Mechanisms of Neutralizing Anti-drug Antibody Formation and Clinical Relevance on Therapeutic Efficacy of Enzyme Replacement Therapies in Fabry Disease.

Fabry disease (FD) is a rare X-linked lysosomal storage disorder caused by mutations in the α-galactosidase A (AGAL/GLA) gene. The lysosomal accumulation of the substrates globotriaosylceramide (Gb3) and globotriaosylsphingosine (lyso-Gb3) results in progressive renal failure, cardiomyopathy associated with cardiac arrhythmia, and recurrent strokes, significantly limiting life expectancy in affected patients. Current treatment options for FD include recombinant enzyme-replacement therapies (ERTs) with intravenous agalsidase-α (0.2 mg/kg body weight) or agalsidase-β (1 mg/kg body weight) every 2 weeks, facilitating cellular Gb3 clearance and an overall improvement of disease burden. However, ERT can lead to infusion-associated reactions, as well as the formation of neutralizing anti-drug antibodies (ADAs) in ERT-treated males, leading to an attenuation of therapy efficacy and thus disease progression. In this narrative review, we provide a brief overview of the clinical picture of FD and diagnostic confirmation. The focus is on the biochemical and clinical significance of neutralizing ADAs as a humoral response to ERT. In addition, we provide an overview of different methods for ADA measurement and characterization, as well as potential therapeutic approaches to prevent or eliminate ADAs in affected patients, which is representative for other ERT-treated lysosomal storage diseases.

Key Points

Introduction

Fabry disease (FD) is a rare X-linked inherited lysosomal storage disease (LSD) due to a deficiency in α-galactosidase A (AGAL) activity [1]. Loss of enzyme function causes a progressive, sometimes life-threatening, multisystem disease due to intracellular accumulation of glycosphingolipids such as globotriaosylceramide (Gb3) [1]. Treatment options for FD have included enzyme-replacement therapy (ERT) since 2001 [2, 3]. Although treatment with the two currently available recombinant enzymes (agalsidase-alfa and agalsidase-beta) generally improves disease load, many male patients are at high risk for the formation of neutralizing anti-drug antibodies (ADAs), which significantly reduce the efficacy of ERT [4-7]. Since ERT needs to be prescribed life-long with mean annual costs of ~ 250.000€ per patient, ADAs increase the economic burden in addition to individual disease load.

In this narrative review, we provide a brief overview of the clinical picture of FD and diagnostic confirmation. The focus is on the biochemical and clinical significance of neutralizing ADAs as a humoral response to ERT. In addition, we provide an overview of different methods for ADA measurement and characterization, as well as potential therapeutic approaches to prevent or eliminate ADAs in affected patients. Since a humoral response to ERT generally follows the same immunological mechanisms, this review can be applied to other ERT-treated LSDs such as Gaucher disease, Mucopolysaccharidosis, Pompe disease, etc.

Clinical Picture and Diagnostic Confirmation of Fabry Disease (FB)

Affected patients with FD suffer from a multisystemic disease that includes progressive renal failure (requiring dialysis or transplantation), cardiomyopathy with sometimes life-threatening cardiac arrhythmias, recurrent transient ischemic attacks and strokes, gastrointestinal pain, and neuropathic pain of the extremities [1, 8]. Due to the random inactivation of one of the two X chromosomes, the clinical phenotype is more variable in affected females than in males [9].

FD is suspected when Fabry-typical symptoms or manifestations are detected and/or a positive family history is present. To confirm the diagnosis in men, determination of AGAL activity in leukocytes or from dried blood spots is the gold standard. A pathologically low AGAL activity confirms the presence of FD. In contrast, in women, a molecular genetic test detecting a disease-causing mutation in the GLA gene is required for confirmation, as women often have AGAL activities in blood that are within the reference range. Nowadays, men with pathologically decreased AGAL enzymatic activity should also undergo molecular genetic testing to determine the disease-causing mutation in order to select an appropriate FD-specific therapy, such as chaperone therapy [10]. As a biomarker for disease burden, pathologically elevated globotriaosylsphingosine (lyso-Gb3), the deacylated form of Gb3, can be measured in plasma or urine and contributes to diagnosis and therapy monitoring [11-17].

In case of unclear diagnostics (i.e., ambiguous AGAL activity, disputed controversial mutation, lyso-Gb3 levels and/or comorbidities), tissue biopsies can be performed to detect multilamellar myelin bodies (“zebra bodies”) by electron microscopy, which are pathognomonic for FD, but require special sample preparation.

