<span class="word">Characterization <span class="word">of <span class="word"><span class="changedDisabled">Oxidative <span class="word"><span class="changedDisabled">Modifications <span class="word">to <span class="word"><span class="changedDisabled">Short <span class="word"><span class="changedDisabled">Peptides <span class="word"><span class="changedDisabled">Using <span class="word"><span class="changedDisabled">Low <span class="word"><span class="changedDisabled">Dose <span class="word"><span class="changedDisabled">Rate <span class="word">X-<span class="word"><span class="changedDisabled">Rays

The method of X-ray Footprinting and Mass Spectrometry (XFMS) using high brightness synchrotron X-ray sources has become an established method in structural biology and is based on the radiolytic production of hydroxyl radicals which oxidatively modify protein sidechains. While other methods of producing hydroxyl radicals are available, one benefit of using high flux density sources is that hydroxyl radical scavenging reactions can be minimized, and exposure times kept short to minimize secondary reactions. Here we present an application of the XFMS method using low dose rate X-rays from a commercial instrument. We demonstrate the feasibility of the approach using short peptides, characterizing the oxidative modifications +14, +16, and +32 Da under both aerated and low-oxygen conditions, and we additionally quantify the hydrogen peroxide production for various doses using the low dose rate source. These results provide fundamental information on the oxidative damage to peptides due to hydroxyl radicals using a low dose rate X-ray source.