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Review

Amphiboreality and Distribution of Snailfishes (Cottiformes: Liparidae) in the Arctic and the North Atlantic

by
Natalia V. Chernova
Zoological Institute of the Russian Academy of Sciences, Universitetskaya Emb. 1, 199034 Saint Petersburg, Russia
Diversity 2022, 14(12), 1097; https://doi.org/10.3390/d14121097
Submission received: 15 September 2022 / Revised: 5 December 2022 / Accepted: 6 December 2022 / Published: 11 December 2022
(This article belongs to the Special Issue Systematics, Phylogeny and Biogeography of Fish in Arctic and Antarctic)
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Abstract

:
The marine ichthyofauna of the Arctic Ocean has an ancestral origin from the Pacific Ocean and, to a lesser extent, from the Atlantic Ocean, which is explained by the amphiboreal concept, developed on groups of fish and invertebrates. Snailfishes (Liparidae) of the Arctic and the North Atlantic are analyzed in the context of this amphiboreal concept. The review is based on the data of many years of research on their taxonomy using various material of morphological differences/similarities of the taxa and patterns of species distribution against the background of biogeographic representations. For the Arctic area, 33 species of the family are known: Liparis (5), Careproctus (21), Paraliparis (2), Rhodichthys (2), and Psednos (3). For the Atlantic fauna, with the same number of species, their composition differs: Liparis (6), Careproctus (3), Paraliparis (12), Psednos (11), and Eutelichthys (1). The amphiboreal concept explains the speciation of Liparis and the majority of Careproctus as the result of trans-Arctic preglacial migrations. For other (deep-sea) species, the hypothesis of a transoceanic dispersal route is applicable; it passed from the North Pacific through the Southern Ocean and then north across the Atlantic.

1. Introduction

The marine fish fauna of the Arctic Ocean cannot be considered in isolation from the neighboring regions; most of the families of fishes and other animals inhabiting it are associated by their root origin to the northern parts of the adjacent Pacific or Atlantic Oceans [1,2,3,4,5,6,7,8,9]. Fish families of Pacific origin are Osmeridae, Stichaeidae, Lumpenidae, Pholidae, Zoarcidae, Cottidae, Psychrolutidae, Agonidae, Cyclopteridae, Liparidae, and Sebastidae [3,4,5]. Each of these families, richly represented in the Pacific Ocean, has a few cold-water Arctic species; they also contain some Atlantic boreal taxa, and the latter have an undoubted morphological and genetic similarity with their Pacific relatives. Families and groups of Atlantic origin are less numerous: Gadidae, Gasterosteidae, Scophthalminae (genera Scophthalmus, Lepidorhombus, Phrynorhombus, and Zeugopterus), Anarchichadidae, Petromyzonidae, and subfamily Ammodytinae (Ammodytes, Gymnammodytes, and Hyperoplus) [5]. As in previous cases, they include several Arctic representatives and some Pacific boreal species similar or identical to their Atlantic congeners. Thus, species of these families are subdivided into similar groups according to their range types and taxonomic rank [3,10].
First, the Pacific families have boreal–Arctic species that extend northward beyond the Bering Strait, where they are continuously distributed west- and eastward, and their Arctic populations are indistinguishable from the Pacific ones. The boundaries of their distribution in the Arctic are different, but some of them reach the Barents Sea in a western direction (Icelus spatula, Triglops pingelii in Cottidae, and Lumpenus medius in Stichaeidae) or Greenland in an eastern direction (Myoxocephalus scorpioides in Cottidae and Eumesogrammus praecisus in Stichaeidae). Another group consists of endemic cold-water Arctic species that are absent in the Pacific Ocean or only enter the northern coldest part of the Bering Sea, but do not enter boreal (temperate) waters further south (Myoxocephalus quadricornis, Artediellus scaber, Gymnacanthus tricuspis in Cottidae, and Lycodes polaris in Zoarcidae). The third group includes several amphiboreal taxa of Pacific origin, which in the boreal Atlantic taxonomically distinguished to the rank of species or even genera. Amphiboreal (from the Greek amphi—around, on both sides) taxa are represented in the boreal regions of the Atlantic and Pacific Oceans. In total, there are up to several dozen amphiboreal groups of fishes and invertebrates [3,6,10]. Their rank is different.
Among fishes, amphiboreal ranges (interrupted in the Arctic) are demonstrated by species: Arctic lamprey Lethenteron camchaticum (Petromyzontidae); capelin Mallotus villosus (Osmeridae); three-spined stickleback Gasterosteus aculeatus (Gasterosteidae); sanlance Ammodytes hexapterus (Ammodytidae); and Greenland halibut Reinhardtius hippoglossoides (Pleuronectidae). There are pairs of closely related species: oceanic herrings (Clupea harengus in the Atlantic and C. pallasii in the Pacific); cods (Gadus morhua and G. microcephalus); smelts (Osmerus eperlanus and O. dentex); halibuts (Hippoglossus hippoglossus and H. stenolepis); and wolf fishes (Anarhichas lupus and A. orientalis, Anarhichadidae). An amphiboreal distribution is found among representatives of the poachers Agonidae, sculpins Cottidae, and eelpouts Zoarcidae. Some Pacific families are represented in the Atlantic Ocean by separate genera (Taurulus in Cottidae, Agonus in Agonidae, Cyclopterus in Cyclopteridae, and Ulvaria and subgenus Chirolophis in Stichaeidae).
The reasons for the existence of such types of taxa and their ranges are explained by the amphiboreal concept developed for groups of fishes and invertebrates [2,3,4,6,10,11,12,13,14]. A brief overview of this hypothesis is as follows: The formation of amphiboreal taxa is associated with migrations of the North Pacific fauna through the Arctic shelf during preglacial boreal transgressions and the rupture of their ranges during the Ice Age (and the same, although on a smaller scale, is applicable to the Atlantic fauna).
Usually, two periods of different time migrations through the Bering Strait region are accepted, Pliocene (preglacial) and postglacial [2,5,6,10,11,13,15,16,17,18,19,20,21,22,23]. The results of Pliocene migrations through the Bering Strait, which was open at the end of the Miocene ca. 5.32 Ma [24], were well-specified amphiboreal species or even genera. The dispersal proceeded along the coasts of Siberia or through the American Arctic. The desalination-resistant species (Petromyzontidae, Osmeridae, and Pleuronectidae) probably migrated mainly along the Asian coast influenced by the flow of the great rivers. Thus, different migration routes can explain the derivation of different amphiboreal groups of species on both sides of the North Atlantic.
The Pacific–Atlantic transition of fauna prevailed, and only separate groups (Clupeidae and Gadidae) migrated in the opposite direction, from the Atlantic to the Pacific. The advantage of the Pacific–Atlantic direction is explained by the greater diversity of the more ancient Pacific fauna compared to the Atlantic, because statistically, the richer the fauna is in species, the more of them can settle through the opened strait. Another reason may lie in the prevailing direction of the currents.
During the Ice Age, the ice sheets occupied the Eurasian shelf at least four times: in the Late Saalian (>140 ka), the Early Weichselian (100–80 ka), the Middle Weichselian (60–50 ka), and the Late Weichselian (25–15 ka) periods [25]. The largest glaciers covered a huge area from the modern British Isles to Severnaya Zemlya [26]. The Bering Land Bridge existed, closing the passage from the Pacific Ocean to the Arctic [27]. The boreal fauna, which earlier occupied a vast range from the North Atlantic to the eastern Arctic, became extinct in the glaciated areas. A few elements could have been preserved in free of ice refugia; some others may have escaped from the glaciers to the bathyal depth. Cold-water fauna began to form in the cool region of the glacier-free Siberian shelf and in periglacial freshwaters. In the Atlantic, the boreal fauna retreated southward; some species could reach the Mediterranean and even the Southern Hemisphere (sandlances Gymnammodytes). In isolated populations, further evolutionary processes may have led to the formation of new species, including bathyal ones. The interglacial migrations may have occurred more than once, which explains the varying degree of morphological and genetic differentiation among amphiboreal taxa or populations.
Postglacial migrations were associated with the postglacial climatic optimum and boreal transgression when the Bering Strait became open (since 11 cal ka BP) [13,27,28,29]. This resulted in a wide distribution of shelf Pacific species into the Arctic, but since then, they have not had time to noticeably separate from the Bering Sea populations. The climate in Central Siberia has become harsher [30,31], and even the most thermophilic fishes died out there [32], and discontinuous ranges of some species have formed.
As an example, the history of the speciation of the genus Icelus (Cottidae) was shown [3,33]. The genus includes at least 18 species, most of which are in the Pacific Ocean. In the Pliocene, a member of the genus migrated into the Arctic and dispersed across the waters of North America to the northwestern Atlantic, where the recent species I. bicornis was formed. With the end of the Ice Age, this fish spread further east, occupying ice-free waters and is currently distributed along the entire Asian shelf. During this time, several related species differentiated in the North Pacific (I. uncinalis and I. spatula). Of these, during the postglacial transgression, I. spatula spread through the Bering Strait into the Arctic; it is currently distributed westward to the Barents Sea and eastward to Greenland. Thus, the result of preglacial migration from the Pacific Ocean is the species I. bicornis with the Atlantic–Arctic range. The product of postglacial migrations is the boreal–Arctic range of the Pacific species I. spatula, which is continuously distributed in the Sea of Okhotsk, the Bering Sea, and the Arctic.
A similar dispersal history was shown for other sculpins of the Pacific genus Triglops [34]. As a result of the Pliocene migrations, the boreal Atlantic species T. murrayi was formed in the North Atlantic. During the Ice Age, T. nybelini was specified as being endemic to the Arctic. In the postglacial time, the Pacific species T. pingelii expanded its distribution and currently has a wide boreal–Arctic range.
Another example is given by the interrupted range of the family Stichaeidae [3]. This group is most diverse in the North Pacific, where the primitive Stichaeus and the most derived Stichaeopsis and Plagiogrammus exist. In the western North Atlantic, there is an endemic genus Ulvaria (U. subbifurcata), whose ancestors, apparently, could have spread to the Atlantic in the preglacial time. Two species with an amphiboreal distribution, Stichaeus punctatus and Eumesogrammus praecisus, appear to have spread during the posglacial migration of the Pacific fauna.
An interesting case is represented by the anadromous Arctic lamprey Lethenteron camtschaticum, whose range is widely interrupted in the Laptev and East Siberian Seas, but a related, nonmigratory freshwater form L. kessleri (or Lethenteron camtschaticum kessleri) continuously settled in river basins [3,9]. The presence of these relict freshwater populations indicates that in the warm postglacial period, the range of the anadromous lamprey could also be continuous from the Far East to the White Sea, but due to subsequent climate cooling, it disappeared along the Siberian coast.
Liparids (or snailfishes) constitute a significant part of the fauna of the North Pacific; in the Arctic and the North Atlantic, at least five genera are present, but the family has not been analyzed within the framework of amphiboreality. Only the genus Liparis was briefly noted in this context [7]. The main aim of this review is to consider whether the amphiboreal concept is applicable to explain the modern ranges and species content of northern Liparidae. The idea was to analyze the issue in a broad way, covering all species of each genus inhabiting northern waters. This requires presenting the species composition of snailfishes living in the Arctic and the North Atlantic. Then we consider each genus from these regions and whether they contain amphiboreal species or groups. This will allow us to discuss whether the probable ways of their distribution and speciation fit into the context of the amphiboreal concept.

