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721 tocRevision of so-called Pomatoschistus (Gobiiformes, Teleostei) from the late Eocene and early Oligocene

Christoph Gierl and Bettina Reichenbacher

Article number: 20.2.33A
https://doi.org/10.26879/721
Copyright Palaeontological Association, July 2017

Author biographies
Plain-language and multi-lingual abstracts
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Submission: 7 September 2016. Acceptance: 13 June 2017

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ABSTRACT

The Gobiiformes (Teleostei) are among the most speciose groups of vertebrates, and are found in all aquatic habitats. Identification of extant gobiiform species is primarily based on soft-tissue characters, and their diversity and phenotypic variability often makes species determination difficult. Fossils normally lack soft-tissue features, and secure assignment of fossil Gobiiformes at family and genus levels can be extremely problematical. “Pomatoschistus bleicheri (Sauvage)” from the lower Oligocene of Rouffach (France) and “Pomatoschistus (?) cf. bleicheri (Sauvage)” from the upper Eocene of the Isle of Wight (England) exemplify these difficulties. These finds are of special interest, because they may represent the oldest fossil skeleton-based members of the Gobiidae + Oxudercidae (gobiiforms with five branchiostegals; hereafter 5brG). Re-examination of the type material of those two species now reveals the presence of a premaxilla with a postmaxillary process, which precludes assignment of these fossils to the genus Pomatoschistus. Indeed, they do not even belong to the 5brG because they display six branchiostegals. We conclude that the fossils from France and England both belong to †Paralates Sauvage. Differences in the shape of the frontal bones and the numbers of caudal fin rays allow us to assign the French material to †Pa. bleicheri Sauvage and the English specimens to †Pa. chapelcorneri n. sp. Thus the oldest currently known 5brG species based on articulated skeletons is †Gobius jarosi Přikryl and Reichenbacher, 2017 from the lower Miocene.

Christoph Gierl. Department of Earth and Environmental Sciences, Ludwig-Maximilians-Universität München, Richard-Wagner Straße 10, 80333 Munich, Bavaria, Germany; c.gierl@lrz.uni-muenchen.de
Bettina Reichenbacher. Department of Earth and Environmental Sciences, Ludwig-Maximilians-Universität München, Richard-Wagner Straße 10, 80333 Munich, Bavaria, Germany; b.reichenbacher@lrz.uni-muenchen.de

Keywords: Fossil gobiiform; new species; Gobiidae; Oxudercidae; branchiostegals

Final citation: Gierl, Christoph and Reichenbacher, Bettina. 2017. Revision of so-called Pomatoschistus (Gobiiformes, Teleostei) from the late Eocene and early Oligocene. Palaeontologia Electronica 20.2.33A: 1-17. https://doi.org/10.26879/721
palaeo-electronica.org/content/2017/1909-revision-of-pomatoschistus

http://zoobank.org/517F0A5F-A93C-4328-BA23-64F8062D97A8

INTRODUCTION

s figure1Gobiiformes are a group that shows high species diversity in marine, brackish and freshwater habitats (Patzner et al., 2011) with numerous adaptations to varied niches in these environments (e.g., Thacker, 2011). Their systematics at the family level was initially based on characteristic suites of morphological characters and has, more recently, been largely confirmed by studies using molecular data (e.g., Miller, 1973; Hoese and Gill, 1993; Johnson and Brothers, 1993; Thacker, 2009; Thacker and Roje, 2009; Agorreta et al., 2013; Thacker et al., 2015). A simplified phylogeny is given in Figure 1. Note that we use Oxudercidae instead of Gobionellidae because the latter is a junior synonym of the former (Nelson et al., 2016).

The fossil record of the Gobiiformes dates back to the lower Eocene (Gaudant, 1996; Bajpai and Kapur, 2004; Bannikov and Carnevale, 2016). Notably the Eocene skeleton-based fossils have not been assigned to any of the extant families, either owing to incomplete preservation (Gaudant, 1996) or because of an unusual character set (Bannikov and Carnevale, 2016). Also the Eocene “gobiid” otoliths described by Bajpai and Kapur (2004) probably do not belong to the Gobiidae but rather represent basal Gobiiformes such as Odontobutidae and Eleotridae (see Gierl et al., 2013).

