Structural basis of neutralization of the major toxic component from the scorpion Centruroides noxius Hoffmann by a human-derived single-chain antibody fragment

It has previously been reported that several single-chain antibody fragments of human origin (scFv) neutralize the effects of two different scorpion venoms through interactions with the primary toxins of Centruroides noxius Hoffmann (Cn2) and Centruroides suffusus suffusus (Css2). Here we present the crystal structure of the complex formed between one scFv (9004G) and the Cn2 toxin, determined in two crystal forms at 2.5 and 1.9 Å resolution. A 15-residue span of the toxin is recognized by the antibody through a cleft formed by residues from five of the complementarity-determining regions of the scFv. Analysis of the interface of the complex reveals three features. First, the epitope of toxin Cn2 overlaps with essential residues for the binding of β-toxins to its Na⁺ channel receptor site. Second, the putative recognition of Css2 involves mainly residues that are present in both Cn2 and Css2 toxins. Finally, the effect on the increase of affinity of previously reported key residues during the maturation process of different scFvs can be inferred from the structure. Taken together, these results provide the structural basis that explain the mechanism of the 9004G neutralizing activity and give insight into the process of directed evolution that gave rise to this family of neutralizing scFvs.     

A Single Mutation in Framework 2 of the Heavy Variable Domain Improves the Properties of a Diabody and a Related Single-Chain Antibody

Excellent results regarding improved therapeutic properties have been often obtained through the conversion of a single‐chain variable fragment (scFv) into a noncovalent dimeric antibody (diabody) via peptide linker shortening. We utilized this approach to obtain a dimeric version of the human scFv 6009F, which was originally engineered to neutralize the Cn2 toxin of Centruroides noxius scorpion venom. However, some envenoming symptoms remained with diabody 6009F. Diabody 6009F was subjected to directed evolution to obtain a variant capable of eliminating envenoming symptoms. After two rounds of biopanning, diabody D4 was isolated. It exhibited a single mutation (E43G) in framework 2 of the heavy‐chain variable domain. Diabody D4 displayed an increase in T_m (thermal transition midpoint temperature) of 6.3 °C compared with its dimeric precursor. The importance of the E43G mutation was tested in the context of the human scFv LR, a highly efficient antibody against Cn2, which was previously generated by our group [Riaño-Umbarila, L., Contreras-Ferrat, G., Olamendi-Portugal, T., Morelos-Juárez, C., Corzo, G., Possani, L. D. and Becerril, B. (2011). J. Biol. Chem. 286, 6143–6151]. The new variant, scFv LER, displayed an increase in T_m of 3.4 °C and was capable of neutralizing 2 LD₅₀ of Cn2 toxin with no detectable symptoms when injected into mice at a 1:1 toxin-to-antibody molar ratio. These results showed that the E43G mutation might increase the therapeutic properties of these antibody fragments. Molecular modeling and dynamics results suggest that the rearrangement of the hydrogen-bonding network near the E43G mutation could explain the improved functional stability and neutralization properties of both the diabody D4 and scFv LER.     

Optimal Neutralization of Centruroides noxius Venom Is Understood through a Structural Complex between Two Antibody Fragments and the Cn2 Toxin

The current trend of using recombinant antibody fragments in research to develop novel antidotes against scorpion stings has achieved excellent results. The polyclonal character of commercial antivenoms, obtained through the immunization of animals and which contain several neutralizing antibodies that recognize different epitopes on the toxins, guarantees the neutralization of the venoms. To avoid the use of animals, we aimed to develop an equivalent recombinant antivenom composed of a few neutralizing single chain antibody fragments (scFvs) that bind to two different epitopes on the scorpion toxins. In this study, we obtained scFv RU1 derived from scFv C1. RU1 showed a good capacity to neutralize the Cn2 toxin and whole venom of the scorpion Centruroides noxius. Previously, we had produced scFv LR, obtained from a different parental fragment (scFv 3F). LR also showed a similar neutralizing capacity. The simultaneous administration of both scFvs resulted in improved protection, which was translated as a rapid recovery of previously poisoned animals. The crystallographic structure of the ternary complex scFv LR-Cn2-scFv RU1 allowed us to identify the areas of interaction of both scFvs with the toxin, which correspond to non-overlapping sites. The epitope recognized by scFv RU1 seems to be related to a greater efficiency in the neutralization of the whole venom. In addition, the structural analysis of the complex helped us to explain the cross-reactivity of these scFvs and how they neutralize the venom.     

