Developability Assessment of an Isolated C<sub>H</sub>2 Immunoglobulin Domain

Pastrana, Belinda; Nieves, Sherly; Li, Wei; Liu, Xianglei; Dimitrov, Dimiter S.

doi:10.1021/acs.analchem.0c02663

Cited by 7 publications

(2 citation statements)

References 28 publications

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“…Among such small binders, the isolated CH2 domain, comprising residues 238–340 (Figure 1a), lacks the disulfide bridges present between domains in intact immunoglobulins and is considered a promising scaffold, having both neonatal Fc receptor and effector binding sites and reasonable pharmacokinetics 28,30–33 . Proof‐of‐concept for CH2 as a binder scaffold has been demonstrated, 34 and its aggregation propensity has been discussed and improved over the past few years 35–38 . However, most studies have been done in the context of fully oxidized CH2, with a disulfide‐bridge formation between C261 and C321, that has been purified in periplasmic conditions 39 or in eukaryotic cells with glycosylation 40 …”

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confidence: 99%

“…28,[30][31][32][33] Proof-ofconcept for CH2 as a binder scaffold has been demonstrated, 34 and its aggregation propensity has been discussed and improved over the past few years. [35][36][37][38] However, most studies have been done in the context of fully oxidized CH2, with a disulfide-bridge formation between C261 and C321, that has been purified in periplasmic conditions 39 or in eukaryotic cells with glycosylation. 40 When Fv and Fab antibody fragments are expressed in a reducing, cytoplasmic environment, it is known that sufficient oxidization is needed to fold these proteins.…”

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The reduced form of the antibody CH2 domain

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Among the immunoglobulin domains, the CH2 domain has the lowest thermal stability, which also depends on amino acid sequence and buffer conditions. To further identify factors that influence CH2 folding and stability, we characterized the domain in the reduced form using differential scanning fluorimetry and nuclear magnetic resonance. We show that the CH2 domain can fold, similarly to the disulfide‐bridged form, without forming a disulfide‐bridge, even though the protein contains two Cys residues. Although the reduced form exhibits thermal stability more than 15°C lower than the disulfide‐bridged form, it does not undergo immediate full oxidization. To explain this phenomenon, we compared CH2 oxidization at different conditions and demonstrate a need for significant fluctuation of the folded conformation to enhance CH2 disulfide‐bridge formation. We conclude that, since CH2 can be purified as a folded, semi‐stable, reduced protein that can coexist with the oxidized form, verification of the level of oxidization at each step is critical in CH2 engineering studies.

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The reduced form of the antibody CH2 domain

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Two‐Dimensional Correlation Spectroscopy: New Developments and Applications

Jung¹,

Noda²

2022

Encyclopedia of Analytical Chemistry

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This article outlines the recent progress in 2D correlation spectroscopy (2D‐COS), especially new and noteworthy developments and its applications. 2D‐COS is a powerful technique applicable to the in‐depth analysis of various spectral data, especially those obtained in various practical spectroscopic experiments. 2D‐COS has undergone rapid developments. This article highlights new types of 2D correlation analysis, such as combination of chemometrics and 2D‐COS, moving‐window 2D analysis, projection 2D analysis, hetero‐correlation analysis, 2D codistribution spectroscopy (2D‐CDS), smooth factor analysis (SFA), two‐trace two‐dimensional (2T2D) correlation spectroscopy, as well as experimental practices, such as various perturbation methods, fields of applications, and analytical probes employed.

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Two‐Dimensional Correlation and Two‐Dimensional Co‐Distribution Spectroscopies of Proteins

Pastrana¹,

Meuse²

2022

Encyclopedia of Analytical Chemistry

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Given the complexity of proteins, the broad nature of infrared bands, and the overlap of the HOH bending mode of water within the 1700–1600 cm −1 spectral region, it was often considered too difficult to include side‐chain vibrational modes in a description of a protein's dynamic behavior in solution. Yet, it is the roles of side‐chains that allow a description of a protein's dynamics to become a site‐specific understanding of stability and provide a basis for the development of protein drugs. This article describes how, in certain cases, site‐specific analysis of protein infrared spectra can be performed using two‐dimensional infrared correlation spectroscopy ( 2D‐COS ) developed by Dr. Isao Noda. The 2D‐COS algorithm spreads overlapped peaks within a spectral region of interest into a second dimension that allows for a complete evaluation of all of the peaks that change during a perturbation. 2D‐COS analysis has been implemented successfully for the study of proteins under different perturbations such as pressure, chemical, pH, concentration, and most commonly temperature. Initially, the interest was in determining conformational changes during thermal unfolding, which then led to evaluating solvent accessibility through hydrogen/deuterium exchange, leading to the use of isotope editing to probe local structural changes and interactions. Herein, we will explore the extent that both 2D‐COS and two‐dimensional co‐distribution spectroscopy ( 2D‐CDS ) have been implemented in the study of proteins. However, we were also keen to include recent advances to site‐specifically monitor protein deamidation in aqueous solution. Protein deamidation, like oxidation and glycosylation, is one of the processes that can initiate protein degradation pathways which could lead to decreased target binding, decreased stability, and possibly aggregation. These concerns have become part of the critical quality attributes ( CQAs ) evaluated during therapeutic protein development because they can potentially impact drug safety and efficacy. To date, tandem liquid chromatography–mass spectrometry ( LC‐MS ) techniques have been the primary method used to ascertain the presence and sites of deamidation in protein samples. However, the LC‐MS process requires multiple steps, including enzymatic digestion and peptide mapping. 2D‐COS and 2D‐CDS analyses provide an alternative that allows the determination of the deamidation sites and the evaluation of the stability of the protein populations within a sample without any sample preparation steps. The 2D‐COS method utilizes an innovative platform comprised of a quantum cascade laser microscope ( QCLM ), slide cell array, and software. The QCLM provides an enhanced signal/noise ratio and real‐time acquisition of hyperspectral images of an array of proteins in solution under accurate thermal control. The method monitors the deamidation process during thermal stress. Spectral data is then subject to 2D‐COS analysis to determine the extent of and site at which both asparagine and glutamine deamidation occur. In addition, 2D‐CDS analysis allows assessment of changes in stability in the distributions of the protein populations during the perturbation. The results presented here for the deamidation of the NISTmAb have been validated by LC‐MS to evaluate this new analytical tool. We foresee this approach as a required step in a therapeutic protein's developability assessment and release testing.

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Developability Assessment of an Isolated C_H2 Immunoglobulin Domain

Cited by 7 publications

References 28 publications

The reduced form of the antibody CH2 domain

The reduced form of the antibody CH2 domain

Two‐Dimensional Correlation Spectroscopy: New Developments and Applications

Two‐Dimensional Correlation and Two‐Dimensional Co‐Distribution Spectroscopies of Proteins

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Developability Assessment of an Isolated CH2 Immunoglobulin Domain

Cited by 7 publications

References 28 publications

The reduced form of the antibody CH2 domain

The reduced form of the antibody CH2 domain

Two‐Dimensional Correlation Spectroscopy: New Developments and Applications

Two‐Dimensional Correlation and Two‐Dimensional Co‐Distribution Spectroscopies of Proteins

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Developability Assessment of an Isolated C_H2 Immunoglobulin Domain