Fisheries Research 109 (2011) 179–186
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Cephalopods caught in the outer Patagonian shelf and its upper and medium slope in relation to the main oceanographic features Ángel Guerra a,∗ , Julio M. Portela b , José Luis del Río b a b
Instituto de Investigaciones Marinas (CSIC), Eduardo Cabello 6, 36208 Vigo, Spain Instituto Espa˜ nol de Oceanografía (IEO), C. O. de Vigo. P.O. Box 1552, 36200 Vigo, Spain
a r t i c l e
i n f o
Article history: Received 1 December 2010 Received in revised form 1 February 2011 Accepted 3 February 2011 Keywords: Cephalopods Biogeography Patagonian slope Southwest Atlantic
a b s t r a c t Ninety cephalopod specimens were collected in 71 of the 132 hauls (54%) during the bottom trawl survey ATLANTIS 2009 undertaken between 24 February and 1 April 2009. The surveyed area was the zone between parallels 44◦ and 48◦ South, east of the Argentinean Exclusive Economic Zone down to the 1500 m depth contour on the high seas of the Southwest Atlantic. The collection was composed of 16 species of squids and 5 of octopods. The best represented groups were Histioteuthidae (5 species) and Octopodidae (5). The most abundant species were Gonatus antarcticus (25.5%), Histioteuthis atlantica (11.1%), and Muusoctopus eureka (8.9%), which were also the most widely encountered. The geographic and/or bathymetric distribution ranges of 9 species are extended, and this is the first record of Galiteuthis glacialis outside circumpolar Antarctic waters. Our data show that several species, mainly of octopuses, penetrate the area studied as the plume of cold sub-Antarctic waters is pushed far into the Southwestern Atlantic by the Falkland (Malvinas) Current. Published by Elsevier B.V.
1. Introduction The Southwest Atlantic Ocean (SWA) supports two major cephalopod fisheries. One is focused on the Patagonian long-finned squid Loligo gahi and the other on the Argentine short-finned squid Illex argentinus. Although there is considerable information on these two species along the continental shelf within the Argentinean and Uruguayan Exclusive Economic Zones (EEZ) (Nigmatullin, 1989; Basson et al., 1996; Agnew et al., 1998; Haimovici et al., 1998; Brunetti et al., 1999; Agnew et al., 2005; Portela et al., 2010), mainly around the Falkland (Malvinas) Islands (e.g. Arkhipkin et al., 2004; Bazzino et al., 2005; Sacau et al., 2005), very little research has been carried out on the High Seas (HS) region. The recently developed Falkland (Malvinas) fishery regularly catches octopuses during survey trawls as does the Falkland Islands Government Fisheries Department (FIGFD) through observers attending commercial trawling operations on the South American continental shelf in the SWA, and research received a further boost when the FIGFD funded a study to identify the octopuses in their fisheries collection (Gleadall et al., 2010). Recently, L. gahi, I. argentinus, Onykia ingens, and Gonatus antarcticus have also been shown to occupy the ecological niche of epipelagic fish on the Falk-
∗ Corresponding author. Tel.: +34 986231939x180; fax: +34 986 292762. E-mail address:
[email protected] (Á. Guerra). 0165-7836/$ – see front matter. Published by Elsevier B.V. doi:10.1016/j.fishres.2011.02.003
land (Malvinas) shelf and slope (Laptikhovsky and Arkhipkin, 2010). Many papers have been devoted to discovering knowledge of the teuthofauna from the Antarctic waters (see, for example, Rodhouse, 1989; Gleadall et al., 2010, and the literature cited therein). However, little attention has been paid to the cephalopod species from the Argentinean shelf and even less to the biodiversity present in the Patagonian upper and medium slope. Practically the only data available came from the cruises carried out by Rodhouse et al. (1992) devoted to the early life cycle of cephalopods, which surveyed a wide area using RMT8 and Bongo nets, and associated the captures with the major oceanographic features of the SWA. This paper examines the cephalopods collected during the cruise ATLANTIS 2009 carried out in the HS of the SWA, including the outer Patagonian shelf and the upper and medium slope, in relation to the main oceanographic features of the SWA. It also aims to contribute to the knowledge of the teuthofauna in the region, the taxonomy of the material collected, as well as its geographical and bathymetric distribution. 2. Study area The area surveyed was the zone between parallels 44◦ and 48◦ South, east of the Argentinean EEZ down to the 1500 m depth contour (Fig. 1), and the depth of the trawls ranged from 107 to 1527 m. The physical oceanography of this area – virtually opposite the Gulf
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Fig. 1. Study area comprised between 44◦ and 48◦ south and to the east of the Argentinean Exclusive Economic Zone (EEZ or ZEE in Spanish). FOCZ: Falkland Islands Outer Conservation Zone; FICZ: Falkland Islands Conservation Zone.
