Design and expression of soluble CTLA-4 variable domain as a scaffold for the display of functional polypeptides.

We have designed and engineered the human cytotoxic T-lymphocyte associated protein-4 (CTLA-4) variable (V-like) domain to produce a human-based protein scaffold for peptide display. First, to test whether the CTLA-4 CDR-like loops were permissive to loop replacement/insertion we substituted either the CDR1 or CDR3 loop with somatostatin, a 14-residue intra-disulfide-linked neuropeptide. Upon expression as periplasmic-targeted proteins in Escherichia coli, molecules with superior solubility characteristics to the wild-type V-domain were produced. These mutations in CTLA-4 ablated binding to its natural ligands CD80 and CD86, whereas binding to a conformation-dependent anti-CTLA-4 monoclonal antibody showed that the V-domain framework remained correctly folded. Secondly, to develop a system for library selection, we displayed both wild-type and mutated CTLA-4 proteins on the surface of fd-bacteriophage as fusions with the geneIII protein. CTLA-4 displayed on phage bound specifically to immobilized CD80-Ig and CD86-Ig and in one-step panning enriched 5,000 to 2,600-fold respectively over wild-type phage. Bacteriophage displaying CTLA-4 with somatostatin in CDR3 (CTLA-4R-Som3) specifically bound somatostatin receptors on transfected CHO-K1 cells pre-incubated with 1 microg/ml tunicamycin to remove receptor glycosylation. Binding was specific, as 1 microM somatostatin successfully competed with CTLA-4R-Som3. CTLA-4R-Som3 also activated as well as binding preferentially to non-glycosylated receptor subtype Sst4. The ability to substitute CDR-like loops within CTLA-4 will enable design and construction of more complex libraries of single V-like domain binding molecules. Proteins 1999;36:217-227.     

Building novel binding ligands to B7.1 and B7.2 based on human antibody single variable light chain domains.

Ligands specific for B7.1 (CD80) and B7.2 (CD86) have applications in disease indications that require inhibition of T-cell activity. As we observed significant sequence and structural similarity between the B7-binding ligand, cytotoxic T-lymphocyte associated protein-4 (CTLA-4), and antibody variable light chain domains (VLs), we have explored the possibilities of making novel B7 binding molecules based on single VL domains.We first describe the "rational" design and construction of a VL/CTLA-4 hybrid molecule in which we have grafted both the CDR1 and CDR3-like loops of CTLA-4 onto a single VL light chain, at sites determined by sequence and structure-based alignment. This molecule was secreted as a soluble product from Escherichia coli, but did not show any binding to B7.1 and B7.2. In a second approach we constructed a VL library in which human VL genes derived from B-cells were spiked with the CDR3-like loop of CTLA-4 and further diversified by DNA shuffling. This library was displayed on phage, and after selection gave B7.1 binding ligands which competed with CTLA-4. In order to evaluate the possible general utility of VL domains as binding ligands, we have constructed a non-biased VL library. From this DNA-shuffled human VL library we have selected single VL domains specific for B7.1, B7.2 or human IgG. Two B7.1-specific VL ligands and one B7.2-specific VL ligand showed competition with CTLA-4. One candidate VL domain-specific for B7.1 was affinity matured by simultaneous randomisation of all CDR loops using DNA shuffling with degenerate CDR-spiking oligonucleotides. From this library, a single VL domain with affinity of 191 nM for B7.1 was obtained, which also showed binding to B7.1 in situ. This VL had mutations in CDR1 and CDR3, indicating that antigen recognition for this single VL is most likely mediated by the same regions as in the VL domain of whole antibodies.The B7.1 and B7.2-specific VL domains described in this study may form the basis of a new family of immunomodulatory recombinant molecules. Furthermore, our studies suggest that it is feasible to create specific single VL domains to diverse targets as is the case for single VH domains.     

An efficient phage plaque screen for the random mutational analysis of the interaction of HIV-1 gp120 with human CD4.

