Spongillida Manconi and Pronzato, 2002

Order Spongillida Manconi and Pronzato, 2002 View in CoL

Species richness of sponges of the order Spongillida Manconi and Pronzato, 2002 inhabiting continental waters (previous suborder Spongillina Manconi and Pronzato, 2002, and subsequent emendations 2011, 2015) reach 240 valid species (about 3%) of the 8850 species of all extant Porifera ( Hooper et al. 2011; Van Soest et al. 2017). The order Spongillida comprises 48 genera belonging to 6 families i.e., Metaniidae , Spongillidae , Lubomirskiidae , Malawispongiidae , Potamolepidae , and the exclusively fossil Palaeospongillidae . The monophyletic Spongillida ( Manconi and Pronzato 2002, 2015, 2016a, b; Erpenbeck and Wörheide 2007; Cárdenas et al. 2012; Morrow and Cardenas 2015) according to earlier studies, colonized continental water not later than in the Triassic from a hypothetical marine Haplosclerida ancestor Pronzato and Manconi 1994; Manconi and Pronzato 2002, 2015).

Spongillida View in CoL are widespread on all continents, excluding Antarctica, and several species, possible species complexes, show a wide geographic range ( Manconi and Pronzato 2007, 2008, 2015, 2016a, b). Several studies focus on their occurrence under extremely stressing conditions e.g., temporary water (permafrost) in circumpolar northern regions, temporary water in hot deserts, small temporary ponds in sub arid-arid conditions, and tropical hydrographic basins characterised by flooding and extreme water level variations Manconi and Pronzato 2008, 2015, 2016b).

The abundance of freshwater sponges varies widely from region to region, and in some cases sponge populations are so dense and flourishing that they strongly impact human health and/or productive activities. In the Amazon basin, for example siliceous spicules of sponges are so abundant in the water column, during the raining season, that they are causing permanent eye damage ( Volkmer-Ribeiro et al. 2006) to riverine populations. In the lower Mekong basin Thailand) high biomass of large sponges heavily colonizes fishermen nets, damaging the fishery and aquacul-

ture infrastructures ( Manconi et al. 2013). On the contrary, sponges are very rare or absent in some Mediterranean islands, in the Canary Archipelago, and several Pacific Ocean archipelagos ( Manconi and Pronzato 1994 a, 2009, 2015; Manconi 2008).

Freshwater sponges display highly variable body shape and dimensions, consistency and colour. Specimens range from thin whitish crusts a few mm thick strictly adhering to the substratum, to dark brown massive cushions, and to green branching or erected growth forms. In most species the body consistency is soft and fragile while in other species it is hard with a notably compact texture ( Fig. 1 View Fig ). Under unfavourable conditions, such as harsh climate periods, freshwater sponges are reduced, by cryptobiosis, to small spherules known as gemmules (resting bodies) in carpets on the substratum, scattered in the skeletal network, or grouped at the sponge basal portion; but they can be also dispersed in sediments and water column.

The main diagnostic traits that enable us to identify Spongillida are few i.e., skeletal architecture, range of spicule arrangement, geometry, size and shape of spicules, and gemmular traits. Skeletal network is a reticulum of siliceous spicules associated with a notably variable amount of spongin. Spicules, both megascleres ( Fig. 2 View Fig ) and microscleres ( Fig. 3 View Fig ) are monaxial from smooth i.e., oxeas and strongyles, to spiny i.e., acanthoxeas and acanthostrongyles. Gemmules of freshwater sponges are subspherical to hemispherical (100–1200 μm in diameter, Fig. 4 View Fig ), and bear a structured coat of spongin (gemmular theca) variably armed by the spicules (gemmuloscleres) to protect a mass of staminal, totipotent cells contained inside. Morphotraits of this resting stage (i.e., gemmular cage, gemmular theca, gemmular foramen, arrangement of spicules, architecture of spongin structures, together with shape and ornamentations of spicules) are notably diversified and diagnostic at the genus and species level ( Manconi and Pronzato 2002) ( Fig. 4 View Fig ). Particularly important, from a taxonomic and phylogenetic point of view, are gemmuloscleres ( Fig. 5 View Fig ).

Identification of gemmule-producing sponge species, however, is usually not possible when gemmules are absent from specimens during a phase of their life cycle. Moreover, a number of freshwater sponges, mostly belonging to taxa endemic to ancient lakes, do not produce gemmules. In the palaeontological context, most of the diagnostic traits mentioned above are not useful. Skeletal architecture/network is usually not preserved because spicules joined with spongin become dispersed after its decay. The main character in palaeontological studies is morphology of gemmuloscleres and, to a lesser degree, microscleres, but these are limited only to certain taxa, as indicated above. Megascleres are usually not characteristic enough for generic determination, but some inferences can be made in some cases, e.g., presence of strongyles vs. oxeas.

If the about 240 species of living freshwater sponges are a small minority compared to the marine ones, among the 5000 of all fossil sponge taxa ( Hooper et al. 2011) freshwater species prior to the Quaternary, are, putatively, no more than 16. Their geographic distribution is largely scattered in all continents, except Australia and Antarctica ( Fig. 6 View Fig ). Considering the palaeogeography, fossil freshwater sponge taxa seem to have preferred temperate and tropical climates ( Fig. 7).

All discussed here freshwater sponge taxa are Miocene or older in age. Sponges from younger deposits, generally ascribed to extant genera and species, are not included. The sixteen taxa are arranged in chronological order, beginning from the oldest to the most recent. Measurements are reported as length and/or length × thickness.

Institutional abbreviations.—MABA, Museo Argentino de Ciencias Naturales “Bernardino Rivadavia”, Buenos Aires, Argentina; PWL, Naturhistorisches Museum (Palaeontological Collection), Mainz, Germany;SMF, Senckenberg Museum Frankfurt, Germany; TMNH, Toyohashi Museum of Natural History, Japan; USNM, National Museum of Natural History, Smithsonian Institution, Washington D.C., USA (formerly United States National Museum).