Euthacanthus macnicoli Powrie, 1864

Newman, Michael J., Burrow, Carole J., Den Blaauwen, Jan L. & Davidson, Robert G., 2014, The Early Devonian acanthodian Euthacanthus macnicoli Powrie, 1864 from the Midland Valley of Scotland, Geodiversitas 36 (3), pp. 321-348 : 326-346

publication ID

https://doi.org/ 10.5252/g2014n3a1

DOI

https://doi.org/10.5281/zenodo.4822661

persistent identifier

https://treatment.plazi.org/id/03AE87E0-8023-C106-22C8-FD6D396EFBE0

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Felipe

scientific name

Euthacanthus macnicoli Powrie, 1864
status

 

Euthacanthus macnicoli Powrie, 1864

( Figs 1-19 View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG View FIG )

Euthacanthus macnicoli Powrie, 1864: 425 , pl.20, fig. 2; 1870: 290, pl. 11, figs 3, 3a, 3b; 1881: 169. — Anonymous 1867: 7, fig. 1. — Barkas 1874: 550. — Traquair 1892: 33. — Dean 1907: 216, figs 23, 36. — Watson 1937: 61, figs 3, 4, pl. 7, figs 1, 2. — Adams & Eddy 1949: fig.11. — Lehman 1959: fig. 22. — Heyler 1969b: 59, figs 1, 20. — Miles 1970: 362. — Moy-Thomas & Miles 1971: figs 4.2, 4.6. — Miles 1973: 183, fig. 36, pl. 15, fig. 1. — Paton 1976: 7. — Jarvik 1977: 212, fig. 11B. — Denison 1979: 27, figs 4A, 10A, 11A, 17C. — Young 1995: 66, fig. 5.

Euthacanthus grandis Powrie, 1870: 292 , pl. 12, fig. 6; 1881: 169. — Barkas 1874: 550. — Traquair 1892: 33.— Gunther 1904: 312. — Miles 1970: 362. — Paton 1976: 6.

Climatius grandis – Woodward & Sherborn 1890: 36, 81. — Woodward 1891: 31. — Dean 1907: 218, fig. 30. — O’Connell 1916: 90.

Climatius macnicoli – Woodward & Sherborn 1890: 36, 81. — Woodward 1891: 30. — O’Connell 1916: 90. — Graham-Smith 1936: 596.

Euthacanthus – Traquair 1894: 257. — Hay 1902: 274. — Heyler 1969a: 40, 42, 43, 49.— Halstead 1969: fig. 17a. — Moy-Thomas & Miles 1971: 61, 69, 70, 71. — Long 1986: 336, fig. 10. — Frickhinger 1991: 239.— Janvier 1996: 177. — Trewin & Davidson 1996: 233, 241. — Benton 1997: fig. 3.14b. — Prothero 1998: fig. 17.23.— Wilson & Anderson 2004: 171. — Hanke & Wilson 2006: 534, 535. — Miller 2007: 994. — Park & Gierlowski-Kordesch 2007: 165. — Brazeau 2009: fig.3. — Franz-Odendaal 2011: 394. — Hanke & Davis 2012: 480, fig. 7A, B.— Davis et al. 2012: fig.4. — Zhu et al. 2013: fig. 6.

Euthacanthus mitchelli – Goodchild 1904: 597. — O’Connell 1916: 90, 175.

Euthacanthus macnicolli [sic] – Moy-Thomas 1939: fig. 8A. — Frickhinger 1991: 239, fig. caption.

Euthacanthus macnicoli – Burrow & Young 1999: 10. — Gagnier et al. 1999: 93. — Dineley 1999: 159, figs 5.6B, C, 5.8C. — Davidson & Newman 2003: 244.— Hanke & Wilson 2004: 189. — Valiukevičius & Burrow 2005: 636. — Hanke & Davis 2008: 318; 2012: 480, 482. — Newman et al. 2011: 101; 2012: 740. — Brazeau 2012: 356.

TYPE SPECIMEN. — NMS G.1891.92.231 and the counterpart NHM P.1337 (near complete specimen missing the snout).

REFERRED SPECIMENS. — Over 50 articulated or partial articulated specimens have been identified by the authors in public museums and private collections. The largest collection of specimens is in the National Museums of Scotland. Furthermore , many hundreds of specimens consisting of disarticulated fin spines and scales have been observed by the authors ; in this state of preservation the species could be considered common. Apart from the holotype, studied specimens include: from Turin Hill, NMS G.1881.5.60, NMS G.1885.54.6B, NMS G.1887.35.6A, NMS G.1891.92.236, NMS G.1891.92.238, NMS G.1891.92.275, NMS G. 1967.12.5 ; from Tillywhandland, NHMP.67308, NMS G.2007.24.2, NMS G.2010.7.39, NMS G. 2010.7.41, NMS G. 2010.7.42, NMS G.2010.7.43, NMS G. 2013.8.1, QMF57175, QMF57176 ; from Duntrune, NMS G.2002.59.97, NMS G.2002.59.100 ; from Balruddery Den, NMS G.2011.33.1 .

