13urn:lsid:arphahub.com:pub:C9EFD5EB-E909-52A5-90B8-2C7119603A4Eurn:lsid:zoobank.org:pub:ED34F394-2E4C-49D6-8300-0DC18F233E6CZoosystematics and EvolutionZSE1435-19351860-0743Pensoft Publishers10.3897/zse.91.57155715Research ArticleInvertebrataGeneral ecologySystematicsWorldStenothoids living with or on other animals (Crustacea, Amphipoda)Krapp-SchickelTraudltraudl.krapp@uni-bonn.de1VaderWim2Zoologisches Forschungsmuseum Alexander KoenigBonnGermanyTromsø MuseumTromsøNorway
201502102015912215246FFCFEF2D-2849-FFC5-FF98-0570FFEB357B89B46F52-BA36-41A9-9D7F-B635CAF052C15757662207201526082015Traudl Krapp-Schickel, Wim VaderThis is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.http://zoobank.org/89B46F52-BA36-41A9-9D7F-B635CAF052C1
This paper describes new or little known species of Stenothoidae, collected from sea anemones, bivalves or hermit crabs. A key to world Stenula species is provided.
TaxonomyAmphipodaStenothoidaenew speciesrevalidated speciesassociations with other animalsIntroduction
Associations between amphipods and other animals are probably not all that rare, but few have been recorded hitherto, mainly because collection methods earlier were too crude. With the advance of Scuba-diving, new associations are being discovered at a rapid pace. The present paper adds a few more examples from the family Stenothoidae.
Material and methods
All specimens in alcohol were studied under a Reichert and Wild M5 dissecting microscope, then drawn from preparations (dissected and stored in glycerine or Faure’s medium) under a Wild M20 microscope. The pencil drawings were partly inked by hand, and partly with the software Adobe Illustrator CS 3, using a Wacom A4 drawing board. The material is lodged at the Museums of Verona (MVR, Italy), Copenhagen (ZMUC, Denmark), Smithsonian Washington (USNM, USA), see detailed indications at the descriptions.
Abbreviations
A1, 2
, antennae 1, 2
; art
, article
; Cx
, coxa
; Ep
, epimeral plate
; Gn 1, 2
, gnathopods 1, 2
; Md
, mandible
; Mx1, 2
, maxillae 1, 2
; Mxp
, maxilliped
; P 3–7
, peraeopods 3–7
; U 1–3
, uropods 1–3
.
In this paper the following terms are applied (see also Krapp-Schickel 2011: 1–2): tooth: non-articulated pointed ectodermal structure; spine: stout, articulated structure (synonymous with “robust seta”); seta: slender, flexible articulated structure.
The diagnosis of this genus is summarized, it shows few eminent features: Md palp lacking totally, P 5 basis linear, P 6–7 basis widened, T laminar. The genus contains many apparently free-living species and others that are living in symbiosis with other marine invertebrates; these latter in many cases show greatly diminished sexual dimorphism.
Stenothoe species are mainly found in the Atlantic and Mediterranean, while few are living in the Pacific, in the region of Australia-New Zealand or in the Indian Ocean (Krapp-Schickel 2015). There remains the strong suspicion that e.g. members living near Australia or in the Indian Ocean are not closely related to those from the Atlantic Ocean (urosome segments tend to lose their clear articulation in the former), but as the easier visible appendages such as legs or antennae match the generic definition, plus the fact that both have lost the Md palp (most probably an independent evolution), also these species are treated in the same genus Stenothoe, for the time being. Here we have examples of these different groups:
female ov. 3 mm, Florida, Monroe County, Cross Key: from Bartholomeaannulata (Lesueur, 1817), 4/10/1971, J. Thomas coll. Slide MVRCr 7716, 7717.
Additional material.
one female front part, slide MVRCr 7718; several hundreds, same locality, same date, in alcohol, deposited at MVRCr.
Type locality.
Florida, Monroe County, Cross Key.
Etymology.
after the host anemone Bartholomeaannulata (Lesueur, 1817), from where it was collected.
Diagnosis.
Sexual dimorphism lacking. Gn 1 and Gn 2 propodus similar in shape, propodus hind margin rounded, in Gn 2 without clear palmar corner. P 6, 7 basis posterodistal corner lengthened and rounded; merus posterodistally widened and lengthened, reaching half length of carpus. U3 peduncle < ramus. T with or without submarginal spines and marginal setae.
Description.
Length 2.5 – 3 mm.
Head. Eyes round, medium. Mouthparts: Md with acute hook on the place where a palp would have inserted; molar absent, incisor and lacinia mobilis strong, spine row present. Mx 1 palp with 2 arts, Mx 2 plates sitting upon each other. Mxp IP small, OP vanishing. Antennae: subequal, A1 flagellum about 15 arts, A2 flagellum about 10 arts.
Peraeon. Gn 1 basis about 3 times as long as wide, merus triangular, distally rounded and beset with spines, nearly reaching end of carpus; carpus triangular; propodus somewhat wider and clearly longer than carpus, anteriorly beset with long setae; palm well defined by a group of spines and palmar corner. Cx 2 tongue-shaped, posteriorly excavate. Gn 2 basis 3 –3.5 times longer than wide, rectangular; merus rectangular-trapezium-shaped, distally pointed, carpus triangular, distally with stiff short and long pectinate setae, propodus oval, posterior margin regularly rounded, palm defined by some robust spines but palmar corner lacking, with one or more small triangular elevations.
Peraeopods: Cx 3 rectangular, distal margin not much longer than proximal one. Cx 4 triangular, clearly wider than long. P 3, 4 similar, slender, dactylus longer than half propodus. P 5 basis rectolinear. P 6, 7 basis with posterior margin rounded, postero-distal lobe well developed; merus lengthened and widened, reaching about half length of carpus; propodus > carpus, dactylus > half of propodus.
Pleon. U 1 peduncle > subequal rami, all beset with a few spines. U 2 peduncle > longer than unequal rami; U 3 peduncle about 3 times as long as wide, peduncle < ramus, ramus art 1 < art 2, with few short spines.
Telson with or without pair of submarginal spines and small marginal setae.
Remarks.
In Krapp-Schickel 2015 a key is offered for Stenothoe species world-wide, grouped after geographical regions. Among these species this new one is one of only two with a regularly rounded Gn 2 male propodus, lacking excavations, deep incisions or prominent elevations. The other one is S.tergestina (Nebeski, 1881), frequently found in the Mediterranean, free-living in algae.
Distribution.
Florida, Atlantic Ocean.
Ecology.
living with and on the sea-anemone Bartholomeaannulata (Lesueur, 1817).
Stenothoebartholomea sp. n. female 3 mm holotype. Gn 1 gnathopod 1; Gn 1’, Gn 1 ‘’, Gn 1 ‘’’ palm and dactylus enlarged; gnathopod 1 dactylus and propodus enlarged; Gn 2 gnathopod 2.
Stenothoebartholomea sp. n. female 3 mm holotype. Gn 2, Gn 2’, Gn 2’’ gnathopod 2 from both sides and tip of carpus + merus resp. palmar corner enlarged.
Stenothoebartholomea sp. n. female 3 mm holotype. P 3–4, P 6–7 peraeopod 3–4; peraeopod 6–7; P 4’, P 4’’ entire leg with coxa resp. distal end of propodus P 4 enlarged; P 7’ distal end of propodus P 7 enlarged.
