Monday, November 14, 2011

New top-down strategy of identifying proteins could lead to early detection of disease

A team led by Northwestern University chemical biologist Neil Kelleher has developed a new "top-down" method that can separate and identify thousands of quickly. Many have been skeptical that such an approach, where each is analyzed intact instead of in smaller parts, could be done on such a large scale.

The promise of a top-down strategy is that the molecular data scientists do collect will be more closely linked to disease.

"Accurate identification of proteins could lead to the identification of and early detection of disease as well as the ability to track the outcome of treatment," Kelleher said. "We are dramatically changing the strategy for understanding protein molecules at the most basic level. This is necessary for the Human Proteome Project -- the mapping of all healthy human proteins in tissues and organs -- to really take off."

Kelleher is the Walter and Mary E. Glass Professor of Molecular Biosciences and professor of chemistry in the Weinberg College of Arts and Sciences. He also is director of the Proteomics Center of Excellence and a member of the Robert H. Lurie Comprehensive Cancer Center of Northwestern University.

Kelleher says his approach is conceptually simple. "We take proteins -- those swimming around in cells -- and we measure them," he said. "We weigh proteins precisely and identify them directly. The way everyone else is doing it is by digesting the proteins, cutting them up into smaller bits called peptides, and putting them back together again. I call it the Humpty Dumpty problem."

The new strategy, Kelleher says, solves the "protein isoform problem" of the "bottom-up" approach where the smaller peptides often do not map cleanly to single . The study will be published Oct. 30 by the journal Nature.

The top-down method can accurately identify which gene produced which protein. The bottom-up method is only 60 to 90 percent accurate in identifying proteins precisely.

"We need to define all the protein molecules in the human body," Kelleher said. "First, we need a map of healthy protein forms, which will become a highly valuable reference list for understanding damaged and diseased forms of proteins. Our technology should allow us to get farther down this road faster."

In the first large-scale demonstration of the top-down method, the researchers were able to identify more than 3,000 protein forms created from 1,043 genes from human HeLa cells.

Their goal was to identify which gene each protein comes from -- to provide a one-to-one picture. They were able to produce this accurate map of thousands of proteins in just a few months.

The researchers also can produce the complete atomic composition for each protein. "If a proton is missing, we know about it," Kelleher said.

One gene they studied, the HMGA1 gene associated with premature aging of cells, produces about 20 different protein forms.

Kelleher's team developed a four-dimensional separation system that uses separations and mass spectrometry to measure the charge, mass and weight of each protein as well as how "greasy" a protein is. The software the researchers developed to analyze the data during years of work prior to the study proved critical to the success of the top-down method.

"If you want to know how the proteins in cancer really work and change, top-down mass spectrometry is getting to the point where it can be part of the discussion," Kelleher said.

"Analyzing the entire set of proteins expressed in a cell presents a continuing and significant technical challenge to the field of proteomics," said Charles Edmonds, who oversees proteomics grants at the National Institute of General Medical Sciences of the National Institutes of Health. "By combining multiple fractionation technologies with , Dr. Kelleher and colleagues have demonstrated more than an order of magnitude improvement in proteome coverage. This is a great start."

More information: The title of the paper is "Mapping Intact Protein Isoforms in Discovery Mode Using Top-Down Proteomics."

Provided by Northwestern University (news : web)

'Fertility chip' determines concentration and mobility of semen

The lab-on-a-chip developed by Segerink measures sperm : the fertility standard states that a millilitre of ejaculate should contain at least 20 million sperm. A second important aspect of fertility is motility. This too can be measured using the lab-on-a-chip. Simple home test kits are already commercially available. These indicate whether the concentration is "above or below the standard value". These tests are too limited, however, as they do not give accurate concentration readings.

On the chip, sperm flow through a liquid-filled channel, beneath electrode "bridges". When a cell passes beneath one of these electrodes, there is a brief fluctuation in the electrical resistance. These events are counted. To test the reliability of her concentration measurements, Segerink added microspheres (tiny balls) to the liquid. Would the system only count sperm, or would it also register other particles? She found that the method was selective enough to distinguish sperm from microspheres. The system was also able to reliably distinguish white blood cells from other bodies. In addition to being an indicator of sperm quality, the white cell count provides important additional information to gynaecologists.

Finally, sperm movement (motility) is another important measure of quality. A small adjustment of the lab-on-a-chip is all that is needed to sort motile sperm from non-motile sperm, after which both can be counted separately. By measuring motility in this way, the chip offers a truly complete test.

