Welcome to The Visible Embryo, a comprehensive educational resource on human development from conception to birth.

The Visible Embryo provides visual references for changes in fetal development throughout pregnancy and can be navigated via fetal development or maternal changes.

The National Institutes of Child Health and Human Development awarded Phase I and Phase II Small Business Innovative Research Grants to develop The Visible Embryo in 1993 as a first generation internet teaching tool consolidating human embryology teaching for first year medical students.

Today, The Visible Embryo is linked to over 600 educational institutions and is viewed by more than 1 million visitors each month. The field of early embryology has grown to include the identification of the stem cell as not only critical to organogenesis in the embryo, but equally critical to organ function and repair in the adult human.

The identification and understanding of genetic malfunction, inflammatory responses, and the progression in chronic disease, begins with a grounding in primary cellular and systemic functions manifested in the study of the early embryo.

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The World Health Organization (WHO) has created a new Web site to help researchers, doctors and patients obtain reliable information on high-quality clinical trials. Now you can go to one website and search all registers to identify clinical trial research underway around the world!

The Molecule mTORC2 Allows Command & Control of Memory

Introductions at a party seem to go in one ear and out the other. However, if you meet someone two or three times during the party, you are more likely to remember his or her name. Your brain has now taken a short-term memory—the introduction—and converted it into a long-term one

The molecular key to this activity is mTORC2 (mammalian target of rapamycin complex 2), according to researchers at Baylor College of Medicine in an article that appeared online in the journal Nature Neuroscience.

"Memory consolidation is a fundamental process," said Dr. Mauro Costa-Mattioli, assistant professor of neuroscience at BCM and corresponding author of the report. "Memories are at the center of our identity. They allow us to remember people, places and events for a long time, even a lifetime. Understanding the precise mechanism by which memories are stored in the brain will lead to the development of new treatments for conditions associated with memory loss."

Actin fibers

For the last five decades, neuroscientists have known that making long-lasting memories is dependent on the ability of brain cells (neurons) to synthesize new proteins. In their studies, Costa-Mattioli and his colleagues found a new mechanism by which memories are stored in the brain. The newly discovered mTORC2 regulates memory formation by modulating actin fibers, an important component of the architectural structure of the neuron.

"These actin fibers allow long-lasting changes in synaptic strength and ultimately long-term memories," said Wei Huang, a BCM graduate student and first author in the study.

"Given that flies and mice last shared a common ancestor 500 million years ago, it is quite remarkable and telling that the function of mTORC2 in the regulation of memory is indeed maintained," said Dr. Gregg Roman, director of the Biology of Behavior Institute at the University of Houston, who contributed to the fly experiments.

Form long-term memories

The Holy Grail of memory neuroscience and to a certain extent, of industry efforts to produce a "smart drug," has been the identification of molecules that promote the formation of long-term memory, said Costa-Mattioli. "We therefore wondered whether by turning on mTORC2 or even actin polymerization itself, we could form long-term memories more easily," said Dr. Ping Jun Zhu, assistant professor of neuroscience at BCM, co-first author and senior scientist in Costa-Mattioli's lab.

The team has identified a small molecule (a drug) that by activating mTORC2 and consequently actin polymerization enhances not only the synaptic strength between nerve cells but also long-term memory formation. In addition, the authors found that by directly promoting actin polymerization, with a second drug, long-term memory is generated more easily.

Costa-Mattioli's team has identified two memory-enhancing drugs, but can they enhance memory in people? It is perhaps too early to say.

Huang said, "mTORC2, as far as we know, is really a new potential target for therapeutic treatments of human disorders. In the next few years, I predict we will see a lot of studies focusing on mTORC2 as a target."

Memory cocktail

"We should start thinking about an efficient 'memory cocktail' rather than a single 'memory pill.' One molecule alone might not be enough. We may be years away from a decisive treatment, but I believe we are definitely on the right path," he said.

Others who took part in this work include Hongyi Zhou, Loredana Stoica and Mauricio Galiano, all of BCM, Krešimir Krnjević of McGill University in Montreal, Canada; and Shixing Zhang of the University of Houston.

Funding for this work came from the National Institute of Mental Health (Grant MH 096816), the National Institute of Neurological Disorders and Stroke (Grant NS 076708), The Searle Award (Grant 09-SSP-211P), a Whitehall Award, The George and Cynthia Mitchell Foundation, the National Institutes of Health (Grant MH091305) and a Texas Norman Hackerman Advanced Research Program Award.

Original article: http://www.bcm.edu/news/item.cfm?newsID=6881