Multisite mutagenesis of interleukin 5 differentiates sites for receptor recognition and receptor activation

Multisite mutagenesis of single-chain and monomeric forms of human interleukin 5 (IL-5) was performed to investigate mechanistic features of receptor activation and the possibility of differentiating sites of activation from those for receptor interaction. The normally dimeric human IL-5 contains two domains, each containing a four-helix bundle. IL-5 has previously been re-engineered into the monomeric, one-domain GM1 form by introducing an eight-residue linker between the third and fourth helices. In this study, we tested a combination of mutations in a single-chain IL-5 (scIL-5) construct, [(89)SLRGG(92),W(110)/(89)AAAAA(92), A(110)]scIL-5. This mutein was found to retain substantial IL-5 receptor alpha-chain binding but with selectively suppressed proliferation of the IL-5-dependent cell line TF-1.28. This result confirms recent findings that IL-5 receptor alpha-chain recognition can be supported by the (89)SLRGG(92) epitope and that, in contrast, Glu110 is important in receptor activation. On the basis of this result, two mutants of GM1 were constructed with the intent to retain receptor alpha-chain binding while modifying receptor activation epitopes. In the first, [(88)SLRGG(92),W(110)]GM1, the wild-type CD-loop sequence (89)EERRR(92) was converted to the mimotope (89)SLRGG(92), and Glu110 to Trp. In the second, [A(13), A(110)]GM1, wild-type Glu13, and Glu110 were both mutated to Ala. GM1 and mutants were expressed in high yield in Escherichia coli, purified under denaturing conditions from inclusion bodies, and refolded. Monomers were screened for binding to shIL-5Ralpha-Fc using optical biosensor and ELISA and for bioactivity by proliferation of TF-1.28 cells. Both [(88)SLRGG(92),W(110)]GM1 and [A(13),A(110)]GM1 were found to interact with the shIL-5Ralpha-Fc, with affinities of 69-585 nM, 2-15-fold weaker than that of the original GM1. The mutants also were able to compete with IL-5 for binding to shIL-5Ralpha in an ELISA. In contrast, both mutants exhibited a disproportionately decreased capacity to stimulate TF-1. 28 cell proliferation. [A(13),A(110)]GM1 bioactivity was 160-fold lower than that of GM1, while that for the [(88)SLRGG(92),W(110)]GM1 mutant was 2600-fold lower. The largely retained IL-5 receptor alpha-chain binding affinities versus relatively suppressed bioactivities of [A(13),A(110)]GM1 and [(88)SLRGG(92),W(110)]GM1 variants, in particular the latter, point to the existence of separable IL-5 epitopes for receptor binding and activation and establish the potential to design smaller IL-5 mimetic antagonists.     

Randomization of the receptor alpha chain recruitment epitope reveals a functional interleukin-5 with charge depletion in the CD loop.

We report the functional phage display of single chain human interleukin-5 (scIL-5) and its use for receptor-binding epitope randomization. Enzyme-linked immunosorbent assays and optical biosensor analyses verified expression of scIL-5 on the phage surface and binding of scIL-5 phage to interleukin-5 receptor alpha chain. Furthermore, an asymmetrically disabled but functional scIL-5 mutant, (wt/A5)scIL-5, was displayed on phage. (wt/A5)scIL-5 was constructed from an N-terminal half containing the original five charged residues (88EERRR92) in the CD loop, including the Glu89 and Arg91 believed key in the alpha chain recognition site, combined with a C-terminal half containing a disabled CD loop sequence (88AAAAA92) missing the key recognition residues. This asymmetric variant was used as a starting point to generate an scIL-5 library in which the intact 88-92 N-terminal CD loop was randomized. From this epitope library, a receptor-binding variant of IL-5 was detected, (SLRGG/A5)scIL-5, in which the only charged residue in the CD loop is an Arg at position 90. Characterization of this variant expressed as a soluble protein in E. coli shows that the IL-5 pharmacophore for receptor alpha chain binding can function with a single positive charge in the CD loop. Charge-depleted CD loop mimetics of IL-5 suggest the importance of charge distribution in functional IL-5 receptor recruitment.     