A lambda phage expression methodology was adapted to dissect protein/ligand interactions efficiently through the creation and rapid screening of large numbers of mutants. Here we describe the method and its specific application to the interaction between the external envelope glycoprotein of the human immunodeficiency virus (HIV-1), gp120, and the human cell surface protein CD4. Random substitutions were introduced throughout the gp120 binding region (amino acids 38-62) in the amino-terminal domain of CD4 by oligonucleotide mutagenesis. These mutations were expressed within phage plaques and directly screened for their effect on binding of gp120 using a modified phage plaque lift procedure. Plaques showing increased, decreased, and no effect on binding were identified and mutations were verified by sequence analysis. In this manner, 25 unique mutations were identified that altered CD4 binding to gp120. A new site was identified at which mutations reduced binding to gp120 and several novel amino acid substitutions were defined at sites previously implicated in binding. Of particular interest, this in vitro genetic approach identified a mutation which significantly increased binding to gp120. The phenotypes of several of these mutants were further characterized by quantitative measurement of their binding affinity. The results confirmed the accuracy of the phenotypic selection and demonstrated that the sensitivity of the system allowed detection of a 3-4-fold increase or decrease in affinity. In the context of the recently determined atomic structure of CD4, these results further implicate residues in the CDR2-like region and in an adjacent loop in recognition of gp120. This methodology should be generally applicable to other high affinity protein/ligand interactions that are compatible with expression in Escherichia coli.     

Refolding and characterization of recombinant human soluble CTLA-4 expressed in Escherichia coli.

CD28 and CTLA-4 are homologous cell surface proteins expressed by T cells. CD28 is constitutively expressed by most T cells, whereas CTLA-4 is expressed by activated T cells. Both proteins are ligands for the costimulatory molecules CD80 and CD86 expressed by activated B cells, macrophages, and dendritic cells. A fusion protein comprising the CTLA-4 extracellular domain joined to a human immunoglobulin heavy chain constant region (CTLA4Ig) binds CD80 and CD-86 with high affinity and inhibits CD80/CD86-dependent immune responses in vitro and in vivo. Attempts at producing the CTLA-4 extracellular domain as an unfused protein have met with limited success. Here we describe the expression and purification of the CTLA-4 extracellular domain as a nonfused protein in Escherichia coli. The 12.5-kDa CTLA-4 extracellular domain was insoluble when expressed in E. coli and required denaturation, reduction, and refolding steps to become soluble and assume its proper conformation. The protein refolded into a mixture of monomers, disulfide-linked dimers, and higher order disulfide-linked aggregates. sCTLA-4 dimers were the predominant refold form when air was used as the oxidizing agent during the refold procedure. Purified sCTLA-4 dimers were 10- to 50-fold more potent than sCTLA-4 monomers at inhibiting T cell activation using a CD80-dependent in vitro bioassay.     

Inhibition of the CD28-CD80 co-stimulation signal by a CD28-binding affibody ligand developed by combinatorial protein engineering

CD28 is one of the key molecules for co-stimulatory signalling in T cells. Here, novel ligands (affibodies) showing selective binding to human CD28 (hCD28) have been selected by phage display technology from a protein library constructed through combinatorial mutagenesis of a 58-residue three-helix bundle domain derived from staphylococcal protein A. Analysis of selected affibodies showed a marked sequence homology and biosensor analyses showed that all investigated affibodies bound to hCD28 with micromolar affinities (KD). No cross-reactivity towards the related protein human CTLA-4 could be observed. This lack of cross-reactivity to hCTLA-4 suggests that the recognition site on hCD28 for the affibodies resides outside the conserved MYPPPYY motif. The apparent binding affinity for hCD28 could be improved through fusion to an Fc fragment fusion partner, resulting in a divalent presentation of the affibody ligand. For the majority of selected anti-CD28 affibodies, in co-culture experiments involving Jurkat T-cells and CHO cell lines transfected to express human CD80 (hCD80) or LFA-3 (hLFA-3) on the cell surface, respectively, pre-incubation of Jurkat cells with affibodies resulted in inhibition of IL-2 production when they were co-cultured with CHO (hCD80+) cells, but not with CHO (hLFA-3+) cells. For one affibody variant denoted Z(CD28:5) a clear concentration-dependent inhibition was seen, indicating that this affibody binds hCD28 and specifically interferes in the interaction between hCD28 and hCD80.     