of San Jorge on the Argentinean coast – is complex. We therefore present a schematic scenario, which will allow us to understand the main features that occur in the study area. The major oceanographic features of the SWA are the Brazil Current (BC), the Falkland (Malvinas) Current (FMC), and their confluence region. The BC originates as a branch of the South Equatorial Current (around 08◦ South) and runs poleward almost parallel to the shelf break. It is tropical in origin and is therefore warm, saline, and relatively oligotrophic. The southern limit of the warm water associated with the BC fluctuates between 36◦ –38◦ and 46◦ South, and is accompanied by the intermittent formation of warm-core, anti-cyclonic eddies (Campos et al., 1995). The encounter between the warm southward flowing BC and the cold northward flow of the FMC, at approximately 38◦ South, generates a strong thermohaline front: the Subtropical Convergence or Subtropical Zone (STZ). The cool, nutrient-rich FMC branches off the Antarctic Circumpolar Current and flows northward along the Patagonian continental slope. This current flows round both sides of the Falkland Islands before turning northward once again as a single flow, approximately 100 km wide. The FMC is the dominant circulation feature along the Falkland Shelf Break. The sub-Antarctic waters from the FMC flow along the shelf as far north as 32◦ South before returning south as the Falkland (Malvinas) Return Current and flowing offshore at the confluence zone. The surface water temperatures in the northerly flowing coastal current, between 24◦ and 33◦ South, are several degrees lower than the Brazil Current and consist of a mixture of cool water from the FMC and warm water being recirculated from the BC. Brazil Current waters have a temperature of >20.0 ◦ C and salinity of >36.0, while FMC waters have a wide temperature range between 4.0 and 15.0 ◦ C, but a narrow salinity signal between 33.7 and 34.1. Because of the large differential between these salinity ranges specified for the Brazil and FM Currents, a large proportion of the water sampled can be expected to have mixed characteristics (Wilson and Rees, 2000, and references therein). Using the nomenclature for the fronts and zones adopted by Peterson and Whitworth (1989), the three zones south of the STZ associated with the Antarctic Circumpolar Current are, from north to south, the Sub-Antarctic Zone (SAZ), the Polar Frontal Zone (PFZ),
and the Antarctic Zone (AZ). These zones are associated with fronts (Fig. 2). 3. Materials and methods A multidisciplinary research cruise was conducted by the Spanish Institute of Oceanography (IEO) to assess the biomass of the main commercial fish stocks on the HS of the SWA and to identify Vulnerable Marine Ecosystems (VME). The multidisciplinary bottom trawl survey (ATLANTIS 2009), undertaken between 24 February and 1 April 2009 on board the RV Miguel Oliver, included 132 trawl stations (Fig. 3 and Table 1). The survey used a stratified random design with strata boundaries defined by latitude and depth ranges. Scheduled fishing stations (hauls of 30 min) were performed using a LOFOTEN type net fitted with a “Rockhopper” mix train with bobbins and rubber separators, suitable for deepwater fishing over irregular bottoms. The headline height averaged 6.1 m, with a wing spread of 20 m. Mesh size ranged from 160 mm in the upper wings to 40 mm in the cod end liner. Trawling was restricted to daylight hours. The positions of the hauls were randomly chosen prior to starting each stratum survey. Thirteen depth strata were defined in the study area (Table 1) and were further subdivided into 2571 grids of around 5 square nautical miles (nm2 ). Finally, 147 hauls were randomly allocated according to the following criteria: (i) The number of hauls in each stratum was proportional to its surface, with a minimum of 2 hauls per stratum. (ii) For each stratum, hauls were randomly allocated among all possible grids, excluding those in adjacent squares. (iii) When fishing was not possible in a selected grid due to bottom characteristics, the haul was put in the nearest square allowing for bottom trawling. Only 132 hauls were performed out of the 149 planned, as characteristics of the seafloor hindered bottom trawling, mainly in stratum 7 (1001–1500 m depth). Moreover, 5 of the hauls were considered null for different reasons, such as net breakage or net
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Fig. 2. Major oceanographic features of the southwest Atlantic Ocean (from Rodhouse et al., 1992). The limits of the fronts and zones change with time of the year and climatic conditions.
