Tandem duplication and divergence of a sea urchin protein belonging to the troponin C superfamily

The Spec1 and Spec2 proteins of the sea urchin Strongylocentrotus purpuratus are related to calmodulin, troponin C, and myosin light chains by sequence similarity in their four calcium binding domains. These domains, the EF-hands, are distinct helix-loop-helix structures of about 40 amino acids. The Spec1 and Spec2 genes are expressed specifically in aboral ectoderm cells of the developing embryo; however, the function of the Spec proteins in these cells is unknown. To find conserved regions of the proteins that might be important for structure and function, Spec homologues from Lytechinus pictus, a distantly related sea urchin, were sought. L. pictus embryos do not synthesize detectable amounts of the 14,000-17,000-Da Spec proteins as determined by two-dimensional gel electro-phoresis, but do synthesize three 34,000-Da proteins that cross-react with Spec1 antibodies and display a similar ontogenetic pattern of expression. cDNA clones were isolated by hybridization to a synthetic oligonucleotide corresponding to the EF-hand. One clone, LpS1, encodes an mRNA with developmental properties like those of the S. purpuratus Spec mRNAs. However, LpS1 contains an open reading frame for a protein of 34,000 Da rather than 17,000 Da, and antibodies raised against part of the LpS1 reading frame demonstrate that LpS1 encodes a 34,000-Da protein in L. pictus embryos. The sequence of LpS1 reveals the presence of eight EF-hand domains, which share structural homology with the Spec1 or Spec2 EF-hands; however, little else in the protein sequence is conserved. The results support the hypothesis that the LpS1 gene arose from a duplication of an ancestral Spec gene and that the overall structural features of the Spec family of proteins are more conserved than the amino acid sequences.     

Classification and evolution of EF-hand proteins

Forty-five distinct subfamilies of EF-hand proteins have been identified. They contain from two to eight EF-hands that are recognizable by amino acid sequence as being statistically similar to other EF-hand domains. All proteins within one subfamily are congruent to one another, i.e. the dendrogram computed from one of the EF-hand domains is similar, within statistical error, to the dendrogram computed from another(s) domain. Thirteen subfamilies - including Calmodulin, Troponin C, Essential light chain, Regulatory light chain - referred to collectively as CTER, are congruent with one another. They appear to have evolved from a single ur-domain by two cycles of gene duplication and fusion. The subfamilies of CTER subsequently evolved by gene duplications and speciations. The remaining 32 subfamilies do not show such general patterns of congruence; however, some - such as S100, intestinal calcium binding protein (calbindin 9kd), and trichohylin - do not form congruent clusters of subfamilies. Nearly all of the domains 1, 3, 5, and 7 are most similar to other ODD domains. Correspondingly the EVEN numbered domains of all 45 subfamilies most closely resemble EVEN domains of other subfamilies. Many sequence and chem-ical characteristics do not show systemic trends by subfamily or species of host organisms; such homoplasy is widespread. Eighteen of the subfamilies are heterochimeric; in addition to multiple EF-hands they contain domains of other evolutionary origins.© Kluwer Academic Publishers     

Calcium binding sequences in calmyrin regulates interaction with presenilin-2

Calmyrin is a myristoylated calcium binding protein that contains four putative EF-hands. Calmyrin interacts with a number of proteins, including presenilin-2 (PS2). However, the biophysical properties of calmyrin, and the molecular mechanisms that regulate its binding to different partners, are not well understood. By site-directed mutagenesis and Ca2+ binding studies, we found that calmyrin binds two Ca2+ ions with a dissociation constant of approximately 53 microM, and that the two C-terminal EF-hands 3 and 4 bind calcium. Using ultraviolet spectroscopy, circular dichroism (CD), and NMR, we found that Ca(2+)-free and -bound calmyrin have substantially different protein conformations. By yeast two-hybrid assays, we found that both EF-hands 3 and 4 of calmyrin must be intact for calmyrin to interact with PS2-loop sequences. Pulse-chase studies of HeLa cells transfected with calmyrin expression constructs indicated that wild-type (Wt) calmyrin has a half-life of approximately 75 min, whereas a mutant defective in myristoylation turns over more rapidly (half-life of 35 min). By contrast, the half-lives of calmyrin mutants with a disrupted EF-hand 3 or EF-hand 4 were 52 and 170 min, respectively. Using immunofluorescence staining of HeLa cells transfected with Wt and mutant calmyrin cDNAs, we found that both calcium binding and myristoylation are important for dynamic intracellular targeting of calmyrin. Double immunofluorescence microscopy indicated that Wt and myristoylation-defective calmyrin proteins colocalize efficiently and to the same extent with PS2, whereas calmyrin mutants defective in calcium binding display less colocalization with PS2. Our results suggest that calmyrin functions as a calcium sensor and that calcium binding sequences in calmyrin are important for interaction with the PS2 loop.     