TYPE LOCALITY. — Tillywhandland Quarry (National Grid reference NO 528 537) near Forfar, Scotland. Tillywhandland Quarry is part of the Turin Hill complex of quarries and it is thought that most specimens recorded as coming fromTurin Hill were collected there ( Trewin & Davidson 1996).

STRATIGRAPHIC HORIZON AND AGE. — Upper part of the Arbuthnott Group of the Lower Devonian (Lochkovian) of the Strathmore Region of Scotland.

OCCURRENCE. — Tillywhandland; Balruddery Den (National Grid reference NO 314 325) and Duntrune Quarry (National Grid reference NO 438 352) both just north of Dundee, Scotland.

REVISED DIAGNOSIS. — Euthacanthus with large polygonal tesserae covering the dorsal surface of the head forward of the hyoid region; five circumorbital plates with the uppermost plate being largest, and ornamented with sinuous radiating nodose ridges; at least two external nares surrounded by small plates; small scales cover the cheek region; at least seven closeset branchiostegal plates above the angle of the jaw and five or more closeset branchiostegal plates below the angle of the jaw that cover the anterior branchial region; branchiostegal plates have an ornament comprising both short inclined or conical tubercles and long subparallel sinuous ridges; three subsidiary gill covers posterodorsal to these plates; scapula shaped like an inverted letter T with a smooth and straight lower edge; paired ventral postbranchial plates spine-shaped, ornamented with apically-directed nodose ridges on the lateral side and irregular tubercles medially; posterior dorsal fin spine is approximately opposite the anal fin spine; leading edge ridge on fin spines is fully rounded, with lateral ridges having a gently curving upper surface separated by a sharp edge from a lower/posterior surface curving steeply down into the groove; scales have subparallel deep grooves and ridges at the anterior end of the crown with the number of grooves ranging between five to twenty depending on the size of the scale; scales along the lateral line are the same size as normal flank scales; scale crowns comprise superposed growth zones with wide radial, ascending and circular vascular canals, Stranggewebe filling the primordial and posterior parts of the crown growth zones, and simple mesodentine filling the anterior parts of the growth zones; scale bases are slightly convex and formed of cellular bone with simple Sharpey’s fibres extending from the base apex to the lower surface of the base.

DESCRIPTION

General features

Of the fifty or more articulated specimens known, nearly all are laterally compressed apart from NMS G.1891.92.275 (only the front third is preserved) and NMS G.2007.24.2, which are dorsoventrally compressed, and NMS G.1891.92.238, which is ventrodorsally compressed. NMSG.2002.59.100 is compressed laterally although the head has twisted to show it in a ventral view. Collection specimens vary in size from 100 mm to an estimated 450 mm long (based on isolated large fin spines and an articulated specimen c. 430 mm long in the private collection of Roger Jones of Geneva). The holotype ( NMS G.1891.92.231; Fig. 3A View FIG ) differs slightly from most other specimens in being more slender, with Duntrune specimen NMS G.2002.59.97 ( Fig. 3B View FIG ) representing the average body shape. The species is fusiform with a maximum depth to length ratio of about 0.2. There are four (e.g., NMS G.2002.59.97) or five prepelvic fin spines (e.g., NMS G.1891.92.231). Watson (1937: 65) stated that one specimen he observed (he did not say which one) had six prepelvic fin spines on one side of the fish, but we have not seen any such specimens and suspect this is a misinterpretation or a pathological aberration rather than a general character. The posterior dorsal fin spine is oppo- site or nearly opposite the anal fin spine, and the anterior dorsal fin spine is positioned far behind the level of the pectoral fin spines, opposite the midpoint of the prepelvic fin spine series .

Head and branchial region

Many specimens show elements of the head but they are usually disarticulated and poorly preserved. Some of the best preserved examples are the holotype NMS G.1891.92.231 ( Fig. 4A View FIG ) and NMS G.1891.92.236 ( Fig. 4B View FIG ) from Turin Hill, NMS G.2002.59.97 ( Fig. 4C View FIG ) from Duntrune and NMS G.2011.33.1 ( Fig. 4D View FIG ) from Balruddery. The ventral surface of the body is exposed on NMS G.1891.92.238 ( Fig. 5A View FIG ), but the jaws appear to have been lost exposing the inner surface of the tectal squamation and sclerotic bones, and a visceral view of the pectoral region. NMS G.1891.92.275 ( Fig. 5B View FIG ) from Turin Hill shows the head and branchial region preserved in dorsal view, and on NMS G.2007.24.2 ( Fig. 5C View FIG ) from Tillywhandland, the head is exposed in dorsal view. NMS G.2002.59.100 ( Fig. 5D View FIG ) from Duntrune is a rare specimen showing the branchial region and some of the head preserved in ventral view. Whereas Watson (1937) stated that the neurocranium and visceral skeleton were unossified and never preserved, we note that at least some elements of the endocranium and visceral skeleton were composed of globular calcified cartilage globules, preserved in situ on rare articulated specimens (e.g., NMS G 1967.12.7) and as patches visible in some thin sections and scattered amongst the dermal structures (e.g., NMS G.2010.7.39). On NMS G. 1967.12.7 ( Fig. 6A View FIG ), the upper and lower jaws are preserved by granular mineralization of the cartilages. The lower jaws have dropped off most specimens before burial, as is common with most LORS acanthodians ( Burrow et al. 2013). Teeth are absent from both the upper and lower jaw.

