A new species of <i>Clausidium</i> Kossmann, 1874 (Crustacea, Copepoda, Cyclopoida, Clausidiidae) associated with ghost shrimps from Iran

Sepahvand, Vahid; Rastegar-Pouyani, Nasrullah; Kihara, Terue C.; Momtazi, Farzaneh

doi:10.1590/2358-2936e2017018

Abstract

A new species of the Clausidium Kossmann, 1874 copepods is described, illustrated and provided by Confocal Laser Scanning Microscope photo on the basis of specimens from the gill chamber of Callianidea typa H. Milne Edwards, 1837 from the Iranian coast of the Persian Gulf. Clausidium persiaensis sp. nov is unique in the possession of a fine spine on endopod-1 of the antennae, large blade-like setae with an acute tip on P1, and the shape of P5 and the anal somite. The new species extends the group distribution into the northwest Indian Ocean and represents the first records of the genus in Iran.

Key words
CLSM; Persian Gulf; Indian Ocean; taxonomy; Callianidea typa

Introduction

Ghost shrimps or mud shrimps, representatives of the infraorders Axiidea and Gebiidea, are among the most common benthic macro-invertebrates in littoral zones of the Persian Gulf and Gulf of Oman ( Sepahvand et al., 2013Sepahvand, V.; Sari, A.; Salehi, H.; Nabavi, S.M.B. and Ghorbanzadeh, S.G. 2013. Littoral mud shrimps (Decapoda: Gebiidea & Axiidea) of the Persian Gulf and Gulf of Oman, Iran. Journal of the Marine Biological Association of the United Kingdom, 93: 999-100.). These shrimps are adapted to a burrowing life-style and their burrows can also be occupied by a variety of organisms, including copepods ( Dworschak et al., 2012Dworschak, P.C.; Felder, D.F and Tudge, C.C. 2012. Infraorders Axiidea de Saint Laurent, 1979 and Gebiidea de Saint Laurent, 1979 (formerly known collectively as Thalassinidea). p. 109-219. In: F.R. Schram and J.C. von Vaupel Klein (eds), Treatise on zoology - anatomy, taxonomy, biology. The Crustacea. Complementary to the volumes translated from the French of the Traité de Zoologie [founded by P.-P. Grassé]. 9 Part B. Eucarida: Decapoda: Astacidea p.p. (Enoplometopoidea, Nephropoidea), Glypheidea, Axiidea, Gebiidea, and Anomura. Leiden, Brill. ). According to Sepahvand et al. (2013)Sepahvand, V.; Sari, A.; Salehi, H.; Nabavi, S.M.B. and Ghorbanzadeh, S.G. 2013. Littoral mud shrimps (Decapoda: Gebiidea & Axiidea) of the Persian Gulf and Gulf of Oman, Iran. Journal of the Marine Biological Association of the United Kingdom, 93: 999-100., two out of 11 species of burrowing shrimps recorded from the littoral zone of Iran have associated copepods from the genus ClausidiumKossmann, 1874Kossmann, R. 1874. Ueber Clausidium testudo, einen neuen Copepoden, nebst Bemerkungen über das System der halbparasitischen Copepoden. Verhandlungen der Physikalischen Gesellschaft zu Würzburg, 7: 280-294. (Clausidiidae, Cyclopoida). Although these clausidiid copepods are relatively rarely recorded because of the cryptic lifestyle of their hosts, a total of 11 species of Clausidium have been described so far ( Kihara and Rocha, 2013Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67.). This genus has seven species recorded from the Atlantic Ocean and two species from the Pacific Ocean. The remaining two species, Clausidium travancorensePillai, 1959Pillai, N.K. 1959. On two new species of Clausidium (Copepoda: Cyclopoida) parasitic on the shrimp Callianassa. Journal of the Marine Biological Association of India, 1: 57-65. and Clausidium chelatum Pillai, 1959 have been found in the Indian Ocean ( Pillai, 1959Pillai, N.K. 1959. On two new species of Clausidium (Copepoda: Cyclopoida) parasitic on the shrimp Callianassa. Journal of the Marine Biological Association of India, 1: 57-65.). In the present study, we investigate Clausidium copepods of Iranian coastal waters of the Persian Gulf, and describe a new species associated with the ghost shrimp Callianidea typa H. Milne Edwards, 1837Milne Edwards, H. 1837. Les Crustacés. p. 1-278. In: G. Cuvier (ed.), Le Règne animal distribué d’après son organisation: pour servir de base a l’histoire naturelle des animaux et d’introduction a l’anatomie comparée. Volume 2. Paris, Masson.. This new species extends the group distribution to the northwest Indian Ocean and represents the first record of the genus in Iran.

