Moshe Giladi

Essential Role of the CBD1-CBD2 Linker in Slow Dissociation of Ca2+ from the Regulatory Two-domain Tandem of NCX1

In NCX proteins CBD1 and CBD2 domains are connected through a short linker (3 or 4 amino acids) forming a regulatory tandem (CBD12). Only three of the six CBD12 Ca2+-binding sites contribute to NCX regulation. Two of them are located on CBD1 (Kd = ∼0.2 μm), and one is on CBD2 (Kd = ∼5 μm). Here we analyze how the intrinsic properties of individual regulatory sites are affected by linker-dependent interactions in CBD12 (AD splice variant). The three sites of CBD12 and CBD1 + CBD2 have comparable Kd values but differ dramatically in their Ca2+ dissociation kinetics. CBD12 exhibits multiphasic kinetics for the dissociation of three Ca2+ ions (kr = 280 s−1, kf = 7 s−1, and ks = 0.4 s−1), whereas the dissociation of two Ca2+ ions from CBD1 (kf = 16 s−1) and one Ca2+ ion from CBD2 (kr = 125 s−1) is monophasic. Insertion of seven alanines into the linker (CBD12–7Ala) abolishes slow dissociation of Ca2+, whereas the kinetic and equilibrium properties of three Ca2+ sites of CBD12–7Ala and CBD1 + CBD2 are similar. Therefore, the linker-dependent interactions in CBD12 decelerate the Ca2+ on/off kinetics at a specific CBD1 site by 50–80-fold, thereby representing Ca2+ “occlusion” at CBD12. Notably, the kinetic and equilibrium properties of the remaining two sites of CBD12 are “linker-independent,” so their intrinsic properties are preserved in CBD12. In conclusion, the dynamic properties of three sites are specifically modified, conserved, diversified, and integrated by the linker in CBD12, thereby generating a wide range dynamic sensor.

Mitotic Spindle Disruption by Alternating Electric Fields Leads to Improper Chromosome Segregation and Mitotic Catastrophe in Cancer Cells

Tumor Treating Fields (TTFields) are low intensity, intermediate frequency, alternating electric fields. TTFields are a unique anti-mitotic treatment modality delivered in a continuous, noninvasive manner to the region of a tumor. It was previously postulated that by exerting directional forces on highly polar intracellular elements during mitosis, TTFields could disrupt the normal assembly of spindle microtubules. However there is limited evidence directly linking TTFields to an effect on microtubules. Here we report that TTFields decrease the ratio between polymerized and total tubulin, and prevent proper mitotic spindle assembly. The aberrant mitotic events induced by TTFields lead to abnormal chromosome segregation, cellular multinucleation, and caspase dependent apoptosis of daughter cells. The effect of TTFields on cell viability and clonogenic survival substantially depends upon the cell division rate. We show that by extending the duration of exposure to TTFields, slowly dividing cells can be affected to a similar extent as rapidly dividing cells.

Proton-sensing Ca2+ Binding Domains Regulate the Cardiac Na+/Ca2+ Exchanger

The cardiac Na+/Ca2+ exchanger (NCX) regulates cellular [Ca2+]i and plays a central role in health and disease, but its molecular regulation is poorly understood. Here we report on how protons affect this electrogenic transporter by modulating two critically important NCX C2 regulatory domains, Ca2+ binding domain-1 (CBD1) and CBD2. The NCX transport rate in intact cardiac ventricular myocytes was measured as a membrane current, INCX, whereas [H+]i was varied using an ammonium chloride “rebound” method at constant extracellular pH 7.4. At pHi = 7.2 and [Ca2+]i < 120 nm, INCX was less than 4% that of its maximally Ca2+-activated value. INCX increases steeply at [Ca2+]i between 130–150 nm with a Hill coefficient (nH) of 8.0 ± 0.7 and K0.5 = 310 ± 5 nm. At pHi = 6.87, the threshold of Ca2+-dependent activation of INCX was shifted to much higher [Ca2+]i (600–700 nm), and the relationship was similarly steep (nH = 8.0±0.8) with K0.5 = 1042 ± 15 nm. The Vmax of Ca2+-dependent activation of INCX was not significantly altered by low pHi. The Ca2+ affinities for CBD1 (0.39 ± 0.06 μm) and CBD2 (Kd = 18.4 ± 6 μm) were exquisitely sensitive to [H+], decreasing 1.3–2.3-fold as pHi decreased from 7.2 to 6.9. This work reveals for the first time that NCX can be switched off by physiologically relevant intracellular acidification and that this depends on the competitive binding of protons to its C2 regulatory domains CBD1 and CBD2.