The oldest skeleton-based records currently assigned to Gobiidae are those of “Pomatoschistus (?) cf. bleicheri (Sauvage, 1883)” from the upper Eocene of the Isle of Wight in England (Gaudant and Quayle, 1988) and “Pomatoschistus bleicheri (Sauvage, 1883)” from the lower Oligocene of the southern sector of the Upper Rhine Graben in France (Sauvage, 1883; Gaudant, 1979). Both have been provisionally assigned to Pomatoschistus, as these authors stated. Gaudant (1979) and Gaudant and Quayle (1988) observed certain features of the skeletons that were later recognized as important for distinguishing gobiids and oxudercids from all other gobiiform families (Gill and Mooi, 2012) and for discrimination within gobiid and oxudercid groups (e.g., McKay and Miller, 1997). The objective of this work is to re-investigate the previously described fossil material in the light of the newer literature and determine whether or not these specimens actually represent species of Pomatoschistus and thus a member of the Oxudercidae.

MATERIALS AND METHODS

The re-investigated specimens of “Pomatoschistus bleicheri ” comprise seven articulated skeletons and one skull from the quarry at Rouffach (France). This material is kept in the Naturhistorisches Museum Basel (NMB) under the collection numbers NMB Ruf 13_1 (skull), NMB Ruf. 6a/b, NMB Ruf. 9_1, NMB Ruf. 9_2, NMB Ruf. 11, NMB Ruf. 13_2 (counterpart of NMB Ruf. 11), NMB Ruf. 15a/b, NMB Ruf. 18. Additional specimens from Rouffach are curated in the NMB, but their preservation is very poor.

The re-investigated “Pomatoschistus cf. bleicheri ” fossils (n = 5) from the Isle of Wight include all available well-preserved specimens but one, which is in a private collection (see Gaudant and Quayle, 1988, p. 31). Three of these specimens are deposited in the Natural History Museum, London (NHMUK, previously BMNH) under the numbers NHMUK PV P 59784, NHMUK PV P 59785 (plus 59785_counterpart) and NHMUK PV P 59786, further poorly preserved specimens are NHMUK PV P 59774, NHMUK PV P 59775, NHMUK PV P 59776, NHMUK PV P 59777, NHMUK PV P 59787, NHMUK PV P 59788, NHMUK PV P 59797. The other two well-preserved specimens are kept in the Sedgwick Museum of Earth Sciences, Cambridge (SM) as SM C.23632 and SM C.23633.

Meristic and osteological characters of the skeletons were studied under a stereomicroscope equipped with a digital camera. Counts of rays in the caudal fin follow Fricke (1983). Counts of vertebrae include the uroterminal centrum. Measurements were taken with ImageJ v1.51a 64-bit (Rasband, 1997-2016) based on the digital images. Unless otherwise indicated, pictures were taken by the first author, and the figures were prepared using Adobe Photoshop CS6 (13.0.6) 64-bit.

Institutional abbreviations: NHMUK (Natural History Museum, London), NMB (Naturhistorisches Museum Basel), SM (Sedgwick Museum of Earth Sciences, Cambridge).

Other abbreviations: 6brG for gobiiforms with six branchiostegal rays; 5brG for gobiiforms with five branchiostegal rays; D2C for the distance between the end of second dorsal fin and the first dorsal (procurrent) ray of the caudal fin.

SYSTEMATIC PALAEONTOLOGY

Taxonomic classification follows Nelson et al. (2016).

Series PERCOMORPHA sensu Johnson and Patterson, 1993
Subseries GOBIIDA Nelson et al., 2016
Order GOBIIFORMES Günther, 1880
Family incertae sedis
Genus †Paralates Sauvage, 1883

Emended diagnosis. Six branchiostegals; first dorsal fin with seven spines; number of vertebrae 29 to 31; base of second dorsal fin shorter than D2C.

Type species.Paralates bleicheri Sauvage, 1883

Paralates bleicheri Sauvage, 1883
Figure 2, Figure 3.1, Figure 4

* 1883 Paralates bleicheri Sauvage: 483-485, pl. XI, figs. 1-2.

s figure21913 Paralates cf. bleicheri Sauvage. - Förster: 45, pl. III, fig. 37.