Material and Methods

Sampling was carried out at three localities along the Iranian coast of the Persian Gulf and Qeshm Island ( Fig. 1). Clausidium persiaensis sp. nov. was collected from the gill chamber of Callianidea typa H. Milne Edwards, 1837Milne Edwards, H. 1837. Les Crustacés. p. 1-278. In: G. Cuvier (ed.), Le Règne animal distribué d’après son organisation: pour servir de base a l’histoire naturelle des animaux et d’introduction a l’anatomie comparée. Volume 2. Paris, Masson. in three different sampling sites in the Persian Gulf and Qeshm Island. At the sampling site, the copepods were relaxed with drops of Menthol 1.5% added to the sea water and separated from the host by filtration through a 63 µm mesh size net. The collected specimens were transferred to 75% ethanol. Whole specimens were temporarily mounted on slides with glycerin, and adhesive plastic discs were used to support the coverslip ( Kihara and Rocha 2013Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67.). Specimens were dissected under a Leica MZ12 stereomicroscope (Leica, Wetzlar, Germany). Dissected parts were mounted on slides using glycerin as mounting medium, and preparations were sealed with transparent nail varnish. The material was studied with a Leica DMR differential interference contrast microscope (Leica, Wetzlar, Germany) equipped with a drawing tube. The descriptive terminology follows Huys et al. (1996Huys, R.; Gee J.M.; Moore, C.G. and Hamond, R. 1996. Marine and brackish water harpacticoid copepods. Part 1. In: D.M. Kermack, R.S.K. Barnes and J.H. Crothers (eds), Synopses of the British Fauna (New Series) No. 51. London, The Linnean Society of London and the Estuarine and Coastal Sciences Association, 352p.). Abbreviations used in the text are: ae, aesthetasc; P1-P5, legs 1-5; exp and enp, exopod and endopod, respectively; exp (enp)-1 (-2, -3), proximal (middle, distal) segments of a ramus.

Figure 1
The type locality of Clausidium persiaensis sp. nov. (Red circle).

The body length was measured from the anterior apex of the cephalothorax to the posterior margin of the caudal rami, excluding caudal setae. The type material is deposited in the collection of the Zoological Museum, University of Tehran (ZUTC).

Confocal laser scanning microscopy ( CLSM)

For confocal laser scanning microscopy (CLSM), selected material was stained with 1:1 solution of Congo Red and Acid Fuchsin overnight. Whole specimens and dissected parts were mounted on slides with glycerin following the procedure described by Michels and Büntzow (2010Michels, J. and Buntzow, M. 2010. Assessment of Congo red as a fluorescence marker for the exoskeleton of small crustaceans and the cuticle of polychaetes. Journal of Microscopy, 238: 95-101.). The material was scanned using a Leica TCS SP5 (Leica, Wetzlar, Germany) equipped with a Leica DM5000 B upright microscope (Leica, Wetzlar, Germany) and 3 visible-light lasers (DPSS 10 mW 561 nm; HeNe 10 mW 633 nm; Ar 100 mW 458 nm, 476 nm, 488 nm and 514 nm), combined with the software Leica Application Suite Advanced Fluorescence (LAS AF 2.2.1) (Leica, Wetzlar, Germany). To obtain a three-dimensional representation from selected body parts, the data produced during the CLSM scanning was processed with the free software Drishti (http://anusf.anu.edu.au/Vizlab/drishti/). Final plates were composed and adjusted for contrast and brightness using the software Adobe Photoshop CS4 (Adobe Systems, San José, U.S.A.).

Systematics

Order Cyclopoida Burmeister, 1834

Family Clausidiidae Embletonn, 1901

Genus Clausidium Kossman, 1874

Clausidium persiaensis Sepahvand and Kihara sp. nov.

( Figs. 2-12)

Type material. Holotype: dissected female on 25 slides (ZUTC 5913), 14.V.2015. Allotype: dissected male on 25 slides (ZUTC, 5914); undissected paratypes 21 couples (ZUTC 5915) deposited in ethanol at the Zoological Museum, University of Tehran Crustacean collection, Tehran, Iran. All material collected from the type locality by Vahid Sepahvand.

Figure 2
Clausidium persiaensis sp. nov. (female). A, antennule; B, caudal ramus; C, caudal rami (male). Scale bars: A, 50 μm; B, C, 25 μm.

Figure 3
Clausidium persiaensis sp. nov. (female). A, maxillule; B, maxilla; C, labrum; D, maxilliped; E, mandible. Scale bars: A, 50 μm; C, D, 25 μm.

Figure 4
Clausidium persiaensis sp. nov. (female). A, P1; B, P2; C, P3; D, P4. Square = adhesive fringe; asterisk = long seta of endopod 2. Scale bars: A, 100 μm ; B, 50 μm.

Figure 5
Clausidium persiaensis sp. nov. A, urosome, dorsal; B, urosome, ventral. Arrow indicates the P6 (female). Scale bar: 50 μm.

Figure 6
Clausidium persiaensis sp. nov. A, rostrum (female); B, P5 (female); C, maxilliped (male); D, P1 (male). Scale bars: A-C, 25 μm; D, 100 μm.

Figure 7
Clausidium persiaensis sp. nov. A, urosome (male); B, antenna (male); C, antenna (female). Circle = P5 (male); star = P6 (male). Scale bars: A, 100 μm; B, 50 μm.

