taxonID	type	description	language	source
03CEAF23A466FF81FF36EBAEF69DFB33.taxon	description	“ Leucosolenida with syconoid, sylleibid or leuconoid organisation, and a distinct cortex supported by tangential tetractines whose centripetal apical actines cross the outer part or the whole of the choanosome. Tangential triactines and small tetractines may also be present in the cortex. The choanoskeleton is typically inarticulated, composed of apical actines of cortical tetractines and the unpaired actines of subatrial spicules. In species with a thick wall, scattered triactines and / or tetractines may also be present, either among the spicules of the inarticulated choanoskeleton or forming a distinct subatrial layer. An atrial skeleton is always present ” (Borojevic et al. 2002).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A466FF81FF36ECD6F067FAEB.taxon	description	“ Amphoriscidae with syconoid organisation of the aquiferous system. Scattered spicules in the choanosome are always absent ” (Borojevic et al. 2002).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A466FF85FF36ED9CF017FCCD.taxon	description	Citations and synonymies: Ute chrysalis Schmidt 1864: 23 (original description); Amphoriscus chrysalis Haeckel 1870: 177; Sycilla chrysalis Haeckel 1872: 256; Sycurus chrysalis Haeckel 1872: 256 (variation of Sycilla chrysalis); Amphoriscus chrysalis Poléjaeff 1883: 7; Dendy & Row 1913: 782; Breitfuss 1935: 29; Burton 1963: 535; Vacelet 1981: 165; Radolović et al. 2015: 305; Klautau, Cavalcanti & Borojevic 2017: 105; Cóndor-Luján et al. 2019: 1825.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A466FF85FF36ED9CF017FCCD.taxon	materials_examined	Type material: Unknown. Type locality: Lesina, Lissa, Adriatic Sea. Analysed material: LBIM 1968 - 557 L (Glenans, France; four slides containing sections of the skeleton). LBIM 1968 - 556 L (Marseille, France; three slides containing sections of the skeleton). LBIM 1968 - 327 (Roscoff, France; four slides containing sections of the skeleton). LBIM 1968 - 355 (Roscoff, France; two slides containing sections of the skeleton). LBIM 1968 - 326 (Roscoff, France; seven slides containing sections of the skeleton and dissociated spicules). LBIM 1968 - 280 (Roscoff, France; one slide containing dissociated spicules). BMNH 1954.8. 12.195 (Plymouth; M. B. L. collection; one slide containing sections of the skeleton). BMNH 195512.13. 9 (Plymouth; R. W. H. collection; one slide containing sections of the skeleton; not A. chrysalis — see below). SME- 500 (Biscay Bay, France; one specimen and one slide containing sections of the skeleton). Morphology: Colour in spirit varies from yellowish-white to yellowish-brown (Burton 1963). The specimen SME- 500 has a tubular shape and measures ca. 4 mm x 1 mm (Fig. 1 A). According to Schmidt (1864), the type had a peduncle, which is not visible in SME- 500. Smooth surface and a single osculum without fringe of trichoxeas. Syconoid aquiferous system. Abundant larvae were observed in the choanosome of LBIM 1968 - 556 L (Figs. 1 B, D, E). Anatomy: Skeleton typical of the family Amphoriscidae (Fig. 1 B). The cortical region is formed mainly by giant and abundant tetractines and a few tangential triactines, pierced by tufts of trichoxeas (Fig. 1 C). Abundant subatrial tetractines and triactines point their unpaired actine towards the cortex (Fig. 1 E). The atrial skeleton is formed exclusively by tetractines, and these have a very long apical actine (Fig. 1 F). Some lacunae occur along the subcortical and subatrial regions, mainly in the specimen LBIM 1968 - 556 L, possibly due to fixation and / or the occurrence of tissue retraction over time (Fig. 1 D). Fusiform diactines were found in the spicules slides of LBIM 1968 - 326, but these were not observed in the sections of the skeleton of the same specimen and were not found in any other analysed material. In addition, BMNH 1955.12.13.9 differs from the remaining analysed samples in its skeletal composition: cortical tetractines, subatrial triactines, and atrial tetractines, and thus cannot be classified as A. chrysalis (see Remarks). Spicules: Among the analysed material, slides containing dissociated spicules were available only for LBIM 1968 - 326. The values shown here therefore only reflect this sample. Cortical tetractines (Fig. 2 A): Conical with blunt tips. The paired actines are curved, and one of the tips is broken in most of the spicules (118.8 – 298.3 ± 90.5 – 520.2 / 23.8 – 38.9 ± 7.9 – 53.1 μm). The unpaired actine is smaller or the same size as the paired actines (106.1 – 203.6 ± 107.4 – 485.1 / 22.2 – 41.5 ± 8.0 – 58.6 μm). The apical actine is straight and longer than the other actines (281.5 – 421.6 ± 87.2 – 636.2 / 23.8 – 39.8 ± 7.7 – 53.7 μm). Cortical triactines (Fig. 2 B): Conical with blunt tips, less abundant than the cortical tetractines. Paired actines are slightly curved (246.2 – 360.5 ± 66.8 – 466.0 / 22.3 – 35.6 ± 6.3 – 45.2 μm). The unpaired actine is straight, sometimes slightly lanceolate (241.7 – 468.8 ± 140.7 – 673.9 / 23.1 – 37.2 ± 8.1 – 52.6 μm). Subatrial triactines and tetractines (Figs. 2 C, D): Cylindrical to slightly conical and blunt. The paired actines are short and straight (triactines: 102.1 – 145.0 ± 23.3 – 185.3 / 6.2 – 10.2 ± 1.9 – 13.6 μm; tetractines: 92.9 – 139.7 ± 45.5 – 253.1 / 6.3 – 8.5 ± 2.0 – 11.4 μm). The unpaired actines are straight and long (triactines: 232.5 – 340.4 ± 49.6 – 435.3 / 8.5 – 13.0 ± 2.4 – 17.4 μm; tetractines: 142.6 – 271.3 ± 67.6 – 350.8 / 8.0 – 9.6 ± 1.2 – 11.1 μm). The apical actine of the tetractines is short and curved (20.3 – 31.0 ± 14.3 – 68.6 / 5.3 – 7.6 ± 1.7 – 10.1 μm). Atrial tetractines (Fig. 2 E): Cylindrical with sharp tips. The paired actines are long and curved (100.3 – 173.0 ± 49.3 – 315.4 / 6.0 – 14.1 ± 15.9 – 97.1 μm). The unpaired actine is straight (62.5 – 169.3 ± 95.9 – 445.6 / 4.9 – 12.3 ± 3.7 – 21.2 μm). The apical actine is straight and long. It is generally twice as large as the paired actines (102.2 – 271.7 ± 126.4 – 527.2 / 7.9 – 11.9 ± 2.6 – 17.8 μm).