Enzyme-Replacement Therapy (ERT)

Therapy Goals and Therapy Initiation

Once the FD diagnosis is confirmed, it is advisable to refer patients to an interdisciplinary Fabry center for initial evaluation and, if indicated, initiation of therapy. According to current expert opinion [18, 19], the following therapeutic goals should be aimed for: (1) a reduction of FD-specific complaints including pain reduction, (2) a prevention and/or delay of progressive organ manifestations with special focus on the kidney, heart, and central nervous system, (3) an improvement of quality of life, and (4) the normalization of life expectancy. Since male FD patients usually show a worse disease progression than females, the recommendations for the initiation of a FD-specific therapy in adult patients with a classic or milder late-onset clinical phenotype include a personalized treatment approach, taking into account the natural history of the specific disease phenotype [19]. In adult males with classic GLA mutations, FD-specific treatment (either ERT or migalastat) should be considered independent of the patient’s symptoms or manifestations. Treatment decisions may also be influenced by advanced age and additional comorbidities. In females with a classic mutation, treatment initiation is appropriate if patients are symptomatic with FD-typical organ involvement. In asymptomatic females with classic GLA mutations, treatment initiation needs to be considered in the presence of renal, cardiac, or central nervous system damage. In patients (females and males) with late-onset mutations (i.e., p.N215S), treatment should be considered in the presence of renal, cardiac, or central nervous system damage, even in the absence of other FD-typical symptoms (such as angiokeratoma, Cornea verticillata, etc.). However, symptoms should be caused by FD, requiring histologic evaluation (biopsies) or biochemical evidence of cellular Gb3 accumulation.

Patients with "benign," non-disease-causing GLA variants/polymorphisms should not be treated with any FD-specific therapy. Since the therapeutic goals are not always achievable, current consensus recommendations [18, 19] provide some guidance to establish appropriate goals between clinicians and FD patients. However, with respect to irreversible end-organ damage, early FD-specific therapy in combination with adjunctive therapy is advisable to delay or slow disease progression.

ERT—Two Approved Active Compounds

ERT as the first causal treatment for FD was approved in 2001 [2, 3]. Currently, two preparations are approved in Europe, which are administered intravenously every 2 weeks. Agalsidase-alfa (Replagal, Takeda/Shire) is produced in human fibrosarcoma cells HT-1080 with a recommended dosage of 0.2 mg/kg body weight. Agalsidase-beta (Fabrazyme, Sanofi Genzyme) is produced in Chinese hamster ovary (CHO) cells with a recommended dose of 1.0 mg/kg body weight. Over the past 20 years, ERT has shown good efficacy by stabilizing or even improving disease burden (reviewed by Lenders and Brand [20]), with beneficial effects especially regarding quality of life and reducing life-threatening events [21-23]. In short, with respect to the individual patients and their manifestations, the following therapeutic effects can be achieved by ERT: stabilization of kidney function (i.e., estimated glomerular filtration rate (eGFR), proteinuria) or delay of progression to terminal kidney failure, stabilization of cardiac mass and function and reduction of left ventricular hypertrophy, amelioration of FD-specific pain and gastrointestinal symptoms, and amelioration of hypohidrosis [20, 24–27].

In addition to ERT, concomitant nephroprotective and cardioprotective medication (angiotensin-converting enzyme or angiotensin II receptor blockers) is highly recommended to preserve renal [28] as well as cardiac [29] function. However, recent reviews and meta-analyses reported only a limited beneficial effect of ERT on patient outcome [30, 31]. An important mechanism responsible for the limited efficacy of therapy is the formation of neutralizing anti-drug antibodies (ADAs) to the infused enzymes, which are the focus of this review.

Humoral Response to ERT

ERT is based on the intravenous infusion of a (mostly) foreign recombinant protein [2, 3, 32]. Consequently, an infused enzyme might be recognized as foreign, and triggers an appropriate immune response, leading to the formation of specific antibodies against the enzyme [32]. Several studies in patients with different LSDs have shown that patients without any endogenous enzyme /protein, which is termed "cross-reactive immunologic material" (CRIM) negative, are at high risk of developing an immune response after ERT initiation [4, 5, 33, 34]. Due to the different effects, it is most important to distinguish between two different responses caused by continuous exposure to ERT.

