Algae in darkness – Survival strategy unraveled

The world’s oceans teem with unicellular algae that carry out photosynthesis in the sunlight. It has been known for a while that the particularly abundant diatoms (unicellular algae with a silicate frustule) are also able to survive in the dark bottom of the ocean, where neither photosynthesis nor respiration with oxygen is possible. Scientists of the Max Planck Institute for Marine Microbiology now disclose this artifice of the algae in the journal Proceedings of the National Academy of Sciences: In darkness, the diatoms breathe with nitrate in place of oxygen.
Microalgae often measure only a few hundredths of a millimeter, but due to their vast abundance in the world’s oceans they are responsible for about 40% of the marine primary production, i.e., the biomass production via carbon dioxide fixation in the sunlight. They often appear as massive blooms near the sea surface or as greenish-brownish meadows on the sea floor, if still reached by sunlight. However, diatoms (unicellular algae with a silicate frustule) are also able to survive in the absence of sunlight and oxygen, for instance, buried in the sea floor. Anja Kamp, Dirk de Beer, Jana L. Nitsch, Gaute Lavik, and Peter Stief, scientists at the Max Planck Institute for Marine Microbiology in Bremen cultivated several diatom species in the laboratory to explore the metabolic process that allows the tiny algae to survive in darkness. A correlation was found between the nitrate that is stored by a diatom cell and its ability to survive in the absence of sunlight and oxygen. The more nitrate the cell contained, the longer it could survive in darkness where the cell does not have the possibility to produce oxygen via photosynthesis for its own respiration. In experiments with the coffee-bean-shaped diatom Amphora coffeaeformis, the scientists proved that diatoms use the nitrate stored in their cells for respiration in the absence of oxygen. Within just one day, most of the stored nitrate is used up, converted to ammonium, and excreted by the cell. A key finding of the Max-Planck scientists was that diatoms use nitrate just for respiration rather than for biomass production, as would be the case in sunlight. Anja Kamp says: “The rapid consumption of nitrate and the absence of biomass production tell us that nitrate respiration in diatoms is a metabolic process that only serves to prepare the cell for a resting stage and therefore nitrate respiration is not sustained for longer time periods.”
In bacteria, nitrate respiration in the absence of oxygen is nothing exceptional, as many of the bacteria studied at the Max-Planck-Institute are able to breathe with nitrate, sulfate, or even iron compounds. It is more spectacular to discover that algae, i.e., organisms with a cell nucleus, are able carry out both photosynthesis and nitrate respiration, each under different environmental conditions. These results have just been published in the renowned interdisciplinary journal Proceedings of the National Academy of Sciences.Further inquiries to:
Dr. Anja Kamp; Phone: +49 421 2028 856; akamp@mpi-bremen.de

or to the press officer:
Dr. Manfred Schlösser; Phone: +49 421 2028 704; mschloes@mpi-bremen.de
Download: http://www.pnas.org/content/early/2011/03/09/1015744108.full.pdf+html

Original article:

Diatoms respire nitrate to survive dark and anoxic conditions. Anja Kamp, Dirk de Beer, Jana L. Nitsch, Gaute Lavik, and Peter Stief. Proceedings of the National Academy of Sciences of the United States of America. doi:10.1073/pnas.1015744108

Farming Freshwater Algae on the High Seas

If you have been paying even the slightest attention to the algae industry, you probably have heard of companies like Solazyme or Synthetic Genomics, the big names that are making big public strides in the field. Algasol Renewables, on the other hand, is one name in the industry that you have probably never heard mentioned. However, Algasol looks to be on the brink of joining those big names as one of leaders in the algae industry with their photobioreactor system.

Photobioreactors (or PBR’s) come in many different shapes, sizes, and designs. Essentially, they consist of some clear material formed in a way that it can hold an algae-containing liquid. Typically, you will find them looking like long tubes, snaking back and forth, that allow sunlight to reach the algae-water concentration that is pumped through it. They work great for growing algae but have typically suffered from high initial and operating costs.

This is where Algasol comes into play. They have designed a photobioreactor system that can potentially cut costs by 90 percent. How have they done this? Well, their thinking has taken them outside the tube and placed them into a bag.

Basically, their system grows freshwater microalgae in large plastic bags that float on top of bodies of saltwater. There, as in any other bioreactor, nutrients and CO2 are pumped in to feed the algae.

