Hydrogen-deuterium exchange measurements are becoming increasingly important in studies of the dynamics of protein molecules and, particularly, of their folding behavior. Electrospray ionization mass spectrometry (ESI-MS) has been used to obtain the distribution of masses within a population of protein molecules that had undergone hydrogen exchange in solution. This information is complementary to that from nuclear magnetic resonance spectroscopy (NMR) experiments, which measure the average occupancy of individual sites over the distribution of protein molecules. In experiments with hen lysozyme, a combination of ESI-MS and NMR was used to distinguish between alternative mechanisms of hydrogen exchange, providing insight into the nature and populations of transient folding intermediates. These results have helped to detail the pathways available to a protein during refolding.
A series of noncovalent complexes formed between the 86 residue acyl CoA binding protein (ACBP) and a series of acyl CoA derivatives has been studied by electrospray ionization mass spectrometry. Conditions were found under which CoA ligands can be observed in the mass spectrometer bound to ACBP. Despite the very low dissociation constants (10 -7 to 10 -10 M) of the acyl CoA ligand complexes high ratios of ligand-to-protein concentration in the electrospray solution were found to increase the proportion of intact complex observed in the spectrum. Variation in the length of the hydrophobic acyl chain of the ligand (C 16 , C 12 , C 8 , C 0 ) resulted in similar proportions of complex observed in the mass spectrum even though significant variation in solution dissociation constants has been measured. A substantially reduced proportion of complex was, however, found for the mutant proteins, Y28N, Y31N, and Y73F, lacking tyrosine residues involved in critical interactions with the CoA ligand. These results have been interpreted in terms of the different factors stabilizing complexes in the gas phase environment of the mass spectrometer. The complexed species were also investigated by hydrogen-deuterium exchange methods combined with mass spectrometric analysis and the results show that folding of ACBP occurs prior to complex formation in solution. The results also show increased hydrogen exchange protection in the complex when compared with the free protein. Furthermore, even after dissociation of the complex, under these nonequilibrium gas phase exchange conditions, increased protection from hydrogen exchange in the complex is maintained.
To achieve the greatest output from their limited genomes, viruses frequently make use of alternative open reading frames, in which translation is initiated from a start codon within an existing gene and, being out of frame, gives rise to a distinct protein product. These alternative protein products are, as yet, poorly characterized structurally. Here we report the crystal structure of ORF-9b, an alternative open reading frame within the nucleocapsid (N) gene from the SARS coronavirus. The protein has a novel fold, a dimeric tent-like beta structure with an amphipathic surface, and a central hydrophobic cavity that binds lipid molecules. This cavity is likely to be involved in membrane attachment and, in mammalian cells, ORF-9b associates with intracellular vesicles, consistent with a role in the assembly of the virion. Analysis of ORF-9b and other overlapping genes suggests that they provide snapshots of the early evolution of novel protein folds.
The periplasmic nitrate reductase of Thiosphaera pantotropha has been purified from a mutant strain (M-6) that overproduces the enzyme activity under anaerobic growth conditions. The enzyme is a complex of a 93-kDa polypeptide and a 16-kDa nitrate-oxidizable cytochrome c552. The complex contains molybdenum; a fluorescent compound with spectral features of a pterin derivative can be extracted. In contrast to the dissimilatory membrane-bound nitrate reductases, the periplasmic nitrate reductase shows high specificity for nitrate as a substrate and is insensitive to inhibition by azide. The 93-kDa subunit exhibits immunological cross-reactivity with the catalytic subunit of Rhodobacter capsulatus N22DNAR' periplasmic nitrate reductase. Mass spectrometric comparisons of holo-cytochrome c552 and apo-cytochrome c552 demonstrated that the polypeptide bound two haem groups. Mediated redox potentiometry of the cytochrome indicated that the haem groups have reduction potentials (pH = 7.0) of approximately -15 mV and +80 mV. The functional significance of these potentials is discussed in relation to the proposed physiological role of the enzyme as a redox valve.
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