1934 Prolebias praecursor Weiler. - Théobald: 122 (pro parte).

1941 Paralates bleicheri Sauvage. - Maïkovsky: 55, pl. XII, fig. 86.

v 1979 Pomatoschistus bleicheri (Sauvage). - Gaudant: 131-137, pl. I, figs. 1-4.

? 1981 Pomatoschistus bleicheri (Sauvage). - Gaudant: 214, pl. I, fig. 4.

Material. A total of 29 specimens from Rouffach are curated in the NMB (NMB Ruf. 1 to NMB Ruf. 29); these specimens represent the entire material of the species available. Only seven articulated skeletons and one skull were well- preserved and served as the basis for this study: NMB Ruf. 13_1 (skull), NMB Ruf. 6a/b, NMB Ruf. 9_1, NMB Ruf. 9_2, NMB Ruf. 11, NMB Ruf. 13_2 (counterpart of 11), NMB Ruf. 15a/b, NMB Ruf. 18. The type material described by Sauvage (1883) is lost. Therefore Gaudant (1979) designated NMB Ruf. 15b as neotype.

Emended diagnosis. Small gobiiform fish ranging from 29 to about 55 mm in length. Body cylindrical. Head length about three times included in the standard length. Frontal bones anteriorly less than one-third of the width of the posterior part. First dorsal with seven spines. Total number of vertebrae: 29-30. Four to six (?seven) simple rays (=unbranched, unsegmented) in caudal fin dorsally and ventrally.

Description. For meristic characters and morphometric distances see Table 1 and Table 2. The description of the skull is mainly based on NMB Ruf. 13_1.

The orbital region of the frontals (Figure 2.1, Figure 3.1) is very narrow, less than one-third as broad as their posterior parts (also in NMB Ruf. 11). Other elements of the skull roof are certainly present, but are unidentifiable within the brownish mass. Of the ethmoid region only parts of the mesethmoid and the vomer are also recognizable.

s figure3In the jaws the premaxilla shows a broad postmaxillary process and a smaller articular process. A spine-like ascending process is not preserved (Figure 2.1). The maxilla is slender and bent, with a thick and forked articular process. The dentary is broad posteriorly and narrows anteriorly. Teeth are not preserved.

Most parts of the suspensorium and the hyoid arch are not identifiable. The quadrate is triangular and has a slender posteroventral process. The ceratohyal is broad in the short posterior part, while its long anterior part is quite slender. The epihyal (=posterior ceratohyal) is not preserved. Branchiostegals are not preserved.

The opercle is triangular and the subopercle is crescent-shaped. The preopercle is partially visible.

The vertebral column consists of 29 to 30 vertebrae, of which 17 or 18 are post-abdominal. The number of rib pairs seems to be at least eight.

The cleithrum is thick and slightly curved. The dorsally placed post-temporal is a rather robust V-shaped bone. The rest of the pectoral girdle is not recognizable.

The pelvic girdle is triangle-shaped in its posterior part and forms with its counterpart a rhombus-like structure. The fins consist of one spine and five rays each.

The first dorsal fin has seven spines, while the second has one spine and 10 rays. The base of the second dorsal is clearly shorter than the caudal peduncle. This is also true for the anal fin, which has one spine and eight or nine rays, and lies slightly behind the second dorsal fin.

s figure4The caudal endoskeleton consists of two hypural plates (hy1+2, hy 3+4). Hypural 3+4 is fused to the terminal centrum (urostyle). Hypural 5 is long and slender, as is the parhypural. Epurals are not preserved. The caudal fin has 12 segmented and branched rays, two specimens may have up to 13 segmented and branched rays (see Table 1). One or two segmented and unbranched rays occur dorsally and ventrally, and four to possibly seven simple rays (=unsegmented and unbranched) are inserted dorsally and ventrally.

Scales and otoliths are not preserved.

