Deuterium Labeling of Isoaspartic and Isoglutamic Acids for Mass Spectrometry Analysis.

Isoaspartic acid (isoAsp) is a common protein modification that spontaneously arises from asparagine or aspartic acid and has been linked to various diseases and health conditions. However, current methods for identifying isoAsp sites in proteins often suffer from ambiguity and have not gained widespread adoption. We developed a novel method that exclusively labels isoAsp with deuterium. This method capitalizes on the unique structural characteristics of isoAsp residues, which possess a free α-carboxyl group and can form an oxazolone ring. Once the oxazolone ring forms, it facilitates racemization at the Cα-position, incorporating a deuteron from a D2O solvent. The sites of deuterium-incorporated isoAsp in proteins can be unequivocally determined by comparing the precursor and product ion masses of the peptides from proteins reacted in H2O and D2O. The effectiveness of this method has been demonstrated through its application to model proteins lysozyme and rituximab. Furthermore, we have confirmed that the isoAsp deuterium-labeling reaction efficiently labels both l- and d-isoAsp without distinction, as well as isoglutamic acid (isoGlu), for which no effective detection methods currently exist.

Discrimination of Aspartic and Isoaspartic Acid Residues in Peptides by Tandem Mass Spectrometry with Hydrogen Attachment Dissociation.

Long-lived proteins undergo chemical modifications that can cause age-related diseases. Among these chemical modifications, isomerization is the most difficult to identify. Isomerization often occurs at the aspartic acid (Asp) residues. In this study, we used tandem mass spectrometry equipped with a newly developed ion activation method, hydrogen attachment dissociation (HAD), to analyze peptides containing Asp isomers. Although HAD preferentially produces [cn + 2H]+ and [zm + 2H]+ via N-Cα bond cleavage, [cn + 58 + 2H]+ and [zm - 58 + 2H]+ originate from the fragmentation of the isoAsp residue. Notably, [cn + 58 + 2H]+ and [zm - 58 + 2H]+ could be used as diagnostic fragment ions for the isoAsp residue because these fragment ions did not originate from the Asp residue. The detailed fragmentation mechanism was investigated by computational analysis using density functional theory. According to the results, hydrogen attachment to the carbonyl oxygen in the isoAsp residue results in the Cα-Cß bond cleavage. The experimental and theoretical joint study indicates that the present method allows us to discriminate Asp and isoAsp residues, including site identification of the isoAsp residue. Moreover, we demonstrated that the molar ratio of peptide isomers in the mixture could be estimated from their fragment ion abundance. Therefore, tandem mass spectrometry with HAD is a useful method for the rapid discrimination and semiquantitative analysis of peptides containing isoAsp residues.

Differentiation of Aspartic and Isoaspartic Acid Using 193 nm Ultraviolet Photodissociation Mass Spectrometry.

Spontaneous conversion of aspartic acid (Asp) to isoaspartic acid (isoAsp) is a ubiquitous modification that influences the structure and function of proteins. This modification of Asp impacts the stability of biotherapeutics and has been linked to the development of neurodegenerative diseases. We explored the use of 193 nm ultraviolet photodissociation (UVPD) to distinguish Asp and isoAsp in the protonated and deprotonated peptides. The differences in the relative abundances of several fragment ions uniquely generated by UVPD were used to differentiate isomeric peptide standards containing Asp or isoAsp. These fragment ions result from the cleavage of bonds N-terminal to Asp/isoAsp residues in addition to the side-chain losses from Asp/isoAsp or the losses of COOH, CO2, CO, or H2O from y-ions. Fragmentation of Asp-containing tryptic peptides using UVPD resulted in more enhanced w/w + 1/y - 1/x ions, while isoAsp-containing peptides yielded more enhanced y - 18/y - 45/y - 46 ions. UVPD was also used to identify an isomerized peptide from a tryptic digest of a monoclonal antibody. Moreover, UVPD of a protonated nontryptic peptide resulted in more enhanced y ions N- and C-terminal to isoAsp and differences in b/y ion ratios that were used to identify the isoAsp peptide.

Testing the link between isoaspartate and Alzheimer's disease etiology.