Infusion-Associated Reactions

Infusion-associated reactions (IARs) most frequently occur in ERT-naïve FD patients directly after ERT initiation, and affected patients are mainly CRIM-negative males having zero endogenous AGAL activity [2, 3, 35, 36]. Symptoms are generally limited to fever and/or chills and require premedication with anti-histamines and steroids and a decreased infusion rate [36]. In addition to milder symptoms such as urticarial skin lesions, facial flushing or swelling, headache, and pain in the limbs, more severe IARs have been reported with chest and throat tightness, dyspnea, hypotension, and life-threatening anaphylactic reactions [37-40]. According to the manufacturer’s instructions, 24% of patients treated with agalsidase-alfa and 67% of patients treated with agalsidase-beta can suffer from these adverse effects. According to the literature, IARs are mainly the result of anaphylactoid (IgE-independent) rather than anaphylactic (IgE-mediated type 1 hypersensitivity) reactions, since only few affected patients were positive for IgEs against recombinant AGAL [21, 39, 41–44]. The risk for IARs seems to be increased in patients with anti-agalsidase IgG antibodies [5, 36]. The IgE-independent mechanisms resulting in hypersensitivity against the infused enzyme are not yet fully understood, but changes in osmotic pressure during infusion might lead to mast cell destabilization and histamine release. In addition, an abnormal activation of the complement system can result in a type II hypersensitivity. However, a recent study identified only 25% of patients with IARs with reduced C4 levels, suggesting that the primary cause for IARs is not complement-mediated cytotoxic hypersensitivity reactions [39]. In this study the authors further demonstrated that circulating dendritic cells were drastically reduced during IARs, suggesting their possible sequestration to the sites of inflammation [39]. An increase in natural killer cells and a decrease in T cells was also observed [39]. In addition, cytokines IL-4, IL-8, and TNF-α showed a significant increase, indicating nonspecific degranulation of mast cells, indicating a crosstalk between immune cells resulting in IgE-independent mast-cell-specific allergic inflammation [39].

In addition to the general recommendations for preventing IARs [36], more specialized protocols for managing severe reactions were established in the last decade. In patients with IgEs against agalsidase-beta, a graded dosing and individual infusion-rate regimen for a duration of 27 infusions resulted in successful reinstitution of agalsidase-beta in five of six patients [42]. A recent study demonstrated the tolerization of agalsidase-beta in eight patients (only one positive for IgEs and six patients with IgGs against AGAL) using a combination of premedications that included corticosteroids, mast cell stabilizers, H1 and H2 blockers, and intravenous (IV) fluids [39]. Aydin and colleagues used an adapted three-bag protocol [45], which was based on a consecutive 1:10 dilution of 14 mg agalsidase-alfa solved in 250 mL normal saline solution (solution 3: 14 mg agalsidase-alfa solved in 250 mL of saline solution; solution 2: 225 mL saline solution + 25 mL solution 3; solution 1: 225 mL saline solution + 25 mL solution 2) to successfully reinstitute agalsidase-alfa infusion in two brothers negative for IgEs [38]. This protocol starts with 1/40,000 of the therapeutic dose and increases dose over 12 steps, resulting in an infusion time of approximately 504 min [38]. However, a recent case study demonstrated that a three-bag protocol alone or in combination with pretreatment including glucocorticoids, H1/H2 antagonists, leukotriene receptor antagonists, and even B-cell depletion via rituximab was not able to reinstitute agalsidase-beta in a patient with IgEs against AGAL, but required a specific anti-IgE inhibition by omalizumab [40].

Clinical Impact of Neutralizing Anti-Drug Antibodies (ADAs)

Anti-drug AGAL IgG antibodies develop within 3–6 months after ERT initiation mainly in male CRIM-negative patients [4, 36, 41], which is the expected timeframe for an appropriate immune response with IgGs. In a recent prospective study, a significant increased risk for the formation of neutralizing ADA in male patients with FD was demonstrated if patients were treated with agalsidase-beta (1.0 mg/kg every other week) compared to agalsidase-alfa (0.2 mg/kg every other week) [46], underlining the importance of dosage for ADA formation. In detail, Arends and colleagues stated that risk calculations for ADAs were performed in classical males only and that antibody measurements were available for 92 classical patients, of whom 11 were excluded due to mixed antibody responses [46]. Of the remaining 81 classical patients, 11 of 39 agalsidase-alfa-treated patients (28%) and 22 of 42 agalsidase-beta-treated patients (52%) were positive for ADAs, resulting in an increased risk of 2.8 (95% confidence interval (CI) 1.02–7.88; p = 0.041) for agalsidase-beta [46]. However, although the authors only included classical male patients in their risk assessments, there is a lack of information on the type of mutations (nonsense, missense, etc.) and CRIM status in these cohorts, which represents a limitation of this study [46].

Furthermore, by using multivariate regression models, van der Veen and colleagues found that nonsense and frameshift mutations in the GLA gene, higher plasma lyso-Gb3 at baseline and agalsidase-beta as first treatment were significantly associated with ADA development [47]. However, the authors failed to reproduce the risk associated with the type of enzyme when they tried to validate the risk score in a second cohort and only the type of mutation remained significant [47]. To analyze if one of the two compounds is associated with a higher risk for ADA formation, more appropriate studies with comparable and larger patient cohorts in addition to a clearly defined mutation status (nonsense, missense, etc.) and CRIM status are warranted. In this respect, this highlights the general limitations of current studies in FD, analyzing an impact of different ERT dosages by comparing heterogeneous populations with different severities of GLA mutations, age at treatment initiation, comorbidities, etc.

