Solution structure of the LDL receptor EGF-AB pair: a paradigm for the assembly of tandem calcium binding EGF domains.

BACKGROUND: From the observed structure and sequence of a pair of calcium binding (cb) epidermal growth factor-like (EGF) domains from human fibrillin-1, we proposed that many tandem cbEGF domains adopt a conserved relative conformation. The low-density lipoprotein receptor (LDLR), which is functionally unrelated to fibrillin-1, contains a single pair of EGF domains that was chosen for study in the validation of this hypothesis. The LDLR is the protein that is defective in familial hypercholesterolaemia, a common genetic disorder that predisposes individuals to cardiovascular complications and premature death. RESULTS: Here, we present the solution structure of the first two EGF domains from the LDL receptor, determined using conventional NMR restraints and residual dipolar couplings. The cbEGF domains have an elongated, rod-like arrangement, as predicted. The new structure allows a detailed assessment of the consequences of mutations associated with familial hypercholesterolaemia to be made. CONCLUSIONS: The validation of the conserved arrangement of EGF domains in functionally distinct proteins has important implications for structural genomics, since multiple tandem cbEGF pairs have been identified in many essential proteins that are implicated in human disease. Our results provide the means to use homology modeling to probe structure-function relationships in this diverse family of proteins and may hold the potential for the design of novel diagnostics and therapies in the future.

The first epidermal growth factor-like domain of the low-density lipoprotein receptor contains a noncanonical calcium binding site.

Removal of cholesterol-containing particles from the circulation is mediated by the low-density lipoprotein (LDL) receptor. Upon ligand binding, the receptor-ligand complex is endocytosed, and the ligand is released. The important biological role of the LDL receptor (LDLR) has been highlighted by the identification of more than 400 LDLR mutations that are associated with familial hypercholesterolemia. The extracellular region of the LDLR is modular in nature and principally comprises multiple copies of ligand binding, epidermal growth factor-like (EGF), and YWTD-type domains. This report describes characterization of the calcium binding properties of the tandem pair of EGF domains. While only the C-terminal EGF module contains the consensus sequence associated with calcium binding, a noncanonical calcium binding site in the N-terminal domain has been revealed using solution NMR spectroscopy. The calcium dissociation constants for the N- and C-terminal sites have been measured under physiologically relevant pH and ionic strength conditions using a combination of solution NMR, intrinsic protein fluorescence, and chromophoric chelator methods to be approximately 50 microM and approximately 10-20 microM, respectively. Identification of the novel calcium binding motif in LDLR sequences from other species suggests that it may confer specificity within the LDLR gene family. Comparison of the K(d) for the C-terminal site with the calcium concentration in late vesicles indicates that the binding properties of this module may be tuned to titrate upon endocytosis of the LDL receptor-ligand complex, and thus calcium binding may play a role in the ligand dissociation process.

A G1127S change in calcium-binding epidermal growth factor-like domain 13 of human fibrillin-1 causes short range conformational effects.

Human fibrillin-1, an extracellular matrix glycoprotein, has a modular organization that includes 43 calcium-binding epidermal growth factor-like (cbEGF) domains arranged as multiple tandem repeats. A missense mutation that changes a highly conserved glycine to serine (G1127S) has been identified in cbEGF13, which results in a variant of Marfan syndrome, a connective tissue disease. Previous experiments on isolated cbEGF13 and a cbEGF13-14 pair indicated that the G1127S mutation caused defective folding of cbEGF13 but not cbEGF14. We have used limited proteolysis methods and two-dimensional NMR spectroscopy to identify the structural consequences of this mutation in a covalently linked cbEGF12-13 pair and a cbEGF12-14 triple domain construct. Protease digestion studies of the cbEGF12-13 G1127S mutant pair indicated that both cbEGF12 and 13 retained similar calcium binding properties and thus tertiary structure to the normal domain pair, because all identified cleavage sites showed calcium-dependent protection from proteolysis. However, small changes in the conformation of cbEGF13 G1127S, revealed by the presence of a new protease-sensitive site and comparative two-dimensional NOESY data, suggested that the fold of the mutant domain was not identical to the wild-type, but was native-like. Additional cleavage sites identified in cbEGF12-14 G1127S indicated further subtle changes within the mutant domain but not the flanking domains. We have concluded the following in this study. (i) Covalent linkage of cbEGF12 preserves the native-like fold of cbEGF13 G1127S and (ii) conformational effects introduced by G1127S are localized to cbEGF13. This study demonstrates that missense mutations in fibrillin-1 cbEGF domains can cause short range structural effects in addition to long range effects previously observed with a E1073K mutation in cbEGF12.

