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{{Short description|Reefs produced by sea sponges.}}
{{confused|sponge ground}}
{{distinguish|sponge ground}}{{use dmy dates|date=June 2022}}{{use Canadian English|date=June 2022}}
[[Image:Aphrocallistes vastus.jpg|thumb|300px|right|[[Cloud sponge]] (''Aphrocallistes vastus'') is a major reef-building species]]
[[File:Haeckel Hexactinellae.jpg|thumb|"Hexactinellae" from [[Ernst Haeckel]]'s ''[[Kunstformen der Natur]]'', 1904]]
[[File:Aphrocallistes vastus.jpg|thumb|224px|right|[[Cloud sponge]] (''Aphrocallistes vastus'') is a major reef-building species]]


'''Sponge reefs''' are [[reef]]s produced by [[sea sponge]]s. All modern sponge reefs are formed by [[hexactinellid]] sponges, which have an [[endoskeleton]] made of [[silica]] [[sponge spicule|spicule]]s and are often referred to as "glass sponges", while historically the non-spiculed, [[calcite]]-skeletoned [[archaeocyathid]] and [[stromatoporoid]] sponges were the primary reef-builders.
'''Sponge reefs''' are reefs formed by [[Hexactinellid]] sponges, which have a [[skeleton]] made of [[silica]], and are often referred to as ''glass sponges''. Such reefs are now very rare, and found only on the western Canadian continental shelf. Although common in the late [[Jurassic]] period, sponge reefs were believed to have gone extinct during or shortly after the [[Cretaceous period]], until the existing reefs were discovered in 1987–1988<ref name="dfo2000">Department of Fisheries and Oceans. 2000. Hexactinellid sponge reefs on the British Columbia continental shelf: geological and biological structure. DFO Pacific Region Habitat Status Report 2000/02.</ref> - hence these sometimes being dubbed [[living fossil]]s.


Sponge reefs were once a dominant landscape in the [[Paleozoic]] and [[Mesozoic]] sea, but are now very rare, and found only in waters off the coast of [[North America]]'s [[Pacific Northwest]] region, more specifically southern [[Alaska]], [[British Columbia]] and [[Washington (state)|Washington]]. Sponge reefs were reported in 2018 within the [[strait of Georgia]] and [[Howe Sound|Howe sound]] close to [[Vancouver]].<ref>{{Cite journal |last1=Dunham |first1=A. |last2=Archer |first2=S. K. |last3=Davies |first3=S. C. |last4=Burke |first4=L. A. |last5=Mossman |first5=J. |last6=Pegg |first6=J. R. |last7=Archer |first7=E. |date=2018-10-01 |title=Assessing condition and ecological role of deep-water biogenic habitats: Glass sponge reefs in the Salish Sea |journal=Marine Environmental Research |language=en |volume=141 |pages=88–99 |doi=10.1016/j.marenvres.2018.08.002 |pmid=30115533 |s2cid=52015990 |issn=0141-1136|doi-access=free }}</ref> Although still common in the late [[Jurassic]] period, reef-building sponges were believed to have gone extinct during or shortly after the [[Cretaceous period]], until the existing reefs were discovered in [[Queen Charlotte Sound (Canada)|Queen Charlotte sound]] in 1987–1988<ref name=dfo2000><br/>{{cite report |publisher=Department of Fisheries and Oceans |date=February 2000 |title=Hexactinellid sponge reefs on the British Columbia continental shelf: Geological and biological structure |series=DFO Pacific Region Habitat Status Report}}</ref> – hence these sometimes being dubbed [[living fossil]]s.
The reefs serve an important ecological function as habitat, breeding and nursery areas for fish and invertebrates but are currently threatened by the fishery, offshore oil and gas industries.<ref name="jamieson2002">Jamieson GS, and Chew L. 2002. Hexactinellid sponge reefs: areas of interest as marine protected areas in the north and central coast areas. Can Sci Adv Sec Res Doc 12.</ref><ref name="cpws2004">Canadian Parks and Wilderness Society. 2004. Protecting the glass sponge reefs from offshore oil and gas. http://cpawsbc.org/pdfs/glass_sponge_reefs.pdf. Accessed on March 28, 2008.</ref> Attempts are being made to protect these unique ecosystems through fishery closures and potentially the establishment of Marine Protected Areas (MAPs) around the [[sponge]] reefs.<ref name="jamieson2002" />

Like [[coral reef]]s, sponge reefs serve an important ecological function as feeding, breeding and nursery [[habitat]]s for [[demersal]] fish and invertebrates but are currently threatened by the commercial fishery, offshore oil and gas industries.<ref name=jamieson2002><br/>{{cite report |author1=Jamieson, G.S. |author2=Chew, L. |year=2002 |title=Hexactinellid sponge reefs: Areas of interest as marine protected areas in the north and central coast areas |series=Can Sci Adv Sec Res Doc |volume=12}}</ref><ref name="cpws2004">{{cite report |publisher=Canadian Parks and Wilderness Society |year=2004 |title=Protecting the glass sponge reefs from offshore oil and gas |url=http://cpawsbc.org/pdfs/glass_sponge_reefs.pdf |url-status=dead <!-- presumed --> |access-date=28 March 2008 |archive-url=https://web.archive.org/web/20041107004734/http://cpawsbc.org/pdfs/glass_sponge_reefs.pdf |archive-date=2004-11-07}}</ref> Attempts are being made to protect these unique ecosystems through fishery closures and potentially the establishment of Marine Protected Areas (MPAs) around the sponge reefs.<ref name="jamieson2002"/>


==Characteristics of hexactinellid sponges==
==Characteristics of hexactinellid sponges==
Hexactinellids, or "glassy" sponges are characterized by a rigid framework of spicules made of [[silica]]. Unlike other poriferans, hexactinellids do not possess the ability to contract. Another unique feature of glassy sponges is that their tissues are made up almost entirely of syncytia.<ref name="jamieson2002" /> In a [[syncytium]] there are many nuclei in a continuous cytoplasm; nuclei are not packaged in discrete cells.
Hexactinellids, or "glassy" sponges are characterized by a rigid framework of spicules made of [[silica]]. Unlike other poriferans, hexactinellids do not possess the ability to contract. Another unique feature of glassy sponges is that their tissues are made up almost entirely of syncytia.<ref name=jamieson2002/> In a [[syncytium]] there are many nuclei in a continuous cytoplasm; nuclei are not packaged in discrete cells.


