Alexrogers Cbdcop7 Deepwatercorals Complete
Alexrogers Cbdcop7 Deepwatercorals Complete
Alexrogers Cbdcop7 Deepwatercorals Complete
Prepared by:
Alex Rogers, PhD.
British Antarctic Survey
©
Copyright: 2004 International Union for Conservation of Nature & Natural Resources
Executive Summary
Deep-sea coral reefs live in the cold, dark waters of the oceans but like
shallow water tropical coral reefs they have a distinct, diverse and
sometimes highly endemic associated animal community. These reefs
are under direct threat from deep-sea trawling and in some areas
have already been seriously impacted by fishing. At present there is no
protection for these habitats on the high seas.
• Deep -sea coral reefs can be very large and spectacular, the biggest is
over 40km long and 2-3km wide
• Deep -water reefs host the early life-stages of many deep-sea animals
including juvenile fish of commercial value
• The main threat to deep -sea coral reefs is trawling by modern fishing
vessels
• Deep -sea coral reefs are vulnerable to fishing because they are very
fragile and easily broken
• Deep -sea corals grow slowly; mature deep -sea coral reefs take many
thousands of years to accumulate
Deep -water coral reefs share many biological and physical features with
tropical shallow water reefs but there are significant differences as well. One
of the main differences is that tropical reef-building corals require light
because their tissues contain tiny symbiotic organisms that photosynthesise
and produce energy and valuable metabolites for the host. These
photosynthetic symbionts are called zooxanthellae and tropical shallow
water corals are therefore called zooxanthellate. Deep-water reef-forming
corals live in the dark and mainly live by preying on zooplankton that drift past
the coral framework on currents. They do not contain zooxanthellae and are
therefore termed azooxanthellate but they are hermatypic (i.e. they build
bioherms or reefs).
1
The cold-water reef-forming coral Lophelia pertusa was mentioned in Pontippidan E (1755) The
Natural History of Norway. A. Linde, London.
2
For example LeDanois E (1948) Les Profondeurs de la Mer. Payot, Paris, 303 pp.
3
Freiwald A (2002) Reef-forming cold-water corals. In: Wefer G, Billett D, Hebbeln D, Jørgensen BB
Schlüter M, Van Weering T (eds) Ocean Margin Systems. Springer-Verlag, Berlin Heidelberg. Pp 365-
385.
4
See Hallock P (1996) Reefs and reef limestones in Earth history. In: Birkeland C (Ed.) Life and Death
of Coral Reefs, Chapman & Hall, New York, pp 13-42.
Where are deep-water reef-forming corals found?
Our knowledge about the distribution of deep -water reefs is very poor and
largely based on detailed studies of a few species n i limited geographic
areas. Deep -water reef-forming corals have special environmental
requirements that determine where they are found. For example, they require
hard a hard surface on which to attach. This may be exposed rock or dead
coral framework but can be as small as a pebble or worm tube. Deep-water
corals are also associated with permanent or episodically strong currents. This
is because the corals rely on a vigorous flow of water to supply them with
food, disperse eggs, sperm and larvae, remove waste products and to keep
the surfaces of the coral free of sediments.
The requirement for a strong flow of water influences the distribution and
growth form of corals at all scales. They are often found on parts of the
continental slope or on the summits or summit rims of seamounts where
currents are strongest. On a smaller scale they favour pinnacles of rock,
basalt dikes, moraine ridges or the raised edges of ice -berg plough marks.
Such features cause currents to accelerate as they pass over them. Deep -
water corals are found beneath the local storm wave base though the depth
of their shallowest occurrence may also be determined by competitive
interactions with other animals, such as sponges, and marine algae. However,
they often occur in very shallow water (as little as 40m depth) in fjords
because of special conditions in these environments. Deep -water coral reefs
also tend to occur in areas with stable physical conditions with limited annual
variations in temperature and salinity. They are often associated with the most
salty water mass at a depth that often coincides with the zone in the water
column where oxygen is at its lowest concentration because of bacterial
activity 5.
The association of deep-water coral reefs with the upper part of the
continental slope and on seamounts may also reflect enhanced mixing of
shallow and deep water in these regions leading to increased surface
productivity. This in turn provides a good food supply for organisms feeding on
suspended particles and zooplankton and favours the growth of deep-water
reefs and the associated attached animals such as sponges and gorgonians.
