Estimation of the deamidation rates of major deamidation sites in a Fab fragment of mouse IgG1-κ by capillary isoelectric focusing of mutated Fab fragments.

The deamidation of asparagine (Asn or N) residues in proteins is a common post-translational chemical modification. The identification of deamidation sites and determination of the degree of deamidation have been carried out by the combination of peptide mapping and mass spectrometry. However, when a peptide fragment contains multiple amides, such analysis becomes difficult and sometimes impossible. In this report, a quantitative method for estimating the deamidation rate of a specific amide in a protein is presented without using peptide mapping. Five Asn residues of a recombinant fragment antigen binding (rFab) (mouse IgG1, κ) were mutated to a serine (Ser) residue, one by one, through site-directed mutagenesis, and the single-residue deamidation rates of the original rFab and the mutants were determined using capillary isoelectric focusing. The difference of the rate between the original rFab and the mutant was assumed to be equal to the deamidation rate of the specific Asn residue, which had been mutated. Among five mutants established, three major deamidation sites-H chain Asn135, L chain Asn157, and L chain Asn161, using the Kabat numbering system-were identified, accounting for 66%, 29%, and 7% of the single-residue deamidation of the original rFab, respectively. Although the former two have been known by peptide mapping, the last one, which resides on the same tryptic peptide that carries one of the former two, previously has not been identified. For the first time, the deamidation rate constants of the three sites were estimated to be 10.5 × 10(-3) h(-1), 4.6 × 10(-3) h(-1), and 1.1 × 10(-3) h(-1) in 0.1 M phosphate buffer, pH 7.5 at 37 °C, respectively, with corresponding half-life of 2.8 days, 6.3 days, and 27 days. The method should be applicable to any recombinant proteins.

Fluorescence-labeled peptide pI markers for capillary isoelectric focusing.

Nineteen fluorescent pH standards or pI markers ranging pH 3.64-10.12 were developed for use in capillary isoelectric focusing using laser-induced fluorescence detection. Tetra- to tridecapeptides containing one cysteine residue were designed to focus sharply at their respective isoelectric points by including amino acids that contain charged side chains, the pKa values of which are close to the corresponding pI values. An iodoacetylated derivative of tetramethylrhodamine was coupled to the thiol group of cysteine to yield fluorescent pI markers. The pI values of the labeled peptides were precisely determined after isoelectric focusing on polyacrylamide gel slabs by direct measurement of the pH of the focused bands. The markers were subjected to capillary isoelectric focusing for 10-15 min in coated capillaries under conditions of low electroosmosis and were detected by means of a scanning laser-induced fluorescence detector down to a level of subpicomolar range. The markers permitted the calibration of a wide-range pH gradient formed in a capillary by fluorescence detection for the first time and should facilitate the development of highly sensitive analytical methods based on a combination of capillary isoelectric focusing and laser-induced fluorescence detection.

Immunoassay of serum alpha(1)-antitrypsin by affinity-probe capillary isoelectric focusing using a fluorescence-labeled recombinant antibody fragment.

An immunoassay for human alpha(1)-antitrypsin based on affinity-probe capillary isoelectric focusing (AP-CIEF) is described. The method is based on the separation of free and bound labeled antibody fragments by CIEF with laser-induced fluorescence detection. A recombinant Fab' fragment of mouse immunoglobulin G1 (IgG1) against human alpha(1)-antitrypsin was labeled with tetramethylrhodamine on the single cysteine residue at the hinge region. A single pI isomer of the labeled Fab' was purified by IEF in a slab of agarose gel and was then used as the affinity probe for alpha(1)-antitrypsin. The use of recombinant Fab' considerably simplified the labeling process. Although there was some difficulty in the quantification of native alpha(1)-antitrypsin with the affinity probe, carbamylation of the antigen sample by heat treatment with urea made the complex peaks appear reproducibly and more distinct, thus facilitating the identification and quantification of the complex. The system provided an almost linear response to a pure sample of alpha(1)-antitrypsin over a concentration range of 5-1000 ng/mL and the detection limit extended down to around 2 ng/mL. Alpha(1)-antitrypsin in a serum sample was determined using this system to be 1.2 mg/mL which is comparable to the reported value for the protein.