A scene from one of my favorite movies, The Goonies - with Haystack Rock (a Neogene igneous intrusion) and Cannon Beach in the background, and typical Oregon coast weather.
Another famous sea stack at Olympic National Park in Washington.
The Pacific Northwest - the "top left" corner of
the United States (and British Columbia!), if you will - is a land that most
people will associate with The Goonies, grunge rock, good coffee, D.B. Cooper, Tillamook ice
cream (and cheese), lumberjacks, tall trees, totem poles, sasquatch, and
Cascade volcanoes. To vertebrate paleontologists like myself, however, the
Pacific Northwest is a playground of discovery including some of the most
spectacular and desolate coastlines on the continent, with magnificent redwood
and pine forests marching right down to concretion-riddled rocky shores. Some
of the earliest marine mammal fossils found on the west coast were discovered
along the coast of Oregon - Pontolis magnus, a giant walrus from the
Empire Formation of Oregon (Coos Bay) described in 1903, and the pseudo-sea
lion Desmatophoca oregonensis, named in 1906 from the Astoria Formation
near Newport, Oregon. Since then many prominent paleontologists and amateur
collectors have scampered along the deserted windblown shoreline of the Pacific
Northwest in search for Cenozoic marine vertebrates, such as Earl Packard,
Douglas Emlong, Guy Pierson, Jim and Gail Goedert. I've done a small amount of
fieldwork, largely constrained to Lincoln County, Oregon, Cape Blanco, Oregon,
and the Eel River Basin near Eureka, California. Paleontological fieldwork in
the Pacific Northwest is challenging - the maximum and minimum tides are more
extreme than central California, the localities are often more isolated, it's
usually far windier and colder - and I've been rained out of fieldwork along
the Oregon coastline nearly 3/4 of the time.
Doug Emlong with one of his skulls of Proneotherium repenningi
from the Astoria Formation, Oregon.
With few
exceptions (e.g. the Goederts and Bruce Welton), the story of marine vertebrate
paleontology in the Pacific Northwest is dominated by amateur collectors. This
is in stark contrast to the bulk of marine mammal material from central and
southern California collected in the 1970s and 1980s, mostly collected by
professional paleontologists and students on field trips from UCMP, LACM, and
SDNHM. Unlike the California coast, which has many fossil sites conveniently
located within an hour's drive of various large universities and other
paleontological institutions, most of the fossil sites in the Pacific Northwest
are a bit further of a drive. Coastal fossil sites need semi-constant
monitoring, as erosion is rapid and new fossils can be exposed after every
storm at some localities. At some fossil sites in central California, I
preferred to visit them three times a year - winter, spring, and summer
(erosion was slowest in the fall). As a result, the most successful collectors
in northern California, Oregon, and Washington have mostly been amateur
collectors or professionals able to go on long trips; being based nearby and
with the ability to visit a locality often is key to collecting well in the
Pacific Northwest. Doug Emlong - one of my heroes - is probably the most
famous, a brilliant, gifted and admittedly tortured individual who amassed a
spectacular collection of fossils from the Oligocene and Miocene of Oregon and
beyond. Many new species, genera, and families have been named from his
collection at the Smithsonian, and several have been named after him including Enaliarctos
emlongi (a pinniped), Seuku emlongi (a desmostylian), Squaloziphius
emlongi (an enigmatic dolphin), and Mancalla emlongi (a large
flightless auk).
One of Ray Troll's famous maps - this one showing Washington and the Pacific coast; a much larger map is coming as part of Kirk Johnson & Ray Troll's sequal to "Cruisin the Fossil Highway", "Cruisin the Eternal Coastline".
The
well-sampled Oligo-Miocene Newport Embayment of Oregon and other regions such
as the Olympic Peninsula have yielded large collections of fossil marine
vertebrates that have answered all sorts of important questions regarding the
origin of pinnipeds, desmostylians, baleen whales, dolphins, and the diversity
of flightless penguin-like diving birds (Plotopteridae). Since I started this
blog in 2008 I haven't posted quite as much as I would have hoped, and I've
always wanted to write about some of the more recent advances in Cenozoic
marine vertebrate paleontology from this fascinating area. It would take
forever to chronicle the entire history of marine vertebrate paleontology from
the Pacific Northwest, so instead I'm going to cover the really new, exciting
research that's come out over the last ten years (e.g. the time in which I've
been doing research on similar subjects).
Sharks and Bony Fish
Teeth of
sharks and bones and teeth of bony fish are typically the most common fossils
in any marine vertebrate fossil assemblage. But, as explored in a previous post
- for unexplained reasons - shark teeth actually seem to be quite rare on the
west coast (with the obvious exception of places like Sharktooth Hill and the
Santa Margarita Sandstone in Santa Cruz). Nevertheless, systematic prospecting
by paleoichthyologist Bruce Welton during the 1970s resulted in large
collections of teeth and other elements from various localities on the west
coast, including Oligo-Miocene rocks in Oregon. Some of these were published in
the 1970s and 1980s, but now that Bruce has retired from the petroleum industry
he's gotten back into publishing and a flurry of papers has come out,
particularly on some of the smaller fossils. Three of these are on basking
sharks (Cetorhinidae). The modern basking shark, Cetorhinus maximus, is
the world's second largest fish (second only to the whale shark), approaching
the size of a minke whale (6-8 meters). Basking sharks are planktivores and as
a result have developed "microdonty" - tiny teeth, and extensive
mineralized gill rakers that function in filter feeding.
