Specific conformation and Ca(2+)-binding mode of yeast calmodulin: insight into evolutionary development

The vertebrate calmodulin is configured with two structurally independent globular lobes in N- and C-terminus, and a flexible central linker. Distinctly, two lobes of calmodulin from Saccharomyces cerevisiae (yCaM) interact and influence the Ca(2+)-binding profile of each other. We explored this further using the mutant proteins with eliminated Ca(2+)-binding ability in one of the lobes and found that the Ca(2+)-bound N-lobe associates with the Ca(2+)-free C-lobe to gain the Ca(2+) affinity of a wild-type level. Next, analysing series of C-terminal residue truncation mutant, we found that the truncation of C-terminal three residues induce the hyper Ca(2+) affinity. These residues are also important for the general structural behaviour of calmodulin, such as Ca(2+)-induced slow mobility shift in polyacrylamide gel electrophoresis and for the ability to activate Cmk1p (yeast calmodulin kinase). These suggest: (i) when Ca(2+) occupies only N-lobe, two lobes interact and form the stable intermediate leading to a proper level of Ca(2+) affinity; (ii) the C-terminal three residues are required to prohibit abnormal stabilization of the intermediate promoting abnormally high Ca(2+) affinity and for recognition of target enzymes. A model for Ca(2+) and target bindings of yCaM is proposed. Evolutional aspect concerning the biological significance of this model was discussed.     

Conformational dynamics of yeast calmodulin in the Ca(2+)-bound state probed using NMR relaxation dispersion

Most calmodulin (CaM) in apo and Ca(2+)-bound states show a dumb-bell-like structure, involving the N- and C-terminal domains, connected with a flexible linker. However, Ca(2+)-bound yeast calmodulin (yCaM) takes on a unique globular structure; the target-binding site of this protein is autoinhibited. We applied NMR relaxation dispersion experiments to yCaM in the Ca(2+)-bound state. The amide (15)N and (1)H(N) relaxation dispersion profiles indicated the presence of conformational dynamics for specific residues at the interface between the N- and C-terminal domains. We conclude that these conformational dynamics were derived from the mobility of the C-terminal domain.     

The solution structure of apocalmodulin from Saccharomyces cerevisiae implies a mechanism for its unique Ca2+ binding property

We have determined the solution structure of calmodulin (CaM) from yeast (Saccharomyces cerevisiae) (yCaM) in the apo state by using NMR spectroscopy. yCaM is 60% identical in its amino acid sequence with other CaMs, and exhibits its unique biological features. yCaM consists of two similar globular domains (N- and C-domain) containing three Ca(2+)-binding motifs, EF-hands, in accordance with the observed 3 mol of Ca(2+) binding. In the solution structure of yCaM, the conformation of the N-domain conforms well to the one of the expressed N-terminal half-domains of yCaM [Ishida, H., et al. (2000) Biochemistry 39, 13660-13668]. The conformation of the C-domain basically consists of a pair of helix-loop-helix motifs, though a segment corresponding to the forth Ca(2+)-binding site of CaM deviates in its primary structure from a typical EF-hand motif and loses the ability to bind Ca(2+). Thus, the resulting conformation of each domain is essentially identical to the corresponding domain of CaM in the apo state. A flexible linker connects the two domains as observed for CaM. Any evidence for the previously reported interdomain interaction in yCaM was not observed in the solution structure of the apo state. Hence, the interdomain interaction possibly occurs in the course of Ca(2+) binding and generates a cooperative Ca(2+) binding among all three sites. Preliminary studies on a mutant protein of yCaM, E104Q, revealed that the Ca(2+)-bound N-domain interacts with the apo C-domain and induces a large conformational change in the C-domain.     

Construction and molecular dynamics simulation of calmodulin in the extended and in a bent conformation.

Analysis of sequence similarity and comparison of the three-dimensional (3D) structures of troponin C and calmodulin have revealed a sequence in the central helix of calmodulin with a high probability for bending. The three amino acids known to form a bend in the N-terminal portion of troponin C are also found in the central helix of calmodulin. The modelling of a bent calmodulin structure, using the dihedral angles of the three residues in the bend of troponin C as a 3D template, results in a conformation of calmodulin where the N- and C-terminal domains are able to form contacts. Dynamics simulations starting from the X-ray structure of calmodulin and from the modelled bent calmodulin were carried out to compare flexibility and correlated movements of Ca2+ in the binding loops. Both conformations of calmodulin remained stable during the period of simulation. In the simulation of calmodulin in the extended form, the motions of the Ca2+ atoms in the two domains (Ca2+1 and Ca2+2 in one domain, and Ca2+3 and Ca2+4 in the other) are correlated. In the simulation of the bent form, an additional correlation between the Ca atoms in the two different domains is observed. The results are compatible with the occurrence of a bent conformation of calmodulin in the presence of targets, and with increased Ca2+ affinity and cooperativity of the Ca(2+)-binding loops in the calmodulin-peptide complexes.     

