Leptalpheus degravei, Scioli & Robles & Felder, 2024

Leptalpheus degravei n. sp.

( Figs. 22–24 View FIGURE 22 View FIGURE 23 View FIGURE 24 , 25a–g View FIGURE 25 )

Leptalpheus forceps View in CoL .— Pachelle et al., 2016: 12 View Cited Treatment , fig. 6C.— Rosário et al., 2020: 63 View Cited Treatment , figs. 2–6 [not L. forceps Williams, 1965 View in CoL ].

Leptalpheus cf. forceps View in CoL .— Anker, 2008: 788 View Cited Treatment , figs. 4, 5, 6A, B.— Anker, 2011: 6 View Cited Treatment , figs. 3A, B; De Grave & Anker, 2017: 12; Chow et al., 2021: fig. 3 [not L. forceps Williams, 1965 View in CoL ].

Leptalpheus aff. forceps View in CoL .— Almeida et al., 2012: 15 View Cited Treatment , figs. 5A–D.

? Leptalpheus forceps View in CoL .— Christoffersen et al., 1998: 361.—Riul et al., 2007: 7.

Type material. Holotype: male (cl 5.1 mm), ULLZ 18510 View Materials [ USNM 1705360 View Materials ], Panama, Caribbean coast, Bocas del Toro, Isla Colón, Boca del Drago, at mouth of small creek south of Playa de Estrellas , with Lepidophthalmus richardi (host catalog no. ULLZ 18514 View Materials [ USNM 1706529 View Materials ]), 0–0.5 m, coll. J.A. Scioli, 03.07.2018 . Paratypes: 1 male (cl 3.6 mm), ULLZ 18511 View Materials [ USNM 1705361 View Materials ], same locality as holotype, with L. richardi (host catalog no. ULLZ 18515 View Materials [ USNM 1706530 View Materials ]), coll. J.A. Scioli, 03.07.2018 ; 1 male (cl 3.6 mm), ULLZ 18505 View Materials [ USNM 1705355 View Materials ], same locality as previous, coll. J.A. Scioli, 18.05.2018 ; 1 ovigerous female (cl 3.6 mm), ULLZ 18507 View Materials [ USNM 1705357 View Materials ], same locality as previous, coll. J.A. Scioli, 25.05.2018 ; 1 male (cl 3.9 mm), ULLZ 18508 View Materials [ USNM 1705358 View Materials ], same locality as previous, coll. J.A. Scioli, 09.06.2018 ; 1 female (cl 3.1 mm), ULLZ 18509 View Materials [ USNM 1705359 View Materials ], same locality as previous, coll. J.A. Scioli, 09.06.2018 ; 1 ovigerous female (cl 4.7 mm), ULLZ 18512 View Materials [ USNM 1705362 View Materials ], same locality as previous, coll. J.A. Scioli, 03.07.2018 ; 1 female (cl 3.7 mm), ULLZ 18506 View Materials [ USNM 1705356 View Materials ], same locality as previous, coll. J.A. Scioli, 25.05.2018 ; 1 male (cl 6.0 mm), 1 female (cl 3.2 mm), UF 51702 , same locality as previous, collected from burrow of Lepidophthalmus richardi , 0.5 m, coll. M. Leray & P.P.G. Pachelle, 05.04.2019 ; 1 male (cl 4.8 mm), MNHN-IU-2011-5238, Panama, Caribbean coast, Bocas del Toro, Isla Bastimentos , near main village, sand flat near mangroves, 0–0.2 m, collected from burrow of Lepidophthalmus sp. , coll. A. Anker, 03.05.2007 .

Additional material examined. 1 male (cl 6.1 mm), UCRMZ 2420-01 , Costa Rica, Caribbean coast, Cahuita, Punta Uva, small mangrove river, coarse sand, with Lepidophthalmus richardi (host catalog no. UCRMZ 2420-02 ), coll. A. Anker, I. Wehrtmann & L. Harris, 26.11.2005 .

