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Crystal structures of T cell receptor chains related to rheumatoid arthritis

¹ Wadsworth Center, New York State Department of Health, and ² Department of Biomedical Sciences, School of Public Health, University at Albany, State University of New York, Empire State Plaza, Albany, New York 12201-0509, USA
³ Stroke Branch, National Institute of Neurological Disorders and Stroke, National Institutes of Health, Bethesda, Maryland 20892, USA

Reprint requests to: Hongmin Li, Wadsworth Center, 150 New Scotland Avenue, CMS-1155, Albany, NY 12208, USA; e-mail: lih{at}wadsworth.org; fax: (518) 408-2190.

(RECEIVED August 1, 2005; FINAL REVISION September 5, 2005; ACCEPTED September 6, 2005)

	Abstract

TOP Abstract Introduction Results and Discussion Materials and methods References

 
The crystal structures of the V17⁺ chains of two human T cell receptors (TCRs), originally derived from the synovial fluid (SF4) and tissue (C5–1) of a patient with rheumatoid arthritis (RA), have been determined in native (SF4) and mutant (C5–1_F104Y/C187S) forms, respectively. These TCR chains form homo-dimers in solution and in crystals. Structural comparison reveals that the main-chain conformations in the CDR regions of the C5–1 and SF4 V17 closely resemble those of a V17 JM22 in a bound form; however, the CDR3 region shows different conformations among these three V17 structures. At the side-chain level, conformational differences were observed at the CDR2 regions between our two ligand-free forms and the bound JM22 form. Other significant differences were observed at the V regions 8–12, 40–44, and 82–88 between C5–1/SF4 and JM22 V17, implying that there is considerable variability in the structures of very similar chains. Structural alignments also reveal a considerable variation in the V–C associations, and this may affect ligand recognition. The crystal structures also provide insights into the structure basis of T cell recognition of Mycoplasma arthritidis mitogen (MAM), a superantigen that may be implicated in the development of human RA. Structural comparisons of the V domains of known TCR structures indicate that there are significant similarities among V regions that are MAM-reactive, whereas there appear to be significant structural differences among those V regions that lack MAM-reactivity. It further reveals that CDR2 and framework region (FR) 3 are likely to account for the binding of TCR to MAM.

Keywords: TCR; crystal structure; superantigen; rheumatoid arthritis; Mycoplasma arthritidis mitogen; structure/function studies; proteins of the immune system; crystallography; protein crystallization; mutagenesis (site-directed and general); protein structures—new; sedimentation

Article published online ahead of print. Article and publication date are at http://www.proteinscience.org/cgi/doi/10.1110/ps.051748305.

	Introduction

TOP Abstract Introduction Results and Discussion Materials and methods References

 
Rheumatoid arthritis (RA) is a chronic inflammatory disease resulting in radiographic joint destruction, severe functional deterioration, and work disability. Although the causes of RA remain unclear, it is thought to involve autoimmune recognition of self-antigens by autoreactive T lymphocytes (Van Boxel and Paget 1975; Gregersen et al. 1987; Nepom et al. 1989; Panayi et al. 1992). The cause of this breakdown of tolerance to self-antigens is not known, but both genetic and environmental factors are probably required to trigger the onset of RA. Genetic risk for RA has been strongly associated with certain major histocompatibility complex (MHC) class II alleles, in particular those in the HLA-DRB1 locus (Nepom et al. 1989; Nepom and Erlich 1991; Lanchbury and Hall 1995). A recognition mechanism involving a "shared epitope" of the QKRAA motif encoded by the RA-related DRB1 genes has been proposed (Gregersen et al. 1987; Nepom et al. 1989; Hiraiwa et al. 1990; Dessen et al. 1997). However, the autoantigens responsible for the induction of autoimmunity in RA have not been determined. Type II collagen, as the predominant protein of joint cartilage, has been proposed as a candidate antigen (Banerjee et al. 1988b; Fugger et al. 1994; Khare et al. 1995; Rosloniec et al. 1997).

RA is a multifactorial disease. In addition to genetic factors, environmental factors are thought to be of importance in the disease process. Microbial agents have long been thought to trigger autoimmune disease via their possession of epitopes that resemble self-peptides on target organs (molecular mimicry) (Oldstone 1987). In addition, it was proposed that microbial superantigens (SAgs) play a role in the initiation of the autoimmune diseases through activation of whole populations of specific V-bearing T cells, including pathogenic anti-self T cell clones (Howell et al. 1991; Paliard et al. 1991; Conrad et al. 1994; Kotzin 1994; VanderBorght et al. 1999; Chini et al. 2002; Zhang et al. 2002). In collagen II-induced arthritis (CIA), an animal model of human RA, T cells expressing V8.2 and V6 are found to be selectively expanded in the synovial tissue, compared to the levels in the peripheral blood of the same individuals (Banerjee et al. 1988a; Spinella et al. 1991; Haqqi et al. 1992, 1995a, Haqqi et al. b; Moder et al. 1993; Chini et al. 2002). In human RA, T cells expressing V3, V14, and V17 are most frequently expanded (Howell et al. 1991; Grom et al. 1993; Li et al. 1994; Zagon et al. 1994; Alam et al. 1995; Moreland et al. 1996, 1998; Cuesta et al. 1997; Goronzy et al. 1998; Yen et al. 1998; Zhang et al. 2002), although conflicting results have also been reported (Uematsu et al. 1991; Van Laar et al. 1991; Struyk et al. 1995). It has been speculated that a SAg produced by Mycoplasma arthritidis (MAM) is involved in the pathogenesis of human RA (Emery et al. 1985; Cole and Griffiths 1993; Knudtson et al. 1997b; Mu et al. 2000; Sawitzke et al. 2000). MAM has been shown capable of triggering and exacerbating autoimmune arthritis in the CIA mouse model. In fact, administration of MAM has been shown to markedly exacerbate arthritis in mice that were convalescent from CIA, or to trigger arthritis in animals that had previously been immunized with collagen II but that had failed to develop clinical disease (Cole and Griffiths 1993). It has also been reported that MAM can induce human lymphocytes to secrete rheumatoid factor (Emery et al. 1985), a typical feature of RA. Moreover, antibodies against MAM were found to be selectively elevated in sera from patients with RA, compared to sera from control patients, whereas elevation of antibodies to Staphylococcus enterotoxins SEA and SEB in sera from patients with rheumatic diseases was less specific (Sawitzke et al. 2000). This suggests that, although M. arthritidis commonly infects rodents, its product, MAM or a MAM-like molecule, may play a role in human RA.

