Cordilleria mutabile ( Kelly, 1942 )

Cordilleria mutabile ( Kelly, 1942)

1942 Diphyphyllum mutabile Kelly, 1942: 358 , pl. 51: 7, 8.

1966 Lithostrotion mutabile Kelly, 1942 ; Bamber 1966: 4, pl. 1: 1a–e.

2007 “ Diphyphyllum ” mutabile Kelly, 1942 ; Fedorowski and Bamber 2007: pl. 2: 1–6, 10–12; pl. 7: 1.

Holotype: GSC 9642 View Materials .

Type locality: “Southwest slope of the mountain northwest of the junction of the McLeod River with Whitehorse Creek” ( Kelly 1942: 359).

Type horizon: Lower Rundle Group, upper Tournaisian.

Emended diagnosis.—Fasciculate colonial coral with n:d value of 20:3.9 mm to 25:6.0 mm ( Fig. 10 View Fig ). Major septa weakly amplexoid, reach up to 1/2 corallite radius on tabulae surfaces, reduced to 1/3–1/4 corallite radius when sectioned between tabulae, i.e., terminated on steep, peripheral parts of tabulae. Protosepta indistinguishable. Cardinal fossula absent. Minor septa almost as long as major septa when latter not elongated. Pseudocolumella short, simple, slightly thickened or thin, rarely underdeveloped. Tabulae complete, slope peripherally under 10–20° when pseudocolumella present, elevated slightly upward next to pseudocolumella. Tabulae horizontal, slightly convex or concave when pseudocolumella absent; both kinds strongly deflected at periphery, rare inner parts of tabulae rest upon underlying tabulae, most meet dissepimentarium or external wall under a variable angle. In immature specimens, tabulae span entire corallite lumen, slightly convex or horizontal with weakly marked peripheral deflection, or straight. Dissepimentarium in one incomplete row of regular, interseptal dissepiments. Microstructure of septa finely trabecular.

Remarks.—The synonymy is restricted to the papers discussing with the holotype. The emended diagnosis, comprising all main characteristics of skeleton of the holotype, is based on description and illustrations by Kelly (1942: pl. 51: 7, 8), restudy of the holotype by Bamber (1966: pl. 1: 1a– e) and on the further restudy of the holotype by Fedorowski and Bamber (2007: pl. 1: 1–11, pl. 2: 1–6, 10–12).

Stratigraphic and geographic range.— Type horizon and locality only.

Cordilleria aff. mutabile ( Kelly, 1942) Figs. 9–11 View Fig View Fig View Fig .

Material.—Three fragments of colonies ( Fig. 6 View Fig ): C-47930 = GSC 142469, C-52546 = GSC 142470, and C-52124 = GSC 142471 from the Flett Formation, Rundle Group, Viséan, Liard Basin, Northwest Territories, Canada and colony C-7349 = GSC 142468 from Rundle Group, Viséan, Rocky Mountains, Bone Mountain, east-central British Columbia, Canada, all comparable in age ( Table 1), included in this description as bearing morphological features important for the discussion on this species and the new genus Cordilleria . All colonies recrystallized.

Description.—N:d values of all colonies vary, some comparable to those of holotype ( Fig. 10 View Fig ). However, increasing number of septa does not always follow increase of corallite diameter in all colonies, holotype included. Corallites in GSC 142469 display smallest number of septa; largest of them equal in septal number to smallest corallites of holotype. In contrast, corallites in GSC 142470 display number of septa comparable to holotype, but diameters larger. Thus, n:d values of those two colonies differ from that in holotype and remaining specimens ( Fig. 10 View Fig ). Also, they differ from one another in morphology ( Figs. 9A View Fig 3 View Fig , B 4 View Fig and 11A View Fig 1 View Fig , B 2 View Fig , respectively) suggesting limits of intraspecific variability provisionally accepted here for C. mutabile are too broad.

