Eupera troglobia, Simone & Ferreira, 2022

Eupera troglobia sp. nov.

Figs 1-6 View Figures 1–6 , 7-13 View Figures 7–13 , 14-21 View Figures 14–21 , 22-26 View Figures 22–26 , 27-30 View Figures 27–30

Material examined.

Holotype. MZSP 155717. Paratypes MZSP 155716, 12 specimens, MNRJ 23647, 1 specimen, USNM, 1 specimen, all from type locality.

Type locality.

Brazil. Tocantins; Lagoa da Confusão, Casa da Pedra cave, 10°49'28.4"S, 49°37'16.5"W [Ferreira col., 3.viii.2021].

Diagnosis.

Adult size ~4.5 mm. Lacking pigmentation in shell and soft parts. Shell very fragile, translucent, light yellow.

Description.

Shell (Figs 1 View Figures 1–6 - 18 View Figures 14–21 ). Adult shell ~4.5 mm. Equivalve; height ~80% of length; width ~60% of length. Walls thin, fragile, translucent. Anterior edge rounded, smaller than posterior edge; ventral edge rounded in medium specimens (Figs 7-9 View Figures 7–13 ) to slightly ascendent in larger specimens (Figs 1-4 View Figures 1–6 , 12 View Figures 7–13 ); posterior edge almost straight in its middle level; dorsal edge weakly convex, almost straight. Color light yellow to light greenish yellow (Figs 1-6 View Figures 1–6 ). Outer surface opaque. Sculpture of uniform concentric growth lines (Figs 1 View Figures 1–6 , 2 View Figures 1–6 , 12 View Figures 7–13 , 13 View Figures 7–13 ); ~15 per mm; each line alternating in height along its length (Fig. 13 View Figures 7–13 ), but mostly 4-5 times taller than wide; interspaces ~10 times wider than each line. Growth lines usually continuous from anterior up to posterior hinge region (Figs 1 View Figures 1–6 , 2 View Figures 1–6 , 12 View Figures 7–13 ). Umbo (um) slightly prosogyrate, central, protruding ~10% height beyond hinge level (Figs 1-4 View Figures 1–6 , 8-9 View Figures 7–13 ), occupying ~20% of dorsal edge. Hinge with small, blunt cardinal tooth (ca) in LV, ~1.5 times longer than tall, tip rounded (Figs 14-16 View Figures 14–21 ), shallow correspondent socket in RV (Fig. 16 View Figures 14–21 ); anterior (al) and posterior (pl) lateral teeth relatively equidistant from cardinal tooth (Figs 4-6 View Figures 1–6 , 7-11 View Figures 7–13 , 14-18 View Figures 14–21 ), similar to each other, in both valves; located in anterior and posterior ends of hinge edge, in blunt angle preceding anterior ad posterior slopes; each lateral tooth ~4-times longer than wide, parallel to hinge edge; anterior pair of tooth usually with anterior small beak (Figs 14-15 View Figures 14–21 : al, 17-18); both lateral teeth of LV slightly more ventral than lateral teeth of RV, encasing ventrally to them; both lateral teeth of RV with narrow socket lying dorsally for counterparts of LV (Figs 5 View Figures 1–6 , 9 View Figures 7–13 , 11 View Figures 7–13 , 18 View Figures 14–21 ). Inner surface glossy; scar of anterior adductor muscle (aa) occupying ~5% of entire inner valve surface, ~twice taller than wide, elliptic, slightly larger than scar of posterior adductor muscle (pa) (Figs 3-4 View Figures 1–6 , 7-9 View Figures 7–13 ). Pallial line continuous, simple, connecting both adductor muscle scars; relatively broad; located along ventral edge ~15% of total height distant from it. Inner surface possessing minute pits, possibly of aesthetes (Figs 10-11 View Figures 7–13 : ae).