2. Materials and Methods

The review is based on Liparidae materials from the Arctic and adjacent areas, studied over many years of practical research in taxonomy and related disciplines (Table 1). Specimens of all four genera involved in the consideration were studied: Liparis, Careproctus, Paraliparis, Rhodichthys, and Psednos [35,36,37,38,39,40,41,42,43]. Materials of liparid species related to the theme were also researched [44,45,46,47,48].
The subgenera and the species groups in the genus Liparis are given according to the review [39]. The composition of the genus Careproctus from the Arctic and North Atlantic is based on the published revisions [37,38], as well as on the original descriptions of eight species [36,38,40,41]. Careproctus of the North Pacific region was studied in connection with the problem of the systematic position of C. gelatinosus [37] and the redescription of the deep-sea C. hyaleius, the only snailfish known from the hydrothermal vents [49]. The original descriptions and reliable literary sources were used for morphologic data [50,51,52,53,54,55,56,57,58,59]. The Careproctus species of the Southern Ocean was analyzed when assisting Anatole Andriashev in preparing his monograph on Liparid fishes of the Southern Ocean [60]. In addition, when describing C. paxtoni [61], ten southern species were studied for comparison.
Methodology. To show the background, after a brief overview of the family Liparidae, the species composition for the Arctic and the North Atlantic is given. The genus Liparis was then analyzed for the presence of amphiboreal species or groups. The same was performed for Careproctus and other genera. Next, the probable ways of distribution and speciation of these taxa were discussed in the context of the amphiboreal concept.
The borders of the Arctic region are considered within the biogeographic boundaries substantiated earlier [62,63]. The area covers the Arctic shelves, the Central Arctic Basin, and the polar basins north of the Greenland–Iceland–Faroe Ridge, which delimits the neighboring (Polar and Atlantic) deep basins.
Morphological characteristics mentioned in the text. The head pore formula (e.g., 2−5−7−2) is consistent with Burke [53] and many subsequent studies of snailfishes; they are listed in order: nasal, infraorbital, preoperculo–mandibular, and suprabranchial.
The formula of the pectoral radials is given according to Andriashev [60]: Rad 4 (3 + 1) means a normal (Liparis-like) arrangement of four radials (three upper and one lower, separated by space); 4 (1 + 1 + 1 + 1) means that the radials are equidistant; 3 (2 + 0 + 1) means the absence of the third radial of the normal set; similarly for 3 (1 + 0 + 1 + 1), 2 (1 + 0 + 1) or 1 (0 + 0 + 1).
Designations: sg.—subgenus, SL—standard length, TL—total length; number of rays in D—dorsal, A—anal, P—pectoral, and C—caudal fins; vert.—number of vertebrae.

3. Results

3.1. Overview of the Family Liparidae

Snailfishes are a specialized branch of the Cottoidei [64]. In generalized species, their ventral fins are modified into a sucking disk (secondary reduced in some genera); the teeth system consists of three-lobed teeth, forming regular oblique rows; the skin has lost its scaly cover. It is a diverse family, with over 430 species from 32 genera worldwide [42,65], which are distributed in temperate and cold zones of both hemispheres and inhabit the deep water of five oceans. The vertical limits of their distribution are extremely wide because they are found in all bathymetric zones, from the littoral (Liparis and Polypera) to the abyssal plains (Paraliparis) and at the hadal depth of oceanic trenches up to 6–8 thousand meters (Pseudoliparis and Notoliparis) [53,66,67,68]. Most snailfishes inhabit temperate areas, but they are also present in the Arctic and Antarctic, adapting to reproduce at negative temperatures. On the other hand, some south boreal species occur in waters with intensive summer heating, such as Liparis franzi, L. chefuensis, and L. choanus from the Yellow Sea [69] and L. fishelsoni from the Red Sea [70]. Many Liparid species are rare or known only from type specimens. Others are quite common and may form large aggregations; in the Sea of Okhotsk, the total biomass of snailfishes ranged from 32 to 51 thousand tons according to trawl surveys in 1997–2000 [71].
The adaptability of snailfishes is wide; along with stenohaline species, which prefer strict oceanic salinity, there are liparids that tolerate the desalination of estuaries and enter the lower streams of river (L. liparis). Some Arctic snailfishes (the group of L. fabricii) are temporarily sympagic, and their juveniles occur under the lower surface of drifting ice [72]. There are littoral species that use their sucking disk for attaching to stones and algal thalli. Other are demersal (Liparis and Careproctus) and common in shelf waters. Except for bathyal and abyssal liparids, benthopelagic and mesopelagic species exist, in which the ventral disk is reduced (for example Nectoliparis, Paraliparis, and Psednos) [54,60,73]. The striking diversity of liparids is the result of their evolutionary plasticity, which made possible an adaptive radiation into various habitats in different biogeographic and bathymetric zones of the World Ocean.
For the Arctic and the North Atlantic, updated data on the species composition of Liparidae are provided below.
In the Arctic area, five genera are known [35,46,74,75,76], and in this paper, the total number of species is 33: Liparis 5, Careproctus 21, Paraliparis 2, Rhodichthys 2, and Psednos 3, not including the boreal species (L. liparis, L. montagui, Paraliparis copei, P. garmani, Psednos christinae, and Ps. groenlandicus) that enter the marginal Arctic areas (Table 2). This number is incomparably less than the Pacific content of the family.
In the boreal North Atlantic, the number of species is the same (33), although the composition of the genera differs: Liparis 6, Careproctus 3, Paraliparis 12, Psednos 11, and one Eutelichthys instead of Rhodichthys (Table 3).

