Maxine Singer, c. 1963. Courtesy National Institutes of Health.
DNA, the molecule that carries all the genetic information for living things, has always been the focus of Maxine Singer’s research. Singer (b. 1931) helped decipher the human genetic code—the chemical language that DNA uses to create the proteins that keep our bodies going and growing. She has studied disease-related genes that actually jump from place to place in DNA. One of her special concerns is recombinant DNA technology.
Singer grew up in New York City and was inspired to go into science by her high school chemistry teacher: “She wasn’t very friendly, but she was a very good teacher,” Singer said of her in an interview. Singer got further encouragement when she attended Swarthmore College, just outside Philadelphia, where she initially majored in chemistry but switched to biology. During the late 1940s and early 1950s, the world of science was not especially welcoming to women, whether it was in academia or in industry. Things were different at Swarthmore. Singer had many women friends who were also science majors, and she recalls that they were treated as equals by both the faculty and their male classmates.
After graduating from Swarthmore in 1952 she entered Yale University, where she earned a Ph.D. in biochemistry in 1957. This was just four years after James Watson and Francis Crick discovered the double-helical structure of DNA. Singer’s professor at Yale advised her that the future of biochemistry was in nucleic acids—DNA and RNA—and that she should study them. Very few scientists in the United States were studying nucleic acids at that time. One of those few was Leon Heppel of the National Institute of Arthritis, Metabolism, and Digestive Diseases at the National Institutes of Health (NIH) in Washington, D.C. Singer’s professor helped her get a job with Heppel as a postdoctoral researcher. This worked out well because her husband, a lawyer, had also found work in Washington. Though she intended to stay only a short time, her postdoc position evolved into a full-time senior research position, and she ended up staying at NIH until 1979. She then moved to the National Cancer Institute, where she stayed until she became president of the Carnegie Institution in 1988, a post she held through 2002.
As a young scientist at NIH in the 1960s, Singer played an important role in experiments being conducted by Heppel, Marshall Nirenberg, and others trying to determine exactly how RNA transferred genetic information from DNA in the cell nucleus to the site of protein synthesis in the cell’s protoplasm. They used RNA molecules, with specific predetermined base sequences made from adenine (A), guanine (G), cytosine (C), and uracil (U)—for example, all uracil—to determine what proteins such RNAs would make from solutions of free amino acids, the chemical components of proteins. By matching each amino acid to a particular triplet of RNA bases, these scientists wrote the dictionary of three-letter words in which the genetic code is written. Singer had the job of constructing the experimental RNAs using a special enzyme to string together the required components.
Maxine Singer. Photo by Harry Kalish. CHF Collections.
Singer continued as a highly productive scientist at NIH, taking on managerial duties as well. Her most important discovery since her contribution towards deciphering the genetic code came in the 1980s while she was administering the Laboratory of Biochemistry at the National Cancer Institute. She had become interested in stretches of mammalian DNA that are repeated thousands of times and interspersed on the genomes of all mammals. She discovered that these long interspersed nucleotide elements (LINEs) are capable of transposition on the genome and the mechanism by which this happens. Her hypothesis that these transpositions play an important role in genetic diseases has been confirmed by other scientists.
Since the field of recombinant DNA and other types of genetic engineering first emerged (see Preserving Health with Biotechnology), Singer has been at the forefront of those concerned with its moral and safety consequences. At NIH she helped formulate the institute’s guidelines about how research in genetic engineering should be carried out. She continues to work for safe and ethical use of biotechnologies today.
Singer has spent her career as a scientist and public advocate, but has also been heavily involved in programs to improve the quality of science education at all levels, from kindergarten to postdoctoral study. She has written several books on genetics with her colleague Paul Berg and has received numerous professional awards, including the National Medal of Science. She and her husband, Daniel Singer, have four grown children.