Remarks. The species †Paralates bleicheri was first described by Sauvage (1883) from the site Rouffach in the Upper Rhine Graben. As the genus name suggests, Sauvage thought this represented a perch-like fossil. Furthermore, he mentioned the presence of seven branchiostegals and two anal fin spines, but these characters are not mentioned in the later descriptions by Gaudant (1979, 1981) and are also absent in the specimens examined here. Nevertheless, judging by the rest of the original description (Sauvage, 1883), e.g., the presence of a long caudal peduncle (longer than the second dorsal fin base), and the original figures, it is clear that the species described by Sauvage is the same as that reported by Gaudant (1979) from the same locality. Gaudant (1979) interpreted †Paralates bleicheri as a gobiid and assigned it to the genus Pomatoschistus based on meristics.

Moreover, in 1981 Gaudant described another specimen of †Paralates bleicheri from the sondage Niederhergheim, not far from Rouffach. This specimen has a slightly smaller anal (8 vs. 9 rays) and second dorsal fin (9 vs. 10 rays) and its frontals also differ in shape from those seen in the specimens from Rouffach. Thus this fish might not represent †Pa. bleicheri and may need revision.

Range. Early Oligocene (Rupelian).

Occurrence. Southern Upper Rhine Graben (Rouffach, ?Niederhergheim; France).

Paralates chapelcorneri n. sp.
Figure 3.2, Figure 5, Figure 6, Figure 7, Figure 8

zoobank.org/06A1F122-AF03-4481-8605-8C6107583C6A

1977 Gobius.  Ford: 109.

s figure5v 1988 Pomatoschistus (?) cf. bleicheri (Sauvage, 1883). - Gaudant and Quayle: 31-35, figs. 13-16.

Material. Five articulated skeletons: NHMUK PV P 59784, NHMUK PV P 59785 (plus 59785_counterpart), NHMUK PV P 59786, SM C.23632, SM C.23633. These specimens served as the basis for this study. Further poorly preserved specimens are NHMUK PV P 59774, NHMUK PV P 59775, NHMUK PV P 59776, NHMUK PV P 59777, NHMUK PV P 59787, NHMUK PV P 59788, NHMUK PV P 59797. The specimens listed above represent the entire material of the species that is accessible.

Holotype. NHMUK PV P 59785 (part and counter part); specimen in lateral view; complete skeleton.

Type locality and horizon. Chapelcorner Fish Bed (Colenutt’s bed 3), collected at King’s Quay, southeast of East Cowes; Isle of Wight (UK); Upper Eocene (Priabonian).

Etymology. Named after the unit in which the fossils were found: Chapelcorner Fish Bed.

Diagnosis. Small fish up to about 35 mm in total length; body cylindrical; frontals relatively broad anteriorly in comparison to their posterior portions (width greater than 40% to that of the posterior section; see Figure 3.2, Figure 5); seven spines in first dorsal fin; 30 to 31 vertebrae; 10 to 12 simple rays (= unbranched and unsegmented) in the caudal fin dorsally and ventrally; pterygiophore formula 3-2121100.

Description. For meristic characters and morphometric distances see Table 1 and Table 2.

The orbital region of the frontal bones is relatively broad (see Diagnosis and Figure 3.2). Other bones in the skull roof are not determinable.

The parasphenoid and basioccipital show a shape typical for gobiiform fishes. The parasphenoid is long and has a slender anterior and a broader posterior part. The basioccipital has a broad, roughly triangular shape and narrows posteriorly.

s figure6The premaxilla has a broad postmaxillary process, a smaller articular process and probably the spine-like ascending process, which seems premorse (Figure 5). Some conical teeth are visible. The maxilla is slender, with a thick articular head. The dentary is long and slender and bears conical teeth.

The shape of the palatine is not discernible. The ectopterygoid is slender and wedge-shaped.

In one specimen (SM C.23632) bones bearing pharyngeal teeth of conical shape can be seen, which could correspond to ceratobranchial 5 and pharyngobranchial 3. The ceratohyal shows a slender anterior and a broader posterior part, the epihyal (=posterior ceratohyal) is not preserved. The number of branchiostegals is six, of which the two slender anterior ones attach to the narrow anterior part of the ceratohyal.

The triangular opercle has cycloid scales on its upper part (Figure 5).

