Structural and functional diversity of Entamoeba histolytica calcium-binding proteins

Entamoeba histolytica (E. histolytica) is an etiological agent of human amoebic colitis, and it causes a high level of morbidity and mortality worldwide, particularly in developing countries. Ca²⁺ plays a pivotal role in amoebic pathogenesis, and Ca²⁺-binding proteins (CaBPs) of E. histolytica appear to be a major determinant in this process. E. histolytica has 27-EF-hand containing CaBPs, suggesting that this organism has complex Ca²⁺ signaling cascade. E. histolytica CaBPs share (29–47%) sequence identity with ubiquitous Ca²⁺-binding protein calmodulin (CaM); however, they do not show any significant structural similarity, indicating lack of a typical CaM in this organism. Structurally, these CaBPs are very diverse among themselves, and perhaps such diversity allows them to recognize different cellular targets, thereby enabling them to perform a range of cellular functions. The presence of such varied signaling molecules helps parasites to invade host cells and advance in disease progression. In the past two decades, tremendous progress has been made in understanding the structure of E. histolytica CaBPs by using the X-ray or NMR method. To gain greater insight into the structural and functional diversity of these amoebic CaBPs, we analyzed and compiled all the available literature. Most of the CaBPs has about 150 amino acids with 4-EF hand or EF-hand-like sequences, similar to CaM. In a few cases, all the EF-hand motifs are not capable of binding Ca²⁺, suggesting them to be pseudo EF-hand motifs. The CaBPs perform diverse cellular signaling that includes cytoskeleton remodeling, phagocytosis, cell proliferation, migration of trophozoites, and GTPase activity. Overall, the structural and functional diversity of E. histolytica CaBPs compiled here may offer a basis to develop an efficient drug to counter its pathogenesis.     

S100 and S100 fused-type protein families in epidermal maturation with special focus on S100A3 in mammalian hair cuticles

Epithelial Ca²⁺-regulation, which governs cornified envelope formation in the skin epidermis and hair follicles, closely coincides with the expression of S100A3, filaggrin and trichohyalin, and the post-translational modification of these proteins by Ca²⁺-dependent peptidylarginine deiminases. This review summarizes the current nomenclature and evolutional aspects of S100 Ca²⁺-binding proteins and S100 fused-type proteins (SFTPs) classified as a separate protein family with special reference to the molecular structure and function of S100A3 dominantly expressed in hair cuticular cells. Both S100 and SFTP family members are identified by two distinct types of Ca²⁺-binding loops in an N-terminal pseudo EF-hand motif followed by a canonical EF-hand motif. Seventeen members of the S100 protein family including S100A3 are clustered with seven related genes encoding SFTPs on human chromosome 1q21, implicating their association with epidermal maturation and diseases. Human S100A3 is characterized by two disulphide bridges and a preformed Zn²⁺-pocket, and may transfer Ca²⁺ ions to peptidylarginine deiminases after its citrullination-mediated tetramerization. Phylogenetic analysis utilizing current genome databases suggests that divergence of the S100A3 gene coincided with the emergence of hair, a defining feature of mammals, and that the involvement of S100A3 in epithelial Ca²⁺-cycling occurred as a result of a skin adaptation in terrestrial mammals.     

CUDASW++2.0: enhanced Smith-Waterman protein database search on CUDA-enabled GPUs based on SIMT and virtualized SIMD abstractions

Background

Ca²⁺-binding proteins are important for the transduction of Ca²⁺ signals into physiological outcomes. As in calmodulin many of the Ca²⁺-binding proteins bind Ca²⁺ through EF-hand motifs. Amongst the large number of EF-hand containing Ca²⁺-binding proteins are a subfamily expressed in neurons and retinal photoreceptors known as the CaBPs and the related calneuron proteins. These were suggested to be vertebrate specific but exactly which family members are expressed outside of mammalian species had not been examined.

Findings

We have carried out a bioinformatic analysis to determine when members of this family arose and the conserved aspects of the protein family. Sequences of human members of the family obtained from GenBank were used in Blast searches to identify corresponding proteins encoded in other species using searches of non-redundant proteins, genome sequences and mRNA sequences. Sequences were aligned and compared using ClustalW. Some families of Ca²⁺-binding proteins are known to show a progressive expansion in gene number as organisms increase in complexity. In contrast, the results for CaBPs and calneurons showed that a full complement of CaBPs and calneurons are present in the teleost fish Danio rerio and possibly in cartilaginous fish. These findings suggest that the entire family of genes may have arisen at the same time during vertebrate evolution. Certain members of the family (for example the short form of CaBP1 and calneuron 1) are highly conserved suggesting essential functional roles.