Early studies demonstrated an inhibitory function of IgGs against infused AGAL, as well as a high cross-reactivity between agalsidase-alfa and agalsidase-beta [4]. The formation of inhibitory ADAs is generally assumed to be irreversible [48], although appropriate long-term studies are still required. The clinical impact of ADAs has been controversially discussed over the past years. High ADA titers (measured by ELISA) were associated with increased Gb3 accumulations in endothelial cells [49], but had an unclear effect on Gb3 levels in plasma [21, 50, 51]. However, on the basis of previously established serum-mediated inhibition assays [4], Rombach and colleagues demonstrated that patients with inhibitory antibodies suffered from higher (lyso)-Gb3 levels in plasma [48]. During follow-up, elevated lyso-Gb3 levels and increased disease burden (measured by patients' disease scores) were confirmed in patients with neutralizing ADAs [5]. Importantly, it was demonstrated that affected patients suffered from a more prominent loss of renal function and increasing septum thickness over time compared to those without ADAs [5]. The clinical outcome under therapy is influenced on the one hand by neutralizing ADAs and certainly by the severity of the disease burden before therapy initiation. To better differentiate the impact, the study populations being compared should have a comparable disease burden before therapy initiation and comparable types of mutations. However, recent case studies confirmed the deleterious effects of ADAs by showing massive Gb3 accumulation in various tissues in an affected male patient even after 6 years of ERT [52] and increasing lyso-Gb3 levels and lack of improvement in symptoms such as abdominal pain and acroparesthesias in two men after 3 years of ERT with high antibody titers [53].

One reason that may explain the different results of the various studies is the combined clinical relevance resulting from the level of ADA titers and the infused dose of the enzyme. A subgroup analysis of patients with neutralizing ADAs revealed a better biochemical response to aga lsidase-beta at 1.0 mg/kg in terms of decreasing lyso-Gb3 levels over time compared to agalsidase-alfa at 0.2 mg/kg [46], suggesting a link between antibody titer and dosages. These data were supported by a recent multicenter study showing a steeper decrease of lyso-Gb3 levels in plasma when patients were switched (back) from agalsidase-alfa (0.2 mg/kg) to agalsidase-beta (1.0 mg/kg) [54]. By measuring the amount of free (unbound) ADAs, it was demonstrated that titers can be saturated during infusions [55] and that a saturation was associated with better clinical outcomes [6]. A schematic model of the interaction between free antibodies and infused enzyme and the concept of ADA saturation is presented in Fig. 1.

Fig. 1

Schematic model of anti-drug antibody (ADA) saturation with an interaction between free antibodies and infused enzyme. A Patients with saturated antibodies: Due to a low ADA titer or sufficient dosage of infused enzyme (α-galactosidase A excess), only a proportion of infused enzyme will be recognized and neutralized by free ADAs. B Patients with non-saturated antibodies: due to high ADA titers or insufficient dosage of infused enzyme (ADA excess), the majority of infused enzyme will be recognized and neutralized by free ADAs. AGAL α-galactosidase A, e.o.w. every other week

Early studies showed that IgGs against AGAL from FD patients have an inhibitory function [4], whereas some subsequent studies distinguished between inhibitory and non-inhibitory ADAs. Since individually formed ADAs are polyclonal, it seems unlikely that a patient’s ADAs recognize only non-important epitopes. Rather, it suggests that patients with positive IgGs without measurable inhibition are likely to have a generally low ADA titer.

Patients at Risk

In general, there are several patient- and product-specific factors that need to be considered in the assessment of the immunogenic risk for patients treated with a recombinant enzyme. Patient-specific factors include the route of therapeutic administration, with the highest risk associated with inhalation. The risk decreases in the following order: subcutaneous, intraperitoneal, intramuscular, and intravenous administration [33, 56]. In FD, the two currently approved products agalsidase-alfa and agalsidase-beta are intravenously infused, and are associated with the lowest risk of triggering an immune response [2, 3]. An additional factor is the dosage, since higher dosages more likely increase the risk [33, 56]. The frequency and duration, repeated dosages, and prolonged exposure may either break or lead to tolerance [33, 56]. Both compounds have relative short plasma half-lives and proteins are hardly detectable in plasma before the next infusion. One of the most important factors is the CRIM status, defined by the presence or absence of endogenous AGAL. CRIM-negative patients without endogenous enzyme have the highest risk of producing antibodies under therapy [33, 56]. Since FD is an X-chromosomal-linked disease, only hemizygous males or homozygous females (very rare) can be CRIM negative. Thus, classical male FD patients with nonsense or null mutations, which result in the absence of any detectable AGAL (functional or non-functional) are at a high risk for the formation of ADAs [4, 5, 46]. The absence of AGAL activity does not necessarily predict the absence of AGAL protein, since even missense mutations can result in a complete loss of function. Thus, quantitative methods are needed and are generally based on western blotting as suggested for Pompe disease [57], but require a polyclonal anti-AGAL reference antibody, recognizing a broad spectrum of epitopes in order to detect even small AGAL protein fragments (due to truncations). Product-specific factors can include host cell protein contaminants or non-human post-translational and artificial chemical modifications of the protein [33, 56]. In this respect, one of the first studies dealing with ADAs in FD suggested that there seems to be a comparable risk for ADAs if patients are treated with similar dosages of agalsidase-alfa or agalsidase-beta (both 0.2 mg/kg) [4]. This might also lead to the assumption that product-specific factors can likely be excluded. Although only five patients were included in each group, the severity of mutations was comparable [4]. Thus, it can be assumed that no differences in antibody production can be observed if males with comparable severity of mutations are analyzed.