Isoaspartate (isoAsp) is a damaging amino acid residue formed in proteins as a result of spontaneous deamidation. IsoAsp disrupts protein structures, making them prone to aggregation. Here we strengthened the link between isoAsp and Alzheimer's disease (AD) by novel approaches to isoAsp analysis in human serum albumin (HSA), the most abundant blood protein and a major carrier of amyloid beta (Aß) and phosphorylated tau (p-tau) in blood. We discovered a reduced amount of anti-isoAsp antibodies (P < 0.0001), an elevated isoAsp level in HSA (P < 0.001), more HSA aggregates (P < 0.0001), and increased levels of free Aß (P < 0.01) in AD blood compared to controls. We also found that deamidation significantly reduces HSA capacity to bind with Aß and p-tau (P < 0.05). These suggest the presence in AD of a bottleneck in clearance of Aß and p-tau, leading to their increased concentrations in the brain and facilitating their aggregations there.

Arabidopsis protein l-ISOASPARTYL METHYLTRANSFERASE repairs isoaspartyl damage to antioxidant enzymes and increases heat and oxidative stress tolerance.

Stressful environments accelerate the formation of isoaspartyl (isoAsp) residues in proteins, which detrimentally affect protein structure and function. The enzyme PROTEIN l-ISOASPARTYL METHYLTRANSFERASE (PIMT) repairs other proteins by reverting deleterious isoAsp residues to functional aspartyl residues. PIMT function previously has been elucidated in seeds, but its role in plant survival under stress conditions remains undefined. Herein, we used molecular, biochemical, and genetic approaches, including protein overexpression and knockdown experiments, in Arabidopsis to investigate the role of PIMTs in plant growth and survival during heat and oxidative stresses. We demonstrate that these stresses increase isoAsp accumulation in plant proteins, that PIMT activity is essential for restricting isoAsp accumulation, and that both PIMT1 and PIMT2 play an important role in this restriction and Arabidopsis growth and survival. Moreover, we show that PIMT improves stress tolerance by facilitating efficient reactive oxygen species (ROS) scavenging by protecting the functionality of antioxidant enzymes from isoAsp-mediated damage during stress. Specifically, biochemical and MS/MS analyses revealed that antioxidant enzymes acquire deleterious isoAsp residues during stress, which adversely affect their catalytic activities, and that PIMT repairs the isoAsp residues and thereby restores antioxidant enzyme function. Collectively, our results suggest that the PIMT-mediated protein repair system is an integral part of the stress-tolerance mechanism in plants, in which PIMTs protect antioxidant enzymes that maintain proper ROS homeostasis against isoAsp-mediated damage in stressful environments.

First Immunoassay for Measuring Isoaspartate in Human Serum Albumin.

Isoaspartate (isoAsp) is a damaging amino acid residue formed in proteins mostly as a result of spontaneous deamidation of asparaginyl residues. An association has been found between isoAsp in human serum albumin (HSA) and Alzheimer's disease (AD). Here we report on a novel monoclonal antibody (mAb) 1A3 with excellent specificity to isoAsp in the functionally important domain of HSA. Based on 1A3 mAb, an indirect enzyme-linked immunosorbent assay (ELISA) was developed, and the isoAsp occupancy in 100 healthy plasma samples was quantified for the first time, providing the average value of (0.74 ± 0.13)%. These results suggest potential of isoAsp measurements for supplementary AD diagnostics as well as for assessing the freshness of stored donor blood and its suitability for transfusion.

An Unusually Rapid Protein Backbone Modification Stabilizes the Essential Bacterial Enzyme MurA.

Proteins are subject to spontaneous rearrangements of their backbones. Most prominently, asparagine and aspartate residues isomerize to their ß-linked isomer, isoaspartate (isoAsp), on time scales ranging from days to centuries. Such modifications are typically considered "molecular wear-and-tear", destroying protein function. However, the observation that some proteins, including the essential bacterial enzyme MurA, harbor stoichiometric amounts of isoAsp suggests that this modification can confer advantageous properties. Here, we demonstrate that nature exploits an isoAsp residue within a hairpin to stabilize MurA. We found that isoAsp formation in MurA is unusually rapid and critically dependent on folding status. Moreover, perturbation of the isoAsp-containing hairpin via site-directed mutagenesis causes aggregation of MurA variants. Structural mass spectrometry revealed that this effect is caused by local protein unfolding in MurA mutants. Our findings demonstrate that MurA evolved to "mature" via a spontaneous post-translational incorporation of a ß-amino acid, which raises the possibility that isoAsp-containing hairpins may serve as a structural motif of biological importance.

The l-isoaspartate modification within protein fragments in the aging lens can promote protein aggregation.

