Daspletosaurus horneri, Thomas D. Carr, David J. Varricchio, Jayc C. Sedlmayr, Eric M. Roberts & ason R. Moore, 2017

Thomas D. Carr, David J. Varricchio, Jayc C. Sedlmayr, Eric M. Roberts & ason R. Moore, 2017, A new tyrannosaur with evidence for anagenesis and crocodile-like facial sensory system, Scientific Reports 7 (44942), pp. 1-11 : 3-9

publication ID

https://doi.org/ 10.1038/srep44942

DOI

https://doi.org/10.5281/zenodo.6040473

persistent identifier

https://treatment.plazi.org/id/0F30DF5A-8E33-5829-AABF-F917FCBEFAAF

treatment provided by

Plazi

scientific name

Daspletosaurus horneri
status

sp. nov.

D. horneri sp. nov.

Etymology

Horneri , Latinized form of Horner, in honor of Jack Horner, in recognition of his successful field program in the Two Medicine Formation that has recovered many new species of dinosaurs that are critical for our understanding of the palaeobiology of dinosaurs in Laramidia, support in the preparation and curation of these specimens, and to acknowledge that his mentoring efforts have launched many professional scientific careers.

Holotype

MOR (Museum of the Rockies, Bozeman) 590, a complete skull, partial pectoral limb, and nearly complete hindlimb ( Fig.1 View Figure 1 , see Supplementary Tables S1–S3).

Paratypes

MOR 1130, an incomplete skull, partial axial series, and partial pelvic girdle and hindlimb. MOR 553S/7.19.0.97, a nearly complete dentary of a small juvenile, based on four features shared with the holotype and the other paratype: 17 dental alveoli, first three alveoli form a rostromedially extending arcade, laterally bowed dentary, rostroventral corner of bone is below the level of the septum between alveoli three and four.

Referred material

AMNH FARB (American Museum of Natural History, Fossil Amphibians, Reptiles, and Birds, New York) 5477, a maxilla, partial postorbital, and parietal; MOR 3068, a partial mandibular ramus; MOR 553D.9.19.91, left ectopterygoid; MOR 553E.7.6.91.196, right ectopterygoid.

Horizon and localities

Glacier County (Co.), Lewis and Clark Co., and Teton Co., Montana, USA; Upper Cretaceous upper Two Medicine Formation.

Stratigraphic Distribution

The type and paratype specimens all come from the upper portion of the Two Medicine Formation 32, 33 (TMF); MOR 590 occurs 65 m below a dated bentonite horizon (TM-4) 7, and the MOR 553 specimens sit at least 10 m above this same bentonite. TM-4 occurs 480m above the base of the ~545 m–thick TMF 32, and recalibration of legacy standards on 40 Ar/ 39 Ar ages from the TMF 32 indicates that the TM-4 tuff is older than previously considered, yielding a recalibrated age of 75.03 Ma +/− 0.72 Ma 34. The fourth skeleton (MOR 1130) comes from within the disturbed belt on the eastern flank of the Rocky Mountains where folding and faulting make determining exact stratigraphic positions difficult. However, the MOR 1130 specimen sits 5.9 m above a newly dated bentonite, reported here to be 74.38 +/− 0.72 Ma (U-Pb zircon weighted mean age (1 σ; MSWD = 0.55); see Supplementary Fig.S1, Discussion S1, Table S4; for bentonite locality information see ref. 35), indicating that it is slightly younger than the other specimens.

Diagnosis

Can be distinguished from all other derived tyrannosauroids, including Daspletosaurus torosus , by the presence of: a wide dental arcade at the front of the snout, where the maxillary and dentary tooth rows extend distinctly rostromedially and the first interdental plate of the maxilla is narrow, which resembles those of the premaxilla where the tooth row is mediolaterally oriented; dentary distinctly bowed (convex) laterally; promaxillary sinus stopping between alveoli 3 and 4, as observed in medial view of the completely prepared pneumatic chamber; rostral end of the choana on the maxilla above alveolus 7; inflated dorsal surface of the lacrimal not reaching the medial edge of the bone; medial pneumatic recess of the lacrimal tall and narrow slot; concave upper half of orbital margin of the lacrimal; entire circumference of the pneumatic recess of the squamosal is undercut and clearly defined; sinuous rostral edge in dorsal view of the dorsotemporal fossa on the frontal; joint surface for the squamosal on the parietal covers the base of the caudolateral process; and the tympanic ridge extends onto the prootic.