Teeth and gill rakers of Keasius taylori from the Eocene Keasey Formation of Oregon.
An
Oligo-Miocene species, Cetorhinus parvus, was named based off of gill
rakers from Europe - but wasn't known from teeth, and the use of the taxon was
contested. A new "skeleton" from the Eocene Keasey Formation of
Oregon includes 22 teeth, fragmentary vertebrae, and gill rakers - and named by
Welton (2013A) as the holotype specimen of Keasius taylori. The teeth
are small, but much more primitive in their morphology and resemble mini-sand
tiger shark teeth, and Welton hypothesized that the ancestral basking shark
would have resembled a sand tiger. This and other fossils of Keasius taylori
clarify the identification of previously reported mid-Cenozoic basking sharks,
many of which are now identified as Keasius rather than Cetorhinus,
and recombined the earlier described species as Keasius parvus.
Vertebrae and gill rakers of Cetorhinus sp. cf. C. maximus from the late Miocene Empire Formation of Oregon.
In contrast,
a newly reported fossil specimen from the much younger (upper Miocene) Empire
Formation of southern Oregon are very close to modern Cetorhinus maximus,
and identified by Welton (2013B) as Cetorhinus sp., cf. C. maximus.
This specimen includes gill rakers and calcified vertebrae; size of these
elements indicates a shark ~4.5-6 meters in length. A third study of fossil
basking sharks reports many isolated teeth of the new species Cetorhinus
piersoni from the lower Miocene Astoria Formation of Oregon and Washington and
lower part of the Round Mountain Silt in southern California. Teeth of
Cetorhinus piersoni are reminiscent of miniature thresher shark teeth and
highly variable in morphology, suggesting a combination of filter feeding and
fish eating. The name honors Guy Pierson, who collected the holotype (who also
collected the holotype of Pteronarctos piersoni).
Teeth of the Oligo-Miocene megamouth shark Megachasma applegatei from the Jewett Sand of California.
Yet another
paper on planktivorous sharks is coauthored by Bruce Welton (Shimada et al.,
2014 - written by partner in crime Doug Long and prolific colleague Kenshu
Shimada) and chronicles an archaic megamouth shark from the Oligo-Miocene of
Oregon and California. The new shark, Megachasma applegatei, is named
after the well-known LACM based paleoichthyologist Shelton Applegate, and is
named after a tooth from the lowermost Miocene Jewett Sand at Pyramid Hill
(Kern County, southern California) and many additional specimens are referred
from the Oligo-Miocene Skooner Gulch Formation of northern California and the
upper Oligocene Yaquina Formation and lower Miocene Nye Mudstone of Lincoln
County, Oregon. In other words, virtually every unit with marine vertebrate
remains of late Oligocene-early Miocene age on the west coast has produced
these distinctive teeth. They resemble modern megamouth shark (Megachasma
pelagios) teeth but have lateral cusplets like mini sand tiger teeth.
Interestingly, the earliest teeth of this taxon reported were figured and
described in the mid 1970s, with the earliest specimens recovered from Pyramid
Hill in the 1960s - long before the modern species Megachasma pelagios
was accidentally discovered by an individual being caught in the anchor of a
Navy ship off Hawaii. The megamouth shark was surprising as it was completely
unknown by science, and such a large shark - up to 5 meters in length. The
megamouth was discovered by scientists first from fossils, but unlike
coelacanths, only by a decade or so in advance, and only then informally as it
took until 2014 for Megachasma applegatei to be formally recognized by
science.
An associated dentition of Rhinoscymnus, from Welton and Goedert (2016).
A series of three related papers were published by Welton (2016 and Welton and Goedert (2016) on squaliform sharks from the Oligocene of Washington and Oregon. These include Orthechinorhinus davidae, a lantern shark from the Alsea Formation of Oregon, Rhinoscymnus viridiadamas, a sleeper shark from the Lincoln Creek Formation of Washington, Somniosus gonzalezi, another sleeper shark from the Pysht Formation of Washington, and Oligodalatias jordani, a kitefin shark from the Pittsburg Bluff Formation of Oregon. Squalomorph sharks typically hang out in deep marine environments, and there is a marked shallowing of vertebrate-bearing sediments from the Oligocene to the Pliocene along the Pacific coast, meaning that at least in some taxa there is a shift in the sorts of marine vertebrates encountered (particularly fish).
A partial rostrum of the billfish Aglyptorhynchus from the Oligocene Lincoln Creek Formation of Washington.
Bony fish
are also collected often from rocks in the Pacific Northwest. Bony fish are
notoriously difficult to study owing to the multitude of bones in their
skeleton (mammals are simple in comparison) and the rarity of complete
skeletons. Faunal studies can be done but require extensive knowledge of a wide
array of skeletal elements. Paleoichthyologist Harry Fierstine focused most of
his career on studying one group of fish - the billfish (swordfish, marlins,
sailfish) - from all over the world. In 2005, Fierstine reported specimens of Aglyptorhynchus
from the upper Oligocene portion of the Lincoln Creek Formation in Washington,
including a partial skull, rostrum and jaw of the new species Aglyptorhynchus
columbianus. A separate species, Aglyptorhynchus maxillaris,
was named earlier by Fierstine from the upper Oligocene Yaquina Formation
further south in Oregon. Another
recent study by Bruce Welton (2015) reports the entire fish fauna from the
Pleistocene Port Orford/Elk River Formation of southwestern Oregon; much of
this fauna consists of otoliths - fish ear bones.