Biochemical Impact of Neutralizing ADAs

Several studies have demonstrated that inhibitory ADAs formed against infused AGAL belong to the subclasses IgG1and IgG4[55, 58, 59]. Depending on the recognized epitopes, ADAs seem to have an impact on several different mechanisms (Fig. 2). In general, uptake of infused AGAL (agalsidase-alfa or agalsidase-beta) is cation-independent mannose-6-phosphate (M6P) receptor-mediated, resulting in increased lysosomal AGAL activity and subsequent Gb3 depletion (Fig. 2a). In addition, infused AGAL can deplete Gb3 and lyso-Gb3 directly within the plasma. In the presence of neutralizing ADAs, infused AGAL is recognized by ADAs, resulting in different effects. ADAs may recognize epitopes localized at uptake-relevant domains including amino acid positions N139, N192, and N215. Binding of ADAs may result in a masking of these positions, which are subsequently not accessible to the M6P receptor, resulting in a decreased enzymatic uptake followed by a reduced Gb3 depletion [7] (Fig. 2b). ADAs may also bind to a processing site and prevent maturation (Fig. 2c), an effect that has not been analyzed in FD so far (to the best of our knowledge). To date the most characterized is the enzymatic activity neutralizing function of ADAs during infusion [4–6, 48, 55], probably mediated by the recognition of epitopes within catalytic domains. First, activity-neutralized AGAL will not be able to reduce Gb3 and lyso-Gb3 in plasma. Second, even if these inactive ADA/AGAL complexes are internalized and translocated to the lysosomes, complexes seem to be unable to dissociate [7] (Fig. 2d). ADAs that do not have a direct effect of AGAL activity or uptake, can be termed “non-neutralizing” (Fig. 2e). However, these non-neutralizing ADAs may also affect pharmacokinetics, trafficking, and conformation, which is also currently yet insufficiently analyzed in FD. Finally, Fcγ-receptor-expressing cells, such as macrophages, recognize drug/ADA complexes via the Fc- fragment and lead to an increased drug clearance [4] (Fig. 2f). Although not directly demonstrated in FD, ADAs might also form large ADA-protein immune complexes, which are either insoluble or can mediate complement activation (planted antigens) and result in membranous nephritis as reported for Pompe disease [60-62] (Fig. 2g). Since ADAs in affected patients with FD are polyclonal and thus recognize different epitopes [7, 63], it can be assumed that in most individuals a combination of the mechanisms leads to decreased therapeutic efficacy.

Fig. 2

Potential impact of anti-drug antibodies (ADAs) on infused α-galactosidase A (AGAL). a In the absence of ADAs, infused AGAL is internalized via the M6P-receptor, resulting in increased lysosomal AGAL activity and increased Gb3 clearance. b Binding of ADAs to the uptake domain (i.e., masking of M6P residues) can prevent AGAL from uptake via the M6P-receptor. c Binding of ADAs to processing domains may result in regular M6P-receptor-mediated uptake, but might lead to inefficiently processed AGAL and reduced intralysosomal enzymatic activity and reduced Gb3 clearance. d Binding of ADAs to catalytic domains can result in unimpaired enzyme uptake, but reduced lysosomal enzymatic activity and impaired Gb3 depletion, due to a missing dissociation. e ADA-binding to non-relevant domains might have no further impact on AGAL uptake and thus lysosomal activity. f Independent of recognized epitopes, ADA/AGAL complexes can be recognized by macrophages via the Fcγ receptor and thus eliminated during infusions. g Multivalent ADAs might cross-link AGAL molecules, resulting in large ADA/AGAL complexes with unknown effects in Fabry disease

Methods for Determination of ADAs

The controversial results of ADAs on treatment efficacy may be explained by the fact that no standardized assays and protocols have yet been developed to determine IgG levels in affected FD patients. Most studies analyzing IgG response are performed either by ERT manufacturers or different independent research laboratories using their own protocols and different methods [64]. Thus, titers from different studies are hardly comparable. Another pitfall in many studies is the lack of a corresponding methods section describing the protocols used. Some studies do not even state whether antibodies were measured by ELISA or not. In the following, we provide a brief overview of the most commonly used methods at present.