3.2. Snailfishes of the Genus Liparis

The genus Liparis includes no less than 72 species, being one of the four largest genera of the family [39]. The genus is the most generalized [35,53,56,60,65]. Plesiomorphic characteristics include innumerous vertebrae (31–53), 2–4 pairs of long saber-shaped pleural ribs, two pairs of nostrils, three-lobed jaw teeth in regular rows, and presence of pseudobranchia. There is a large sucking disk (6.4–21.7% SL in diameter) modified from pelvic fins. The shoulder girdle of the pectoral fin possesses four notched radials and three large interradial fenestrae. The pectoral fin is notched and may include a large number of rays (up to 46). The anus and genital openings are open closer to the anal fin than to the ventral disk. In skin, green and orange pigments are present; the color is usually olive-brown, mottled, or striped. The length of most Liparis usually does not exceed 15–30 cm; the largest known length (L. ochotensis) is 74 cm [121]; the weight sometimes reaches 6 kg [122].
The species of the genus are distributed on the shelves of the Northern Hemisphere. The only species from the Southern Hemisphere, L. antarcticus, described from the coast of Chile, may have originated from the waters of California [123] (p. 60). The center of diversity of the genus is located in the northern part of the Pacific Ocean (81% of the species). Inside the Pacific, most of Liparis are found in Asian waters (83%), mainly in the Sea of Japan and Sea of Okhotsk.
The Liparis species is divided into five subgenera by morphological characteristics [39]; four of them (Neoliparis, Liparis, Careliparis, and Lycocara) are of interest for this review.
The subgenus Neoliparis is the most generalized and diverse, containing 26 species in six groups [39]. Although it is considered polyphyletic in a recent molecular study [65], I prefer to follow a taxonomic system based on morphology, until further synthetic studies are performed. Except for other characteristics, they all have a short caudal peduncle that includes up to three vertebrae. The dorsal and anal fins usually do not fuse with the caudal fin. Short gill openings are located above the base of the pectoral fin. Other species of Liparis lack a caudal peduncle; the dorsal and anal fins extend to the caudal fin, and the dorsal fin notch is usually absent or diminishingly small. In the boreal Atlantic, there are four species of this subgenus: L. atlanticus, L. inquilinus, and L. coheni inhabit the western North Atlantic; L. montagui occurs along the European shelf, and others live in the boreal North Pacific.
The subgenus Liparis is less diverse than the previous one and includes about eight species. All of them, in addition to similar counts, have teeth with lobes of the same size and short gill openings. Two species occur in the boreal Atlantic waters: L. liparis is found along the European shelf, and L. barbatus (which I consider in a rank of species) replaces the latter in the Baltic Sea. There is one species in the Arctic, L. tunicatus, which lives mainly in coastal areas.
The subgenus Careliparis includes about 30 species in five species groups [39]. Unlike other congeners, they all have large gill openings (reaching the level of 12th–19th rays of the pectoral fin) and three-lobed teeth with a noticeably larger central lobe; the body is usually deep and humpbacked. One of them, L. bathyarcticus, has an almost circumpolar distribution along the Arctic shelf; others live in the boreal Pacific waters.
The subgenus Lycocara includes at least three similar species with black-pigmented peritoneum and simple teeth (with reduced lateral lobes). They are L. fabricii sensu stricto (described from Bellsund, Spitsbergen), L. koefoedi (Green Harbor, Spitsbergen), L. laptevi (Laptev Sea), and some undescribed forms. They all are often considered as the L. cf. fabricii complex, which has circumpolar Arctic distribution. In the boreal waters of the Pacific Ocean, not a single congener with these characteristics is known.

3.2.1. Liparis of the Boreal Atlantic and the Arctic

The above shows, therefore, that only a few Liparis are found outside the Pacific Ocean. In the boreal Atlantic, there are six species, different from two sides of the ocean; L. atlanticus, L. inquilinus, and L. coheni inhabit the western North Atlantic; L. montagui, L. liparis, and L. barbatus are found in the eastern North Atlantic. Two of these species, L. liparis and L. montagui, may move northward within warm currents to the Murman Coast (in the western part of the Barents Sea), which is in fact the transitional area to the Arctic (in winter, the sea there is ice-free).
In the Arctic, L. tunicatus occurs at a shallow depth; L. bathyarcticus prefers deeper waters along the shelf edge. Representatives of the black-bellied complex L. cf. fabricii are found inshore and offshore, often among the ice. All of them, L. tunicatus, L. bathyarcticus, and L. cf. fabricii complex, have a circumpolar distribution and have adapted to live and reproduce in cold waters.

3.2.2. Groups of Liparis with Amphiboreal and Boreal–Arctic Distribution

In a frame of the amphiboreal concept, six groups of Liparis can be considered (Table 4).
The “Liparis montagui” is the first group. The European L. montagui has a distinguishing characteristic; the posterior pair of nostrils is completely closed (no openings). The species with reduced posterior nostrils is absent in the Arctic, but there are four of them in the boreal Pacific: L. punctulatus in the Sea of Japan, L. burkei (sensu Kido 1988) on the Pacific side of Japan, and L. chefuensis and L. petschiliensis in the Yellow Sea (Figure 1). All five are similar to each other by other traits (including counts) and are members of the “L. montagui” group [39]. The distribution of this group is amphiboreal; one species occurs in the eastern North Atlantic, and four occur in the western North Pacific.
Liparis atlanticus is characterized by a comb-like structure of the anterior part of the dorsal fin (each ray is separated). Similar species are absent in the Arctic, but there are three of them in the boreal Pacific Ocean: L. schantarensis (Sea of Okhotsk), L. schmidti (Sea of Japan), and L. rutteri (Aleutian Islands and American waters southward to California); they all represent the “L. atlanticus” group. The distribution of this group (Figure 2) is amphiboreal, with one species in the western North Atlantic and three species in the North Pacific.
A characteristic feature of the Atlantic snailfish L. inquilinus is the separated anterior lobe of the dorsal fin (with fused rays, such as in Polypera). Four species have the same characteristic, all from the western North Pacific: L. grebnitzkii (Peter the Great Bay, southeastern Kamchatka, and Bering Island), L. mednius (Commander Islands), L. kusnetzovi (Tatar Strait in the Sea of Japan), and L. miostomus (Hokkaido) (Figure 3). All are in the “L. grebnitzkii” group. The distribution of this group is amphiboreal.
Thus, three above-mentioned species groups (“L. montagui”, “L. atlanticus”, and “L. grebnitzkii”) show examples of interrupted amphiboreal distribution, as they are absent in the Arctic and present in the boreal waters of the Atlantic and Pacific Oceans by distinct, well-defined species. All these groups have plesiomorphic characteristics and belong to the generalized subgenus Neoliparis.
The next group, the subgenus Liparis, is another example (Figure 4). Three species are present in the boreal Atlantic: L. coheni off the American coast, L. liparis along the European shelf, and L. barbatus in the Baltic Sea. In the Arctic, L. tunicatus is found, which is considered circumpolar (and the poorly studied L. herschelinus is described from Herschel Island at the mouth of the Mackenzie River). Four other species are known in the boreal Pacific: L. brashnikovi and L. frenatus (Sea of Japan and adjacent waters), L. marmoratus (Sea of Okhotsk and northern Bering Sea), and L. bristolensis (western Bering Sea). Thus, this group demonstrates an example of amphiboreal–Arctic distribution.
The fifth group is represented by members of the subgenus Careliparis. The Arctic L. bathyarcticus is a member of the “L. megacephalus” group, in which the posterior pair of nostrils is reduced in size (to about half the size of the anterior pair). Eight other species, poorly studied, were described from the North Pacific: L. eos, L. lindbergi, L. rotundirostris and L. quadrimodo (all from off Sakhalin Island), L. brevicaudus (Sea of Japan), L. megacephalus (eastern Bering Sea), L. punctatus (Sea of Okhotsk), and L. meridionalis (Peter the Great Bay, Tatar Strait, and Aniva Bay). Thus, this group demonstrates an example of boreal–Arctic distribution, with most species in the North Pacific and one representative in the Arctic.
The last group is the Liparis cf. fabricii complex, which includes snailfishes with black peritoneum and simple teeth. The species with the same characteristics are not known in boreal areas. Thus, this is an example of a group that is endemic to the Arctic (and isolated enclaves of Arctic fauna, such as the harsh northern part of the Okhotsk Sea).