Sea turtles
Sea turtles
are an uncommon find along the west coast, but are found on occasion. Sea
turtles do stray into cold temperate waters - the leatherback Dermochelys strays
as far north as the coast of Washington State - but the sheer majority of sea
turtle fossils in the eastern North Pacific are from southern California. In
2009 Brinkman reported a skull of an indeterminate sea turtle in the tribe
Carretini (loggerhead sea turtles). This well preserved skull - collected by
Doug Emlong of course - constitutes the oldest record of the loggerhead tribe
Carretini and the first record from the Pacific coast of North America.
A skull of an unidentified loggerhead (Carretini indet.) from the early Miocene Nye Mudstone of Oregon.
Marine Birds
Quite a bit of research has been published very recently on
fossil sea birds from the Pacific northwest. One of the
bird groups I've actually published on is also one of the rarest - the bony
toothed birds or pelagornithids. A few records of pelagornithids are already
known from the Pacific northwest, including Eocene
records (formerly identified by Goedert in the 1980s as Dasornis, but
now Pelagornithidae indet.), and several specimens of "Osteodontornis"
(now known as Pelagornis) are known from the Emlong collection from the
early Miocene of Oregon, but have never been described. A new study by Mayr et
al. (2013) reports a new, well-preserved postcranial skeleton of the giant bony
toothed bird Pelagornis collected by Jim Goedert from the latest
Oligocene-earliest Miocene Nye Mudstone near Newport, Oregon. This skeleton
includes many vertebrae, a synsacrum, and most of the hindlimb. The hindlimb
morphology indicates that other mid-Cenozoic suspected pelagornithids Tympanonesiotes
and Palaeochenoides with Pelagornis, and reiterate an earlier
conclusion that all Neogene pelagornithids belong within the genus Pelagornis.
A partial skeleton (hindlimb elements depicted here) of Pelagornis from the early Miocene Nye Mudstone of Oregon.
The type specimen of Makahala mirae from the Makah Formation of Washington.
A little gem of a bird skeleton collected by Jim Goedert was
recently prepared out of a concretion and named Makahala mirae (Mayr
2015). This little bird hails from the Eocene-Oligocene Makah Formation and
consists of a partial disarticulated skeleton including humerus, radius, ulna,
and other forelimb elements. This is one of only two records of a fossil
procellariiform (tubenoses: petrels, albatrosses, and shearwaters) bird from
the Paleogene of North America (many shearwaters and albatrosses are known from
Neogene rocks in California and
the east coast). Furthermore, it has some strange adaptations in the wing, and
may have used flapping more frequently than gliding (as is the case in diving
petrels) as opposed to the majority of procellariiformes which are efficient
gliders.
The Astoria Fm. albatross from Mayr and Goedert (2017).
In summer 2017, Gerald Mayr and Pacific Northwest "amateur" paleontologist Jim Goedert published some interesting albatross specimens from the Oligocene Lincoln Creek Formation and lower Miocene Astoria Formation of Washington state. The Lincoln Creek albatross was named Diomedavus knapptonensis, and represents a fairly plesiomorphic member of the Diomedeidae (the albatross family). The holotype includes a partial humerus, tarsometatarsus, and other elements. Additional fossils from the Astoria Formation include a spectacular partial skull (above) but critically lacks appendicular elements directly comparable with other fossil albatrosses, and is not yet named. These fossils indicate that early albatrosses inhabited the North Pacific during the Oligocene and early Miocene, living alongside the giant pelagornithids. Aspects of the postcranial skeleton suggest that these early forms may have been more adept at terrestrial locomotion than (notoriously clumsy) modern albatrosses and other tubenoses.
The type coracoid of Stemec suntokum from the Oligocene Sooke Formation, British Columbia.
An incomplete and unassuming specimen collected recently by
avid amateur paleontologist Stephen Suntok and his family from the late
Oligocene Sooke Formation of Vancouver Island was reported by Kaiser et al.
(2015). This specimen is an isolated coracoid of a flightless plotopterid
seabird, which was named Stemec suntokum (Kaiser et al., 2015). Most
birds have a flattened, wide coracoid but Stemec is unusual in being
very narrow and rod-like. Another recent discovery is that of many more
specimens of the plotopterid Tonsala hildegardae and the newly described
Tonsala buchanani (Dyke et al., 2011). These new specimens of Tonsala
from the Makah and Pysht Formations of the Olympic Peninsula indicate (collected
by Jim Goedert) that plotopterids likely experienced similar loads on the
hindlimb during terrestrial walking like penguins, but the wings did not,
suggesting that Tonsala "flew" underwater in a fashion more
similar to an auk or puffin than a penguin. Plotopterids have traditionally
been placed within the "Pelecaniformes", now known to be a
wastebasket grade, but nonetheless considered close to cormorants, boobies, and
gannets. A provocative hypothesis by Gerald Mayr suggested that plotopterids
may actually be most closely related to penguins, readily explaining away many
of their similarities. A new study by Mayr et al. (2015) reports well-preserved
plotopterid skulls (Tonsala hildegardae) collected by Jim Goedert from
around the early/late Oligocene boundary within the Pysht Formation of the
Olympic Peninsula in Washington. Cladistic analysis of bird relationships using
these new specimens seems to confirm the traditional interpretation of suloid
(gannet/booby) affinities, but also placed the penguins as the next group
outside the expanded Suloidea. The plot thickens! Future work on plotopterids
from the Oligo-Miocene of Japan is eagerly awaited. A number of excellent presentations at the 2016 and 2017 meetings of the Society of Vertebrate Paleontology indicate that some really exciting research is coming soon on these spectacular fossil birds.