Stenothoebartholomea sp. n. female 3 mm holotype. Ep 1, 2, 3 epimeral plates 1–3. U 1, 2, 3 uropod 1, 2, 3; U 2’ uropod 2 enlarged; U 3’, U 3’’ uropod 3 in two enlargements. T’, T’’ telson enlarged in different positions.
https://binary.pensoft.net/fig/58980AnimaliaAmphipodaStenothoidaeE3FF7A5F-FCC7-59ED-805B-AF69B9D8CD4AStenothoemiersii(Haswell, 1879)Figures 6, 7MontaguaMiersii Haswell, 1879: 323, pl. 24, fig. 4.Montagualongicornis Haswell, 1879: 323, pl. 24, fig. 5.Stenothoemiersi. —Stebbing 1906: 200 (in part). —Stebbing 1910: 637 (in part). Lowry and Stoddart 2003: 260. —Krapp-Schickel 2009: 873–875.Stenothoe?miersii. —J.L. Barnard 1974: 120, figs 75–76.Stenothoevalida. —Sheard 1937: 21 (=S.miersii, but confused with other species).not Montaguanamiersii. —Chilton 1883: 79 (part =S.moe, J.L Barnard 1972).not Montaguamiersii. —Chilton 1884: 1043 (part =S.moe, J.L Barnard 1972).not Proboliummiersii. —Thomson and Chilton 1886: 150 (=S.valida).Type locality.
Port Jackson, New South Wales, Australia.
Material examined.
1 spec. from Bermagui (400 km S of Port Jackson, Australia), 8/6/1989, Wim Vader collected on a hermit crab in shallow water. Stored at the Australian Museum (AM xxx) Sydney.
Remarks.
In Haswell (1879) two species of Montagua were described from Port Jackson, Sydney: M.miersii, directly followed by M.longicornis. It appears that the first was the female, the latter the male of the same species, belonging to Stenothoe. J.L. Barnard (1974) described four species of Stenothoe from Australia. One of these he called S.?miersi, doubting about the synonymy, as no type material is available. Barnard‘s description matches the different populations around most of the Australian coastline, also the Lizard Island specimens (Krapp-Schickel 2009: 873–875), and again the illustrations given here of a female.
Ecology.
It may well be that this specimen lived among the encrusting hydroids and bryozoans growing on top of the hermit-crab-shell and thus had no direct association with the crab; it was the only Stenothoe specimen found among many hermit crabs.
Stenothoemiersii (Haswell, 1879) male 3 mm; P 5–7 peraeopod 5–7; U 1–3 uropod 1–3; U 3’ third uropod enlarged; Ep 3 third epimeral plate; T telson.
https://binary.pensoft.net/fig/58982Genera Metopa Boeck, 1871 and Stenula Barnard, 1962
Lincoln 1979 has synonymized Stenothoideslatipes Chevreux & Fage, 1925, with Metoparubrovittata Sars, 1883 and transferred both to the genus Stenula, a genus coined by Barnard 1962.
Members of Metopa are mainly distributed in the Atlantic and Arctic, only very few are living outside. They can be divided into three groups by looking at their Gn 1 palmar corner:
L Gn 1 locking, palmar corner 120°, propodus widened
SI simple, Gn 1 palmar corner absent, propodus hind margin straight
N normal, Gn 1 palmar corner 150–160°, propodus hind margin rounded
Atlantic Ocean and Arctic:
M.abyssalis Stephensen, 1931 N
M.aequicornis Sars, 1879 N
M.affinis Boeck, 1871 SI/N
M.alderi (Bate, 1857) N
M.boeckii Sars, 1892 N
M.borealis Sars, 1883 SI
M.bruzelii (Goës, 1866) SI
M.clypeata (Krøyer, 1842) SI
M.cristata Gurjanova, 1955 L
M.eupraxiae Krapp-Schickel, 2009 L
M.gigas Just, 2013 SI
M.glacialis Krøyer, 1842 L
M.groenlandica Hansen, 1888 L
M.hearni Dunbar, 1954 N
M.invalida Sars, 1892 SI
M.latimana Hansen, 1888 N
M.leptocarpa Sars, 1883 L (Md palp lacking?)
M.longicornis Boeck, 1871 SI
M.longirama Dunbar, 1942 SI
M.normani Hoek, 1889 N
M.norvegica (Liljeborg, 1851) L
M.palmata Sars, 1895 SI
M.propinqua Sars, 1892 SI
M.pusilla Sars, 1892 SI
M.quadrangula Reibisch, 1905 SI
M.robusta Sars, 1892 SI
M.rubrovittata Sars, 1883 N
M.samsiluna J.L. Barnard, 1966 N
M.sinuata Sars, 1892 N
M.solsbergi Schneider, 1884 N
M.spinicoxa Shoemaker, 1955 N
M.submajuscula Gurjanova, 1948 L
M.spitzbergensis Brüggen, 1907 SI
M.tenuimana Sars, 1892 SI
M.wiesei Gurjanova, 1933 SI
Pacific Ocean:
M.abyssi Pirlot, 1933 Pacific N
M.angustimana Gurjanova, 1948 SI
M.bulychevae Gurjanova, 1955 L
M.cistella J.L. Barnard, 1969 SI
M.colliei Gurjanova, 1948 L
M.dawsoni J.L. Barnard, 1962 SI
M.exigua Krapp-Schickel, 2009 N
M.japonica Gurjanova, 1952 L
M.kobjakovae Gurjanova, 1955 L
M.koreana Gurjanova, 1952 SI
M.layi Gurjanova, 1948 N
M.majuscula Gurjanova, 1948 L
M.mirifica Gurjanova, 1952 L
M.samsiluna JL Barnard, 1966 L
M.timonovi Gurjanova, 1955 L
M.torbeni Krapp-Schickel, 2009 SI
M.uschakovi Gurjanova, 1948 N
Many authors have cited Metoparubrovittata: Sars 1883: 90, 1895: 255, Reibisch 1905: 31, Chevreux and Fage 1925: 125, Stephensen 1929: 5, 1931: 189, 1938: 175, Schellenberg 1942: 120, Gurjanova 1951: 432, Oldevig 1959: 44, Moore 1984: 26. None of them gives illustrations of the mouthparts, only Lincoln 1979: 192 found a very short uniarticulate mandible palp in his material from the British coasts which he then called Stenularubrovittata (Sars), confirmed by Vader (see Lincoln op. cit., p. 180) for a specimen from the Norwegian west coast, but we have no information about the mouthparts of the Norwegian material called Metoparubrovittata collected by Sars.
Chevreux 1900 erected a new genus Stenothoides for stenothoid species with present, but reduced mandibular palp.
J.L. Barnard 1962 coined a new genus Stenula leaving the species with rectilinear basis of P 6 in Stenothoides and splitting those species which have P 6 basis widened (see Chevreux and Fage 1925: 130, Gurjanova 1938: 279 and 1951: 445). His diagnosis for Stenula is the following:
P 5 basis slender; P 6, 7 basis broad; Md palp with 1 article; Mx1 palp with 1 article.