Coiled coil miniprotein randomization on phage leads to charge pattern mimicry of the receptor recognition determinant of interleukin 5

Phage display was used to identify sequences that mimic structural determinants in interleukin5 (IL5) for IL5 receptor recognition. A coiled coil stem loop (CCSL) miniprotein scaffold library was constructed with its turn region randomized and panned for binding variants against human IL5 receptor alpha chain (IL5Ralpha). Competition enzyme-linked immunosorbent assays identified CCSL-phage selectants for which binding to IL5Ralpha was competed by IL5. The most frequently selected and IL5-competed CCSL-phage contain charged residues Arg and Glu in their turn sequences, in this regard resembling a beta strand sequence in the 'CD turn' region, of IL5, that has been proposed to present a key determinant for IL5 receptor alpha chain recognition. The most dominant CCSL-phage selectant sequence, PVEGRV, contains a negative/positive charge pattern similar to that seen in the original CD turn. To test the relatedness of CCSL-phage selectant sequences to the IL5 receptor recognition epitope, PVEGRV was grafted into the sequence 87--92 of a monomeric IL5. The resulting IL5 variant, [(87)PVEGRV(92)]GM1, was able to bind to IL5Ralpha in biosensor assays, to elicit TF-1 cell proliferation and to induce STAT5 phosphorylation in TF-1 cells. The results help discern sequence patterns in the IL5 CD turn region which are key in driving receptor recognition and demonstrate the utility of CCSL miniprotein scaffold phage display to identify local IL5 mimetic sequence arrangements that may ultimately lead to IL5 antagonists.     

Cyclic peptide interleukin 5 antagonists mimic CD turn recognition epitope for receptor alpha

The cyclic peptide AF17121 (Ac-VDECWRIIASHTWFCAEE) that inhibits interleukin 5 (IL-5) function and IL-5 receptor alpha-chain (IL-5Ralpha) binding has been derived from recombinant random peptide library screening and follow-up synthetic variation. To better understand the structural basis of its antagonist activity, AF17121 and a series of analogs of the parent peptide were prepared by solid phase peptide synthesis. Sequence variation was focused on the charged residues Asp(2), Glu(3), Arg(6), Glu(17), and Glu(18). Two of those residues, Glu(3) and Arg(6), form an EXXR motif that was found to be common among library-derived IL-5 antagonists. The E and R in the EXXR motif have a proximity similar to charged residues in a previously identified receptor alpha binding region, the beta-strand between the C- and D-helices of human IL-5. Optical biosensor interaction kinetics and cell proliferation assays were used to evaluate the antagonist activities of the purified synthetic peptides, by measuring competition with the highly active single chain IL-5. Analogs in which acidic residues (Asp(2), Glu(3), Glu(17), and Glu(18)) were replaced individually by Ala retained substantial competition activity, with multiple replacements in these residues leading to fractional loss of potency at most. In contrast, R6A analogs had strongly reduced competition activity. The results reveal that the arginine residue is crucial for the IL-5Ralpha binding of AF17121, while the acidic residues are not essential though likely complex-stabilizing particularly in the Asp(2)-Glu(3) region. By CD, AF17121 exhibited mostly disordered structure with evidence for a small beta-sheet content, and replacement of the arginine had no influence on the observed secondary structure of the peptides. The dominance of Arg(6) in AF17121 activity corresponds to previous findings of dominance of the positive charge balance in the antiparallel beta-sheet of IL-5 composed of (88)EERRR(92) in one strand of the CD turn region of IL-5 and with Arg(32) in the neighboring beta-strand. These results argue that AF17121 and related library-derived peptides function by mimicking the CD turn receptor alpha recognition epitope in IL-5 and open the way to small molecule antagonist design.     

Three residues in the common beta chain of the human GM-CSF, IL-3 and IL-5 receptors are essential for GM-CSF and IL-5 but not IL-3 high affinity binding and interact with Glu21 of GM-CSF.

