Marine life diverse but declining, finds survey
December 14, 2005
SUMMARY: A comprehensive census of all the marine life in the world’s oceans is halfway complete. The 10-year international project that began in 2000 and now involves some 1700 researchers from 73 countries has uncovered new evidence of rich biodiversity in the world’s oceans along with an alarming decline of many marine species.
1st Census of Marine Life at Mid-Point:
Exploring the Unknown, Assembling the Known, Defining the Unknowable
Census of Marine Life release
Drawing comparisons to the Domesday Book that comprehensively surveyed England in 1066, the Census has enrolled leading global experts in a 10-year scientific partnership, unprecedented in scale, to assess and explain the diversity, distribution and abundance of life in all oceans, a baseline against which future change may be measured.
They are assembling in one place for the first time most of what we know about marine life, and marking what is unknown and may yet be unknowable. They are reconstructing the history of ocean life since fishing became important, censusing the present state, and using the past and present to forecast future marine life. They are satisfying basic human curiosity about what lives beneath the waves as well as generating insights useful for better managing and preserving ocean resources.
Starting the 10-year project in 2000 with about 250 collaborators, an almost seven-fold increase has taken place in five years. Some 1,700 experts from 73 nations are today working to produce the 1st Census by 2010. In November 2005, some 150 leaders of all components of the Census met in Frankfurt to review progress and harmonize their efforts to cover all habitats and species by 2010.
The Census reached maturation in project breadth in 2005 with 17 initiatives, four of them new this year1. Expeditions to previously unexplored regions rose from 8 in 2004 to 14 in 2005, with many more planned through 2010. The years 2006-8 will see the most intense field work; the results will be analysed and integrated in 2009-10.
The research spans species from microbes to whales, from near-shore to mid-ocean, from the world’s deepest mud in the abyssal plains to the foamy and sparkling surface, from hot seafloor vents to the ice oceans at both poles. Areas of exploration include the submerged edges of continents, seamounts dotting the ocean’s floor, and coral reefs.
Using new approaches and technologies, including supersensitive visual and acoustic devices, Census researchers can sample life in all ocean realms and identify specimens quickly through genetic science and digital image libraries.
Census scientists photographed this jellyfish, Crossota millsae, in the depths of the Canada Basin, beyond its previously known range. ©2005, Kevin Raskoff.
A physconect siphonophore, Marrus sp., photographed during NOAA’s Arctic “Hidden Ocean” expedition in support of the Census of Marine Life. ©2005, Kevin Raskoff.
A new species of comb jelly, a cydipppid ctenophore, was discovered by Census scientists during a month-long expedition to the Arctic Ocean. ©2005, Kevin Raskoff.
Sea cucumbers such as Kolga hyalina were the dominant sea floor fauna at several stations during an expedition to the Canada Basin. ©2005, Bodil Bluhm and Katrin Iken/NOAA.
This red peniagone sea cucumber is one of four new species of sea cucumbers discovered by Census scientists along the Mid-Atlantic Ridge. ©2004, Andrey Gebruk.
“Immense scale challenges the Census,” says Dr. Victor A. Gallardo of Chile, Vice-Chair of the Census Scientific Steering Committee and a professor at the Universidad de Concepcion in Chile, “The deep-sea floor is an area of 300 million square kilometers, of which the area sampled to date is equal to a few football fields. The number of seamounts” (underwater mountains rising at least 1,000 meters from the ocean floor, often extinct volcanoes that failed to grow tall enough to become islands) “is estimated at between 30,000 and 100,000, of which a few hundred have been biologically sampled, less than 50 of them sampled well. Representative sampling on a global scale is the key for an effective census.”
Discoveries and highlights, 2005: Fish with Chips
Marine animals carrying computer chips that report their locations show that fish and many other species use well-defined ocean zones.
The POST (Pacific Ocean Shelf Tracking) project has revealed the Pacific migration routes of young wild salmon from US and Canadian rivers. Because many salmon die in the ocean, knowing their usual travels along marine highways has far-reaching implications worldwide for authorities who determine when fisheries should be open or closed to conserve endangered stocks.