Table 1 Characteristics of depth strata and number of hauls per stratum in ATLANTIS 2009 cruise. Meters (m); nautical miles (nm), square nautical miles (nm2 ). Stratum
Depth range (m)
Surface (nm2)
No of grids (∼5 nm2 )
Scheduled hauls
Hauls made Valid
1 2 3 4 5 6 7 8 9 10 11 12 13 Total
<200 201–300 301–400 401–500 501–700 701–1000 1001–1500 <200 201–300 301–400 401–500 501–1000 1001–1500
1144 279 366 538 1483 1964 2037 1395 111 123 74 977 2547 13,038
229 56 73 108 297 393 407 279 22 25 15 195 509 2608
13 3 4 6 17 22 22 16 2 2 2 11 29 149
13 3 4 6 17 21 – 18 2 2 2 11 28 127
Null
1 2 1 – 1
5
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Fig. 3. Location of the cephalopod trawled species in ATLANTIS 2009 cruise. Semirossia patagonica (Sp); Austrorossia mastigophora (Am); Neorossia caroli (Nc); Gonatus antracticus (Ga); Histioteuthis arcturi (Ha); H. atlantica (Hat); H. bonnellii (Hb); H. eltaninae (He); H. reversa (Hr); Chiroteuthis veranyii (Cv); Slosarczykovia circumantarctica (Sc); Onykia ingens (Oi); Bathytheuthis abyssicola (Ba); Batoteuthis skolops (Bs); Galiteuthis glacialis (Gg); Taonius pavo (Tp); Graneledona antractica (Gan); Granleledone macrotyla (Gm); Taumeledone gunteri (Tg); Muusoctopus eureka (Me); Muusoctopus longibrachus akambei (Mla).
entanglement. Table 1 shows the scheme of fishing stations by depth stratum and summarizes their main characteristics: depth range (m), surface (nm2 ), and number of grids per stratum. Hydrographical parameters (sea surface temperature [SST], sea bottom temperature [SBT], and salinity) were collected during the cruise using a CTD-probe. Catches were sorted immediately after capture. Cephalopods were stored in labelled plastic boxes and frozen at −20 ◦ C on board. Specimens were taken by the vessel to Vigo (Spain) where the samples were transported to the Instituto de Investigaciones Marinas (IIM, CSIC) marine research laboratory for detailed examination. After defrosting at room temperature, cephalopods were identified from published guides, and old (e.g. Nesis, 1987; Voss, 1976; Voss et al., 1998) and recent papers (e.g. Guerra et al., 2000; Lipinski, 2001; Allcock et al., 2004; Vecchione et al., 2005; Gleadall et al., 2010). Total length (TL), dorsal mantle length (ML), and wet weight were measured immediately, and the sex was also determined.
All the material caught on this cruise, except Batoteuthis skolops, which is in the National Museum of Natural History (Washington, DC, USA), has been deposited at the Museo do Mar de Galicia (Vigo, Spain, www.museodomar.com).