Fibrillin: from domain structure to supramolecular assembly.

In the last 5 years, significant progress has been made in understanding the structure and function of all the major domains composing the fibrillins. A previous review [Meth. Enzymol. 245 (1994), 29] focused on the isolation of fibrillin monomers and fibrillin-containing polymers (microfibrils). In this article, information gained from recent studies which have further elucidated molecular structure and investigated effects of mutations on structural and functional properties will be summarized. In addition, studies of functional domains in fibrillins which may be important in assembling microfibrils will be discussed. Throughout this review, the authors have attempted to identify areas of research which have been controversial. In the conclusion, we raise important questions which remain unresolved.

Hybrid and complex glycans are linked to the conserved N-glycosylation site of the third eight-cysteine domain of LTBP-1 in insect cells.

Covalent association of LTBP-1 (latent TGF-beta binding protein-1) to latent TGF-beta is mediated by the third eight-cysteine (also referred to as TB) module of LTBP-1, a domain designated as CR3. Spodoptera frugiperda (Sf9) cells have proved a suitable cell system in which to study this association and to produce recombinant CR3, and we show here that another lepidopteran cell line, Trichoplusia niTN-5B1-4 (High-Five) cells, allows the recovery of large amounts of functional recombinant CR3. CR3 contains an N-glycosylation site, which is conserved in all forms of LTBP known to date. When we examined the status of this N-glycosylation using MALDI-TOF mass spectrometry and enzymatic analysis, we found that CR3 is one of the rare recombinant peptides modified with complex glycans in insect cells. Sf9 cells mainly processed the fucosylated paucomannosidic structure (GlcNAc)(2)(Mannose)(3)Fucose, although hybrid and complex N-glycosylations were also detected. In High-Five cells, the peptide was found to be modified with a wide variety of hybrid and complex sugars in addition to paucomanosidic oligosaccharides. Most glycans had one or two fucose residues bound through alpha1,3 and alpha1,6 linkages to the innermost GlcNAc. On the basis of these results and on the structure of an eight-cysteine domain from fibrillin-1, we present a model of glycosylated CR3 and discuss the role of glycosylation in eight-cysteine domain protein-protein interactions.

Backbone dynamics of a cbEGF domain pair in the presence of calcium.

Calcium binding (cb) epidermal growth factor-like (EGF) domains are found in a wide variety of extracellular proteins with diverse functions. In several proteins, including the fibrillins (1 and 2), the low-density lipoprotein receptor, the Notch receptor and related molecules, these domains are organised as multiple tandem repeats. The functional importance of calcium-binding by EGF domains has been underscored by the identification of missense mutations associated with defective calcium-binding, which have been linked to human diseases. Here, we present (15)N backbone relaxation data for a pair of cbEGF domains from fibrillin-1, the defective protein in the Marfan syndrome. The data were best fit using a symmetric top model, confirming the extended conformation of the cbEGF domain pair. Our data demonstrate that calcium plays a key role in stabilising the rigidity of the domain pair on the pico- to millisecond time-scale. Strikingly, the most dynamically stable region of the construct is centred about the domain interface. These results provide important insight into the properties of intact fibrillin-1, the consequences of Marfan syndrome causing mutations, and the ultrastructure of fibrillins and other extracellular matrix proteins.

EGF-like domain calcium affinity modulated by N-terminal domain linkage in human fibrillin-1.

