Tag Archives: Research

Image of Viral Coat

image of exterior of virus - made up of 5 million atoms

High-energy X-ray diffraction was used to pinpoint some 5 million atoms in the protective protein coat of the PsV-F virus. The coat’s symmetrical features are shared by hundreds of viruses. The red and yellow sections illustrate how building blocks of four proteins come together to form the spherical shell.

The image reveals the structure of a type of protein coat shared by hundreds of known viruses containing double-stranded RNA genomes. The image was painstakingly created from hundreds of high-energy X-ray diffraction images and paints the clearest picture yet of the viruses’ genome-encasing shell called a “capsid.”

Viruses can reproduce themselves only by invading a host cell and highjacking its biochemical machinery. But when they invade, viruses need to seal off their genetic payload to prevent it from being destroyed by the cell’s protective mechanisms. Though there are more than 5,000 known viruses, including whole families that are marked by wide variations in genetic payload and other characteristics, most of them use either a helical or a spherical capsid.

“Spherical viruses like this have symmetry like a soccer ball or geodesic dome,” Pan said. “The whole capsid contains exactly 120 copies of a single protein.” Previous studies had shown that spherical capsids contain dozens of copies of the capsid protein, or CP, in an interlocking arrangement. The new research identified the sphere’s basic building block, a four-piece arrangement of CP molecules called a tetramer, which could also be building blocks for other viruses’ protein coats.

Full press release

Scientists Target Bacteria Where They Live

Scientists Learning to Target Bacteria Where They Live

Scientists have learned that bacteria that are vulnerable when floating around as individual cells in what is known as their “planktonic state” are much tougher to combat once they get established in a suitable place — whether the hull of a ship or inside the lungs — and come together in tightly bound biofilms. In that state, they can activate mechanisms like tiny pumps to expel antibiotics, share genes that confer protection against drugs, slow down their metabolism or become dormant, making them harder to kill.

The answer, say researchers, is to find substances that will break up biofilms.
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Melander said “a throwaway sentence in an obscure journal” — the Bulletin of the Chemical Society of Japan — gave them another clue. They isolated a compound from the sponge that disperses biofilms and figured out how to synthesize it quickly and cheaply.
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But dispersing biofilms without understanding all the ramifications could be a “double-edged sword,” Romeo warned, because some bacteria in a biofilm could wreak worse havoc once they disperse.

“Simply inducing biofilm dispersion without understanding exactly how it will impact the bacterium and host could be very dangerous, as it might lead to spread of a more damaging acute infection,” he said.

Why Does Hair Turn Grey as We Age?

A team of European scientists have learned why our hair turns gray as we age. Despite the notion that gray hair is a sign of wisdom, these researchers show that going gray is caused by a massive build up of hydrogen peroxide due to wear and tear of our hair follicles. The peroxide winds up blocking the normal synthesis of melanin, our hair’s natural pigment.

“Not only blondes change their hair color with hydrogen peroxide,” said Gerald Weissmann, MD, Editor-in-Chief of The FASEB Journal. “All of our hair cells make a tiny bit of hydrogen peroxide, but as we get older, this little bit becomes a lot. We bleach our hair pigment from within, and our hair turns gray and then white. This research, however, is an important first step to get at the root of the problem, so to speak.”

The researchers made this discovery by examining cell cultures of human hair follicles. They found that the build up of hydrogen peroxide was caused by a reduction of an enzyme that breaks up hydrogen peroxide into water and oxygen (catalase). They also discovered that hair follicles could not repair the damage caused by the hydrogen peroxide because of low levels of enzymes that normally serve this function (MSR A and B). Further complicating matters, the high levels of hydrogen peroxide and low levels of MSR A and B, disrupt the formation of an enzyme (tyrosinase) that leads to the production of melanin in hair follicles. Melanin is the pigment responsible for hair color, skin color, and eye color. The researchers speculate that a similar breakdown in the skin could be the root cause of vitiligo.

Weissmann added. “This study is a prime example of how basic research in biology can benefit us in ways never imagined.”