4. Results Locations of trawls conducted during the ATLANTIS 2009 survey are shown in Fig. 3. The typical range of SST, SBT, and salinity at the different zones, or the oceanographic features cited in the text and Fig. 2 are shown in Table 2. During the cruise, 90 cephalopod specimens, comprising 16 squids and 5 octopods, were collected. Depth ranges of capture and numbers of hauls with cephalopod catches are shown in Table 3. Cephalopods were present in 71 of the 127 valid hauls (56%) carried out during the cruise. The family of squids best represented was Histioteuthidae with 5 species, while the Octopodidae was repre-
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Table 2 ATLANTIS 2009 cruise typical range of sea surface temperature (SST), sea bottom temperature (SBT), and salinity at the different zones or currents mentioned in the text and Fig. 2. PS: Patagonian shelf; STZ: Subtropical Zone or Subtropical Front; FMC: Falkland (Malvinas) Current (at 52–53.3◦ S–58–61◦ W); SAZ: Subantartic Zone; PFZ: Polar Frontal Zone; AZ: Antarctic Zone. S: Summer; W: Winter. Data sources: CIMAS (Cooperative Institute for Marine and Atmospheric Studies, University of Miami; Arkhipkin et al., 2004; Deacon, 1984; Glorioso, 1987; Peterson and Whitworth, 1989). These data vary with time of the year and weather conditions, when there is no indication the information correspond to March–April months. Zone
PS
STZ
FMC
SAZ
PFZ
AZ
SST◦ C
7.5–18.0
7.0–14.0
9.5–14.6
2.0–4.0
2.0–3.0
SBT
13.0–14.0 (450 m)
4.0–5.0 (200 m)
Salinity
34.57–35.70
34.90–34.60
4.5–8.0 (200 m) 2.2–3.8 (1000 m) 33.8–34.2
4.0–14.0 S 4.0–8.0 W 2.0–3.0 (200 m) 2.0–0.0 (1000 m) 33.90–34.90 W >33.0 S
2.0–0.0 (1000 m) 33.80–34.10 W >33.0 s
−0.2 to 0.4 (2000 m) 33.50–34.70 W >33.0 S
sented with 5 species (Table 3). The most abundant squids were of the Gonatus antarcticus Lönngerg, 1898, species (25.5%), followed by Histioteuthis atlantica (11.1%) (Hoyle, 1885). The most abundant octopus species (8.9%) was Muusoctopus eureka (Robson, 1929). G. antarcticus also appears to be the most diverse spatially and was captured at 14 stations (Table 3). However, the distribution of H. atlantica and M. eureka, which appear in 8 stations, respectively, also have a wide geographical area of distribution within the limits of the total area explored. Size and some other biological data of captured specimens and families (10) of each species are detailed in Table 4. Table 5 shows the cephalopod distribution caught during this cruise in relation to the major oceanographic features of the study area.
5. Discussion Six specimens of Brachioteuthidae share the diagnostic characters of Slosarczykovia circumantarctica Lipinski, 2001. This is one of the most common squids in Antarctic waters (Lipinski and Young, http://tolweb.org/Slosarczykovia/24102). Until now, very few specimens of Batoteuthis skolops Young and Roper, 1968 have been collected (Young and Roper, 1968; Rodhouse et al., 1992; Young and Roper, http://tolweb.org/Batoteuthidae/19452). The species is found only in Antarctic and sub-Antarctic waters and little is known of its biology. Due to the interest in our specimen, we plan to present a detailed description and discussion elsewhere.
