The crystal structure of Arabidopsis BON1 provides insights into the copine protein family

The Arabidopsis thaliana BON1 gene product is a member of the evolutionary conserved eukaryotic calcium‐dependent membrane‐binding protein family. The copine protein is composed of two C2 domains (C2A and C2B) followed by a vWA domain. The BON1 protein is localized on the plasma membrane, and is known to suppress the expression of immune receptor genes and to positively regulate stomatal closure. The first structure of this protein family has been determined to 2.5‐Å resolution and shows the structural features of the three conserved domains C2A, C2B and vWA. The structure reveals the third Ca²⁺‐binding region in C2A domain is longer than classical C2 domains and a novel Ca²⁺ binding site in the vWA domain. The structure of BON1 bound to Mn²⁺ is also presented. The binding of the C2 domains to phospholipid (PSF) has been modeled and provides an insight into the lipid‐binding mechanism of the copine proteins. Furthermore, the selectivity of the separate C2A and C2B domains and intact BON1 to bind to different phospholipids has been investigated, and we demonstrated that BON1 could mediate aggregation of liposomes in response to Ca²⁺. These studies have formed the basis of further investigations into the important role that the copine proteins play in vivo.     

Solution structure of a bacterial immunoglobulin‐like domain of the outer membrane protein (LigB) from Leptospira

Leptospiral immunoglobulin‐like (Lig) proteins are surface proteins expressed in pathogenic strains of Leptospira. LigB, an outer membrane protein containing tandem repeats of bacterial Ig‐like (Big) domains and a no‐repeat tail, has been identified as a virulence factor involved in adhesion of pathogenic Leptospira interrogans to host cells. A Big domain of LigB, LigBCen2R, was reported previously to bind the GBD domain of fibronectin, suggesting its important role in leptospiral infections. In this study, we determined the solution structure of LigBCen2R by nuclear magnetic resonance (NMR) spectroscopy. LigBCen2R adopts a canonical immunoglobulin‐like fold which is comprised of a beta‐sandwich of ten strands in three sheets. We indicated that LigBCen2R is able to bind to Ca²⁺ with a high affinity by isothermal titration calorimetry assay. NMR perturbation experiment identified a number of residues responsible for Ca²⁺ binding. Structural comparison of it with other Big domains demonstrates that they share a similar fold pattern, but vary in some structural characters. Since Lig proteins play a vital role in the infection to host cells, our study will contribute a structural basis to understand the interactions between Leptospira and host cells. Proteins 2015; 83:195–200. © 2014 Wiley Periodicals, Inc.     

Exploring the sequence–structure–function relationship for the intrinsically disordered βγ-crystallin Hahellin

βγ-Crystallins are a superfamily of proteins containing crystallin-type Greek key motifs. Some βγ-crystallin domains have been shown to bind Ca²⁺. Hahellin is a newly identified intrinsically disordered βγ-crystallin domain from Hahella chejuensis. It folds into a typical βγ-crystallin structure upon Ca²⁺ binding and acts as a Ca²⁺-regulated conformational switch. Besides Hahellin, another two putative βγ-crystallins from Caulobacter crescentus and Yersinia pestis are shown to be partially disordered in their apo-form and undergo large conformational changes upon Ca²⁺ binding, although whether they acquire a βγ-crystallin fold is not known. The extent of conformational disorder/order of a protein is determined by its amino acid sequence. To date how this sequence–structure relationship is reflected in the βγ-crystallin superfamily has not been investigated. In this work, we comparatively studied the sequence and structure of Hahellin with those of Protein S, an ordered βγ-crystallin, via various computational biophysical techniques. We found that several factors, including presence of a C-terminal disorder prone region, high content of energetic frustrations, and low contact density, may promote the formation of the disordered state of apo-Hahellin. We also analyzed the disorder propensities for other putative disordered βγ-crystallin domains. This study provides new clues for further understanding the sequence–structure–function relationship of βγ-crystallins.     

