Lifeboat Foundation

Nice.

A gene called Prkci can point cells in the right direction, according to a new study in Developmental Biology.

In the study, USC Stem Cell researcher In Kyoung Mah from the laboratory of Francesca Mariani and colleagues demonstrated Prkci’s role in organizing cells into balls and tubes during early embryo and organ formation.

Continue reading “Gene called Prkci helps organize organisms and their organs” »

Why gene studies and solutions matter.

Scientists have confirmed that a gene mutation causes severe glaucoma and blindness in children. Now they want to target the gene for treatment.

Stress during pregnancy may raise the risk for having a child with autism for women who have an altered gene.

Very insightful for my deep mind/ neuro mapping friends.

If you have trouble learning a new language as an adult, maybe you can blame your genes and brain structure, a U.S. study suggested Monday.

The study by researchers at the University of Washington showed that genetic variations of the so-called COMT gene and a measure of the strength of the brain’s communications network — known as “white matter”— jointly accounted for 46 percent of the reason for why some college students performed better than others in the second language class.

Continue reading “Genes, brain structure influence second language learning: study” »

Diabetes 2 tie to Vitamin D issues.

First study of Emiratis’ genes highlights the links between type 2 diabetes and a deficiency in vitamin D. Soon doctors may be able to prioritise care for those who are most at risk.

ABU DHABI // The first study to examine Emirati genes and the links between type 2 diabetes and vitamin D deficiency uncovered a genetic code that identifies those susceptible to the deficiency.

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Jumping genes — not jumping beans.

“Jumping genes” are ubiquitous. Every domain of life hosts these sequences of DNA that can “jump” from one position to another along a chromosome; in fact, nearly half the human genome is made up of jumping genes. Depending on their specific excision and insertion points, jumping genes can interrupt or trigger gene expression, driving genetic mutation and contributing to cell diversification. Since their discovery in the 1940s, researchers have been able to study the behavior of these jumping genes, generally known as transposons or transposable elements (TE), primarily through indirect methods that infer individual activity from bulk results. However, such techniques are not sensitive enough to determine precisely how or why the transposons jump, and what factors trigger their activity.

Reporting in the Proceedings of the National Academy of Sciences, scientists at the University of Illinois at Urbana-Champaign have observed jumping gene activity in real time within living cells. The study is the collaborative effort of physics professors Thomas Kuhlman and Nigel Goldenfeld, at the Center for the Physics of Living Cells, a National Science Foundation Physics Frontiers Center.

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Visual information from near and far space are processed with differing degrees of acuity.

Neuroscientists from Tübingen have discovered how our brain processes visual stimuli above and below the horizon differently. The researchers led by Dr. Ziad Hafed of the Werner Reichardt Centre for Integrative Neuroscience (CIN) at the University of Tübingen investigated non-human primates, ascertaining that different parts of the visual field are represented asymmetrically in the superior colliculus, a brain structure central to visual perception and behavior. More neural tissue is assigned to the upper visual field than to the lower. As a result, visual stimuli above the horizon are processed sharper, stronger, and faster: our brain is wearing bifocals, so to speak.

Seeing — arguably our most important way of perceiving the world — mostly happens without conscious intent. We see much better in the center of our visual field (along the visual axis) than in the periphery. So when our brain detects an object of interest in the periphery of our visual field, it immediately initiates an eye movement so our visual axis intersects with those objects. Once an object is in our direct line of sight, we can perceive it in far more depth and detail.

Continue reading “Neuroscientists discover how the brain processes upper and lower visual stimuli differently” »

THE only way for humanity to survive the artificial intelligence (AI) revolution is for us to merge with the machines ourselves, according to US Presidential candidate Zoltan Istvan.

“With the LinkedIn acquisition, Microsoft snares two prizes: the massive amounts of data contained in LinkedIn’s 433 million member profiles that are kept scrupulously up to date by business professionals and to which competitors have no access and the brainy computer algorithms that crunch that data.” the writeup.

Buying the Facebook of professional networks is perhaps the best illustration yet that the cloud wars are heating up.