See full press release

Study on Citation of Open Access Papers v. Closed Access Papers

Open Access to Scientific Papers May Not Guarantee Wide Dissemination

To test this theory, James A. Evans, an assistant professor of sociology at the University of Chicago, and Jacob Reimer, a student of neurobiology also at the University of Chicago, analyzed millions of articles available online, including those from open source publications and those that required payment to access.

The results were surprising. On average, when a given publication was made available online after being in print for a year, being published in an open source format increased the use of that article by about 8 percent. When articles are made available online in a commercial format a year after publication, however, usage increases by about 12 percent.

“Across the scientific community,” Evans said in an interview, “it turns out that open access does have a positive impact on the attention that’s given to the journal articles, but it’s a small impact.”

Yet Evans and Reimer’s research also points to one very positive impact of the open source movement that is sometimes overlooked in the debate about scholarly publications. Researchers in the developing world, where research funding and libraries are not as robust as they are in wealthier countries, were far more likely to read and cite open source articles.

The University of Chicago team concludes that outside the developed world, the open source movement “widens the global circle of those who can participate in science and benefit from it.”

So while some scientists and scholars may chose to pay for scientific publications even when free publications are available, their colleagues in other parts of the world may find that going with open source works is the only choice they have.

I remain a strong advocate for open science. The out of date model of publishing research in closed journals does not make sense. Especially not for any government funded research or any research supported by foundations, universities or others that aim to promote science.

The quote above and the interview webcast also provide unclear data on what the actual impact is (on how often a paper is cited in other papers). Maybe the article would be clearer but I can’t tell because it is closed access. This link has some worthwhile comments: Generalizing the OA impact advantage.

Scientists Say Biotechnology Seed Companies Prevent Research

Crop Scientists Say Biotechnology Seed Companies Are Thwarting Research

Biotechnology companies are keeping university scientists from fully researching the effectiveness and environmental impact of the industry’s genetically modified crops, according to an unusual complaint issued by a group of those scientists.
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The researchers, 26 corn-insect specialists, withheld their names because they feared being cut off from research by the companies. But several of them agreed in interviews to have their names used.

The problem, the scientists say, is that farmers and other buyers of genetically engineered seeds have to sign an agreement meant to ensure that growers honor company patent rights and environmental regulations. But the agreements also prohibit growing the crops for research purposes.

So while university scientists can freely buy pesticides or conventional seeds for their research, they cannot do that with genetically engineered seeds. Instead, they must seek permission from the seed companies. And sometimes that permission is denied or the company insists on reviewing any findings before they can be published, they say.

Such agreements have long been a problem, the scientists said, but they are going public now because frustration has been building.

This is not acceptable. Regulators need to put safety above politically connected powerful groups. The bigger problem is we keep electing people more interested in who gives than money than the public interest. But part of the dynamic is embarrassing those that subvert the public good to reward those providing the politicians money. By shining light on what is being done the abuses are often reduced a bit.

Self Re-assembling Robots

Cool modular robots can self re-assemble if kicked apart. Shape-shifting robots take form:

DARPA programme manager Mitch Zakin is pursuing what he calls “programmable matter”. These are so-called “mesoscale” mini-machines, a millimetre to a centimetre in size, that can arrange themselves to form whatever shape is desired. Initially, Zakin expects the outcome to be devices the size of small Lego pieces, but as the technology improves the modules and the machines assembled from them should scale down further. Ultimately you could tell a sack of “smart sand” what to do, and the grains would assemble themselves into a hammer, a wrench or even a morphing robotic aircraft. “It’s making machines more like materials, and materials more like machines,” says Daniela Rus, a robotics researcher at the Massachusetts Institute of Technology.

Extinct Ibex is Resurrected by Cloning

Extinct ibex is resurrected by cloning

The Pyrenean ibex, a form of wild mountain goat, was officially declared extinct in 2000 when the last-known animal of its kind was found dead in northern Spain. Shortly before its death, scientists preserved skin samples of the goat, a subspecies of the Spanish ibex that live in mountain ranges across the country, in liquid nitrogen.

Using DNA taken from these skin samples, the scientists were able to replace the genetic material in eggs from domestic goats, to clone a female Pyrenean ibex, or bucardo as they are known. It is the first time an extinct animal has been cloned.