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A466FF85FF36ED9CF017FCCD.taxon	discussion	Remarks: According to the original description (Schmidt 1864), Amphoriscus chrysalis is comprised only of tetractines (the presence of only this spicule category and the external morphology are the only characters mentioned by the author). The material analysed here has cortical and subatrial triactines, differing from the original description. Haeckel (1872) also described A. chrysalis as having only tetractines, though subatrial (and possibly cortical) triactines similar to those we observed were illustrated in his work (Plate 43, figures 2 and 3). It is not clear if Haeckel analysed the same material described by Schmidt (1864), but the short original description lacking either spicule measurements or illustrations of the spicule types and skeleton show the importance of Haeckel’s (1872) work for the recognition of A. chrysalis. The difficulty in recognising this species is also caused by a lack of type material. Our results and the figure provided by Haeckel (1872) thus allow us to state that A. chrysalis has triactines. We were also able to recognise the main feature of A. chrysalis reported by Haeckel (1872) in the samples analysed here: the long apical actine of the atrial tetractines (> 100 μm). This feature was important for supporting our decision to identify some samples as A. chrysalis sensu Haeckel (1872). Among the analysed samples, BMNH 1954.8.12.195 and BMNH 1955.12.13.9 had been listed by Burton (1963: 634) under the name A. chrysalis. Our results indicate that the latter does not belong to A. chrysalis due to its different skeletal composition. Here, we allocate it in A. decennis sp. nov., while BMNH 1954.8.12.195 remains A. chrysalis. Some of the samples analysed in this study had previously been identified as A. chrysalis by Borojevic et al. (1968), namely: LBIM 1968 - 557, LBIM 1968 - 556 L, LBIM 1968 - 327, LBIM 1968 - 355, LBIM 1968 - 326, and LBIM 1968 - 280. The list of species from Roscoff was provided without morphological details, meaning that these specimens are described for the first time in this study. Compared to the other species of the genus, the most similar to A. chrysalis is A. elongatus. However, the main difference between them is the abundance of tetractines: the former has abundant tetractines in the subatrial region, while in A. elongatus tetractines were observed to be rare. Additionally, the actines of the subatrial triactines of A. chrysalis are more conical and bear blunt tips, unlike A. elongatus, which has more cylindrical actines and with sharp tips.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A466FF85FF36ED9CF017FCCD.taxon	distribution	Distribution: Amphoriscus chrysalis is one of the few species of the genus that has several records besides its type locality. It has been described in the Adriatic and Celtic Seas (Schmidt 1864; Borojevic et al. 1968) and is reported here in the Mediterranean part of France and the Bay of Biscay (Fig. 3). The corresponding marine ecoregions of the world (MEOW) are the Celtic Seas, South European Atlantic Shelf, Adriatic Sea, and Western Mediterranean (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A462FF8AFF36EB8DF738FE65.taxon	materials_examined	Type material: BMNH 1884.4. 22.27 (holotype). Station 145, off Prince Edward Islands (46 ° 40 ’ S – 37 ° 50 ’ E), 275 to 567 m depth, 27 December 1873. Type locality: off Prince Edward Islands, Indian Ocean. Analysed material: BMNH 1884.4. 22.27 (holotype; specimen and one slide containing sections of the skeleton). BMNH 1955.12. 13.10 (one slide containing sections of the skeleton) and BMNH 1955.12. 13.11 (one slide containing sections of the skeleton), both from Plymouth; R. W. H. Row collection.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A462FF8AFF36EB8DF738FE65.taxon	description	Morphology: The colour of the holotype in ethanol is white (Fig. 4 A). It is a fragment with tubular shape and apical osculum, measuring 4 cm x 0.2 cm (length x width). The surface is slightly hispid. Syconoid aquiferous system (Fig. 5). Anatomy: The skeleton is typical of the genus Amphoriscus, and the inarticulation is evident (Figs. 4 D and 5 D, E). The cortical region is formed by giant tetractines and small sagittal triactines (Figs. 4 B, C). The apical actine of these giant tetractines may reach the atrial cavity. All the analysed samples exhibited trichoxeas perforating the cortex without forming tufts (Fig. 5 C). The subatrial region is formed by abundant triactines with long unpaired actine and rare tetractines (Fig. 5 D). The latter are more frequent in the specimens BMNH 1955.12. 13.10 and BMNH 1955.12. 13.11 but also occur in the holotype. Additionally, in these specimens from Plymouth, we also observed a few modified subatrial triactines in which the actines that surround the atrial wall have different lengths and shapes (Fig. 5 E). These spicules were found in the sections. Due to the occurrence of other spicules overlapping them, it was not clear if they were pseudosagittal. All the subatrial spicules point their unpaired actines to the cortex, in opposition to the apical actine of the cortical tetractines (Figs. 4 D and 5 D, E). The atrial region is comprised exclusively of tetractines (Fig. 5 F). Spicules (Table 1): A figure containing only the spicule categories, commonly shown in studies of the taxonomy of calcareous sponges, could not be prepared since only slides containing sections of the skeleton were available. Cortical tetractines: Giant, conical with blunt tips. Paired actines are curved and long. The unpaired actine is curved and smaller or the same size as the paired actines. The apical actine is straight and long. Cortical triactines: Slightly conical and sharp. Paired actines are straight to slightly curved. Unpaired actine is shorter and straight. Subatrial triactines: Cylindrical to slightly conical with sharp tips. Paired actines are straight. Unpaired actine is straight and long, sometimes reaching the cortical region. Subatrial tetractines: Rare, with cylindrical actines and sharp tips. Paired actines are slightly curved. Unpaired actine is straight and larger than the paired ones. Apical actine is short and curved. Atrial tetractines: Vary in size. Cylindrical actines with sharp tips. Paired actines are long, thin, and straight. Unpaired actine is slightly curved. Apical actine is straight.