GYF domain proteomics reveals interaction sites in known and novel target proteins

GYF domains are conserved eukaryotic adaptor domains that recognize proline-rich sequences. Although the structure and function of the prototypic GYF domain from the human CD2BP2 protein have been characterized in detail, very little is known about GYF domains from other proteins and species. Here we describe the binding properties of four GYF domains of various origins. Phage display in combination with SPOT analysis revealed the PPG(F/I/L/M/V) motif as a general recognition signature. Based on these results, the proteomes of human, yeast, and Arabidopsis thaliana were searched for potential interaction sites. Binding of several candidate proteins was confirmed by pull-down experiments or yeast two-hybrid analysis. The binding epitope of the GYF domain from the yeast SMY2 protein was mapped by NMR spectroscopy and led to a structural model that accounts for the different binding properties of SMY2-type GYF domains and the CD2BP2-GYF domain.     

Recognition sequences for the GYF domain reveal a possible spliceosomal function of CD2BP2

Protein-protein interactions are often mediated by small domains that recognize solvent-exposed peptide sequences. Deciphering the recognition code for these adapter domains is an important step in the understanding of multi-protein assemblies. Here, we investigate the sequence requirements for the CD2BP2-GYF domain, a proline-rich sequence binding module previously shown to be involved in T cell signaling. We show that the signature (R/K/G)XXPPGX(R/K) defines a preferred peptide-binding motif that is present in several proteins of the splicing machinery. Specifically, the core small nuclear ribonucleoprotein, SmB/B', contains several PPP-PGMR motifs that interact with the CD2BP2-GYF domain in vitro and in vivo. The colocalization of CD2BP2 and SmB proteins in the nucleus of Jurkat T cells and HeLa cells suggests a function of the GYF domain of CD2BP2 in mediating protein-protein interactions within the spliceosome.     

The GYF domain

GYF domains are small, versatile adaptor domains that recognize proline-rich sequences (PRS). They are present in most eukaryotic species sequenced so far, but in contrast to other PRS-recognition domains (PRD), GYF domains have not experienced the same amplification in metazoa during evolution. Mutational and structural analysis has shown the conserved signature W-X-Y-X(6-11)-GPF-X(4)-M-X(2)-W-X(3)-GYF to be the site of interaction with proline-rich peptides. In contrast, composition and length of the C-terminal half of GYF domains are not conserved. Similar to other PRD, GYF domains bind to many different PRS that converge on a minimal consensus sequence. All GYF domains analyzed so far selected for the core motif PPG, whereas amino-acid preferences adjacent to this motif vary. As a result of this analysis, two subfamilies have been identified: CD2BP2-type and SMY2-type GYF domains. The latter subfamily comprises most GYF domains and is characterized by a shorter beta(1)-beta(2) loop and an aspartate instead of the tryptophan found at position 8 in CD2BP2-type GYF domains. Recent analysis of binding specificities for GYF domains allowed identification of novel interaction partners. Thereby proteomics has contributed to a functional understanding of GYF domain-containing proteins and sets the stage for a more systematic investigation of their functions in vivo.     

Alternative binding modes of proline-rich peptides binding to the GYF domain

Recognition of proline-rich sequences plays an important role for the assembly of multiprotein complexes during the course of eukaryotic signal transduction and is mediated by a set of protein folds that share characteristic features. The GYF (glycine-tyrosine-phenylalanine) domain is known as a member of the superfamily of recognition domains for proline-rich sequences. Recent studies on the complexation of the CD2BP2-GYF domain with CD2 peptides showed that the peptide adopts an extended conformation and forms a polyproline type-II helix involving residues Pro4-Pro7 [Freund et al. (2002) EMBO J. 21, 5985-5995]. R/K/GxxPPGxR/K is the key signature for the peptides that bind to the GYF domain [Kofler et al. (2004) J. Biol. Chem. 279, 28292-28297]. In our combined theoretical and experimental study, we show that the peptides adopt a polyproline II helical conformation in the unbound form as well as in the complex. From molecular dynamics simulations, we identify a novel binding mode for the G8W mutant and the wild-type peptide (shifted by one proline in register). In contrast, the conformation of the peptide mutant H9M remains close to the experimentally derived wild-type GYF-peptide complex. Possible functional implications of this altered conformation of the bound ligand are discussed in the light of our experimental and theoretical results.     