Main muscle system (Figs 22 View Figures 22–26 , 24 View Figures 22–26 , 27 View Figures 27–30 ). Anterior adductor muscle (aa) with elliptic transverse section, dorso-ventral height of slightly twice anterior-posterior width; located close to blunt angulation between dorsal and anterior shell edges. Posterior adductor muscle (pa) slightly smaller and located slightly more ventrally than anterior muscle. Pair of anterior pedal retractor muscles (ar) originated just dorsal to anterior adductor muscle in elliptic area equivalent to ~15% of that of anterior adductor muscle; running towards posterior relatively narrow, along ~20% of shell length, attached to adjacent visceral integument; insertion splaying in antero-dorsal foot base. No detectable protractor pedal muscle. Pair of posterior pedal retractor muscles (pr) originating similarly as anterior pedal muscle, but dorsally to posterior adductor muscle; running narrow anteriorly along ~50% of shell length, as central base to local visceral mass and attached to adjacent visceral integument; insertion splaying in postero-dorsal side of pedal base.

Foot (Fig. 24 View Figures 22–26 : ft). Cylindric, ~3-times longer than wide in contracted condition; ~half projected anteriorly beyond its base. Posterior region ventrally bulged, rounded. Anterior end bluntly tapering. Byssal furrow (bf) narrow, occupying ~1/4 of middle region of ventral foot surface. Byssus (by) as single, narrow, yellow thread.

Mantle (Figs 22 View Figures 22–26 , 26 View Figures 22–26 , 27 View Figures 27–30 ). Mantle lobe thin, translucent, thickened only in edges. Colorless. Edges of both lobes fused with each other in region of anterior adductor muscle, and in region posterior to middle level of ventral edge; fusion provided by inner fold. Mantle edge in non-fused region (Fig. 26 View Figures 22–26 ) with narrow, flattened outer (of) and middle (mf) folds, no papilla or special structures detectable; inner fold (if) located in inner base of middle fold, with ~half of remaining folds height, as wide as tall. Pallial musculature (pm) thin, present in base of three folds. Fusion between posterior half of mantle edges (un) simple. Incurrent siphon (Fig. 27 View Figures 27–30 : is) simple, cylindric, walls weakly muscular; distal edges simple, lacking papillae; length in retracted condition ~5% of shell length, ~twice longer than wide. Excurrent siphon (ex) similar to, but ~30% smaller than incurrent siphon; preserved inverted in several specimens. Siphonal musculature immersed in local mantel edges, lacking detectable bundles, neither producing pallial sinus in shell. Gill suspensory membrane (su) connected by cilia in posterior end of gill, membrane-like separating completely incurrent from excurrent chambers (Fig. 27 View Figures 27–30 ).

Pallial cavity (Fig. 22 View Figures 22–26 ). Outer demibranchs (od) with ~1/4 of shell height in its middle region; tapering gradually towards anterior, up to middle level of inner demibranch dorsal edge; tapering subtly towards posterior; lamellae very narrow, with ventral curve covering small region of inner demibranch dorsal edge (Fig. 23 View Figures 22–26 : od); dorsal connection with visceral mass via cilia (ci). Inner demibranchs (di) wide, area ~double as outer demibranchs; anterior region slightly wider than half of shell height, gradually tapering towards posterior up to certain distance from posterior adductor muscle; transversely folded; descendent lamella (Fig. 23 View Figures 22–26 : id) simple, very narrow, free from ascendent lamella; ascendent lamella with ~70% of descendent lamella length; narrow food groove (fg) in inner demibranch ventral edge; inner demibranch connections with visceral mass and its counterpart (in posterior half - Fig. 24 View Figures 22–26 ) via cilia (ci). Inner demibranch serving as marsupium of ~6-8 young specimens (Fig. 31 View Figures 31–32 : yo), detailed below. Pair of palps (Figs 24 View Figures 22–26 , 25 View Figures 22–26 : pp) small (~half of anterior adductor muscle area), located just posterior to anterior adductor muscle; outer hemipalps (op) ~3-times longer than wide, 8-10 strong transverse folds, from edge to edge (even protruding beyond edges); tapering distally; folds ending before mouth area (mo), keeping smooth perioral area; inner hemipalp (ip) similar to outer hemipalp, but slightly smaller, usually placed close to anterior region of visceral mass.