Calcium binding epidermal growth factor-like domains (cbEGFs) are present in many extracellular proteins, including fibrillin-1, Notch-3, protein S, factor IX and the low density lipoprotein (LDL) receptor, which perform a diverse range of functions. Genetic mutations that cause amino acid changes within these proteins have been linked to the Marfan syndrome (MFS), CADASIL, protein S deficiency, haemophilia B and familial hypercholesterolaemia, respectively. A number of these mutations disrupt calcium binding to cbEGFs, emphasising the critical functional role of calcium in these proteins. We have determined the calcium binding affinity of two sites within a cbEGF pair (cbEGF12-13) from human fibrillin-1 using two-dimensional nuclear magnetic resonance (NMR) and fluorescence techniques. Fibrillin-1 is a mosaic protein containing 43 cbEGF domains, mainly arranged as tandem repeats. Our results show that the cbEGF13 site in the cbEGF12-13 pair possesses the highest calcium affinity of any cbEGF investigated from fibrillin-1. A comparative analysis of these and previously reported calcium binding data from fibrillin-1 demonstrate that the affinity of cbEGF13 is enhanced more than 70-fold by the linkage of an N-terminal cbEGF domain. In contrast, comparison of calcium binding by cbEGF32 in isolation relative to when linked to a transforming growth factor beta-binding protein-like domain (TB6-cbEGF32) reveals that the same enhancement is not observed for this heterologous domain pair. Taken together, these results indicate that fibrillin-1 cbEGF Ca2+ affinity can be significantly modulated by the type of domain which is linked to its N terminus. The cbEGF12-13 pair is located within the longest contiguous section of cbEGFs in fibrillin-1, and a number of mutations in this region are associated with the most severe neonatal form of MFS. The affinities of cbEGF domains 13 and 14 in this region are substantially higher than in the C-terminal region of fibrillin-1. This increased affinity may be important for fibrillin assembly into 10-12 nm connective tissue microfibrils and/or may contribute to the biomechanical properties of the microfibrillar network.

Defective calcium binding to fibrillin-1: consequence of an N2144S change for fibrillin-1 structure and function.

Fibrillin-1 is a major structural component of 10-12 nm connective tissue microfibrils and has a modular organisation that includes 43 calcium binding epidermal growth factor-like (cbEGF) domains and seven transforming growth factor beta-binding protein-like (TB) domains. Mutations in the fibrillin-1 (FBN1) gene cause the Marfan syndrome (MFS) and related connective tissue disorders. We have previously investigated an N2144S change, identified in a MFS patient, which removes one of the key calcium binding ligands within cbEGF domain 32. In this study the structural consequences of the N2144S amino acid change for the folding and calcium binding properties of mutant and wild-type TB6-cbEGF32 and cbEGF32-33 domain pairs have been analysed by nuclear magnetic resonance. The presence of an N2144S substitution does not alter the native fold of either the TB6 domain, or cbEGF domains 32 and 33. Comparison of calcium dissociation constants measured for the wild-type and mutant pairs shows that: (i) the affinity of cbEGF32 is weakly enhanced by N-terminal linkage of TB6 relative to cbEGF32 in isolation; (ii) the affinity of cbEGF32 is approximately ninefold decreased by the N2144S substitution in the TB-cbEGF pair; and (iii) reduced affinity of cbEGF32 does not result in lower affinity of cbEGF33 for calcium. Together, these data suggest that the TB6-cbEGF32 linkage is flexible and the structural effect of the mutation is localised to the interdomain linkage. We have also investigated the effect of defective calcium binding to cbEGF32 on fibrillin-1 produced by N2144S MFS fibroblasts. 35S-pulse-chase analysis shows that the N2144S substitution does not detectably affect fibrillin-1 biosynthesis, rate of secretion or processing. Deposition of reducible fibrillin-1 into the extracellular matrix was also unaffected. The implications of these results for the assembly and properties of the microfibril are discussed.

NMR of modular proteins.

NMR studies of domains, dissected from large modular proteins, are described. Particular emphasis is placed on modules from the extracellular proteins fibrillin-1 and fibronectin.

A Gly --> Ser change causes defective folding in vitro of calcium-binding epidermal growth factor-like domains from factor IX and fibrillin-1.

The calcium-binding epidermal growth factor-like (cbEGF) domain is a common motif found in extracellular proteins. A mutation that changes a highly conserved Gly residue to Ser in this domain has been identified both in the factor IX (FIX) and fibrillin-1 genes, where it is associated with relatively mild variants of hemophilia B and Marfan syndrome, respectively. We have investigated the structural consequences in vitro of this amino acid change when introduced into single cbEGF domains from human FIX (G60S) and human fibrillin-1 (G1127S), and a covalently linked pair of cbEGF domains from fibrillin-1. High pressure liquid chromatography analysis, mass spectrometry, and 1H NMR analysis demonstrate that wild-type cbEGF domains purified in the reduced form and refolded in vitro adopt the native fold. In contrast, the Gly --> Ser change causes defective folding of FIX and fibrillin-1 cbEGF domains. However, in the case of the factor IX mutant domain, a Ca2+-dependent change in conformation, identified by NMR in a proportion of the refolded material, suggests that some material refolds to a native-like structure. This is consistent with enzyme-linked immunosorbent assay analysis of FIX G60S from a hemophilia B patient Oxford d2, which demonstrates that the mutant protein is partially recognized by a monoclonal antibody specific for this region of FIX. NMR analysis of a covalently linked pair of fibrillin cbEGF domains demonstrates that the C-terminal domain adopts the native epidermal growth factor fold, despite the fact that the adjacent mutant domain is misfolded. The implications of these results for disease pathogenesis are discussed.