Molecular Modeling of Immunoglobulin Superfamily Proteins: Predicting the Three Dimensional Structure of the Extracellular Domain of CTLA-4 (CD152)

The interactions between CD28/CTLA-4 (CD152) on T cells and their ligands CD80/CD86 on antigen presenting cells provide costimulatory signals critical for T cell activation. CD28/CTLA-4 and CD80/CD86 are members of the immunoglobulin superfamily (IgSF). CD28 and CTLA-4 both contain a single extracellular immunoglobulin (Ig) domain which binds CD80/CD86. Here we report modeling studies on the three-dimensional (3D) structure of the CTLA-4 binding domain. Since CTLA-4 displays only very weak sequence homology to proteins with known 3D structure, conventional modeling techniques were difficult to apply. Structure-oriented sequence comparison, consensus residue analysis, conformational searching, and inverse folding calculations were employed to aid in the generation of a comparative CTLA-4 model. Regions of high and low prediction confidence were identified, and the sequence-structure compatibility of the model was determined. Characteristics of the modeled structure, which resembles an Ig V domain, were analyzed, and the model was used to map N-linked glycosylation sites and residues critical for CTLA-4 function. The modeling approach described here can be applied to predict 3D structures of other IgSF proteins.     

Molecular Modeling of Immunoglobulin Superfamily Proteins: CTLA-4 (CD152) - Comparison of a Predicted and Experimentally Determined Three-Dimensional Structure

The CD28 and CTLA-4 (CD152) receptors on T cells recognize CD80 and CD86 ligands on antigen presenting cells. These interactions provide and control costimulatory signals required for effective T cell activation. CD28 and CTLA-4 belong to the immunoglobulin superfamily (IgSF) and contain a single extracellular ligand binding domain. The three-dimensional (3D) structure of the binding domain of CTLA-4 was modeled previously using a combination of structure-based sequence comparison, IgSF consensus residue analysis, conformational search, and inverse folding calculations. Recently, the 3D structure of CTLA-4 was determined by NMR. Comparison of the modeled and experimentally determined CTLA-4 structure has made it possible to assess the accuracy of our predictions. We found that the overall accuracy of the model was sound and sufficient for a meaningful application of the model in experimental studies. Major errors in the model are limited to the conformation and position of some loops. Our studies on CTLA-4 provide an example for the opportunities and limitations of comparative protein modeling in the presence of low sequence similarity.Electronic Supplementary Material available.     

Molecular Modeling of Immunoglobulin Superfamily Proteins: Predicting the Three Dimensional Structure of the Extracellular Domain of CTLA-4 (CD152)

The interactions between CD28/CTLA-4 (CD152) on T cells and their ligands CD80/CD86 on antigen presenting cells provide costimulatory signals critical for T cell activation. CD28/CTLA-4 and CD80/CD86 are members of the immunoglobulin superfamily (IgSF). CD28 and CTLA-4 both contain a single extracellular immunoglobulin (Ig) domain which binds CD80/CD86. Here we report modeling studies on the three-dimensional (3D) structure of the CTLA-4 binding domain. Since CTLA-4 displays only very weak sequence homology to proteins with known 3D structure, conventional modeling techniques were difficult to apply. Structure-oriented sequence comparison, consensus residue analysis, conformational searching, and inverse folding calculations were employed to aid in the generation of a comparative CTLA-4 model. Regions of high and low prediction confidence were identified, and the sequence-structure compatibility of the model was determined. Characteristics of the modeled structure, which resembles an Ig V domain, were analyzed, and the model was used to map N-linked glycosylation sites and residues critical for CTLA-4 function. The modeling approach described here can be applied to predict 3D structures of other IgSF proteins.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s008940050025     

Role of the non‐hypervariable FR3 D‐E loop in single‐domain antibody recognition of haptens and carbohydrates

