Abstract
"Antibody-breeding" approach potentially generates therapeutic/diagnostic antibody mutants with greater performance than native antibodies. Therein, antibody fragments (e.g., single-chain Fv fragments; scFvs) with a variety of mutations are displayed on bacteriophage to generate diverse phage-antibody libraries. Rare clones with improved functions are then selected via panning against immobilized or tagged target antigens. However, this selection process often ended unsuccessful, mainly due to the biased propagation of phage-antibody clones and the competition with a large excess of undesirable clones with weaker affinities. To break radically from such panning-inherent problems, we developed a novel method, clonal array profiling of scFv-displaying phages (CAP), in which colonies of the initial bacterial libraries are examined one-by-one in microwells. Progenies of scFv-displaying phages generated are, if show sufficient affinity to target antigen, captured in the microwell via pre-coated antigen and detected using a luciferase-fused anti-phage scFv. The advantage of CAP was evidenced by its application with a small error-prone-PCR-based library (~ 105 colonies) of anti-cortisol scFvs. Only two operations, each surveying only ~ 3% of the library (9,400 colonies), provided five mutants showing 32–63-fold improved Ka values (> 1010 M−1), compared with the wild-type scFv (Ka = 3.8 × 108 M−1), none of which could be recovered via conventional panning procedures operated for the entire library.
Similar content being viewed by others
Introduction
As shown by the feat that the pioneers in this field received Novel Prize in Chemistry in 20181, the in vitro molecular evolution revolutionalized in generating therapeutic and diagnostic antibodies with artificial sequences that might show advanced characteristics compared with native antibodies (“antibody-breeding”)2,3,4,5. Typically, smaller fragments (e.g., single-chain Fv fragments; scFvs) of prototype antibodies are mutagenized to generate a diverse library of mutants (Fig. 1A). Then, genotype–phenotype-connecting systems play a vital role in isolating rarely appearing evolved species. Among the systems developed, the phage display used the most because of its easier handling and availability of the necessary materials6,7,8. Therein, mutant scFvs are expressed on Ff bacteriophage (e.g., M13 phage) particles, as fusion proteins usually with the minor coat protein pIII (Fig. 1B). The scFv-displaying phages (scFv-phages) with improved antigen-binding characteristics are commonly isolated via panning, wherein all the library members are simultaneously reacted with a limited amount of immobilized or tagged antigens (Fig. 1B). The goal is to recover desirable species as the bound fraction, which are then proliferated by infecting bacteria for subsequent panning or characterization.
However, the panning-based selection process often fails to straightforward discovery of improved scFv-phages even after extensive efforts. As the reason for this crucial problem, we should not disregard for biasness for propagating transformants as well as for infection/replication of phage clones9 and competition with a large excess of undesirable mutants with weaker affinities against target antigens (Fig. 1B). To enable more sensitive immunochemical analyses10,11, we have generated affinity-matured scFv mutants against estradiol-17β12,13,14, cotinine15, and cortisol16, each of which gained an equilibrium affinity constant (Ka) enhanced by > 150-fold, > 40-fold, and > 30-fold, respectively (Fig. 2A–C). These improved binders were all isolated by the panning, but with different protocols arranged after trial and error. However, we had to examine the affinity of > 1,000, ~ 500, and ~ 50 scFv-phage clones in detail until we discovered the desirable anti-estradiol-17β, anti-cotinine, and anti-cortisol scFv mutant, respectively, despite that the tested clones were the members of “enriched” populations. It should be noted that acceptably efficient selection was achieved only for isolation of the anti-cortisol scFv (Fig. 2C)16 that was performed with the simplest panning protocol among the three instances.
Such panning-inherent limitations should be overcome by screening individual phage clones generated from the initial bacterial libraries that maintain the original diversity, and not from panning-enriched libraries. Thus, we devised “clonal array profiling of scFv-displaying phages (CAP),” a reliable and robust system for recovering rare affinity-matured scFv phages that does not require sophisticated machinery or intelligent technology. This system, schematically illustrated in Fig. 1C, directly (i.e., without any enrichment step) provided a set of scFv mutants showing 32–63-fold improved and 1010-order Ka values against a small biomarker cortisol (hydrocortisone; Fig. 2C and Supplementary Fig. S1), contained in a small (~ 105-order) scFv library generated via a simple mutagenesis based on error-prone polymerase chain reaction (PCR). None of such improved species could be recovered via a multiple operation of panning including three different protocols. We then applied CAP to a related but different scFv library, and again succeeded in isolating affinity-matured mutants with a minimum experimental effort.
Results
Basic principle of CAP
In our CAP, we examined the colonies of the initial bacterial library grown on agar plates one-by-one in different microwells, so as not to disturb their original diversity or compete with the different clones (Fig. 1C). TG1 strain of Escherichia coli (E. coli) was transformed with a mutant scFv gene library and spread on agar plates. The colonies grown on agar were transferred individually into microwells in 96-well plates pre-coated with the target antigen and filled with liquid medium containing the KM13 helper phage17. The plates were then incubated, and antigen-specific scFv-phages rescued therein were, if present with enough affinity and/or copy numbers, captured on the microwells and detected with the bioluminescent assay using an in-house-prepared fusion protein linking an scFv against M13 phage (specific to the pVIII major coat protein)18 and Gaussia luciferase19 (anti-M13-GLuc) (Supplementary Fig. S2A–C). We confirmed that the virions with 1.8 × 1010 plaque forming units (pfu) were generated in a single microwell (according to the average of tested 58 colonies), and could be easily detected using anti-M13-GLuc (Supplementary Fig. S2C). For more selective isolation of the higher affinity mutants, a variation of CAP containing “off-rate-dependent (ORD) selection” process was performed in parallel with the standard CAP procedure, which is described later.