The solution structure of the Mg2+ form of soybean calmodulin isoform 4 reveals unique features of plant calmodulins in resting cells

Soybean calmodulin isoform 4 (sCaM4) is a plant calcium‐binding protein, regulating cellular responses to the second messenger Ca²⁺. We have found that the metal ion free (apo‐) form of sCaM4 possesses a half unfolded structure, with the N‐terminal domain unfolded and the C‐terminal domain folded. This result was unexpected as the apo‐forms of both soybean calmodulin isoform 1 (sCaM1) and mammalian CaM (mCaM) are fully folded. Because of the fact that free Mg²⁺ ions are always present at high concentrations in cells (0.5–2 mM), we suggest that Mg²⁺ should be bound to sCaM4 in nonactivated cells. CD studies revealed that in the presence of Mg²⁺ the initially unfolded N‐terminal domain of sCaM4 folds into an α‐helix‐rich structure, similar to the Ca²⁺ form. We have used the NMR backbone residual dipolar coupling restraints ¹D_NH, ¹D_CαHα, and ¹D_C′Cα to determine the solution structure of the N‐terminal domain of Mg²⁺‐sCaM4 (Mg²⁺‐sCaM4‐NT). Compared with the known structure of Ca²⁺‐sCaM4, the structure of the Mg²⁺‐sCaM4‐NT does not fully open the hydrophobic pocket, which was further confirmed by the use of the fluorescent probe ANS. Tryptophan fluorescence experiments were used to study the interactions between Mg²⁺‐sCaM4 and CaM‐binding peptides derived from smooth muscle myosin light chain kinase and plant glutamate decarboxylase. These results suggest that Mg²⁺‐sCaM4 does not bind to Ca²⁺‐CaM target peptides and therefore is functionally similar to apo‐mCaM. The Mg²⁺‐ and apo‐structures of the sCaM4‐NT provide unique insights into the structure and function of some plant calmodulins in resting cells.     

Investigation of the Ca2+-dependent interaction of trifluoperazine with S100a: A19F NMR and circular dichroism study

S100a is a heterodimeric, acidic calcium-binding protein that interacts with calmodulin antagonists in a Ca²⁺-dependent manner. In order to study the behavior of the hydrophobic domain on S100a when bound to Ca²⁺, its interaction with trifluoperazine (TFP) was investigated using¹⁶F nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The dissociation constant (K _d) values of TFP, as estimated from the chemical shifts of¹⁹F NMR, were 191 and 29 m in the absence and presence of Ca²⁺, respectively, and were similar to those previously reported for S100b. However, the TFP linewidth in the presence of Ca²⁺-bound S100a was 65 Hz greater than in the presence of Ca²⁺-bound S100b. This suggests a slower TFP exchange rate for S100a than for S100b. Thus, the TFP linewidths observed for each isoform may reflect differences in structural and modulatory properties of the Ca²⁺-dependent hydrophobic domains on S100a and S100b. Additionally, the presence of magnesium had no effect on the observed Ca²⁺-induced TFP spectral changes in S100a solutions. Circular dichroism studies indicate that Ca²⁺ induces a small transition from -helix to random coil in S100a; in contrast, the opposite transition is reported for calmodulin (Hennesseyet al., 1987). However, TFP did not significantly alter the secondary structure of Ca²⁺-bound S100a; this observation is similar to the effect of TFP on Ca²⁺-bound calmodulin and troponin C (Shimizu and Hatano, 1984; Gariépy and Hodges, 1983). It is, therefore, proposed that TFP binds to a hydrophobic domain on S100a in a fashion similar to other calcium-modulated proteins.     

Variation in assembly stoichiometry in non‐metazoan homologs of the hub domain of Ca2+/calmodulin‐dependent protein kinase II