Description. Frontal margin of carapace broadly rounded, without rostral projection or orbital crests ( Fig. 22a, b View FIGURE 22 ). Carapace glabrous; branchiostegal margin with narrow folded lip; lip broadest posteriorly and gradually tapering in breadth anteriorly; pterygostomian angle rounded, not strongly projecting anteriorly. Telson 2–4 times as long as basal breadth, gradually tapering in breadth throughout length; distal margin arcuate, 0.4–0.6 times as broad as basal margin; dorsal surface with two pairs of spiniform setae; anterior pair inserted at 0.25–0.5 length of telson from base; posterior pair inserted at 0.5–0.7 length of telson from base; posterolateral margins with two pairs of spiniform setae; mesial pair 5–6 times length of lateral pair ( Fig. 22d View FIGURE 22 ).

Antennular peduncles stout; stylocerite somewhat appressed against first article, with subacute tip not reaching distal margin of first antennular article; ventromesial carina bearing subacute, anteriorly directed ventral tooth; second antennular article 2–3 times as long as broad; secondary ramus of lateral flagellum furnished with aesthetascs beginning on article 4–7 ( Fig. 22a–c View FIGURE 22 ). Antennal peduncles subequal in length to antennular peduncles; basicerite bearing broad, subacute ventrolateral tooth, tip of latter not reaching distal margin of stylocerite; scaphocerite broad, oval-shaped, 2–3 times as long as widest breadth, bearing minute, subacute distolateral tooth; carpocerite broad, 2–5 times as long as widest breadth, distally overreaching scaphocerite ( Fig. 22a, b View FIGURE 22 ).

Mouthparts somewhat typical for genus. Mandible with two-segmented palp; molar process small, bearing rows of minute, stiff setae; incisor process bearing five teeth ( Fig. 22e View FIGURE 22 ). Maxillule with bilobed palp ( Fig. 22f View FIGURE 22 ). Maxilla with dorsal endite bearing deep groove; scaphognathite somewhat broad, palp present ( Fig. 22g View FIGURE 22 ). First maxilliped with small palp; exopod with expanded caridean lobe; epipod bilobed ( Fig. 22h View FIGURE 22 ). Second maxilliped with broad, roughly oval-shaped epipod ( Fig. 22i View FIGURE 22 ). Third maxilliped with well-developed arthrobranch; lateral plate slender, elongate, distally overreaching half-length of antepenultimate article, with subacute tip; exopod long, tip reaching or nearly reaching distal margin of antepenultimate article; ultimate article shorter than antepenultimate article, bearing transverse rows of setae on mesial face, with blunt tip ( Fig. 22j View FIGURE 22 ).

Major cheliped slender; ischium bearing subacute subtriangular projection on ventromesial margin; merus slender, 4.5–7 times as long as maximum breadth, with ventral margin concave to accommodate chela when folded; ventrolateral, ventromesial and dorsal margins of merus all lined with minute tubercles throughout length; carpus short, cup-shaped, with two subtriangular projections on distoventral margins; chela slender, tapering in breadth distally, bearing numerous minute tubercles throughout ventral half; adhesive disks absent; fingers 0.2–0.25 palm length; dactylus bearing 4–7 rounded, subacute teeth in proximal two-thirds of length, with distal third strongly curving ventrally to ventrally-pointed subacute tip; pollex bearing 5 rounded subacute teeth in proximal half, distalmost tooth directed anterodorsally, tip slightly curving dorsally; fingers crossing at tips when closed ( Fig. 24 View FIGURE 24 ).

Minor cheliped distinctly smaller than major cheliped; ischium unarmed; merus relatively slender, 5.5–8 times as long as maximum breadth, with concave ventral face to accommodate chela when folded; ventrolateral, ventromesial and dorsal margins smooth; carpus short, cup-shaped; chela slender, 4–6 times as long as maximum height; fingers subequal in length to palm; ventral margin slightly concave at base of fingers; dactylus and pollex both with raised cutting margins bearing minute, subacute medial projections; tips distally crossing when closed ( Fig. 23a, b View FIGURE 23 ).

