Fouldenia ischiptera, (TRAQUAIR, 1881)

FOULDENIA ISCHIPTERA ( TRAQUAIR, 1881)

Holurus ischipterus Traquair, 1881

Styracopterus ischipterus Traquair, 1890

Fouldenia ottadinica White, 1927

Styracopterus ottadinica Moy-Thomas, 1937

Styracopterus ischipterus Moy-Thomas, 1937

Styracopterus fulcratus Gardiner, 1985

Holotype: GSE 2187 (M1122b, holotype of ‘ Styracopterus ischipterus ’), British Geological Survey , Edinburgh, UK, nearly complete articulated individual in part (EBL: 6 cm).

Paratypes: NHM P13178 (holotype of ‘ Fouldenia ottadinica ’), Natural History Museum , London, UK, nearly complete, flattened articulated individual showing dorsal aspect in part (EBL: 9 cm); NHM P13179, impression of complete articulated skull in part (EBL: 8 cm); NHM P13187 (part) and NHM P13188 (counterpart), nearly complete articulated individual (EBL: 5 cm); NHM P13180 (part) and NHM P14560 (counterpart), incomplete articulated anterior half of individual (EBL: 8 cm); NHM P13182 (part) and NHM P13183 (counterpart), incomplete articulated anterior half of individual (EBL: 8.5 cm); NHM P13186, articulated posterior half of individual in part (EBL: 10 cm); NHM P13186, articulated caudal portion of individual in part (EBL: 10 cm) .

Additional material: GSE 2143, articulated anterior portion of individual, including skull (EBL: 3 cm); NHM P14562, incomplete articulated individual in part (EBL: 6 cm); NHM P14564, nearly complete articulated individual in part (EBL: 9 cm); NHM P61546, incomplete articulated individual in part with trunk squamation and skull (EBL: 8 cm); NHM P61549, complete articulated individual in part (EBL: 10 cm); NHM P61002, incomplete articulated individual in part with trunk squamation, paired fins, and posterior skull (EBL: 10.5 cm); NHM P13181 (part) and NHM P14561 (counterpart), incomplete articulated anterior third of individual (EBL: 12 cm); NHM P61548, nearly complete articulated individual in part and counterpart (EBL: 12 cm); NMS 1980.40.30, National Museums of Scotland, Edinburgh, Scotland, UK, articulated postcranium of individual in part and counterpart (EBL: 4 cm); NMS 1965.4.2, nearly complete articulated individual in part (EBL: 5 cm); NMS 1965.4.2, articulated postcranium of individual in part (EBL: 5.5 cm); NMS 1980.40.27, articulated postcranium of individual in part and counterpart (EBL: 6.5 cm); NMS 1965.4.3, nearly complete articulated individual in part and counterpart (EBL: 7 cm); NMS 1956.5.1, incomplete articulated individual in part and counterpart (EBL: 7.5 cm); NMS 1984.67.61, nearly complete articulated individual in part (EBL: 7.5 cm); NMS 1984.67.63, nearly complete articulated individual in part and counterpart (EBL: 9 cm); NMS 1980.40.31, nearly complete articulated individual in part (EBL: 9.5 cm); NMS 1984.67.65, nearly complete articulated individual in part and counterpart (EBL: 9.5 cm); NMS 1984.67.64, incomplete anterior two-thirds of individual in part (EBL: 11 cm); NMS 1984.67.62, nearly complete articulated individual in part, lacking axial lobe (EBL: 11.5 cm); GLAHM V8327 View Materials , Hunterian Museum , Glasgow, Scotland, UK, nearly complete articulated postcranium of individual in part (EBL: 8 cm) .

Type localities and horizon: River Tweed below Coldstream, Berwickshire, Scotland, UK. Calciferous Sandstone Series, Cementstone Group, Schopfites claviger-Auroraspor macra (CM) miospore biozone (348–347 Mya; Smithson et al., 2012), Tournasian 3 (TN3) zone, Ivorian regional substage, Dinantian regional stage, late Tournaisian stage, Mississippian subsystem, Carboniferous system ( Traquair, 1881; Gardiner, 1985; Smithson et al., 2012).

Other localities and horizons: Foulden Fish Bed, Foulden Burn, Berwickshire, Scotland, UK. Calciferous Sandstone Series, Cementstone Group, CM biozone, TN3 zone, Courceyan regional substage, Dinantian regional stage, late Tournaisian stage, Mississippian subsystem, Carboniferous system ( White, 1927; Gardiner, 1985; Wood & Rolfe, 1985; Dineley & Metcalfe, 1999; Smithson et al., 2012); Coomsden Burn, Redewater, Northumberland, England, Cementstone Group, Dinantian regional stage, late Tournaisian stage, Mississippian subsystem, Carboniferous system ( White, 1927; Moy-Thomas, 1938; Gardiner, 1985).

Diagnosis (emended from Traquair, 1881): As for genus.

Remarks: The genus Fouldenia includes all specimens from Foulden previously assigned to Styracopterus ( Moy-Thomas, 1937; Gardiner, 1985), as well as specimens from the Calciferous Sandstones at Coldstream originally attributed to Holurus ischipterus , subsequently to S. ischipterus (or ‘ischypterus’), and finally to S. fulcratus ( Traquair, 1881, 1890; Moy-Thomas, 1937; Gardiner, 1985). The Coldstream specimens are here found to be indistinguishable from juveniles of Fouldenia , as originally predicted by Moy-Thomas (1937), and are thus reassigned to the latter taxon. The older name for the single known species within Fouldenia is therefore ischipterus ( Traquair, 1881) , not ottadinica . This has been corrected to ischiptera to agree with the gender of the genus. Likewise, the appropriate holotype for Fouldenia is GSE 2187, as designated for Holurus ischipterus by Traquair (1881), rather than NHM P13178 as proposed for Fouldenia by White (1927).