The taxonomy of the octopuses is still undergoing major revision (see, for example, Norman and Hochberg, 2005) and to date incirrate octopuses have yet to be the subject of a comprehensive study using nucleotide sequence data. Such data are now being collected and research is also under way to provide clear species re-descriptions based upon morphometric data, leading to a much better understanding of the major groups and biodiversity of shallow water octopuses (Gleadall et al., 2010). These authors have described three inkless octopodids from the continental shelf off south-eastern South America. These octopuses are a non-commercial by-catch in the Falkland (Malvinas) fishery. Muusoctopus eureka (Robson, 1929) is one of two common inkless octopuses, is of medium size, with orange–pink skin, and a distinctive pattern of irregular dark markings, interspersed with white spots visible only in living or freshly dead specimens. Eight specimens caught in our cruise belong to this species. Another four specimens also captured during our cruise belong to Muusoctopus longibrachus akambei Gleadall et al., 2010. Two specimens (21–30 mm ML) of the Patagonian bobtail squid Semirossia patagonica (Smith, 1881) were caught on the Falkland (Malvinas) shelf by an RMT8 net from the surface to the bottom (Rodhouse et al., 1992). This species has also been collected on the Argentinean shelf (Reid and Jereb, 2005). The records presented here represent an expansion of the geographical range of the species eastwards. According to depth, SST, and SBT (Table 2), our specimens were caught in the STZ, usually located between 35◦ and 45◦ South, where the average SST changes from about 12 ◦ C to 7–8 ◦ C (Campos et al., 1995). One specimen of the bobtail Austrorossia mastigophora (Chun, 1915) was also captured in this STZ
Table 3 Cephalopod species caught during the ATLANTIS 2009 survey in March 2009, with number of hauls (N) where they were caught, depth range (DR), maximum sea surface temperature (SST) and sea bottom temperature (SBT), salinity (S), and number of specimens caught (NC). Family
Species
N
Sepiolidae
Semirossia patagonica Austrorossia mastigophora Neorossia caroli Gonatus antarcticus Histioteuthis arcturi Histioteuthis atlantica Histioteuthis bonnellii Histioteuthis eltaninae Histioteuthis reversa Chiroteuthis veranyii Slosarczykovia circumantarctica Onykia ingens Bathyteuthis abyssicola Batoteuthis skolops Galiteuthis glacialis Taonis pavo Graneledone antractica Graneledone macrotyla Thaumeledone gunteri Muusoctopus eureka M. longibrachus akambei
2 1 1 14 1 8 5 1 3 3 6 1 1 1 2 1 3 2 4 8 3 71
Gonatidae Histioteuthidae
Chiroteuthidae Brachioteuthidae Onychoteuthidae Bathyteuthidae Batoteuthidae Cranchiidae Octopodidae
Totals
SST-SBT (◦ C)
DR (m) 114–144 116–119 601–603 690–1502 1176–1187 135–998 625–1291 717–720 618–846 766–1187 881–1224 1043–1050 1497–1502 1198–1221 1103–1365 1359–1365 1156–1461 774–870 855–1190 111–1156 428–921
13.4–4.1 13.5–5.9 12.0–3.8 10.5–2.2 9.5–2.7 9.8–2.8 11.0–2.3 12.9–3.6 13.1–3.0 12.0–2.7 11.9–2.3 9.8–2.9 9.9–2.2 9.8–2.8 10.5–2.6 10.2–2.5 9.7–2.4 10.3–3.1 9.6–2.6 14.6–2.8 12.0–2.9
S 33.7–34.0 33.6–33.9 33.8–34.1 33.8–34.3 33.9–34.3 33.9–34.1 33.8–34.2 33.7–34.1 33.6–34.1 33.8–34.3 33.8–34.3 33.7–34.2 33.9–34.3 33.9–34.2 33.8–34.3 33.7–34.3 33.9–34.3 33.8–34.2 33.8–34.3 33.5–34.3 33.7–34.1
NC 2 1 1 23 1 10 5 4 3 3 9 1 1 1 3 1 3 2 4 8 4 90
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Table 4 Cephalopod species caught during ATLANTIS 2009 cruise. Family; size range (ML: dorsal mantle length in millimeters); BD: biological data; M: male; F: female; SA: subadult; J: juvenile; NC: number of specimens caught; Ma: mature; Mat: maturating; IM: immature; Sfm: stomach full of myctophids; Sfe: stomach full of euphausids. Species
Family
ML
BD
NC
Semirossia patagonica Austrorossia mastigophora Neorossia caroli Gonatus antarcticus Histioteuthis arcturi Histioteuthis atlantica Histioteuthis bonnellii Histioteuthis eltaninae Histioteuthis reversa Chiroteuthis veranyii Slosarczykovia circumantarctica Onykia ingens Bathyteuthis abyssicola Batoteuthis skolops Galiteuthis glacialis Taonis pavo Graneledone antractica Graneledone macrotyla Thaumeledone gunteri Muusoctopus eureka Muusoctopus longibrachus akambei Total