As a result, the sponge has a distinctive electrical conduction system across its body. This allows the sponge to rapidly respond to disturbances such as a physical impact or excessive sediment in the water. The sponge’s response is to stop feeding. It will try to resume feeding after 20–30 minutes, but will stop again if the irritation is still present.<ref name="jamieson2002" />
As a result, the sponge has a distinctive electrical conduction system across its body. This allows the sponge to rapidly respond to disturbances such as a physical impact or excessive sediment in the water. The sponge's response is to stop feeding. It will try to resume feeding after 20–30&nbsp;minutes, but will stop again if the irritation is still present.<ref name=jamieson2002/>


Hexactinellids are exclusively marine and are found throughout the world in deep (>1000 m) oceans.<ref name="whitney2005">Whitney F, Conway K, Thomson R, Barrie V, Krautter M, and Mungov G. 2005. Oceanographic habitat of sponge reefs on the western Canadian continental shelf. Cont Shelf Res, 25: 211-226.</ref> Individual sponges grow at a rate of 0–7&nbsp;cm/year, and can live to be at least 220 years old.<ref name="krautter2001" /> Little is known about hexactinellid sponge reproduction. Like all poriferans, the hexactinellids are filter feeders. They obtain nutrition from direct absorption of dissolved substances, and to a lesser extent from particulate materials.<ref name="whitney2005" /> There are no known predators of healthy reef sponges.<ref name="krautter2001">Krautter M, Conway K, Barrie JV, and Neuweiler M. 2001. Discovery of a "living dinosaur": globally unique modern hexactinellid sponge reefs off British Columbia, Canada. Facies, 44: 265-282.</ref> This is likely because the sponges possess very little organic tissue; the siliceous skeleton accounts for 90% of the sponge body weight.<ref name="whitney2005" />
Hexactinellids are exclusively marine and are found throughout the world in deep (>1000 m) oceans.<ref name=whitney2005><br/>{{cite journal |author1=Whitney, F. |author2=Conway, K. |author3=Thomson, R. |author4=Barrie, V. |author5=Krautter, M. |author6=Mungov, G. |year=2005 |title=Oceanographic habitat of sponge reefs on the western Canadian continental shelf |journal=Cont Shelf Res |volume=25 |issue=2 |pages=211–226|doi=10.1016/j.csr.2004.09.003 }}</ref> Individual sponges grow at a rate of 0–7&nbsp;cm/year, and can live to be at least 220&nbsp;years old.<ref name=krautter2001/> Little is known about hexactinellid sponge reproduction. Like all poriferans, the hexactinellids are filter feeders. They obtain nutrition from direct absorption of dissolved substances, and to a lesser extent from particulate materials.<ref name=whitney2005/>
There are no known predators of healthy reef sponges.<ref name=krautter2001><br/>{{cite journal |author1=Krautter, M. |author2=Conway, K. |author3=Barrie, J.V. |author4=Neuweiler, M. |year=2001 |title=Discovery of a "living dinosaur": Globally unique modern hexactinellid sponge reefs off British Columbia, Canada |journal=Facies |volume=44 |pages=265–282|doi=10.1007/BF02668178 |s2cid=128410530 }}</ref> This is likely because the sponges possess very little organic tissue; the siliceous skeleton accounts for 90% of the sponge body weight.<ref name=whitney2005/>


Hexasterophoran sponges have spicules called hexactines that have six rays set at right angles. Orders within [[hexasterophora]] are classified by how tightly the spicules interlock with Lyssanctinosan spicules less tightly interlocked than those of Hexactinosan sponges.
Hexasterophoran sponges have spicules called hexactines that have six rays set at right angles. Orders within [[hexasterophora]] are classified by how tightly the spicules interlock with Lyssanctinosan spicules less tightly interlocked than those of Hexactinosan sponges.


The primary frame-building sponges are all members of the order Hexactinosa, and include the species ''Chonelasma/Heterochone calyx'' (chalice sponge), ''Aphrocallistes vastus'' ([[cloud sponge]]), and ''Farrea occa''.<ref name="krautter2001" /> Hexactinosan sponges have a rigid scaffolding of "fused" spicules that persists after the death of the sponge.
The primary frame-building sponges are all members of the order Hexactinosa, and include the species ''Chonelasma/Heterochone calyx'' (chalice sponge), ''Aphrocallistes vastus'' ([[cloud sponge]]), and ''Farrea occa''.<ref name=krautter2001/> Hexactinosan sponges have a rigid scaffolding of "fused" spicules that persists after the death of the sponge.


Other sponge species abundant on sponge reefs are members of the order Lyssactinosa (Rosselid sponges) and include ''Rhabdocalyptus dawsoni'' (boot sponge), ''Acanthascus platei'', ''Acanthascus cactus'' and ''[[Staurocalyptus]] [[Staurocalyptus dowlingi|dowlingi]]''.<ref name="krautter2001" /> Rosselid sponges have a "woven" or "loose" siliceous skeleton that does not persist after the death of the sponge, and are capable of forming mats, but not reefs.<ref name="jamieson2002" />
Other sponge species abundant on sponge reefs are members of the order Lyssactinosa (Rosselid sponges) and include ''Rhabdocalyptus dawsoni'' (boot sponge), ''Acanthascus platei'', ''Acanthascus cactus'' and ''[[Staurocalyptus]] [[Staurocalyptus dowlingi|dowlingi]]''.<ref name=krautter2001/> Rosselid sponges have a "woven" or "loose" siliceous skeleton that does not persist after the death of the sponge, and are capable of forming mats, but not reefs.<ref name=jamieson2002/>


==Location of sponge reefs==
==Location of sponge reefs==
[[image:NWCoast1a.png|thumb|300px|right|Sponge reefs can only be found off a small part of the northwest coast of North America]]
Although hexactinellid sponges are found worldwide in deep seawater, the only place that they are known to form reefs is between south east Alaska and off [[Grays Harbor|Grays harbor]].<ref name=dfo2000/><ref name=conway2005><br/>{{cite journal |author1=Conway, K. |author2=Barrie, J. |author3=Krautter, M. |year=2005 |title=Geomorphology of unique reefs on the western Canadian shelf: sponge reefs mapped by multibeam bathymetry |journal=Geo-Mar Lett |volume=25 |issue=4 |pages=205–213|doi=10.1007/s00367-004-0204-z |s2cid=129356194 }}</ref><ref name=jamieson2002/><ref name=whitney2005/> Communities of Rosselid sponges called "sponge mats" are widely distributed; they are found in canyons in the North Atlantic, in the Canadian Arctic and on Antarctic continental shelves.<ref name=whitney2005/> There is also a reef formed of siliceous [[Demospongiae]] species off of [[Axel Heiberg Island]] in the Arctic Ocean.<ref name=eluik1991>{{cite journal |author=Eluik, L. |year=1991 |title=Siliceous sponge communities, biological zonation, and recent sea-level change on the Arctic margin: Ice Island results: Discussion |journal=Can J Earth Sci |volume=28 |issue=3 |pages=459–462|doi=10.1139/e91-040 }}</ref>