DESCRIPTION

Skull

The construction of the skull of Fouldenia is largely as illustrated by White (1927) and Gardiner (1985), but there are several discrepencies. Starting at the anterior end, Fouldenia bears an elongate, nearly erect median rostral, featuring sigmoidal lateral margins ( Figs 5–7 View Figure 5 View Figure 6 View Figure 7 , 13 View Figure 13 ). The rostral exhibits a slight curve in smaller specimens, but is significantly inclined halfway along its length in larger individuals, where it is ornamented with wide, horizontal ganoine bands ( Figs 7B View Figure 7 , 13D View Figure 13 ). The elongate, curved nasals of Fouldenia are bounded by the premaxilla and lachrymal ventrally, and frontal and dermosphenotic dorsally ( Figs 5C, D, F, G View Figure 5 , 6C View Figure 6 , 7C, D, E View Figure 7 ). The nasal widens towards the gape and does not exhibit marginal indentitions for the nostrils, contrary to Gardiner’s (1985) reconstruction.

In the smallest specimens of Fouldenia (e.g. NHM P14562; Fig. 5B View Figure 5 ), the frontals and parietals are relatively wide and nearly equal in size, but in larger fish (e.g. NHM P13181; Fig. 7D View Figure 7 ) the frontals appear longer and narrower. These are joined at a diagonal suture line formed by the posterolateral processes on the frontals. The supraorbital canal runs through the lateral midline of these bones, and the mesial surface of the canal is apparent in the holotype NHM P13178 ( Fig. 6B View Figure 6 ) and NHM P61549 ( Fig. 6H View Figure 6 ). Frontal ornament consists primarily of horizontal striations, although a curved ridge at the midpoint marks a granulated or wavy posteromedial ornament field in both NHM P14562 ( Fig. 5B View Figure 5 ) and NHM P13181 ( Fig. 7D View Figure 7 ). The parietal ornament consists of intercalating wavy ridges laterally and more longitudinal bands dorsally, as is apparent in NHM P13179, NHM P13180, and NHM P13181 ( Figs 5F, G View Figure 5 , 7D View Figure 7 ). The dermopterotic is more like that described by White (1927) than Gardiner’s (1985) reconstruction; the posterior portion is wide and the margins are smooth ( Figs 5–7 View Figure 5 View Figure 6 View Figure 7 ). The lateral margin curves to form an anterior point. This margin sits at the level of the curved ridge on the frontal in NHM P14562 ( Fig. 5B View Figure 5 ) and NHM P13181 ( Fig. 7D View Figure 7 ), whereas the straight posterior margin contacts the extrascapular. This spatial relationship appears fixed in individuals of all sizes. Fouldenia possesses one pair of rectangular extrascapulars ( Figs 5B, F, D View Figure 5 , 6A, C, F, B View Figure 6 , 7D View Figure 7 ) that sit at the level of the anterior margin of the opercular series, ornamented with short horizontal striations. The post-temporal is wide with a diagonal posterior margin. Although the general form is blunt and rounded in smaller fish (e.g. NHM P14562, NHM P13179, NHM P13180; Fig. 5B, F, G View Figure 5 ), it tapers to a rounded lateral point in larger specimens (e.g. NMS 1984.67.64, NHM P61002, NHM P61548; Fig. 7A, B, D View Figure 7 ). The post-temporal is also long, extending past the opercular series.

The orbit in Fouldenia is bounded by the nasal, the dermosphenotic, and two infraorbitals (the lachrymal and jugal), but not by the premaxilla as described by Gardiner (1985). The dermosphenotic is ornamented with horizontal ridges ( Fig. 6C View Figure 6 ) and stretches from the nasal to the preoperculum, leaving little room for any unobserved supraorbitals or suborbitals. In specimens under 7 cm in total length (e.g. NHM P14562 and NMS 1965.4.3; Fig. 5B, C View Figure 5 ), the dermosphenotic is a homogenous, thick crescent, whereas in larger specimens (e.g. NHM P14564 and NMS 1984.67.64; Figs 6C View Figure 6 , 7C View Figure 7 ) it features a distinct rectangular ventral portion and an elongated anterior process. Contrary to the previous description by Gardiner (1985) and coding for a t-shaped dermosphenotic by Gardiner & Schaeffer (1989), there is no evidence for a distinct posterior process (NHM P14562, NMS 1965.4.3, NMS 1956.5.1, and NHM P14564; Figs 5B, C, D View Figure 5 , 6C View Figure 6 ).

The jugal is unfortunately incomplete in specimens of Fouldenia , but largely conforms to that described by Gardiner (1985). It forms a thick arch extending from the dermosphenotic to the midpoint of the orbit in NMS 1984.67.65 and NHM P13179 ( Figs 5F View Figure 5 , 6F View Figure 6 ), and widens with size (NHM P61548 and NHM P13181; Fig. 7D, E View Figure 7 ). It is not clear if the horizontally ridged ornament in NMS 1965.4.3, NHM P13181, and NHM P61548 ( Figs 5C, D View Figure 5 , 7E View Figure 7 ) has any relationship with a branching suborbital canal, as in Amphicentrum ( Coates, 1988) . The lachrymal is rectangular and meets the premaxilla and nasal at an anterior margin that is blunt in small individuals (NHM P14562; Fig. 5B View Figure 5 ), but is tapered in the largest specimens (NHM P13181; Fig. 7D View Figure 7 ).