The beta subunit (beta c) of the receptors for human granulocyte macrophage colony stimulating factor (GM-CSF), interleukin-3 (IL-3) and interleukin-5 (IL-5) is essential for high affinity ligand-binding and signal transduction. An important feature of this subunit is its common nature, being able to interact with GM-CSF, IL-3 and IL-5. Analogous common subunits have also been identified in other receptor systems including gp130 and the IL-2 receptor gamma subunit. It is not clear how common receptor subunits bind multiple ligands. We have used site-directed mutagenesis and binding assays with radiolabelled GM-CSF, IL-3 and IL-5 to identify residues in the beta c subunit involved in affinity conversion for each ligand. Alanine substitutions in the region Tyr365-Ile368 in beta c showed that Tyr365, His367 and Ile368 were required for GM-CSF and IL-5 high affinity binding, whereas Glu366 was unimportant. In contrast, alanine substitutions of these residues only marginally reduced the conversion of IL-3 binding to high affinity by beta c. To identify likely contact points in GM-CSF involved in binding to the 365-368 beta c region we used the GM-CSF mutant eco E21R which is unable to interact with wild-type beta c whilst retaining full GM-CSF receptor alpha chain binding. Eco E21R exhibited greater binding affinity to receptor alpha beta complexes composed of mutant beta chains Y365A, H367A and I368A than to those composed of wild-type beta c or mutant E366A. These results (i) identify the residues Tyr365, His367 and Ile368 as critical for affinity conversion by beta c, (ii) show that high affinity binding of GM-CSF and IL-5 can be dissociated from IL-3 and (iii) suggest that Tyr365, His367 and Ile368 in beta c interact with Glu21 of GM-CSF.     

Characterization of a powerful high affinity antagonist that inhibits biological activities of human interleukin-13

Interleukin-13 (IL-13), a predominantly Th2-derived cytokine, appears to play a central pathological role in asthma, atopic dermatitis, allergic rhinitis, some parasitic infections, and cancer. We hypothesized that an IL-13 antagonist may have profound therapeutic utility in these conditions. We, therefore, mutagenized human IL-13 in which Glu at position 13 was substituted by a Lys residue. This highly purified recombinant IL-13 variant, IL-13E13K, bound with 4-fold higher affinity to the IL-13 receptor than wild-type IL-13 but retained no detectable proliferative activity on the TF-1 hematopoietic cell line. IL-13E13K competitively inhibited IL-13- and IL-4-dependent TF-1 proliferation. It also inhibited IL-13-induced STAT-6 (signal transduction and activator of transducer-6) activation in immune cells and cancer cells and reversed IL-13-induced inhibition of CD14 expression on human primary monocytes. These results demonstrate that high affinity binding and signal generation can be uncoupled efficiently in a ligand receptor interaction. These results also suggest that IL-13E13K may be a useful antagonist for the treatment of allergic, inflammatory, and parasitic diseases or even malignancies in which IL-13 plays a central role.     

Genetic variants of the receptors for thromboxane A2 and IL-4 in atopic dermatitis

Thromboxane A2 (TXA2) is an arachidonate metabolite which is considered to relate to chronic inflammation in atopic diseases characterized by elevated immunoglobulin E productivity. The elevation of immunoglobulin E levels involves many molecules including interleukin-4 (IL-4) and interleukin-4 receptor alpha chain (IL-4R alpha). To assess whether genetic variants of TXA2 receptor, IL-4 and IL-4R alpha genes relate to the elevation of serum immunoglobulin E levels in patients with atopic dermatitis (AD), we conducted an association study of genetic polymorphisms of TXA2 receptor (795C/T), IL-4 (-589C/T), and IL-4R alpha (Ile50Val) in a Japanese population (n = 789). The TXA2 receptor 795TT genotype strongly related to AD with high serum immunoglobulin E concentrations. AD patients with both TXA2 receptor 795TT genotype and the IL-4R alpha Ile50/Ile50 genotype showed the greatest immunoglobulin E concentrations. These results suggest TXA2 receptor polymorphism strongly interacts with IL-4R alpha polymorphism as a major determinant of high serum immunoglobulin E levels in AD.     

Analysis of antibody A6 binding to the extracellular interferon gamma receptor alpha-chain by alanine-scanning mutagenesis and random mutagenesis with phage display