This design led Frost & Sullivan to give Algasol their 2010 “Global Algae Biofuels Award.” According to them, “Algasol Renewables provides a critical and innovative method for micro algae biomass production. Its modular floating bag technology, a new variation of photobioreactors (PBRs), provides a low-cost design coupled with industrial scalability, optimal light exposure, high biomass concentration, low energy consumption, and efficient system control.”

The oceans of the world have a great potential to be the location for floating algae farms. First off, oceans cover around 70 percent of the world. With land (especially agricultural land) becoming a very precious commodity, moving production of fuel offshore is a major bonus.

Additionally, the ocean cuts out a lot of the energy costs associated with traditional PBR’s. For example, the water surrounding the bags acts as a temperature buffer, a process that would require spraying down the outsides of the photobioreactor in typical systems. Also, the wave action in the ocean helps to mix the algae in the bags, something that would otherwise take additional energy in land-based designs.

Now, some may be concerned about putting all this plastic into the ocean should a storm comes along or worried about what happens if these bags break. Luckily, engineers at Algasol have addressed both of these problems. If a storm comes along, the bags have been designed to be submerged beneath the water to levels up to 250 feet. There, they can wait out a tropical storm, hurricane, etc.

Researchers are also not too concerned if one of the bags breaks. Since the algae will be freshwater species, they will die when exposed to saltwater and there, researchers have concluded, they can become food for fish and other marine life.

Their system has proven very successful in testing conducted in conjunction with Arizona State University. Right now, after taking account for the costs, they estimate that a 250 hectares (or 418 acres) system can produce oil at $1.40/gallon before refining, or roughly $60 a barrel.

These costs are actually calculated from the lower end of production levels (35 grams of algae per square meter). Algasol has achieved significantly higher production levels and higher productivity would potentially lower the cost even more. However, reaching these production levels rely more on outside factors than on the system itself.

“At the end of the day, we are dealing with a live organism here,” Miguel Verhein, Executive Director of Algasol said. “If this organism is not taken care of under the right conditions, then we can have a variation in productivity that is irrelevant to the photobioreactor system.”

Overall, Algasol is solely a technology company that, according to Verhein, “just wanted to make the best PBR based on CAPEX/OPEX and scalability.” As such, their goal is to sell their patented product and method to companies rather than produce the algae themselves.

This goal is quickly becoming a reality, with several organizations, including one large oil company, looking to purchase their technology. As with algae industry as a whole, all that seems to be required for Algasol to make it big is a little more time.

Source: http://algaenews.com/?p=529

Pacific Rim BioEnergy

About Pacific Rim

We are a Canadian West Coast algae start-up that is dedicated to the growth and development of high-quality algae oil and biomass products. Our goal is to achieve commercial production capabilities and establish a distribution network of algae co-products and by-products into new Canadian West Coast markets.

We have assembled a skilled management team with a wide range of background experience and knowledge for the purpose of achieving our goals. If you need to contact our team for employment, investment or partnership opportunities, please visit our contact us page on our official web site. We will attempt to respond in a timely manner.

 

Source: http://www.pacificrimbiodiesel.com/?page_id=2

Alga for Feed Project

The world population growth – World Statistics, and increasing average standard of living, implies an increasing demand on feeds – total world feed output is approximately 614 million tonnes – IFIF Statistics. Animal feed consumption already exceeds direct human food consumption by almost four, and this ratio can only rise as the demand more animal protein increases. The ability to produce increasing amounts of feeds is one of the greatest challenges facing mankind, perhaps even greater than the environmental, energy, global warming and resource crisis. An increase in world population plays an important role on increasing feed demand. For instance, there are currently 6.5 billion people in the world. It is estimated that by 2030 there will be 2 billion more mouths to feed. This world population growth is driving meat consumption, and more meat means more grain … feed demand and animal feed supplements are rising!

Microalgae can play an important role in the future. They are one of the potential sources of foods and feeds provided by Nature with the potential to feed an ever growing and affluent population. Microalgae are the photosynthetic organisms in the first levels of the aquatic food-chains, on which an ever growing part of our food will have to come from. Our challenge is to domesticate these plants, as we have done with higher plants, to allow us to manage their large scale production for a wide range of applications, including feeds.

 

This Brief aims to (1) bring together the most relevant information available on microalgae feed production – and (2) promote the knowledge management to help accelerate the development of algae feeds. We hope that is Brief will contribute for the emergence and expansion of projects and ventures in this sector.

Source: http://www.algae4feed.org/about.php