Conclusions

The findings support the designation of the calneurons as a distinct sub-family. While the gene number for CaBPs/calneurons does not increase, a distinctive evolutionary change in these proteins in vertebrates has been an increase in the number of splice variants present in mammals.     

Crystal structure of wild-type centrin 1 from <Emphasis Type="Italic">Mus musculus</Emphasis> occupied by Ca<Superscript>2+</Superscript>

Mus musculus centrin 1 (MmCen1) is located at the cilium of photoreceptor cells connecting the outer segment through signal transduction components to the metabolically active inner segment. In the cilium, MmCen1 is involved in the translocation of transducin between compartments as a result of photoreceptor activation. In this study, we report the crystal structure of wild-type MmCen1 and its Ca²⁺-binding properties using structure-based mutagenesis. The crystal structure exhibits three structural features, i.e. four Ca²⁺ equally occupied at each EF-hand motif, structural changes accompanying helix motion at the N- and C-lobes, and adoption of N–C type dimerization when Ca²⁺ binds to EF-hand I and II in the N-lobe. The presence of MmCen1 dimers was confirmed in solution by native PAGE. Isothermal titration calorimetry data showed sequential binding of Ca²⁺ at four independent sites. Mutations S45A and D49A in EF-hand I alone disrupted the Ca²⁺-binding property of the wild-type protein. Based on the crystal structure of MmCen1, we suggest that a dimerization mode between the N- and C-lobes may be required by Ca²⁺ binding at the N-lobe.     

Regulatory and structural EF-hand motifs of neuronal calcium sensor-1: Mg 2+ modulates Ca 2+ binding, Ca 2+ -induced conformational changes, and equilibrium unfolding transitions

Neuronal calcium sensor-1 (NCS-1) is a major modulator of Ca²⁺ signaling with a known role in neurotransmitter release. NCS-1 has one cryptic (EF1) and three functional (EF2, EF3, and EF4) EF-hand motifs. However, it is not known which are the regulatory (Ca²⁺-specific) and structural (Ca²⁺- or Mg²⁺-binding) EF-hand motifs. To understand the specialized functions of NCS-1, identification of the ionic discrimination of the EF-hand sites is important. In this work, we determined the specificity of Ca²⁺ binding using NMR and EF-hand mutants. Ca²⁺ titration, as monitored by [¹⁵N,¹H] heteronuclear single quantum coherence, suggests that Ca²⁺ binds to the EF2 and EF3 almost simultaneously, followed by EF4. Our NMR data suggest that Mg²⁺ binds to EF2 and EF3, thereby classifying them as structural sites, whereas EF4 is a Ca²⁺-specific or regulatory site. This was further corroborated using an EF2/EF3-disabled mutant, which binds only Ca²⁺ and not Mg²⁺. Ca²⁺ binding induces conformational rearrangements in the protein by reversing Mg²⁺-induced changes in Trp fluorescence and surface hydrophobicity. In a larger physiological perspective, exchanging or replacing Mg²⁺ with Ca²⁺ reduces the Ca²⁺-binding affinity of NCS-1 from 90 nM to 440 nM, which would be advantageous to the molecule by facilitating reversibility to the Ca²⁺-free state. Although the equilibrium unfolding transitions of apo-NCS-1 and Mg²⁺-bound NCS-1 are similar, the early unfolding transitions of Ca²⁺-bound NCS-1 are partially influenced in the presence of Mg²⁺. This study demonstrates the importance of Mg²⁺ as a modulator of calcium homeostasis and active-state behavior of NCS-1.     

Crystal Structure of Calcium Binding Protein-5 from Entamoeba histolytica and Its Involvement in Initiation of Phagocytosis of Human Erythrocytes

