The interaction of CaM7 and CNGC14 regulates root hair growth in Arabidopsis

Oscillations in cytosolic free calcium determine the polarity of tip‐growing root hairs. The Ca²⁺ channel cyclic nucleotide gated channel 14 (CNGC14) contributes to the dynamic changes in Ca²⁺ concentration gradient at the root hair tip. However, the mechanisms that regulate CNGC14 are unknown. In this study, we detected a direct interaction between calmodulin 7 (CaM7) and CNGC14 through yeast two‐hybrid and bimolecular fluorescence complementation assays. We demonstrated that the third EF‐hand domain of CaM7 specifically interacts with the cytosolic C‐terminal domain of CNGC14. A two‐electrode voltage clamp assay showed that CaM7 completely inhibits CNGC14‐mediated Ca²⁺ influx, suggesting that CaM7 negatively regulates CNGC14‐mediated calcium signaling. Furthermore, CaM7 overexpressing lines phenocopy the short root hair phenotype of a cngc14 mutant and this phenotype is insensitive to changes in external Ca²⁺ concentrations. We, thus, identified CaM7‐CNGC14 as a novel interacting module that regulates polar growth in root hairs by controlling the tip‐focused Ca²⁺ signal.     

Characterisation of a novel gene family of putative cyclic nucleotide- and calmodulin-regulated ion channels in Arabidopsis thaliana

In plants, cyclic GMP is involved in signal transduction in response to light and gibberellic acid. For cyclic AMP, a potential role during the plant cell cycle was recently reported. However, cellular targets for cyclic nucleotides in plants are largely unknown. Here we report on the identification and characterisation of a new gene family in Arabidopsis, which share features with cyclic nucleotide-gated channels from animals and inward-rectifying K⁺ channels from plants. The identified gene family comprises six members (Arabidopsis thaliana cyclic nucleotide-gated channels, AtCNGC1–6) with significant homology among the deduced proteins. Hydrophobicity analysis predicted six membrane-spanning domains flanked by hydrophilic amino and carboxy termini. A putative cyclic nucleotide binding domain (CNBD) which contains several residues that are invariant in other CNBDs was located in the carboxy terminus. This domain overlaps with a predicted calmodulin (CaM) binding site, suggesting interaction between cyclic nucleotide and CaM regulation. We demonstrated interaction of the carboxy termini of AtCNGC1 and AtCNGC2 with CaM in yeast, indicating that the CaM binding sites are functional. Furthermore, it was shown that both AtCNGC1 and AtCNGC2 can partly complement the K⁺-uptake-deficient yeast mutant CY162. Therefore, we propose that the identified genes constitute a family of plant cyclic nucleotide- and CaM-regulated ion channels.     

cAMP activates hyperpolarization-activated Ca2+ channels in the pollen of Pyrus pyrifolia

Many signal-transduction processes in plant cells have been suggested to be triggered by signal-induced opening of calcium ion (Ca²⁺) channels in the plasma membrane. Cyclic nucleotides have been proposed to lead to an increase in cytosolic free Ca²⁺ in pollen. However, direct recordings of cyclic-nucleotide-induced Ca²⁺ currents in pollen have not yet been obtained. Here, we report that cyclic AMP (cAMP) activated a hyperpolarization-activated Ca²⁺ channel in the Pyrus pyrifolia pollen tube using the patch-clamp technique, which resulted in a significant increase in pollen tube protoplast cytosolic-Ca²⁺ concentration. Outside-out single channel configuration identified that cAMP directly increased the Ca²⁺ channel open-probability without affecting channel conductance. cAMP-induced currents were composed of both Ca²⁺ and K⁺. However, cGMP failed to mimic the cAMP effect. Higher cytosolic free-Ca²⁺ concentration significantly decreased the cAMP-induced currents. These results provide direct evidence for cAMP activation of hyperpolarization-activated Ca²⁺ channels in the plasma membrane of pollen tubes, which, in turn, modulate cellular responses in regulation of pollen tube growth.     