Figure 8
Clausidium persiaensis sp. nov. (female). Confocal laser scanning microscopy images. A, habitus, dorsal; B, habitus, ventral; C, oral region. White arrow = somite that bears P5; blue arrow = genital double somite. Scale bars: A, B, 200 μm; C, 100 μm.

Figure 9
Clausidium persiaensis sp. nov. (female). Confocal laser scanning microscopy images. A, caudal rami and anal somite, dorsal; B, caudal rami and anal somite, ventral. Scale bars: 100 μm.

Figure 10
Clausidium persiaensis sp. nov. (male) Confocal laser scanning microscopy images. A, habitus, dorsal; B, habitus, ventral; C, oral region. Scale bars: A, B, 100 μm; C, 50 μm.

Figure 11
Clausidium persiaensis sp. nov. (couple). Confocal laser scanning microscopy images. A, habitus, dorsal; B, habitus, ventral; C, male grasping female with maxilliped. Scale bars: A, B, 200 μm; C, 50 μm.

Figure 12
Clausidium persiaensis sp. nov. Three-dimensional representation (Drishti software) based on confocal laser scanning microscopy images. A, anal somite, dorsal (female); B, anal somite, lateral (female); C, P1 (female); D, P1 (male). Blue arrow = medial pore; white arrow = genital apertures. Scale bars: 50 μm.

Type locality. Persian Gulf, Iran (Qeshm Island, Parke-zeyton 27º81’06”N 56°24’11”E, Fig. 1). Specimens collected from the gill chambers of the ghost shrimp Callianidea typa.

Description. Female: total length 1.31-1.36 mm (N = 10). Greenish in color when alive. Body broadly rounded ( Figs. 8A, B, 11A, B), dorsoventrally compressed. Prosome ( Fig. 8A, B) 2.5 times longer than urosome. Maximum width measured at posterior margin of second pedigerous somite. First pedigerous somite fused with cephalosome, forming cephalothorax. Body prosomites with minute integumental pits, sensilla and numerous pores distributed as illustrated in figures. Epimera of second and third pedigerous somites expanded posteriorly. Fourth pedigerous somite almost as long as the two anterior somites combined. Posterior margin of fourth pedigerous somite rounded.

Urosome ( Figs. 5A, B, 8B) 3-segmented, distinctly narrower than prosome. Urosome comprising fifth pedigerous somite, genital double-somite and anal somite. Somite bearing P5 ( Fig. 8B) 2.3 times wider than long in ventral view and with P5 arising ventrolaterally. Genital double-somite ( Figs. 5, 9) wider than long. Genital apertures located dorsolaterally on each side (showed with white arrow in Fig. 12A), near fifth pedigerous somite posterior margin. Medial pore presence (showed with blue arrow in Fig. 12A) in dorsal surface. Anal somite ( Figs. 9, 12) well developed, formed by second to fourth abdominal somites fused into one single segment; almost quadrate, incised medially, with intricate folders dorsally and along lateral margins, outer corners swollen and with special convoluted pattern as illustrated in figures. Caudal rami ( Figs. 2B, 9) about 5 times longer than wide, and armed with 6 setae. Rostrum ( Figs. 6A, 8B) incorporated into cephalothorax, with broad posteroventral margin.

Antennule ( Figs. 2B, 8B) 7-segmented. Segment 2 longest, with long seta inserted on inner distal corner and almost reaching the tip of segment 5. Aesthetascs inconspicuous. Segment 7 with apical acrothek consisting of aesthetasc and 2 setae. Armature formula: I-[5], II-[15]III-[6], IV-[3], V-[5], VI-[3], VII-[8]. Antenna ( Figs. 7C, 8C) 4-segmented. Coxobasis elongated, with row of spinules along inner margin, with single seta on inner distal corner. Endopod 3-segmented; segment 1 with small seta along the inner margin; segment 2 with 2 pectinate spines and 2 setae (1 pinnate and 1 naked); segment 3 with 6 apical setae (2 pectinate, 2 pinnate and 2 naked).

Labrum ( Figs. 3C, 8C) 2 times wider than long; distal area and lateral projections with row of long setules. Metastomal area ornamented as in Fig. 3C. Mandible ( Fig. 3E) armed distally with 2 strong, denticulate or spinulose elements and 1 small, spiniform seta, pulp represented by spinulose lobe. Maxillule ( Figs. 3A, 10C) subrectangular, faintly bilobed, with row of spinules and 1 lateral seta at proximal margin. Outer lobe with row of spinules along outer margin and 4 pinnate setae apically. Inner lobe with 3 pinnate setae. Maxilla ( Figs. 3B, 8C) 2-segmented. Syncoxa almost 2 times longer than wide, with 2 pinnate setae and 1 pinnate spine. Basis with large serrate process, bearing 3 setae (1 pinnate, 1 serrate and 1 naked) and 1 pinnate spine. Maxilliped ( Figs. 3D, 5C) 4-segmented. Syncoxa with 2 pinnate setae along inner margin. Basis with 1 naked and 1 pinnate seta. Endopod 2-segmented; first segment armed with 1 naked seta; second segment bearing 1 naked lateral seta, 3 stout distal spines and 1 naked inner seta.