Entamoeba histolytica is the etiological agent of human amoebic colitis and liver abscess, and causes a high level of morbidity and mortality worldwide, particularly in developing countries. There are a number of studies that have shown a crucial role for Ca²⁺ and its binding protein in amoebic biology. EhCaBP5 is one of the EF hand calcium-binding proteins of E. histolytica. We have determined the crystal structure of EhCaBP5 at 1.9 Å resolution in the Ca²⁺-bound state, which shows an unconventional mode of Ca²⁺ binding involving coordination to a closed yet canonical EF-hand motif. Structurally, EhCaBP5 is more similar to the essential light chain of myosin than to Calmodulin despite its somewhat greater sequence identity with Calmodulin. This structure-based analysis suggests that EhCaBP5 could be a light chain of myosin. Surface plasmon resonance studies confirmed this hypothesis, and in particular showed that EhCaBP5 interacts with the IQ motif of myosin 1B in calcium independent manner. It also appears from modelling of the EhCaBP5-IQ motif complex that EhCaBP5 undergoes a structural change in order to bind the IQ motif of myosin. This specific interaction was further confirmed by the observation that EhCaBP5 and myosin 1B are colocalized in E. histolytica during phagocytic cup formation. Immunoprecipitation of EhCaBP5 from total E. histolytica cellular extract also pulls out myosin 1B and this interaction was confirmed to be Ca²⁺ independent. Confocal imaging of E. histolytica showed that EhCaBP5 and myosin 1B are part of phagosomes. Overexpression of EhCaBP5 increases slight rate (∼20%) of phagosome formation, while suppression reduces the rate drastically (∼55%). Taken together, these experiments indicate that EhCaBP5 is likely to be the light chain of myosin 1B. Interestingly, EhCaBP5 is not present in the phagosome after its formation suggesting EhCaBP5 may be playing a regulatory role.     

Calcium binding proteins in the sarcoplasmic/endoplasmic reticulum of muscle and nonmuscle cells

In this paper we review some of the large quantities of information currently available concerning the identification, structure and function of Ca²⁺-binding proteins of endoplasmic and sarcoplasmic reticulum membranes. The review places particular emphasis on identification and discussion of Ca²⁺ storage proteins in these membranes. We believe that the evidence reviewed here supports the contention that the Ca²⁺-binding capacity of both calsequestrin and calreticulin favor their contribution as the major Ca²⁺-binding proteins of muscle and nonmuscle cells, respectively. Other Ca²⁺-binding proteins discovered in both endoplasmic reticulum and sarcoplasmic reticulum membranes probably contribute to the overall Ca²⁺ storage capacity of these membrane organelles, and they also play other important functional role such as posttranslational modification of newly synthesized proteins, a cytoskeletal (structural) function, or movement of Ca²⁺ within the lumen of the sarcoplasmic/endoplasmic reticulum towards the storage sites.Abbreviations SR Sarcoplasmic Reticulum - ER Endoplasmic Reticulum - InsP₃ Inositol 1,4,5-trisphosphate - SDS-PAGE Sodium Dodecyl Sulfate-Polyacrylamide Gel Electrophoresis - PDI Protein Disulphide Isomerase - T₃BP Thyroid Hormone Binding Protein - Grp Glucose regulated proteins - HCP Histidine-rich Ca²⁺ binding Protein - LDL Low Density Lipoprotein     

The renaissance of Ca2+-binding proteins in the nervous system: secretagogin takes center stage

Effective control of the Ca²⁺ homeostasis in any living cell is paramount to coordinate some of the most essential physiological processes, including cell division, morphological differentiation, and intercellular communication. Therefore, effective homeostatic mechanisms have evolved to maintain the intracellular Ca²⁺ concentration at physiologically adequate levels, as well as to regulate the spatial and temporal dynamics of Ca²⁺signaling at subcellular resolution. Members of the superfamily of EF-hand Ca²⁺-binding proteins are effective to either attenuate intracellular Ca²⁺ transients as stochiometric buffers or function as Ca²⁺ sensors whose conformational change upon Ca²⁺ binding triggers protein-protein interactions, leading to cell state-specific intracellular signaling events. In the central nervous system, some EF-hand Ca²⁺-binding proteins are restricted to specific subtypes of neurons or glia, with their expression under developmental and/or metabolic control. Therefore, Ca²⁺-binding proteins are widely used as molecular markers of cell identity whilst also predicting excitability and neurotransmitter release profiles in response to electrical stimuli. Secretagogin is a novel member of the group of EF-hand Ca²⁺-binding proteins whose expression precedes that of many other Ca²⁺-binding proteins in postmitotic, migratory neurons in the embryonic nervous system. Secretagogin expression persists during neurogenesis in the adult brain, yet becomes confined to regionalized subsets of differentiated neurons in the adult central and peripheral nervous and neuroendocrine systems. Secretagogin may be implicated in the control of neuronal turnover and differentiation, particularly since it is re-expressed in neoplastic brain and endocrine tumors and modulates cell proliferation in vitro. Alternatively, and since secretagogin can bind to SNARE proteins, it might function as a Ca²⁺ sensor/coincidence detector modulating vesicular exocytosis of neurotransmitters, neuropeptides or hormones. Thus, secretagogin emerges as a functionally multifaceted Ca²⁺-binding protein whose molecular characterization can unravel a new and fundamental dimension of Ca²⁺signaling under physiological and disease conditions in the nervous system and beyond.     