Transparency in the lens is accomplished by the dense packing and short-range order interactions of the crystallin proteins in fiber cells lacking organelles. These features are accompanied by a lack of protein turnover, leaving lens proteins susceptible to a number of damaging modifications and aggregation. The loss of lens transparency is attributed in part to such aggregation during aging. Among the damaging post-translational modifications that accumulate in long-lived proteins, isomerization at aspartate residues has been shown to be extensive throughout the crystallins. In this study of the human lens, we localize the accumulation of l-isoaspartate within water-soluble protein extracts primarily to crystallin peptides in high-molecular weight aggregates and show with MS that these peptides are from a variety of crystallins. To investigate the consequences of aspartate isomerization, we investigated two αA crystallin peptides 52LFRTVLDSGISEVR65 and 89VQDDFVEIH98, identified within this study, with the l-isoaspartate modification introduced at Asp58 and Asp91, respectively. Importantly, whereas both peptides modestly increase protein precipitation, the native 52LFRTVLDSGISEVR65 peptide shows higher aggregation propensity. In contrast, the introduction of l-isoaspartate within a previously identified anti-chaperone peptide from water-insoluble aggregates, αA crystallin 66SDRDKFVIFL(isoAsp)VKHF80, results in enhanced amyloid formation in vitro The modification of this peptide also increases aggregation of the lens chaperone αB crystallin. These findings may represent multiple pathways within the lens wherein the isomerization of aspartate residues in crystallin peptides differentially results in peptides associating with water-soluble or water-insoluble aggregates. Here the eye lens serves as a model for the cleavage and modification of long-lived proteins within other aging tissues.

A Fluorescence-Based High-Throughput Coupled Enzymatic Assay for Quantitation of Isoaspartate in Proteins and Peptides.

Formation of isoaspartate (IsoAsp) from spontaneous asparagine (Asn) deamidation or aspartate (Asp) isomerization is one of the most common non-enzymatic pathways of chemical degradation of protein and peptide pharmaceuticals. Rapid quantitation of IsoAsp formation can enable rank-ordering of potential drug candidates, mutants, and formulations as well as support shelf life prediction and stability requirements. A coupled enzymatic fluorescence-based IsoAsp assay (CEFIA) was developed as a high-throughput method for quantitation of IsoAsp in peptides and proteins. In this note, application of this method to two therapeutic candidate proteins with distinct structural scaffolds is described. In addition, the results obtained with this method are compared to those from conventional assays.

Mildly acidic conditions eliminate deamidation artifact during proteolysis: digestion with endoprotease Glu-C at pH 4.5.

Common yet often overlooked, deamidation of peptidyl asparagine (Asn or N) generates aspartic acid (Asp or D) or isoaspartic acid (isoAsp or isoD). Being a spontaneous, non-enzymatic protein post-translational modification, deamidation artifact can be easily introduced during sample preparation, especially proteolysis where higher-order structures are removed. This artifact not only complicates the analysis of bona fide deamidation but also affects a wide range of chemical and enzymatic processes; for instance, the newly generated Asp and isoAsp residues may block or introduce new proteolytic sites, and also convert one Asn peptide into multiple species that affect quantification. While the neutral to mildly basic conditions for common proteolysis favor deamidation, mildly acidic conditions markedly slow down the process. Unlike other commonly used endoproteases, Glu-C remains active under mildly acid conditions. As such, as demonstrated herein, deamidation artifact during proteolysis was effectively eliminated by simply performing Glu-C digestion at pH 4.5 in ammonium acetate, a volatile buffer that is compatible with mass spectrometry. Moreover, nearly identical sequence specificity was observed at both pH's (8.0 for ammonium bicarbonate), rendering Glu-C as effective at pH 4.5. In summary, this method is generally applicable for protein analysis as it requires minimal sample preparation and uses the readily available Glu-C protease.

Isoaspartate-dependent molecular switches for integrin-ligand recognition.

Integrins are cell-adhesion receptors that mediate cell-extracellular-matrix (ECM) and cell-cell interactions by recognizing specific ligands. Recent studies have shown that the formation of isoaspartyl residues (isoAsp) in integrin ligands by asparagine deamidation or aspartate isomerization could represent a mechanism for the regulation of integrin-ligand recognition. This spontaneous post-translational modification, which might occur in aged proteins of the ECM, changes the length of the peptide bond and, in the case of asparagine, also of the charge. Although these changes typically have negative effects on protein function, recent studies suggested that isoAsp formation at certain Asn-Gly-Arg (NGR) sites in ECM proteins have a gain-of-function effect, because the resulting isoAsp-Gly-Arg (isoDGR) sequence can mimic Arg-Gly-Asp (RGD), a well-known integrin-binding motif. Substantial experimental evidence suggests that the NGR-to-isoDGR transition can occur in vitro in natural proteins and in drugs containing this motif, thereby promoting integrin recognition and cell adhesion. In this Commentary, we review these studies and discuss the potential effects that isoAsp formation at NGR, DGR and RGD sites might have in the recognition of integrins by natural ligands and by drugs that contain these motifs, as well as their potential biological and pharmacological implications.