Comparison of CAP and the conventional panning
A comparative study was performed according to the workflow shown in Fig. 3. As a target for the testing, a small and simple gene library (randomly-mutated library) was generated by a single random mutagenesis with error-prone PCR12,13,14,15,16,20 throughout the gene fragment encoding the wild-type scFv against cortisol (wt-scFv), which was composed of the non-mutated heavy and light chain variable domains (VH and VL) of a mouse anti-cortisol antibody (Ab#3)16 (Fig. 3A).
a. Panning
TG1 cells were transformed with these mutant scFv genes, and the resulting bacterial library that initially contained 5.9 × 105 transformants as colony-forming unit (cfu) was cultivated 1 h and equally divided to make multiple glycerol stocks. These were separately used for a standard phage rescue with the KM13 helper phage, and the generated virions were submitted to one of three kinds of panning (I–III), each of which was performed with three rounds using polystyrene tubes (immunotubes) coated with a conjugate of cortisol and bovine serum albumin (CS-BSA)19 (Fig. 3B) as follows. (I) Binding reaction of phages was performed against the immunotubes immobilized with a constant concentration of CS-BSA (#1–6). After washing with a constant stringency, bound phages were eluted with a standard acidic (pH 2.2; #1–3) or basic (pH 12; #4–6) condition. (II) Binding reaction was performed against the immunotubes immobilized with gradually reduced concentrations of CS-BSA (#7, 8). After washing with a gradually increased stringency, bound phages were eluted with the acidic (pH 2.2) condition. (III) Binding reaction was performed using the immunotubes immobilized with a constant concentration of CS-BSA (#9, 10). After washing with a constant stringency, bound phages were eluted by addition of cortisol solutions with gradually reduced concentrations: this protocol previously succeeded in isolating the improved anti-cortisol scFv as referred to above16 (Fig. 2C).
Among the recovered scFv-phages from each tube, 50 clones (thus, total 500 clones) were analyzed with the phage-targeted enzyme-linked immunosorbent assay (ELISA)12,13,14,15,16. The 34 positive clones that showed bound absorbance of > 0.3 were converted to the soluble (non-phage-linked) scFv form, and their Ka values against free (not immobilized) cortisol were determined by the Scatchard analysis12,13,14,15,16,21. Only seven mutants had improved Ka compared with wt-scFv (Ka, 3.8 × 108 M−1), however, the greatest Ka of which (1.9 × 109 M−1) was only 5.0-fold higher than that of wt-scFv (Fig. 4A). Unexpectedly, the highest (aforementioned) and second-highest Ka (1.5 × 109 M−1) were recorded with the mutants (scFv#mc5-19 and 1-7) both isolated from the panning (I) performed with the mildest stringency. The panning (II) with a standard protocol with the gradually-increased stringency provided only a poorly improved binder (scFv#mc7-24) showing a Ka in the 108 M−1 range. The panning (III), previously succeeded in isolating the affinity-matured anti-cortisol scFv from a similar library, generated no improved mutant.
The panning (I), performed simultaneously in sextuplicate, revealed difficulty in obtaining reproducible results: i.e., the clones scFv#mc1-7, 2-17, and 2-21 appeared from two or more different panning tubes, while the tubes #3 and #6 showed no improved clones (Fig. 3B). For these seven mutants, the number of substitutions per entire scFv molecule ranged from 1 to 7 positions with the average of 4.1. Proportions of these substitutions occurred in the VH and in the complementarity-determining regions (CDRs) were 40% and 24%, respectively (calculated excluding those in the linker).
The most remarkable feature observed for the panning-derived mutants was the fact that each of the seven mutants contained an amino acid substitution at the VL49 position that eliminated the original cysteine (C), which was rather unusual because C residues are rarely observed in the antibody variable regions, except for those highly conserved at the VH22 and VH92, VL23 and VL88, each pair of which forms the intra-chain disulfide bonds22.
b. CAP
Using the same scFv gene library as above, a bacterial library with a similar size (3.4 × 105 transformants) was obtained, from which 9,400 transformants (corresponding to ~ 3%) were directly submitted to CAP using 100 microplates with manual handling (Fig. 3C). From the 761 clones that generated > 100,000 arbitrary units (a.u.) of bioluminescence (~ 8% of 9,400 clones; Fig. 3D), the top 40 clones were selected and the relevant virions were retrieved from the microwells to examine the binding ability in the phage-targeted ELISA (Fig. 3C). Seven species (scFv#m1-1, 2, 7, 8, 10, 18, and 19) that showed stronger inhibition after adding the cortisol standards were converted to soluble scFvs. Four out of the seven scFvs (scFv#m1-2, 7, 10, and 18) showed 14–37-fold enhanced Ka (0.53–1.4 × 1010 M−1) versus wt-scFv [Fig. 4A (right/upper rectangle); Scatchard plots21 are in Supplementary Fig. S3A]. We should emphasize here the excellent efficiency that enabled generation of the four improved mutants from the top 40 clones. Because these top 40 were selected from ~ 3% of the library, we could estimate the remaining ~ 97% might contain an additional 4 × (97/3) affinity-matured species.
To increase the efficiency of obtaining affinity-matured phage-scFvs, ORD selection, which might preferentially isolate the mutants with slower dissociation (i.e., lower off-rate)23, was employed in this profiling system (Fig. 3C'). The 376 scFv-phages that showed strong luminescence (~ 10% of the tested 9,400 clones) (Fig. 3D) were propagated in different plates to allow for their “initial binding” to the immobilized cortisol. After removing unbound materials, the microwells were incubated with a solution of 14 µM free cortisol for 4 h, and then the supernatant (potentially containing scFv-phages that had been dissociated and complexed with free cortisol) was removed again. In these incubation steps, we set the molar ratio of the free cortisol added versus the immobilized cortisol-residues to be 300:1 to prevent re-binding of dissociated virions to the immobilized cortisol residues. The incubation period employed here was near the t1/2 of scFvs with the kd of ca. 5 × 10−5 s−1. This cycle was repeated three times and the bioluminescence was measured after each removal. Sixteen scFv-phage clones that still showed significant luminescence (Supplementary Fig. S4) were examined for their cortisol-binding ability. Four out of the 16 clones were found to display scFvs (scFv#m2-4, 91, 97, and 183; thus, higher probability than the without ORD selection) that showed 16–63-fold higher Ka (0.59–2.4 × 1010 M−1) than wt-scFv, as the soluble form [Fig. 4A (right/lower rectangle); Scatchard plots are in Supplementary Fig. S3B]. Indeed, bio-layer interferometry (BLI) analysis24 showed that these mutants had lower dissociation rate constants (kd) than that of wt-scFv (2.4 × 10−3 s−1): i.e., for scFv#m2-4, 91, 97, and 183, the kd values were 0.38, 0.21, 0.87, and 2.0 × 10−3 s−1, respectively (average of 0.87 × 10−3 s−1).