Several autapomorphies were obtained by the cladistic analysis; autapomorphies were not included in the data matrix, but several characters were optimized on the terminal branch of D. horneri . These include a pneumatic foramen penetrating the lateral surface of the quadratojugal, shallow notch between the basal tubera, short epipophyses of the anterior cervicals, and the humerus is ~34% the length of the femur (for further comparisons see Supplementary Discussion S2 and Supplementary Fig.S2).

Previous work

The so-called Two Medicine tyrannosaurine has been included in several phylogenetic analyses 2 – 4, 8, 11, 36, with scorings based primarily on MOR 590. It has universally been recovered as a derived tyrannosaurine, but its specific relationships are unresolved, where it has been recovered as the sister species of D. torosus 2, 3, 8, 36 or closer to T. rex 4, 36. Description of the taxon has been limited to brief summaries of salient features (e.g., form of lacrimal horn) that distinguish it from D. torosus and to differentiate Daspletosaurus from other genera of tyrannosaurs 1, 37, but an extensive description of the taxon has not been made.

Description and comparisons

The D. horneri holoype is estimated to be ~9.0 m in total length and 2.2 m tall at the acetabulum (for additional measurements, see Supplementary Tables S1, S2 and S3). D. horneri differs from its sister species in that D. torosus has a rostral ramus of the lacrimal that is longer than the ventral ramus, indicating that D. horneri has a taller skull. The antorbital fossa of the lacrimal is separated by a deep concavity from the ventral ramus of the bone in D. torosus , whereas these surfaces are confluent in D. horneri . In D. torosus , the coronoid region of the surangular faces equally dorsally and laterally, whereas it faces more laterally than dorsally in D. horneri .

Daspletosaurus is one of the best-supported tyrannosaurid clades, distinguished by a suite of unique, mostly cranial features ( Fig.2 View Figure 2 ) that suggests a relatively long evolutionary history. In particular, the cornual processes (‘horns’) of Daspletosaurus are enhanced: a new, secondary horn extends from the side of the large, triangular primary lacrimal horn that is expressed by most tyrannosaurids; and the postorbital horn, which nearly spans the rostrocaudal width of the postorbital bar, is the largest seen among tyrannosaurids. The primary cornual process of the lacrimal differs between the two Daspletosaurus species, being taller in D. torosus (ratio height of process to maximum height of rostral ramus: 69%) than in D. horneri (ratio: 53%).

Results

Phylogeny. The phylogenetic analysis (see Supplementary phylogenetic character list, Tables S5 and S6) recovered 18 most parsimonious trees, each having a tree length of 802 steps, a CI of 0.56, an HI of 0.44, and an RC of 0.45. The topology conforms to that of earlier works 3, 11, but the strict consensus tree and 50% majority rule tree shows that Aviatyrannis and Proceratosauridae and the lineage leading to more derived tyrannosauroids form an unresolved trichotomy ( Fig.2 View Figure 2 A; see Supplementary Fig.S3). Also, the tyrannosaurines Lythronax , Teratophoneus , and Nanuqsaurus form an unresolved trichotomy. Alioramus and Qianzhousaurus are recovered as sister species, and given that relationship we regard the genus Qianzhousaurus as a junior synonym of Alioramus ( Fig.2 View Figure 2 A). We follow the taxonomic practice in regarding sister species as congeneric, so this renaming does not constitute a phylogenetic rearrangement of alioramins. This convention is followed elsewhere in the tree (e.g., Albertosaurus , Daspletosaurus , Tyrannosaurus ). Our results recover Timurlengia as more derived than Xiongguanlong and as the sister species of a new taxon from the Iren Dabasu Formation. The latter taxon (under study by TDC) is based on a partial individual (AMNH FARB 6556) that includes several teeth (premaxillary, lateral) and skull bones (lacrimal, jugal, pterygoid, ectopterygoid, quadratojugal) that was collected in 1923 under the auspices of the AMNH. The presence of D-shaped premaxillary teeth and the presence of a jugal pneumatic recess with a secondary fossa identifies it as a derived tyrannosauroid. The absence of hindlimb bones prevents comparison with the lectotype of Alectrosaurus olseni , and so it was treated as a separate taxon in our analysis (for a complete list of unambiguously resolved synapomorphies see Supplementary synapomorphy list).