The salmon are implanted with almond-sized electronic tags scanned by devices on the ocean floor when they pass over, like an electronic tag on a car passing through a highway tollbooth (see animation). The data reveal the movement and survival of each tagged fish as it migrates within the system and the distribution of all the tagged fish.
The current array stretches more than 1,550 km, from Washington State, through British Columbia to north of the Alaskan panhandle. By 2010, the CoML team aims to cover the entire western North America coast, with a goal to replicate the network on continental shelves worldwide. Continental shelves average about 80 km (50 mi) wide, and the edge of the shelf occurs at an average depth of about 200 m (660 ft), where it falls steeply into the deep sea. Salmon and many other marine animals travel extensively along shelves.
The number of fish tagged almost tripled in 2005 some 2,700 salmon from 19 US and Canadian stocks in 16 river systems, up from 1,050 fish tagged from 14 stocks in 8 river systems in 2004. The array performed nearly flawlessly, revealing substantial differences in the paths, speed, distribution and survival of species and stocks within species, both wild and from hatcheries.
Among other benefits, the work will provide clues how fish behaviour would change should ocean waters warm.
Says POST lead scientist, David Welch: “New developments in the technology mean that we will be able to monitor individual fish with tags that will last 10-20 years. For salmon, this means we will also be able to monitor the return migration of adults, providing information that could help better protect endangered stocks.”
Science Suggests Smart Fishing
“The dream of abundant and sustainable stocks of commercial fish is now one step closer, thanks to this Census of Marine Life program. The new data reveal for the first time those zones of the ocean where we have the highest leverage for conservation and thus smarter fishing,” said D. James Baker, President of the Academy of Natural Sciences of Philadelphia and former long-time chief of the US National Oceanic and Atmospheric Administration, responsible for management of marine fisheries.
Why did the Fish Cross the Ocean?
The TOPP (Tagging of Pacific Pelagics) project, meanwhile, found many salmon sharks (Lamna ditropsis) from Alaska share with humans an attraction to warmer winter destinations and frequently migrate to destinations like Hawaii. Growing to more than 300 kilograms (660 pounds), the salmon sharks can attain speeds of more than 50 kilometers (30 miles) per hour. The project’s shark team also recorded an unprecedented 305-day track of a white shark that completed a full migratory cycle from coastal waters to off-shore and back again.
TOPP’s state-of-the-art tags have also allowed marine turtle researchers to determine how much energy a leatherback sea turtle burns at sea. Says TOPP researcher and postdoctoral Research Associate at Duke University Bryan Wallace, “Imagine that the turtles are cars. These measurements allow us to know their ratings for miles per gallon on the road, not just idling in traffic. And with the help of habitat data the turtles are collecting, TOPP research may just help make traveling a bit safer for this highly endangered species.”
Discoveries and highlights, 2005: Diversity
Carnivorous Sponges and other New Species in Southern Oceans: Unexpected biodiversity greeted scientists on two expeditions to the abyssal plains and basins of the South Atlantic and Southern Oceans. Although those seas are low in biomass, they are rich in variety, and scientists say 50% to 90% of specimens collected from the two expeditions are new to science. The southern deep abyss may hold reservoirs of genetic diversity and evolutionary novelties. Among the most intriguing creatures were tiny carnivorous sponges, about 5 mm (0.2 inches) in diameter, which engulf other organisms with their “mouths” (sponges typically feed by filtering small particles from the water) Three of four carnivorous sponge species found in the Southern Ocean abyss had never been seen before. Sponges with calcium skeletons living much deeper than expected also created surprise. Also found: minute unicellular animals (called “xenophyophore”) using sediment grains to construct delicate shells that resemble soccer balls.
Novelties Still in North Atlantic: Exploring the northern Mid-Atlantic Ridge, beneath the most-traveled ocean surface on Earth, researchers documented several new and rare species, including strange varieties of deep-sea fish, two possibly new species of squid and, at the ocean floor, at least four new species of sea cucumbers. They also found almost one-quarter of demersal (deep swimming) fish species identified were new to the study area, reflecting how much there is yet to learn about the distribution and abundance of species known already.
