Structure determination of biomacromolecules under in-cell conditions is a relevant yet challenging task. Electron paramagnetic resonance (EPR) distance measurements in combination with site-directed spin labeling (SDSL) are a valuable tool in this endeavor but the usually used nitroxide spin labels are not well-suited for in-cell measurements. In contrast, triarylmethyl (trityl) radicals are highly persistent, exhibit a long relaxation time and a narrow spectral width. Here, the synthesis of a versatile collection of trityl spin labels and their application in in vitro and in-cell trityl-iron distance measurements on a cytochrome P450 protein are described. The trityl labels show similar labeling efficiencies and better signal-to-noise ratios (SNR) as compared to the popular methanethiosulfonate spin label (MTSSL) and enabled a successful in-cell measurement.
EPR-based nanometre distance measurements are becoming ever more important in structural biology. Usually the distance constraints are measured between two nitroxide spin labels. Yet, distance measurements between a metal center and spin labels enable, e.g., the localization of metal ions within the tertiary fold of biomolecules. Therefore, it is important to find methods that provide such distance information quickly, with high precision and reliability. In the present study, two methods, pulsed electron-electron double resonance (PELDOR) and relaxation-induced dipolar modulation enhancement (RIDME), are compared on the heme-containing and spin-labeled cytochrome P450cam. Special emphasis is put on the optimization of the dead-time free RIDME experiment and several ways of data analysis. It turned out that RIDME appears to be better suited for distance measurements involving metal ions like low-spin Fe(3+) than PELDOR.
Fatty acid biosynthesis is an essential component of metabolism in both eukaryotes and prokaryotes. The fatty acid biosynthetic pathway of Gram-negative bacteria is an established therapeutic target. Two homologous enzymes FabA and FabZ catalyze a key step in fatty acid biosynthesis; both dehydrate hydroxyacyl fatty acids that are coupled via a phosphopantetheine to an acyl carrier protein (ACP). The resulting trans-2-enoyl-ACP is further polymerized in a processive manner. FabA, however, carries out a second reaction involving isomerization of trans-2-enoyl fatty acid to cis-3-enoyl fatty acid. We have solved the structure of Pseudomonas aeruginosa FabA with a substrate allowing detailed molecular insight into the interactions of the active site. This has allowed a detailed examination of the factors governing the second catalytic step. We have also determined the structure of FabA in complex with small molecules (so-called fragments). These small molecules occupy distinct regions of the active site and form the basis for a rational inhibitor design program.
Structure determination of biomacromolecules under in-cell conditions is ar elevant yet challenging task. Electron paramagnetic resonance (EPR) distance measurements in combination with site-directed spin labeling (SDSL) are av aluable tool in this endeavor but the usually used nitroxide spin labels are not well-suited for in-cell measurements.I nc ontrast, triarylmethyl (trityl) radicals are highly persistent, exhibit along relaxation time and anarrowspectral width. Here,the synthesis of aversatile collection of trityl spin labels and their application in in vitro and in-cell trityl-iron distance measurements on ac ytochrome P450 protein are described. The trityl labels shows imilar labeling efficiencies and better signal-to-noise ratios (SNR) as compared to the popular methanethiosulfonate spin label (MTSSL) and enabled asuccessful in-cell measurement.
A focused strategy has been directed towards the structural characterization of selected proteins from the bacterial pathogen P. aeruginosa. The objective is to exploit the resulting structural data, in combination with ligand-binding studies, and to assess the potential of these proteins for early-stage antimicrobial drug discovery.
Inflammasomes sense intracellular clues of infection, damage, or metabolic imbalances. Activated inflammasome sensors polymerize the adaptor ASC into micron-sized "specks" to maximize caspase-1 activation and the maturation of IL-1 cytokines. Caspase-1 also drives pyroptosis, a lytic cell death characterized by leakage of intracellular content to the extracellular space. ASC specks are released among cytosolic content, and accumulate in tissues of patients with chronic inflammation. However, if extracellular ASC specks contribute to disease, or are merely inert remnants of cell death remains unknown. Here, we show that camelid-derived nanobodies against ASC (VHH ASC ) target and disassemble post-pyroptotic inflammasomes, neutralizing their prionoid, and inflammatory functions. Notably, pyroptosis-driven membrane perforation and exposure of ASC specks to the extracellular environment allowed VHH ASC to target inflammasomes while preserving pre-pyroptotic IL-1b release, essential to host defense. Systemically administrated mouse-specific VHH ASC attenuated inflammation and clinical gout, and antigen-induced arthritis disease. Hence, VHH ASC neutralized post-pyroptotic inflammasomes revealing a previously unappreciated role for these complexes in disease. VHH ASC are the first biologicals that disassemble pre-formed inflammasomes while preserving their functions in host defense.
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