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A462FF8AFF36EB8DF738FE65.taxon	discussion	Remarks: The original description of Amphoriscus elongatus was based on a single specimen sampled during the Challenger expedition (Poléjaeff 1883). It was tubular and elongated (hence the species name elongatus). Close to the osculum, it was divided into two tubes, a feature that can no longer be recognised in the type (Fig. 4 A). According to Poléjaeff (1883), A. elongatus has “ an important anatomical peculiarity — the tendency of the radial tubes to meet in threes, fours, or in larger numbers around the same shallow invagination of the gastric cavity ”. We could not clearly understand this organisation described by Poléjaeff (1883), even after analysing the holotype and additional specimens. Nevertheless, we are convinced that the aquiferous system of A. elongatus is not a typical syconoid in which choanocyte chambers run in parallel from the atrium to the cortex. Instead, choanocyte chambers of A. elongatus seem to branch, possibly causing, when sectioned, the holes observed in Figure 5 along the chambers’ length. More studies are needed to better describe this organisation, which depends on the discovery of fresh specimens for histological and electron microscopy analyses. Our results indicate an important difference between our description of the holotype and that provided by Poléjaeff (1883), namely the occurrence of rare subatrial tetractines. We first observed this characteristic in the slides of the specimens from Plymouth and then, after a careful reanalysis, also in the holotype. With respect to the geographical distribution, BMNH 1955.12. 13.10 and BMNH 1955.12. 13.11 are from Plymouth, United Kingdom (Northern Atlantic Ocean), while the holotype BMNH 1884.4. 22.27 was sampled “ off Prince Edward Islands ” (Southern Indian Ocean). In general, representatives of a species with such a disjunct distribution are viewed as questionable in the literature, mainly due to the low dispersal capability of the larvae of calcareous sponges (Maldonado 2006). The only morphological difference between the three analysed samples is the putative presence of pseudosagittal triactines in the subatrial region of those from Plymouth. These spicules were not found in the holotype, and we assumed that the absence could be the result of plasticity. The analysis of a larger set of specimens, preferably using an integrative approach, is needed to elucidate this question. The species that most closely resembles A. elongatus in its skeletal composition is A. pedunculatus (cortical triactines, tetractines and trichoxeas, subatrial triactines, and atrial tetractines). These species differ mainly in the presence of rare subatrial tetractines in the former and the size of the cortical tetractines, which are larger in A. elongatus (paired actines: 443.6 ± 59.0 / 48.7 ± 7.9 μm; unpaired actine: 397.2 ± 42.1 / 52.7 ± 4.9 μm; apical actine: 453.8 ± 60.3 / 48.2 ± 6.4 μm) than in A. pedunculatus (paired actines: 225.5 ± 39.3 / 27.2 ± 4.3 μm; unpaired actine: 182.9 ± 7.2 / 27.2 ± 3.8 μm; apical actine: 303.8 ± 50.7 / 29.4 ± 5.4 μm).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A462FF8AFF36EB8DF738FE65.taxon	distribution	Distribution: Off Prince Edward Islands, South Africa (Poléjaeff 1883) and Plymouth, United Kingdom (present study). Corresponding MEOW: Prince Edward Islands and Celtic Seas (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46EFF8FFF36E8B4F2CAFC35.taxon	materials_examined	Type material: BMNH 1896.11. 5.18 (paratype). Lesina, Adriatic Sea (The holotype had not been located). Type locality: Lesina, Adriatic Sea. Analysed material: BMNH 1896.11. 5.18 (paratype; two slides containing sections of the skeleton). Morphology: The type specimen was not available. However, according to the original description, the sponge has a branched body formed by several tubes with apical osculum and unified at the base (Lendenfeld 1891). The aquiferous system is syconoid. Amphiblastulae are easily observed in some of the histological sections (Fig. 6 A). Anatomy: The cortical skeleton is formed by giant tetractines and has trichoxeas perpendicularly disposed. The cortical tetractines have a long apical actine, which often protrude through the atrial cavity (Figs. 6 B, C, E). The subatrial region is formed exclusively by triactines (Fig. 6 E). The atrium presents tetractines with short apical actine and few triactines (Fig. 6 F). Spicules (Tables 2 and 3): A figure containing only the spicule categories, in line with common practice, could not be prepared since only slides containing sections of the skeleton were available. Cortical tetractines: Slightly conical with blunt tips. The paired actines are long and slightly curved, being usually broken for unknown reasons. The unpaired actine is curved and smaller than the paired ones. The apical actine is long and thick, commonly perforating the atrial wall. Subatrial triactines: Slightly conical to cylindrical, sharp tips. The paired actines are straight or have a slight curvature when touching the atrial wall. The unpaired actine is straight and long, extending up to the cortical region. Atrial tetractines: Cylindrical and sharp. Paired actines are long and curved. The unpaired actine is straight and smaller or the same size as the paired ones. The apical actine is short and curved. Atrial triactines: Not abundant, similar in shape to the atrial tetractines.