Analysis of the binding loops configuration and surface adaptation of different crystallized single‐domain antibodies in response to various antigens

Monoclonal antibodies have revolutionized the biomedical field through their ubiquitous utilization in different diagnostics and therapeutic applications. Despite this widespread use, their large size and structural complexity have limited their versatility in specific applications. The antibody variable region that is responsible for binding antigen is embodied within domains that can be rescued individually as single‐domain antibody (sdAb) fragments. Because of the unique characteristics of sdAbs, such as low molecular weight, high physicochemical stability, and the ability to bind antigens inaccessible to conventional antibodies, they represent a viable alternative to full‐length antibodies. Consequently, 149 crystal structures of sdAbs, originating from human (VH), camelids (VHH), or sharks (VNAR), were retrieved from the Protein Data Bank, and their structures were compared. The 3 types of sdAbs displayed complementarity determining regions (CDRs) with different lengths and configurations. CDR3 of the VHH and VNAR domains were dominated by pleated and extended orientations, respectively. Although VNAR showed the smallest average molecular weight and molecular surface area compared with VHH and VH antibodies. However, the solvent accessible surface area measurements of the 3 tested sdAbs types were very similar. All the antihapten VHH antibodies showed pleated CDR3, which were sufficient to create a binding pocket to accommodate haptens (methotrexate and azo dyes) in terms of shape and electrostatic potential. The sdAbs that recognized lysozyme showed more diversity in their CDR3 orientation to enable them to recognize various topographies of lysozyme. Subsequently, the three sdAb classes were different in size and surface area and have shown distinguishable ability to optimize their CDR length and orientation to recognize different antigen classes.     

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.     

Antigen recognition by single-domain antibodies: structural latitudes and constraints

Single-domain antibodies (sdAbs), the autonomous variable domains of heavy chain-only antibodies produced naturally by camelid ungulates and cartilaginous fishes, have evolved to bind antigen using only three complementarity-determining region (CDR) loops rather than the six present in conventional V_H:V_L antibodies. It has been suggested, based on limited evidence, that sdAbs may adopt paratope structures that predispose them to preferential recognition of recessed protein epitopes, but poor or non-recognition of protuberant epitopes and small molecules. Here, we comprehensively surveyed the evidence in support of this hypothesis. We found some support for a global structural difference in the paratope shapes of sdAbs compared with those of conventional antibodies: sdAb paratopes have smaller molecular surface areas and diameters, more commonly have non-canonical CDR1 and CDR2 structures, and have elongated CDR3 length distributions, but have similar amino acid compositions and are no more extended (interatomic distance measured from CDR base to tip) than conventional antibody paratopes. Comparison of X-ray crystal structures of sdAbs and conventional antibodies in complex with cognate antigens showed that sdAbs and conventional antibodies bury similar solvent-exposed surface areas on proteins and form similar types of non-covalent interactions, although these are more concentrated in the compact sdAb paratope. Thus, sdAbs likely have privileged access to distinct antigenic regions on proteins, but only owing to their small molecular size and not to general differences in molecular recognition mechanism. The evidence surrounding the purported inability of sdAbs to bind small molecules was less clear. The available data provide a structural framework for understanding the evolutionary emergence and function of autonomous heavy chain-only antibodies.     

Evaluation of a noncanonical Cys40‐Cys55 disulfide linkage for stabilization of single‐domain antibodies

Incorporation of noncanonical disulfide linkages into single‐domain antibodies (sdAbs) has been shown to enhance thermostability and other properties. Here, we evaluated the effects of introducing a novel disulfide linkage formed between Cys residues at IMGT positions 40 and 55 on the melting temperatures (T _ms), reversibility of thermal unfolding, solubility, and antigen‐binding affinities of three types of sdAbs (V_HH, V_H, and V_L domains). The Cys40‐Cys55 disulfide linkage was tolerated by 9/9 V_HHs, 12/12 V_Hs, and 2/11 V_Ls tested and its formation was confirmed by mass spectrometry. Using circular dichroism, we found that the Cys40‐Cys55 disulfide linkage increased sdAb T _m by an average of 10.0°C (range: 0–21.8°C). However, enhanced thermostability came at the cost of a partial loss of refolding ability upon thermal denaturation as well as, for some sdAbs, significantly decreased solubility and antigen‐binding affinity. Thus, Cys40/Cys55 can be added to the panel of known locations for introducing stabilizing noncanonical disulfide linkages into antibody variable domains, although its effects should be tested empirically for individual sdAbs.     

