Structural basis for regulation of the Crk signaling protein by a proline switch

Proline switches, controlled by cis-trans isomerization, have emerged as a particularly effective regulatory mechanism in a wide range of biological processes. Here we report the structures of both the cis and trans conformers of a proline switch in the Crk signaling protein. Proline isomerization toggles Crk between two conformations: an autoinhibitory conformation, stabilized by the intramolecular association of two tandem SH3 domains in the cis form, and an uninhibited, activated conformation promoted by the trans form. In addition to acting as a structural switch, the heterogeneous proline recruits cyclophilin A, which accelerates the interconversion rate between the isomers, thereby regulating the kinetics of Crk activation. The data provide atomic insight into the mechanisms that underpin the functionality of this binary switch and elucidate its remarkable efficiency. The results also reveal new SH3 binding surfaces, highlighting the binding versatility and expanding the noncanonical ligand repertoire of this important signaling domain.     

Structural mechanism governing cis and trans isomeric states and an intramolecular switch for cis/trans isomerization of a non-proline peptide bond observed in crystal structures of scorpion toxins

Non-proline cis peptide bonds have been observed in numerous protein crystal structures even though the energetic barrier to this conformation is significant and no non-prolyl-cis/trans-isomerase has been identified to date. While some external factors, such as metal binding or co-factor interaction, have been identified that appear to induce cis/trans isomerization of non-proline peptide bonds, the intrinsic structural basis for their existence and the mechanism governing cis/trans isomerization in proteins remains poorly understood. Here, we report the crystal structure of a newly isolated neurotoxin, the scorpion alpha-like toxin Buthus martensii Karsch (BmK) M7, at 1.4A resolution. BmK M7 crystallizes as a dimer in which the identical non-proline peptide bond between residues 9 and 10 exists either in the cis conformation or as a mixture of cis and trans conformations in either monomer. We also determined the crystal structures of several mutants of BmK M1, a representative scorpion alpha-like toxin that contains an identical non-proline cis peptide bond as that observed in BmK M7, in which residues within or neighboring the cis peptide bond were altered. Substitution of an aspartic acid residue for lysine at residue 8 in the BmK M1 (K8D) mutant converted the cis form of the non-proline peptide bond 9-10 into the trans form, revealing an intramolecular switch for cis-to-trans isomerization. Cis/trans interconversion of the switch residue at position 8 appears to be sequence-dependent as the peptide bond between residues 9 and 10 retains its wild-type cis conformation in the BmK M1 (K8Q) mutant structure. The structural interconversion of the isomeric states of the BmK M1 non-proline cis peptide bond may relate to the conversion of the scorpion alpha-toxins subgroups.     

磷酸化对多肽中Xaa-Pro片段肽脯酰胺键顺反异构的影响研究

多肽和蛋白质中Xaa-Pro片段肽脯酰胺键顺反异构对其构象与功能有重要影响.设计合成了一系列模型多肽及其磷酸化多肽,并采用核磁共振实验和分子动力学模拟的方法,研究了所合成多肽中肽脯酰胺键的顺反异构化.结果表明,对脯氨酸之前的Xaa残基进行侧链O-磷酸化会极大地影响该顺反异构化过程,进而调节肽链构象.此外,磷酸化使得多肽顺式构象比例增加,且当磷酸基团不带负电荷时顺式构象所占比例最大.同时,分子动力学模拟所得结果与核磁共振实验相一致,包括最稳定构象和顺反构象统计分布.磷酸基团所带电荷及其空间位阻可能是影响这类磷酸化多肽构象变化的主要因素.     

Structural characterization of a proline-driven conformational switch within the Itk SH2 domain

Interleukin-2 tyrosine kinase (Itk) is a T cell-specific kinase required for a proper immune response following T cell receptor engagement. In addition to the kinase domain, Itk is composed of several noncatalytic regulatory domains, including a Src homology 2 (SH2) domain that contains a conformationally heterogeneous Pro residue. Cis-trans isomerization of a single prolyl imide bond within the SH2 domain mediates conformer-specific ligand recognition that may have functional implications in T cell signaling. To better understand the mechanism by which a proline switch regulates ligand binding, we have used NMR spectroscopy to determine two structures of Itk SH2 corresponding to the cis and trans imide bond-containing conformers. The structures indicate that the heterogeneous Pro residue acts as a hinge that modulates ligand recognition by controlling the relative orientation of protein-binding surfaces.     