The multi‐subunit Ca²⁺/calmodulin‐dependent protein kinase II (CaMKII) holoenzyme plays a critical role in animal learning and memory. The kinase domain of CaMKII is connected by a flexible linker to a C‐terminal hub domain that assembles into a 12‐ or 14‐subunit scaffold that displays the kinase domains around it. Studies on CaMKII suggest that the stoichiometry and dynamic assembly/disassembly of hub oligomers may be important for CaMKII regulation. Although CaMKII is a metazoan protein, genes encoding predicted CaMKII‐like hub domains, without associated kinase domains, are found in the genomes of some green plants and bacteria. We show that the hub domains encoded by three related green algae, Chlamydomonas reinhardtii, Volvox carteri f. nagarensis, and Gonium pectoral, assemble into 16‐, 18‐, and 20‐subunit oligomers, as assayed by native protein mass spectrometry. These are the largest known CaMKII hub domain assemblies. A crystal structure of the hub domain from C. reinhardtii reveals an 18‐subunit organization. We identified four intra‐subunit hydrogen bonds in the core of the fold that are present in the Chlamydomonas hub domain, but not in metazoan hubs. When six point mutations designed to recapitulate these hydrogen bonds were introduced into the human CaMKII‐α hub domain, the mutant protein formed assemblies with 14 and 16 subunits, instead of the normal 12‐ and 14‐subunit assemblies. Our results show that the stoichiometric balance of CaMKII hub assemblies can be shifted readily by small changes in sequence.     

Three structural representatives of the PF06855 protein domain family from Staphyloccocus aureus and Bacillus subtilis have SAM domain-like folds and different functions

Protein domain family PF06855 (DUF1250) is a family of small domains of unknown function found only in bacteria, and mostly in the order Bacillales and Lactobacillales. Here we describe the solution NMR or X-ray crystal structures of three representatives of this domain family, MW0776 and MW1311 from Staphyloccocus aureus and yozE from Bacillus subtilis. All three proteins adopt a four-helix motif similar to sterile alpha motif (SAM) domains. Phylogenetic analysis classifies MW1311 and yozE as functionally equivalent proteins of the UPF0346 family of unknown function, but excludes MW0776, which likely has a different biological function. Our structural characterization of the three domains supports this separation of function. The structures of MW0776, MW1311, and yozE constitute the first structural representatives from this protein domain family.     

Investigation of the Ca2+-dependent interaction of trifluoperazine with S100a: A19F NMR and circular dichroism study

S100a is a heterodimeric, acidic calcium-binding protein that interacts with calmodulin antagonists in a Ca²⁺-dependent manner. In order to study the behavior of the hydrophobic domain on S100a when bound to Ca²⁺, its interaction with trifluoperazine (TFP) was investigated using¹⁶F nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The dissociation constant (K _d) values of TFP, as estimated from the chemical shifts of¹⁹F NMR, were 191 and 29 μm in the absence and presence of Ca²⁺, respectively, and were similar to those previously reported for S100b. However, the TFP linewidth in the presence of Ca²⁺-bound S100a was 65 Hz greater than in the presence of Ca²⁺-bound S100b. This suggests a slower TFP exchange rate for S100a than for S100b. Thus, the TFP linewidths observed for each isoform may reflect differences in structural and modulatory properties of the Ca²⁺-dependent hydrophobic domains on S100a and S100b. Additionally, the presence of magnesium had no effect on the observed Ca²⁺-induced TFP spectral changes in S100a solutions. Circular dichroism studies indicate that Ca²⁺ induces a small transition from α-helix to random coil in S100a; in contrast, the opposite transition is reported for calmodulin (Hennesseyet al., 1987). However, TFP did not significantly alter the secondary structure of Ca²⁺-bound S100a; this observation is similar to the effect of TFP on Ca²⁺-bound calmodulin and troponin C (Shimizu and Hatano, 1984; Gariépy and Hodges, 1983). It is, therefore, proposed that TFP binds to a hydrophobic domain on S100a in a fashion similar to other calcium-modulated proteins.     

The crystal structure of the C₂A domain of otoferlin reveals an unconventional top loop region

Otoferlin (Otof), whose genetic mutations cause profound deafness in humans, is a protein composed of at least six C₂ domains, which are known as Ca²⁺-binding and phospholipid-binding regions. Mammalian ferlin proteins are proposed to act in membrane fusion events, with Otof being specifically required for exocytosis in auditory hair cells. Ferlin C₂ domains exhibit a rather low level of sequence similarity to those of synaptotagmins, protein kinase C isoforms, or phospholipases. Here, we report the crystal structure of the N-terminal C₂ domain of Otof (C₂A) at 1.95-Å resolution. In contrast to previous predictions, we found that this C₂ domain is complete with eight β-strands. Comparing the structure of Otof C₂A to those of other C₂ domains revealed one top loop in Otof to be significantly shorter. This results in a depression of the surface, which is positively charged for the Otof C₂A domain, and contrasts with the head-like protrusion surrounded by a negatively charged “neck” typically found in other C₂ domains. Isothermal titration calorimetry and circular dichroism spectroscopy studies confirmed that Otof C₂A is unable to bind Ca²⁺, while the synaptotagmin-1 C₂A domain exhibited Ca²⁺ binding under the same conditions. Furthermore, floatation assays revealed a failure of Otof C₂A to bind to phospholipid membranes. Accordingly, no positively charged β-groove-like surface structure, which is known to bind phosphatidylinositol-4,5-bisphosphate in other C₂ domains, was found at the respective position in Otof C₂A. Taken together, these data demonstrate that the Otof C₂A domain differs structurally and functionally from other C₂ domains.     