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46EFF8FFF36E8B4F2CAFC35.taxon	discussion	Remarks: Lendenfeld (1891) described a set of specimens, with the presence of embryos reported for at least one. Sections of this specimen were represented by the author in plate IV, figure 123 b (Lendenfeld 1891), though we cannot unequivocally confirm that it corresponds to the paratype analysed here based solely on the illustration. Our suspicion was raised by the presence of embryos in BMNH 1896.11.5.18, which can be easily observed along the walls of the choanocyte chambers (Fig. 6). Ebnerella was erected to allocate species of Amphoriscus with diactines (Lendenfeld 1891). Ebnerella gregorii was the only species originally described to this genus, which was soon abandoned (Dendy & Row 1913). After analysing the paratype, we figured out that the diactines mentioned by Lendenfeld (1891) correspond to trichoxeas. Burton (1963) questioned the presence of atrial triactines in A. gregorii. These spicules were confirmed in this study (Fig. 6 F). They are not abundant and usually have a broken unpaired actine, which makes it difficult to recognise them immediately. Compared to other species belonging to Amphoriscus, A. gregorii most closely resembles A. bucchichii. They differ mainly by the presence of atrial triactines in the former, while the latter only has atrial tetractines. Additionally, only one category of tetractines can be seen in the cortical region in A. gregorii, while reports on A. bucchichii by Ebner (1887) mention the presence of subcortical tetractines in addition to the cortical tetractines. Amphoriscus chrysalis, A. cyathiscus, A. cylindrus, A. kryptoraphis, A. oviparus, A. salfii, A. synapta, A. testiparus, and A. urna have tetractines in the subatrial region, which are absent in A. gregorii. Amphoriscus elongatus has triactines in the cortical region while A. gregorii has only cortical tetractines. Finally, the recently described species, A. ancora and A. pedunculatus, have anchoring spicules and peduncle, absent in A. gregorii.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46EFF8FFF36E8B4F2CAFC35.taxon	distribution	Distribution: Lesina, Adriatic Sea (Lendenfeld 1891). Corresponding MEOW: Adriatic Sea (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A468FF8DFF3CEBD5F0F6F85A.taxon	materials_examined	Type material: UFRJPOR 5802 (Holotype). Saco do Poço, São Sebastião, São Paulo State, Brazil (23 ° 45 ’ 40.3 ” S – 45 ° 14 ’ 53.5 ” W); 13 m depth; F. F. Cavalcanti, V. Padula & L. Kremer; 03 December 2008. UFRJPOR 5803 (Paratype). Saco da Ponta Grossa, São Sebastião, São Paulo State, Brazil (23 ° 46 ’ 31.8 ” S – 45 ° 13 ’ 54.8 ” W); 6 m depth; F. F. Cavalcanti & V. Padula, 03 December 2008. Type locality: Saco do Poço, São Sebastião, São Paulo State, Brazil. Analysed material: UFRJPOR 5802 (holotype; specimen and slides containing sections of the skeleton and dissociated spicules). UFRJPOR 5803 (paratype; specimen and slides containing sections of the skeleton and dissociated spicules). UFRJPOR 5801 (specimen and slides containing sections of the skeleton and dissociated spicules), Serraria Island, São Sebastião, São Paulo, Brazil (23 ° 48 ’ 47.9 ” S – 45 ° 13 ’ 44.0 ” W); 9 m depth; F. F. Cavalcanti & V. Padula, 04 December 2008. MNRJ 5818 (specimen and slides containing sections of the skeleton and dissociated spicules). Alcatrazes Archipelago, São Sebastião, São Paulo, Brazil (24 ° 06 ’ 00.0 ” S – 45 ° 40 ’ 59.9 ” W); 12 m depth; M. Custódio & C. Santos, 03 May 2002. UFRJPOR 5776 (specimen and slides containing sections of the skeleton and dissociated spicules), Saco da Saia, Arraial do Cabo, Rio de Janeiro, Brazil (23 ° 00 ’ 23.0 ” S – 42 ° 00 ’ 36.0 ” W); 1 m depth; G. Muricy, 17 March 1988. Morphology: The specimens are similar in size and shape, with tubular shape and apical osculum surrounded by a delicate fringe of trichoxeas (Fig. 7 A). The peduncle is white in live specimens and brownish / orange in ethanolpreserved specimens, but the peduncle is brownish / orange. The surface is slightly hispid due to the trichoxeas of the cortical region. The atrial cavity is hispid and fills the entire body of the specimens. The aquiferous system is syconoid. Anatomy: The cortical region has several broken spicules. It is mostly formed by giant tetractines with long apical actines. Triactines are also present, but they are less abundant (Fig. 7 B and C). Trichoxeas are abundant throughout the entire cortex (Fig. 7 D) and may reach the choanosome (Fig. 7 E). The subatrial region is comprised exclusively of triactines. They vary in size, but the unpaired actine is always long (Fig. 7 C). The atrial skeleton is comprised of tetractines (Fig. 7 F). Spicules (Table 4; Fig. 8): Trichoxeas: Very thin, fusiform with sharp tips. Straight or slightly curved. Mostly broken (Fig. 7 D). Cortical triactines (Fig. 8 A): Conical with blunt tips. The paired actines are slightly curved. The unpaired actine is straight. Cortical tetractines (Fig. 8 B): Conical with blunt tips. The paired actines are slightly curved, as well as the unpaired one. The apical actine is straight and long. Subatrial triactines (Fig. 8 C): Conical to slightly conical and blunt. Paired actines are short and straight. The unpaired actine is straight. Atrial tetractines: Slightly conical and sharp. Paired actines are slightly curved and larger or the same size as the apical actine. The unpaired actine is straight and longer than the other actines. The apical actine is straight (Fig. 8 D).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A468FF8DFF3CEBD5F0F6F85A.taxon	discussion	Remarks: Amphoriscus pedunculatus was recently described (Klautau et al. 2017), with an original description in which important taxonomic characters were fully described and illustrated. The redescription provided in the present study differs only with respect to the tips of the spicules: cortical and subatrial spicules are described here as having blunt tips while they were reported as being sharp in the original description. In our opinion, the differentiation between blunt and sharp tips may not always be obvious, but the availability of images (as in Figure 8) helps resolve any doubts. Slight differences were also found in the measurements of the cortical tetractines of the holotype: according to Klautau et al. (2017), the range observed in the length of the unpaired actine is larger (120.0 – 238.5 ± 58.2 – 350.0 µm) than that obtained here (177.8 – 182.9 ± 7.2 – 188.0 µm). These differences may be related to the existence of several microscopical slides containing dissociated spicules, and the largest spicules may not be evenly distributed. Among the species with peduncle, Amphoriscus pedunculatus is the only one with a subatrial skeleton formed exclusively by triactines. The remaining species, A. chrysalis, A. cyathiscus, and A. testiparus, have both triactines and tetractines or only tetractines.