Large dermal bones are only present in the orbital and branchial regions. The eyes are very far forward, with a ring of five robust bones of which the most dorsal one is markedly larger than the others ( Figs 4A, D View FIG ; 5C View FIG ). The bones are convex radially as well as laterally and ornamented with noded sinuous ridges that sometimes bifurcate. There are no sensory lines present on any of the orbital bones and, contra Watson (1937), these are interpreted as sclerotic rather than circumorbital bones (see Burrow et al. 2011).

Euthacanthus macnicoli has a very blunt snout terminating just in front of the orbits ( Fig. 5A, C View FIG ). Two circular objects preserved as impressions behind the eyes on NMS G.1891.92.238 ( Fig. 5A View FIG ) could represent the otic capsules.

Th e dorsal surface of the head is covered with dermal tesserae circa 0.5 mm wide in between the main lateral lines, and larger, more polygonal tesserae c. 1.0 mm anteriorly as shown in NMS G.1881.5.60 ( Fig. 7 View FIG ) from Turin Hill. In the cheek region between the orbits and the branchial chamber are small scales that progressively decrease in size from the ventral anterior to the posterior dorsal. Th is area is particularly well preserved in NMS G.2007.24.2 ( Fig. 5C View FIG ), with scales aligned in posteroventral to anterodorsal rows. Th e posterior dorsal cheek region abuts the subcircular mandibular operculum (sensu Watson 1937), which is covered with small rod like scales that are larger than the scales of the cheek region. Th e rest of the relatively long branchial region is well preserved on a number of specimens, and was described in detail by Watson (1937). Th e anterior branchial region has a dermal cover comprising up to 25 slender plates. Following the designation of Hanke & Wilson (2004), these are divisible into a series above the angle of the jaw and another series below the angle of the jaw; the widest and longest rays are those near the jaw articulation. Th ese robust dermal plates appear smooth on the holotype; Watson (1937) described these elements as unornamented, but we suggest that his description was based on specimens in which the outer layer was lost when the specimen was split and/or he was looking at the smooth internal surfaces, as ornament is visible on several other articulated specimens (e.g., Fig. 5D View FIG ). Th e ornament consists of tubercles and long sinuous ridges running subparallel to the edges of the branchiostegal plates, giving them a rugose surface. Th e tubercles are irregular in form, with some being conical and forming short rows such as on QMF57175 and QMF57176 ( Fig. 6B, C View FIG ), and others short and inclined as on disassociated plates in the acidprepared regurgitate/coprolite NHM P.67308 ( Fig. 6D View FIG ). Th e branchiostegal rays become much thinner on the ventral side of the fish in the gular region, as exemplified on NMS G.1891.92.238 ( Fig. 5A View FIG ) which is preserved ventral side up. Th is specimen also shows separate areas of thinner rays oriented obliquely across each side between the branchiostegal series. Possibly when the jaws fell off the specimen, the skin and gular rays remained behind but were flipped backwards. As noted by Watson (1937), there are three well-defined postopercular branchial arches. In NMS G.1891.92.231 ( Fig. 4A View FIG ) and NMS G.1891.92.236 ( Fig. 4B View FIG ) the gill septa are covered by a series of moderately long, narrow rods that curve posteriorly at their ventral ends. Additional rods are inserted between the upper ends of these rods before the curvature, creating a narrow gill cover. Th ese subsidiary gill covers are better preserved in NMS G 1891.92.238 ( Fig.5A View FIG ), NMS G.2011.33.1 ( Fig.4D View FIG ) and NMS G.2002.59.100 ( Fig. 5D View FIG ). In these specimens the rods are positioned more horizontally and are closer packed, forming a continuous covering. On NMS G.2002.59.100 ( Fig. 5D View FIG ), the small specimen with ventral surface exposed, both the pectoral fin spines and the postbranchial spinose plates are preserved in position. Th e rods and plates of the first and second subsidiary gill covers extend down to the edge of the postbranchial plate; all three posterior gill slits are of equal length, but the posteriormost subsidiary gill cover is shallower than the other two.