Four hexactinellid reefs were discovered in the Queen Charlotte Basin (QCB) in 1987–1988.<ref name=dfo2000/> Three more reefs were reported in the Georgia Basin (GB) in 2005.<ref name=conway2005/> The QCB reefs are found 70–80&nbsp;km from the coastline in water 165–240&nbsp;m deep.<ref name=krautter2001/> These reefs cover over 700&nbsp;km² of the ocean floor.<ref name=whitney2005/>
[[image:NWCoast1a.png|thumb|300px|right|Islands and major straits of the northern Pacific Northwest Coast]]


Sponge reefs require unique conditions, which may explain their global rarity. They are found only in glacier-scoured troughs of low-angle [[continental shelf]]. The seafloor is stable and consists of rock, coarse gravel, and large boulders.<ref name=whitney2005/> Hexactinellid sponges require a hard substrate, and do not anchor to muddy or sandy sea floors.<ref name=krautter2001/>
Although hexactinellid sponges are found worldwide in deep seawater, the only place that they are known to form reefs is on the western Canadian continental shelf.<ref name="dfo2000" /><ref name="conway2005">Conway K, Barrie J, and Krautter M. 2005. Geomorphology of unique reefs on the western Canadian shelf: sponge reefs mapped by multibeam bathymetry. Geo-Mar Lett, 2005: 205-213.</ref><ref name="jamieson2002" /><ref name="whitney2005" /> Communities of Rosselid sponges called "sponge mats" are widely distributed; they are found in canyons in the North Atlantic, in the Canadian Arctic and on Antarctic continental shelves.<ref name="whitney2005" /> There is also a reef formed of siliceous [[Demospongiae]] species off of Axel Heiberg Island in the Arctic ocean.<ref name="eluik1991">Eluik L. 1991. Siliceous sponge communities, biological zonation, and recent sea-level change on the Arctic margin: Ice Island results: Discussion. Can J Earth Sci, 28: 459-462.</ref>


They are found only where sedimentation rates are low, dissolved silica is high (43–75&nbsp;μM), and bottom currents are between 0.15 and 0.30&nbsp;m/s.<ref name=whitney2005/> Dissolved oxygen is low (64–152&nbsp;μM), and temperatures are a cool 5.5-7.3&nbsp;°C at the reefs.<ref name=whitney2005/> Surface temperatures range between 6&nbsp;°C in April and 14&nbsp;°C in August.<ref name=krautter2001/>
Four hexactinellid reefs were discovered in the Queen Charlotte Basin (QCB) in 1987–1988.<ref name="dfo2000" /> Three more reefs were reported in the Georgia Basin (GB) in 2005.<ref name="conway2005" /> The QCB reefs are found 70–80&nbsp;km from the coastline in water 165–240 m deep.<ref name="krautter2001" /> These reefs cover over 700 km2 of the ocean floor.<ref name="whitney2005" />


Downwellings are common in [[Hecate Strait]] and [[Queen Charlotte Sound (Canada)|Queen Charlotte Sound]], especially in winter, but there is an occasional summer [[upwelling]].<ref name=whitney2005/> These upwellings bring nutrient-rich waters to the sponge reefs.
Sponge reefs require unique conditions, which may explain their global rarity. They are found only in glacier-scoured troughs of low-angle [[continental shelf]]. The seafloor is stable and consists of rock, coarse gravel, and large boulders.<ref name="whitney2005" /> Hexactinellid sponges require a hard substrate, and do not anchor to muddy or sandy sea floors.<ref name="krautter2001" />

They are found only where sedimentation rates are low, dissolved silica is high (43-75 μM), and bottom currents are between 0.15 and 0.30&nbsp;m/s.<ref name="whitney2005" /> Dissolved oxygen is low (64-152 μM), and temperatures are a cool 5.5-7.3°C at the reefs.<ref name="whitney2005" /> Surface temperatures range between 6°C in April and 14°C in August.<ref name="krautter2001" />

Downwellings are common in [[Hecate Strait]] and [[Queen Charlotte Sound (Canada)|Queen Charlotte Sound]], especially in winter, but there is an occasional summer [[upwelling]].<ref name="whitney2005" /> These upwellings bring nutrient-rich waters to the sponge reefs.


==Structure of sponge reefs==
==Structure of sponge reefs==
[[File:Generalised food web for sponge reefs.jpg|thumb|upright=2| {{center|'''Generalised food web for sponge reefs'''{{hsp}}<ref name= Archer2020>{{cite journal |last1=Archer |first1=Stephanie K. |last2=Kahn |first2=Amanda S. |last3=Thiess |first3=Mary |last4=Law |first4=Lauren |last5=Leys | first5=Sally P. |last6=Johannessen |first6=Sophia C. |last7=Layman | first7=Craig A. | last8=Burke |first8=Lily |last9=Dunham |first9=Anya |date=24 September 2020 |title=Foundation species abundance influences food web topology on glass sponge reefs |journal=Frontiers in Marine Science |publisher=Frontiers Media SA |volume=7 |issn=2296-7745 |doi=10.3389/fmars.2020.549478 |doi-access=free}} [[File:CC-BY icon.svg|50px]] Material was copied from this source, which is available under a [https://creativecommons.org/licenses/by/4.0/ Creative Commons Attribution 4.0 International License].</ref>}}]]


Each living sponge on the surface of the reef can be over 1.5 m tall. The reefs are composed of mounds called "bioherms" that are up to 21 m high, and sheets called "biostromes" that are 2–10 m thick and may be many km wide.<ref name="whitney2005" />
Each living sponge on the surface of the reef can be over 1.5&nbsp;m tall. The reefs are composed of mounds called "bioherms" that are up to 21&nbsp;m high, and sheets called "biostromes" that are 2–10&nbsp;m thick and may be many kilometers wide.<ref name=whitney2005/>


Each sponge in the order Hexactinosa has a rigid skeleton that persists after the death of the animal. This provides an excellent substrate for sponge larvae to settle upon, and new sponges grow on the framework of past generations. The growth of sponge reefs is thus analogous to that of [[coral reefs]]. The tendrils of new sponges wrap around spicules of older, deceased sponges. The tendrils will later form the basal plate of the adult sponge that firmly anchors the animal to the reef.
Each sponge in the order Hexactinosa has a rigid skeleton that persists after the death of the animal. This provides an excellent substrate for sponge larvae to settle upon, and new sponges grow on the framework of past generations. The growth of sponge reefs is thus analogous to that of [[coral reefs]]. The tendrils of new sponges wrap around spicules of older, deceased sponges. The tendrils will later form the basal plate of the adult sponge that firmly anchors the animal to the reef.