While the importance of TCR in RA appears clear, no crystal structure of a TCR implicated in human RA has yet been determined. Several TCRs derived from the synovial fluid and tissue of a RA patient with "classic" RF⁺ polyarticular, symmetrical inflammation, and a DR4,7 haplotype have been cloned (Li et al. 1994). Among these TCRs, two (SF4 and C5–1)V17 TCRs are particularly interesting because they respectively represent a majority TCR population (C5–1) and a minority one (SF4) in the synovial fluid and tissue of the RA patient. SF4 V17 was isolated from the synovial fluid of the patient, 4 mo before synovectomy, while C5–1 V17 was obtained upon activation of T cells from the synovial tissue by the SAg MAM (Li et al. 1994). The CDR3 sequence of the C5–1 V17 is highly homologous (86.4%) to that of a dominant V17, representing more than 40% of the V17 TCR population that was present in tissue of the patient (Li et al. 1994). The antigen specificities of the SF4 and C5–1 TCRs are unknown. However, the T cell clone expressing C5–1 TCR (V2.3V17) could be selectively proliferated by EBV-transformed lymphoblastoid B cell lines expressing RA-associated HLA-DR alleles of DR4, Dw4, and Dw14 (Li et al. 1994).

In the current study, we describe the crystal structures of the two V17⁺ chains related to human RA. We expressed, purified, and crystallized the native SF4 V17 and a F104Y/C187S double mutant of the C5–1 V17 (designated as C5–1_YS) in unbound states (see Materials and Methods). The crystal structures were determined by the multiple anomalous diffraction (MAD) method. Structural comparisons with the TCR chains of known structures revealed that the overall topology of the two V17 TCR chains derived from the RA patient is very similar to that of most other known TCR chains. The conformations in the complementarity determining regions (CDRs) of the RA-related V17 chains in the absence of contacts with antigens are very close to the conformation in a JM22 TCR V17V10 recognizing the matrix protein 58–66 of influenza virus presented by HLA-A2 (Stewart-Jones et al. 2003), although they were originated from CD4⁺ (SF4 and C5–1 V17) and CD8⁺ (JM22 TCR) T cells, respectively. The individual V and C domains of these two classes of V17 chains can be readily superimposed onto the counterparts of other TCR chains; however, structure alignments of the complete chains resulted in large root-mean-square deviations (RMSDs), implying considerable variation in the V–C associations. The crystal structures also provide insights into the structure basis of T cell recognition of MAM, a superantigen that may be implicated in the development of human RA. Structure comparison of the V17 domains with V domains of known structures indicates that there are significant similarities among V regions that are MAM-reactive whereas there appear to be significant structural differences among those V regions that lack MAM-reactivity. Detailed structural comparison further reveals that CDR2 and framework region (FR) 3 may account for the TCR binding to MAM.

	Results and Discussion

TOP Abstract Introduction Results and Discussion Materials and methods References

 
Overall structure
We have expressed, purified, and crystallized two human RA-related TCR chains, designated as V17SF4 and V17C5–1, respectively. The SF4 and C5–1 V17 chains possess different CDR3 sequences (Fig. 1). The crystal structures of the RA-associated V17 chains, native SF4 and mutant C5–1_YS (see Materials and Methods), were determined to about 2.7 Å resolution (Table 1; Fig. 2). For C5–1, a mutation of C187S was introduced to eliminate the free cysteine, while a mutation of F104Y was introduced to generate a TCR V17 molecule with high affinity to MAM (Hodtsev et al. 1998). The electron-density maps were of good quality for both chains (Fig. 2). Most parts of the structures were well ordered except for the CDR3 regions, where electron densities were not observed for some side chains, including Arg96 and Arg98 of both chains in SF4 V17, and Gln99 (chain A) and Met100 (chain B) in C5–1 V17 (Fig. 2A,B).

View larger version (22K): [in this window] [in a new window]   Figure 1. Primary sequence alignment of the CDR3 regions (underlined) of three human V17 TCR chains: V17 SF4, C5–1, and JM22 (Stewart-Jones et al. 2003). Identical CDR3 residues are shaded.

View larger version (69K): [in this window] [in a new window]   Figure 2. The structures of V17 TCR chains. (A,B) Representative (2Fo – Fc) electron density maps, contoured at 1.0, of the CDR3 regions of V17C5–1YS (A) and V17SF4 (B). (C,D) Ribbon diagram of the V17C5–1YS homodimers in two possible associations. (C) Dimerization via V domains; (D) dimerization via C domains. The TCR V, C and CDR loops are labeled.

Sedimentation characterization of soluble V17 TCR chains

To characterize the oligomerization state of the re-folded V17 molecules, we performed sedimentation-velocity (SV) experiments using the analytical ultracentrifugation technique. As shown in Figure 3A, the sedimentation coefficient (S value) distribution of V17SF4 at a concentration of 14 µ M (~0.39 mg/mL) displayed two distinct peaks, at 2.2 S and 3.2 S, corresponding respectively to the monomeric and dimeric forms of V17SF4. Such a dimer formation is noncovalent, because mutation of the free cysteine (C187) to serine does not affect the dimerization of the V17 C5–1, showing both monomeric and dimeric peaks in the SV experiment (Fig. 3A). This demonstrated that noncovalently associated V17 dimer exists in solution, as well as in the crystal structures. At moderate protein concentrations, it is apparent that the majority of V17SF4 and V17C5–1_YS mutant proteins exist as monomers with a peak at 2.2 S. Higher protein concentration promoted dimer formation, resulting in an overall increase of the proportion of the V17 dimer (Fig. 3A). This shift strongly implies that dimer formation for V17 is concentration-dependent, which is consistent with a self-association behavior.