Th e sensory lines on the head are preserved as a gap between rows of rod-like scales or plates ( Fig. 5B, 5C View FIG ), and their layout was well described by Watson (1937: fig.3, pl. 7, fig. 2). However, we consider that the structures that Watson labelled as mandibular canal, oral canal and supramaxillary are probably not sensory lines, but the outlines of the jaw cartilages ( Fig. 6A View FIG ). We still recognize a preopercular canal that more or less follows the upper edge of the palatoquadrate.

Pectoral region

A pair of robust triangular plates with a spinose projection are positioned anteromedially to each of the pectoral fin spines ( Fig. 5C, D View FIG ). Watson (1937: fig. 4B) referred to these structures as antero-lateral pectoral dermal bones. Their lateral ornamentation comprises broad tubercles that run in rows to the apex and coalesce in places into ridges, with these ridges becoming finer towards the spine tip ( Figs 4B View FIG ; 8A View FIG ). The medial surfaces of these “plates” are also ornamented, with more irregularly placed tubercles ( Fig. 8B View FIG ). Miles (1973) described the structures as pinnal plates and interpreted the spine projection as prepectoral spine three, and also stated that the posterolateral edge of the plate was bevelled as in Parexus Agassiz, 1845 and Vernicomacanthus . Although characterized as a spine-bearing plate, its preservation in the dorsoventrally compressed specimens ( Figs 5A, D View FIG ) and ornamentation on both sides show that it was more spine-like than plate-like in life, projecting down from the body of the fish. Their preservation sometimes between the pectoral fin spines suggests that these plates could be admedian rather than prepectoral structures, but as the plates are usually displaced we are not certain of their homology and continue referring to them as prepectoral plates.

The scapulocoracoid is a simple structure comprising a columnar scapular shaft expanding sharply to a triangular area with a flat lower edge articulating with the base of the pectoral fin spine ( Fig.8C, D View FIG ).

Figure 9 View FIG is a new reconstruction of the head, branchial and pectoral regions of Euthacanthus macnicoli in lateral view, based on Watson (1937: fig. 4) and incorporating our reinterpretation of some of the morphological features.

Fin spines

In general the fin spines are of moderate length and thickness with short bases. From splitting of the fish-bearing blocks, the fin spines are often fractured lengthwise showing the cores rather than the surface ornament. Where the ornament is preserved, it consists of smooth, longitudinal ridges and deep grooves ( Fig.10A, B View FIG ). The grooves terminate along the leading edge toward the tip of the spine. The posterior dorsal fin spine ( Fig. 10A View FIG ) is longest, with c. seven ridges and grooves on each

The Early Devonian acanthodian Euthacanthus macnicoli Powrie, 1864 from the Midland Valley of Scotland

inner lamellar bone layer; I, thin section towards the distal end of the spine, showing tissues between the small central cavity and groove on the outer surface, with vascular canals and bone cell lacunae with cell processes of middle osteodentine layer. Abbrevia- tions: ad.fs, anterior dorsal fin spine; cc, central cavity; p.fs, pectoral fin spine; pd.fs, posterior dorsal fin spine; ppv.fs, prepelvic fin spine; pv.fs, pelvic fin spine. Scale bars: A-C, 10 mm; D, E, I, 0.05 mm; F, G, 0.25 mm; H, 0.1 mm.

side of the straight fin spine. The anterior dorsal fin spine is only slightly shorter, with c. five ridges and grooves on each side of the spine. The anal fin spine ( Fig. 10B View FIG ) is slightly shorter than the anterior dorsal fin spine, straight, and quite thin, with four or five ridges and grooves on each side of the fin spine. The pectoral fin spine ( Fig. 10C View FIG ) is slightly curved, shorter than the anal fin spine, with a rela- tively long base compared with the other fin spines, and usually having six ridges and grooves on each side of the spine. The pelvic fin spines ( Fig. 10C View FIG ) have four ridges per side, are a similar length to the pectoral spines, and are about twice as long as the largest prepelvic fin spine. The prepelvic spines ( Fig. 10C View FIG ) decrease in length towards the anterior. Four ridges and grooves on each side of the spine converge at the tip, and the spines are strongly laterally compressed and slightly curved.

Thin sections through the anal and posterior dorsal fin spines on NMS G.2010.7.42 ( Figs 10 View FIG D-I; 11) show variations in the cross-sectional shape of the ridges and infilling of the central pulp cavity between the base and the tip. Near the tip, the ridges are sharp-crested ( Fig.10D View FIG ), becoming more rounded toward the base ( Fig. 10F View FIG ); the pulp cavity is wholly infilled by bone ( Figs 10D, I View FIG ; 11 View FIG ) at the distal end, and wide open toward the spine base. Through most of the length of the spine, a dense lamellar layer lines the inner surface ( Fig. 10E View FIG ), overlain by thick osteodentine that extends into the ridges ( Figs 10H View FIG ; 11 View FIG ). Only a thin outer layer is devoid of the wide vascular canal network penetrating the spine.

