Beaked whale

Beaked whales are a group of cetaceans noted as being one of the least known groups of mammals because of their deep-sea habitat and apparent low abundance.[1] Only three to four of the 22 species are reasonably well-known. Baird's beaked whales and Cuvier's beaked whales were subject to commercial exploitation, off the coast of Japan, while the northern bottlenose whale was extensively hunted in the northern part of the North Atlantic late in the 19th and early 20th centuries.[2]

Beaked whale
Temporal range: Miocene–Recent
Baird's beaked whale (Berardius bairdii)
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Artiodactyla
Infraorder: Cetacea
Superfamily: Ziphioidea
Family: Ziphiidae
Gray, 1850
Genera

See text

Synonyms
  • Hyperoodontidae Gray, 1850

Physical characteristics

Blainville's beaked whale

Beaked whales are moderate in size, ranging from 4.0 to 13 metres (13.1 to 42.7 ft) and weighing from 1.0 to 15 tonnes (0.98 to 14.76 long tons; 1.1 to 16.5 short tons). Their key distinguishing feature is the presence of a 'beak', somewhat similar to many dolphins. Other distinctive features include a pair of converging grooves under the throat, and the absence of a notch in the tail fluke. Although Shepherd's beaked whale is an exception, most species have only one or two pairs of teeth, and even these do not erupt in females. Beaked whale species are often sexually dimorphic  one or the other sex is significantly larger. The adult males often possess a large bulging forehead.[3] However, aside from dentition and size, very few morphological differences exist between male and female beaked whales.[4]

Individual species are very difficult to identify in the wild, since body form varies little from one species to another. The observer must rely on often subtle differences in size, color, forehead shape, and beak length.

The blubber of these whales is almost entirely (94%) composed of wax ester, a unique characteristic of this family.[5]

Dentition

Beaked whales are unique among toothed whales in that most species only have one pair of teeth. The teeth are tusk-like, but are only visible in males, which are presumed to use these teeth in combat for females for reproductive rights. In females, the teeth do not develop and remain hidden in the gum tissues.[6]

In December 2008, researchers from the Marine Mammal Institute at Oregon State University completed a DNA tree of 13 of 15 known species of Mesoplodon beaked whales (excluding spade-toothed whale, which was then only known from a skeletal and a few stranded specimens). Among the results of this study was the conclusion that the male's teeth are actually a secondary sexual characteristic, similar to the antlers of male deer. Each species' teeth have a characteristically unique shape. In some cases, these teeth even hinder feeding; in the strap-toothed whale, for example, the teeth curve over the upper jaw, effectively limiting the gape to a few centimeters. Females are presumed to select mates based on the shape of the teeth, because the different species are otherwise quite similar in appearance.[6]

The social structure is not well known, but sightings of single males accompanying multiple females suggest a polygynous mating system, which would considerably limit the number of males a female can choose.[6]

Taxonomy

Beaked whales comprise at least 22 species of small whales in the family Ziphiidae, which is one of the least-known families of large mammals; several species have been described only in the last two decades. Six genera have been identified.

The beaked whales are the second-largest family of cetaceans (after the dolphins). They were one of the first groups to diverge from the ancestral lineage. The earliest known beaked whale fossils date to the Miocene, about 15 million years ago.[7]

Arnoux's beaked whale

Evolutionary history

As many as 26 genera antedate humans.[1][10] Some included ancestors of giant beaked whales (Berardius), such as Microberardius and Cuvier's beaked whale (Ziphius) had many relatives, such as Caviziphius, Archaeoziphius, and Izikoziphius. They were probably preyed upon by predatory whales and sharks, including Carcharocles megalodon. Recently, a large fossil ziphiid sample was discovered off the South African coast, confirming the extant ziphiid diversity might just be a remnant of a higher past diversity. After studying numerous fossil skulls off the shore of South Africa, researchers discovered the absence of functional maxillary teeth in all South African fossil ziphiids, which is evidence that suction feeding had already developed in several beaked whale lineages during the Miocene. Researchers also found fossil ziphiids with robust skulls, signaling that tusks were used for male-male interactions (speculated with extant beaked whales).[1]