Jaws and dentition

A badly preserved palatoquadrate is found in NHM P13183 ( Fig. 6A View Figure 6 ), but little can be determined about the morphology. The dorsal surface of the parasphenoid is fairly wide in NMS 1984.67.65 ( Fig. 5E View Figure 5 ), with a shallow central depression and lateral margins marked by prominent ridges that might represent parabasal canals. The bone is laterally thick in NHM P13180 ( Fig. 5G View Figure 5 ) and NMS 1984.67.65 ( Fig. 6E View Figure 6 ), widening towards the posterior wall of the orbit. Phylogenetically important information concerning the extent and condition of the ascending process remains unknown ( Patterson, 1982; Gardiner & Schaeffer, 1989; Coates, 1999).

The maxilla is well preserved in nearly all specimens of Fouldenia and overlaps the mandible, particularly a rounded posteroventral process. The maxilla features a rounded, triangular posteriorly expanded portion and a rectangular anterior ramus ending in a blunt margin. In the smallest individuals (e.g. NMS 1980.40.30 and NHM P14562; Fig. 5A, B View Figure 5 ), the two portions are nearly equal in height to the premaxilla, and the bone features rounded, edentulous ventral margins, as best shown in NHM P13180 and NMS 1984.67.62 ( Figs 5G View Figure 5 , 7C View Figure 7 ). The premaxilla bears rounded lateral processes that sit above the maxillae ( Figs 7C View Figure 7 , 13 View Figure 13 ), but these are less prominent than reconstructed by Gardiner (1985), and do not contact the orbit.

The surangular is not visible in any specimen of Fouldenia , and there appears to be little room for such a bone between the dentary and angular. The dentary is robust in specimens over 10 cm in total length ( Fig. 7 View Figure 7 ), expanding dorsally such that the symphysial margin is diagonal and the jaw margin is prominent. In smaller specimens ( Fig. 5 View Figure 5 ), a more gracile, blunt dentary is almost entirely overlapped by the maxilla. The crescent-shaped angular in Fouldenia ( Figs 5D, G View Figure 5 , 6A, F, G View Figure 6 ) is obscured by the maxilla in smaller specimens, as described by White (1927) and Gardiner (1985). However, it extends posteriorly in larger fish (e.g. NHM P13185, NHM P14562, and NMS 1984.67.65; Figs 6B, C View Figure 6 , 7B View Figure 7 ), with its juncture with the quadratojugal exposed.

Bands of smooth ganoine sit parallel with the jaw margins in all specimens, and the prominence of these is apparent in NHM P14564 ( Fig. 6C View Figure 6 ), NHM 1984.67.65 ( Fig. 6E View Figure 6 ), NHM P61549 ( Fig. 6G View Figure 6 ), NHM 1984.67.64 ( Fig. 7B View Figure 7 ), and NHM P61548 ( Fig. 7E View Figure 7 ). The smallest specimens (e.g. NMS 1980. 40.30 and NHM P14562; Fig. 5A, B View Figure 5 ) have a single rectangular tract on each side of the gape. This increases to two maxillary and three mandibular bands in mid-sized individuals, such as NHM P13179 ( Fig. 5F View Figure 5 ), with an additional tract added along the anterodorsal margin of the maxilla in larger individuals like NMS 1984.67.65 ( Fig. 6E View Figure 6 ). In the largest specimens of Fouldenia (e.g. NMS 1984.67.64; Fig. 7B View Figure 7 ), the bands are fused and intercalated, joined by shorter segments of ornament, forming a solid enameloid ‘beak’. Similar ganoine cover is found in Styracopterus (see above) and the Visean styracopterid Benedenius ( Van Beneden, 1871; Traquair, 1877 –1914, 1878; De Koninck, 1878; Moy-Thomas, 1937; L.C.S., pers. observ.; Appendix S1), as well as the Cheirodopsis , Amphicentrum, Paramesolepi s, and Eurynotus , albeit without distinct bands (L.C.S., pers. observ.; Appendix S1; Fig. 15 View Figure 15 ). A line of tiny holes in the dentary ornament marks the mandibular canal in NMS 1984.67.64 ( Fig. 7B View Figure 7 ), as do similar openings in Eurynotus (NMS 1957.1.5686; L.C.S., pers. observ.), Amphicentrum ( Coates, 1988) , and Styracopterus (L.C.S., pers. observ.). The rest of the maxilla is ornamented with concentric ridges at the margins (as in NMS 1984.67.65; Fig. 6E View Figure 6 ) and a distinct field of lateralized wavy ridges at the centre of the posterior portion. The angular in Fouldenia is almost completely covered by enameloid patches in fish over 9 cm in total length, such as NMS 1984.67.65, NHM P61002, and NMS 1985.67.64 ( Figs 6F View Figure 6 , 7A, B View Figure 7 , 13C, D View Figure 13 ), yet is naked in smaller individuals.