Squamation

The caudal fin shows a similar pattern to that of Acanthodes described by Heyler (1969a, b) and expanded on by Miles (1970). The notch on the tail of Watson’s (1937: fig. 4A) reconstruction is a preservational artifact caused by the separation of zone Z2 from Zone Z2”. The only difference between Miles’s (1970: fig. 7) reconstruction of the tail zonation of Acanthodes and that of Euthacanthus macnicoli ( Fig. 12 View FIG ) is a further subdivision being present in the latter at the anterior end of the hypochordal lobe, which has scales which are notably larger than the surrounding scales. Miles (1970) also noted this feature in the Early Devonian acanthodians Ischnacanthus gracilis (Egerton, 1861) and Mesacanthus mitchelli (Egerton, 1860) , as did Dean (1907) in the Early Devonian acanthodian Parexus recurvus Agassiz 1844 . Later, Miles (1973: text-fig. 3) described the same condition in Early Devonian acanthodian Ptomacanthus anglicus Miles, 1973 and denoted this Zone Z3”. Zone Z1 consists of scales of the caudal prolongation of the trunk and are typical body scales. Zone Z3 and zone Z4 are separated only by a transitional boundary, with Zone Z4 having smaller scales than Zone Z3. Zone Z2 consists of a thin strip of scales on the dorsal edge of the tail. Zone Z2 has a 45 degree rotation of enlarged scales in comparison to zone Z1. This rotation is reversed in Zone Z2” where the scales are much smaller than in Zone Z1.

Miles (1973: pl. 15, fig. 1) described lepidotrichia-like scale rows on a pectoral fin web of NMS G.1971.38. This specimen was assigned by Miles (1973) to Euthacanthus sp. but belongs in the species Euthacanthus macnicoli as there is a large portion of the body trunk preserved, but no sign of the enlarged lateral line scales that characterize Euthacanthus gracilis ( Newman et al. 2011) . Other specimens of E. macnicoli show the same character, e.g., NMS G.1891.92.240.

Scales

The scales range in length from 0.5-2 mm. The crown is ornamented with deep furrows and ridges leading back from the anterior edge. On moderate sized individuals such as NMS G. 2013.8.1 ( Fig.13A View FIG ) from Tillywhandland, normal flank scales show only slight morphological variation over the length of the body. Scales in the pectoral and anterior dorsal region consistently have four strong parallel ridges running the full length of the crown ( Fig. 13B View FIG ). Mid-body scales also have four ridges, but these are less robust and fade out past the centre of the crown ( Fig. 13C View FIG ). Mid-flank scales between the posterior dorsal and anal fin spines have only two or three short, weakly developed ridges, with shallow grooves between them ( Fig. 13D View FIG ). Scales mid-tail are almost smooth, with only two very weak short ridges anteromedially on the crown ( Fig. 13E View FIG ).

The thin sections made from NMS G. 2013.8.1 ( Fig. 14 View FIG ) show that all the normal body scales have three to five crown growth zones, with Stranggewebe (sensu Gross 1971: mesodentine comprising parallel tubules extending between vascular canals) filling the primordial and posterior parts of the crown growth zones, and simple mesodentine filling the anterior parts of the growth zones. Growth zones are not visible in the base; rounded to oval bone cell lacunae are relatively densely and evenly distributed through the base of all scales, and simple Sharpey’s fibres extend from the base apex to the lower surface of the base. Wide radial, circular and ascending vascular canals form a network throughout the crown, with the ascending canals extending back below the crown surface grooves. Scales in the pectoral and anterior dorsal regions have a relatively flat base ( Fig. 14 View FIG A-E), midbody scale bases are slightly more convex ( Fig. 14 View FIG F-H), and caudal scales have the most convex bases ( Fig.14 View FIG I- N). The scale structure conforms to the Nostolepis sensu stricto type as defined by Valiukevičius & Burrow (2005).

NMS G.2010.7.42 is the articulated tail, plus dorsal and anal fin spines ( Fig. 15A View FIG ) from a fairly small individual from Tillywhandland. All scales on sectioned blocks ( Fig. 15 View FIG B-E) and from acid residues ( Fig.15 View FIG F-M) show very similar morphology, being short, rhombic and 0.1-0.2 mm wide and long, with two strong parallel ridges running back from the anterior edge, fading out near the middle of the crown. Occasionally a third, weaker ridge is developed lateral to the central ridges; the ridges become lower on scales closer to the tail tip ( Fig. 15 View FIG D-E). The lateral parts of the crown plane are flat and smooth, and the lateral edges meet at a single posterior point which extends slightly beyond the posterior corner of the base. The scale neck is concave and relatively deep, with two or three large vascular canal openings on each of the four sides. The base is low and slightly concave. Histological sections through scales on the specimen ( Fig.15 View FIG N- P) show a small fin web scale with a wide pulp cavity in the primordium and a highly concave base ( Fig.15N View FIG ), and a caudal scale and two similar scales abutting a fin spine showing three crown growth zones, Strangewebbe and wide vascular canals in the crown, and a flat base ( Fig. 15O, P View FIG ).