As early as 2001, ELISA-based measurements demonstrated the early formation of ADA s against infused agalsidase-beta within the first 6 months after therapy initiation [3]. Due to the lack of serial dilutions, ADA titers could be detected but not quantified in patients [3]. Using serial dilutions of sera from FD patients, Linthorst and colleagues provided relative ADA titers and demonstrated cross-reactivity of ADAs with respect to agalsidase-alfa and agalsidase-beta [4]. In general, relative titers can be expressed by using sera from healthy controls, from patients who ultimately did not develop ADAs, or from patients who are ERT-naïve [2, 4, 49, 65]. Some other studies used animal-derived anti-AGAL antibodies as positive controls [59]. However, due to the different species, different secondary antibodies are required for final detection, which do not allow for proper quantification. In addition, animal-derived polyclonal antibodies may differ in their individual binding affinity and epitope recognition compared to human antibodies, and are not recommended as proper controls for the quantification of human ADAs. Thus, the use of a human reference antibody with a known concentration and comparable biochemical characteristics for the quantification of ADA titers from human samples is strongly advised (Fig. 3A). To overcome the limitations, van der Veen and colleagues pooled sera from FD patients with ADAs to generate a positive control, allowing ADA measurements with the same secondary detection antibodies [58]. However, due to the unknown antibody concentration within the positive control, even this approach did not allow a quantification of measured ADA titers. Recently, Lenders and colleagues generated a polyclonal reference antibody by pooling purified and characterized anti-AGAL antibodies from 22 patients, allowing an ELISA-based measurement and ADA titer quantification expressed as ng/mL serum [66]. The use of ELISA-based assays also allows determination of and distinguishing between appropriate IgG isotypes.

Fig. 3

Methods for the detection and characterization of α-galactosidase A (AGAL)-specific anti-drug antibodies (ADAs). A ELISA-based quantification of ADAs: AGAL-specific IgGs of serial dilutions from blood samples bind to immobilized AGAL and are detected with enzyme-labeled secondary antibodies. A serial dilution of a proper reference antibody allows a subsequent quantification. B Inhibition assay: AGAL hydrolyzes the artificial substrate 4-MU-α-Gal to fluorescent 4-MU if not blocked by inhibitory ADAs. A titration of individual free IgGs determines the amount of enzyme-replacement therapy (ERT) required to saturate ADAs during infusion. C Cellular uptake assays: Fluorescence-labeled AGAL is pre-incubated with the patient’s IgGs and added to appropriate cells. Subsequent assays can analyze whether ADA/AGA L complexes are formed (1), inhibit intracellular enzymatic activity (2) and/ or uptake (3). (i) Intracellular fluorescence signal from labeled AGAL can be quantified by appropriate techniques. Also, indirect AGAL or ADA detection can be performed using appropriate primary and secondary antibodies. (ii) Cells can be lysed to determine intracellular AGAL activity after uptake. (iii) Cell lysates can also be used for ELISA-based detection of AGAL uptake (free or as ADA/AGAL complexes). The use of appropriate primary detection antibodies directly allows the determination of AGAL/ADA complex-forming IgG subclasses

Linthorst and colleagues also reported an easily measurable neutralizing activity of ADAs in vitro [4]. This assay is based on the hydrolysis of the artificial AGAL substrate 4-methylumbelliferyl-α-D-galactopyranoside (4-MU-α-Gal) to 4-methyl-umbelliferone (4-MU) (Fig. 3B). In short, a fixed amount of AGAL will be pre-incubated with sera of interest and subsequently the residual enzymatic activity will be measured and compared to a negative and a positive control. Thus, an inhibition assay is a functional assay, detects activity-neutralizing ADAs, and can classify patients as “neutralization-negative” or “-positive” [4]. However, probably due to the proteolytic effects of the serum in combination with a basic to neutral pH, the standard serum-mediated inhibition assays have a relatively high background, resulting in decreased sensitivity [55]. To improve sensitivity, Lenders and colleagues separate whole IgG fractions from raw sera, allowing the authors to improve sensitivity and to estimate the required amount of infused AGAL to overcome and saturate existing free and unbound ADAs during infusion [6, 55] (Fig. 3B).

