The controlling effect of carbohydrate in human, rabbit and bovine immunoglobulin G on proteolysis by papain

About two-thirds of the hexose of human and rabbit immunoglobulin G (IgG) was located in the Fc fragment and one-third in the `hinge' region of the γ (heavy) polypeptide chain at the junction of the Fab and Fc fragments. In contrast, bovine IgG contained more hexose in the `hinge' region than in the Fc fragment. The initial cleavage of susceptible IgG molecules into Fab and Fc fragments by papain under the conditions given by Porter (1959) had reached completion after digestion for 2hr., though bovine IgG was digested somewhat more slowly than human or rabbit IgG. The release of `hinge' peptides from human and rabbit IgG had also reached completion by 2hr., but was slower from bovine IgG and continued for several hours longer. Since bovine IgG molecules contained on the average a greater amount of hexose in the `hinge' region, carbohydrate on this part of the γ-chain may influence not only the initial rate of enzymic hydrolysis into Fab and Fc fragments, but also, and to a greater extent, the rate of further limited hydrolysis of the N-terminal regions of the Fc fragment. The presence of carbohydrate in the `hinge' region does not appear to account for the resistance of some IgG molecules to papain digestion and of some Fc fragments to N-terminal degradation.     

Elevated cleavage of human immunoglobulin gamma molecules containing a lambda light chain mediated by iron and histidine

Monoclonal antibodies in liquid formulation undergo nonenzymatic hydrolysis when stored at 5 °C for extended periods. This hydrolysis is enhanced at extreme pH and high temperature. In this study we discover that iron in the presence of histidine also enhanced cleavage of human immunoglobulin gamma (IgG) molecules containing a lambda light chain when incubated at 40 °C. The level of cleavage was concentration dependent on both iron and histidine levels. Enhanced cleavage with iron and histidine was not observed on IgG molecules containing a kappa light chain. Using CE-SDS to quantify levels of Fab + Fc, the Fab arm, and free light chain (LC) and heavy chain (HC) fragments, we show that cleavage resulted in elevated levels of free light and heavy chain fragments. Using MS we find elevated scission between residues E/C on the LC resulting in LC fragment 1-215. We also observed enhanced cleavage between S/C residues of the HC resulting in HC fragment 1-217. The corresponding Fab + Fc fragment beginning with cys-218 was not found. Instead, we find elevation of a Fab + Fc fragment that began with aspartic acid (cleavage between C/D). Further studies to understand how iron and histidine enhance cleavage of lambda light chain IgG molecules are ongoing.     

Glycosylation in the Fc domain of IgG increases resistance to proteolytic cleavage by papain

IgG antibodies (Abs) and fragments of IgG Abs are becoming major biotherapeutics to treat an assortment of human diseases. Commonly prepared fragments of IgGs include Fc, Fab, and F(ab')2 fragments, all of which can be made using the sulfhydryl protease papain, although prolonged digestion times and/or excessive amounts of papain typically result in further cleavage of the Fc domain into smaller fragments. During our attempts to use papain to isolate Fc fragments from different IgG monoclonal Abs, it was observed that prior removal of Fc glycans resulted in a faster rate of papain-mediated degradation of the Fc domain. Subsequent time-course experiments comparing glycosylated and deglycosylated versions of IgG antibodies showed that the majority of molecules in a deglycosylated IgG sample were converted into Fab, Fc, and smaller Fc fragments in less than one hour, whereas the original glycosylated IgG required more than two hours to convert into a comparable amount of Fab and Fc fragments. Furthermore, whereas papain digestion converted almost all of a deglycosylated Fc fragment into smaller fragments of approximately 10 and approximately 12 kDa within 4 h, more than 40% of a glycosylated Fc fragment remained intact even after 24 h of digestion. These results indicate that the presence of CH(2) domain glycans in either IgGs or purified Fc fragments increases resistance to papain digestion. Increased sensitivity of non-glycosylated Fc domains to papain is consistent with the Fc domains lacking a defined structure, as exemplified by their inability to bind Fcgamma receptors, since misfolded proteins are often degraded by proteases because of increased accessibility of their proteolytic cleavage sites. Based on these observations it is possible to use papain sensitivity as a means of assessing proper Fc structure of IgG molecules.     