Mapping of an epitope recognized by a neutralizing monoclonal antibody specific to toxin Cn2 from the scorpion Centruroides noxius, using discontinuous synthetic peptides.

The Na+-channel-affecting toxin Cn2 represents the major and one of the most toxic components of the venom of the Mexican scorpion Centruroides noxius Hoffmann. A monoclonal antibody BCF2 raised against Cn2 has been shown previously to be able to neutralize the toxic effect of Cn2 and of the whole venom of C. noxius. In the present study the epitope was mapped to a surface region comprising the N- and C-terminal segments of Cn2, using continuous and discontinuous synthetic peptides, designed on the basis of the sequence and a three-dimensional model of Cn2. The study of peptides of varying length resulted in the identification of segments 5-14 and 56-65 containing residues essential for recognition by BCF2. The peptide (abbreviated SP7) with the highest affinity to BCF2 (IC50 = 5.1 microM) was a synthetic heterodimer comprising the amino acid sequence from position 3-15 (amidated) of Cn2, bridged by disulfide to peptide from position 54-66, acetylated and amidated. Similar affinity was found with peptide SP1 [heterodimer comprising residues 1-14 (amidated) of Cn2, bridged with synthetic peptide 52-66 (acetylated)]. SP1 and SP7 were used to induce anti-peptide antibodies in mouse and rabbit. Both peptides were highly immunogenic. The sera obtained were able to recognize Cn2 and to neutralize Cn2 in vitro. The most efficient protection (8.3 microgram Cn2 neutralized per mL of serum) was induced by rabbit anti-SP1 serum.     

An nmr conformational analysis of a synthetic peptide Cn2(1-15)NH2-S-S-acetyl-Cn2(52-66)NH2 from the New World Centruroides noxius 2 (Cn2) scorpion toxin: comparison of the structure with those of the Centruroides scorpion toxins

The solution structure of a synthetic peptide, Cn2(1-15)NH2-S-S-acetyl-Cn2(52-66)NH2 from toxin 2 (Cn2) of the New World scorpion Centruroides noxius was determined using nmr and molecular dynamics calculations. The peptide has no significant secondary structure such as an alpha-helix or a beta-sheet, yet it has a fixed conformation for the first chain. The backbone secondary structure involving residues 6-12 in this peptide shows an excellent overlap with the structures of natural neurotoxins from Centruroides sculpturatus Ewing. Residues 6-9 form a distorted type I beta-turn and residues 10-12 form a gamma-turn. As residues 7-10 in the Centruroides toxins correspond to one of the regions of highest sequence variability, it may account for the species specificity and/or selectivity of toxic action. The conformation of this region evidently plays an important role in receptor recognition and in binding to the neutralizing monoclonal antibody BCF2 raised against the intact toxin.     

Exploiting cross-reactivity to neutralize two different scorpion venoms with one single chain antibody fragment

We report the optimization of a family of human single chain antibody fragments (scFv) for neutralizing two scorpion venoms. The parental scFv 3F recognizes the main toxins of Centruroides noxius Hoffmann (Cn2) and Centruroides suffusus suffusus (Css2), albeit with low affinity. This scFv was subjected to independent processes of directed evolution to improve its recognition toward Cn2 (Riaño-Umbarila, L., Juárez-González, V. R., Olamendi-Portugal, T., Ortíz-León, M., Possani, L. D., and Becerril, B. (2005) FEBS J. 272, 2591–2601) and Css2 (this work). Each evolved variant showed strong cross-reactivity against several toxins, and was capable of neutralizing Cn2 and Css2. Furthermore, each variant neutralized the whole venoms of the above species. As far as we know, this is the first report of antibodies with such characteristics. Maturation processes revealed key residue changes to attain expression, stability, and affinity improvements as compared with the parental scFv. Combination of these changes resulted in the scFv LR, which is capable of rescuing mice from severe envenomation by 3 LD₅₀ of freshly prepared whole venom of C. noxius (7.5 μg/20 g of mouse) and C. suffusus (26.25 μg/20 g of mouse), with surviving rates between 90 and 100%. Our research is leading to the formulation of an antivenom consisting of a discrete number of human scFvs endowed with strong cross-reactivity and low immunogenicity.     