The primary structures indicated that the improved mutants obtained here were quite different from those obtained with the panning (Fig. 4A). Substitutions and insertions were lesser (average number was 2.3), the proportions of which in the VH (81%) and in the CDRs (31%) (calculated as described above) were obviously higher than those found in the panning-derived mutants. One of the most notable aspects, however, was the fact that the five mutants gained 16–37-fold greater Ka as the result of only a single substitution (scFv#m1-10, 18, #m2-91, and 183) or a single insertion (scFv#m1-2). Furthermore, four of the five scFvs (scFv#m1-2, 10, scFv#m2-91, and 183) were modified at their VH framework region (FR) 1. Three mutants with multiple substitutions (scFv#m1-7, #m2-4 and 97) also substituted at the VH-FR1. The protein modelling docked with cortisol was shown for the FR1-modified mutants (scFv#m1-10 and #m2-97) with wt-scFv, in which the FR1 sequences were highlighted (Fig. 4B). However, prominent alterations in the backbone and CDR conformations were not observed after the substitutions. We should pay attention to one more mutant scFv#m1-18. This gained 37-fold greater Ka as a result of a single serine(S) → glycine(G) substitution at the third residue of the linker combining the VH and VL domains: the original sequence of which was the following 19 residues as V(valine)SS(GGGGS)3 T(threonine), and the underlined S was substituted.
It was also noteworthy that scFv#m1-2 and 10 referred above were the products of scFv genes containing a nonsense codon. Thus, the gene encoding scFv#m1-2 had an insertion of amber (TAG) codon between the codons for the VH6 and VH7 amino acids, while the gene encoding scFv#1-10 had an opal (TGA) codon introduced by a G → A transition altering the original TGG codon that encoded the VH36 tryptophan (W). Such a nonsense mutation was also found in the gene encoding the panning-derived mutants (scFv#mc1-7 and 2-21; Fig. 4A). Since these scFvs bound to cortisol with significant Ka values (over 108 M−1), the nonsense codons should be readthrough to generate full-length scFv molecules. We identified the incorporated amino acids by Edman sequencing for scFv#m1-2 and liquid chromatography-tandem mass spectrometry (LC/MS/MS) fingerprinting for scFv#m1-10, mc1-7, and 2-21 (Supplementary Fig. S5), both performed on affinity-purified soluble-form scFv proteins: the amber codons in scFv#m1-2, mc1-7, and 2-21 were decoded as glutamine (Q), and opal codon in scFv#m1-10 was decoded as W, respectively, as expected from the previously shown stop codon readthrough in bacteria (Nonsense suppressor-EcoliWiki, https://ecoliwiki.org/colipedia/index.php/Nonsense_suppressor). Consequently, the VH36 amino acid in scFv#m1-10 was found not to be substituted, maintaining the original residue in wt-scFv (i.e., W).
Antigen-binding performance of affinity-matured scFv mutants
Cortisol is used as a biomarker for the functions of the hypothalamic–pituitary–adrenal axis25 and thus practical anti-cortisol antibodies have always been in great demand as diagnostic reagents. However, only a few publications have demonstrated the production of monoclonal antibodies capable of targeting serum or urinary cortisol26,27,28. Immunoassay sensitivities closely correlate with affinities of the antibodies used10. As expected, the five mutants with a Ka of > 1010 M−1 isolated from the randomly-mutated library with CAP (scFv#m1-10, 18, #m2-4, 91, and 97) showed dramatically enhanced sensitivities in competitive ELISAs, as shown by 11–25-fold lower midpoint values (31–71 pg/assay) than those of wt-scFv (768 pg/assay) in dose–response curves (Fig. 5A). Among the panning-derived mutants, scFv#mc7-24 isolated from the protocol (II) with the fourth highest Ka among the seven mutants showed the most increased sensitivities with 2.3-fold lower midpoint values, but was not as sensitive as the CAP-derived mutants (Fig. 4B). The six mutants from the protocol (I) exhibited only slightly increased (scFv#mc1-7 and #mc5-9; ~ 1.3 and 1.2-fold as midpoint values) or a rather deteriorated response (the other four scFvs) despite their obviously improved Ka values (Fig. 4A). We have no clear explanation for these contradicting results now, but this might be attributable to a possible feature of these mutants to recognize the bridge (linker) structure connecting cortisol and BSA in the conjugate coated on the microplates29.
The detection limit of the ELISAs using the four mutants that exhibited midpoints of less than 50 pg/assay, i.e., scFv#m1-10, 18, #m2-91, and 97, was 5.5, 11, 8.1, and 9.0 pg/assay, respectively, based on the definition as the cortisol amount that provided a bound signals two standard deviations (SDs) below the average (n = 10) of the signals at zero concentration; which corresponds to 1.1–2.2 ng/mL serum cortisol levels (assuming that serum specimens could be directly applied by diluting tenfold). Considering the normal levels for serum cortisol (10–250 ng/mL)30, these ELISA systems are sensitive enough for diagnostic applications. Although cross-reactivity with eight kinds of endogenous steroids indicated that the amino acid substitution accompanied alteration in specificity (Supplementary Table S1), the recognition pattern of these affinity-matured scFvs was, overall, acceptable from the view of clinical application16,19.
Application of CAP to a different library composed of FR1-extended scFvs
In the initial trial of CAP described above, we obtained an affinity-matured scFv with a rare and suggestive structural alteration; namely, scFv#m1-2 that showed ~ 1010 M–1 affinity owing to the insertion of an extra amino acid Q between the amino acids at the position 6 (Q) and 7 (proline; P), located in the FR1 of VH domain (Fig. 4A). This finding prompted us to generate a new library of anti-cortisol scFvs having extended FR1 sequences due to the insertion of a single or, doubly- or triply-consecutive randomized amino acid(s) between the positions VH6 and VH7 (Fig. 6A). This library theoretically includes 8,420 (= 20 + 202 + 203) different sequences. We submitted a portion (~ 0.1%) of the bacterial library transformed with the resulting scFv genes to CAP without and with ORD selection (Fig. 6A). Only two operations provided five scFv mutants showing > 16-fold increased Ka values (Fig. 6B). We should emphasize that the same clone as scFv#m1-2 (named scFv#em1-4 here), which should be contained in the new library, was isolated again. These mutants, when used for ELISA, showed obviously higher sensitivity (midpoint ranged 28–30 pg/assay; meaning 26–27-fold improvement) than that in the ELISA using wt-scFv (Fig. 6C).
Discussion
It is well known that the phage display-based antibody engineering (i.e., “antibody-breeding”) strategy has supplied precious antibody reagents, both for therapeutic and diagnostic use1,2,3,4,5,6,7,8. However, the panning, which should work as a key process therein, has often troubled us with its inefficiency and uncertainty due to somewhat fluctuating reproducibility as shown with the present study (Fig. 3B) in selecting improved species. To radically avoid such panning-inherent problems, we constructed CAP method, in which colonies of the initial bacterial libraries are examined one-by-one in individual microwells, so as not to disturb their original diversity and not to compete with different clones during bacterial propagation and following events. Monoclonal scFv-phage progenies should be generated in the microwell where the parent bacterium was inoculated and propagated, maintaining the genotype (scFv gene in the bacterium) and phenotype (scFv protein displayed on phage) linkage. If scFv-phage clones show significant antigen-binding ability, they should be captured in the microwell via a pre-coated antigen, forming microwell-based array of antigen-binding scFv-phage clones, which are then detected in a sensitive bioluminescent assay with the aid of the anti-M13-GLuc fusion protein. To improve the efficiency in obtaining high-affinity binders, an advanced variation of the profiling involving “ORD selection” was also devised.