The gape in all specimens of Fouldenia appears edentulous in lateral aspect. White (1927) described and illustrated small, blunt teeth from the posterior portion of the dermal mandible in NHM P13183 ( Fig. 6A View Figure 6 ). These possess flat, bulbous crowns and thin waists ( Fig. 14 View Figure 14 ), resembling the pediculate dentition of the Palaeozoic actinopterygians Mesolepis ( Traquair, 1879; Boulenger, 1902; Coates, 1988; L.C.S., pers. observ.; Appendix S1), Eurysomus , as illustrated by Traquair (1879: pl. IV; fig. 6.5), and Benedenius , as described by Boulenger (1902). Given the position of these ‘teeth’ in the Fouldenia specimen NHM P13182–3 ( Fig. 6A View Figure 6 ), away from the dentary and just ventral to the palatoquadrate, they are likely associated with coronoid-derived mandibular tooth plates like those found in Styracopterus and other eurynotiform fishes ( Moy-Thomas & Miles, 1971; Coates, 1988; L.C.S., pers. observ.; Appendix S1; Fig. 14 View Figure 14 ).

There is also evidence for an upper jaw dentition obscured from lateral view. In NHM P61549 ( Fig. 6G View Figure 6 ), a homogeneous set of closely situated, small round elements is exposed by a gap in the anterior ramus of the maxilla. In NMS 1984.67.61 ( Fig. 5E View Figure 5 ), tall cylindrical teeth with expanded crowns are found in the same area, with roots attached to what is either the mesial surface of the maxilla or reinforced palatal bones. NMS 1980.40.31 ( Fig. 6D View Figure 6 ) has imprints of tooth or denticle bases overlying an impression of the maxilla and remnants of ganoine ornamentation. These teeth are positioned similarly to the maxillary dentition found in Amphicentrum and Styracopterus , but may also be associated with ectopterygoid-derived tooth plates, as in the same taxa ( Bradley Dyne, 1939; Coates, 1988; L.C.S., pers. observ.; Appendix S1). In light of the mandibular tooth plate denticles in NHM P13183, it is probable that Fouldenia possesses both maxillary teeth and palatal tooth plates ( Fig. 14 View Figure 14 ), but the fossil evidence and/or morphological similarity prevents definite differentiation.

The jaws of Fouldenia are supported by a nearly vertical suspensorium, as reconstructed by Gardiner (1985). The hyomandibula is exposed in a number of individuals of different sizes, including NMS 1980.40.30, NHM P14562, NHM P14564, and NMS 1985.67.64 ( Figs 5A, B View Figure 5 , 6C View Figure 6 , 7B View Figure 7 ). The thick hyomandibula features an expanded dorsal head located near the dermopterotic, as in Amphicentrum ( Bradley Dyne, 1939) , and covered laterally by a teardropshaped dermohyal with an ornament of vertical ridges ( Figs 6G View Figure 6 , 7B View Figure 7 ). Whereas the hyomandibula is nearly straight in smaller specimens (e.g. NMS 1980.40.30; Fig. 1A View Figure 1 ), it exhibits a high degree of curvature in the large individuals listed above.

The preoperculum in Fouldenia , best preserved in NMS 1980.40.30, NHM P13180, NHM P14564, and NHM P61002 ( Figs 5A, G View Figure 5 , 6C View Figure 6 , 7A View Figure 7 ), is tall with an indistinct dorsal arm ending near the skull roof and a thick posteroventral process to the quadratojugal. The anterior margin is shallowly curved, whereas the posterior margin mirrors the hyomandibula and is lined by a wide ridge. A horizontal pit line is visible just above the maxilla in many specimens (e.g. NHM P61002, NHM P13180, NHM P13179, NMS 1956.5.1, and NMS 1985.67.64; Figs 5D, F, G View Figure 5 , 7A, B View Figure 7 ), and bisects the ornament into a ventral field of vertical ridges and a dorsal field of horizontal and inclined lines (see NHM P14564 and NHM P61002; Figs 6C View Figure 6 , 7A View Figure 7 ) .

Opercular series

The operculum of Fouldenia is similar to that reconstructed by White (1927), in that it is slightly inclined with a rounded apex just under the extrascapular and a sigmoidal ventral margin at the level of the horizontal pitline (see NMS 1984.67.64, NHM P13179, NMS 1980.40.30; Figs 5A, F View Figure 5 , 7B View Figure 7 ). The bone is wider and much less tapered in individuals over 8 cm ( Figs 6 View Figure 6 , 7 View Figure 7 ), so that it appears more plate-like than ovoid. The ornamentation consists of intercalated diagonal ridges running posteroventrally, as seen in NHM P61002 ( Fig. 7A View Figure 7 ).

The suboperculum of Fouldenia is largely rectangular in NHM P61002 ( Fig. 7A View Figure 7 ). It extends ventrally to the quadratojugal and posteriorly to the level of the post-temporal. The posterior margin is slightly rounded, whereas the ventral margin is sigmoidal, bearing an anteroventral process reaching towards the jaw joint, as originally illustrated by White (1927; Figs 6E View Figure 6 , 7A View Figure 7 , 13 View Figure 13 ) and also found in other styracopterids, eurynotiforms, and the Palaeozoic taxa listed in the description of Styracopterus (L.C.S., pers. observ.; Appendix S1). Like the other styracopterids (L.C.S., pers. observ.; Appendix S1), the ornamentation of the suboperculum in NHM P13180 ( Fig. 5G View Figure 5 ) and NHM P61002 ( Fig. 7A View Figure 7 ) is divided: the ganoine ridges on the process and near the ventral margin are posteroventrally diagonal, whereas the ornamentation elsewhere radiates horizontally or dorsally from the anterior margin of the bone.