Dynamic interaction of CD2 with the GYF and the SH3 domain of compartmentalized effector molecules

Intracellular protein interaction domains are essential for eukaryotic signaling. In T cells, the CD2BP2 adaptor binds two membrane-proximal proline-rich motifs in the CD2 cytoplasmic tail via its GYF domain, thereby regulating interleukin-2 production. Here we present the structure of the GYF domain in complex with a CD2 tail peptide. Unlike SH3 domains, which use two surface pockets to accommodate proline residues of ligands, the GYF domain employs phylogenetically conserved hydrophobic residues to create a single interaction surface. NMR analysis shows that the Fyn but not the Lck tyrosine kinase SH3 domain competes with CD2BP2 GYF-domain binding to the same CD2 proline-rich sequence in vitro. To test the in vivo significance of this competition, we used co-immunoprecipitation experiments and found that CD2BP2 is the ligand of the membrane-proximal proline-rich tandem repeat of CD2 in detergent-soluble membrane compartments, but is replaced by Fyn SH3 after CD2 is translocated into lipid rafts upon CD2 ectodomain clustering. This unveils the mechanism of a switch of CD2 function due to an extracellular mitogenic signal.     

The GYF domain is a novel structural fold that is involved in lymphoid signaling through proline-rich sequences.

T cell activation through the CD2 cell surface receptor is transmitted by proline-rich sequences within its cytoplasmic tail. A membrane-proximal proline-rich tandem repeat, involved in cytokine production, is recognized by the intracellular CD2 binding protein CD2BP2. We solved the solution structure of the CD2 binding domain of CD2BP2, which we name the glycine-tyrosine-phenylalanine (GYF) domain. The GYF sequence is part of a structurally unique bulge-helix-bulge motif that constitutes the major binding site for the CD2 tail. A hydrophobic surface patch is created by motif residues that are highly conserved among a variety of proteins from diverse eukaryotic species. Thus, the architecture of the GYF domain may be widely used in protein-protein associations.     

Structural investigations of a GYF domain covalently linked to a proline-rich peptide

Protein structure determination of low affinity complexes of interacting macromolecules is often hampered by a lack of observable NOEs between the binding partners. Covalent linkage offers a way to shift the equilibrium of the interaction partners to the bound state. Here we show that a single-chain protein containing the GYF domain of CD2BP2 and the target peptide SHRPPPPGHRV from CD2 allows for the intramolecular association of the binding partners. We obtained NOEs between the GYF domain and the peptide that could define the principal orientation of the peptide in the complex. In conjunction with general recognition rules for proline-rich sequence recognition these NOEs allowed the accurate modeling of the protein-peptide complex.     

The adaptor protein 3BP2 binds human CD244 and links this receptor to Vav signaling, ERK activation, and NK cell killing

Adaptor proteins, molecules that mediate intermolecular interactions, are crucial for cellular activation. The adaptor 3BP2 has been shown to positively regulate NK cell-mediated cytotoxicity. In this study we present evidence for a physical interaction between 3BP2 and the CD244 receptor. CD244, a member of the CD150 family, is a cell surface protein expressed on NK, CD8+ T, and myeloid cells. CD244 interacts via its Src homology 2 domain with the X-linked lymphoproliferative disease gene product signaling lymphocytic activation molecule-associated protein (SAP)/SH2 domain protein 1A. 3BP2 interacts with human but not murine CD244. CD244-3BP2 interaction was direct and regulated by phosphorylation, as shown by a three-hybrid analysis in yeast and NK cells. Tyr337 on CD244, part of a consensus motif for SAP/SH2 domain protein 1A binding, was critical for the 3BP2 interaction. Although mutation of Tyr337 to phenylalanine abrogated human 3BP2 binding, we still observed SAP association, indicating that this motif is not essential for SAP recruitment. CD244 ligation induced 3BP2 phosphorylation and Vav-1 recruitment. Overexpression of 3BP2 led to an increase in the magnitude and duration of ERK activation, after CD244 triggering. This enhancement was concomitant with an increase in cytotoxicity due to CD244 ligation. However, no differences in IFN-gamma secretion were found when normal and 3BP2-transfected cells were compared. These results indicate that CD244-3BP2 association regulates cytolytic function but not IFN-gamma release, reinforcing the hypothesis that, in humans, CD244-mediated cytotoxicity and IFN-gamma release involve distinct NK pathways.     