We should refer, here, to the selection based on next-generation sequencing (NGS), which attracted much attention several years ago. NGS has enabled the ranking of antibody-displaying phage clones enriched after the panning, based on the frequency of gene sequence encoding a part of the variable regions31,32,33,34. Lesser antigen-binding dependency makes this strategy advantageous when target antigens are difficult to obtain. However, due to the panning-inherent problem described previously, more frequent sequences do not always associate with more improved mutants in terms of antigen-binding characteristics. To confirm whether the phenotype of the selected genes in fact exhibits improved antigen-binding abilities, considerable effort is required for constructing the genes encoding the full-length antibody fragments anew and for their expression.
The CAP approach that we have proposed here might be regarded as a return to “primitive-in-a-sense” screening from “theoretically-rational and elegant” selection (panning). However, we are convinced that CAP should be the most straightforward and robust way to overcome the selection problem, and should enable high-throughput isolation of improved species. It might be worth referring to that, in the middle of 1990s, the Stemmer’s group suggested the efficiency of individual screening of ~ 10,000 transformants for finding improved mutants in their study for generating improved green fluorescent protein species35. In fact, an advantage was evidenced by its application to a small, easily-preparable randomly-mutated library of anti-cortisol scFvs. Even though only two operations (with or without the ORD selection step) were performed each on a small portion (only ~ 3%) of the library, we obtained eight mutants showing > 14-fold improved Ka values over the wild-type scFv, and five of the eight exhibited 1010-range Ka values. In contrast, ten operations of conventional panning on the entire library (i.e., 100% of the colonies), even with the three different protocols, only provided seven moderately improved binders (with 1.1–5.0-fold higher Ka). The fact that the panning protocol (III) provided no improved clone, despite the previous contribution for isolating an improved scFv against cortisol derived from the same wild-type scFv as that used in this study (Fig. 2C)16, demonstrated difficulty in panning-based selections.
The utility of CAP was further supported by the additional trial mining of a different library that was composed of scFvs with extended FR1 sequences, from which five improved mutants (with > 16-fold improved Ka values) were successfully isolated. As we discussed previously10,14, improving antibodies against low-molecular-weight antigens (haptens) such as cortisol, dealt with in this study, is challenging. Particularly, mining affinity-matured mutants can become dramatically difficult when the parental scFv already shows significant affinity (e.g., Ka > 108 M−1) for the target antigen, like our instances shown in Fig. 2. During the period of about a quarter century after in vitro evolution was established, less than 10 studies have succeeded in practical affinity maturation: in which mutants with a Ka of > 109 M−1 were generated after over fourfold improvement, and the mutants were reactive against free (not immobilized) hapten molecules10,14 (Supplementary Fig. S6). The CAP method, however, facilitated success by generating a total of 13 mutants that exceeded this criterion (Figs. 4, 6), even with only four operations (counting the mining of FR1-extended library together), each working with a randomly selected small portion (9,400 or 4,700 colonies) of a small library (containing 105 ~ 106-members as cfu) as summarized in Figs. 3 and 6. Extensive working power that is required for performing such a screening-based approach will be diminished in the future by automatization using robotic colony pickers so as to allow for full screening of > 106-size libraries. If we could process the entire library discussed above, we should, mathematically, obtain more similarly-improved mutants, i.e., 267 [= 8 × (100/3)] from the randomly-mutated library (Fig. 3C or C’) and 5,000 [= 5 × (100/0.1)] from the FR1-extended library (Fig. 6A). Analytical significance of the CAP-derived mutant scFvs was shown in the competitive ELISA, dose–response curves of which were obviously more sensitive than that with wt-scFv (Figs. 5 and 6C).
During this study, we obtained some unexpected and important information regarding the primary structures of the affinity-matured mutants. The CAP-derived mutants from the randomly-mutated library had prominently different features from those obtained with the panning (Fig. 4A), represented by the less substitutions (and insertions) that were concentrated more in the VH and in CDRs. It should be noted that no scFv mutant obtained with CAP, as well as that recovered from the panning, had substitution/insertion in the VH-CDR3 that is regarded as the most crucial among the six CDRs to generate affinity and specificity against a definite antigen structure11(Fig. 4A). Moreover, the substitutions/insertions frequently occurred in FR1 in the VH domain, suggesting that this region might be an “untapped hotspot,” where mutations introduced therein might result in the affinity maturation in high probability. This assumption was strongly supported by our additional application of CAP to the FR1-extended scFv library (Fig. 6). The FR1 is unlikely to participate for direct contact with the antigens, as suggested by the protein modelling of scFvs (Fig. 4B), but might interact with the loop structure of VH-CDR3 due to the proximity. Otherwise, it might influence the dimerization or thermodynamic stability of scFvs36. In addition, isolation of affinity-matured mutant with a single substitution on the linker (scFv#m1-18) was remarkable, and prompts us to generate a small library by randomization of the linker sequence.
One more interesting feature was the role of “unusual” C (cysteine) at the position 49 in the VL domain referred above. While the panning-derived and moderately improved mutants all deleted this C by substitution, the CAP-derived and successfully improved mutants all retained this residue. Therefore, it is reasonable to deduce that this C plays an important role for exerting the cortisol-binding affinity. This was supported by additional experiments, in which we examined the affinities (estimated with ELISA dose–response curves) of 10 kinds of VL97-substituted mutants prepared from scFv#m2-97 (the mutant with the highest Ka in this study) (Supplementary Fig. S7). Isoleucine (I)- and tyrosine (Y)-substituted mutants showed a slightly-improved response over scFv#m2-97, however, the other eight mutants all deteriorated significantly.