Deep ocean currents carry fine sediments that are captured by the scaffolding of sponge reefs. A sediment matrix of silt, clay, and some sand forms around the base of the sponge bioherms. The sediment matrix is soft near the surface, and firm below one metre deep.<ref name="krautter2001" /> Dead sponges become covered in sediment, but do not lose their supportive siliceous skeleton.<ref name="krautter2001" /> The sponge sediments have high levels of silica and organic carbon. The reefs grow parallel to the glacial troughs, and the morphology of reefs is due to deep currents.<ref name="conway2005" />
Deep ocean currents carry fine sediments that are captured by the scaffolding of sponge reefs. A sediment matrix of silt, clay, and some sand forms around the base of the sponge bioherms. The sediment matrix is soft near the surface, and firm below one metre deep.<ref name=krautter2001/> Dead sponges become covered in sediment, but do not lose their supportive siliceous skeleton.<ref name=krautter2001/> The sponge sediments have high levels of silica and organic carbon. The reefs grow parallel to the glacial troughs, and the morphology of reefs is due to deep currents.<ref name=conway2005/>


==In the fossil record==
=="Living fossils"==
Hexactinellids first appeared in the fossil record during the Late [[Proterozoic]], and the first [[Hexactinosa|hexactinosans]] were found in the Late [[Devonian]].<ref name=krautter2001/> Hexactinellid sponge reefs were first identified in the Middle [[Triassic]] (245-208&nbsp;million years ago). The sponges reached their full extent in the late [[Jurassic]] (201-145&nbsp;million years ago) when a discontinuous reef system 7,000&nbsp;km long stretched across the northern [[Tethys Ocean|Tethys]] and North Atlantic basins.<ref name=krautter2001/> This chain of sponge reefs is the largest known biostructure to have ever existed on Earth.<ref name=krautter2001/>


The sponge reefs declined throughout the [[Cretaceous]] period as coral and [[Rudists|rudist]] reefs were becoming prominent.<ref name=krautter2001/> It is theorized that the spread of [[diatoms]] may have been detrimental to the sponges, as diatoms compete with hexactinellid sponges for silica.<ref name=whitney2005/>
Hexactinellids first appeared in the fossil record during the Late [[Proterozoic]], and the first Hexactinosans were found in the Late [[Devonian]].<ref name="krautter2001" /> Hexactinellid sponge reefs were first identified in the Middle [[Triassic]] (245-208 million years ago). The sponges reached their full extent in the late [[Jurassic]] (208-146 million years ago) when a discontinuous reef system 7,000&nbsp;km long stretched across the northern [[Tethys ocean|Tethys]] and North Atlantic basins.<ref name="krautter2001" /> This chain of sponge reefs is the largest known biostructure to have ever existed on Earth.<ref name="krautter2001" />


It is estimated through radiocarbon dating of reef cores that the reefs have been living on the continental shelf of Western Canada for 8,500–9,000&nbsp;years.<ref name=dfo2000/>
The sponge reefs declined throughout the [[Cretaceous]] period as coral and rudist reefs were becoming prominent.<ref name="krautter2001" /> It is theorized that the spread of [[diatoms]] may have been detrimental to the sponges, as diatoms compete with hexactinellid sponges for silica.<ref name="whitney2005" />

It is estimated through radiocarbon dating of reef cores that the reefs have been living on the continental shelf of Western Canada for 8500–9000 years.<ref name="dfo2000" />


==Ecological significance==
==Ecological significance==
Sponge reefs provide structure on the otherwise relatively featureless continental shelf. They provide habitat for fish and invertebrates, and may serve as an important nursery area for these animals. More research is required to determine the full ecological importance of these reefs.<ref name=dfo2000/><ref name=jamieson2002/>


Observations by crewed submersible indicate that the fauna of sponge reefs differs from surrounding areas.<ref name=dfo2000/> Organisms found in and around sponge reefs include annelid worms, [[bryozoans]], spider crab, King crab, shrimp, prawns, and [[euphausids]]. [[Echinoderms]], especially sea urchins and sea stars, were abundant in areas of the reef where the sponges were dying or deceased, and can be used as an indicator of sponge reef health.<ref name=krautter2001/> Rockfish, especially [[Sebastes]] species, live in openings and in between sponges.<ref name=krautter2001/> Gravid and juvenile rockfish were observed, suggesting that the reefs are being used as a nursery area.<ref name=whitney2005/> [[Foraminiferans]] are abundant around the reefs, and [[diatoms]] are scarce. The consortium of organisms living in and around sponge reefs has changed very little since the Jurassic.<ref name=krautter2001/>
Sponge reefs provide structure on the otherwise relatively featureless continental shelf. They provide habitat for fish and invertebrates, and may serve as an important nursery area for these animals. More research is required to determine the full ecological importance of these reefs.<ref name="dfo2000" /><ref name="jamieson2002" />

Observations by manned submersible indicate that the fauna of sponge reefs differs from surrounding areas.<ref name="dfo2000" /> Organisms found in and around sponge reefs include annelid worms, [[bryozoans]], spider crab, King crab, shrimp, prawns, and [[euphausids]]. [[Echinoderms]], especially sea urchins and sea stars, were abundant in areas of the reef where the sponges were dying or deceased, and can be used as an indicator of sponge reef health.<ref name="krautter2001" /> Rockfish, especially [[Sebastes]] species, live in openings and in between sponges.<ref name="krautter2001" /> Gravid and juvenile rockfish were observed, suggesting that the reefs are being used as a nursery area.<ref name="whitney2005" /> [[Foraminiferans]] are abundant around the reefs, and [[diatoms]] are scarce. The consortium of organisms living in and around sponge reefs has changed very little since the Jurassic.<ref name="krautter2001" />


