Engineering of conserved residues near antibody heavy chain complementary determining region 3 (HCDR3) improves both affinity and stability

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2023-07-01 DOI:10.1016/j.bbapap.2023.140915

Merve Arslan , Tuğçe Uluçay , Seyit Kale , Sibel Kalyoncu

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Abstract

Affinity and stability are crucial parameters in antibody development and engineering approaches. Although improvement in both metrics is desirable, trade-offs are almost unavoidable. Heavy chain complementarity determining region 3 (HCDR3) is the best-known region for antibody affinity but its impact on stability is often neglected. Here, we present a mutagenesis study of conserved residues near HCDR3 to elicit the role of this region in the affinity-stability trade-off. These key residues are positioned around the conserved salt bridge between V_H-K94 and V_H-D101 which is crucial for HCDR3 integrity. We show that the additional salt bridge at the stem of HCDR3 (V_H-K94:V_H-D101:V_H-D102) has an extensive impact on this loop's conformation, therefore simultaneous improvement in both affinity and stability. We find that the disruption of π-π stacking near HCDR3 (V_H-Y100E:V_L-Y49) at the V_H-V_L interface cause an irrecoverable loss in stability even if it improves the affinity. Molecular simulations of putative rescue mutants exhibit complex and often non-additive effects. We confirm that our experimental measurements agree with the molecular dynamic simulations providing detailed insights for the spatial orientation of HCDR3. V_H-V102 right next to HCDR3 salt bridge might be an ideal candidate to overcome affinity-stability trade-off.

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抗体重链互补决定区3（HCDR3）附近保守残基的工程化提高了亲和力和稳定性

亲和性和稳定性是抗体开发和工程方法中的关键参数。尽管这两个指标的改进都是可取的，但权衡几乎是不可避免的。重链互补决定区3（HCDR3）是最著名的抗体亲和力区，但其对稳定性的影响往往被忽视。在这里，我们对HCDR3附近的保守残基进行了诱变研究，以引出该区域在亲和稳定性权衡中的作用。这些关键残基位于VH-K94和VH-D101之间的保守盐桥周围，这对HCDR3的完整性至关重要。我们发现，HCDR3茎部的额外盐桥（VH-K94:VH-D101:VH-D102）对该环的构象有广泛影响，因此同时提高了亲和力和稳定性。我们发现，在VH-VL界面处，HCDR3（VH-Y100E:VL-Y49）附近的π-π堆积的破坏导致了不可恢复的稳定性损失，即使它提高了亲和力。假定的拯救突变体的分子模拟表现出复杂且通常是非加性效应。我们证实，我们的实验测量结果与分子动力学模拟一致，为HCDR3的空间取向提供了详细的见解。紧邻HCDR3盐桥的VH-V102可能是克服亲和稳定性权衡的理想候选者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464