Importantly, Daspletosaurus horneri is recovered as the sister species of D. torosus ; this relationship is supported by 11 unambiguously optimized synapomorphies ( Fig.2 View Figure 2 B–G), including the presence of a coarse subcutaneous surface of the maxilla, an accessory cornual process on the lacrimal, a partly concealed maxillary process of the lacrimal, a cornual process of the postorbital that closely approaches the laterotemporal fenestra, a rostral tip of the squamosal that stops caudal to the rostral margin of the laterotemporal fenestra, a ridge along the nasal process of the frontal, a deep ventral keel on the vomer, a caudal pneumatic recess of the palatine that is positioned caudal to the rostral margin of the dorsal process, a distinct mediolaterally oriented ridge on the dorsum of the laterosphenoid that extends toward the medial edge of the dorsotemporal fenestra, a ‘chin’ of the dentary (where the rostral and ventral margins of the dentary join) that is positioned below the third dentary tooth, and there are more than 13 maxillary teeth.

Historical biogeography. The pattern of historical biogeography indicated by our parsimony analysis is consistent with the hypothesis of Brusatte and Carr 11, where North American taxa are not divided into northern and southern subclades 4. Our topology shows an Asian diversification intermediate-grade tyrannosauroids ( Xiongguanlong baimoensis , Timurlengia euotica, Iren Dabasu taxon) during the mid- and early Late Cretaceous that preceded a dispersal event to North America, which was followed by subsequent and frequent exchange between the landmasses throughout the Late Cretaceous.

Ontogeny. The growth series of D. horneri includes juveniles, subadults, and an adult ( Fig.3 View Figure 3 ). The smallest specimen, a dentary, has a tooth row that is 221.5 mm long, in contrast to the 423.0 mm tooth row of the adult, which has a 947.0 mm long skull. The length of the dentary tooth row has been shown by Currie 38 that in comparison with skull length, it shows a weak negative allometry. Therefore, the original skull length of the small specimen was greater than 496.0mm, slightly more than half the length of the adult skull.

The parsimony analysis of morphological features (see Supplementary ontogenetic character list, Data S1) resulted in a single most parsimonious growth series of 168 steps, with a CI of 0.93, an HI of 0.07, an RI of 0.93, and an RC of 0.91 ( Fig.3 View Figure 3 ; see Supplementary Fig.S4). The transition from a gracile juvenile to a robust adult in D. horneri is similar to that seen in other tyrannosauroids 8, 26, 28.

Soft tissues. The excellent quality of preservation of these specimens permits us to assess the type of soft tissue that covered the face (premaxilla, maxilla, nasal, lacrimal, jugal, postorbital, squamosal, dentary). In D. horneri , and in all derived tyrannosauroids, the subcutaneous texture is coarse and shows a hierarchy of textures (see Supplementary Discussion S3). In order to identify the soft tissue that produced this complex surface, we compared the condition of tyrannosaurids with that of crocodylians ( Alligator mississippiensis ) and birds ( Struthio camelus , Anser sp., Anas sp., Cygnus sp., Meleagris gallopavo ), and we followed several studies 29, 31, 39, 40 to identify osteological correlates imprinted on the cortical surface of facial bones to deduce their causal soft tissues.