Stabilization of a strained protein loop conformation through protein engineering.

Staphylococcal nuclease is found in two folded conformations that differ in the isomerization of the Lys 116-Pro 117 peptide bond, resulting in two different conformations of the residue 112-117 loop. The cis form is favored over the trans with an occupancy of 90%. Previous mutagenesis studies have shown that when Lys 116 is replaced by glycine, a trans conformation is stabilized relative to the cis conformation by the release of steric strain in the trans form. However, when Lys 116 is replaced with alanine, the resulting variant protein is identical to the wild-type protein in its structure and in the dominance of the cis configuration. The results of these studies suggested that any nuclease variant with a non-glycine residue at position 116 should also favor the cis form because of steric requirements of the beta-carbon at this position. In this report, we present a structural analysis of four nuclease variants with substitutions at position 116. Two variants, K116E and K116M, follow the "beta-carbon" hypothesis by favoring the cis form. Furthermore, the crystal structure of K116E is nearly identical to that of the wild-type protein. Two additional variants, K116D and K116N, provide exceptions to this simple "beta-carbon" rule in that the trans conformation is stabilized relative to the cis configuration by these substitutions. Crystallographic data indicate that this stabilization is effected through the addition of tertiary interactions between the side chain of position 116 with the surrounding protein and water structure. The detailed trans conformation of the K116D variant appears to be similar to the trans conformation observed in the K116G variant, suggesting that these two mutations stabilize the same conformation but through different mechanisms.     

Folding and domain-domain interactions of the chaperone PapD measured by 19F NMR

The folding of the two-domain bacterial chaperone PapD has been studied to develop an understanding of the relationship between individual domain folding and the formation of domain-domain interactions. PapD contains six phenylalanine residues, four in the N-terminal domain and two in the C-terminal domain. To examine the folding properties of PapD, the protein was both uniformly and site-specifically labeled with p-fluoro-phenylalanine ((19)F-Phe) for (19)F NMR studies, in conjunction with those of circular dichroism and fluorescence. In equilibrium denaturation experiments monitored by (19)F NMR, the loss of (19)F-Phe native intensity for both the N- and C-terminal domains shows the same dependence on urea concentration. For the N-terminal domain the loss of native intensity is mirrored by the appearance of separate denatured resonances. For the C-terminal domain, which contains residues Phe 168 and Phe 205, intermediate as well as denatured resonances appear. These intermediate resonances persist at denaturant concentrations well beyond the loss of native resonance intensity and appear in kinetic refolding (19)F NMR experiments. In double-jump (19)F NMR experiments in which proline isomerization does not affect the refolding kinetics, the formation of domain-domain interactions is fast if the protein is denatured for only a short time. However, with increasing time of denaturation the native intensities of the N- and C-terminal domains decrease, and the denatured resonances of the N-terminal domain and the intermediate resonances of the C-terminal domain accumulate. The rate of loss of the N-terminal domain resonances is consistent with a cis to trans isomerization process, indicating that from an equilibrium denatured state the slow refolding of PapD is due to the trans to cis isomerization of one or both of the N-terminal cis proline residues. The data indicate that both the N- and C-terminal domains must fold into a native conformation prior to the formation of domain-domain interactions.     

Apoptotic regulation by the Crk adapter protein mediated by interactions with Wee1 and Crm1/exportin

The adapter protein Crk contains an SH2 domain and two SH3 domains. Through binding of particular ligands to the SH2 domain and the N-terminal SH3 domain, Crk has been implicated in a number of signaling processes, including regulation of cell growth, cell motility, and apoptosis. We report here that the C-terminal SH3 domain, never shown to bind any specific signaling molecules, contains a binding site for the nuclear export factor Crm1. We find that a mutant Crk protein, deficient in Crm1 binding, promotes apoptosis. Moreover, this nuclear export sequence mutant [NES(-) Crk] interacts strongly, through its SH2 domain, with the nuclear tyrosine kinase, Wee1. Collectively, these data suggest that a nuclear population of Crk bound to Wee1 promotes apoptotic death of mammalian cells.     