By-passing immunisation. Human antibodies from synthetic repertoires of germline VH gene segments rearranged in vitro.

By display of antibody repertoires on the surface of a filamentous bacteriophage and selection of the phage by binding to antigen, we can mimic immune selection. Recently, by tapping the repertoire of rearranged V-genes from the peripheral blood lymphocytes of unimmunised donors, we succeeded in making human antibody fragments with different specificities, including both haptens and proteins, from the same library of phage. Now we have built a repertoire of human VH genes from 49 human germline VH gene segments rearranged in vitro to create a synthetic third complementarity determining region (CDR) of five or eight residues. The rearranged VH genes were cloned with a human V lambda 3 light chain as single chain Fv fragments for phage display, and the library of phage panned by binding to each of two haptens, 2-phenyl-5-oxazolone (phOx) or 3-iodo-4-hydroxy-5-nitrophenyl-acetate (NIP) coupled to bovine serum albumin (BSA). Many different antibody fragments were isolated which bound specifically to hapten, some with affinities in the micromolar range. The in vitro "immune response" to the hapten NIP was dominated by the 9-1 segment (VH3 family), and that to phOx by the VH26 segment (VH3 family) with an invariant aromatic residue (Tyr, Phe, Trp) at residue 97 of CDR3. However, the isolation of phage against protein antigens proved more elusive, with a single phage binding to human tumour necrosis factor, and none to bovine serum albumin, turkey egg-white lysozyme or human thyroglobulin. Nevertheless, the work shows that human antibody fragments with specific binding activities can be made entirely in vitro.     

Pentamerization of single-domain antibodies from phage libraries: a novel strategy for the rapid generation of high-avidity antibody reagents

We describe a novel type of molecule in which single-domain antibodies (sdAbs) isolated from a nai;ve llama single domain antibody library are linked to an oligomerization domain to generate high-avidity, antigen-binding reagents. An sdAb is fused to the B-subunit of Escherichia coli verotoxin, or shiga-like toxin, which self-assembles to form a homopentamer and results in simultaneous sdAb pentamerization and introduction of avidity. Molecular modeling indicated that this fusion protein (PDB: 1OJF), termed pentabody, has structural flexibility for binding to surface-presented antigen. In the instance of an sdAb specific for a peptide antigen, pentamerization resulted in a dramatic increase in functional affinity for immobilized antigen. The pentabody was expressed in high yield in E.coli in a non-aggregated state, and exhibited excellent thermostability and protease resistance. This technology provides a relatively rapid means of generating novel antigen-binding molecules that bind strongly to immobilized antigen. It is expected that pentavalent sdAbs will have general applicability in proteomics, immunochemical staining, cancer diagnosis and other applications in which antigens are presented multivalently.     

Paratope Duality and Gullying are Among the Atypical Recognition Mechanisms Used by a Trio of Nanobodies to Differentiate Ebolavirus Nucleoproteins