Auxiliary Ca2+ binding sites can influence the structure of CIB1

Recent X-ray crystal structures and solution NMR spectroscopy data for calcium- and integrin-binding protein 1 (CIB1) have all revealed a common EF-hand domain structure for the protein. However, the orientation of the two protein domains, the oligomerization state, and the conformations of the N- and C-terminal extensions differ among the structures. In this study, we examine whether the binding of glutathione or auxiliary Ca²⁺ ions as observed in the crystal structures, occur in solution, and whether these interactions can influence the structure or dimerization of CIB1. In addition, we test the potential phosphatase activity of CIB1, which was hypothesized based on the glutathione binding site geometry observed in one of the crystal structures of the protein. Biophysical and biochemical experiments failed to detect glutathione binding, protein dimerization, or phosphatase activity for CIB1 under several solution conditions. However, our data identify low affinity (K_d, 10⁻²M) Ca²⁺ binding events that influence the structures of the N- and C-terminal extensions of CIB1 under high (300 mM) Ca²⁺ crystallization conditions. In addition to providing a rationale for differences amongst the various solution and crystal structures of CIB1, our results show that the impact of low affinity Ca²⁺ binding events should be considered when analyzing and interpreting protein crystallographic structures determined in the presence of very high Ca²⁺ concentrations.     

A calmodulin-stimulated Ca-ATPase from plant vacuolar membranes with a putative regulatory domain at its N-terminus

A cDNA, BCA1, encoding a calmodulin-stimulated Ca²⁺-ATPase in the vacuolar membrane of cauliflower (Brassica oleracea) was isolated based on the sequence of tryptic peptides derived from the purified protein. The BCA1 cDNA shares sequence identity with animal plasma membrane Ca²⁺-ATPases and Arabidopsis thaliana ACA1, that encodes a putative Ca²⁺ pump in the chloroplast envelope. In contrast to the plasma membrane Ca²⁺-ATPases of animal cells, which have a calmodulin-binding domain situated in the carboxy-terminal end of the molecule, the calmodulin-binding domain of BCA1 is situated at the amino terminus of the enzyme.     

A Highlights from MBoC Selection: Mutations that disrupt Ca2+-binding activity endow Doc2β with novel functional properties during synaptic transmission

Double C2-domain protein (Doc2) is a Ca²⁺-binding protein implicated in asynchronous and spontaneous neurotransmitter release. Here we demonstrate that each of its C2 domains senses Ca²⁺; moreover, the tethered tandem C2 domains display properties distinct from the isolated domains. We confirm that overexpression of a mutant form of Doc2β, in which two acidic Ca²⁺ ligands in the C2A domain and two in the C2B domain have been neutralized, results in markedly enhanced asynchronous release in synaptotagmin 1–knockout neurons. Unlike wild-type (wt) Doc2β, which translocates to the plasma membrane in response to increases in [Ca²⁺]_i, the quadruple Ca²⁺-ligand mutant does not bind Ca²⁺ but is constitutively associated with the plasma membrane; this effect is due to substitution of Ca²⁺ ligands in the C2A domain. When overexpressed in wt neurons, Doc2β affects only asynchronous release; in contrast, Doc2β Ca²⁺-ligand mutants that constitutively localize to the plasma membrane enhance both the fast and slow components of synaptic transmission by increasing the readily releasable vesicle pool size; these mutants also increase the frequency of spontaneous release events. Thus, mutations in the C2A domain of Doc2β that were intended to disrupt Ca²⁺ binding result in an anomalous enhancement of constitutive membrane-binding activity and endow Doc2β with novel functional properties.     