Structural basis for the evolutionary inactivation of Ca2+ binding to synaptotagmin 4

The neuronal protein synaptotagmin 1 functions as a Ca(2+) sensor in exocytosis via two Ca(2+)-binding C(2) domains. The very similar synaptotagmin 4, which includes all the predicted Ca(2+)-binding residues in the C(2)B domain but not in the C(2)A domain, is also thought to function as a neuronal Ca(2+) sensor. Here we show that, unexpectedly, both C(2) domains of fly synaptotagmin 4 exhibit Ca(2+)-dependent phospholipid binding, whereas neither C(2) domain of rat synaptotagmin 4 binds Ca(2+) or phospholipids efficiently. Crystallography reveals that changes in the orientations of critical Ca(2+) ligands, and perhaps their flexibility, render the rat synaptotagmin 4 C(2)B domain unable to form full Ca(2+)-binding sites. These results indicate that synaptotagmin 4 is a Ca(2+) sensor in the fly but not in the rat, that the Ca(2+)-binding properties of C(2) domains cannot be reliably predicted from sequence analyses, and that proteins clearly identified as orthologs may nevertheless have markedly different functional properties.     

Calcium binding properties of recombinant calcium binding protein 40, a major calcium binding protein of lower eukaryote Physarum polycephalum

Calcium binding protein 40 (CBP40) is a Ca(2+)-binding protein abundant in the plasmodia of Physarum polycephalum. CBP40 consists four EF-hand domains in the COOH-terminal half and a putative alpha-helix domain in the NH(2)-terminal half. We expressed recombinant proteins of CBP40 in Escherichia coli to investigate its Ca(2+)-binding properties. Recombinant proteins of CBP40 bound 4 mol of Ca(2+) with much higher affinity (pCa(1/2) = 6.5) than that of calmodulin. When residues 1-196 of the alpha-helix domain were deleted, the affinity for Ca(2+) decreased to pCa(1/2) = 4.6. A chimeric calmodulin was generated by conjugating the alpha-helix domain of CBP40 with calmodulin. The affinity of Ca(2+) for the chimeric calmodulin was higher than that for calmodulin, suggesting that the alpha-helix domain is responsible for the high affinity of CBP40 for Ca(2+). CBP40 forms large aggregates reversibly in a Ca(2+)-dependent manner. A mutant protein with a deletion of NH(2)-terminal 32 residues, however, could not aggregate, indicating the importance of these residues for the aggregation. The aggregation occurs above micromolar levels of Ca(2+) concentration, so it may only occur when CBP40 is secreted out of the plasmodial cells.     

The primary structure of a new Mr 18,000 calcium vector protein from amphioxus

The amino acid sequence of a new Ca2+-binding protein (CaVP) from Amphioxus muscle (Cox, J. A., J. Biol. Chem. 261, 13173-13178) has been determined. The protein contains 161 amino acid residues and has a molecular weight of 18,267. The N terminus is blocked by an acetyl group. The two functional Ca2+-binding sites have been localized based on homology with known Ca2+-binding domains, on internal homology and on secondary structure prediction, and appear to be the domains III and IV. The C-terminal half of CaVP, which contains the two Ca2+-binding sites, shows a remarkable similarity with human brain calmodulin (45%) and with rabbit skeletal troponin C (40%). Functional domain III contains 2 epsilon-N-trimethyllysine residues in the alpha-helices flanking the Ca2+-binding loop. Sequence determination revealed two abortive Ca2+-binding domains in the N-terminal half of CaVP with a similarity of 24 and 30% as compared with calmodulin and troponin C, respectively. This half is also characterized by the presence of a disulfide bridge linking the N-terminal helix of domain I to the C-terminal helix of domain II. This disulfide bond is very resistant to reduction in the native state, but not in denatured CaVP. The optically interesting aromatic chromophores (2 tryptophan and 1 tyrosine residues) are all located in the nonfunctional domain II.     

