Shore Lab Discovery Center Blog

The Last Little Cow In The Ocean

I wish this was a happy blog post but it is not. This topic concens the Vaquita Porpoise. A species of Cetacean that is endemic to the Northern Gulf of California. It's name in Spainish means "little cow". It is the smallest, only 141 cm or 54 inches, rarest and most endangered porpoise living. Humankind has managed to kill all but 30. They are on the brink of extiction. They may not survive past 2018.

 u.1.SLDCWEB.jpgIllegal gill net fishing for another endangered species of fish the Totoaba is the problem. Gill nets set to catch the Totoaba also catch the Vaquita. The Vaquita drown in the nets once they are entangled. The Totoaba are illegally caught for their swim bladders used in you guessed it-Chinese medicine. The local fisherman cannot resist the profits made which out weigh the risks. 

When they are gone, the world will have lost another magnificient creature of the oceans and for what? So some shop in China can fool someome into thinking that the swim bladder from the endangered Totoaba they are selling will cure their ailments. All that remains is to ask the question: What kind of world are our childern going to inherit? and What are we going to do about it?

u.1.Vaquita.jpgBut there are organizations who are going to try and save this beautiful creature from extinction. For more information www.porpoise.org.

 Take a look at this video. https://youtu.be/IDxUV6Rn35g.

 

 

 

 

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Dr. Massimo Boyer

u.1.SLDCWEB.jpgNew book to be published by our collegue-Dr. Massimo Boyer. Massimo in a marine biologist, researcher, sailor, explorer, adventurer and underwater cinematographer. He recently had a bout with malaria contracted on expedition. He has recovered and we all wish him well.

 

Massimo is in the process of publishing his latest book on underwater photography and photographic techniques. He can use your help in getting the book to print.  Massimo's pictures and films are breath-taking. You can see his work at www.edge-of-reef.com. There you can get details on how you can help to support the publication. You can also find Massimo at Facebook, Twitter and Linkedin.

 

The web page is in Italian but Massimo is fluent in several languages including English. Just send him an email and he will give you details. You can also use google translate to get the English version of the page.

 

 

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Our Acid Seas

Climate Change, you hear the term daily. It is poorly understood and has split opinions around the globe. However, CO2 emissions are degrading our atmosphere and oceans at an alarming rate. Our planet can no longer keep up with the continued industrialization of the planet. We need to find solutions or we will face a tragic future. The great astrophysicist Steven Hawkins has estimated that humankind, in the next 1000 years, will have irreversibly alterated the planets atmosphere and depleted Earth’s resources. Humankind and our planet will go extinct. Well you say that’s a pretty long time from now but why does that mean to me today? To answer that we have to go back to the beginning of this story and u.1.SLDCWEB.jpglook at the root causes. It started at the beginning of the 20th century with the industrial age. Let’s back up even further to talk about climate changes that our earth has experienced over the millennia. The planet has been on a roller coaster ride of cooling and warming for billions of years. In fact we are coming out of a glaciation period that ended about 12,000 years ago.

To find a period analogous to what is going on now, you have to go back at least 55 million years, to what is known as the Paleocene-Eocene Thermal Maximum. During the PETM huge quantities of carbon were released into the atmosphere. The source of the carbon is still under speculation but it may have come from seeps under the ocean floor. Temperatures around the world soared by around ten degrees Fahrenheit, and marine chemistry changed dramatically. The ocean depths became so corrosive that in many places shells stopped piling up on the seafloor and simply dissolved.

 The PETM, while extreme, was not as extreme as what's happening today. The PETM took place over thousands of years, slow enough for the chemical effects to spread through the entire ocean. Today the rate of carbon emissions is roughly ten times as fast, and there's not enough time for the water layers to mix. In the coming century acidification will be concentrated near the surface, where most shell building organisms and all tropical corals reside.

So what makes this all so different today versus 55 million years ago? The emergence of humankind and Industrialization. Humankind is the largest consumer of resources on the planet. Our numbers are growing by the billions and the planet’s resources are finite. We are entrepreneurs. We make up crazy stories like “if you eat the gill cartilage of a Manta Rays it will cure your cancer”.  So we try and kill every last Manta Ray on the planet to make a sale, under the pretenses of a cure. Then we lobby for protection for Manta’s to CITIES who controls the financial trade in the Manta’s. Crazy, right?

Since the start of the industrial revolution in the 20th century, enough fossil fuels coal, oil, and natural gas have been burned to emitu.1.Carbon Cycle.jpg  more than 500 billion tons of CO2 into the atmosphere to eventually wind up in our oceans. The atmosphere now has a higher concentration of CO2 today than at any point in the past 800,000 years.

Carbon emissions are changing the oceans. In the 1990s an international team of scientists undertook a project that involved collecting and analyzing more than 77,000 seawater samples from different depths and locations around the world. The project lasted for over 15 years. It showed that the oceans have absorbed 30 percent of the CO2 released by humans over the past two centuries. They continue to absorb roughly a million tons every hour.

So it’s not just that these epoch events are cyclical and will happen anyway. It’s that this one is racing us to extinction and fueled by the CO2 we put into our atmosphere. For life on land; every ton of CO2 the oceans remove from the atmosphere is a ton that's not contributing to global warming. But for life in the ocean a great disaster is unfolding. The head of the National Oceanic and Atmospheric Administration, has called ocean acidification global warming's "evil twin."