The monoclonal antibody A6 binds a conformational epitope comprising mainly the CC' surface loop on the N-terminal fibronectin type-III domain of the extracellular interferon gamma receptor (IFNgammaR). The crystal structure of an A6 Fab-IFNgammaR complex revealed an interface rich in the aromatic side chains of Trp, Tyr, and His residues. These aromatic side chains appear to interact with both polar and hydrophobic groups at the interface, a property which, in general, may be advantageous for ligand binding. To analyze these interactions in more detail, the affinities of 19 A6 alanine-scanning mutants for the IFNgammaR have been measured, using engineered A6 single chain variable region fragments, and a surface plasmon resonance biosensor. Energetically important side chains (DeltaG(mutant) - DeltaG(wt) > 2.4 kcal/mol), that form distinct hot spots in the binding interface, have been identified on both proteins. These include V(L)W92 in A6, whose benzenoid ring appears well situated for a pi-cation (or pi-amine) interaction with the side chain of receptor residue K47 and simultaneously for T-stacking onto the indole ring of W82 in the receptor. At another site, energetically important residues V(H)W52 and V(H)W53, as well as V(H)D54 and V(H)D56, surround the aliphatic side chain of the hot receptor residue K52. Taken together, the results show that side chains distributed across the interface, including many aromatic ones, make key energetic contributions to binding. In addition, the receptor CC' loop has been subjected to random mutagenesis, and receptor mutants with high affinity for A6 have been selected by phage display. Residues previously identified as important for receptor binding to A6 were conserved in the clones isolated. Some mutants, however, showed a much improved affinity for A6, due to changes at Glu55, a residue that appeared to be energetically unimportant for binding the antibody by alanine-scanning mutagenesis. An E55P receptor mutant bound A6 with a 600-fold increase in affinity (K(D) approximately 20 pM), which is one of the largest improvements in affinity from a single point mutation reported so far at any protein-protein interface.     

Two distinct and independent sites on IL-6 trigger gp 130 dimer formation and signalling.

The helical cytokine interleukin (IL) 6 and its specific binding subunit IL-6R alpha form a 1:1 complex which, by promoting homodimerization of the signalling subunit gp130 on the surface of target cells, triggers intracellular responses. We expressed differently tagged forms of gp130 and used them in solution-phase binding assays to show that the soluble extracellular domains of gp130 undergo dimerization in the absence of membranes. In vitro receptor assembly reactions were also performed in the presence of two sets of IL-6 variants carrying amino acid substitutions in two distinct areas of the cytokine surface (site 2, comprising exposed residues in the A and C helices, and site 3, in the terminal part of the CD loop). The binding affinity to IL-6R alpha of these variants is normal but their biological activity is poor or absent. We demonstrate here that both the site 2 and site 3 IL-6 variants complexed with IL-6R alpha bind a single gp130 molecule but are unable to dimerize it, whereas the combined site 2/3 variants lose the ability to interact with gp130. The binding properties of these variants in vitro, and the result of using a neutralizing monoclonal antibody directed against site 3, lead to the conclusion that gp130 dimer is formed through direct binding at two independent and differently oriented sites on IL-6. Immunoprecipitation experiments further reveal that the fully assembled receptor complex is composed of two IL-6, two IL-6R alpha and two gp130 molecules. We propose here a model representing the IL-6 receptor complex as hexameric, which might be common to other helical cytokines.     

Identification of amino acid residues critical for biological activity in human interleukin-18

Interleukin-18 (IL-18) is a pro-inflammatory cytokine, and IL-18-binding protein (IL-18BP) is a naturally occurring protein that binds IL-18 and neutralizes its biological activities. Computer modeling of human IL-18 identified two charged residues, Glu-42 and Lys-89, which interact with oppositely charged amino acid residues buried in a large hydrophobic pocket of IL-18BP. The cell surface IL-18 receptor alpha chain competes with IL-18BP for IL-18 binding, although the IL-18 receptor alpha chain does not share significant homology to IL-18BP. In the present study, Glu-42 was mutated to Lys and Lys-89 to Glu; Glu-42 and Lys-89 were also deleted separately. The deletion mutants (E42X and K89X) were devoid of biological activity, and the K89E mutant lost 95% of its activity. In contrast, compared with wild-type (WT) IL-18, the E42K mutant exhibited a 2-fold increase in biological activity and required a 4-fold greater concentration of IL-18BP for neutralization. The binding of WT IL-18 and its various mutants to human natural killer cells was evaluated by competition assays. The mutant E42K was more effective than WT IL-18 in inhibiting the binding of (125)I-IL-18 to natural killer cells, whereas the three inactive mutants E42X, K89E, and K89X were unable to compete with (125)I-IL-18 for binding. Similarly, WT IL-18 and the E42K mutant induced degradation of Ikappa-Balpha, whereas the three biologically inactive mutants did not induce degradation. The present study reveals that Glu-42 and Lys-89 are critical amino acid residues for the integrity of IL-18 structure and are important for binding to cell surface receptors, for signal transduction, and for neutralization by IL-18BP.     