Visceral mass (Fig. 24 View Figures 22–26 ). All visceral structures white. Stomach (st) occupying most of anterior half, disposed anterior-ventrally. Digestive diverticular (dg), lying along anterior region of stomach. Gonad and genital structures occupying anterior ~half of posterior half of visceral mass, covering posterior surface of stomach. Reno-pericardial structures occupying posterior half of posterior half of visceral mass, up to posterior adductor muscle. Details below.

Circulatory and excretory systems (Figs 24 View Figures 22–26 , 27 View Figures 27–30 ). Heart occupying anterior half of reno-pericardial area. Ventricle (ve) large, as dorsal structure, totally surrounding intestine; wall thick. Anterior and posterior aortas initially running attached to adjacent intestine. Pair of auricles (au) connected to anterior region of ventricle, each one conic, running towards ventral and lateral; connecting to central region of gills. Kidneys (ki) as posterior half of reno-pericardial volume, connected anterior and dorsal surface of posterior adductor muscle; anterior region hollow, as urinary chamber; nephropore (ur) as single, small slit located in ventro-anterior surface of supra-branchial chamber; posterior region mostly filled by white, solid renal tissue.

Digestive system (Fig. 24 View Figures 22–26 ). Palps (pp) and mouth (mo) (Fig. 25 View Figures 22–26 ) described above (pallial cavity). Esophagus (es) simple, narrow, running along ~20% of shell length from posterior region of anterior adductor muscle towards posterior and dorsal, inserting in anterior surface of stomach between its middle and dorsal thirds. Stomach (st) large, dorsally rounded, ventrally tapering towards ventral and anterior up to anterior region of foot base. No clear separation between intestine and style sac (ss). Duct to digestive diverticula (dd) located in center of both gastric lateral walls. Stomach inner surface simple, lacking chambers and large folds; gastric shield thin, located in postero-dorsal region. Intestine (in) subtly running posteriorly and dorsally after style sac end, flanking dorsal surface of foot base; short zigzag only in its middle level; intestinal length slightly larger than shell length; in pericardial region crossing directly, gradually directing ventrally and posteriorly up to posterior side of posterior adductor muscle, initially immersed in pallial edge tissue; after short distance running on supra-anal chamber (Fig. 27 View Figures 27–30 ). Anus (an) simple, sessile, located between posterior and ventral surface of posterior adductor muscle; large anal papilla in middle of anal dorsal edge (Fig. 27 View Figures 27–30 : an).

Reproductive system (Fig. 24 View Figures 22–26 ). Gonad white, solid, small, mostly located in lateral regions of stomach. Large hollow brood pouch as posterior 2/3 of genital structures, full of large embryos (em); brood pouch tapering towards ventral and posterior, opening in both sides in small orifice (ap) located in middle level of suprabranchial chamber.

Central nervous system (Figs 24 View Figures 22–26 , 27-29 View Figures 27–30 ). Pair of cerebral ganglia (ce) located in region dorsal to mouth, each one ~1/20 of anterior adductor muscle size. Each ganglion (Fig. 28 View Figures 27–30 : ce) elliptical, ~twice longer than wide; cerebral commissure (cc) wide, as long as each ganglion. Pair of pedal ganglia (Fig. 29 View Figures 27–30 : pg) located in middle level of pedal base; both totally fused with each other, forming spheric mass; pair of statocysts (sy) very small, located in posterior side of pedal ganglia; both pedal ganglia slightly larger than one cerebral ganglion. Pair of visceral ganglia (Fig. 27 View Figures 27–30 : vg) located slightly anterior to posterior adductor muscle central side; each ganglion fusiform, ~3 times longer than wide, located very close to each other, with pedal commissure very short; each visceral ganglion slightly larger than each cerebral ganglion; posteriorly single large nerve running towards posterior, ventrally to posterior adductor muscle (nv).