Although tyrannosaurids, crocodylians, and birds share neurovascular foramina that are densely clustered at the front of the jaws and form rows along the oral margin, the smooth texture of the snout in birds is sharply different from the hummocky texture of the facial bones of crocodylians and tyrannosaurids. The coarse surface of crocodylians is covered by many flat scales 29, whereas in birds the rhamphotheca (beak) covered the smooth surface of the snout and jaws. The coarse texture shared between tyrannosaurids and crocodylians indicates a primary covering of flat scales on the face of the nonavian dinosaurs ( Fig.4 View Figure 4 ).

In archosaurs, a scaly integument appears to be correlated with the multiple rows of foramina seen in crocodylians and tyrannosaurids, whereas in birds the foramina deep to the beak are limited to the jaw tips, the caudal end of the maxilla, and in a row along the side of the lower jaw. A similar localization of foramina is seen in ornithischian dinosaurs, whose jaws and oral margins were sheathed by beaks ahead of the tooth row 39.

Unlike crocodylians, the alveolar row of foramina in the dentary of derived tyrannosauroids and birds occurs in a common groove that extends for much of the length of the bone. This groove is not seen in crocodylians, although caudodorsally extending sulci extend from the foramina. In birds the groove is covered by the rhamphotheca, and the ventral branches of the rictal vessels and the external branch of the mandibular nerve lie in the groove 40. The groove in tyrannosauroids is shallowly inset, unlike the sharply inset condition that is seen in birds. The presence of the groove in tyrannosauroids indicates that the ventral branches of the rictal vessels evolved prior to, and might have been prerequisites for, the later appearance of the beak (in terms of the stepwise vascular changes leading from nonbeak to beak), at least on the lower jaw. The caudal end of the groove fades out in birds, a condition that is also seen in mature tyrannosauroids 41.

Variation in the coarse zone of the face in tyrannosaurids indicates a variety of epidermal types, in addition to flat scales. The rostral surface of the premaxilla, dorsum of the nasals, dorsolateral surface of the lacrimal, cornual process of the jugal, and the rostroventrolatral surface of the dentary, bear small bony papillae, which indicate regions of armor-like skin 29 ( Fig.4 View Figure 4 , see Supplementary Discussion S3). Finally, the coarse and rim-like edges of the postorbital horn, and its smooth central region, indicate a cornified sheath-like covering on its surface and part of the postorbital bar ( Fig.4 View Figure 4 ).

Discussion

Anagenesis. A hypothesis of anagenesis amongst tyrannosaurids ( D. torosus -> D. horneri -> T. rex ) is defensible if: (1) the taxa are sister species or a phylogenetically successive series of species, (2) the species are stratigraphically sequential, (3) the phylogenetic relationships do not conflict with their stratigraphic sequence, and the taxa (4) are from the same landmass or adjacent landmasses that had connections that do not conflict with their chronological sequence.

Our new phylogeny ( Fig.2 View Figure 2 A) shows that D. torosus and D. horneri are sister species, whereas T. rex is nested in a separate clade. This topology is different from the phylogenetic arrangement of previous workers 1, where D. torosus is the sister species of a clade composed of D. horneri and T. rex . In our phylogeny, T. rex is separated from the Daspletosaurus clade by two phylogenetically- and almost certainly stratigraphically-successive 4 sister species, Zhuchengtyrannus magnus and T. bataar .

Chronostratigraphic and lithostratigraphic correlation between the TMF and Dinosaur Park Formation (DPF) suggests that the DPF correlates with the upper 220 m of the TMF 42 – 45. In-progress high-precision U-Pb dating of the four ash beds spanning the top of the Oldman Formation, the DPF and the lower part of the Bearpaw Formation (BPF) indicates an age range between 76.69 Ma–74.26 Ma (internal error <±30ka) for this stratal package 46. Given that uppermost date of 74.26 Ma is from the lower BPF and these workers have identified a slowdown in sedimentation rates for the upper 22 meters of the DPF-BPF transition 46, the age of the top of the DPF is likely no younger than 74.5 Ma. Because D. torosus specimens are restricted to the lower two-thirds of the DPF (~76.7–75.2 Ma), and D. horneri specimens are limited to the uppermost part of the TMF 45 (~75.1–74.4 Ma) there appears to be little or no stratigraphic overlap between Daspletosaurus specimens from these two field areas. New high-precision CA-TIMS U-Pb dating is underway and promises to better resolve stratigraphic uncertainties.