The occurrence of reefs of the coral Lophelia pertusa in the north-eastern
Atlantic has also been suggested to be correlated with sub -surface faults and
other structures associated with low -level hydrocarbon seepage6. Some
animals with symbiotic bacteria can utilise hydrocarbons such as methane as
a source of energy and it has been suggested that Lophelia pertusa also uses
this resource. However, many occurrences of this coral are not associated
with hydrocarbon seepage and the chemical composition of the tissues of
the coral are not consistent with methane as a source of nutrition.
5
Freiwald A. et al., (2002) Facies 47: 179-200; See also Rogers A.D. (1999) International Review of
Hydrobiology 84 (4): 315-410.
6
Hovland M., Thomsen E., (1997) Marine Geology 137: 159-164.
Deep -water reef-forming corals are widely distributed in the world’s ocean
but the fairly precise environmental requirements of these organisms mean
that they only form reefs in specific localities, usually on the upper reaches of
the continental slope and on offshore ridges, plateaus, banks and seamounts.
Lophelia pertusa is at present the best -studied deep -water reef-forming coral.
In the northeast Atlantic it forms reefs and reef-mounds on the continental
slope and offshore banks between 200 and 1,000m depth and also occurs in
fjords as far north as 71 oN. Lophelia reefs have also been found further south
off the coast of West Africa and off the eastern coast of the United States and
Brazil. Along with Lophelia pertusa , the coral Enallopsammia profunda is also
a major component of the deep-water coral reefs on the Blake Plateau and
other areas in the north -western Atlantic.
The coral Solenosmilia variabilis is the main framework building coral of reefs
on the Tasman Seamounts south of Tasmania. These dramatic reefs have
been observed at between 1300 –1500m depth, with coral rubble across a
wider area7. Solenosmilia variabilis also appears to form extensive frameworks
in areas such as the Kermadec, Three Kings and Macquarie Ridges off New
Zealand, and possibly also on seamounts in the Heezen Fracture Zone in the
South Pacific. Again this species can occur in Lophelia reefs in the North
Atlantic contributing to the coral framework. The species Goniocorella
dumosa also forms deep -water coral reefs off New Zealand, particularly on
the Campbell Plateau most commonly in depths between 300 – 400m. This
coral also occurs on the Chatham Rise and off South Africa, Indonesia and
Japan.
Finally the species Oculina varicosa probably has the most restricted
geographic range and forms reefs between 50 – 100m depth off the coast of
Florida. This species is particularly interesting because in shallow water it
contains zooxanthellae, but deeper water reef-forming colonies are
azooxanthellate.
The formation of deep -water reefs is a poorly understood process and what
data is available at present mainly relates to one framework building species,
Lophelia pertusa. This species initially colonises a site as larvae that settle on
hard substrates. If conditions are suitable a larva will form a colony and as the
7
Koslow et al., (2001) Marine Ecology Progress Series 213: 111-125.
colony grows parts of the coral skeleton are attacked by boring organisms
such as sponges and worms. Pieces of the initial colony fall off as a result of
this process of bioerosion. As these are still alive they form daughter colonies
around the initial colony. This entire structure forms a hemispherical or
“cauliflower” shaped growth. Eventually the daughter colonies grow
sufficiently large that water circulation is cut off from the centre of the
growing coral framework and this then dies forming a characteristic ring-
shaped colony known as a “Wilson Ring”. Amongst the dead, eroded and
broken coral fragments sediment begins to accumulate, originating from the
action of bioeroding organisms breaking up the coral and by particulate
matter falling out of the water as it is slowed down by the coral framework.
These structures coalesce to form mature deep -water coral reefs that
characteristically have a living coral layer overlying a framework of dead
coral mixed with sediments.