Ecology

Diving

Beaked whales are deep divers with extreme dive profiles.[11] They regularly dive deeper than 500 m (1,600 ft) to echolocate for food, and these deep dives are often followed by multiple shallower dives less than 500 m.[12] This pattern is not always followed, however. Animals have been observed spending more than an hour at or near the surface breathing. Beaked whales are often seen surfacing synchronously, but asynchronous surfacing has also been observed.[13] In March 2014, a study by Cascadia Research revealed that beaked whales were recorded to dive at least 2992 m in depth and lasting as long as 137.5 minutes, both mammalian records (Cuvier's).[14]

Deep-diving mammals face a number of challenges related to extended breath-holding and hydrostatic pressure. Cetaceans and pinnipeds that prolong apnea must optimize the size and use of their oxygen stores, and they must deal with the accumulation of lactic acid due to anaerobic metabolism.[11] Beaked whales have several anatomical adaptations to deep diving: large spleens, livers, and body shape. Most cetaceans have small spleens. However, beaked whales have much larger spleens than delphinids, and may have larger livers, as well. These anatomical traits, which are important for filtering blood, could be adaptations to deep diving. Another notable anatomical adaptation among beaked whales is a slight depression in the body wall that allows them to hold their pectoral flippers tightly against their bodies for increased streamlining.[4] However, they are not invulnerable to the effects of diving so deep and so often. Cascadia Research shows that the deeper the whales dive, the less often they dive per day, cutting their efforts by at least 40%.[14]

The challenges of deep diving are also overcome by the unique diving physiology of beaked whales. Oxygen storage during dives is mostly achieved by blood hemoglobin and muscle myoglobin.[12] While the whale is diving, its heart rate slows and blood flow changes. This physiological dive response ensures oxygen-sensitive tissues maintain a supply of oxygen, while those tissues tolerant to hypoxia receive less blood flow. Additionally, lung collapse obviates the exchange of lung gas with blood, likely minimizing the uptake of nitrogen by tissues.[4]

Feeding

The throats of all beaked whales have a bilaterally paired set of grooves that are associated with their unique feeding mechanism, suction feeding.[4] Instead of capturing prey with their teeth, beaked whales suck it into their oral cavity. Suction is aided by the throat grooves, which stretch and expand to accommodate food. Their tongues can move very freely. By suddenly retracting the tongue and distending the gular (throat) floor, pressure immediately drops within the mouth, sucking the prey in with the water.

Dietary information is available from stomach contents analyses of stranded beaked whales and from whaling operations. Their preferred diet is primarily deep-water squid,[6] but also benthic and benthopelagic fish and some crustaceans, mostly taken near the sea floor.[13] In a recent study, gouge marks in the sea floor were interpreted to be a result of feeding activities by beaked whales.[15]

To understand the hunting and foraging behavior of beaked whales, researchers used sound and orientation recording devices on two species: Cuvier's beaked whale (Ziphius cavirostris) and Blainville's beaked whale (Mesoplodon densirostris). These whales hunt by echolocation in deep water (where the majority of their prey is located) between about 200 and 1,885 m (656 and 6,184 ft) and usually catch about 30 prey per dive. Cuvier's beaked whales must forage on average at 1,070 m (3,510 ft) for 58 minutes and Blainville's beaked whales typically forage at 835 m (2,740 ft) deep for an average of 47 minutes.[11]

Range and habitat

The family Ziphiidae is one of the most widespread families of cetaceans, ranging from the ice edges at both the north and south poles, to the equator in all the oceans.[16] Specific ranges vary greatly by species, though beaked whales typically inhabit offshore waters that are at least 300 m deep.

Beaked whales are known to congregate in deep waters off the edge of continental shelves, and bottom features, such as seamounts, canyons, escarpments, and oceanic islands, including the Azores and the Canary Islands,[13] and even off the coasts of Hawaii.[14]

Life history

Very little is known about the life history of beaked whales. The oldest recorded age is 84 years for a male Baird's beaked whale and 54 years for a female. For all other beaked whale species studied, the oldest recorded age is between 27 and 39 years. Sexual maturity is reached between seven and 15 years of age in Baird's beaked whales and northern bottlenose whales. Gestation varies greatly between species, lasting 17 months for Baird's beaked whales and 12 months for the northern bottlenose whale.[17] No data are available on their reproductive rates.