Sepiolidae Sepiolidae Sepiolidae Gonatidae Histioteuthidae Histioteuthidae Histioteuthidae Histioteuthidae Histioteuthidae Chiroteuthidae Brachioteuthidae Onychoteuthidae Bathyteuthidae Batoteuthidae Cranchiidae Cranchiidae Octopodidae Octopodidae Octopodidae Octopodidae Octopodidae
21–30 21 47 50–226 21 43–79 58–82 66–75 21–83 84–297 105–182 480 52 125 350–372 323 21–130 27–60 35–51 49–80 42–78
Ma M + F Ma F Ma F 9 Ma M10 Mat F, 4JSfm J 6M + 4F 2M + 3F 1M + 3F 2M + 1F 1F + 2J 4 Ma M 2 Ma F, 3 J MA F Sme M J J and SA SA 2 In F 1J 1 Ma M 1J Ma M 5 Ma M 3 In F 2 Ma M 2 Mat F
2 1 1 23 1 10 5 4 3 3 9 1 1 1 3 1 3 2 4 8 4 90
(45◦ 46 30 South–60◦ 27 29 West). The known geographical distribution of this bobtail squid was western, southern, and eastern Africa (from Guinea and Somalia to the Cape of Good Hope), but doubtful in Chilean waters (Reid and Jereb, 2005). Therefore, this is the first time that the species is caught in the western part of the South Atlantic Ocean. The Carol bobtail squid Neorossia caroli (Joubin, 1902) was caught south more frequently than the previous bobtail squids (47◦ 32 60 South–60◦ 14 19 West) and in the deeper, cooler waters (Table 2) of the FMC. This species is represented on the Patagonian slope north of the Falkland (Malvinas) Islands by the subspecies N. caroli jeannae Nesis et al., 2001, while our specimen was recorded much further north than any other until now. The jewel squids Histioteuthis reversa (Verrill, 1880), H. atlantica (Hoyle, 1885), H. bonnelli (Férussac, 1834), and H. eltaninae N. Voss, 1969 caught are common in the area explored by our cruise, showing an already well-known vertical and geographic distribution inside the FMC (Voss et al., 1998). However, this is the most southern record (45◦ 13 52 South–59◦ 24 04 West) of Histioteuthis
arcturi (Robson, 1948), which had previously only been registered between 28◦ North and 25◦ South (Voss et al., 1998). To date, the known distribution of the squid Slosarczykonia circumantarctica was off Wilkes Land (Australian Antarctic Territory) and in circumpolar Antarctic waters (Lipinski and Young, http://tolweb.org/Slosarczykovia/24102). Our findings extend the geographical distribution area of the species towards the north and east of the SWA, occupying the western border of the FMC (from approximately 46◦ 54 South–59◦ 49 West to 45◦ 17 South–59◦ 33 West), at depths ranging from 881 to 1224 m, and SST and SBT between 11.9 and 2.3 ◦ C, respectively (Table 2). According to the map of the records of B. skolops provided by Young and Roper (http://tolweb.org/Batoteuthidae/19452), our record is the most northern for this species (44◦ 30 22 –44◦ 29 54 South). The glacial cranch squid Galiteuthis glacialis (Chun, 1906) is found throughout the circumpolar Antarctic waters where it is one of the most abundant (Nesis, 1987). According to the map given by Young and Mangold
Table 5 Cephalopod distribution in relation to Subtropical Zone (STZ), Patagonian shelf (PS), Falkland/Malvinas Current (FMC), Subantartic Zone (SAZ), Polar Frontal Zone (PFZ), Antarctic Zone (AZ). ×: previous papers: P: present paper. Species
PS
STZ
FMC
Semirossia patagonica Austrorossia mastigophora Neorossia caroli jeannae Gonatus antarcticus Histioteuthis arcturi Histioteuthis atlantica Histioteuthis bonnellii Histioteuthis eltaninae Histioteuthis reversa Chiroteuthis veranyii Slosarczykovia circumantarctica Onykia ingens Bathyteuthis abyssicola Batoteuthis skolops Galiteuthis glacialis Taonis pavo Graneledone antractica Graneledone macrotyla Thaumeledone gunteri Muusoctopus eureka Muusoctopus longibrachus akambei
×
P P
×
× × ×
×
×
×
×
×P ×P ×P ×P ×P ×P ×P P P P P ×P P P P P P ×P ×P
SAZ
PFZ
AZ
Authority Rodhouse et al., 1999; Reid and Jereb, 2005
×
×
×
× × × × × × ×?