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A468FF8DFF3CEBD5F0F6F85A.taxon	distribution	Distribution: The species seems to be restricted to the southeastern Brazilian coast in São Sebastião (São Paulo state), and Arraial do Cabo (Rio de Janeiro state) (Klautau et al. 2017). Distribution: São Sebastião (São Paulo state) and Arraial do Cabo (Rio de Janeiro state). Corresponding MEOW: Southeastern Brazil (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46BFF91FF36ECCEF3B9FE41.taxon	materials_examined	Type material: ZMB 2698 (Holotype; Ambon Island, Maluku, Indonesia). Not analysed in the present work. Type locality: Ambon Island, Maluku, Indonesia. Analysed material: BMNH 1886.6.7.32 (two slides containing sections of the skeleton). Port Jackson, Australia; previously identified as A. cylindrus in Burton, 1963: 634. Morphology: The holotype of A. semoni was not available for redescription, and the material analysed here (deposited in the NHM) was comprised of two microscope slides. Aquiferous system is syconoid. Anatomy: The material evaluated in the present study (BMNH 1886.6.7.32) was deposited at the Porifera collection of the NHM under the name A. cylindrus (Fig. 9). It is formed by giant cortical tetractines, with paired and unpaired actines laying on the cortex (Figs. 9 A, B). The organisation of the skeleton is inarticulate due to the unpaired actine of the subatrial triactines and the apical actine of the cortical tetractines (Figs. 9 A – C). The atrium is perforated by the apical actine of the small atrial tetractines (Fig. 9 D). Spicules (Tables 5 and 6): A figure containing only the spicule categories could not be prepared due to the lack of a slide of dissociated spicules. Cortical tetractines: Irregular, conical, and sharp. The basal actines (paired and unpaired) are slightly curved from the base to the tips. The apical actine is straight and long. Subatrial triactines: Irregular, cylindrical to slightly conical, sharp. The paired actines are straight. The unpaired actine is longer or the same size as the paired actines. Atrial tetractines: Irregular, cylindrical, small, thin, and sharp. The paired actines are curved. The unpaired actine is similar to the paired ones. The apical actine is straight and short, always very thin.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46BFF91FF36ECCEF3B9FE41.taxon	discussion	Remarks: BMNH 1886.6.7.32 was deposited in the NHM as A. cylindrus (Burton 1963), but its subatrial skeleton is comprised of triactines and not tetractines, as in A. cylindrus. The only species of Amphoriscus whose organisation is consistent with this specimen — cortical tetractines, subatrial triactines, and atrial tetractines — is A. semoni. The specimen is from Port Jackson, Australia, in the same biogeographical region as the type locality of A. semoni (Ambon Island, Indonesia) and isolated from the type locality of A. cylindrus (the Adriatic Sea). Therefore, we suggest the identification of BMNH 1886.6.7.32 as A. semoni. Figure 9 shows its skeletal organisation, in which the subatrial and atrial layers are clearly evident. In our opinion, these illustrations are important for further recognition of specimens belonging to A. semoni. Among the characters described by Breitfuss (1896), A. semoni is bright white when preserved, and the atrial surface is perforated by the apical actine of the colossal cortical tetractines. The specimens described as A. semoni by Van Soest & De Voogd (2015, 2018) present minor differences in the colour and length of these apical actines. The sample ZMAPOR 08073, collected in Sumbawa, Indonesia, was green alive and beige after fixation. The apical actine of its cortical tetractines does not exceed 600 μm (see Tables 8 and 9; Van Soest & De Voogd 2015), while in the holotype, they vary from 520 to 790 μm (Breitfuss 1896). In their most recent study, Van Soest & De Voogd (2018) described a new set of specimens of A. semoni (ZMAPOR 10527), sampled in Seychelles, Western Indian Ocean, which were white alive and beige after fixation. The apical actines of the cortical tetractines do not perforate the atrium, although they measure 239 – 882 μm (Van Soest & De Voogd 2018). The differences between the holotype and the other specimens described in both works by Van Soest & De Voogd provide a better understanding of the intraspecific variation of A. semoni. These are precious data, usually rare for Amphoriscus species since the original description, based on one or few specimens, is all that is available for many species of the genus. Amphoriscus semoni resembles two species of the Adriatic Sea, namely A. gregorii and A. bucchichii. However, A. semoni differs in having a cortical skeleton comprised exclusively of tetractines.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A46BFF91FF36ECCEF3B9FE41.taxon	distribution	Distribution: Ambon Island, Indonesia (Breitfuss 1896); Seychelles (Van Soest & De Voogd 2018); Port Jackson, Australia (present study). Corresponding MEOW: Banda Sea, Seychelles, and Manning-Hawkesbury (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A476FF90FF36EA01F6C9F835.taxon	etymology	Etymology: From the Latin decem + annus (meaning decades). The name is related to the time span the specimens remained in the collection before being recognised as a new species.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A476FF90FF36EA01F6C9F835.taxon	diagnosis	Diagnosis: Amphoriscus with cortical skeleton comprised of trichoxeas and one type of tetractine variable in size, subatrial skeleton comprised of triactines and atrial tetractines.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A476FF90FF36EA01F6C9F835.taxon	materials_examined	Type material: UFRJPOR 9031 holotype (Île Riou, Marseille, France; 05 / VI / 1967). UFRJPOR 9032, UFRJPOR 9033, UFRJPOR 9034, and UFRJPOR 9035 — paratypes (Île Riou, Marseille, France; 05 / VI / 1967). Type locality: Île Riou, Marseille, France. Additional material: UFRJPOR 5822 (Île Riou, Marseille, France; 05 / VI / 1967). Several fragments from one or more specimens. BMNH 1955.12. 