==Destruction of sponge reefs==
==Destruction of sponge reefs==

[[Image:Trawling Drawing.jpg|thumb|right|240px|Bottom trawling, in which a net is dragged along the sea floor, is particularly damaging to sponge reefs]]
[[Image:Trawling Drawing.jpg|thumb|right|240px|Bottom trawling, in which a net is dragged along the sea floor, is particularly damaging to sponge reefs]]
The reefs are susceptible to damage by fishing, especially bottom [[trawling]] and dredging. In typical groundfish trawling, a large net is dragged across the ocean floor, its mouth held open by two 2&nbsp;tonne doors called otterboards. The siliceous skeleton of the sponges is fragile, and these organisms are easily broken by physical impact. The impacts of bottom trawling have been observed in three of the reefs in the QCB.<ref name=jamieson2002/> Trawling damage appears as parallel tracks 70–100 m apart that may extend for several kilometers. Each trawl track is 10&nbsp;cm deep, 20&nbsp;cm wide, and occurs at depths of 210–220&nbsp;m. Sponges in the vicinity of trawl tracks are shattered or completely removed.


While less harmful, hook and line fishing as well as crustacean trapping may also damage the reefs. When the fishing gear is hauled to the surface, the lines and traps drag along the ocean floor and have the potential to break corals and sponges. Broken sponge "stumps", as well as those with abraded sides, were found in regions where line and trap fishing took place.<ref name=jamieson2002/>
The reefs are susceptible to damage by fishing, especially bottom [[trawling]] and dredging. In typical groundfish trawling, a large net is dragged across the ocean floor, its mouth held open by two 2-tonne doors called otterboards. The siliceous skeleton of the sponges is fragile, and these organisms are easily broken by physical impact. The impacts of bottom trawling have been observed in three of the reefs in the QCB.<ref name="jamieson2002" /> Trawling damage appears as parallel tracks 70–100 m apart that may extend for several km. Each trawl track is 10&nbsp;cm deep, 20&nbsp;cm wide, and occurs at depths of 210–220 m. Sponges in the vicinity of trawl tracks are shattered or completely removed.

While less harmful, hook and line fishing as well as crustacean trapping may also damage the reefs. When the fishing gear is hauled to the surface, the lines and traps drag along the ocean floor and have the potential to break corals and sponges. Broken sponge "stumps", as well as those with abraded sides, were found in regions where line and trap fishing took place.<ref name="jamieson2002" />


Breakage of reef sponges may have dire consequences for the recruitment of new sponges, as sponge larvae require the siliceous skeletons of past generations as a substrate.<ref name="krautter2001" /> Without a hard substrate, new sponges cannot settle and regrow broken parts of the reef. It has been estimated that broken sponge reefs may take up to 200 years to recover.<ref name="jamieson2002" />
Breakage of reef sponges may have dire consequences for the recruitment of new sponges, as sponge larvae require the siliceous skeletons of past generations as a substrate.<ref name=krautter2001/> Without a hard substrate, new sponges cannot settle and regrow broken parts of the reef. It has been estimated that broken sponge reefs may take up to 200&nbsp;years to recover.<ref name=jamieson2002/>


In addition, offshore oil and gas exploration threatens the reefs. The government of British Columbia has lifted a moratorium preventing exploratory drilling and tanker traffic in Hecate Strait and Queen Charlotte Sound, and the area has been leased by the oil and gas industry.<ref name="jamieson2002" /> Even if exploratory drilling is not done on or immediately adjacent to the reefs, it may still have a negative impact by increasing the amount of sediment in the seawater, or through hydrocarbon pollution.<ref name="cpws2004" />
In addition, offshore oil and gas exploration threatens the reefs. The government of British Columbia has lifted a moratorium preventing exploratory drilling and tanker traffic in Hecate Strait and Queen Charlotte Sound, and the area has been leased by the oil and gas industry.<ref name=jamieson2002/> Even if exploratory drilling is not done on or immediately adjacent to the reefs, it may still have a negative impact by increasing the amount of sediment in the seawater, or through hydrocarbon pollution.<ref name=cpws2004/>


==Protection==
==Protection==
In 1999, [[Fisheries and Oceans Canada]] requested that [[groundfish]] [[Trawling|trawlers]] voluntarily avoid the sponge reefs. In 2002, following reports of new reef damage sustained since 1999, the ministry initiated regulated closures of groundfish trawling and voluntary closures of shrimp trawl fishing in areas where sponge reefs were known to inhabit.<ref name=jamieson2002/>


Protection of the four sponge reefs in Hecate Strait and Queen Charlotte Sound was included as a "management issue" in the 2005/06 groundfish trawling management plan.<ref name=dfo2005><br/>{{cite report |publisher=Department of Fisheries and Oceans |year=2005 |title=Groundfish trawl integrated fisheries management plan |url=http://www-ops2.pac.dfo-mpo.gc.ca/xnet/content/MPLANS/plans05/GFTrawl05.pdf |access-date=28 March 2008}}</ref> The management plan recommended that an additional {{convert|9|km|mi|abbr=on}} buffer zone around the reefs be added to the existing groudfish trawl closures.<ref name=jamieson2002/> The reefs were also being considered as locations for future [[Fisheries and Oceans Canada#Marine Protected Areas|Marine Protected Areas]] (MPAs).<ref name=jamieson2002/> Although MPAs may be more effective than fishery closures for long-term protection of the reefs from bottom trawling, the oil and gas industry would still pose a threat.<ref name=dfo2005/>
It was requested in 1999 that groundfish trawlers voluntarily avoid sponge reefs.<ref name="jamieson2002" /> In 2002 voluntary closures of shrimp trawl fishing, and regulated closures of groundfish trawling were initiated in areas where sponge reefs were known.<ref name="jamieson2002" /> However, voluntary avoidance by fishers is not an entirely effective method, and new damage to the reefs was reported between 1999 and 2002,<ref name="jamieson2002" /> indicating that the reefs were not entirely missed.


