Scientists have found the most primitive creature to have had a face like humans, and there's definitely something fishy about it.This first face belongs to the newfound species Entelognathus primordialis, "primordial complete-jaw," an armored fish that plied the seas nearly 420 million years ago. Related fish from that period had simple jaws made mostly of cartilage. But Entelognathus had a complex jaw, knit together from many bony plates like those found in the jaws of humans and dogs and thousands of other living animals with backbones. That strangely modern jaw — stuck on an otherwise primitive body — gives it what could be called the earliest known modern face."This is like finding the nose of a space shuttle in a hay wagon from the Middle Ages," paleontologist Xiaobo Yu of Kean University in New Jersey, one of the researchers responsible for the new find, says via e-mail. The new fish is also contributing to a major upheaval in scientists' understanding of the base of the family tree that spawned rattlesnakes and guppies and penguins and, eventually, Homo sapiens.The first Entelognathus fossil was unearthed in China in 2010, but it was not until scientists had chipped away at the specimen in the lab that they realized they were onto something very weird. Their new fish looked like a placoderm, an ancient swimmer girded in homegrown armor made of bony plates. The fish, described in this week's issue of Nature, had small, almost immobile eyes and a flat forehead. And then there was its lower face: a jigsaw puzzle of interlocking bones a lot like humans. It's a homely ancient fish with a supermodel's bone structure.Read the full article here.

Bycatch reduction, gear recovery and direct-seafood marketing are among the topics currently addressed through collaborative research with commercial and recreational fishermen.Other projects examine rockfish populations within the Rockfish Conservation Areas; yellowtail movement patterns in Southern California, and spawning populations of night smelt along the North Coast.All of the projects are unique in that fishermen are in some way directly involved with the research. They may have initiated the project’s basic concept, or they may be helping to collect data. In some cases, they are also helping analyze it. The unifying theme is that both anglers and commercial fishermen are engaged in work that often, previously has been isolated within academic or management circles.California Sea Grant supports this innovative research through our partnership with the non-profit Collaborative Fisheries Research West, funded by the California Ocean Protection Council. California Sea Grant Extension specialists are lead investigators on several of the projects, as well.The 12 projects listed below include both large, multi-year grants, with awards ranging from $206,000 to $242,000 plus matching funds, and mini grants, with awards at or below $25,000 plus matching funds.Read the full article here.

NORMANBY ISLAND, Papua New Guinea — Katharina Fabricius plunged from a dive boat into the Pacific Ocean of tomorrow.She kicked through blue water until she spotted a ceramic tile attached to the bottom of a reef.A year earlier, the ecologist from the Australian Institute of Marine Science had placed this small square near a fissure in the sea floor where gas bubbles up from the earth. She hoped the next generation of baby corals would settle on it and take root.Fabricius yanked a knife from her ankle holster, unscrewed the plate and pulled it close. Even underwater the problem was clear. Tiles from healthy reefs nearby were covered with budding coral colonies in starbursts of red, yellow, pink and blue. This plate was coated with a filthy film of algae and fringed with hairy sprigs of seaweed.Instead of a brilliant new coral reef, what sprouted here resembled a slimy lake bottom.Isolating the cause was easy. Only one thing separated this spot from the lush tropical reefs a few hundred yards away.Carbon dioxide.In this volcanic region, pure CO2 escapes naturally through cracks in the ocean floor. The gas bubbles alter the water’s chemistry the same way rising CO2 from cars and power plants is quickly changing the marine world.In fact, the water chemistry here is exactly what scientists predict most of the seas will be like in 60 to 80 years.That makes this isolated splash of coral reef a chilling vision of our future oceans.Watch the introduction video.Read the complete article, watch the videos and look at the images here.  