Second pereopod slender, with merus longer than ischium; carpus subdivided into five articles, with article ratio approximately 9: 2: 3: 2: 6; fingers of chela subequal in length to palm, bearing sparse setal tufts ( Fig. 23c View FIGURE 23 ). Third pereopod laterally compressed; ischium unarmed; merus unarmed, 2.5–4.5 times as long as maximum height; carpus 0.4–0.5 length of merus, bearing distoventral spiniform seta, with distodorsal margin projecting over carpo-propodal articulation; propodus bearing three spiniform setae along ventral margin; dactylus tapering in breadth to acute, simple tip ( Fig. 23d View FIGURE 23 ). Fourth pereopod similar to third, but slightly slenderer ( Fig. 23e View FIGURE 23 ). Fifth pereopod slender, not compressed; ischium short, unarmed; merus slender, 3.5–6 times as long as maximum height; carpus slender, with distodorsal margin slightly projecting; propodus bearing 3–6 transverse rows of grooming setae on lateral face and minute spiniform seta in middle of ventromesial margin; dactylus simple, with acute tip ( Fig. 23f View FIGURE 23 ).

Male second pleopod with long, slender appendix masculina, latter 1.5–2 length of appendix interna, bearing apical setae ( Fig. 22k View FIGURE 22 ). Uropod with bilobed protopod; lateral lobe of protopod with shallow concavity on distal margin; uropodal exopod with truncate distal margin; uropodal endopod with or without distal appendix composed of 1–5 articles ( Fig. 22l View FIGURE 22 ).

Variation. Some, but not all, specimens of L. degravei n. sp. had caudal appendices on the distal margins of the uropodal endopods. Specimens with caudal appendices were larger-bodied (cl 4.7–6.0 mm) than those that lacked them (cl 3.2–3.9 mm).

Color in life. Semitransparent with sparse red chromatophores throughout body, arranged into diffuse transverse rows on dorsal surface of abdomen; walking legs without chromatophores; ovaries and eggs yellow-green ( Figs. 25a–g View FIGURE 25 ; also see Anker 2011: fig. 3A, B; Pachelle et al. 2016: fig. 6C; Rosário et al. 2020: fig. 2).

Etymology. Named in honor of our colleague Sammy De Grave (Oxford University Museum of Natural History, Oxford, UK), for his significant contributions to the biology and taxonomy of caridean shrimps, including those of Caribbean Panama.

Type locality. Isla Colón, Bocas del Toro , Caribbean Coast, Panama.

Distribution. Southwestern Atlantic and Caribbean Sea: Brazil ( Pachelle et al. 2016; Rosário et al. 2020); the Caribbean coasts of Panama ( Anker 2011; De Grave & Anker 2017; present study) and Costa Rica ( Anker 2008; present study).

Ecology. Obligate burrow cohabitant of callichirid ghost shrimps in the genus Lepidophthalmus : associated with L. richardi in Panama and Costa Rica ( Anker 2008; present study), Lepidophthalmus cf. sinuensis Lemaitre & Rodrigues, 1991 in Panama ( Anker 2011; De Grave & Anker 2017), and Lepidophthalmus siriboia Felder & Rodrigues, 1993 in Brazil ( Pachelle et al. 2016; Rosário et al. 2020).