Gulars and branchiostegals

Fouldenia has small leaf-shaped median gular with ventral ornament of concentric bands mirroring the same shape, as revealed by the displaced bones of NMS 1984.67.64 and NHM P61548 ( Fig. 7B, E View Figure 7 ). The morphology of rectangular lateral gulars in NHM P13180, NMS 1984.67.65, and NMS 1984.67.64 ( Figs 5G View Figure 5 , 6E View Figure 6 , 7B View Figure 7 ) is difficult to distinguish from the branchiostegals. The largest individuals of Fouldenia may have up to 12 rectangular branchiostegal rays with rounded distal margins, although no specimen has a complete set ( Fig. 7 View Figure 7 ). The rays increase in length posteriorly and are held at an almost 45° angle to their origin in 10–12-cm fish, as shown by NMS 1984.67.64 ( Fig. 7B View Figure 7 ). This ‘flaring’ is unusual as the branchiostegals are directed inwards towards the ventral midline in most early actinopterygians ( Gardiner, 1984). It might be caused by diagenetic crushing or other taphonomic processes, as all Foulden actinopterygians share this trait ( White, 1927; Moy-Thomas, 1938; Gardiner, 1985; Fig. 17 View Figure 17 ). However, the open positioning of the branchiostegals in these fishes may be induced by a robust clavicle and shoulder girdle, forcing the branchiostegal bases above the ventral body margin ( Gardiner, 1985; L.C.S., pers. observ.; Appendix S1; Figs 5E, B View Figure 5 , 7C, E View Figure 7 , 13C, D View Figure 13 ). It is notable that individuals of Fouldenia under 8 cm in length do not exhibit such flaring, and likewise have more ventrally positioned gapes ( Figs 5C, D View Figure 5 , 13A, B View Figure 13 ).

Shoulder girdle

The inclined, rounded supracleithrum in Fouldenia extends to a pointed margin near the midline of the suboperculum ( Fig. 7B View Figure 7 ). There is no evidence of the course of the posterior lateral line, as it is likely to be obscured by the dense, vertical ganoine ridges spread out around the midline in NHM P61548 ( Fig. 7B View Figure 7 ). Neither White (1927) nor Gardiner (1985) described postcleithra in Fouldenia , but a single postcleithrum is preserved in NMS 1984.67.62, NMS 1984.67.65, NHM P61549, and NHM P13180 ( Figs 5C, G View Figure 5 , 6E, G View Figure 6 ). This is similar to the postcleithra in Paramesolepis ( Moy-Thomas & Bradley Dyne, 1938) , Amphicentrum ( Coates, 1988) , and Styracopterus (L.C.S., pers. observ.; Appendix S1), in that it is long with rounded margins and ends around the first branchiostegal.

The cleithrum in Fouldenia is inclined posteriorly, and bears a broadly crescentic dorsal process with a pointed dorsal limit and a rounded posterior process underlying the pectoral fin insertion. ( Figs 5A, B, E View Figure 5 , 6B View Figure 6 , 7A View Figure 7 ), as in other Foulden actinopterygians ( White, 1927; Moy-Thomas, 1938; Gardiner, 1985; L.C.S., pers. observ.; Appendix S1). The cleithrum is ornamented with vertical stripes of ganoine that mirror the curved posterior margin. A process of the endoskeletal shoul- der girdle is exposed where the cleithrum curves around the point of pectoral fin insertion in NHM P14562 ( Fig. 5B View Figure 5 ) and NHM P61546 ( Fig. 5H View Figure 5 ), and is covered with longitudinal ridges distinct from any nearby dermal ornament. The cleithrum joins with the laterally convex posterior margin of the clavicle at the level of the opercular series in NMS 1984.67.62 ( Fig. 7C View Figure 7 ) and NMS 1984.67.65 ( Fig. 6F View Figure 6 ). The morphology of the clavicle is largely obscured, but it appears very thick (as discussed above) and somewhat triangular in the lateral dimension in NMS 1984.67.61, NHM 1984.67.65, NHM P61002, and NHM P14564 ( Figs 5E View Figure 5 , 6C, F View Figure 6 , 7A View Figure 7 ).

Paired fins

The pectoral fin is situated near the ventral body margin and has a nearly vertical insertion into the shoulder. The fin is supported by at least six radials: posterior/ventral radials preserved in NHM P61002 ( Fig. 8J View Figure 8 ) and NMS 1984.65.61 ( Fig. 8C View Figure 8 ) are elongate, with narrow, somewhat overlapped proximal ends and rounded distal portions. The middle of each radial in NHM P61002 ( Fig. 8J View Figure 8 ) consists of a narrow cylindrical body with a thin ventral flange. GLAHM V8327 ( Fig. 8E View Figure 8 ) shows the squat anterior/ dorsalmost radials, which sit in a shorter space between the primary fin rays and the dermal shoul- der. The presumptive propterygium is surrounded by fin rays, as is diagnostic for actinopterans ( Coates, 1999; Gardiner et al., 2005). The difference in length between the anterior and posterior radials matches the diagonal orientation of lepidotrichial bases in NHM P13183, GLAHM V8327, and NHM P14564 ( Fig. 8F, G View Figure 8 ), an arrangement found in other early actinopterygians such as Mimipiscis ( Choo, 2011) and Styracopterus (L.C.S., pers. observ.; Appendix S1).

