&lt;i&gt;Koristocetus pescei&lt;/i&gt; gen. et sp. nov., a diminutive sperm whale (Cetacea: Odontoceti: Kogiidae) from the late Miocene of Peru

Abstract. Among odontocetes, members of the family Kogiidae (pygmy and dwarf sperm whales) are known as small-sized and in many respects enigmatic relatives of the great sperm whale Physeter macrocephalus. Most of the still scanty fossil record of Kogiidae is represented by isolated skulls and ear bones from Neogene deposits of the Northern Hemisphere, with the significant exception of Scaphokogia, a highly autapomorphic genus from late Miocene deposits of the Pisco Formation exposed along the southern coast of Peru. Here we report on a new fossil kogiid from Aguada de Lomas, a site where the late Miocene beds of the Pisco Formation are exposed. This specimen consists of an almost complete cranium representing a new taxon of Kogiidae: Koristocetus pescei gen. et sp. nov. Koristocetus mainly differs from extant Kogia spp. by displaying a larger temporal fossa and well-individualized dental alveoli on the upper jaws. Coupled with a relatively elongated rostrum, these characters suggest that Koristocetus retained some degree of raptorial feeding abilities, contrasting with the strong suction feeding specialization seen in Recent kogiids. Our phylogenetic analysis recognizes Koristocetus as the earliest branching member of the subfamily Kogiinae. Interestingly, Koristocetus shared the southern coast of present-day Peru with members of the genus Scaphokogia, whose unique convex rostrum and unusual neurocranial morphology seemingly indicate a peculiar foraging specialization that has still to be understood. In conclusion, Koristocetus evokes a long history of high diversity, morphological disparity, and sympatric habits in fossil kogiids, thus suggesting that our comprehension of the evolutionary history of pygmy and dwarf sperm whales is still far from being exhaustive.

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A new physeteroid from the late Miocene of Peru expands the diversity of extinct dwarf and pygmy sperm whales (Cetacea: Odontoceti: Kogiidae)

Comptes Rendus Palevol ◽

10.5852/cr-palevol2020v19a5 ◽

2020 ◽

Author(s):

Alberto COLLARETA ◽

Olivier LAMBERT ◽

Christian de MUIZON ◽

Aldo Marcelo BENITES PALOMINO ◽

Mario URBINA ◽

...

Keyword(s):

Late Miocene ◽

Early Stage ◽

Dorsal Surface ◽

Sperm Whale ◽

Sister Group ◽

New Taxon ◽

Sperm Whales ◽

Southeastern Pacific ◽

Pisco Formation ◽

Late Neogene

Nowadays, the odontocete family Kogiidae is monotypic and only includes two species of diminutive relatives of the great sperm whale Physeter Linnaeus, 1758. Conversely, a growing body of extinct species indicates that kogiids were diverse and disparate during the late Neogene. The fossil record of Kogiidae is, to date, represented by several cranial specimens from Mio-Pliocene localities of the Northern Hemisphere, with the significant Southern Hemisphere exception of the Pisco Formation of Peru, from which two genera were known so far, including Scaphokogia Muizon, 1988, a highly idiosyncratic form characterised by a distinctly spoon-shaped dorsal surface of the neurocranium and a downturned semicylindrical rostrum, which is even placed in its own subfamily Scaphokogiinae. Here, we report on two skulls of Kogiidae from the Messinian (upper Miocene) portion of the Pisco Formation exposed in the East Pisco Basin. These two skulls are referred to the new taxon Platyscaphokogia landinii n. gen., n. sp., which our phylogenetic analysis recovers as sister group of Scaphokogia, within the subfamily Scaphokogiinae. Although Platyscaphokogia n. gen. shares with Scaphokogia a remarkably spoon-like dorsal aspect of the neurocranium, it retains a non-pachyostotic, dorsoventrally thin rostrum that distinctly points anteriorly; as such, Platyscaphokogia n. gen. might be regarded as testifying an early stage in the evolution of the scaphokogiine cranial anatomy. Morphofunctional and palaeoecological considerations allow for hypothesising that Platyscaphokogia n. gen. was a raptorial physeteroid that foraged along the water column in relatively open-sea palaeoenvironments. In conclusion, our finds expand the palaeodiversity of Kogiidae, as well as our knowledge on the late Miocene sperm whales of the southeastern Pacific, and further suggest that the fossil content of the East Pisco Basin is crucial for reconstructing the Neogene evolutionary history of physeteroids.