Therefore, D. torosus and D. horneri meet the primary criteria for anagenesis: They are sister species, stratigraphically successive, and are from the Northern Rocky Mountain Region. In contrast, the divergence between the Daspletosaurus clade on the one hand, and the Z. magnus + Tyrannosaurus clade on the other, was the result of a cladogenetic (lineage-splitting) event, since they do not form a continuous series of stratigraphically sequential taxa. Therefore, T. rex was not a continuation of the anagenetic Daspletosaurus lineage 1.

The Z. magnus + Tyrannosaurus clade consists of a pair of sister species ( T. bataar + T. rex ) and a sister taxon that extends from the preceding node ( Z. magnus ). This topology is consistent with a hypothesis of anagenesis: Z. magnus lived no less than 73.5 Ma 47, and T. rex lived between 66.0 and ~67.2–67.4 Ma 48. The age of the Nemegt Formation, from which T. bataar has been collected, is less than 75.0 Ma based on radiometric dating of the underlying Barun Goyot Formation 49. Therefore, if T. bataar is intermediate in age between Z. magnus and T. rex , then the chronological sequence of these tyrannosaurs is also consistent with anagenesis. The time gap (~6.1– 6.3 Myrs) that separates Z. magnus and T. rex greatly exceeds that between D. torosus and D. horneri ; therefore, the hypothesis of anagenesis from Z. magnus to T. rex will be tested as new tyrannosaur specimens are collected from that interval in Asia and included in new phylogenetic analyses.

This is also the case for the two sister species of Albertosaurus , which are stratigraphically successive and from the same geographic region, in northern Laramidia 37, 50. If the Asian sister species Alioramus remotus and A. sinensis are shown to be stratigraphically successive (the taxa are widely separated geographically, and neither is constrained by radiometric dates 5, 10), then they meet the criteria as well, but in the absence of those data the decision between anagenesis and cladogenesis is equivocal.

Based on this approach, the evidence for anagenesis might be widespread among other dinosaur lineages with high-quality fossil records. If so, then anagenesis was an important contributor towards the generation of species diversity, in addition to cladogenesis, and in some instances cladogenesis might be an artifact of an incomplete fossil record.

Ontogenetic tooth count reduction. D. horneri shows another occurrence of growth related reduction in maxillary tooth count among tyrannosaurids, which starts in juveniles (AMNH FARB 5477) with 15 maxillary teeth, increases to 17 tooth positions in subadults (MOR 590), and then decreases to 15 in adults (MOR 1130). In contrast, the number of dentary teeth is constant, where 17 alveoli are seen in juveniles (MOR 553S/7.19.0.97), subadults (MOR 590) and adults (MOR 1130).

The pattern of tooth count increase followed by a decrease in D. horneri may result from individual variation. However, this general pattern is also seen in the maxilla of D. torosus , where the least mature specimen (TMP 1994.143.0001) has a count of 13 teeth that increases in more mature specimens to 15 (AMNH FARB 5346) or 16 (MOR 395), which is followed by a decrease in the most mature specimens (CMN 8506) to a minimum of 14.

The phenomenon of growth related tooth count reduction is seen in the maxilla and dentary of T. rex 26, 28. The pattern of an initial increase to a later decrease is also seen in the recently published data for T. rex of Brown et al. 51, where an increase in tooth count of the dentary (from 16 to 17) is seen in the two least mature specimens (CMNH 7541, BMRP 2002.4.1). Work in progress by one of us (TDC) finds that the smaller CMNH 7541 is the less mature specimen of the two. An increase is potentially also seen in the maxilla, where the tooth count for one specimen (BMRP 2002.4.1) is different between sides (left: 16, right: 15), but the authors only included the lower count in their data set 51. Including the higher count would result in an increase from 15 to 16 teeth, followed by a decrease in number with increasing size, as seen in their data. If the tooth counts reflect ontogeny, and allowing for slightly different rates of tooth increase on each side of the jaw, it appears that an initial increase in tooth count followed by a decrease in number is typical of derived tyrannosaurines.

