Unlocking design secrets of deep-sea microbes

"The molecular study of proteins is rapidly expanding as the technology supporting the field keeps advancing," says Vincent Conticello. "You're only limited by your interest and your imagination." (Photo by Carol Clark)

The microbe Pyrodictium abyssi is an archaeaon — a member of what’s known as the third domain of life — and an extremophile. It lives in deep-sea thermal vents, at temperatures above the boiling point of water, without light or oxygen, withstanding the enormous pressure at ocean depths of thousands of meters. 

A biomatrix of tiny tubes of protein, known as cannulae, link cells of Pyrodictium abyssi together into a highly stable microbial community. No one knew how these single-celled microbes accomplished this feat of extreme engineering — until now. 

A study using advanced microscopy techniques reveals new details about the elegant design of the cannulae and the remarkable simplicity of their method of construction. Nature Communications published the work, led by scientists at Emory University; the University of Virginia, Charlottesville; and Vrije Universiteit Brussel in Belgium. 

The discovery holds the potential to inspire innovations in biotechnology, from the development of new “smart” materials to nanoscale drug delivery systems. 

“Not only are the cannulae strong enough to endure extreme conditions, they’re beautiful,” says Vincent Conticello, Emory professor of chemistry and co-senior author of the paper. “To me, they resemble columns from the classical architecture of ancient Greece or Rome,” he adds, citing their fluted edges and precise regularity.

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Electric charge connects jumping worm to prey

A tiny worm that leaps high into the air — up to 25 times its body length — to attach to flying insects uses static electricity to perform this astounding feat, scientists have found. The journal PNAS published the work on the nematode Steinernema carpocapsae, a parasitic roundworm, led by researchers at Emory University and the University of California, Berkeley. 

“We’ve identified the electrostatic mechanism this worm uses to hit its target, and we’ve shown the importance of this mechanism for the worm’s survival,” says co-author Justin Burton, an Emory professor of physics whose lab led the mathematical analyses of laboratory experiments. “Higher voltage, combined with a tiny breath of wind, greatly boosts the odds of a jumping worm connecting to a flying insect.” 

“You might expect to find big discoveries in big animals, but the tiny ones also hold a lot of interesting secrets,” adds Victor Ortega-Jiménez, co-lead author and assistant professor of biomechanics at the University of California, Berkeley. He conducted the experiments, including the use of highspeed microscopy techniques to film the parasitic worm — whose length is about the diameter of a needle point — as it leaped onto electrically charged fruit flies. 

The researchers showed how a charge of a few hundred volts, similar to that generated by an insect’s wings beating the air, initiates an opposite charge in the worm, creating an attractive force. They identified electrostatic induction as the charging mechanism driving this process.

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New Method to Control Dengue Mosquito Shows Public Health Benefit

In advance of the rainy season, local public health officials sprayed a long-lasting insecticide, safe for indoor use, targeted to areas where the Aedes mosquito prefers to hang out.

A novel disease prevention strategy — targeting a mosquito that spreads the dengue virus — significantly reduces both the mosquito numbers and cases of disease across a community, finds a major new study. New England Journal of Medicine published the results of the large, randomized clinical trial — considered the gold standard for evaluating the effectiveness of an intervention — led by Emory University. 

The research was conducted in Merida, a city of one million in the Mexican state of the Yucatan, through a close collaboration with the Autonomous University of the Yucatan, the Yucatan Ministry of Health and the Federal Ministry of Health of Mexico. 

The project tested an intervention that previous Emory research found promising: Targeted indoor residual spraying of insecticide, or TIRS, conducted before an outbreak occurs. The method is aimed at a particular species of mosquito, Aedes aegypti, that is perfectly adapted to live with humans in an urban setting. 

“Our study showed that the TIRS method reduced numbers of these mosquitos by 6o percent for a period of six months,” says Gonzalo Vazquez-Prokopec, senior author of the study and Emory professor of environmental sciences. “The results also quantified a 24 percent mean reduction community-wide in cases of dengue fever, even in the context of a record-breaking outbreak of dengue in Merida.”

Read the full story here.

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Emory scientists continue Jane Goodall's legacy

Elizabeth Lonsdorf as a PhD student in 2000, with Jane Goodall in Gombe.

While championing the causes of wildlife and the environment, legendary primatologist Jane Goodall — who passed away Oct. 1 at the age of 91 — also transformed the lives of countless people around the world. They include many Emory students, postdoctoral researchers and faculty members who are carrying on Goodall’s core mission in Tanzania: to study and conserve the chimpanzees and ecosystem of Gombe Stream National Park, while supporting the health and wellbeing of people. 

“Meeting Jane Goodall changed everything for me,” says Elizabeth Lonsdorf, Emory professor of anthropology. “She was an incredible inspiration and mentor.” 

Lonsdorf is co-director of the Jane Goodall Institute’s Gombe Ecosystem Health Project, along with Thomas Gillespie, professor and chair of Emory’s Department of Environmental Sciences. The pioneering project developed a “One Health” approach to quantify illness and methods of disease transmission between humans, wildlife and domestic animals at Gombe, to design effective interventions. 

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New methods expand access to molecules key to human health

"I love solving problems, the more challenging the better," says San Pham, first author of the paper. Senior author is Frank McDonald, Emory professor of chemistry and Pham's PhD advisor.

A new approach to an established reaction boosts the ability to synthesize vinylic ethers — key building blocks for many molecules that are important to human health. The American Chemical Society’s Organic Letters published the breakthrough, made by chemists at Emory University. 

“Our method is easy to reproduce and is based on widely available and inexpensive compounds,” says San Pham, an Emory PhD candidate and first author of the paper. “We can apply this method to make multiple natural products, including novel vinylic ethers.” 

Her research improves the reliability, yield and generality of what is known as the Chan-Evans-Lam reaction. These enhancements greatly expand the reaction’s potential for the synthesis of complex, biologically active compounds for drug research.

Read the full story here.

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