Insights into modulation of calcium signaling by magnesium in calmodulin, troponin C and related EF-hand proteins

The Ca²⁺-binding helix-loop-helix structural motif called “EF-hand” is a common building block of a large family of proteins that function as intracellular Ca²⁺-receptors. These proteins respond specifically to micromolar concentrations of Ca²⁺ in the presence of ~1000-fold excess of the chemically similar divalent cation Mg²⁺. The intracellular free Mg²⁺ concentration is tightly controlled in a narrow range of 0.5-1.0 mM, which at the resting Ca²⁺ levels is sufficient to fully or partially saturate the Ca²⁺-binding sites of many EF-hand proteins. Thus, to convey Ca²⁺ signals, EF-hand proteins must respond differently to Ca²⁺ than to Mg²⁺. In this review the structural aspects of Mg²⁺ binding to EF-hand proteins are considered and interpreted in light of the recently proposed two-step Ca²⁺-binding mechanism (Grabarek, Z., J. Mol. Biol., 2005, 346, 1351). It is proposed that, due to stereochemical constraints imposed by the two-EF-hand domain structure, the smaller Mg²⁺ ion cannot engage the ligands of an EF-hand in the same way as Ca²⁺ and defaults to stabilizing the apo-like conformation of the EF-hand. It is proposed that Mg²⁺ plays an active role in the Ca²⁺-dependent regulation of cellular processes by stabilizing the “off state” of some EF-hand proteins, thereby facilitating switching off their respective target enzymes at the resting Ca²⁺ levels. Therefore, some pathological conditions attributed to Mg²⁺ deficiency might be related to excessive activation of underlying Ca²⁺-regulated cellular processes. This article is part of a Special Issue entitled: 11th European Symposium on Calcium.     

Structural Insights into Ca2+-dependent Regulation of Inositol 1,4,5-Trisphosphate Receptors by CaBP1