We had previously shown that three anti–Marburg virus nanobodies (VHH or single-domain antibody [sdAb]) targeted a cryptotope within an alpha-helical assembly at the nucleoprotein (NP) C-terminus that was conserved through half a century of viral evolution. Here, we wished to determine whether an anti–Ebola virus sdAb, that was cross-reactive within the Ebolavirus genus, recognized a similar structural feature upstream of the ebolavirus NP C-terminus. In addition, we sought to determine whether the specificities of a less cross-reactive anti–Zaire ebolavirus sdAb and a totally specific anti–Sudan ebolavirus sdAb were the result of exclusion from this region. Binding and X-ray crystallographic studies revealed that the primary determinant of cross-reactivity did indeed appear to be a preference for the helical feature. Specificity, in the case of the Zaire ebolavirus–specific sdAb, arose from the footprint shifting away from the helices to engage more variable residues. While both sdAbs used CDRs, they also had atypical side-on approaches, with framework 2 helping to accommodate parts of the epitope in sizeable paratope gullies. The Sudan ebolavirus–specific sdAb was more remarkable and appeared to bind two C-terminal domains simultaneously via nonoverlapping epitopes—“paratope duality.” One mode involved paratope gullying, whereas the other involved only CDRs, with CDR3 restructuring to wedge in between opposing walls of an interdomain crevice. The varied routes used by sdAbs to engage antigens discovered here deepen our appreciation of the small scaffold's architectural versatility and also reveal lucrative opportunities within the ebolavirus NP C-termini that might be leveraged for diagnostics and novel therapeutic targeting.     

“Cleavable” hapten-biotin conjugates: Preparation and use for the generation of anti-steroid single-domain antibody fragments

Antibody engineering technology has the potential to provide artificial antibodies with higher performance than conventional antibodies. Filamentous phage particles are often used to express a vast diversity of mutated antibody fragments from which clones displaying improved fragments can be isolated. We recently showed that hapten-biotin conjugates, combined via a linker involving a reductively cleavable disulfide bond, are useful for isolating phage clones displaying high-affinity anti-hapten antibody fragments. Here we prepare cleavable hapten-biotin conjugates and use them to isolate anti-hapten antibody fragments with relatively low affinities. Three diagnostically important steroids (estradiol-17β [E₂], cortisol, and 17α-hydroxyprogesterone) were each coupled with a biotin derivative containing a disulfide bond. These conjugates could be bound simultaneously by their relevant anti-steroid antibody and NeutrAvidin, and their linkers were easily cleaved by dithiothreitol (DTT) treatment. The E₂-biotin conjugate was used to generate anti-E₂ single-domain antibody fragments (sdAbs). Random point mutations were introduced by error-prone PCR into the gene fragment encoding the V_H domain of a mouse anti-E₂ antibody, and these products were expressed as phagemid particles that were reacted with the E₂-biotin conjugates that had already been immobilized on a solid-phase via NeutrAvidin. Thorough washing off of nonspecific phages and subsequent DTT treatment provided a phagemid clone that displayed a mutated sdAb with improved binding properties.     

A phage‐displayed single‐chain Fab library optimized for rapid production of single‐chain IgGs

Phage‐displayed synthetic antibody (Ab) repertoires have become a major source of affinity reagents for basic and clinical research. Specific Abs identified from such libraries are often screened as fragments antigen binding (Fabs) produced in bacteria, and those with desired biochemical characteristics are reformatted for production as full‐length immunoglobulin G (IgG) in mammalian cells. The conversion of Fabs to IgGs is a cumbersome and often rate‐limiting step in the development of Abs. Moreover, biochemical properties required for lead IgG development are not always shared by the Fabs, and these issues are not uncovered until a significant effort has been spent on Abs that ultimately will not be useful. Thus, there is a need for simple and rapid techniques to convert phage‐displayed Fabs to IgGs at an early stage of the Ab screening process. We report the generation of a highly diverse phage‐displayed synthetic single‐chain Fab (scFab) library, in which the light and heavy chains were tethered with an optimized linker. Following selection, pools of scFabs were converted to single‐chain IgGs (scIgGs) en masse, enabling facile screening of hundreds of phage‐derived scIgGs. We show that this approach can be used to rapidly screen for and select scIgGs that target cell‐surface receptors, and scIgGs behave the same as conventional IgGs.     