3.2.3. Amphiboreal Concept and Speciation of Liparis in the Arctic and North Atlantic

It was shown above that according to the types of ranges and the degree of taxonomic isolation, the Liparis species is divided into the same groups as other fish families of Pacific origin. The distribution and speciation of northern Liparis can be represented as follows: During preglacial migrations (the Pliocene transgression), some of the Pacific Liparis entered the Arctic through the Bering Strait and distributed to the Atlantic coasts of North America and Europe. Transitions, apparently, went both in the west- and eastward directions, because different species formed in the boreal waters of the West Atlantic (L. atlanticus, L. coheni, and L. inquilinus) and the East Atlantic (L. montagui and L. liparis). All these recent species live in the coastal shallow-water zone. This fact is consistent with the conclusion drawn for amphiboreal invertebrates: in the group of shelf species that retreated south during the Ice Age (to regions not subjected to glaciation); only littoral and sublittoral species could survive [13].
Part of the Pacific migrants could adapt to the coldness during the Ice Age, and the circumpolar L. tunicatus and the black-bellied complex L. cf. fabricii formed in the Arctic. They are stenotherm cold-water fishes, endemic to the Arctic. In the postglacial period, when the Bering Strait became open, they did not penetrate far south into warmer waters, such as other high Arctic species, that prefer temperatures close to zero—Arctic alligatorfish Aspidophoroides olrikii (Agonidae), Hamecon Artediellus scaber (Cottidae), Canadian eelpout Lycodes polaris (Zoarcidae), and Polar cod Boreogadus saida (Gadidae).
During the period of the postglacial climatic optimum, the ancestor of L. bathyarcticus was able to settle in the Arctic seas, westward at least to the Barents Sea. However, it did not have time to significantly separate from the Bering Sea group of species; L. bathyarcticus is still very similar to its Pacific relatives.
New data on the morphology and distribution of Liparis in the Arctic and adjacent waters make it possible to reconsider the idea that the Baltic L. barbatus is a relict of the Ice Age, preserved from the time of supposed existence of the connection between the Baltic and the White Seas [105,124]. Based on recent data, it is unlikely that the ancestral form entered the Baltic Sea from the White Sea during the Yoldian period, as this connection has been disproved [125]. More probable, it could have happened from the Atlantic, during the Littorina Sea transgression that dated from 9500 calibrated year BP [126] to 8000 cal. BP [127]. Then, due to the eustatic rise of the bottom in the area of the Belts and the establishment of the modern hydrological regime of the Baltic Sea 1000–2000 years ago [128], the continuous range of the ancestral form was interrupted, and the isolated Baltic population transformed into L. barbatus adapted to desalinated conditions.
The presented data show, therefore, that the history of the formation of the Arctic Liparis fauna does not fundamentally differ from the speciation and distribution patterns of other fish groups of Pacific origin.
In conclusion it should be noted that the phylogenetic tree of the genus Liparis (based on the COI analysis), which includes 25 species of this genus, shows two clades containing Arctic and Atlantic species (Figure 9 by James Orr et al. [65]). One clade includes L. bathyarcticus, and another (polytomic) combines seven other species (L. liparis, L. inquilinus, L. tinicatus, L. atlanticus, L. montagui, L. fabricius, and L. bristolensis). This can be interpreted as a correlation with two groups, migrating from the Pacific Ocean at different times (posglacial and preglacial); their further evolution proceeded independently from the Pacific congeners. However, the second clade unites rather different species (in axial skeleton and dental systems), which have morphologically similar congeners in the outer clades (L. montaguiL. punctulatus; L. atlanticusL. rutteri). If the COI tree is followed, this means that complex morphological structures in different clades should be allowed to arise independently, which is difficult to explain. Further studies should be performed.

3.3. Snailfishes of the Arctic—Genus Careproctus

The genus Careproctus (sea tadpoles) includes no less than 162 species and is one of the four largest genera in the family [42] updated.
Careproctus differs from Liparis in the absence (reduction) of the posterior pair of nostrils and pseudobranchia and the fusion of two hypuralia in the caudal skeleton; unlike in Liparis, pectoral fin rays are less numerous than the anal fin rays. The origin of sea tadpoles was probably associated with the settlement of and the adaptation to the bathyal–aphotic zone; this can explain the disappearance of green and brown pigments in the skin, which makes their ground color a solid pink or orange.
Most of the species live in the northern part of the Pacific Ocean, where at least 77 species are known [42] updated. There is no overview of the Careproctus for this area.
The secondary center of speciation is located in the waters of the Southern Ocean, and the revision of Careproctus of this fauna, performed by Anatole Andriashev, contains 44 species [60]. He subdivided the species into two subgenera, and the new sg. Careproctula was established (type C. fedorovi Andriashev et Stein 1998, the Scotia Sea). Seven southern species were included in sg. Careproctus, similar to the type species of the genus C. reinhardti, described from southwestern Greenland. They all have strong pleural ribs and notched radials 4 (3 + 1) in the pectoral girdle (=plesiomorhic Liparis-like features). Most sea tadpoles of the Southern Ocean (37) have been included in the sg. Careproctula. They do not have pleural ribs, and in the shoulder girdle, the radials are round, and the interradial fenestrae are reduced.

3.3.1. Careproctus of the Arctic and North Atlantic

The Careproctus diversity of regions is at the stage of initial description; the number of species will obviously increase, especially in the bathyal and abyssal depths of the oceans. The current list includes 21 species in the Arctic (Table 2) and 3 in the North Atlantic (Table 3). Morphologically, they can be assigned to the subgenera Careproctus and Careproctula, mentioned above [37,38] updated. There has not been an updated analysis of these species, so a brief review is necessary before looking for their relatives.
The subgenus Careproctus in the northern regions includes 15 taxa, all from the Arctic. Four of them are well defined: (1) C. reinhardti (Figure 5a) described from southwestern Greenland, the type species of the genus [37]; (2) C. longipinnis (Figure 5b) from the Norwegian Sea (caught at a depth of 1322 m) [37]; (3) C. solidus from the slope of the Laptev Sea (2151–1934 m) [36]; and (4) C. lerikimae from the Beaufort Sea (175–500 m) [81]. The other 11 species make up the “C. dubius” group: they differ from each other (Figure 6a,b and Figure 7a) but have a set of common characters (Table 5). They all have simple teeth (simplified from the three-lobed form); the lower lobe of the pectoral fin is strongly elongated (1.3–1.5 times as long as its upper lobe) and apparently performs a tactile or taste function; the prickles on the skin are cactus-like.
A characteristic feature of the “C. dubius” group is a longitudinally oval pupil, which may be associated with the low illumination of habitats in polar conditions or at a depth of the aphotic zone. In addition, in the species of the group, the anus and genital openings are shifted forward to the very edge of the pelvic sucking disk. Males have a large urogenital papilla, indicating that their fertilization process is internal. This suggests also the complexity of mating behavior. Carcinophilia (laying of eggs in the gill cavity of craboids) has not been recorded for the Arctic or Atlantic Careproctus, but for C. fulvus (from the Kara Sea), spongiophilia was described (laying of eggs in the cavity of glass sponges [40]). This suggests that in other members of this group, similar ways of caring for offspring can be present.
The subgenus Careproctula includes nine species, six of which occur in the Arctic areas and three in the North Atlantic. They all have round radials in the pectoral girdle, absent interradial fenestrae (or rudimentary), and absent pleural ribs (or rudimentary). The lower pectoral fin lobe is usually shorter than the upper lobe. Suprabranchial pore one, the second suprabranchial pore (=rudimentary element of the trunk lateral line) is reduced; the pore formula is 2−6−7−1. The body is elongated and low, and the maximum depth is 12–24% SL. The skin is usually naked and rarely with microscopic needle-like spines. Four groups can be recognized, according to the type of the shoulder girdle and the number of vertebrae (Table 5). Thus, the Careproctula species is heterogeneous, which makes it probable that it belongs to different phylogenetic lineages. The most generalized one is C. (Careproctula) ranula, having three-lobed teeth and a large disk (7.7–9.0% SL).
Among the Arctic species, four are deep-water fishes living at a depth of 952–1695 m: C. kidoi in the Baffin Bay and C. micropus, C. moskalevi, and C. latiosus in the northern part of the Norwegian Sea. Two others are shelf species: C. mica from the Kara Sea (205 m) (Figure 7b) and C. canusocius, which inhabits the upper slope of the Beaufort Sea (488–599 m).
Within the North Atlantic species, C. ranula is a boreal shallow-water fish, known from the entrance to Halifax Harbor at a depth of 95 m (WNA); C. merretti and C. aciculipunctatus are abyssal fishes that live in the Porcupine Seabight at 3990–4100 m (ENA).

