taxonID	type	description	language	source
03AEC940FF8AF506FBC6D2BDFA65FD2F.taxon	description	MNHN. F INA 30, an incomplete and broken premaxilla. Locality West of In Abangharit, Agadez District, Niger. Horizon and age Echkar Formation, Tegama Series. Late Albian (Lower Cretaceous) to early Cenomanian (Upper Cretaceous). Description The lateral surfaces of MNHN. F INA 30 are convex, whereas the anterior margin is more vertically oriented. There is a raised rim around the external nares, which is most prominent at the anterior margin of the narial opening (Fig. 3). Along this anterior margin there is no dorsal projection, although this could be because of the presence of the raised narial rim. The loss of this projection is considered to be a defining characteristic of Pholidosauridae (Fortier et al., 2011), with the premaxilla anterior to the external nares being convex in most pholidosaurids (e. g. Mook, 1934; Wu et al., 2001; Hua et al., 2007; Lepage et al., 2008; Fortier et al., 2011); however, a dorsal projection is present on the most well-preserved specimen of E. cherifiensis (MNHN. F SAM 129) and in well-preserved isolated premaxillae (MNHN. F MRS 334). Therefore, this characteristic may define a subset of pholidosaurids, rather than an unambiguous apomorphy of the clade. Ornamentation on the dorsal surface of MNHN. F INA 30 is composed of numerous irregularly distributed pits that vary in size and shape. On the lateral and anterior surfaces of the premaxilla, the ornamentation becomes less pitted with a more irregular array of grooves and raised ridges. The posterior margins of the premaxillae are not preserved, and both posterior processes are missing. Thus we cannot determine the nature of the premaxilla – maxilla contact or the premaxillary constriction (i. e. the narrowing of the premaxilla immediately posterior to the point of maximum width). Moreover, because of the fragmentary nature of the premaxillae, and the post-mortem surface damage it experienced, the medial (i. e. non-alveolar) palatal surfaces are poorly preserved. Fortunately, the dorsal and lateral surfaces are better preserved. There is an undivided, dorsallyfacing external naris (Fig. 3). As a result of imperfect preservation, it is hard to discern how extensive the fossa within the narial opening would have been. Moreover, because of the fragmentary nature of the premaxilla we cannot ascertain the former in vivo shape, although it is likely to be very similar to that of E. cherifiensis (de Lapparent de Broin, 2002). The posteromedial section of the narial margin is not preserved, and the preserved premaxillary fragments do not fully contact one another along the midline posterior to the external nares. Thus, it is likely that MNHN. F INA 30 shared the same condition as E. cherifiensis (de Lapparent de Broin, 2002; MNHN. F SAM 129), that the anterior processes of the nasals prevented the premaxillae from suturing along the rostral midline, and that the nasals contributed to the posterior margin of the external nares. The maximal width of the premaxilla of MNHN. F INA 30 was mostly level with the P 3 and P 4 alveoli, as in E. cherifiensis (de Lapparent de Broin, 2002; MNHN. F SAM 129). The right premaxilla bears five alveoli, whereas the fifth alveolus is not preserved in the left premaxilla (Fig. 3). This matches the premaxillary tooth count of five seen in specimens referred to E. cherifiensis (not four as stated by de Lapparent de Broin, 2002). The first two alveoli (P 1 and P 2) of both premaxillae are aligned in the same coronal plane, and are oriented vertically and slightly posteriorly. The first two alveoli of both premaxillae form a row of four small and tightly spaced alveoli. These would have created the premaxillary overhang of the dentary seen in other pholidosaurids (e. g. Mook, 1933, 1934; Sereno et al., 2001; Wu et al., 2001; Hua et al., 2007; Lepage et al., 2008; Fortier et al., 2011; Martin et al., 2014). The shape, and how many premaxillary