13.9 (Plymouth; R. W. H. Row). Morphology: The specimens are cylindrical, with differences in thickness along the body, as they are thicker at the base. Smooth surface, colour white in spirit. The osculum is apical and naked. The holotype (UFRJPOR 9031) measures 2.0 x 1.0 cm (height x width), while the largest specimen, the paratype UFRJPOR 9035, measures 3.0 x 1.0 cm (Fig. 10 A). The atrial cavity occupies the entire body of the specimen. The aquiferous system is syconoid and seems slightly disorganised in the paratype UFRJPOR 9032, possibly due to the presence of embryos and amphiblastulae. Anatomy: The organisation is typical of Amphoriscidae, with an inarticulate skeleton formed mainly by giant cortical tetractines (Fig. 10 B). Smaller tetractines also occur in the cortex and are less abundant than the giant ones. Trichoxeas are present (Fig. 10 C). The inarticulation of the skeleton is due to the apical actine of the cortical tetractines and the unpaired actines of subatrial triactines (Fig. 10 D). The atrial region is comprised exclusively of tetractines with short apical actines (Fig. 10 E, F). These short apical actines and those of the giant cortical tetractines perforate the atrial cavity, making the atrial surface hispid. Spicules (Table 7; Fig. 11): Cortical tetractines: Actines are conical and blunt. The paired actines are curved, while the unpaired one is straight. Apical actine is long, straight, and usually extends up to the atrial cavity (Figs. 11 A, A’). Subatrial triactines: Actines are cylindrical to slightly conical, with blunt tips. The paired actines are curved from the base to the tips and are always smaller than the unpaired one (Fig. 11 B). Atrial tetractines: Actines are cylindrical and sharp. The paired actines are long and curved from the base to the tips. Unpaired actine is curved and usually smaller than the paired actines. The apical actine is short and straight or slightly curved (Figs. 11 C, C’).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A476FF90FF36EA01F6C9F835.taxon	discussion	Remarks: Amphoriscus decennis sp. nov. does not present anchoring spicules or peduncle, which differs from A. ancora, A. chrysalis, A. cyathiscus, A. pedunculatus, A. synapta, and A. testiparus. Among the remaining species, A. semoni most closely resembles the new species due to its skeletal organisation: cortical tetractines, subatrial triactines, and atrial tetractines. Nevertheless, the atrial tetractines of A. decennis sp. nov. have smaller apical actines [holotype: 47.0 – 61.2 ± 9.3 – 73.4 / 9.4 – 10.7 ± 1.1 – 13.2 μm] than the type of A. semoni [according to the original description, the apical actine is 100 – 130 / 9 μm; Breitfuss (1896)]. Among the proposed paratypes, the largest apical actine of the new species was 97.2 μm (maximum value, obtained for the specimen UFRJPOR 9033). Although close to the minimum value of the size range described by Breitfuss (1896), the measurements found here for A. decennis sp. nov. for this actine are, in general, smaller than in A. semoni. Additionally, cortical spicules are considerably thicker in A. decennis sp. nov. (holotype — paired: 31.9 – 58.5 μm, unpaired 30.1 – 41.4 μm, apical 35.0 – 52.1 μm versus paired: 10 – 20 μm, unpaired 10 – 20 μm, apical 19 – 27 μm in A. semoni). Finally, only A. decennis sp. nov. has trichoxeas. The presence of small cortical tetractines in A. decennis sp. nov. may also be useful to differentiate it from A. semoni, although we considered them to belong to the same category as the giant cortical tetractines. The geographical distribution of both species is also different. Type specimens of A. decennis sp. nov. were sampled in the Mediterranean Sea (more specifically at Île Riou, Marseille, France), while A. semoni is known to occur across the central Indo-Pacific region (type locality — Ambon Island, Indonesia). A specimen of A. decennis sp. nov. from Plymouth was also recognised (as discussed along with the remarks of A. chrysalis), which remains consistent with a separate species distribution from that of A. semoni. A wide distributional range is not common in calcareous sponges and has been associated with erroneous taxonomic identification [such as the specimen BMNH 1886.6.7.32, from Australia, previously identified as A. cylindrus by Burton (1963)] or with the occurrence of introduced species. Since there is no reason to suspect that A. semoni could have invaded regions outside the Indo-Pacific, we consider the distribution additional evidence to support the new species.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A476FF90FF36EA01F6C9F835.taxon	distribution	Distribution: Mediterranean Sea and Plymouth, United Kingdom (BMNH 1955.12.13.9; see remarks of A. chrysalis). Corresponding MEOW: Western Mediterranean and Celtic Seas (Spalding et al. 2007).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A471FF9BFF36ED61F739FE19.taxon	materials_examined	Type material: BMNH 1928.2. 15.833 (Holotype; St. 6, Tristan da Cunha, South Atlantic; 80 – 140 m deep). Type locality: Tristan da Cunha, South Atlantic. Morphology: Colour is beige after fixation. The holotype is a tubular fragment (Fig. 12 A), and a fringe of trichoxeas was present, according to Burton (1932). The type of aquiferous system is unclear. Anatomy: The skeleton has no similarity with the other species of Amphoriscus. The cortical region is formed by triactines of varying sizes and subcortical giant tetractines (which are possibly the only typical character of Amphoriscidae). However, there is no typical inarticulation (Fig. 12 B). The presence of several broken spicules makes the visualisation of the triactines difficult (Fig. 12 C). The apical actines of the subcortical tetractines cross the entire choanosome, often perforating the atrium (Figs. 12 D, E). The subatrial / atrial region is comprised exclusively of large tangential diactines. They are abundant and line the atrial cavity (Figs. 12 E, F). A specific atrial skeleton comprised of triactines or tetractines is absent. According to Burton (1932), large diactines similar to those found in the inner part of the sponge were found projecting from the cortex, but they were not observed here. The aquiferous system could not be recognised and was not mentioned along the original description. Spicules: Cortical triactines: Regular, actines are slightly conical and sharp. The actines are straight (paired actines: 123.1 – 150.7 ± 21.6 – 204.4 / 8.4 – 12.2 ± 1.7 – 15.3 μm; unpaired actines: 81.5 – 133.6 ± 23.2 – 180.0 / 8.9 – 122.3 ± 2.0 – 18.3 μm) (Fig. 13 A). Subcortical tetractines: Giant, actines are slightly conical to conical and blunt. The paired actines are slightly curved (111.4 – 146.6 ± 21.8 – 192.1 / 10.8 – 14.5 ± 2.0 – 19.2 μm). The unpaired actine is curved from the base to the tip (93.9 – 116.7 ± 21.5 – 156.6 / 14.1 – 15.2 ± 1.1 – 16.9 μm). The apical actine is long and conical (174.3 – 228.3 ± 29.1 – 285.4 / 16.9 – 20.8 ± 2.2 – 26.3 μm) (Fig. 13 B). Diactines: Large, sinuous along their length. Most of them have one of the tips blunt while the other is sharp (330.0 – 464.8 ± 89.6 – 632.6 / 9.0 – 18.9 ± 4.0 – 25.7 μm) (Fig. 13 C).