Analysis of the CD2 and spliceosomal Sm B/B' polyproline-arginine motifs defined by a monoclonal antibody using a phage-displayed random peptide library

The cytoplasmic region of the CD2 receptor of lymphocytes contains proline-rich motifs, which are involved in T cell activation and interleukin-2 production. An intracellular CD2 binding protein, CD2BP2, interacts with two tandem PPPPGHR segments of the CD2 tail. CD2BP2 contains a GYF (glycine-tyrosine-phenylalanine) domain that confers binding to these proline-rich sequences. Monoclonal antibody 3E10 that was previously raised against a peptide containing the CD2 PPPPGHR segment reacts with the native CD2 molecule and spliceosomal Sm B/B' proteins. To identify the exact epitope on the CD2 peptide recognized by 3E10, a phage-displayed combinatorial peptide library was used. Analysis of the selected clones revealed that the mAb 3E10 binds preferentially to the motif PxxPPGxR. Experiments using amino acid substitutions with synthetic peptides confirmed the reactivity of mAb 3E10 with this motif. In addition, we show that several similarities exist between this motif and the CD2BP2-GFY recognition motif PPGxR/K. Binding of antibody 3E10 indicates some degree of degeneracy, which is consistent with its ability to recognize structurally related polyproline-arginine motifs found in intracellular proteins including Sm B/B' proteins and other RNA binding proteins. Thus, mAb 3E10 can be used to specifically identify a sub-class of proline-rich motifs, and as such can be used to study the potential role of these proline-rich sequences in mediating protein-protein interactions.     

A cdc15-like adaptor protein (CD2BP1) interacts with the CD2 cytoplasmic domain and regulates CD2-triggered adhesion.

A human CD2 cytoplasmic tail-binding protein, termed CD2BP1, was identified by an interaction trap cloning method. Expression of CD2BP1 is restricted to hematopoietic tissue, being prominent in T and natural killer (NK) cells, with long (CD2BP1L) and short (CD2BP1S) variants arising by alternative RNA splicing. Both CD2BP1 molecules are homologous to Schizosaccharomyces pombe cdc15, and include a helical domain, variable length intervening PEST sequence and C-terminal SH3 domain. Although the CD2BP1 SH3 domain binds directly to the CD2 sequence, KGPPLPRPRV (amino acids 300-309), its association is augmented markedly by the CD2BP1 N-terminal segment. Upon ligand-induced clustering of surface CD2 molecules, CD2BP1 redistributes from a cytosolic to a surface membrane compartment, co-localizing with CD2. In turn, CD2-stimulated adhesion is downregulated by CD2BP1, apparently through coupling of the protein tyrosine phosphatase (PTP)-PEST to CD2. These findings offer the first molecular view into the control processes for T cell adhesion.     

GYF结构域蛋白特性及其生物学功能研究进展

甘氨酸-络氨酸-苯丙氨酸(glycine-tyrosine-phenylalanine,GYF)结构域是一种小型的、能识别富脯氨酸序列(proline rich sequences,PRS)的保守、多功能接合结构域,GYF结构域蛋白在蛋白蛋白相互作用、翻译起始、mRNA剪接、监管与翻译抑制、泛素连接、信号转导、免疫蛋白酶调控等方面起重要作用。本文从结构域特性、与靶蛋白的相互作用及其功能等方面综述GYF结构域蛋白的研究进展。     

Mutational analysis of the human 2B4 (CD244)/CD48 interaction: Lys68 and Glu70 in the V domain of 2B4 are critical for CD48 binding and functional activation of NK cells

Interaction between receptors and ligands plays a critical role in the generation of immune responses. The 2B4 (CD244), a member of the CD2 subset of the Ig superfamily, is the high affinity ligand for CD48. It is expressed on NK cells, T cells, monocytes, and basophils. Recent data indicate that 2B4/CD48 interactions regulate NK and T lymphocyte functions. In human NK cells, 2B4/CD48 interaction induces activation signals, whereas in murine NK cells it sends inhibitory signals. To determine the structural basis for 2B4/CD48 interaction, selected amino acid residues in the V domain of the human 2B4 (h2B4) were mutated to alanine by site-directed mutagenesis. Following transient expression of these mutants in B16F10 melanoma cells, their interaction with soluble CD48-Fc fusion protein was assessed by flow cytometry. We identified amino acid residues in the extracellular domain of h2B4 that are involved in interacting with CD48. Binding of CD48-Fc fusion protein to RNK-16 cells stably transfected with wild-type and a double-mutant Lys(68)Ala-Glu(70)Ala h2B4 further demonstrated that Lys(68) and Glu(70) in the V domain of h2B4 are essential for 2B4/CD48 interaction. Functional analysis indicated that Lys(68) and Glu(70) in the extracellular domain of h2B4 play a key role in the activation of human NK cells through 2B4/CD48 interaction.     