Ontogenetic facial texture reduction. There is an ontogenetic reduction in the coarseness of the facial texture from subadult (MOR 590) to adult (MOR 1130), especially of the nasal bones that form the top of the snout, where the texture is reduced. Examination of specimens of T. rex reveals the same pattern, where the snout is coarse in relatively young adults (AMNH FARB 5027), whereas it is smoother in relatively old adults (LACM 23844) 28. This reduction in texture that is seen among tyrannosaurines is similar to the reduction in cephalic ornamentation that also occurs in other dinosaurs, including ceratopsids 52 – 54 and pachycephalosaurians 55. It is possible that ornament reduction in adults is an ancestral feature for dinosaurs. A complete list of synontomorphies (growth-related features) and an extended discussion of the growth series can be found in the Supplementary synontomorphy list and Discussion S4.

Quadratojugal foramen. It has been claimed that the presence of a large pneumatic foramen in the lateral surface of the quadratojugal is unique to the contentious tyrannosaurid taxon Nanotyrannus lancensis 56, the holotype of which has been revised to represent a juvenile T. rex 26, 28. However, this feature is also seen in the adult specimen of D. horneri , and in an isolated tyrannosaurid quadratojugal from the upper Campanian strata of southern Alberta (CMN 57080). Although our phylogenetic analysis shows that the quadratojugal foramen evolved independently in D. horneri and T. rex , the additional occurrence in the unidentified taxon from Alberta indicates that the foramen might be synapomorphic for derived tyrannosaurines.

Phylogenetic implications. The phylogenetic analysis places D. horneri as the sister species of D. torosus , indicating a monophyly of the known species within Daspletosaurus , in contrast to a recent hypothesis that the clade is paraphyletic 4. We attribute the difference in results to the absence of the lacrimal, frontal, and vomer characters from the data set of Loewen et al. 4. Therefore, the Daspletosaurus lineage traces back to the interval between the emplacement of the WIS at 99.5 Ma, as represented by the Thermopolis Shale 57, and approximately 80 million years ago, the age of the oldest tyrannosaurines from the American West 4.

Biogeographic implications. The stratigraphic distribution of specimens discussed above shows that Daspletosaurus spp. inhabited northern Laramidia (what is now southern Alberta and northern Montana) for a minimum duration of ~2.3 Ma. This areal distribution makes Daspletosaurus one of the most widely distributed Late Cretaceous tyrannosaurid clades in Laramidia before the arrival of T. rex ; in contrast, the distribution of other taxa is marked by high endemism, where species are limited to local basins of deposition 4. In Alberta, D. torosus was sympatric with another large tyrannosaurid, Albertosaurus libratus 37, but in Montana, at present, no sympatric tyrannosaurids are known.

Dispersal of tyrannosaurines from Laramidia to Asia must have occurred in that span (99.5 to ~80.0 Ma), to account for the presence in Asia of the relatively basal Alioramus and derived Tyrannosaurus (both from the Nemegt Formation, ~75.0–66.0 Ma 49), and the derived Z. magnus (Wangshi Group, 73.5+ Ma 47). Also, there is no evidence for faunal exchange between the landmasses from 80 to 75.7 Ma, so the dispersal had to occur prior to this point. Since Daspletosaurus is the sister species of the Zhuchengtyrannus + Tyrannosaurus clade, both had to arise before the dispersal event. From these observations we predict that species of the Daspletosaurus lineage will be present in rocks several Myrs older than the oldest existing examples of individuals from that lineage (from the DPF, ~76.7 Ma).

