Naturally occurring amino acids have been broadly used as additives to improve protein solubility and inhibit aggregation. In this study, improvements in protein signal intensity obtained with the addition of l -serine, and structural analogs, to the desorption electrospray ionization mass spectrometry (DESI-MS) spray solvent were measured. The results were interpreted at the hand of proposed mechanisms of solution additive effects on protein solubility and dissolution. DESI-MS allows for these processes to be studied efficiently using dilute concentrations of additives and small amounts of proteins, advantages that represent real benefits compared to classical methods of studying protein stability and aggregation. We show that serine significantly increases the protein signal in DESI-MS when native proteins are undergoing unfolding during the dissolution process with an acidic solvent system ( p -value = 0.0001), or with ammonium bicarbonate under denaturing conditions for proteins with high isoelectric points ( p -value = 0.001). We establish that a similar increase in the protein signal cannot be observed with direct ESI-MS, and the observed increase is therefore not related to ionization processes or changes in the physical properties of the bulk solution. The importance of the presence of serine during protein conformational changes while undergoing dissolution is demonstrated through comparisons between the analyses of proteins deposited in native or unfolded states and by using native state-preserving and denaturing desorption solvents. We hypothesize that direct, non-covalent interactions involving all three functional groups of serine are involved in the beneficial effect on protein solubility and dissolution. Supporting evidence for a direct interaction include a reduction in efficacy with d -serine or the racemic mixture, indicating a non-bulk-solution physical property effect; insensitivity to the sample surface type or relative placement of serine addition; and a reduction in efficacy with any modifications to the serine structure, most notably the carboxyl functional group. An alternative hypothesis, also supported by some of our observations, could involve the role of serine clusters in the mechanism of solubility enhancement. Our study demonstrates the capability of DESI-MS together with complementary ESI-MS experiments as a novel tool for understanding protein solubility and dissolution and investigating the mechanism of action for solubility-enhancing additives.
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Analysis of histidine‐tagged recombinant proteins from nickel and copper coated surfaces by direct electrospray ionization and desorption electrospray ionization mass spectrometry
Purification of recombinant proteins is a necessary step for functional or structural studies and other applications. Immobilized metal affinity chromatography is a common recombinant protein purification method. Mass spectrometry (MS) allows for confirmation of identity of expressed proteins and unambiguous detection of enzymatic substrates and reaction products. We demonstrate the detection of enzymes purified on immobilized metal affinity surfaces by direct or ambient ionization MS, and follow their enzymatic reactions by direct electrospray ionization (ESI) or desorption electrospray ionization (DESI).
A protein standard, His‐Ubq, and two recombinant proteins, His‐SHAN and His‐CS, expressed in
Small proteins (His‐Ubq) and medium proteins (His‐SAHN) could readily be detected from 96‐well plates by direct infusion ESI, or from microscope slides by DESI‐MS after purification on surface from clarified
The immobilization, purification, release and detection of His‐tagged recombinant proteins using immobilized metal affinity surfaces for direct infusion ESI‐MS or ambient DESI‐MS analyses were successfully demonstrated. Recombinant proteins were purified to allow identification directly out of clarified cell lysate. Biological activities of the recombinant proteins were preserved allowing the investigation of enzymatic activity via MS.
- Award ID(s):
- 2003379
- NSF-PAR ID:
- 10419262
- Publisher / Repository:
- Wiley Blackwell (John Wiley & Sons)
- Date Published:
- Journal Name:
- Rapid Communications in Mass Spectrometry
- Volume:
- 37
- Issue:
- S1
- ISSN:
- 0951-4198
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract The site‐selective functionalization of proteins has broad application in chemical biology, but can be limited when mixtures result from incomplete conversion or the formation of protein containing side products. It is shown here that when proteins are covalently tagged with pyridyl‐tetrazines, the nickel‐iminodiacetate (Ni‐IDA) resins commonly used for His‐tags can be directly used for protein affinity purification. These Affinity Bioorthogonal Chemistry (ABC) tags serve a dual role by enabling affinity‐based protein purification while maintaining rapid kinetics in bioorthogonal reactions. ABC‐tagging works with a range of site‐selective bioconjugation methods with proteins tagged at the C‐terminus, N‐terminus or at internal positions. ABC‐tagged proteins can also be purified from complex mixtures including cell lysate. The combination of site‐selective conjugation and clean‐up with ABC‐tagged proteins also allows for facile on‐resin reactions to provide protein‐protein conjugates.
