Superregnum: Eukaryota
Regnum: Animalia
Subregnum: Eumetazoa
Cladus: Bilateria
Cladus: Nephrozoa
Superphylum: Deuterostomia
Phylum: Chordata
Cladus: Craniata
Subphylum: Vertebrata
Infraphylum: Gnathostomata
Megaclassis: Osteichthyes
Superclassis/Classis: Actinopterygii
Classis/Subclassis: Actinopteri
Subclassis/Infraclassis: Neopterygii
Infraclassis: Teleostei
Megacohors: Osteoglossocephalai
Supercohors: Clupeocephala
Cohors: Euteleosteomorpha
Subcohors: Neoteleostei
Infracohors: Eurypterygia
Section: Aulopa
Ordo: Aulopiformes
Subordo: Alepisauroidei
Familia: Alepisauridae
Genus: Anotopterus
Species (3): A. nikparini – A. pharao – A. vorax
Name
Anotopterus Zugmayer, 1911
References
Joseph S. Nelson: Fishes of the World. John Wiley & Sons, 2006. ISBN 0-471-25031-7.
Anotopterus – Taxon details on Integrated Taxonomic Information System (ITIS).
The daggertooths (genus Anotopterus) are a genus of marine mesopelagic fish in the order Aulopiformes, the sole genus of the family Anotopteridae. They are found in oceans worldwide, but prefer cooler waters.[1]
Description
Daggertooths are similar in appearance to the related lancetfishes and barracudina. They are elongate, silvery, predatory marine fishes that lack scales and have sharp teeth likely used for hunting fishes. However, as their scientific name (meaning "without fins on its back") suggests, they lack dorsal fins which easily differentiates them from their close allies, especially the similar looking lancetfishes. Another feature that distinguishes daggertooths from lancetfishes are the placement of the large, fang-like teeth. In lancetfishes, the fangs appear on both the upper and lower jaws while in daggertooths the fangs are only seen along the upper jaw. Whether it is the fangs or the distinctly protruding mandible that inspired the common name "daggertooth" remains unclear. Anotopterus spp. have been reported to grow to as long as 147 cm (4.82 ft). The skin of daggertooths makes them highly refractive to light. Like their close relatives, they lack swim bladders.
A daggertooth trawled from the mesopelagic near Bear's Seamount in the North Atlantic. The Yellow coloration in this photo is actually the yellow of a hi-vis life jacket reflecting off of the silvery skin of this fish. Photo by Dr. Jon A. Moore
Species and taxonomy
The currently recognized species in this genus are:[2]
Anotopterus nikparini, Kukuev, 1998 (North Pacific daggertooth)
Anotopterus pharao, Zugmayer, 1911 (daggertooth)
Anotopterus vorax, Regan, 1913 (south ocean daggertooth)
A possible fourth species was discovered in 2008, but has yet to receive a taxonomic name.[3]
Anotopterus has long been considered a unique taxonomic family with close affinity to the families Paralepididae and Alepisauridae. Recent Bayesian assessment of fossil records, taxonomic relationships and four key molecular markers have determined a much closer kinship between Anotopterus to basal Paralepididae, like Magnisudis spp., with the implication being that the genus Anotopterus might more appropriately be considered a member of the barracudina family, Paralepididae.[4]
Ecology and life history
The form of Anotopterus suggests that of a swift swimmer, at least of a fish that can dart through water quickly for short distances, like some of its closest relatives in Paralepididae have been reported to do. Like its close cousins, it is likely that these fishes readily avoid collecting nets at the depths they most frequently occur in the mesopelagic, especially larger individuals. Daggertooth are predators of other fishes and are prey to larger fishes including its close cousins the lancetfishes.[5]
Very little is known about the feeding habits of daggertooths, although they have been said to eat young Pacific salmon, barracudina, and other mesopelagic fishes and it is generally assumed that they predate the most abundant fishes available. This ignorance of diet is partly due to the potential prevalence of regurgitation among net caught specimens, where nearly 100% of net caught daggertooths were documented with completely empty stomachs, the supposed reason being the regurgitation of freshly eaten food upon capture in nets as a defense mechanism.[6] They are likely visually based predators and adult individuals can easily engulf relatively large prey, fishes with 20–30 cm fork length, whole due to their unattached pectoral girdles and distensible stomachs. Observations of slash marks on numerous young Pacific salmon in the northern Pacific prompted an investigation into the potential impact of daggertooth depredation on young salmon stocks by assessment of the tooth marks left on the salmon and estimations of daggertooth abundance. The subsequent findings showed that slashes from failed daggertooth attacks could be distinguished from failed lancetfish attacks by the placement of the tooth marks, as daggertooths only have fang-like teeth along their upper jaw while lancetfish have fang like teeth along both the upper and lower jaws.[6] Whether daggertooth have a significant impact on northern Pacific Salmon stock remained inconclusive.[7]
It has been noted that as daggertooths age their teeth begin to diminish and their stomachs and intestines atrophy while their gonads increase greatly in size.[5] This observed, ontogenetic shift hints to a potentially semelparous reproductive modality, while this aspect of life history has not yet been fully substantiated. Like their relatives, it is thought that daggertooths are simultaneous hermaphrodites while their spawning and actual reproductive behavior remains a mystery.
