Leptodesma Hall, 1883

Genus Leptodesma Hall, 1883 View in CoL

TYPE SPECIES: Leptodesma potens Hall, 1883 . SD S.A. Miller, 1889 .

DIAGNOSIS: Shells lacking costae; left valve umbo more prominent than right; large posterior auricle with deeply embayed margin; cardinal teeth few and variable in number.

DISTRIBUTION: Middle Silurian­Permian, cosmopolitan.

DISCUSSION: Hall (1883) differentiated his new genera Leptodesma and Leiopteria by

the form of the anterior auricle, angular in the former versus rounded in the latter. In the Treatise on Invertebrate Paleontology, Newell and LaRocque (1969: 300–301) accepted this distinction at the subgeneric level, recognizing Leptodesma (Leptodesma) and L. ( Leiopteria ). This practice was followed by Pojeta et al. (1986: 94), who refigured the original drawings of the type specimens and discussed their dissimilarities. We concur with the subgeneric usage and assign our new species to L. ( Leptodesma ). It is worth noting, however, that our study collection exhibits significant variation in topography and outline of the anterior auricle.

Leptodesma (Leptodesma) falcata Boyd and Newell , new species Figures 1–4 View Fig View Fig View Fig

DIAGNOSIS: Small, posteriorly elongated shell with sharply pointed posterior wings; valves strongly discordant; right valve (RV) less convex than left valve (LV); anterior auricle truncate; LV bears strong commarginal 3 ridges, RV unornamented; two cardinal teeth on LV, one on mature RVs; one prominent posterior lateral tooth on each valve.

ETYMOLOGY: Latin falcata (sickle­shaped) refers to the distinctive form of mature valves.

DISTRIBUTION: Road Canyon Formation ; Middle Permian (Roadian Stage); Glass Mountains, West Texas, USA. Leptodesma falcata is known from a single locality, USNM 703 About USNM c, described in detail by Cooper and Grant (1972: 142) .

MATERIAL: Our study collection consists of 270 disarticulated valves (165 L; 105 R) and three articulated shells. All specimens are si­

3 Cox (1969: N103) introduced this term ‘‘for direction usually described as concentric’’. We accept the spelling established by Cox.

licified. Forty­seven LVs and 25 RVs are essentially undamaged except for common breakage of the distal part of the posterior wing.

DESCRIPTION: The following observations are arranged in this sequence: 1. valve shape; 2. ornamentation; 3. muscle scars; 4. ligament; 5. dentition; and 6. microstructure.

1. During ontogeny, progressive accentuation of the posterior growth component produced the distinctive retrocrescentic shape and arcuate umbonal ridge, both especially pronounced in LVs (table 1). The truncation of the anterior auricle margin, commonly cit­ ed as a criterion for the subgenus L. ( Leptodesma ) (e.g., Newell and LaRocque, 1969), is obvious on typical LVs but is less angular on many RVs. A change in slope, rather than a distinct sulcus, separates the anterior auricle from the main body of each valve. LVs lack a byssal sinus although the anterior margin below the auricle is slightly concave on large specimens. By contrast, a concavity in this part of the margin typifies small RVs but is lost with increase in valve size. Our one well­preserved articulated shell (fig. 2) exhibits a slitlike byssal gape in anterior view. The deep posterior sinus, a distinctive feature of undamaged valves, is commonly diminished due to breakage of the mucronate posterior wing.

2. The flangelike commarginal ridges of LVs are prominent on umbo and anterior flank, but are weakly developed or absent beyond valve heights greater than 7 or 8 mm. On some valves, the change is abrupt. Where most prominent, the ridges rise sharply above the intervening troughs. They vary in spacing and in lateral continuity; mergers, offsets, and terminations are common. Ridge continuations on the posterior flank are subdued but they become closely spaced and uniform where meeting the long dorsal margin behind the beak, giving a serrate profile to that area.

3. Muscle attachment sites are poorly represented in our collection. Of the numerous valves with well­preserved inner surfaces, many show no indication of either muscle scars or pallial line. Where such evidence is present, it is commonly vague, as for the posterior adductor, or difficult to interpret because of inconsistent size and location, as for small anterodorsal pits. Johnston (1993: 33) discussed similar interpretive problems regarding umbonal scars in Devonian pterineids.

The part of the interior surface where a pallial line might be expected is featureless in most valves. Rare exceptions exhibit a well­defined line in the anterodorsal region, but it fades out ventrally and is not present on the posterior side of the valve. The posterior adductor scar, never sharply outlined, is commonly represented by a flattened or slightly indented area on the slope between the shelflike posterior auricle and the strong­ ly concave interior. In the anterodorsal part of each valve, we recognize a small scar on the shoulder separating the anterior auricle from the umbonal cavity (fig. 4b). In our interpretation, this scar is the imprint of a small anterior adductor.

4. The ligament area is dominated by as many as seven strongly asymmetric chevron grooves. The long and slightly sinuous posterior limbs of the chevrons meet the ventral margin of the cardinal area at very low angles (e.g., 6°). Well­preserved valves have a tiny (e.g., 0.2 mm base) resiliferlike pit directly beneath the beak, separating it from the apex of the first chevron (fig. 3a). This situation suggests the ontogenetic discontinuity described by Waller (1998: 21) who noted that in some Pteriomorphia a primary resilium is replaced by a duplivincular ligament system.