Resonance assignments of the nucleotide-free wildtype MloK1 cyclic nucleotide-binding domain

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels play crucial roles in neuronal excitability and signal transduction of sensory cells. These channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide-binding domain (CNBD). A comparison of the structures of wildtype ligand-free and ligand-bound CNBD is essential to elucidate the mechanism underlying nucleotide-dependent activation of CNBDs. We recently reported the solution structure of the Mesorhizobium loti K1 (MloK1) channel CNBD in complex with cAMP. We have now extended these studies and achieved nearly complete assignments of ¹H, ¹³C and ¹⁵N resonances of the nucleotide-free CNBD. A completely new assignment of the nucleotide-free wildtype CNBD was necessary due to the sizable chemical shift differences as compared to the cAMP bound CNBD and the slow exchange behaviour between both forms. Scattering of these chemical shift differences over the complete CNBD suggests that nucleotide binding induces significant overall conformational changes.     

Solution structure of the Mesorhizobium loti K1 channel cyclic nucleotide‐binding domain in complex with cAMP

Cyclic nucleotide‐sensitive ion channels, known as HCN and CNG channels, are crucial in neuronal excitability and signal transduction of sensory cells. HCN and CNG channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide‐binding domain (CNBD). However, the mechanism by which the binding of cyclic nucleotides opens these channels is not well understood. Here, we report the solution structure of the isolated CNBD of a cyclic nucleotide‐sensitive K⁺ channel from Mesorhizobium loti. The protein consists of a wide anti‐parallel β‐roll topped by a helical bundle comprising five α‐helices and a short 3₁₀‐helix. In contrast to the dimeric arrangement (‘dimer‐of‐dimers’) in the crystal structure, the solution structure clearly shows a monomeric fold. The monomeric structure of the CNBD supports the hypothesis that the CNBDs transmit the binding signal to the channel pore independently of each other.     

Resonance assignments and secondary structure of calmodulin in complex with its target sequence in rat olfactory cyclic nucleotide-gated ion channel

Calmodulin (CaM), the primary receptor for intracellular Ca²⁺, regulates a large number of key enzymes and controls a wide spectrum of important biological responses. Olfactory cyclic nucleotide-gated ion channels (OLF channels) mediate olfactory transduction in olfactory receptor neurons. The opening of OLF leads to a rise in cytosolic concentration of Ca²⁺, upon binding to Ca²⁺, CaM disrupts the open conformation by binding to the CaM-binding domain in the N-terminal region and triggers the close mechanism. In order to unravel the regulatory role of CaM from structural point of view, NMR techniques were used to characterize the structure of CaM in association with the CaM binding domain of rat OLF channel (OLFp, 28 residues). Our data indicated that two distinct CaM/OLFp complexes existed simultaneously with stable structures that were not inter-exchangeable within the NMR time scale. Here, we report the full backbone and side chain resonance assignments of these two complexes of CaM/OLFp.     

External Cd2+ and protons activate the hyperpolarization-gated K+ channel KAT1 at the voltage sensor

The functionally diverse cyclic nucleotide binding domain (CNBD) superfamily of cation channels contains both depolarization-gated (e.g., metazoan EAG family K⁺ channels) and hyperpolarization-gated channels (e.g., metazoan HCN pacemaker cation channels and the plant K⁺ channel KAT1). In both types of CNBD channels, the S4 transmembrane helix of the voltage sensor domain (VSD) moves outward in response to depolarization. This movement opens depolarization-gated channels and closes hyperpolarization-gated channels. External divalent cations and protons prevent or slow movement of S4 by binding to a cluster of acidic charges on the S2 and S3 transmembrane domains of the VSD and therefore inhibit activation of EAG family channels. However, a similar divalent ion/proton binding pocket has not been described for hyperpolarization-gated CNBD family channels. We examined the effects of external Cd²⁺ and protons on Arabidopsis thaliana KAT1 expressed in Xenopus oocytes and found that these ions strongly potentiate voltage activation. Cd²⁺ at 300 µM depolarizes the V₅₀ of KAT1 by 150 mV, while acidification from pH 7.0 to 4.0 depolarizes the V₅₀ by 49 mV. Regulation of KAT1 by Cd²⁺ is state dependent and consistent with Cd²⁺ binding to an S4-down state of the VSD. Neutralization of a conserved acidic charge in the S2 helix in KAT1 (D95N) eliminates Cd²⁺ and pH sensitivity. Conversely, introduction of acidic residues into KAT1 at additional S2 and S3 cluster positions that are charged in EAG family channels (N99D and Q149E in KAT1) decreases Cd²⁺ sensitivity and increases proton potentiation. These results suggest that KAT1, and presumably other hyperpolarization-gated plant CNBD channels, can open from an S4-down VSD conformation homologous to the divalent/proton-inhibited conformation of EAG family K⁺ channels.     