Antibody BCF2 against scorpion toxin Cn2 from Centuroides noxius Hoffmann: primary structure and three-dimensional model as free Fv fragment and complexed with its antigen.

The antibody BCF2 generated against the mammal-specific toxin Cn2 of the scorpion Centuroides noxius Hoffmann neutralizes the effect of both the toxin and the venom. We cloned and sequenced the genes coding for the Fv fragment of BCF2. A three-dimensional (3D) model of the Fv fragment was generated using a knowledge-based approach. Furthermore, a 3D model of the complex Cn2-BCF2 was built using the nuclear magnetic resonance (NMR) structure of Cn2 and experimental results on a putative epitope region around the N and C termini. The initial complex conformations were submitted to a new refinement procedure of rigid-body energy minimization combined with flexible-side-chain molecular dynamics. The final complex, selected after an extensive evaluation, uses the loop 7-11 as the central part of the epitope. The generated complex allows the following conclusions: 1) the neutralizing capacity of BCF2 toward the venom of C. noxius might rather be caused by the high venom concentration and toxicity of Cn2 than by a broad specificity, 2) the region involved in the binding of Cn2 to the Na(+) channel, should overlap with the employed epitope region, and 3) contact residues SerL91, AsnL92, LeuH50, AspH56, TyrH95, and TyrH98 of BCF2 are candidates for mutations to broaden its specificity. Proteins 1999;37:130-143.     

CMG2-Fc 融合蛋白突变体筛选及中和炭疽毒素活性分析

目的:筛选能有效中和炭疽毒素和抵抗炭疽毒素损伤细胞的CMG2-Fc(炭疽毒素受体II-人免疫球蛋白Fc段融合蛋白)突变体。方法:运用FoldX等计算软件分析CMG2与PA晶体学结构,设计能提高CMG2-PA亲和力的突变体分子,并与人IgG1Fc片段构成融合基因,转染CHO-S细胞并通过亲和层析获得CMG2-Fc突变体蛋白,通过亲和力检测和细胞保护实验分析各突变体中和炭疽毒素能力。结果:筛选并表达了8个CMG2-Fc突变体分子,亲和力实验显示其中E117Q突变可明显提高CMG2-Fc与PA的亲和力(KD=1.35×10-11 mol/L),细胞保护实验提示E117Q突变能有效提高CMG2-Fc中和炭疽毒素能力(CMG2-Fc(E117Q)的IC50为15 ng/μL,而wt CMG2-Fc的IC50为50ng/μL)。结论:CMG2-Fc(E117Q)突变体分子可作为拮抗炭疽毒素损伤的炭疽治疗药物分子,进行进一步研究。     

A strategy for the generation of specific human antibodies by directed evolution and phage display. An example of a single-chain antibody fragment that neutralizes a major component of scorpion venom

This study describes the construction of a library of single-chain antibody fragments (scFvs) from a single human donor by individual amplification of all heavy and light variable domains (1.1 x 10(8) recombinants). The library was panned using the phage display technique, which allowed selection of specific scFvs (3F and C1) capable of recognizing Cn2, the major toxic component of Centruroides noxius scorpion venom. The scFv 3F was matured in vitro by three cycles of directed evolution. The use of stringent conditions in the third cycle allowed the selection of several improved clones. The best scFv obtained (6009F) was improved in terms of its affinity by 446-fold, from 183 nm (3F) to 410 pm. This scFv 6009F was able to neutralize 2 LD(50) of Cn2 toxin when a 1 : 10 molar ratio of toxin-to-antibody fragment was used. It was also able to neutralize 2 LD(50) of the whole venom. These results pave the way for the future generation of recombinant human antivenoms.     

