Introduction

Most representatives of the polyphyletic group “Sphinctozoa“, the chambered sponges, are hypercalcified animals that probably belong to the Demospongea. The “Sphinctozoa“ range from the Cambrian to Recent. Senowbari-Daryan and García-Bellido (2002) provide a comprehensive overview on occurrence and distribution patterns of sphinctozoan sponges. They represent the most common sponges in late Palaeozoic and Triassic reefs and shallow-water calcareous deposits (Senowbari-Daryan and García-Bellido 2002; Senowbari-Daryan and Zankl 2010). Among hexactinellid sponges, chambered representatives are exceedingly rare; their record consists of only a few taxa from the Upper Triassic and Upper Jurassic. Five genera have been erected to date, including Casearia Quenstedt, 1858 (including the synonyms Innaecoelia Boiko, 1990 and Monilispongia Wu and Xiao, 1989), Caucasocoelia Boiko, 1990, Dracolychnos Wu and Xiao, 1989, Pseudoverticillites Boiko, 1990, and Esfahanella Senowbari-Daryan and Amirhassankhani 2012. The genus Casearia has been reported from the Upper Triassic and Upper Jurassic. Late Triassic representatives have been described from Iran, China and central Europe (Rigby et al. 1998; Senowbari-Daryan and Hamadani 1999; Senowbari-Daryan and Zankl 2010; Senowbari-Daryan and Amirhassankhani 2012), while the Late Jurassic ones come from Germany and Tadjhikistan (Schmidel 1780; Zittel 1878; Quenstedt 1858; Kolb 1910; Schrammen 1936; Müller 1974; Boiko 1990). Caucasocoelia and Pseudoverticillites have been reported from the Upper Triassic of Russia (Boiko 1990), while Dracolychnos comes from the Upper Triassic of China (Wu and Xiao 1989; Rigby et al. 1998). Esfahanella occurs in the Upper Triassic of Iran (Senowbari-Daryan and Amirhassankhani 2012).

We are not aware of any report of a chambered hexactinellid sponge older than Mesozoic. Moreover, the oldest representatives of the order Hexactinosida currently known are from the Late Devonian (e.g., Mehl and Mostler 1993; Rigby et al. 2001; Krautter 2002; Pisera 2006). The Late Ordovician hexactinellids Wareembaia Rigby and Webby, 1988 and Kalimnospongia Rigby and Webby, 1988 from Australia were initially included within the Lyssacinosida by Rigby and Webby (1988), but later placed in the family Wareembaiidae Finks and Rigby, 2004b and re-classified as Hexactinosida by Finks and Rigby (2004b). However, a number of reasons argue against hexactinosid affinity. For example, Mehl and Mostler (1993) have pointed out that the outermost skeletal layer of Wareembaia, which consists of supposed dictyonal strands (Rigby and Webby 1988: pls. 41: 4; 42: 6, 43: 1, 2), does not show the typical, fused hexactines, but rather diactines interconnected by synapticulae. Even the emended diagnoses of Wareembaia and Kalimnospongia in Finks and Rigby (2004b) leave doubts about the nature of sponge spiculation, suggesting that the “dictyonal strands” rather represent “rhabdodiactines”.

Fig. 1.

A. Geological map of the Cantabrian Zone with the provinces and units of Julivert (1971) and Pérez-Estaún et al. (1988). B. Simplified geological map of the Esla Nappe near Colle, showing location of study area. Based on Lobato et al. (1984). Modified after Fernández et al. (2006).

Zhuravleva and Pyanovskaya (1995) erected the family Tadassiidae and claimed that Tadassia from the Cambrian of Russia (South Tien Shan) is similar to representatives of Mesozoic chambered hexactinellid sponges (order Innaecoelida Boiko, 1990). Finks and Rigby (2004b) listed the Tadassiidae under class and order uncertain thus questioning their assignment to hexactinellid sponges at all. However, according to the description it seems very probable that these sponges are hexactinellids, especially when possessing stauractine spicules. But what we doubt is the chambered structure. Based on the figures it seems that variously shaped “chambers” rather represent single individuals overgrowing each other and not successive chambers within one individual.

