The Gerwick team's study of algae and cyanobacteria has led to the isolation of a number of compounds with pharmaceutical potential, among them:

Curacin A - In 1993, the group discovered a marine cyanobacterium while collecting in Cura�ao, the crude extract of which showed potent cancer cell toxicity. Subsequently they isolated a compound they named Curacin A that was responsible for this bioactivity. Curacin A is a relatively simple compound known as a lipopeptide, which combines amino acid and fatty acid components. It has garnered much attention, however, because of its unique structure. "It's unlike anything else that's ever been found in nature," says Gerwick. Its mechanism of action also appears to be unique. In animal models the compound was discovered to decompose quickly, so it did not have the anticancer activity expected based on in vivo studies. However, the team has successfully cloned the biosynthetic gene cluster that codes for the proteins used to produce Curacin A and are working to express these genes in organisms more readily grown in the laboratory than the source cyanobacterium. One of the goals of this work is to ultimately tweak this production system to produce analogs of Curacin A that are more stable.

Somocysteinamide - Obtained from a mix of two cyanobacteria species (Lyngbya majuscula and Schizothrix sp.) this compound has also shown very potent cancer cell toxicity, particularly against neuroblastoma cells. Gerwick allows, however,"It was one of the most perplexing detective stories that we ever encountered." The problem was that somocysteinamide is quite unstable, so NMR experiments revealed that the compound would change from one day to the next. The team had to work backwards, looking at the structure as it changed over time to infer the natural product's starting structure. A key challenge in working with the compound is that the cyanobacteria produce only very small quantities, meaning sufficient quantities complete initial evaluations or to do in vitro testing have not yet been available. Gerwick therefore believes that the compound would be an ideal lead for a synthetic chemist to use to develop a technique for synthesizing larger quantities, though no such work is yet underway.

Scytonemin - The story of scytonemin actually begins in the 1850s, when scientists first observed that some cyanobacteria produce and exude from their cells a dark pigment into sheath material that is normally clear. Most interestingly, this process was observed in response to exposure to sunlight. The chemical structure of the compound responsible remained a mystery for 150 years. Then, a group of researchers at the University of Oregon came across the early reports of the pigment and were studying the phenomenon. The group contacted Gerwick's team, which was the first to investigate the pigment's chemical structure. What they discovered in scytonemin was a promising and novel, but very complex, compound. Scytonemin shows potent anti-inflammatory properties, which, combined with UV protection properties, is a promising combination for potential use in a sunscreen. The patent on the compound is jointly held between the University of California system and Oregon State University and researchers are working to achieve a commercial licensing agreement for the compound.

- VIDEO CLIP 5: "The Discovery of Somocysteinamide and the Need for Synthetic Chemistry"

Bill Gerwick's love for the ocean and marine algae and cyanobacteria began when he was "a kid poking around in tide pools," and his interest grew from there. As an undergraduate he attended the University of California, Davis, and conducted phycology (the study of algae) research with Dr. Norma Lang. He credits this work and Dr. Lang as the inspiration for his current career. After finishing at Davis, he went to the Scripps Institution of Oceanography, where he did Ph.D. work with Bill Fenical and studied the chemistry of macrophytic marine algae, mostly brown algae. "That was tremendous fun," says Gerwick. He became increasingly interested in biosynthesis and so, for postdoctoral research at the University of Connecticut, he explored that topic, studying the biosynthesis of anti-cancer agents. Next he spent a few years in a junior faculty position at the University of Puerto Rico in Rio Piedras, which he recalls as "a fantastic opportunity for collecting marine organisms." Eventually he wanted to return to the Pacific West Coast, so he took a position with Oregon State University, where he worked for over 20 years before transferring to his current position at Scripps in 2005.

- VIDEO CLIP 6: "Growing the Microbes, Elucidating the Structures"