As noted by White (1927), no specimen of Fouldenia exhibits a complete pectoral fin, obscuring its exact shape. The proximal fins in GSE 2143, GLAHM V8327, NHM P13183, and NHM P14564 ( Fig. 8A, E, F, G View Figure 8 ) suggest that it was wide-based with a slightly curved anterior margin lined by fringing fulcra that are barely distinguishable from lepidotrichial terminals. The lepidotrichia are thin, cylindrical, and densely packed, with long segments throughout their length. Thus, the pectoral fin more closely resembles that of Phanerosteon ovensi ( White, 1927; L.C.S., pers. observ.; Appendix S1) and the Visean Tarrasius (Sallan, 2012) , than Styracopterus .

Only a handful of specimens have incomplete pelvic fins. The curved anterior edge is preserved in NMS 1984.67.61 ( Fig. 8D View Figure 8 ), with an unsegmented primary fin ray and further lepidotrichia similar to those of the pectoral fin. Large, leaf-shaped fringing fulcra are differentiated from lepidotrichial terminals by linear central furrows. Two large, ovoid basal fulcra overlap the leading edge of the pelvic fin in NMS 1984.67.65 ( Fig. 8I View Figure 8 ). These are ornamented with concentric, longitudinal striations that fuse at the posterior margin. The size of the fin base is restricted by the short distance between the pelvic and anal basal fulcra in all fish, even though the position of the pelvic fin changes with size ( Fig. 13 View Figure 13 ). In the 4-cm individual NMS 1980.40.30, the pelvic fin is situated near the distal pectoral fin, whereas in larger specimens, such as NMS 1984.67.65, it originates posterior to the body midline ( Fig. 8 View Figure 8 ).

Median fins

The dorsal fins in the largest specimens of Fouldenia are as described by White (1927): tall and superficially triangular, with the peak in the posterior half of the fin. In these individuals (e.g. NHM P61548 and NHM P61549; Fig. 9E, F View Figure 9 ), the anterior margin of the dorsal fin and leading lepidotrichia are straight, and the fin originates in the posterior portion of the body ( Fig. 13C, D View Figure 13 ). In the smaller specimens NMS 1980.40.30, NMS 1980.40.27, and NMS 1965.4.3 ( Fig. 9A, B, C View Figure 9 ), the dorsal fin is rounded with curved lepidotrichia held nearly parallel with the body axis, and originates at the midpoint of the trunk, opposite the pelvics and well before the anal fin ( Fig. 13A, B View Figure 13 ). Robust, erect basal fulcra sit against the dorsal lepidotrichia. Disarticulated fulcra in NMS 1980.40.31 ( Fig. 9D View Figure 9 ) exhibit needle-like distal processes with paired cylindrical ridges separated by a deep furrow, bounded ventrally by rounded plates with concentric ornament. The primary dorsal lepidotrichia are thick and unsegmented, presenting a spine-like form when combined with the elliptical fringing fulcra ( Fig. 9 View Figure 9 ). The remaining lepidotrichia have rounded bases and short plate-like segments with cylindrical anterior ridges.

The anal fin in Fouldenia is very similar to the dorsal fin, with the first few lepidotrichia likewise consolidated into ‘spines’, a feature readily apparent in NMS 1965.4.3 ( Fig. 10C, D View Figure 10 ). Anal basal fulcra in NMS 1984.67.62 and NHM P61548 ( Fig. 10I, J View Figure 10 ) are evocative of their dorsal equivalents and those of Styracopterus (see above). However, more anterior basal fulcra in this series of four or five are thick and rounded like the dorsal ridge scales. The anal fin base extends to the base of the caudal peduncle. Like the dorsal fin, the anal fin is rounded in smaller specimens such as GSE 2187 ( Fig. 10B View Figure 10 ) and NHM P13183. The anterior margin remains curved in the largest fishes, whereas the posterior margin is deeply concave (e.g. NHM P13183), resulting in a superficially half-crescent form in NHM P61548 ( Fig. 10J View Figure 10 ).

Tail and caudal fin

The caudal region of Fouldenia comprises over a third of the total body length in the smallest specimens (e.g. NMS 1980.40.30; Figs 11A View Figure 11 , 13A View Figure 13 ) and a quarter in the largest (e.g. NHM P61549; Figs 12D View Figure 12 , 13D View Figure 13 ). As described by White (1927), the tail consists of a thick caudal peduncle, a deep yet shallowly cleft caudal fin, and a very long, tapering axial lobe extending beyond the fin. The dorsal surfaces of the peduncle and axial lobe are covered by enlarged basal fulcra that, as preserved in NHM P13183 and holotype NHM P13178 ( Fig. 12A, B View Figure 12 ), are identical to the dorsal fin basal fulcra in NMS 1980.40.31 ( Fig. 9D View Figure 9 ). The posteriormost basal fulcra on the ventral surface of the peduncle in NMS P13183 ( Fig. 12A View Figure 12 ), originally illustrated by White (1927), are nearly mirror images, except that the paired rami separate to form distinct points distally ( Fig. 12A View Figure 12 ), and are thus narrower versions of the same scales in Styracopterus . More posterior basal fulcra on both the peduncle and axial lobe are progressively shorter and have pointed apices, providing a highly overlapped, elliptical appearance in lateral view ( Figs 11 View Figure 11 , 12 View Figure 12 ).