Barnard 1962 included 10 species in Stenula: S.angusta (Shoemaker), S.arctica (Gurjanova), S.bassarginensis (Gurjanova), S.beringiensis (Gurjanova), S.carinatus (Gurjanova), S.latipes (Chevreux & Fage) (type), S.modosa J.L. Barnard, 1962, S.ratmanovi (Gurjanova), S.serripes (Gurjanova), S.ussuriensis (Gurjanova), nota bene 7 of 10 species described by Gurjanova from the Arctic Sea.
Just 1980: 52 transferred Metopanordmanni Stephensen, 1931 to Stenula.
In the European register of marine species Bellan-Santini and Costello 2001 cited 15 Stenula species: the ten above specified by Barnard 1962, plus S.alexanderi Tzvetkova & Golikov, 1990, S.nordmanni (Stephensen, 1931), S.peltata (where they mistakenly cited Della Valle 1893 as author instead of Smith 1874) and – following Lincoln 1979 – they placed Stenothoideslatipes Chevreux & Fage, 1925 in junior synonymy with S.rubrovittata (Sars, 1892), which according to them therefore should be the actual type at the moment. We do not think this is correct, as Stenothoideslatipes remains in any case the type.
S.carinatus (Gurjanova) was transferred to Metopa and renamed M.eupraxiae sp. n. by Krapp-Schickel 2009b.
Thus at the beginning of this study 14 species belong to Stenula. Judging from the illustrations of the mandible in Tandberg 2011: fig. 25, M.invalida Sars, 1892 from N. Norway has to be added as 15th species. These species are mainly living in the far north region (N-Atlantic, N-Pacific, Arctic), only two of them were described by J.L. Barnard from California.
Tandberg & Vader could demonstrate in Tandberg (2011), that the character of Gn 2 palmar corner present/absent does not bring any clear results in a cladistic analysis. E.g. Metopaclypeata (the type species) or M.palmata, both with strongly rectangular palmar corner, strangely enough are not grouped together with M.alderi = M.spectabilis or M.norvegica, probably because of the strong allometry, which shows their members with very different palmar corners depending on age. It might therefore be more helpful to look at the shape of Gn 1, which shows normally much less allometry and which can be basic (the type of Stenula plus several other members of this genus and a lot of Metopa, with the carpus shorter than or equal to the propodus) or elongated (type of Metopa and some other Stenula, with Gn 1 simple and carpus, often also propodus, much lengthened and narrow).
Tandberg 2011 cites in her thesis at the beginning a letter from G.O. Sars to Sparre-Schneider, writing „I have advanced to the supposedly most difficult of all amphipod-families: Stenothoidae“. There is no doubt that there is a great difference between having a fully developed mandibular palp (Metopa) or none (Stenothoe), but the genus Stenula, as presently conceived, gathers all transitions, and is with high probability heterogeneous.
There are also various transitions within the maxillae, having two (Stenothoe) or one (Metopa, Stenula) articles in Mx1 palp, where often one cannot clearly decide if and where an articulation is present; while the Mx2 plates may sit in tandem-position (many Metopa like M.affinis, aequicornis, groenlandica, glacialis, clypeata) or riding position (in some Stenothoe and Stenula), with all steps in-between.
In three species we have no information about the mandible palp at all: S.rubrovittata, S.modosa, S.peltata. The following have a short stump, about as long as the width of the mandible-incisor: S.angusta, S.bassarginensis, S.ratmanovi. All other species have a uniarticulate mandible palp which is clearly longer than the mandible-incisor: S.alexanderi, S.arctica, S.beringiensis, S.incola, S.serripes, S.ussuriensis, and also Metopaderjugini Gurjanova, 1948, which is therefore here also transferred to Stenula (see above). Just 1980: 52 looked at the mandible of Metopanordmanni using the type specimen, and found again a uniarticulate palp longer than the mandible-incisor (also illustrated by Tzvetkova and Golikov 1990), while Shoemaker 1955: 127 found material from Point Barrow with strikingly similar legs but different antennae (A1>A2), a two-jointed Mx1 palp and a 3-articulated mandible palp. Although he cites Metopanordmanni Stephensen, 1931 in the synonymy-list, his species belongs to Proboloides and thus is a different animal with nearly identical body but different mouthparts, an observation which can be made rather frequently within Stenothoidae.
Stenula species could also be divided by the ratios of articles in Gn 1, having propodus subequal to carpus, or clearly much longer resp. clearly shorter. The first group is formed by the majority: S.beringiensis, S.derjugini, S.incola, S.latipes, S.modosa, S.peltata, S.ratmanovi, S.serripes; propodus is longer than carpus in S.angusta; propodus is shorter than carpus in S.arctica, S.bassarginensis, S.nordmanni, S.ussuriensis and also
S.alexanderi (this species is very aberrant also in the shape of Gn 1 dactylus).
It is the great help of a cladistic analysis that one can test the states of many characters together, and if a group of characters is changing together, it is more probable that a naturally related clade is found. But in the above listed species there are A1 subequal A2 or much different, Gn 1 propodus simple, rounded or with strong palmar corner, Gn 1 carpus short or extremely lengthened, Gn 2 propodus regularly rounded or deeply excavated, P 6, 7 strongly rounded or with widened but parallel margins, telson spinose or naked. And even using more than 60 characters as in the very exhaustive phylogenetic analysis of Tandberg & Vader (Tandberg 2011), there remains the big danger that the character states are not homologous. As an example, several analyses bring Stenulaincola J.L. Barnard, 1969 from the intertidal of California always closely together with Stenulaserripes Gurjanova, 1955: both show a one-articulate mandibular palp of medium length, Gn 2 with a well defined palmar corner, P 7 basis about as wide as long and P 7 merus very much lengthened and widened, and they are thus „very similar“ after the coded characters. But their biogeography, Gn 1 and P 6 are obviously quite different, and they are most probably not closely related at all.
At the moment there is nothing else to do than to continue „making order“ within this complicated family of Stenothoidae in describing as completely as possible its single members.
First we tried to find material of Metoparubrovittata Sars from the northern North Atlantic (type loc. Christiansund and Finnmark) for comparing it with material of Stenulalatipes (Chevreux & Fage) from the English Channel (type loc. Saint Vaast la Hougue, see Chevreux 1908: 42, 1925: 130).
–7 spec. in alcohol, 2 on slide: Surtsey (Vestmannaeyjar) off Iceland, 63.30 N, -20.60 W. NA 30 m 18/8/1971 leg. Sigurdsson, det. J. Just. ZMUC-CRU–4464.
–1 spec. 20/8/1971 same locality as above, ZMUC-CRU–4465.
– 4 spec. North Sea without date, 4 spec., 57.266667 N 5.5 E. ZMUC-CRU–4467.
Discussion.
It seemed strange that the sharp eye of Chevreux would have overlooked the synonymy between M.rubrovittata (cited by him in the same work Chevreux and Fage 1925: 127, fig. 125) and his newly erected Stenothoideslatipes (loc. cit.: 129, fig. 127, 128), later transferred to Stenula and finally synonymized as Stenularubrovittata (Sars, 1883) by Lincoln 1979. But until now really nobody had looked at the mouthparts of M.rubrovittata, an often cited species, which nevertheless is rarely found in Museum collections.