In 2008, the issue of preserving sensitive underwater ecosystems along the [[British Columbia Coast|North Coast of British Columbia]] were consolidated within the [[Pacific North Coast Integrated Management Area]]. The goal was to develop a plan to conserve this relatively undeveloped region, while fostering sustainable economies on the coast, which promised to make Canada a world leader in marine conservation. However, in 2011, the [[Fisheries and Oceans Canada|ministry]] withdrew support for the process in favour of greater consistency with ocean planning on the other coasts of Canada.
Protection of the four sponge reefs in Queen Charlotte Sound and Hecate Strait is included as a "management issue" in the 2005/06 groundfish trawling management plan.<ref name="dfo2005">Department of Fisheries and Oceans. 2005. Groundfish trawl integrated fisheries management plan. http://www-ops2.pac.dfo-mpo.gc.ca/xnet/content/MPLANS/plans05/GFTrawl05.pdf. Accessed on March 28, 2008.</ref> Fishing activities around the sponge reefs are to be monitored to ensure that the reefs are being adequately protected from trawling.<ref name="dfo2005" />


In February&nbsp;2017, the sponge reefs of Hecate Sound and Queen Charlotte Sound were formally protected within the [[Hecate Strait and Queen Charlotte Sound Glass Sponge Reefs Marine Protected Area]]. The marine protected area covers an area of {{convert|2410|km2|mi2|abbr=on}} and prohibits any activity that could disturb or destroy the sponge reefs.<ref>{{cite press release |publisher=Government of Canada |department=Fisheries and Oceans Canada |date=2019-09-18 |df=dmy-all |title=Hecate Strait/Queen Charlotte Sound Glass Sponge Reefs Marine Protected Area (HS/QCS MPA) |url=https://www.dfo-mpo.gc.ca/oceans/mpa-zpm/hecate-charlotte/index-eng.html |access-date=2020-09-10 |website=www.dfo-mpo.gc.ca}}</ref>
It is recommended that an additional nine km buffer zone around the reefs be added to the existing groudfish trawl closures.<ref name="jamieson2002" /> The four reefs in the QCB, and one reef in the GB are also being considered as locations for future Marine Protected Areas (MPAs).<ref name="jamieson2002" /> Although MPAs may be more effective than fishery closures for long-term protection of the reefs from bottom trawling, the oil and gas industry would still pose a threat.<ref name="dfo2005" />


==See also==
==See also==
* [[Hexactinellid]] sponges (glass sponges)
* [[Cloud sponge]]
* [[Sponge Reef Project]]
* [[Sponge Reef Project]]


==References==
==References==
{{reflist}}
{{reflist|25em}}


==External links==
==External links==
*The Sponge Reef Project. http://www.porifera.org/a/ciopen.html. Accessed on March 25, 2008.
* [https://web.archive.org/web/20110224072816/http://www.porifera.org/a/ciopen.html The Sponge Reef Project - Accessed on March 25, 2008]
*Natural Resources Canada. Sponge Reefs on the continental shelf. http://gsc.nrcan.gc.ca/marine/sponge/index_e.php. Accessed on March 25, 2008.
* [https://web.archive.org/web/20111009050131/http://gsc.nrcan.gc.ca/marine/sponge/index_e.php Natural Resources Canada - Sponge Reefs on the continental shelf - Accessed on March 25, 2008.]
*Austin, W. C. 2003. Sponge gardens: A hidden treasure in British Columbia. http://www.mareco.org/khoyatan/spongegardens/home/. Accessed on March 25, 2008.
* [https://web.archive.org/web/20111005142502/http://www.mareco.org/khoyatan/spongegardens/home Austin, W. C. 2003 - Sponge gardens: A hidden treasure in British Columbia - Accessed on March 25, 2008]
*University of California Museum of Paleontology. Hexactinellida. http://www.ucmp.berkeley.edu/porifera/hexactinellida.html . Accessed on April 7, 2008.
* [http://www.ucmp.berkeley.edu/porifera/hexactinellida.html University of California Museum of Paleontology - Hexactinellida - Accessed on April 7, 2008]


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[[Category:Reefs]]
[[Category:Reefs]]
[[Category:Sponge biology]]
[[Category:Sponge biology]]
[[Category:Fisheries]]
[[Category:Fisheries science]]

Latest revision as of 08:18, 25 August 2024

"Hexactinellae" from Ernst Haeckel's Kunstformen der Natur, 1904
Cloud sponge (Aphrocallistes vastus) is a major reef-building species

Sponge reefs are reefs produced by sea sponges. All modern sponge reefs are formed by hexactinellid sponges, which have an endoskeleton made of silica spicules and are often referred to as "glass sponges", while historically the non-spiculed, calcite-skeletoned archaeocyathid and stromatoporoid sponges were the primary reef-builders.

Sponge reefs were once a dominant landscape in the Paleozoic and Mesozoic sea, but are now very rare, and found only in waters off the coast of North America's Pacific Northwest region, more specifically southern Alaska, British Columbia and Washington. Sponge reefs were reported in 2018 within the strait of Georgia and Howe sound close to Vancouver.[1] Although still common in the late Jurassic period, reef-building sponges were believed to have gone extinct during or shortly after the Cretaceous period, until the existing reefs were discovered in Queen Charlotte sound in 1987–1988[2] – hence these sometimes being dubbed living fossils.

Like coral reefs, sponge reefs serve an important ecological function as feeding, breeding and nursery habitats for demersal fish and invertebrates but are currently threatened by the commercial fishery, offshore oil and gas industries.[3][4] Attempts are being made to protect these unique ecosystems through fishery closures and potentially the establishment of Marine Protected Areas (MPAs) around the sponge reefs.[3]

Characteristics of hexactinellid sponges

[edit]

Hexactinellids, or "glassy" sponges are characterized by a rigid framework of spicules made of silica. Unlike other poriferans, hexactinellids do not possess the ability to contract. Another unique feature of glassy sponges is that their tissues are made up almost entirely of syncytia.[3] In a syncytium there are many nuclei in a continuous cytoplasm; nuclei are not packaged in discrete cells.

As a result, the sponge has a distinctive electrical conduction system across its body. This allows the sponge to rapidly respond to disturbances such as a physical impact or excessive sediment in the water. The sponge's response is to stop feeding. It will try to resume feeding after 20–30 minutes, but will stop again if the irritation is still present.[3]

Hexactinellids are exclusively marine and are found throughout the world in deep (>1000 m) oceans.[5] Individual sponges grow at a rate of 0–7 cm/year, and can live to be at least 220 years old.[6] Little is known about hexactinellid sponge reproduction. Like all poriferans, the hexactinellids are filter feeders. They obtain nutrition from direct absorption of dissolved substances, and to a lesser extent from particulate materials.[5]

There are no known predators of healthy reef sponges.[6] This is likely because the sponges possess very little organic tissue; the siliceous skeleton accounts for 90% of the sponge body weight.[5]

Hexasterophoran sponges have spicules called hexactines that have six rays set at right angles. Orders within hexasterophora are classified by how tightly the spicules interlock with Lyssanctinosan spicules less tightly interlocked than those of Hexactinosan sponges.