Effects of mutations in the calcium-binding sites of recoverin on its calcium affinity: evidence for successive filling of the calcium binding sites

A molecule of the photoreceptor Ca(2+)-binding protein recoverin contains four potential EF-hand Ca(2+)-binding sites, of which only two, the second and the third, are capable of binding calcium ions. We have studied the effects of substitutions in the second, third and fourth EF-hand sites of recoverin on its Ca(2+)-binding properties and some other characteristics, using intrinsic fluorescence, circular dichroism spectroscopy and differential scanning microcalorimetry. The interaction of the two operating binding sites of wild-type recoverin with calcium increases the protein's thermal stability, but makes the environment around the tryptophan residues more flexible. The amino acid substitution in the EF-hand 3 (E121Q) totally abolishes the high calcium affinity of recoverin, while the mutation in the EF-hand 2 (E85Q) causes only a moderate decrease in calcium binding. Based on this evidence, we suggest that the binding of calcium ions to recoverin is a sequential process with the EF-hand 3 being filled first. Estimation of Ca(2+)-binding constants according to the sequential binding scheme gave the values 3.7 x 10(6) and 3.1 x 10(5) M(-1) for third and second EF-hands, respectively. The substitutions in the EF-hand 2 or 3 (or in both the sites simultaneously) do not disturb significantly either tertiary or secondary structure of the apo-protein. Amino acid substitutions, which have been designed to restore the calcium affinity of the EF-hand 4 (G160D, K161E, K162N, D165G and K166Q), increase the calcium capacity and affinity of recoverin but also perturb the protein structure and decrease the thermostability of its apo-form.     

Structural characterization of calcineurin B homologous protein 1

Calcineurin B homologous protein 1 (CHP1), also known as p22, is a calcium-binding EF-hand protein that plays a role in membrane trafficking. It binds to multiple effector proteins, including Na(+)/H(+) exchangers, a serine/threonine kinase, and calcineurin, potentially modulating their function. The crystal structure of calcium-bound CHP1 from rat has been determined at 2.2 Angstroms of resolution. The molecule has a compact alpha-helical structure containing four EF-hands. The overall folding topology of the protein is similar to that of the regulatory B subunit of calcineurin and to that of calcium- and integrin-binding protein. The calcium ion is coordinated in typical fashion in the third and fourth EF-hands, but the first and second EF-hands contain no calcium ion. The first EF-hand is maintained by internal interactions, and the second EF-hand is stabilized by hydrophobic interactions. CHP1 contains a hydrophobic pocket on the opposite side of the protein to the EF-hands that has been implicated in ligand binding.     

Structures and metal-ion-binding properties of the Ca2+-binding helix-loop-helix EF-hand motifs

The 'EF-hand' Ca2+-binding motif plays an essential role in eukaryotic cellular signalling, and the proteins containing this motif constitute a large and functionally diverse family. The EF-hand is defined by its helix-loop-helix secondary structure as well as the ligands presented by the loop to bind the Ca2+ ion. The identity of these ligands is semi-conserved in the most common (the 'canonical') EF-hand; however, several non-canonical EF-hands exist that bind Ca2+ by a different co-ordination mechanism. EF-hands tend to occur in pairs, which form a discrete domain so that most family members have two, four or six EF-hands. This pairing also enables communication, and many EF-hands display positive co-operativity, thereby minimizing the Ca2+ signal required to reach protein saturation. The conformational effects of Ca2+ binding are varied, function-dependent and, in some cases, minimal, but can lead to the creation of a protein target interaction site or structure formation from a molten-globule apo state. EF-hand proteins exhibit various sensitivities to Ca2+, reflecting the intrinsic binding ability of the EF-hand as well as the degree of co-operativity in Ca2+ binding to paired EF-hands. Two additional factors can influence the ability of an EF-hand to bind Ca2+: selectivity over Mg2+ (a cation with very similar chemical properties to Ca2+ and with a cytoplasmic concentration several orders of magnitude higher) and interaction with a protein target. A structural approach is used in this review to examine the diversity of family members, and a biophysical perspective provides insight into the ability of the EF-hand motif to bind Ca2+ with a wide range of affinities.     