Binding of an antibody mimetic of the human low density lipoprotein receptor to apolipoprotein E is governed through electrostatic forces. Studies using site-directed mutagenesis and molecular modeling

Monoclonal antibody 2E8 is specific for an epitope that coincides with the binding site of the low density lipoprotein receptor (LDLR) on human apoE. Its reactivity with apoE variants resembles that of the LDLR: it binds well with apoE3 and poorly with apoE2. The heavy chain complementarity-determining region (CDRH) 2 of 2E8 shows homology to the ligand-binding domain of the LDLR. To define better the structural basis of the 2E8/apoE interaction and particularly the role of electrostatic interactions, we generated and characterized a panel of 2E8 variants. Replacement of acidic residues in the 2E8 CDRHs showed that Asp(52), Glu(53), and Asp(56) are essential for high-affinity binding. Although Asp(31) (CDRH1), Glu(58) (CDRH2), and Asp(97) (CDRH3) did not appear to be critical, the Asp(97) --> Ala variant acquired reactivity with apoE2. A Thr(57) --> Glu substitution increased affinity for both apoE3 and apoE2. The affinities of wild-type 2E8 and variants for apoE varied inversely with ionic strength, suggesting that electrostatic forces contribute to both antigen binding and isoform specificity. We propose a model of the 2E8.apoE immune complex that is based on the 2E8 and apoE crystal structures and that is consistent with the apoE-binding properties of wild-type 2E8 and its variants. Given the similarity between the LDLR and 2E8 in terms of specificity, the LDLR/ligand interaction may also have an important electrostatic component.     

Interaction of macrophage-stimulating protein with its receptor. Residues critical for beta chain binding and evidence for independent alpha chain binding.

Macrophage-stimulating protein (MSP) and hepatocyte growth factor/scatter factor (HGF/SF) are plasminogen-related growth and motility factors that interact with cell-surface protein tyrosine kinase receptors. Each one is a heterodimeric protein comprising a disulfide-linked alpha chain and a serine protease-like beta chain. Despite structural similarities between MSP and HGF, the primary receptor binding site is located on the alpha chain of HGF/SF but on the beta chain of MSP. To obtain insight into the structural basis for MSP beta chain binding, beta chain structure was modeled from coordinates of an existing model of the HGF beta chain. The model revealed that the region corresponding to the S1 specificity pocket in trypsin is filled by the Asn(682)/Glu(648) interacting pair, leaving a shallow cavity for possible beta chain interaction with the receptor. Mutants in this region were created, and their binding characteristics were determined. A double mutation of Asn(682)/Glu(648) caused diminished binding of the beta chain to the MSP receptor, and a single mutation of neighboring Arg(683) completely abolished binding. Thus, this region of the molecule is critical for binding. We also found that at equimolar concentrations of free alpha and beta chains, alpha chain binding to receptor was detectable, at levels considerably lower than beta chain binding. The EC(50) values determined by quantitative enzyme-linked immunosorbent assay are 0.25 and 16.9 nM for beta and alpha chain, respectively. The data suggest that MSP has two independent binding sites with high and low affinities located in beta and alpha chain, respectively, and that the two sites together mediate receptor dimerization and subsequent activation.     

Rational design of a receptor super-antagonist of human interleukin-6.

Interleukin-6 (IL-6) is a differentiation and growth factor for a variety of cell types and its excessive production plays a major role in the pathogenesis of multiple myeloma and post-menopausal osteoporosis. IL-6, a four-helix bundle cytokine, is believed to interact sequentially with two transmembrane receptors, the low-affinity IL-6 receptor (IL-6R alpha) and the signal transducer gp130, via distinct binding sites. In this paper we show that combined mutations in the predicted A and C helices, previously suggested to establish contacts with gp130, give rise to variants with no bioactivity but unimpaired binding to IL-6R alpha. These mutants behave as full and selective IL-6 receptor antagonists on a variety of human cell lines. Furthermore, a bifacial mutant was generated (called IL-6 super-antagonist) in which the antagonist mutations were combined with amino acid substitutions in the predicted D helix that increase binding for IL-6R alpha. The IL-6 super-antagonist has no bioactivity, but improved first receptor occupancy and, therefore, fully inhibits the wild-type cytokine at low dosage. The demonstration of functionally independent receptor binding sites on IL-6 suggests that it could be possible to design super-antagonists of other helical cytokines which drive the assembly of structurally related multisubunit receptor complexes.     