DNA Identifiers for 800 Fish: DNA barcodes, a standardized segment of the genome, can rapidly and accurately identify species. The Census now has a library of barcodes for almost 800 fish species, and another 1,000 species will be added by mid-2006. Researcher Bronwyn Innes (Tasmania, Australia) barcoded eight tuna species and used the barcodes to identify tuna carcasses on longliners in the Indian Ocean. Some misidentifications were revealed, including instances of endangered Southern Bluefin being misidentified as yellowfin or bigeye tuna.
Microbe Database: Marine microbes are the tiniest of ocean species but constitute 90% of the ocean’s biomass and cycle 98% of the carbon and nitrogen. To census microbes, CoML in 2005 launched an array of online resources that allows researchers to exploit molecular, environmental, geospatial, and taxonomic information, “MicrOBIS”. MicrOBIS allows researchers to cross-check the identity of collected microbes against known species. Discoveries and highlights, 2005: Distribution
Unexpected Presences in Arctic: Census explorers in the Arctic Ocean’s frigid Canada Basin discovered many creatures never seen there before, including several species of squid and the area’s first known octopus.
First Atlantic Hydrothermal Vent South of Equator: An international team of researchers, towing remotely operated vehicles to explore the southern Mid- Atlantic Ridge, found the first known hydrothermal vents south of the equator in the Atlantic. They sampled animals adapted to life in these extreme vent environments, where water super-heated to 350° C in Earth’s crust flows from “black smokers” on the deep ocean floor. Comparison of the specimens collected with those found on hydrothermal vents previously discovered north of the Equator provides clues to the mysterious deep currents that may disperse them.
Whales Follow Undersea Ridges: Tagging of baleen whales show they use the mid-ocean ridge as a feeding area and north-south migration route in the North Atlantic.
Expansion of Near-shore Coverage: In a cooperative effort to catalog biodiversity in the near-shore environment, scientists and volunteers are now working at 80 official Census sites around the world, encompassing more than three-quarters of the world’s coastlines.
Discoveries and highlights, 2005: Abundance
Dead Zone around Tsunami Epicenter: On the first scientific expedition to the epicenter of the December 2004 tsunami, deadliest in recorded history, Census biologists found little or no effect on deep-sea fauna except at one site off Sumatra roughly 4000 m (2.5 miles) deep, where five months after the disaster there was no evidence of large animals during an 11 hour dive. The absence of biological life at the site was “unprecedented in 25 years of deep-sea sampling.”
Gulf of Maine Fluctuations: A joint operation of scientists coordinating data from surface ships from small airplanes documented in 2005 major fluctuations in the abundance of feeding whales, pelagic fish, and plankton in the Gulf of Maine.
Reconstruction of North Sea Marine Life back to Middle Ages: Creatively mining historical data from such sources as salt tax records, Census researchers have revealed drastic declines in populations of whales, seals, birds, large fish, and oysters during the past 500 years in the Wadden Sea, part of the North Sea bordering Denmark, Germany, and the Netherlands. The area once teeming with large animals would be unrecognizable to the early civilizations that lived there, characterized today by quiet mud flats. Ocean historians also documented that recent conservation efforts such as hunting bans and habitat protection have benefited seals as well as some birds.
Global Demography of Tuna and Billfish since 1950: Using records of fish hooked on longlines in open oceans, researchers found the abundance and species diversity of large pelagic fish declined rapidly over the past 50 years. Global concentrations of such key predators such as tuna, marlin, and swordfish decreased dramatically worldwide. The research also uncovered four regions where high diversity persists off the east coasts of the US, Australia, and Sri Lanka; south of Hawaii; and in the South-Eastern Pacific.
Discoveries and highlights, 2005: Synthesis
North Pacific Pilot Inventory: To test the feasibility of the global Census, a team of CoML experts in the North Pacific Science Organization (a.k.a. PICES) prepared the pilot Census “Marine Life in the North Pacific: The Known, Unknown, and Unknowable.” The report surveys bacterio-plankton, phytoplankton, zooplankton, unexploited fishes and invertebrates, commercially important fishes and invertebrates, seabirds, marine mammals, and turtles. While everything cannot be known in detail because of the vastness of the system and rapid fluctuations of some populations, the North Pacific report encouragingly points the way toward the 2010 Census.
OBIS Inventory Grows
Perhaps the foremost legacy of the inaugural Census will be the geographical information system it is creating for all data about marine life where the species of the specimen and the place it was observed are reliably recorded.