Development.

Large embryos found in gonadal brood pouch located inside visceral mass (Fig. 24 View Figures 22–26 : em). Embryos coming out by genital orifice (Fig. 24 View Figures 22–26 : ap), located in middle level of inner demibranchs. Both inner demibranchs serving as external branchial brood pouches (Fig. 31 View Figures 31–32 : yo), becoming full of young specimens (yo) in their internal area between both lamellae. Young specimens with prodissoconch of ~0.2 mm (Fig. 20 View Figures 14–21 ), growing up to teleoconch becoming ~3-times larger than prodissoconch (Figs 19 View Figures 14–21 , 32 View Figures 31–32 ), with ~0.7 mm. Prodissoconch almost plane, circular, smooth (Figs 19 View Figures 14–21 , 20 View Figures 14–21 ); teleoconch possessing only concentric undulations and growth lines (Figs 19 View Figures 14–21 , 32 View Figures 31–32 ); valves translucent (Fig. 32 View Figures 31–32 ). Young intra-brood pouch specimen rounded, slightly flattened, dorsal region almost straight, umbos not protruding (Figs 19 View Figures 14–21 , 32 View Figures 31–32 ); shell lacking teeth in hinge and with almost no inner muscular scars (Fig. 21 View Figures 14–21 ). Gross anatomy of these young specimens (Fig. 30 View Figures 27–30 ) with very small adductor muscles (aa, pa), with anterior slightly more ventral; mantle lobes edges (mb) not fused with each other, lacking siphons; gill with only inner demibranch visible (id), relatively squared, possessing 7-8 transverse folds only; foot lacking visible byssal furrow.

Material examined.

Types.

Measurements

(in mm). Holotype MZSP 155717 (Figs 1-6 View Figures 1–6 ): 4.3 by 3.5; Paratypes MZSP 153866: #7 (Figs 7-11 View Figures 7–13 ): 2.3 by 1.9; #8 (Fig. 12 View Figures 7–13 ): 4.5 by 3.6.

Etymology.

The specific epithet refers to the troglobitic mode of life of the animal, being an adjective in the feminine nominative singular.

Habitat.

Specimens of Eupera troglobia sp. nov. were only observed in the Casa de Pedra cave, and are possibly endemic to this cave (Fig. 33A, B View Figure 33 ). The Casa de Pedra cave comprises a cave in limestone from the Couto Magalhães Carbonatic Formation, associated with the Neoproterozoic basement of the Baixo Araguaia Supergroup, which, in addition to the limestones, presents subordinate phyllites, slates, metargilites, metarenites and quartzites ( Pereira and Morais 2012). The climate of the region is tropical, with two distinct periods: a dry season, between May and September, and a rainy season, between October and April, with a total annual rainfall around 1750 mm ( Martins et al. 2002).

The cave has 1,038 meters of total length, with predominantly ellipsoidal conduits. There are few speleothems, in addition to thick allochthonous sediments on the cave floor. The cave is inserted in a limestone outcrop located close to the Lagoa da Confusão karstic lake (Figs 33C View Figure 33 , 34A View Figure 34 ), which overflows during the rainy season, flooding part of the flood plain surrounding it. In such periods (October to April), most cave conduits are completely filled with water. On the other hand, the cave becomes dry during the dry season, as few intermittent dams are present.

A visit paid to the cave in August 2021, revealed the cave partially flooded, with most conduits inaccessible. The main entrance gallery was filled with water, which was still forming a small lake outside the cave (Fig. 34A View Figure 34 ). Reaching the deepest areas inside the cave through the main entrance was impossible in that moment, but since there is another entrance in the middle of the cave (Figs 34B View Figure 34 , 35A View Figure 35 ), the inner portions were accessible (Fig. 35B View Figure 35 ).