Mouse S100G protein exhibits properties characteristic of a calcium sensor

Bovine S100 G (calbindin D_9k, small Ca²⁺-binding protein of the EF-hand superfamily) is considered as a calcium buffer protein; i.e., the binding of Ca²⁺ practically does not change its general conformation. A set of experimental approaches has been used to study structural properties of apo- and Ca²⁺-loaded forms of mouse S100 G (81.4% identity in amino acid sequence with bovine S100 G). This analysis revealed that, in contrast to bovine S100 G, the removal of calcium ions increases α-helices content of mouse S100 G protein and enhances its accessibility to digestion by α-chymotrypsin. Furthermore, mouse apo-S100 G is characterized by a decreased surface hydrophobicity and reduced tendency for oligomerization. Such behavior is typical of calcium sensor proteins. Apo-state of mouse S100 G still has rather compact structure, which can be cooperatively unfolded by temperature and GdnHCl. Computational analysis of amino acid sequences of S100 G proteins shows that these proteins could be in a disordered state upon a removal of the bound calcium ions. The experimental data show that, although mouse apo-S100 G is flexible compared to the Ca²⁺-loaded state, the apo-form is not completely disordered and preserves some cooperatively meting structure. The origin of the unexpectedly high stability of mouse S100 G can be rationalized by an exceptionally strong association of its N- and C-terminal parts containing the EF-hands I and II, respectively.     

Biophysical studies of engineered mutant proteins based on calbindin D9k modified in the pseudo EF-hand

The genes for four mutant proteins from calbindin D9k, all with mutations in the N-terminal Ca2+-binding domain (pseudo EF-hand) have been synthesized and expressed in Escherichia coli. The purification scheme has been modified to minimize the formation of deamidated proteins. The set of modifications in the pseudo EF-hand is an attempt to turn this site into a structure resembling an archetypal EF-hand, with its characteristic 113Cd-NMR shift (-80 to -110 ppm) and high calcium-binding constants, whereas the C-terminal Ca2(+)-binding site (EF-hand) is kept intact in all mutant proteins. The mutant proteins studied here all have pseudo EF-hands with a lower calcium-binding constant and a higher calcium off-rate to the pseudo EF-hand than the wild-type protein. From the results obtained it is obvious that proline 20 in the pseudo EF-hand, which has been deleted or replaced by glycine in three of the mutants, has a stabilizing effect on calcium binding to that site. Furthermore, the modifications in the pseudo EF-hand seem to have only a local effect, leaving the tertiary structure of the protein and the calcium-binding properties of the unmodified site virtually unchanged.     

Interleukin-11 binds specific EF-hand proteins via their conserved structural motifs

Interleukin-11 (IL-11) is a hematopoietic cytokine engaged in numerous biological processes and validated as a target for treatment of various cancers. IL-11 contains intrinsically disordered regions that might recognize multiple targets. Recently we found that aside from IL-11RA and gp130 receptors, IL-11 interacts with calcium sensor protein S100P. Strict calcium dependence of this interaction suggests a possibility of IL-11 interaction with other calcium sensor proteins. Here we probed specificity of IL-11 to calcium-binding proteins of various types: calcium sensors of the EF-hand family (calmodulin, S100B and neuronal calcium sensors: recoverin, NCS-1, GCAP-1, GCAP-2), calcium buffers of the EF-hand family (S100G, oncomodulin), and a non-EF-hand calcium buffer (α-lactalbumin). A specific subset of the calcium sensor proteins (calmodulin, S100B, NCS-1, GCAP-1/2) exhibits metal-dependent binding of IL-11 with dissociation constants of 1–19 μM. These proteins share several amino acid residues belonging to conservative structural motifs of the EF-hand proteins, ‘black’ and ‘gray’ clusters. Replacements of the respective S100P residues by alanine drastically decrease its affinity to IL-11, suggesting their involvement into the association process. Secondary structure and accessibility of the hinge region of the EF-hand proteins studied are predicted to control specificity and selectivity of their binding to IL-11. The IL-11 interaction with the EF-hand proteins is expected to occur under numerous pathological conditions, accompanied by disintegration of plasma membrane and efflux of cellular components into the extracellular milieu.     

