Cancer causing mutations occur in our bodies every day – but luckily, we have specific genes that recognize these malignant events and keep cells from growing out of control. Only a few of these genes – called tumor suppressors – are currently known.

Now scientists at the University of North Carolina at Chapel Hill School of Medicine and Harvard Medical School have added to the list another powerful tumor suppressor, a gene called LKB1. Their research indicates that this gene is mutated in almost a quarter of all human lung cancers. In mice, these mutations result in tumors that are more aggressive and more likely to spread throughout the body.

With the finding that fever is produced by the action of a hormone on a specific site in the brain, scientists have answered a key question as to how this adaptive function helps to protect the body during bacterial infection and other types of illness.

Reported by researchers at Beth Israel Deaconess Medical Center (BIDMC), the study results appear today in Nature Neuroscience’s Advance Online Publication.

“This study shows how the brain produces fever responses during infections,” explains senior author Clifford Saper, MD, PhD, Chairman of the Department of Neurology at BIDMC and James Jackson Putnam Professor of Neurology and Neuroscience at Harvard Medical School.

Ocean historians affiliated with the Census of Marine Life have painted the first detailed portrait of a burst of fishing from 1900 to 1950 that preceded the collapse of once abundant bluefin tuna populations off the coast of northern Europe.

The chronicle of decimation of the bluefin tuna population in the North Atlantic is being published as other affiliated researchers release the latest results of modern electronic fish tagging efforts off Ireland and in the Gulf of Mexico, revealing remarkable migrations and life-cycle secrets of the declining species.

Dusting off sales records, fishery yearbooks and other sources, researchers Brian R.

When explorers like Magellan and Columbus sailed from Europe to the New World 500 years ago, they amazingly managed to navigate the open sea without terrestrial landmarks, natural boundaries or the navigational technology we have today.

Historical reports suggest that some explorers and other seafaring people did so by imagining an island just over the horizon; if they kept track of where the "virtual island" was, they knew which direction to go in the open water.

But new research from the University of Iowa suggests that people's ability to imagine virtual islands -- without any perceptual cues to help -- is quite limited.

Scientists at the Institute for Stem Cell Research, of the University of Edinburgh show that mouse embryonic stem cells need the protein FGF4 to become competent to be converted into specialized cell types, such as brain or muscle cells.

These findings add to the growing body of knowledge that researchers all over the world are using to direct embryonic stem cells to become specific specialised cells – a fundamental requirement for using lab-grown cells to model disease, test the effects of new drugs and, potentially, treat disease and injury.

Embryonic stem cells have the unique ability to divide to produce both copies of themselves and other, more specialised, cell types. The process whereby embryonic stem cells commit to become specialised cells is still obscure.

Plasmodium falciparum is responsible for the most severe forms of human malaria. Invasion of host red blood cells is an essential step of the complex life cycle of this parasite.

During the process of invasion, P. falciparum, which appears in the stage of a “merozoite”, is exposed to antibodies from the immune system. Consequently, the proteins of the merozoite that interact with red blood cells are a possible weak point, and thus a very clear target to develop vaccines.