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New sperm whale remains from the late Miocene of the North Sea and a revised family attribution for the small crown physeteroid Thalassocetus Abel, 1905

Comptes Rendus Palevol ◽

10.5852/cr-palevol2021v20a39 ◽

2021 ◽

Author(s):

Apolline ALFSEN ◽

Mark BOSSELAERS ◽

Olivier LAMBERT

Keyword(s):

North Sea ◽

Late Miocene ◽

Sperm Whale ◽

Close Relative ◽

Sperm Whales ◽

The North ◽

The Family ◽

The North Sea ◽

Early Radiation ◽

The One

In spite of a continuously expanding physeteroid fossil record, our understanding of the origin and early radiation of the two modern sperm whale families Kogiidae Gill, 1871 (including the pygmy and dwarf sperm whales, Kogia spp.) and Physeteridae Gray, 1821 (including the great sperm whale, Physeter Linnaeus, 1758) remains limited, especially due to the poorly resolved phylogenetic relationships of a number of extinct species. Among those, based on fragmentary cranial material from the late early to middle Miocene of Antwerp (Belgium, North Sea basin), the small-sized Thalassocetus antwerpiensis Abel, 1905 has been recognized for some time as the earliest branching kogiid. The discovery of a new diminutive physeteroid cranium from the late Miocene (Tortonian) of Antwerp leads to the description and comparison of a close relative of T. antwerpiensis. Thanks to the relatively young ontogenetic stage of this new specimen, the highly modified plate-like bones making the floor of its supracranial basin could be individually removed, a fact that greatly helped deciphering their identity and geometry. Close morphological similarities with T. antwerpiensis allow for the reassessment of several facial structures in the latter; the most important reinterpretation is the one of a crest-like structure, previously identified as a sagittal facial crest, typical for kogiids, and here revised as the left posterolateral wall of the supracranial basin, comprised of the left nasal (lost in kogiids for which the postnarial region is known) and the left maxilla. Implemented in a phylogenetic analysis, the new anatomical interpretations result in the new Belgian specimen and T. antwerpiensis being recovered as sister-groups in the family Physeteridae. Consequently, the geologically oldest kogiids are now dated from the Tortonian, further extending the ghost lineage separating these early late Miocene kogiid records from the estimated latest Oligocene to earliest Miocene divergence of kogiids and physeterids.

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Architecture of the sperm whale forehead facilitates ramming combat

PeerJ ◽

10.7717/peerj.1895 ◽

2016 ◽

Vol 4 ◽

pp. e1895 ◽

Cited By ~ 4

Author(s):

Olga Panagiotopoulou ◽

Panagiotis Spyridis ◽

Hyab Mehari Abraha ◽

David R. Carrier ◽

Todd C. Pataky

Keyword(s):