Determining group size for beaked whales is difficult, due to their inconspicuous surfacing behavior. Groups of beaked whales, defined as all individuals found in the same location at the same time, have been reported as ranging from one to 100 individuals. Nevertheless, some populations' group size has been estimated from repeated observations. For example, northern and southern bottlenose whales (H. ampullatus and H. planifrons), Cuvier's beaked whales, and Blainville's beaked whales (Mesoplodon densirostris) have a reported maximum group size of 20 individuals, with the average ranging from 2.5 to 3.5 individuals. Berardius species and Longman's beaked whales (Indopacetus pacificus) are found in larger groups of up to 100 individuals.[13]

Not much information is available about group composition of beaked whales. Only three species have been studied in any detail: northern bottlenose whales, Blainville's beaked whales, and Baird's beaked whales. Female northern bottlenose whales appear to form a loose network of social partners with no obvious long-term associations. In contrast to females, some male northern bottlenose whales have been repeatedly recorded together over several years, and possibly form long-term associations. Studies of Blainville's beaked whales have revealed groups usually consist of a number of females, calves, and/or juvenile animals. These whales are assumed to live in "harem-like" groups, where several females and young are accompanied by a single male.[6] Baird's beaked whales are known to occur in multiple male groups, and in large groups consisting of adult animals of both sexes. Arnoux’s beaked whales have also been observed to form large pods of up to 47 individuals off the Southern Ocean off the coast of Kemp Land, Antarctica.[18]

Conservation

For many years, most beaked whale species were insulated from anthropogenic impacts because of their remote habitat. However, now several issues of concern include:

  • Studies of stranded beaked whales show rising levels of toxic chemicals in their blubber.[19]
  • As a top predator, beaked whales, like raptors, are particularly vulnerable to build-up of biocontaminants. They can ingest plastic (which can be lethal).[13]
  • They more frequently become trapped in trawl nets, due to the expansion of deepwater fisheries.[20]
  • Decompression sickness

A major conservation concern for beaked whales (family Ziphiidae) is they appear to be vulnerable to modern sonar operations, which arises from recent strandings that temporally and physically coincide with naval sonar exercises.[21] Mid-frequency active sonar (MFAS), developed in the 1950s for submarine detection, is thought to induce panic in when experienced by whales at depth.[22] This raises their heart-rates, forcing them to attempt to rapidly ascend toward the surface in search of air. This artificially-induced rapid ascent can cause decompression.[22]

Post mortem examinations of the stranded whales in concurrence with naval exercises have reported the presence of hemorrhaging near the ears or gas and fat emboli, which could have a deleterious impact on beaked whales that is analogous to decompression sickness in humans.[12] Gas and fat emboli have been shown to cause nervous and cardiovascular system dysfunction, respiratory distress, pain, and disorientation in both humans and animals.[21] In the inner ear, gas embolism can cause hemorrhages, leading to disorientation or vestibular dysfunction.

Breath-holding divers, like beaked whales, can develop decompression-related problems (the "bends") when they return to the surface after deep dives.[11] This is a possible hypothesis for the mass strandings of pelagic beaked whales associated with sonar-related activities. To illustrate, a diving beaked whale may be surfacing from a deep dive and must pass vertically through varying received sound levels. Since the whale has limited remaining oxygen supplies at the end of a long dive, it probably has limited abilities to display any normal sound avoidance behavior. Instead, the whale must continue to swim towards the surface to replenish its oxygen stores.[13] Avoiding sonar inevitably requires a change in behavior or surfacing pattern. Therefore, sonar in close proximity to groups of beaked whales has the potential to cause hemorrhaging or to disorient the animal, eventually leading to a stranding.