A quantitative analysis of spontaneous isoaspartate formation from N-terminal asparaginyl and aspartyl residues.

The formation of isoaspartate (isoAsp) from asparaginyl or aspartyl residues is a spontaneous post-translational modification of peptides and proteins. Due to isopeptide bond formation, the structure and possibly function of peptides and proteins is altered. IsoAsp modifications within the peptide chain have been reported for many cytosolic proteins. Amyloid peptides (Aß) deposited in Alzheimer's disease may carry an N-terminal isoAsp-modification. Here, we describe a quantitative investigation of isoAsp-formation from N-terminal Asn and Asp using model peptides similar to the Aß N-terminus. The study is based on a newly developed separation of peptides using capillary electrophoresis (CE). 1H NMR was employed to validate the basic finding of N-terminal isoAsp-formation from Asp and Asn. Thereby, the isomerization of Asn at neutral pH (0.6 day(-1), peptide NGEF) is approximately six times faster than that within the peptide chain (AANGEF). The difference in velocity between Asn and Asp isomerization is approximately 50-fold. In contrast to N-terminal Asn, Asp isomerization is significantly accelerated at acidic pH. The kinetic solvent isotope (kD2O/kH2O) effect of 2.46 suggests a rate-limiting proton transfer in isoAsp-formation. The proton inventory is consistent with transfer of one proton in the transition state, supporting the previous notion of rate-limiting deprotonation of the peptide backbone amide during succinimide-intermediate formation. The study provides evidence for a spontaneous N-terminal isoAsp-formation within peptides and might explain the accumulation of N-terminal isoAsp in amyloid deposits.

Characterization of the isomerization products of aspartate residues at two different sites in a monoclonal antibody.

PURPOSE: To identify and understand isomerization products and degradation profile of different aspartate residues in an IgG1 monoclonal antibody. METHODS: Recombinant IgG1 was incubated for extended periods of time in a formulation buffer at recommended and accelerated storage temperatures. Isomerization reaction products were analyzed using ion exchange chromatography (IEC), hydrophobic interaction chromatography (HIC), peptide mapping, and LC-MS. Model peptides with sequences containing specific aspartate residues in IgG1 were synthesized and incubated under accelerated conditions. Products of isomerization reactions of peptides were analyzed by reverse phase chromatography (RP-HPLC) and LC-MS. X-ray crystallography data from Fab of IgG1 were used to understand mechanism of isomerization reactions. RESULTS: A MAb containing labile Asp32-Gly sequence in CDR I region undergoes rapid isomerization reaction and leads to formation of isoaspartate (IsoAsp) and cyclic imide (Asu) forms. Isomerization of aspartate residues was observed in a non-CDR region containing Asp74-Ser sequence. Isomerization reaction at Asp74-Ser led to formation of Asu74 and trace isoAsp74. While isoAsp32 increased linearly with time, isoAsp74 did not increase during storage. Asu32 and Asu74 followed non-linear degradation kinetics and reached steady state over time. Isomerization reaction of two different model peptides containing Asp32-Gly or Asp74-Ser with neighboring amino acid sequences as those found in the MAb result in formation of IsoAsp. CONCLUSIONS: Observed levels of Asu and trace IsoAsp at the Asp74 site are unusual for typical isomerization reactions. In addition to primary sequences, pKa, solvent exposure and high order structure around aspartate residues may have influenced isomerization reaction at Asp74 in MAbI. Different degradation profiles from the two Asp residues can influence shelf life and should be carefully evaluated during product development.

How is the anionic tetrahedral intermediate involved in the isomerization of aspartyl peptides to iso-aspartyl ones? A DFT study on the tetra-peptide.

