Written by
School of Engineering and Applied Science, Molly Sharlach, Princeton University
Aug. 13, 2020

The research team included (from left) associate research scholar César Carrasco-López; postdoctoral research fellow Agnieszka Gil, assistant professor of molecular biology Jared Toettcher; and . José Avalos, an assistant professor of chemical and biological engineering and the Andlinger Center for Energy and the Environment. Photo by Sameer A. Khan/Fotobuddy

In a pair of papers published Aug. 13 in Nature Communications, the researchers describe the creation of OptoBinders that can specifically latch onto a variety of proteins both inside and outside of cells. OptoBinders can bind or release their targets in response to blue light. The team reported that one type of OptoBinder changed its affinity for its target molecules up to 330-fold when shifted from dark to blue light conditions, while others showed a five-fold difference in binding affinity — all of which could be useful to researchers seeking to understand and engineer the behaviors of cells.

Crucially, OptoBinders can target proteins that are naturally present in cells, and their binding is easily reversible by changing light conditions — “a new capability that is not available to normal antibodies,” said co-author José Avalos, an assistant professor of chemical and biological engineering and the Andlinger Center for Energy and the Environment. “The ability to let go [of a target protein] is actually very valuable for many applications,” said Avalos, including engineering cells’ metabolisms, purifying proteins or potentially making biotherapeutics.

The new technique is the latest in a collaboration between Avalos and Jared Toettcher, an assistant professor of molecular biology. Both joined the Princeton faculty in 2015, and soon began working together on new ways to apply optogenetics — a set of techniques that introduce genes encoding light-responsive proteins to control cells’ behaviors.

 “We hope that this is going to be the beginning of the next era of optogenetics, opening the door to light-sensitive proteins that can interface with virtually any protein in biology, either inside or outside of cells,” said Toettcher, the James A. Elkins, Jr. ’41 Preceptor in Molecular Biology.

Avalos and his team hope to use OptoBinders to control the metabolisms of yeast and bacteria to improve the production of biofuels and other renewable chemicals, while Toettcher’s lab is interested in the molecules’ potential to control signaling pathways involved in cancer.

The two papers describe different types of light-switchable binders: opto-nanobodies and opto-monobodies. Nanobodies are derived from the antibodies of camelids, the family of animals that includes camels, llamas and alpacas, which produce some antibodies that are smaller (hence the name nanobody) and simpler in structure than those of humans or other animals.

 

 

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“When you turn the light on and off, these tools bind and release their target almost immediately, so that brings another level of control” that was not previously possible, said co-author César Carrasco-López, an associate research scholar in Avalos’ lab. Photo by Sameer A. Khan/Fotobuddy

 

 

Nanobodies’ small size makes them more adaptable and easier to work with than traditional antibodies; they recently received attention for their potential as a COVID-19 therapy. Monobodies, on the other hand, are engineered pieces of human fibronectin, a large protein that forms part of the matrix between cells. 

“These papers go hand in hand,” said Avalos. “The opto-nanobodies take advantage of the immune systems of these animals, and the monobodies have the advantage of being synthetic, which gives us opportunities to further engineer them in different ways.”

The two types of OptoBinders both incorporate a light-sensitive domain from a protein found in oat plants.

“When you turn the light on and off, these tools bind and release their target almost immediately, so that brings another level of control” that was not previously possible, said co-author César Carrasco-López, an associate research scholar in Avalos’ lab. “Whenever you are analyzing things as complex as metabolism, you need tools that allow you to control these processes in a complex way in order to understand what is happening.”

 

 

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The types of OptoBinders developed by postdoctoral research fellow Agnieszka Gil and colleagues could in principle be engineered to target any protein in a cell, opening new possibilities for fundamental research, biofuel production and therapeutics. Photo by Sameer A. Khan/Fotobuddy

 

 

In principle, OptoBinders could be engineered to target any protein found in a cell. With most existing optogenetic systems, “you always had to genetically manipulate your target protein in a cell for each particular application,” said co-author Agnieszka Gil, a postdoctoral research fellow in Toettcher’s lab. “We wanted to develop an optogenetic binder that did not depend on additional genetic manipulation of the target protein.”

In a proof of principle, the researchers created an opto-nanobody that binds to actin, a major component of the cytoskeleton that allows cells to move, divide and respond to their environment. The opto-nanobody strongly bound to actin in the dark, but released its hold within two minutes in the presence of blue light. Actin proteins normally join together to form filaments just inside the cell membrane and networks of stress fibers that traverse the cell. In the dark, the opto-nanobody against actin binds to these fibers; in the light, these binding interactions are disrupted, causing the opto-nanobody to scatter throughout the cell. The researchers could even manipulate binding interactions on just one side of a cell — a level of localized control that opens new possibilities for cell biology research.

OptoBinders stand to unlock scores of innovative, previously inaccessible uses in cell biology and biotechnology, said Andreas Möglich, a professor of biochemistry at the University of Bayreuth in Germany who was not involved in the studies. But, Möglich said, “there is much more to the research” because the design strategy can be readily translated to other molecules, paving the way to an even wider repertoire of customized, light-sensitive binders.

“The impressive results mark a significant advance,” he said.

“Future applications will depend on being able to generate more OptoBinders” against a variety of target proteins, said Carrasco-López. “We are going to try to generate a platform so we can select OptoBinders against different targets” using a standardized, high-throughput protocol, he said, adding that this is among the first priorities for the team as they resume their experiments after lab research was halted this spring due to COVID-19.

Beyond applications that involve manipulating cell metabolism for microbial chemical production, Avalos said, OptoBinders could someday be used to design biomaterials whose properties can be changed by light.

The technology also holds promise as way to reduce side effects of drugs by focusing their action to a specific site in the body or adjusting dosages in real time, said Toettcher, who noted that applying light inside the body would require a device such as an implant. “There aren’t many ways to do spatial targeting with normal pharmacology or other techniques, so having that kind of capability for antibodies and therapeutic binders would be a really cool thing,” he said. “We think of this as a sea change in what sorts of processes can be placed under optogenetic control.”

Other authors on the opto-monobody paper were Evan Zhao, who earned a Ph.D. in chemical and biological engineering from Princeton in 2019; and Nathan Alam, an undergraduate from the Class of 2021. Zhao was also a co-author on the opto-nanobody paper, along with Liyuan Zhu, a graduate student in the Department of Chemistry; Pavithran Ravindran, a research specialist in molecular biology; Maxwell Wilson, a former associate research scholar in molecular biology who is now an assistant professor at the University of California-Santa Barbara; and Alexander Goglia, a medical student in the Robert Wood Johnson Medical School and Princeton University M.D./Ph.D. program.

The work was supported in part by the U.S. National Institutes of Health, National Science Foundation and Department of Energy; the Pew Charitable Trusts; and the Eric and Wendy Schmidt Transformative Technology Fund.