The chambered sponges described in this paper come from the Lower Devonian (Emsian) locality of Colle in the Cantabrian Mountains. The Colle outcrops have been well known for their well-preserved and abundant invertebrate fossils since the 19th century (e.g., Verneuil 1850; Mallada 1875; Comte 1938, 1959; Truyols-Massoni 1981; Alvarez 1999; Schröder and Soto 2003). Fernández et al. (2006) conducted a facies analysis and sequence stratigraphic interpretation of the studied interval that focused on the development of reef complexes composed of coral biostromes and mud mounds. The latter yield an hexactinellid sponge fauna that was initially reported on by Fernández et al. (2006). From these rocks we describe the first chambered hexactinellid sponge from the Palaeozoic. This fossil represents the oldest record of the order Hexactinosida.

Fig. 2.

A. Chronostratigraphic chart, showing Devonian lithostratigraphic units of Asturo-Leonese facies that have been defined in the regions of Asturias (northern part of the Cantabrian Zone) and León (southern part of the Cantabrian Zone). Absolute ages based on Gradstein et al. (2004). Stratigraphic subdivision of the La Vid Group according to Vilas Minondo (1971) and Vera de la Puente (1989), but subdivision by Keller (1988) is also shown. B. Simplified stratigraphy of La Vid Group in relation to sea-level development (based on Keller and Grötsch 1990) showing location of studied interval of Valporquero Formation. Modified after Fernández et al. (2006).

Institutional abbreviations.—SNSB-BSPG, Bavarian State Collection of Palaeontology and Geology, Munich, Germany.

Geological setting

The fossils were collected from the Lower Devonian (Lower Emsian) succession of the upper Valporquero Formation near the village of Colle in the Cantabrian Mountains. The Valporquero Formation is part of the La Vid Group and comprises the more shaly unit in its middle and upper part. This shaly unit is rather monotonous, although its upper part contains a marly interval with limestone intercalations that constitutes the studied interval (Figs. 1, 2). These limestone beds are mostly bioclastic, although some coral biostromes and mud mounds exist as well, the latter of which contain the fossils described below (Figs. 3, 4). The coral biostromes are well understood today based on the work of Stel (1975), while the mud mounds have only been described briefly by Schmid et al. (2001). This interval corresponds to the Sagüera Member of the Esla Formation named by Keller (1988) and the Intermediate Limestone Member of Leweke (1982). According to the facies and sequence stratigraphic analysis by Fernández et al. (2006), mud mounds developed in 5th-order transgressive and early highstand systems tracts tied to 4th-order late lowstand to early transgressive systems tracts. Field relationships suggest that the mud mounds grew coevally with muddy sedimentation, with high frequency variations in carbonate vs. terrigenous mud sedimentation influencing their development. Mud mounds are encased in fossiliferous reddish shales/marls. They are dominated by microbial micrite, and fenestellid and fistuliporid bryozoans. Other metazoans such as crinoids, solitary corals, and the chambered sponges play only a minor role in mound formation and composition.

Fig. 3.

Stratigraphic section of Valporquero Formation at Colle, showing facies distribution including polymicritic mud mounds and part of section from which chambered hexactinellid sponge Casearia has been collected from mud mound facies. Modified after Fernández et al. (2006).

Environment and palaeoecology

The siliceous sponge-bearing, polymicritic bryozoan mudmounds and the surrounding fossiliferous sedimentary deposits (reddish shale/marlstone; facies C of Fernández et al. 2006) formed in a low-energy, fairly deep marine environment below the storm wave base, but apparently still under the influence of periodic storms. The latter is attested to by the occurrence of thin skeletal beds, which we interpret as distal tempestites, formed by storm-induced offshore directed bottom currents (storm surge) capable of transporting their suspension load even beyond the storm wave base (cf. Aigner 1982; Tucker and Wright 1990).

The overall faunal composition, textural features and the geometry of the Colle mounds are somewhat similar to deep water mounds constructed of microbial boundstone (Lees and Miller 1995; Monty 1995; Pratt 1995).

The assumption that these formations developed in relatively deep water is further corroborated by the scattered occurrence of the hexactinosidan sponge Casearia within the mounds (see systematic palaeontology below). In general, hexactinellids are indicative of deep water environments, not only in the Palaeozoic but also in the Meso- and Cenozoic (e.g., Wendt et al. 1989; Pratt 1995; Krautter 1997). In Recent environments, the order Hexactinosida proliferate in water depths between 100 and 6860 metres and range from the Arctic to Antarctic (e.g., Vodrážka and Crame 2011).