NMR analysis of cbEGF domains gives new insights into the structural consequences of a P1148A substitution in fibrillin-1.

Fibrillin-1 is a modular glycoprotein and a major component of the 10-12 nm microfibrils of the extracellular matrix. Mutations in the fibrillin-1 (FBN 1) gene result in the connective tissue disease the Marfan syndrome (MFS) and related disorders. The calcium binding EGF-like (cbEGF) domain is the predominant structural motif of the protein and >70% of mutations leading to MFS disrupt this domain. A missense mutation which changes a proline to alanine (P1148A) in cbEGF domain 13 has been associated with a number of fibrillin disorders including MFS and Shprintzen-Goldberg syndrome. However, it has also been described as a polymorphism. In this study comparative NMR analyses on wild-type and mutant forms of covalently-linked fibrillin cbEGF domain pairs have been performed to investigate the structural consequences of this substitution. A comparison of the two-dimensional NOESY spectra of the wild-type and mutant forms of cbEGF domains 12 & 13 and cbEGF domains 13 & 14 indicated that the proline to alanine amino acid change does not introduce a significant structural defect into cbEGF domain 13 or the adjacent domains and most likely represents a polymorphism. These results demonstrate how, in the case of a protein with a well defined domain organisation such as fibrillin-1, comparative NMR analyses can be used to substantiate genetic evidence for the polymorphic status of an amino acid.

Solution structure of the transforming growth factor beta-binding protein-like module, a domain associated with matrix fibrils.

Here we describe the high resolution nuclear magnetic resonance (NMR) structure of a transforming growth factor beta (TGF-beta)-binding protein-like (TB) domain, which comes from human fibrillin-1, the protein defective in the Marfan syndrome (MFS). This domain is found in fibrillins and latent TGF-beta-binding proteins (LTBPs) which are localized to fibrillar structures in the extracellular matrix. The TB domain manifests a novel fold which is globular and comprises six antiparallel beta-strands and two alpha-helices. An unusual cysteine triplet conserved in the sequences of TB domains is localized to the hydrophobic core, at the C-terminus of an alpha-helix. The structure is stabilized by four disulfide bonds which pair in a 1-3, 2-6, 4-7, 5-8 pattern, two of which are solvent exposed. Analyses of MFS-causing mutations and the fibrillin-1 cell-binding RGD site provide the first clues to the surface specificity of TB domain interactions. Modelling of a homologous TB domain from LTBP-1 (residues 1018-1080) suggests that hydrophobic contacts may play a role in its interaction with the TGF-beta1 latency-associated peptide.

Solution structure of a pair of calcium-binding epidermal growth factor-like domains: implications for the Marfan syndrome and other genetic disorders.

The nuclear magnetic resonance structure of a covalently linked pair of calcium-binding (cb) epidermal growth factor-like (EGF) domains from human fibrillin-1, the protein defective in the Marfan syndrome, is described. The two domains are in a rigid, rod-like arrangement, stabilized by interdomain calcium binding and hydrophobic interactions. We propose a model for the arrangement of fibrillin monomers in microfibrils that reconciles structural and antibody binding data, and we describe a set of disease-causing mutations that provide the first clues to the specificity of cbEFG interactions. The residues involved in stabilizing the domain linkage are highly conserved in fibrillin, fibulin, thrombomodulin, and the low density lipoprotein receptor. We propose that the relative orientation of tandem cbEGF domains in these proteins is similar, but that in others, including Notch, pairs adopt a completely different conformation.

Calcium binding properties of an epidermal growth factor-like domain pair from human fibrillin-1.

