“One of the biggest things I hope for in my career is that in 20 years, I still feel the same joy and enthusiasm for research and training that I feel now,” says Prabodhika Mallikaratchy, Ph.D., a professor in the department of molecular, cellular, and biomedical sciences at the City University of New York (CUNY) School of Medicine. Dr. Mallikaratchy talks with us about her career path, research on developing new immunotherapies and molecular tools using nucleic acids, and her belief in the importance of being passionate about your career.

Q: How did you first become interested in science?

A: Growing up in Sri Lanka, I was always a curious child. I remember being drawn to science and math, but there was no particular incident that sparked my interest. By the time I reached high school, though, I had become especially interested in chemistry.

Some might think that protein is only important for weightlifters. In truth, all life relies on the activity of protein molecules. A single human cell contains thousands of different proteins with diverse roles, including:

• Providing structure. Proteins such as actin make up the three-dimensional cytoskeleton that gives cells structure and determines their shapes.
• Aiding chemical reactions. Many proteins are biological catalysts called enzymes that speed up the rate of chemical reactions by reducing the amount of energy needed for the reactions to proceed. For example, lactase is an enzyme that breaks down lactose, a sugar found in dairy products. Those with lactose intolerance don’t produce enough lactase to digest dairy.
• Supporting communication. Some proteins act as chemical messengers between cells. For example, cytokines are the protein messengers of the immune system and can increase or decrease the intensity of an immune response.

Public health crises often disproportionately impact rural America. Sally L. Hodder, M.D., works to alleviate these disparities, especially regarding the opioid crisis and the COVID-19 pandemic. She’s the director of the West Virginia Clinical and Translational Science Institute (WVCTSI), the associate vice president of clinical and translational research, and a professor of medicine at West Virginia University.

Dr. Hodder’s work is focused in West Virginia, but her results are valuable assets to researchers across the country. Not only does treating chronic diseases in rural populations contribute to the overall understanding of those diseases, but engaging with and involving people in those communities in research makes science more accessible to them. Dr. Hodder says, “When folks participate in the science, when there is good community discussion about the trial designs and the results, then I think those populations may be more trusting of the results."

“Science provides adventure and excitement every single day. When you’re pushing boundaries, you get to jump into the abyss of new areas. It can be scary, but it’s an incredible opportunity to try to improve our world and people’s lives,” says César de la Fuente, Ph.D., a Presidential Assistant Professor in the Perelman School of Medicine and School of Engineering and Applied Science at the University of Pennsylvania, Philadelphia. Our interview with Dr. de la Fuente highlights his journey of becoming a scientist and his research using artificial intelligence to discover new drugs.

Q: How did you first become interested in science?

A: I’ve always been fascinated by the world around me. I grew up in a town in northwest Spain, right on the Atlantic Ocean. As a kid, I would go to the beach to investigate marine organisms and bring home all sorts of different fish to study. My mom wasn’t too happy about that! We’re all born scientists, but we tend to lose that curiosity as we enter adulthood. The key is to not lose our ability to learn every day.

“Being able to discover new, unexpected things is why you wake up every day and go to work as a scientist. The other part is hopefully to have a positive impact on human health—through combatting conditions ranging from antibiotic resistance to cancer,” says Elizabeth Parkinson, Ph.D., an assistant professor of organic chemistry at Purdue University in West Lafayette, Indiana. In an interview, Dr. Parkinson shared with us her path to a scientific career, research on natural products made by soil-dwelling bacteria, and advice for students.

Q: What sparked your interest in science?

A: My high school freshman biology teacher, Mr. O’Connell, first got me interested in science. He’d bring objects to class, and we’d have to guess how they might relate to the day’s subject matter. One time he brought strawberries, and we isolated DNA from them, which I really enjoyed. I also participated in a science fair for the first time that year. My project focused on how the color of light affected plant growth, and that was a very fun experience.

Have you ever wondered why your cells don’t spill into each other or what keeps your skin separate from your blood? The answer to both is lipids—a diverse group of organic compounds that don’t dissolve in water. They’re one of the four major building blocks of our bodies, along with proteins, carbohydrates, and nucleic acids. Types of lipids include:

• Fats, necessary for our bodies’ long-term energy storage and insulation. Some essential vitamins are fat soluble, meaning they must be associated with fat molecules to be effectively absorbed.
• Phospholipids, which make up a large part of cell and organelle membranes.
• Waxes, which help protect delicate surfaces. For instance, earwax protects the skin of the ear canal.
• Steroids, including cholesterol, a precursor to many hormones, which helps maintain the fluidity of cell membranes.

“You’re doing something really important with people who are important to you,” Paul Worsley remarks when asked about having his younger brothers Caleb and Adam as lab mates. The trio are undergraduate students working in the lab of Santimukul Santra, Ph.D., at Pittsburg State University in Pittsburg, Kansas.

All three brothers are part of the Kansas IDeA Networks of Biomedical Research Excellence (K-INBRE). Paul is currently a junior majoring in biology and history. He plans to go to medical school when he graduates, but his time in the lab has given him a love for research—and has even led him to toy with the idea of going to graduate school instead. His twin brothers Caleb and Adam are only freshmen, but they both think they want to pursue scientific research when they graduate.

When Paul was a sophomore, he applied for a K-INBRE research spot in Dr. Santra’s lab and was immediately accepted. He quickly realized that organic chemistry in the lab was much different—and more exciting—than anything he’d seen in the classroom. “I like organic synthesis because it really tests your knowledge,” he says. “Answering exam questions is way different than actually doing it in a lab.” Despite the challenges that came with research, Paul was clearly doing great work because one day Dr. Santra joked, “Hey, you got any brothers?” Paul responded, “Actually, yes.”

Many of us learned in English class that an antagonist is a person or thing that a hero fights. But in biomedical science, an antagonist is a molecule that binds to a cellular receptor to prevent a response, such as a muscle contraction or hormone release. Antagonists can be important medical treatments, like the antagonist naloxone—also known as Narcan —that can reverse an opioid overdose.