Cyclic Nucleotide Gated Channels and Ca2+-Mediated Signal Transduction During Plant Innate Immune Response to Pathogens

Transitory perturbations in the level of cytosolic Ca²⁺ are well known to be involved in numerous cell signaling pathways in both plant and animal systems. However, not much is known at present about the molecular identity of plant plasma membrane Ca²⁺ conducting ion channels or their specific roles in signal transduction cascades. A recent study employing genetic approaches as well as patch clamp electrophysiological analysis of channel currents has provided the first such direct evidence linking a specific gene product with inward Ca²⁺ currents across the plant cell membrane. This work identified Ca²⁺ permeation through (Arabidopsis) cyclic nucleotide gated channel isoform 2 (CNGC2) as contributing to the plant innate immunity signaling cascade initiated upon perception of a pathogen. Here, we expand on the implications of CNGC2 mediated cytosolic Ca²⁺ elevations associated with plant cell response to pathogen recognition, and propose some additional steps that may be involved in the innate immunity signal cascade.Key Words: calcium, CNGC, hypersensitive response, nitric oxide, plant innate immunity, plant ion channel, reactive oxygen species     

Analysis of the cyclic nucleotide binding domain of the HERG potassium channel and interactions with KCNE2

Mutations in the cyclic nucleotide binding domain (CNBD) of the human ether-a-go-go-related gene (HERG) K+ channel are associated with LQT2, a form of hereditary Long QT syndrome (LQTS). Elevation of cAMP can modulate HERG K+ channels both by direct binding and indirect regulation through protein kinase A. To assess the physiological significance of cAMP binding to HERG, we introduced mutations to disrupt the cyclic nucleotide binding domain. Eight mutants including two naturally occurring LQT2 mutants V822M and R823W were constructed. Relative cAMP binding capacity was reduced or absent in CNBD mutants. Mutant homotetramers carry little or no K+ current despite normal protein abundance and surface expression. Co-expression of mutant and wild-type HERG resulted in currents with altered voltage dependence but without dominant current suppression. The data from co-expression of V822M and wild-type HERG best fit a model where one normal subunit within a tetramer allows nearly normal current expression. The presence of KCNE2, an accessory protein that associates with HERG, however, conferred a partially dominant current suppression by CNBD mutants. Thus KCNE2 plays a pivotal role in determining the phenotypic severity of some forms of LQT2, which suggests that the CNBD of HERG may be involved in its interaction with KCNE2.     

A heat-activated calcium-permeable channel--Arabidopsis cyclic nucleotide-gated ion channel 6--is involved in heat shock responses

An increased concentration of cytosolic calcium ions (Ca²⁺) is an early response by plant cells to heat shock. However, the molecular mechanism underlying the heat‐induced initial Ca²⁺ response in plants is unclear. In this study, we identified and characterized a heat‐activated Ca²⁺‐permeable channel in the plasma membrane of Arabidopsis thaliana root protoplasts using reverse genetic analysis and the whole‐cell patch‐clamp technique. The results indicated that A. thaliana cyclic nucleotide‐gated ion channel 6 (CNGC6) mediates heat‐induced Ca²⁺ influx and facilitates expression of heat shock protein (HSP) genes and the acquisition of thermotolerance. GUS and GFP reporter assays showed that CNGC6 expression is ubiquitous in A. thaliana, and the protein is localized to the plasma membrane of cells. Furthermore, it was found that the level of cytosolic cAMP was increased by a mild heat shock, that CNGC6 was activated by cytosolic cAMP, and that exogenous cAMP promoted the expression of HSP genes. The results reveal the role of cAMP in transduction of heat shock signals in plants. The correlation of an increased level of cytosolic cAMP in a heat‐shocked plant with activation of the Ca²⁺ channels and downstream expression of HSP genes sheds some light on how plants transduce a heat stimulus into a signal cascade that leads to a heat shock response.     