Deep -water Lophelia reefs show many types of shapes. In the north east
Atlantic these range from “haystack-shaped” mounds have been observed
with a base size of up to 4km and a height of up to 165m from the surrounding
seabed. Similar conical-shaped reefs of Goniocorella dumosa have been
observed on the Campbell Plateau off New Zealand with a base-size of 700m
and a height of 40m above the seabed. Oculina varicosa is also associated
with reef-mounds with a base diameter of up to 1000m and a height of up to
17m. Sometimes mound -shaped reefs can coalesce to form barrier like
structures. Alternatively, as in the Sula Ridge, off the coast of Norway, a
complex of Lophelia pertusa reefs can form. At this locality the individual reefs
are up to 70m across but the entire reef complex is 14km long and up to 35m
in height. The distribution of corals is strongly influenced by ice -berg
ploughmarks5. The coral reefs formed by Solenosmilia variabilis on the Tasman
Seamounts appear to be large coalesced coral frameworks though details of
the structure of these reefs have not been published. Recently an even larger
Lophelia reef has been found to the west of the island of Røst in the Lofoten
Islands in the Norwegian EEZ. This reef lies in 300-400m depth, is 40km long and
2-3km wide, covering an area of 100km2. Lophelia also occurs as much
smaller, isolated frameworks of up to 50m across. The Darwin Mounds, in the
northern Rockall Trough, which have recently been protected under the
European Habitats Directive, consist of sediment mounds of a few metres
elevation and of a 100m diameter with coral framework on top 8. There are
several hundred of these low -relief mounds in a small area.
8
The Darwin Mounds have recently been protected by an emergency measure (European Commission
Regulation No 1475/2003), which prohibits the use of bottom trawl or similar bottom towed nets in this
area, and might be designated as a Special Area of Conservation, under the European Habitats
Directive (92/43/EEC).
Influence on biodiversity
Deep -water coral reefs like shallow water tropical reefs consist of a complex
three -dimensional coral framework with many sub-habitats that can be
occupied by other animals. These sub -habitats include the living coral itself,
the spaces between the coral branches, exposed dead coral framework,
sediment-clogged dead coral framework and the coral rubble surrounding a
reef. Large organisms live mainly attached to dead coral framework or rubble
(other corals, sponges, anemones, clams, starfish, sea urchins), burrowing in to
or living within cavities inside the dead coral branches (sponges, worms) or in
the sediments associated with the reef. Large mobile predators such as fish,
crabs and lobsters also live amongst the coral branches.
The diversity of animals that live associated with deep -water corals reefs is
comparable to that on some shallow water coral reefs. In the north-eastern
Atlantic over 1300 species have been found to be associated with Lophelia
pertusa 9. For many groups of animals this level of diversity is comparable to
that found on tropical shallow water reefs at a regional scale. However, some
groups of animals have a much lower diversity on Lophelia reefs than in
tropical shallow water reefs including the reef-building corals themselves,
molluscs and fishes. The majority of associated organisms are found in deep -
sea habitats outside of the reef and only a few species appear to only live
amongst Lophelia frameworks and not anywhere else. Not all sub-habitats in
Lophelia reefs have been investigated to date and the full extent of the
biodiversity of the associated animals has not yet been fully studied (e.g.
animals living in the coral rubble). Lophelia reefs are sharply demarcated
from the surrounding seabed and the coral-associated animal community is
distinct from the background deep -sea fauna, even when other hard
substrate habitats such as rock are considered and even where relatively
small accumulations of coral have been investigated (such as the Darwin
Mounds).
The fauna of Solenosmilia variabilis reefs on the Tasman Seamounts also have
high species diversity. On a single cruise 299 species of animals were sampled
from these seamounts of which 24-43% were new to science and are
endemic to this region10. Many of these were associated with the deep -water
coral reefs formed by Solenosmilia variabilis.
Deep -water coral reefs show other similarities with shallow -water tropical
reefs. Many of the processes of reef growth (accretion) and destruction
(erosion) are very similar between shallow and deep reefs. Many of the same
groups of organisms, such as sponges and worms are involved in bioerosion of
both shallow and deep -water reefs. On tropical shallow water reefs there are
many examples of commensal or mutual relationships amongst the organisms
9
Figures compiled by Dr M. Roberts, Scottish Association of Marine Sciences, Oban, Scotland, from
data gathered by the EU-funded Atlantic Coral Ecosystems Project.