Calcium-binding protein 1 (CaBP1), a neuron-specific member of the calmodulin (CaM) superfamily, modulates Ca²⁺-dependent activity of inositol 1,4,5-trisphosphate receptors (InsP₃Rs). Here we present NMR structures of CaBP1 in both Mg²⁺-bound and Ca²⁺-bound states and their structural interaction with InsP₃Rs. CaBP1 contains four EF-hands in two separate domains. The N-domain consists of EF1 and EF2 in a closed conformation with Mg²⁺ bound at EF1. The C-domain binds Ca²⁺ at EF3 and EF4, and exhibits a Ca²⁺-induced closed to open transition like that of CaM. The Ca²⁺-bound C-domain contains exposed hydrophobic residues (Leu¹³², His¹³⁴, Ile¹⁴¹, Ile¹⁴⁴, and Val¹⁴⁸) that may account for selective binding to InsP₃Rs. Isothermal titration calorimetry analysis reveals a Ca²⁺-induced binding of the CaBP1 C-domain to the N-terminal region of InsP₃R (residues 1-587), whereas CaM and the CaBP1 N-domain did not show appreciable binding. CaBP1 binding to InsP₃Rs requires both the suppressor and ligand-binding core domains, but has no effect on InsP₃ binding to the receptor. We propose that CaBP1 may regulate Ca²⁺-dependent activity of InsP₃Rs by promoting structural contacts between the suppressor and core domains.Calcium ion (Ca²⁺) in the cell functions as an important messenger that controls neurotransmitter release, gene expression, muscle contraction, apoptosis, and disease processes (1). Receptor stimulation in neurons promotes large increases in intracellular Ca²⁺ levels controlled by Ca²⁺ release from intracellular stores through InsP₃Rs (2). The neuronal type-1 receptor (InsP₃R1)² is positively and negatively regulated by cytosolic Ca²⁺ (3-6), important for the generation of repetitive Ca²⁺ transients known as Ca²⁺ spikes and waves (1). Ca²⁺-dependent activation of InsP₃R1 contributes to the fast rising phase of Ca²⁺ signaling known as Ca²⁺-induced Ca²⁺ release (7). Ca²⁺-induced inhibition of InsP₃R1, triggered at higher cytosolic Ca²⁺ levels, coordinates the temporal decay of Ca²⁺ transients (6). The mechanism of Ca²⁺-dependent regulation of InsP₃Rs is complex (8, 9), and involves direct Ca²⁺ binding sites (5, 10) as well as remote sensing by extrinsic Ca²⁺-binding proteins such as CaM (11, 12), CaBP1 (13, 14), CIB1 (15), and NCS-1 (16).Neuronal Ca²⁺-binding proteins (CaBP1-5 (17)) represent a new sub-branch of the CaM superfamily (18) that regulate various Ca²⁺ channel targets. Multiple splice variants and isoforms of CaBPs are localized in different neuronal cell types (19-21) and perform specialized roles in signal transduction. CaBP1, also termed caldendrin (22), has been shown to modulate the Ca²⁺-sensitive activity of InsP₃Rs (13, 14). CaBP1 also regulates P/Q-type voltage-gated Ca²⁺ channels (23), L-type channels (24), and the transient receptor potential channel, TRPC5 (25). CaBP4 regulates Ca²⁺-dependent inhibition of L-type channels in the retina and may be genetically linked to retinal degeneration (26). Thus, the CaBP proteins are receiving increased attention as a family of Ca²⁺ sensors that control a variety of Ca²⁺ channel targets implicated in neuronal degenerative diseases.CaBP proteins contain four EF-hands, similar in sequence to those found in CaM and troponin C (18) (Fig. 1). By analogy to CaM (27), the four EF-hands are grouped into two domains connected by a central linker that is four residues longer in CaBPs than in CaM. In contrast to CaM, the CaBPs contain non-conserved amino acids within the N-terminal region that may confer target specificity. Another distinguishing property of CaBPs is that the second EF-hand lacks critical residues required for high affinity Ca²⁺ binding (17). CaBP1 binds Ca²⁺ only at EF3 and EF4, whereas it binds Mg²⁺ at EF1 that may serve a functional role (28). Indeed, changes in cytosolic Mg²⁺ levels have been detected in cortical neurons after treatment with neurotransmitter (29). Other neuronal Ca²⁺-binding proteins such as DREAM (30), CIB1 (31), and NCS-1 (32) also bind Mg²⁺ and exhibit Mg²⁺-induced physiological effects. Mg²⁺ binding in each of these proteins helps stabilize their Ca²⁺-free state to interact with signaling targets.Open in a separate windowFIGURE 1.Amino acid sequence alignment of human CaBP1 with CaM. Secondary structural elements (α-helices and β-strands) were derived from NMR analysis. The four EF-hands (EF1, EF2, EF3, and EF4) are highlighted green, red, cyan, and yellow. Residues in the 12-residue Ca²⁺-binding loops are underlined and chelating residues are highlighted bold. Non-conserved residues in the hydrophobic patch are colored red.Despite extensive studies on CaBP1, little is known about its structure and target binding properties, and regulation of InsP₃Rs by CaBP1 is somewhat controversial and not well understood. Here, we present the NMR solution structures of both Mg²⁺-bound and Ca²⁺-bound conformational states of CaBP1 and their structural interactions with InsP₃R1. These CaBP1 structures reveal important Ca²⁺-induced structural changes that control its binding to InsP₃R1. Our target binding analysis demonstrates that the C-domain of CaBP1 exhibits Ca²⁺-induced binding to the N-terminal cytosolic region of InsP₃R1. We propose that CaBP1 may regulate Ca²⁺-dependent channel activity in InsP₃Rs by promoting a structural interaction between the N-terminal suppressor and ligand-binding core domains that modulates Ca²⁺-dependent channel gating (8, 33, 34).     

Oligomerization of the Polycystin-2 C-terminal Tail and Effects on Its Ca2+-binding Properties

Polycystin-2 (PC2) belongs to the transient receptor potential (TRP) family and forms a Ca²⁺-regulated channel. The C-terminal cytoplasmic tail of human PC2 (HPC2 Cterm) is important for PC2 channel assembly and regulation. In this study, we characterized the oligomeric states and Ca²⁺-binding profiles in the C-terminal tail using biophysical approaches. Specifically, we determined that HPC2 Cterm forms a trimer in solution with and without Ca²⁺ bound, although TRP channels are believed to be tetramers. We found that there is only one Ca²⁺-binding site in the HPC2 Cterm, located within its EF-hand domain. However, the Ca²⁺ binding affinity of the HPC2 Cterm trimer is greatly enhanced relative to the intrinsic binding affinity of the isolated EF-hand domain. We also employed the sea urchin PC2 (SUPC2) as a model for biophysical and structural characterization. The sea urchin C-terminal construct (SUPC2 Ccore) also forms trimers in solution, independent of Ca²⁺ binding. In contrast to the human PC2, the SUPC2 Ccore contains two cooperative Ca²⁺-binding sites within its EF-hand domain. Consequently, trimerization does not further improve the affinity of Ca²⁺ binding in the SUPC2 Ccore relative to the isolated EF-hand domain. Using NMR, we localized the Ca²⁺-binding sites in the SUPC2 Ccore and characterized the conformational changes in its EF-hand domain due to trimer formation. Our study provides a structural basis for understanding the Ca²⁺-dependent regulation of the PC2 channel by its cytosolic C-terminal domain. The improved methodology also serves as a good strategy to characterize other Ca²⁺-binding proteins.     