Sadly, the newborn ibex kid died shortly after birth due to physical defects in its lungs. Other cloned animals, including sheep, have been born with similar lung defects. But the breakthrough has raised hopes that it will be possible to save endangered and newly extinct species by resurrecting them from frozen tissue.

It has also increased the possibility that it will one day be possible to reproduce long-dead species such as woolly mammoths and even dinosaurs.

An Artificial Nerve Networks

When neurons – brain nerve cells – are grown in culture, they don’t form complex ‘thinking’ networks. Moses, Feinerman and Rotem wondered whether the physical structure of the nerve network could be designed to be more brain-like. To simplify things, they grew a model nerve network in one dimension only – by getting the neurons to grow along a groove etched in a glass plate. The scientists found they could stimulate these nerve cells using a magnetic field (as opposed to other systems of lab-grown neurons that only react to electricity).

Experimenting further with the linear set-up, the group found that varying the width of the neuron stripe affected how well it would send signals. Nerve cells in the brain are connected to great numbers of other cells through their axons (long, thin extensions), and they must receive a minimum number of incoming signals before they fire one off in response. The researchers identified a threshold thickness, one that allowed the development of around 100 axons. Below this number, the chance of a response was iffy, while just a few over this number greatly raised the chance a signal would be passed on.

The scientists then took two thin stripes of around 100 axons each and created a logic gate similar to one in an electronic computer. Both of these ‘wires’ were connected to a small number of nerve cells. When the cells received a signal along just one of the ‘wires,’ the outcome was uncertain; but a signal sent along both ‘wires’ simultaneously was assured of a response. This type of structure is known as an AND gate. The next structure the team created was slightly more complex: Triangles fashioned from the neuron stripes were lined up in a row, point to rib, in a way that forced the axons to develop and send signals in one direction only. Several of these segmented shapes were then attached together in a loop to create a closed circuit. The regular relay of nerve signals around the circuit turned it into a sort of biological clock or pacemaker.

Moses: ‘We have been able to enforce simplicity on an inherently complicated system. Now we can ask, ‘What do nerve cells grown in culture require in order to be able to carry out complex calculations?’ As we find answers, we get closer to understanding the conditions needed for creating a synthetic, many-neuron ‘thinking’ apparatus.’

Full press release

MRI That Can See Bacteria, Virus and Proteins

IBM team boosts MRI resolution

The researchers demonstrated this imaging at a resolution 100 million times finer than current MRI. The advance could lead to important medical applications and is powerful enough to see bacteria, viruses and proteins, say the researchers.

The researchers said it offered the ability to study complex 3D structures at the “nano” scale. The step forward was made possible by a technique called magnetic resonance force microscopy (MRFM), which relies on detecting very small magnetic forces.

In addition to its high resolution, MRFM has the further advantage that it is chemically specific, can “see” below surfaces and, unlike electron microscopy, does not destroy delicate biological materials.

Now, the IBM-led team has dramatically boosted the sensitivity of MRFM and combined it with an advanced 3D image reconstruction technique. This allowed them to demonstrate, for the first time, MRI on biological objects at the nanometre scale.

That is very cool.

Science Commons: Making Scientific Research Re-useful

Science Commons is a project of Creative Commons. Like other organizations trying to support the advancement of science with open access they deserve to be supported (PLoS and arXiv.org are other great organizations supporting science).

Science Commons has three interlocking initiatives designed to accelerate the research cycle – the continuous production and reuse of knowledge that is at the heart of the scientific method. Together, they form the building blocks of a new collaborative infrastructure to make scientific discovery easier by design.

Making scientific research re-useful, help people and organizations open and mark their research and data for reuse. Learn more.

Enabling one-click access to research materials, streamline the materials-transfer process so researchers can easily replicate, verify and extend research. Learn more.

Integrating fragmented information sources, help researchers find, analyze and use data from disparate sources by marking and integrating the information with a common, computer-readable language. Learn more.

NeuroCommons, is their proof-of-concept project within the field of neuroscience. The NeuroCommons is a beta open source knowledge management system for biomedical research that anyone can use, and anyone can build on.