Orthonychia enorme ( Lindstroem , 1884)

Orthonychia enorme ( Lindstroem, 1884)

Figs 3 View Figure 3 , 4 View Figure 4 , 5 View Figure 5 , 6 View Figure 6 , 7 View Figure 7 , 8 View Figure 8

1884 Platyceras enorme sp. nov. - Lindström: 69, pl. 2, figs 59-72. cf. 1976 Platyceras (Orthonychia) cf. P. (Orthonychia) enorme Lindström, 1884 - Peel and Yochelson: 17.

Lectotype.

Selected here, NRM Mo 38219 from the Eke Formation at Rikvide, Gotland, illustrated by Lindström (1884, pl. 2, figs 60, 61, re-illustrated here in Fig. 3A View Figure 3 . The specimen is laterally compressed and incomplete when it comes to height but shows the early ontogeny, the tube-like expansion of the shell and the distinct ornamentation.

Other type material.

Lindström (1884) illustrated an additional six specimens from the same locality as the lectotype, and these are here considered paralectotypes (NRM Mo 38218, Mo 38220-Mo 38324); see Figs 3B View Figure 3 - 5B View Figure 5 . The identity of specimens listed by Lindström (1884) from other localities cannot be established, with the exception of the specimen from Slite which is not conspecific with O. enorme (see below). The other localities mentioned by Lindström (1884) span older strata (Djupvik and Klinteberget = Slite beds of Sheinwoodian/Homerian age; Havdhem and Hammar in Kräklingbo = Hemse beds of Gorstian/Ludfordian age) and younger strata (Burgsvik = the Burgsvik Sandstone just overlying the Eke Formation).

Additional material.

Ca. 240 juvenile shells (illustrated material SNSB-BSPG 2023 X 1-15). from the Eke Formation at Bodudd (S Gotland, Sweden, 57°04'05.8"N, 18° 11'34.7"E, compare Calner et al. 2004, fig. 2) which is Ludfordian (Ludlow, upper Silurian) in age GoogleMaps .

Description of type material

(Figs 3 View Figure 3 - 5 View Figure 5 , Table 1 View Table 1 ). Largest shell 16.5 mm tall and 7.5 mm in apertural length (in lateral view). On average the shell is twice as tall as long (in lateral view). NRM Mo 38219 (Fig. 3A View Figure 3 ) deviates by length of aperture being 75% of height, but the shell is laterally compressed. NRM Mo 38222 (Fig. 5B View Figure 5 ) has an aperture length that is only about 40% of shell height. Rate of expansion high when viewed in a lateral perspective, but less when viewed anteriorly/posteriorly, making aperture sub-oval. Growth lines irregularly crenulated, but overall attitude is straight across posterior section of shell (Figs 3A3 View Figure 3 , 4A4 View Figure 4 ), gently arched on lateral surfaces and curved into broad median sinus anteriorly. Here the growth lines are sinusoid with two asymmetrical crenulations of which the left has greater amplitude (Figs 3A4 View Figure 3 , 4A3 View Figure 4 ). Although the intensity and irregularity of the crenulations vary, there are no major deviations from the overall co-marginal alignment. The co-marginal ribs or frills seen in early ontogeny widens into distinct growth increments, spaced less than 1 mm apart and ending in seemingly short lamellae. Fine radial striae may be present within each growth increment. Specimen NRM 38220 appears to have a mostly smooth shell with fine growth lines only, but increments with lamellae are visible on the initial part of the shell (Figs 3B3, B4 View Figure 3 ). Space between increments get narrower in late ontogeny (Fig. 4A, B View Figure 4 ). Radial ornamentation is absent.

Description of additional material from sieved bulk samples

(juvenile and encrusted shells, Figs 6 View Figure 6 - 8 View Figure 8 ). Shell with tightly coiled ca. 1.5-2.5 initial whorls including protoconch and early teleoconch; largest shell studied with SEM 4.1 mm long, 1.9 mm wide; encrusted specimens (forming cores of oncoids) probably belonging to the present species up to 20 mm long; protoconch with round, convex whorls and slightly elevated spire, lacking ornament (but re-crystallized); encrusted (oncoid) specimens possibly belong to this species up to 20 mm long; diameter of first whorl 0.17-0.25 mm, diameter of protoconch 0.37-0.68 mm (two measurements); protoconch/teleoconch-transition indistinct due to preservation (re-crystallization) but apparent by sudden onset of co-marginal ribs (may also appear as frills or lamellae) and rapid increase of expansion rate of whorl diameter; later teleoconch detaches and becomes uncoiled, bent to slightly elongated, slowly increasing in diameter, forming a cap-shaped tube; teleoconch ornamented by sharp, narrow co-marginal ribs separated by wide interspaces; strength of ribs and density of ribbing variable; ribs can also form lamellae; ribs appear much longer (lamellae) in specimens studied in thin sections than ribs in specimens from bulk samples suggesting that such lamellar ribs broke off during processing of sample; teleoconch also ornamented by thin spiral lirae, much weaker than co-marginal ribs; shell having a calcitic layer as suggested by thin sections.