3.3.2. Amphiboreal Concept and Speciation of Sea Tadpoles in the Arctic and North Atlantic

When searching for related congeners, one may view the Careproctus species of the Southern Ocean, the characteristics of which are uniformly described [60]. The conclusions are as follows: Arctic representatives of the sg. Careproctus differ from all southern species in the combination of numerous vertebrae (59–63 versus 43–59 in the majority), simple teeth (but not three-lobed), anteriorly shifted anus and genital openings, and a strongly elongated lower lobe of the pectoral fin. The head sensory system is distinguished by the absence of the postorbital pore and the presence of two suprabranchial pores (2−5−7−2). Therefore, there are no similar species in the Southern Ocean; related congeners are most likely to be found in the North Pacific.
For C. reinhardti, I consider C. mederi from the Sea of Ohkotsk to be the closest morphologically (including a large gill opening and slanted mouth), although there are significant differences between them (in the latter, the lower lobe of the pectoral fin is shorter, and the postorbital pore is present). Careproctus longipinnis seems to be most similar to C. trachysoma, known from the Sea of Japan [81].
The origin of the “C. dubius” group should be confidently associated with the North Pacific, as evidenced by the presence of its characteristic features in several species of the Pacific area. The lower lobe of the pectoral fin is greatly elongated in C. colletti, C. cyclocephalus, C. gilberti, C. pellucidus, C. rastrinus, C. rhodomelas, C. spectrum, and C. trachysoma. Cactus-like prickles are present in C. acanthodes, C. rastrinus, and C. trachysoma. The absence of the postorbital pore (formula 2−5−7−2) is known at least for C. acanthodes, C. entomelas, C. homopterus, C. macrodiscus, and C. pellucidus. A longitudinally oval pupil has been noted for C. simus and C. spectrum and in the holotype of C. furcellus [53]. Therefore, an amphiboreal concept can be discussed for Arctic species of sg. Careproctus, although there are not enough comparative Pacific materials for all species.
Preliminary assumptions may be as follows: During preglacial migrations, ancestral Pacific forms of sg. Careproctus entered the Arctic through the Bering Strait and spread toward the Atlantic. During the Ice Age, different parts of the population could move away from the glaciers to the bathyal depth, where deep-water species later formed: C. longipinnis in the Norwegian Sea Basin (at a depth of about 1322 m) and C. solidus on the northern slope of the Laptev Sea (2151–1934 m). On the shelf areas, which were repeatedly becoming free of glaciers, a species flock of the “C. dubius” group was produced. They are vicariant in the southwestern Barents Sea (C. macrophthalmus and C. tapirus), in the north of the Spitsbergen archipelago (C. derjugini), and in the depressions of the Barents Sea (C. telescopus and C. knipowitschi). In the Kara Sea, they were speciated in the southwestern area (C. rosa) and in the Novaya Zemlya Trench (C. fulvus and C. uter); two species have adapted to live in the pelagic zone (C. karaensis and C. carinatus).
The similarity of all these species (for example, in counts: vert. 59−63, D 53−57, A 47−51, P 29−34, and C 10−12) can be explained by the “bottleneck” effect, when the nomadic population in the Arctic was founded by a small number of individuals. The presence of free ecological niches and the weak pressure of competitors in the deglaciated waters can explain the variety of species. The presence of internal fertilization (and behavioral rituals associated with it) were additional factors of isolation that contributed to accelerated speciation.
Among the representatives of sg. Careproctula, the amphiboreal concept is most likely applied to C. ranula, a shallow-water fish from the boreal western North Atlantic. In preglacial times, the ancestral form probably spread from the Pacific to the Atlantic along the coast of North America, and during the Ice Age, it retreated south and formed the recent species. It is possible that other parts of the ancestral population descended from the glaciers to a bathyal depth of 952–1695 m and gave the origin to C. kidoi in the Baffin Basin and C. micropus, C. moskalevi, and C. latiosus in the Norwegian Basin. These species are rather close to each other in main characteristics (Table 4). Two Careproctula known from the central Arctic could have been speciated during periodical deglaciations of the Ice Age: C. mica in the Kara Sea (at a depth of about 205 m) and C. canusocius in the Beaufort Sea (488–599 m). The origin of the mentioned Careproctula in the Southern Ocean is less probable, because there are no similar species there.
However, in contrast to what was shown above, the speciation of the two deepest North Atlantic Careproctula (C. merretti and C. aciculipunctatus, 3990–4100 m) in the eastern North Atlantic was explained differently. The Bering Strait during all periods of its existence was shallow; therefore, the amphiboreal concept does not explain the origin of abyssal fishes. Their penetration into the North Atlantic was explained by another hypothesis of transoceanic dispersal (Pacific–Southern Ocean–North Atlantic), based on the materials of the worldwide ranges of Liparidae and Zoarcidae [7,60,73,129]. Among the Liparidae, this hypothesis is supposed for Paraliparis and, in addition, for the abyssal C. merretti and C. aciculipunctatus. This concept is beyond the scope of the present study. It is sufficient to point out that Careproctula like them are known from deep-sea trenches of the Southern Hemisphere; C. vladibeckeri and C. atakamensis have the same pore formula (2–6–7–1) and the presence of two opposite radials (1 + 0 + 0 + 1). The northern C. aciculipunctatus and C. merretti obviously represent a continuation of this evolutionary line, which is expressed in an increase in the metameric elements of the axial skeleton (vertebrae and fin rays) during the development of the eel-like type of locomotion in fishes at the oceanic depth [60].
The phylogeny of Liparidae based on the COI analysis includes at least 38 Careproctus (Figure 10 by James Orr et al. [65]). It shows two clades containing the Arctic and Atlantic species (four of them were considered in total). This can be interpreted as a correlation with two groups that migrated into the Arctic at different times. These are: (1) C. reinhardti and C. lerikimae (sg. Careproctus) and (2) C. micropus and C kidoi (sg. Careproctula). Among the outer clades, there is the Pacific species C. trachysoma, grouped with the first pair; the second pair is grouped with another branch of the Pacific congeners. These data are consistent with the ideas about the system and the Pacific relatives of the mentioned Arctic–Atlantic species.

3.4. Other Liparids of the Arctic and Atlantic

The genus Paraliparis includes no less than 117 species, twelve of which are known in the North Atlantic (Table 3) and only two in the Arctic, P. bathybius and P. violaceus (Table 2). The dispersal of Paraliraris into the North Atlantic and the Arctic is explained by Andriashev’s hypothesis mentioned above. For the deep-sea genus Paraliparis, the secondary center of speciation is in Antarctica, and then, from the southwestern Atlantic, the species spread north into the depths of the North Atlantic. This route is confirmed by the morphological similarity of the northern and southern species, some of which (the P. copei group) demonstrate a chain of related forms [60].
The migration of the ancestor of P. bathybius into the Polar Basin from the Atlantic can be considered highly probable. This is supported by the discovery in the adjacent North Atlantic of a morphologically similar species P. abyssorum from waters south of the Faroe–Icelandic Sill [45].
Species similar to the Arctic P. violaceus have not yet been found. When compared with P. bathybius, it turns out that P. violaceus combines some ancestral features for the Paraliparis (two hypuralia, four pectoral radials, and epurale present) with characteristics of specialization (reduction in the anterior portion of the dorsal fin and the absence of the notch in the pectoral fin). This gives grounds to suggest an earlier penetration of its ancestral form into the Arctic compared to P. bathybius.
In the phylogeny of Paraliparis based on the COI analysis (Figure 11 by James Orr et al. [65]), the Arctic P. bathybius and the North Atlantic P. garmani are close to the group of South Oceanic species (P. stehmani and others), which is consistent with the above ideas.
Rhodichthys is the endemic genus to the Polar Basin. It was considered monotypic, but the second species, Rh. melanocephalus, was recently described from the Norwegian Basin southwest of Bear Island (depth of 1470–1695 m) [84]. The large oblique mouth, huge gill opening, and modified gill rakers suggest a filter feeding in these meso- and bathypelagic fishes. Until recently, there was not even an assumption about related forms. Then, the abandoned snailfish genus Menziesichthys was restored (based on M. bacescui from the Peru–Chile Trench, 1296–1317 m), and even the second species M. alaid was described from the area of the Kuril Islands (Sea of Okhotsk, 820 m) [130]. These fishes share some unique morphological characteristics with the Rhodichthys, e.g., very large gill slits reaching in front of the lower end of the pectoral fin base and gill rakers modified in a similar way, which obviously are the results of adaptations to pelagic feeding. My guess is that Rhodichthys may have derived from the same root as the Pacific Menziesichthys.
In the phylogeny of Liparidae based on the COI analysis (Figure 11 by James Orr et al. [65]), Rh. regina is in the South Oceanic Paraliparis group. However, among Paraliparis, there are no even remotely similar species. Rhodichthys differs in a unique orobranchial apparatus at the generic rank. The passway of Rhodichthys to the Arctic is not clear. This most likely happened before P. bathybius did. During the glaciations, Rhodichthys was probably driven to the polar depths into the meso- and bathypelagic layers, where it changed greatly, adapting to the filtering method of pelagic feeding.
Psednos includes 11 species in the North Atlantic and 3 species in the marginal Arctic. The center of origin of this genus is in Australian waters, where generalized species occur [61]. Most Psednos are meso- and bathypelagic fishes, found in the Atlantic, Pacific, and Indian Oceans. Many are known from several or even single specimens. Three Arctic Psednos (P. gelatinosus, P. melanocephalus, and P. micruroides) occur in the midwaters of southwest and southeast Greenland (Table 2). These areas are affected by a strong upwelling, which allows deep-sea dwellers to rise closer to the surface, and many of deep-sea Atlantic fishes are found in these marginal Arctic regions [77]. The three mentioned Psednos can be assigned to this fish complex (i.e., they may have an Atlantic distribution). This is all the more likely because two other species recorded in Greenland waters (P. christinae and P. groenlandicus) are also known elsewhere in the North Atlantic (on the Mid-Atlantic Ridge). Consequently, the Psednos of the marginal Arctic are of the Atlantic origin.
Finally, a few words on Eutelichthys should be added. This genus is close to Paraliparis, but differs in the reduction in one of the branchial rays and in the small size of adults (miniaturization). In terms of its characteristics, it is closest to the North Atlantic P. hystryx and P. murieli. Deep-sea fishes, such as Paraliparis, may have entered the Mediterranean from the Atlantic during the opening of the Strait of Gibraltar around 5.33 million years ago [112,131,132]. As a result of the subsequent isolation of the Mediterranean Sea from the depths of the Atlantic, the separation of the ancestral Eutelichthys to the generic rank could have occurred. During the same period of the Mediterranean flood, some Liparis, which were the ancestors of modern L. fishelsoni [70], may have come here from the Atlantic, but later they become extinct there, remaining only in the Red Sea as a relict form.