The environmental settings of the Mesozoic (Late Triassic, Jurassic) Casearia species are generally characteristic of deep water (e.g., Müller 1974; Rigby et al. 1998; Senowbari- Daryan and Hamadani 1999), although one species has been described from the shallow water Dachstein reef limestone (Senowbari-Daryan and Zankl 2010).

Mounds are known to have been formed predominantly by semi-lithified cyanobacterial micritic crusts and fenestellid and fistuliporid bryozoans (Fernández et al. 2006). Mud mound growth and its early lithification by bacterially precipitated peloidal crusts were essentially coeval with the sedimentation of the surrounding fossiliferous reddish shales/marlstone. The small mounds (up to 0.8 m thick) grew during relatively short periods of time, and under generally reduced background sedimentation rates. However, clay fallout rates varied with time, giving rise to periods of mud mound growth and encroachment onto the substrate, and periods of mound inactivity and clay veneering of its surface. Intermittent sedimentation rates and/or sediment winnowing during mound growth are indicated not only by the shaly partings within the mounds, but also by the ragged margins of both the mounds and the mushroom-like morphotypes of coral and multilayered bryozoan colonies (e.g., fistuliporids) in the inter-mound-facies. The mounds lack layering and zonation patterns, and it seems that they did not evolve beyond an embryonic developmental stage, and it is likely that largely uniform ecological conditions prevailed over the mud mounds' lifetime (Fernández et al. 2006). Moreover, undisturbed conditions during mud mound formation are also evidenced by the ecological requirements of hexactinosidan sponges, which are fragile, sessile suspension feeders.

Fig. 4.

Field image of a small polymicritic mud mound containing Casearia devonica sp. nov., Colle, Cantabrian Mountains; Lower Emsian.

It is noteworthy that numerous recent studies have reported hexactinosidan-dominated Mesozoic sponge faunas associated with sea-level highstands and accompanied by low sedimentation rates (e.g., Vodrážka et al. 2009; Schneider et al. 2011). The hexactinosidan sponges described in this paper proliferated under similar sedimentological conditions: mud mounds developed during transgression and subsequent stillstand with reduced but still existing background clay sedimentation (Fernández et al. 2006).

The dominance within the mounds of encrusting bryozoans over reef builders such as rugose and tabulate corals, as well as the common occurrence of mushroom-shaped, heavily calcified bryozoans in the contemporaneous intermound facies, might be due to (i) water depths exceeding those suitable for coral and stromatoporoid growth and/or (ii) a temperate shelf environment, which is a typical habitat for bryozoan communities (e.g., Smith 1995; Reguant and Zamarreño 1987). It has been speculated that the Colle mounds grew in somewhat cooler water based on the deeper- water setting, the fact that extant siliceous sponges grow exclusively in waters colder than 15° C and the palaeolatitudinal position of northern Spain at the southern margin of the tropical/subtropical belt (Krautter 1997; Copper 2002). However, sea surface temperature calculations for Early Devonian localities (including the Cantabrian Mountains) reveal a mean temperature of 25° C typical for modern tropical/ subtropical surface waters VanGeldern et al. (2006).

The overall dominance of heterotrophs (bryozoans, crinoids, sponges), as well as the growth of mound-forming microbialites, point to slightly increased nutrient input with mesotrophic conditions (Wood 1993; Copper 2002; Webby 2002). Moreover, Mesozoic microbialites are believed to have generally developed under slightly increased input of nutrients (Leinfelder et al. 1993; Dupraz and Strasser 1999; Olivier et al. 2005).

Systematic palaeontology

At high taxonomic levels, we follow the classification system for Mesozoic and Cenozoic hexactinellid sponges introduced by Reid (2004). It is noteworthy, that non-hexactinellid origin of the studied material was tested, too, especially because some Paleozoic “lithistid” demosponges may produce skeletons that could resemble hexactinosidan frameworks. This is the case of anthaspidellids (Paleozoic demosponges of the order Orchocladina Rauff, 1895; e.g., Finks and Rigby 2004a), which possess skeletons composed of regularly arranged dendroclones and trabs cored by monaxons. However, no one of these features have been identified in studied thin sections.