In fact, the studied material shows a classical mandible palp of Metopa species with 3 articles, though it has to be admitted that it was quite a difficult task to see always the articulations. But nevertheless, already the length of the mandible palp is very different in the material from the Channel (cf. Fig. 8 with Fig. 10B, C), thus it can be confirmed that Chevreux was right: both Metoparubrovittata Sars, 1883 as well as Stenulalatipes (Chevreux & Fage, 1925) do exist, and they show extremely similar body morphology, colour pattern and even ecological niche, only the mouthparts are somewhat different. Thus, Metoparubrovittata Sars, 1892 is herewith revalidated and Stenothoideslatipes (Chevreux & Fage, 1925) remains the type species of Stenula. It is not clear what the geographical distribution of the two species is, as all the numerous citations cannot be judged without examining their mandible.
For control Jean-Claude Sorbe sent us material from the Bay of Biscay, and the single specimen he had collected affirms this decision.
Grandcamp-les-Bains (Calvados), on the shell of Eupagurusbernhardus (L.); very common in a dredge of 20m depth in Saint-Vaast-la-Hougue. English Channel. Chevreux and Fage 1925: 11 specified that the shell from which the amphipod was collected was Buccinumundatum inhabited by the hermit crab.
Material examined.
1 spec. 3 mm, Survey OXYBENT 9 STN OB9–B–TS04; 43.8175 N, 2.042 W; Bay of Biscay, Capbreton Canyon; 500–510 m; 22/06/1999; coll. Sorbe.
4 spec. Denmark, Anholt (Kattegat) without date, 17,5 fathoms = 31,5 m. ZMUC-CRU–4466.
AnimaliaAmphipodaStenothoidae884A43C4-6A96-5F97-804F-C8B353A815C5?Stenulapeltata(Smith, 1872)Figures 11, 12, 13Smith 1872 in: Smith and Harger 1872: 29, pl. 3, fig. 5–8; Della Valle 1893: 570; Stebbing 1906: 194–195.? synonymous to Gurjanova 1948: 310 S.ratmanoviType locality.
St. George’s Banks, 55 m depth. Near Cultivator Shoal.
Material examined.
one specimen USNM 35636, 41.5557 N, 68.1641 W, NA, 30 fathoms, sandy bottom, 29/8/1872.
As the original paper is not easily accessible and as there is some confusion about the authors, I repeat herewith the type-description by Smith:
Description.
Female. Eyes round and nearly white in alcohol. Antennulae (=A1) considerably shorter than epimera of the 4th segment (Cx 4); first article of the peduncle stout, subequal to head, the second shorter, the third very short and similar to the arts of the flagellum; flagellum scarcely longer than the peduncle, with 8 arts. Antennae (=A 2) slightly longer than antennulae; peduncle art 4, 5 about equal in length; flagellum subequal to flagellum of antennulae. Cx 2 (fig. 5) nearly ovate, twice as high as broad; Cx 3 somewhat rectangular, not wider than the second but considerably deeper; Cx 4 (fig. 6) very large, slightly deeper than Cx 3 and 1/3–1/4 longer than deep, being about as long as the first five segments of the thorax, the inferior margin regularly curved and the posterior convex in outline. Gn 1 (fig. 7) small and slender; merus triangular and distally broader than the carpus, which is not quite twice as long as broad and has the lateral margins parallel; propodus narrower but slightly longer than the carpus and narrowed distally; dactylus about half as long as the propodus. Gn 2 (Fig. 5) stouter; merus short triangular, carpus much broader than long and only slightly produced beneath the propodus; propodus about as long as the breadth of Cx 2, nearly twice as long as broad; palmar margin (Fig. 8) convex in outline, slightly oblique, with an acute lobe and a spine at the posterior angle, within which the top of the dactylus closes. P 4, 5 slender and nearly naked, P 5 basis slender, four times as long as broad, not wider than the merus. P 6, 7 slightly shorter than P 5, basis posteriorly dilated and squamiform in both pairs, but broader in P 7. U 3 ramus slightly longer than the peduncle.
Length of largest specimen, from front of head to tip of telson, about 6 mm.
The mandibles are without palp or molar tubercles, and in all other characters the species agrees with the genus Stenothoe as restricted by Boeck, but it seems to be very distinct from either of the European species.
Discussion.
The hint after the original description, that this species should belong to Stenothoe as it has no mandible palp, was not convincing: no Stenothoe is described from the region off Massachusetts or Connecticut, nor from the entire Atlantic, with gnathopods similar to the ones illustrated.
The incomplete illustrations of S.ratmanovi (Gurjanova, 1948) are very similar to what little we know about ?Stenothoepeltata, and the two species may well be synonymous, in spite of the large geographic distance between the type localities. In that case the older name Stenulapeltata (Smith, 1874) would become the valid name of the taxon.
We hoped to get more information by studying the single type specimen (see Fig. 11, 12) and illustrate here all what we could see; but there were no mouthparts except the maxilliped, and we still don’t know anything about the shape of the mandibular palp.
A sample in the collections of the Smithsonian Inst. (Washington) raised new hope to shed light in this situation: there could exist a Stenula sp. from the coelenteron of Haliactisarctica. Will this be S.peltata?
Stenulapeltata (Smith, 1872): illustration of the single type specimen; A 1, 2 antenna 1, 2; Mx 1 maxilla 1; Mxp maxilliped; Gn 1 gnathopod 1 without propodus and dactylus; Gn 1’ dactylus, propodus and carpus enlarged; Gn 2 gnathopod 2; Gn 2’ dactylus and propodus enlarged; Gn 2’’ gnathopod 2 tip of carpus enlarged.
Stenulapeltata (Smith, 1872): illustration of the single type specimen; P 3, 4 5, 7 peraeopod 3, 4, 5, 7; Ep 3 third epimeral plate; U 1, 2, 3 uropod 1, 2, 3; T telson.
male 3 mm in alcohol; USNM 1241824; M/v“John N.Cobb“, cruise 43, sta. 45, Project Chariot Cruise, Vessel John N Cobb R/V; Chukchi Sea: 67°31‘N, 167°12‘W coll. Spark. 27 fm = 49 m depth, 19/8/1959. Gear dredge. From coelenteron of Haliactisarctica T. Bowman Acc.No.234238.
Additional material.
male, female on 2 slides, both 3 mm.
Type locality.
Chukchi Sea, Arctic. From coelenteron of Haliactisarctica.
Etymology.
the epitheton should remind on the shape of the propodus Gn 2, which looks somewhat like a small fist, in Latin „pugilla“; it is used as noun in apposition.
Description.
Length 3 mm.
Head. Eyes round, normal. Mouthparts: Md with very short palp, length about half of width of incisor. Mx 1 palp with one art, Mx 2 plates in tandem – position. Antennae: subequal, A 1 and A 2 flagellum about 10–12 arts. Mxp length of inner plate about half length of ischium, outer plate about 1/3–1/2 of merus.
Peraeon. Gn 1 basis on anterior margin setose, merus with short stiff setae, carpus with long setae and pectinate spines, propodus hind margin setose, somewhat rounded to nearly straight.
Cx 2 tongue-shaped. Gn 2 male and female basis on both margins beset with setae; merus rectangular, naked, carpus triangular, with stiff setae posterodistally, propodus medially widest with setose palm, defined by thumb-shaped protrusion.
Peraeopods: Cx 3 narrow, distally rounded, posteriorly with some setae; Cx 4 distally about 3× wider than Cx 3. P 3 dactylus clearly longer than in other peraeopods; P 3–7 merus somewhat widened and not much lengthened; P 6, 7 basis widened, with parallel margins.