Antibody–receptor interactions mediate antibody-dependent cellular cytotoxicity

Binding of antibodies to their receptors is a core component of the innate immune system. Understanding the precise interactions between antibodies and their Fc receptors has led to the engineering of novel mAb biotherapeutics with tailored biological activities. One of the most significant findings is that afucosylated monoclonal antibodies demonstrate increased affinity toward the receptor FcγRIIIa, with a commensurate increase in antibody-dependent cellular cytotoxicity. Crystal structure analysis has led to the hypothesis that afucosylation in the Fc region results in reduced steric hindrance between antibody–receptor intermolecular glycan interactions, enhancing receptor affinity; however, solution-phase data have yet to corroborate this hypothesis. In addition, recent work has shown that the fragment antigen-binding (Fab) region may directly interact with Fc receptors; however, the biological consequences of these interactions remain unclear. By probing differences in solvent accessibility between native and afucosylated immunoglobulin G1 (IgG1) using hydroxyl radical footprinting–MS, we provide the first solution-phase evidence that an IgG1 bearing an afucosylated Fc region appears to require fewer conformational changes for FcγRIIIa binding. In addition, we performed extensive molecular dynamics (MD) simulations to understand the molecular mechanism behind the effects of afucosylation. The combination of these techniques provides molecular insight into the steric hindrance from the core Fc fucose in IgG1 and corroborates previously proposed Fab–receptor interactions. Furthermore, MD-guided rational mutagenesis enabled us to demonstrate that Fab–receptor interactions directly contribute to the modulation of antibody-dependent cellular cytotoxicity activity. This work demonstrates that in addition to Fc–polypeptide and glycan-mediated interactions, the Fab provides a third component that influences IgG–Fc receptor biology.     

Intracellular distribution and degradation of immunoglobulin G and immunoglobulin G fragments injected into HeLa cells

Intact rabbit immunoglobulin G molecules (IgGs) and their papain or pepsin fragments were radio-iodinated and injected into HeLa cells. Whole IgGs, Fab2, and Fc fragments were degraded with half-lives of 60- 90 h, whereas half-lives of Fab fragments were 110 h. These results indicate that proteolytic cleavage in the hinge region of the IgG molecule is not the rate-limiting step in its intracellular degradation. The hingeless human myeloma protein, Mcg, was degraded at the same rate as bulk human IgG, providing further evidence that the proteolytically susceptible hinge region is not important for intracellular degradation of IgG molecules. SDS acrylamide gel analysis of injected rabbit IgG molecules revealed that heavy and light chains were degraded at the same rate. Injected rabbit IgGs and rabbit IgG fragments were also examined on isoelectric focusing gels. Fab, Fab2, and Fc fragments were degraded without any correlation with respect to isoelectric point. Positively charged rabbit IgGs disappeared more rapidly than their negative counterparts, contrary to the trend reported for normal intracellular proteins. The isoelectric points of two mouse monoclonal antibodies were essentially unchanged after injection into HeLa cells, suggesting that the altered isoelectric profile observed for intact rabbit IgG resulted from degradation and not protein modification. The intracellular distributions of IgG fragments and intact rabbit IgG molecules were determined by autoradiography of thin sections through injected cells. Intact IgG molecules were excluded from HeLa nuclei whereas both Fab and Fc fragments readily entered them. Thus, for some proteins, entry into the nuclear compartment is determined primarily by size.     