Remarks.

Lindström (1884, p. 69) mentioned several specimens from various localities on Gotland, but figured only specimens from Rikvide. In the NRM collection only specimens from Rikvide and Burgsvik are registered, but specimens from the latter locality were not available for study. The specimen from Slite in the PMU collections, mentioned by Lindström (1884), is illustrated here in Fig. 5B View Figure 5 . It comes from the much older Slite Group sediments and is here treated as Orthonychia sp. The species was also listed from the Slite Beds by Manten (1971, table 11). However, it differs markedly from O. enorme in the initial shell having higher rate of coiling, possibly more coiled whorls before extending into the tubular shell, the shell is proportionally broader at the aperture, the W/H ratio is higher (0.65), it lacks clear growth increments and lamellae, and have a distinct radial ornamentation crossing the fine co-marginal growth lines thus creating a fine reticulate pattern. Furthermore, the shell reverses curvature during growth.

Lindström (1884, p. 69, pl. 2, fig. 71) described and illustrated a fine radial ornamentation. Some faint striations may be discerned in NRM 38218 (Fig. 4B2 View Figure 4 ) but similar ornamentation is not seen in other macro-specimens. Fine and widely spaced lirae are present in early ontogeny (Gotland Ortho 1, C2). The two-element illustration in Lindström (1884) cannot readily be linked to any of the available specimens.

Peel and Yochelson (1976, p. 17) listed Platyceras (Orthonychia) cf. P. (Orthonychia) enorme Lindström, 1884 from the Telychian of Norway.

The present material from the bulk samples closely resembles the type material of Platyceras enorme Lindström, 1884 as described and illustrated above. The type specimens are much larger (more than 16 mm long) than the specimens from the washed residue reported here. However, strongly encrusted specimens studied by Schugmann (2015) and herein (Fig. 6 View Figure 6 ) are also in this larger size range suggesting that the specimens from the residues are juveniles. Platyceras cornutum from the upper Silurian of Gotland as illustrated by Lindström (1884) is similar but lacks ornamentation of axial ribs/frills and spiral lirae; instead it has co-marginal irregular bulges. Moreover, the teleoconch of Platyceras cornutum is generally more curved.

The Devonian Crossoceras Boucot & Yochelson, 1966 ( Platyceratidae ) is ornamented with co-marginal sharp ribs (frills) and a fine spiral lineation similar to the ornament of Platyceras enorme . However, Crossoceras has a stronger curvature of the teleoconch and is thus close to Platyceras in this respect. A close phylogenetic relationship of Crossoceras and Orthonychia enorme seems to be likely. The protoconch of Crossoceras is unknown; judging from the illustration given by Boucot and Yochelson (1966, pl. 3, fig. 11) it could be tightly coiled as in Orthonychia enorme but the preservation is insufficient to be sure.

Pragoserpulina tomasi Frýda, 1998a, type species of Pragoserpulina Frýda, 1998a, family Pragoserpulinidae Frýda, 1998a, from the Early Devonian of the Czech Republic (Dvorce-Prokop Limestone, Praha Formation, Pragian, Czech Republic) closely resembles O. enorme in teleoconch morphology and in having the same type of tightly coiled protoconch. However, the uncoiled teleoconch of P. tomasi is more bent, its ribbing is denser, the co-marginal ribs are stronger; the ribs are rounded and not as sharp (no frills). Bouchet et al. (2005, 2017) classified Pragoserpulinidae as a Paleozoic taxon that certainly belongs to gastropods, unassigned to superfamily - it is possible that Pragoserpulina is platycerate.

The tightly coiled protoconchs shown here for Orthonychia enorme and that illustrated by Frýda (1998a) for Pragoserpulina tomasi are clearly not of the vetigastropod type (see e. g., Bandel 1982; Haszprunar et al. 1995; Nützel 2014). They probably were produced by larvae with a short-termed planktotrophic phase. Similar protoconchs were reported for the Paleozoic neritimorph Naticopsis ( Nützel and Mapes 2001; Nützel et al. 2007b) and Platyceras ( Frýda et al. 2009). The same type of protoconch was found in Devonian and early Carboniferous gastropods with a cap-shaped teleoconch placed in the family Pragoscutulidae Frýda, 1998a ( Cook et al. 2008). They were classified as Caenogastropoda but a neritimorph relation seems also possible. Pragoscutulidae are much stouter i.e., they have a much wider apical angle.