Amino acid sequence and immunological characterization with monoclonal antibodies of two toxins from the venom of the scorpion Centruroides noxius Hoffmann.

Two toxins, which we propose to call toxins 2 and 3, were purified to homogeneity from the venom of the scorpion Centruroides noxius Hoffmann. The full primary structures of both peptides (66 amino acid residues each) was determined. Sequence comparison indicates that the two new toxins display 79% identity and present a high similarity to previously characterized Centruroides toxins, the most similar toxins being Centruroides suffusus toxin 2 and Centruroides limpidus tecomanus toxin 1. Six monoclonal antibodies (mAb) directed against purified fraction II-9.2 (which contains toxins 2 and 3) were isolated in order to carry out the immunochemical characterization of these toxins. mAb BCF2, BCF3, BCF7 and BCF9 reacted only with toxin 2, whereas BCF1 and BCF8 reacted with both toxins 2 and 3 with the same affinity. Simultaneous binding of mAb pairs to the toxin and cross-reactivity of the venoms of different scorpions with the mAb were examined. The results of these experiments showed that the mAb define four different epitopes (A-D). Epitope A (BCF8) is topographically unrelated to epitopes B (BCF2 and BCF7), C (BCF3) and D (BCF9) but the latter three appear to be more closely related or in close proximity to each other. Epitope A was found in all Centruroides venoms tested as well as on four different purified toxins of C. noxius, and thus seems to correspond to a highly conserved structure. Based on the cross-reactivity of their venoms with the mAb, Centruroides species could be classified in the following order: Centruroides elegans, Centruroides suffusus suffusus = Centruroides infamatus infamatus, Centruroides limpidus tecomanus, Centruroides limpidus limpidus, and Centruroides limpidus acatlanensis, according to increasing immunochemical relatedness of their toxins to those of Centruroides noxius. All six mAb inhibited the binding of toxin 2 to rat brain synaptosomal membranes, but only mAb BCF2, which belongs to the IgG2a subclass, displayed a clear neutralizing activity in vivo.     

The importance of framework residues H6, H7 and H10 in antibody heavy chains: experimental evidence for a new structural subclassification of antibody V(H) domains

The N-terminal segment (FR-H1) of the heavy chain (V(H)) of antibodies shows significant conformational variability correlating with the nature of the amino acids H6, H7 and H10 (Kabat H9). In this study, we have established a causal relationship between the local sequence and the structure of this framework region and linked this relationship to important biophysical properties such as affinity, folding yield and stability. We have generated six mutants of the scFv fragment aL2, covering some of the most abundant amino acid combinations in positions H6, H7 and H10 (according to a new consensus nomenclature, Kabat H9). For the aL2 wild-type (w.t.) with the sequence 6(Q)7(P)10(A) and for two of the mutants, the X-ray structures have been determined. The structure of the triple mutant aL2-6(E)7(S)10(G) shows the FR-H1 backbone conformations predicted for this amino acid combination, which is distinctly different from the structure of the w.t, thus supporting our hypothesis that these residues determine the conformation of this segment. The mutant aL2-6(E)7(P)10(G) represents a residue combination not occurring in natural antibody sequences. It shows a completely different, unique structure in the first beta-strand of V(H), not observed in natural Fv fragments and forms a novel type of diabody. Two V(H) domains of the mutant associate by swapping the first beta-strand. Concentration-dependent changes in Trp fluorescence indicate that this dimerization also occurs in solution. The mutations in amino acids H6, H7 and H10 (Kabat H9) influence the dimerization behavior of the scFv and its thermodynamic stability. All the observations reported here have practical implications for the cloning of Fv fragments with degenerate primers, as well as for the design of new antibodies by CDR grafting or synthetic libraries.     