4. Conclusions

The data presented in the article are intended to give a broad background of complex events of transoceanic migrations of the northern representatives of Liparidae. We used the comparative methods of analyzing our materials collected over many years of Liparid studying. The conclusions are based on morphological differences/similarities of taxa, patterns of species distribution on the background of biogeographic representations, and data obtained for other groups of animals. Our results are mainly consistent with those based on multitaxon mitochondrial data that provide an overview of the dynamics of transarctic dispersal and gene flow [133]. Moreover, they expand the evidence base for further genetic research and may provide an opportunity to look at their results from a different angle.
In the study of Liparidae, a new result is an updated overview of the species composition of the Arctic. The list includes five genera, Liparis, Careproctus, Paraliparis, Rhodichthys, and Psednos. Of the total number of 33 species (excluding the boreal ones entering the marginal Arctic regions), the majority are representatives of the genus Careproctus (21). The amphiboreal concept explains the speciation of Liparis and the bulk of the Careproctus species as a result of trans-Arctic migrations. For two Arctic Paraliparis, the South Oceanic dispersal route can be accepted, which pass from the North Pacific through the Southern Ocean and then north across the Atlantic. The origin of the endemic Rhodichthys is still unclear. The Psednos species, found in the Arctic so far only near southern Greenland, has appeared from the Atlantic, as it is widely distributed in the meso- and bathypelagic waters of warm oceans. Thus, the liparid fauna of the Arctic, although having their ancient roots from the North Pacific, came from both neighboring oceans, mostly through the Bering Strait and, to a lesser extent, from the Atlantic. The latter route is shown for deep-sea liparids: abyssal Careproctula species, benthopelagic Paraliparis, and meso-and benthopelagic Psednos.
The overview of the Liparidae in the North Atlantic revealed the same number of species as in the Arctic (33), but in a different composition: fewer Liparis and Careproctus, more Paraliparis and Psednos, and Eutelichthys instead of Rhodichthys. Boreal shelf species, all Liparis and C. (Careproctula) ranula, may have speciated from the ancestors of the trans-Arctic preglacial routes; others are more likely to have South Oceanic relatives.
Further research is needed to clarify views on the formation of the snailfish fauna, on the one hand, in the field of molecular genetics, and, on the other hand, in the fields of morphology and biogeography.

Funding

This research was funded by State Assignments for the Zoological Institute of the Russian Academy of Sciences No. 122031100285-3.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

Data can be found in the manuscript and in the sources cited.

Acknowledgments

I thank all those who helped me during the study of museum specimens for this research, including David Stein, Horst Wilkens, Jørgen Nielsen, Peter Rask Møller, Ralf Thiel, Ingvar Byrkjedal, Guy Duhamel, Matthias Stehmann, Bo Fernholm, Irina Eidus, Hartel Karsten, Tammes Menne, Sandra Raredon, and Victoria Palm. Special gratitude goes to V. Petrov for editing the manuscript. In addition, I express my deep gratitude to the reviewers, whose comments helped me to improve the manuscript.

