Benthic Foraminifera from the Capricorn Group, Great Barrier Reef, Australia Author Mamo, Briony L. text Zootaxa 2016 4215 1 1 123 journal article 37169 10.11646/zootaxa.4215.1.1 0087fa4c-a4f0-45d9-a2de-d433d7885753 1175-5326 272923 B91D1782-C11A-4CDC-96B6-76104FEE51BD Calcarina capricornia n. sp. ( Fig. 24 :5–14) 1965 Calcarina hispida Brady ; Jell et al ., 277, pl. 44, fig. 3. 2002 Calcarina spengleri Gmelin ; Lobegeier, p. 212, pl. 1, figs 1–8; pl. 2, figs 1–7. Diagnosis. This species is determind by its large size, thick, coarsely perforate test wall featuring pustolose ornamentation and multiple spines that are canaliculate throughout. Description. Test free, unequally biconvex and trochospiral. Large in size (1.3–1.6 mm diameter without spines), with thick, coarsely perforate test walls ( Fig. 24 :10) with calcite bosses on both the umbilical and spiral sides of the test, though in greater abundance on the spiral side. Five to seventeen thick spines with spikes extending from the test periphery that are canaliculate throughout ( Fig. 24 :5, 12, 14). Chambers slightly inflated with depressed sutures clearly visible on umbilical side ( Fig. 24 :8, 9). Remarks. This species is characterised by its thick, coarsely perforate test wall, its large size, visibly depressed sutures and its large number of spines that are canaliculate throughout. Calcarina capricornia bears similarity to Calcarina hispida Brady 1876 but C. hispida has a non-perforate test that is smaller in size and its spines are non-canaliculate in the centre ( Renema & Hohenegger 2005 ). Additionally, C. capiricornia does not possess the same mass of hispid spines across the test that cover the test so thickly that they obscure the sutures except for the final few chambers. Calcarina exuberans Debenay 2013 (previously Calcarina hispida var. pulchella Chapman 1900 ) bears similarity to C. capricornia , particularly with the large number of thick spines, however the test wall is much thinner, the spines are more numerous and more varied in nature and the test is smaller—the same size as C. hispida . Calcarina capricornia additionally lacks the distinct “exuberant” outgrowths on the extremities of the spines that make C. exuberans so distinctive. Calcarina gaudichaudii d’Orbigny 1840 is similar to this species in that they both possess distinctly thick, perforated test walls yet C. gaudichaudii has a much smoother test with smaller calicitic bosses, a pinched periphery, and bears fewer spines which are more regular, without spikes and have a blunted tip. Intraspecific variability includes the number of spines and the abundance and distribution of the calcitic bosses. Some specimens have calcitic bosses isolated to the central area of the test and others have them covering most of the test, including the spaces between spines. This species has been previously recorded from the GBR on both Heron Island ( Jell et al. 1965 ) and Green Island ( Lobegeier 2002 ). Jell et al . (1965) reported this species where it commonly constituted 50% or more of sedimentary grains, but was not present in dredged samples from deeper waters and Lobegeier’s (2002) investigation found them to be a robust species habituating areas of high UV-radiation levels and high energy reef flat environments within strands of filamentous turf algae including Laurencia sp. and Chlorodesmis fastigiata . Derivation of name. This species is named after the region from the southern GBR where it was collectedthe Capricorn Group. Material. Holotype—QM#G465953 ( Fig. 24 :5); Paratypes QM#G465800 ( Fig. 24 :6, 7), QM#G465799 ( Fig. 24 :8, 9), QM#G465783 ( Fig. 24 :10), QM#G466041 ( Fig. 24 :11, 12) and QM#G466047 ( Fig. 24 :13, 14), all specimens were retrieved at a depth of 3 m or less from Heron Reef flat, Capricorn Group , Great Barrier Reef , Australia , Holocene. Distribution within study area. Calcarina capricornia was collected from all sampled reefs and often accounted for 50–75% of all specimens collected from each site. In fact, C . capricornia was the most abundant species from the CG, accounting for 38.6% of the total number of foram specimens collected. This species occurs in shallow, high energy, tidally influenced waters across reef flat areas similar to other Calcarina species ( Hohenegger et al. 1999 ; Lobegeier 2002 ; Yordanova & Hohenegger 2002 ; Renema & Hohenegger 2005 ). Sites of low abundance include site 10 along ST transect and site 15, along transect 2 across Heron Reef flat where the edge of the reef flat becomes pure reef platform to rubble zone and there are low levels of sedimentation and algae growth. Additionally, the three deepest sites within Heron Lagoon also have the lowest abundance. The same pattern occurs in Wistari and One Tree Lagoons. Of note is that where the abundance of C . capricornia decreases, the abundance of B . sphaerulata often increases. The most extreme example of this case occurs at site 15 along Transect 2 of Heron Reef and site 28, Sykes Reef and is likely due to a shift in dominant algal type in different regions of the reef flat.