A $9.5 million meta-database, the Ocean Biogeographical Information System (OBIS), now links 60 databases containing 8.4 million taxonomic records (species, date, latitude, longitude, and depth found), an increase of 62% from 5.2 million records last year.
OBIS today contains more than 40,000 of an estimated 230,000 marine species described in science literature so far (which may only represent only one-tenth of all marine species in existence).
Of the 40,000 species of all types inventoried, 78 are marine fish newly added in the first 11 months of 2005, an average of 6.5 species added monthly. The total number of marine fish species in the database is now 15,717.
OBIS (www.iobis.org) is intended to become the world’s primary source of species distribution data essential to knowing if a species is rare or common, where an alien invasive species originated, and if certain ocean areas are species hotspots that merit special protection. Ten regional nodes were established in 2005 to make it easier for users around the world both to deposit and access data.
Best represented species: some 80% of known fish and other marine vertebrates, as well as anemones and corals, are now included in the OBIS catalogue of life.
Census of Marine Life sponsors:
Support for the Census of Marine Life comes from government agencies concerned with science, environment, and fisheries in a growing list of nations as well as from private foundations and companies. The Census is associated or affiliated with several intergovernmental international organizations including the Intergovernmental Oceanographic Commission of the UN, the Food and Agriculture Organization of the UN, the UN Environment Programme and its World Conservation Monitoring Centre, the Global Biodiversity Information Facility, the International Council for the Exploration of the Seas, and the North Pacific Marine Science Organization. It is also affiliated with international nongovernmental organizations including the Scientific Committee on Oceanic Research and the International Association of Biological Oceanography of the International Council for Science. The Census is led by an independently constituted international Scientific Steering Committee whose members serve in their individual capacities and a growing set of national and regional implementation committees.
For more check out coml.org.
Coralreeffish.com, a coral reef fish research site, today announced the availability of a photographic web-guide to the late-stage larvae of coral reef fishes. The guide is aimed at both assisting researchers in identifying the myriad fish larvae that are caught in reef surveys and providing an overview of this intriguing, and often invisible, world to students and interested laymen.
Coral reefs decimated by 2050, Great Barrier Reef’s coral 95% dead
Australia’s Great Barrier Reef could lose 95 percent of its living coral by 2050 should ocean temperatures increase by the 1.5 degrees Celsius projected by climate scientists. The startling and controversial prediction, made last year in a report commissioned by the World Worldwide Fund for Nature (WWF) and the Queensland government, is just one of the dire scenarios forecast for reefs in the near future. The degradation and possible disappearance of these ecosystems would have profound socioeconomic ramifications as well as ecological impacts says Ove Hoegh-Guldberg, head of the University of Queensland’s Centre for Marine Studies.
According to an international team of researchers based in Australia’s Great Barrier Reef, using recordings of reef sounds may increase reef fish stocks depleted by shipping traffic, underwater drilling and overfishing. Scientists have discovered that some species of young coral reef fish are lured back to home reefs by sounds they hear while still developing in the egg. By piping in convincing reef music,’ consisting of recorded fish and shrimp noises through underwater speakers, marine biologists have been able to attract reef fish to artificial reefs to start new colonies. In the future, researchers hope to employ the same tactics to lead young reef fish to natural reefs where fish stocks have been decreased by outside factors or to populate newly established conservation areas.
The largest island off the Central American Pacific coast may be hiding big secrets in its reefs, among them, a possible cure for malaria. Coiba, an island 12 miles off the coast of Panama and once a notorious penal colony, is poised on the brink of transition and transformation. The 10-mile wide and 30-mile long island possesses a unique ecology that may host potential drugs for treating numerous ills. The future of Coiba depends on how its resources are managed by the government.
While there have been numerous articles written recently about the proliferation of artificial island projects, the astounding “The World” venture among them, few have addressed or assessed the environmental impact of such massive undertakings and the transformation of both the sea and landscape. Until recently, Nakheel, the government-controlled corporation developing these ambitious projects, has been able to focus predominantly on promoting rather than defending the islands, but new evidence of environmental detriment is bringing the company and its projects under fire from certain groups.
This article features a modified news release from the Census of Marine Life.