Steric Accessibility of the Cleavage Sites Dictates the Proteolytic Vulnerability of the Anti‐HIV‐1 Antibodies 2F5, 2G12, and PG9 in Plants

Broadly neutralizing antibodies (bNAbs) to human immunodeficiency virus type 1 (HIV‐1) hold great promise for immunoprophylaxis and the suppression of viremia in HIV‐positive individuals. Several studies have demonstrated that plants as Nicotiana benthamiana are suitable hosts for the generation of protective anti‐HIV‐1 antibodies. However, the production of the anti‐HIV‐1 bNAbs 2F5 and PG9 in N. benthamiana is associated with their processing by apoplastic proteases in the complementarity‐determining‐region (CDR) H3 loops of the heavy chains. Here, it is shown that apoplastic proteases can also cleave the CDR H3 loop of the bNAb 2G12 when the unusual domain exchange between its heavy chains is prevented by the replacement of Ile¹⁹ with Arg. It is demonstrated that CDR H3 proteolysis leads to a strong reduction of the antigen‐binding potencies of 2F5, PG9, and 2G12‐I19R. Inhibitor profiling experiments indicate that different subtilisin‐like serine proteases account for bNAb fragmentation in the apoplast. Differential scanning calorimetry experiments corroborate that the antigen‐binding domains of wild‐type 2G12 and 4E10 are more compact than those of proteolysis‐sensitive antibodies, thus shielding their CDR H3 regions from proteolytic attack. This suggests that the extent of proteolytic inactivation of bNAbs in plants is primarily dictated by the steric accessibility of their CDR H3 loops.     

Multiplexed fluid array screening of phage displayed anti-ricin single domain antibodies for rapid assessment of specificity

Phage display is a well-known technique that facilitates the selection of peptides or proteins that bind to a desired target. Using this tool, binding elements contained in the natural immune repertoires of the source animal or from a synthetically generated collection may be selected. The unpaired variable domain of the llama's heavy-chain-only classes of immunoglobulins represents an ideal source of genetic material to create phage display libraries. Initial panning of a semi-synthetic llama library yielded only one binder to the toxin ricin. In an effort to increase the number of monoclonal phage binders selected, the Luminex xMAP technology (Luminex, Austin, TX, USA) was used in addition to the enzyme-linked immunosorbent assay (ELISA) to screen clonal populations of phage after three rounds of selection. The xMAP technology detected phage displayed single domain antibody (sdAb) bound to ricin immobilized on the surface of microspheres under equilibrium conditions. This enhanced capability led directly to the identification of additional single domain antibodies of interest. The selected sdAbs were expressed, purified, and then evaluated for their specificity as well as enhanced thermal stability in comparison to conventional immunoglobulin G (IgG). We determined equilibrium dissociation constants and demonstrated their use as effective capture molecules in sandwich immunoassays.     

Rugged single domain antibody detection elements for Bacillus anthracis spores and vegetative cells

Significant efforts to develop both laboratory and field-based detection assays for an array of potential biological threats started well before the anthrax attacks of 2001 and have continued with renewed urgency following. While numerous assays and methods have been explored that are suitable for laboratory utilization, detection in the field is often complicated by requirements for functionality in austere environments, where limited cold-chain facilities exist. In an effort to overcome these assay limitations for Bacillus anthracis, one of the most recognizable threats, a series of single domain antibodies (sdAbs) were isolated from a phage display library prepared from immunized llamas. Characterization of target specificity, affinity, and thermal stability was conducted for six sdAb families isolated from rounds of selection against the bacterial spore. The protein target for all six sdAb families was determined to be the S-layer protein EA1, which is present in both vegetative cells and bacterial spores. All of the sdAbs examined exhibited a high degree of specificity for the target bacterium and its spore, with affinities in the nanomolar range, and the ability to refold into functional antigen-binding molecules following several rounds of thermal denaturation and refolding. This research demonstrates the capabilities of these sdAbs and their potential for integration into current and developing assays and biosensors.     