View larger version (18K): [in this window] [in a new window]   Figure 3. Sedimentation velocity and equilibrium analysis of V17C5– 1YS and V17SF4 dimerization. (A) Sedimentation coefficient distributions of V17SF4 at 14 µ M () and 140 µ M (), and of V17C5–1YS at 42 µ M () concentration. (B) Absorbance distributions for the sedimentation of V17SF4 at 22.3 µ M at 20° C at rotor speeds of 20,000 rpm (), 25,000 rpm (), and 30,000 rpm (). For clarity, only every second data point is shown. Distributions were analyzed as part of a global fitting to the absorbance data at multiple loading concentrations. Solid lines are the global best-fit distributions using a reversible monomer–dimer model with an equilibrium constant of KD = 380 µ M.

The homodimer of the V17 TCR chain
The crystals of the SF4 and C5–1_YS V17 chains are isomorphous. The V17 chains form homodimers in the crystals. Because noncrystallographic symmetric (NCS) restraints were used throughout the structure refinement, the main-chain conformations of the two monomers of the dimer are nearly identical, with respective RMSD values of 0.05 Å and 0.06 Å for V17C5–1_YS and V17SF4.

The packing in the crystal structure suggests two possible ways in which the homodimer in solution could form (Fig. 2C,D). A V17 homodimer could be formed through interactions between the TCR C domains (Fig. 2D). Alternatively, a homodimer could be formed through interactions between the TCR V domains (Fig. 2C). In the latter way, the dimer is formed in a head-to-tail manner, with the CDR loops pointing in opposite directions. Similar arrangements of homodimers have been found in the crystal structures of the 14.3.d TCR chain and of its complexes with SAgs (Bentley et al. 1995; Fields et al. 1996; Li et al. 1998b; Sundberg et al. 2002), as well as in the structure of the ES204 TCR V3 (Li et al. 1998a). This type of dimer arrangement is not analogous to that in the TCR heterodimer; the physiological, active form of TCRs. In the TCR heterodimer, the TCR V chain pairs with the TCR V using the same buried surface of the TCR V domain as is used in the V homodimer studied here, but in such a way that all of the CDR loops of the TCR V and V chains are oriented in the same direction. In this manner, an antigen-combining site is formed (Garcia et al. 1999).

Similar to the authentic TCR heterodimers, the V17 chains in the crystals form homodimers mainly through hydrophobic interactions. In both forms of homodimers, considerable amounts of the solvent-accessible surfaces of the V17 chains are buried (data not shown). It has also been reported that the TCR V domains can form homodimers in the absence of TCR V domains (Fields et al. 1995; Li et al. 1997; Plaksin et al. 1999). Although the homodimer arrangement does not have relevance to the physiological V:V dimers, the dimerization of TCR V domains may involve a general mechanism by which the hydrophobic surface is shielded so that each TCR V or V can be efficiently folded, regardless of the presence of their partners (Rudolph et al. 2001). Therefore, a cross-linking disulfide bond is required for the native, heterodimeric TCRs to ensure their correct chain pairing so as to form the antigen recognition site (Rudolph et al. 2001). In addition, the self-association mechanism of TCR V domains may be important for T cell development and differentiation. Skewed expression of TCR V gene families into CD4⁺ or CD8⁺ subsets has been reported, apparently occurring independently of the TCR V pairing (Utsunomiya et al. 1989). The unpaired TCR V chains might be protected through a self-association mechanism during the early stage of T cell development.

The conformations of the CDR regions in ligand-free and ligand-bound states
To date, only a limited number of crystal structures of TCRs have been determined in both a ligand-free and a bound form. These include TCRs 2C (Garcia et al. 1996, 1998), D10 (Hare et al. 1999; Reinherz et al. 1999), Kb5-C20 (Housset et al. 1997; Reiser et al. 2002), and Lc13 (Kjer-Nielsen et al. 2002, 2003). Structural superimposition of the liganded and unliganded forms of each TCR revealed that no major domain rearrangements are associated with ligand binding. However, it has been proposed that TCRs recognize pMHC molecules through an induced-fit mechanism involving conformational changes at CDR regions (Garcia et al. 1998, 1999; Reiser et al. 2002; Kjer-Nielsen et al. 2003).

To date, the crystal structures of three V17 chains of human TCR, namely the V17SF4 and V17C5–1_YS chains in this paper, and a V17 chain of the JM22 TCR (Stewart-Jones et al. 2003), have been determined. The structure of JM22 TCR was determined in a ligand-bound form, whereas the structures of SF4 and C5–1_YS chains were determined in a ligand-free form. Structural comparison between the C5–1_YS/SF4 chains and the JM22 TCR chain may allow us to determine the range of structural changes that occurs upon complex formation, particularly in the CDR1, CDR2, and hypervariable 4 (HV4) regions, in which the sequences are identical. The variable domains of the RA-related V17 C5–1_YS and SF4 have nearly identical conformation with an overall RMSD of 0.19 Å for the C positions. The largest structural differences are in the CDR3 regions, which have an RMSD of 0.74 Å. Because C5–1_YS and SF4 chains have nearly identical structures, and because JM22 V17 is more similar to C5–1_YS in sequence than it is to SF4 V17, the structure of C5–1_YS V17 was used for interpretation and further discussion, except for the CDR3 regions: In the latter, the conformations of C5–1_YS and SF4 V17 differ significantly. However, the conclusions are broadly applicable to SF4 V17 as well.

