sea level fluctuations drove extinctions of mollusks on both the Pacific and Atlantic coasts of North America, resulting in lower diversity of oysters, scallops, and loss of gigantic mussels in California.

The molluskivore niche was filled during the Pleistocene by sea otters, sea ducks, and the extinct flightless goose Chendytes. Potential niche fillers also include bat rays, wolf eels, and sheepshead wrasses. Critically, sea otters and Chendytes did not newly appear prior to the extinction of Valenictus - rather, they appeared later, perhaps suggesting physical bottom-up drivers for the extinction of Valenictus and company, rather than competition; these vacant niches were then, in my opinion, likely passively filled later on during the ice ages. However - we really do need more fossils from the late Pliocene and Pleistocene, and better understanding of the niches and trophic structure of the Pliocene marine vertebrate fauna from the Pacific coast - otherwise this is all just informed speculation.

References

Barnes, L. G., and Perry, F. A. (1989): A toothless walrus from the Purisima Formation in California, U.S.A. [Paper presentation]. 8th Biennial Conference on the Biology of Marine Mammals, Pacific Grove, CA, U.S.A.

Barnes, L. G., and Raschke, R. E. (1991). Gomphotaria pugnax, a new genus and species of late Miocene dusignathine otariid pinniped (Mammalia: Carnivora) from California. Natural History Museum of Los Angeles County Contributions in Science, 426, 1–27.

Boessenecker, R. W. (2013). A new marine vertebrate assemblage from the Late Neogene Purisima Formation in Central California, Part II: pinnipeds and cetaceans. Geodiversitas, 35(4), 815–940. https://doi. org/10.5252/g2013n4a5 

Boessenecker, R. W. (2017). A new early Pliocene record of the toothless walrus Valenictus (Carnivora, Odobenidae) from the Purisima Formation of Northern California. PaleoBios, 34, 1–6. https://doi. org/10.5070/P9341035289

R.W. Boessenecker, A.W. Poust, S.J. Boessenecker & M. Churchill (2024): Tusked walruses (Carnivora: Odobenidae) from the Miocene–Pliocene Purisima Formation of Santa Cruz, California (U.S.A.): a new species of the toothless walrus Valenictus and the oldest records of Odobeninae and Odobenini, Journal of Vertebrate Paleontology.

Deméré, T. A. (1994a). The family Odobenidae: a phylogenetic analysis of fossil and living taxa. Proceedings of the San Diego Society of Natural History, 29, 99–123.

Deméré, T. A. (1994b). Two new species of fossil walruses (Pinnipedia: Odobenidae) from the Upper Pliocene San Diego Formation, California. Proceedings of the San Diego Society of Natural History, 29, 77–98.

Kellogg, R. (1921). A new pinniped from the Upper Pliocene of California. Journal of Mammalogy, 2(4), 212–226. https://doi.org/ 10.2307/1373555 

Magallanes, I., Parham, J. F., Santos, G. P., and Velez-Juarbe, J. (2018). A new tuskless walrus from the Miocene of Orange County, California, with comments on the diversity and taxonomy of odobenids. PeerJ, 6, e5708. https://doi.org/10.7717/peerj.5708 

Mitchell, E. D. (1961). A new walrus from the imperial Pliocene of Southern California: with notes on odobenid and otariid humeri. Los Angeles County Museum Contributions in Science, 44, 1–28.

Ray, C. E. (1975). The relationships of Hemicaulodon effodiens Cope 1869 (Mammalia: Odobenidae). Proceedings of the Biological Society of Washington, 26, 281–304.

Repenning, C. A., and Tedford, R. H. (1977). Otarioid seals of the Neogene. US Geological Survey Professional Paper, 992, 1–87. https://doi.org/10.3133/pp992

Sunday, January 21, 2024

The Oligocene dolphin Xenorophus, part 1: introduction to Xenorophus sloanii and the Xenorophidae

In November I published a rather massive monograph on the fossil dolphin Xenorophus - it's my longest publication to date (166 pages!), and my third published monograph - and one of two published in 2023* (check out my blog summary of my other 2023 monograph on Coronodon here, here, and here). This series of posts will be in four parts: 1) an introduction to Xenorophus sloanii and the family Xenorophidae; 2) new specimens of Xenorophus sloanii; 3) the new species Xenorophus simplicidens; and 4) the paleobiology of these dolphins and some of what we've learned about them.