Structure of a sarcoplasmic calcium-binding protein from Nereis diversicolor refined at 2.0 A resolution.

The crystal structure of a sarcoplasmic Ca(2+)-binding protein (SCP) from the sandworm Nereis diversicolor has been determined and refined at 2.0 A resolution using restrained least-squares techniques. The two molecules in the crystallographic asymmetric unit, which are related by a non-crystallographic 2-fold axis, were refined independently. The refined model includes all 174 residues and three calcium ions for each molecule, as well as 213 water molecules. The root-mean-square difference in co-ordinates for backbone atoms and calcium ions of the two molecules is 0.51 A. The final crystallographic R-factor, based on 18,959 reflections in the range 2.0 A less than or equal to d less than or equal to 7.0 A, with intensities exceeding 2.0 sigma, is 0.182. Bond lengths and bond angles in the molecules have root-mean-square deviations from ideal values of 0.013 A and 2.2 degrees, respectively. SCP has four distinct domains with the typical helix-loop-helix (EF-hand) Ca(2+)-binding motif, although the second Ca(2+)-binding domain is not functional due to amino acid changes in the loop. The structure shows several unique features compared to other Ca(2+)-binding proteins with four EF-hand domains. The overall structure is highly compact and globular with a predominant hydrophobic core, unlike the extended dumbbell-shaped structure of calmodulin or troponin C. A hydrophobic tail at the COOH terminus adds to the structural stability by packing against a hydrophobic pocket created by the folding of the NH2 and COOH-terminal Ca(2+)-binding domain pairs. The first and second domains show different helix-packing arrangements from any previously described for Ca(2+)-binding proteins.     

Three-dimensional structure of a sarcoplasmic calcium-binding protein from Nereis diversicolor

The three-dimensional structure of a sarcoplasmic Ca2(+)-binding protein from the sandworm Nereis diversicolor has been determined at 3.0 A resolution using multiple isomorphous replacement techniques. The NH2-terminal half of the molecule contains one variant Ca2(+)-binding domain with a novel helix-loop-helix conformation and one Ca2(+)-binding domain that is no longer functional because of amino acid changes. The overall conformation of this pair of domains is different from any previously described Ca2(+)-binding protein. The COOH-terminal half of the protein contains two Ca2(+)-binding domains with the usual helix-loop-helix configuration and is similar to calmodulin and troponin C. Unlike calmodulin or troponin C, there is no exposed alpha-helix connecting the two halves of the molecule, so the overall structure is much more compact.     

A structural basis for S100 protein specificity derived from comparative analysis of apo and Ca(2+)-calcyclin

Calcyclin is a homodimeric protein belonging to the S100 subfamily of EF-hand Ca(2+)-binding proteins, which function in Ca(2+) signal transduction processes. A refined high-resolution solution structure of Ca(2+)-bound rabbit calcyclin has been determined by heteronuclear solution NMR. In order to understand the Ca(2+)-induced structural changes in S100 proteins, in-depth comparative structural analyses were used to compare the apo and Ca(2+)-bound states of calcyclin, the closely related S100B, and the prototypical Ca(2+)-sensor protein calmodulin. Upon Ca(2+) binding, the position and orientation of helix III in the second EF-hand is altered, whereas the rest of the protein, including the dimer interface, remains virtually unchanged. This Ca(2+)-induced structural change is much less drastic than the "opening" of the globular EF-hand domains that occurs in classical Ca(2+) sensors, such as calmodulin. Using homology models of calcyclin based on S100B, a binding site in calcyclin has been proposed for the N-terminal domain of annexin XI and the C-terminal domain of the neuronal calcyclin-binding protein. The structural basis for the specificity of S100 proteins is discussed in terms of the variation in sequence of critical contact residues in the common S100 target-binding site.     

C-terminal half of human centrin 2 behaves like a regulatory EF-hand domain

Human centrin 2 (HsCen2) is an EF-hand protein that plays a critical role in the centrosome duplication and separation during cell division. We studied the structural and Ca(2+)-binding properties of two C-terminal fragments of this protein: SC-HsCen2 (T94-Y172), covering two EF-hands, and LC-HsCen2 (M84-Y172), having 10 additional residues. Both fragments are highly disordered in the apo state but become better structured (although not conformationally homogeneous) in the presence of Ca(2+) and depending on the nature of the cations (K(+) or Na(+)) in the buffer. Only the longer C-terminal domain, in the Ca(2+)-saturated state and in the presence of Na(+) ions, was amenable to structure determination by nuclear magnetic resonance. The solution structure of LC-HsCen2 reveals an open two EF-hand structure, similar to the conformation of related Ca(2+)-saturated regulatory domains. Unexpectedly, the N-terminal helix segment (F86-T94) lies over the exposed hydrophobic cavity. This unusual intramolecular interaction increases considerably the Ca(2+) affinity and constitutes a useful model for the target binding.     