5. The simple dentition of this species (fig. 3b, c) contrasts sharply with the complex array of major and minor teeth in mature shells of some Silurian and Devonian pterineids (e.g., Johnston, 1991: fig. 9B; 1993: fig. 26). However, the growth series of the Devonian Cornellites catellus , elegantly diagrammed by Johnston (1993: fig. 26), begins with a simple hinge that invites comparison with that of our Permian material. One can speculate that the anterior cardinal and prominent posterior lateral of the LV of Leptodesma falcata are homologous with, respectively, teeth Ap3 and Pp3 of Johnston’s figure 26. However, the equivalent to the posterior cardinal of L. falcata has to be sought among the secondary teeth that are introduced early in the ontogeny of C. catellus . In that series, tooth s5 bears the desired relationship to Ap3 (Johnston, 1993: fig. 26C), but the absence of s1 and s 3 in L. falcata suggests that the relationship of its posterior cardinal to s5 of C. catellus represents analogous topog­ raphy rather than homology. In contrast, Johnston (personal commun., 2000) thinks there is reason to believe that s5 teeth in Leptodesma , Umburra , and Cornellites are homologs. He notes that s5 appears before s1 and s 3 in Umburra . Assuming a similar ontogeny for Leptodesma , the loss of s1 and s3 could have occurred through paedomorphosis.

As with the LV, the RV hinge of L. falcata is reminiscent of that of juvenile Cornellites (Johnston, 1993: figs. 23G, H; 29G). This is especially true of the posterior area with its prominent splinterlike tooth (Pp2 of Johnston) below the distinctive wedge­shaped socket. The slightly thickened dorsal rim of that socket is the equivalent of tooth Pp4 of Johnston’s (1993) figure 29G. By contrast, tooth Ap2, the apparent equivalent of the knoblike cardinal tooth of L. falcata , is a ridge that slopes downward from the ligament area toward the anterior margin. At the anterior end of the hinge, L. falcata RVs lack an equivalent of the arcuate tooth Ap4 although a tiny protuberance in front of the anterior socket is present in small (<10 mm maximum dimension) valves. The absence of that minor tooth in mature RVs is the only change we can document involving addition or subtraction of teeth in the ontogeny of L. falcata . It is noteworthy that another Permian pterineid for which we have information on dentition resembles our hinges in simplicity although not in detail. Nakazawa and Newell (1968) described poorly preserved Leptodesma valves from Japan with one (LV) or two (RV) cardinal teeth and one (LV) or two (RV) posterior lateral teeth.

6. External surfaces of many LVs include areas that show evidence of the original microstructure of the outer ostracum (fig. 4a). In these places, closely spaced fibers and laths of silica are arrayed roughly perpendicular to growth lines. Dr. Joseph Carter (personal commun., 2000) interprets this pattern as fibrous prismatic to irregular spherulitic prismatic. This structure was not described in Carter’s (1990: 205) review of pterineid microstructure, which summarized the sparse information on Devonian and Carboniferous species. As a matter of historical interest, we note that Hall (1884: 184) may have observed this structure in a Devonian Leptodesma . His description of L. protextum stated that the surface of an exfoliated shell shows ‘‘obsolescent radii which appear to belong to the intimate shell­structure, and which are not shown on well­preserved specimens’’.

In Carter’s (1990) report, the structure of the calcitic outer layer of Leptodesma LVs was said to be regular simple prismatic although in some other pterineids it varies from irregular simple prismatic to homogeneous mosaic. The same report mentioned only regular simple prismatic structure for the outer layer of pterineid RVs. In our collection, we have no unequivocal evidence of RV microstructure. Most external surfaces are unbroken expanses of cryptocrystalline silica. In rare valves, such surfaces are interrupted by granular patches with texture suggestive of very small simple prisms. The strongly discordant margins of closed valves (fig. 2) provide circumstantial evidence for a RV prismatic layer that originally extended posteroventrally beyond the inner layer. The resulting flexible margin of the RV should have produced a wide margin of contact between the two valves, with the adaptive aspects discussed by Carter and Tevesz (1978). Presumably, the flexible marginal area decayed soon after death. Carter (1990: 205) noted that middle and inner layers of pterineid shells are nacreous. Our specimens offer no evidence in this regard; the inner layer is represented either by cryptocrystalline silica or by a fine honeycomb of silica that we suspect represents partial replacement of recrystallized carbonate.

Comparisons: Leptodesma gouldii (Bee­ de), a common fossil in the Permian Whitehorse Sandstone of Oklahoma and Texas, was described in detail by Newell (1940). The new genus he erected for it, Dozierella , was later placed in the synonymy of Leptodesma (Newell and LaRocque, 1969) . The Whitehorse species differs from L. falcata in having a more complex dentition and in lacking commarginal ridges and alate wing.

Girty (1908) illustrated a LV from the West Texas Permian that resembles ours in general form and ornamentation. He based a new species, Pteria guadalupensis , on the specimen and provided a single illustration in which the entire anterior margin is restored. Hinge characters are unknown. Although his description is based on one specimen, he cited two occurrences of the species in the Capitan Formation of the Guadalupe Mountains. More material from that formation would be necessary to determine the validity of Girty’s species. Furthermore, as Girty (1908: 426) recognized, an unequivocal generic assignment would require knowledge of hinge characters. The problem of homeomorphy in the families of pterioid bivalves is exemplified by the striking resemblance of our duplivincular species to the multivincular Bakevellia ceratophaga from the Permian of England (Logan, 1967: pl. 4, figs. 13–16).

Another Permian species similar in general form to L. falcata is Leiopteria carrandibbiensis Dickins, 1957 , from Australia. It lacks the arcuate umbonal ridge and prominent beak of our species, and the ligament grooves are parallel longitudinal lines rather than chevrons. Its dentition is unknown.