The CDR1, CDR2, and HV4 regions of V17 C5– 1_YS adopt canonical CDR conformations (Al-Lazikani et al. 2000; Fig. 4A,B). In the crystal, V17 CDR1 residues are not involved in crystal packing (except for Asn28, which makes one contact with Ser168 of the NCS-mate). In contrast, both CDR2 and HV4 regions participate in crystal contacts, including both van der Waals contacts and hydrogen bonds, with symmetry-related molecules. Nevertheless, regardless of crystal contacts, the conformations of the CDR1, CDR2, and HV4 regions of V17 C5–1_YS closely resemble those seen for JM22 V17 in its liganded form (Stewart-Jones et al. 2003; Fig. 4A,B). Structural superimposition of the V domains resulted in RMSD values of 0.5 Å (CDR1), 0.6 Å (CDR2), and 0.3 Å (HV4) in C positions between C5–1_YS and JM22 V17 molecules. These values are smaller than the RMSD (~0.7 Å) for the entire V domain of the two molecules, implying that the conformations of these loops are well conserved upon complex formation. Although no major conformational differences are observed between the ligand-free C5–1_YS and liganded JM22 V17, subtle conformational differences can be seen at the side-chain level. The largest conformational differences occur at residues Tyr50 and Asn55, with positional differences of the tips of Tyr50 and Asn55 as large as 6 Å and 4 Å, respectively (Fig. 4B). In the crystal structure of JM22-HLA-A2/MP complex, Asn55 is involved in recognition of the HLA molecule (Stewart-Jones et al. 2003). In the structure of C5–1_YS V17, Asn55 makes a number of crystal contacts, including three hydrogen bonds. Nevertheless, these differences are within the natural range of variations seen for TCRs (Wang et al. 1998).

View larger version (50K): [in this window] [in a new window]   Figure 4. Structural comparisons of V17C5–1YS with the known three-dimensional structures of TCR chains. (A) Structural comparison of the CDR1 regions of C5–1YS (cyan) and JM22 V17 (PDB code 1OGA [PDB] ) (gray). Atoms for the C5–1YS V17 residues are colored as follows: nitrogen, blue; oxygen, red; carbon, yellow. (B) Structural comparison of the CDR2 regions of C5–1YS (cyan) and JM22 V17 (gray). Atoms for the C5–1YS V17 residues are colored as in A. (C) Structural comparison of the complete chains of V17C5–1YS (red) and JM22 V17 (green). The TCR V domains have been optimally superimposed. (D) Structural comparison of the variable domain of human V17C5–1YS (yellow) with three MAM-reactive TCR chains: mouse V8.2 (blue), human V3 (green), and V12.3 (red). (E) Structural comparison of the variable domain of human V17C5–1YS (yellow) with four MAM-nonreactive TCR chains: mouse V2 (red) and V5.2 (blue), and human V2.1 (green), and V6.3 (magenta). The PDB codes for the TCR chains used here are as follows: mouse V2, 1KB5 (Housset et al. 1997); V5.2, 1NFD (Wang et al. 1998); V8.2, 1TCR (Garcia et al. 1996); human V2.1, 1KTK (Sundberg et al. 2002); V3, 1FYT (Hennecke et al. 2000); V6.3, 1KGC (Kjer-Nielsen et al. 2002); V12.3, 1AO7 (Garboczi et al. 1996a); and V17, 1OGA (Stewart-Jones et al. 2003).

The C5–1_YS, SF4, and JM22 V domains encode different sequences with C5–1_YS more similar to JM22 than is SF4. The structural differences in CDR3 between C5–1_YS and JM22 (RMSD 1.8 Å) and between SF4 and JM22 (RMSD 1.3 Å) are greater than the RMSD for the CDR3 regions between C5–1_YS and SF4 (0.74 Å ). Although the CDR3 regions have different conformations, they all contain -turns at the tip of CDR3. JM22 V17 forms a type II -turn composed of residues 98–101, while these residues in C5–1_YS and SF4 form type I -turns. In addition, regardless of their sequence differences and ligand states, the CDR3 loops of the three molecules are positioned similarly; each fold back toward CDR1 and CDR2. Moreover, several hydrogen bonds, including the one between His31 N1 and conserved Ser95 O, are well conserved. The large structural differences in CDR3 seem not to have a large impact on other CDR regions, as only small RMSD values are observed for CDR1 and CDR2. These data could imply that V17 molecules are required to undergo only small conformational changes upon complex formation.

Comparison of the V17 domains of MHC class I and class II-restricted TCRs
The TCR V gene products are known to interact with both class I and class II MHC molecules (Acuto et al. 1985). Although the structures of many TCRs have been determined, structural determinations for those TCRs that use the same TCR V to recognize both class I and II peptide/MHC molecules are thus far limited solely to murine V8.2. TCR 2C (V3V8.2) recognizes class I MHC H-2K^b (Garcia et al. 1996, 1998), while TCR D10 (V2V8.2) and 172.10 (V2.3V8.2) are respectively specific for class II MHCs I-A^k (Reinherz et al. 1999) and I-A^u (Maynard et al. 2005). Structural comparisons indicate that the overall conformation of V8.2 in 2C, D10, and 172.10 TCRs is very well conserved, with the exception of V CDR3 regions (Garcia et al. 1999; Hare et al. 1999; Maynard et al. 2005). It is not currently known whether other TCRs maintain a single V conformation in the recognition of different classes of MHC molecules.

Structural determination of SF4 and C5–1_YS V17 of class II MHC-restricted TCRs, together with the structure of JM22 V17 of a class-I MHC restricted TCR, provided additional support for the hypothesis that the TCR V domains maintain their main-chain conformation regardless of their CD4⁺ or CD8⁺ origins. TCRs encoding V17 SF4 and C5–1 were derived from CD4⁺ T cells with unknown epitopes, while the JM22 TCR originated from CD8⁺ T cells, recognizing class I MHC HLA-A2 in the context of a matrix protein peptide (MP58–66) of influenza virus (Stewart-Jones et al. 2003). These three V17 chains differ significantly in their CDR3 sequences (Fig. 1). In other regions, the sequences of V17C5–1 and the JM22 V17 are nearly identical, except for amino acid 114. Amino acid 114 is Thr in the JM22 V17 chain, while it is Leu in the V17 chains derived from the RA patient. In addition, V17SF4 differs from the other two V17 chains at positions 107, 110, 112, 118, and 119. The residues at these positions are Ser107, Gln110, Ser112, Asn118, and Lys119 for V17SF4, while they are Pro107, Arg110, Thr112, Lys118, and Asn119 in the other two V17 chains.