Connective Tissue ◽

Structural Engineering ◽

Sperm Whale ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Moby Dick ◽

Unique Structure ◽

Complex Structural ◽

Von Mises ◽

Von Mises Stresses

Herman Melville’s novelMoby Dickwas inspired by historical instances in which large sperm whales (Physeter macrocephalus L.) sank 19th century whaling ships by ramming them with their foreheads. The immense forehead of sperm whales is possibly the largest, and one of the strangest, anatomical structures in the animal kingdom. It contains two large oil-filled compartments, known as the “spermaceti organ” and “junk,” that constitute up to one-quarter of body mass and extend one-third of the total length of the whale. Recognized as playing an important role in echolocation, previous studies have also attributed the complex structural configuration of the spermaceti organ and junk to acoustic sexual selection, acoustic prey debilitation, buoyancy control, and aggressive ramming. Of these additional suggested functions, ramming remains the most controversial, and the potential mechanical roles of the structural components of the spermaceti organ and junk in ramming remain untested. Here we explore the aggressive ramming hypothesis using a novel combination of structural engineering principles and probabilistic simulation to determine if the unique structure of the junk significantly reduces stress in the skull during quasi-static impact. Our analyses indicate that the connective tissue partitions in the junk reduce von Mises stresses across the skull and that the load-redistribution functionality of the former is insensitive to moderate variation in tissue material parameters, the thickness of the partitions, and variations in the location and angle of the applied load. Absence of the connective tissue partitions increases skull stresses, particularly in the rostral aspect of the upper jaw, further hinting of the important role the architecture of the junk may play in ramming events. Our study also found that impact loads on the spermaceti organ generate lower skull stresses than an impact on the junk. Nevertheless, whilst an impact on the spermaceti organ would reduce skull stresses, it would also cause high compressive stresses on the anterior aspect of the organ and the connective tissue case, possibly making these structures more prone to failure. This outcome, coupled with the facts that the spermaceti organ houses sensitive and essential sonar producing structures and the rostral portion of junk, rather than the spermaceti organ, is frequently a site of significant scarring in mature males suggest that whales avoid impact with the spermaceti organ. Although the unique structure of the junk certainly serves multiple functions, our results are consistent with the hypothesis that the structure also evolved to function as a massive battering ram during male-male competition.

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Socially segregated, sympatric sperm whale clans in the Atlantic Ocean

Royal Society Open Science ◽

10.1098/rsos.160061 ◽

2016 ◽

Vol 3 (6) ◽

pp. 160061 ◽

Cited By ~ 16

Author(s):

Shane Gero ◽

Anne Bøttcher ◽

Hal Whitehead ◽

Peter Teglberg Madsen

Keyword(s):

Social Interactions ◽

Sperm Whale ◽

Mantel Test ◽

Good Evidence ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Sympatric Populations ◽

The Pacific ◽

Matrix Correlation ◽

Social Units

Sperm whales ( Physeter macrocephalus ) are unusual in that there is good evidence for sympatric populations with distinct culturally determined behaviour, including potential acoustic markers of the population division. In the Pacific, socially segregated, vocal clans with distinct dialects coexist; by contrast, geographical variation in vocal repertoire in the Atlantic has been attributed to drift. We examine networks of acoustic repertoire similarity and social interactions for 11 social units in the Eastern Caribbean. We find the presence of two socially segregated, sympatric vocal clans whose dialects differ significantly both in terms of categorical coda types produced by each clan (Mantel test between clans: matrix correlation = 0.256; p ≤ 0.001) and when using classification-free similarity which ignores defined types (Mantel test between clans: matrix correlation = 0.180; p ≤ 0.001). The more common of the two clans makes a characteristic 1 + 1 + 3 coda, while the other less often sighted clan makes predominantly regular codas. Units were only observed associating with other units within their vocal clan. This study demonstrates that sympatric vocal clans do exist in the Atlantic, that they define a higher order level of social organization as they do in the Pacific, and suggests that cultural identity at the clan level is probably important in this species worldwide.

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Calves as social hubs: dynamics of the social network within sperm whale units

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2013.1113 ◽

2013 ◽

Vol 280 (1763) ◽

pp. 20131113 ◽

Cited By ~ 31

Author(s):

Shane Gero ◽

Jonathan Gordon ◽

Hal Whitehead

Keyword(s):