The influence of antibody fragment format on phage display based affinity maturation of IgG

Today, most approved therapeutic antibodies are provided as immunoglobulin G (IgG), whereas small recombinant antibody formats are required for in vitro antibody generation and engineering during drug development. Particularly, single chain (sc) antibody fragments like scFv or scFab are well suited for phage display and bacterial expression, but some have been found to lose affinity during conversion into IgG.   In this study, we compared the influence of the antibody format on affinity maturation of the CD30-specific scFv antibody fragment SH313-F9, with the overall objective being improvement of the IgG. The variable genes of SH313-F9 were randomly mutated and then cloned into libraries encoding different recombinant antibody formats, including scFv, Fab, scFabΔC, and FabΔC. All tested antibody formats except Fab allowed functional phage display of the parental antibody SH313-F9, and the corresponding mutated antibody gene libraries allowed isolation of candidates with enhanced CD30 binding. Moreover, scFv and scFabΔC antibody variants retained improved antigen binding after subcloning into the single gene encoded IgG-like formats scFv-Fc or scIgG, but lost affinity after conversion into IgGs. Only affinity maturation using the Fab-like FabΔC format, which does not contain the carboxy terminal cysteines, allowed successful selection of molecules with improved binding that was retained after conversion to IgG. Thus, affinity maturation of IgGs is dependent on the antibody format employed for selection and screening. In this study, only FabΔC resulted in the efficient selection of IgG candidates with higher affinity by combination of Fab-like conformation and improved phage display compared with Fab.     

Proteolytic machinery of glomerular epithelial cells against IgG.

Accumulation of immune complexes in the subepithelial region of the glomerular basement membrane results in the lesion of membranous nephropathy. The inefficient handling of immune complexes by the glomerular epithelial cell was investigated by studying the mechanism of IgG proteolysis by the intracellular proteases of cultured epithelial cells. Radiolabelled IgG was incubated with extracts of cells and the digestion of IgG was monitored by SDS-PAGE analysis. Prolonged incubation of IgG with the cell extracts resulted in only partial degradation of the IgG. The enzyme responsible for the breakdown was determined to be the lysosomal cathepsin D based on the pH optimum and the presence of aspartate in the active site of the enzyme. SDS-PAGE analysis of the digestion fragments revealed that a large proportion of the incompletely degraded IgG was the (Fab)2 fragment, which was resistant to further proteolysis. This could be one of the possible explanations for the slow removal of IgG from the subepithelial location of the basement membrane.     

Characterization of two species of Fc fragments obtained from rat IgG2a by prolonged papain digestion.

Prolonged papain digestion of rat IgG2a produced two molecular species of Fc fragments, termed Fc(I) and Fc(II). Studies by gel filtration chromatography and polyacrylamide gel electrophoresis in SDS/urea indicated that the two subunit polypeptide chains in each Fc preparation were associated by non-covalent bonds only. By analytical ultracentrifugation Fc(I) was found to have a m.w. of 47,100 and a sedimentation coefficient of 4.08S. Fc(II) had a m.w. of 39,800 and a sedimentation coefficient of 3.83S. The m.w. for the subunit chains of Fc(I) and Fc(II) were 25,300 and 20,300, respectively, as determined by analytical ultracentrifugation under dissociating conditions. Calculation of the frictional coefficient ratios indicated that both Fc fragments possessed compact globular structures. The difference in size between these two Fc fragments probably was due to a loss of some carboxy-terminal residues in Fc(II). Both Fc fragments possessed nearly identical amino-terminal amino acid sequences. Papain cleavage occurred primarily between residues 233/234 and 234/235. The carbohydrate compositions of the two species of Fc fragments were similar. It was concluded that under acid and reducing conditions papain cleavage of rat IgG2a occurred to the carboxy-terminal side of the hinge region. Prolonged papain digestion led to secondary attack in the carboxy-terminal end of the CGAMMA3 domain at an unidentified site, or sites, producing a stable second species of Fc fragments.     