Reversible photocontrol of peptide helix content: adjusting thermal stability of the cis state

Cross-linking reagents based on an azobenzene core can be used to reversibly photoregulate secondary structure when introduced as intramolecular bridges in peptides and proteins. Photoisomerization of the azobenzene core in the trans to cis direction is triggered by photon absorption but isomerization from cis to trans occurs thermally as well as photochemically. The rate of the thermal process effectively determines the half-life of the cis form as well as the extent to which the trans form can be recovered. We designed and characterized a series of methanethiosulfonate (MTS)-bearing thiol-reactive azo-benzene-based cross-linkers. These cross-linkers are shown to permit photoregulation of helix content in a test peptide with half-lives for the cis conformation ranging from 11 s to 43 h at 25 degrees C. The cross-linkers described here thus broaden the range of reagents available for reversible photocontrol of peptide and protein conformation.     

Direct evidence by H/D exchange and ESI-MS for transient unproductive domain interaction in the refolding of an antibody scFv fragment

The refolding kinetics of a single-chain Fv (scFv) fragment, derived from a stabilized mutant of the phosphorylcholine binding antibody McPC603, was investigated by H/D exchange and ESI-MS and compared with the folding kinetics of its constituting domains V(H) and V(L). Both V(H) and V(L) adopt essentially native-like exchange protection within the dead time of the manual-mixing H/D exchange experiment (10 s) and in the case of V(L), which contains two cis-prolines in the native conformation, this fast protection is independent of proline cis/trans isomerization. At the earliest time point resolvable by manual mixing, fewer deuterons are protected in the scFv fragment than in the two isolated domains together, despite the fact that the scFv fragment is significantly more stable than V(L) and V(H). Full H/D exchange protection in the scFv fragment is gained on a time scale of minutes. This means that the domains in the scFv fragment do not refold independently. Rather, they associate prematurely and in nonnative form, a kinetic trap. Unproductive domain association is observed both after equilibrium- and short-term denaturation. For the equilibrium-denatured scFv fragment, whose native structure formation is dependent on a cis conformation of an interface proline in V(L), this cis/trans isomerization reaction proceeds about one order in magnitude more slowly than the escape from the trap to a conformation where full H/D exchange protection is already achieved. We interpret these data in terms of a general kinetic scheme involving intermediates with and without domain association.     

Mutagenic analysis of the roles of SH2 and SH3 domains in regulation of the Abl tyrosine kinase.

We have used in vitro mutagenesis to examine in detail the roles of two modular protein domains, SH2 and SH3, in the regulation of the Abl tyrosine kinase. As previously shown, the SH3 domain suppresses an intrinsic transforming activity of the normally nontransforming c-Abl product in vivo. We show here that this inhibitory activity is extremely position sensitive, because mutants in which the position of the SH3 domain within the protein is subtly altered are fully transforming. In contrast to the case in vivo, the SH3 domain has no effect on the in vitro kinase activity of the purified protein. These results are consistent with a model in which the SH3 domain binds a cellular inhibitory factor, which in turn must physically interact with other parts of the kinase. Unlike the SH3 domain, the SH2 domain is required for transforming activity of activated Abl alleles. We demonstrate that SH2 domains from other proteins (Ras-GTPase-activating protein, Src, p85 phosphatidylinositol 3-kinase subunit, and Crk) can complement the absence of the Abl SH2 domain and that mutants with heterologous SH2 domains induce altered patterns of tyrosine-phosphorylated proteins in vivo. The positive function of the SH2 domain is relatively position independent, and the effect of multiple SH2 domains appears to be additive. These results suggest a novel mechanism for regulation of tyrosine kinases in which the SH2 domain binds to, and thereby enhances the phosphorylation of, a subset of proteins phosphorylated by the catalytic domain. Our data also suggest that the roles of the SH2 and SH3 domains in the regulation of Abl are different in several respects from the roles proposed for these domains in the closely related Src family of tyrosine kinases.     

