The first paper is a collaboration with Rachel Racicot,
Brian Beatty, and Tom Deméré and finally describes the extinct odontocete
informally known as the “skimmer” or “half-beaked” porpoise. The new fossil
phocoenid is named Semirostrum ceruttii, the genus name referring to the
dramatically shorter rostrum, and is also an homage to the half-beak fish, Hemiramphus.
The species name is in honor of Richard Cerutti, longtime field paleontologist
and preparatory for the San Diego Natural
History Museum.
Mr. Cerutti collected the holotype in the early 90’s from the Pliocene San
Diego Formation – I met him during a 2012 visit to the SDNHM.
The holotype skull, earbone, and mandible of Semirostrum ceruttii, and a composite skeletal reconstruction from three specimens. From Racicot et al. (2014); skeletal reconstruction by yours truly.
The new fossil porpoise has a somewhat longer rostrum than
modern phocoenids, and is slightly more delphinid-like than modern porpoises as
well. Most obviously, Semirostrum has a bizarre lower jaw with an
elongate, fused mandibular symphysis that is developed into a laterally
flattened and expanded, paddle-shaped process that juts far beynd the edge of
the rostrum. The teeth in the mandible do not extend past the rostrum, so the
majority of the symphysis is edentulous. The preserved teeth have labial wear
facets, which we interpret as being the result of substrate abrasion – the
observed patterns of tooth wear differ from extant phocoenids in lacking apical
wear facets. When articulated, the wear facets do not match up with occluding
upper teeth – indicating that regular tooth wear does not account for the
observed pattern. We hypothesize that the elongate mandibular symphysis is a
benthic probe, and that Semirostrum pushed its “chin” through the
substrate, with sediment streaming along the lateral sides of the toothrow –
snatching up any burrowing prey that came into contact with the “chin” or
rostrum. In my life restoration, I illustrated Semirostrum as using it’s
mandibular symphysis like a benthic plough, ploughing through the uppermost
layer of the sediment in its search for burrowing invertebrates. The type
specimen consists of a complete skull and mandible with periotic, tympanic
bulla, and postcrania – an absolutely gorgeous set of fossils which I first had
the opportunity to examine on my first visit to the SDNHM back in 2007.
Life restoration of Semirostrum ceruttii, from Racicot et al. (2014) - by yours truly.
My contribution to the paper was describing fossil material
of Semirostrum from the Purisima Formation. Although the holotype
specimen of Semirostrum ceruttii is from the San Diego Formation,
multiple specimens of Semirostrum have been collected from
contemporaneous sections of the Purisima Formation. In fact, one of the
earliest known specimens of Semirostrum – collected in the mid 1980s by
local collector Wayne Thompson – consists of a pair of fused mandibles. The
specimen still unpublished and is now at LACM, but I was not able to see it on
my last museum visit in November 2013. Material from the Purisima Formation
includes a nearly complete skull and isolated mandible, a partial rostrum, and
a couple of isolated periotics. None of the material is associated – it’s all
scattered material preserved in bonebeds and other inner shelf sediments,
presumably scattered across the seafloor by currents or from drifting
carcasses. Nevertheless, every referred element exhibits morphological features
unique to Semirostrum. Some specimens – including the periotics and the
mandible – are morphologically indistinguishable from and identical in age to Semirostrum
ceruttii. However, the skull and partial rostrum are somewhat older, from
about the Mio-Pliocene boundary; furthermore, the skull exhibits a slightly
asymmetrical facial region – which is a bit more primitive than extant
phocoenids, and Semirostrum ceruttii. For these reasons, we interpreted
this slightly older material as representing an as yet unnamed, slightly older
species, and chose to simply identify it as Semirostrum sp.
Examples of different preservational features on shark teeth (A), odontocete vertebrae (B), auk (Alcidae) humeri (C), and odontocete periotics (D) - specifically, the top periotic is Parapontoporia wilsoni, and the bottom periotic is a referred periotic of Semirostrum ceruttii figured by Racicot et al. (2014:figure 2).
Histograms of taphonomic characteristics of bones, teeth, and cartilage from different lithofacies of the Purisima Formation. In general, highest energy conditions are on left, lowest energy on right.
I’ll discuss the highlights later on in a dedicated series
of posts, but these are takeaway points:
1) vertebrate material is most abundantly concentrated along
time-rich hiatal or erosional surfaces – namely, bonebeds and shell beds.
2) taphonomic damage – abrasion, phosphatization,
fragmentation, polish – are all positively correlated with both high-energy,
shallower water deposits, and time-rich surfaces.
3) this indicates a systematic relationship between
sedimentary architecture and marine vertebrate preservation, and that the sheer
majority of the marine vertebrate fossil record is controlled by physical
sedimentary processes, rather than biotically controlled. From a
paleoecological perspective, there is not much hope that using any sort of
specimen counting methods (e.g. relative abundance) for faunal analysis will be
able to backstrip the rather severe taphonomic overprint.