Effect of chloroquine and methylamine on endocytosis of fluorescein-labelled controlled IgG and of anti-(plasma membrane) IgG by cultured fibroblasts

We report here the effect of chloroquine and methylamine two lysosomotropic drugs, on the binding, uptake and subcellular localization of fluorescein-labelled control immunoglobulin G (control IgG) a marker for non-specific adsorptive endocytosis and of anti-(plasma membrane) IgG (specific IgG), a specific ligand of cell-surface antigens. At 4 degrees C, methylamine and chloroquine inhibit the binding of control IgG to the cell surface, probably by a reversible competition. These two drugs, methylamine more than chloroquine, considerably slow down the rate at which control IgG is transferred from its binding sites on the phagosomal membrane to the lysosomal compartment; both drugs block almost completely the intralysosomal digestion of this IgG as well as the release of degradation products into the culture medium. They do not affect the binding and uptake of the specific IgG. In addition, methylamine seems to inhibit partially the return of the cell surface of membrane antigens and of membrane fragments bearing 5'-nucleotidase or binding sites for control IgG. We conclude that important steps (binding to cell surface, delivery to lysosomes, digestion and recycling of plasma membrane) involved in the uptake and the processing of IgG by fibroblasts are inhibited by these two substances. The effects of lysosomotropic agents on the regulation and function of the endocytic pathway and of lysosomes could have many pharmacological and therapeutic implications.     

Non-covalent interactions between Fab and Fc regions in immunoglobulin G molecules. Hydrogen-deuterium exchange studies

To reveal non-covalent interactions between the Fab and Fc regions of IgG molecules the average conformational free-energy change (delta Go), associated with reversible micro-unfoldings, was measured by hydrogen-deuterium exchange for the Fab and Fc fragments and the complete molecule. Human monoclonal IgG1 and pooled IgG samples were used in these experiments. Hydrogen-deuterium exchange data were summarized and compared in the form of exchange relaxation spectra. The experimentally observed relaxation spectrum of intact IgG could not be deduced by weighted summation of spectra measured for Fab and Fc fragments. A comparison of the measured and calculated data revealed a 5-kJ/mol increase in the conformational free energy upon splitting the IgG molecule into two Fab and Fc pieces, i.e. an increase of conformational mobility occurred. This change can be explained either by related fluctuation patterns of the Fab and Fc pieces in the intact molecule or by a shielding effect on the contact surfaces. Both interpretations suppose non-covalent interactions between Fab and Fc that can be a means of information transduction between recognition and effector sites. The pH dependence of the hydrogen-deuterium exchange also indicates interactions between the Fab and Fc regions. A shift in the relaxation spectra of the Fab fragment was observed between pH 8.2 and 7.3 revealing destabilization of the structure at lower pH. This effect is absent in the intact molecule, reflecting interactions that stabilize the Fab structure. Comparison of the relaxation spectra of Fab and Fc shows a difference of about 10 kJ/mol in the microstability of these fragments: the Fab part possesses more conformational flexibility (i.e. its microstability is smaller) than the Fc part.     

Comparative conformational studies on the tryptic digestion fragments of human immunoglobulins M and G

IgM¹ immunoglobulins were cleaved into Fabμ and (Fc)5μ fragments by tryptic digestion. Comparative circular dichroism studies with the corresponding IgG fragments show that the Fab portions of IgG and IgM proteins have very similar CD spectral features, although the same is not true for their Fc fragments. These studies indicate the presence of higher amount of beta-structured regions in Fcμ than in Fcγ. Also, there are considerable differences in their pH-dependent structural transitions as measured by CD spectral changes. The conformational differences between IgG and IgM immunoglobulins are more pronounced in their Fc portions, which carry out class specific biological functions, rather than in Fab portions, which contain antigen combining sites.     