Generation of affinity matured scFv antibodies against mouse neural cell adhesion molecule L1 by phage display

The recognition molecule L1 plays important functional roles in the nervous system and in non-neural tissues. Since antibodies to L1 are of prime importance to study its functional properties, we have generated affinity matured human single chain variable fragment (scFv) antibodies against mouse L1 by introducing random mutations in the complementarity determining regions (CDRs) of a previously isolated scFv antibody heavy chain (CDR1 and CDR2) and light chain (CDR3). After biopanning the mutant library, a clone (5F7) that gave the strongest ELISA signal was expressed, purified, and characterized. The dissociation constant of 5F7 (2.86 x 10(-8)M) was decreased 60-fold compared to the wild type clone G6 (1.72 x 10(-6)M). 5F7 detected L1 by Western blot analysis in mouse brain homogenates and recognized L1 in L1 transfected cells and cryosections from mouse retina and optic nerve by immunofluorescence. Bivalent 5F7 scFv antibody (5F7-Cys) was also generated and showed a dissociation constant of 5.22 x 10(-9)M that is 5.5-fold lower than that of monomeric 5F7 antibody. The bivalent affinity matured L1 scFv antibody thus showed stronger binding by a factor of 310 compared to the wild type clone. This antibody should be useful in various biological assays.     

Construction and functional evaluation of a single-chain antibody fragment that neutralizes toxin AahI from the venom of the scorpion Androctonus australis hector.

9C2 is a murine monoclonal IgG that participates in the neutralization of Androctonus australis hector scorpion venom. It recognizes AahI and AahIII, two of the three main neurotoxins responsible for almost all the toxicity of the venom when injected into mammals. Using PCR we cloned the antibody variable region coding genes from 9C2 hybridoma cells and constructed a gene encoding a single-chain antibody variable fragment molecule (scFv). This scFv was produced in the periplasm of Escherichia coli in a soluble and functional form and purified in a single step using protein L-agarose beads yielding 1-2 mg.L(-1) of bacterial culture. scFv9C2 was predominantly monomeric but also tended to form dimeric and oligomeric structures, all capable of binding toxin AahI. The affinity of scFv and the parental mAb for toxin AahI and homologous toxin AahIII was of the same magnitude, in the nanomolar range. Similarly, purified forms of scFv9C2 completely inhibited the binding of toxin AahI to rat brain synaptosomes. Finally, scFv9C2 was efficient in protecting mice against the toxic effects of AahI after injection of the toxin and scFv to mice by the intracerebroventricular route in a molar ratio as low as 0.36 : 1. Thus, we produced a recombinant scFv that reproduces the recognition properties of the parent antibody and neutralizes the scorpion neurotoxin AahI, thereby opening new prospects for the treatment of envenomation.     

Contributions of the Complementarity Determining Regions to the Thermal Stability of a Single-Domain Antibody

Single domain antibodies (sdAbs) are the recombinantly-expressed variable domain from camelid (or shark) heavy chain only antibodies and provide rugged recognition elements. Many sdAbs possess excellent affinity and specificity; most refold and are able to bind antigen after thermal denaturation. The sdAb A3, specific for the toxin Staphylococcal enterotoxin B (SEB), shows both sub-nanomolar affinity for its cognate antigen (0.14 nM) and an unusually high melting point of 85°C. Understanding the source of sdAb A3’s high melting temperature could provide a route for engineering improved melting temperatures into other sdAbs. The goal of this work was to determine how much of sdAb A3’s stability is derived from its complementarity determining regions (CDRs) versus its framework. Towards answering this question we constructed a series of CDR swap mutants in which the CDRs from unrelated sdAbs were integrated into A3’s framework and where A3’s CDRs were integrated into the framework of the other sdAbs. All three CDRs from A3 were moved to the frameworks of sdAb D1 (a ricin binder that melts at 50°C) and the anti-ricin sdAb C8 (melting point of 60°C). Similarly, the CDRs from sdAb D1 and sdAb C8 were moved to the sdAb A3 framework. In addition individual CDRs of sdAb A3 and sdAb D1 were swapped. Melting temperature and binding ability were assessed for each of the CDR-exchange mutants. This work showed that CDR2 plays a critical role in sdAb A3’s binding and stability. Overall, results from the CDR swaps indicate CDR interactions play a major role in the protein stability.     