Structural analysis of free and enzyme-bound amaranth alpha-amylase inhibitor: classification within the knottin fold superfamily and analysis of its functional flexibility.

The three-dimensional structure of the amaranth alpha-amylase inhibitor (AAI) adopts a knottin fold of abcabc topology. Upon binding to alpha-amylase, it adopts a more compact conformation characterized by an increased number of intramolecular hydrogen bonds, a decreased volume and in addition a trans to cis isomerization of Pro20. A systematic analysis of the 3-D structural databanks revealed that similar proteins and domains share with AAI the characteristic presence of proline residues, many of which are in a cis backbone conformation. As these proteins fulfil a variety of functional roles and are expressed in very different organisms, we conclude that the structure of the knottin fold, including the propensity of the cis bond, are the result of convergent evolution.     

Structural analysis of the immature form of the GFP homologue DsRed

The crystal structures of DsRed have shown that it contains an unusual non-proline containing cis peptide linkage. We have shown that it is also present in the precyclized immature form of DsRed, thereby eliminating the possibility that cis/trans isomerization drives the formation of the acylimine, which is responsible for DsRed's red fluorescence. Two mechanisms have been proposed for chromophore formation in green fluorescent protein (GFP), a "reduced" and an "oxidized" mechanism. DsRed adopts a tight turn conformation, such as that found in GFP, in the immature intermediate proposed in the oxidized mechanism, but not in the one predicted by the reduced mechanism.     

Photomodulation of conformational states. III. Water-soluble bis-cysteinyl-peptides with (4-aminomethyl) phenylazobenzoic acid as backbone constituent

In previous studies we have shown that light-induced cis/trans isomerization of the azobenzene moiety in cyclo-[Ala-Cys-Ala-Thr-Cys-Asp-Gly-Phe-AMPB] [AMPB: (4-aminomethyl)phenylazobenzoic acid] leads both in the monocyclic and in the oxidized bicyclic form to markedly differentiated conformational states in DMSO, a fact that lends itself for photomodulation of the redox potential of such bis-cysteinyl-peptides. For this purpose water-soluble systems are required, and this was achieved by replacing three residues outside the Cys-Ala-Thr-Cys active-site motif of thioredoxin reductase with lysines. The resulting cyclo-[Lys-Cys-Ala-Thr-Cys-Asp-Lys-Lys-AMPB] fully retains its photoresponsive properties in water as well assessed by uv and CD measurements. Paralleling results of the previously investigated azobenzene-containing cyclic peptides, the trans --> cis isomerization of the water-soluble monocyclic and oxidized bicyclic peptide is accompanied by a marked transition from a well-defined conformation to an ensemble of possible conformations. However, the conformational preferences are very dissimilar from those of the DMSO-soluble peptides. In fact, hydrogen bonds as well as secondary structure elements were found that change in the mono- and bicyclic peptide upon irradiation. The photo switch between different turn types and hydrogen bonding networks offers the structural rational for the significantly differentiated redox potentials, but also the possibility of monitoring by femtosecond uv-vis and ir spectroscopy fast and ultra fast backbone rearrangement processes following the electronic trans --> cis isomerization.     

Allosteric signaling of ATP hydrolysis in GroEL-GroES complexes

The double-ring chaperonin GroEL and its lid-like cochaperonin GroES form asymmetric complexes that, in the ATP-bound state, mediate productive folding in a hydrophilic, GroES-encapsulated chamber, the so-called cis cavity. Upon ATP hydrolysis within the cis ring, the asymmetric complex becomes able to accept non-native polypeptides and ATP in the open, trans ring. Here we have examined the structural basis for this allosteric switch in activity by cryo-EM and single-particle image processing. ATP hydrolysis does not change the conformation of the cis ring, but its effects are transmitted through an inter-ring contact and cause domain rotations in the mobile trans ring. These rigid-body movements in the trans ring lead to disruption of its intra-ring contacts, expansion of the entire ring and opening of both the nucleotide pocket and the substrate-binding domains, admitting ATP and new substrate protein.     