从大容量噬菌体抗体库中筛选抗Acr蛋白人源单链抗体

目的:从天然的大容量噬菌体抗体库中筛选特异的抗结核分枝杆菌晶体蛋白( alpha-crystallin Acr)的人源抗体.方法:以结核分枝杆菌Acr蛋白包被免疫管,通过对噬菌体抗体库进行4轮“吸附-洗脱-扩增”的过程从大容量抗体库中筛选特异性抗结核分枝杆菌Acr蛋白的抗体,并对可变区序列进行了测序分析.将特异性的噬菌体抗体感染HB2151菌,经IPTG诱导表达,制备了抗结核分枝杆菌Acr蛋白的可溶性单链抗体;对其序列和抗原结合活性进行分析鉴定.结果:经过4轮筛选,获得了43个与结核分枝杆菌Acr蛋白结合的阳性克隆,其中29个特异结合的克隆;测序分析有26不同的可变区片段;通过可溶性单链抗体(scFv)表达筛选到14株特异性结合Acr蛋白的可溶性单链抗体克隆;经过基因测序,分析了可变区基因的亚群.成功制备了可溶性单链抗体.Westren blotting分析证实筛选的人源单链抗体能与天然蛋白结合.结论:利用单链大容量抗体库获得抗结核分枝杆菌Acr蛋白的噬菌体抗体并且成功制备抗结核分枝杆菌Acr天然蛋白的可溶性单链抗体,为今后的研究和应用奠定基础.     

Crystal structure of a 3B3 variant—A broadly neutralizing HIV‐1 scFv antibody

We present the crystal structure determination of an anti‐HIV‐1 gp120 single‐chain variable fragment antibody variant, 3B3, at 2.5 Å resolution. This 3B3 variant was derived from the b12 antibody, using phage display and site‐directed mutagenesis of the variable heavy chain (V_H) complementary‐determining regions (CDRs). 3B3 exhibits enhanced binding affinity and neutralization activity against several cross‐clade primary isolates of HIV‐1 by interaction with the recessed CD4‐binding site on the gp120 envelope protein. Comparison with the structures of the unbound and bound forms of b12, the 3B3 structure closely resembles these structures with minimal differences with two notable exceptions. First, there is a reorientation of the CDR‐H3 of the V_H domain where the primary sequences evolved from b12 to 3B3. The structural changes in CDR‐H3 of 3B3, in light of the b12‐gp120 complex structure, allow for positioning an additional Trp side chain in the binding interface with gp120. Finally, the second region of structural change involves two peptide bond flips in CDR‐L3 of the variable light (V_L) domain triggered by a point mutation in CDR‐H3 of Q100eY resulting in changes in the intramolecular hydrogen bonding patterning between the V_L and V_H domains. Thus, the enhanced binding affinities and neutralization capabilities of 3B3 relative to b12 probably result from higher hydrophobic driving potential by burying more aromatic residues at the 3B3‐gp120 interface and by indirect stabilization of intramolecular contacts of the core framework residues between the V_L and V_H domains possibly through more favorable entropic effect through the expulsion of water.     

An anti-hapten camelid antibody reveals a cryptic binding site with significant energetic contributions from a nonhypervariable loop

Conventional anti-hapten antibodies typically bind low-molecular weight compounds (haptens) in the crevice between the variable heavy and light chains. Conversely, heavy chain-only camelid antibodies, which lack a light chain, must rely entirely on a single variable domain to recognize haptens. While several anti-hapten VHHs have been generated, little is known regarding the underlying structural and thermodynamic basis for hapten recognition. Here, an anti-methotrexate VHH (anti-MTX VHH) was generated using grafting methods whereby the three complementarity determining regions (CDRs) were inserted onto an existing VHH framework. Thermodynamic analysis of the anti-MTX VHH CDR1-3 Graft revealed a micromolar binding affinity, while the crystal structure of the complex revealed a somewhat surprising noncanonical binding site which involved MTX tunneling under the CDR1 loop. Due to the close proximity of MTX to CDR4, a nonhypervariable loop, the CDR4 loop sequence was subsequently introduced into the CDR1-3 graft, which resulted in a dramatic 1000-fold increase in the binding affinity. Crystal structure analysis of both the free and complex anti-MTX CDR1-4 graft revealed CDR4 plays a significant role in both intermolecular contacts and binding site conformation that appear to contribute toward high affinity binding. Additionally, the anti-MTX VHH possessed relatively high specificity for MTX over closely related compounds aminopterin and folate, demonstrating that VHH domains are capable of binding low-molecular weight ligands with high affinity and specificity, despite their reduced interface.     