An isomerization reaction of a tetra-peptide, Ac-Gly-Asp-Gly-Gly-NHMe → Ac-Gly-isoAsp-Gly-Gly-NHMe, was investigated by DFT calculations. Thirteen water molecules were added to the peptide for simulating proton transfers during the isomerization. As a starting analysis, the number (m) of water molecules participating in ready proton transfers was examined by the use of a small model system, H(3)C-NH-C(=O)-CH(2)-CH(2)-COOH and (H(2)O)(m). The m = 2 stepwise path was found to be of the smallest activation free energy. On the basis of this result, the first isomerization path of the tetra-peptide was obtained with four elementary processes. The m = 2 proton-transfer pattern is involved in them. A different proton transfer gives the second isomerization path with six elementary processes. The second path (with ionization) is more likely than the first one (without ionization). Formation of the five membered rings of the aminosuccinimidyl-residue and anionic tetrahedral intermediates enhances the encapsulation of H(3)O(+) through the wound tetra-peptide ring. The role of the hydrogen bonds on the encapsulation was discussed in terms of the optimized geometries of proton-transfer transition states and intermediates.

PIMT-Mediated Labeling of l-Isoaspartic Acid with Tris Facilitates Identification of Isomerization Sites in Long-Lived Proteins.

Isomerization of individual residues in long-lived proteins (LLPs) is a subject of growing interest in connection with many age-related human diseases. When isomerization occurs in LLPs, it can lead to deleterious changes in protein structure, function, and proteolytic degradation. Herein, we present a novel labeling technique for rapid identification of l-isoAsp using the enzyme protein l-isoaspartyl methyltransferase (PIMT) and Tris. The succinimide intermediate formed during reaction of l-isoAsp-containing peptides with PIMT and S-adenosyl methionine (SAM) is reactive with Tris base and results in a Tris-modified aspartic acid residue with a mass shift of +103 Da. Tris-modified aspartic acid exhibits prominent and repeated neutral loss of water when subjected to collisional activation. In addition, another dissociation pathway regenerates the original peptide following loss of a characteristic mass shift. Furthermore, it is demonstrated that Tris modification can be used to identify sites of isomerization in LLPs from biological samples such as the lens of the eye. This approach simplifies identification by labeling isomerization sites with a tag that causes a mass shift and provides characteristic loss during collisional activation.

Critical role of flanking residues in NGR-to-isoDGR transition and CD13/integrin receptor switching.

Various NGR-containing peptides have been exploited for targeted delivery of drugs to CD13-positive tumor neovasculature. Recent studies have shown that compounds containing this motif can rapidly deamidate and generate isoaspartate-glycine-arginine (isoDGR), a ligand of alphavbeta3-integrin that can be also exploited for drug delivery to tumors. We have investigated the role of NGR and isoDGR peptide scaffolds on their biochemical and biological properties. Peptides containing the cyclic CNGRC sequence could bind CD13-positive endothelial cells more efficiently than those containing linear GNGRG. Peptide degradation studies showed that cyclic peptides mostly undergo NGR-to-isoDGR transition and CD13/integrin switching, whereas linear peptides mainly undergo degradation reactions involving the alpha-amino group, which generate non-functional six/seven-membered ring compounds, unable to bind alphavbeta3, and small amount of isoDGR. Structure-activity studies showed that cyclic isoDGR could bind alphavbeta3 with an affinity >100-fold higher than that of linear isoDGR and inhibited endothelial cell adhesion and tumor growth more efficiently. Cyclic isoDGR could also bind other integrins (alphavbeta5, alphavbeta6, alphavbeta8, and alpha5beta1), although with 10-100-fold lower affinity. Peptide linearization caused loss of affinity for all integrins and loss of specificity, whereas alpha-amino group acetylation increased the affinity for all tested integrins, but caused loss of specificity. These results highlight the critical role of molecular scaffold on the biological properties of NGR/isoDGR peptides. These findings may have important implications for the design and development of anticancer drugs or tumor neovasculature-imaging compounds, and for the potential function of different NGR/isoDGR sites in natural proteins.

Repair of isoaspartate formation modulates the interaction of deamidated 4E-BP2 with mTORC1 in brain.