The divergent domains of the NEFA and nucleobindin proteins are derived from an EF-hand ancestor

The human protein NEFA (DNA binding, EF-hand, Acidic region) has previously been isolated from a KM3 cell line and immunolocalized on the plasma membrane, in the cytoplasma, and in the culture medium. Sequence analysis of a cDNA clone encoding NEFA identified a hydrophilic domain, two EF-hands, and a leucine zipper at the C- terminus. These characters are shared with nucleobindin (Nuc). In this paper we have further characterized NEFA and probed its evolutionary origins. Circular dichroism (CD) spectra of recombinant NEFA indicated a helical content of 51% and showed that the EF-hands are capable of binding Ca2+. Experiments with recombinant NEFA and synthesized peptides revealed that the leucine zipper cannot form a homodimer. The leucine zipper may allow heterodimer formation of NEFA and an unknown protein. Phylogenetic analyses suggest that this protein is derived from a four-domain EF-hand ancestor with subsequent duplications and fusions. The leucine zipper and putative DNA-binding domains of NEFA have evolved secondarily from existing EF-hand sequences. These analyses provide insights into how complex proteins may originate and trace the precursor of NEFA to the common ancestor of eukaryotes.      

Calcium affinity, cooperativity, and domain interactions of extracellular EF-hands present in BM-40

The structure and function of cytosolic Ca(2+)-binding proteins containing EF-hands are well understood. Recently, the presence of EF-hands in an extracellular protein was for the first time proven by the structure determination of the EC domain of BM-40 (SPARC (for secreted protein acidic and rich in cysteine)/osteonectin) (Hohenester, E., Maurer, P., Hohenadl, C., Timpl, R., Jansonius, J. N., and Engel, J. (1996) Nat. Struct. Biol. 3, 67-73). The structure revealed a pair of EF-hands with two bound Ca(2+) ions. Two unusual features were noted that distinguish the extracellular EF-hands of BM-40 from their cytosolic counterparts. An insertion of one amino acid into the loop of the first EF-hand causes a variant Ca(2+) coordination, and a disulfide bond connects the helices of the second EF-hand. Here we show that the extracellular EF-hands in the BM-40 EC domain bind Ca(2+) cooperatively and with high affinity. The EC domain is thus in the Ca(2+)-saturated form in the extracellular matrix, and the EF-hands play a structural rather than a regulatory role. Deletion mutants demonstrate a strong interaction between the EC domain and the neighboring FS domain, which contributes about 10 kJ/mol to the free energy of binding and influences cooperativity. This interaction is mainly between the FS domain and the variant EF-hand 1. Certain mutations of Ca(2+)-coordinating residues changed affinity and cooperativity, but others inhibited folding and secretion of the EC domain in a mammalian cell line. This points to a function of EF-hands in extracellular proteins during biosynthesis and processing in the endoplasmic reticulum or Golgi apparatus.     

The B cell receptor-induced calcium flux involves a calcium mediated positive feedback loop

The B cell receptor (BCR)-elicited calcium flux results in activation of mature B cells. We have recently shown that the adaptor protein Swiprosin-1/EFhd2 (EFhd2) amplifies the BCR-induced calcium flux in B cell lines. EFhd2 is a calcium binding adaptor protein with two predicted EF-hands. Here we asked whether these domains are functional and control its function. Using a blot-overlay assay with radioactive calcium we show that both EF-hands of EFhd2 have an intrinsic capacity to bind calcium. Equilibrium centrifugation confirmed that EFhd2 binds 2 calcium ions, with an apparent Kd of 110 μM. Point mutations revealed that the conserved residues E116 and E152, which reside in the canonical calcium binding loop in EF-hands 1 and 2, are essential for calcium binding by EFhd2. These mutations as well as deletion of the EF-hands, in particular EF-hand 1, abolished the ability of EFhd2 to restore BCR-induced calcium signaling in EFhd2-deficient WEHI231 cells. N-terminal deletions, but not C-terminal deletions, acted similarly. Thus, the N-terminal part of EFhd2 as well as calcium binding to its EF-hands control the intracellular calcium concentration in response to BCR stimulation in WEHI231 cells. Hence, EFhd2 regulates the BCR-elicited calcium flux through a calcium-dependent positive feedback mechanism in WEHI231 cells.     