× × × × × × ×
×? ×
×? ×
× × × × × × × × × ×
Nesis et al., 2001 Rodhouse et al., 1999; Nesis, 2003 Rodhouse et al., 1999 Voss et al., 1998; Nesis, 2003 Rodhouse et al., 1999 Voss et al., 1998 Nesis, 1987 Lipinski, 2001; Lipinski and Young tolweb Nesis, 1987; Vecchione et al. tolweb Nesis, 1987 Young and Roper, 1968; Rodhouse et al., 1999; Nesis, 2003 Nesis, 1987, 2003 Voss, 1980 Voss, 1976, 1988; Kubodera and Okutani, 1994 Voss, 1976, 1988; Kubodera and Okutani, 1994 Allcock et al., 2004 Gleadall et al., 2010 Gleadall et al., 2010
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Fig. 4. Falkland/Malvinas current in the January–March period (black arrows enclosed in white). Source: CIMAS, University of Miami, Rosenstiel School of Marine and Atmospheric Science, USA.
(http://tolweb.org/Galiteuthis glacialis/19572), our records are the first outside circumpolar Antarctic waters, thus expanding the geographical distribution of the species towards the north, at least until 44◦ 02 95 South. SST and SBT seem to indicate that this species was caught along the western border of the FMC. Type locality of Graneledone antarctica Voss, 1976 is the Ross Sea (74◦ 05 06 South, 175◦ 05 02 West) (Voss, 1976). However, Kubodera and Okutani (1994) captured 1 specimen at 45◦ 44 South, 59◦ 46 West at 858 m depth, which is close to our area of study and within the bathymetric range of our specimens (Table 3). Despite the resemblance of the Kubodera and Okutani specimen to G. antarctica, these authors did not risk identifying it as such. Their argument was that it was captured near the Crozet Islands at such a considerable distance that they hesitate to conclude that the material was conspecific. Nevertheless, the coordinates of capture that the authors give twice (their Table 1 and on page 214) do not correspond to these islands but to the Patagonian shelf or south-eastern Argentinean EEZ waters, where they also obtained some samples. Our specimens (1 juvenile and 2 immature females, Table 4) share the diagnostic characters of the species. Considering this information, we therefore believe that the species is present off the Patagonian shelf at depths of 1156–1461 (Table 3) and from 44◦ to 47◦ South. The species was found in the western boundary (59◦ 25 West) of the FMC, where the SST was 9.7 ◦ C and the SBT 2.4 ◦ C (Table 2). The large-tuberculate octopus Graneledone macrotyla Voss, 1976 was for many years only known by type-locality (54◦ 43 South, 55◦ 30 West in 1647–2044 m) (Voss, 1976, 1988). However, the
collection studied by Kubodera and Okutani (1994) extended the known distribution of the species to the north of 45◦ South along south-eastern Argentina, at depths ranging from 858 to 2044 m, which agrees with the latitudinal distribution shown by the present sample (from 45◦ to 47◦ South). The western range where this species was caught (59◦ 32 –60◦ 01 West) and the SST and SBT (Table 2) suggest that it inhabits the northern part of the FMC. Our 4 mature males of Thaumeledone gunteri Robson, 1930 share the main characters given by Allcock et al. (2004). These authors indicated that the distribution of this species is probably restricted to South Georgia and Shang Rocks at a depth of 366–964 m and probably deeper. However, we found this inkless octopus further north, at depths ranging from 855 to 1190 m, with a sea surface temperature of 9.6 ◦ C, and a sea bottom temperature of 2.6 ◦ C (Table 3). Laptikhovsky (2001) reported 32 females of Benthoctopus eureka collected on the Falkland (Malvinas) shelf (48◦ 40 –52◦ 59 South, 56◦ 51 –60◦ 15 West, depth range 125–344 m) during expeditions on board the RV Dorada. Gleadall et al. (2010) are currently proposing a new taxonomic combination for eureka, which is Muusoctopus eureka (Robson, 1929). The species was caught in the same area explored by our cruise. However, the specimens were mainly on the 200 m depth contour (Gleadall et al., 2010), whereas the bathymetric range of the 8 specimens included in this paper was 111–1156 m. Therefore, it seems that this species is adapted to a relatively wide range of temperature, possibly from 8 ◦ C to −0.8 ◦ C (Tables 2 and 5). Previously known specimens of M. longibrachus akambei (holotype and paratypes) were caught on different cruises around 49◦ 22 South and between 59◦ 10 and 66◦ 70 West from 147 to 377 m
