Zijie Xia scite author profile

Salts are often necessary to maintain the native structures and functions of many proteins and protein complexes, but many buffers adversely affect protein analysis by native mass spectrometry (MS). Here, protein and protein complex ions are formed directly from a 150 mM KCl and 25 mM Tris-HCl buffer at pH 7 that is widely used in protein chemistry to mimic the intracellular environment. The protein charge-state distributions are not resolved from electrospray ionization MS using 1.6 μm diameter emitter tips, resulting in no mass information. In contrast, the charge-state distributions are well-resolved using 0.5 μm tips, from which the masses of proteins and protein complexes can be obtained. Adduction of salt to protein ions decreases with decreasing tip size below ∼1.6 μm but not above this size. This suggests that the mechanism for reducing salt adduction is the formation of small initial droplets with on average fewer than one protein molecule per droplet, which lowers the salt:protein ratio in droplets that contain a protein molecule. This is the first demonstration of native mass spectrometry of protein and protein complex ions formed from a buffer containing physiological ionic strengths of nonvolatile salts that mimics the intracellular environment, and this method does not require sample preparation or addition of reagents to the protein solution before or during mass analysis.

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Native Mass Spectrometry from Common Buffers with Salts That Mimic the Extracellular Environment

Susa

2017

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Nonvolatile salts are essential for the structures and functions of many proteins and protein complexes but can severely degrade performance of native mass spectrometry by adducting to protein and protein complex ions, thereby reducing sensitivity and mass measuring accuracy. Small nanoelectrospray emitters are used to form protein and protein complex ions directly from high-ionic-strength (>150 mm) nonvolatile buffers with salts that mimic the extracellular environment. Charge-state distributions are not obtained for proteins and protein complexes from six commonly used nonvolatile buffers and ≥150 mm Na with conventionally sized nanoelectrospray emitter tips but are resolved with 0.5 μm tips. This method enables mass measurements of proteins and protein complexes directly from a variety of commonly used buffers with high concentrations of nonvolatile salts and eliminates the need to buffer exchange into volatile ammonium buffers traditionally used in native mass spectrometry.

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Effect of droplet lifetime on where ions are formed in electrospray ionization

Xia

Williams

2019

Analyst

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Zijie Xia

Small Emitter Tips for Native Mass Spectrometry of Proteins and Protein Complexes from Nonvolatile Buffers That Mimic the Intracellular Environment

Native Mass Spectrometry from Common Buffers with Salts That Mimic the Extracellular Environment

Effect of droplet lifetime on where ions are formed in electrospray ionization

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