Role of cytosolic free calcium in the reorientation of pollen tube growth

Growing pollen tubes of Agapanthus umbellatus exhibited a tip-to-base gradient in cytosolic free calcium ([Ca²⁺]_c). Although this gradient is believed to be involved in pollen tube growth, its role in specifying reorientation is unknown. The direction of pollen tube growth could be modified by iontophoretic micro-injection, electrical fields (EFs) or photolysis of caged Ca²⁺. Iontophoretic injection resulted in a temporary cessation of growth, an increase in [Ca²⁺]_c and, upon recovery, reoriented growth. Weak EFs also elevated [Ca²⁺]_c, reduced growth rates and resulted in the reorientation of pollen tubes towards the cathode. Treatment with very low concentrations of the Ca²⁺-channel blocker lanthanum chloride, prior to exposure to an EF, inhibited both the increase in [Ca²⁺]_c and reorientation whilst only slightly affecting growth rates. The responses of growth inhibition and reorientation were mimicked when [Ca²⁺]_c was artificially elevated by photoactivating caged Ca²⁺ (Nitr-5). Our data suggest that [Ca²⁺]_c is part of a transduction mechanism which enables growing pollen tubes to successfully reorient to directional signals in the style and thus accomplish eventual fertilization of the egg.     

Neuronal galvanotropism is independent of external Ca2+ entry or internal Ca2+ gradients

The mechanism by which growing neurites sense and respond to small applied electrical fields is not known, but there is some evidence that the entry of Ca²⁺ from the external medium, with the subsequent formation of intracellular Ca²⁺ gradients, is important in this process. We have employed two approaches to test this idea. Xenopus spinal neurites were exposed to electrical fields in a culture medium in which Ca²⁺ was chelated to very low levels compared to the normal extracellular concentration of 2 mM. In other experiments, loading the neurites with the calcium buffer, 1,2‐bis(o‐aminophenoxy)ethane‐N,N,N′,N′‐tetraacetic acid (BAPTA), disrupted the putative internal Ca²⁺ gradients, and the effects on the electrical response were determined. Fields of 100 mV/mm were applied for 12 h, and no difference was detected in the cathodal turning response between the treated neurites and the untreated controls. Using the Differential Growth Index (DGI), an asymmetry index, to quantitate the turning response, we recorded DGIs of −0.64, −0.65, and −0.62 for control cells, cells in Ca²⁺‐free medium, and cells preloaded with BAPTA, respectively. Furthermore, we detected an increase in neurite length for those neurons cultured in Ca²⁺‐free medium; they were 1.5–1.7 times as long as neurites from neurons cultured in normal Ca²⁺ medium. Likewise, we found that BAPTA‐loaded neurites were longer than control neurites. Our data indicate that neuronal galvanotropism is independent of the entry of external Ca²⁺ or of internal Ca²⁺ gradients. Both cell‐permeant agonistic and antagonistic analogs of cyclic 3′,5′‐adenosine monophosphate (cAMP) increased the response to applied electrical fields. © 2000 John Wiley & Sons, Inc. J Neurobiol 45: 30–38, 2000     

Tuning sperm chemotaxis by calcium burst timing

Marine invertebrate oocytes establish chemoattractant gradients that guide spermatozoa towards their source. In sea urchin spermatozoa, this relocation requires coordinated motility changes initiated by Ca²⁺-driven alterations in sperm flagellar curvature. We discovered that Lytechinus pictus spermatozoa undergo chemotaxis in response to speract, an egg-derived decapeptide previously noted to stimulate non-chemotactic motility alterations in Strongylocentrotus purpuratus spermatozoa. Sperm of both species responded to speract gradients with a sequence of turning episodes that correlate with transient flagellar Ca²⁺ increases, yet only L. pictus spermatozoa accumulated at the gradient source. Detailed analysis of sperm behavior revealed that L. pictus spermatozoa selectively undergo Ca²⁺ fluctuations while swimming along negative speract gradients while S. purpuratus sperm generate Ca²⁺ fluctuations in a spatially non-selective manner. This difference is attributed to the selective suppression of Ca²⁺ fluctuations of L. pictus spermatozoa as they swim towards the source of the chemoattractant gradient. This is the first study to compare and characterize the motility components that differ in chemotactic and non-chemotactic spermatozoa. Tuning of Ca²⁺ fluctuations and associated turning episodes to the chemoattractant gradient polarity is a central feature of sea urchin sperm chemotaxis and may be a feature of sperm chemotaxis in general.     