Social Relationships ◽

Social Role ◽

Group Formation ◽

Time Lag ◽

Group Living ◽

Sperm Whale ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Social Unit ◽

The Social

It is hypothesized that the primary function of permanent social relationships among female sperm whales ( Physeter macrocephalus ) is to provide allomothers for calves at the surface while mothers make foraging dives. In order to investigate how reciprocity of allocare within units of sperm whales facilitates group living, we constructed weighted social networks based on yearly matrices of associations (2005–2010) and correlated them across years, through changes in age and social role, to study changes in social relationships within seven sperm whale units. Pairs of association matrices from sequential years showed a greater positive correlation than expected by chance, but as the time lag increased, the correlation coefficients decreased. Over all units considered, calves had high values for all measured network statistics, while mothers had intermediate values for most of the measures, but high values for connectedness and affinity. Mothers showed sharp drops in strength and connectedness in the first year of their new calves' lives. These broad patterns appear to be consistent across units. Calves appeared to be significant nodes in the network of the social unit, and thus provide quantitative support for the theory in which communal care acts as the evolutionary force behind group formation in this species.

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Recent strandings of sperm whale, Physeter macrocephalus, in southern Peru

Latin American Journal of Aquatic Mammals ◽

10.5597/00236 ◽

2018 ◽

Vol 12 (1-2) ◽

pp. 50-52

Author(s):

Jose Pizarro-Neyra

Keyword(s):

Sperm Whale ◽

Physeter Macrocephalus ◽

Southern Coast ◽

Southern Peru

Author reports on a stranding of a female sperm whale in the Peruvian southern coast and review other similar events.

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DNA preserved in jetsam whale ambergris

Biology Letters ◽

10.1098/rsbl.2019.0819 ◽

2020 ◽

Vol 16 (2) ◽

pp. 20190819 ◽

Cited By ~ 1

Author(s):

Ruairidh Macleod ◽

Mikkel-Holger S. Sinding ◽

Morten Tange Olsen ◽

Matthew J. Collins ◽

Steven J. Rowland

Keyword(s):

Natural Product ◽

Dna Sequences ◽

Reference Data ◽

Nuclear Genome ◽

Indirect Evidence ◽

Sperm Whale ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Ecological Mechanisms

Jetsam ambergris, found on beaches worldwide, has always been assumed to originate as a natural product of sperm whales (Physeteroidea). However, only indirect evidence has ever been produced for this, such as the presence of whale prey remains in ambergris. Here, we extracted and analysed DNA sequences from jetsam ambergris from beaches in New Zealand and Sri Lanka, and sequences from ambergris of a sperm whale beached in The Netherlands. The lipid-rich composition of ambergris facilitated high preservation-quality of endogenous DNA, upon which we performed shotgun Illumina sequencing. Alignment of mitochondrial and nuclear genome sequences with open-access reference data for multiple whale species confirms that all three jetsam samples derived originally from sperm whales ( Physeter macrocephalus ). Shotgun sequencing here also provides implications for metagenomic insights into ambergris-preserved DNA. These results demonstrate significant implications for elucidating the origins of jetsam ambergris as a prized natural product, and also for the understanding of sperm whale metabolism and diet, and the ecological mechanisms underlying these coproliths.

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The nose of the sperm whale: overviews of functional design, structural homologies and evolution

Journal of the Marine Biological Association of the United Kingdom ◽

10.1017/s0025315414001118 ◽

2014 ◽

Vol 96 (4) ◽

pp. 783-806 ◽

Cited By ~ 14

Author(s):

Stefan Huggenberger ◽

Michel André ◽

Helmut H. A. Oelschläger

Keyword(s):

Sperm Whale ◽

Pulse Generation ◽

Nasal Passage ◽

Generation Process ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Acoustic Window ◽