A site-directed mutagenesis study of yeast calmodulin

A site-directed mutagenesis study was carried out in order to understand the regulatory mechanism of calmodulin. We started from the yeast (Saccharomyces cerevisiae) calmodulin gene since it has many differences in amino acid sequence and inferior functional properties compared with the vertebrate calmodulin. Recombinant yeast calmodulins were generated in Escherichia coli transformed by constructed expression plasmids. Three recombinant calmodulins were obtained. The first two were YCM61G, in which the Ca2(+)-binding site 2 (the four Ca2(+)-binding EF-hand structures in calmodulin were numbered from the N-terminus) was converted to the same as that in vertebrate calmodulin, and YCM delta 132-148, in which the C-terminal half sequence of site 4 was deleted. These two recombinant calmodulins had the same maximum Ca2+ binding (3 mol/mol) as yeast calmodulin, which indicates that site 4 of yeast calmodulin was the one losing Ca2+ binding capacity. YCM delta 132-148 could not activate target enzymes, whereas its Ca2+ binding profile was similar to those of yeast calmodulin and YCM61G. Therefore, the structure in site 4 which cannot bind Ca2+ is indispensable for the regulatory function of yeast calmodulin. The complete regulatory function of vertebrate calmodulin can be attained by the combination of 4 Ca2+ binding structures. The negative charge cluster in the central alpha-helix region is suggested to stabilize the active conformation of calmodulin, since the third yeast calmodulin mutant, YCM83E, which had the negative charge cluster, increased the maximum activation of myosin light chain kinase.     

Calcium and lanthanide affinity of the EF-loops from the C-terminal domain of calmodulin

To obtain site-specific information about individual EF-hand motifs, the EF-hand Ca(2+)-binding loops from site III and site IV of calmodulin (CaM) were inserted separately into a non-Ca(2+)-binding cell adhesion protein, domain 1 of CD2 (denoted as CaM-CD2-III-5G-52 and CaM-CD2-IV-5G-52). Structural analyses using various spectroscopic methods have shown that the host protein CD2 retains its native structure after the insertion of the 12-residue loops. The Tb(3+) fluorescence enhancement upon formation of a Tb(3+)-protein complex and the direct competition by La(3+) and Ca(2+) suggest that native Ca(2+)-binding pockets are formed in both engineered proteins. Moreover, as revealed by NMR, both Ca(2+) and La(3+) specifically interact with the residues at the grafted EF-loop. The CaM-CD2-III-5G-52 has stronger affinities to Ca(2+), Tb(3+) and La(3+) than CaM-CD2-IV-5G-52, indicating differential intrinsic metal-binding affinities of the EF-loops.     

The EF-hand domain: A globally cooperative structural unit

EF-hand Ca(2+)-binding proteins participate in both modulation of Ca(2+) signals and direct transduction of the ionic signal into downstream biochemical events. The range of biochemical functions of these proteins is correlated with differences in the way in which they respond to the binding of Ca(2+). The EF-hand domains of calbindin D(9k) and calmodulin are homologous, yet they respond to the binding of calcium ions in a drastically different manner. A series of comparative analyses of their structures enabled the development of hypotheses about which residues in these proteins control the calcium-induced changes in conformation. To test our understanding of the relationship between protein sequence and structure, we specifically designed the F36G mutation of the EF-hand protein calbindin D(9k) to alter the packing of helices I and II in the apoprotein. The three-dimensional structure of apo F36G was determined in solution by nuclear magnetic resonance spectroscopy and showed that the design was successful. Surprisingly, significant structural perturbations also were found to extend far from the site of mutation. The observation of such long-range effects provides clear evidence that four-helix EF-hand domains should be treated as a single globally cooperative unit. A hypothetical mechanism for how the long-range effects are transmitted is described. Our results support the concept of energetic and structural coupling of the key residues that are crucial for a protein's fold and function.     