Close up of an Anotopterus pharao and its "daggertooth". Collected from Bear's Seamount in the western North Atlantic. Photo by Dr. Jon A. Moore
Hubbs et al., (1953) speculated that daggertooths have an anti-tropical distribution and live in temperate and boreal latitudes at either pole.[8] Later work investigating the distributional overlap between daggertooths and Pacific salmon (Oncorhynchus sp.) seemed to verify this assertion although some lack of findings pointed to a spotty distribution in certain pole-ward regions.[7] Counter to this assumption, however, are the findings of Kim et al. (1997) who discovered that daggertooths can comprise a sizable portion of the diets of deep diving tuna in certain areas of the tropical, west Pacific.[9] It is possible that the latitudinal distribution of daggertooths is anti-tropical in the epipelagic with preferred temperatures being available at depth worldwide, which would also explain the conservation of such few species with near global distributions.[10]
References
Johnson, R.K.; Eschmeyer, W.N. (1998). Paxton, J.R.; Eschmeyer, W.N. (eds.). Encyclopedia of Fishes. San Diego: Academic Press. p. 126. ISBN 0-12-547665-5.
Froese, Rainer and Pauly, Daniel, eds. (2012). Species of Anotopterus in FishBase. February 2012 version.
Stewart, Andrew. "Science report: Denizens of the deep: daggertooth and stareater." IPY-CAML Voyage 2008. Ministry of Fisheries. Crown Copyright: 2008.
Davis, M.P.; Fielitz, C. (2010). "Estimating divergence times of lizardfishes and their allies (Euteleostei: Aulopiformes) and the timing of deep-sea adaptations". Molecular Phylogenetics and Evolution. 57: 1194–1208. doi:10.1016/j.ympev.2010.09.003. PMID 20854916.
Rofen R.R. (1966). Olsen, Y.H. & Atz, J.W. (eds.). Fishes of the Western North Atlantic Number 1. Part 5. New Haven: Yale University. pp. 482–497.
Radchenko, V.I.; Semenchenko, A.Y. (1996). "Predation of doggertooth on immature Pacific salmon". Journal of Fish Biology. 49: 1323–1325. doi:10.1111/j.1095-8649.1996.tb01799.x.
Nagasawa, K.; Azumaya, T.; Ishida, Y (2010). "Impact of Predation by Salmon Sharks (Lamna ditropis) and Daggertooths (Anotopterus nikparini) on Pacific Salmon (Oncorhynchus spp.) Stocks in the North Pacific Ocean". NPAFC Technical Report. 4: 51–52.
Hubbs, C.L.; Mead, G.W. & Wilmovsky, N.J. (1953). Zobell, C.D.; Fox, D.L. & Munk,W.H. (eds.). The Widespread, Probably Antitropical Distribution and the Relationship of the Bathypelagic Iniomous Fish Anotopterus Pahrao. Berkeley and Los Angeles: University of California Press. pp. 173–191.
Kim, J.C.; Moon, D.Y.; Kwon, J.N.; Kim, T.I.; Jo, H.S. (1997). "Diets of Bigeye and Yellowfin tunas in the Western Tropical Pacific". Korean Journal of Fisheris and Aquatic Sciences. 30 (5): 719–729.
Haedrich, R.L. (1997). Randall, D.P. (ed.). Deep-Sea Fishes. 16th edition. San Diego: Academic Press. pp. 79–115.
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