Selection,characterization, and thermal stabilization of llama single domain antibodies towards Ebola virus glycoprotein

Background

A key advantage of recombinant antibody technology is the ability to optimize and tailor reagents. Single domain antibodies (sdAbs), the recombinantly produced variable domains derived from camelid and shark heavy chain antibodies, provide advantages of stability and solubility and can be further engineered to enhance their properties. In this study, we generated sdAbs specific for Ebola virus envelope glycoprotein (GP) and increased their stability to expand their utility for use in austere locals. Ebola virus is extremely virulent and causes fatal hemorrhagic fever in ~ 50 percent of the cases. The viral GP binds to host cell receptors to facilitate viral entry and thus plays a critical role in pathogenicity.

Results

An immune phage display library containing more than 10⁷ unique clones was developed from a llama immunized with a combination of killed Ebola virus and recombinantly produced GP. We panned the library to obtain GP binding sdAbs and isolated sdAbs from 5 distinct sequence families. Three GP binders with dissociation constants ranging from ~ 2 to 20 nM, and melting temperatures from ~ 57 to 72 °C were selected for protein engineering in order to increase their stability through a combination of consensus sequence mutagenesis and the addition of a non-canonical disulfide bond. These changes served to increase the melting temperatures of the sdAbs by 15–17 °C. In addition, fusion of a short positively charged tail to the C-terminus which provided ideal sites for the chemical modification of these sdAbs resulted in improved limits of detection of GP and Ebola virus like particles while serving as tracer antibodies.

Conclusions

SdAbs specific for Ebola GP were selected and their stability and functionality were improved utilizing protein engineering. Thermal stability of antibody reagents may be of particular importance when operating in austere locations that lack reliable refrigeration. Future efforts can evaluate the potential of these isolated sdAbs as candidates for diagnostic or therapeutic applications for Ebola.

     

Preferential selection of Cys‐constrained peptides from a random phage‐displayed library by anti‐glucitollysine antibodies

Phage‐displayed peptides recognized by two monoclonal antibodies against glucitollysine were selected. The most prominent feature of the peptide panel was the presence of paired Cys in most of them (21/24 peptides). The availability of a wide variety of peptides having differently spaced paired Cys, as well as truly linear Cys‐free peptides, gave the opportunity to explore the role of disulfide bridges in phage selection. Some Cys‐containing peptides came from a Cys‐flanked cyclic 9‐mer library, but most of them (18/21) were derived from a totally random 12‐mer library, and hence the presence of Cys was dictated by the selector antibodies. Motifs shared by several peptides (potentially involved in binding) often contained or were flanked by Cys residues. Binding of all Cys‐containing phage‐displayed peptides was abolished/decreased after a reducing treatment. Screening a random peptide library (without invariant Cys residues) is powerful enough to clearly reveal the need, preferences, and diversity of Cys‐mediated structural constraints for recognition. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

人源抗ICAM-1单链抗体的制备及其生物学活性鉴定

利用噬菌体展示技术筛选特异性人源抗ICAM-1单链抗体（Anti-human ICAM-1 scFv）并进行生物学活性鉴定。应用Tomlinson I+J噬菌体抗体库,以P1抗原肽为包被抗原,经过4轮“吸附-洗脱-扩增”进行亲和富集筛选。以PCR反应、ELISA抗原交叉反应和Dot blotting实验进行阳性克隆的鉴定。scFv经原核表达和分离纯化后,以Western blotting实验、竞争ELISA实验和细胞黏附抑制实验对其生物学活性进行初步鉴定。Tomlinson I+J噬菌体抗体库经4轮亲和富集筛选,利用ELISA方法成功筛出4株阳性克隆。通过PCR鉴定反应、ELISA抗原交叉反应和Dot blotting实验,最终获得了1株既能与P1抗原肽特异结合又能与人ICAM-1抗原特异结合的阳性克隆J-A1。对scFv进行原核表达和亲和层析后获得了高纯度的目的蛋白。竞争ELISA实验和细胞黏附抑制实验证实纯化的scFv具有良好的亲和活性和抗细胞黏附活性。文中成功利用噬菌体展示技术筛选到特异性人源抗ICAM-1 scFv,为进一步探索该抗体在炎症相关性疾病治疗中的应用奠定了基础。     