The skull of Tonsala (left) in comparison with a booby (B), cormorant (C), and a penguin (D).
A beak and postcrania of Tonsala hildegardae, Pysht Formation, Washington.
Pinnipeds - seals, sea lions, and walruses
One of my favorite groups of marine vertebrates are the
pinnipeds – seals, sea lions, and walruses. The oldest pinnipeds are recorded
from the late Oligocene of the Pacific Northwest, and
includes a number of well-preserved specimens of the harbor seal sized archaic
enaliarctine seals – characterized by bear-like dentitions. Most modern
pinnipeds are sexually dimorphic (males and females of differing sizes), with
modern elephant seals, sea lions, and walruses constituting some of the most
sexually dimorphic of all mammals. A recent study by Cullen et al. (2014)
interpreted the available sample of the seal Enaliarctos emlongi (originally
reported from the lower Miocene Nye Mudstone by Annalisa Berta in 1991) as
reflecting sexual dimorphism. The holotype specimen is a male with a large
skull, proportionally large canines, and a sagittal crest – whereas the
putative female is smaller and has proportionally smaller canines. However,
these authors only made limited comparisons in order to substantiate their
identification and curiously made no comparisons with the diminutive species Enaliarctos
mitchelli, which is also known from the Nye Mudstone.
Sexual dimorphism in Enaliarctos and Arctocephalus.
The Bushell specimen of Callorhinus gilmorei from the Plio-Pleistocene Rio Dell Formation of Humboldt County, California.
Several other recent papers have focused on the fur seals
and sea lions – the Otariidae. The first of these is a paper I published in JVP
in 2011 and reports fossils of the northern fur seal lineage – Callorhinus.
These fossils were collected from the Plio-Pleistocene Rio Dell Formation from
Scotia Bluffs in Humboldt County California. The older (late Pliocene) specimen
consists of a beautiful pair of mandibles in a large siltstone concretion
identifiable to the Pliocene species Callorhinus gilmorei, also known
from coeval rocks in southern California and Japan. This and other specimens of
Callorhinus gilmorei have incipient fusion of the primitively double
rooted teeth of earlier pinnipeds, whereas extant fur seals all have single
rooted postcanine teeth. Further up near the top of the Rio Dell Formation
(early Pleistocene) is a second specimen of an unnamed species reported
preliminarily as Callorhinus sp. with mostly single rooted teeth except
for a well developed double root on the lower molar – intermediate between C.
gilmorei and the modern northern fur seal Callorhinus ursinus. This
fossil record suggests that the Callorhinus lineage represents a
circum-north Pacific population that has not budded into different species
since the Pliocene – an evolutionary pattern known as anagenesis.
The skull of the Pleistocene sea lion Proterozetes ulysses, Port Orford Formation, Oregon.
One of the oldest fossil records of a true sea lion
(Otariinae) in North America is Proterozetes ulysses, represented by a
skull, mandible, and postcrania collected from the Port Orford Fm. in
southwestern Oregon by none other than Doug Emlong in the 1970s and formally
named by Barnes et al. (2006). Prior to being named, this sea lion was
originally reported as an unnamed species of Eumetopias - the same genus
as the modern northern sea lion. While I still agree with that generic
allocation, Proterozetes curiously appears to be morphologically
intermediate between the California sea lion (Zalophus) and Eumetopias
in being relatively large with a short rostrum but possessing a large Zalophus-like
sagittal crest. Barnes et al. (2006) originally reported the age as Pliocene
based upon work from the 1940's - much more recent biostratigraphic studies and
amino acid racemization put the locality as middle Pleistocene, approximately
700 Ka. As expected, no sea lions have been found in the intensely sampled San
Diego Formation, suggesting a true absence of sea lions in the region until the
Pleistocene.