Pleon. U 1 peduncle spinose, > slightly unequal rami; U 2 rami subequal; U 3 peduncle = ramus art 1 = ramus art 2.
Telson naked, triangular.
Female: subsimilar to male.
Remarks.
The note ‚from the coelenteron of Haliactis‘ on the label of this sample may as well just have meant that the sea anemones had contracted on collection.
Discussion.
Within the above discussed criteria of dividing Stenula species into groups, the new species belongs to the majority having Gn 1 propodus subequal to carpus (together with S.solsbergi, see below, here transferred to Stenula) and to the few members having a very short stump of mandible palp. The shape of Gn 2 palm male and female defined by a thumb-like hump is unique and quite helpful in identifying this species.
Stenulapugilla sp. n. male 3 mm: Gn 2 gnathopod 2; P 6, 7 peraeopod 6, 7; U 1–3 uropod 1–3; T telson.
https://binary.pensoft.net/fig/58993AnimaliaAmphipodaStenothoidaeF999B437-F88A-578C-BEE0-FA51895A562AStenulasolsbergi(Schneider, 1884)Figures 19, 20Metopasolsbergi Schneider, 1884: 71; Sars 1892: 266, t. 94; Lincoln 1979: 186, fig. 84.Material examined.
one specimen, 3 mm, from the vicinity of Tromsø, N Norway (without date), collected together with Chlamys. The material was dredged in an area with much Metridium.
Vader 1983 reported already Metopasolsbergi from the North Atlantic: Elmhirst 1925 found this species present on Metridiumsenile L. on pier piling in western Scotland, Fenwick and Steele 1983 off the coast of Newfoundland, Canada, again on Metridium.
This seems to be the very first time that the mouthparts were checked, and a reduced, uniarticulate mandibular palp could be illustrated, moving also this species to Stenula.
At the end of our study, we now know 16 members of the genus Stenula, as S.invalida, S.solsbergi and S.pugilla sp. n. are added, S.arctica given in synonymy with S.nordmanni, S.latipes revived and S.rubrovittata put back into Metopa:
S.alexanderi Tzvetkova & Golikov, 1990; Siberia
S.angusta (Shoemaker, 1955); Alaska, N Pacific
S.bassarginensis (Gurjanova, 1948); Arctic
S.beringiensis (Gurjanova, 1948); Bering Sea, N Pacific
S.derjugini (Gurjanova, 1948); Bering Sea, N Pacific
S.ratmanovi (Gurjanova, 1948) (could be junior synonym of S.peltata)
S.serripes (Gurjanova, 1955); Kurile Isl., NE Pacific
S.solsbergi (Schneider, 1884); N. Norway, N. Atlantic
S.ussuriensis (Gurjanova, 1948); Japan Sea, NE Pacific
Key to world Stenula s. l.
The amphipod genus Stenula is probably not a monophyletic entity (cf. Tandberg and Vader 2011, this paper), and it is at present not possible to decide which taxa belong to it. In this key we have therefore cast our nets widely, and we include all species in the Metopa-Stenula complex with a uniarticulate mandible palp. This palp is very short in what we might call ‚typical Stenula‘, a bit longer, but still shorter than the incisor of the mandible, in a number of other species, also traditionally placed in Stenula, and still a bit longer, but clearly uniarticulate, in a few Metopa species: M.hearni, M.palmata and M.sinuata. Just’s (1980) „Stenula sp.“ is in our opinion identical with M.sinuata, as that author himself already suspected.
The task has been made more difficult by several factors: many species have only been partly illustrated, and at least for the species S.angusta, S.invalida, S.modosa and ?S.peltata, as well as possibly some of Gurjanova‘s species, males are still unknown.
We treat here the 16 Stenula species mentioned above, plus three species which are closely related, but until now still left unchanged in Metopa:
1
Coxa 4 distal margin clearly sinuous; N. Norway, 4 mm
M.sinuata Sars, 1892
–
Coxa 4 distal margin regularly convex or almost straight
2
2
Gn 1 propodus and carpus very long and slender, dactylus broad and heavily setose; Gn 2 rectipalmate
3
–
Gnathopods not as above
4
3
Gn 1 propodus < carpus, palm concave, dactylus length to width > 2; N. Norway, 5 mm
M.palmata Sars, 1892 (see note 1)
–
Gn 1 propodus > carpus, palm convex, dactylus length to width = 3:2; Laptev Sea, 3.8 mm
S.alexanderi Tzvetkova & Golikov, 1990 (see note 2)
4
P 6 –7 basis and merus posteriorly serrated, hind margin of basis proximally with acute tooth; Kurile Islands, NE Pacific, 7 mm
S.serripes (Gurjanova, 1955)
–
P 6 –7 basis not serrated nor with tooth
5
5
Gn 2 propodus in male with deep U-shaped excavation
6
–
Gn 2 propodus in male not with deep U-shaped excavation
7
6
Gn 2 propodus palm in male semicircularly excavated near distal corner, rest of palm much longer than width of excavation; Japan Sea, 4 mm
S.ussuriensis (Gurjanova, 1948)
–
Gn 2 propodus palm in male deeply and irregularly excavated, rest of palm shorter than width of excavation. Japan Sea, 5 mm
S.bassarginensis (Gurjanova, 1948)
7
Gn 2 propodus male palm clearly irregular, defined by strong tooth
8
–
Gn 2 propodus in male smooth or slightly crenulate, convex or straight
9
8
Telson with 3 pairs of spines; Kamchatka, NE. Pacific, 3.5 mm
S.beringiensis (Gurjanova, 1948)
–
Telson naked or with small setules; California, 2 mm.
S.incola Barnard, 1969
9
Gn 2 propodus palmar corner prominent, shaped like a finger-tip; Chukchi Sea, 3 mm
S.pugilla Krapp-Schickel & Vader, 2015
–
Gn 2 propodus palmar corner blunt or with acute tooth
10
10
Gn 1 carpus unusually long, up to 3 × longer than wide; eyes very large
11
–
Gn 1 carpus clearly not as long; eyes normal
12
11
Gn 1 dactylus not reaching half length of propodus; A1 clearly shorter than A2; P 6–7 basis with rounded hind margin; W. Greenland, 5 mm
S.nordmanni (Stephensen, 1931) (= S.arctica (Gurjanova, 1951) (see note 3)
–
Gn 1 dactylus reaching half length of propodus. A1 and 2 subequal; P 6–7 basis with straight hind margin; California, 2 mm.
S.modosa Barnard, 1962
12
Telson with 2 pairs of spines; Bering Sea, 4 mm.
S.derjugini (Gurjanova, 1948)
–
Telson naked
13
13
Gn 1 carpus clearly shorter than propodus
14
–
Gn 1 carpus subequal to propodus
15
14
P 7 very broad, posterior margin convex; mandiblepalp long, but unarticulated; Canada, 3–4 mm
M.hearni (Dunbar, 1954)
–
P 7 basis slender, posterior margin rather straight; mandible-palp shor, Point Barrow, Alaska, 3 mm.
