Barbara Mellone, assistant professor of molecular and cell biology, in her lab. Photo by Jessica Tommaselli

(麻豆淫院Org.com) -- Biologist Barbara Mellone uses tiny cameras to study what happens when a dividing cell makes a mistake.

On the second floor of Beach Hall in her newly renovated biology lab, Barbara Mellone has a complex set of high-tech cameras. She uses these cameras to snap high-resolution photos - and even make videos - of her research organisms, which can often be elusive. But these cameras aren鈥檛 those large digital ones with manual focus and interchangeable lenses that many photographers use.

In fact, they鈥檙e small enough to fit into the lens of a microscope.

Mellone, an assistant professor of molecular and cell biology in the College of Liberal Arts and Sciences, studies the process of , in which cells split in two to create new, 鈥渄aughter鈥 cells. Her goal is to identify the molecular events that lead to successful cell duplication, and these cameras let her and her students watch the action as it happens.

鈥淚t gives us a fantastic way to monitor ,鈥 she says. 鈥淚t鈥檚 much easier to see when something鈥檚 going wrong.鈥
Living cells are constantly dividing, as old cells die and new ones take their place. When new cells are needed, the cells replicate their DNA within chromosomes, and using a central region called a centromere, they split the equally into two new cells.
At least, that鈥檚 what鈥檚 supposed to happen.

Mellone is interested in what happens when a dividing cell makes a mistake. If the are accidentally given too many or too few - a condition scientists call aneuploidy - it can lead to dysfunction and . And if those cells happen to be like those that make up sperm and eggs, aneuploidy can lead to , conditions such as , and even death of the developing embryo. is also common in tumors and cancer cells, says Mellone.

鈥淵ou need a robust centromere connection to have good replication,鈥 she says. 鈥淚n tissue that divides endlessly, like cancer cells, there鈥檚 more of a chance that something will go wrong. The cells need a fine balance of what鈥檚 necessary to propagate.鈥

This is where her specialized cameras come in. Using a technique that labels proteins to express different fluorescent colors, Mellone and her students take time-lapse photography of dividing under the microscope. The result is a cell division video - a colorful, revealing look at just how each cell part functions over time.

Mellone was recently awarded a four-year, $730,000 grant from the National Science Foundation to study how centromeres assemble themselves in the fruit fly Drosophila. She will use the funds to study the role of CENP-A, an essential protein required for centromeres to exist, which is found in all organisms with cell membranes, including humans.

鈥淐ENP-A is a special protein that marks DNA specifically at the centromere,鈥 says Mellone. 鈥淟ike all centromeric proteins, it is essential for survival. If you don鈥檛 have CENP-A, you鈥檙e dead.鈥

Mellone uses her time-lapse photography not only in her research, but also in the classroom and to teach students in her lab. Teaching students about the cell cycle from a textbook can be difficult and confusing, she says, but viewing movies of the cycle can make it much clearer. She recalls showing her videos in a graduate class she taught in her first year at UConn.

鈥淭he students were just blown away,鈥 she says. 鈥淲hen you just talk about the different stages, it鈥檚 very abstract. It makes so much more sense when you can visualize the process.鈥

Mellone has used her videos in an interdisciplinary science course for female freshmen and sophomores that she helped develop in collaboration with UConn鈥檚 Women in Math, Science, and Engineering (WiMSE) Learning Community.

This summer, she also mentored three local high school students in her laboratory through UConn鈥檚 Mentor Connection program. Hailing from Putnam High School, Convent of the Sacred Heart, and Crosby High School, the students were actively engaged in the molecular research in Mellone鈥檚 laboratory, including learning how to make these videos and interpret their results.

Although Mellone studies theses processes in fruit flies, the concepts can be extended to inform what we know about cell division in all multicellular organisms. She hopes her studies will help scientists understand how these highly specialized processes have evolved differently in different species.

鈥淚t鈥檚 becoming more and more obvious that there鈥檚 so much more we need to learn about these processes,鈥 she says. 鈥淭hese studies in Drosophila tell us about the mechanisms behind the events, and how they鈥檝e evolved.鈥

Provided by University of Connecticut