Deep Diving ◽

Toothed Whale ◽

Fat Bodies

The hypertrophic and much elongated epicranial (nasal) complex of sperm whales (Physeter macrocephalus) is a unique device to increase directionality and source levels of echolocation clicks in aquatic environments. The size and shape of the nasal fat bodies as well as the peculiar organization of the air sac system in the nasal sound generator of sperm whales are in favour of this proposed specialized acoustic function. The morphology of the sperm whale nose, including a ‘connecting acoustic window’ in the case and an anterior ‘terminal acoustic window’ at the rostroventral edge of the junk, supports the ‘bent horn hypothesis’ of sound emission. In contrast to the laryngeal mechanism described for dolphins and porpoises, sperm whales may drive the initial pulse generation process with air pressurized by nasal muscles associated with the right nasal passage (right nasal passage muscle, maxillonasolabialis muscle). This can be interpreted as an adaptation to deep-diving and high hydrostatic pressures constraining pneumatic phonation. Comparison of nasal structures in sperm whales and other toothed whales reveals that the existing air sac system as well as the fat bodies and the musculature have the same topographical relations and thus may be homologous in all toothed whales (Odontoceti). This implies that the nasal sound generating system evolved only once during toothed whale evolution and, more specifically, that the unique hypertrophied nasal complex was a main driving force in the evolution of the sperm whale taxon.

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Coda communication by sperm whales (Physeter macrocephalus) off the Galápagos Islands

Canadian Journal of Zoology ◽

10.1139/z93-098 ◽

1993 ◽

Vol 71 (4) ◽

pp. 744-752 ◽

Cited By ~ 57

Author(s):

Linda Weilgart ◽

Hal Whitehead

Keyword(s):

Social Cohesion ◽

Temporal Pattern ◽

Sequential Analysis ◽

Sperm Whale ◽

Galapagos Islands ◽

Physeter Macrocephalus ◽

Galápagos Islands ◽

Sperm Whales ◽

Insight Into

To gain insight into the function of sperm whale vocalizations known as codas (short, patterned series of clicks), sperm whales (Physeter macrocephalus) were tracked continuously for periods of days totalling months off the Galápagos Islands, Ecuador, and vocalizations were tape recorded systematically. In total, 1333 codas were classified according to their temporal pattern and the number of clicks they contained. Codas were found to be temporally very clustered, and could be categorized into 23 fairly discrete types. Sequential analysis of codas revealed that they overlapped one another according to type in a nonrandom way, and that type 5 tended to initiate coda exchanges. "Regular" coda types (with evenly spaced clicks) tended to occur with other regular coda types and "irregular" coda types (with one or two delayed final clicks) were heard with other irregular coda types. Codas may function principally as a means of communication, to maintain social cohesion within stable groups of females following periods of dispersion during foraging.

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Foraging on squid: the sperm whale mid-range sonar

Journal of the Marine Biological Association of the United Kingdom ◽

10.1017/s0025315407054847 ◽

2007 ◽

Vol 87 (1) ◽

pp. 59-67 ◽

Cited By ~ 10

Author(s):

M. André ◽

T. Johansson ◽

E. Delory ◽

M. van der Schaar

Keyword(s):

Stomach Contents ◽

Sperm Whale ◽

Target Strength ◽

Directional Hearing ◽

Experimental Measurements ◽

Physeter Macrocephalus ◽

Sperm Whales ◽

Long Time ◽

Minimum Requirements ◽

The Subject

The sonar capabilities of the sperm whale, Physeter macrocephalus, have been the subject of speculation for a long time. While the usual clicks of this species are considered to support mid-range echolocation, no physical characteristics of the signal have clearly confirmed this assumption nor have they explained how sperm whales forage on squid. The recent data on sperm whale on-axis recordings have allowed us to simulate the propagation of a 15 kHz pulse as well as its received echoes from different targets, taking into account the reflections from the bottom and the sea surface. The analysis was performed in a controlled environment where the oceanographic parameters and the acoustic background could be modified. We also conducted experimental measurements of cephalopod target strength (TS) (Loligo vulgaris and Sepia officinalis) to further investigate and confirm the TS predictions from the geometric scattering equations. Based on the results of the computer simulations and the TS experimental measurements (TS squid=−36.3±2.5 dB), we were able to determine the minimum requirements for sperm whale sonar, i.e. range and directional hearing, to locate a single 24.5 cm long squid, considered to be (from stomach contents) the major size component of the sperm whale diet. Here, we present the development of the analysis which confirms that sperm whale usual clicks are appropriate to serve a mid-range sonar function, allowing this species to forage on individual organisms with low sound-reflectivity at ranges of several hundreds of metres.

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