Ca-dependent binding of calcium-binding protein 1 to presynaptic group III metabotropic glutamate receptors and blockage by phosphorylation of the receptors

Presynaptic group III metabotropic glutamate receptors (mGluRs) and Ca²⁺ channels are the main neuronal activity-dependent regulators of synaptic vesicle release, and they use common molecules in their signaling cascades. Among these, calmodulin (CaM) and the related EF-hand Ca²⁺-binding proteins are of particular importance as sensors of presynaptic Ca²⁺, and a multiple of them are indeed utilized in the signaling of Ca²⁺ channels. However, despite its conserved structure, CaM is the only known EF-hand Ca²⁺-binding protein for signaling by presynaptic group III mGluRs. Because the mGluRs and Ca²⁺ channels reciprocally regulate each other and functionally converge on the regulation of synaptic vesicle release, the mGluRs would be expected to utilize more EF-hand Ca²⁺-binding proteins in their signaling. Here I show that calcium-binding protein 1 (CaBP1) bound to presynaptic group III mGluRs competitively with CaM in a Ca²⁺-dependent manner and that this binding was blocked by protein kinase C (PKC)-mediated phosphorylation of these receptors. As previously shown for CaM, these results indicate the importance of CaBP1 in signal cross talk at presynaptic group III mGluRs, which includes many molecules such as cAMP, Ca²⁺, PKC, G protein, and Munc18-1. However, because the functional diversity of EF-hand calcium-binding proteins is extraordinary, as exemplified by the regulation of Ca²⁺ channels, CaBP1 would provide a distinct way by which presynaptic group III mGluRs fine-tune synaptic transmission.     

Missense mutations affecting Ca2+-coordination in GCAP1 lead to cone-rod dystrophies by altering protein structural and functional properties

Guanylate cyclase activating protein 1 (GCAP1) is a neuronal calcium sensor (NCS) involved in the early biochemical steps underlying the phototransduction cascade. By switching from a Ca²⁺-bound form in the dark to a Mg²⁺-bound state following light activation of the cascade, GCAP1 triggers the activation of the retinal guanylate cyclase (GC), thus replenishing the levels of 3′,5′-cyclic monophosphate (cGMP) necessary to re-open CNG channels. Here, we investigated the structural and functional effects of three missense mutations in GCAP1 associated with cone-rod dystrophy, which severely perturb the homeostasis of cGMP and Ca²⁺. Substitutions affect residues directly involved in Ca²⁺ coordination in either EF3 (D100G) or EF4 (E155A and E155G) Ca²⁺ binding motifs. We found that all GCAP1 variants form relatively stable dimers showing decreased apparent affinity for Ca²⁺ and blocking the enzyme in a constitutively active state at physiological levels of Ca²⁺. Interestingly, by corroborating spectroscopic experiments with molecular dynamics simulations we show that beside local structural effects, mutation of the bidentate glutamate in an EF-hand calcium binding motif can profoundly perturb the flexibility of the adjacent EF-hand as well, ultimately destabilizing the whole domain. Therefore, while Ca²⁺-binding to GCAP1 per se occurs sequentially, allosteric effects may connect EF hand motifs, which appear to be essential for the integrity of the structural switch mechanism in GCAP1, and perhaps in other NCS proteins.     

