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Deamidation

From Wikipedia, the free encyclopedia
Deamidation reaction of Asn-Gly (top right) to Asp-Gly (at left) or iso(Asp)-Gly (in green at bottom right)

Deamidation is a chemical reaction in which an amide functional group in the side chain of the amino acids asparagine or glutamine is removed or converted to another functional group. Typically, asparagine is converted to aspartic acid or isoaspartic acid. Glutamine is converted to glutamic acid or pyroglutamic acid (5-oxoproline). In a protein or peptide, these reactions are important because they may alter its structure, stability or function and may lead to protein degradation. The net chemical change is the addition of a water group and removal of an ammonia group, which corresponds to a +1 (0.98402) Da mass increase. Although deamidation occurs on glutamine, glycosylated asparagine and other amides, these are negligible under typical proteolysis conditions.[1]

In the deamidation of an asparagine residue under physiological conditions, the side chain is attacked by the nitrogen atom of the following peptide group (in black at top right of Figure), forming an asymmetric succinimide intermediate (in red). The asymmetry of the intermediate results in two products of its hydrolysis, either aspartic acid (in black at left) or isoaspartic acid, which is a beta amino acid (in green at bottom right). However, there is a concern that aspartic acid can be isomerized after deamidation.[2] The deamidation of a glutamine residue may proceed via the same mechanism but at a much slower rate since formation of the six-member-ring glutarimide intermediate is less favoured than the succinimide intermediate for asparagine. In general, deamidation can be eliminated by proteolysis at an acidic pH or at a slightly basic pH (4.5 and 8.0, respectively) using the endoprotease, Glu-C.[2]

The rates of deamidation depend on multiple factors, including the primary sequences and higher-order structures of the proteins, pH, temperature, and components in the solutions. Most potential deamidation sites are stabilized by higher order structure. Asn-Gly (NG),is the most flexible and since it is acidic, it is most prone to deamidation with a half-life around 24 h under physiological conditions (pH 7.4, 37 °C).[3]

As a free amino acid, or as the N-terminal residue of a peptide or protein, glutamine deamidates readily to form pyroglutamic acid (5-oxoproline). The reaction proceeds via nucleophilic attack of the α-amino group on the side-chain amide to form a γ-lactam with the elimination of ammonia from the side-chain.

Analytical method

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Protein deamidation has been commonly analyzed by reverse-phase liquid chromatography (RPLC) through peptide mapping. Recently reported novel ERLIC-MS/MS method would enhance the separation of deamidated and non-deamidated peptides with increased identification and quantitation quantification.[4]

Mass spectrometry is commonly used to characterize deamidation states of proteins, including therapeutic monoclonal antibodies.[5] The technique is especially useful for deamidation analysis due to its high sensitivity, speed, and specificity. This allows site-specific deamidation analysis.[6]

A major challenge of using mass spectrometry is the formation of deamidation artifacts during sample preparation. These artifacts significantly skew results because they suggest greater rates of spontaneous deamidation than what is truly observed. This can prove problematic in the case of therapeutic proteins which can be mischaracterized in QC protocols if a large percentage of detected deamidation is due to artifacts. Recent studies indicate that lower pH can reduce the rate of deamidation artifacts.[2]

Kinetics of deamidation

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Deamidation reactions have been conjectured to be one of the factors that limit the useful lifetime of proteins.[1]

Deamidation proceeds much more quickly if the susceptible amino acid is followed by a small, flexible residue such as glycine whose low steric hindrance leaves the peptide group open for attack. Deamidation reactions also proceed much more quickly at elevated pH (>10) and temperature.

The endoprotease, Glu-C, has shown specificity to only glutamic acid when in specific pH conditions (4.5 and 8.0) and cleaved the C-terminal side when in a solution with Tris-HCl, bicarbonate, or acetate.

See also

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References

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  1. ^ a b Clarke, S (2003). "Aging as war between chemical and biochemical processes: protein methylation and the recognition of age-damaged proteins for repair". Ageing Res Rev. 2 (3): 263–285. doi:10.1016/S1568-1637(03)00011-4. PMID 12726775. S2CID 18135051.
  2. ^ a b c Liu, Shanshan; Moulton, Kevin Ryan; Auclair, Jared Robert; Zhou, Zhaohui Sunny (2016-04-01). "Mildly acidic conditions eliminate deamidation artifact during proteolysis: digestion with endoprotease Glu-C at pH 4.5". Amino Acids. 48 (4): 1059–1067. doi:10.1007/s00726-015-2166-z. ISSN 1438-2199. PMC 4795971. PMID 26748652.
  3. ^ Tyler-Cross R, Schirch V (1991) Effects of amino acid sequence, buffers, and ionic strength on the rate and mechanism of deamidation of asparagine residues in small peptides. J Biol Chem 266:22549–22556
  4. ^ Zhen, Jing (2018). "Antibody characterization using novel ERLIC-MS/MS-based peptide mapping". mAbs. 10 (7): 1–9. doi:10.1080/19420862.2018.1505179. PMC 6204790. PMID 30130443.
  5. ^ Wang, Weijie; Meeler, Andrea R.; Bergerud, Luke T.; Hesselberg, Mark; Byrne, Michael; Wu, Zhuchun (2012). "Quantification and characterization of antibody deamidation by peptide mapping with mass spectrometry". International Journal of Mass Spectrometry. 312: 107–113. Bibcode:2012IJMSp.312..107W. doi:10.1016/j.ijms.2011.06.006.
  6. ^ Hao, Piliang; Adav, Sunil S.; Gallart-Palau, Xavier; Sze, Siu Kwan (November 2017). "Recent advances in mass spectrometric analysis of protein deamidation". Mass Spectrometry Reviews. 36 (6): 677–692. Bibcode:2017MSRv...36..677H. doi:10.1002/mas.21491. ISSN 1098-2787. PMID 26763661.