The formation of Ca<Superscript>2+</Superscript> gradients at the cleavage furrows during cytokinesis of Zebrafish embryos

In dividing embryos, a localized elevation in intracellular Ca²⁺ ([Ca²⁺]_i) at the cleavage furrow has been shown to be essential for cytokinesis. However, the underlying mechanisms for generating and maintaining these [Ca²⁺]_i gradients throughout cytokinesis are not fully understood. In the present study, we analyzed the role of inositol 1,4,5-trisphosphate receptors (IP₃Rs) and endoplasmic reticulum (ER) distribution in determining the intracellular Ca²⁺ gradients in early zebrafish blastomeres. Application of the injected Ca²⁺ indicator, Indo-1, showed that during the first cell division a standing Ca²⁺ gradient was formed ∼35 min after fertilization, with the [Ca²⁺]_i spatially decaying from 500–600 nmol/L at the cleavage furrow to 100–200 nmol/L around the nucleus. While the IP3R immunohistochemical fluorescence was relatively concentrated in the peri-furrow region, ER labeling was relatively enriched in both peri-furrow and peri-nuclear regions. Numeric simulation suggested that a divergence in the spatial distribution of IP3R and the locations of Ca²⁺ uptake within the ER was essential for the formation of a standing Ca²⁺ gradient, and the Ca²⁺ gradient could only be well-established under an optimal stoichiometry of Ca²⁺ uptake and release. Indeed, while inhibition of IP3R Ca²⁺ release blocked the generation of the Ca²⁺ gradient at a lower [Ca²⁺]_i level, both Ca²⁺ release stimulation by inositol 1,4,5-trisphosphate (IP3) injection and ER Ca²⁺ pump inhibition by cyclopiazonic acid also eliminated the Ca²⁺ gradients at higher [Ca²⁺]_i levels. Our results suggest a dynamic relationship between ER-mediated Ca²⁺ release and uptake that underlies the maintenance of the perifurrow Ca²⁺ gradient and is essential for cytokinesis of zebrafish embryos.     

Calcium Signaling Network in Plants: An Overview

Calcium ion (Ca²⁺) is one of the very important ubiquitous intracellular second messenger molecules involved in many signal transduction pathways in plants. The cytosolic free Ca²⁺ concentration ([Ca²⁺]_cyt) have been found to increased in response to many physiological stimuli such as light, touch, pathogenic elicitor, plant hormones and abiotic stresses including high salinity, cold and drought. This Ca²⁺ spikes normally result from two opposing reactions, Ca²⁺ influx through channels or Ca²⁺ efflux through pumps. The removal of Ca²⁺ from the cytosol against its electrochemical gradient to either the apoplast or to intracellular organelles requires energized ‘active’ transport. Ca²⁺-ATPases and H⁺/Ca²⁺ antiporters are the key proteins catalyzing this movement. The increased level of Ca²⁺ is recognised by some Ca²⁺-sensors or calcium-binding proteins, which can activate many calcium dependent protein kinases. These kinases regulate the function of many genes including stress responsive genes, resulted in the phenotypic response of stress tolerance. Calcium signaling is also involved in the regulation of cell cycle progression in response to abiotic stress. The regulation of gene expression by cellular calcium is also crucial for plant defense against various stresses. However, the number of genes known to respond to specific transient calcium signals is limited. This review article describes several aspects of calcium signaling such as Ca²⁺ requiremant and its role in plants, Ca²⁺ transporters, Ca²⁺-ATPases, H⁺/ Ca²⁺-antiporter, Ca²⁺-signature, Ca²⁺-memory and various Ca²⁺-binding proteins (with and without EF hand).Key Words: Calcium binding proteins, Ca²⁺ channel, Ca²⁺-dependent protein kinases, Ca²⁺/H⁺ antiport, calcium memory, calcium sensors, calcium signatures, Ca²⁺-transporters, EF hand motifs, plant signal transduction     

