Protein Fluorescence
“Protein Fluorescence” by Joseph R. Lacowicz, published by Springer US in July 2013, delves into the intricate world of biochemical fluorescence, focusing on the natural fluorescence of proteins. This edition, comprising 310 pages, explores the roles of fluorescent amino acids such as phenylalanine, tyrosine, and tryptophan, with tryptophan being the primary intrinsic fluorophore found in proteins. The book discusses how the emission characteristics of these residues are influenced by various excited state processes, including spectral relaxation and interactions with nearby quenching groups.
Readers will find a comprehensive examination of the complexities involved in interpreting intrinsic protein fluorescence, particularly the challenges posed by the interactions between tryptophan and tyrosine residues. The text highlights the historical context of biochemical fluorescence research, tracing its evolution from qualitative observations in the 1950s to more quantitative analyses by the mid-1980s. Lacowicz addresses the difficulties in resolving fluorescence data from individual tryptophan residues, providing insights into the multi-exponential nature of protein intensity decays. This work serves as a valuable resource for those interested in the intersections of science, chemistry, and biochemistry.
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The intrinsic or natural fluorescence of proteins is perhaps the most complex area of biochemical fluorescence. Fortunately the fluorescent amino acids, phenylalanine, tyrosine and tryptophan are relatively rare in proteins. Tr- tophan is the dominant intrinsic fluorophore and is present at about one mole % in protein. As a result most proteins contain several tryptophan residues and even more tyrosine residues. The emission of each residue is affected by several excited state processes including spectral relaxation, proton loss for tyrosine, rotational motions and the presence of nearby quenching groups on the protein. Additionally, the tyrosine and tryptophan residues can interact with each other by resonance energy transfer (RET) decreasing the tyrosine emission. In this sense a protein is similar to a three-particle or mul- particle problem in quantum mechanics where the interaction between particles precludes an exact description of the system. In comparison, it has been easier to interpret the fluorescence data from labeled proteins because the fluorophore density and locations could be controlled so the probes did not interact with each other. From the origins of biochemical fluorescence in the 1950s with Prof- sor G. Weber until the mid-1980s, intrinsic protein fluorescence was more qualitative than quantitative. An early report in 1976 by A. Grindvald and I. Z. Steinberg described protein intensity decays to be multi-exponential. Attempts to resolve these decays into the contributions of individual tryp- phan residues were mostly unsuccessful due to the difficulties in resolving closely spaced lifetimes.
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