In eukaryotes, a rate-limiting step of translation initiation is recognition of the mRNA 5' m(7)GpppN cap structure by the eukaryotic initiation factor 4F (eIF4F), a heterotrimeric complex consisting of the cap-binding protein, eIF4E, along with eIF4G, and eIF4A. The eIF4E-binding proteins (4E-BPs) repress translation by disrupting eIF4F formation, thereby preventing ribosome recruitment to the mRNA. Of the three 4E-BPs, 4E-BP2 is the predominant paralog expressed in the mammalian brain and plays an important role in synaptic plasticity and learning and memory. 4E-BP2 undergoes asparagine deamidation, solely in the brain, during early postnatal development. Deamidation spontaneously converts asparagines into a mixture of aspartates or isoaspartates, the latter of which may be destabilizing to proteins. The enzyme protein L-isoaspartyl methyltransferase (PIMT) prevents isoaspartate accumulation by catalyzing the conversion of isoaspartates to aspartates. PIMT exhibits high activity in the brain, relative to other tissues. We report here that 4E-BP2 is a substrate for PIMT. In vitro deamidated 4E-BP2 accrues isoapartyl residues and is methylated by recombinant PIMT. Using an antibody that recognizes 4E-BP2, which harbors isoaspartates at the deamidation sites, Asn(99) and Asn(102), we demonstrate that 4E-BP2 in PIMT-/- brain lysates contains isoaspartate residues. Further, we show that 4E-BP2 containing isoaspartates lacks the augmented association with raptor that is a feature of deamidated 4E-BP2.

Differentiating N-terminal aspartic and isoaspartic acid residues in peptides.

Formation of isoaspartic acid (isoAsp) is a common modification of aspartic acid (Asp) or asparagine (Asn) residue in proteins. Differentiation of isoAsp and Asp residues is a challenging task owing to their similar properties and identical molecular mass. It was recently shown that they can be differentiated using ion-electron or ion-ion interaction fragmentation methods (ExD) because these methods provide diagnostic fragments c + 57 and z(•) - 57 specific to the isoAsp residue. To date, however, the presence of such fragments has not been explored on peptides with an N-terminal isoAsp residue. To address this question, several N-terminal isoAsp-containing peptides were analyzed using ExD methods alone or combined with chromatography. A diagnostic fragment [M + 2H - 74](+•) was observed for the doubly charged precursor ions with N-terminal isoAsp residues. For some peptides, identification of the N-terminal isoAsp residue was challenging because of the low diagnostic ion peak intensity and the presence of interfering peaks. Supplemental activation was used to improve diagnostic ion detection. Further, N-terminal acetylation was offered as a means to overcome the interference problem by shifting the diagnostic fragment peak to [M + 2H - 116](+•).

Sequence-specific predictive chromatography to assist mass spectrometric analysis of asparagine deamidation and aspartate isomerization in peptides.

Deamidation of asparagine and spontaneous isomerization of aspartic acid in proteins and peptides occur frequently. These modifications result in a mixture of peptide variants containing all three residues in the sequences. Identification and isomer quantification for these systems are challenging tasks for tandem mass spectrometry commonly utilized in protein analysis. Chromatographic data provide a set of sequence-specific information complementary to mass spectrometry. In order to compare measured retention times (RTs) with those calculated from the sequences derived from protein databases, it is necessary to develop chromatographic models and tools allowing the prediction of RT and elution order for peptides with modified residues. In this work we extended recently introduced critical liquid chromatography of biomacromolecule model for prediction of RTs for peptides containing asparagines, aspartic acid, and isoaspartic acid residues.

A DFT calculation on nonenzymatic degradation of isoaspartic residue.

ßAsp is an isomer of Asp that can be formed by either deamidation of Asn or isomerization of Asp and known as biological clock. The presence of ßAsp affects the proteolytic stability of the protein. Formation of the isomerized Asp plays a diverse and crucial role in aging, cancer, autoimmune, neurodegenerative, and other diseases. A number of methods have been developed to detect ßAsp, and they are usually used in conjunction. Because of identical mass, differentiation of ßAsp and Asp residues is challenged. Degradation of ßAsp is still unclear and needed to be explored. The energetics and mechanism of five possible pathways for cleavages at ßAsp in peptide model have been investigated by DFT/B3LYP/6-311 + + G(d,p) level of the theory. The calculations show that peptide bond cleavage at α-chain (amino side) due to αOC → αCN ring closure is the most favorable reaction. The result is in agreement with experiment utilizing PSD/CRF method. The second most favorable pathway is due to αOC → ßC ring closure results in ß-chain cleavage. The cleavage products ßAsp and Asp fragments can be used to signify an abundance of ßAsp residue in nonenzymatic condition. Other three cyclizations initiated by either α- or ß-amino nitrogen result in various cleavages, isomerization to Asp, and reconversion to original ßAsp. These three cyclization pathways are obstructed because they require mostly high activation barriers and their intermediates are quite less thermodynamically stable. Thus, computational results also confirm that ßAsp → Asp is prohibited in case of nonenzymatic condition which means that protein L-isoaspartyl O-methyl transferase (PIMT) is needed for this modification.