NMR structure of the alpha-hemoglobin stabilizing protein: insights into conformational heterogeneity and binding

The structure of alpha-hemoglobin stabilizing protein (AHSP), a molecular chaperone for free alpha-hemoglobin, has been determined using NMR spectroscopy. The protein native state shows conformational heterogeneity attributable to the isomerization of the peptide bond preceding a conserved proline residue. The two equally populated cis and trans forms both adopt an elongated antiparallel three alpha-helix bundle fold but display major differences in the loop between the first two helices and at the C terminus of helix 3. Proline to alanine single point mutation of the residue Pro-30 prevents the cis/trans isomerization. The structure of the P30A mutant is similar to the structure of the trans form of AHSP in the loop 1 region. Both the wild-type AHSP and the P30A mutant bind to alpha-hemoglobin, and the wild-type conformational heterogeneity is quenched upon complex formation, suggesting that just one conformation is the active form. Changes in chemical shift observed upon complex formation identify a binding interface comprising the C terminus of helix 1, the loop 1, and the N terminus of helix 2, with the exposed residues Phe-47 and Tyr-51 being attractive targets for molecular recognition. The characteristics of this interface suggest that AHSP binds at the intradimer alpha1beta1 interface in tetrameric HbA.     

A 31-amino-acid N-terminal extension regulates c-Crk binding to tyrosine-phosphorylated proteins.

Overproduction of v-Crk, but not of c-Crk, in chicken embryo fibroblasts results in cell transformation. The transforming activity of v-Crk mutants correlates with their ability to cause increased tyrosine phosphorylation of specific cellular proteins, a property that depends on the binding of v-Crk to phosphotyrosine residues via its SH2 domain. In this study, proteins translated in rabbit reticulocyte lysates were used to analyze interactions between Crk derivatives and tyrosine-phosphorylated proteins, particularly the epidermal growth factor (EGF) receptor. The results demonstrate that the binding affinity of c-Crk is much lower than that of v-Crk, despite the fact that both proteins contain identical SH2 domains. Moreover, a 31-amino-acid N-terminal extension of c-Crk, resulting from upstream translational initiation at a CUG codon, significantly increases the ability of the resulting protein to bind to phosphotyrosine-containing proteins. Of those 31 amino acids, 24 can be found in the 27-amino-acid region between Gag and Crk sequences in v-Crk, and removal of this region results in a protein with lower affinity toward the EGF receptor. In addition, fusion of Gag to the amino terminus of c-Crk yields a protein with a binding activity that is lower than that of v-Crk but significantly higher than that of c-Crk without the fusion. These data suggest that sequences N terminal to the Crk SH2 regulate binding activity to tyrosine-phosphorylated proteins and that the amino acids encoded immediately 5' to the c-Crk initiator AUG specifically increase binding affinity. In contrast, deletion of one or two SH3 domains of c-Crk proteins did not change their affinity for the EGF receptor. These results were confirmed in vivo by using A431-derived cell lines overproducing either the chicken c-Crk protein or c-Crk with the 31-amino-acid N-terminal extension. Furthermore, the in vivo experiments suggest that binding of Crk proteins to the stimulated EGF receptor results in Crk phosphorylation and subsequent loss of binding affinity.     

Single proline residues can dictate the oxidative folding pathways of cysteine-rich peptides

The cysteine-rich N and C-terminal domains of minicollagen-1 from Hydra nematocysts fold with excesses of oxidized/reduced glutathione (10:1) into globular structures with distinct cystine frameworks despite their identical cysteine sequence pattern. An additional main difference is the cis conformation of a conserved proline residue in the N-terminal and the trans conformation of this residue in the C-terminal domain. Comparative analysis of the oxidative folding revealed for the C-terminal domain a fast and highly cooperative formation of a single disulfide isomer. Conversely, oxidation of the N-terminal domain proceeds mainly via an intermediate that results from the fast quasi-stochastic disulfide formation according to the proximity rule. The rate of conversion of the bead-like isomer into the globular end-product is largely dominated by the trans-to-cis isomerization of the critical proline residue as well assessed by its replacement with (4R)- and (4S)-fluoroproline known to exhibit distinct propensities for the trans and cis conformation, respectively. Independently, whether the trans or cis conformation is favored by these substitutions, both analogues retain sufficient sequence-encoded information to fold almost quantitatively into the identical cystine framework and thus spatial structure of the parent peptide with the critical proline residue as cis isomer, but at rates significantly lower for the (4R) than for the (4S)-fluoroproline analogue. Correspondingly, other sequence-encoded structural elements have to act as a driving force for these unidirectional folding pathways despite the rather simple sequence composition consisting only of aliphatic residues, some proline and only one aromatic residue (tyrosine) in the core parts of the C and N-terminal domains. The two cysteine-rich domains of minicollagen-1 may well represent ideal targets for ab initio structure calculations in order to learn more about the elementary information encoded in such primordial molecules.     