Single‐domain antibodies (sdAbs), the variable domains of camelid heavy chain‐only antibodies, are generally thought to poorly recognize nonproteinaceous small molecules and carbohydrates in comparison with conventional antibodies. However, the structures of anti‐methotrexate, anti‐triclocarban and anti‐cortisol sdAbs revealed unexpected contributions of the non‐hypervariable “CDR4” loop, formed between β‐strands D and E of framework region 3, in binding. Here, we investigated the potential role of CDR4 in sdAb binding to a hapten, 15‐acetyl‐deoxynivalenol (15‐AcDON), and to carbohydrates. We constructed and panned a phage‐displayed library in which CDR4 of the 15‐AcDON‐specific sdAb, NAT‐267, was extended and randomized. From this library, we identified one sdAb, MA‐232, bearing a 14‐residue insertion in CDR4 and showing improved binding to 15‐AcDON by ELISA and surface plasmon resonance. On the basis of these results, we constructed a second set of phage‐displayed libraries in which the CDR4 and other regions of three hapten‐ or carbohydrate‐binding sdAbs were diversified. With the goal of identifying sdAbs with novel glycan‐binding specificities, we panned the library against four tumor‐associated carbohydrate antigens but were unable to enrich binding phages. Thus, we conclude that while CDR4 may play a role in binding of some rare hapten‐specific sdAbs, diversifying this region through molecular engineering is probably not a general solution to sdAb carbohydrate recognition in the absence of a paired V_L domain.     

Innate-Like Control of Human iNKT Cell Autoreactivity via the Hypervariable CDR3β Loop

Invariant Natural Killer T cells (iNKT) are a versatile lymphocyte subset with important roles in both host defense and immunological tolerance. They express a highly conserved TCR which mediates recognition of the non-polymorphic, lipid-binding molecule CD1d. The structure of human iNKT TCRs is unique in that only one of the six complementarity determining region (CDR) loops, CDR3β, is hypervariable. The role of this loop for iNKT biology has been controversial, and it is unresolved whether it contributes to iNKT TCR:CD1d binding or antigen selectivity. On the one hand, the CDR3β loop is dispensable for iNKT TCR binding to CD1d molecules presenting the xenobiotic alpha-galactosylceramide ligand KRN7000, which elicits a strong functional response from mouse and human iNKT cells. However, a role for CDR3β in the recognition of CD1d molecules presenting less potent ligands, such as self-lipids, is suggested by the clonal distribution of iNKT autoreactivity. We demonstrate that the human iNKT repertoire comprises subsets of greatly differing TCR affinity to CD1d, and that these differences relate to their autoreactive functions. These functionally different iNKT subsets segregate in their ability to bind CD1d-tetramers loaded with the partial agonist α-linked glycolipid antigen OCH and structurally different endogenous β-glycosylceramides. Using surface plasmon resonance with recombinant iNKT TCRs and different ligand-CD1d complexes, we demonstrate that the CDR3β sequence strongly impacts on the iNKT TCR affinity to CD1d, independent of the loaded CD1d ligand. Collectively our data reveal a crucial role for CDR3β for the function of human iNKT cells by tuning the overall affinity of the iNKT TCR to CD1d. This mechanism is relatively independent of the bound CD1d ligand and thus forms the basis of an inherent, CDR3β dependent functional hierarchy of human iNKT cells.     

CTLA-4 lacking the cytoplasmic domain costimulates IL-2 production in T-cell hybridomas