*I am very tired.

The Discovery of Xenorophus sloanii 

Paleontology in Charleston had an early start - likely owing to the combination of the plantation economy (lots of digging activity) and some of the earliest correctly identified fossil vertebrates from North America in general were found by enslaved Africans on the Stono Plantation in the mid 18th century and identified by them as elephant teeth - later revised to mammoth teeth. During the antebellum years, other finds made by the enslaved and slaveowners include the holotype skull of the Oligocene dolphin Agorophius pygmaeus and the Eocene basilosaurid Dorudon serratus. After the Civil War, the phosphate mining boom resulted in a proliferation of fossil discoveries and widespread stratigraphic confusion that took another century to untangle (see my earlier blog post on the Ashley Phosphate Beds here).


 The holotype skull of Xenorophus sloanii, collected from the Ingleside Mining Pit near Ladson, South Carolina, sometime before Kellogg's (1923) publication.


 My own photograph of
Xenorophus sloanii - from a 2016 visit to USNM collections with Morgan Churchill and Sarah - just after our colleague Dr. Rachel Racicot's wedding a few miles away!

The mining boom had died down by 1890 or so, but a few marl pits continued operating into the early 20th century. One such pit, the Ingleside Mining Pit*, yielded an unusual cetacean skull sometime before 1923 and was acquired by Earl Sloan, the state geologist, who subsequently donated to the Smithsonian for Remington Kellogg to study. Kellogg named the skull Xenorophus sloanii** in 1923 after Sloan just three years before Sloan passed away. The specimen was clearly from the "Cooper Marl" - now known as the Ashley Formation. Kellogg recognized that this specimen represented an early odontocete, which he referred to as a "dolphin" and noted archaic features such as double rooted multicuspate teeth and retention of an intertemporal constriction. However, he also noted that this skull had a very unusual lacrimal bone, and premaxilla. The lacrimal is the bone that houses the tear duct in terrestrial mammals; in most marine mammals the duct is lost and the bone just forms the anterior part of the orbit. In most dolphins, it is relatively small and forms the anteriormost part of the orbit - but is also fused to the jugal bone, stretched into a delicate bone the thickness of a toothpick. Instead, in Xenorophus, the lacrimal is large and triangular and covers the entire front half of the orbit - but on the dorsal side. In most other odontocetes, the dorsal part of the orbit is typically formed by ascending process of the maxilla. Xenorophus also has an ascending process of the maxilla - clearly making it an odontocete. The premaxilla, on the other hand, is also quite strange. In a normal odontocete, the premaxilla forms the tip of the snout, bears a few teeth, forms the middle of the snout (housing the mesorostral groove/gutter) and then wraps around the left and right sides of the blowhole. The premaxilla does all of these things in Xenorophus - but also invades the entire part of the skull between the eye socket and the blowhole and has a large, posteriorly expanding cone-shaped body that is actually exposed ventrally just behind the eye socket where the frontal bone has a large ring-shaped window in it. Normally the premaxilla is a thin plate that lies atop the maxilla around the nares - but in this case, the opposite is true: the maxilla instead lies above the premaxilla. The premaxilla basically occupies a space in the skull normally 'built' by the frontal. All of this is just bonkers-ass crazy, even for dolphins, which already have bizarre skulls. But we're not done: the inflated part of the premaxilla here is also osteosclerotic - extremely dense.

*Coincidentally, on the property of the Ingleside Plantation, the plantation of Francis Holmes - former curator of the College of Charleston Museum and the guy who started the phosphate mining boom - and discoverer of Agorophius.

**Commonly misspelled sloani, but the correct spelling by Kellogg shows it as sloanii


 The holotype maxilla fragment of Squalodon pelagius - as figured by Leidy (1869).