Calmodulin Regulates Ca2+-sensing Receptor-mediated Ca2+ Signaling and Its Cell Surface Expression

The Ca²⁺-sensing receptor (CaSR) is a member of family C of the GPCRs responsible for sensing extracellular Ca²⁺ ([Ca²⁺]_o) levels, maintaining extracellular Ca²⁺ homeostasis, and transducing Ca²⁺ signaling from the extracellular milieu to the intracellular environment. In the present study, we have demonstrated a Ca²⁺-dependent, stoichiometric interaction between CaM and a CaM-binding domain (CaMBD) located within the C terminus of CaSR (residues 871–898). Our studies suggest a wrapping around 1–14-like mode of interaction that involves global conformational changes in both lobes of CaM with concomitant formation of a helical structure in the CaMBD. More importantly, the Ca²⁺-dependent association between CaM and the C terminus of CaSR is critical for maintaining proper responsiveness of intracellular Ca²⁺ responses to changes in extracellular Ca²⁺ and regulating cell surface expression of the receptor.     

植物环核苷酸门控离子通道及其功能研究进展

环核苷酸门控离子通道(CNGC)是非选择性的阳离子通道, 可以直接被细胞内信使小分子——环核苷酸(cAMP和cGMP)活化。该通道蛋白包含6个跨膜α-螺旋, C端各具一个交叠的环核苷酸与钙调蛋白结合区。CNGC广泛存在于各种植物细胞中。研究表明, 模式植物拟南芥(Arabidopsis thaliana)的CNGC家族有20个成员, 分为4个亚群, 它们在抗病、花粉管生长、对Ca²⁺响应、抵抗重金属离子毒害和抗盐等多种信号途径中发挥重要作用, 协助植物细胞应对各种生物与非生物胁迫。该文简要介绍了CNGC的结构、表达谱及其调控因子, 并着重总结了近年来CNGC生物学功能的研究进展, 以期为今后系统开展其功能研究提供理论依据。     

Importance of the interaction protein–protein of the CaM–PDE1A and CaM–MLCK complexes in the development of new anti‐CaM drugs

Protein–protein interactions play central roles in physiological and pathological processes. The bases of the mechanisms of drug action are relevant to the discovery of new therapeutic targets. This work focuses on understanding the interactions in protein–protein–ligands complexes, using proteins calmodulin (CaM), human calcium/calmodulin‐dependent 3′,5′‐cyclic nucleotide phosphodiesterase 1A active human (PDE1A), and myosin light chain kinase (MLCK) and ligands αII–spectrin peptide (αII–spec), and two inhibitors of CaM (chlorpromazine (CPZ) and malbrancheamide (MBC)). The interaction was monitored with a fluorescent biosensor of CaM (hCaM M124C–mBBr). The results showed changes in the affinity of CPZ and MBC depending on the CaM–protein complex under analysis. For the Ca²⁺–CaM, Ca²⁺–CaM–PDE1A, and Ca²⁺–CaM–MLCK complexes, CPZ apparent dissociation constants (K_ds) were 1.11, 0.28, and 0.55 μM, respectively; and for MBC K_ds were 1.43, 1.10, and 0.61 μM, respectively. In competition experiments the addition of calmodulin binding peptide 1 (αII–spec) to Ca²⁺–hCaM M124C–mBBr quenched the fluorescence (K_d = 2.55 ± 1.75 pM) and the later addition of MBC (up to 16 μM) did not affect the fluorescent signal. Instead, the additions of αII–spec to a preformed Ca²⁺–hCaM M124C–mBBr–MBC complex modified the fluorescent signal. However, MBC was able to displace the PDE1A and MLCK from its complex with Ca²⁺–CaM. In addition, docking studies were performed for all complexes with both ligands showing an excellent correlation with experimental data. These experiments may help to explain why in vivo many CaM drugs target prefer only a subset of the Ca²⁺–CaM regulated proteins and adds to the understanding of molecular interactions between protein complexes and small ligands. Copyright © 2013 John Wiley & Sons, Ltd.     