Cell-based antibody assays are mainly important to further analyze the functionality of ADAs (Fig. 3C). In their initial study, Linthorst and colleagues demonstrated the uptake of AGAL/ADA complexes by leukocytes, suggesting the IgG-mediated uptake of AGAL/ADA complexes via Fcγ receptors [4]. Later on, Mauhin and colleagues showed that ADAs from FD patients can be internalized by blood mononuclear cells and inhibit intracellular AGAL activity [59]. However, since FD is a small-vessel disease and the endothelium should internalize ERT rather than peripheral blood mononuclear cells (PBMCs), the use of endothelial cells for uptake analyses is recommended more than using PBMCs. The use of fluorescence-labeled AGAL enabled Stappers and colleagues to demonstrate a patient- and thus antibody/epitope-dependent inhibitory effect of ADAs on cellular uptake [7] (Fig. 3C(i)). Furthermore, by combining the fluorescence-based in vivo measures with subsequent cell lysis and AGAL activity measures (Fig. 3C(ii)) and ELISAs (Fig. 3C(iii)), the authors demonstrated that ADA/AGAL complexes are internalized, but lack enzymatic activity within cells due to lack of dissociation [7].

For completeness, a rapid immunochromatographic bedside test has also been developed, allowing fast detection of ADAs in sera [67]. However, since this assay requires an optical estimation of signal strength, its use for titer estimations is limited.

Other, more sophisticated methods for quantifying and characterizing ADAs may include epitope mappings and affinity measurements. Recently, Kukacka and colleagues used a proteolytic epitope excision with subsequent mass spectrometry to identify the single epitope and binding affinity of a monoclonal rabbit antibody against human AGAL [68]. Due to the complexity, such an approach would not be feasible for measuring comparable characteristics for human polyclonal antibodies. Instead, epitope mappings with fragmented AGAL successfully revealed individual epitopes for patients, suggesting polyclonal antibodies [63].

However, the exclusive use of single peptides covering the AGAL sequence is a limitation, since conformational epitopes cannot be detected with this approach. Antibody affinities as a further important characteristic can be measured for example by ELISA, surface plasmon resonance immunoassays, or quartz crystal microbalance with dissipation monitoring (QCM-D). Recently, Lenders and colleagues demonstrated no significant differences for QCM-D-based ADA affinity measures between agalsidase-alfa, agalsidase-beta, and mossAGAL [66]. However, these data were based on the reference antibody pooled from 22 patients and do not necessarily reflect individual patient-specific affinities. Since high ADA affinities seem to be associated with increasing inhibitory capacities [69], while decreasing affinities might indicate the onset of tolerization [70], appropriate analyses will be of interest in future studies to identify FD patients at risk.

Methods to Prevent or Reduce ADAs

Specific protocols to prevent or reduce pre-existing neutralizing ADAs in patients with FD have not been reported in detail so far. However, Lenders and colleagues demonstrated that an immunosuppressive therapy in transplanted male FD patients might prevent ADA formation in ERT-naïve patients and reduce ADA titers in patients already under ERT [71].

In addition to FD, the most frequent LSDs currently treatable with ERT are Gaucher disease, MPS I, MPS II, MPS IVa, MPS VI, and Pompe disease (Table 1). For all diseases, a humoral response has been reported [72]. However, risk for ADA formation differs between these diseases [72], which is due to the underlying heredity (autosomal recessive or X-chromosomal) as well as disease-causing mutations. FD is an X-chromosomal linked disease due to ~ 1.000 different variants within the GLA gene. On the other hand, Pompe disease is an autosomal recessive disease, with only a few known specific mutations within the GAA gene. Whereas only male patients and homozygous females with FD and nonsense mutations can be CRIM negative, nearly all affected Pompe disease patients are CRIM negative with an increased risk for ADA formation [72]. In addition, awareness among treating physicians of the impact of ADAs on treatment efficacy varies across diseases. In a disease with rapid disease progression that eventually leads to early death, such as infantile Pompe disease, the deleterious effects of neutralizing ADAs are much more apparent than in FD. In conclusion, research concerning ADA formation, impact, prevention, and suppression is advanced in Pompe and Gaucher disease, which is reflected by the various reported immune-modulating protocols [72, 73]. Since the main underlying mechanisms (for an immune response) are the same in all diseases treated with ERT, existing knowledge and appropriate treatment protocols can be transferred to other diseases treated with ERT.

Table 1

Overview of the most common ERT-treatable lysosomal storage diseases associated with an immune response and formation of ADAs