P1 ( Figs. 4A, 12C) biramous, both rami 3-segmented, and modified for prehension. Coxa and basis fused forming protopod with naked seta on outer corner near exopod insertion; large blade-like element on inner corner, with rounded projection along the outer margin, concentrically lines and acute apex. Exp-1 with outer seta. Exp-2 with 1 small seta. Exp-3 with 3 outer setae (proximal and distal ones reduced), 2 apical naked setae and 2 inner pinnate setae.

Enp-1 with 1 stout curved process with adhesive areas along the distal margin (marked with square in Fig. 4A). Enp-2 with a long seta (marked with asterisk in Fig. 4A). Enp-3 elongated, irregular segment ending in a lobe armed with 1 seta and 2 sucking discs; proximal sucking disc 1.5 larger than distal one. P2-P4 ( Fig. 4B-D) biramous, with both rami 3-segmented. Coxae with inner pinnate seta. Basis with pinnate seta on outer distal corner and row of setules along inner margin. Exopod outer spines serrate. Endopod outer apical spines serrate, sucking discs on distal outer edge of enp-1 and proximal and subterminal outer edges of enp-3. Armature formula of P2-P4 as follows (Roman numerals representing spines, Arabic numerals representing setae):

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Coxa Basis Exopod Endopod P2 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-2; I,II,3 P3 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-2; I,II,3 P4 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-2; I,II,2

P5 ( Fig. 6B) uniramous, 2-segmented and located laterally on somite. Protopod with 1 outer seta; free exopodal segment with characteristic shape as shown in Fig. 6B, with 3 serrate spines along outer margin and 1 serrate spine apically. P6 ( Fig. 7A marked with blue square) consisting of 2 setae.

Male: total length 0.49-0.65 mm (N = 15). Body cyclopiform ( Fig. 10A, B).

Prosome ( Fig. 10A, B) longer than urosome (1.6:1). Maximum width measured at midlength of cephalic shield. First pedigerous somite fused with cephalothorax. Body prosomites with minute integumental pits, sensilla and pores distributed as illustrated in figures. Cephalothorax and 3 free prosomites with posterior borders smooth; somites bearing P2-P3 subequal; somite bearing P4 with distal margin concave medially.

Urosome ( Figs. 7A, 10A, B) 5-segmented, narrower than prosome. Somite bearing P5 ( Figs. 7A, 10B) 2 times wider than long in ventral view and with P5 arising ventrolaterally. Anal somite (Figs. 7A, 10B) extremely reduced and deeply incised medially. Caudal rami ( Figs. 2C, 7A), shorter than to the female and seta V, 3 times longer than seta IV.

Antenna ( Figs. 7B, 10C) 4-segmented. Coxobasis elongated, with row of spinules along inner margin, with seta on inner distal corner. Endopod 3-segmented; segment 1 with pinnate spine inserted along inner margin; segment 2 with row of denticles, 2 naked setae, 1 pinnate spine and 1 serrate spine; segment 3 with 4 pinnate setae and 2 spines (1 pinnate and 1 serrate). Mandible, maxilla and maxillule as in female. Maxilliped ( Figs. 6C, 10C) strongly modified for prehension. Syncoxa with 2 pinnate setae. Basis with 1 naked seta, unequal denticulate projections and distal half of border curved and with irregular margin. Endopod represented by a strong serrate claw.

P1 ( Figs. 6D, 12D) similar to female. Coxa and basis fused with 1 naked seta on outer corner and 1 pinnate seta on inner distal edge. Exp-1 with outer seta. Exp-2 with 1 small outer seta. Exp-3 with 2 outer setae, 1 serrate spine and 1 pinnate spine apically and 2 pinnate inner spines. Enp-1 with adhesive fringe along distal margin, stout curved process and long pinnate seta on inner distal corner. Enp-2 with a long seta. Enp-3 elongated, irregular segment ending in a lobe armed with 1 seta and 2 sucking discs.

P2-P4 ( Fig. 10B) with larger coxae and not so elongated basis when compared with female. Armature formula of P2-P4 as follows (Roman numerals representing spines, Arabic numerals representing setae):

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Coxa Basis Exopod Endopod P2 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-1; I,II,3 P3 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-1; I,II,3 P4 0-1 1-0 I-0; I-1; III,I,4 0-1; 0-1; I,II,2

P5 ( Fig. 7A) elongated, 7 times longer than wide and almost stright. Exopodal segment elongated with 2 serrate spines and naked seta along outer margin and 1 pinnate spine apically, spine I inserted near spine II, on the distal third of the segment. P6 ( Fig. 7A) with 1 pinnate seta.

Etymology. The species name persiaensis is derived from the Latin meaning of or belonging to Persia referring to the provenance of the material.