Segerink developed the "fertility chip" in the BIOS Lab-on-a-Chip research group of Prof. Albert van den Berg, in collaboration with the Twente Medical Spectrum. The research group is part of the MESA+ Institute for Nanotechnology of the University of Twente. Various companies (PigGenetics, Blue4Green, R&R Mechatronics, Menzis, and Lionix) also participated in this project, which was funded by the STW Technology Foundation in The Netherlands.

More information: Segerink’s doctoral defence will take place on 4 November 2011.

Provided by University of Twente (news : web)

World's most efficient flexible organic light-emitting diodes created on plastic

Researchers in the University of Toronto's Department of Materials Science & Engineering have developed the world's most efficient organic light-emitting diodes (OLEDs) on plastic. This result enables a flexible form factor, not to mention a less costly, alternative to traditional OLED manufacturing, which currently relies on rigid glass.


The results are reported online in the latest issue of Nature Photonics.


OLEDs provide high-contrast and low-energy displays that are rapidly becoming the dominant technology for advanced electronic screens. They are already used in some cell phone and other smaller-scale applications.


Current state-of-the-art OLEDs are produced using heavy-metal doped glass in order to achieve high efficiency and brightness, which makes them expensive to manufacture, heavy, rigid and fragile.


"For years, the biggest excitement behind OLED technologies has been the potential to effectively produce them on flexible plastic," says Materials Science & Engineering Professor Zheng-Hong Lu, the Canada Research Chair (Tier I) in Organic Optoelectronics.


Using plastic can substantially reduce the cost of production, while providing designers with a more durable and flexible material to use in their products.


The research, which was supervised by Professor Lu and led by PhD Candidates Zhibin Wang and Michael G. Helander, demonstrated the first high-efficiency OLED on plastic. The performance of their device is comparable with the best glass-based OLEDs, while providing the benefits offered by using plastic.


"This discovery, unlocks the full potential of OLEDs, leading the way to energy-efficient, flexible and impact-resistant displays," says Professor Lu.


Story Source:



The above story is reprinted from materials provided by University of Toronto Faculty of Applied Science & Engineering.


Note: Materials may be edited for content and length. For further information, please contact the source cited above.


Journal Reference:

Z. B. Wang, M. G. Helander, J. Qiu, D. P. Puzzo, M. T. Greiner, Z. M. Hudson, S. Wang, Z. W. Liu, Z. H. Lu. Unlocking the full potential of organic light-emitting diodes on flexible plastic. Nature Photonics, 2011; DOI: 10.1038/nphoton.2011.259

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New material for air cleaner filters that captures flu viruses

Xuebing Li, Peixing Wu and colleagues explain that in an average year, influenza kills almost 300,000 people and sickens millions more worldwide. The constant emergence of new strains of virus that shrug off vaccines and anti-influenza medications has led to an urgent need for new ways of battling this modern-day scourge. So Li, Wu and colleagues sought a new approach, using a substance termed chitosan made from ground shrimp shells.

The scientists combined chitosan with substances that the attaches to in order to infect cells. They found that this new version of chitosan ideal for attaching to fibers of and air filters was highly effective in capturing flu virus. The material could become an important addition to vaccinations, anti-influenza medications, and other measures in battling flu, they suggest.

More information: Carbohydrate-Functionalized Chitosan Fiber for Influenza Virus Capture, Biomacromolecules, Article ASAP. DOI: 10.1021/bm200970x

Abstract
The high transmissibility and genetic variability of the influenza virus have made the design of effective approaches to control the infection particularly challenging. The virus surface hemagglutinin (HA) protein is responsible for the viral attachment to the host cell surface via the binding with its glycoligands, such as sialyllactose (SL), and thereby is an attractive target for antiviral designs. Herein we present the facile construction and development of two SL-incorporated chitosan-based materials, either as a water-soluble polymer or as a functional fiber, to demonstrate their abilities for viral adhesion inhibition and decontamination. The syntheses were accomplished by grafting a lactoside bearing an aldehyde-functionalized aglycone to the amino groups of chitosan or chitosan fiber followed by the enzymatic sialylation with sialyltransferase. The obtained water-soluble SL–chitosan conjugate bound HA with high affinity and inhibited effectively the viral attachment to host erythrocytes. Moreover, the SL-functionalized chitosan fiber efficiently removed the virus from an aqueous medium. The results collectively demonstrate that these potential new materials may function as the virus adsorbents for prevention and control of influenza. Importantly, these materials represent an appealing approach for presenting a protein ligand on a chitosan backbone, which is a versatile molecular platform for biofunctionalization and, thereby, can be used for not only antiviral designs, but also extensive medical development such as diagnosis and drug delivery.

Provided by American Chemical Society (news : web)