Differential contribution of EF-hands to the Ca²⁺-dependent activation in the plant two-pore channel TPC1

Two‐pore channels (TPC) have been established as components of calcium signalling networks in plants and animals. In plants, TPC1 in the vacuolar membrane is gated open upon binding of calcium in a voltage‐dependent manner. Here, we analyzed the molecular mechanism of the Ca²⁺‐dependent activity of TPC1 from Arabidopsis thaliana, using site‐directed mutagenesis of its two canonical EF‐hands. Wild‐type TPC1 and TPC1‐D335A with a mutated first Ca²⁺ ligand in EF‐hand 1 produced channels that retained their voltage‐ and Ca²⁺‐dependent gating characteristics, but were less sensitive at Ca²⁺ concentrations <200 μm . Additional mutation of the first Ca²⁺ ligand in EF‐hand 2 resulted in silent TPC1‐D335A/D376A channels. Similarly, the single mutant TPC1‐D376A could not be activated up to 1 mm Ca²⁺, indicating that the second EF‐hand is essential for the Ca²⁺‐dependent channel gating. Molecular modeling suggests that EF‐hand 1 displays a low‐affinity Ca²⁺/Mg²⁺‐binding site, while EF‐hand 2 represents a high‐affinity Ca²⁺‐binding site. Together, our data prove that EF‐hand 2 is responsible for the Ca²⁺‐receptor characteristics of TPC1, while EF‐hand 1 is a structural site required to enable channel responses at physiological changes in Ca²⁺ concentration.     

Variations in transmembrane Ca2+ gradient and apoptosis of macrophages induced by oxidized low density lipoprotein

While Ca²⁺ has been proposed to be a messenger in OxLDL-induced cell death, few studies have addressed the possibility that it may influence the occurrence of apoptosis and necrosis of macrophages induced by OxLDL in virtue of change of transmembrane Ca²⁺ gradient including that across plasma membrane and intracellular organelle membranes. In this paper, various lipophilic Ca²⁺ fluorescent indicators and specific organelle markers were used to study the relationship between the changes of the transmembrane Ca²⁺ gradients and the OxLDL induced apoptosis of macrophages. Our results showed that following exposure of low dose OxLDL to macrophages, the transmembrane Ca²⁺ gradient across the plasma membrane, as well as the membrane-proximal Ca²⁺ gradient, the transnuclear, and the transmitochondrial membrane Ca²⁺ gradient were all changed significantly. These data suggested that changes in transmembrane Ca²⁺ gradients might be involved in the apoptosis of macrophages induced by OxLDL.     

Nuclear magnetic resonance structure of calcium-binding protein 1 in a Ca(2+) -bound closed state: Implications for target recognition

Calcium‐binding protein 1 (CaBP1), a neuron‐specific member of the calmodulin (CaM) superfamily, regulates the Ca²⁺‐dependent activity of inositol 1,4,5‐triphosphate receptors (InsP3Rs) and various voltage‐gated Ca²⁺ channels. Here, we present the NMR structure of full‐length CaBP1 with Ca²⁺ bound at the first, third, and fourth EF‐hands. A total of 1250 nuclear Overhauser effect distance measurements and 70 residual dipolar coupling restraints define the overall main chain structure with a root‐mean‐squared deviation of 0.54 Å (N‐domain) and 0.48 Å (C‐domain). The first 18 residues from the N‐terminus in CaBP1 (located upstream of the first EF‐hand) are structurally disordered and solvent exposed. The Ca²⁺‐saturated CaBP1 structure contains two independent domains separated by a flexible central linker similar to that in calmodulin and troponin C. The N‐domain structure of CaBP1 contains two EF‐hands (EF1 and EF2), both in a closed conformation [interhelical angles = 129° (EF1) and 142° (EF2)]. The C‐domain contains EF3 and EF4 in the familiar Ca²⁺‐bound open conformation [interhelical angles = 105° (EF3) and 91° (EF4)]. Surprisingly, the N‐domain adopts the same closed conformation in the presence or absence of Ca²⁺ bound at EF1. The Ca²⁺‐bound closed conformation of EF1 is reminiscent of Ca²⁺‐bound EF‐hands in a closed conformation found in cardiac troponin C and calpain. We propose that the Ca²⁺‐bound closed conformation of EF1 in CaBP1 might undergo an induced‐fit opening only in the presence of a specific target protein, and thus may help explain the highly specialized target binding by CaBP1.     