Discussion

There are a large number of different classification schemes proposed for the copepods in molecular, morphological or integrated approaches ( Ho, 1990Ho, J.-S. 1990. Phylogenetic analysis of copepod orders. Journal of Crustacean Biology, 10: 528-536.; 1994Ho, J.-S. 1994. Copepod phylogeny: a reconsideration of Huys & Boxshall’s ‘parsimony versus homology’. Hydrobiologia, 292/293: 31-39.; Huys and Boxshall, 1991Huys, R. and Boxshall, G.A. 1991. Copepod evolution. London, The Ray Society , 468p.). The phylogenetic relationships of the copepods are very controversial as Huys and Boxshall (1991)Huys, R. and Boxshall, G.A. 1991. Copepod evolution. London, The Ray Society , 468p. argued. They proposed ten orders in their phylogenetics scheme and considered Poecilostomatoida as a valid order. Boxshall and Hasley (2004)Boxshall, G.A and Halsey, S.H. 2004. An introduction to copepod diversity. London, The Ray Society, 966p. proposed 9 orders for copepods and Cyclopoida treated as an order that comprises all those families previously attributed to both the Cyclopoida and the Poecilostomatoida. It should be noted that Huys et al. (2012)Huys, R.; Fatih, F.; Ohtsuka, S. and Llewellyn-Hughes, J. 2012. Evolution of the bomolochiform superfamily complex (Copepoda: Cyclopoida): new insights from ssrDNA and morphology, and origin of umazuracolids from polychaete-infesting ancestors rejected. International Journal for Parasitology, 42: 71-92., by the use of molecular evidence, confirmed that the Poecilostomatoida order was not a monophyletic group, but rather it splits from the Cyclopoida. Hence this supports the decision to include all these in one order.

In the present study, we accept the concept discussed by Boxshall and Hasley (2004Boxshall, G.A and Halsey, S.H. 2004. An introduction to copepod diversity. London, The Ray Society, 966p.) and assign our new species to Cyclopoida. The generic characters of Clausidium are not completely clear as many species descriptions lack male specimens, and so depend heavily on female morphology. On the other hand, many species of Clausidium described many years ago are not well illustrated and nor well described (see Pearse, 1947Pearse, A.S. 1947. Parasitic copepods from Beaufort, North Carolina. Journal of the Elisha Mitchell Scientific Society, 63: 1-16.; Wilson, 1932Wilson, C.B. 1932. The copepods of the Woods Hole region, Massachusetts. Bulletin of the United States National Museum, 158: 1-635.; Kensley, 1974Kensley, B. 1974. A new species of Clausidium from South Africa (Copepoda, Cyclopoida, Clausidiidae). Crustaceana, 27: 154-158.). Following Boxshall and Halsey’s (2004)Boxshall, G.A and Halsey, S.H. 2004. An introduction to copepod diversity. London, The Ray Society, 966p. key, the present new species is assigned to Clausidium by the small sucker on endopods of legs 1 to 4. It seems that the mentioned character is the most reliable homology for recognition and to use in a phylogenetic study. Furthermore, the following characters can be used as supplementary ones for defining Clausidium: body oval and flattened, prosome comprising cephalothorax and 3 free pedigerous somites, urosome comprising 5 or 6 segments, antennule 7-segmented, antenna 4-segmented, legs 1 to 4 biramous, first pair highly modified, fifth leg uniramous and 2-segmented.

Clausidium persiaensis sp. nov. shares with C. travancorense the armature formula of legs 2 to 4, but can be easily distinguished from its congener by the unique characteristics observed in the female’s antenna with 2 strong pectinate spines on endopod 2, as well as in the armature and swimming legs with elongated basis. Another differential feature observed in males is the maxilliped with distinct projections. The most obvious differentiation between the two species is in the shape of the body, P1 and P5. In a dorsal view of C. persiaensis sp. nov., the shape of the females body is suboval and the anterior margin is narrower than the posterior one, and the third pedigerous somites are 2.6 as wide as long. In contrast, C. travancorense is more flattened, slightly narrowing posteriorly, the posterior margin tapers to a rounded apex, and the third pedigerous somite is 1.2 as wide as long. The P1 in C. persiaensis sp. nov. with a blade like process acute tip ( versus blunt tip) and Exp2 of P1 with 1 setae ( versus 2 setae) is also diagnostic. The shape and armature of the P5 are different between the two species. The free exopodal segment of C. persiaensis sp. nov. is wide, with a curved proximal part in the general outline, rather than being elongate and slender in C. travancorense. The P5 in C. persiaensis sp. nov. also has 3 serrate spines along the outer margin and 1 serrate spine apically ( versus 3 setae along outer margin and 1 seta apically).

Clausidium persiaensis sp. nov. further shares with Clausidium rodriguesiKihara and Rocha, 2013Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67. the armature of P2 -P5, and maxilla and mandible, but is distinguished from the later by the free exopodal segment of P5, which is elongated about 2 times longer than wide and with 4 serrate spines ( versus 3 times longer than wide with 3 serrate spines and 1 naked seta). The basis of the syncoxa has a large serrate process, bearing 3 setae (1 pinnate, 1 serrate and 1 naked) and 1 pinnate spine ( versus 2 pinnate, 1 naked setae and 1 pinnate spine). The basis of the maxilliped has 1 naked and 1 pinnate seta ( versus 1 pinnate seta and 1 spine), and the endopod is 2-segmented; first segment armed with 1 naked seta; second segment bearing 1 naked lateral seta, 3 stout distal spines and 1 naked inner seta ( versus endopod being 2-segmented; first segment unarmed; second segment bearing 2 naked lateral setae, 3 pinnate distal setae and stout distal spine).