Fig. 5.

Holotype of chambered hexactinellid sponge Casearia devonica sp. nov. from the Lower Emsian at Colle, Cantabrian Mountains, NW Spain; in three serial thin sections (A–C). Main branch sectioned almost parallel to axial spongocoel, exhibiting stacked annular chambers. Serial sections of branch in lower left, which although not parallel to the axial spongocoel, shows changing growth direction. Overgrowth by cementing bryozoans (e.g., fistuliporids). A. BSPG 2012 I 46a; A₂, detail of A₁, showing tangential section of wall between chambers (i.e., dermal cortex) formed by spherically-enlarged multiradiate nodes producing triangular meshes. B. BSPG 2012 I 46b; B₂, detail of B₁, focusing on two subsequent chambers and gastral surface within spongocoel; fused hexactines produce polygonal to rounded meshes (examples arrowed). C. BSPG 2012 I 46c.

Fig. 6.

Chambered hexactinellid sponge Casearia devonica sp. nov., BSPG 2012 I 46c (holotype) from the Lower Emsian at Colle, Cantabrian Mountains, NW Spain. A. Detail of Fig. 5C; branch with irregularly-chambered structure, sectioned roughly parallel to growth direction and tangentially to dermal cortex. Upper chambers exhibiting seemingly irregular hexactinellid framework, which shows regular rectangular meshes in radial cross-sections (compare with Figs. 7 and 8A). B. Detail of A, showing tangentially-sectioned dermal cortex of small chamber (indicated by arrow), completely enclosed by considerably larger subsequent chamber. Triangular meshes of dermal cortex resulting from interconnecting, spherically-enlarged multiradiate nodes. C. Detail of lowermost chamber in A; tangential section showing enlarged nodes forming dermal cortex and producing triangular meshes (arrowed), and regular rectangular meshes directly below dermal cortex.

Fig. 7.

Three-armed branched individual of chambered hexactinellid sponge Casearia devonica sp. nov., BSPG 2012 I 47a (paratype) from the Lower Emsian at Colle, Cantabrian Mountains, NW Spain. Central branch exhibiting almost longitudinal section with chambers gradually increasing in size from base to top, and axial spongocoel. Irregular gastral surface within spongocoel, showing possible openings of exhalant canals (arrows). Sponge encrusted by fistuliporid bryozoans, at least some of which colonized surface of sponge post mortem, see, e.g., bryozoan fully overgrowing the osculum.

Fig. 8.

Chambered hexactinellid sponge Casearia devonica sp. nov. A. BSPG 2012 I 46b (holotype); regular rectangular meshes of hexactinosidan skeleton in radial cross section. Note paragaster in lower right of image and dissolved centres of several thickened spicule nodes (arrowed) which seem to be identical with those forming pseudolychniscid structures similar to that described, e.g., by Müller (1974). B. BSPG 2012 I 47a (paratype); dermal cortex between two chambers, constructed of single thickened hexactine layer with spherically-enlarged nodes. Nodes often irregularly elongated perpendicular to surface of wall (arrow).

Conclusions

Deeper-water mud mounds from the Lower Devonian of the Cantabrian Mountains (Northern Spain) yield a new hexactinosidan species, Casearia devonica sp. nov., which represents the first Paleozoic representative of the chambered hexactinellid sponges and the oldest hexactinosidan sponge. In spite of minor differences in overall skeletal organization, we believe that, the fossils from Spain can still be assigned to the genus Casearia with confidence. In contrast to other species in that genus, Casearia devonica sp. nov. shows stacked annular chambers that are highly variable in size and shape, and a cortex on the dermal surface that is composed of a single layer of hexactines with spherically-enlarged multiradiate nodes. Moreover, C. devonica sp. nov. was probably characterized by shallow, “primitive” inhalant canals based on the dense network of polygonal to rounded meshes on the gastral surface. Mounds (and sponges) grew below the storm wave base under reduced, but still noticeable background sedimentation rates. The faunal association, the ecological requirements of hexactinellids and the palaeolatitudinal circumstances together are suggestive of a temperate shelf environment.