Temporal sampling,resetting, and adaptation orchestrate gradient sensing in sperm

Sperm, navigating in a chemical gradient, are exposed to a periodic stream of chemoattractant molecules. The periodic stimulation entrains Ca²⁺ oscillations that control looping steering responses. It is not known how sperm sample chemoattractant molecules during periodic stimulation and adjust their sensitivity. We report that sea urchin sperm sampled molecules for 0.2–0.6 s before a Ca²⁺ response was produced. Additional molecules delivered during a Ca²⁺ response reset the cell by causing a pronounced Ca²⁺ drop that terminated the response; this reset was followed by a new Ca²⁺ rise. After stimulation, sperm adapted their sensitivity following the Weber–Fechner law. Taking into account the single-molecule sensitivity, we estimate that sperm can register a minimal gradient of 0.8 fM/µm and be attracted from as far away as 4.7 mm. Many microorganisms sense stimulus gradients along periodic paths to translate a spatial distribution of the stimulus into a temporal pattern of the cell response. Orchestration of temporal sampling, resetting, and adaptation might control gradient sensing in such organisms as well.     

Ca2+ binding to F‐ATP synthase β subunit triggers the mitochondrial permeability transition

F‐ATP synthases convert the electrochemical energy of the H⁺ gradient into the chemical energy of ATP with remarkable efficiency. Mitochondrial F‐ATP synthases can also undergo a Ca²⁺‐dependent transformation to form channels with properties matching those of the permeability transition pore (PTP), a key player in cell death. The Ca²⁺ binding site and the mechanism(s) through which Ca²⁺ can transform the energy‐conserving enzyme into a dissipative structure promoting cell death remain unknown. Through in vitro, in vivo and in silico studies we (i) pinpoint the “Ca²⁺‐trigger site” of the PTP to the catalytic site of the F‐ATP synthase β subunit and (ii) define a conformational change that propagates from the catalytic site through OSCP and the lateral stalk to the inner membrane. T163S mutants of the β subunit, which show a selective decrease in Ca²⁺‐ATP hydrolysis, confer resistance to Ca²⁺‐induced, PTP‐dependent death in cells and developing zebrafish embryos. These findings are a major advance in the molecular definition of the transition of F‐ATP synthase to a channel and of its role in cell death.     

The Epidermal Ca Gradient: Measurement Using the Phasor Representation of Fluorescent Lifetime Imaging

Ionic gradients are found across a variety of tissues and organs. In this report, we apply the phasor representation of fluorescence lifetime imaging data to the quantitative study of ionic concentrations in tissues, overcoming technical problems of tissue thickness, concentration artifacts of ion-sensitive dyes, and calibration across inhomogeneous tissue. We used epidermis as a model system, as Ca²⁺ gradients in this organ have been shown previously to control essential biologic processes of differentiation and formation of the epidermal permeability barrier. The approach described here allowed much better localization of Ca²⁺ stores than those used in previous studies, and revealed that the bulk of free Ca²⁺ measured in the epidermis comes from intracellular Ca²⁺ stores such as the Golgi and the endoplasmic reticulum, with extracellular Ca²⁺ making a relatively small contribution to the epidermal Ca²⁺ gradient. Due to the high spatial resolution of two-photon microscopy, we were able to measure a marked heterogeneity in average calcium concentrations from cell to cell in the basal keratinocytes. This finding, not reported in previous studies, calls into question the long-held hypothesis that keratinocytes increase intracellular Ca²⁺, cease proliferation, and differentiate passively in response to changes in extracellular Ca²⁺. The experimental results obtained using this approach illustrate the power of the experimental and analytical techniques outlined in this report. Our approach can be used in mechanistic studies to address the formation, maintenance, and function of the epidermal Ca²⁺ gradient, and it should be broadly applicable to the study of other tissues with ionic gradients.     