Other Early Discoveries of Xenorophidae

Famed American paleontologist Joseph Leidy was a contemporary of Francis Holmes, who sent a small rostrum fragment with a single tooth (found along the Ashley River) to Leidy. Leidy published the specimen in his 1869 monograph, naming it Squalodon pelagius. Leidy almost certainly used the genus Squalodon here as a wastebasket owing to the occurrence of double-rooted triangular teeth. He also noted the presence of what we now call embrasure pits - pits to accommodate the opposing teeth. These pits are unique to the family Xenorophidae, and I think this specimen compares quite well with Echovenator and Albertocetus (see below for more on these taxa). Unfortunately, the specimen is now lost.

 The mysterious skull of Archaeodelphis patrius, from Miller (1921) - my scan of a copy of Ed Mitchell's personal copy of the paper with his labeling and highly distinctive writing - which he had provided to Ewan Fordyce (long before all that Llanocetus nonsense).

Another curious specimen was 'discovered' in the collections of the Museum of Comparative Zoology at Harvard around World War 1 and named Archaeodelphis patrius by prominent mammalogist Grover M. Allen. This specimen consists of a braincase somewhat resembling Xenorophus, but with an orbit that is only partially covered by the ascending process of the maxilla - uniquely 'primitive' amongst all fossil odontocetes.* Like Xenorophus, this specimen possesses an intertemporal constriction and a relatively untelescoped skull. However, it doesn't quite have the same sort of highly inflated premaxilla. Archaeodelphis patrius has been needing redescription and reinterpretation for a century - and for the past half century, was locked away in a loan cabinet - while many researchers have considered it one of the most important fossil odontocetes ever discovered. OK, but here's the rub: we have no idea where the damned thing is from or how old it is. In general, the skull "looks" like an Oligocene dolphin - only Oligocene dolphins are as archaic in their morphology. A similar specimen at Charleston Museum, ChM PV 4746, was collected from the Chandler Bridge Formation of South Carolina - but the morphology is an inexact match. Unfortunately, during 100 years of collecting, not a single perfect match has been found - which is admittedly a little bit of a problem, as most of the taxa we have here - named or unnamed - are known by at least a couple of specimens (however, ChM PV 4746 is an exception and is still a singleton). Still, Charleston seems likely for several key reasons: it's the only place in the southeastern USA where fossils of archaic odontocetes were being routinely found in the 19th century. The skull was likely part of the collection Agassiz was studying and at some point divorced from its documentation (and never labeled). Holmes and Leidy never wrote about such a specimen - but perhaps it was discovered late in the 19th century (post-Leidy?) by someone in Charleston and whoever committed the information to memory either died or forgot it, and the skull sat in MCZ collections for some time prior to being 'discovered'. Finding a new Archaeodelphis would really be something.

*I very strongly suspect that the holotype of Archaeodelphis is a juvenile, however, and some of this may simply be ontogenetic recapitulation of archaic to derived features.


 The holotype skull of
Albertocetus meffordorum, whitened with ammonium chloride - the skull is nearly black in color. It is much closer in morphology to Xenorophus than it is to Echovenator or Cotylocara. From Uhen (2008).

 

Size comparison of Albertocetus and Xenorophus. Modified from Uhen (2008).

 

Skull, endocast, earbones, vertebrae, and skeletal reconstruction of Albertocetus meffordorum - images from Boessenecker et al. (2017B).

A North Carolina xenorophid: Albertocetus

Onslow Beach in coastal North Carolina has long been a location where fossils have been found strewn along the water line. In the early 2000s, several dolphin-bearing concretions were discovered and sent to the Smithsonian. I saw a talk by Mark Uhen in 2006 at the Neoceti symposium at the SVP meeting in Ottawa (my second SVP ever!) reporting these archaic specimens - and in 2008, Uhen published a paper naming Albertocetus meffordorum, the first xenorophid named in 90 years. Like specimens from the famous "Emlong collection" at the Smithsonian, this specimen had to be carefully prepared out of a hard calcareous nodule using air scribes. Albertocetus has a similar facial region to Xenorophus, and a braincase that looks - well, a lot like an archaeocete whale. Critically, it also preserved the first good earbones for the Xenorophidae - a periotic is preserved in Archaeodelphis, but it was not well-figured. Later, in 2017, I reported new specimens of Albertocetus from the Ashley Formation of Charleston - demonstrating that this taxon lived in both the Charleston and Salisbury embayments during the Oligocene - hardly a surprise. These specimens also preserved earbones removed from the skull and associated postcrania.