The primary frame-building sponges are all members of the order Hexactinosa, and include the species Chonelasma/Heterochone calyx (chalice sponge), Aphrocallistes vastus (cloud sponge), and Farrea occa.[6] Hexactinosan sponges have a rigid scaffolding of "fused" spicules that persists after the death of the sponge.

Other sponge species abundant on sponge reefs are members of the order Lyssactinosa (Rosselid sponges) and include Rhabdocalyptus dawsoni (boot sponge), Acanthascus platei, Acanthascus cactus and Staurocalyptus dowlingi.[6] Rosselid sponges have a "woven" or "loose" siliceous skeleton that does not persist after the death of the sponge, and are capable of forming mats, but not reefs.[3]

Location of sponge reefs

[edit]
Sponge reefs can only be found off a small part of the northwest coast of North America

Although hexactinellid sponges are found worldwide in deep seawater, the only place that they are known to form reefs is between south east Alaska and off Grays harbor.[2][7][3][5] Communities of Rosselid sponges called "sponge mats" are widely distributed; they are found in canyons in the North Atlantic, in the Canadian Arctic and on Antarctic continental shelves.[5] There is also a reef formed of siliceous Demospongiae species off of Axel Heiberg Island in the Arctic Ocean.[8]

Four hexactinellid reefs were discovered in the Queen Charlotte Basin (QCB) in 1987–1988.[2] Three more reefs were reported in the Georgia Basin (GB) in 2005.[7] The QCB reefs are found 70–80 km from the coastline in water 165–240 m deep.[6] These reefs cover over 700 km² of the ocean floor.[5]

Sponge reefs require unique conditions, which may explain their global rarity. They are found only in glacier-scoured troughs of low-angle continental shelf. The seafloor is stable and consists of rock, coarse gravel, and large boulders.[5] Hexactinellid sponges require a hard substrate, and do not anchor to muddy or sandy sea floors.[6]

They are found only where sedimentation rates are low, dissolved silica is high (43–75 μM), and bottom currents are between 0.15 and 0.30 m/s.[5] Dissolved oxygen is low (64–152 μM), and temperatures are a cool 5.5-7.3 °C at the reefs.[5] Surface temperatures range between 6 °C in April and 14 °C in August.[6]

Downwellings are common in Hecate Strait and Queen Charlotte Sound, especially in winter, but there is an occasional summer upwelling.[5] These upwellings bring nutrient-rich waters to the sponge reefs.

Structure of sponge reefs

[edit]
Generalised food web for sponge reefs[9]

Each living sponge on the surface of the reef can be over 1.5 m tall. The reefs are composed of mounds called "bioherms" that are up to 21 m high, and sheets called "biostromes" that are 2–10 m thick and may be many kilometers wide.[5]

Each sponge in the order Hexactinosa has a rigid skeleton that persists after the death of the animal. This provides an excellent substrate for sponge larvae to settle upon, and new sponges grow on the framework of past generations. The growth of sponge reefs is thus analogous to that of coral reefs. The tendrils of new sponges wrap around spicules of older, deceased sponges. The tendrils will later form the basal plate of the adult sponge that firmly anchors the animal to the reef.

Deep ocean currents carry fine sediments that are captured by the scaffolding of sponge reefs. A sediment matrix of silt, clay, and some sand forms around the base of the sponge bioherms. The sediment matrix is soft near the surface, and firm below one metre deep.[6] Dead sponges become covered in sediment, but do not lose their supportive siliceous skeleton.[6] The sponge sediments have high levels of silica and organic carbon. The reefs grow parallel to the glacial troughs, and the morphology of reefs is due to deep currents.[7]

In the fossil record

[edit]

Hexactinellids first appeared in the fossil record during the Late Proterozoic, and the first hexactinosans were found in the Late Devonian.[6] Hexactinellid sponge reefs were first identified in the Middle Triassic (245-208 million years ago). The sponges reached their full extent in the late Jurassic (201-145 million years ago) when a discontinuous reef system 7,000 km long stretched across the northern Tethys and North Atlantic basins.[6] This chain of sponge reefs is the largest known biostructure to have ever existed on Earth.[6]

The sponge reefs declined throughout the Cretaceous period as coral and rudist reefs were becoming prominent.[6] It is theorized that the spread of diatoms may have been detrimental to the sponges, as diatoms compete with hexactinellid sponges for silica.[5]

It is estimated through radiocarbon dating of reef cores that the reefs have been living on the continental shelf of Western Canada for 8,500–9,000 years.[2]

Ecological significance

[edit]

Sponge reefs provide structure on the otherwise relatively featureless continental shelf. They provide habitat for fish and invertebrates, and may serve as an important nursery area for these animals. More research is required to determine the full ecological importance of these reefs.[2][3]

Observations by crewed submersible indicate that the fauna of sponge reefs differs from surrounding areas.[2] Organisms found in and around sponge reefs include annelid worms, bryozoans, spider crab, King crab, shrimp, prawns, and euphausids. Echinoderms, especially sea urchins and sea stars, were abundant in areas of the reef where the sponges were dying or deceased, and can be used as an indicator of sponge reef health.[6] Rockfish, especially Sebastes species, live in openings and in between sponges.[6] Gravid and juvenile rockfish were observed, suggesting that the reefs are being used as a nursery area.[5] Foraminiferans are abundant around the reefs, and diatoms are scarce. The consortium of organisms living in and around sponge reefs has changed very little since the Jurassic.[6]

Destruction of sponge reefs

[edit]
Bottom trawling, in which a net is dragged along the sea floor, is particularly damaging to sponge reefs

The reefs are susceptible to damage by fishing, especially bottom trawling and dredging. In typical groundfish trawling, a large net is dragged across the ocean floor, its mouth held open by two 2 tonne doors called otterboards. The siliceous skeleton of the sponges is fragile, and these organisms are easily broken by physical impact. The impacts of bottom trawling have been observed in three of the reefs in the QCB.[3] Trawling damage appears as parallel tracks 70–100 m apart that may extend for several kilometers. Each trawl track is 10 cm deep, 20 cm wide, and occurs at depths of 210–220 m. Sponges in the vicinity of trawl tracks are shattered or completely removed.