Effects of Metal-Binding Properties of Human Kv Channel-Interacting Proteins on their Molecular Structure and Binding with Kv4.2 Channel

The goal of the present study is to explore whether Ca²⁺ and Mg²⁺-binding properties of isomeric Kv channel-interacting proteins (KChIPs) have different effects on their molecular structure and the binding with Kv channel. 8-Anilinonaphthalene- 1-sulfonate fluorescence measurement showed that KChIP4.1 and KChIP2.2 possessed one and two types of Ca²⁺-binding sites, respectively, and only one type of Mg²⁺-binding site was noted in the two KChIP proteins. Removal of EF-hand 4 (EF-4) caused a marked drop in their high affinities for Ca²⁺, but the binding affinity for Mg²⁺ remained mostly the same. Unlike KChIP4.1, the intact EF-4 was essential for the Kv channel-binding ability of KChIP2.2 in a metal-free buffer. Nevertheless, the interaction of wild-type KChIPs and EF-4-truncated mutants with Kv channel was enhanced by the addition of Mg²⁺ and Ca²⁺. In contrast to KChIP4.1, the thermal stability of KChIP2.2 was decreased by the binding of Mg²⁺ and Ca²⁺. These results suggest that the conformational change with metal-bound KChIP4.1 is crucial for its interaction with Kv channel but not for KChIP2.2, and that the Mg²⁺- and Ca²⁺-binding properties of KChIP2.2 and KChIP4.1 have different effects on their molecular structure.     

STIM proteins,Orai1, and gene expression

Cytoplasmic Ca²⁺ is an universal intracellular messenger that activates cellular responses over a broad temporal range, from neurotransmitter release to cell growth and proliferation.^1,2 Inherent to the use of the multifarious Ca²⁺ signal is the question of specificity: how can some Ca²⁺-dependent responses be activated in a cell and not others? A rise in cytoplasmic Ca²⁺ can evoke a response either by binding directly to the target (as occurs with certain Ca²⁺-activated K⁺ and Cl⁻ channels, for example) or through recruitment of intermediary proteins, such as calmodulin and troponin C. A substantial body of evidence has now established that Ca²⁺-binding proteins differ both in their affinities for Ca²⁺ and in their on- and off-rates for Ca²⁺ binding/unbinding. Furthermore, different Ca²⁺-binding proteins often occupy distinct locations within the cell. Therefore, the size, kinetics and spatial profile of a cytoplasmic Ca²⁺ signal are all important in determining which Ca²⁺-dependent response will be activated, when and for how long.³     

An update on fibrous flagellar roots in green algae

Summary In flagellate green algae two types of fibrous flagellar roots can be distinguished: system I fibres, cross-striated bundles of 2nm filaments (striation periodicity about 30 nm), which are associated with flagellar root microtubules, and system II fibres, contractile bundles of 4–8 nm filaments which are often cross-striated (striation periodicity variable but greater than 80 nm). The major protein of system II fibres is centrin, a Ca²⁺-modulated phosphoprotein, which is a member of the EF-hand protein family. The major protein of system I fibres (of severalChlamydomonas-type green algae) is a 34 kDa phosphoprotein, named assemblin. Because of the solubility characteristics of system I fibres and the properties of their major protein (paracrystal-formation in vitro, several isoelectric variants, heptad motifs in parts of the amino acid sequence), assemblin is presumably related to the k-m-e-f class of -helical fibrous proteins.Abbreviations NBBC nucleus-basal body connector - SMAC striated microtubule-associated component - k-m-e-f class keratin-myosin-elastin-fibrinogen class - EF-hand protein family Ca²⁺-binding proteins containing one to several Ca²⁺-binding motifs consisting of a peculiar helix-loop-helix configuration - PVDF polyvinyhdene difluoride     

Dissecting a regulatory calcium-binding site of CLC-K kidney chloride channels

The kidney and inner ear CLC-K chloride channels, which are involved in salt absorption and endolymph production, are regulated by extracellular Ca²⁺ in the millimolar concentration range. Recently, Gradogna et al. (2010. J. Gen. Physiol. http://dx.doi.org/10.1085/jgp.201010455) identified a pair of acidic residues (E261 and D278) located in the loop between helices I and J as forming a putative intersubunit Ca²⁺-binding site in hClC-Ka. In this study, we sought to explore the properties of the binding site in more detail. First, we verified that the site is conserved in hClC-Kb and rClC-K1. In addition, we could confer Ca²⁺ sensitivity to the Torpedo marmorata ClC-0 channel by exchanging its I–J loop with that from ClC-Ka, demonstrating a direct role of the loop in Ca²⁺ binding. Based on a structure of a bacterial CLC and a new sequence alignment, we built homology models of ClC-Ka. The models suggested additional amino acids involved in Ca²⁺ binding. Testing mutants of these residues, we could restrict the range of plausible models and positively identify two more residues (E259 and E281) involved in Ca²⁺ coordination. To investigate cation specificity, we applied extracellular Zn²⁺, Mg²⁺, Ba²⁺, Sr²⁺, and Mn²⁺. Zn²⁺ blocks ClC-Ka as well as its Ca²⁺-insensitive mutant, suggesting that Zn²⁺ binds to a different site. Mg²⁺ does not activate CLC-Ks, but the channels are activated by Ba²⁺, Sr²⁺, and Mn²⁺ with a rank order of potency of Ca²⁺ > Ba²⁺ > Sr²⁺ = Mn²⁺ for the human CLC-Ks. Dose–response analysis indicates that the less potent Ba²⁺ has a lower affinity rather than a lower efficacy. Interestingly, rClC-K1 shows an altered rank order (Ca²⁺ > Sr²⁺ >> Ba²⁺), but homology models suggest that residues outside the I–J loop are responsible for this difference. Our detailed characterization of the regulatory Ca²⁺-binding site provides a solid basis for the understanding of the physiological modulation of CLC-K channel function in the kidney and inner ear.     