The Herpes Virus Fc Receptor gE-gI Mediates Antibody Bipolar Bridging to Clear Viral Antigens from the Cell Surface

The Herpes Simplex Virus 1 (HSV-1) glycoprotein gE-gI is a transmembrane Fc receptor found on the surface of infected cells and virions that binds human immunoglobulin G (hIgG). gE-gI can also participate in antibody bipolar bridging (ABB), a process by which the antigen-binding fragments (Fabs) of the IgG bind a viral antigen while the Fc binds to gE-gI. IgG Fc binds gE-gI at basic, but not acidic, pH, suggesting that IgG bound at extracellular pH by cell surface gE-gI would dissociate and be degraded in acidic endosomes/lysosomes if endocytosed. The fate of viral antigens associated with gE-gI–bound IgG had been unknown: they could remain at the cell surface or be endocytosed with IgG. Here, we developed an in vitro model system for ABB and investigated the trafficking of ABB complexes using 4-D confocal fluorescence imaging of ABB complexes with transferrin or epidermal growth factor, well-characterized intracellular trafficking markers. Our data showed that cells expressing gE-gI and the viral antigen HSV-1 gD endocytosed anti-gD IgG and gD in a gE-gI–dependent process, resulting in lysosomal localization. These results suggest that gE-gI can mediate clearance of infected cell surfaces of anti-viral host IgG and viral antigens to evade IgG-mediated responses, representing a general mechanism for viral Fc receptors in immune evasion and viral pathogenesis.     

IgG4 can induce an M2-like phenotype in human monocyte-derived macrophages through FcγRI

Antibodies evoke cellular responses through the binding of their Fc region to Fc receptors, most of which contain immunoreceptor tyrosine-based activation motif domains and are thus considered “activating.” However, there is a growing appreciation of these receptors for their ability to deliver an inhibitory signal as well. We previously described one such phenomenon whereby interferon (IFN)γ signaling is inhibited by immune complex signaling through FcγRI. To understand the implications of this in the context of therapeutic antibodies, we assessed individual IgG subclasses to determine their ability to deliver this anti-inflammatory signal in monocyte-derived macrophages. Like IgG1, we found that IgG4 is fully capable of inhibiting IFNγ-mediated events. In addition, F(ab’)2 fragments that interfere with FcγRI signaling reversed this effect. For mAbs developed with either an IgG1 or an IgG4 constant region for indications where inflammation is undesirable, further examination of a potential Fc-dependent contribution to their mechanism of action is warranted.     

Purification of antibody Fab and F(ab')2 fragments using Gradiflow technology

The Gradiflow, a preparative electrophoresis instrument designed to separate molecules on the basis of their size and charge, was used to purify antibody Fab and F(ab')2 fragments. The method described is charge based, utilizing the difference in the pI between the antibody Fab/F(ab')2 fragments and antibody Fc fragments that occur after enzyme digestion of whole antibody molecules. This method of purification was successful across a range of monoclonal and polyclonal antibodies. In particular, F(ab')2 fragments were purified from a number of mouse monoclonal antibodies (both IgG1 and IgG2a isotypes) and Fab fragments were purified from egg yolk IgY polyclonal antibodies. This is a rapid purification method which has advantages over alternative methods that usually comprise ion exchange and gel filtration chromatography. This method may be applicable to most antibody digest preparations.     

Fate of plasma membrane during endocytosis. II. Evidence for recycling (shuttle) of plasma membrane constituents