Scientists expect climate change and warmer oceans to push the fish that people rely on for food and income into new territory. Predictions of where and when species will relocate, however, are based on broad expectations about how animals will move and have often not played out in nature. New research based at Princeton University shows that the trick to more precise forecasts is to follow local temperature changes.The researchers report in the journal Science the first evidence that sea creatures consistently keep pace with "climate velocity," or the speed and direction in which changes such as ocean temperature move. They compiled 43 years of data related to the movement of 128 million animals from 360 species living around North America, including commercial staples such as lobster, shrimp and cod. They found that 70 percent of shifts in animals' depth and 74 percent of changes in latitude correlated with regional-scale fluctuations in ocean temperature."If we follow the temperature, which is easier to predict, that provides a method to predict where the species will be, too," said first author Malin Pinsky, a former Princeton postdoctoral researcher in ecology and evolutionary biology who is now an assistant professor of ecology and evolution at Rutgers University."Climate changes at different rates and in different directions in different places," he said. "Animals are basically being exposed to different changes in temperature."The researchers compiled survey data collected from 1968 to 2011 by American and Canadian fishery-research centers and government panels. The surveys recorded surface and bottom temperatures, as well as the complete mass of animals in nine areas central to North American fisheries: the Aleutian Islands; the eastern Bering Sea; the Gulf of Alaska; the West Coast from Washington to California; the Gulf Coast from Louisiana to Mexico; the Northeast coast from North Carolina to Maine; the coast of Nova Scotia; the southern Gulf of St. Lawrence; and the Atlantic Ocean east of Newfoundland.Details of the surveys revealed that sea creatures adhere to a "complex mosaic of local climate velocities," the researchers reported. On average, changes in temperature for North America moved north a mere 4.5 miles per decade, but in parts of Newfoundland that pace was a speedier 38 miles north per decade. In areas off the U.S. West Coast, temperatures shifted south at 30 miles per decade, while in the Gulf of Mexico velocities varied from 19 miles south to 11 miles north per decade.Animal movements were just as motley. As a whole, species shifted an average of 5 miles north per decade, but 45 percent of animal specific populations swam south. Cod off Newfoundland moved 37 miles north per decade, while lobster in the northeastern United States went the same direction at 43 miles per decade. On the other hand, pink shrimp, a staple of Gulf Coast fisheries, migrated south 41 miles per decade, the researchers found.Read the full article here.

SEAFOOD.COM NEWS [seafoodnews.com] Sept 12, 2013 - Ray Hilborn, Professor, School of Aquatic and Fishery Sciences University of Washington was one of the people who testified at the House Committee on Natural Resources Magnuson hearing this week. Ray makes the point that we have lost sight of the original goals of Magnuson, which were to achieve jobs and economic benefits from sustainable resources, as well as protecting those resources from over use. Accordingly, he suggests that too rigid an approach to fishery management focusing exclusively on overfishing has distorted the outcome, so that while we lose perhaps 3% of total yield to continued overfishing, we lose as much as 48% of achievable yield by not fishing enough. He calls for a rebalancing of these goals, so that we may have both sustainable fisheries, and the economic benefits that are acheivable from our resources.Read the full testimony transcript here.

In recent weeks, there has been a significant uptick in news from Fukushima, Japan. Officials from the Japanese government and the Tokyo Electric Power Company, or TEPCO, admitted that radioactive water is still leaking from the nuclear plant crippled by the 2011 earthquake and tsunami.The new revelations about the amount of water leaking from the plant have caused a stir in the international community and led to additional scrutiny of Pacific Ocean seafood. Last week, South Korea announced it had banned all imports of Japanese seafood from a large area around Fukushima. And Al Jazeera reported that the cost to the region’s fishing industry over the past two years exceeds $3.5 billion.Now, fears are mounting that the radiation could lead to dangerous contamination levels in seafood from more of the Pacific Basin. Numerous blog posts and articles expressed concern about the potential for higher concentrations of radioactive particles, particularly in highly migratory species such as tuna that may have encountered Fukushima’s isotopes—including highly dangerous and toxic materials such as cesium-137, strontium-90, and iodine-131—on their transoceanic travels.Amid alarmist outcry and opposing assurances that the radiation levels in fish are no more harmful than what’s found in the average banana, I decided to dig a little deeper, and a few weeks ago, I posted a brief analysis on Climate Progress. After reading the comments on that piece, it became clear I needed to do a bit more homework.Read the full article here.