Isolation and characterization of phage-displayed single chain antibodies recognizing nonreducing terminal mannose residues. 1. A new strategy for generation of anti-carbohydrate antibodies

Phage-display technology is probably the best available strategy to produce antibodies directed against various carbohydrate moieties since conventional hybridoma technologies have yielded mostly low-affinity antibodies against a limited number of carbohydrate antigens. Because of difficulties in immobilization of carbohydrate antigens onto plastic plates, however, the same procedures used for protein antigens cannot be readily applied. We adapted phage-display technology to generate human single chain antibodies (scFvs) using neoglycolipids as antigens. This study describes the isolation and characterization of phage-displayed antibodies (phage Abs) that recognized nonreducing terminal mannose residues. We first constructed a phage Ab library with a large repertoire using CDR shuffling and VL/VH shuffling methods with unique vector constructs. The library was subjected to four rounds of panning against neoglycolipids synthesized from mannotriose (Man3) and dipalmitoylphosphatidylethanolamine (DPPE) by reductive amination. Of 672 clones screened by enzyme-linked immunosorbent assay (ELISA) using Man3-DPPE as an antigen, 25 positive clones encoding scFvs with unique amino acid sequences were isolated as candidates for phage Abs against Man3 residues. TLC-overlay assays and surface plasmon resonance analyses revealed that selected phage Abs bound to neoglycolipids bearing mannose residues at nonreducing termini. In addition, binding of the phage Ab to RNase B carrying high mannose type oligosaccharides but not to fetuin carrying complex type and O-linked oligosaccharides was confirmed. Furthermore, first round characterization of scFvs expressed from respective phages indicated good affinity and specificity for nonreducing terminal mannose residues. These results demonstrated the usefulness of this strategy in constructing human scFv against various carbohydrate antigens. Further studies on the purification and characterization of these scFvs are presented in an accompanying paper in this issue.     

Structure and specificity of several triclocarban‐binding single domain camelid antibody fragments

The variable VHH domains of camelid single chain antibodies have been useful in numerous biotechnology applications due to their simplicity, biophysical properties, and abilities to bind to their cognate antigens with high affinities and specificity. Their interactions with proteins have been well‐studied, but considerably less work has been done to characterize their ability to bind haptens. A high‐resolution structural study of three nanobodies (T4, T9, and T10) which have been shown to bind triclocarban (TCC, 3‐(4‐chlorophenyl)‐1‐(3,4‐dichlorophenyl)urea) with near‐nanomolar affinity shows that binding occurs in a tunnel largely formed by CDR1 rather than a surface or lateral binding mode seen in other nanobody‐hapten interactions. Additional significant interactions are formed with a non‐hypervariable loop, sometimes dubbed “CDR4”. A comparison of apo and holo forms of T9 and T10 shows that the binding site undergoes little conformational change upon binding of TCC. Structures of three nanobody‐TCC complexes demonstrated there was not a standard binding mode. T4 and T9 have a high degree of sequence identity and bind the hapten in a nearly identical manner, while the more divergent T10 binds TCC in a slightly displaced orientation with the urea moiety rotated approximately 180° along the long axis of the molecule. In addition to methotrexate, this is the second report of haptens binding in a tunnel formed by CDR1, suggesting that compounds with similar hydrophobicity and shape could be recognized by nanobodies in analogous fashion. Structure‐guided mutations failed to improve binding affinity for T4 and T9 underscoring the high degree of natural optimization.