Good Vibrations

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A knot-like structure in a section of RNA from a flavivirus
Findings in mice may lead to a drug-free, noninvasive way to treat chronic wounds in people with type 2 diabetes. Credit: Stock image.

For people living with type 2 diabetes, wounds often heal slowly, sometimes even becoming chronic. Now, scientists have shown that low-intensity vibrations can speed up the healing process in a strain of diabetic mice commonly used to study delayed wound healing. The research team, led by Timothy Kohof the University of Illinois at Chicago, found that exposing the mice to barely perceptible vibrations five times a week for just 30 minutes promoted wound healing by increasing the formation of new blood vessels and of granulation tissue, a type of tissue critical in the early stages of healing. If researchers can show that the vibration technique also works in humans, this approach could one day offer a drug-free, non-invasive therapy for chronic wounds in people with diabetes.

This work also was funded by NIH’s National Institute of Dental and Craniofacial Research.

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Learning How Mosquito-Borne Viruses Use Knot-like RNA to Cause Disease

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A knot-like structure in a section of RNA from a flavivirus
A knot-like structure in RNA enables flaviviruses to cause diseases like yellow fever, West Nile virus and dengue fever, which threaten roughly half the world’s population. Credit: Jeffrey Kieft.

Roughly half the world’s population is now at risk for mosquito-borne diseases other than malaria, such as yellow fever, West Nile virus and dengue fever. These three diseases are caused by flaviviruses, a type of virus that carries its genetic material as a single strand of RNA.

Flaviviruses have found a way not only to thwart our bodies’ normal defenses, but also to harness a human enzyme—paradoxically, one normally used to destroy RNA—to enhance their disease-causing abilities. A team of scientists led by Jeffrey Kieft at the University of Colorado at Denver found that flaviviruses accomplish both feats by bending and twisting a small part of their RNA into a knot-like structure.

The scientists set out to learn more about this unusual ability. First, they determined the detailed, three-dimensional architecture of the convoluted flaviviral RNA. Then, they examined several different variations of the RNA. In doing so, they pinpointed parts that are critical for forming the knot-like shape. If researchers can find a way to prevent the RNA from completing its potentially dangerous twist, they’ll be a step closer to developing a treatment for flaviviral diseases, which affect more than 100 million people worldwide.

This work also was supported by the National Institute of Allergy and Infectious Diseases and the National Cancer Institute.

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Knowing Networks

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Artist's rendition of a network diagram. Credit: Allison Kudla, Institute for Systems Biology.
Artist’s rendition of a network diagram. Credit: Allison Kudla, Institute for Systems Biology.

Networks—both real and virtual—are everywhere, from our social media circles to the power grid that delivers electricity. The interactions of genes, proteins and other molecules in a cell are examples of networks, too.

Scientists working in a field called systems biology study and chart living networks to learn how the individual parts work together to make a functioning whole and what happens when these complex, dynamic systems go awry. For example, the network diagram here depicts yeast cells (superimposed circles) and the biochemical “chatter” between them (lines) that tells the cells to gather together in clumps. This clumping helps them survive stressful conditions like a shortage of nutrients.

Network diagrams provide more than just hub-and-spoke pictures. They can yield information that helps us better understand—and potentially influence—complex phenomena that affect our health.

Read more about network analysis and systems biology in this Inside Life Science article.

Multitarget Drugs to Challenge Microbial Resistance

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A group of purple, rod-shaped bacterial cells rendered by computer at Centers for Disease Control and Prevention by Melissa Brower.
Computer-generated image of drug-resistant Mycobacterium tuberculosis bacteria. Credit: Melissa Brower, Centers for Disease Control and Prevention.

Drugs that target a single essential protein in a microbial invader can be effective treatments. But the genomes of pathogens—including bacteria, fungi and parasites—mutate rapidly, and resistance can develop if a mutation changes a target protein’s structure. Molecules that interfere with multiple microbial proteins at once have the potential to overcome the growing problem of antimicrobial drug resistance.

Researchers led by Eric Oldfield of the University of Illinois recently explored whether an experimental drug called SQ109, developed to treat tuberculosis (TB), could be tweaked to attack multiple enzymes, as well as to kill different types of microbes. The scientists succeeded in creating several multitarget analogs of SQ109 that were more effective than the original drug at killing their target pathogens in laboratory experiments. These analogs included one compound that was five times more potent against the bacterium that causes TB while also being less toxic to a human cell line tested.

This work was also funded by the National Cancer Institute; the National Heart, Lung, and Blood Institute; the National Institute of Allergy and Infectious Diseases and the NIH Office of the Director.

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A Medicine’s Life Inside the Body

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Heart
Most often, the bloodstream is the vehicle for carrying medicines throughout the body. Credit: Stock image.

Pharmacology is the scientific field that studies how the body reacts to medicines and how medicines affect the body. Scientists funded by the National Institutes of Health are interested in many aspects of pharmacology, including one called pharmacokinetics, which deals with understanding the entire cycle of a medicine’s life inside the body.

Knowing more about each of the four main stages of pharmacokinetics—absorption, distribution, metabolism and excretion—aids the design of medicines that are more effective and that produce fewer side effects.

