Arnold C. Satterthwait earned his PhD In Biochemistry with William Jencks from Brandeis University in 1973. He carried out postdoctoral research in Chemistry at Harvard University with Frank Westheimer, Imperial College with Alan Fersht and MIT with the Nobel laureate Gobind Khorana. In 1984, he joined The Scripps Research Institute in La Jolla, CA as an Assistant Professor. He moved to Sanford Burnham Prebys in 1998.
Related Disease
Anthrax, Breast Cancer, Cancer, HIV/AIDS, Prostate Cancer
The development of diagnostic reagents, drugs and vaccines is the visible outcome of a long process that spans the researcher’s laboratory and doctor’s office. The translation of disease discoveries into early detection, treatment, and prevention both tests and shapes our understanding of disease. Traditionally, drug companies have screened large collections of compounds against diseases to identify drugs. The Satterthwait lab seeks to take advantage of the explosion of new discoveries at the molecular level. We have developed synthetic methods that allow us to independently make and manipulate the critical three-dimensional regions of proteins that are being implicated in many diseases. These mini proteins are being used to assess new theories of disease at the molecular level to identify targets for various uses. We are currently using mini proteins to identify new antibodies (HIV-1), cancer drugs (prostate, breast and lung), and vaccines (anthrax).
Arnold Satterthwait’s Research Report
Peptide engineering relies on synthetic procedures to fold peptides into bioactive structures. It seeks to bridge a gap between chemistry and molecular biology by reducing the active sites of proteins to smaller molecules. Although synthetic peptides show occasional activity they are, unlike proteins, disordered and because of this often inactive. By refolding peptides into three-dimensional structures, they become active, opening up new avenues for studies on protein structure and function as well as providing leads for drugs and vaccines.
To fold peptides, we developed covalent hydrogen bond mimics. On average, greater than 60% of the amino acids in globular proteins engage in main-chain to main-chain hydrogen bonding (NH –> O=CRNH). In addition, protein substructures are defined by distinct hydrogen bonding patterns. Because hydrogen bonds are weak bonds, insufficient for stabilizing peptide structure, we replace them at structure defining positions in peptides with amidinium (N-C(R) = NH-CH2CH2) and hydrazone (N-N=CH-CH2CH2) covalent links. To simplify these transformations, we developed machine-assisted, multiple-peptide-synthesis procedures for inserting the hydrazone link into peptides which we link to automated multiple purifications. While these procedures, like peptide synthesis, remain labor intensive and often problematic, the critical problems have been breached.
Conformational analysis is as much a part of peptide engineering as synthesis because any claim to structure requires rigorous proof and further advances rely on understanding the relation between structure and chemistry. We have made considerable use of 2D NMR spectroscopy for structural analysis and calculations and with the help of collaborators, X-ray crystallography. These studies show unequivocally that covalent hydrogen bond mimics can stabilize peptides as b-turns, the a-helix, and even complex loops, which together make up the majority of protein substructures found on the surfaces of globular proteins.
Because protein substructure mimetics are now accessible, we have been examining the relationship between structure and activity by comparing the activities of peptides with substructure mimetics. From the several examples we have studied in detail, it is clear that remarkable gains in activity can be achieved.
Kolluri SK, Zhu X, Zhou X, Lin B, Chen Y, Sun K, Tian X, Town J, Cao X, Lin F, Zhai D, Kitada S, Luciano F, O’Donnell E, Cao Y, He F, Lin J, Reed JC, Satterthwait AC, Zhang XK