Modern conservation techniques have brought us the resurgence of American bald eagles, sustainable forest harvests and the rescue of prized lobster fisheries. So how can modern conservation strategies also have wrought such failures, from the catastrophic loss of Guatemalan forests to the economy-crippling Klamath River salmon kill in 2006?

Indiana University political scientist Elinor Ostrom and colleagues argue that while many basic conservation strategies are sound, their use is often flawed.

For more than 100 years, scientists have tried to figure out the cell size problem: How does a cell know when it is big enough to divide? In research conducted in budding yeast (Saccharomyces cerevisiae), scientists at Rockefeller University have now identified the cellular event that marks the moment when a cell knows it is big enough to commit to cell division and spawn genetic replicas of itself.

The findings provide a precise and quantitative framework for studying the possible mechanisms that allow cells to monitor and sense their size.

During the first phase of the cell cycle, known as G1, budding yeast grows and begins to form a bud; in the final stage, the cell splits into two — one bigger than the other.

Florida Atlantic University received U.S. patent no. 10/822,496, “Promoting Cardiac Cell Differentiation,” based on an invention which induces and restores cardiac muscle function.

The invention was discovered by FAU researcher and vice president for research, Dr. Larry F. Lemanski and his postdoctoral fellow, Dr. Chi Zhang. Their research has focused on understanding the mechanisms that regulate myocardial (heart muscle mass) cell differentiation and myofibrillogenesis (the process by which proteins in the heart are changed into heart muscle cells) in the developing heart. From their findings, these researchers hope to repair myocardial deficiencies in the human heart which are caused by either congenital heart defects or heart attacks.

A University of Leicester mathematician has been working with scientists in Japan and The Netherlands to develop a new technique that produces accurate mathematical models of the actual behaviour of nerve (neural) cells. Developing such models requires detailed information about the dynamics of components responsible for the spike generation in the cell.

The main barrier between mathematical modelling and reality is that the most of intrinsic variables of living cell are not available for direct observation. Dr Ivan Tyukin and his colleagues developed a method for automatic reconstructing of hidden variables describing the cell dynamics using only the recordings of evoked electric activity of the cell.

Positive selection in human evolution plays a role in genes associated with schizophrenia, according to a new study in the Sept. 2007 edition of Proceedings of the Royal Society B. It found that genes believed to be linked to schizophrenia are more likely to show evidence of natural selection than those not associated with the disorder.

“Schizophrenia has a huge impact on health and reproduction, yet it persists at a high frequency in the human population. This is something of a paradox from an evolutionary perspective,” said East Carolina University biologist Kyle Summers, who conducted the research with colleagues Bernard Crespi from Simon Fraser University (Canada) and Steven Dorus from the University of Bath (United Kingdom).

Sonia Garel intend to tackle one of the great mysteries of neurobiology - how the brain is built up during embryonic development. There have long been fundamental unanswered questions relating both to the wiring of the brain during growth, and how evolution drove forward the sophisticated neural circuitry associated with mammals.

Garel will focus on two key processes involved in development of neural circuitry in the forebrains of young mammals as they grow. One of these processes concerns the formation of connections between neurons, the nerve cells of the brain.

These connections are needed to process sensory information, execute motor functions, and provide the network for cognitive abilities.