Making sense out of Ca2+ signals: their role in regulating stomatal movements

Plant cells maintain high Ca²⁺ concentration gradients between the cytosol and the extracellular matrix, as well as intracellular compartments. During evolution, the regulatory mechanisms, maintaining low cytosolic free Ca²⁺ concentrations, most likely provided the backbone for the development of Ca²⁺‐dependent signalling pathways. In this review, the current understanding of molecular mechanisms involved in Ca²⁺ homeostasis of plants cells is evaluated. The question is addressed to which extent the mechanisms, controlling the cytosolic Ca²⁺ concentration, are linked to Ca²⁺‐based signalling. A large number of environmental stimuli can evoke Ca²⁺ signals, but the Ca²⁺‐induced responses are likely to differ depending on the stimulus applied. Two mechanisms are put forward to explain signal specificity of Ca²⁺‐dependent responses. A signal may evoke a specific Ca²⁺ signature that is recognized by downstream signalling components. Alternatively, Ca²⁺ signals are accompanied by Ca²⁺‐independent signalling events that determine the specificity of the response. The existence of such parallel‐acting pathways explains why guard cell responses to abscisic acid (ABA) can occur in the absence, as well as in the presence, of Ca²⁺ signals. Future research may shed new light on the relation between parallel acting Ca²⁺‐dependent and ‐independent events, and may provide insights in their evolutionary origin.     

Characterization of Two EF‐hand Domain‐containing Proteins from Toxoplasma gondii

The universal role of calcium (Ca²⁺) as a second messenger in cells depends on a large number of Ca²⁺‐binding proteins (CBP), which are able to bind Ca²⁺ through specific domains. Many CBPs share a type of Ca²⁺‐binding domain known as the EF‐hand. The EF‐hand motif has been well studied and consists of a helix‐loop‐helix structural domain with specific amino acids in the loop region that interact with Ca²⁺. In Toxoplasma gondii a large number of genes (approximately 68) are predicted to have at least one EF‐hand motif. The majority of these genes have not been characterized. We report the characterization of two EF‐hand motif‐containing proteins, TgGT1_216620 and TgGT1_280480, which localize to the plasma membrane and to the rhoptry bulb, respectively. Genetic disruption of these genes by CRISPR (clustered regularly interspaced short palindromic repeats)/Cas9 (CRISPR‐associated protein 9) resulted in mutant parasite clones (Δtg216620 and Δtg280480) that grew at a slower rate than control cells. Ca²⁺ measurements showed that Δtg216620 cells did not respond to extracellular Ca²⁺ as the parental controls while Δtg280480 cells appeared to respond as the parental cells. Our hypothesis is that TgGT1_216620 is important for Ca²⁺ influx while TgGT1_280480 may be playing a different role in the rhoptries.     

Coordination structures of Mg2+ and Ca2+ in three types of tobacco calmodulins in solution: Fourier‐transform infrared spectroscopic studies of side‐chain COO− groups