Our CAP might be associated with colony-lift assays, which were developed in the 1990s37,38,39,40. This method arrowed direct and simultaneous screening for multiple bacterial colonies regarding the ability to produce antigen-binding scFv (or Fab), but remained several problems that hamper reliable discovery of affinity-matured mutants: i.e., insufficiency of reproducibility, quantitativity, resolution between colonies growing closely on agar. Moreover, the phenotype (visualized spots) and genotype (causal bacterial colonies) were separated on different membranes. We overcame these drawbacks using a “one-pot” (i.e., same microwell) and individual operation for cultivating monoclonal transformants and monitoring the propagated scFv-phages with robust immunoreactions. To enable this, proliferation potency of monoclonal phages and high sensitivity of the bioluminescent assay were mandatory. Therefore, CAP works successfully by taking advantage of the intrinsic advantage of phages; i.e., the potential of replication, similar to the panning where the propagating nature is also essential for multiplying trace amounts of recovered phages for the following stage of work. The analysis of individual scFv-phage particles using a flow cytometry (FC)-like principle seems to be a more sophisticated approach. This might be realized simply by adding FC-applicable microbeads coated with CS-BSA one-by-one into the microwells, in which individual transformant grows and generates scFv-phages. It should be noted that a similar and elegant principle has been reported that used micro droplets in water-in-oil emulsions as the compartments that correspond to our microwells41.
In conclusion, the present CAP should readily be applicable for laboratories with standard equipment, and should overcome the longstanding trouble in isolating rare and improved antibody species, enabling the isolation of conventionally-overlooked mutants. CAP will contribute widely for providing “next-generation” antibody reagents useful for both therapeutic and diagnostic applications. We have already undertaken modification of the present CAP into more efficient and feasible procedures. To surely recover scFv mutants bound on the antigen-immobilized solid phases with extremely high affinity, we might employ the dissociation-independent methods such that we previously reported14,42,43.
Materials and methods
Buffers
PB: 50 mM sodium phosphate buffer (pH 7.3); PBS: PB containing 9.0 g/L NaCl; G-PBS: PBS containing 1.0 g/L gelatin; T-PBS: PBS containing 0.050% (v/v) Tween 20; M-PBS: PBS containing 20 g/L skim milk; PVG-PBS: G-PBS containing 1.0 g/L polyvinyl alcohol (average polymerization degree 500; Nacalai Tesque); PBS-2: 10 mM Na2HPO4, 1.8 mM KH2PO4, 0.14 M NaCl, 2.7 mM KCl (pH 7.4); M-PBS-2: PBS-2 containing 20 g/L skim milk; and T-PBS-2: PBS-2 containing 0.10% (v/v) Tween 2012,13,14,15,16.
Production of anti-M13-GLuc
A gene encoding the scFv derived from Ab-M13#7118 was amplified using the M13#71VH-Rev18 and CS#10VL-For-219 primers to add another linker sequence at the 3′-end for fusion with the GLuc gene (a gene fragment encoding “wild-type” Gaussia luciferase19 followed by sequences encoding FLAG and His6 tags, and TAATGA codons) (Supplementary Fig. S2). The re-amplified scFv and GLuc gene fragments (200 ng each) were spliced by performing overlap-extension PCR12,13,14,15,16. The resulting anti-M13-GLuc fusion gene was expressed in E.coli XL1-Blue cells (Agilent Technologies) under induction with isopropyl β-D-thiogalactopyranoside and sucrose12,13,14,15,16. Periplasmic extracts containing anti-M13-GLuc fusion protein was used for phage detection without further purification.
Bioluminescent detection of scFv-phages bound to microwells
White 96-well microplates (#3922; Corning) were coated with BSA conjugated with cortisol19 or estradiol-17β12,13,14, using 1.0 µg/mL solutions in 0.10 M carbonate buffer (pH 8.6), and blocked with Block Ace (DS Pharma Biomedical). scFv-phages against cortisol or estradiol-17β [0–109 colony-forming units (cfu)], rescued with KM13 helper phage17, were added as suspension in 2 × YT medium to the microwells (200 µL/well) and incubated at 37 ºC for 60 min. After washing with T-PBS-2 three times, appropriately diluted anti-M13-GLuc in M-PBS was added (100 µL/well) and further incubated for 30 min at 37 ºC. After washing, 5.0 µM coelenterazine (Nanolight) in PBS was added (100 µL/well), mixed, and scanning (2.4 well/s) of luminescence (emission at a range of 300–700 nm was collected) was initiated 27 s after addition of the substrate using a Synergy HTX multi-mode microplate reader (Biotech).
Construction of the randomly-mutated anti-cortisol scFv gene library
Error-prone PCR12,13,14,15,16,20 was performed to amplify the anti-cortisol wt-scFv gene16 in a buffer solution (100 µL) with 0.10 mM MnCl2, the reverse (5′-GGATTGTTATTACTCGCGGC-3′) and forward (5′-CCTGATGTGTG CGTCTTAGT-3′) primers (0.10 nmol each), AmpliTaq DNA polymerase (Applied Biosystems) (5 U), and 0.10 µmol of each dNTP (except dATP, which was present at 0.020 µmol). These mixtures were amplified for 35 cycles of 95 ºC (1 min), 50 ºC (1 min), and 72 ºC (3 min), followed by a 10-min extension at 72 ºC. The mutated scFv genes were ligated into the pEXmide 7 vector16. TG1 cells (Agilent Technologies) were transformed with the resulting plasmid (ca. 0.4 µg) by electroporation. After an electrical pulse was discharged, the cells were immediately incubated in SOC medium (1.0 mL) at 37 °C for 60 min. For the conventional panning, the resulting cell suspension was centrifuged (1,800 × g, 20 min), the pellet was suspended in SOC medium (100 µL), and spread on 90φ plates containing 2 × YT agar supplemented with 100 µg/mL ampicillin and 1.0% glucose. The plates were incubated overnight at 37 ºC and all the colonies grown were scraped into a 2 × YT medium containing 15% glycerol (1.5 mL). The resulting suspension was divided into aliquots and stored at – 80 ºC, ten of which were used for the panning later. For CAP, the aforementioned cell suspension in SOC medium was adequately diluted with the SOC medium, aliquots (200 µL) of which were then spread on 144 × 100 mm rectangle plates containing 2 × YT agar supplemented as above. After overnight incubation at 37 ºC, the colonies grown were subjected to CAP as described later.
Phage rescue and the conventional panning
The aliquots of the ten glycerol stocks for the bacterial library transformed with the randomly-mutated anti-cortisol scFv genes were each inoculated into 2 × YT medium containing 100 µg/mL ampicillin and 2.0% glucose (50 mL), and shaken (200 rpm) at 37 ºC until the absorbance (600 nm) reached ~ 0.4. The KM13 helper phage was added at a multiplicity of infection of 20, and the mixture was incubated at 37 ºC for 30 min. After centrifugation (1,000 × g, 20 min), the precipitated cells were resuspended in 2 × YT medium containing 100 µg/mL ampicillin and 50 µg/mL kanamycin (20 mL × 2), and then shaken (120 rpm) for 12–16 h at 25 ºC. This culture was centrifuged and the virions generated were precipitated by adding polyethylene glycol 8,000 in 2.5 M NaCl (5.0 mL). After centrifugation, the precipitated phages were resuspended in sterile PBS-2 and submitted to one of the three panning experiments described below. In these panning protocols (I)–(III), in common, three rounds of selections were performed using MaxiSorp 12 × 75 mm polystyrene tubes (ThermoFisher Scientific) (i.e., immunotubes) coated with solutions of CS-BSA in the carbonate buffer19 and blocked with M-PBS-213. Therein, ~ 1 × 1011 cfu/tube phages were input as a suspension in PVG-PBS (2.0 mL) and incubated for 60 min at 37 ºC with continuous tumbling.