While less harmful, hook and line fishing as well as crustacean trapping may also damage the reefs. When the fishing gear is hauled to the surface, the lines and traps drag along the ocean floor and have the potential to break corals and sponges. Broken sponge "stumps", as well as those with abraded sides, were found in regions where line and trap fishing took place.[3]

Breakage of reef sponges may have dire consequences for the recruitment of new sponges, as sponge larvae require the siliceous skeletons of past generations as a substrate.[6] Without a hard substrate, new sponges cannot settle and regrow broken parts of the reef. It has been estimated that broken sponge reefs may take up to 200 years to recover.[3]

In addition, offshore oil and gas exploration threatens the reefs. The government of British Columbia has lifted a moratorium preventing exploratory drilling and tanker traffic in Hecate Strait and Queen Charlotte Sound, and the area has been leased by the oil and gas industry.[3] Even if exploratory drilling is not done on or immediately adjacent to the reefs, it may still have a negative impact by increasing the amount of sediment in the seawater, or through hydrocarbon pollution.[4]

Protection

[edit]

In 1999, Fisheries and Oceans Canada requested that groundfish trawlers voluntarily avoid the sponge reefs. In 2002, following reports of new reef damage sustained since 1999, the ministry initiated regulated closures of groundfish trawling and voluntary closures of shrimp trawl fishing in areas where sponge reefs were known to inhabit.[3]

Protection of the four sponge reefs in Hecate Strait and Queen Charlotte Sound was included as a "management issue" in the 2005/06 groundfish trawling management plan.[10] The management plan recommended that an additional 9 km (5.6 mi) buffer zone around the reefs be added to the existing groudfish trawl closures.[3] The reefs were also being considered as locations for future Marine Protected Areas (MPAs).[3] Although MPAs may be more effective than fishery closures for long-term protection of the reefs from bottom trawling, the oil and gas industry would still pose a threat.[10]

In 2008, the issue of preserving sensitive underwater ecosystems along the North Coast of British Columbia were consolidated within the Pacific North Coast Integrated Management Area. The goal was to develop a plan to conserve this relatively undeveloped region, while fostering sustainable economies on the coast, which promised to make Canada a world leader in marine conservation. However, in 2011, the ministry withdrew support for the process in favour of greater consistency with ocean planning on the other coasts of Canada.

In February 2017, the sponge reefs of Hecate Sound and Queen Charlotte Sound were formally protected within the Hecate Strait and Queen Charlotte Sound Glass Sponge Reefs Marine Protected Area. The marine protected area covers an area of 2,410 km2 (930 sq mi) and prohibits any activity that could disturb or destroy the sponge reefs.[11]

See also

[edit]

References

[edit]
  1. ^ Dunham, A.; Archer, S. K.; Davies, S. C.; Burke, L. A.; Mossman, J.; Pegg, J. R.; Archer, E. (1 October 2018). "Assessing condition and ecological role of deep-water biogenic habitats: Glass sponge reefs in the Salish Sea". Marine Environmental Research. 141: 88–99. doi:10.1016/j.marenvres.2018.08.002. ISSN 0141-1136. PMID 30115533. S2CID 52015990.
  2. ^ a b c d e f
    Hexactinellid sponge reefs on the British Columbia continental shelf: Geological and biological structure (Report). DFO Pacific Region Habitat Status Report. Department of Fisheries and Oceans. February 2000.
  3. ^ a b c d e f g h i j k l m n
    Jamieson, G.S.; Chew, L. (2002). Hexactinellid sponge reefs: Areas of interest as marine protected areas in the north and central coast areas (Report). Can Sci Adv Sec Res Doc. Vol. 12.
  4. ^ a b Protecting the glass sponge reefs from offshore oil and gas (PDF) (Report). Canadian Parks and Wilderness Society. 2004. Archived from the original (PDF) on 7 November 2004. Retrieved 28 March 2008.
  5. ^ a b c d e f g h i j k l m
    Whitney, F.; Conway, K.; Thomson, R.; Barrie, V.; Krautter, M.; Mungov, G. (2005). "Oceanographic habitat of sponge reefs on the western Canadian continental shelf". Cont Shelf Res. 25 (2): 211–226. doi:10.1016/j.csr.2004.09.003.
  6. ^ a b c d e f g h i j k l m n o p q
    Krautter, M.; Conway, K.; Barrie, J.V.; Neuweiler, M. (2001). "Discovery of a "living dinosaur": Globally unique modern hexactinellid sponge reefs off British Columbia, Canada". Facies. 44: 265–282. doi:10.1007/BF02668178. S2CID 128410530.
  7. ^ a b c
    Conway, K.; Barrie, J.; Krautter, M. (2005). "Geomorphology of unique reefs on the western Canadian shelf: sponge reefs mapped by multibeam bathymetry". Geo-Mar Lett. 25 (4): 205–213. doi:10.1007/s00367-004-0204-z. S2CID 129356194.
  8. ^ Eluik, L. (1991). "Siliceous sponge communities, biological zonation, and recent sea-level change on the Arctic margin: Ice Island results: Discussion". Can J Earth Sci. 28 (3): 459–462. doi:10.1139/e91-040.
  9. ^ Archer, Stephanie K.; Kahn, Amanda S.; Thiess, Mary; Law, Lauren; Leys, Sally P.; Johannessen, Sophia C.; Layman, Craig A.; Burke, Lily; Dunham, Anya (24 September 2020). "Foundation species abundance influences food web topology on glass sponge reefs". Frontiers in Marine Science. 7. Frontiers Media SA. doi:10.3389/fmars.2020.549478. ISSN 2296-7745. Material was copied from this source, which is available under a Creative Commons Attribution 4.0 International License.
  10. ^ a b
    Groundfish trawl integrated fisheries management plan (PDF) (Report). Department of Fisheries and Oceans. 2005. Retrieved 28 March 2008.
  11. ^ "Hecate Strait/Queen Charlotte Sound Glass Sponge Reefs Marine Protected Area (HS/QCS MPA)". Fisheries and Oceans Canada. www.dfo-mpo.gc.ca (Press release). Government of Canada. 18 September 2019. Retrieved 10 September 2020.
[edit]