Specificity tuning of antibody fragments to neutralize two human chemokines with a single agent

Chemokines are important mediators of the immune response that are responsible for the trafficking of immune cells between lymphoid organs and migration towards sites of inflammation. Using phage display selection and a functional screening approach, we have isolated a panel of single-chain fragment variable (scFv) capable of neutralizing the activity of the human chemokine CXCL10 (hCXCL10). One of the isolated scFv was weakly cross-reactive against another human chemokine CXCL9, but was unable to block its biological activity. We diversified the complementarity determining region 3 (CDR3) of the light chain variable domain (VL) of this scFv and combined phage display with high throughput antibody array screening to identify variants capable of neutralizing both chemokines. Using this approach it is therefore possible to engineer pan-specific antibodies that could prove very useful to antagonize redundant signaling pathways such as the chemokine signaling network.Key words: cross-reactive antibody, antibody arrays, chemotaxis, multiple targeting, affinity maturation, phage display     

Solution structure of toxin 2 from centruroides noxius Hoffmann, a beta-scorpion neurotoxin acting on sodium channels

We have determined the solution structure of Cn2, a beta-toxin extracted from the venom of the New World scorpion Centruroides noxius Hoffmann. Cn2 belongs to the family of scorpion toxins that affect the sodium channel activity, and is very toxic to mammals (LD50=0.4 microg/20 g mouse mass). The three-dimensional structure was determined using 1H-1H two-dimensional NMR spectroscopy, torsion angle dynamics, and restrained energy minimization. The final set of 15 structures was calculated from 876 experimental distance constraints and 58 angle constraints. The structures have a global r. m.s.d. of 1.38 A for backbone atoms and 2.21 A for all heavy atoms. The overall fold is similar to that found in the other scorpion toxins acting on sodium channels. It is made of a triple-stranded antiparallel beta-sheet and an alpha-helix, and is stabilized by four disulfide bridges. A cis-proline residue at position 59 induces a kink of the polypeptide chain in the C-terminal region. The hydrophobic core of the protein is made up of residues L5, V6, L51, A55, and by the eight cysteine residues. A hydrophobic patch is defined by the aromatic residues Y4, Y40, Y42, W47 and by V57 on the side of the beta-sheet facing the solvent. A positively charged patch is formed by K8 and K63 on one edge of the molecule in the C-terminal region. Another positively charged spot is represented by the highly exposed K35. The structure of Cn2 is compared with those of other scorpion toxins acting on sodium channels, in particular Aah II and CsE-v3. This is the first structural report of an anti-mammal beta-scorpion toxin and it provides the necessary information for the design of recombinant mutants that can be used to probe structure-function relationships in scorpion toxins affecting sodium channel activity.     

Using homology modeling to interrogate binding affinity in neutralization of ricin toxin by a family of single domain antibodies

In this report we investigated, within a group of closely related single domain camelid antibodies (V_HHs), the relationship between binding affinity and neutralizing activity as it pertains to ricin, a fast‐acting toxin and biothreat agent. The V1C7‐like V_HHs (V1C7, V2B9, V2E8, and V5C1) are similar in amino acid sequence, but differ in their binding affinities and toxin‐neutralizing activities. Using the X‐ray crystal structure of V1C7 in complex with ricin's enzymatic subunit (RTA) as a template, Rosetta‐based homology modeling coupled with energetic decomposition led us to predict that a single pairwise interaction between Arg29 on V5C1 and Glu67 on RTA was responsible for the difference in ricin toxin binding affinity between V1C7, a weak neutralizer, and V5C1, a moderate neutralizer. This prediction was borne out experimentally: substitution of Arg for Gly at position 29 enhanced V1C7's binding affinity for ricin, whereas the reverse (ie, Gly for Arg at position 29) diminished V5C1's binding affinity by >10 fold. As expected, the V5C1_R29G mutant was largely devoid of toxin‐neutralizing activity (TNA). However, the TNA of the V1C7_G29R mutant was not correspondingly improved, indicating that in the V1C7 family binding affinity alone does not account for differences in antibody function. V1C7 and V5C1, as well as their respective point mutants, recognized indistinguishable epitopes on RTA, at least at the level of sensitivity afforded by hydrogen‐deuterium mass spectrometry. The results of this study have implications for engineering therapeutic antibodies because they demonstrate that even subtle differences in epitope specificity can account for important differences in antibody function.     