alveoli contribute to this overhang, vary amongst pholidosaurids and are potentially phylogenetically informative. The P 3 and P 4 alveoli are separated from P 1 and P 2 alveoli by large foramina, just as in the specimens referred to E. cherifiensis (MNHN. F SAM 129 and MRS 334; NHMUK PV R 36828; de Lapparent de Broin, 2002). These large, paired foramina appear to be for the reception of the enlarged first dentary tooth crowns. Similar notches (or in some cases just depressions) are also present on the palatal surface of the premaxillae of other pholidosaurids (e. g. Mook, 1933; Sereno et al., 2001; Lepage et al., 2008; Fortier et al., 2011); however, in Meridiosaurus, Oceanosuchus, Sarcosuchus, and Terminonaris these notches are posterior to the P 1 and P 2 alveoli (or just the P 2 alveoli), and are ventral to the external nares (Mook, 1933; Sereno et al., 2001; Lepage et al., 2008; Fortier et al., 2011). The position and very large size of these foraminae, and the separation of the premaxillary alveoli into distinct units, are autapomorphies of Elosuchus. As with E. cherifiensis, the P 3 and P 4 alveoli of MNHN. F INA 30 are considerably larger than the P 1 and P 2 alveoli, and are in approximately the same sagittal plane. The P 3 and P 4 alveoli are widely separated from one another, with a deep interalveolar space created by their high alveolar rims. The left premaxilla preserves the P 5 alveolus posteromedial to the P 4 alveolus. There is no deep interalveolar space between these alveoli, and the gap between the P 4 and P 5 alveoli is proportionally smaller than the P 3 – P 4 interalveolar space. The P 5 alveolus is smaller than the P 1 – P 4 alveoli. Also, it is oriented posteriorly. The posteriorly oriented P 5 and its posteromedial position relative to the P 4 alveolus (rather than posterolateral) are characteristics that MNHN. F INA 30 shares with E. cherifiensis (MNHN. F SAM 129; de Lapparent de Broin, 2002). The P 5 alveoli of most other pholidosaurids are posterolateral to the P 4 alveoli (e. g. Mook, 1934; Sereno et al., 2001; Wu et al., 2001; Hua et al., 2007; Lepage et al., 2008; Fortier et al., 2011); however, the P 5 alveoli of Chalawan thailandicus (Martin et al., 2014) are also in a posteromedial position. Thus, contra Fortier et al. (2011), the posterolateral position of the fifth premaxillary tooth is not an unambiguous synapomorphy of a monophyletic Pholidosauridae, although the medial ‘ migration’ of these alveoli could be a shared characteristic of a more inclusive clade within pholidosaurids. TETHYSUCHIA BUFFETAUT, 1982 (SENSU ANDRADE ET AL., 2011) FORTIGNATHUS GEN. NOV. http: // ZOOBANK. ORG / URN: LSID: ZOOBANK. ORG: ACT: 0 F 0 CCD 3 A- 2831 - 40 DA- A 05 C- E 29 E 30524889 Type species	en	Young, Mark T., Hastings, Alexander K., Allain, Ronan, Smith, Thomas J. (2017): Revision of the enigmatic crocodyliform Elosuchus felixi de Lapparent de Broin, 2002 from the Lower-Upper Cretaceous boundary of Niger: potential evidence for an early origin of the clade Dyrosauridae. Zoological Journal of the Linnean Society (Zool. J. Linn. Soc.) 179 (5): 377-403, DOI: 10.1111/zoj.12452, URL: http://dx.doi.org/10.1111/zoj.12452
03AEC940FF8AF506FBC6D2BDFA65FD2F.taxon	etymology	Etymology ‘ Strong jaws’. Derived from the Latin for strong or powerful (fortis) and the Latinized form of the Greek for jaws (gnathus). Named for the robustness of MNHN. F INA 21 (a referred specimen from a very large individual). Diagnosis Same as the only known species (monotypic genus). FORTIGNATHUS FELIXI (DE LAPPARENT DE BROIN,	en	Young, Mark T., Hastings, Alexander K., Allain, Ronan, Smith, Thomas J. (2017): Revision of the enigmatic crocodyliform Elosuchus felixi de Lapparent de Broin, 2002 from the Lower-Upper Cretaceous boundary of Niger: potential evidence for an early origin of the clade Dyrosauridae. Zoological Journal of the Linnean Society (Zool. J. Linn. Soc.) 179 (5): 377-403, DOI: 10.1111/zoj.12452, URL: http://dx.doi.org/10.1111/zoj.12452