The EF-hand Ca2+ Binding Domain Is Not Required for Cytosolic Ca2+ Activation of the Cardiac Ryanodine Receptor

Activation of the cardiac ryanodine receptor (RyR2) by elevating cytosolic Ca²⁺ is a central step in the process of Ca²⁺-induced Ca²⁺ release, but the molecular basis of RyR2 activation by cytosolic Ca²⁺ is poorly defined. It has been proposed recently that the putative Ca²⁺ binding domain encompassing a pair of EF-hand motifs (EF1 and EF2) in the skeletal muscle ryanodine receptor (RyR1) functions as a Ca²⁺ sensor that regulates the gating of RyR1. Although the role of the EF-hand domain in RyR1 function has been studied extensively, little is known about the functional significance of the corresponding EF-hand domain in RyR2. Here we investigate the effect of mutations in the EF-hand motifs on the Ca²⁺ activation of RyR2. We found that mutations in the EF-hand motifs or deletion of the entire EF-hand domain did not affect the Ca²⁺-dependent activation of [³H]ryanodine binding or the cytosolic Ca²⁺ activation of RyR2. On the other hand, deletion of the EF-hand domain markedly suppressed the luminal Ca²⁺ activation of RyR2 and spontaneous Ca²⁺ release in HEK293 cells during store Ca²⁺ overload or store overload-induced Ca²⁺ release (SOICR). Furthermore, mutations in the EF2 motif, but not EF1 motif, of RyR2 raised the threshold for SOICR termination, whereas deletion of the EF-hand domain of RyR2 increased both the activation and termination thresholds for SOICR. These results indicate that, although the EF-hand domain is not required for RyR2 activation by cytosolic Ca²⁺, it plays an important role in luminal Ca²⁺ activation and SOICR.     

Physiologically Relevant Free Ca2+ Ion Concentrations Regulate STRA6-Calmodulin Complex Formation via the BP2 Region of STRA6

The interaction of calmodulin (CaM) with the receptor for retinol uptake, STRA6, involves an α-helix termed BP2 that is located on the intracellular side of this homodimeric transporter (Chen et al., 2016 [1]). In the absence of Ca²⁺, NMR data showed that a peptide derived from BP2 bound to the C-terminal lobe (C-lobe) of Mg²⁺-bound CaM (^MgCaM). Upon titration of Ca²⁺ into ^MgCaM-BP2, NMR chemical shift perturbations (CSPs) were observed for residues in the C-lobe, including those in the EF-hand Ca²⁺-binding domains, EF3 and EF4 (^CaK_D = 60 ± 7 nM). As higher concentrations of free Ca²⁺ were achieved, CSPs occurred for residues in the N-terminal lobe (N-lobe) including those in EF1 and EF2 (^CaK_D = 1000 ± 160 nM). Thermodynamic and kinetic Ca²⁺ binding studies showed that BP2 addition increased the Ca²⁺-binding affinity of CaM and slowed its Ca²⁺ dissociation rates (k_off) in both the C- and N-lobe EF-hand domains, respectively. These data are consistent with BP2 binding to the C-lobe of CaM at low free Ca²⁺ concentrations (<100 nM) like those found at resting intracellular levels. As free Ca²⁺ levels approach 1000 nM, which is typical inside a cell upon an intracellular Ca²⁺-signaling event, BP2 is shown here to interact with both the N- and C-lobes of Ca²⁺-loaded CaM (^CaCaM-BP2). Because this structural rearrangement observed for the ^CaCaM-BP2 complex occurs as intracellular free Ca²⁺ concentrations approach those typical of a Ca²⁺-signaling event (^CaK_D = 1000 ± 160 nM), this conformational change could be relevant to vitamin A transport by full-length ^CaCaM-STRA6.