The vertebral column consists of (29?) 30-31 vertebrae with 18?-19 post-abdominal vertebrae. There are at least seven rib pairs.

The pectoral fins have about 16 rays. The cleithrum is slightly curved, the supracleithrum is club-shaped (Figure 5). The post-temporal is V-shaped and has a process at the apex. Radials are present but not well-preserved.

The pelvic girdle is recognizable but badly preserved. The pelvic fins have one spine and five rays.

The first dorsal fin has seven spines, the second dorsal fin one spine and 10 rays. The pterygiophore formula of the first dorsal fin is 3-2121100.

The anal fin inserts slightly behind the second dorsal, and has one spine and eight rays.

s figure7The caudal endoskeleton consists of two triangular hypural plates (hypural plate 1+2 and 3+4, see Figure 7). The upper one is fused to the terminal centrum. Hypural 5 is small and splint-like. The parhypural is slender and as long as the lower margin of hypural 1+2. At least one epural is present. The caudal fin has 12 or 13 segmented and branched rays, and one to two segmented and unbranched rays, dorsally and ventrally. There are 10 to 12 simple rays (=unbranched and unsegmented) dorsally and 12 ventrally [caudal fin formula according to the scheme of Fricke (1983) in specimen NHMUK PV P 59785_counterpart: (x), ii, 13, ii, (xii), see Figure 7].

The squamation consists of cycloid scales on the opercle and ctenoid scales on the rest of the body.

Remark. The meristic data for the specimens from Rouffach are rather similar to that for the fishes from the Isle of Wight (see Table 1), as is the long caudal peduncle, and we therefore place the species †Paralates chapelcorneri n. sp. in the same genus as †P. bleicheri.

Paralates chapelcorneri n. sp. from the Isle of Wight is different from †Pa. bleicheri from Rouffach for two reasons:

(1) In †Pa. chapelcorneri n. sp. the supraorbital part of the frontals is clearly broader than in the Rouffach fishes (see Figure 3.2 vs. Figure 3.1). In NMB Ruf. 13 the width in the supraorbital part (0.63 mm) is 22 % of the width in the posterior part (2.86 mm); in NHMUK PV P 59786 from England it is 40 % (0.71 mm vs. 1.77 mm). Also Gaudant and Quayle (1988: 32) mentioned that the supraorbital part of the frontal is relatively broad in NHMUK PV P 59786 (now †Pa. chapelcorneri n. sp.). Although the specimen of †Pa. chapelcorneri n. sp. shown in Figure 3.2 is more dorso-ventrally compressed than the specimen of Pa. bleicheri shown in Figure 3.1, the shapes of their frontals are different and this cannot be explained by differences in preservation alone.

(2) †Paralates chapelcorneri n. sp. has more unbranched and unsegmented rays in the caudal fin (at least 10 vs. maximal seven).

DISCUSSION

s figure8The specimens re-examined here display certain features, which clearly show that they belong neither to Pomatoschistus nor even to the Oxudercidae (see below).

Assignment to the Gobiiformes

The fishes from both localities are members of the Gobiiformes because they exhibit the following features (see Springer, 1983; Johnson and Brothers, 1993; Winterbottom, 1993; Wiley and Johnson, 2010): suspensorium fenestrae are large (Figure 8) (Gosline, 1955; see for illustration Parmentier et al., 2013, figure 4 A); hypurals 1 and 2 are fused; hypurals 3 and 4 are fused to each other and to the urostyle (Figure 7); parietals are absent.

Relationship to Pomatoschistus?

Pomatoschistus is a member of the ‘sand-goby’ group among the Oxudercidae (Agorreta et al., 2013). The ‘sand-gobies’ have been defined as a distinct clade based on morphological characters by McKay and Miller (1997). This clade has additionally been confirmed based on molecular work (see McKay and Miller, 1997; Agorreta et al., 2013; Thacker, 2013).