Calmodulin (CaM) is a Ca²⁺‐binding protein that regulates a number of fundamental cellular activities. Nicotiana tabacum CaM (NtCaM) comprises 13 genes classified into three types, among which gene expression and target enzyme activation differ. We performed Fourier‐transform infrared spectroscopy to compare the secondary and coordination structures of Mg²⁺ and Ca²⁺ among NtCaM1, NtCaM3, and NtCaM13 as representatives of the three types of NtCaMs. Data suggested that NtCaM13 has a different secondary structure due to the weak β‐strand bands and the weak 1661 cm^?1 band. Coordination structures of Mg²⁺ of NtCaM3 and NtCaM13 were similar but different from that of NtCaM1, while the Ca²⁺‐binding manner was similar among the three CaMs. The amplitude differences of the band at 1554–1550 cm^?1 obtained by second‐derivative spectra indicated that the intensity change of the band of NtCaM13 was smaller in response to [Ca²⁺] increases under low [Ca²⁺] conditions than were those of NtCaM1 and NtCaM3, while the intensity reached the same level under high [Ca²⁺]. Therefore, NtCaM13 has a characteristic secondary structure and specific Mg²⁺‐binding manner and needs higher [Ca²⁺] for bidentate Ca²⁺ coordination of 12th Glu in EF‐hand motifs. The Ca²⁺‐binding mechanisms of the EF‐hand motifs of the three CaMs are similar; however, the cation‐dependent conformational change in NtCaM13 is unique among the three NtCaMs. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 472–483, 2013.     

High‐affinity cooperative Ca2+ binding by MICU1–MICU2 serves as an on–off switch for the uniporter

The mitochondrial calcium uniporter is a Ca²⁺‐activated Ca²⁺ channel that is essential for dynamic modulation of mitochondrial function in response to cellular Ca²⁺ signals. It is regulated by two paralogous EF‐hand proteins—MICU1 and MICU2, but the mechanism is unknown. Here, we demonstrate that both MICU1 and MICU2 are stabilized by Ca²⁺. We reconstitute the MICU1–MICU2 heterodimer and demonstrate that it binds Ca²⁺ cooperatively with high affinity. We discover that both MICU1 and MICU2 exhibit affinity for the mitochondria‐specific lipid cardiolipin. We determine the minimum Ca²⁺ concentration required for disinhibition of the uniporter in permeabilized cells and report a close match with the Ca²⁺‐binding affinity of MICU1–MICU2. We conclude that cooperative, high‐affinity interaction of the MICU1–MICU2 complex with Ca²⁺ serves as an on–off switch, leading to a tightly controlled channel, capable of responding directly to cytosolic Ca²⁺ signals.     

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.     

Ion channel clustering enhances weak electric field detection by neutrophils: apparent roles of SKF96365-sensitive cation channels and myeloperoxidase trafficking in cellular responses

We have tested Galvanovskis and Sandblom’s prediction that ion channel clustering enhances weak electric field detection by cells as well as how the elicited signals couple to metabolic alterations. Electric field application was timed to coincide with certain known intracellular chemical oscillators (phase-matched conditions). Polarized, but not spherical, neutrophils labeled with anti-K_v1.3, FL-DHP, and anti-TRP1, but not anti-T-type Ca²⁺ channels, displayed clusters at the lamellipodium. Resonance energy transfer experiments showed that these channel pairs were in close proximity. Dose-field sensitivity studies of channel blockers suggested that K⁺ and Ca²⁺ channels participate in field detection, as judged by enhanced oscillatory NAD(P)H amplitudes. Further studies suggested that K⁺ channel blockers act by reducing the neutrophil’s membrane potential. Mibefradil and SKF93635, which block T-type Ca²⁺ channels and SOCs, respectively, affected field detection at appropriate doses. Microfluorometry and high-speed imaging of indo-1-labeled neutrophils was used to examine Ca²⁺ signaling. Electric fields enhanced Ca²⁺ spike amplitude and triggered formation of a second traveling Ca²⁺ wave. Mibefradil blocked Ca²⁺ spikes and waves. Although 10 μM SKF96365 mimicked mibefradil, 7 μM SKF96365 specifically inhibited electric field-induced Ca²⁺ signals, suggesting that one SKF96365-senstive site is influenced by electric fields. Although cells remained morphologically polarized, ion channel clusters at the lamellipodium and electric field sensitivity were inhibited by methyl-β-cyclodextrin. As a result of phase-matched electric field application in the presence of ion channel clusters, myeloperoxidase (MPO) was found to traffic to the cell surface. As MPO participates in high amplitude metabolic oscillations, this suggests a link between the signaling apparatus and metabolic changes. Furthermore, electric field effects could be blocked by MPO inhibition or removal while certain electric field effects were mimicked by the addition of MPO to untreated cells. Therefore, channel clustering plays an important role in electric field detection and downstream responses of morphologically polarized neutrophils. In addition to providing new mechanistic insights concerning electric field interactions with cells, our work suggests novel methods to remotely manipulate physiological pathways.     