The SF4 and C5–1_YS V17 chains of the class II MHC-restricted TCRs superimpose closely with the JM22 V17 of class I MHC-restricted TCR (Stewart-Jones et al. 2003), with overall RMSD values of 0.67 Å and 0.74 Å, respectively (Fig. 4C). Regions 8–12, 40–44, 82–88, and 97–101 showed structure differences larger than 1.5 Å between the chains of MHC class I and II-restricted TCRs. The first three among the four regions are within the V framework (FR) regions, with identical sequences. Analysis of the structural differences in these regions indicated that the structural differences in loop 40–44 between C5–1_YS and JM22 V17 are likely due to crystal packing. Residues 40–44 form a loop that is located at the V17 dimer interface in the V17 C5–1_YS crystals (Fig. 4C). Loop 40–44, which lies at the interface of the authentic TCR heterodimer, showed various conformations when paired with the TCR chains in TCRs of known structures (data not shown). A conformation different from that in JM22 V17 is necessary, in order for loop 40–44 to avoid steric conflict with the other monomer of the C5–1_YS V17 dimer. In all TCR chains, residues 8–12 form two consecutive turns linking the interrupted TCR A- and A'-strands that form -sheets with the B- and G-strands, respectively (Bentley et al. 1995). Structural comparison indicates that the conformation of this linker region is not conserved among the known TCR structures. Nevertheless, superimposition of the JM22 V17 onto the C5–1_YS V17 in the crystal structures resulted in only minor close contact between the JM22 residue S9 and N162 of the NCS-mate of C5–1_YS V17. Therefore, it is possible that the structural difference at this region is due to crystal packing forces. On the other hand, this structural difference could be due to the TCR -chain’s intrinsic nature to recognize different classes of MHC molecules. Notably, structural comparison of a class II-restricted D10 TCR with a class I-restricted 2C TCR revealed similar structural differences at this region (Hare et al. 1999).

In contrast to loops 8–12 and 40–44, loop 82–88 is not involved in crystal packing contacts in the crystal structures of either JM22 or C5–1_YS V17. Residues 82–88 lie at the opposite ends of the CDR loops, and are close but not in the TCR V–C interface. When the JM22 V17 was superimposed on the C5–1_YS V17 or vice versa, the conformation of residues 82–88 from one molecule is not such that it would interfere with the crystal packing of the other. Therefore, the structural differences may not be due to differences in crystal packing, although the possibility can not be formally ruled out. Further structural comparisons revealed that the conformations of this loop in the JM22 and C5–1_YS V17 domains are different from those of all other TCR V domains whose structures have been determined. With the exception of murine V2, which shows a different conformation due to a unique conformation of the adjacent C'' -strand (Reiser et al. 2000, 2003), the loops 82–88 of most other TCR V domains with RMSD values within 2.0 Å adopt similar conformations that are composed of one 3₁₀ helix from residues 83 to 87 (nomenclature from the 2C TCR structure). In contrast, loops 82–88 of human JM22 and C5–1 V17 display completely different conformations that lack obvious secondary structure elements (Fig. 4C). The three human V17 chains, JM22, C5–1_YS, and SF4, differ from all other TCR chains at the loop region (amino acids 82–88) with RMSD values larger than 3.1 Å. The V17 chains of class I and II MHC-restricted TCRs also differ from one another with an RMSD of 3.2 Å. Although the biological significance of this loop is unknown, it is clear that loop 82–88 is flexible and capable of adopting multiple conformations.

Comparison of the TCR V–C associations
The overall topologies of the V17 TCR chains derived from the RA patient are very similar to those of most other TCR chains (Fig. 4). Although the individual V and C domains of these two V17 chains can be readily superimposed onto their counterparts in other TCR chains, structural alignments of the complete chains result in large RMSD values, indicating considerable variation in the V–C associations. Interestingly, although the residues at the V–C interface are identical in the JM22 V17 chain (Stewart-Jones et al. 2003) and in the two V17 chains derived from the RA patient, a rotation angle as large as 23.4° is required for the best alignment of the C domains, after optimal alignment of the V domains (Fig. 4C). Structural comparison with other TCR chains revealed that the V–C associations of V17 SF4 and C5–1 are most similar to that of 2C TCR (PDB code 1MWA [PDB] ) in the crystal structure of a TCR-MHC complex (Luz et al. 2002), with a 15.3° rotation required to optimally align these C domains after optimal superimposition of the V domains. Comparison with other TCR V–C associations resulted in rotation angles ranging from 15.3° to 25.6° (data not shown). This finding implies that the TCR chains can tolerate quite large inter-domain movements, although the overall structures of individual domains of the TCR chains are relatively rigid (Bentley et al. 1995).