The present species agrees with the female description of Clausidium maximusHwang, Lee & Kim, 2016Hwang, H.; Lee, J. and Kim, I.-H. 2016. Two New Species of Clausidiidae (Copepoda, Poecilostomatoida) from Korea. Animal Systematics, Evolution and Diversity, 32: 93-104. in some aspects, which are: the armature formula of legs 1 to 4, maxilla, mandible and caudal ram. Clausidium persiaensis sp. nov. is easily defined from that species by the following characters: P5 in the later species having 4 serrate spine ( versus 4 naked setae), segment 2 of the antennal endopod with 2 pectinate spines and 2 setae ( versus 4 setae); segment 3 with 6 apical setae ( versus 7 setae). Also, there are some differences between the male specimens of the above species that includes: free exopodal segment of P5 in Clausidium persiaensis elongated with armed with 3 serrate spines with 1 naked seta ( versus 5 setae).

Early researchers studying Clausidium assumed some species were symbiotic and associated of ghost shrimps ( Corsetti and Strasser 2003Corsetti, J.L and Strasser, K.M. 2003. Host selection of the symbiotic copepod Clausidium dissimilein two sympatric populations of ghost shrimp. Marine Ecology Progress Series, 256: 151-159. ; Kihara and Rocha 2013Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67.), although some species were thought to be parasitic ( Kossmann, 1874Kossmann, R. 1874. Ueber Clausidium testudo, einen neuen Copepoden, nebst Bemerkungen über das System der halbparasitischen Copepoden. Verhandlungen der Physikalischen Gesellschaft zu Würzburg, 7: 280-294.; Wilson, 1937Wilson, C.B. 1937. Two new semi-parasitic copepods from the Peruvian coast. Parasitology, 29: 206-211. ; Pearse, 1947Pearse, A.S. 1947. Parasitic copepods from Beaufort, North Carolina. Journal of the Elisha Mitchell Scientific Society, 63: 1-16.; Humes, 1949Humes, A.G. 1949. A new copepod (Cyclopoida: Clausidiidae) parasitic on mud shrimps in Louisiana. Transactions of the American Microscopical Society, 68: 93-103. ; Pillai, 1959Pillai, N.K. 1959. On two new species of Clausidium (Copepoda: Cyclopoida) parasitic on the shrimp Callianassa. Journal of the Marine Biological Association of India, 1: 57-65.). This complex interaction is a potentially important aspect of ghost shrimp biology. Because of the influential role that ghost shrimps play in aquatic systems, Clausidium copepods may have indirect effects on local communities and ecosystem processes via their direct effects on ghost shrimps.

Acknowledgements

We are very grateful to Professor Dr. Pedro Martínez Arbizu from Senckenberg am Meer, German Center for Marine Biodiversity Research, Wilhelmshaven for help and encouragement during this study. His hospitality during the molecular and CLSM study in his lab to Vahid Sepahvand is gratefully acknowledged. The authors express their gratitude to Dr. Abdolvahab Maghsoudlou from Iranian National Institute for Oceanography and Atmospheric Science for his cooperation in this study. Thanks are due to Dr. Alireza Sari and Dr. Reza Naderloo from the University of Tehran for their help. Special thanks are due to Dr Christopher Tudge from the American University and Smithsonian Institution, Washington DC, for reading the manuscript and his worthy comments. Sampling would have been impossible without the help of Mr. Abdolmohammad Baziar form the Iranian National Institute for Oceanography and Atmospheric Science (INIOAS).