Individuals of Eupera troglobia sp. nov. were found associated to a consolidated sediment deposit in a deeper portion of the cave (Figs 33D View Figure 33 , 35C View Figure 35 ). Many specimens were adhered to the sediments already exposed to the air (Fig. 35E, F View Figure 35 ), while others were still under water (Fig. 35D, H, G View Figure 35 ). However, it is important to note that the cave was still drying up, so all specimens would be exposed to the air. Considering that the cave remains out of water during at least three months a year, the individuals do survive during all this period somehow avoiding desiccation. The only known cave-restricted clam species, all belonging to the genus Congeria , from caves in the Dinaric Alps, also exhibit this behavior, presenting a notable tolerance to air exposure ( Jovanović et al. 2016). Interestingly, in the case of all three Congeria species, only part of their populations becomes exposed during dry periods, and most part of the population remains underwater in such periods. Furthermore, even considering that Congeria specimens are able to tolerate air exposure for periods as 2 months, some individuals were observed still active, with their shells open and inhalant and exhalant syphons extruded ( Jovanović et al. 2016). In the case of E. troglobia sp. nov. the single visit paid to the cave does not make it possible to form any hypothesis regarding the individuals’ behavior along the air exposure (e.g., whether they remain active or not). Accordingly, it is highly recommendable that further studies investigate the biology and life cycle of this species. It is worth mentioning that Silva (2006), in her report from the present cave, mentioned the presence of clams also associated to root masses pending from the cave ceiling during their survey (in the dry period). In that case, all specimens were also exposed to the air, and there were only few small ponds inside the cave, apparently devoid of clams.

During the clam sampling in August 2021, some hydrochemical parameters were evaluated, both inside the cave and in the epigean lake (Lagoa da Confusão lake), which floods to the cave during rainy periods. The parameters inside the cave were quite distinct from those from the external lake: cave waters: temperature: 23.6 °C; pH 6.17; conductivity: 0.124 mS/cm; dissolved oxygen: 0.92 mg/L; TDS (total dissolved solids): 0.08 g/L; Salinity: 0.06‰; external lake: temperature: 28.1 °C; pH 7.14; conductivity: 0.017 mS/cm; dissolved oxygen: 10.35 mg/L; TDS (total dissolved solids): 0.011 g/L; Salinity: 0.01‰. It is noticeable the differences in temperature (lower inside the cave), pH (lower inside the cave), conductivity (higher inside the cave) and dissolved oxygen (much lower inside the cave). This certainly demonstrates that the species is not only able to survive in conditions quite distinct from those observed in surface waters, but also probably tolerates high levels of variation in hydrochemical parameters along the year, considering that the cave water originates from the lake flooding.

Finally, it is also worth mentioning the number of embryos found in E. troglobia . Although in the literature, it is usual to find the term “embryo” referring to both the true embryos and the young, such stages are, in fact, distinct. True embryos (still in ontogenetic development) are those individuals found in the visceral marsupium. Those found in the inner demibranchs are called “young”, as they are already formed and the shell shows growth lines. In E. troglobia , there are a maximum of 10 young in each gill (~20 in total) and another 5-6 embryos in the visceral marsupium (on each side - 10-12 in total). Hence, the species presents around 30 immatures (considering both embryos and young). In the consulted literature, only the young specimens inside gills are considered. The other already studied Eupera species (all epigean), presented a considerably larger reported number. As an example, E. platensis had between 22 and 66 young specimens in gills ( Ituarte 1988); E. cubensis between 25 and 35 ( Heard 1964) and E. klappenbachi had between 24 and 62 ( Mansur and Veitenheimer 1975). Most cave-restricted species from several distinct groups usually have k-strategies ( Howarth 1983; Bellés 1992), due to the relatively stable environments that subterranean habitats usually present. Among the reproductive adaptations related to such strategy, there are a reduced number of offspring, increased offspring body size, parental care, among others. The reduced number of embryos compared to some epigean Eupera species, associated to the proportional large size of the young observed in the visceral marsupium of E. troglobia , probably represent another adaptation to the cave environment, confirming the cave-restricted status of this species.