T2BP, a novel TRAF2 binding protein, can activate NF-kappaB and AP-1 without TNF stimulation.

TRAF2 is a key molecule involved in TNF signaling, which is crucial for the regulation of inflammatory processes. We have identified a novel TRAF2 binding protein, designated as T2BP (TRAF2 binding protein), by a mammalian two-hybrid screening approach. T2BP is a relatively small protein of 184 amino acids, which includes a forkhead-associated domain, the phosphopeptide binding motif. The interaction domain search showed that the TRAF domain in TRAF2 is required for the binding to T2BP whereas almost the entire protein in T2BP binds to TRAF2. The interaction was further confirmed by co-immunoprecipitation. Expression profiling for T2BP and TRAF2 revealed an ubiquitous expression in adult mouse tissues. Overexpression of T2BP in HEK293 cells activated NF-kappaB and AP-1 in a dose dependent manner as well as seen in the TNF-treated control cells. Our results suggest that T2BP is involved in the TNF-mediated signaling by its interaction with TRAF2.     

Design, structure and biological activity of beta-turn peptides of CD2 protein for inhibition of T-cell adhesion.

The interaction between cell-adhesion molecules CD2 and CD58 is critical for an immune response. Modulation or inhibition of these interactions has been shown to be therapeutically useful. Synthetic 12-mer linear and cyclic peptides, and cyclic hexapeptides based on rat CD2 protein, were designed to modulate CD2-CD58 interaction. The synthetic peptides effectively blocked the interaction between CD2-CD58 proteins as demonstrated by antibody binding, E-rosetting and heterotypic adhesion assays. NMR and molecular modeling studies indicated that the synthetic cyclic peptides exhibit beta-turn structure in solution and closely mimic the beta-turn structure of the surface epitopes of the CD2 protein. Docking studies of CD2 peptides and CD58 protein revealed the possible binding sites of the cyclic peptides on CD58 protein. The designed cyclic peptides with beta-turn structure have the ability to modulate the CD2-CD58 interaction.     

Structural and functional characterization of the CD2 immunoadhesion domain. Evidence for inclusion of CD2 in an alpha-beta protein folding class

The T-lymphocyte transmembrane glycoprotein CD2 plays an important physiological role in facilitating adhesion between T-lymphocytes and their cognate cellular partners. This interaction is mediated by binding of CD2 to the broadly distributed surface polypeptide LFA-3 and augments the recognition function of the CD3-Ti antigen-major histocompatibility complex receptor via stabilization of conjugate formation between cells. To define better the structural components of the CD2 extracellular region which are important in contact-mediated cellular adhesion, a single-domain CD2 immunoadhesion protein has been prepared from papain digestion of a soluble two-domain CD2 molecule. This amino-terminal domain fragment binds to LFA-3 on human B-cells with a dissociation constant of 0.4 microM, possesses functional immunoadhesion epitopes as defined by the binding of monoclonal antibodies raised to native CD2, and retains the ability to inhibit sheep erythrocyte rosette formation with human T-cells. Thus, all of the immunoadhesion functions ascribed to CD2 reside within the amino-terminal domain. Circular dichroism analysis of the isolated CD2 adhesion domain suggests the presence of substantial alpha-helical character (22%), consistent with earlier computer modeling analyses that predicted a pattern of alternating alpha-helices and beta-sheets within the extracellular region of CD2. Despite the existence of short stretches of sequence homology between CD2 and immunoglobulin superfamily members, the circular dichroism data provide supporting biophysical evidence for classification of CD2 in an alpha-beta (either alpha/beta or alpha + beta) protein folding class.     

The 3BP2 adapter protein is required for optimal B-cell activation and thymus-independent type 2 humoral response

3BP2 is a pleckstrin homology domain- and Src homology 2 (SH2) domain-containing adapter protein that is mutated in the rare human bone disorder cherubism and which has also been implicated in immunoreceptor signaling. However, a function for this protein has yet to be established. Here we show that mice lacking 3BP2 exhibited a perturbation in the peritoneal B1 and splenic marginal-zone B-cell compartments and diminished thymus-independent type 2 antigen response. 3BP2(-/-) B cells demonstrated a proliferation defect in response to antigen receptor cross-linking and a heightened sensitivity to B-cell receptor-induced death via a caspase-3-dependent apoptotic pathway. We show that 3BP2 binds via its SH2 domain to the CD19 signaling complex and is required for optimum Syk phosphorylation and calcium flux.