The informal name ‘sand goby’ refers to the preferred occurrence of these fishes on sandy substrates; no formal name exists for this clade. The group comprises the genus Pomatoschistus, together with Gobiusculus, Knipowitschia, Economidichthys and Hyrcanogobius (see McKay and Miller, 1997; Agorreta et al., 2013). The ‘sand gobies’ show a distinctive feature in the jaws: the absence of a postmaxillary process on the premaxilla, except in some females of Gobiusculus flavescens (McKay and Miller, 1997). Other oxudercids, most gobiids, as well as the members of the families with six branchiostegals (see Figure 1), possess such a postmaxillary process (McKay and Miller, 1997). Moreover, McKay and Miller (1997) found that the pterygiophore formula in the ‘sand gobies’ starts with (12...) and that there is more than one interneural space.

A postmaxillary process on the premaxilla is present in both species of †Paralates (see Figure 2.1, Figure 5.1). Additionally, the pterygiophore formula is discernible in the specimen NHMUK PV P 59785 of †Paralates chapelcorneri n. sp. (Figure 6.2) and starts with (21...). We therefore conclude that †Paralates is clearly different from the genus Pomatoschistus and not a member of the ‘sand gobies’.

Moreover, †Paralates is not a member of the Gobiidae or Oxudercidae, because it has six branchiostegals. Gaudant and Quayle (1988) mentioned the presence of an entopterygoid, which would provide an additional criterion for exclusion of the fossil from the Gobiidae and Oxudercidae. However, the bone depicted as an entopterygoid by Gaudant and Quayle (1988) is not positioned near the ectopterygoid (as would be expected), and its anatomical assignment is therefore difficult to verify; it may be the distorted metapterygoid. The long caudal peduncle, which is longer than the base of the second dorsal fin, may also argue for an assignment to the “non-Gobiidae” (see Murdy et al., 2002).

Affinity of †Paralates to Previously Described Gobiiform Fossils

One feature that clearly differentiates †Paralates from other fossil Gobiiformes is the number of spinous rays in the first dorsal fin. The only previously described species that has a first dorsal fin with seven spines is the Oligocene species †Pirskenius radoni Přikryl, 2014. However, the genus †Pirskenius is also characterized by seven branchiostegal rays (Obrhelová, 1961; Přikryl, 2014) whereas only six branchiostegal rays are present in †Paralates.

A few fossil gobiiforms with six branchiostegal rays have been described, i.e., †Lepidocottus aries (Agassiz, 1839) (see Gierl et al., 2013), †L. papyraceus (Agassiz, 1839) (see Pandolfi et al., 2016), †Eleogobius brevis (Agassiz, 1839) and †E. gaudanti Gierl and Reichenbacher, 2015. Whereas the species of †Lepidocottus have only 25-26 vertebrae, the two known species of †Eleogobius Gierl and Reichenbacher, 2015 from the lower Miocene of S. Germany, like †Paralates, have 29-31. However, in †Eleogobius the D2C can sometimes be slightly longer than the base of D2 (Gierl and Reichenbacher, 2015), while †Paralates has a very long D2C that is about twice the length of the base of D2 (see Table 3).

Further species with large numbers of vertebrae compared to †Paralates include †Gobius multipinnatus (Meyer, 1852) from the lower Miocene of Germany and Pomatoschistus sp. from the upper Miocene of the North Caucasus, Russia. Also these species, however, clearly differ from †Paralates: †G. multipinnatus has a bigger second dorsal fin (D2) (I+12-13 vs. I+10 in †Paralates) and the length of the base of D2 exceeds D2C (see Gierl and Reichenbacher, 2015). Pomatoschistus sp., besides being younger (middle Miocene), has bigger anal and dorsal fins (see Carnevale et al., 2006).

Phenotypic Affinity of †Paralates to the Extant Eleotrid Gobiomorphus

The pterygiophore formula 3-2121100 seen in †Paralates has been described (albeit with only one interneural space) in a few members of the Gobiidae, Thalasseleotrididae, and Eleotridae (see Birdsong et al., 1988). This specific formula, however, occurs only in genera that show some polymorphism with regard to the pterygiophore formula, e.g., in Gobiomorphus, Gobiosoma, Gobulus, Gobiodon, and Thalasseleotris (see Table 3). In addition, it is never the ‘normal case’ but always exceptional (see Hoese and Larson, 1987; Birdsong et al., 1988; Lee 1993; our unpublished data). However, those genera of the Gobiidae and Thalasseleotrididae for which a pterygiophore formula 3-212110 has been reported always have more or fewer vertebrae than are seen in †Paralates (Hoese and Larson, 1987; Birdsong et al., 1988; Lee 1993; our unpublished data) (see Table 3). Only the eleotrid genus Gobiomorphus reveals six branchiostegals (like in †Paralates) and a similar combination of the pterygiophore formula and vertebrae count as seen in †Paralates: The pterygiophore formula is 3-212110 (vs. 3-2121100) and the number of vertebrae is 12+19 (vs. 12+17-19).

