Cytheridae Baird, 1850

Family Cytheridae Baird, 1850 View in CoL

Remarks.—The Middle Jurassic species Dolocythere maculosa Bate, 1963 , recognized here as a species of Minyocythere gen. nov., was originally placed by that author in the mid-Cretaceous genus Dolocythere Mertens, 1956 and it is therefore necessary to discuss the suitability of that genus for the new Middle Jurassic species we describe below which are clearly congeners with D. maculosa .

Dolocythere rara Mertens, 1956 is the type species of Dolocythere View in CoL . We figure paratypes of D. rara ( Fig. 18A, B View Fig ) together with Senckenberg material that is conspecific in our opinion ( Fig. 18C–F View Fig ). There are clear differences between Albian Dolocythere rara and our Middle Jurassic Minyocythere View in CoL gen. nov. in, for example, StPC, in muscle scar pattern and in the shape of the mandibular depression (median depression = fulcral point of Van Morkhoven 1962) ( Figs. 4 View Fig , 5). Mertens (1956) cites dimorphism (see Appendix 1 for generic diagnosis) but does not mention this for D. rara in text or figures. We have inspected numerous adults and juveniles of D. rara of Aptian–Albian age from NW Germany (Erich Triebel collection in SMF) and find that putative males are difficult to recognize and rather rare. It is clear that revision of the genus is necessary and more than one species is involved, thus we describe Dolocythere amphistiela View in CoL sp. nov. as distinct from D. rara .

Minyocythere View in CoL shows differently developed muscle scars and especially the mandibular fulcral depression, both genera have lophodont hingement but less strongly developed in Minyocythere View in CoL than in Dolocythere View in CoL and with an accommodation groove on LV. Both genera have StPC but Minyocythere View in CoL has large and easily recognizable StPC (StPC-M herein; “caps” of Luppold 2012) whereas Dolocythere View in CoL does not. Minyocythere View in CoL has two of these StPC-M in a stable antero-dorsal position ( Fig. 6 View Fig ) which we consider probably a diagnostic character for Minyocythere View in CoL as it is common to the four (five?) known species of the genus and it is not present in Dolocythere View in CoL . Minyocythere macroporosa View in CoL sp. nov. and M. angulata View in CoL sp. nov. show pre-adult sexual dimorphism (= “precocious sexual dimorphism”), a feature that is well-known in ostracods (living examples: Heterocythereis albomaculata ( Baird, 1838) View in CoL and Loxoconcha elliptica Brady, 1868 View in CoL [ Athersuch et al. 1989: 23–24], Keijcyoidea infralittoralis Tsukagoshi, Okada, and Horne, 2006 View in CoL [ Okada et al. 2008]; fossil examples: four species of Glyptocythere Brand and Malz, 1962 View in CoL , Glabellacythere Wienholz, 1967 View in CoL , Lophocythere Sylvester-Bradley, 1948 View in CoL [ Whatley and Stephens 1977], Praeschuleridea decorata Bate, 1968 [ Bate 1968]). The important aspects for fossil material are: (i) to check internal fea-

Fig. 5. Comparison of valve morphology and muscle scars in cytherid ostracods Dolocythere View in CoL (A, B) and Minyocythere View in CoL (C–G). A. Dolocythere rara Mertens, 1956 from Borehole Lingen 196, 697– 704 m, NW Germany, Lower Albian. Paratype, BGR T.-K. 1300 (Mertens Collection, Hannover), female left valve in internal view (A 1), detail (A 2). B. Dolocythere amphistiela View in CoL sp. nov. from Borehole Rodewald WA 4, 187 m, NW Germany, lower Middle →

tures carefully to assess full maturity (see Athersuch et al. ble the younger Minyocythere gen. nov. externally but they

1989: fig. 16 with A-1 dimorphs in L. elliptica demonstrating are easily differentiated by hingement which is merodont in simple calcified inner lamella features of the penultimate the former and lophodont in the latter. Differences between moult) and (ii) the problem of time-averaging in micropalae- Minyocythere and Dolocythere are discussed above.

ontological samples which may conceal ecological fluctua- David Horne (personal communication 2019) commented tions reflected in size variation in mature animals over time. on the similarity in valve shape between Minyocythere gen.

In this context larger adults may appear as post-maturation nov. and Cytherissa Sars, 1925 , the latter a living lacustrine

moults although this seems rare, for example, Whittaker in taxon that displays a wide range of morphological variation

his study of The Fleet, Dorset, UK (personal communication ( Danielopol et al. 1990). The hingement of both genera is

to ARL; 1968, 1975) cites Paradoxostoma pulchellum Sars , similar, smooth and tripartite, and both have relatively nar-

1866 with 1700 live adults collected over three years but only row and simple marginal zones but differ in details of StPC

one was 15–20% larger than other adults, and Hirschmannia and muscle scars in addition to the fact that Minyocythere

viridis ( Müller, 1785) View in CoL with 1500 live and dead adults over is Jurassic, marine and extinct whereas Cytherissa View in CoL is

three years with only one 15–28% larger.?Paleogene, Pliocene to Recent ( Colin and Carbonel 1990),