Optimal T-cell activation depends on the antigen-specific signal mediated by the TCR and engagement of costimulatory receptors such as CD28. CTLA-4, a homologous counterpart of CD28, is considered to be a crucial inhibitory receptor. To test its function separately from CD28 in an antigen-driven and ligand-specific model, we stably transfected the T-cell hybridomas A1.1 and DO11.10, which lack significant endogenous CD28 or CTLA-4 expression, with wild-type CTLA-4 (CTLA-4 WT) and a construct lacking the cytoplasmic tail (tailless [TL]). Functional studies were carried out by co-incubation with APC expressing the B7 ligands for CTLA-4 and appropriate MHC molecules loaded with their cognate antigens. IL-2 production on costimulation of CTLA-4WT and TCR did not differ significantly from untransfected controls. However, coligation of TCR and CTLA-4TL resulted in a vigorous IL-2 response specific for the interaction of CTLA-4 with B7. Thus, lack of the cytoplasmic tail converted CTLA-4 into a costimulatory receptor. This indicates that the CTLA-4 inhibitory function may not be attributable to sequestration of the common B7 ligands when competing with CD28. Rather, ligation of B7 by the CTLA-4 extracellular domain can enhance TCR activation, whereas in the full-length receptor, inhibitory signals mediated by the cytoplasmic domain may override this activation.     

A region in domain 1 of CD4 distinct from the primary gp120 binding site is involved in HIV infection and virus-mediated fusion.

The high affinity binding site for human immunodeficiency virus (HIV) envelope glycoprotein gp120 resides within the amino-terminal domain (D1) of CD4. Mutational and antibody epitope analyses have implicated the region encompassing residues 40-60 in D1 as the primary binding site for gp120. Outside of this region, a single residue substitution at position 87 abrogates syncytium formation without affecting gp120 binding. We describe two groups of CD4 monoclonal antibodies (mAbs) which recognize distinct epitopes associated with these regions in D1. These mAbs distinguish between the gp120 binding event and virus infection and virus-induced cell fusion. One cluster of mAbs, which bind at or near the high affinity gp120 binding site, blocked gp120 binding to CD4 and, as expected, also blocked HIV infection of CD4+ cells and virus-induced syncytium formation. A second cluster of mAbs, which recognize the CDR-3 like loop, did not block gp120 binding as demonstrated by their ability to form ternary complexes with CD4 and gp120. Yet, these mAbs strongly inhibited HIV infection of CD4+ cells and HIV-envelope/CD4-mediated syncytium formation. The structure of D1 has recently been solved at atomic resolution and in its general features resembles IgVk regions as predicted from sequence homology and mAb epitopes. In the D1 structure, the regions recognized by these two groups of antibodies correspond to the C'C" (Ig CDR2) and FG (Ig CDR3) hairpin loops, respectively, which are solvent-exposed beta turns protruding in two different directions on a face of D1 distal to the D2 domain. This face is straddled by the longer BC (Ig CDR1) loop which bisects the plain formed by C'C' and FG. This structure is consistent with C'C' and FG forming two distinct epitope clusters within D1. We conclude that the initial interaction between gp120 and CD4 is not sufficient for HIV infection and syncytium formation and that CD4 plays a critical role in the subsequent virus-cell and cell-cell membrane fusion events. We propose that the initial binding of CD4 to gp120 induces conformational changes in gp120 leading to subsequent interactions of the FG loop with other regions in gp120 or with the fusogenic gp41 potion of the envelope gp160 glycoprotein.     

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.     

Affinity transfer to a human protein by CDR3 grafting of camelid VHH

VHH is the binding domain of the IgG heavy chain. Some VHHs have an extremely long CDR3 that contributes to antigen binding. We studied the antigen binding ability of CDR3 by grafting a CDR3 from an antigen-binding VHH onto a nonbinding VHH. cAb-CA05-(1RI8), the CDR3-grafted VHH, had an antigen-binding ability. To find a human scaffold protein acceptable for VHH CDR3 grafting, we focused on the conserved structure of VHH, especially the N-terminal and C-terminal amino acid residues of the CDR3 loop and the Cys residue of CDR1. Human origin protein structures with the same orientation were searched in PDB and ubiquitin was selected. Ubi-(1RI8), the CDR3-grafted ubiquitin, had antigen-binding ability, though the affinity was relatively low compared to cAb-CA05-(1RI8). The thermodynamic parameters of Ubi-(1RI8) binding to HEWL were different from cAb-CA05-(1RI8). Hydrogen-deuterium exchange experiments showed decreased stability around the CDR3 grafting region of Ubi-(1RI8), which might explain the decreased antigen-binding ability and the differences in thermodynamic properties. We concluded that the orientation of the CDR3 sequence of Ubi-(1RI8) could not be reconstructed correctly.     