Binding of calcium is sensed structurally and dynamically throughout the second calcium‐binding domain of the sodium/calcium exchanger

We report the effects of Ca²⁺ binding on the backbone relaxation rates and chemical shifts of the AD and BD splice variants of the second Ca²⁺‐binding domain (CBD2) of the sodium–calcium exchanger. Analysis of the Ca²⁺‐induced chemical shifts perturbations yields similar K_D values of 16–24 μM for the two CBD2‐AD Ca²⁺‐binding sites, and significant effects are observed up to 20 Å away. To quantify the Ca²⁺‐induced chemical shift changes, we performed a comparative analysis of eight Ca²⁺‐binding proteins that revealed large differences between different protein folds. The CBD2 ¹⁵N relaxation data show the CBD2‐AD Ca²⁺ coordinating loops to be more rigid in the Ca²⁺‐bound state as well as to affect the FG‐loop located at the opposite site of the domain. The equivalent loops of the CBD2‐BD splice variant do not bind Ca²⁺ and are much more dynamic relative to both the Ca²⁺‐bound and apo forms of CBD2‐AD. A more structured FG‐loop in CBD2‐BD is suggested by increased S² order parameter values relative to both forms of CBD2‐AD. The chemical shift and relaxation data together indicate that, in spite of the small structural changes, the Ca²⁺‐binding event is felt throughout the molecule. The data suggest that the FG‐loop plays an important role in connecting the Ca²⁺‐binding event with the other cytosolic domains of the NCX, in line with in vivo and in vitro biochemical data as well as modeling results that connect the CBD2 FG‐loop with the first Ca²⁺‐binding domain of NCX. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Model for the allosteric regulation of the Na+/Ca2+ exchanger NCX

The Na⁺/Ca²⁺ exchanger provides a major Ca²⁺ extrusion pathway in excitable cells and plays a key role in the control of intracellular Ca²⁺ concentrations. In Canis familiaris, Na⁺/Ca²⁺ exchanger (NCX) activity is regulated by the binding of Ca²⁺ to two cytosolic Ca²⁺‐binding domains, CBD1 and CBD2, such that Ca²⁺‐binding activates the exchanger. Despite its physiological importance, little is known about the exchanger's global structure, and the mechanism of allosteric Ca²⁺‐regulation remains unclear. It was found previously that for NCX in the absence of Ca²⁺ the two domains CBD1 and CBD2 of the cytosolic loop are flexibly linked, while after Ca²⁺‐binding they adopt a rigid arrangement that is slightly tilted. A realistic model for the mechanism of the exchanger's allosteric regulation should not only address this property, but also it should explain the distinctive behavior of Drosophila melanogaster's sodium/calcium exchanger, CALX, for which Ca²⁺‐binding to CBD1 inhibits Ca²⁺ exchange. Here, NMR spin relaxation and residual dipolar couplings were used to show that Ca²⁺ modulates CBD1 and CBD2 interdomain flexibility of CALX in an analogous way as for NCX. A mechanistic model for the allosteric Ca²⁺ regulation of the Na⁺/Ca²⁺ exchanger is proposed. In this model, the intracellular loop acts as an entropic spring whose strength is modulated by Ca²⁺‐binding to CBD1 controlling ion transport across the plasma membrane. Proteins 2016; 84:580–590. © 2016 Wiley Periodicals, Inc.     