Disease	Deficient enzyme	Main accumulated substrate	Approved drug	IARs	Neutralizing ADAs	Agents used for immune tolerance
Gaucher disease	β-Glucosidase	Glucosylceramide	Imiglucerase, Velaglucerase, Taliglucerase-alfa	Yes	Yes	Cyclophosphamide, IVIG
Fabry disease	α-Galactosidase A	Globotriaosylceramide	Agalsidase-alfa, Agalsidase-beta	Yes	Yes	NA
MPS I	α-l-iduronidase	Dermatan sulfate and heparan sulfate	Laronidase	Yes	Yes	Cyclosporine, azathioprine
MPS II	Iduronate-2-sulfatase	Dermatan sulfate and heparan sulfate	Idursulfase-alfa, Idursulfase-beta	Yes	Yes	Rituximab, ofatumumab, bortezomib, methotrexate, IVIG,
MPS IVa	N-acetylgalactosamine-6 sulfatase (GALNS)	Keratan sulfate and chondroitin-6-sulfate	Elosulfase	Yes	Yes	Rituximab, methotrexate
MPS VI	N-acetylgalactosamine 4-sulfatase	Dermatan sulfate	Galsulfase	Yes	Yes	Corticosteroids, rituximab, IVIGs, methotrexate.
Pompe disease	Acid α-glucosidase	Glycogen	Alglucosidase-alfa	Yes	Yes	Rituximab, methotrexate, IVIG, methylprednisolone, rapamycin, cyclophosphamide, bortezomib

ADA anti-drug antibody, ERT enzyme-replacement therapy, IARS infusion-associated reaction, IVIG intravenous immunoglobulin, MPS mucopolysaccharidosis, NA not available

Several immune adsorption protocols based on non-specific IgG depletion showed high therapeutic efficiencies [74-76]. However, nonspecific adsorption systems remove complete Ig fractions and thus may further affect and weaken the humoral immune response [76]. In contrast, an antigen-specific immune adsorption results in depletion of pathogenic antibodies, while other antibodies and the humoral immune response remain unaffected [77-80]. In this respect, Lenders and colleagues demonstrated that AGAL-specific ADAs can be selectively re moved from the sera of FD patients in vitro [7, 66].

However, titers appear to recover very rapidly, which would require a high frequency of immunoadsorptions. Immunomodulation protocols appear to be clinically easier to implement. Most successful approaches included the inhibition of folic acid metabolism, DNA alkylation, and antibody-mediated B-cell depletion [81-91].

However, since memory B cells are not depleted by rituximab, the additional administration of bortezomib has been reported to effectively reduce ADA titers in infantile Pompe disease [83] and of omalizumab to reduce IgEs in FD [40]. Other options would be to use specific blocking peptides identified by epitope mapping or simply to increase the infused enzyme dosage to overcome existing ADA titers [6]. However, the maximum approved dosage of agalsidase-beta is currently restricted to 1 mg/kg body weight, making a dosage increase only implementable when switching from the regular approved agalsidase-alfa dosage (0.2 mg/kg) or lower agalsidase-beta dosage (< 1 mg/kg) to the regular approved agalsidase-beta dosage (1 mg/kg) [6]. Furthermore, this approach might not be suitable for every patient, since a dosage increase can result in increasing ADA titers [6, 40].

Knowledge Gaps and Outlook

Although major progress has been made in recent years in the characterization of neutralizing ADAs in FD, there are still important gaps in our knowledge that need to be addressed in future studies. Key tasks include developing strategies to prevent or reduce ADAs in affected patients. As reported above, appropriate already existing protocols for immunomodulation could be adapted for FD patients at risk. In addition, new approaches may also be conceivable for patients with FD.

For example, oral antigen administration resulted in significantly lower ADA titers in mice with Pompe disease or hemophilia A [92, 93]. To date, it has not been investigated whether oral administration of low-dose AGAL might support immune tolerance, resulting in lower ADA titers in an AGAL-deficient background. Of note, patients treated orally with human recombinant AGAL might benefit twice in that the risk for ADAs could be reduced, in addition to a reduction in gastrointestinal symptoms [94].

Finally, novel treatment strategies will also present new questions and obstacles. A prolonged half-life in plasma either by more stable compounds such as pegunigalsidase-alfa or by constant gene therapy-mediated expression will probably require modified assays to detect antibodies. The currently used assays aim to detect free antibodies in plasma and fail to detect ADA/AGAL complexes.

Samples from patients treated with next-generation ERTs or gene therapy might therefore require special sample preparation to dissociate existing ADA/AGAL complexes, or additional assays may need to be developed for the detection of these complexes.

Conclusion

CRIM-negative patients such as classical male FD patients with nonsense GLA mutations suffer from a high risk of a humoral response including ADAs against ERT.

The formation of ADAs is often associated with worse clinical outcome and disease progression. ADAs can already inhibit infused enzyme during infusions and reduce cellular enzyme uptake. Already existing protocols for immune tolerance induction to avoid or reduce ADAs can be transferred from other ERT-treated diseases to improve therapeutic efficacy in FD and other LSDs.

Classical male patients with Fabry disease (FD) have a high risk for a humoral response including anti-drug antibodies (ADAs) against enzyme-replacement therapy (ERT).

The formation of ADAs is associated with worse clinical outcomes.

ADAs already inhibit infused enzyme during infusions and impair cellular enzyme uptake.

ADAs can be saturated by increased dosages of infused enzymes or suppressed by appropriate immune-modulatory approaches