Common EF-hand motifs in cholinesterases and neuroligins suggest a role for Ca2+ binding in cell surface associations

Comparisons of protein sequence via cyclic training of Hidden Markov Models (HMMs) in conjunction with alignments of three-dimensional structure, using the Combinatorial Extension (CE) algorithm, reveal two putative EF-hand metal binding domains in acetylcholinesterase. Based on sequence similarity, putative EF-hands are also predicted for the neuroligin family of cell surface proteins. These predictions are supported by experimental evidence. In the acetylcholinesterase crystal structure from Torpedo californica, the first putative EF-hand region binds the Zn2+ found in the heavy metal replacement structure. Further, the interaction of neuroligin 1 with its cognate receptor neurexin depends on Ca2+. Thus, members of the alpha,beta hydrolase fold family of proteins contain potential Ca2+ binding sites, which in some family members may be critical for heterologous cell associations.     

Molecular mechanism of the calcium-induced conformational change in the spectrin EF-hands.

Calcium is a universally employed cytosolic messenger in eukaryotic cells. Most of the proteins that bind signalling calcium are members of the calmodulin superfamily and share two or more helix-loop-helix motifs known as EF-hands. A model, based on structure comparison of different domains and supported by preliminary NMR data, has suggested that EF-hands involved in signal transduction undergo a major conformational change upon calcium binding from a 'closed' to an 'open' state allowing protein-protein interaction. We have determined the solution structures of the EF-hand pair from alpha-spectrin in the absence and in the presence of calcium. The structures are in the closed and open conformation respectively, providing a definite experimental proof for the closed-to-open model. Our results allow formulation of the rules which govern the movement induced by calcium. These rules may be generalized to other EF-hands since the key residues involved are conserved within the calmodulin family.     

Target selectivity in EF-hand calcium binding proteins

EF-hand calcium binding proteins have remarkable sequence homology and structural similarity, yet their response to binding of calcium is diverse and they function in a wide range of biological processes. Knowledge of the fine-tuning of EF-hand protein sequences to optimize specific biochemical properties has been significantly advanced over the past 10 years by determination of atomic resolution structures. These data lay the foundation for addressing how functional selectivity is generated from a generic ionic signal. This review presents current ideas about the structural mechanisms that provide the selectivity of different EF-hand proteins for specific cellular targets, using S100 and calmodulin family proteins to demonstrate the critical concepts. Three factors contribute significantly to target selectivity: molecular architecture, response to binding of Ca(2+) ions, and the characteristics of target binding surfaces. Comparisons of calmodulin and S100 proteins provide insights into the role these factors play in facilitating the variety of binding configurations necessary for recognizing a diverse set of targets.     

Isolated EF-loop III of calmodulin in a scaffold protein remains unpaired in solution using pulsed-field-gradient NMR spectroscopy

Calmodulin (CaM) is a trigger calcium-dependent protein that regulates many biological processes. We have successfully engineered a series of model proteins, each containing a single EF-hand loop but with increasing numbers of Gly residues linking the EF-hand loop to a scaffold protein, cluster of differentiation 2 (CD2), to obtain the site-specific calcium-binding ability of a protein with EF-hand motifs without the interference of cooperativity. Loop III of calmodulin with two Gly linkers in CD2 (CaM-CD2-III-5G) has metal affinities with K(d) values of 1.86 x 10(-4) and 5.8 x 10(-5) M for calcium and lanthanum, respectively. The oligomeric states of the CD2 variants were examined by pulsed-field-gradient nuclear magnetic resonance (PFG NMR). The diffusion coefficient values of CD2 variants are about 11.1 x 10(-7) cm(2)/s both in the presence and absence of metal ions, which are the same as that of wild-type CD2. This suggests that the isolated EF-loop III of calmodulin inserted in the scaffold protein is able to bind calcium and lanthanum as a monomer, which is in contrast to the previous observation of the EF-hand motif. Our results imply that additional factors that reside outside of the EF-loop III may contribute to the pairing of EF-hand motifs of calmodulin. This result is of interest as it opens up the way for studying the ion-binding properties of isolated EF-hands, which in turn can answer important questions about the properties of EF-hands, the large and important group of calcium-binding signaling proteins.     

Functional properties of calbindin D9K mutants with exchanged Ca2+ binding sites

We have constructed three different engineered proteins based on calbindin D9K by either exchanging the two calcium binding sites within the protein or making the amino acid sequence of the two calcium binding sites identical. The individual calcium binding sites of the engineered proteins retain most of their ion binding characteristics as well as the basal structure of their Ca2+ ligand sphere in the new environment. Even the protein with its sites interchanged, a mutation involving 30 amino acids out of a total of 75, still binds calcium with an affinity as high as that of many natural EF-hand proteins.