Calcium-regulated GTPase activity in the calcium-binding protein calexcitin

Calexcitin (CE) is a calcium-binding protein, closely related to sarcoplasmic calcium-binding proteins, that is involved in invertebrate learning and memory. Early reports indicated that both Hermissenda and squid CE also could bind GTP; however, the biochemical significance of GTP-binding and its relationship to calcium binding have remained unclear. Here, we report that the GTPase activity of CE is strongly regulated by calcium. CE possessed a P-loop-like structure near the C-terminal similar to the phosphate-binding regions in other GTP-binding proteins. Site-directed mutagenesis of this region showed that Gly¹⁸², Phe¹⁸⁶ and Gly¹⁸⁷ are required for maximum affinity, suggesting that the GTP-binding motif is G-N-x-x-[FM]-G. CE cloned from Drosophila CNS possessed a similar C-terminal sequence and also bound and hydrolyzed GTP. GTPase activity in Drosophila CE was also strongly regulated by Ca²⁺, exhibiting over 23-fold higher activity in the presence of 0.3 μM calcium. Analysis of the conserved protein motifs defines a new family of Ca²⁺-binding proteins representing the first example of proteins endowed with both EF-hand calcium binding domains and a C-terminal, P-loop-like GTP-binding motif. These results establish that, in the absence of calcium, both squid and Drosophila CE bind GTP at near-physiological concentrations and hydrolyze GTP at rates comparable to unactivated ras. Calcium functions to increase GTP-binding and GTPase activity in CE, similar to the effect of GTPase activating proteins in other low-MW GTP-binding proteins. CE may, therefore, act as a molecular interface between Ca²⁺ cytosolic oscillations and the G protein-coupled signal transduction.     

Spectral studies of the Ca2+-dependent interaction of trifluoperazine with S100b

S100b is a calcium-binding protein that will bind to many calmodulin target molecules in a Ca²⁺-dependent manner. In order to study the Ca²⁺-dependent binding properties of S100b, its interaction with a calmodulin antagonist, trifluoperazine (TFP), was investigated using [¹⁹F]- and [¹H]-NMR and UV-difference spectroscopy. It was estimated from [¹⁹F]-NMR that in the absence of Ca²⁺, thek _1/2 value of TFP was 130 µM, while itsk _1/2 value decreased to 28 µM in the presence of Ca²⁺. The addition of KCl was not antagonistic to the Ca²⁺-dependent interaction of TFP to S100b. The chemical exchange rate of TFP with Ca²⁺-bound S100b was estimated to be 9×10² sec^–1. By comparison with TFP-calmodulin exchange rates, it is suggested that the TFP-binding site on S100b is structurally different from its binding sites on calmodulin. Proton NMR resonance broadening in the range 6.8–7.2 ppm, corresponding to phenylalanine nuclei of S100b, indicates that these residues may be involved in TFP binding. Addition of Ca²⁺ to a 1:1 mixture of S100b and TFP resulted in a red-shifted UV-difference spectrum, while no significant difference spectrum was detected when Mg²⁺ was added to a S100b-TFP solution. Thus, we suggest that Ca²⁺ induces the exposure of a hydrophobic domain on S100b containing one or more phenylalanine residues that will bind TFP but that this domain is different from the hydrophobic domain on calmodulin.     

Calcium binding and conformational properties of calmodulin complexed with peptides derived from myristoylated alanine-rich C kinase substrate (MARCKS) and MARCKS-related protein (MRP)

The myristoylated alanine-rich C kinase substrate (MARCKS) and the MARCKS-related protein (MRP) are members of a distinct family of protein ki-nase C (PKC) substrates that bind calmodulin (CaM) in a manner regulated by Ca²⁺ and phosphorylation by PKC. The CaM binding region overlaps with the PKC phosphorylation sites, suggesting a potential coupling between Ca²⁺-CaM signalling and PKC-mediated phosphorylation cascades. We have studied Ca²⁺ binding of CaM complexed with CaM binding peptides from MARCKS and MRP using flow dialysis, NMR and circular dichroism (CD) spectroscopy. The wild-type MARCKS and MRP peptides induced significant increases in the Ca²⁺ affinity of CaM (pCa 6.1 and 5.8, respectively, compared to 5.2, for CaM in the absence of bound peptides), whereas a modified MARCKS peptide, in which the four serine residues susceptible to phosphorylation in the wild-type sequence have been replaced with aspartate residues to mimic phosphorylation, had smaller effect (pCa 5.6). These results are consistent with the notions that phosphorylation of MARCKS reduces its binding affinity for CaM and that the CaM binding affinity of the peptides is coupled to the Ca²⁺ affinity of CaM. All three MARCKS/MRP peptides perturbed the backbone NMR resonances of residues in both the N- and C-terminal domains of CaM and, in addition, the wild-type MARCKS and the MRP peptides induced strong positive cooperativity in Ca²⁺ binding by CaM, suggesting that the peptides interact with the amino- and carboxy-terminal domains of CaM simultaneously. NMR analysis of the Ca²⁺-CaM-MRP peptide complex, as well as CD measurements of Ca²⁺-CaM in the presence and absence of MARCKS/MRP peptides suggest that the peptide bound to CaM is non-helical, in contrast to the α-helical conformation found in the CaM binding regions of myosin light-chain kinase and CaM-dependent protein kinase II. The adaptation of the CaM molecule for binding the peptide requires disruption of its central helical linker between residues Lys-75 and Glu-82. Received: 26 September 1996 / 22 October 1996     