As discussed earlier, the crystal structures of V17 SF4 and C5–1_YS are in a nonliganded form, while the structure of the JM22 TCR is in a liganded form (Stewart-Jones et al. 2003). Therefore, it is possible that the difference in V–C domain arrangement between C5–1_YS and JM22 V17 represents a conformational change upon ligand binding, although crystal packing effects can not be ruled out. The structural differences in V–C domain arrangement observed here may have functional significance. A difference in V–C arrangement may affect the elbow angle of a TCR. Elbow angle is a term coined to define the angle between the V_L/V_H and C_L/C_H1 pseudo dyads of a Fab fragment of an antibody. Due to the structural similarity between TCR and Fab, the elbow angle terminology can also be used for TCR, to define the relative orientation between the TCR V and C modules. Although there is no solid evidence for any signaling function through the elbow region of the TCR, the elbow angle of an antibody is thought to be essential for molecular signaling upon complexing with the antigen (Colman 1988; Lesk and Chothia 1988; Guddat et al. 1994, 1995; Landolfi et al. 2001). Nevertheless, a difference in V–C arrangement will affect the relative orientations of V and V domains of the TCR, which in turn influence the peptide/MHC specificity (Garcia et al. 1999). It is well known that the relative orientations of the TCR V/V domains vary significantly (Li et al. 1997; Garcia et al. 1999). Although this has not been extensively studied, due to the limited number of crystal structures of TCRs available, the impact of V/V pairing variability on the TCR’s ligand specificity has been demonstrated in a recent study (Maynard et al. 2005). Both TCRs D10 and 172.10 use V8.2. Their V domains, V2 in D10 and V2.3 in 172.10, are also highly similar, with 84% sequence identity. These two TCRs recognize different peptide/MHC molecules (Reinherz et al. 1999; Maynard et al. 2005). However, structural comparison showed that the V–V association in the two TCRs differs by a rotational angle of 15°, resulting in TCR footprints on different regions of the peptide/MHC molecules. Clearly, differences in TCR V–C associations will ultimately affect the relative V–V orientations, which may modulate the TCR’s peptide/MHC specificity (Garcia et al. 1999; Maynard et al. 2005).

Possible binding site for the superantigen MAM
The SAg MAM has been proposed to be involved in the pathogenesis of human RA (Emery et al. 1985; Cole and Griffiths 1993; Knudtson et al. 1997b; Mu et al. 2000; Sawitzke et al. 2000). The crystal structure of a MAM-MHC complex (Zhao et al. 2004) reveals that MAM, like other SAgs, binds very well to class II MHC molecules. In addition, MAM interacts with TCRs in a V-restricted fashion, as occurs for other SAgs. It has been demonstrated that MAM stimulates T cells expressing murine V6, 7, and 8.1–3. Although human T cells are less responsive to MAM than are murine ones, T cells bearing human V 3.1, 5.1, 7.1, 8.1, 10, 11.1, 12, 13.1, 14, 17, or 20 can be polyclonally expanded to various degrees during MAM induction (Knudtson et al. 1997a). Structure determination of human V17 may allow us to investigate the molecular mechanism by which human T cells are activated by MAM, a superantigen that may be implicated in the development of human RA.

Although the crystal structure of a MAM-TCR complex has not been determined, crystal structures of several staphylococcal and streptococcal pyrogenic SAgs complexed with TCR chains have been reported (Fields et al. 1996; Li et al. 1998b; Sundberg et al. 2002). In these pyrogenic SAg-TCR complexes, SAgs bind uniformly to the CDR2 and FR3 regions of the TCR chains, although the V CDR1, CDR3, and HV4 regions contribute to a certain extent toward the binding to various SAgs (Fields et al. 1996; Li et al. 1998b; Li et al. 1999; Sundberg et al. 2002). A SAg-TCR recognition mechanism, which is highly dependent on the main-chain conformations of the TCR V CDR2 and FR3 regions, has been proposed (Fields et al. 1996; Li et al. 1998b, 1999). The SAgs MAM, SEB, and SEC1–3 have nearly identical TCR V specificities (Fields et al. 1996; Knudtson et al. 1997a). Possibly, the binding site on the TCR V domains for MAM is similar to the binding sites for SEB and SEC1–3. As indirect evidence, MAM, SEB, and SEC3 bind to class II MHC at nearly identical sites (Jardetzky et al. 1994; Sundberg et al. 2003; Zhao et al. 2004), although MAM does not show any structural similarity to SEB or SEC1–3 (Zhao et al. 2004).

Nevertheless, crystal structures have been determined for both MAM-reactive and nonreactive TCR chains, and comparison of these structures may reveal critical information about the MAM binding sites on TCR chains. Although there are about 37 PDB entries related to TCRs, including TCRs (Garcia et al. 1996; Housset et al. 1997; Wang et al. 1998; Hare et al. 1999; Allison and Garboczi 2002; Kjer-Nielsen et al. 2002), TCR components (Bentley et al. 1995; Fields et al. 1995; Li et al. 1997, 1998a; Plaksin et al. 1999; Machius et al. 2001; Rudolph et al. 2001), TCRs complexed with class I or class II MHC/peptide complex molecules (Garboczi et al. 1996a; Ding et al. 1998, 1999; Garcia et al. 1998; Reinherz et al. 1999; Degano et al. 2000; Hennecke et al. 2000; Reiser et al. 2000, 2002, 2003; Hennecke and Wiley 2002; Luz et al. 2002; Buslepp et al. 2003; Kjer-Nielsen et al. 2003; Stewart-Jones et al. 2003; Hahn et al. 2005; Maynard et al. 2005), and TCR components complexed with bacterial superantigens (Fields et al. 1996; Li et al. 1998b; Sundberg et al. 2002), only eight TCR V families have been structurally characterized. Three are of mouse origin (V2, V5.2, and V8.2) and five are from humans (V2, V3, V6.3, V12.3, and V17). Structural superposition of the human V17C5–1_YS V domain in our study onto other TCR V domains resulted in RMSD values that fell into two distinct groups. The V17C5–1 V domain superimposed well onto murine V8.2, and onto human V3 and V12.3, with overall RMSD values ranging from 0.73 Å to 0.98 Å (Fig. 4D). It is notable that these four TCR chains, murine V8.2 and human V3, V12.3, and V17, are the primary ones used by MAM (Knudtson et al. 1997b). On the other hand, the RMSD values between V17C5–1 and murine V2 and V5.2, and between C5–1_YS and human V2.1 and V6.3, are much larger, ranging from 1.24 Å to 1.67 Å (Fig. 4E). T cells bearing these chains (murine V2 and V5.2, and human V2.1 and V6.3) are known to be nonreactive to MAM stimulation (Knudtson et al. 1997a).