For the large partial articulated specimen NMS G.2010.7.39 ( Fig. 16 View FIG ), flank scales show a wide range of size and crown ornament, with scales up to 1.8 mm wide. The smaller scales ( Fig. 16A, B View FIG ) are identical to those of average sized Euthacanthus macnicoli such as NMS G. 2013.8.1 and NMSG.2010.7.42 (described above). On the scales with three or more ridges, some of the ridges bifurcate near the anterior edge of the crown ( Fig.16 View FIG C- O). The anterior edge is sharp on most scales, only rarely rounded ( Fig. 16 View FIG I-J). Large scales have up to 12 ridges running back from the anterior edge of the crown, with the ridges becoming shorter, lower and weaker as the number increases. All scales have a flat smooth lateral region, although this is comparatively narrow on the larger scales with many ridges (e.g., Fig.16L, N View FIG ). The number of vascular canal openings on the neck increases with the number of growth zones. Scales from the ventral region are mostly large and very robust with worn crowns ( Fig. 16 View FIG H-N,?P), and as shown by patches which remained articulated after acid treatment, were closely packed with posterior corners overlapping the scales behind ( Fig. 16R View FIG ). Specialized scales include pinnal scales, presumed to be from the ventral pectoral region, that have a strongly inclined crown ( Fig. 16Q View FIG ). A large mass of tiny scales was observed in the head region of NMS G.2010.7.39, of which nearly all are assign-

able to Euthacanthus ( Fig.16S, T View FIG ). However, some of the scales were shiny smooth-crowned scales probably from Mesacanthus mitchelli . The scale mass could have been overlain by the main speci-

men, or they could be oral or branchial scales. The tiny Euthacanthus scales could also have been some of the small scales forming the cheek squamation ( Fig. 5C View FIG ). They differ from normal flank scales in their small size, and in being narrow and elongate with a curving crown, and occasionally with two posterior crown points.

Serial thin sections of the NMS G.2010.7.39 counterpart ( Fig. 17 View FIG ) show the histological structure of a good range of scales. Small flank scales ( Fig.17 View FIG B-C) show the same structure as the scales on average sized fish. However, most of the scales are larger, with more growth zones ( Fig. 17 View FIG D-H), on average eight, but with some scales having more. Inner zones show that when younger, the scale morphology resembled average sized specimens of E. macnicoli with overlying layers having more ridges.

Flank scales from the disarticulated specimen NMS G.2010.7.43 ( Fig. 18A View FIG ) have four to six strong parallel crown ridges with a narrow smooth lateral edge. Specialised scales were also found in the acid residues, including stellate head scales ( Fig. 18 View FIG G-K), tuberculated head scales ( Fig. 18I View FIG ), and umbellate scales ( Fig. 18J View FIG ) which were positioned next to sensory canals. Histological structure ( Fig. 18 View FIG L-Q) is comparable with the scales from NMS G.2010.7.39.

COMPARISON

Berg (1940) raised the family Euthacanthidae to incorporate Euthacanthus and possibly Brachyacanthus . Miles (1966) also considered that Euthacanthus and Brachyacanthus were members of the same family as both forms have no teeth and a principle gill cover that did not cover the whole gill chamber. Miles (1966) also stated that Parexus and Climatius belonged in the same family ( Climatiidae ) as both forms had teeth in the lower jaw and the principal gill cover covered most, if not all of the gill chamber. Later, Miles (1973) suggested a close relationship between Euthacanthus , Parexus and Vernicomacanthus as these three forms have a complete reduction of the posterior lorical plate and the ventral pinnal laminae. Miles (1973) also stated that Euthacanthus differed from the other two forms as it lacked the anterior lorical, the median prepectoral and the anterior pinnal plates. Hanke & Wilson (2004) suggested that Parexus had a close relationship to Euthacanthus due to the apparent unique character of the prepectoral spine being plate-like and well-separated from the pectoral fin spine. However, our investigations show that the “prepectoral plate” in Euthacanthus is more spine-like than previously recognized, and could possibly even be an admedian spine + plate. Fin spines of Euthacanthus differ from those of LORS taxa traditionally referred to the Climatiiformes in having smooth ridges, a character shared with ischnacanthiform, acanthodiform and diplacanthiform taxa.

Hanke & Wilson (2004) stated that the new species collected from the Early Devonian of Canada made previous classification schemes too simplistic and that any attempt to reclassify the acanthodians would be premature, until work on describing new species from Canada and Russia, which was in progress, was completed, and that the work on reinterpreting the acanthodians already described from the Early Devonian of Canada and the Scottish Early Devonian (of which this is part) was also required. As noted earlier, neither of the recent cladistic analyses by Davis et al. (2012) and Zhu et al. (2013) show Euthacanthus closely allied to any other taxa.