In 2009, Ashley Poust, Lee Hall, and myself - all students at Montana State University - took an epic road trip for spring break, driving to my hometown in California by way of the Oregon coast from Bozeman, Montana. We drove in shifts, leaving at 3am and arriving on the shore of the Pacific just in time for sunset - making it in about 16 hours (which was also a new record for me). I have done the drive solo in one shot before, but being able to pass out in the back next to the cooler and Ash's guitar was a substantial improvement. After cooking hot dogs over an open flame and a good night of rest in the foggy Oregon rainforest, we set out along the beach in search of Emlong's Proterozetes locality - this was my third or fourth visit. After a few hours turned up nothing, I was returning north to meet up with Ash and Lee. Ash indicated he had two things to show to me. The first was a dissappointing lump, which we quickly redeposited on the beach. He nonchalantly pulled out of his windbreaker pocket a second fossil and said "I'm not sure this is anything" - and he placed in my hand a nearly complete sea lion mandible embedded in a concretion! He laughed, knowing full well my reaction would consist of a number of surprising expletives. The specimen was my first successful acid preparation experiment, becoming completely clean after only about 2-3 weeks in 5% acetic. A few years later we decided to write a paper on it, noting that the original paper by Barnes et al. (2006) had never really described the referred mandible collected by Emlong. We worked slowly on the paper after we went our separate ways to Ph.D. programs at UC Berkeley and New Zealand, and it was just finally published earlier this year. The paper describes the new mandible, provides a much-needed description of the larger referred mandible collected by emlong, and proposes a couple of new autapomorphies for the genus Proterozetes.
One of the strangest marine mammals from the Pacific Northwest is the "oyster bear", Kolponomos - originally described in the 1960s by UCMP paleontologist RA Stirton, who initially interpeted it as a giant marine racoon. Subsequent discoveries by Doug Emlong and others revealed complete skulls with mandibles, and a second species - all from the lowermost Miocene of Oregon (Nye Mudstone) and Washington (Clallam Formation). Kolponomos has a skull approximately the size of a black bear, with enlarged sea-otter like teeth and a fused mandibular symphysis; muscle attachments on the back of the skull indicate it had powerful neck muscles. A new paper by carnivore specialist Jack Tseng (et al., 2017) - well-known for his work on hyenas - utilized finite element modeling to study how this carnivore crushed molluscan prey. Unlike sea otters which have tiny, dextrous paws well-adapted for grasping and using tools, Kolponomos apparently had to use its canines and neck muscles to pry mollusks off of hard substrates. Further unlike sea otters, Kolponomos has an unfused mandibular symphysis. Surprisingly, Kolponomos is similar in biomechanical terms to the jaw-closing system in sabertooth cats like Smilodon.
Ashley Poust 's Proterozetes mandible (left) and Ash desperately trying to maintain footing on gooey Pleistocene marine outcrops.
In 2009, Ashley Poust, Lee Hall, and myself - all students at Montana State University - took an epic road trip for spring break, driving to my hometown in California by way of the Oregon coast from Bozeman, Montana. We drove in shifts, leaving at 3am and arriving on the shore of the Pacific just in time for sunset - making it in about 16 hours (which was also a new record for me). I have done the drive solo in one shot before, but being able to pass out in the back next to the cooler and Ash's guitar was a substantial improvement. After cooking hot dogs over an open flame and a good night of rest in the foggy Oregon rainforest, we set out along the beach in search of Emlong's Proterozetes locality - this was my third or fourth visit. After a few hours turned up nothing, I was returning north to meet up with Ash and Lee. Ash indicated he had two things to show to me. The first was a dissappointing lump, which we quickly redeposited on the beach. He nonchalantly pulled out of his windbreaker pocket a second fossil and said "I'm not sure this is anything" - and he placed in my hand a nearly complete sea lion mandible embedded in a concretion! He laughed, knowing full well my reaction would consist of a number of surprising expletives. The specimen was my first successful acid preparation experiment, becoming completely clean after only about 2-3 weeks in 5% acetic. A few years later we decided to write a paper on it, noting that the original paper by Barnes et al. (2006) had never really described the referred mandible collected by Emlong. We worked slowly on the paper after we went our separate ways to Ph.D. programs at UC Berkeley and New Zealand, and it was just finally published earlier this year. The paper describes the new mandible, provides a much-needed description of the larger referred mandible collected by emlong, and proposes a couple of new autapomorphies for the genus Proterozetes.
Prey acquisition and mastication in the "oyster bear" Kolponomos.
One of the strangest marine mammals from the Pacific Northwest is the "oyster bear", Kolponomos - originally described in the 1960s by UCMP paleontologist RA Stirton, who initially interpeted it as a giant marine racoon. Subsequent discoveries by Doug Emlong and others revealed complete skulls with mandibles, and a second species - all from the lowermost Miocene of Oregon (Nye Mudstone) and Washington (Clallam Formation). Kolponomos has a skull approximately the size of a black bear, with enlarged sea-otter like teeth and a fused mandibular symphysis; muscle attachments on the back of the skull indicate it had powerful neck muscles. A new paper by carnivore specialist Jack Tseng (et al., 2017) - well-known for his work on hyenas - utilized finite element modeling to study how this carnivore crushed molluscan prey. Unlike sea otters which have tiny, dextrous paws well-adapted for grasping and using tools, Kolponomos apparently had to use its canines and neck muscles to pry mollusks off of hard substrates. Further unlike sea otters, Kolponomos has an unfused mandibular symphysis. Surprisingly, Kolponomos is similar in biomechanical terms to the jaw-closing system in sabertooth cats like Smilodon.