Current research reveals two species of beaked whales are most affected by sonar: Cuvier's (Z. cavirostris) and Blainville's (M. densirostris) beaked whales. These animals have been reported as stranding in correlation with military exercises in Greece, the Bahamas, Madeira, and the Canary Islands.[23] The livers of these animals had the most damage.[24]

In 2019, a review of evidence on the mass strandings of beaked whale linked to naval exercises where sonar was used was published. It concluded that the effects of mid-frequency active sonar are strongest on Cuvier's beaked whales but vary among individuals or populations, and the strength of their response may depend on whether the individuals had prior exposure to sonar. The report considered that the most plausible explanation of the symptoms of decompression sickness such as gas embolism found in stranded whales to be the whales' response to sonar. It noted that no more mass strandings had occurred in the Canary Islands once naval exercises where sonar was used were banned there, and recommended that the ban be extended to other areas where mass strandings continue to occur.[25][26]

Four species are classified by the IUCN as "lower risk, conservation dependent": Arnoux's and Baird's beaked whales, and the northern and southern bottlenose whales. The status of the remaining species is unknown, preventing classification.[27]

Captivity

Beaked whales live very short lives in captivity when compared to other cetaceans such as common bottlenose dolphins and short-finned pilot whales,[28] most surviving only a few days out of the ocean.[29] The longest time period for a beaked whale living in captivity was 25 days. Alexander and Nicholas, two male beaked whales—their species unknown, though they were thought to be either Hubbs' beaked whale or Blainville's beaked whale—had become stranded in California on 24 August 1989. They were taken to Marine World California.[30] Both of the whales would die of pneumonia; Nicholas died on 8 September and Alexander died 10 days later.[31]

A handful of other beaked whales have been briefly kept in captivity. A juvenile female Cuvier's beaked whale was found stranded on a kelp bed off of Santa Catalina Island on February 23rd, 1956. She was taken to Marineland of the Pacific, where she was named Martha Washington.[32] On June 16th, 1969, a Cuvier's beaked whale live stranded in St. Augustine. The whale, thought to be a male, was then transported to Marineland of Florida. It’s unknown what happened to the whale, but it was still alive on June 18th, 1969.[33]

gollark: Blame SCP-3125.
gollark: [REDACTED]
gollark: ++delete <@319753218592866315>
gollark: Nobody, not everything has to be weird and NSFW.
gollark: What happened to sleep?