Equilibrium and kinetic analysis of human interleukin-13 and IL-13 receptor alpha-2 complex formation

Interleukin 13 (IL-13) is a pleiotropic cytokine secreted by activated T cells. Both IL-13 and its polymorphic variant (IL-13-R110Q) have been shown to be associated with multiple diseases such as asthma and allergy. Two IL-13 receptors have been identified, IL-13R alpha-1 receptor (IL-13Rα1) and IL-13R alpha-2 receptor (IL-13Rα2). It has been well established that IL-13 binds to IL-13Rα1 alone with low nM affinity while binding to the IL-13Rα1/IL-4R receptor complex is significantly tighter (pM). The affinity between IL-13 and IL-13Rα2, however, remains elusive. Several values have been reported in the literature varying from 20 pM to 2.5 nM. The affinities previously reported were obtained using surface plasmon resonance (SPR) or Scatchard analysis of (125) I-IL-13 binding data. This report presents the results for the kinetics and equilibrium binding analysis studies performed using label-free kinetic exclusion assay (KEA) for the interaction of human IL-13 and IL-13Rα2. KEA equilibrium analysis showed that the affinities of IL-13Rα2 are 107 and 56 pM for IL-13 and its variant (IL-13-R110Q), respectively. KEA kinetic analysis showed that a tight and very stable complex is formed between IL-13Rα2 and IL-13, as shown by calculated dissociation rate constants slower than 5?×?10(-5) per second. Kinetic analysis also showed significant differences in the kinetic behavior of wild type (wt) versus IL-13-R110Q. IL-13-R110Q not only associates to IL-13Rα2 slower than wt human IL-13 (wt-IL-13), as previously reported, but IL-13-R110Q also dissociates slower than wt-IL-13. These results show that IL-13Rα2 is a high affinity receptor and provide a new perspective on kinetic behavior that could have significant implications in the understanding of the role of IL-13-R110Q in the disease state.     

Structure-activity relationship study of human interleukin-3. Identification of residues required for biological activity by site-directed mutagenesis

Recombinant human interleukin-3 (rhuIL-3) variants were generated by site-directed mutagenesis and expression in Escherichia coli. Amino acid deletions and substitutions were made in the previously identified epitopes of two huIL-3-specific neutralizing monoclonal antibodies (mAbs). The rhuIL-3 variants were analyzed for their ability to bind to the IL-3 receptor and to induce the proliferation of the human IL-3-dependent cell line M-O7. Several deletion mutants spanning the epitopes of these neutralizing mAbs indicated the importance of residues Pro33 and Leu34 for biological activity. Further, substitution of Pro33 with Asn (Asn33) showed an enhanced proliferative activity (4-fold) and a moderate increase in receptor binding (2-fold) compared to wild-type (wt) rhuIL-3. The most remarkable change, however, was seen with variant Gly33, which showed a 14-fold increase in promoting the growth of M-O7 cells without a significant modification in its receptor binding capacity. In contrast, substitution of Leu34 with Gly (Gly34) yielded an IL-3 variant that had a 25-fold decreased receptor binding capacity and proliferative activity, while Glu34 had properties similar to wild-type rhuIL-3. Analysis of the binding of these variants to different rhuIL-3-specific monoclonal antibodies suggested that no major modification had occurred in their conformations. These results indicate that both residues, Pro33 and Leu34, play a critical role in modulating the activity of rhuIL-3.     

Role of the C-terminus in the activity, conformation, and stability of interleukin-6.

Two murine interleukin-6 (mIL-6) variants were constructed using the polymerase chain reaction (PCR), one lacking the last five residues (183-187) at the C-terminus (pMC5) and another with the last five residues of mIL-6 substituted by the corresponding residues of human IL-6 (pMC5H). The growth stimulatory activity of pMC5 on the mouse hybridoma cell line 7TD1 was < 0.05% of mIL-6, whereas pMC5H and mIL-6 were equipotent. The loss of biological activity of pMC5 correlated with its negligible receptor binding affinity on 7TD1 cells, while the binding of pMC5H was comparable to that of mIL-6. Both pMC5 and pMC5H, like mIL-6, failed to interact with recombinant soluble human IL-6 receptor when assayed by surface plasmon resonance-based biosensor analysis. These studies suggest that the C-terminal seven amino acids of human IL-6, alone, do not define species specificity for receptor binding. A variety of biophysical techniques, as well as the binding of a conformational-specific monoclonal antibody, indicated that the global fold of the mIL-6 variants was similar to that of mIL-6, although small changes in the NMR spectra, particularly for pMC5, were observed. Some of these changes involved residues widely separated in the primary structure. For instance, interactions involving Tyr-22 were influenced by the C-terminal amino acids suggesting that the N- and C-termini of mIL-6 are in close proximity. Equilibrium unfolding experiments indicated that pMC5 was 0.8 kcal/mol less stable than mIL-6, whereas pMC5H was 1.4 kcal/mol more stable. These studies emphasize the structural importance of the C-terminal amino acids of IL-6 and suggest that truncation or mutation of this region could lead to small but significant alterations in other regions of the molecule.     

