Most drugs enter the blood after administration and are distributed to various tissues. In the bloodstream, they bind to serum proteins, such as albumin. The interactions of drugs with serum proteins significantly affect their pharmacokinetics and pharmacodynamics and are therefore carefully evaluated during drug discovery and development (1–3). Many of the currently used therapeutic antibodies are administered intravenously and exert their effect in the blood (4). However, limited studies have been conducted on the effects of interactions between therapeutic antibodies and serum proteins.

A previous study found that serum polyclonal antibodies had a negative effect on antibody-dependent cellular cytotoxicity (ADCC) (5). This may be the result of their competitive inhibition of the binding of therapeutic antibodies to Fcγ receptor IIIa (FcγRIIIa) through their Fc region. In this regard, the binding target of the serum protein is not the therapeutic antibody, but rather its cognate receptor. Such Fc-mediated competitive binding unavoidably occurs with various Fc receptors, including FcRn, thereby affecting other effector functions and pharmacokinetics of therapeutic antibodies, such as blood half-life (6). On the other hand, several studies have indicated that human serum components can interact with immunoglobulin G (IgG). For instance, analytical ultracentrifugation indicated that human serum albumin (HSA) interacts with human monoclonal IgG1 (7, 8), whereas our nuclear magnetic resonance (NMR) studies demonstrated that mouse IgG2b semi-specifically interacts with the Fab region of pooled human serum polyclonal antibody but barely with HSA (9, 10). However, the functional effects of these interactions remain unexplored.

Given this situation, we investigated the effects of the interaction between serum proteins and human IgG1 on its ADCC function mediated by FcγRIIIa. We used rituximab, an anti-CD20 mouse/human-chimeric IgG1 (11), along with HSA and polyclonal antibody, which together account for >70% of the serum proteins (12). Additionally, we characterized the interactions using stable-isotope-assisted NMR spectroscopy.

Rituximab is clinically used to treat certain cancers, including chronic lymphocytic leukemia and non-Hodgkin’s lymphoma (11). The anticancer activity of this therapeutic antibody is based on ADCC through its interaction with FcγRIIIa, which is typically expressed on natural killer cells. We evaluated ADCC activity using a reporter cell line expressing human FcγRIIIa and NFAT-driven luciferase reporter gene (20). The EC50 obtained from the present ADCC reporter assay was approximately 20 ng/mL, which is consistent with the previous report (22). The serum concentrations of HSA and polyclonal IgG have been reported as 35-50 mg/mL and 4.1-21.7 mg/mL, respectively (23, 24). Taking this into account, 600 μM of HSA or 240 μM of polyclonal human IgG-Fab were added to this cell-based assay system. However, an equimolar amount of their Fab fragment was used instead of polyclonal IgG antibodies because full-length IgG was expected to be competitive with rituximab regarding the Fc-mediated binding to FcγRIIIa (5). The assay results revealed that ADCC was moderately compromised by the polyclonal IgG-Fab fragments, while HSA negatively affected ADCC more intensely ( Figure 1 ). These serum proteins little affected EC50, but rather reduced the magnitude of the maximum response, indicating their non-competitive inhibition.

Next, the effects of these serum proteins on IgG1–FcγRIIIa interaction were examined via BLI analysis. The extracellular region of FcγRIIIa was immobilized onto a sensor, which was subjected to rituximab solutions in the presence or absence of HSA or polyclonal IgG-Fab. The results showed that HSA negatively affected their interaction, while no significant inhibition was observed by polyclonal IgG-Fab ( Figure 2 ). Hence, we attempted to use a more sensitive technique for detecting weak interactions involving the serum proteins.

NMR can be a valuable tool for detecting weak interactions while dealing with heterogeneous systems. For selective observation of antibody NMR signals, we have established stable-isotope-labeling techniques of IgG glycoproteins using various eukaryotic expression systems (10, 14, 25, 26). In the present study, we prepared uniformly ¹⁵N-labeled rituximab, which was cleaved into Fab and Fc fragments for HSQC spectral measurements, to assess their interactions with HSA or polyclonal IgG-Fab. Additionally, we subjected uniformly ¹⁵N-labeled sFcγRIIIb to HSQC spectral measurements. Upon addition of HSA, the HSQC peaks of these ¹⁵N-labeled proteins exhibited attenuation of intensity ( Figure 3 ), which was quantified for each peak according to the equation (Io-Ip)/Io, where Io and Ip are original peak intensity and intensity after perturbation, respectively. The degree of impact by HSA decreased in the order of rituximab-Fab > rituximab-Fc > sFcγRIIIb ( Figure 4 ). The serum polyclonal IgG-Fab induced significant intensity attenuation for the peaks originating from rituximab-Fc, but the impact was smaller than that caused by HSA ( Figures 3 , 4 ). We have established assignments of the backbone HSQC peaks originating from Fc (16) and sFcγRIIIb (15), enabling us to map the spectral perturbation on their crystal structures (27, 28). The results showed that the interactions with HSA and polyclonal IgG-Fab cover these molecular surfaces extensively ( Figure 5 ). Thus, the NMR data provide valuable information regarding the interactions of rituximab with the serum proteins, although the method required much higher concentrations of ¹⁵N-labeled proteins as compared with the expected concentration in the blood for rituximab treatment (>10 μg/mL), due to the sensitivity limitations of the NMR method (30). Human serum itself and the full-length form of serum polyclonal IgG caused more enhanced spectral changes of rituximab-Fc than the polyclonal IgG-Fab and HSA ( Figure 6 ).

