Anabarites compositus Missarzhevsky

Kouchinsky, Artem, Bengtson, Stefan, Landing, Ed, Steiner, Michael, Vendrasco, Michael & Ziegler, Karen, 2017, Terreneuvian stratigraphy and faunas from the Anabar Uplift, Siberia, Acta Palaeontologica Polonica 62 (2), pp. 311-440 : 420-421

publication ID	https://doi.org/ 10.4202/app.00289.2016
persistent identifier	https://treatment.plazi.org/id/03AD87A8-FFF6-6D49-FCB9-FEF5641184C1
treatment provided by	Felipe
scientific name	Anabarites compositus Missarzhevsky
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Anabarites compositus Missarzhevsky in Rozanov et al., 1969

Fig. 77 View Fig .

Material.—Over one hundred internal moulds with rare fragments of phosphatized walls, including figured SMNH X3677–3679, 3681–3684, 6029, 6030, from sample 5a/34.5 (see Kouchinsky et al. 2009; Fig. 77A–I View Fig ), and probably also several glauconitised internal moulds, including figured SMNH X6031, 6032, from sample 5a/18.5, Emyaksin Formation, eastern Anabar Uplift, Siberian Platform, Russia. Correlated with lower part of Cambrian Stage 2.

Description.—Almost straight tubes with rounded hexagonal inner cross-section ( Fig. 77G, J View Fig ) and transverse, flanged growth lines. Internal protrusions of the conch wall are obliquely inclined towards the aperture ( Fig. 77H View Fig 1) and replicated as three rows of notches in the middle of each depression on the internal mould ( Fig. 77F View Fig 2 View Fig , I, K). A semi-circular pocket in the inner surface of the tube wall is associated with each protrusion ( Fig. 76E, H View Fig 1, D 2). These structures produce chevron-like elements on the internal moulds.

Remarks.—The internal indentations on Anabarites compositus tubes are spine-like and rounded in cross-section (Kouchinsky et al. 2009: fig. 30A, B). They differ from the blade-like, longitudinally elongate indentations along the axis of the tube moulds in A. tristichus (compare Fig. 77K View Fig with Fig. 76A View Fig ). The pocket-like structures in the wall of A. compositus are reminiscent of the circumferential internal folds in the walls of Aculeochrea rugosa Val’kov and Sysoev, 1970 ( Fig. 78 View Fig ) and A. ornata Val’kov and Sysoev, 1970 (see Kouchinsky et al. 2009: fig. 49). For this reason, Missarzhevsky (1989: 193) assigned A. compositus to Aculeochrea Val’kov and Sysoev, 1970.

Spine-like protrusions covered by “lamellae” are apparently present in Aculeochrea trilamellosa Vasil’eva, 1998, and Aculeochrea mesezhnikovi Vasil’eva, 1998 (Vasil’eva 1998: pl. 16: 1–5, pl. 17: 1, 2, 5). The “lamellae” presumably represent similar structures on the internal moulds as the chevrons in A. compositus . Aculeochrea mesezhnikovi is reportedly different from A. compositus in having “lamellae” situated in depressed parts of the mould (grooves), whereas the more prominent and wider lobes are devoid of such “laminae” (Vasil’eva 1998). Aculeochrea trilamellosa similarly has three longitudinal rows of “lamellae” and a circular cross-section of the internal mould. The illustrations by Vasil’eva (1998) do not, however, allow a more detailed comparison with Anabarites compositus . A fossil from the upper lower Cambrian of England misidentified ( Hinz 1987: pl. 14: 37, 38) as A. compositus actually resembles Selindeochrea tricarinata (Missarzhevsky; see also Brasier 1989: 135), but most likely represents the orthothecid hyolith Gracilitheca .

Stratigraphic and geographic range.— Lower part of Cambrian Stage 2, Siberian Platform.

References

Figures

Fig. 2. Composite δ13Ccurve for the Bol’shaya Kuonamka River sections 96-4, 5, and 5a and sampled horizons with fossiliferous samples (arrows with carb numbers). Arrow 4/4 indicates “marker bed with angustiochreids” (Val’kov 1975; Kouchinsky et al. 1999). For section 96-6 see Kouchinsky et al. (2001, 2015a). Shift in stratigraphic column at Manykay–Emyaksin formations contact indicates position of sequence boundary. Stratigraphic ranges and first appearances of fossils (see SOM 1): 1, first appearance of helcionellid molluscs; 2, Oelandiella korobkovi; 3, Securiconus cf. simus; 6, Obtusoconus vostokovae; 7, Obtusoconus cf. mirabilis; 8, Anabarella plana; 13, Aldanella attleborensis; 14, Aldanella cf. sibirica; 22, Purella antiqua; 24, Yunnanopleura accurata; 34, Lopochites sp.; 35, Tianzhushania longa; 37, first appearance of Halkieria sp.; 38, Chancelloria symmetrica; 42, Khetatheca cotuiensis; 44, Conotheca cf. mammilata; 46, Turcutheca sp.; 47, Cupitheca sp.; 50, Orthothecid operculum type C; 51, Protohertzina anabarica; 52, Fomitchella infundibuliformis; 53, Fomitchella aff. infundibuliformis; 54, Fomitchella acinaciformis; 55, Fomitchella aff. acinaciformis; 56, Hyolithellus vladimirovae; 57, Hyolithellus sp.; 60, Selindeochrea cf. tecta; 61, Selindeochrea tripartita; 62, Selindeochrea missarzhevskyi; 63, Selindeochrea ternaria; 64, Anabarites trisulcatus; 65, Anabarites latus; 66, Anabarites natellus; 67, Anabarites kelleri; 68, Anabarites biplicatus; 69, Anabarites tristichus; 70, Anabarites compositus; 71, Anabarites hexasulcatus; 72, Anabarites hariolus; 73, Aculeochrea rugosa; 74, Tiksitheca licis; 75, Cambrotubulus decurvatus; 76, Platysolenites antiquissimus.