Structural biology, the study of the shapes of biologically important molecules, is a foundational science in the understanding of life;it is principally the result of single crystal diffraction studies. The project """"""""Enabling Technologies for Macromolecular Crystallization"""""""" expands upon the work of the High Throughput Search Lab (HTSlab), a macromolecular crystallization facility at the Hauptman-Woodward Institute in Buffalo, NY. The HTSlab specializes in the development of high throughput methods to grow crystals of macromolecules suitable for diffraction studies;the formation of such crystals is a significant bottleneck in the science of structural biology. We will continue to partner with general biology, structural biology and structural genomics groups to undertake crystallization trials and enable analysis of these trials on as many as 1000 macromolecules each year. We will work in three areas: the provision of crystallization expertise and services for members of the three biology communities;the development and testing of crystallization methods and materials in a high throughput environment;and the integration of informatics services and tools for the analysis of crystallization results. We expect to work closely with the PSI community as it directs its further efforts toward a deeper understanding of the biology of complex systems.
Structural biology studies the shapes of biologically important molecules, particularly macromolecules, to understand their function. Currently, 86% of all structures in the literature result from single crystal X-ray diffraction studies. Our work is aimed at helping researchers in the general biology, structural biology and structural genomics communities grow crystals for biomedically important projects.
|Luft, Joseph R; Wolfley, Jennifer R; Franks, Eleanor Cook et al. (2015) The detection and subsequent volume optimization of biological nanocrystals. Struct Dyn 2:041710|
|Luft, Joseph R; Newman, Janet; Snell, Edward H (2014) Crystallization screening: the influence of history on current practice. Acta Crystallogr F Struct Biol Commun 70:835-53|
|Bruno, Andrew E; Ruby, Amanda M; Luft, Joseph R et al. (2014) Comparing chemistry to outcome: the development of a chemical distance metric, coupled with clustering and hierarchal visualization applied to macromolecular crystallography. PLoS One 9:e100782|
|Calero, Guillermo; Cohen, Aina E; Luft, Joseph R et al. (2014) Identifying, studying and making good use of macromolecular crystals. Acta Crystallogr F Struct Biol Commun 70:993-1008|
|Grant, Thomas D; Luft, Joseph R; Wolfley, Jennifer R et al. (2013) The structure of yeast glutaminyl-tRNA synthetase and modeling of its interaction with tRNA. J Mol Biol 425:2480-93|
|Luft, Joseph R; Wolfley, Jennifer R; Snell, Edward H (2011) What's in a drop? Correlating observations and outcomes to guide macromolecular crystallization experiments. Cryst Growth Des 11:651-663|
|Luft, Joseph R; Snell, Edward H; Detitta, George T (2011) Lessons from high-throughput protein crystallization screening: 10 years of practical experience. Expert Opin Drug Discov 6:465-80|