Ca2+ binding epidermal growth factor-like (EGF-like) domains are found in a large number of extracellular proteins with diverse functions, including those involved in blood coagulation, determination of cell fate, cell adhesion and connective tissue architecture. Their importance is emphasised by the identification of mutations in these domains in patients with haemophilia B (defective in coagulation factor IX) and the Marfan syndrome (defective in the connective tissue protein fibrillin-1). The X-ray crystal structure of a single Ca2+ binding EGF-like domain from human coagulation factor IX has recently been solved. It shows that the Ca2+ ligands form a pentagonal bipyramid, where one ligand is provided by an adjacent (N-terminal) EGF-like domain in the crystal. The N and C termini of the neighbouring domains are only approximately 4 angstrum apart, hence the crystal packing has been proposed as a model for the association of contiguous EGF-like domains in proteins. Since the adjacent EGF-like domain in the crystal, although close, is not covalently linked to its neighbour, this model requires verification. In this study we have expressed and purified a Ca2+ binding EGF-like domain pair from human fibrillin-1 and used an in vitro refolding system to obtain protein with the correct EGF fold. The Ca2+ binding properties of the protein have been investigated by two-dimensional NMR. The affinity of the C-terminal domain for Ca2+ is approximately 25-fold higher than that of the N-terminal domain, consistent with the two Ca2+ binding sites having different local environments. In addition, these data provide the first direct experimental evidence that Ca2+ plays a major role in defining the interdomain linkage in multiple repeats of Ca2+ binding EGF-like domains.

The solution structure and backbone dynamics of the fibronectin type I and epidermal growth factor-like pair of modules of tissue-type plasminogen activator.

BACKGROUND: The thrombolytic serine protease tissue-type plasminogen activator (t-PA) is a classical modular protein consisting of three types of domain in addition to the serine protease domain: F1 (homologous to fibronectin type I); G (epidermal growth factor-like) and kringle. Biochemical data suggest that the F1 and G modules play a major role in the binding of t-PA to fibrin and to receptors on hepatocytes. RESULTS: We have derived the solution structure of the F1 and G pair of modules from t-PA by two- and three-dimensional NMR techniques, in combination with dynamical simulated annealing calculations. We have also obtained information about the molecule's backbone dynamics through measurement of amide 15N relaxation parameters. CONCLUSIONS: Although the F1 and G modules each adopt their expected tertiary structure, the modules interact intimately to bury a hydrophobic core, and the inter-module linker makes up the third strand of the G module's major beta-sheet. The new structural results allow the interpretation of earlier mutational data relevant to fibrin-binding and hepatocyte-receptor binding.

The effects of variable glycosylation on the functional activities of ribonuclease, plasminogen and tissue plasminogen activator.

The relatively large size and dynamics of oligosaccharides can result in substantial shielding of functionally important areas of proteins to which they are attached, modulate the interactions of glycoconjugates with other molecules and affect the rate of processes which involve conformational changes. This review focuses on the occupancy of N-linked glycosylation sites on three enzymes, ribonuclease, plasminogen and tissue plasminogen activator. Each of these proteins occurs naturally as two populations of molecules, distinguished from each other only by the presence or absence of an oligosaccharide at one glycosylation site. The presence of an oligomannose sugar on ribonuclease (at Asn-34) alters its overall dynamics, increases its stability towards proteinases and decreases its functional activity towards double-stranded RNA. The N-linked sugar on plasminogen (at Asn-288) within kringle 3 reduces the rate of the beta- to alpha-conformational change, modulates the transport of plasminogen into the extravascular compartment, decreases plasminogen binding to U937 cells and downregulates the activation of plasminogen by both urokinase and tissue plasminogen activator. Additionally, in fibrinolysis, within a ternary complex of fibrin, plasminogen and tissue plasminogen activator, the N-linked sugar of plasminogen hinders the initial interaction with tissue plasminogen activator (i.e., it alters Km). The presence of an N-linked glycan (at Asn-184) in the kringle 2 domain of tissue plasminogen activator hinders the rearrangement of this ternary complex, decreasing the turnover rate (Kcat).

The calcium binding properties and molecular organization of epidermal growth factor-like domains in human fibrillin-1.