Prominent fringing fulcra line the entire ventral margin of the caudal fin in NMS 1965.4.2, NMS 1965.4.3, NMS 1980.40.31, and NHM P13185 ( Figs 11A, F View Figure 11 , 12C, E View Figure 12 ). These are also elliptical, slightly overlapped, and sit perpendicular to the lepidotrichia. Fulcra appear as narrow spines with longitudinal furrows on the base of the axial lobes in NHM P13183 and NMS 1965.4.2 ( Figs 11C View Figure 11 , 12A View Figure 12 ), becoming smaller and more inclined distally in GSE 2187, NMS 1965.4.3, and NHM P13185 ( Figs 11C, F View Figure 11 , 12E View Figure 12 ). Fulcra in the second half of the series are paired in larger specimens ( Fig. 12 View Figure 12 ), a trait previously reported only in Cheirolepis ( Gardiner, 1984) , but also found along the distalmost tails of Styracopterus , Aesopichthys , and other Foulden fishes (L.C.S., pers. observ.; Appendix S1). In fact, all the axial lobe fulcra are paired in smaller, probably juvenile individuals with relatively shorter axial lobes, such as NHM P13187, NMS 1965.4.2, and NMS 1980.40.27 ( Fig. 11B, C, E View Figure 11 ), suggesting fusion during ontogeny in Fouldenia and perhaps other actinopterygians. The large specimens NMS 1980.40.31 and NHM P13185 ( Fig. 12C, E View Figure 12 ) are the only individuals with complete axial lobes, which lack fulcra distal to the caudal fin. This arrangement is similar to that of the elongated axial lobe in the deep-bodied Serpukhovian genus Aesopichthys ( Poplin & Lund, 2000; L.C.S., pers. observ.; Appendix S1), as well as other styracopterids and Eurynotus (e.g. NMS 1878.18.12; Traquair, 1879; L.C.S., pers. observ.; Appendix S1).

Both NMS 1980.40.31 and NHM P13185 ( Fig. 12C, E View Figure 12 ) bear remnants of a distinct epichordal fin around the distalmost tail. Lepidotrichia found along the ventral surface of the posteriormost axial lobe differ from the caudal lepidotrichia in their tapering morphology, and originate after a considerable gap.

The first few lepidotrichia of the caudal fin are consolidated and bear elongated fringing fulcra like their equivalents in the median fins ( Figs 11 View Figure 11 , 12 View Figure 12 ). Likewise, the remaining rays in the ventral lobe have plate-like segments with anterior ridges and taper to a point ( Figs 11 View Figure 11 , 12 View Figure 12 ). The bases of ventral lobe lepidotrichia are distinctly thick and wide in NHM P61548 ( Fig. 12 View Figure 12 ), giving the appearance of an extended peduncle. Lepidotrichia in the dorsal lobe originate from the axial lobe in NHM P13185, NHM P61549, and NMS 1980.40.31, and are similar to the paired fin rays in their thin, cylindrical morphology. These apparently lack bifurcation, although most are truncated at their distal extremities.

The overall appearance of the tail and caudal fin varies between size classes. Small individuals have long peduncles that exhibit a gradual, not well marked, transition into a thin axial lobe ( Figs 11 View Figure 11 , 12 View Figure 12 , 13A, B View Figure 13 ). Their long caudal fins exhibit shallow clefts and small, narrow fringing fulcra. In contrast, the largest individuals, such as NHM P61548 and NHM P13183 ( Fig. 12E, F View Figure 12 ), have tall peduncles with nearly vertical posterior margins and a marked transition into a wide-based, distally tapering axial lobe. Caudal fins have deep clefts and are equilobate, and feature robust fringing fulcra. The terminus of the lateral line changes along with the morphology. In the 5-cm individual NMS 1965.4.2 ( Fig. 11C View Figure 11 ), the lateral line curves parallel with the posterior margin of the caudal peduncle as it approaches the end of the body, turning onto the midline of the axial lobe. In the 12-cm fishes NHM P13185 and NHM P61548 ( Fig. 12E, F View Figure 12 ), the lateral line is largely horizontal, and appears to end on the caudal fin just ventral to the base of the axial lobe, but may continue at the caudal fin base.

Squamation

The largest individual of Fouldenia, NHM P 61548 (~ 12 cm EBL), has 51 sigmoidal scale rows from the skull to the peduncle, with up to 34 scales from the dorsal ridge to the anal midline. However, individuals under 6 cm in length have significantly fewer scales: NMS 1965.4.2 (5 cm EBL) has approximately 34 rows of up to 25 scales. The slightly longer NMS 1965.4.6 (5.5 cm EBL) has around 40 rows, whereas NMS 1980.40.27 (6.5 cm EBL) had almost the maximum number of rows, although the number of scales per row remains at 25. The larger NMS 1984.67.61 (7.5 cm EBL) has 30 scales per row at maximum body depth. Fish of 8–9 cm in total length, such as NHM P61002 and NMS 1984.67.63, have approximately the same counts as the largest specimen. Thus, scale counts increase with body size primarily through the generation of rows up to the midpoint of the observed growth series, at which point addition at the margins and increases in scale height cover changes in body area.

In smaller specimens of Fouldenia , such as GSE 2143 (3 cm EBL), NMS 1980.40.30 (4 cm EBL), NMS 1965.4.6 (5.5 cm EBL), NHM P14562 (6 cm EBL), and GSE 2187 (6 cm EBL), all scales are small and acuminate, with smooth margins ( Fig. 14A, B View Figure 14 ), and bear two longitudinal bands of smooth ganoine. These are identical to the scales found on the smallest specimens of the co-occurring Aetheretmon (NHM P61006; L.C.S., pers. observ.). Like Aetheretmon , the smallest Fouldenia individuals, such as NMS 1980.40.30 ( Fig. 9A View Figure 9 ), lack scales around the bases of their median fins. This suggests that squamation first developed around the lateral line in these fishes, just as it does in living teleosts ( Koumoundoros, Divanach & Kentouri, 2001).