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A471FF9BFF36ED61F739FE19.taxon	discussion	Remarks: This species was originally described as Leucaltis gastrorhabdifera (subclass Calcinea) and was later transferred to Amphoriscus (subclass Calcaronea) (Burton 1932, 1963). Such a reallocation would, by the standards of modern-day research on Calcarea systematics, be considered out of the ordinary and require a detailed explanation, yet at that time Burton did not note the reasons supporting his decision in any detail. In his discussion of the genus Leucaltis, Burton (1963) argued that “ L. gastrorhabdifera is aberrant and is here doubtfully assigned to Amphoriscus ”, suggesting that the only certainty the author had was that it was not Leucaltis. He named the species “ Amphoriscus? gastrorhabdifera ”, and although we suspect that he was influenced by the presence of the giant cortical tetractines, this cannot be confirmed. Also, there is no information or illustration in the literature about the aquiferous system of A. gastrorhabdifera, which would be essential to support its allocation in Amphoriscus. Whether or not it was one of the characters used by Burton to assign the species in Amphoriscus is a question that remains unanswered. We analysed the holotype (BMNH 1928.2.15.833) in this study. The microscopical slides contain sections of the skeleton that were probably not stained since it was not possible to unequivocally confirm whether A. gastrorhabdifera has the syconoid aquiferous system typical of the genus. We observed the main morphological characters reported in the original description, such as the presence of cortical triactines, subcortical giant tetractines with a long apical actine, and diactines. Burton (1932) mentioned diactines protruding through the cortex, but we did not observe this characteristic. The absence of a subatrial layer of triactines / tetractines was also confirmed and, consequently, the absence of inarticulate skeletal organisation. Therefore, the most important diagnostic characters typical of Amphoriscus either could not be confirmed (the syconoid aquiferous system) or are absent (the inarticulation formed by the apical actines of giant cortical tetractines and the unpaired actine of subatrial spicules). In order to assess the possibility of assigning A. gastrorhabdifera in another genus, a diagnosis of all genera under the order Leucosolenida was carried out. The presence of triactines and tetractines and of an atrial layer of diactines is a remarkable character found only in Sycodorus, although members of this genus are syconoid. Tangential triactines and tetractines also occur along the atrial cavity, suggesting that, even if A. gastrorhabdifera is syconoid, it could not be allocated in Sycodorus. An alternative decision would be to propose a new genus. The reasons why we did not choose this option to solve the problem of A. gastrorhabdifera were as follows: (i) the holotype is tiny, and no reports of additional specimens exist that could enrich our understanding of the morphology of the new genus; (ii) the lack of data on the aquiferous system could raise doubts on the family in which the genus should be inserted and also makes the description of a robust diagnosis difficult; (iii) the species is represented only by the holotype, found at Tristan da Cunha, Southern Atlantic Ocean, at a depth of 80 to 140 m. The lack of perspective in finding fresh samples to elucidate the questions mentioned earlier suggests that the problem with the species would persist (not as Amphoriscus but as a newly named genus); finally, (iv) we cannot undoubtedly rule out A. gastrorhabdifera actually belonging to Amphoriscus as the absence of an inarticulate organisation could be a secondary character caused by the loss of subatrial spicules along the species’ evolutionary history. The latter question will be resolved after the species is tested in phylogenetic analyses, though, as highlighted above, there is no fresh material available. Therefore, we decided to be conservative and avoid potentially increasing the number of open questions on the classification of this species. Amphoriscus gastrorhabdifera is thus maintained in the genus, but we indicate that it should be considered as incertae sedis until the discovery of additional samples.	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47CFF9BFF36E9F9F621FC85.taxon	description	“ Leuconoid Calcaronea with the skeleton either composed exclusively of microdiactines or in which microdiactines constitute exclusively or predominantly a specific sector of the skeleton, such as choanoskeleton or atrial skeleton. Large or giant spicules are frequently present in the cortical skeleton, from which they can partially or fully invade the choanoderm. In sponges with a reinforced cortex, the inhalant pores can be restricted to a sieve-like ostia-bearing region. Dagger-shaped small tetractines (pugioles) are frequently the sole skeleton of the exhalant aquiferous system. Although the skeleton may be highly reinforced by the presence of dense layers of microdiactines in a specific region, an aspicular calcareous skeleton is not present ” (Borojevic et al. 2002).