Lifeboat Foundation

In a new scientific article, researchers at Uppsala University describe how, using a completely new method, they have synthesised an artificial enzyme that functions in the metabolism of living cells. These enzymes can utilize the cell’s own energy, and thereby enable hydrogen gas to be produced from solar energy.

Hydrogen gas has long been noted as a promising energy carrier, but its production is still dependent on fossil raw materials. Renewable hydrogen gas can be extracted from water, but as yet the systems for doing so have limitations.

In the new article, published in the journal Energy and Environmental Science, an interdisciplinary European research group led by Uppsala University scientists describe how artificial enzymes convert solar energy into hydrogen gas. This entirely new method has been developed at the University in the past few years. The technique is based on photosynthetic microorganisms with genetically inserted enzymes that are combined with synthetic compounds produced in the laboratory. Synthetic biology has been combined with synthetic chemistry to design and create custom artificial enzymes inside living organisms.

Continue reading “Artificial enzymes convert solar energy into hydrogen gas” »

A fluorescent molecule whose luminosity depends upon how fast it can rotate is helping researchers measure how viscous the fluid is inside different parts of a cell.

“There’s a lot of interest in the biophysical field in developing chemical probes that can be used to characterize the environment inside a cell or any kind of biological compartment,” says Peter Bond, from A*STAR’s Bioinformatics Institute.

Researchers from the United Kingdom and Singapore—including A*STAR scientists such as Bond’s team who led the computational arm of the project—have modeled, developed and tested a molecule comprising two parts; a genetic probe designed to home in on particular proteins, so it can be directed to wherever in a cell that protein is found; and a molecular rotor—a fluorescent molecule whose fluorescence lasts longer, the slower it spins. A*STAR researchers simulated how this molecule would perform in different microenvironments at scales of millionths or even billionths of a meter.

Continue reading “Fluorescent molecule could shed light on the inner workings of the cellular environment” »

https://www.youtube.com/watch?v=EX1PiRyIOis

They used a gene drive to create a genetic time bomb.

The display screens of modern televisions, cell phones and computer monitors rely on liquid crystals—materials that flow like liquids but have molecules oriented in crystal-like structures. However, liquid crystals may have played a far more ancient role: helping to assemble Earth’s first biomolecules. Researchers reporting in ACS Nano have found that short RNA molecules can form liquid crystals that encourage growth into longer chains.

Scientists have speculated that life on Earth originated in an “RNA world,” where RNA fulfilled the dual role of carrying genetic information and conducting metabolism before the dawn of DNA or proteins. Indeed, researchers have discovered catalytic RNA strands, or “ribozymes,” in modern genomes. Known ribozymes are about 16–150 nucleotides in length, so how did these sequences assemble in a primordial world without existing ribozymes or proteins? Tommaso Bellini and colleagues wondered if liquid crystals could help guide short RNA precursors to form longer strands.

To find out, the researchers explored different scenarios under which short RNAs could self-assemble. They found that at high concentrations, short RNA sequences (either 6 or 12 nucleotides long) spontaneously ordered into liquid crystal phases. Liquid crystals formed even more readily when the researchers added magnesium ions, which stabilized the crystals, or polyethylene glycol, which sequestered RNA into highly concentrated microdomains. Once the RNAs were held together in liquid crystals, a chemical activator could efficiently join their ends into much longer strands. This arrangement also helped avoid the formation of circular RNAs that could not be lengthened further. The researchers point out that polyethylene glycol and the chemical activator would not be found under primordial conditions, but they say that other molecular species could have played similar, if less efficient, roles.

The field of epigenetics sits precariously on the precipice of the classic nature versus nurture debate. Instead of a simple environment versus genetics dichotomy, epigenetic examines how specific genes are either switched on or off through external forces encountered in a person’s lifetime. Striking new research from scientists at the University of British Columbia and Harvard University is suggesting that adults who were victims of abuse as children may carry an imprint of that trauma in regions of their DNA.

Today, we would like to share with you a talk by Dr. Michael West from AgeX Therapeutics, a company developing therapies to combat age-related diseases by encouraging the body to regenerate cells and tissues.

On July 12th, we hosted our first conference, Ending Age-Related Diseases: Investment Prospects & Advances in Research, at the Frederick P. Rose Auditorium, which is part of the Cooper Union campus in New York City. The packed event saw a range of people from research, investment, and the wider community coming together for a day of science and biotech business presentations and panels.

Continue reading “The Reversibility of Human Aging” »

To rapidly detect the presence of E. coli in drinking water, Cornell University food scientists now can employ a bacteriophage — a genetically engineered virus — in a test used in hard-to-reach areas around the world.

Be gone flat earthism.

The nature-versus-nurture argument of intelligence just got a lot more complicated with the discovery that the environment can modify the expression of a key gene in the brain, affecting intelligence far more than we previously thought.

Such a finding may not come as a surprise if you remember that numerous genes influence our IQ and stressful experiences can lock and unlock genes in our brains. Yet having hard evidence of the link will no doubt stir debate on just what it means to be “smart”.

Continue reading “Your Environment Could Be Changing Your IQ on a Genetic Level, Study Finds” »