Cetaceans - baleen whales and toothed whales
Until 2016, not that much had actually been written about fossil toothed
whales from this region, and only a single scrappy specimen was published
- a chunk of an odontocete mandible reported by Barnes et al. (2010) from the
lower Miocene Nye Mudstone near Newport, Oregon. The fragment consists of the
posterior part of a fused mandibular symphysis with a homodont dentition (based
on the alveoli), and is rather narrow - leading Barnes et al. (2010) to
identify it as a platanistine - a "true" relative of the Ganges river
dolphin (Platanista). Few other examples of platanistine fossils exist,
and only time will tell if less scrappy evidence of such an early origin for
the subfamily is founded.
A purported mandibular fragment of a platanistine dolphin from the early
Miocene Nye Mudstone of Oregon.
The holotype skull of the allodelphinid dolphin Goedertius oregonensis.
However, 2016 saw the publication of a monograph by Toshiyuki Kimura and Larry Barnes on the Allodelphinidae - an enigmatic group of long snouted dolphins in the equally enigmatic clade Platanistoidea. The only extant platanistoid is the Ganges/Indus river dolphin, Platanista gangetica; it is quite weird, and has large bony facial crests that wrap around the melon and house a series of air-filled sinuses. Formerly allodelphinids included only Allodelphis pratti, but this new paper refers the longirostrine dolphin Zarhinocetus errabundus (from Sharktooth Hill, California) to the family and names several new allodelphinids. Chief among these is Goedertius oregonensis - yet another taxon named after Gail and Jim Goedert. This new dolphin was discovered and excavated by the Goederts from the Nye Mudstone in Oregon (earliest Miocene) and it is a rather small, longirostrine dolphin; the earbones remain in place. The Goedertius holotype represents one of the most spectacularly preserved fossil odontocetes from the North Pacific. Another allodelphinid is named in the genus Zarhinocetus - Zarhinocetus donnamatsonae, from the lower Miocene Astoria Formation of Washington state.
Holotype skull and life restoration of the bizarre platanistid dolphin Dilophodelphis fordycei (artwork by Alex Boersma).
In 2017, student Alex Boersma and colleagues published a new dolphin from the Emlong collection and named it Dilophodelphis fordycei - the specific name after my Ph.D. adviser, Ewan Fordyce (who is fittingly fascinated with the platanistoids) and the genus name after the two large maxillary crests, and a bit of an homage to the dinosaur Dilophosaurus. Dilophodelphis hails from the Astoria Formation near Newport, Oregon, and is early Miocene in age. The cranial crests are large and bulbous and not pneumatized, unlike modern Platanista. This study clarifies some issues in the sequence of cranial evolutionary weirdness within Platanistidae.
Palatal vascularization and teeth in modern Balaenoptera and Aetiocetus weltoni (top) and a skeletal reconstruction of Aetiocetus (copyright R.W. Boessenecker 2015).
The Pacific northwest is well known
amongst marine mammal paleontologists for a plethora of early baleen whales,
first discovered by Doug Emlong in the 1960s. A later discovered fossil, named
in 1995 as Aetiocetus weltoni, is a toothed baleen whale from the early
late Oligocene Yaquina Formation near Newport Oregon. Aetiocetus weltoni had
a flattened but apparently akinetic palate and rostrum, and was likely about
the size of a large bottlenose dolphin. It was originally given a
"telegraphic" description with a much longer treatment reserved for
later, but was never undertaken. Originally thought to be a mysticete lacking
baleen, Deméré et al. (2008) reported the presence of vascular foramina and
grooves in the palate of the type specimen and made the daring hypothesis that
aetiocetids - or, at least some of them - possessed teeth and baleen. This was
followed up by a much more in depth study of the skull, mandible, dentition,
and earbones; the postcranial skeleton unfortunately has not been prepared, and
whereas it is supposed to be at UCMP, its current whereabouts are unknown. Very
recently, another aetiocetid has been described, collected by Jim Goedert from
the early Oligocene Makah Formation of the Olympic Peninsula in Washington.
This new aetiocetid, a small bodied (porpoise sized) species named Fucaia
buelli, is known from much of a postcranial skeleton and a well preserved
braincase with beautiful earbones and several teeth. No palate is known, and
thus the presence or absence of baleen is unknown. Fucaia buelli
gets its name from the Strait of Juan de Fuca, and prolific (but unfortunately
retired) paleoartist Carl Buell. Whereas Aetiocetus weltoni has a near homodont
dentition (all teeth look similar), Fucaia buelli still has archaeocete
like multicuspate cheek teeth, attesting to some dental diversity within the
Aetiocetidae. This study also reclassified Chonecetus goedertorum
as Fucaia goedertorum (a taxonomic decision that caused a bit of
confusion during my last museum visit with C.H. Tsai, as we habitually referred
to the more complete species Chonecetus goedertorum simply as Chonecetus
during our Ph.D. program).
Life restoration of Fucaia buelli (left, by Jaime Bran) and R.E. Fordyce
with the type skeleton (right) from the Makah Formation of Washington.
Alfred the aetiocetid whale, with teeth showing signs of toothwear and possible enlarged gums.