Multiple cyclic nucleotide‐gated channels coordinate calcium oscillations and polar growth of root hairs

Calcium gradients underlie polarization in eukaryotic cells. In plants, a tip‐focused Ca²⁺‐gradient is fundamental for rapid and unidirectional cell expansion during epidermal root hair development. Here we report that three members of the cyclic nucleotide‐gated channel family are required to maintain cytosolic Ca²⁺ oscillations and the normal growth of root hairs. CNGC6, CNGC9 and CNGC14 were expressed in root hairs, with CNGC9 displaying the highest root hair specificity. In individual channel mutants, morphological defects including root hair swelling and branching, as well as bursting, were observed. The developmental phenotypes were amplified in the three cngc double mutant combinations. Finally, cngc6/9/14 triple mutants only developed bulging trichoblasts and could not form normal root hair protrusions because they burst after the transition to the rapid growth phase. Prior to developmental defects, single and double mutants showed increasingly disturbed patterns of Ca²⁺ oscillations. We conclude that CNGC6, CNGC9 and CNGC14 fulfill partially but not fully redundant functions in generating and maintaining tip‐focused Ca²⁺ oscillations, which are fundamental for proper root hair growth and polarity. Furthermore, the results suggest that these calmodulin‐binding and Ca²⁺‐permeable channels organize a robust tip‐focused oscillatory calcium gradient, which is not essential for root hair initiation but is required to control the integrity of the root hair after the transition to the rapid growth phase. Our findings also show that root hairs possess a large ability to compensate calcium‐signaling defects, and add new players to the regulatory network, which coordinates cell wall properties and cell expansion during polar root hair growth.     

Crystal structure of the trimeric N‐terminal domain of ciliate Euplotes octocarinatus centrin binding with calcium ions

Centrin is a member of the EF‐hand superfamily of calcium‐binding proteins, a highly conserved eukaryotic protein that binds to Ca²⁺. Its self‐assembly plays a causative role in the fiber contraction that is associated with the cell division cycle and ciliogenesis. In this study, the crystal structure of N‐terminal domain of ciliate Euplotes octocarinatus centrin (N‐EoCen) was determined by using the selenomethionine single‐wavelength anomalous dispersion method. The protein molecules formed homotrimers. Every protomer had two putative Ca²⁺ ion‐binding sites I and II, protomer A, and C bound one Ca²⁺ ion, while protomer B bound two Ca²⁺ ions. A novel binding site III was observed and the Ca²⁺ ion was located at the center of the homotrimer. Several hydrogen bonds, electrostatic, and hydrophobic interactions between the protomers contributed to the formation of the oligomer. Structural studies provided insight into the foundation for centrin aggregation and the roles of calcium ions.     

MICU1 and MICU2 play nonredundant roles in the regulation of the mitochondrial calcium uniporter

The mitochondrial uniporter is a selective Ca²⁺ channel regulated by MICU1, an EF hand‐containing protein in the organelle's intermembrane space. MICU1 physically associates with and is co‐expressed with a paralog, MICU2. To clarify the function of MICU1 and its relationship to MICU2, we used gene knockout (KO) technology. We report that HEK‐293T cells lacking MICU1 or MICU2 lose a normal threshold for Ca²⁺ intake, extending the known gating function of MICU1 to MICU2. Expression of MICU1 or MICU2 mutants lacking functional Ca²⁺‐binding sites leads to a striking loss of Ca²⁺ uptake, suggesting that MICU1/2 disinhibit the channel in response to a threshold rise in [Ca²⁺]. MICU2's activity and physical association with the pore require the presence of MICU1, though the converse is not true. We conclude that MICU1 and MICU2 are nonredundant and together set the [Ca²⁺] threshold for uniporter activity.