Read more about a medicine’s life inside the body in this Inside Life Science article.

Understanding Complex Diseases Through Computation

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Scientists developed a computational method that could help identify various subtypes of complex diseases. Credit: Stock image

Complex diseases such as diabetes, cancer and asthma are caused by the intricate interplay of genetic, environmental and lifestyle factors that vary among affected individuals. As a result, the same medications may not work for every patient. Now, scientists have shown that a computational method capable of analyzing more than 100 clinical variables for a large group of people can identify various subtypes of asthma, which could ultimately lead to more targeted and personalized treatments. The research team, led by Wei Wu Exit icon of Carnegie Mellon University and Sally Wenzel of the University of Pittsburgh, used a computational approach developed by Wu to identify several patient clusters consistent with known subtypes of asthma, as well as a possible new subtype of severe asthma that does not respond well to conventional drug treatment. If supported by further studies, the researchers’ proposed approach could help improve the understanding, diagnosis and treatment not just of asthma but of other complex diseases.

This work also was funded by NIH’s National Heart, Lung, and Blood Institute.

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The Inner Life of Nerve Cells

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“Before this research, we didn’t even know that neurons had this special mechanism to control neuropeptide function. This is why we do basic research. This is why it’s important to understand how neurons work, down to the subcellular and molecular levels.”—Kenneth Miller”

Nerve cells (neurons) in the brain use small molecules called neuropeptides to converse with each other. Disruption of this communication can lead to problems with learning, memory and other brain functions. Through genetic studies in a model organism, the tiny worm C. elegans, a team led by Kenneth Miller of the Oklahoma Medical Research Foundation has uncovered a previously unknown mechanism that nerve cells use to package, move and release neuropeptides. The researchers found that a protein called CaM kinase II, which plays many roles in the brain, helps control this mechanism. Neuropeptides in worms lacking CaM kinase II spilled out from their packages before they reached their proper destinations. A more thorough understanding of how neurons work, provided by studies like this, may help researchers better target drugs to treat memory disorders and other neurological problems in humans.

This work also was funded by NIH’s National Institute of Mental Health.

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Two Proteins That Regulate Energy Use Play Key Role in Stem Cell Development

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Stem cells. Credit: Julie Mathieu, University of Washington.
The protein HIF1 alpha is beneficial for creating induced pluripotent stem cells (green) from adult human cells. Credit: Julie Mathieu, University of Washington.

Hannele Ruohola-Baker and a team of researchers at the University of Washington recently discovered that two proteins responsible for regulating how cells break down glucose are also essential for stem cell development. The scientists showed that the proteins HIF1 alpha and HIF2 alpha are both required to reprogram adult human cells into pluripotent stem cells, which have the ability to mature into any cell type in the body. Taking a closer look at what each protein does on its own, the researchers found that HIF1 alpha was beneficial for reprogramming throughout the process, whereas HIF2 alpha was required at early stages but was detrimental at later stages of reprogramming. Because the two proteins also play a role in transforming normal cells into cancer cells, the findings could lead to future advances in cancer research.

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Once Upon a Stem Cell Article from Inside Life Science
Learning About Cancer by Studying Stem Cells Article from Inside Life Science
Sticky Stem Cells Article from Inside Life Science

How Cells Take Out the Trash

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Proteins entering the proteasome. Credit: Office of Biological and Environmental Research of the U.S. Department of Energy Office of Science.
When proteins enter the proteasome, they’re chopped into bits for re-use. Credit: Office of Biological and Environmental Research of the U.S. Department of Energy Office of Science.

As people around the world mark Earth Day (April 22) with activities that protect the planet, our cells are busy safeguarding their own environment.

To keep themselves neat, tidy and above all healthy, cells rely on a variety of recycling and trash removal systems. If it weren’t for these systems, cells could look like microscopic junkyards—and worse, they might not function properly. Scientists funded by the National Institutes of Health are therefore working to understand the cell’s janitorial services to find ways to combat malfunctions.

Read more about how cells take out the trash and handle recycling in this Inside Life Science article.

Basic Research Fuels Medical Advances

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Genetic defect that causes myotonic dystrophy type 2 and used that information to design drug candidates to counteract the disease. Credit: Ilyas Yildirim, Northwestern University.
Scientists revealed a detailed image of the genetic change that causes myotonic dystrophy type 2 and used that information to design drug candidates to counteract the disease. Credit: Ilyas Yildirim, Northwestern University. View larger image

This image may look complicated, but it tells a fairly straightforward tale about basic research: Learning more about basic life processes can pave the way for medical and other advances.

In this example, researchers led by Matthew Disney of the Scripps Research Institute’s Florida campus focused on better understanding the structural underpinnings of myotonic dystrophy type 2, a relatively rare, inherited form of adult-onset muscular dystrophy. While this work is still in the preliminary stages, it may hold potential for someday treating the disorder.

Some 300,000 NIH-funded scientists are working on projects aimed at improving disease diagnosis, treatment and prevention, often through increasing understanding of basic life processes.

Read the complete Inside Life Science article.