References

  1. Bianucci, Giovanni; Post, Klaas; Lambert, Olivier (2008). "Beaked whale mysteries revealed by seafloor fossils trawled off South Africa". South African Journal of Science. 104 (3–4): 140–142. Retrieved 11 January 2014.
  2. Government of Canada, Environment. "Recovery Strategy for the Northern Bottlenose Whale (Hyperoodon ampullatus), Scotian Shelf population, in Atlantic Canadian Waters - Species at Risk Public Registry". www.registrelep-sararegistry.gc.ca. Retrieved 27 April 2018.
  3. Christensen, Ivar (1984). Macdonald, David W. (ed.). The Encyclopedia of Mammals. New York: Facts on File. pp. 210–211. ISBN 978-0-87196-871-5. OCLC 10403800.CS1 maint: ref=harv (link)
  4. Rommel, S. A.; Costidis, A. M.; Fernandez, A.; Jepson, P. D.; Pabst, D. A.; McLellan, W. A.; Houser, D. S.; Cranford, T. W.; van Helden, A. L.; Allen, D. M.; Barros, N. B. (2006). "Elements of beaked whale anatomy and diving physiology and some hypothetical causes of sonar-related stranding" (PDF). Journal of Cetacean Research and Management. 7 (3): 189–209. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  5. Litchfield, Carter; Greenberg, Anne J.; Caldwell, David K.; Caldwell, Maria C.; Sipos, J. C.; Ackman, R. G. (1975). "Comparative lipid patterns in acoustical and nonacoustical fatty tissues of dolphins, porpoises and toothed whales". Comparative Biochemistry and Physiology B. 50 (4): 591–7. doi:10.1016/0305-0491(75)90095-4. OCLC 733963359. PMID 1122741.CS1 maint: ref=harv (link)
  6. Dalebout, Merel L.; Steel, Debbie; Baker, C. Scott (2008). "Phylogeny of the Beaked Whale Genus Mesoplodon (Ziphiidae: Cetacea) Revealed by Nuclear Introns: Implications for the Evolution of Male Tusks" (PDF). Systematic Biology. 57 (6): 857–875. doi:10.1080/10635150802559257. PMID 19085329. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  7. Lambert, Olivier (2006). "Archaeoziphius microglenoideus, a new primitive beaked whale (Mammalia, Cetacea, Odontoceti) from the Middle Miocene of Belgium". Journal of Vertebrate Paleontology. 26: 182–191. doi:10.1671/0272-4634(2006)26[182:AMANPB]2.0.CO;2.
  8. Yamada, Tadasu K.; Kitamura, Shino (30 August 2019). "Description of a new species of beaked whale (Berardius) found in the North Pacific". Scientific Reports. 9 (1): 12723. Bibcode:2019NatSR...912723Y. doi:10.1038/s41598-019-46703-w. PMC 6717206. PMID 31471538.
  9. Dalebout, Merel L. (2014). "Resurrection of Mesoplodon hotaula Deraniyagala 1963: A new species of beaked whale in the tropical Indo-Pacific". Marine Mammal Science. 30 (3): 1081–1108. doi:10.1111/mms.12113. hdl:1957/51503.
  10. Bianucci, Giovanni; Miján, Ismael; Lambert, Olivier; Post, Klaas; Mateus, Octávio (2013). "Bizarre fossil beaked whales (Odontoceti, Ziphiidae) fished from the Atlantic Ocean floor off the Iberian Peninsula". Geodiversitas. 35 (1): 105–153. doi:10.5252/g2013n1a6. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  11. Tyack, Peter L.; Johnson, Mark; Soto, Natacha Aguilar; Sturlese, Albert; Madsen, Peter T. (2006). "Extreme diving of beaked whales". Journal of Experimental Biology. 209 (21): 4238–4253. doi:10.1242/jeb.02505. PMID 17050839.CS1 maint: ref=harv (link)
  12. Zimmer, Walter M. X.; Tyack, Peter L. (2007). "Repetitive shallow dives pose decompression risk in deep-diving beaked whales". Marine Mammal Science. 23 (4): 888–925. doi:10.1111/j.1748-7692.2007.00152.x.CS1 maint: ref=harv (link)
  13. MacLeod, Colin D.; D'Amico, Angela (2006). "A review of beaked whale behavior and ecology in relation to assessing and mitigating impacts of anthropogenic noise" (PDF). Journal of Cetacean Research and Management. 7 (3): 211–221. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  14. http://www.cascadiaresearch.org/reports/Schorretal2014.pdf.
  15. Auster, Peter J.; Watling, Les (2010). "Beaked whale foraging areas inferred by gouges in the seafloor". Marine Mammal Science. 26 (1): 226–233. doi:10.1111/j.1748-7692.2009.00325.x.CS1 maint: ref=harv (link)