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depth off the coastal waters of Argentina (Gleadall et al., 2010). The specimens presented in this paper were captured about 140 nautical miles to the north (46◦ 53 98 South), at a similar western longitude (59◦ 48 –60◦ 39 West), and in deeper waters (428–921 m) (see Table 3). From a biogeographic point of view our data show that several species, mainly benthic octopuses (Table 5), penetrate the area studied with the plume of cold sub-Antarctic waters and are pushed far into the South Atlantic by the FMC (Fig. 4). This concurs with observations by Strugnell et al. (2008), who showed that the deepsea lineage had their evolutionary origins in Antarctica. We suggest that sampling in the near future should be attempted on either side of this plume, in regions where there is no Antarctic water, in order to test the presence of cold water-adapted species. Acknowledgements We would like to extend our warmest thanks to authorities of the Spanish Secretaría General del Mar (SGM, General Secretary for the Sea) who owned the research vessel. We are also very grateful to Dr. Ian Cleadall for his useful comments on the original manuscript and to María Teresa Fernández Álvarez (IIM, CSIC) for her technical assistance. We would also like to thank the crew of the vessel, the scientific staff, and Raúl Vilela for his assistance with GIS tools. References Allcock, A.L., Collins, M.A., Piatkowski, U., Vecchione, M., 2004. Thaumeledone and other deep water octopodids from the Southern Ocean. Deep-Sea Res. Part II 51, 1883–1901. Agnew, D.J., Baranowski, R., Beddington, J.R., des Clers, S., Nolan, C.P., 1998. Approaches to assessing stocks of Loligo gahi around the Falkland Islands. Fish. Res. 35, 155–169. Agnew, D., Hill, S.L., Beddington, J.R., Purchase, L.V., Wakeford, R.C., 2005. Sustainability and management of Southwest Atlantic squid fisheries. Bull. Mar. Sci. 76, 579–593. Arkhipkin, A., Grzebielec, R., Sirota, A.M., Remeslo, A.V., Polishchuk, I.A., Middleton, D.A.J., 2004. The influence of seasonal environmental changes on ontogenetic migrations of the squid Loligo gahi on the Falkland shelf. Fish. Oceanogr. 13, 1–9. Basson, M., Beddington, J.R., Crombie, J.A., Holden, S.J., Purchase, L.V., Tingley, G.A., 1996. Assessment and management techniques for migratory annual squid stocks: the Illex argentinus fishery in the Southwest Atlantic as an example. Fish. Res. 28, 3–27. ´ Bazzino, G., Quinones, R.A., Norbis, W., 2005. Environmental associations of shortfin squid Illex argentinus (Cephalopoda: Ommastrephidae) in the Northern Patagonian Shelf. Fish. Res. 76, 401–416. Brunetti, N.E., Ivanovic, M.L., Sakai, M., 1999. Calamares de importancia comercial en la Argentina. Biología, distribución, pesquerías, muestreo biológico. Instituto Nacional de Investigación y Desarrollo Pesquero (INIDEP), Mar del Plata, Argentina, 45 p. Cooperative Institute for Marine and Atmospheric Studies (CIMAS), University of Miami. http://oceancurrents.rmas.miami.edu. Campos, E.J.D., Jerry, L., Miller, J.L., Müller, T.J., Peterson, R.G., 1995. Physical oceanography of the Southwest Atlantic Ocean. Oceanography 8, 87–91. Deacon, G., 1984. The Antarctic Circumpolar Ocean. Cambridge University Press. Gleadall, I.G., Guerrero-Kommritz, J., Hochberg Jr., F.G., Laptikhovsky, V.V., 2010. The inkless octopuses (Cephalopoda: Octopodidae) of the Southwest Atlantic. Zool. Sci. 27, 528–553. Glorioso, P.D., 1987. Temperature distribution related to shelf-sea fronts on the Patagonian shelf. Cont. Shelf Res. 7, 27–34. Guerra, A., González, A.F., Cherel, Y., 2000. Graneledone gonzalezi sp. nov. (Mollusca: Cephalopoda): a new octopod from the Îlles Kerguelen. Antarct. Sci. 12, 33–40.
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