Cultured rat embryo fibroblasts were first allowed to store for 24 h fluorescein-labeled goat immunoglobulins directed against rabbit immunoglobulins (F anti-R IgG), and were subsequently exposed for 24 h to [(3)H]acetylated rabbit immunoglobulins known to bind to the cell membrane either specifically (anti-plasma membrane IgG: A anti-PM IgG) or unspecifically (contol IgG: AC IgG). As a result of immunological interaction between the two antibodies (no effect was found if the cells had been preloaded with control goat FC IgG), a substantial portion of the stored F anti-R IgG was unloaded from its intracellular storage site, appearing in the medium in the form of soluble immune complexes with rabbit A IgG. Part of the unloaded F anti-R IgG also was recovered in association with the plasma membrane, but only when A anti-PM IgG was used. In addition, significant reverse translocation of AC IgG from plasma membrane to lysosomes or some related intracellular storage compartment was also observed. With A anti-PM IgG, this translocation was less marked and affecte at the same time the plasma membrane marker 5’- nucleotidase. Cells that had stored horseradish peroxidase (HRP) simultaneously with F anti-R IgG did not unload HRP when exposed to A anti-PM IgG. These results support strongly, though not unequivocally, the concept that plasma membrane patches interiorized by endocytosis are recycled, or shuttled, back to the cell surface. In the framework of this concept, recycling antibody-coated membrane is taken to serve as vehicle for the selective intracellular capture and extracellular discharge of immunologically bound F anti-R IgG. The alternative explanation of regurgitation triggered off by immune complexes is considered less likely in view of the lack of HRP unloading.     

Catabolism and biologic properties of two species of rat IgG2a Fc fragments.

Prolonged papain digestion of rat IgG2a has recently been shown to yield two species of Fc fragments, termed Fc(I) AND Fc(II). The results of structural studies indicated that Fc(II) fragment was 15 to 20% smaller than Fc(I), probably secondary to loss of a carboxy-terminal peptide. The effects of these structural laterations on the catabolism and biologic properties of the Fc fragments were determined. The results of catabolic experiments indicated that after injection into normal rats Fc(I) fragments were retained in the circulation and slowly catabolized whereas Fc(II) fragments rapidly underwent filtration in the kidneys. In nephrectomized rats, however, both Fc(I) and Fc(II) fragments possessed identical slow rates of catabolism, as determined by serum disappearance and whole body catabolic experiments. Fragment pFc, corresponding to Cgamma3 domain, was different from either of the Fc fragments in exhibiting rapid rates of catabolism in both normal and nephrectomized rats. Fc(I) was more active in complement fixation and in adherence to the Fc receptor on monocytes in comparison with Fc(II). These results support the conclusion that catabolism of Fc and maintenance in circulation are separate processes influenced by different structures in the Fc fragment. The catabolism of Fc is controlled by structures in the Cgamma2 domain. This process probably is not related either to complement fixation or to adherence to the Fc receptor on monocytes. Some correlations between the structure and biologic properties of these Fc fragments are discussed.     

Passive enhancement of mouse skin allografts by alloantibodies is Fc dependent.

The capacity of F(ab')2 fragments of alloantibodies to enhance mouse allografts was studied in B6AF1 recipients of B10.D2 skin grafts. F(ab')2 obtained by digestion of B6AF1 anti-B10.D2 antibodies was purified by means of affinity chromatography, with anti-subclass antisera and protein A. The degree of contaminating IgG was less than 0.02%. Administration of F(ab')2 with an antigen-binding capacity similar to the IgG from which it originated, inhibited acute antibody-mediated graft rejection but was unable to induce enhancement. Even a dose that was 130 times the molar amount of the minimal enhancing dose of undigested IgG2 was ineffective. We conclude, therefore, that passive enhancement of mouse skin allografts by alloantibodies requires the Fc part.     

Monoclonal antibody to human IgG Fc receptors. Cross-linking of receptors induces lysosomal enzyme release and superoxide generation by neutrophils