NMR analysis of free and lipid nanodisc anchored CEACAM1 membrane proximal peptides with Ca2+/CaM

CEACAM1, a homotypic transmembrane receptor with 12 or 72 amino acid cytosolic domain isoforms, is converted from inactive cis-dimers to active trans-dimers by calcium-calmodulin (Ca²⁺/CaM). Previously, the weak binding of Ca²⁺/CaM to the human 12 AA cytosolic domain was studied using C-terminal anchored peptides. We now show the binding of ¹⁵N labeled Phe-454 cytosolic domain peptides in solution or membrane anchored using NMR demonstrates a significant role for the lipid bilayer. Although binding is increased by the mutation Phe454Ala, this mutation was previously shown to abrogate actin binding. On the other hand, Ca²⁺/CaM binding is abrogated by phosphorylation of nearby Thr-457, a post-translation modification required for actin binding and subsequent in vitro lumen formation. Binding of Ca²⁺/CaM to a membrane proximal peptide from the long 72 AA cytosolic domain anchored to lipid nanodiscs was very weak compared to lipid free conditions, suggesting membrane specific effects between the two isoforms. NMR analysis of ¹⁵N labeled Ca²⁺/CaM with unlabeled peptides showed the C-lobe of Ca²⁺/CaM is involved in peptide interactions, and hydrophobic residues such as Met-109, Val-142 and Met-144 play important roles in binding peptide. This information was incorporated into transmembrane models of CEACAM1 binding to Ca²⁺/CaM. The lack of Ca²⁺/CaM binding to phosphorylated Thr-457, a residue we have previously shown to be phosphorylated by CaMK2D, also dependent on Ca²⁺/CaM, suggests stepwise binding of the cytosolic domain first to Ca²⁺/CaM and then to actin.     

Structural Studies of Soybean Calmodulin Isoform 4 Bound to the Calmodulin-binding Domain of Tobacco Mitogen-activated Protein Kinase Phosphatase-1 Provide Insights into a Sequential Target Binding Mode