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Abstract The site‐selective functionalization of proteins has broad application in chemical biology, but can be limited when mixtures result from incomplete conversion or the formation of protein containing side products. It is shown here that when proteins are covalently tagged with pyridyl‐tetrazines, the nickel‐iminodiacetate (Ni‐IDA) resins commonly used for His‐tags can be directly used for protein affinity purification. These Affinity Bioorthogonal Chemistry (ABC) tags serve a dual role by enabling affinity‐based protein purification while maintaining rapid kinetics in bioorthogonal reactions. ABC‐tagging works with a range of site‐selective bioconjugation methods with proteins tagged at the C‐terminus, N‐terminus or at internal positions. ABC‐tagged proteins can also be purified from complex mixtures including cell lysate. The combination of site‐selective conjugation and clean‐up with ABC‐tagged proteins also allows for facile on‐resin reactions to provide protein‐protein conjugates.
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Abstract Galectins are soluble carbohydrate binding proteins that can bind β‐galactose‐containing glycoconjugates by means of a conserved carbohydrate recognition domain (CRD). In mammalian systems, galectins have been shown to mediate very important roles in innate and adaptive immunity as well as facilitating host‐pathogen relationships. Many of these studies have relied on purified recombinant galectins to uncover key features of galectin biology. A major limitation to this approach is that certain recombinant galectins purified using standard protocols are easily susceptible to loss of glycan‐binding activity. As a result, biochemical studies that employ recombinant galectins can be misleading if the overall activity of a galectin remains unknown in a given assay condition. This article examines fundamental considerations when purifying galectins by lactosyl‐sepharose and nickel‐NTA affinity chromatography using human galectin‐4N and ‐7 as examples, respectively. As other approaches are also commonly applied to galectin purification, we also discuss alternative strategies to galectin purification, using human galectin‐1 and ‐9 as examples. © 2021 Wiley Periodicals LLC.
This article was corrected on 20 July 2022. See the end of the full text for details.
Basic Protocol 1 : Purification of galectins using lactosyl‐sepharose affinity chromatographyBasic Protocol 2 : Purification of human galectin‐7 using a nickel‐NTA affinity chromatography columnAlternate Protocol 1 : Iodoacetamide alkylation of free sulfhydryls on galectin‐1Alternate Protocol 2 : Purification of human galectin‐9 using lactosyl‐sepharose column chromatography -
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Abstract The analog methanobactin (amb) peptide with the sequence ac‐His1‐Cys2‐Gly3‐Pro4‐Tyr5‐His6‐Cys7(amb5A) will bind the metal ions of zinc, nickel, and copper. To further understand how amb5Abinds these metals, we have undertaken a series of studies of structurally related heptapeptides where one or two of the potential His or Cys binding sites have been replaced by Gly, or the C‐terminus has been blocked by amidation. The studies were designed to compare how these metals bind to these sequences in different pH solutions of pH 4.2 to 10 and utilized native electrospray ionization (ESI) with ion mobility‐mass spectrometry (IM‐MS) which allows for the quantitative analysis of the charged species produced during the reactions. The native ESI conditions were chosen to conserve as much of the solution‐phase behavior of the amb peptides as possible and an analysis of how the IM‐MS results compare with the expected solution‐phase behavior is discussed. The oligopeptides studied here have applications for tag‐based protein purification methods, as therapeutics for diseases caused by elevated metal ion levels or as inhibitors for metal‐protein enzymes such as matrix metalloproteinases.