Our detailed new information on histology of the scales of Euthacanthus macnicoli , as well as giving as comprehensive as possible detail on the variation over the body and between different sized fish, allows comparison of scale structure with some other LORS taxa that fall outside the well-supported ischnacanthiform and acanthodiform clades – Nostolepis scotica (Newton, 1892) ( Burrow&Turner 2010) , Parexus recurvus Agassiz, 1845 ( Burrow et al. 2013) and Climatius reticulatus Agassiz, 1845 (Burrow et al. in press) – as well as with some of the contemporary “spiny” taxa from the MOTH locality in Canada, including Obtusacanthus corroconis Hanke & Wilson, 2004 and Lupopsyroides macracanthus Hanke& Wilson, 2004 ( Hanke & Wilson 2004), Brochoadmones milesi Bernascek & Dineley, 1977 ( Hanke & Wilson 2006), Kathemacanthus rosulentus Gagnier & Wilson, 1996 (Hanke & Wilson 2010) and Lupopsyrus pygmaeus Bernacsek & Dineley, 1977 ( Hanke & Davis 2012). Histological studies have not yet been done on scales of LORS taxa Brachyacanthus and Vernicomacanthus . However, of the other listed taxa, only Euthacanthus and Nostolepis have the “typical acanthodian” histological scale structure with superposed crown growth zones, combined with Nostolepis - type histology sensu Gross (1971).

BIOGEOGRAPHY

None of the other main sources of articulated gnathostomes of Lochkovian age (MOTH local-

H, midneck horizontal section showing vascular canal opening into lower crown.Abbreviations: bcl, bone cell lacunae; igl, incremental growth lines; m, mesodentine; Sf, Sharpey’s fibres; Sg, Stranggewebe; vc, vascular canal. Scale bars: A, 0.25 mm; B-H, 0.1 mm.

ity, Canada and Severnaya Zemlya) have yielded specimens of Euthacanthus macnicoli . However, the morphology and histology of the scales of E. macnicoli compare closely with some isolated scales from the Baltic region of Europe. As demonstrated above, this histological structure is of the Nostolepis - type. Variations within this grouping were further refined by Valiukevičius & Burrow (2005) in order to delimit the genus Nostolepis s.s., which had scores of new species assigned to it over the last several decades (e.g., Valiukevičius 1994, 1998, 2003a, b). The scale histology for Euthacanthus macnicoli corresponds to that of Nostolepis s.s. Valiukevičius has erected many new Siluro-Devonian acanthodian taxa based on isolated scales, and several of the varieties which he assigned to Cheiracanthoides spp. are strikingly similar to those of Euthacanthus . Scales of Cheiracanthoides borealis Valiukevičius, 1994 ( Valiukevičius 1994: figs 65.4, 66.1, 2, pl. 23, figs1-5) from the Lochkovian-Pragian of Taimyr, Russia are most similar morphologically to those of Euthacanthus macnicoli s.l., having four to six parallel ridges with flat areas laterally on the crown. In the original description, the Taimyr scales are described as lacking Stranggwebe, but as shown by the hundreds of sections which we have of Euthacanthus macnicoli scales, this tissue is vis- ible only when sections are made directly through the Stranglakunae in the scales. Other scales with more numerous (13-21) short fine ridges on the anterior crown from a lower stratum in the same section in Taimyr, assigned to Cheiracanthoides rarus Valiukevičius, 1994 ( Valiukevičius 1994: figs71.1-3, 72.1, pl. 23, figs 6-8), resemble those of large specimens of E. macnicoli morphologically, but have only narrow canals in the scale crowns. Scales of Cheiracanthoides nativus Valiukevičius, 1998 ( Valiukevičius 1998: pl. 1, fig. 16, 19, 20, 21; pl. 9, figs 6-8; pl. 10, figs 1-9; pl. 11, figs 1-2) from the Lochkovian Stoniskiai Regional Stage of Lithuania, Latvia, Kaliningrad ( Russia), and C.planus Valiukevičius, 1998 ( Valiukevičius 1998: pl. 3, figs 9-11, 14, 15; pl. 9, figs 1-5) from the Pridoli-Lochkovian of the East Baltic and Byelorussia fit within both the morphological and histological variation shown by the scales of Euthacanthus spp. However, as recently shown by Burrow et al. (2013) it cannot be assumed that isolated scales with similar morphology and histology belong to the same species, genus or perhaps even class of fish. Our study has shown a wider range of body scale morphotypes for E.macnicoli than previously imagined, and future studies of isolated scale assemblages should encompass this variation in determining species composition.

zones; N, low crown horizontal section of a flank scale; O, crown horizontal section through an incomplete large scale showing nine or ten crown growth zones; P, mid-neck horizontal section through a small flank scale; Q, vertical transverse section with four crown growth zones. Scale bars: A, 10 mm; B-F, 0.25 mm; G-Q, 0.1 mm.