Protocol (I): The immunotubes were coated in sextuplicate with 5.0 µg/mL solution of CS-BSA (2 mL/tube). After the incubation with phages, the tubes were washed three times with T-PBS-2 (4 mL), and bound phages were eluted by incubation with 0.10 M glycine-HCl (pH 2.2) or 0.10 M triethylamine (pH 12) (1.0 mL) at room temperature for 10 min. The solutions recovered were neutralized by addition of 2.0 M Tris (pH 10.6) or 1.0 M Tris–HCl (pH 7.4), respectively. Protocol (II): The immunotubes were coated in duplicate with 5 µg/mL, 0.5 µg/mL, or 0.05 µg/mL solution of CS-BSA (2 mL/tube) for the first, second, or third round, respectively. After the incubation with phages, the tubes were washed three, six, or twelve times with T-PBS-2 (4 mL) for the first, second, and third round, respectively, and the bound phages were eluted by incubation with 0.10 M glycine-HCl (pH 2.2) (1.0 mL) at room temperature for 10 min. The solutions recovered were neutralized as above. Protocol (III): The immunotubes were coated in duplicate with 0.5 µg/mL solution of CS-BSA (2 mL/tube). After the incubation with phages, the tubes were washed three, three, or five times with T-PBS-2 (4 mL) for the first, second, and third round, and the bound phages were eluted by incubation with 10, 1, or 0.1 ng/mL solution of cortisol in PVG-PBS (1 mL/tube) for 120 min at 37 ºC.
The eluted phages were added to log-phase TG1 cells in 2 × YT medium (9 mL), and then incubated at 37 ºC for 30 min. After centrifugation (10,000 × g, 10 min), the pellet was resuspended in 2 × YT medium (100 µL) and spread on 90φ plates containing 2 × YT agar supplemented with 100 µg/mL ampicillin and 1.0% glucose, and incubated overnight at 37 ºC. The colonies were then scraped into 2 × YT medium containing 15% glycerol (1.5 mL) and an aliquot was used for phage rescue in the next round of selection12,13,14,15,16.
CAP
Individual bacterial colonies grown on agar (described above) were picked with sterile toothpicks and dipped in 2 × YT liquid medium containing 100 µg/mL ampicillin, 5.0 µg/mL kanamycin, and ca. 5 × 108 pfu/mL KM13 helper phage, which was filled in microwells (200 µL/well) of 96-well white microplates (#3922) pre-coated with CS-BSA as described above. After incubation at 25 ºC for 45 h with continuous shaking (800 rpm), these microplates were washed three times with T-PBS-2, and appropriately diluted anti-M13-GLuc in M-PBS (100 µL/well) was added, and the plates were incubated at 37 ºC for 30 min. After washing, 5.0 µM coelenterazine solution was added (100 µL/well), mixed, and the luminescence was scanned as described above (Fig. 1D). For microwells that generated strong luminescence, the mixture therein was removed, 0.10 M glycine-HCl (pH 2.2) was added (100 µL/well), and incubated at room temperature for 10 min. The solutions recovered were neutralized as above and the scFv-phages contained therein were propagated through infection to TG1 cells in log-phase growth for characterization.
ORD selection of scFv-phages
The scFv-phages that showed high luminescence in CAP were recovered and added to liquid 2 × YT medium containing ca. 3 × 108 cells/mL TG1 cells growing in log phase (100 µL/well) in microplates (#3922) coated with CS-BSA. After incubation at 37 ºC for 30 min, 2 × YT medium containing 200 µg/mL ampicillin, 10 µg/mL kanamycin, and 1 × 109 pfu/mL KM13 helper phage was added (100 µL/well) and the microplates were incubated at 25 ºC for 45 h with continuous shaking (800 rpm). Then, the microplates were washed, reacted with anti-M13-GLuc, the coelenterazine solution was added, and scanned to read the luminescence of each well as described above to obtain “initial signals”. The microplates were washed again, and 5.0 µg/mL (14 µM) cortisol dissolved in G-PBS (200 µL/well) was incubated therein at 25 ºC for 4.0 h. After removing the mixture and washing, the luminescence of each well was read again. This cycle was repeated three more times and the decreasing luminescence due to progressively diminishing bound scFv-phages was monitored. scFv-phages that still showed relatively high luminescence were propagated through infection to TG1 cells for characterization.
Preparation and characterization of soluble scFvs
scFv-phages selected as described above were transformed into the corresponding soluble (non-phage-linked) scFv proteins according to our previous method16, and their analytical performance in the competitive ELISA was examined. The 96-well microplates (#3590; Corning) coated with CS-BSA were incubated at 4 ºC for 120 min with a mixture of cortisol (or analogous steroid) standard (50.0 µL/well) and soluble scFv protein (100 µL/well), both diluted in G-PBS. The microplates were washed three times with T-PBS and probed using an anti-FLAG M2 antibody labeled with peroxidase (POD) (Sigma–Aldrich), diluted in G-PBS (0.20 µg/mL; 100 µL/well)12,13,14,15,16. After incubation at 37 ºC for 30 min, the microplates were washed and the captured POD activity was colorimetrically determined (490 nm) employing o-phenylenediamine as chromogen12,13,14,15,16. To construct the ELISA dose–response curves, GraphPad Prism version 3.0a (GraphPad Software) was used for curve fitting and determination of the reaction parameters. The midpoint (i.e., IC50) values were derived from a four parametric logistic equation [log(analyte dose) vs. B/B0 (%)] as the EC50 value. The top (the maximum response) and bottom (the basal response) were constrained to constant values of 100 and 0, respectively. The unit "X g/assay" was used in the abscissa, which means that a total of X g (mass) of the analyte or cross-reactive analogs was added to the assay chamber (microwells) for the competitive antigen–antibody reactions.