Soft tissue interpretations. In tyrannosaurids, a scaly facial integument in association with multiple rows of neurovascular foramina on the snout and jaws serves as a reliable proxy for tactile sensitivity in these giant predatory dinosaurs. In crocodylians the craniomandibular foramina convey hundreds of afferent branches from the trigeminal nerve (N. V) in a density that transmits high resolution tactile sensations from the skin, making their snouts more sensitive than human fingertips 58. The density of foramina in crocodylians maps with the distribution of the integumentary sensory organs (ISOs) in the skin of the head, where they are densest at the rostral end of the jaws and along the oral margins adjacent to the teeth, and sparsest on the sides of the jaws and top of the snout. Given the nearly identical arrangement and density of foramina to crocodylians, we can now infer that tyrannosaurids possessed ISOs ( Fig.4 View Figure 4 ) to transmit trigeminal innervation from the facial skin, as in seen in crocodylians and comparable mechanoreceptors of other terrestrial tetrapods (e.g., monotremes, moles, toads, frogs, snakes, ducks) 58.

If our soft–tissue inferences regarding the presence of flat facial scales and ISOs are correct, then behavioral inferences for tyrannosaurids can be drawn based on comparison with crocodylians 59. Tyrannosaurids had a highly sensitive facial tactile system that functioned in prey capture, and object identification and manipulation, given the skeletal similarities with crocodylians 58, 59. In crocodylians the bony casements around the nerve branches protect them from injuries sustained during communal feeding while maintaining highly sensitive skin 58; given the similarity in foramen morphology, this protective function was present in tyrannosaurids (whose bony oral margins often show lesions), showing that this multipurpose cephalic tactile system was not limited to life in an aquatic environment.

Assuming that crocodylians are suitable models for dinosaur behavior, and that tyrannosaurids were primarily terrestrial, tactile stimulation, such as rubbing, was probably more important in tyrannosaurid agonistic behavior than detecting water borne vibrations 59. As in crocodylians, female tyrannosaurids would have relied upon ISOs on the snout for detecting the optimal temperature of a nest site, and for maintaining nest temperature and the nest materials; also, ISOs would have aided adult tyrannosaurids in harmlessly picking up eggs and nestlings and, in courtship, tyrannosaurids might have rubbed their sensitive faces together as a vital part of pre-copulatory play 59.

Methods

Character dataset. We included D. horneri in an updated data matrix that is based on the most recent tyrannosauroid phylogeny 11, which analyzed 366 characters, and we contributed another 20 new characters to the data matrix, for a total of 386 (see Supplementary Phylogenetic character list and Tables S5 and S6). We also included Timurlengia euotica 7 and an undescribed species from the Iren Dabasu Formation that is currently under study by one of us (TDC), for a total of 28 ingroup taxa. Unlike some other analyses 4, ours does not include Bagaraatan ostromi or Alectrosaurus olseni , but we include the referred material of Teratophoneus curriei . We take the view that Alioramus altai is synonymous with A. remotus , which we coded together into a single taxonomic unit. We regard Raptorex kriegsteini as a juvenile tyrannosaurine, which we excluded from the analysis.

Parsimony analysis. We built the data matrix in MacClade 4 v.4.08 60; we analyzed the data in a branch-and-bound search using PAUP* v. 4.0b10 61. Ordering of characters followed reference 11. As in the preceding analyses, Allosaurus sp., Maniraptora, Ornithomimosauria, and Compsognathus longipes were included as the outgroup taxa. The common components of the MPTs were summarized in a strict consensus and in a 50% majority rule consensus, which had the same topology ( Fig.2 View Figure 2 A); Bremer decay and bootstrap values we used to assess clade support (see Supplementary Fig.S3).

Ontogeny. We reconstructed a hypothetical growth series for D. horneri , based on a cladistic analysis of 164 characters coded for 5 specimens (see Supplementary Data S1). We built the data matrix in MacClade 4 v.4.08 60; we analyzed the data in a branch-and-bound search using PAUP* v. 4.0b10 61 with the characters unordered and unweighted. An all-zero artificial embryo was included to optimize the characters on the topology.

Data archiving. All primary data, including the geochronological analysis, phylogenetic character list and character-taxon matrix, ontogenetic character list and character-specimen matrix, are available in the supplementary information and Extended Data.

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