Tyrosine-phosphorylated epidermal growth factor receptor and cellular p130 provide high affinity binding substrates to analyze Crk-phosphotyrosine-dependent interactions in vitro.

The genome of CT10 avian sarcoma virus encodes a 47-kDa fusion protein that consists of viral gag sequences fused to a cell-derived sequence containing SH2 and SH3 domains (v-crk). Genetic and biochemical evidence suggests that v-Crk can induce transformation of chicken embryo fibroblasts by influencing the activity of cellular proteins involved in growth regulation. In this report, we have developed an in vitro microtiter assay to study the binding of bacterially expressed glutathione S-transferase-fusion proteins of v-Crk and its cellular homolog, c-Crk, to the phosphorylated epidermal growth factor receptor (EGFR). Competitive binding data are presented that compare the abilities of heterologous glutathione S-transferase-fusion proteins containing GAPSH2[N], AblSH2, SrcSH2, and PLC-gamma SH2[N] sequences to inhibit Crk binding. Results indicate that both full-length Crk and GAPSH2[N] bind the phosphorylated EGFR with high affinity and can quantitatively compete the binding of each other by competitive enzyme-linked immunosorbent assay. Binding of full-length Crk or the isolated SH2 domains of GAP or Abl resulted in a significant protection of phosphorylated EGFR against dephosphorylation by cellular phosphatase activity, but did not appear to stimulate the intrinsic tyrosine kinase activity of the EGFR. To extend these findings to p130, the major phosphotyrosine-containing protein in CT10-transformed cells, we utilized a nitrocellulose filter binding assay. Results demonstrate high affinity binding of Crk toward denatured p130 and, as is the case for phosphorylated EGFR, Crk binding can partially protect p130 from phosphatase activity. However, no apparent competition of Crk binding was noted with heterologous SH2-containing proteins including GAPSH2[N], suggesting a possible specificity of Crk-p130 binding. These data are consistent with a direct role of SH2 in the modulation of cellular phosphotyrosine status in vivo.     

Energetic coupling between native-state prolyl isomerization and conformational protein folding

In folded proteins, prolyl peptide bonds are usually thought to be either trans or cis because only one of the isomers can be accommodated in the native folded protein. For the N-terminal domain of the gene-3 protein of the filamentous phage fd (N2 domain), Pro161 resides at the tip of a beta hairpin and was found to be cis in the crystal structure of this protein. Here we show that Pro161 exists in both the cis and the trans conformations in the folded form of the N2 domain. We investigated how conformational folding and prolyl isomerization are coupled in the unfolding and refolding of N2 domain. A combination of single-mixing and double-mixing unfolding and refolding experiments showed that, in unfolded N2 domain, 7% of the molecules contain a cis-Pro161 and 93% of the molecules contain a trans-Pro161. During refolding, the fraction of molecules with a cis-Pro161 increases to 85%. This implies that 10.3 kJ mol(-1) of the folding free energy was used to drive this 75-fold change in the Pro161 cis/trans equilibrium constant during folding. The stabilities of the forms with the cis and the trans isomers of Pro161 and their folding kinetics could be determined separately because their conformational folding is much faster than the prolyl isomerization reactions in the native and the unfolded proteins. The energetic coupling between conformational folding and Pro161 isomerization is already fully established in the transition state of folding, and the two isomeric forms are thus truly native forms. The folding kinetics are well described by a four-species box model, in which the N2 molecules with either isomer of Pro161 can fold to the native state and in which cis/trans isomerization occurs in both the unfolded and the folded proteins.