Conflicts of Interest

The author declares no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

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Diversity 14 01097 g001 550
Figure 1. Distribution of “L. montagui” group in the Atlantic: blue line—L. montagui; in the Pacific: green dot—L. petchiliensis, pink dot—L. chefuensis, lilac line—L. punctulatus, and yellow line—L. burkei; arrow shows the most probable direction of the preglacial pathway.
Figure 1. Distribution of “L. montagui” group in the Atlantic: blue line—L. montagui; in the Pacific: green dot—L. petchiliensis, pink dot—L. chefuensis, lilac line—L. punctulatus, and yellow line—L. burkei; arrow shows the most probable direction of the preglacial pathway.
Diversity 14 01097 g001
Diversity 14 01097 g002 550
Figure 2. Distribution of “L. atlanticus” group in the Atlantic: green line—L. atlanticus; in the Pacific: lilac line—L. shantarensis, yellow—L. schmidti, and blue—L. rutteri; arrows show the most probable direction of the preglacial pathway.
Figure 2. Distribution of “L. atlanticus” group in the Atlantic: green line—L. atlanticus; in the Pacific: lilac line—L. shantarensis, yellow—L. schmidti, and blue—L. rutteri; arrows show the most probable direction of the preglacial pathway.
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Diversity 14 01097 g003 550
Figure 3. Distribution of “L. grennitzkii” group in the Atlantic: lilac line—L. inquilinus; in the Pacific: red dots—L. grennitzkii, green line—L. kuznetsovi, blue line—L. miostomus, and yellow dot—L. mednius; arrows show the most probable direction of the preglacial pathway.
Figure 3. Distribution of “L. grennitzkii” group in the Atlantic: lilac line—L. inquilinus; in the Pacific: red dots—L. grennitzkii, green line—L. kuznetsovi, blue line—L. miostomus, and yellow dot—L. mednius; arrows show the most probable direction of the preglacial pathway.
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Diversity 14 01097 g004 550
Figure 4. Distribution of the subgenus Liparis group in the Atlantic: lilac line—L. coheni, light green line—L. liparis, and yellow—L. barbatus; in the Pacific: red dots—L. marmoratus, dark green—L. frenatus, gray—L. brashnikovi, and brown—L. bristolensis; in the Arctic: blue line—L. tunicatus that occurs mainly in coastal zone (dots) and dark lilac—L. hershelinus.
Figure 4. Distribution of the subgenus Liparis group in the Atlantic: lilac line—L. coheni, light green line—L. liparis, and yellow—L. barbatus; in the Pacific: red dots—L. marmoratus, dark green—L. frenatus, gray—L. brashnikovi, and brown—L. bristolensis; in the Arctic: blue line—L. tunicatus that occurs mainly in coastal zone (dots) and dark lilac—L. hershelinus.
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Diversity 14 01097 g005a 550Diversity 14 01097 g005b 550
Figure 5. Arctic species of Careproctus: (a) C. reinhardti, Baffin Bay, ZMUC P82456; (b) C. longipinnis, Holotype ZMUC P82180, TL 221 mm.
Figure 5. Arctic species of Careproctus: (a) C. reinhardti, Baffin Bay, ZMUC P82456; (b) C. longipinnis, Holotype ZMUC P82180, TL 221 mm.
Diversity 14 01097 g005aDiversity 14 01097 g005b
Diversity 14 01097 g006 550
Figure 6. Arctic species of Careproctus: (a) C. fulvus. Holotype ZIN 55421, TL 224 mm; (b) C. rosa. Holotype, TL 121 mm.
Figure 6. Arctic species of Careproctus: (a) C. fulvus. Holotype ZIN 55421, TL 224 mm; (b) C. rosa. Holotype, TL 121 mm.
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Diversity 14 01097 g007a 550Diversity 14 01097 g007b 550
Figure 7. Arctic species of Careproctus: (a) Careproctus uter (sg. Careproctus), Holotype; (b) C. mica (sg. Careproctula), Holotype, TL 78 mm.
Figure 7. Arctic species of Careproctus: (a) Careproctus uter (sg. Careproctus), Holotype; (b) C. mica (sg. Careproctula), Holotype, TL 78 mm.
Diversity 14 01097 g007aDiversity 14 01097 g007b
Table
Table 1. Volume of processed material of fishes of the family Liparidae, number.
Table 1. Volume of processed material of fishes of the family Liparidae, number.
GeneraSpeciesSpecimensStations/LotsRadiograms
Liparis551555525359
Careproctus27549192142
Paraliparis67229140183
Psednos32423945
Rhodichthys2755
Total:1832382901734
Table
Table 2. List of Liparidae of the Arctic (including those entering marginal areas from the Atlantic).
Table 2. List of Liparidae of the Arctic (including those entering marginal areas from the Atlantic).
TaxaRange, Depth (m)References
Genus Liparis Scopoli, 1777
Subgenus Liparis Scopoli, 1777
L. liparis (Linnaeus, 1766) *SW Barents Sea (Murman), 0–78 m[35]
L. montagui (Donovan, 1804) *SW Barents Sea (Murman), 0–3 m[35]
L. tunicatus Reinhardt, 1937Circumpolar, shallow waters [35]; SW, NW, NE Greenland [77][35,77]
Subgenus Careliparis Garman, 1892
“L. megacephalus” group
L. bathyarcticus Parr, 1931 1Obviously circumpolar, depth 12–510, usually 5–350 m [35]; Gulf of St. Lawrence [78][35,78]
Subgenus Lycocara Gill, 1884
Liparis cf. fabricii complex 2
L. fabricii Krøyer, 1847
L. koefoedi Parr, 1932
L. laptevi Popov, 1933		Circumpolar, 12–628 (usually 40–350) m [39], near Greenland to 1460 m [77]; Gulf of St.Lawrence [78][39,77,78]
Genus Careproctus Kröyer, 1862 3
Subgenus Careproctus Kröyer, 1862
C. reinhardti sensu stricto (Krøyer, 1862) 3SW Greenland [37,79], Gulf of St. Lawrence [78][37,78,79]
C. longipinnis Burke, 1912Norwegian Sea, north of Faeroe Islands, 1322 m[37,80,81]
C. solidus Chernova, 1999Laptev Sea, 2151–1934 m[36,81]
C. lerikimae Orr, Kai et Nakabo, 2015Beaufort Sea, depth 178 m[81]
C. dubius” group
C. dubius Zugmayer, 1911Spitsbergen, Havre Green, 150 m[37,81]
C. derjugini Chernova, 2005northeast of Spitsbergen, 344–363 m[38]
C. knipowitschi Chernova, 2005Barents Sea, 298–293 m[38,82]
C. macrophthalmus Chernova, 2005southwest of the Barents Sea, 260–275 m[38,82]
C. tapirus Chernova, 2005southwest of the Barents Sea, 170–320 m[38]
C. telescopus Chernova, 2005Barents Sea, 260–307 m[38]
C. fulvus Chernova, 2014Kara Sea, Novaya Zemlya Trench, 190–414 m[40]
C. rosa Chernova, 2014southwest of the Kara Sea, 140 m[41]
C. karaensis Chernova, 2014Kara Sea, east of Novaya Zemlya, pelagic at 0−30 m[41,81]
C. uter Chernova, 2014Kara Sea, Novaya Zemlya Trench, 206 m[41]
C. carinatus Chernova, 2014southwest of the Kara Sea, pelagic at 0−30 m[41]
Subgenus Careproctula Andriashev, 2003
C. micropus (Günther, 1887)Faeroe Channel, depth 540 and 608 fathoms (987–1112 m)[37]
C. kidoi Knudsen et Møller, 2008Baffin Bay; SW Greenland, NW Greenland, 952–1487 m[77,83]
C. moskalevi Andriashev et Chernova, 2010Norwegian Sea, southwest of the Bear Island, 1478–1691 m[82,84]
C. latiosus Andriashev et Chernova, 2010Norwegian Sea, southwest of the Bear Island, 1478–1695 m[82,84]
C. mica Chernova, 2014Kara Sea, Novaya Zemlya Trench, 204 m[41,82]
C. canusocius Orr, 2020Beaufort Sea, 488–599 m[82]
Genus Paraliparis Collett, 1879
P. bathybius (Collett, 1879)Norwegian Basin, 1000–1847 m and pelagic at 20–1000 m; Faroe Trench, 1170 m; Central Polar Basin: northeast of Spitsbergen [35], north of the Laptev Sea, 2824–2775 m [75]; Greenland, benthopelagic, 545–1600 m [77][35,75,77,85,86,87,88,89,90]
P. copei copei Goode et Bean, 1896 *SW, SE Greenland, benthopelagic, (360) 710–1460 (1902) m [77]; Gulf of St.Lawrence [78]. Elsewhere found in the North Atlantic (see Table 2)[77,78]
P. garmani Burke, 1912 *SW, SE Greenland, 550–987. Elsewhere found in WN Atlantic (see Table 2).[77]
P. violaceus Chernova, 1991Central Polar Basin, north of Severnaya Zemlya Archipelago, 2365 m[35]
Genus Rhodichthys Collett, 1879
Rh. regina Collett, 1879Norwegian Basin, 1394–2341 m, Faroe Bank, 400–500 m; Baffin Bay, 1200–1800 m, NW Greenland, NE Greenland, benthopelagic at 1180–1480 m; Polar Basin: northeast of Spitsbergen, 1080–1090 m, north of Severnaya Zemlya, 1445 m[35,77,91,92,93,94,95,96]
Rh. melanocephalus Andriashev et Chernova, 2010Norwegian Basin, southwest of the Bear Island, 1470–1695 m[84]
Genus Psednos Barnard 1927
P. christinae Andriashev, l992 (*)SE Greenland, 843–854 m. Elsewhere found in the Mid-Atlantic Ridge (see Table 2)[77]
P. gelatinosus Chernova, 2001SE Greenland (63°05′54″ N), mesopelagic at 650–0 m[46,77]
P. groenlandicus Chernova, 2001 (*)SW Greenland (63–65° N) and SE Greenland (61°53′ N), mesopelagic at 786–1460 m. Elsewhere found in the Mid-Atlantic Ridge (see Table 2)[46,77]
P. melanocephalus Chernova et Stein, 2002SW Greenland, 58°15′ N, 0–3172 m and 64°03′ N, 926 m; 949–962 m[77,97,98]
P. micruroides Chernova, 2001SW Greenland (63°45′ N), 0–900 m and SE Greenland (63°50′18″ N), mesopelagic at 0–1333 m[46,77,98]
* Boreal or (*) Atlantic mesopelagic species that penetrate the marginal waters of the Arctic. 1 After the revision [99], the species L. gibbus, that was described from the Bristol Bay of the Bering Sea, was accepted to occur circumpolarly [46,77]. Additional studies show that the Arctic specimens belong to L. bathyarcticus, described from Spitsbergen. 2 After the revision [99], the species L. fabricii Krøyer, 1847 was accepted to occur circumpolarly [46,77]. According to my studies, the Arctic specimens represent more than one species. 3 Some authors [100] regard that only one species (C. reinhardti) occurs all over the Arctic, which is at least strange, considering the diversity of Careproctus in the Pacific or the Antarctic.