Yet another new study on aetiocetids was published in 2016, this time a preliminary investigation of feeding behavior and feeding ecology in an undescribed aetiocetid - some sort of critter intermediate in size and morphology between Fucaia and Aetiocetus. Marx et al. (2016) found that this specimen, a skull from the Oligocene Pysht Formation of Washington, has a number of teeth with abrasive toothwear restricted to the tips of the teeth - suggesting that the base of the teeth were embedded in gums. They further interpreted this as evidence that the whale was a suction feeder, and cast doubt on the hypothesis that aetiocetids possessed baleen - increased blood supply to the palate was instead related to thickened gums. It's an interesting study, but it's important to note that there's a big gap in logic between tooth wear and suction feeding - and further important to note that aetiocetids possess no skeletal adaptations for suction feeding. All cetaceans primitively possess the ability to do so, but only some actually exhibit positive evidence for doing so (e.g. shortened rostra, tooth reduction) - neither of which really characterize aetiocetids.
Holotype skull of the possible eomysticetid Sitsqwayk cornishorum from the Oligocene Pysht Formation of Washington.
Not all mysticetes from the Oligocene of the Pacific Northwest are toothed aetiocetids. Ph.D. student Carlos Peredo and his adviser Mark Uhen (2016) named an eomysticetid-like mysticete, Sitsqwayk cornishorum, from the Oligocene Pysht Formation of Washington. The holotype specimen includes a partial skull and the anterior 2/3 of the postcranial skeleton. The skull shares a number of features with eomysticetids I had described during my Ph.D. from the Oligocene of New Zealand: limited telescoping, a long intertemporal region, and several features of the squamosal. I suspect better earbones are needed to tell, as cladistic analysis places this taxon one node down the tree - and a large number of cranial characters remain unknown.
Surprising range extension of the archaic whale Herpetocetus, as demonstrated by a skull from the Plio-Pleistocene Falor Formation of northern California.
Much more recent baleen whales from the Plio-Pleistocene
have also been reported recently. The dwarf baleen whale Herpetocetus
has a surprising record from the early-middle Pleistocene Falor Formation of
Humboldt County, CA, based upon a partial braincase collected by Ron Bushell
and described by yours truly (Boessenecker, 2013). This find extends the
geochronologic range of the dwarf mysticete Herpetocetus from the late Miocene
and early Pliocene into the Pleistocene, indicating significant temporal
overlap with modern species of baleen whales - indicating that Herpetocetus
*almost* made it into the modern fauna. Another specimen (also collected by Ron
Bushell) from the same age but from the Rio Dell Formation further south in
Humboldt County consists of a well preserved tympanic bulla and posterior
process. I invited my labmate Cheng-Hsiu Tsai (a mysticete fanatic) to study
the specimen, and together we published it last year in Journal of
Paleontology. This specimen is identifiable as an anatomically modern gray
whale, Eschrichtius sp., cf. E. robustus, and dates to the
earliest Pleistocene. Somewhat more archaic gray whales (Eschrichtius sp.)
are known from the late Pliocene of Japan. Because Eschrichtius is
currently unknown from well sampled Pliocene assemblages, we interpreted the
fossil record of Eschrichtius to indicate that it evolved or was present
in the western North Pacific in the Pliocene prior to dispersing eastward to
the California margin during the Pleistocene.
Comparison of Pleistocene Eschrichtius sp., cf. E. robustus from the Rio Dell Formation of California with modern E. robustus.
Comparison of Pleistocene fin whale (left, Rio Dell Formation) and modern fin whale (Balaenoptera physalus).
Comparison of Pleistocene fin whale (left, Rio Dell Formation) and modern fin whale (Balaenoptera physalus).
Another Pleistocene earbone of a baleen whale was discovered shortly after our paper was published on the Pleistocene gray whale bulla from the Rio Dell Formation. The new specimen consisted of a much larger bulla, from a different locality out on the coast that had received substantially more research attention in terms of stratigraphy, geochronology, and depositional history. The specimen was collected by my good friend Chris Pirrone, an attorney in the San Francisco area; he agreed to donate the specimen for study. I continued preparation, using a combination of acid and mechanical preparation, and invited CH Tsai to study the specimen - and in 2017 the paper was published. morphologically, the specimen is identical to modern Balaenoptera physalus - the fin whale, the second largest animal to have ever lived, next to the blue whale - albeit slightly smaller in total size. Molecular clock calibration suggests the modern species blue and fin whales diverged in the late Miocene or Pliocene - though we have no fossils indicating such a claim is reasonable. The fact that these two species are capable of interbreeding and have not really been collected from well-sampled Pliocene deposits suggests that their divergence has been overestimated. This information underscores the importance of sampling Pleistocene marine mammal fossils.
Well preserved skull of the early desmostylian Cornwallius sookensis from the Oligocene Yaquina Formation of Oregon.
Desmostylians - extinct hippo-like sea cow relatives
Some of the most spectacularly bizarre marine mammals of all
time are the desmostylians, nicknamed by some as "sea hippos".
Desmostylians are related to sea cows (Sirenia) and elephants (Proboscidea),
are hippo-like in build and found exclusively in marine sediments along the
margins of the North Pacific (Japan, Sakhalin, Kamtchatka, Alaska, British
Columbia, Washington, Oregon, California, Baja California). They have strange
teeth composed of cylindrical cusps with some approaching a package of sushi
rolls or a six pack of beer cans. Desmostylians come in two flavors:
broad-snouted hippo-like mouths and narrow, elongate snouts; both types have
short upper and lower tusks. Several recent papers have greatly improved our
knowledge of the oldest known desmostylians from North America.