  16. MacLeod, Colin D.; Perrin, William F.; Pitman, Robert; Barlow, Jay; Ballance, Lisa; D'Amicon, Angela; Gerrodette, Tim; Joyce, Gerald; Mullin, Keith D.; Palka, Debra L.; Waring, Gordon T. (2006). "Known and inferred distributions of beaked whales" (PDF). Journal of Cetacean Research and Management. 7 (3): 271–286. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  17. Mead, James G. (1984). "Survey of reproductive data for the beaked whales (Ziphiidae)" (PDF). Reports of the International Whaling Commission (Special Issue 6): 91–96. Retrieved 11 January 2014.CS1 maint: ref=harv (link) (PDF from IWC)
  18. Rogers, Tracey L.; Brown, Sarah M. (1970). "Acoustic observations of Arnoux's beaked whale (Berardius arnuxii) off Kemp Land, Antarctica". Marine Mammal Science. 15: 192–198. doi:10.1111/j.1748-7692.1999.tb00789.x.
  19. Law, R. J.; Allchin, C. R.; Jones, B. R.; Jepson, P. D.; Baker, J. R.; Spurrier, C. J. H. (1997). "Metals and organochlorines in tissues of a Blainville's beaked whale (Mesoplodon densirostris) and a killer whale (Orcinus orca) stranded in the United Kingdom". Marine Pollution Bulletin. 34 (3): 208–212. doi:10.1016/S0025-326X(96)00148-8.CS1 maint: ref=harv (link)
  20. Fertl, D.; Leatherwood, S. (1997). "Cetacean interactions with trawls: a preliminary review" (PDF). Journal of Northwest Atlantic Fishery Science. 22: 219–248. doi:10.2960/j.v22.a17. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  21. Fernández, A.; Edwards, J. F.; Rodríguez, F.; Espinosa de los Monteros, A.; Herráez, P.; Castro, P.; Jaber, J. R.; Martín, V.; Arbelo, M. (2005). ""Gas and Fat Embolic Syndrome" involving a mass stranding of beaked whales (family Ziphiidae) exposed to anthropogenic sonar signals". Veterinary Pathology. 42 (4): 446–457. doi:10.1354/vp.42-4-446. PMID 16006604.CS1 maint: ref=harv (link)
  22. "Sonar can scare whales to death, study shows. But scientists have a possible fix". NBC News.
  23. Faerber, Meghan M.; Baird, Robin W. (2010). "Does a lack of observed beaked whale strandings in military exercise areas mean no impacts have occurred? A comparison of stranding and detection probabilities in the Canary and main Hawaiian Islands" (PDF). Marine Mammal Science. 26 (3): 602–613. doi:10.1111/j.1748-7692.2010.00370.x. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  24. Jepson, P. D.; Arbelo, M.; Deaville, R.; Patterson, I. A. P.; Castro, P.; Baker, J. R.; Degollada, E.; Ross, H. M.; Herráez, P.; Pocknell, A. M.; Rodríguez, F.; Howie, F. E.; Espinosa, A.; Reid, R. J.; Jaber, J. R.; Martin, V.; Cunningham, A. A.; Fernández, A. (2003). "Gas-bubble lesions in stranded cetaceans: was sonar responsible for a spate of whale deaths after an Atlantic military exercise?" (PDF). Nature. 425 (6958): 575–576. Bibcode:2003Natur.425..575J. doi:10.1038/425575a. PMID 14534575. Retrieved 11 January 2014.CS1 maint: ref=harv (link)
  25. Bernaldo de Quirós Y, Fernandez A, Baird RW, Brownell RL Jr, Aguilar de Soto N, Allen D, Arbelo M, Arregui M, Costidis A, Fahlman A, Frantzis A, Gulland FMD, Iñíguez M, Johnson M, Komnenou A, Koopman H, Pabst DA, Roe WD, Sierra E, Tejedor M, Schorr G. (30 January 2019). "Advances in research on the impacts of anti-submarine sonar on beaked whales". Proceedings of the Royal Society B. 286 (1895): 20182533. doi:10.1098/rspb.2018.2533. PMC 6364578. PMID 30963955.CS1 maint: uses authors parameter (link)
  26. Batchelor, Tom (30 January 2019). "Scientists demand military sonar ban to end mass whale strandings". The Independent.
  27. "Cetacean update of the 2008 IUCN Red List of Threatened Species" (PDF). IUCN. 2008. Archived from the original (PDF) on 16 May 2013. Retrieved 11 January 2014.
  28. Reeves, R.; Leatherwood, S. (1984). "Live-Capture Fisheries for Cetaceans in U. S. and Canadian Waters, 1973–1982". Report of the International Whaling Commission. 34: 497–507.
  29. "Beaked Whales in Captivity". Ceta-Base Blog & Captive Cetacean News. Archived from the original on 5 October 2016. Retrieved 23 September 2016.
  30. "Rare Beaked Whale Takes Turn for the Worse". Schenectady Gazette. 29 August 1989. Retrieved 23 September 2016.
  31. "The second of two rare beaked whales that..." Orland Sentinel. 19 September 1989. Retrieved 23 September 2016.
  32. "Rare Young Whale Taken From Kelp Trap Near Catalina Adjusting Self To Aquarium". The San Bernardino County Sun. 23 February 1956. Retrieved 3 July 2020.
  33. "Beaked Whale Rare For Local Waters". Orlando Evening Star. 18 June 1969. Retrieved 3 July 2020.
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