The calcium regulatory protein calmodulin (CaM) binds in a calcium-dependent manner to numerous target proteins. The calmodulin-binding domain (CaMBD) region of Nicotiana tabacum MAPK phosphatase has an amino acid sequence that does not resemble the CaMBD of any other known Ca²⁺-CaM-binding proteins. Using a unique fusion protein strategy, we have been able to obtain a high resolution solution structure of the complex of soybean Ca²⁺-CaM4 (SCaM4) and this CaMBD. Complete isotope labeling of both parts of the complex in the fusion protein greatly facilitated the structure determination by NMR. The 12-residue CaMBD region was found to bind exclusively to the C-lobe of SCaM4. A specific Trp and Leu side chain are utilized to facilitate strong binding through a novel “double anchor” motif. Moreover, the orientation of the helical peptide on the surface of Ca²⁺-SCaM4 is distinct from other known complexes. The N-lobe of Ca²⁺-SCaM4 in the complex remains free for additional interactions and could possibly act as a calcium-dependent adapter protein. Signaling through the MAPK pathway and increases in intracellular Ca²⁺ are both hallmarks of the plant stress response, and our data support the notion that coordination of these responses may occur through the formation of a unique CaM-MAPK phosphatase multiprotein complex.Calmodulin (CaM)² is a ubiquitous intracellular Ca²⁺ sensor protein that plays an essential role in various Ca²⁺ signaling pathways. Contiguous and unique CaM-binding domain (CaMBD) regions are found widely distributed in many different types of CaM target proteins including protein phosphatases and kinases, cytoskeletal proteins, ion channels, and pumps (1, 2). Even though the CaMBD from various proteins share relatively poor amino acid sequence similarity, the majority of CaMBD become α-helical upon binding to CaM, and they can be grouped into either the 1-5-10 or the 1-8-14 motif, where the first and the last number indicate the position of two hydrophobic anchor residues that attach the CaMBD to the two binding pockets of the bilobal Ca²⁺-CaM. However, several noncanonical classes of CaMBD have also been identified. For example, in the CaMBD of the MARCKS protein, the two anchor residues are separated by a single amino acid residue (3). On the other hand, in the recently determined crystal structure of Ca²⁺-CaM complexed with the CaMBD of the skeletal muscle ryanodine receptor RYR1, they are separated by 15 residues (1–17 motif) (4). Bulky hydrophobic side chains of residues such as Trp, Leu, Phe, and Ile are most commonly utilized as anchor residues (see Fig. 1a), and these are usually deeply inserted into the hydrophobic target-binding pocket of either the N- or C-lobe of Ca²⁺-CaM. However, in several cases, including the N-methyl-d-aspartate receptors (NMDAR) (5) and the voltage-gated Ca²⁺ channels (Cav1–2) (6, 7), a polar side chain from Thr or Tyr has also been found to act as an anchor residue. In almost all Ca²⁺-CaM complexes studied to date, the two lobes of Ca²⁺-CaM become collapsed on the helical CaMBD, and they form a globular complex structure. An exception was found in the case of the Ca²⁺-CaM complex with an incomplete CaMBD from the plasma membrane Ca²⁺ pump (C20W), where only the C-lobe of Ca²⁺-CaM binds to the CaMBD, and the N-lobe was free in solution (8). The versatility of CaM target protein binding has been discussed in many recent reviews (for example, Refs. 2, 9–11).Open in a separate windowFIGURE 1.a, amino acid sequences of CaMBD from tobacco NtMKP1 (residues 438–449), Arabidopsis AtMKP1 (residues 451–462), and rice OsMKP1 (residues 456–467) are compared with various CaMBDs. The sequences are aligned at the position of the first hydrophobic anchor residue. The hydrophobic anchor residues are colored in red, while the other hydrophobic residues are shown in green. The basic residues and acidic residues are colored in cyan and pink, respectively. The residue numbers of the NtMKP1 sequence in SCaM4-NtMKP1/NtMKP1 protein are also indicated. b, schematic drawing of the two fusion proteins, SCaM4-NtMKP1 and SCaM4CT-NtMKP1.In plant cells, Ca²⁺ signals, arising from various extracellular stimuli such as abiotic stresses, hormones, or phytopathogens are mediated by multiple CaM isoforms to create specific cellular responses. In contrast, only a single CaM protein exists in animal cells. For example, the model plant Arabidopsis thaliana has nine CaM genes (CaM1–9) encoding seven different CaM isoforms (12, 13). Five distinct CaM genes (SCaM1–5) encoding four different CaM proteins have been identified so far in the soybean genome (14). Despite the relatively high amino acid sequence identity among these