Determination of affinity parameters for soluble scFvs
The equilibrium affinity constants (Ka) of scFvs were determined by the Scatchard analysis21. Mixtures of [1, 2, 6, 7-3H]-cortisol (3.53 TBq/mmol; PerkinElmer) (ca. 250 Bq), varying amounts of standard cortisol, and a constant amount of each scFv (adjusted to capture ca. 50% of the tritium-labeled cortisol in the absence of standard cortisol) were incubated in GPB (700 µL) at 4 ºC overnight (~ 16 h). The bound (B) and free (F) fractions were separated by a dextran-coated charcoal method, and radioactivity of the B fraction was measured. Dissociation rate constants (kd) of the soluble scFvs obtained by the ORD selection were determined by the BLI24 at 25 °C using BLItz (ForteBio), a BLI sensor. Streptavidin-coated biosensor tips, which were saturated with a biotin-labeled CS-BSA, prepared by reaction with EZ-Link NHS-LC-Biotin (Thermo Fisher Scientific)44,45, were dipped into 4.0-µL scFv solutions in G-PBS (50–1,600 nmol/L). Association of the scFvs with the cortisol residues was monitored for 120 s, and then dissociation was measured for 600 s in G-PBS.
Preparation and CAP-based selection of the anti-cortisol FR1-extended scFv library
PCR was performed to amplify the anti-cortisol wt-scFv gene subcloned in pEXmide 7 vector16 in a buffer solution (100 µL) with KOD Fx DNA polymerase (TOYOBO) (5 U), 40 nmol of each dNTP, using one of the following reverse primers 5′-NNS1 (5′-ATTGTTATTACTCGCGGCCCAACCGGCCATGGCCCAGGTCCAACTGCAGCAGNNSCCTGGGGCTGAACTTGTGAAGC), 5′-NNS2 (5′-ATTGTTATTACTCGCGGCCCAACCGGCCATGGCCCAGGTCCAACTGCAGCAGNNSNNSCCTGGGGCTGAACTTGTGAAGC), or 5′-NNS3 (5′-ATTGTTATTACTCGCGGCCCAACCGGCCATGGCCCAGGTCCAACTGCAGCAGNNSNNSNNSCCTGGGGCTGAACTTGTGAAGC) in combination with the fixed 3′-primer, CS#3VL-For16 (50 pmol each). These mixtures were amplified for 94 ºC (2 min) followed by 35 cycles of 98 ºC (10 s), 55 ºC (30 s), and 68 ºC (1 min). The resulting three kinds of scFv mutant genes were separately ligated into the pEXmide 7 vector16. Then the reaction mixtures were equally mixed, with which TG1 cells were transformed by electroporation. After an electrical pulse was discharged, the cells were immediately incubated in SOC medium (1.0 mL) at 37 °C for 60 min. The cell suspension was adequately diluted, spread on the rectangle agar plates, and colonies grown were subjected to CAP as described above.
Data availability
The data sets generated during the current study are available from the corresponding author upon request.
References
Gibney, E., Noorden, R. V., Ledford, H., Castelvecchi, D. & Warren, M. Nobel for test-tube evolution. Nature 562, 176 (2018).
Dübel, S. (ed.) Handbook of Therapeutic Antibodies (Wiley-Blackwell, New Jersey, 2001).
Bradbury, A. R. M., Sidhu, S., Dübel, S. & McCafferty, J. Beyond natural antibodies: The power of in vitro display technologies. Nat. Biotechnol. 29, 245–254 (2011).
Chiu, M. L. & Gilliland, G. L. Engineering antibody therapeutics. Curr. Opin. Struct. Biol. 38, 163–173 (2016).
Kennedy, P. J., Oliveira, C., Granja, P. L. & Sarmento, B. Monoclonal antibodies: technologies for early discovery and engineering. Crit. Rev. Biotechnol. 38, 394–408 (2018).
Smith, G. P. & Petrenko, V. A. Phage display. Chem. Rev. 97, 391–410 (1997).
Clackson, T. & Lowman, H. B. (eds) Phage Display (Oxford University Press, New York, 2004).
Zhao, A., Tohidkia, M. R., Siegel, D. L., Coukos, G. & Omidi, Y. Phage antibody display libraries: a powerful antibody discovery platform for immunotherapy. Crit. Rev. Biotechnol. 36, 276–289 (2016).
Derda, R. et al. Diversity of phage-displayed libraries of peptides during panning and amplification. Molecules 16, 1776–1803 (2011).
Kobayashi, N. & Oyama, H. Antibody engineering toward high-sensitivity high-throughput immunosensing of small molecules. Analyst 136, 642–651 (2011).
Oyama, H. et al. Seeking high-priority mutations enabling successful antibody-breeding: systematic analysis of a mutant that gained over 100-fold enhanced affinity. Sci. Rep. 10, 4807 (2020).
Kobayashi, N. et al. Anti-estradiol-17β single-chain Fv fragments: generation, characterization, gene randomization, and optimized phage display. Steroids 73, 1485–1499 (2008).
Kobayashi, N. et al. Two-step in vitro antibody affinity maturation enables estradiol-17β assays with more than 10-fold higher sensitivity. Anal. Chem. 82, 1027–1038 (2010).
Oyama, H., Yamaguchi, S., Nakata, S., Niwa, T. & Kobayashi, N. “Breeding” diagnostic antibodies for higher assay performance: A 250-fold affinity-matured antibody mutant targeting a small biomarker. Anal. Chem. 85, 4930–4937 (2013).
Oyama, H. et al. One-shot in vitro evolution generated an antibody fragment for testing urinary cotinine with more than 40-fold enhanced affinity. Anal. Chem. 89, 988–995 (2017).
Oyama, H. et al. A single-step “breeding” generated a diagnostic anti-cortisol antibody fragment with over 30-fold enhanced affinity. Biol. Pharm. Bull. 40, 2191–2198 (2017).
Kristensen, P. & Winter, G. Proteolytic selection for protein folding using filamentous bacteriophages. Fold. Des. 3, 321–328 (1998).
Kiguchi, Y. et al. Antibodies and engineered antibody fragments against M13 filamentous phage to facilitate phage-display-based molecular breeding. Biol. Pharm. Bull. 41, 1062–1070 (2018).
Oyama, H. et al. Gaussia luciferase as a genetic fusion partner with antibody fragments for sensitive immunoassay monitoring of clinical biomarkers. Anal. Chem. 87, 12387–12395 (2015).
Leung, D. W., Chen, E. & Goeddel, D. V. A method for random mutagenesis of a defined DNA segment using a modified polymerase chain reaction. Technique 1, 11–15 (1989).
Scatchard, G. The attractions of proteins for small molecules and ions. Ann. N. Y. Acad. Sci. 51, 660–672 (1949).
