On the surface, Fulla Abdul-Jabbar seems like any other young Argonne researcher. She is eager to learn, deftly navigates laboratory spaces and speaks passionately about her work. But one major detail sets her apart from her colleagues — she is 21 years old and has only worked at Argonne for a brief 10 weeks.
Abdul-Jabbar is one of 76 participants in the U.S. Department of Energy’s (DOE) Summer Undergraduate Laboratory Internships (SULI) program at Argonne. Through the program, students who are pursuing or have just completed an undergraduate degree are able to conduct research at one of 17 DOE national laboratories.
Abdul-Jabbar came to Argonne from the University of Michigan, where she received her degree in biochemistry this past spring. She was born in Iraq during the First Persian Gulf War and immigrated to the United States from Jordan with her family at the age of five. Growing up in a suburb of Detroit, Abdul-Jabbar found herself drawn to science as early as elementary school.
In college, Abdul-Jabbar researched various topics, ranging from the chemical ecology of milkweed roots’ defense mechanisms to the synthesis of antibiotics that can treat tuberculosis. In between working at an enzymology lab during school, she spent a summer doing drug design research. “During that experience I realized, ‘this is for me.’ I enjoy applying chemistry in creative ways to things that people care about, such as human health,” she said.
At Argonne, Abdul-Jabbar has been able to pursue her interest in applied biochemistry. She works with Argonne Distinguished Fellow Andrzej Joachimiak, whose team seeks to improve techniques for determining protein structures, particularly those involved in pathogens that affect humans. Their research informs our understanding of how to combat microbial diseases, and they frequently collaborate on drug design with pharmaceutical and biotechnology organizations.
Joachimiak and his team at the Midwest Center for Structural Genomics, which is based at Argonne, use a series of semi-automated techniques that allow for rapid protein structure determination. Their methods substantially speed up what was traditionally a long and tedious process. “In other labs, it can take a week to purify one protein,” said Abdul-Jabbar. “With Argonne’s resources, I can purify up to 16 proteins in the same amount of time.”
Along the structure determination pipeline, Abdul-Jabbar focuses on protein expression, purification and crystallization. Her goal is to find crystals that crystallographers can analyze to infer the structure of proteins. From these structures, she and her colleagues try to interpret the proteins’ functions.
Abdul-Jabbar’s work entails harvesting a large, pure amount of a targeted protein, testing it under conditions that induce crystallization and screening the samples for crystals. If she finds a crystal, X-ray crystallographers at Argonne’s Structural Biology Center can use X-ray diffraction to observe the arrangement of atoms in the sample.
During her brief time at Argonne, Abdul-Jabbar has already found three crystals that have led to the identification of new bacterial protein structures. Two of these are the first structures to be determined in an organism called Slackia heliotrinireducins; the other structure belongs toSpirosoma linguale. These proteins are part of the DOE’s Genomic Encyclopedia of Bacteria and Archaea project, which aims to sequence the genomes of species far out on the tree of life.
After her internship, Abdul-Jabbar wants to flesh out her research interests before committing to graduate school. In addition to biochemistry, she is interested in biotechnology and synthetic biology.
Aside from research, Abdul-Jabbar hopes to explore science communication. She is curious about using art and design to make science more accessible. “Science, especially the life sciences, plays such an important role in people’s lives,” she said. “People get scared of words like ‘engineer’ or ‘synthesize’ because they may not be sufficiently informed. I think there are creative ways to change these points of view and deliver science in a way that doesn’t intimidate but rather engages people.”
This past year, Abdul-Jabbar worked with James King, a speculative designer who visualizes the ways in which future biotechnologies might be integrated into people’s daily lives. She sees potential in the application of design thinking to scientific thinking. “I ultimately want to get a Ph.D. because I want to bring science to people, and I believe it’s important to be well-trained to do so,” she said. “Whatever I end up doing, however, I want to be able to navigate the space between design and science. There might be ways to apply design to many aspects of research – be it the research process itself or designing a product like a drug or even an organism.”
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