X-ray structures of the microglia/macrophage-specific protein Iba1 from human and mouse demonstrate novel molecular conformation change induced by calcium binding

The ionized calcium-binding adaptor molecule 1 (Iba1) with 147 amino acid residues has been identified as a calcium-binding protein, expressed specifically in microglia/macrophages, and is expected to be a key factor in membrane ruffling, which is a typical feature of activated microglia. We have determined the crystal structure of human Iba1 in a Ca(2+)-free form and mouse Iba1 in a Ca(2+)-bound form, to a resolution of 1.9 A and 2.1 A, respectively. X-ray structures of Iba1 revealed a compact, single-domain protein with two EF-hand motifs, showing similarity in overall topology to partial structures of the classical EF-hand proteins troponin C and calmodulin. In mouse Iba1, the second EF-hand contains a bound Ca(2+), but the first EF-hand does not, which is often the case in S100 proteins, suggesting that Iba1 has S100 protein-like EF-hands. The molecular conformational change induced by Ca(2+)-binding of Iba1 is different from that found in the classical EF-hand proteins and/or S100 proteins, which demonstrates that Iba1 has an unique molecular switching mechanism dependent on Ca(2+)-binding, to interact with target molecules.     

Regulation of the erythrocyte Ca(2+)-ATPase by mutant calmodulins with Glu----Ala substitutions in the Ca(2+)-binding domains.

We have used four mutant calmodulins to study the regulation of human erythrocyte Ca(2+)-ATPase by the calmodulin-dependent pathway; the conserved Glu at position 12 in each of the four Ca(2+)-binding domains of calmodulin (Glu31, Glu67, Glu104, or Glu140) was replaced by Ala. At pCa 7, where unmodified calmodulin maximally activates the erythrocyte Ca(2+)-ATPase, all four mutants stimulated Ca(2+)-ATPase activity to the same maximal velocity. However, the concentrations of mutant calmodulins required for half-maximal activation (KCaM) were significantly higher than that for unmodified calmodulin and were strongly dependent on the domain in which the mutated Glu was located; substitution in either the first or second Ca(2+)-binding domain had little effect (2-3-fold increase in KCaM), whereas substitution in either the third or fourth domain resulted in a dramatic, 25-71-fold increase in KCaM. The same order of sensitivity was observed when the Ca2+ dependence of enzyme activation was measured at a constant 100 nM concentration of mutant calmodulin. These data point to dramatic differences in the functional significance of the replacement of the Glu at position 12 in each of the four Ca(2+)-binding domains for activation of the Ca(2+)-ATPase. The 2 Glu residues located in the carboxyl-terminal half of calmodulin (particularly Glu140) are crucial for activation of the Ca(2+)-ATPase at physiologically significant Ca2+ concentrations.     

Decoding the molecular design principles underlying Ca(2+) binding to βγ-crystallin motifs

Numerous proteins belonging to the recently expanded βγ-crystallin superfamily bind Ca(2+) at the double-clamp N/D-N/D-X(1)-X(2)-S/T-S motif. However, there have been no attempts to understand the intricacies involving Ca(2+) binding, such as the determinants of Ca(2+)-binding affinity and their contributions to gain in stability. This work is an in-depth analysis of understanding the modes and determinants of Ca(2+) binding to βγ-crystallin motifs. We have performed extensive naturally occurring substitutions from related proteins on the βγ-crystallin domains of flavollin, a low-affinity Ca(2+)-binding protein, and clostrillin, a moderate-affinity protein. We monitored the consequences of these modifications on Ca(2)(+) binding by isothermal titration calorimetry, thermal stability and conformational and crystal structure analyses. We demonstrate that Ca(2)(+) binding to the two sites of a βγ-domain is interdependent and that the presence of Arg at the fifth position disables a site. A change from Thr to Ser, or vice versa, influences Ca(2+)-binding affinity, highlighting the basis of diversity found in these domains. A subtle change in the first site has a greater influence on Ca(2)(+) binding than a similar alteration in the second site. Thus, the second site is more variable in nature. Replacing an acidic or hydrophobic residue in a binding site alters the Ca(2+)-binding properties drastically. While it appears from their binding site sequence that these domains have evolved randomly, our examination illustrates the subtlety in the design of these modules. Decoding such design schemes would aid in our understanding of the functional themes underlying differential Ca(2)(+) binding and in predicting these in emerging sequence information.     

Monoclonal antibodies to the calcium-binding region peptide of human C-reactive protein alter its conformation.