References

Burmeister, H. 1835. Beschreibung einiger neuen oder weniger bekannten Schmarotzerkrebse, nebst allgemeinen Betrachtungen über die Gruppe, welcher sie angehören. Nova Acta Physico-Medica Academiae Caesareae Leopoldino-Carolinae Naturae Curiosorum ( Acta der Kaiserlichen Leopoldinisch-Carolinischen Deutschen Akademie der Naturforscher), Halle 17: 269-336, pls. 23, 24, 24a, 25. (1833)
Boxshall, G.A and Halsey, S.H. 2004. An introduction to copepod diversity. London, The Ray Society, 966p.
Corsetti, J.L and Strasser, K.M. 2003. Host selection of the symbiotic copepod Clausidium dissimilein two sympatric populations of ghost shrimp. Marine Ecology Progress Series, 256: 151-159.
Dworschak, P.C.; Felder, D.F and Tudge, C.C. 2012. Infraorders Axiidea de Saint Laurent, 1979 and Gebiidea de Saint Laurent, 1979 (formerly known collectively as Thalassinidea). p. 109-219. In: F.R. Schram and J.C. von Vaupel Klein (eds), Treatise on zoology - anatomy, taxonomy, biology. The Crustacea. Complementary to the volumes translated from the French of the Traité de Zoologie [founded by P.-P. Grassé]. 9 Part B. Eucarida: Decapoda: Astacidea p.p. (Enoplometopoidea, Nephropoidea), Glypheidea, Axiidea, Gebiidea, and Anomura. Leiden, Brill.
Embleton, A.L. 1901. Goidelia japonica -a new Entozoic Copepod from Japan, associated with an Infusorian ( Trichodina). Journal of the Linnean Society (Zoology), 28: 211-229, pls. 21-22.
Ho, J.-S. 1990. Phylogenetic analysis of copepod orders. Journal of Crustacean Biology, 10: 528-536.
Ho, J.-S. 1994. Copepod phylogeny: a reconsideration of Huys & Boxshall’s ‘parsimony versus homology’. Hydrobiologia, 292/293: 31-39.
Humes, A.G. 1949. A new copepod (Cyclopoida: Clausidiidae) parasitic on mud shrimps in Louisiana. Transactions of the American Microscopical Society, 68: 93-103.
Huys, R.; Fatih, F.; Ohtsuka, S. and Llewellyn-Hughes, J. 2012. Evolution of the bomolochiform superfamily complex (Copepoda: Cyclopoida): new insights from ssrDNA and morphology, and origin of umazuracolids from polychaete-infesting ancestors rejected. International Journal for Parasitology, 42: 71-92.
Huys, R. and Boxshall, G.A. 1991. Copepod evolution. London, The Ray Society , 468p.
Huys, R.; Gee J.M.; Moore, C.G. and Hamond, R. 1996. Marine and brackish water harpacticoid copepods. Part 1. In: D.M. Kermack, R.S.K. Barnes and J.H. Crothers (eds), Synopses of the British Fauna (New Series) No. 51. London, The Linnean Society of London and the Estuarine and Coastal Sciences Association, 352p.
Hwang, H.; Lee, J. and Kim, I.-H. 2016. Two New Species of Clausidiidae (Copepoda, Poecilostomatoida) from Korea. Animal Systematics, Evolution and Diversity, 32: 93-104.
Kensley, B. 1974. A new species of Clausidium from South Africa (Copepoda, Cyclopoida, Clausidiidae). Crustaceana, 27: 154-158.
Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67.
Kossmann, R. 1874. Ueber Clausidium testudo, einen neuen Copepoden, nebst Bemerkungen über das System der halbparasitischen Copepoden. Verhandlungen der Physikalischen Gesellschaft zu Würzburg, 7: 280-294.
Michels, J. and Buntzow, M. 2010. Assessment of Congo red as a fluorescence marker for the exoskeleton of small crustaceans and the cuticle of polychaetes. Journal of Microscopy, 238: 95-101.
Milne Edwards, H. 1837. Les Crustacés. p. 1-278. In: G. Cuvier (ed.), Le Règne animal distribué d’après son organisation: pour servir de base a l’histoire naturelle des animaux et d’introduction a l’anatomie comparée. Volume 2. Paris, Masson.
Pearse, A.S. 1947. Parasitic copepods from Beaufort, North Carolina. Journal of the Elisha Mitchell Scientific Society, 63: 1-16.
Pillai, N.K. 1959. On two new species of Clausidium (Copepoda: Cyclopoida) parasitic on the shrimp Callianassa Journal of the Marine Biological Association of India, 1: 57-65.
Sepahvand, V.; Sari, A.; Salehi, H.; Nabavi, S.M.B. and Ghorbanzadeh, S.G. 2013. Littoral mud shrimps (Decapoda: Gebiidea & Axiidea) of the Persian Gulf and Gulf of Oman, Iran. Journal of the Marine Biological Association of the United Kingdom, 93: 999-100.
Wilson, C.B. 1932. The copepods of the Woods Hole region, Massachusetts. Bulletin of the United States National Museum, 158: 1-635.
Wilson, C.B. 1937. Two new semi-parasitic copepods from the Peruvian coast. Parasitology, 29: 206-211.

Zoobank:

http://zoobank.org/urn:lsid:zoobank.org:pub:250A92D6-A978-4D2C-98D3-6C86579172EA

Publication Dates

Publication in this collection
2017

History

Received
30 Nov 2016
Accepted
08 Mar 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Burmeister, H. 1835. Beschreibung einiger neuen oder weniger bekannten Schmarotzerkrebse, nebst allgemeinen Betrachtungen über die Gruppe, welcher sie angehören. Nova Acta Physico-Medica Academiae Caesareae Leopoldino-Carolinae Naturae Curiosorum ( Acta der Kaiserlichen Leopoldinisch-Carolinischen Deutschen Akademie der Naturforscher), Halle 17: 269-336, pls. 23, 24, 24a, 25. (1833)

[2] Boxshall, G.A and Halsey, S.H. 2004. An introduction to copepod diversity. London, The Ray Society, 966p.