The first reports additional unpublished material collected from the type
locality of Cornwallius (Beatty, 2006), consisting of a pair of femora
rediscovered in Smithsonian collections. The second study (Beatty, 2009) reported
new skulls and mandibles of the poorly known desmostylian Cornwallius
sookensis, previously known only from isolated teeth from the late
Oligocene Sooke Formation of Vancouver Island. This new material (collected by
Doug Emlong, of course) reported revealed that Cornwallius had an
unusally elongate, narrow snout. The most primitive known desmostylian, Behemotops,
was originally based upon two species: Behemotops emlongi (characterized
by wide mandible and enormous tusk) and Behemotops proteus (characterized
by narrow mandible). Each was erected based on a single specimen, and in 1994,
a third specimen that was morphologically intermediate led the original authors
to synonymize both into Behemotops proteus. New material of Behemotops
proteus from the late Oligocene Sooke Formation reported by Beatty and Cockburn
(2015) includes most of a skull and quite a bit of the postcranial skeleton.
The snout is very elongate and narrow, similar to Cornwallius. This
discovery highlights the disparate anatomy of the broad-mouthed Behemotops
emlongi, which is apparently different enough to warrant placement in a
separate genus as Seuku emlongi - its relationships remain unclear.
The bizarre skull of the primitive desmostylian Behemotops proteus from the Oligocene Sooke Formation of British Columbia.
Barnacle covered sea lion bones (Proterozetes) from the Pleistocene Port Orford Formation of Oregon.
Taphonomy - fossil preservation
Occasionally bones with interesting preservational features
are discovered. One such discovery was made by yours truly while hiking along a
desolate foggy coastline in southwestern Oregon back in 2008 when I spotted a
couple of bones poking out of a low cliff; I didn't have any of my normal
supplies as I was on a road trip at the time, but quickly carved the two bones
out of the cliff and wrapped them in newspaper. A returned to my car soaking
wet, and continued my drive south. When I got home to sunny San
Francisco, I put the two bone-bearing lumps of
sediment onto my driveway and started to douse them with a water hose; after a
few minutes I noticed that barnaces were poking out. I looked closer, and they
were attached to the bone! A few months later at MSU I had cleaned off the
remaining stubborn matrix - I had two associated thoracic vertebrae of a sea
lion (middle Pleistocene) completely encrusted with barnacles. The extent of
the barnacles indicated that the bones must have rolled around a bit. Previous
reports of barnacle encrusted bones had been mentioned with the significance of
a footnote and never figured - but a significant amount of data could be
gleaned where nobody bothered to look before. (note: this is the same locality as Proterozetes above, and these discoveries were made a couple years before Ashley Poust's mandible was found).
Aetiocetid teeth from the Oligocene Pysht Formation of Washington with Osedax boreholes.
A more exciting series of finds were the first reports of
damage caused by bone-eating worms - boreholes and cavities excavated by the
annelid worm Osedax within bones of Oligocene cetaceans (Kiel et al.,
2010). These had been widely reported since 2005 in whale falls, and predicted
to be present in fossils but so far never reported. Micro-CT scans permitted 3D
models of the borings to be produced. Later on, similar borings were also
reported from bird bones (Kiel et al., 2011) and then from fish bones and
aetiocetid teeth (Kiel et al., 2013). These discoveries indicate that processes
which biologists have found affecting modern cetacean skeletons on the seafloor
have had a serious (yet unquantified) effect on the marine vertebrate fossil record.
Notably, these sorts of bone modifications are not yet reported for younger
Neogene marine vertebrates from the west coast and appear to be restricted to
the Paleogene.
Prospectus
After a lag in research output in the late 1990s and early
2000s, it seems that serious scientific attention is again being redirected at
these important fossil collections and localities from the Pacific
northwest. The sheer majority of these fossils have been collected
by a few unnaturally talented individuals, and while a large number of unprepared specimens at various institutions in the US (Burke Museum, Washington; Smithsonian NHM, Washington DC; Los Angeles County Museum, California) await preparation, new efforts are needed to explore critical yet under-studied localities such as the Empire and Port Orford Formations of Oregon and the Eel River Basin of California. Many new projects have been started and research effort in the Pacific Northwest is likely at an all time high - research is actively being undertaken upon fossil sharks and fish (E. Popov, B. Welton), birds (G. Mayr), sea turtles (K. Awalt, P. Holroyd, J.F. Parham), sea otters (R. Boessenecker), pinnipeds (R.W. Boessenecker, M. Churchill, A. Poust), cetaceans (R. Boessenecker, E. Fitzgerald, E. Fordyce, F. Marx, M. Nelson, T. Park, N. Pyenson, C. Peredo, C.H. Tsai, M. Uhen, J. Velez), and sirenians (R. Boessenecker, J. Velez). The future is bright!
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Welton, B.J. 2016b. First report of Orthechinorhinus (Squaliformes: Etmopteridae) from the Pacific basin; a new species from early Oligocene rocks of Oregon, USA. New Mexico Museum of Natural History and Science Bulletin 74:303-308.
Welton, B.J. 2016a. A new dalatiid shark (Squaliformes: Dalatiidae) from the early Oligocene of Oregon and California, USA. New Mexico Museum of Natural History and Science Bulletin 74:289-302.
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Amazing collection of knowledge , hank you for putting it together!!
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