Abstract
The ability to sense and respond to various key environmental cues is important for the survival and adaptability of many bacteria, including pathogens. The particular sensitivity of iron–sulfur (Fe–S) clusters is exploited in nature, such that multiple sensor-regulator proteins, which coordinate the detection of analytes with a (in many cases) global transcriptional response, are Fe–S cluster proteins. The fragility and sensitivity of these Fe–S clusters make studying such proteins difficult, and gaining insight of what they sense, and how they sense it and transduce the signal to affect transcription, is a major challenge. While mass spectrometry is very widely used in biological research, it is normally employed under denaturing conditions where non-covalently attached cofactors are lost. However, mass spectrometry under conditions where the protein retains its native structure and, thus, cofactors, is now itself a flourishing field, and the application of such ‘native’ mass spectrometry to study metalloproteins is now relatively widespread. Here we describe recent advances in using native MS to study Fe–S cluster proteins. Through its ability to accurately measure mass changes that reflect chemistry occurring at the cluster, this approach has yielded a remarkable richness of information that is not accessible by other, more traditional techniques.
Highlights
IntroductionElectrospray ionization mass spectrometry (ESI-MS), coupled with liquid chromatography (LC), is today’s method of choice for proteomic analysis
Electrospray ionization mass spectrometry (ESI-MS), coupled with liquid chromatography (LC), is today’s method of choice for proteomic analysis. Proteins rarely retain their native structure in the solvent mixtures employed in such experiments, leading to a loss of non-covalent interactions
Native MS is used for accurate mass detection of intact proteins and protein complexes, and has been
Summary
Electrospray ionization mass spectrometry (ESI-MS), coupled with liquid chromatography (LC), is today’s method of choice for proteomic analysis. Proteins rarely retain their native structure in the solvent mixtures (e.g. water/acetonitrile/ formic acid) employed in such experiments, leading to a loss of non-covalent interactions. Mass spectrometry approaches have been instrumental in the identification and characterisation of a wide variety of metalloproteins.[26,27,28,29,30,31,32,33,34,35,36] Fe–S clusters have been generally less amenable to investigation by mass spectrometry because of their sensitivity; they are acid-labile and were invariably lost under the mildly acidic conditions employed during early ESI-MS investigations, with only the most robust Fe–S proteins retaining their cluster following ionization.
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