[3] Corsetti, J.L and Strasser, K.M. 2003. Host selection of the symbiotic copepod Clausidium dissimilein two sympatric populations of ghost shrimp. Marine Ecology Progress Series, 256: 151-159.

[4] Dworschak, P.C.; Felder, D.F and Tudge, C.C. 2012. Infraorders Axiidea de Saint Laurent, 1979 and Gebiidea de Saint Laurent, 1979 (formerly known collectively as Thalassinidea). p. 109-219. In: F.R. Schram and J.C. von Vaupel Klein (eds), Treatise on zoology - anatomy, taxonomy, biology. The Crustacea. Complementary to the volumes translated from the French of the Traité de Zoologie [founded by P.-P. Grassé]. 9 Part B. Eucarida: Decapoda: Astacidea p.p. (Enoplometopoidea, Nephropoidea), Glypheidea, Axiidea, Gebiidea, and Anomura. Leiden, Brill.

[5] Embleton, A.L. 1901. Goidelia japonica -a new Entozoic Copepod from Japan, associated with an Infusorian ( Trichodina). Journal of the Linnean Society (Zoology), 28: 211-229, pls. 21-22.

[6] Ho, J.-S. 1990. Phylogenetic analysis of copepod orders. Journal of Crustacean Biology, 10: 528-536.

[7] Ho, J.-S. 1994. Copepod phylogeny: a reconsideration of Huys & Boxshall’s ‘parsimony versus homology’. Hydrobiologia, 292/293: 31-39.

[8] Humes, A.G. 1949. A new copepod (Cyclopoida: Clausidiidae) parasitic on mud shrimps in Louisiana. Transactions of the American Microscopical Society, 68: 93-103.

[9] Huys, R.; Fatih, F.; Ohtsuka, S. and Llewellyn-Hughes, J. 2012. Evolution of the bomolochiform superfamily complex (Copepoda: Cyclopoida): new insights from ssrDNA and morphology, and origin of umazuracolids from polychaete-infesting ancestors rejected. International Journal for Parasitology, 42: 71-92.

[10] Huys, R. and Boxshall, G.A. 1991. Copepod evolution. London, The Ray Society , 468p.

[11] Huys, R.; Gee J.M.; Moore, C.G. and Hamond, R. 1996. Marine and brackish water harpacticoid copepods. Part 1. In: D.M. Kermack, R.S.K. Barnes and J.H. Crothers (eds), Synopses of the British Fauna (New Series) No. 51. London, The Linnean Society of London and the Estuarine and Coastal Sciences Association, 352p.

[12] Hwang, H.; Lee, J. and Kim, I.-H. 2016. Two New Species of Clausidiidae (Copepoda, Poecilostomatoida) from Korea. Animal Systematics, Evolution and Diversity, 32: 93-104.

[13] Kensley, B. 1974. A new species of Clausidium from South Africa (Copepoda, Cyclopoida, Clausidiidae). Crustaceana, 27: 154-158.

[14] Kihara, T.C. and Rocha, C.E.F. 2013. First record of Clausidium (Copepoda, Clausidiidae) from Brazil: a new species associated with ghost shrimps Neocallichirus grandimana (Gibbes, 1850) (Decapoda, Callianassidae). Zookeys, 335: 47-67.

[15] Kossmann, R. 1874. Ueber Clausidium testudo, einen neuen Copepoden, nebst Bemerkungen über das System der halbparasitischen Copepoden. Verhandlungen der Physikalischen Gesellschaft zu Würzburg, 7: 280-294.

[16] Michels, J. and Buntzow, M. 2010. Assessment of Congo red as a fluorescence marker for the exoskeleton of small crustaceans and the cuticle of polychaetes. Journal of Microscopy, 238: 95-101.

[17] Milne Edwards, H. 1837. Les Crustacés. p. 1-278. In: G. Cuvier (ed.), Le Règne animal distribué d’après son organisation: pour servir de base a l’histoire naturelle des animaux et d’introduction a l’anatomie comparée. Volume 2. Paris, Masson.

[18] Pearse, A.S. 1947. Parasitic copepods from Beaufort, North Carolina. Journal of the Elisha Mitchell Scientific Society, 63: 1-16.

[19] Pillai, N.K. 1959. On two new species of Clausidium (Copepoda: Cyclopoida) parasitic on the shrimp Callianassa Journal of the Marine Biological Association of India, 1: 57-65.

[20] Sepahvand, V.; Sari, A.; Salehi, H.; Nabavi, S.M.B. and Ghorbanzadeh, S.G. 2013. Littoral mud shrimps (Decapoda: Gebiidea & Axiidea) of the Persian Gulf and Gulf of Oman, Iran. Journal of the Marine Biological Association of the United Kingdom, 93: 999-100.

[21] Wilson, C.B. 1932. The copepods of the Woods Hole region, Massachusetts. Bulletin of the United States National Museum, 158: 1-635.

[22] Wilson, C.B. 1937. Two new semi-parasitic copepods from the Peruvian coast. Parasitology, 29: 206-211.

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