This study demonstrated that HSA, the most abundant serum protein, negatively affects the interaction between rituximab and FcγRIIIa and compromises ADCC. The NMR data provide direct evidence for the interaction of HSA with rituximab, and to a lesser extent, with the extracellular region of FcγRIIIb. The extracellular region of FcγRIIIa shares 96% amino acid identity with that of FcγRIIIb and therefore possibly interacts with HSA to the same extent as FcγRIIIb in this condition, although their N-glycans may affect the interaction. HSA interacted with both the Fab and Fc regions of rituximab, but to a greater extent with Fab, which is not only responsible for antigen binding but also directly involved in the interaction with FcγRIIIa (13, 19, 31). Hence, HSA may interfere at various points in ADCC, at least for interaction with FcγRIIIa mediated by both Fab and Fc, and possibly for antigen recognition.

Residues perturbed by HSA were widely distributed in the Fc and sFcγRIIIb molecules, including their binding sites, suggesting that the interaction is not mediated by specific sites ( Figure 5 ). Our previous NMR study demonstrated that mouse IgG2b-Fc interacted with polyclonal IgG-Fab from pooled human serum but to a considerably weaker extent with HSA (9). In contrast, analytical centrifugation detected weak reversible interactions between HSA and adalimumab, a human IgG1 monoclonal antibody antagonizing tumor necrosis factor (7). Thus, the interaction with HSA exhibits specificity for human IgG1 to a certain extent.

Although HSA harbors versatile binding pockets that accommodate basic, acidic, or neutral small molecules (32), the overall physical properties, such as net charges, rather than local structural features, may govern its interactions with macromolecules. Indeed, charge variation in IgG affects the binding to FcγRIIIa (33). In a neutral solution, HSA (pI = 5.7) is net negatively charged and therefore interacts preferably with positively charged proteins. This consistently explains the NMR observations, i.e., extensive, moderate, and undetectable interactions with rituximab-Fab (pI = 8.8), rituximab-Fc (pI = 7.1), and sFcγRIIIb (pI = 6.2), respectively. This may also explain why mouse IgG2b-Fc (pI = 6.3) shows little binding to HSA. This means that charge variations of IgG1, such as deamination, affect its interaction with HSA. According to this theory, an Fab with a λ chain would be more intensively interact with HSA than rituximab-Fab. This is because the Cλ domains have a higher isoelectric point (pI = 6.9 – 9.1) than that of the Cκ domain (pI = 5.6), which is harbored in rituximab-Fab.

Although much less pronounced than the effect of HSA, the Fab fragment from the pooled serum polyclonal IgG specifically interacted with the Fc region of rituximab and significantly affected ADCC. It was unexpected that polyclonal IgG-Fab interacted with the Fc region of rituximab, i.e. human IgG1-Fc, rather than the more heterologous rituximab-Fab harboring mouse-derived variable region. As in the HSA interaction, this significant preference may be attributed to the difference in net charge between Fab and Fc regions in rituximab because polyclonal IgG-Fab isolated from human serum generally has a pI of >7 (34). However, polyclonal IgG-Fab barely interacts with sFcγRIIIb, which has the lower pI value than rituximab-Fc, suggesting that some unknown factors determine the reactivity of polyclonal IgG-Fab. Anyway, the negative effect on ADCC is plausibly enhanced in the full-length form of serum polyclonal IgG with bivalency and bulkiness in addition to the Fc-mediated competition for FcγRIIIa (5). Indeed, the intact form of polyclonal IgG and human serum containing it had greater impacts on rituximab-Fc than the Fab fragment derived it ( Figure 6 ).

Because many therapeutic antibodies and Fc-fusion therapeutics share the common Fc region derived from human IgG1 (35), serum polyclonal IgG as well as HSA are likely to interact with these protein drugs affecting their interactions with FcγRIIIa and functional efficacy. The interactions with the serum proteins cover the Fc surface so extensively that they can act pan-inhibitory on various Fc receptor-mediated functions and pharmacokinetics. Furthermore, the non-competitive inhibition of ADCC by HSA and polyclonal IgG-Fab suggests that they can be allosteric inhibitors of Fc affecting its dynamic structure (36). Therefore, controlling the interactions with the serum proteins is an essential factor to consider in the development of therapeutic antibodies and Fc-fusion therapeutics. Their interactions are likely to depend on artificial and naturally occurring modifications, such as drug conjugation and glycosylation, and are presumably controllable through mutational charge modifications. Serum components, including HSA and polyclonal antibodies, can differ qualitatively and quantitatively depending on the disease state and drug administration history (37). In this regard, methods to assess interactions with serum components are valuable for the development and application of antibody-based drugs with increased efficacy and safety.

The original contributions presented in the study are included in the article/supplementary material. Further inquiries can be directed to the corresponding author.

SY: Conceptualization; data curation; funding acquisition; formal analysis; investigation; writing – original draft preparation; writing – review and editing. RY: Conceptualization; data curation; writing – review and editing. HY: data curation; writing – review and editing. MO: data curation; writing – review and editing. NW: data curation; writing – review and editing. YY: data curation; writing – review and editing. SU: data curation; investigation; writing – review and editing. KK: Conceptualization; funding acquisition; investigation; project administration; supervision; writing – original draft preparation; writing – review and editing. All authors contributed to the article and approved the submitted version.