Cool Videos: Spying on Cancer Cell Invasion

Spying on Cancer Cell Invation

If you’re a fan of the Mission: Impossible spy thrillers, you might think that secret agent Ethan Hunt has done it all. But here’s a potentially life-saving mission that his force has yet to undertake: spying on cancer cells. Never fear—some scientific sleuths already have!

So, have a look at this bio-action flick recently featured in the American Society for Cell Biology’s 2015 Celldance video series. Without giving too much of the plot away, let me just say that it involves cancer cells escaping from a breast tumor and spreading, or metastasizing, to other parts of the body. Along the way, those dastardly cancer cells take advantage of collagen fibers to make a tight-rope getaway and recruit key immune cells, called macrophages, to serve as double agents to aid and abet their diabolical spread.

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Gene Expression Test Aims to Reduce Antibiotic Overuse

Doctor with ER patient

Caption: Duke physician-scientist Ephraim Tsalik assesses a patient for a respiratory infection.
Credit: Shawn Rocco/Duke Health

Without doubt, antibiotic drugs have saved hundreds of millions of lives from bacterial infections that would have otherwise been fatal. But their inappropriate use has led to the rise of antibiotic-resistant superbugs, which now infect at least 2 million Americans every year and are responsible for thousands of deaths [1]. I’ve just come from the World Economic Forum in Davos, Switzerland, where concerns about antibiotic resistance and overuse was a topic of conversation. In fact, some of the world’s biggest pharmaceutical companies issued a joint declaration at the forum, calling on governments and industry to work together to combat this growing public health threat [2].

Many people who go to the doctor suffering from respiratory symptoms expect to be given a prescription for antibiotics. Not only do such antibiotics often fail to help, they serve to fuel the development of antibiotic-resistant superbugs [3]. That’s because antibiotics are only useful in treating respiratory illnesses caused by bacteria, and have no impact on those caused by viruses (which are frequent in the wintertime). So, I’m pleased to report that a research team, partially supported by NIH, recently made progress toward a simple blood test that analyzes patterns of gene expression to determine if a patient’s respiratory symptoms likely stem from a bacterial infection, viral infection, or no infection at all.

In contrast to standard tests that look for signs of a specific infectious agent—respiratory syncytial virus (RSV) or the influenza virus, for instance—the new strategy casts a wide net that takes into account changes in the patterns of gene expression in the bloodstream, which differ depending on whether a person is fighting off a bacterial or a viral infection. As reported in Science Translational Medicine [4], Geoffrey Ginsburg, Christopher Woods, and Ephraim Tsalik of Duke University’s Center for Applied Genomics and Precision Medicine, Durham, NC, and their colleagues collected blood samples from 273 people who came to the emergency room (ER) with signs of acute respiratory illness. Standard diagnostic tests showed that 70 patients arrived in the ER with bacterial infections and 115 were battling viruses. Another 88 patients had no signs of infection, with symptoms traced instead to other health conditions.

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Creative Minds: What Can Hibernation Tell Us About Human Health?

Black bear

Credit: Karen Laubenstein (Big Game Alaska)/U.S. Fish and Wildlife Service

When bears, bats, and other animals prepare to hibernate, they pack on fat at an impressive pace to almost double their weight. As they drift off into their winter slumber, their heart rates, breathing, and metabolism slow dramatically. Hibernating mammals can survive in this state of torpor for a period of weeks or even months without eating or drinking anything at all!

It’s a fascinating and still rather mysterious process—and one that William Israelsen of The University of Texas Southwestern Medical Center, Dallas, thinks may yield intriguing insights with implications for human health. A recipient of a 2015 NIH Director’s Early Independence Award, Israelsen plans to use a little-known mouse species to study hibernation in the laboratory at a level of detail that’s not possible in the wild. He especially wants to learn how hibernating animals shift their metabolic gears over the course of the year, and what those findings might reveal about human obesity, cancer, and other health conditions.

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Zika Virus: An Emerging Health Threat

Credit: Kraemer et al. eLife 2015;4:e08347

For decades, the mosquito-transmitted Zika virus was mainly seen in equatorial regions of Africa and Asia, where it caused a mild, flu-like illness and rash in some people. About 10 years ago, the picture began to expand with the appearance of Zika outbreaks in the Pacific islands. Then, last spring, Zika popped up in South America, where it has so far infected more than 1 million Brazilians and been tentatively linked to a steep increase in the number of babies born with microcephaly, a very serious condition characterized by a small head and brain [1]. And Zika’s disturbing march may not stop there.

In a new study in the journal The Lancet, infectious disease modelers calculate that Zika virus has the potential to spread across warmer and wetter parts of the Western Hemisphere as local mosquitoes pick up the virus from infected travelers and then spread the virus to other people [2]. The study suggests that Zika virus could eventually reach regions of the United States in which 60 percent of our population lives. This highlights the need for NIH and its partners in the public and private sectors to intensify research on Zika virus and to look for new ways to treat the disease and prevent its spread.

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Snapshots of Life: From Arabidopsis to Zinc

heat map of zZinc levels in an Arabidopsis thaliana plant leaf

Credit: Suzana Car, Maria Hindt, Tracy Punshon, and Mary Lou Guerinot, Dartmouth College, Hanover, NH

To most people, the plant Arabidopsis thaliana might seem like just another pesky weed. But for plant biologists, this member of the mustard green family is a valuable model for studying a wide array of biological processes—including the patterns of zinc acquisition shown so vividly in the Arabidopsis leaf above. Using synchrotron X-ray fluorescence technology, researchers found zinc concentrations varied considerably even within a single leaf; the lowest levels are marked in blue, next lowest in green, medium in red, and highest in white, concentrated at the base of tiny hairs (trichomes) that extend from the leaf’s surface.

A winner in the Federation of American Societies for Experimental Biology’s 2015 BioArt competition, this micrograph stems from work being conducted by Suzana Car and colleagues in the NIH-funded lab of Mary Lou Guerinot at Dartmouth College, Hanover, NH. The researchers are still trying to figure out exactly what zinc is doing at the various locations within Arabidopsis, as well as whether zinc concentrations are constant or variable. What is well known is that zinc is an essential micronutrient for human health, with more than 300 enzymes dependent on this mineral to catalyze chemical reactions within our bodies.

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