Our conclusion is that the suite of Middle Jurassic spe- living, and common in shallow and deep lake environments

cies: Minyocythere macroporosa sp. nov., M. angulata sp. ( Meisch 2000), and is a potential case of homeomorphy or

nov., M. maculosa ( Bate, 1963) and M. tuberculata ( Luppold,

2012) represent a new genus that we erect as Minyocythere convergent evolution. The question arises of family place-

gen. nov. and which differs from Dolocythere in develop- ment. On balance we believe Minyocythere to be closer to ment of hingement, in details of the muscle scar pattern, in living Cythere and the Family Cytheridae than to Cytherissa the nature of the mandibular depression and in the morpho- and the Family Cytherideidae , and also close to Dolocythere logical diversity of the NPC. which is considered a Cytheridae taxon, however, the definition of families of Jurassic ostracods is in need of revision.

Genus Minyocythere nov. Reference is made both above and below to Japanese

ZooBank LCID: urn:lsid:zoobank.org:act:00137DD9-13E3-4ABB- work on NPC of the genus Cythere , especially by Tsukagoshi

8367-8F1865C9D53D and Ikeya (1987), which provides an important compara-

Type species: Minyocythere macroporosa sp. nov., Borehole Hambüh- tive dataset. Cythere , a widespread living and fossil genus ren WA2, NW Germany; Early Bajocian. which gives its name to the family Cytheridae , has heavily

Species included: Minyocythere angulata sp. nov., M. maculosa (Bate, calcified sub-quadrate valves ornamented with pits and/or

1963), M. tuberculata ( Luppold, 2012) . ridges, with internally merodont hingement, broad calcified

Etymology: From Greek, μΙΝΥΟ (minyo), of small dimension and κΥθερα, inner lamella without vestibules and fairly numerous mar-

κΥθερης ( Cythera, Cytherias [Kuthêra, Kuthêrias]), different forms of ginal pore canals especially anteriorly, and is sexually di-

a surname of Aphrodite, derived from the town of Cythera in Crete, or from the island of Cythera , where the goddess was said to have first morphic with females slightly higher than males. Although emerged, and where she had a celebrated temple. Cythere and Minyocythere fall in the same family they are not thought to be closely related.

Diagnosis.—A genus of the Family Cytheridae character- An apparent progression in time of strength of ornament

ized by subtriangular to subrectangular shape, modified lophodont hingement with accommodation groove on LV in Minyocythere species is evident: Minyocythere angulata and up to three types of normal pore canal especially large (almost smooth), M. macroporosa (ranges from weak to round or rarely elongate sieve-type pore canals. strong depressions), M. maculosa (strong depressions), M. tuberculata (strong swollen curving ridges), which, perhaps

Remarks.— Phraterfabanella Whatley and Boomer in Boomer surprisingly, matches the stratigraphic occurrence of these

et al., 2001 (Sinemurian), Camptocythere Triebel, 1950 and species in borehole Hambühren WA2 (although less well

Aphelocythere Triebel and Klingler, 1959 View in CoL (both Toarcian– in borehole Rodewald WA 2 where occurrences are patchy)

Aalenian) (diagnoses in Appendix 1) are the earliest examples (discussed below).

known to us of StPC in cytheroid ostracods (see “The fossil record of StPC” above). Some species of Aphelocythere, Stratigraphic and geographic range.—Aalenian–Bajocian,

e.g., A. perforata Plumhoff, 1963 ( Fig. 3A View Fig 1 View Fig ) closely resem- Middle Jurassic; NW Europe.

Albian. Paratype, SMF Xe 23765, male left valve in internal view (B 1), detail (B 2). C, D. Minyocythere maculosa ( Bate, 1963) . C. Topotype, SMF Xe 23743 from Bajocian, Basement Beds; Everthorpe Quarry, South Cave, UK, female left valve in internal view (C 1), detail (C 2), median depression (C 3). D. SMF Xe 23746 from Borehole Hambühren WA2, 171– 174 m, NW Germany, Witchellia laeviuscula Zone (Braun Jura γ), Lower Bajocian, female left valve in internal view (D 1), detail (D 2). E. Minyocythere macroporosa gen. et sp. nov. from Borehole Hambühren WA 2, 166 m, NW Germany, Witchellia laeviuscula Zone (Braun Jura γ), Lower Bajocian. Holotype, SMF Xe 23721, male left valve in internal view (E 1), detail (E 2). F. Minyocythere sp. cf. M. macroporosa gen. et sp. nov. from Borehole Rodewald WA 12, 386 m, NW Germany, Upper Aalenian (Braun Jura β upper). SMF Xe 23724, male right valve in internal view (F 1), detail (F 2). G. Minyocythere angulata gen. et sp. nov. from Borehole Hambühren WA2, 192– 198 m, NW Germany, Upper Aalenian (Braun Jura β). Paratype, SMF Xe 23741, male left valve in internal view (G 1), detail (G 2). Thin white arrows point to median depression; thick white arrows point to frontal scar; black square indicates detail of frontal scar.