Five mouse mAb were generated against a synthetic peptide corresponding to the proposed Ca(2+)-binding region of human C-reactive protein (CRP). The peptide consists of amino acids 134 to 148 and possesses a calmodulin Ca(2+)-binding sequence. The mAb reacted with a surface epitope(s) on native, intact CRP as well as the closely related pentraxin protein, serum amyloid P-component. Three of the 5 mAb inhibited the Ca(2+)-dependent phosphorylcholine-(PC) binding activity of CRP, but did not bind to the PC-binding region itself. Four of the five mAb also inhibited the recognition of an epitope in the PC-binding site of CRP. Four of the mAb partially, or completely, protected CRP from selective cleavage by pronase between residues 146 and 147. The findings suggest that the Ca(2+)-binding region is on the surface of CRP, has substantial flexibility, and is probably responsible for the allosteric effects of Ca2+ ions on CRP.     

Cation- and peptide-binding properties of human calmodulin-like skin protein

Human CLSP, a new Ca(2+)-binding protein specifically expressed in differentiated keratinocytes, is a 15.9 kDa, four EF-hand containing protein with 52% sequence identity to calmodulin (CaM). The protein binds four Ca(2+) ions at two pairs of sites with [Ca(2+)](0.5) values of 1.2 and 150 microM, respectively. Mg(2+) at millimolar concentrations strongly decreases the affinity for Ca(2+) of the two high-affinity sites, but has no effect on the low-affinity sites. The protein can also bind two Mg(2+) ([Mg(2+)](0.5) = 57 microM) at the sites of high Ca(2+) affinity. Thus, as fast skeletal muscle troponin C (TnC), CLSP possesses two high-affinity Ca(2+)-Mg(2+) mixed sites and two low-affinity Ca(2+)-specific sites. Studies on the isolated recombinant N- (N-CLSP) and C-terminal half domains of CLSP (C-CLSP) revealed that, in contrast to the case of TNC, the high-affinity Ca(2+)-Mg(2+) mixed sites reside in the N-terminal half. The binding of cations modifies the intrinsic fluorescence of the two Tyr residues. Upon Ca(2+) binding, hydrophobicity is exposed at the protein surface that can be monitored with a fluorescent probe. The Ca(2+)-dependency of the two conformational changes is biphasic in the absence of Mg(2+), but monophasic in the presence of 2 mM Mg(2+), both corresponding closely to direct binding of Ca(2+) to CLSP. In the presence of Ca(2+), human CLSP forms a high-affinity 1:1 complex with melittin, a natural peptide considered to be a model for the interaction of CaM with its targets. In the complex, CLSP binds Ca(2+) with high affinity to all four binding sites. Isolated N- and C-CLSP show only a weak interaction with melittin, which is enhanced when both halves are simultaneously presented to the model peptide.     

The calcium-binding loops of the tandem C2 domains of synaptotagmin VII cooperatively mediate calcium-dependent oligomerization

Synaptotagmin VII (Syt VII), a proposed regulator for Ca2+-dependent exocytosis, showed a robust Ca2+-dependent oligomerization property via its two C2 domains (Fukuda, M., and Mikoshiba, K. (2001) J. Biol. Chem. 276, 27670-27676), but little is known about its structure or the critical residues directly involved in the oligomerization interface. In this study, site-directed mutagenesis and chimeric analysis between Syt I and Syt VII showed that three Asp residues in Ca2+-binding loop 1 or 3 (Asp-172, Asp-303, and Asp-357) are crucial to robust Ca(2+)-dependent oligomerization. Unlike Syt I, however, the polybasic sequence in the beta4 strands of the C2 structures (so-called "C2 effector domain") is not involved in the Ca2+-dependent oligomerization of Syt VII. The results also showed that the Ca2+-binding loops of the two C2 domains cooperatively mediate Syt VII oligomerization (i.e. the presence of redundant Ca2+-binding site(s)) as well as the importance of Ca2+-dependent oligomerization of Syt VII in Ca2+-regulated secretion. Expression of wild-type tandem C2 domains of Syt VII in PC12 cells inhibited Ca2+-dependent neuropeptide Y release, whereas mutant fragments lacking Ca2+-dependent oligomerization activity had no effect. Finally, rotary-shadowing electron microscopy showed that the Ca2+-dependent oligomer of Syt VII is "a large linear structure," not an irregular aggregate. By contrast, in the absence of Ca2+ Syt VII molecules were observed to form a globular structure. Based on these results, we suggest that the linear Ca2+-dependent oligomer may be aligned at the fusion site between vesicles and plasma membrane and modulate Ca2+-regulated exocytosis by opening or dilating fusion pores.