CONCLUSIONS

This work is part of a project to revise and expand descriptions of all the Scottish Devonian acanthodians, updating general morphological characters and incorporating new data to clarify classification of the acanthodians and their relationships with other groups of fishes. Previous cladistic approaches have been hampered by the lack of data on articulated acanthodians across the Old Red Sandstone continent. This problem is being addressed by various workers working particularly in the Siluro-Devonian of the Canadian MOTH locality and the Scottish Old Red Sandstone. Euthacanthus macnicoli (new reconstruction shown in Fig. 19 View FIG ) is important in this regard as many workers (e.g., Denison 1979) considered the species as one of the more “primitive” acanthodians, and more recently as a stem acanthodiform ( Brazeau 2009), or the basal taxon of the osteichthyan stem lineage ( Davis et al. 2012), or in a polytomy with Ptomacanthus , ischnacanthiforms,[ Climatius + Brachyacanthus + Parexus ], acanthodiforms and [stem chondrichthyan “acanthodians” + Chondrichthyes] ( Zhu et al. 2013). Here we support the view that the species is not closely allied to the climatiids, and that Euthacanthus is the sole genus in the family Euthacanthidae .Work in progress on other LORS taxa should help to clarify relationships between the traditional “ Acanthodii ” and other early gnathostomes.

NMS

National Museum of Scotland - Natural Sciences

Kingdom

Animalia

Phylum

Chordata

Family

Euthacanthidae

Genus

Euthacanthus

Loc

Euthacanthus macnicoli Powrie, 1864

Newman, Michael J., Burrow, Carole J., Den Blaauwen, Jan L. & Davidson, Robert G. 2014
2014
Loc

Euthacanthus macnicoli

HANKE G. F. & DAVIS S. P. 2012: 480
NEWMAN M. J. & DAVIDSON R. G. & DEN BLAAUWEN J. L. & BURROW C. J. 2012: 740
BRAZEAU M. D. 2012: 356
NEWMAN M. J. & DAVIDSON R. G. & DEN BLAAUWEN J. L. & BURROW C. J. 2011: 101
HANKE G. F. & DAVIS S. P. 2008: 318
VALIUKEVICIUS J. & BURROW C. J. 2005: 636
HANKE G. F. & WILSON M. V. H. 2004: 189
DAVIDSON R. G. D. & NEWMAN M. J. 2003: 244
BURROW C. J. & YOUNG G. C. 1999: 10
GAGNIER P. - Y. & HANKE G. F. & WILSON M. V. H. 1999: 93
DINELEY D. L. 1999: 159
1999
Loc

Euthacanthus macnicolli

FRICKHINGER K. A. 1991: 239
1991
Loc

Euthacanthus mitchelli

O'CONNELL M. B. 1916: 90
GOODCHILD J. G. 1904: 597
1904
Loc

Euthacanthus

HANKE G. F. & DAVIS S. P. 2012: 480
MILLER R. F. 2007: 994
HANKE G. F. & WILSON M. V. H. 2006: 534
WILSON H. M. & ANDERSON L. I. 2004: 171
JANVIER P. 1996: 177
TREWIN N. H. & DAVIDSON R. G. 1996: 233
FRICKHINGER K. A. 1991: 239
LONG J. A. 1986: 336
HEYLER D. 1969: 40
HAY O. P. 1902: 274
TRAQUAIR R. H. 1894: 257
1894
Loc

Climatius grandis

O'CONNELL M. B. 1916: 90
DEAN B. 1907: 218
WOODWARD A. S. 1891: 31
WOODWARD A. S. & SHERBORN C. D. 1890: 36
1890
Loc

Climatius macnicoli

O'CONNELL M. B. 1916: 90
WOODWARD A. S. 1891: 30
WOODWARD A. S. & SHERBORN C. D. 1890: 36
1890
Loc

Euthacanthus grandis

PATON R. L. 1976: 6
MILES R. S. 1970: 362
GUNTHER A. 1904: 312
TRAQUAIR R. H. 1892: 33
BARKAS W. J. 1874: 550
POWRIE J. 1870: 292
1870
Loc

Euthacanthus macnicoli

YOUNG V. T. 1995: 66
DENISON R. 1979: 27
JARVIK E. 1977: 212
PATON R. L. 1976: 7
MILES R. S. 1973: 183
MILES R. S. 1970: 362
HEYLER D. 1969: 59
WATSON D. M. S. 1937: 61
DEAN B. 1907: 216
TRAQUAIR R. H. 1892: 33
BARKAS W. J. 1874: 550
ANONYMOUS 1867: 7
POWRIE J. 1864: 425
1864
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