CaM isoforms (50–90%), each isoform is utilized to regulate different target enzymes related to specific cellular responses (15, 16). For example, the expression of two soybean CaM isoforms, SCaM4 and 5 is markedly up-regulated after pathogen infection, and these two proteins can activate the enzyme nitric-oxide synthase (NOS) (17). Production of nitric oxide is thought to be one of the early events in the plant defense reactions (18, 19). On the other hand, SCaM1 is incapable of activation of the NOS enzyme, and it does in fact act as a competitive inhibitor. Likewise, in Nicotiana tabacum (tobacco), the CaM isoforms NtCaM1 and NtCaM13 are overexpressed in tobacco leaf tissue in response to wounding and the TMV-triggered hypersensitive reaction, respectively (20). Recently, we have addressed the question as to how distinct CaM isoforms can give rise to selectivity in their target regulation by determining the solution structures of the two soybean CaM isoforms, SCaM1 and SCaM4 (21). However, there are currently no structures available for plant CaM isoforms in a complex with a target CaMBD peptide, although many such complex structures have been determined for animal CaM. Therefore, determining the structure of plant CaM-target complexes and uncovering their unique features relative to those of animal CaM or other plant CaM isoforms will undoubtedly enhance our understanding of the CaM-target regulation mechanisms in plants and mammals.The mitogen-activated protein kinase cascade (MAPK cascade) is an important signal transduction pathway in animals, yeast as well as in plants (22). The activity of MAPK is regulated via phosphorylation by its immediate upstream regulator, MAPK kinase (MAPKK). Following activation, MAPKs are dephosphorylated and inactivated by MAPK phosphatases. Recently, the MAPK phosphatase from tobacco (NtMKP1) was shown to be a novel plant-specific CaM-binding protein (23). This finding indicated a possible link between the MAPK cascade and Ca²⁺ signaling pathways in plant cells. The MAPK cascade is thought to play an important role in plant defense signaling, and the accumulation of Ca²⁺ in plant cells is also a well-known response to pathogens and other stresses (for recent reviews, see Refs. 24, 25). The putative CaMBD reported for NtMKP1 (residues 396–447) is located directly upstream of the conserved Ser-rich domain in the middle of the protein. Mutagenesis studies have revealed that Trp⁴⁴⁰ and Leu⁴⁴³ are indispensable for Ca²⁺-CaM binding. More recently, we have tested various truncated versions of the CaMBD of NtMKP1 and narrowed it down to 12 residues (residues 438–449) (Fig. 1a) that are sufficient for Ca²⁺-CaM binding (26). Interestingly, the NtMKP1 CaMBD does not belong to any of the typical CaM-binding motif classes. Binding assays using isothermal titration calorimetry (ITC) as well as NMR titration studies for various SCaM isoforms, and their half-lobe fragments have revealed a novel sequential target binding mechanism for the Ca²⁺-CaM isoforms. The first strong binding event involves the C-lobe of Ca²⁺-CaM and the reported binding constant for NtMKP1 peptide was 10⁷–10⁸ m⁻¹. On the other hand, the binding of a second CaMBD of NtMKP1 occurs only through the N-lobe of Ca²⁺-CaM, and the binding constant was around 10⁵ m⁻¹ (26). To date, structural information about the manner in which Ca²⁺-CaM binds sequentially to the unusual amino acid sequence of the CaMBD of NtMKP1 is unavailable. Here, we have determined the solution NMR structure of the C-lobe fragment of SCaM4 (SCaM4CT) fused with the CaMBD of NtMKP1 (Fig. 1b). We have chosen SCaM4 over other SCaM isoforms, as the stress-induced SCaM4 would provide a more important connection between stress MAPK response and Ca²⁺ signaling. The interaction of the α-helical CaMBD of NtMKP1 with SCaM4CT domain is stabilized by hydrophobic interactions mainly through Trp⁴⁴⁰ and Leu⁴⁴³ in the NtMKP1 sequence. Moreover, the basic residue, Arg⁴⁴⁴ that is unusual at position 5 (Fig. 1a) stays outside of the hydrophobic patch, and it seems to form a unique hydrogen bond to Glu⁸⁴ of the SCaM4CT domain. The resulting orientation of the α-helical CaMBD relative to the SCaM4CT domain is therefore very different from those seen in the other previously reported Ca²⁺-CaM-target complexes. We have also studied binding of a synthetic CaMBD peptide to intact Ca²⁺-SCaM4 fused at the C-terminal end with the CaMBD of NtMKP1 (Fig. 1b) providing additional information about the role of the N-lobe of Ca²⁺-SCaM4 in NtMKP1 binding. Furthermore, we have studied the interactions between the N-lobe of Ca²⁺-SCaM4 and a second potential CaMBD in the C-terminal region of NtMKP1.     

