From Hopkins: Cell Biology “Johns Hopkins researchers aim to design self-driving cells to pursue deadly bacteria”
[THIS POST IS DEDICATED TO THE CELL BIOLOGIST WHO i MET AT SOURLAND LAST WEEK. I HOPE HE SEES IT]
Drawing on their expertise in control systems and cell biology, Johns Hopkins University researchers are setting out to design and test self-directed microscopic warriors that can locate and neutralize dangerous strains of bacteria.
A five-member team from the university’s Whiting School of Engineering and its School of Medicine recently received a four-year, $5.7 million federal contract to devise a prototype biocontrol system that can dispatch single-cell fighters to track down and engulf specific pathogens, rendering them harmless. The funding was awarded by the Defense Advanced Research Projects Agency, commonly called DARPA.
Possible first targets in this proof-of-concept project include Legionella, the bacteria that cause Legionnaire’s disease; and Pseudomonas aeruginosa, a bacterial strain that is the second-leading cause of infections found in hospitals. If the project succeeds, these tiny infection-fighters might one day be dispatched to curtail lethal microbes lurking in medical settings. Eventually, they could also be used to cleanse contaminated soil or possibly defend against bioterror attacks.
An important goal of the project is that each of the proposed soldier cells must carry out its own mission without relying on step-by-step commands from a remote human operator.
“Once you set up this biocontrol system inside a cell, it has to do its job autonomously, sort of like a self-driving car,” said Pablo A. Iglesias, principal investigator on the project. Iglesias, a professor of electrical and computer engineering in the Whiting School, shifted his research focus from man-made to biological control systems about 15 years ago.
“Think about how the cruise control in your car senses your speed and accelerates or slows down to stay at the pace you’ve requested,” Iglesias said. “In a similar way, the biocontrol systems we’re developing must be able to sense where the pathogens are, move their cells toward the bacterial targets, and then engulf them to prevent infections among people who might otherwise be exposed to the harmful microbes.”
To develop the bio-circuitry needed for these tasks, Iglesias teamed up with four School of Medicine cell biology and biological chemistry experts:
Peter Devreotes, a professor and director of the Department of Cell Biology whose expertise is in cell movement
Takanari Inoue, an associate professor of cell biology whose expertise is in synthetic biology, particularly how to engineer biological circuits
Tamara O’Connor, an assistant professor in the Department of Biological Chemistry whose expertise is in the interaction between hosts and pathogens
Douglas Robinson, a professor in the Department of Cell Biology
These experts plan to biologically embed search-and-surround orders within a familiar type of amoeba cell called Dictyostelium discoideum. These widely studied microbes, commonly found in damp soil such as riverbeds, typically engulf and dine on bacteria, which are much smaller.
“These amoebas possess receptors that can detect the biochemical ‘scents’ emitted by bacteria,” Robinson said. “Our goal is to use concepts from control theory to design a ‘super amoeba’ that can recognize a particular bad guy—a specific type of disease-causing bacteria—and then move toward and attack these target cells.”
Robinson added: “The plan is to develop amoebas that are super-sensitive to these bacterial signals and home in on them as though they were a plate piled high with fresh chocolate chip cookies. The goal is to make these amoebas behave as though this is the most natural thing to do.”
These bioengineering experiments are required to operate under strict safety and ethics rules, he said, including those related to the environmental release of engineered organisms. But if the project is successful, the researchers say the single-cell fighters could eventually be introduced into the cooling and ventilation system in a hospital, where they could feast on the bacteria that are currently causing dangerous infections. One possible method of introducing the infection fighters into such systems might be through use of a spray solution.
Iglesias noted that initial efforts will focus on bacteria lurking outside, not within the body.
“In this contract, we are not targeting bacteria in human blood,” he said, “but the hope is that the techniques we develop would ultimately be useful for that.”
See the full article here .
The Johns Hopkins University opened in 1876, with the inauguration of its first president, Daniel Coit Gilman. “What are we aiming at?” Gilman asked in his installation address. “The encouragement of research … and the advancement of individual scholars, who by their excellence will advance the sciences they pursue, and the society where they dwell.”
The mission laid out by Gilman remains the university’s mission today, summed up in a simple but powerful restatement of Gilman’s own words: “Knowledge for the world.”
What Gilman created was a research university, dedicated to advancing both students’ knowledge and the state of human knowledge through research and scholarship. Gilman believed that teaching and research are interdependent, that success in one depends on success in the other. A modern university, he believed, must do both well. The realization of Gilman’s philosophy at Johns Hopkins, and at other institutions that later attracted Johns Hopkins-trained scholars, revolutionized higher education in America, leading to the research university system as it exists today.