Because MAM can stimulate T cells bearing chains of a number of V families, regions that show large structural differences among various MAM-reactive chains probably do not contribute greatly to the binding to MAM. Structural alignments of the MAM-reactive TCR V domains reveal that these V domains superimpose well onto one another, with exceptions at regions 8–12, 40–44, 82–88, CDR3, and HV4; in these regions, relatively large structural differences are observed (Fig. 4D). In addition to the regions where large structural differences were observed among MAM-reactive V domains, significant structural differences between MAM-reactive and nonreactive TCR V domains were observed at the CDR1, CDR2, and FR3 regions (Fig. 4E). It should be noted that the latter two regions contribute most strongly to the binding to the pyrogenic SAgs (Fields et al. 1996; Li et al. 1998b, 1999; Sundberg et al. 2002). Because MAM is known to activate T cells bearing murine V8.2, and human V3, V12.3, and V17, but not murine V2, V5.2, or human V2.1, V6.3, the structural differences in the CDR2 and FR3 regions indicate that these portions of the TCR chains account for the binding to MAM. Since the TCR chains recognized by various SAgs differ significantly in the CDR2 and FR3 regions, we could extend the hypothesis to all SAgs: The CDR2 and FR3 regions of TCR chains may determine the SAg specificity. In other words, the SAgs may uniformly bind to the CDR2 and FR3 regions of TCR chains. Structural studies of TCR -chain complexed with MAM or other SAgs are needed before we can determine whether a common recognition mechanism operates to permit MAM and other SAgs to interact with various V families.

	Materials and methods

TOP Abstract Introduction Results and Discussion Materials and methods References

 
Expression plasmid constructions
The cDNA plasmids encoding the chains (V17) of T cell receptors (C5–1 and SF4) derived from the synovial fluid and tissue of a RA patient (Li et al. 1994) were used as the source for the molecular cloning. The primers used to generate TCR chains (residues 1–242) were 5'-GGAATTCCATATGGATG GTGGAATCACTCAGTCC-3' (upstream primer) and 5'-CC GCTCGAGTCAGTCTGCTCTACCCCAGGCCTC-3' (downstream primer), and they contained the NdeI and XhoI restriction sites (underlined), respectively. The PCR products were subcloned into the TA cloning vector (Invitrogen). The resulting positive plasmids were confirmed by restriction mapping and DNA sequencing analysis. The plasmids were double-digested with NdeI and XhoI, and the extracted inserts were ligated into the pET26b(+) vector (Novagen), to generate the expression plasmid. For V17C5–1 (V17–D2–J2.1–C2), further mutagenesis was carried out to change the free cysteine, Cys187, to a serine. In order to generate a TCR V17 molecule with high affinity to the SAg MAM (Hodtsev et al. 1998), we introduced a F104Y mutation into V17 C5–1 (designated as C5–1_YS). Pairs of primers (C187S: 5'-AATGACTCCAGATAC TCCCTGAGCAGCCGCCTGAG-3' and 5'-CTCAGGCGGC TGCTCAGGGAGTATCTGGAGTCATT-3'; F104Y: 5'-CAG ATGAATGAGCAGTACTTCGGGCCAGGGACACG-3' and 5'-CGTGTCCCTGGCCCGAAGTACTGCTCATTC ATCTG) were used with the expression plasmid pET26b-V17C5–1 as the template for site-directed mutagenesis (Stratagene). The correct mutation of the resulting mutant plasmid was confirmed by DNA sequencing analysis.

Protein expression, purification, and refolding
Native proteins of V17C5–1_YS and V17SF4 were expressed as inclusion bodies in Escherichia coli BL21 (DE3)pLysS (Novagen). To produce selenium-methionine (Se-Met)-substituted V17C5–1_YS, the expression plasmid was transformed into the methionine auxotrophic E. coli strain B834 (Novagen). Cells were grown in minimal medium containing Se-Met at 37°C. Soluble native and Se-Met-substituted V17 proteins were refolded from purified inclusion bodies, using the protocol as described (Garboczi et al. 1996b). The refolded proteins were concentrated in an Amicon stirred cell unit (Millipore), filtered to remove precipitates, and subjected to gel filtration chromatography on a Superdex-200 column (Pharmacia). The peak fractions were pooled together and dialyzed at 4° against 20 mM Tris buffer (pH 8.0). Further purification was carried out on a Pharmacia MonoQ anion-exchange column with a linear NaCl gradient. Fractions containing the V17 proteins were recovered, buffer-exchanged, and concentrated to about 5 mg/mL in the buffer containing 20 mM Tris (pH 8.0), 100 mM NaCl, 1 mM DTT, for further analysis. For Se-Met-substituted protein, 5 mM DTT was added, to prevent oxidization of the Se-Met.

Crystallization, diffraction data collection, structure determination, and refinement
Using the hanging drop evaporation method, we obtained small crystals, under condition 16 of the Hampton Crystallization Screen (1.5 M lithium sulfate as the precipitate) within 30 min after the start of the crystallization experiment. After optimization, the best crystals were obtained at room temperature by mixing 2 µ L of protein solution with an equal volume of 0.6–0.7 M sodium citrate, 0.1 M HEPES (pH 7.5). Eye-shaped crystals grew to dimensions up to 0.3 x 0.3 x 0.1 mm³ within 1 wk. The crystals belong to space group P6₃22, with cell dimensions a = b = 187.5 Å, c = 86.7 Å for native V17SF4, and a = b = 187.3 Å, c = 86.3 Å for Se-Met-substituted V17C5–1_YS. There are two TCR chains per asymmetric unit.