ST. PETERSBURG, Fla. — Acidification of the Arctic Ocean is occurring faster than projected according to new findings published in the journal PLOS ONE.  The increase in rate is being blamed on rapidly melting sea ice, a process that may have important consequences for health of the Arctic ecosystem.Ocean acidification is the process by which pH levels of seawater decrease due to greater amounts of carbon dioxide being absorbed by the oceans from the atmosphere.  Currently oceans absorb about one-fourth of the greenhouse gas.  Lower pH levels make water more acidic and lab studies have shown that more acidic water decrease calcification rates in many calcifying organisms, reducing their ability to build shells or skeletons.  These changes, in species ranging from corals to shrimp, have the potential to impact species up and down the food web.The team of federal and university researchers found that the decline of sea ice in the Arctic summer has important consequences for the surface layer of the Arctic Ocean.  As sea ice cover recedes to record lows, as it did late in the summer of 2012, the seawater beneath is exposed to carbon dioxide, which is the main driver of ocean acidification.In addition, the freshwater melted from sea ice dilutes the seawater, lowering pH levels and reducing the concentrations of calcium and carbonate, which are the constituents, or building blocks, of the mineral aragonite. Aragonite and other carbonate minerals make up the hard part of many marine micro-organisms’ skeletons and shells. The lowering of calcium and carbonate concentrations may impact the growth of organisms that many species rely on for food.The new research shows that acidification in surface waters of the Arctic Ocean is rapidly expanding into areas that were previously isolated from contact with the atmosphere due to the former widespread ice cover."A remarkable 20 percent of the Canadian Basin has become more corrosive to carbonate minerals in an unprecedented short period of time.  Nowhere on Earth have we documented such large scale, rapid ocean acidification" according to lead researcher and ocean acidification project chief, U.S. Geological Survey oceanographer Lisa Robbins.Globally, Earth's ocean surface is becoming acidified due to absorption of man-made carbon dioxide. Ocean acidification models show that with increasing atmospheric carbon dioxide, the Arctic Ocean will have crucially low concentrations of dissolved carbonate minerals, such as aragonite, in the next decade.Read the full article here.

Around the world, the status of fish and fisheries is grim indeed. Approximately 85 percent of global fish stocks are either over-exploited, fully-exploited, depleted or recovering from depletion. But rigorous management efforts have resulted in some American fisheries making a comeback.The new report by the National Research Council assessed 55 fisheries and found 10 that have been rebuilt and five that showed good progress toward rebuilding; only nine continue to experience overfishing. What about the rest? Eleven have not shown strong progress in rebuilding but are expected to rebuild if fishing levels remain reduced and a whopping 20 were not actually over-fished despite having been initially classified as such.The report comes with a neat interactive online graphic to track the fate of fish populations in different regions over the years. By selecting particular species or geographic areas, users can watch, as for example, yelloweye rockfish becomes steadily overfished, as chinook salmon numbers – especially susceptible to changing environmental conditions – swing wildly back and forth, and the likes of lingcod, George’s Bank haddock, king mackerel and Bering Sea snow crab stage their marches toward recovery.The report is fairly technical, so for a summary – and an explanation of what it means in practical terms for U.S. fish consumers – Discovery News turned to Chris Dorsett, Director of Ecosystem Conservation Programs for the Ocean Conservancy.“If you look at a map of the United States and where overfishing is still occurring, it’s almost exclusively an east coast problem,” he points out. “And when I say east coast, I mean Gulf of Mexico as well. Where we have not seen success in terms of species recovering based on management actions, that could be due to climatic factors, which aren’t particularly good for productivity. It could be due to management regimes that aren’t particularly effective. But what exacerbates the issue is that, when you drive a population to an extremely low abundance level, environmental variability plays an even more meaningful role in the recovery of that population, so recovery is a little less predictable.”As the classic case in point, Dorsett points to cod fisheries off Canada, which collapsed in the 1990s and subsequently saw catches slashed essentially to zero. Despite such drastic measures, neither the fish population nor the fishery has shown signs of recovery.As the NRC report notes, however, there remains some variation: fishing pressure is still too high for some fish stocks, and others have not rebounded as quickly as plans projected. To a large extent, argues Dorsett, that’s a function of natural variability in fish populations and their environments, as well as differences in the ways fisheries have been managed over the years.In general, though, the news remains positive, increasingly so, and is reflected in the choices available to consumers.Read the full article here.