Remarks. Leptalpheus degravei n. sp. is morphologically very similar to L. forceps and was previously reported as L. forceps , L. cf. forceps , and L. aff. forceps ( Anker 2008; 2011; Almeida et al. 2012; Pachelle et al. 2016; De Grave & Anker 2017; Rosário et al. 2020; Chow et al. 2021). Anker (2008) first expressed some doubt that specimens collected in Costa Rica were conspecific with L. forceps described from North Carolina, most notably because of the presence of caudal appendices on the uropodal endopods of Costa Rican specimens, which are absent in the type specimens of L. forceps . The same author continued to report Caribbean specimens as L. cf. forceps in a later study based on Panamanian material, although the Panamanian specimens lacked caudal appendices, on the basis of the proportions of the antennular peduncle resembling the Costa Rican specimens and differing somewhat from the description of L. forceps , as well as the smaller body size of mature adult specimens compared to L. forceps from the Atlantic coast of the USA ( Anker 2011). A specimen reported as L. aff. forceps from Canavieiras, Bahia, Brazil was compared with a specimen from the Atlantic coast of Florida and differs in the dentition of the major cheliped and the proportions of the antennular peduncle ( Almeida et al. 2012). Later records of L. forceps from Brazil included remarks that they more closely resembled specimens of L. cf. forceps from Costa Rica and Panama ( Anker 2008; 2011) than L. forceps from the Atlantic coast of the United States ( Rosário et al. 2020). The morphological variation and taxonomic uncertainty expressed in these records motivated our genetic investigation of material identified as or resembling L. forceps .

Our genetic results clearly delimited specimens from the Caribbean coast of Panama and Brazil ( L. degravei n. sp.) from specimens from the Atlantic coast of the USA and Gulf of Mexico ( L. forceps sensu stricto). Pairwise COI distances were significantly greater between the two species (15.2–16.9% divergence) than within each species (0–0.8% divergence in L. forceps , 0–1.7% divergence in L. degravei n. sp.). The same pattern was true for 16S sequences (0–0.9% intraspecific divergence vs. 3.0–4.8% interspecific divergence) and 12S sequences (0–0.6% intraspecific divergence vs 2.5–3.2% interspecific divergence).

There are few reliable morphological characters that distinguish L. degravei n. sp. from L. forceps . Although some authors noted the presence of caudal appendices on the uropods of L. degravei n. sp. ( Anker 2008; Rosário et al. 2020), which has not previously been reported in L. forceps from the Gulf of Mexico or Atlantic coast of the USA, these structures do sometimes occur in L. forceps sensu stricto (see remarks on L. forceps below). Anker (2008) also noted differences between the relative proportions of the scaphocerite between Costa Rican specimens of L. degravei n. sp. and the description of L. forceps . These proportions, however, are also somewhat variable in L. forceps sensu stricto. Variation in the dentition of the fingers of the major cheliped overlapped between the two species. The only morphological character that consistently separates the two species is the proportions of the antennular peduncle: the second antennular article is shorter in L. degravei n. sp. (2–3 times as long as broad) than in L. forceps (3.5–6 times as long as broad) (compare Fig. 22a View FIGURE 22 vs. Fig. 21i, j View FIGURE 21 ). L. degravei n. sp. also appears to be a smaller-bodied species, as specimens of L. degravei (cl 3.1–6.1 mm) did not reach as large body sizes as L. forceps (cl 3.0– 10.5 mm). Leptalpheus degravei n. sp. can be distinguished from all species of Leptalpheus and related genera other than L. forceps , including L. ankeri n. sp., by the dentition pattern of the fingers of the major cheliped, which bear series of subacute teeth proximally and gape distally.

Based upon our results, we consider the identity of all records of L. forceps from the Caribbean Sea as L. degravei n. sp. We were able to confirm that the material reported by Pachelle et al. (2016) as L. forceps from Ceará, Brazil, is L. degravei n. sp., as the genetic sequence from this material published by Chow et al. (2021) matches sequences of L. degravei n. sp. Furthermore, we can say with confidence that specimens reported as L. forceps from Bahia and Pará, Brazil, are in fact L. degravei n. sp. based on the proportions of the antennular peduncle in the accompanying illustrations (see Almeida et al. 2012: fig. 5A; Rosário et al. 2020: fig. 3A). Records from Sergipe ( Christoffersen 1998) and Paraíba ( Riul et al. 2008), Brazil, are likely also L. degravei n. sp., but as there are no accompanying illustrations or genetic data, we cannot ascertain their identity beyond reasonable doubt.