S.angusta (Shoemaker, 1955)
15
P 6–7 posterior tip on merus reaches halfway of less along carpus
16
–
P 6–7 posterior lobe on merus reaches clearly further than halfways along carpus
17
16
Gn 2 propodus length:width = 3. P 7 basis broad, length = 2 width.; N. Norway, 4 mm
S.invalida (Sars, 1892)
–
Gn 2 propodus l:w = 2; P7 basis less wide, l< 2w, N. Norway, 7 mm
S.solsbergi (Sp. Schneider, 1884)
17
We have been unable to find reliable differences between Stenulalatipes (Chevreux & Fage, 1925), a species associated with hermit crabs in W. Europe, and S.ratmanovi (Gurjanova, 1948), an only partly described species from Kamchatka in the northern Pacific. Moreover, the illustrations of this latter species and those of Stenothoepeltata (Smith, 1874) from Georges Banks, NW Atlantic, are, as far as they go, practically identical.
Notes
This is the type species of Norman’s (1902) short-lived genus Sthenometopa.
Probably not a Stenula, to be transferred to Metopa or Sthenometopa.
In transferring Metopanordmanni to Stenula, Just (1980) apparently overlooked the fact that this species is clearly identical to Stenulaarctica (Gurjanova, 1951).
A short survey of associations between stenothoids and larger marine invertebrates (Table 1).
Table 1 lists the associations between stenothoid amphipods and other marine invertebrates known to us, with the exception of those reported from sponges, hydroids or bryozoans. These latter are excluded because in most cases it is unclear what the exact niche of the amphipods is: usually the labels say only ‚among hydroids and bryozoans‘ or ‚found together with sponges‘. Among the others the associates of various large coelenterates and also those found in ascidians generally do not seem to be obligate symbionts. Although now and then found in large numbers (e.g. Metopabruzelii and Proboloidescalcarata on gorgonians), the same species are also regularly found apparently free-living.
Associations of Stenothoidae with larger marine invertebrates.
The situation is different for the associates of mollusks (all Metopa species) and those on sea anemones (mostly Stenothoe and Stenula species). Practically all these species appear to be obligate associates of only a single or in some cases a few hosts, and they have never been found free-living (for a possible exception see Blain and Gagnon 2014, who claim to have found numbers of Stenothoebrevicornis on the alga Desmarestiaviridis). The amphipod associates of sea anemones always live on the column of the host or among the tentacles (Elmhirst 1925, Krapp-Schickel and Vader 2009, Krapp-Schickel et al. 2015; Vader 1983, Vader and Krapp-Schickel 1996), with the possible exception of Stenulapugilla, found according to the label ‚in the coelenteron of Haliactisarctica‘ (this paper). At least Stenothoebrevicornis, somewhat surprisingly, feeds to a large extent on host tissue (Moore et al. 1994), contrary to earlier assumptions (Vader 1983). Large numbers of amphipods are usually found on a single host, and ovigerous females are commonly present. Interestingly, sexual dimorphism is in most cases much less developed in the associates of sea anemones than in related free living stenothoids (see also Vader 1983).
In contradistinction to the case with sea anemones, all the stenothoid associates of bivalve mollusks are Metopa species. Once more the associations seem to be obligate ones, the amphipods are rarely found free-living (and never leave their hosts in laboratory observations) and they are confined to a single host or, in the case of Metopaglacialis, to a series of closely related host species. A partial exception is Metopaalderi, usually an associate of large hydroids and hydromedusae, that recently was found in Musculus spp in N. Spitsbergen (Tandberg et al. 2010b). The data on mollusk-associated stenothoids have recently been reviewed by Tandberg et al. (2010a): the amphipods live inside the host and feed on that part of the ingested material that the host does not consume itself. In addition, the stenothoid symbionts of bivalves seem to exhibit territoriality as well as extended parental care: invariably only a single pair of adults is present within a single host, often together with several cohorts of juveniles.
In the case of the single, quite aberrant Stenothoe species that lives on a spider crab, S.symbiotica Shoemaker, 1956, its biology is as yet completely unknown, but also this association appears to be an obligate and probably species-specific one; the species has never been collected elsewhere and it has clearly prehensile peraeopods. Also the amphipod associates of hermit crabs and their tenanted mollusk shells are of unknown biology. Metopelloidespaguri Marin & Sinelnikov, 2012 and M.micropalpa (Shoemaker, 1930) have slightly but clearly prehensile posterior peraeopods, and may therefore well be direct associates of their host hermit crabs (Vader 1983b). But the somewhat mysterious pair of Metoparubrovittata Sars and Stenulalatipes (Chevreux & Fage) do not have prehensile peraeopods (even though the posterior legs carry maybe more spines than is usual in Metopa species?) and many authors have associated these species primarily with the Hydractinia-cover of the tenanted gastropod shells rather than with the hermit crabs themselves, although without any proof. These two species occupy the same niche, and slightly different, but possibly overlapping distributions, and have the exactly identical, quite special coloration pattern, but according to present classifications they have to be placed in different genera. Also the species associated with hermit crabs seem to be largely obligate symbionts, although possibly occurring on a larger range of hosts.
Acknowledgements
We are grateful to Dr. Chad Walter of the Smithsonian Institution, Washington DC, who after thirty years refound the unidentified sample that contained Stenulapugilla, and lent it to us. We thank prof. R.T. Barrett, Tromsø for linguistic assistance, as well as Dr. Oliver Coleman, Naturkunde Museum Berlin, for constructive criticism.