Modeling the three-dimensional structures of an unbound single-chain variable fragment (scFv) and its hypothetical complex with a Corynespora cassiicola toxin, cassiicolin

Rubber trees infected with a host-specific cassiicolin toxin often experience considerable leaf fall, which in turn results in loss of crop productivity. It was recently revealed that cassiicolin-specific single-chain variable fragments (scFv) can successfully reduce the toxic effects of cassiicolin. However, the detailed mechanism of antibody action remains poorly understood. The primary sequence of the newly sequenced cassiicolin-specific scFv was highly homologous to several members of single-chain antibodies in the 14B7 family. In this study, with the aid of homology modeling, the three-dimensional structure of cassiicolin-specific scFv was elucidated, and was found to exhibit a characteristic immunoglobulin fold that mainly consists of β sheets. Additionally, molecular docking between the modeled scFv antibody and the available three-dimensional crystal structure of cassiicolin toxin was also performed. The predicted structural complex and the change in accessible surface area between the toxin and the scFv antibody upon complexation reveal the potential role of certain complementarity determining region (CDR) amino acid residues in the formation of the complex. These computational results suggest that mutagenesis experiments that are aimed at validating the model and improving the binding affinity of cassiicolin-specific scFv antibodies for the toxin should be performed.     

鼠源抗B型肉毒毒素单链抗体噬菌体文库的构建筛选及抗体免疫学活性的初步研究

B型肉毒毒素重链C-端片段(BoNTB/Hc)经金属螯和层析法纯化后免疫Balb/c小鼠,从其脾淋巴细胞中提取总RNA,反转录成cDNA,用抗体可变区混合引物进行全套抗体重、轻链可变区基因的扩增,体外随机装配成单链抗体(scFv)。将其克隆至pCANTAB5E中,构建单链抗体噬菌体抗体库。结果表明经过4轮"吸附-洗脱-扩增"的富集过程,筛选获得高亲和力的克隆。序列测定符合抗体可变区结构特点。     

Contributions of a highly conserved VH/VL hydrogen bonding interaction to scFv folding stability and refolding efficiency.

The assembly of single-chain Fv (scFv) antibody fragments, consisting of an interconnected variable heavy chain (VH) and variable light chain (VL), is a cooperative process that requires coupled folding and domain association. We report here an initial investigation of VH/VL domain-domain assembly with a site-directed mutagenesis study that probes a highly conserved VH/VL hydrogen bonding interaction. Gln168 of the S5 scFv (Kabat VH 39) is absolutely conserved in 95% of all VH, and Gln44 (Kabat VL 38) is found in 94% of all kappa VL (Glx in 95% of all lambda VL). These side chains form two hydrogen bonds in head-to-tail alignment across the VH/VL interface. Double mutant cycles at Gln168 and Gln44 were constructed to first investigate their contribution to thermodynamic folding stability, second to investigate whether stability can be improved, and third to determine whether refolding efficiencies are affected by mutations at these positions. The results demonstrate that the Gln168-Gln44 interaction is not a key determinant of S5 scFv folding stability, as sequential modification to alanine has no significant effect on the free energy of folding. Several mutations that alter the glutamines to methionine or charged amino acids significantly increase the thermodynamic stability by increasing the m(g) associated with the unfolding isotherm. These effects are hypothesized to arise largely from an increase in the VH/VL association free energy that leads to tighter coupling between domain-domain association and folding. All of the mutants also display a reduced antigen binding affinity. Single and double methionine mutants also displayed significant increases in refolding efficiency of 2.4- to 3-fold over the native scFv, whereas the double alanine/methionine mutants displayed moderate 1.9- to 2.4-fold enhancement. The results suggest that reengineering the VH/VL interface could be useful in improving the stability of single-chain antibodies, as Ala/Met mutations at these conserved positions increase the free energy of folding by 46% while minimally perturbing binding affinity. They also could be useful in improving scFv recovery from inclusion bodies as the mutations increase the refolding efficiency by more than twofold.