Species of Gobiomorphus are now restricted to coastal rivers of Eastern Australia and rivers and lakes in New Zealand (Hoese and Larson, 1987). Among the Gobiiformes, Gobiomorphus is difficult to define based on meristic and osteological characters because it belongs to the genera with the highest levels of variation in skeletal features (see McDowall, 1975; Hoese and Larson, 1987; Birdsong et al., 1988). For instance, the ectopterygoid is present in some species, and lacking in others (Hoese, 1984; Hoese and Larson, 1987), the epural number varies between 1 and 2 (see Birdsong et al., 1988) and the number of vertebrae (excluding the terminal centrum) ranges from 26 to 31 (McDowall, 1975). Nonetheless, the genus Gobiomorphus has been recognized as monophyletic based on molecular and morphological data (see McDowall, 1975; Stevens and Hicks, 2009).

Skeletons of Gobiomorphus-like fossils have been described from the Miocene of New Zealand: †Mataichthys bictenatus Schwarzhans et al., 2012 has a lower vertebral count (28) and a smaller anal fin (I+7) (see Schwarzhans et al., 2012) than seen in †Paralates. Gobiomorphus sp. (described in McDowall et al., 2006) also has fewer vertebrae (26-28), and the count of its rays in the caudal fin falls into the range of †Paralates. Most other counts are uncertain, due to the moderate preservation of the fossils. So it is hard to say if there is a relationship between the fossil Gobiomorphus sp. from New Zealand and †Paralates, in spite of the similarities between the latter and extant Gobiomorphus species.

Conclusions

The question remains whether ‘sand gobies’ are represented in the fossil record. A specimen determined as “Pomatoschistus cf. bleicheri ” from the lower Miocene of Bergama (Turkey) was described (Rückert-Ülkümen, 2000), but the description given makes it hard to accept the proposed assignment (7 branchiostegals; only 27 vertebrae). The only reliable records of ‘sand goby’ skeletons seem to be Pomatoschistus sp. (with otoliths in situ) from the upper Miocene of the North Caucasus (Russia) described in Carnevale et al. (2006) and the species described in Schwarzhans et al. (2017) from the middle Miocene (Sarmatian) of the Central Paratethys (Croatia). Besides, there are some otolith-based species of the ‘sand gobies’ from the middle Miocene (see Weiler, 1943; Wienrich et al., 2009; Schwarzhans, 2010, 2014; Bratishko et al., 2015; Schwarzhans et al., 2015; Schwarzhans et al., 2017).

For now, the oldest member of modern Gobiiformes with five branchiostegals in the fossil record is the gobiid †Gobius jarosi Přikryl and Reichenbacher, 2017 in Reichenbacher et al. (2017) from the lower Miocene of Central Europe (Czech Republic). Phylogenetic analyses based on a combination of morphology, and molecular data will be necessary to more accurately understand the phylogenetic relationships of the many different extant and extinct gobiiform fishes from Europe.

ACKNOWLEDGEMENTS

We would like to thank E. Bernard (NHMUK, London, UK), M. Riley (Sedgwick Museum, Cambridge, UK), and L. Costeur (NMB, Basel, Switzerland) for their kind support with the loan of the specimens described here. We are grateful for the UV pictures provided by H. Tischlinger and the photographs made by M. Schellenberger and K. Webb. We also acknowledge the constructive comments of D. Erpenbeck (LMU Munich, Germany), two anonymous reviewers, and the editorial crew of PE. This work was funded by a grant from the Deutsche Forschungsgemeinschaft (RE 1113/20-1).

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