The skull of xenorophid Cotylocara macei from the Chandler Bridge Formation of South Carolina, from Geisler et al. (2014).

 
The holotype skull of Cotylocara macei on display at my former institution - the Mace Brown Museum of Natural History - and a 3D model of the skull with some of the bony sinus fossae on the skull.

Xenorophids and the origin of Echolocation: Cotylocara and Echovenator

Shortly thereafter witnessed a flurry of papers on xenorophid dolphins from Charleston, South Carolina. The first of these made it into the journal Nature - likely to be the highest profile publication to ever come out of the College of Charleston (very curious). The study, published by Jonathan Geisler et al. (2014), named the new genus and species Cotylocara macei - the holotype of which, CCNHM 101, is the first published specimen from my old institution, the Mace Brown Museum of Natural History at the College of Charleston. Cotylocara macei is clearly a xenorophid, though it has a much narrower snout than Xenorophus, and a wider, dish-shaped facial region. It also has a somewhat more telescoped skull - barely having an intertemporal constriction at all, with the facial bones thrusted posteriorly and overriding most of the anterior part of the braincase. However, it is distinctive in possessing a large pit behind the blowhole, which Geisler et al. named the postnarial fossa. Additionally, the specimen has very well-preserved antorbital fossae, noted previously but not interpreted. These large facial fossae are further lined with low-density bone similar to that lining the air-filled sinuses of extant odontocetes. This suggests that Cotylocara had considerable air-filled sinuses in its facial region, likely connected to diverticulae in the highly modified blowhole and indicating the ability to produce high frequency sounds used in echolocation. However, CT scans of the cochlea of Cotylocara were not informative at the time to confirm whether or not these sounds could be heard. 

 
Travis Park with the North Carolina xenorophid periotic reported by Park et al. (2016) and a modern delphinid periotic - specimen subsequently reidentified as Echovenator.
 

 
The skull, mandible, atlas vertebra, and earbones of Echovenator sandersi - from Churchill et al. (2016).
 

Life restoration of Echovenator sandersi - by Alberto Gennari.

 

 

Comparison of periotics of Albertocetus from the Ashley Formation of Charleston SC (A-B) and Belgrade Formation of NC (C-D; collected Gary Grimsley in 2016), the North Carolina Echovenator periotic studied by Park et al. (E-F; collected J. Mefford, Onslow Beach NC), and a periotic of cf. Echovenator I collected from Belgrade Quarry in 2017 (G-H) - from Boessenecker et al. (2017B).

High frequency hearing was later confirmed in xenorophid dolphins by two studies that came out in parallel: Park et al. (2016), who scanned an isolated periotic of a xenorophid from Onslow Beach (North Carolina - same site as Albertocetus), and Churchill et al. (2016), who reported another xenorophid, Echovenator sandersi, from the same rock unit as Cotylocara - the Chandler Bridge Formation of South Carolina. The North Carolina periotic had evidence of adaptations for hearing high frequency sounds, but was unidentifiable (at the time) past the family level. The beautifully preserved skull of Echovenator sandersi, on the other hand, had some similar, but more subtle facial sinus fossae like Cotylocara, and well-preserved periotic bones. Morphometric analysis of the scans indicated that Echovenator could hear high frequency sounds; between these two genera, xenorophids in general were clearly able to echolocate. Ironically, Park et al. (2016) and Churchill et al. (2016) were unaware that the other team were working on the same taxon: a year later, I published an article reporting the periotic morphology of Albertocetus, and in it reidentified the North Carolina specimen as Echovenator sp. owing to numerous shared features. 

The partial holotype skull (and referred specimen - E) of the dwarf, snort-snouted toothless suction-feeding dolphin Inermorostrum xenops - from Boessenecker et al. (2017A).

My life restoration of Inermorostrum xenops.  

 Rostral proportions through time in Odontoceti - Inermorostrum is already one of the most brevirostrine odontocetes, and it evolved within just a few million years of the mysticete-odontocete split. From Boessenecker et al. (2017A).