Amplexoid character of major septa differentiated. Most advanced in GSC 142469 ( Fig. 9B View Fig 4 View Fig ), where some major septa reach more than 2/3 corallite radius. In GSC 142471 and GSC 142470 ( Figs. 9A View Fig 3 View Fig and 11B View Fig 2 View Fig , respectively), amplexoid character of major septa hardly recognizable. Longest major septa in corallites of those colonies reach only slightly more than 1/3 corallite radius. In all specimens studied, major septa thin and protosepta indistinguishable irrespective of presence or absence of pseudocolumella. Minor septa longest in GSC 142469 ( Fig. 9B View Fig 4 View Fig ), closely comparable to those in holotype. In remaining specimens, minor septa vary in length both between corallites and during growth of individual corallites; longest reach 2/3 length of major septa or slightly more. Those reaching 1/2–2/3 length of major septa prevail, but slightly shorter ones occur. Occurrence of pseudocolumellae strongly differentiated; present as a slightly thickened body in all corallites observed in transverse section of colony GSC 142469, but not in fragments of longitudinal sections of several corallites within that colony ( Fig. 9B View Fig 4 View Fig and B 1 –B View Fig 3 View Fig , respectively). Pseudocolumella absent from all corallites in two other colonies studied from the Flett Formation ( Figs. 9A View Fig , 11B View Fig 2 View Fig ). Differences in longitudinal section depend mainly on development of pseudocolumella. Closely resembling each other, including holotype ( Fedorowski and Bamber 2007: pl. 2: 5, 6, 10), when pseudocolumella not developed ( Figs. 9A View Fig 1 View Fig , A 2 View Fig , B 1 View Fig (white arrow), B 2, B 3, 11B 1). In columellate part of longitudinal section of GSC 142469 ( Fig. 9B View Fig 1 View Fig , black arrow), inner tabulae elevated steeply towards thickened pseudocolumella. Many of them rest upon underlying tabulae to form short lasting columnotheca. Columnotheca rarely occurs in holotype. Also, inner parts of its tabulae elevated much less steeply than tabulae in the illustrated GSC 142469. Colony GSC 142468 additionally included in this paper, ( Fig. 11A View Fig ) displays morphology intermediate between GSC 142469 and holotype. This especially concerns the development vs. absence of pseudocolumella. Pseudocolumella in colony GSC 142468 strongly interrupted, making acolumellate colonies from the Liard Basin an extreme variant of a sequence starting with colonies with pseudocolumella almost invariably continuous in all corallites to colonies composed of acolumellate corallites. Also, it documents secretion of pseudocolumella by epidermis of polyp’s floor ( Fig. 11A View Fig 2 View Fig , A 4 View Fig ), discussed in more detail in general remarks. Dissepimentarium mostly in one incomplete row of rectangular, interseptal dissepiments, i.e., like in holotype, but in colony GSC 142471 may occasionally increase to 2–3 rows in small parts of corallite and during short period of the corallite growth ( Fig. 9A View Fig 1 View Fig ). Offsetting ( Fig. 11C, D View Fig ) documented by offsets in various growth stages appearing by chance in transverse thin sections. Their morphology follows particular growth stages illustrated by Fedorowski and Bamber (2007: pl. 1: 1–11) in holotype.

Remarks.—The morphological variability in almost all characters of specimens described from the Flett Formation extends beyond the parameters established above for the holotype. The small n:d value of GSC 142469 and its rather strongly amplexoid major septa resemble those in C. flexuosum ( Warren, 1927) , whereas its very long minor septa and its morphology in longitudinal section distinguishes it clearly from that species. The morphology in transverse sections of the other colonies and the slightly reduced length of some of their minor septa resemble C. oculinum ( Sando, 1963) , whereas the great length of most of the minor septa, the weakly marked amplexoid character of the major septa and the morphology in longitudinal sections form a set of characters distinguishing them from the latter species. All those characters, the long minor septa and the morphology in the longitudinal sections allow all the colonies discussed to be distinguished from C. warreni ( Nelson, 1960) .