Fine specificity of ligand-binding domain 1 in the polymeric Ig receptor: importance of the CDR2-containing region for IgM interaction

The human polymeric Ig receptor (pIgR), also called transmembrane secretory component, is expressed basolaterally on exocrine epithelia, and mediates specific external transport of dimeric IgA and pentameric IgM. The extracellular part of pIgR consists of five Ig-like domains (D1-D5), and a highly conserved D1 region appears to mediate the initial noncovalent ligand interaction. While the human pIgR binds both dimeric IgA and pentameric IgM with high affinity, the rabbit counterpart has virtually no binding capacity for pentameric IgM. This remarkable disparity constitutes evidence that the binding site of the two ligands differs with regard to essential receptor contact elements. Therefore, we expressed human/rabbit chimeric pIgRs in Madin-Darby canine kidney cells and found that human pIgR D1 is crucial for the interaction with pentameric IgM when placed in the context of a full-length receptor regardless of its backbone species. D1 contains three complementarity-determining region-like loops (CDR1-3), and to further map human D1 regions involved in pentameric IgM binding, we transfected Madin-Darby canine kidney cells with human/rabbit chimeric receptors in which the regions containing the CDR-like loops had been interchanged. Our results showed that the region containing the CDR2-like loop is the most essential for pentameric IgM binding. The region containing the CDR1-like loop also contributed substantially to this interaction, whereas only little contribution was provided by the region containing the CDR3-like loop, although it appeared to be necessary for maximal pentameric IgM binding.     

A Novel Heavy Domain Antibody Library with Functionally Optimized Complementarity Determining Regions

Today a number of synthetic antibody libraries of different formats have been created and used for the selection of a large number of recombinant antibodies. One of the determining factors for successful isolation of recombinant antibodies from libraries lies in the quality of the libraries i.e. the number of correctly folded, functional antibodies contained in the library. Here, we describe the construction of a novel, high quality, synthetic single domain antibody library dubbed Predator. The library is based on the HEL4 domain antibody with the addition of recently reported mutations concerning the amino acid composition at positions critical for the folding characteristics and aggregation propensities of domain antibodies. As a unique feature, the CDR3 of the library was designed to mimic the natural human immune response by designating amino acids known to be prevalent in functional antibodies to the diversity in CDR3. CDR randomizations were performed using trinucleotide synthesis to avoid the presence of stop codons. Furthermore a novel cycle free elongation method was used for the conversion of the synthesized single stranded DNA containing the randomized CDRs into double stranded DNA of the library. In addition a modular approach has been adopted for the scaffold in which each CDR region is flanked by unique restrictions sites, allowing easy affinity maturation of selected clones by CDR shuffling. To validate the quality of the library, one round phage display selections were performed on purified antigens and highly complex antigen mixtures such as cultured eukaryotic cells resulting in several specific binders. The further characterization of some of the selected clones, however, indicates a reduction in thermodynamic stability caused by the inclusion the additional mutations to the HEL4 scaffold.     

Antigen binding and solubility effects upon the veneering of a camel VHH in framework-2 to mimic a VH

Heavy chain only antibodies of camelids bind their antigens with a single domain, the VHH, which acquired adaptations relative to classical VHs to function in the absence of a VL partner. Additional CDR loop conformations, outside the canonical loop structures of VHs, broaden the repertoire of the antigen-binding site. The combined effects of part of the CDR3 that folds over the "former" VL binding site and framework-2 mutations to more hydrophilic amino acids, enhance the solubility of VHH domains and prevent VL pairing. cAbAn33, a VHH domain specific for the carbohydrate moiety of the variant surface glycoprotein of trypanosomes, has a short CDR3 loop that does not cover the former VL binding site as well as a VH-specific Trp47 instead of the VHH-specific Gly47. Resurfacing its framework-2 region (mutations Tyr37Val, Glu44Gly and Arg45Leu) to mimic that of a human VH restores the VL binding capacity. In solution, the humanised VHH behaves as a soluble, monomeric entity, albeit with reduced thermodynamic stability and affinity for its antigen. Comparison of the crystal structures of cAbAn33 and its humanised derivative reveals steric hindrance exerted by VHH-specific residues Tyr37 and Arg45 that prevent the VL domain pairing, whereas Glu44 and Arg45 are key elements to avoid insolubility of the domain.     