A xenorophid that really sucked: Inermorostrum

One of my first projects at CCNHM was to report this adorable little skull clearly representing an adult dwarf xenorophid. This skull has a vertex with similar skull sutures to Albertocetus, and shared with it and Xenorophus a flat vertex - in other words, lacking the postnarial fossa of Echovenator and Cotylocara. While the small size is distinctive, that pales in comparison to the business end of the skull: the snout is quite short - approximately 1/3 of the length of Cotylocara if you scale it to the width of the snout - and completely toothless. That is not to say the teeth fell out - there are no tooth sockets, either - indicating that the species was completely toothless. We named this new genus and species Inermorostrum xenops - the genus name meaning 'weaponless snout' and the species name meaning strange face, hearkening back to Xenorophus itself and the family. This little dolphin was from the Ashley Formation, a contemporary of Albertocetus and Xenorophus and about 28-30 million years in age; only a single referred specimen exists, a partial vertex in Charleston Museum collections. Analyses of rostrum length evolution through time indicated that longirostry (long snouts) and brevirostry (short snouts) evolved many times in parallel within the Odontoceti, and that xenorophids evolved short snouts very, very early in odontocete evolution, shortly after diverging from the baleen whales. What good is a short, toothless mouth? Reduction of the dentition has occurred in many modern odontocetes including sperm whales (Physeroidea), beaked whales (Ziphiidae), Risso's dolphin (Grampus griseus), and the narwhal (Monodon monoceros). In all such cases, the few teeth that are retained are generally reserved for combat and not used in biting prey. Most also happen to have short snouts. Many toothy dolphins with short snouts also exist. What these all share is the ability to suction feed for soft-bodied prey like squid and fish. The loss of teeth accomplishes two things: streamlines the mouth to improve the flow of water, and in the case of those species that feed on squid, decreases hard points that suckers can attach to easily. A short snout makes for a smaller mouth, which if paired with large lips, increases suction forces as well. The tiny size of Inermorostrum means that it was also a shallow, rather than deep diver: this rules out deep dives for squid. Perhaps Inermorostrum was coastal in its distribution (like most small odontocetes today) and foraged on the shallow sea floor for soft bodied prey like sea cucumbers, octopus, and worms.


A family portrait of Xenorophidae - from left to right: Xenorophus sloanii, Cotylocara macei, Echovenator sandersi, and Inermorostrum xenops.

In sum, many new xenorophids have been discovered since Kellogg named Xenorophus sloanii in 1923 - but that's obviously not all that's been uncovered. Next up in Part 2, I'll review the new specimens of this new species and some of what we've learned.

References 

Allen, G.M. A new fossil cetacean. Bulletin of the Museum of Comparative Zoology 1921, 65, 3-14.

Allen, J.A. Note on squalodont remains from Charleston, S.C. Bulletin of the American Museum of Natural History 1887, 12, 35-39. 

Boessenecker, R.W.; Fraser, D.; Churchill, M.; Geisler, J.H. A toothless dwarf dolphin (Odontoceti: Xenorophidae) points to explosive feeding diversification of modern whales (Neoceti). Proceedings of the Royal Society B 2017A, 284, 20170531

Boessenecker, R.W.; Ahmed, E.; Geisler, J.H. New records of the dolphin Albertocetus meffordorum (Odontoceti: Xenorophidae) from the lower Oligocene of South Carolina: encephalization, sensory anatomy, postcranial morphology, and ontogeny of early odontocetes. PLoS ONE 2017B, 12, e0186476.

Churchill, M.; Martinez-Caceres, M.; Muizon, C.d.; Mnieckowski, J.; Geisler, J.H. The origin of high-frequency hearing in whales. Current Biology 2016, 26, 2144-2149.

Geisler, J.H.; Colbert, M.W.; Carew, J.L. A new fossil species supports an early origin for toothed whale echolocation. Nature 2014, 508, 383-386.

Kellogg, R. Description of an apparently new toothed cetacean from South Carolina. Smithsonian Miscellaneous Collections 1923, 76, 1-7.

Park, T.; Fitzgerald, E.M.G.; Evans, A.R. Ultrasonic hearing and echolocation in the earliest toothed whales. Biology Letters 2016, 12, 20160060. Uhen, M.D. A new Xenorophus-like odontocete cetacean from the Oligocene of North Carolina and a discussion of the basal odontocete radiation. Journal of Systematic Palaeontology 2008, 6, 433-452.