ReferencesAusterPJHeinonenKBWatlingLParrish-KuhnCHeupelELindholmJ (2011) A rare deepwater anemone and its associates in the Stellwagen Bank National Marine Sanctuary (Gulf of Maine, north-west Atlantic).4: 19. doi: 10.1017/s1755267211000200BarnardJL (1962) Benthic marine Amphipoda of southern California: 3) Families Amphilochidae, Leucothoidae, Stenothoidae, Argissidae, Hyalidae.3(1/2/3): 1–163. BarnardJL (1966) Benthic Amphipoda of Monterey Bay, California.119(3541): 1–41. doi: 10.5479/si.00963801.119-3541.1BarnardJL (1969) Gammaridean Amphipoda of the Rocky Intertidal of California: Monterey Bay to La Jolla.258: 1–230. BarnardJL (1972) Gammaridean Amphipoda of Australia, Part I.103: 1–333. BarnardJL (1974) Gammaridean Amphipoda of Australia, Part 2.139: 1–148. BarnardKH (1916) Contributions to the Crustacean Fauna of South Africa. 5. The Amphipoda.15: 105–302. doi: 10.5962/bhl.title.10646BarnardKH (1932) Amphipoda.5: 1–326. BateCS (1857) A synopsis of the British edriophthalmous Crustacea. (ser 2) 19: 135–152. Bellan-SantiniDCostelloMJ (comps.) (2001) Amphipoda. In: CostelloMJEmblowCSWhiteR (Eds) European Register of Marine Species. A check-list of the marine species in Europe and a bibliography of guides to their identification.50: 295–308. BesnerA (1976) . PhD Thesis, Univ. of Montreal, Montreal, 119 pp. BlainCGagnonP (2014) Canopy-forming seaweeds in urchin-dominated systems in eastern Canada: Structuring forces or simple prey for grazers?9(5): e98204. doi: 10.1371/journal.pone.0098204BlakeCH (1929) Crustacea. New Crustacea from the Mount Desert region.3: 8–34. BoeckA (1871) CrustaceaAmphipoda Borealia et Arctica.1870: 83–280. BrüggenE von der (1907) Amphipoda. Zoologische Ergebnisse der russischen Expeditionen nach Spitzbergen.11: 214–244. BrunelPBosseLLamarcheG (1998) Catalogue of the marine invertebrates of the estuary and Gulf of St. Lawrence., 126–405. Buhl-MortensenLMortensenPB (2004) Crustaceans associated with the deep-water gorgonian corals Paragorgiaarborea (L., 1758) and Primnoaresedaeformis (Gunnerus, 1763).38: 1233–1247. doi: 10.1080/0022293031000155205Buhl-MortensenLMortensenPB (2005) Distribution and diversity of species associated with deep-sea gorgonian corals off Atlantic Canada. In: FreiwaldARobertsJM (Eds) . Springer Verlag, Berlin-Heidelberg, 849–879. doi: 10.1007/3-540-27673-4_44ChevreuxE (1908) Sur les commensaux de Bernard l’Hermite.14: 183–189. ChevreuxEFageL (1925) Amphipodes.9: 1–488. ChiltonC (1883) XIV – Addition to the Sessile-eyed Crustacea of New Zealand.15: 249–255. ChiltonC (1884) Notes on a few Australian Edriophthalmata.9(4): 1–10. DahlE (1946) Notes on some amphipods from the Gullmar Fiord.38A(8): 1–8. DanaJD (1852) Conspectus crustaceorum quae in orbis terrarum circumnavigatione, Carolo Wilkes e classe Rei publicae Faederatae Duce, lexit et descripsit Jacobis D. Dana. Pars III [Amphipoda Nr 1].2: 201–220. De BroyerCChapelleGDuchesnePAMunnRNyssenFScailteurYVan RoozendaelFDaubyP (2003) Structural and ecofunctional biodiversity of the amphipod crustacean benthic taxocoenoses in the Southern Ocean.1: 1–51. Della ValleA (1893) Gammarini., 948 pp. DunbarMJ (1954) The amphipod Crustacea of Ungava Bay, Canadian eastern Arctic.11: 709–798. doi: 10.1139/f54-044ElmhirstR (1925) I. Associations between the amphipod genus Metopa and coelenterates. Part I.155: 149–150. EvansWAshworthJW (1909) Some medusae and ctenophores from the Firth of Forth.17: 300–311. FenwickGDSteeleDH (1983) Amphipods of Placentia Bay, Newfoundland.7: 1–22. GiardA (1908) Un amphipode mimétique des hydraires: Metopa rubrovittata G. O. Sars. 31: 214. GoësA (1866) CrustaceaAmphipoda Maris Spetsbergiam alluentis, cum speciebus aliis arcticis enumerat.1865: 517–536. GosnerKL (1971) . John Wiley & Sons, 693 pp. GurjanovaE (1933) Zur Amphipodenfauna des Karischen Meeres.103: 119–128. GurjanovaE (1938) (Amphipoda, Gammaroidea of Siaukhu Bay and Sudzukhe Bay (Japan Sea))., 1: 241–404. [In Russian]GurjanovaE (1948) Amphipoda Tixogo Okeana II., 287–325. GurjanovaE (1951) Akademii Nauk, Bokoplavy morej SSSR, Moscow, 1031 pp. GurjanovaE (1952) Novye vidy bokoplavov (Amphipoda, Gammaridea) iz dal’nevostochnyx morei. Akademii Nauk SSSR.12: 171–195. GurjanovaE (1955) Novye vidy bokoplavov (AmphipodaGammaridea) iz severnoi chasti Tixogo (=Tikhogo) Okeana. Zoological Institute Ak.18: 166–218. HamondR (1967) The Amphipoda of Norfolk.8: 113–152. HansenHJ (1888) Malacostraca marina Groenlandiae occidentalis. Oversigt over det vestlige Grønlands fauna af Malakostrake Havkrepsdyr.1887: 5–226. HanssonHG (1971) Några fynd av atlantiska faunaelement i Bohuslän efter höststormarna i 969.66: 118–120. HaswellWA (1879) On some additional new genera and species of amphipodous crustaceans.4/5: 319–350. HoekPPC (1889) Crustacea Neerlandica.ser. 2, 2: 170–234. JustJ (1980) Amphipoda (Crustacea) of the Thule area, northwest Greenland: faunistics and taxonomy.2: 1–61. JustJ (1983) Anonyxaffinis (Crus., Amphipoda; Lysianassidae), commensal in the bivalve Musculuslaevigatus, with notes on Metopaglacialis (Amphipoda: Stenothoidae).12: 69–74. JustJ (2013) Metopagigas, sp. n. from southern Greenland, a giant among congeners (Crustacea, Amphipoda. Stenothoidae).3641(3): 289–295. doi: 10.11646/zootaxa.3641.3.8Krapp-SchickelG (1976) Die Gattung Stenothoe (Crustacea; Amphipoda) im Mittelmeer.46: 1–34. Krapp-SchickelT (2009) New and poorly described stenothoids (Crustacea, Amphipoda) from the Pacific Ocean.66: 95–116. Krapp-SchickelT (2009) Stenothoidae. In: LowryJKMyersAA (Eds) Benthic Amphipoda (Crustacea: Peracarida) of the Great Barrier Reef, Australia.2260: 872–879. Krapp-SchickelT (2011) New antarctic stenothoids sensu lato (Amphipoda, Crustacea).1: 1–17. doi: 10.5852/ejt.2011.2Krapp-SchickelT (2013) On the Austral-Antarctic stenothoids Proboloides, Metopoides, Torometopa and Scaphodactylus (Crustacea: Amphipoda). Part 2: group of Proboloides, Scaphodactylus, Torometopa with two new genera (Stenothoidae, Amphipoda).86: 11–45. Krapp-SchickelT (2015) Minute but constant morphological differences within members of Stenothoidae: The Stenothoegallensis – group with four new members, keys to Stenothoe world-wide, a new species of Parametopa and Sudanea n. gen. (Crustacea, Amphipoda).. doi: 10.1080/00222933.2015.1021873Krapp-SchickelTHäussermannVVaderW (2015) A new Stenothoe species (Crustacea: Amphipoda: Stenothoidae) living on Boloceropsisplatei (Anthozoa: Actiniaria) from Chilean Patagonia.69: 213–220. Krapp-SchickelTVaderW (2009) A new Parametopella species (Crustacea: Amphipoda: Stenothoidae) from Antholobaachates (Anthozoa: Actiniaria) from Coquimbo, Chile (with remarks on Parametopaalaskensis (Holmes)).89: 1281–1287. doi: 10.1017/S0025315409000484KrøyerH (1842) Nye nordiske Slaegter og Arter af Amfipodernes Orden, henhørende til Familien Gammarina. (Foreløbigt Uddrag af et større Arbejde).4: 141–166. LesueurCA (1817) Observations on several species of the genus „Actinia“; illustrated by figures.1: 149–154, 169–189. LewisJB (1992) Abundance, distribution and behavior of a commensal amphipod Stenothoevalida Dana on the hydrocoral Milleporacomplanata Lamarck.51: 245–249. LiljeborgV (1851) Bidrag till Norra Rysslands och Norriges fauna, samlade under en vetenskaplig Resa i dessa Lander 1848, (series 3) 2: 233–341. LincolnRJ (1979) British Museum, London, 658 pp. LowryJKStoddartH (2003) 19.2B. Environment Australia, 373 pp. MarinISinelnikovS (2012) Metopelloidespaguri sp. nov., a new species of symbiotic stenothoid amphipod (Crustacea: Amphipoda: Stenothoidae) associated with sublittoral hermit crabs from the Russian coasts of the Sea of Japan.3244: 59–67. McGinitieGE (1955) Distribution and ecology of the marine invertebrates of Point Barrow, Alaska.139–9: 1–201. McGrathD (1978) Stenulalatipes (Chevreux et Fage) (Crustacea: Amphipoda) associated with the hermit crab Pagurusbernhardus (L.), new to the British fauna.19: 196–197. MoorePG (1984) The fauna of the Clyde Sea area. Crustacea: Amphipoda.2: 1–84. MoorePGRainbowPSVaderW (1994) On the feeding and comparative biology of iron in coelenterate-associated gammaridean Amphipoda (Crustacea) from N.Norway.178: 205–231. doi: 10.1016/0022-0981(94)90037-XNebeskiO (1881) Beitraege zur Kenntniss der Amphipoden der Adria.3(2): 1–52. OckelmannKW (1983) Descriptions of mytilid species and definition of the Dacrydiinae n. subfam. (Mytilacea-Bivalvia).22: 81–123. doi: 10.1080/00785326.1983.10427225OldevigH (1959) Arctic, subarctic and Scandinavian Amphipods in the collections of the Swedish Natural History Museum Stockholm. (6B) 8(2): 5–132. PearseAS (1947) On the occurrence of ectoconsortes on marine animals at Beaufort, N. C.33: 453–458. doi: 10.2307/3273324PirlotJM (1933a) 33c: 115–167. PirlotJM (1933b) Un nouvel amphipode ascidicole.633: 1–6. ReibischJ (1905) Faunistisch-biologische Untersuchungen über Amphipoden der Nordsee. Wissenschaftliche Meeresuntersuchungen, herausgegeben von der Kommission zur Untersuchung der deutschen Meere in Kiel und der Biologischen Anstalt auf Helgoland.8: 147–236. SarsGO (1879) Crustacea et Pycnogonida nova in itinere 2do et 3tio expeditionis Norvegicae anno 1877 & 78 collecta. (Prodromus descriptionis).4: 427–476. SarsGO (1883) Oversigt af Norges Crustaceer med forelobige Bemaerkninger over de nye eller mindre bekjendte Arter. I.18: 124. SarsGO (1890–1895) . 1, 2 vols. Alb. Cammermeyers Forlag, Christiania and Copenhagen, 1, 711 pp. SchellenbergA (1942) Flohkrebse oder Amphipoda. Krebstiere oder Crustacea. In: . F. Dahl. Jena, Gustav Fischer4: 252. SchneiderJS (1884) Undersøgelser af dyrelivet i de arktiske fjorde. II. Crustacea og Pycnogonida indsamlede i Kvaenangsfjorden 1881.7: 47–134. SheardK (1937) A catalogue of Australian Gammaridea.61: 17–29. ShoemakerCR (1955) Amphipoda collected at the Arctic Laboratory, Office of Naval Research, Point Barrow, Alaska, by G.E. MacGinitie.128(1): 1–78ShoemakerCR (1956) A new genus and two new species of amphipods from Dry Tortugas, Florida.46: 61–64. SmithSI (1874) Notes on some of the species enumerated. In: SmithSIHargerO (Eds) Report on the Dredging in the Region of St. George’s Banks, in 1872.3: 1–57. StebbingTRR (1906) Amphipoda, I. Gammaridea.21: 1–806. [Abb. 1–127] StebbingTRR (1910) V. Amphipoda. Scientific results of the trawling expedition of H.M.C.S. „Thetis“.4(2): 565–658. StebbingTRR (1920) Crustacea from the Falkland Islands collected by Mr Rupert Vallentin, F. L. S. Part III. (1919): 327–340. StephensenK (1929) Marine CrustaceaAmphipoda.23: 1–40. StephensenK (1931) , 179–290. StephensenK (1938) Amphipoda, Tanaidacea and Pycnogonida.20(3/4): 236–264. StephensenKThorsonG (1936) On the amphipod Metopagroenlandica H. J. Hansen found in the mantle cavity of the lamellibranchiate Pandoraglacialis Leach in East Greenland.118–4: 1–7. TandbergAHS (2011) . A dissertation for the degree of Philosophiae Doctor, University of Tromsø, 48 + 36 + 25+ 94 + 2 + 11 + 36 pp. TandbergAHSSchanderCPleijelF (2010) First record of the association between the amphipod Metopaalderi and the bivalve Musculus. 3, e 5, 2 pp. doi: 10.1007/s00300-010-0833-9TandbergAHSVaderW (2009) A redescripiton of Metopa species (Amphipoda, Stenothoidae) based on the type material. 1. Zoological Museum, Copenhagen (ZMUC).2093: 1–36. TandbergAHSVaderWBergeJ (2010) Studies on the association of Metopaglacialis (Amphipoda, Crustacea) and Musculusdiscors (Mollusca, Mytilidae).33: 1407–1418. ThomasJDCairnsKD (1984) Discovery of a majid host for the commensal amphipod Stenothoesymbiotica Shoemaker, 1956.34: 484–485. ThomsonGMChiltonC (1886) Critical list of the CrustaceaMalacostraca of NZ.18: 141–159. ToulmondATruchotJP (1964) Inventaire de la faune marine de Roscoff. Amphipodes-Cumacés., Supplément, 1–42. TzvetkovaNLGolikovAA (1990) (Fauna, ecology and role in ecosystems of amphipods (Amphipoda, Gammaridea) at the New Siberian shoals and adjacent waters of the Laptev Sea.)37(45): 258–343. [In Russian]VaderW (1972) Associations between gammarid and caprellid amphipods and medusae.50: 51–56. VaderW (1983a) Associations between amphipods (Crustacea: Amphipoda) and sea anemones (Anthozoa, Actiniaria).18: 141–153. doi: 10.3853/j.0067-1967.18.1984.380VaderW (1983b) Prehensile pereopods in gammaridean Amphipoda.68: 139–148. VaderW (1984) Notes on Norwegian marine amphipods 8. Amphipods found in association with sponges and tunicates. Fauna Norvegica, Ser.5: 16–21. VaderWBeehlerCL (1983) Metopaglacialis (Krøyer) (Stenothoidae) in the Barents and Beaufort Seas, and its association with the lamellibranchs Musculusniger (Gray) and M.discors (Linnaeus) s. l.12(1979): 57–61. VaderWKrapp-SchickelG (1996) Redescription and biology of Stenothoebrevicornis Sars (Amphipoda: Crustacea), an obligate associate of the sea anemone Actinostolacallosa (Verrill).30: 51–66. doi: 10.1080/00222939600770041VaderWTandbergAHS (2013) A survey of amphipods associated with molluscs.86: 1038–1049. doi: 10.1163/15685403-00003210VaderWTandbergAHS (2015) Amphipods as associates of other Crustacea, a survey.. doi: 10.1163/1937240X-00002343WatlingL (1976) Parametopellainquilinus, new species from Delaware Bay oyster beds (Amphipoda: Stenothoidae).88: 429–432.