Oligomerization and Ca2+/calmodulin control binding of the ER Ca2+-sensors STIM1 and STIM2 to plasma membrane lipids

Ca²⁺ (calcium) homoeostasis and signalling rely on physical contacts between Ca²⁺ sensors in the ER (endoplasmic reticulum) and Ca²⁺ channels in the PM (plasma membrane). STIM1 (stromal interaction molecule 1) and STIM2 Ca²⁺ sensors oligomerize upon Ca²⁺ depletion in the ER lumen, contact phosphoinositides at the PM via their cytosolic lysine (K)-rich domains, and activate Ca²⁺ channels. Differential sensitivities of STIM1 and STIM2 towards ER luminal Ca²⁺ have been studied but responses towards elevated cytosolic Ca²⁺ concentration and the mechanism of lipid binding remain unclear. We found that tetramerization of the STIM1 K-rich domain is necessary for efficient binding to PI(4,5)P₂-containing PM-like liposomes consistent with an oligomerization-driven STIM1 activation. In contrast, dimerization of STIM2 K-rich domain was sufficient for lipid binding. Furthermore, the K-rich domain of STIM2, but not of STIM1, forms an amphipathic α-helix. These distinct features of the STIM2 K-rich domain cause an increased affinity for PI(4,5)P₂, consistent with the lower activation threshold of STIM2 and a function as regulator of basal Ca²⁺ levels. Concomitant with higher affinity for PM lipids, binding of CaM (calmodulin) inhibited the interaction of the STIM2 K-rich domain with liposomes in a Ca²⁺ and PI(4,5)P₂ concentration-dependent manner. Therefore we suggest that elevated cytosolic Ca²⁺ concentration down-regulates STIM2-mediated ER–PM contacts via CaM binding.     

Calmodulin regulation of the calcium-leak channel Sec61 is unique to vertebrates

In eukaryotes, protein transport into the endoplasmic reticulum (ER) is facilitated by a protein-conducting channel, the Sec61 complex. The presence of large, water-filled pores with uncontrolled ion permeability, such as those formed by Sec61 complexes in the ER membrane, would interfere with the regulated release of calcium from the ER lumen into the cytosol, an essential mechanism of intracellular signaling. We identified a calmodulin (CaM) binding motif in the cytosolic N-terminus of Sec61α from Canis familiaris that binds CaM, but not Ca²⁺-free apo-CaM, with nanomolar affinity and sequence specificity. In single channel lipid bilayer measurements, CaM potently mediated Sec61-channel closure in a Ca²⁺-dependent manner. No functional CaM binding motif was identified in the corresponding region of Sec61p from Saccharomyces cerevisiae, and no channel closure occurred in the presence of CaM and Ca²⁺. Therefore, CaM binding to the cytosolic N-terminus of Sec61α is involved in limiting Ca²⁺-leakage from the ER in C. familiaris but not S. cerevisiae.     

Principles of Calcium Signal Generation and Transduction in Plant Cells

Calcium ions exhibit unique properties and a universal ability to transmit diverse signals in plant cells under the primary action of hormones, pathogens, light, gravity, and various abiotic stressors. In the last few years, considerable progress has been achieved in deciphering the mechanisms of Ca²⁺ involvement in the regulation of plant responses. Recent studies revealed the genes encoding Ca²⁺-permeable channels that conduct Ca²⁺ currents across the membranes during the transduction of the Ca²⁺ signal. These proteins comprise the ligand-gated Ca²⁺-permeable channels activated by cyclic nucleotides (CNGC) and amino acids (glutamate receptor-like channels, GLR), the voltage-gated tonoplast channel (two-pore channel, TPC1), mechanosensitive channels (MSL, MCA, OSCA1), and annexins. The role of Ca²⁺-ATPase and Ca²⁺/H⁺-exchangers in the active extrusion of excess cytoplasmic Ca²⁺ into the apoplast or cell organelles was examined in detail. The calmodulins (CaM), CaM-like proteins (CML), Ca²⁺-dependent protein kinases (CDPK), and complexes of calcineurin-B-like proteins (CBL) with CBL-interacting protein kinases (CIPK) were found to produce intricate signaling networks that decode Ca²⁺ signals and elicit plant responses to external stimuli. This review analyzes the data accumulated over the past decade on the principles of formation and propagation of the calcium signal in plant cells.