 

u.1.acid-rain-2a.jpgThe pH scale, which measures acidity in terms of the concentration of hydrogen ions, runs from zero to 14. At the low end of the scale are strong acids, such as hydrochloric acid, that release hydrogen readily (more readily than carbonic acid does). At the high end are strong bases such as lye. Pure, distilled water has a pH of 7, which is neutral. Seawater should be slightly basic, with a pH around 8.2 near the sea surface. So far CO2 emissions have reduced the pH by about 0.1. Like the Richter scale, the pH scale is logarithmic, so even small numerical changes represent large effects. A pH drop of 0.1 means the water has become 30 percent more acidic. If present trends continue, surface pH will drop to around 7.8 by 2100. At that point the water will be 150 percent more acidic than it was in 1800. The acidification that has occurred so far is probably irreversible.  Even if CO2 emissions were somehow to cease today, it would take tens of thousands of years for ocean chemistry to return to preindustrial condition.

The biggest losers in our acid seas are the corals. Coral polyps are tiny animals that form a thin layer of living tissue on the surface of a reef. They're shaped like flowers, with six or more tentacles that captures food. External sources of food are a small fraction of what coral polyps consume. They get a majority of their food from algae that lives symbiotically within the polyp. The algae photosynthesize inside the polyp providing food for the coral. Photosynthesis is a process used by plants and other organisms to convert light energy into chemical energy that can be later released to fuel the organisms' activities. This chemical energy is stored in carbohydrate molecules such as sugars, which are synthesized from carbon dioxide and water.

Corals are also builders, each polyp surrounds itself with a protective, cup-shaped exoskeleton of calcium carbonate that contributes to the collective skeleton of the whole colony. To make calcium carbonate, corals need two ingredients: calcium ions and carbonate ions. Acids react with carbonate ions, in effect tying them up. So as atmospheric CO2 levels rise, carbonate ions become scarcer in the water, and corals have to expend more energy to collect them. Once a reef can no longer grow fast enough to keep up with erosion, this community will crumble.

Corals are just one kind of calcium dependent that is being affected by ocean acidification. There are thousands of others. Crustaceans like barnacles, sea stars, sea urchins, clams, oysters and coralline algae (their calcium carbonate secretions help cement coral reefs together). Scientists are beginning to explore the ways that ocean acidification is affecting more complex organisms such as fish and marine mammals. Changes at the bottom of the marine food web will inevitably affect the animals higher up.

So what this means to you is that your children’s children will live in a different world then you or I live in today. It will be barren of all that we currently take for granted. The beauty and majesty of our blue water planet will be gone. We would have destroyed their heritage. It's still possible to change all this by dramatically reducing CO2 emissions. At the moment, our oceans face a global economy built on cheap fossil fuels. By 2050 CO2 concentrations in the atmosphere will be roughly double what they were in preindustrial times. We need to halt or greatly curtail CO2 emissions and find alternatives to fossil fuels. Humankind needs to find ways to live sustainably. The time to correct the destruction to our planet is now in the 21st century. We owe our children their inheritance. There is no wiggle room. It’s now or never.

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Searching for Cures

There are scientists from around the globe who are busy searching our oceans and rainforests for new chemical compounds that can be sent back to the laboratory to be screened against known targets of human diseases. Having a reaction could mean the first step in developing a life-saving drug. The samples are coming from the natural world; plants, insects, animals, bacteria and fungi. In many cases there is a rush to explore some of the more remote areas before they succumb to human encroachment and the opportunity to find a potential candidate that could lead to a cure is lost.

u.1.SLDCWEB.jpgSuch is the case for researchers who have been combing the Amazonian Rainforest looking for Inga shrubs, which contain powerful toxins that could be useful to medical research. They have focused their efforts in the Ecuadorian Yasuni National Park. A section of the Amazonian Rainforest where researchers have found 60 species of Inga plants 40 of which were previously unknown to science. The mysteries of the Yasuni rainforest are many and they are at risk. Under the forest lies oil. The pressure to extract the oil is tremendous and the collateral damage would be irreparable.

It's not just the Rainforests that offer hope in curing the ailments of humankind. Our oceans and wetlands are offering some remarkable possibilities. Sponges, tunicates, sea anemones, corals, marine invertebrates and microorganisms are being investigated. Marine organisms produce a variety of chemical defenses to defend against predators. The chemicals react with the predators biological receptors much in the same way drug molecules interact in humans. Fungi and bacteria collected from the Everglades by the University of South Florida are being tested to develop a potential cure for MRSA (Methicillin Staphylococcus). The University has also had success with a starfish from Antarctica. Its chemical defenses shows promise as a cure for the biggest disease problem of the modern world-Malaria.

Then there is the curious case of the Bryozoan. A creature found in all the waterways of the world. A Bryozoan is a small creature about .5 millimeter in size, it lives in colonies and is a filter feeder. There are about 4000 known species but one in particular came from the waterways of the Florida Panhandle. In 1968 the National Cancer Institute, a Department of Health and Human Services placed an order for Bryozoans with a biological specimen collector from Panacea, Florida.

A class of drugs called Bryostatins were created from the Bryozoans as an anti-cancer chemotherapy. Then fate stepped in. During the course of the research a study patient with Alzheimer's began to regain his memory. Scientists discovered the drug’s hidden potential to stop Alzheimer’s disease and repair the damage it creates. Bryostatins have proven to be effective in rewiring connections in the brain that were previously destroyed by stroke, head trauma, or by the effects of aging.

The answers to our ailing planet and the ailments of humankind have been right under our noses and the natural world needs to be protected. Humankind's very existence will someday depend on a vibrant and diverse planet. Allowing the destruction of our oceans and rainforests means eminent extinction of millions of life forms including humankind. Our survival and Earths survival are contained in the vast libraries of the natural world. It is our responsibility in a world of technology and innovation to make science literacy for our youth a national priority. The next generation of scientists will finish the work begun by the current generation and go on to create their own discoveries.

 

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