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47CFF9BFF36EB45F1CDFB31.taxon	description	“ Baerida with a choanoskeleton consisting of giant triactines, and / or of tetractines in no particular order, and / or of very numerous microdiactines. No traces of radial organisation can be seen in the choanoskeleton. The cortical skeleton consists of triactines, giant diactines, and / or numerous microdiactines, and occasionally the basal actines of cortical giant tetractines. The choanoskeleton consists of scattered spicules similar to those observed in the cortex, to which numerous microdiactines can be added or which can be entirely replaced by microdiactines. The exhalant aquiferous system is formed by ramified canals that have no tangential skeleton, being loosely or densely covered by harpoon-shaped pugioles and / or microdiactines ” (Borojevic et al. 2002).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47CFF9BFF36ECD1F0C2FA51.taxon	description	“ Baeriidae in which the choanoskeleton consists of giant triactines and / or tetractines, lying without apparent order, and of very numerous microdiactines. A cavity equivalent to the atrium, localised only under the oscula, has a skeleton supported by tangential triactines. All the other exhalant canals have a skeleton composed of harpoon-shaped pugioles ” (Borojevic et al. 2002).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47CFF9AFF36EE30F379FA0D.taxon	materials_examined	Type material: SZN POR 207, holotype — not analysed by the present work. Ischia Island, Gulf of Naples, Tyrrhenian Sea; depth 40 m. Type locality: Ischia Island, Gulf of Naples, Tyrrhenian Sea. Morphology: As explained above, the type material (SZN POR 207) could not be analysed, and additional samples were not available or could not be located. According to the original description (Sarà 1960), the specimen has an ellipsoidal shape and apical osculum without fringe of trichoxeas. No data about the aquiferous system is provided, and the lack of illustrations of the skeletal or histological organisations prevented any inferences from being made. Anatomy: The cortical skeleton is formed by triactines and giant tetractines, which point the apical actines to the middle of the sponge body (Sarà 1960). Microdiactines are present along the whole skeleton, but Sarà (1960) emphasised they are more abundant at the atrial skeleton, which is also formed by small and particular tetractines (see remarks below). Spicules (according to the original description): Cortical tetractines: Giant, actines have similar length (700 – 1200 / 70 – 120 μm). Cortical triactines: Smaller than the cortical tetractines (170 – 350 / 15 – 35 μm). Atrial tetractines (see remarks below): They have a particular (harpoon) shape. Apical (70 – 80 / 7 – 9 μm) and unpaired (55 – 70 μm) actines are considerably longer than the paired ones (20 – 35 μm). Microdiactines: Lanceolate (60 – 70 / 4 μm).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47CFF9AFF36EE30F379FA0D.taxon	discussion	Remarks: Due to the small size of the type specimen (<1 cm), it could not be loaned, and microscope slides could not be prepared by the current staff of the Stazione Zoologica Anton Dohrn di Napoli (Andrea Travaglini, personal communication). Nevertheless, based only on the original description, we figured out that (1) important characters typical of Amphoriscus were not reported along the description of this species, such as the syconoid aquiferous system and the inarticulate skeleton formed by the apical actines of the cortical tetractines and the unpaired actine of the subatrial spicules; and (2) the shape of the small atrial tetractines, of which “ la forma è molto caratteristica ” (Sarà 1960), suggesting that they are pugioles. These spicules correspond to small harpoon — (or dagger-) shaped spicules present in the order Baerida (Borojevic et al. 2002; Alvizu et al. 2018, 2019). Besides the presence of pugioles, the description provided by Sarà (1960) contains other characters found in the definition of Baerida: the presence of cortical large and giant spicules (triactines and tetractines, respectively, in the case of A. dohrni), and the presence of microdiactines abundant in the atrial skeleton (although it is not clear if they are more abundant than the atrial pugioles). Therefore, based on these features, there is no support for keeping the species inside the genus Amphoriscus, and we propose to transfer it to Baerida. According to Van Soest et al. (2021), Baerida is formed by four families: Baeriidae Borojevic, Boury-Esnault & Vacelet, 2000, Petrobionidae Borojevic, 1979, Trichogypsiidae Borojevic, Boury-Esnault & Vacelet, 2000, and Lepidoleuconidae Vacelet, 1967. Among the families mentioned above, only Baeriidae and Petrobionidae include pugioles in their composition (Borojevic et al. 2002; Alvizu et al. 2019). Petrobionidae has a basal calcareous skeleton of calcite. This family is monotypic, and Petrobiona massiliana Vacelet & Lévi, 1958 does not resemble “ A ”. dohrni, in which the basal skeleton is absent (Borojevic et al. 2002). Baeriidae includes four genera: Leuconia Grant, 1833, Eilhardia Poléjaeff, 1883, Lamontia Kirk, 1895, and Leucopsila Dendy & Row, 1913. However, only Leuconia and possibly Lamontia are pugiole-bearing genera. The latter is characterised by having diactines perforating the cortex and microdiactines throughout the choanoskeleton, characters that were not reported for “ Amphoriscus ” dohrni (Sarà 1960; Borojevic et al. 2002). Since this species does have atrial pugioles, we decided to allocate it within Leuconia ¸ despite the absence of sagittal triactines in the atrium. We therefore highlight the need for a taxonomic revision of Leuconia and the entire order Baerida, echoing recent suggestions from Alvizu et al. (2018, 2019).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
03CEAF23A47DFF9AFF36EDCDF6DFF9E5.taxon	description	In order to facilitate the comparison between species of Amphoriscus and, consequently, their taxonomic identification, the skeletal composition and type locality of all Amphoriscus species is summarised below (Tab. 8).	en	Chagas, Cléslei, Cavalcanti, Fernanda F. (2021): Partial taxonomic revision of Amphoriscus Haeckel, 1870 (Porifera: Calcarea) with description of A. decennis sp. nov. Zootaxa 5061 (1): 39-68, DOI: https://doi.org/10.11646/zootaxa.5061.1.2