Juvenile scales develop near the dorsal and ventral midlines and are retained on the posterior half of specimens NMS 1965.4.3, NMS 1984.65.61, and NMS 1956.5.1, which range from 7 to 7.5 cm in estimated body length, and have greater body depths anteriorly ( Fig. 13C View Figure 13 ). In individuals over 8 cm in length [e.g. NHM P13178 (9 cm EBL), NMS 1984.67.65 (9.5 cm EBL), NHM P61502 (10 cm EBL), NMS 1984.67.65 (11 cm EBL), and NMS 1984.67.65 (11 cm EBL); White 1927; Fig. 13C View Figure 13 ], ‘juvenile’ scales are limited to an anterior ventral field around the pectoral fins and clavicle. The largely scaleless actinopterygian Phanerosteon (e.g. NMS 1970.26.27; L.C.S., pers. observ.; Appendix S1), found at both Foulden and Glencartholm, exhibits rows of small scales in the same area ( White, 1927; Gardiner, 1985). Scale rows in this region in Amphicentrum and Benedenius have a different orientation from those on the rest of the flank ( Traquair, 1878, 1879; L.C.S., pers. observ.; Appendix S1). This anterior ventral field (or pectoral peduncle; Sire & Arnulf, 1990) might represent a distinct region of scale development in some early actinopterygians, just as it does in some living teleosts ( Koumoundoros et al., 2001).

In individuals larger than 8 cm in length, such as NMS 1984.65.61 and NHM P13182 ( Fig. 13C, D View Figure 13 ), rhomboid scales on the anterolateral flank have smooth margins and exhibit four or more posteroventrally diagonal bands of ganoine. The scales in larger fish (e.g. NHM P61546) are taller and feature a more complex ornament of diagonal ganoine bands that fuse in nested fashion towards the posteroventral corner and a stripe lining the posterior margin. This ornamentation is repeated vertically on the taller, more rectangular anterior flank scales of the larger specimens. A small notch on the posterior margin marks the transition between ornamentation fields, giving the bilobate appearance described by White (1927) and the impression of scale fusion.

Scales on the posterior flank of fish over 8 cm (e.g. GLAHM V8327 and NHM P13182) are shorter and horizontally elongated ( Fig. 13C, D View Figure 13 ), yet exhibit a rhomboid shape and ornamentation similar to the more anterior squamation. In specimens over 10 cm in total length, these scales have the same relative height and morphology as anterior flank scales in 8-cm fish ( Fig. 13C, D View Figure 13 ). In large specimens of Fouldenia , the lateral line scales are taller than other members of the same row, but are otherwise indistinguishable apart from a raised cylindrical bump that bisects the ornament horizontally ( Fig. 13C, D View Figure 13 ). The lateral line runs from the level of the supracleithrum to the midline of the caudal peduncle in the largest specimens ( Figs 12F View Figure 12 , 13D View Figure 13 ). The diverse flank scales in Fouldenia are similar in shape and ornament to various iterations in the Permian taxon Acrolepis sedgwicki Agassiz, 1833 –1844, as first illustrated by Agassiz (1833 –1844; NHM P553; L.C.S., pers. observ.; Appendix S1), which is a large marine fusiform actinopterygian that diverges from Fouldenia in most other non-plesiomorphic traits.

All specimens over 8 cm in length possess a distinct ‘hinge line’ in the peduncle squamation, marking the transition between scales with vertically directed pegs and those with posteriorly directed pegs, a trait found in many other early actinopterygians ( Patterson, 1982; Gardiner & Schaeffer, 1989; Coates, 1998, 1999; Figs 12F View Figure 12 , 13C, D View Figure 13 ). Peduncle rows on both sides of the hinge line contain small rhomboid scales fully covered in ganoine and featuring an anterior ridge ( Figs 12D View Figure 12 , 13C, D View Figure 13 ). These resemble the microsquamation present on the entire tail surface of Tarrasius (Sallan, 2012; L.C.S., pers. observ.; Appendix S1). Scales on the proximal axial lobe and along the base of the caudal fin are diamond shaped, whereas the more distal squamation consists of very small elliptical scales resembling the ‘juvenile’ flank scales ( Figs 12D View Figure 12 , 13 View Figure 13 ).

Fouldenia specimens over 8 cm in length possess prominent dorsal ridge scales that run from the nape to the dorsal fin basal fulcra ( White, 1927; Fig. 13C, D View Figure 13 ). They are highly overlapped: each has a triangular furrow on the anterodorsal surface to hold the distal end of their neighbour. The anteriormost ridge scales are squat with rounded margins and slightly pointed apices, and feature longitudinal striations. Ridge scales in the posterior half of the series are longer, wider, and vertically oriented, and exhibit more robust ornamentation. The last few ridge scales are thinner and have distal processes like the dorsal basal fulcra, and are similarly erect and overlapped. Thick ganoine ridges on these scales run parallel with the body axis. Thus, the transition between the last two dorsal ridge scales, the basal fulcra, and the primary lepidotrichia appears gradual ( Fig. 13C, D View Figure 13 ).