Prior to data collection, all crystals were transferred to a reservoir solution containing 20% glycerol, and then flash-cooled under a nitrogen stream at 100 K. Data for the native V17SF4 crystals were collected to 2.65 Å resolution at 100 K at beamline X25 of the National Synchrotron Light Source (NSLS) of the Brookhaven National Laboratory (BNL) (Table 1). All of the diffraction data were processed and scaled using HKL2000 (Otwinowski and Minor 1997), followed by truncation with programs in the CCP4 suite (CCP4 1994).

Attempts to determine the crystal structures of V17SF4 by molecular replacement with known structures of the TCR V domains, including V17 (Stewart-Jones et al. 2003), as the search models failed. We therefore determined the crystal structures using the MAD phasing method. V17C5–1_YS was selected for the production of Se-Met-substituted protein, because V17C5–1_YS has two nonterminal Met residues, as compared to one in V17SF4. A set of three-wavelength MAD data was collected to 2.7 Å for the Se-Met-substituted V17C5–1_YS crystals at beamline X25 of the NSLS (Table 1). MAD calculation using the program SOLVE (Terwilliger and Berendzen 1999) clearly defined the positions of the two Se atoms. Further search for additional sites failed to generate obvious solutions, presumably because other Met residues were not well-ordered in the crystal. Nevertheless, an interpretable electron density map could be generated after density modification using the program RESOLVE (Terwilliger 2001). Polyalanine fragments containing about 60% of the V17C5–1_YS residues of one molecule and 40% of the residues of the second molecule could be automatically traced. The partial structure showed -strand structure, which is typical for a TCR. Therefore, the variable and constant domains of the known V17 structure of a JM22 TCR (Stewart-Jones et al. 2003) were manually aligned with this partial structure using the program TURBO-FRODO (Roussel and Cambillau 1989). The structure refinement was completed using CNS (Brunger et al. 1998). After the rigid-body refinement, iterative cycles of simulated annealing and positional, torsion angle, and temperature factor (B) refinements, were carried out with noncrystallographic symmetry (NCS) restrains; these cycles were interspersed with model rebuilding into _A-weighted (F_o – F_c) and (2F_o – F_c) electron density maps. At 2.7 Å resolution, the final R_cryst is 23.7%, with an R_free of 28.0%.

The structure of V17SF4 was determined by the difference Fourier method, using the partially refined structure of V17C5–1_YS as a starting model. The structure refinement was carried out similarly to that done for V17C5–1_YS using CNS. Omit maps for groups of V17 CDR3 residues were frequently calculated, as a check of the correct tracing and conformations. At 2.65 Å resolution, the final R_cryst is 23.3% with an R_free of 28.6%.

For the nonglycine residues, the main-chain torsion angles of all residues lie in the most favored or allowed regions of the Ramachandran plot (data not shown). The refinement statistics are summarized in Table 1. Atomic coordinates for V17C5–1_YS and V17SF4 have been deposited in the Protein Data Bank (PDB) as entries 2AXH [PDB] and 2AXJ.

Analytical ultracentrifugation
Sedimentation-velocity experiments were done at 20°C in a Beckman Optima XL-I analytical ultracentrifuge at a rotor speed of 55,000 rpm. (An50Ti rotor). Double-sector cells were loaded with 400 µ L of proteins at a concentration of 14 µ M (V17SF4), 42 µ M (V17C5–1_YS), or 140 µ M (V17SF4), in 2 mM DTT, 0.1 M NaCl, 10 mM Hepes buffer (pH 7.5). Data were recorded with absorbance detection at wavelengths of 280, 294, and 300 nm for low, moderate, and high concentrations of protein, respectively. Absorbance fringe displacement profiles were analyzed with the software SEDFIT (http://www.analyticalultracentrifugation.com) (Vistica et al. 2004), using a model for continuous sedimentation coefficient distributions c(s) (Schuck et al. 2002). Distributions were calculated with maximum entropy regularization at a predetermined confidence level of 1 standard deviation. In further analysis, the differential S value distribution was integrated, to determine weight-average sedimentation coefficients.

Sedimentation equilibrium studies were conducted at a temperature of 20°C and at three rotor speeds of 20,000 rpm, 25,000 rpm, and 30,000 rpm. 110 µ L of proteins were respectively loaded into Epon double-sector centerpieces, at a concentration of 8.7 µ M, 14 µ M, or 22.3 µ M, in 2 mM DTT, 0.1 M NaCl, 10 mM Hepes buffer (pH 7.5). Equilibrium absorbance profiles were acquired at 294-nm wavelength. The equilibrium sedimentation data were analyzed using the software SEDPHAT (http://www.analyticalultracentrifugation.com) (Vistica et al. 2004). Data analysis was performed by global least-squares analysis of the data from multiple concentrations and multiple rotor speeds, based on the well-known superposition of the Boltzmann distributions of ideal species in the centrifugal field, using conservation of mass constraints (Vistica et al. 2004).

	Footnotes

 
⁴ Present address: Department of Biological Chemistry and Molecular Pharmacology, Harvard Medical School, Boston, MA 02115, USA.

	Acknowledgments

 
This research is supported by grant AI50628 from the NIH (to H.L.). We thank the Biochemistry and Macromolecular Crystallography Core facilities at the Wadsworth Center for assistance with the sedimentation and crystallography experiments, and the Molecular Genetics Core facility for DNA sequencing. We also thank A. Verschoor at the Wadsworth Center for critical review of the manuscript and R. Sweet and M. Becker at NSLS for assistance in X-ray data collection. The X-ray diffraction facilities at the NSLS are supported by the Department of Energy and by grants from the NIH.

	References

TOP Abstract Introduction Results and Discussion Materials and methods References

 
Acuto, O., Hussey, R.E., and Reinherz, E.L. 1985. Multiple class I and class II major histocompatibility complex allospecificities are generated with T cell receptor variable (V) domains created by a single Ti V gene family. J. Exp. Med. 162: 1387–1392.[Abstract/Free Full Text]

Alam, S.M., Sim, B.C., and Gascoigne, N.R. 1995. Selection of TCR V by MHC class II predicts superantigen reactivity. Int. Immunol.