融合蛋白ICOSIg的三维结构模建的研究

目的:利用结构相似性的序列比对来模建ICOSIg的三维结构,分析其可能的结合位点,为改造ICOSIg的突变体,提高其结合活性提供理论基础。方法:利用生物信息学手段分析ICOS所属CD28家族各成员分子的结构域,通过基于结构相似的序列比对,以空间结构已经得到解析的CTLA4为模板,利用同源模建的方法,模建ICOS膜外区的空间结构。进一步地以人IgG2和CTLA4为模板,模建了ICOSIg全长的空间结构。在此基础上,结合氨基酸特性,分析其可能的功能位点。结果:FDPPPF及KTKGSGN基序可能是ICOSIg的功能结合位点。结论:模建了ICOSIg的空间结构,分析了其可能结合位点,为突变ICOSIg提高其亲和力提供了线索。     

Lysophospholipid presentation by CD1d and recognition by a human Natural Killer T-cell receptor

Invariant Natural Killer T (iNKT) cells use highly restricted αβ T cell receptors (TCRs) to probe the repertoire of lipids presented by CD1d molecules. Here, we describe our studies of lysophosphatidylcholine (LPC) presentation by human CD1d and its recognition by a native, LPC‐specific iNKT TCR. Human CD1d presenting LPC adopts an altered conformation from that of CD1d presenting glycolipid antigens, with a shifted α1 helix resulting in an open A’ pocket. Binding of the iNKT TCR requires a 7‐Å displacement of the LPC headgroup but stabilizes the CD1d–LPC complex in a closed conformation. The iNKT TCR CDR loop footprint on CD1d–LPC is anchored by the conserved positioning of the CDR3α loop, whereas the remaining CDR loops are shifted, due in part to amino‐acid differences in the CDR3β and Jβ segment used by this iNKT TCR. These findings provide insight into how lysophospholipids are presented by human CD1d molecules and how this complex is recognized by some, but not all, human iNKT cells.     

Chimeric co-stimulatory molecules that selectively act through CD28 or CTLA-4 on human T cells

CD28 and CTLA-4 (CD152) play a pivotal role in the regulation of T cell activation. Upon ligation by CD80 (B7-1) or CD86 (B7-2), CD28 induces T cell proliferation, cytokine production, and effector functions, whereas CTLA-4 signaling inhibits expansion of activated T cells and induces tolerance. Therefore, we hypothesized that co-stimulatory molecules that preferentially bind CD28 or CTLA-4 would have dramatically altered biological properties. We describe directed molecular evolution of CD80 genes derived from human, orangutan, rhesus monkey, baboon, cat, cow, and rabbit by DNA shuffling and screening. In contrast to wild-type CD80, the evolved co-stimulatory molecules, termed CD28-binding protein (CD28BP) and CTLA-4-binding protein (CTLA-4BP), selectively bind to CD28 or CTLA-4, respectively. Furthermore, CD28BP has improved capacity to induce human T cell proliferation and interferon-gamma production compared with wild-type CD80. In contrast, CTLA-4BP inhibited human mixed leukocyte reaction (MLR) and enhanced interleukin 10 production in MLR, supporting a role for CTLA-4BP in inducing T cell anergy and tolerance. In addition, co-stimulation of purified human T cells was significantly suppressed when CTLA-4BP was cotransfected with either CD80 or CD28BP. The amino acid sequences of CD28BP and CTLA-4BP were 61 and 96% identical with that of human CD80 and provide insight into the residues that are critical in the ligand binding. These molecules provide a new approach to characterization of CD28 and CTLA-4 signals and to manipulation of the T cell response.