The monoclonal antibody KuFc79 binds to a determinant on the Fc receptors (Fc gamma R) of human leukocytes. We examined the biologic effects of the interaction of this antibody with Fc gamma R on human neutrophils (PMNL). The univalent Fab fragment of KuFc79 inhibits the formation of rosettes with IgG-sensitized sheep erythrocytes by as much as 91.7%. In other experiments in which PMNL were washed after exposure to Fab of KuFc79, phagocytosis of IgG-sensitized sheep erythrocytes was inhibited by 36%. Fab fragments of other mouse IgG2b monoclonal proteins did not have these effects. When PMNL are exposed to coverslips coated with univalent Fab fragments of this antibody, the Fc gamma R are removed from the surface of the PMNL. Under these conditions, rosetting could be inhibited by 85.4%. We examined cross-linking of receptor bound monoclonal antibody or its Fab fragment by either Protein A or F(ab')2 of an anti-mouse Ig. As much as 31.7% of beta-glucuronidase, a marker for lysosomal enzymes, is specifically released by cross-linking the Fc gamma R on PMNL. The generation of O2- is also induced by specifically cross-linking Fc gamma R with Fab and anti-Fab. The data constitute the first formal demonstration that cross-linking of Fc gamma R on PMNL leads to enzyme release and superoxide generation.     

Relationship between human IgE-binding factors (IgE-BF) and lymphocyte receptors for IgE

This study indicates that human IgE-binding factors (IgE-BF) found in the cellfree culture supernatant (CSN) of Fc epsilon R-bearing B cells are breakdown products of the surface Fc epsilon R. This conclusion is suggested by the following observations. 1) Fc epsilon R and IgE-BF share several antigenic determinants as shown by immunoprecipitation with several Mab to Fc epsilon R (MabER) and SDS-PAGE analysis of the precipitates. 2) Upon incubation at 37 degrees C, normal tonsillar lymphocytes lose their Fc epsilon R and this is associated in a time-related manner with the release in the CSN of molecules reacting with two MabER. 3) Surface radioiodinated tonsillar lymphocytes or RPMI 8866 cells release labeled IgE-binding molecules displaying the same antigenic composition and the same migration on SDS-PAGE as purified IgE-BF. 4) Peptide mapping of highly purified IgE-BF and Fc epsilon R reveals the presence of several identical fragments after digestion with either alpha-chymotrypsin, trypsin, or papain. Moreover, papain digestion of the 25-27 kD IgE-BF and of the affinity-purified Fc epsilon R, generated a 15 kD fragment reacting with two MabER and that is known to bind IgE. Although these data strongly suggest that IgE-BF may be directly derived from cell surface IgE receptors, they do not exclude the possibility that some IgE-BF may also be secreted without being first anchored in the cell membrane.     

Combined glyco- and protein-Fc engineering simultaneously enhance cytotoxicity and half-life of a therapeutic antibody

While glyco-engineered monoclonal antibodies (mAbs) with improved antibody-dependent cell-mediated cytotoxicity (ADCC) are reaching the market, extensive efforts have also been made to improve their pharmacokinetic properties to generate biologically superior molecules. Most therapeutic mAbs are human or humanized IgG molecules whose half-life is dependent on the neonatal Fc receptor FcRn. FcRn reduces IgG catabolism by binding to the Fc domain of endocytosed IgG in acidic lysosomal compartments, allowing them to be recycled into the blood. Fc-engineered mAbs with increased FcRn affinity resulted in longer in vivo half-life in animal models, but also in healthy humans. These Fc-engineered mAbs were obtained by alanine scanning, directed mutagenesis or in silico approach of the FcRn binding site. In our approach, we applied a random mutagenesis technology (MutaGen^TM) to generate mutations evenly distributed over the whole Fc sequence of human IgG1. IgG variants with improved FcRn-binding were then isolated from these Fc-libraries using a pH-dependent phage display selection process. Two successive rounds of mutagenesis and selection were performed to identify several mutations that dramatically improve FcRn binding. Notably, many of these mutations were unpredictable by rational design as they were located distantly from the FcRn binding site, validating our random molecular approach. When produced on the EMABling^® platform allowing effector function increase, our IgG variants retained both higher ADCC and higher FcRn binding. Moreover, these IgG variants exhibited longer half-life in human FcRn transgenic mice. These results clearly demonstrate that glyco-engineering to improve cytotoxicity and protein-engineering to increase half-life can be combined to further optimize therapeutic mAbs.