10
Koslow JA, Gowlett-Holmes, K (1998) The seamount fauna off southern Tasmania: benthic
communities, their conservation and impacts of trawling. Report to Environment Australia CSIRO
Division of Marine Research FRDC Project 95/058. 104pp.
associated with the reef. Examples include the relationship between large
predatory sea anemones and the clown fish that live amongst their tentacles.
Evidence for commensal relationships is sparse for deep-water reefs but these
habitats are difficult to observe and have only been studied for a short time.
One example of such an interspecies relationship has been identified
between the reef-building coral Lophelia pertusa and a large, predatory,
tube-dwelling polychaete worm called Eunice norvegicus. These worms build
paper-like tubes amongst the bran ches of the reef and the corals secrete
calcium carbonate that solidifies around the tubes providing protection for
the worms11. The worms in turn are extremely aggressive and will attack
predators such as sea urchins that approach the living parts of the corals. The
worms may also steal food from the coral polyps (kleptoparasitism). There is
even evidence that the worm tubes may act as a substrate for the settlement
of coral larvae. These worms are found associated with Lophelia pertusa
wherever it forms reefs in the NE Atlantic.
Lophelia pertusa also acts as a nursery area for many juvenile animals. This
includes the juvenile stages of commercially valuable fish species such as
redfish (Sebastes spp). Damage to deep-water corals reefs can effectively
destroy these nursery grounds potentially having marked knock-on effects on
the surrounding ecosystem.
It has been estimated that in Norwegian waters 50% of Lophelia reefs have
been removed by trawling impacts12. In other parts of the European
continental slope it has also been suggested that the distribution of Lophelia
11
Kaszemeik & Freiwald. Lophelia pertusa (Scleractinia) – from skeletal structures to growth patterns
and morphotypes.. Manuscript in submission.
12
Fosså, J.H., Mortensen P.B., Furevik D.M. (2002) Hydrobiologia 471: 1-12.
pertusa and associated reefs has been reduced by intensive trawling13. Trawl-
scar marks are presen t on the upper slope throughout this region 14 and
submersible and camera observations have shown direct impacts of trawls on
Lophelia pertusa reefs and the Darwin Mounds regions. The most striking
evidence for the impact of deep -water trawling on deep -water coral reefs
has come from the Tasman Seamounts7,10. These seamounts have been
subject to intensive trawling for orange roughy and oreo. On the most
intensively trawled seamounts the deep -water coral reefs formed mainly by
Solenosmilia variabilis have been totally removed or reduced to rubble.
Deeper seamounts that were un -fished hosted a rich and highly endemic
deep -water coral reef community.
Deep -sea corals grow slowly and deep-sea reefs take thousands of years to
develop. There is evidence from recent research that recruitment of coral
larvae is sporadic. Also genetic and reproductive studies strongly suggest that
in areas where deep -water corals are impacted by trawling, the colonies can
be reduced to a small size where sexual reproduction is no longer viable15.
Given these factors, recovery of deep -water corals reefs from significant
trawling impacts is likely to be extremely slow and where the habitat is altered
may never happen. On the Tasman seamounts impacted areas were
reduced to bare rock grazed by sea urchins and in such a case re-growth of
a deep -water coral reef is unlikely. Given that these coral reefs are also
essential habitat for other organisms including commercially valuable fish
species16, these animals will also be removed. Destruction of essential fish
habitat may be one reason that many deep -water fisheries that have been
depleted in the last 20 years have not recovered.
13
Roberts J.M. et al., (2003) Marine Pollution Bulletin 46: 7 -20.
14
Roberts J.M. et al., (2000) Hydrobiologia 441: 173-183; Hall-Spencer et al., (2002) Proceedings of
the Royal Society London B 269: 507-511.
15
Le Goff-Vitry, Pybus OG, Rogers AD Genetic structure of the deep -sea coral Lophelia pertusa in the
North East Atlantic revealed by microsatellites and ITS sequences. Molecular Ecology. In press.
16
Husebo et al., (2002) Hydrobiologia 471 (Special Issue): 91-99.
17
Reed J.K., (2002) Hydrobiologua 471 (Special Issues): 43-55.
Further Reading
The Sula Reef complex, Norwegian shelf. Facies 47: 179 -200.
Koslow JA, Boehlert GW, Gordon JDM, Haedrich RL, Lorance P, Parin N (2000)
Rogers AD (1999)