Quantitation of the Calcium and Membrane Binding Properties of the C2 Domains of Dysferlin

Dysferlin is a large membrane protein involved in calcium-triggered resealing of the sarcolemma after injury. Although it is generally accepted that dysferlin is Ca²⁺ sensitive, the Ca²⁺ binding properties of dysferlin have not been characterized. In this study, we report an analysis of the Ca²⁺ and membrane binding properties of all seven C2 domains of dysferlin as well as a multi-C2 domain construct. Isothermal titration calorimetry measurements indicate that all seven dysferlin C2 domains interact with Ca²⁺ with a wide range of binding affinities. The C2A and C2C domains were determined to be the most sensitive, with K_d values in the tens of micromolar, whereas the C2D domain was least sensitive, with a near millimolar K_d value. Mutagenesis of C2A demonstrates the requirement for negatively charged residues in the loop regions for divalent ion binding. Furthermore, dysferlin displayed significantly lower binding affinity for the divalent cations magnesium and strontium. Measurement of a multidomain construct indicates that the solution binding affinity does not change when C2 domains are linked. Finally, sedimentation assays suggest all seven C2 domains bind lipid membranes, and that Ca²⁺ enhances but is not required for interaction. This report reveals for the first time, to our knowledge, that all dysferlin domains bind Ca²⁺ albeit with varying affinity and stoichiometry.     

Quantitation of the Calcium and Membrane Binding Properties of the C2 Domains of Dysferlin

Dysferlin is a large membrane protein involved in calcium-triggered resealing of the sarcolemma after injury. Although it is generally accepted that dysferlin is Ca²⁺ sensitive, the Ca²⁺ binding properties of dysferlin have not been characterized. In this study, we report an analysis of the Ca²⁺ and membrane binding properties of all seven C2 domains of dysferlin as well as a multi-C2 domain construct. Isothermal titration calorimetry measurements indicate that all seven dysferlin C2 domains interact with Ca²⁺ with a wide range of binding affinities. The C2A and C2C domains were determined to be the most sensitive, with K_d values in the tens of micromolar, whereas the C2D domain was least sensitive, with a near millimolar K_d value. Mutagenesis of C2A demonstrates the requirement for negatively charged residues in the loop regions for divalent ion binding. Furthermore, dysferlin displayed significantly lower binding affinity for the divalent cations magnesium and strontium. Measurement of a multidomain construct indicates that the solution binding affinity does not change when C2 domains are linked. Finally, sedimentation assays suggest all seven C2 domains bind lipid membranes, and that Ca²⁺ enhances but is not required for interaction. This report reveals for the first time, to our knowledge, that all dysferlin domains bind Ca²⁺ albeit with varying affinity and stoichiometry.     

Crystal structures of three representatives of a new Pfam family PF14869 (DUF4488) suggest they function in sugar binding/uptake

Crystal structures of three members (BACOVA_00364 from Bacteroides ovatus, BACUNI_03039 from Bacteroides uniformis and BACEGG_00036 from Bacteroides eggerthii) of the Pfam domain of unknown function (DUF4488) were determined to 1.95, 1.66, and 1.81 Å resolutions, respectively. The protein structures adopt an eight-stranded, calycin-like, β-barrel fold and bind an endogenous unknown ligand at one end of the β-barrel. The amino acids interacting with the ligand are not conserved in any other protein of known structure with this particular fold. The size and chemical environment of the bound ligand suggest binding or transport of a small polar molecule(s) as a potential function for these proteins. These are the first structural representatives of a newly defined PF14869 (DUF4488) Pfam family.