Caption: Pioneers in building Africa’s genomic research capacity; front, Charlotte Osafo (l) and Yemi Raji; back, David Burke (l) and Tom Glover. Credit: University of Michigan, Ann Arbor
About a year ago, Tom Glover began sifting through a stack of applications from prospective students hoping to be admitted into the Master’s Degree Program in Human Genetics at the University of Michigan, Ann Arbor. Glover, the program’s director, got about halfway through the stack when he noticed applications from two physicians in West Africa: Charlotte Osafo from Ghana, and Yemi Raji from Nigeria. Both were kidney specialists in their 40s, and neither had formal training in genomics or molecular biology, which are normally requirements for entry into the program.
Glover’s first instinct was to disregard the applications. But he noticed the doctors were affiliated with the Human Heredity and Health in Africa (H3Africa) Initiative, which is co-supported by the Wellcome Trust and the National Institutes of Health Common Fund, and aims in part to build the expertise to carry out genomics research across the continent of Africa. (I am proud to have had a personal hand in the initial steps that led to the founding of H3Africa.) Glover held onto the two applications and, after much internal discussion, Osafo and Raji were admitted to the Master’s Program. But there were important stipulations: they had to arrive early to undergo “boot camp” in genomics and molecular biology and also extend their coursework over an extra term.
Imagine going to work or school every day, working out at the gym, spending time with family and friends—basically, living your life in a full and vigorous way. Then one day, you wake up, feeling sick. A bad cold maybe, or perhaps the flu. A few days pass, and you think it should be over—but it’s not, you still feel achy and exhausted. Now imagine that you never get better— plagued by unrelenting fatigue not relieved by sleep. Any exertion just makes you worse. You are forced to leave your job or school and are unable to participate in any of your favorite activities; some days you can’t even get out of bed. The worst part is that your doctors don’t know what is wrong and nothing seems to help.
Unfortunately, this is not fiction, but reality for at least a million Americans—who suffer from a condition that carries the unwieldy name of Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS), a perplexing disease that biomedical research desperately needs to unravel . Very little is currently known about what causes ME/CFS or its biological basis . Among the many possibilities that need to be explored are problems in cellular metabolism and changes in the immune system.
Bacteria are single-cell organisms that reproduce by dividing in half. Proteins within these cells organize themselves in a number of fascinating ways during this process, including a recently discovered mechanism that makes the mesmerizing pattern of waves, or oscillations, you see in this video. Produced when the protein MinE chases the protein MinD from one end of the cell to the other, such oscillations are thought to center the cell’s division machinery so that its two new “daughter cells” will be the same size.
To study these dynamic patterns in greater detail, Anthony Vecchiarelli purified MinD and MinE proteins from the bacterium Escherichia coli. Vecchiarelli, who at the time was a postdoc in Kiyoshi Mizuuchi’s intramural lab at NIH’s National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), labeled the proteins with fluorescent markers and placed them on a synthetic membrane, where their movements were then visualized by total internal reflection fluorescence microscopy. The proteins self-organized and generated dynamic spirals of waves: MinD (blue, left); MinE (red, right); and both MinD and MinE (purple, center) .
It’s an inescapable conclusion from the book of Ecclesiastes that’s become part of popular culture thanks to folk legends Pete Seeger and The Byrds: “To everything (turn, turn, turn), there is a season.” That’s certainly true of viral outbreaks, from the flu-causing influenza virus peaking each year in the winter to polio outbreaks often rising in the summer. What fascinates Micaela Martinez is, while those seasonal patterns of infection have been recognized for decades, nobody really knows why they occur.
Martinez, an infectious disease ecologist at Princeton University, Princeton, NJ, thinks colder weather conditions and the tendency for humans to stay together indoors in winter surely play a role. But she also thinks an important part of the answer might be found in a place most hadn’t thought to look: seasonal changes in the human immune system. Martinez recently received an NIH Director’s 2016 Early Independence Award to explore fluctuations in the body’s biological rhythms over the course of the year and their potential influence on our health.
Caption: Scanning electron microscopic image of Staphylococcus aureus bacteria (orange). Credit: CDC/Jeff Hageman, MHS
Over the years, people suffering from eczema have slathered their skin with lotions containing everything from avocado oil to zinc oxide. So, what about a lotion that features bacteria as the active ingredient? That might seem like the last thing a person with a skin problem would want to do, but it’s actually a very real possibility, based on new findings that build upon the growing realization that many microbes living in and on the human body—our microbiome—are essential for good health. The idea behind such a bacterial lotion is that good bugs can displace bad bugs.
Eczema is a noncontagious inflammatory skin condition characterized by a dry, itchy rash. It most commonly affects the cheeks, arms, and legs. Previous studies have suggested that the balance of microbes present on people with eczema is different than on those with healthy skin . One major difference is a proliferation of a bad type of bacteria, called Staphylococcus aureus.
Recently, an NIH-funded research team found that healthy human skin harbors beneficial strains of Staphylococcus bacteria with the power to keep Staph aureus in check. To see if there might be a way to restore this natural balance artificially, the researchers created a lotion containing the protective bacteria and tested it on the arms of volunteers who had eczema . Just 24 hours after one dose of the lotion was applied, the researchers found the volunteers’ skin had greatly reduced levels of Staph aureus. While further study is needed to learn whether the treatment can improve skin health, the findings suggest that similar lotions might offer a new approach for treating eczema and other skin conditions. Think of it as a probiotic for the skin!