Kabat, E. A., Wu, T. T., Perry, H. M., Gottesman, K. S. & Foeller, C. Sequences of Proteins of Immunological Interest (U.S. Department of Health and Human Services, National Institutes of Health, U.S. Government Printing Office, Washington, DC, 1991).
Hawkins, R. E., Russell, S. J. & Winter, G. Selection of phage antibodies by binding affinity: Mimicking affinity maturation. J. Mol. Biol. 226, 889–896 (1992).
Kamat, V. & Rafique, A. Designing binding kinetic assay on the bio-layer interferometry (BLI) biosensor to characterize antibody-antigen interactions. Anal. Biochem. 536, 16–31 (2017).
Chrousos, G. P., Kino, T. & Charmandari, E. Evaluation of the hypothalamic-pituitary-adrenal axis function in childhood and adolescence. NeuroImmunoModulation 16, 272–283 (2009).
Crichton, D. et al. The production and assessment of monoclonal antibodies to cortisol. Steroids 45, 503–517 (1985).
Lewis, J. G., Manley, L., Whitlow, J. C. & Elder, P. A. Production of a monoclonal antibody to cortisol: Application to a direct enzyme-linked immunosorbent assay of plasma. Steroids 57, 82–85 (1992).
Kobayashi, N. et al. Generation of a novel monoclonal antibody against cortisol-[C-4]-bovine serum albumin conjugate: Application to enzyme-linked immunosorbent assay for urinary and serum cortisol. Anal. Sci. 18, 1309–1314 (2002).
Hosoda, H., Kobayashi, N., Ishii, N. & Nambara, T. Bridging phenomena in steroid immunoassays. The effect of bridge length on sensitivity in enzyme immunoassay. Chem. Pharm. Bull. 34, 2105–2111 (1986).
Oyama, H. et al. Anti-idiotype scFv-enzyme fusion proteins: A clonable analyte-mimicking probe for standardized immunoassays targeting small biomarkers. Anal. Chem. 85, 11553–11559 (2013).
Reddy, S. T. et al. Monoclonal antibodies isolated without screening by analyzing the variable-gene repertoire of plasma cells. Nat. Biotechnol. 28, 965–969 (2010).
Hardiman, G. Next-generation antibody discovery platforms. Proc. Natl. Acad. Sci. USA. 109, 18245–18246 (2012).
Yang, W. et al. Next-generation sequencing enables the discovery of more diverse positive clones from a phage-displayed antibody library. Exp. Mol. Med. 49, e308 (2017).
Rouet, R., Jackson, K. J. L., Langley, D. B. & Christ, D. Next-generation sequencing of antibody display repertoires. Front. Immunol. 9, 118 (2018).
Crameri, A., Whitehorn, E. A., Tate, E. & Stemmer, W. P. C. Improved green fluorescent protein by molecular evolution using DNA shuffling. Nat. Biotechnol. 14, 315–319 (1996).
Jung, S. et al. The importance of framework residues H6, H7 and H10 in antibody heavy chains: experimental evidence for a new structural subclassification of antibody VH domains. J. Mol. Biol. 309, 701–716 (2001).
Dreher, M. L., Gherardi, E., Skerra, A. & Milstein, C. Colony assays for antibody fragments expressed in bacteria. J. Immunol. Methods 139, 197–205 (1991).
Stemmer, W. P., Morris, S. K. & Wilson, B. S. Selection of an active single chain Fv antibody from a protein linker library prepared by enzymatic inverse PCR. Biotechniques 14, 256–265 (1993).
Schlehuber, S., Beste, G. & Skerra, A. A novel type of receptor protein, based on the lipocalin scaffold, with specificity for digoxigenin. J. Mol. Biol. 297, 1105–1120 (2000).
Azriel-Rosenfeld, R., Valensi, M. & Benhar, I. A human synthetic combinatorial library of arrayable single-chain antibodies based on shuffling in vivo formed CDRs into general framework regions. J. Mol. Biol. 335, 177–192 (2004).
Buhr, D. L. et al. Use of micro-emulsion technology for the directed evolution of antibodies. Methods 58, 28–33 (2012).
Kobayashi, N., Karibe, T. & Goto, J. Dissociation-independent selection of high-affinity anti-hapten phage antibodies using cleavable biotin-conjugated haptens. Anal. Biochem. 347, 287–296 (2005).
Kobayashi, N. et al. “Cleavable” hapten-biotin conjugates: preparation and use for the generation of anti-steroid single-domain antibody fragments. Anal. Biochem. 387, 257–266 (2009).
Morita, I. et al. Antibody fragments for on-site testing of cannabinoids generated via in vitro affinity maturation. Biol. Pharm. Bull. 40, 174–181 (2017).
Morita, I. et al. Enantioselective monoclonal antibodies for detecting ketamine to crack down on illicit use. Biol. Pharm. Bull. 41, 123–131 (2018).
Guex, N., Diemand, A. & Peitsch, M. C. Protein modelling for all. Trends Biochem. Sci. 24, 364–367 (1999).
Grosdidier, A., Zoete, V. & Michielin, O. SwissDock, a protein-small molecule docking web service based on EADock DSS. Nucleic Acids Res. 39, W270–W277 (2011).
Acknowledgements
We thank Dr. Eskil Söderlind (Avena Partners AB, Sweden) and Professor Carl A. K. Borrebaeck (Lund University, Sweden) for allowing us to use the pEXmide 5 and 7 phagemid vectors. The KM13 helper phage was kindly donated from the Medical Research Council (UK). Edman sequencing of the scFv protein was performed in Apro Science (Naruto, Japan).
Author information
Authors and Affiliations
Contributions
N.K. conceived the project; N.K., Y. Kiguchi, and H.O. designed the research; Y. Kiguchi, H.O., I.M., M.M., A.N., W.F., Y.I., M.S., Y.S., Y. Kanemoto, K.M., Y.B., and A.T. performed the research and analyzed the data; N.K., Y. Kiguchi, and H.O. wrote the paper.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Kiguchi, Y., Oyama, H., Morita, I. et al. Clonal array profiling of scFv-displaying phages for high-throughput discovery of affinity-matured antibody mutants. Sci Rep 10, 14103 (2020). https://doi.org/10.1038/s41598-020-71037-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-71037-3
- Springer Nature Limited
This article is cited by
-
A high throughput bispecific antibody discovery pipeline
Communications Biology (2023)
-
Potential of Phage Display Antibody Technology for Cardiovascular Disease Immunotherapy
Journal of Cardiovascular Translational Research (2022)
-
The VH framework region 1 as a target of efficient mutagenesis for generating a variety of affinity-matured scFv mutants
Scientific Reports (2021)