HepG2 cells predominantly express the type II interleukin 1 receptor (biochemical and molecular characterization of the IL-1 receptor).

In this study we have characterized the cell surface interleukin 1 (IL-1) receptor in HepG2 hepatoma cells. We found that HepG2 cells bind both IL-1 alpha and beta with high affinity, KDs of 136 and 180 pM and receptor densities of 16,000 and 8500 binding sites/cell respectively. The binding sites appeared to be predominantly type II since phorbol ester treatment of the cells, which selectively downregulates type II IL-1 receptors, reduced binding by 68% while treatment of the cells with an inhibitory monoclonal antibody specific for the type I receptor had no significant effect on IL-1 binding. Competition studies with a modified IL-1 beta analog (Glu4) also revealed binding kinetics more consistent with binding to type II receptors than to type I. Crosslinking and ligand blotting with human 125I-IL-1 demonstrated the presence of two bands, a 78 kDa band typical of crosslinking to type II (p60) receptor, and a 98 kDa band, typical of crosslinking to the type I (p80) receptor. Low level expression of the type I receptor was consistent with molecular biological studies employing polymerase chain reaction (PCR) amplification which indicated that mRNA for the type I receptor was produced by the HepG2 cells. Functional receptors were demonstrated by the induction of IL-8 by IL-1 stimulated cells.     

The effects of MHC gene dosage and allelic variation on T cell receptor selection

In a T cell receptor transgenic mouse model of thymic selection, the efficiency of selection of the transgenic alpha beta heterodimer is significantly enhanced in animals that express higher densities of the relevant major histocompatibility complex molecule (I-Ek/b). These results imply that there is a stochastic component to positive selection in the thymus. Allelic variants of the original selecting I-Ek molecule are either less efficient (E alpha k:E beta b) or incapable (E alpha k:E beta s and I-Ed) of mediating the selection of transgenic alpha beta + T cells. Two of these three I-E variants appear to differ from I-Ek in amino acid residues of the peptide binding site and not in residues capable of contacting the T cell receptor, suggesting that specific peptides, or conformations of peptides, play a role in positive selection. In contrast, mice transgenic for only the beta chain of this T cell receptor show selection for CD4+ T cells in the presence of all four I-E variants tested.     

A novel gain-of-function mutation of the integrin alpha2 VWFA domain.

Integrin alpha2beta1 is the major receptor for collagens in human tissues, being involved in cell adhesion and the control of collagen and collagenase gene expression. The collagen binding site of alpha2beta1 has been localized to the alpha2 von Willebrand Factor type A (VWFA) domain (A-domain or I-domain) and the residues responsible for the interaction with collagen have been mapped. We report a study of alpha2 VWFA domain in which residue E318, which lies outside the collagen binding site, is mutated to tryptophan, showing that this is a gain-of-function mutation. Recombinant alpha2-E318W VWFA domain showed elevated and specific binding to collagen I compared with the wild-type. Side chain hydrophobicity was important for the gain-of-function as elevated binding was seen with E318I and E318Y, but not with E318R. The E318W mutation had additional effects on VWFA domain properties as alpha2-E318W VWFA domain differed from the wild-type in its cation preferences for ligand binding and in binding to monoclonal antibody JA203, which bound at a site distal to E318. The gain-of-function effect was not restricted to binding to collagen I as alpha2-E318W also showed elevated binding to collagen IV, collagen I C-propeptide, laminin and E-cadherin. Binding to these ligands was inhibited by collagen peptide containing the GFOGER motif, indicating that these bound to the VWFA domain by a similar mechanism to collagen I. These data indicate that residue E318 plays a novel and important role in modulating alpha2 VWFA domain--ligand binding and may be involved in the conformational changes associated with its regulation.