Human fibrillin-1 is a 350-kDa glycoprotein found in 10-nm connective tissue microfibrils. Mutations in the gene encoding this protein cause the Marfan syndrome, a disease characterized by cardiovascular, ocular, and skeletal abnormalities. Fibrillin-1 has a modular structure that includes 47 epidermal growth factor-like (EGF-like) domains, 43 of which contain a consensus sequence associated with calcium binding. A mutation causing an Asn-2144 --> Ser amino acid change in one of the potential calcium binding residues has been described in a patient with the Marfan syndrome. We have chemically synthesized a wild-type EGF-like domain (residues 2126-2165 of human fibrillin-1) and a mutant EGF-like domain containing the Asn-2144 --> Ser amino acid change and measured calcium binding to each using 1H-NMR spectroscopy. The wild-type domain binds calcium with a similar affinity to isolated EGF-like domains from coagulation factors IX and X; however, the mutant domain exhibits > 5-fold reduction in affinity. Rotary shadowing of fibrillin-containing microfibrils, isolated from dermal fibroblast cultures obtained from the Marfan patient, shows that the mutation does not prevent assembly of fibrillin into microfibrils but does alter the appearance of the interbead region. We have modeled a region of fibrillin-1 (residues 2126-2331) encompassing five calcium binding EGF-like domains, using data derived from the recently determined crystal structure of a calcium binding EGF-like domain from human factor IX. Our model suggests that these fibrillin-1 EGF-like domains adopt a helical arrangement stabilized by calcium and that defective calcium binding to a single EGF-like domain results in distortion of the helix. We propose a mechanism for the interaction of contiguous arrays of calcium binding EGF-like domains within the microfibril.

The activation of type 1 and type 2 plasminogen by type I and type II tissue plasminogen activator.

Tissue plasminogen activator (tPA) was fractionated using lysine-Sepharose affinity chromatography. Type I, type II, and a minor peak with high affinity for lysine (designated type D) tPA were recovered. In an indirect amidolytic assay involving native human Glu-plasminogen and fibrin, type II tPA showed a 2-fold higher activity than type I. To explore the combinatorial effect of the variable glycosylation status of both tPA and plasminogen, kinetic constants for fibrin-dependent plasminogen activation were determined for combinations of type I, II, and D tPA with type 1 and 2 plasminogen. Within a 4-fold range, the fastest rate was achieved from the combination of type D (type II + D) tPA and type 2 plasminogen. N-Glycosylation of plasminogen increased the Km value for activation by all tPA variants; N-glycosylation of type I tPA at Asn184 decreased the kcat (turnover) values for the fibrin-dependent activation of plasminogen over type II tPA, while type D tPA showed the highest turnover rate. In the presence of fibrinogen fragments, N-glycosylation of plasminogen at site 289 modulates the kinetics of association of enzyme and substrate, while N-glycosylation at site 184 on tPA modulates the turnover rate of the enzyme.

Three-dimensional solution structure of the pleckstrin homology domain from dynamin.

BACKGROUND: The pleckstrin homology (PH) domain is a region of approximately 100 amino acids, defined by sequence similarity, that has been found in about 60 proteins, many of which are involved in signal transduction downstream of cell surface receptors; the function of PH domains is unknown. The only clue to the function of PH domains is the circumstantial evidence that they may link beta gamma subunits of G proteins to second messenger systems. Knowledge of the three-dimensional structures of PH domains should help to elucidate the roles they play in the proteins that contain them. RESULTS: Using homonuclear and heteronuclear magnetic resonance spectroscopy, we have determined the solution structure of the PH domain of the GTPase dynamin, one of a number of proteins that have PH domains and interact with GTP. The fold of the dynamin PH domain is composed of two antiparallel beta-sheets, which pack face-to-face at an angle of approximately 60 degrees. The first beta-sheet comprises four strands (residues 13-58) from the amino-terminal half of the protein sequence; the second beta-sheet contains three strands (residues 63-99). A single alpha-helix (residues 102-116) flanks one edge of the interface between the two sheets, parallel in orientation to the second sheet, in an alpha/beta roll motif similar to that of the B oligomer of verotoxin-1 from Escherichia coli. CONCLUSIONS: The structure of the dynamin PH domain is very similar to the recently reported structures of the pleckstrin and spectrin PH domains. This shows that, despite the low level of sequence similarity between different PH domains, they do have a characteristic polypeptide fold. On the basis of our structure, the suggestion that PH domains engage in coiled-coil interactions with G protein beta gamma subunits seems unlikely and should be re-evaluated.