Table
Table 3. List of Liparidae of the North Atlantic.
Table 3. List of Liparidae of the North Atlantic.
TaxaRange, Depth (m)References
Genus Liparis Scopoli, 1777
Subgenus Neoliparis Steindachner, 1876
L. montagui” group
L. montagui (Donovan, 1804) *Europe: from Portugal to Murman, intertidal and shallow waters[35,39,90]
L. atlanticus” group
L. atlanticus (Jordan et Evermann, 1898)WN Atlantic: Quebec, Newfoundland, Nova Scotia [99], Gulf of St. Lawrence [78]; intertidal to 90 m[78,99]
L. grebnitzkii” group
L. inquilinus Able, 1973WN Atlantic: from the Gulf of St. Lawrence to Cape Hatteras, 5–97 m[101,102,103]
Subgenus Liparis Linnaeus, 1766
L. coheni Able, 1976WN Atlantic: Gulf of Maine, Nova Scotia, Gulf of St. Lawrence, 2–210 m[104]
L. liparis (Linnaeus, 1766) *Europe: from the North Sea to Murman; intertidal to 78 m[35,39,90]
L. barbatus Ekström, 1832Baltic Sea: Gulf of Finland, Gulf of Bothnia, shallow water, enters rivers[35,105] (as L.liparis barbatus); [39] (as L. barbatus)
Genus Careproctus Kröyer, 1862
Subgenus Careproctula Andriashev, 2003
C. ranula (Goode et Bean, 1879)WN Atlantic: Halifax Harbor, Nova Scotia, 95 m[37,106]
C. merretti” group
C. merretti Andriashev et Chernova, 1988EN Atlantic: Porcupine Seabight (49°37′ N, 13°49′ W), 3990–3920 m[44]
C. aciculipunctatus Andriashev et Chernova, 1997EN Atlantic: south of the Porcupine bank (50°13.8′ N, 14°36.1′ W), 4100 m[45]
Genus Paraliparis Collett, 1879
P. abyssorum Andriashev et Chernova, 1997EN Atlantic: near the Porcupine Bank (49°54′ N, 13°56′ W), 3640–3715 m[45]
P. bipolaris Andriashev, 1997WN Atlantic: southwest of Ireland (50°12′ N, 13°40′ W), 3000–3040 m[107]
P. calidus Cohen, 1968WN Atlantic: Gulf of Mexico (27°25′ N, 93°40′ W), 730 m; Gulf of St. Lawrence[78,108]
P. challengeri Andriashev, 1993EN Atlantic: Rockall Trough (57°01′ N, 10°05′ W), Porcupine Seabight (49°46′ N, 12°31′ W), 2000–2100 m[109]
P. copei copei Goode et Bean, 1896 *WN Atlantic: 430–1980 m; described from the Long Island (39°12′17″ N, 72°09′30″ W), 951 m. EN Atlantic: 1125–1400 m. Elsewhere found near South Greenland (see Table 1).[48,110], our data
P. edwardsi (Vaillant, 1888)EN Atlantic: coast of Marocco, between Cape Spartel and Cape Blanko (33°46′ N, 9°02′ E), 1319 m[108,111,112]
P. garmani Burke, 1912 *WN Atlantic: from Labrador to Cape Hatteras; benthopelagic, 550–987 m. Elsewhere found near South Greenland (see Table 1).[77,80]
P. hystrix Merrett, 1983EN Atlantic: to the west of Britain, (49–59° N, 07–18° W), 255–1140 m [113]. WN Atlantic: (36–38° N, 70–74° W), 0–1008 m [90][90,113,114]
P. liparinus (Goode, 1881)WN Atlantic: southeast of Long Island, 891 m[109]
P. murielae Matallanas, 1984West of the Mediterranean Sea, 500–600 m[115]
P. nigellus Chernova et Moller, 2008North Atlantic: Mid-Atlantic Ridge, between the Azores and Charlie–Gibbs Fracture Zone, 1950–2107 m[48]
P. vailanti Chernova, 2004WN Atlantic: Laurentian Channel (46°39′ N, 58°41′ W), mesopelagic, 423 m over a depth of 1150 m[116]
Genus Psednos Barnard, 1927
P. andriashevi Chernova, 2001EN Atlantic: west of Ireland (54°21′ N, 17°59′ W), mesopelagic at 800 m[46]
P. barnardi Chernova, 2001WN Atlantic: slope of New England (39°49′ N, 70°39′ W), mesopelagic at 1042–1368 m, juv at 750–1001 m[46]
P. christinae Andriashev, l992 (*),1North Atlantic: Mid-Atlantic Ridge (49°48′ N, 25°55′ W), 1000–1500 m; Greenland (see Table 1)[117]
P. delawarei Chernova et Stein, 2002WN Atlantic: south of Cape Cod (39°48′05″ N, 70°43′28″ W), 0–1000 m[97]
P. islandicus Chernova et Stein, 2002EN Atlantic: 59°59.7′ N, 19°42.2′ W, 1250–1500 m[97]
P. groenlandicus Chernova, 2001 (*)North Atlantic: north of the Mid-Atlantic Ridge, mesopelagic, 981–2015 m over greater depth. Ellsewhere found near South Greenland (see Table 1)[48]
P. harteli Chernova, 2001WN Atlantic: 40°45′ N, 65°03′ W, 1008–0 m[46]
P. mirabilis Chernova, 2001WN Atlantic: slope of New England (39° N, 70°39′ W), 0–700 m over 1370–1700 m[46]
P. rossi Chernova et Stein, 2004 2WN Atlantic: Cape Hatteras (35°30.036″ N, 74°46.497″ W), 500–674 m over 900 m[118]
P. sargassicus Chernova, 2001Sargasso Sea (35°30′ N, 67°14′30″ W, 0–1050 m[46]
P. spirohira Chernova et Stein, 2002EN Atlantic: west of northern Spain (41°56.2′ N, 16°50.1′ W), 985–1010 m[92]
Genus Eutelichthys Tortonese, 1959
E. leptochirus Tortonese, 1959EN Atlantic: southwestern part of the Mediterranean Sea and Bay of Lyon, 500–917 m[90,112,119,120]
* Boreal or (*) mesopelagic species, which penetrate the marginal Arctic (waters of South Greenland and southwestern part of the Barents Sea). 1 The specimen from off Ireland was later described as P. andriashevi [46]. 2 Psednos rossi was separated in a new genus Aetheliparis Stein, 2012. Additional data are needed to decide on the validity of this genus.
Table
Table 4. Groups of Liparis with amphiboreal and boreal–Arctic distribution.
Table 4. Groups of Liparis with amphiboreal and boreal–Arctic distribution.
North AtlanticArcticNorth Pacific
Subgenus Neoliparis Steindachner, 1876
L. montagui” group
* L. montagui EurL. burkei (Jordan et Thompson, 1914) Jap
L. chefuensis Wu et Wang, 1933 Yell
L. petschiliensis (Rendahl, 1926) Yell
L. punctulatus (Tanaka, 1916) Jap
L. atlanticus” group
L. atlanticus WNAL. rutteri (Gilbert et Snyder, 1898) Amer Ale
L. schantarensis (Lindberg et Dulkeit, 1929) Okh
L. schmidti Lindberg et Krasyukova, 1987 Jap
L. grebnitzkii” group
L. inquilinus WNAL. miostomus Matsubara et Iwai, 1954 Hokk, Kam
L. kusnetzovi Taranetz, 1935 Jap
L. mednius (Soldatov, 1930) Com
L. grebnitzkii (Schmidt, 1904) Com
Subgenus Liparis Scopoli, 1777
L. coheni WNA L. brashnikovi Soldatov, 1930 Jap, Kam
* L. liparis EurL. tunicatus circL. frenatus (Gilbert et Burke, 1912) Jap, Hokk, Okh
L. barbatus Balt L. marmoratus Schmidt, 1950 Okh, Ber
L. bristolensis (Burke, 1912) Ber, Al
Subgenus Careliparis Garman, 1892
“L. megacephalus” group
L. bathyarcticus circL. meridionalis Schmidt, 1950 Jap
L. punctatus Schmidt, 1950 Okh
L. eos Krasyukova, 1894 Sakh
L. rotundirostris Krasyukova, 1894 Sakh
L. megacephalus (Burke, 1912) eBer
L. brevicaudus Mori, 1956 Jap
L. quasimodo Krasyukova, 1894 Sakh
L. lindbergi Krasyukova, 1894 Sakh
Subgenus Lycocara Gill, 1884
L. cf. fabricii complex circ
(L. fabricii s. str. Spits
L. koefoedi Spits
L. laptevi Lap)
* Boreal species, which penetrate the marginal waters of the Arctic (the Barents Sea). Designations of the distribution areas: Al—Alaska, Ale—Aleutian Islands, Amer—American Pacific, Balt—Baltic Sea, Beauf—Beaufort Sea, Ber—Bering Sea, circ—circumpolar distribution, Com—Commander Islands, e—eastern, Eur—Europe, Grenl—Greenland, Hokk—Hokkaido, Jap—Sea of Japan, Kam—west of the Kamchatka Peninsula, Lap—Laptev Sea, Okh—Sea of Okhotsk, Sakh—Sakhalin, Spits—Spitsbergen, St.Law—Gulf of St. Lawrence, WNA—western North Atlantic, Yell—Yellow Sea.
Table
Table 5. Basic characteristics of Careproctus from the Arctic and North Atlantic.
Table 5. Basic characteristics of Careproctus from the Arctic and North Atlantic.
Subgenus Careproctus (pectoral radials notched, 2–3 interradial fenestra present; pleural ribs saber-like)
Pectoral radials4 (3 + 1)3 (2 + 0 + 1)3 (2 + 0 + 1)2 (1 + 0 + 0 + 1)
Vertebrae59–6460
Pectoral fin rays29–3631
Pores 2–5–7–2C. reinhardtiC. solidus
C. longipinnis
C. lerikimae
“C. dubius”(11 species) 1
Subgenus Careproctula (pectoral radials unnotched; interradial fenestra absent; pleural ribs absent or rudimentary)
Pectoral radials4 (3 + 1)3 (2 + 0 + 1)3 (2 + 0 + 1)2 (1 + 0 + 0 + 1)
Vertebrae60–6257–6264–6569
Pectoral fin rays26–2822–2927–2822–25
Pores 2–6–7–1C. ranula *
C. kidoi		C. micropusC. canusociusC. merretti *
C. aciculipunctatus *
C. moskalevi
C. latiosus2
C. mica
* Atlantic species. 1C. dubius” group includes C. carinatus, C. fulvus, C. derjugini, C. dubius, C. karaensis, C. knipowitschi, C. macrophthalmus, C. rosa, C. tapirus, C. telescopus, and C. uter. 2 The number of pectoral radials in C. latiosus is variable: 4 (3 + 1) or 3 (2 + 0 + 1).
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Chernova, N.V. Amphiboreality and Distribution of Snailfishes (Cottiformes: Liparidae) in the Arctic and the North Atlantic. Diversity 2022, 14, 1097. https://doi.org/10.3390/d14121097

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Chernova NV. Amphiboreality and Distribution of Snailfishes (Cottiformes: Liparidae) in the Arctic and the North Atlantic. Diversity. 2022; 14(12):1097. https://doi.org/10.3390/d14121097

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Chernova, Natalia V. 2022. "Amphiboreality and Distribution of Snailfishes (Cottiformes: Liparidae) in the Arctic and the North Atlantic" Diversity 14, no. 12: 1097. https://doi.org/10.3390/d14121097

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