An alternative pathway for reduced folate biosynthesis in bacteria and halophilic archaea

Whereas tetrahydrofolate is an essential cofactor in all bacteria, the gene that encodes the enzyme dihydrofolate reductase (DHFR) could not be identified in many of the bacteria whose genomes have been entirely sequenced. In this communication we show that the halophilic archaea Halobacterium salinarum and Haloarcula  marismortui  contain  genes  coding for proteins with an N‐terminal domain homologous to dihydrofolate synthase (FolC) and a C‐terminal domain homologous to dihydropteroate synthase (FolP). These genes are able to complement a Haloferax volcanii mutant that lacks DHFR. We also show that the Helicobacter pylori dihydropteroate synthase can complement an Escherichia coli mutant that lacks DHFR. Activity resides in an N‐terminal segment that is homologous to the polypeptide linker that connects the dihydrofolate synthase and dihydropteroate synthase domains in the haloarchaeal enzymes. The purified recombinant H. pylori dihydropteroate synthase was found to be a flavoprotein.

FolM, A New Chromosomally Encoded Dihydrofolate Reductase in Escherichia coli

Escherichia coli (thyA DeltafolA) mutants are viable and can grow in minimal medium when supplemented with thymidine alone. Here we present evidence from in vivo and in vitro studies that the ydgB gene determines an alternative dihydrofolate reductase that is related to the trypanosomatid pteridine reductases. We propose to rename this gene folM.

Sodium recognition by the Na+/Ca2+ exchanger in the outward-facing conformation.

Significance Na+/Ca2+ exchangers (NCXs) have a key role in the homeostasis of cellular Ca2+ and consequently are implicated in diverse human-health disorders, including neurodegenerative and cardiovascular diseases. A detailed understanding of the molecular mechanisms of these membrane proteins is therefore of interest from fundamental and biomedical standpoints. Here, we establish the structural mechanism of Na+ recognition in a prokaryotic NCX homolog, using atomistic molecular-dynamics simulations based on recently reported crystallographic data, as well as experimental transport assays of wild-type and mutagenized exchangers. The results have general implications pertaining to the ion exchange stoichiometry and electrogenicity of the Na+/Ca2+ transport cycle across the NCX family, and provide the basis for future investigations of the conformational mechanism of these important transporters. Na+/Ca2+ exchangers (NCXs) are ubiquitous membrane transporters with a key role in Ca2+ homeostasis and signaling. NCXs mediate the bidirectional translocation of either Na+ or Ca2+, and thus can catalyze uphill Ca2+ transport driven by a Na+ gradient, or vice versa. In a major breakthrough, a prokaryotic NCX homolog (NCX_Mj) was recently isolated and its crystal structure determined at atomic resolution. The structure revealed an intriguing architecture consisting of two inverted-topology repeats, each comprising five transmembrane helices. These repeats adopt asymmetric conformations, yielding an outward-facing occluded state. The crystal structure also revealed four putative ion-binding sites, but the occupancy and specificity thereof could not be conclusively established. Here, we use molecular-dynamics simulations and free-energy calculations to identify the ion configuration that best corresponds to the crystallographic data and that is also thermodynamically optimal. In this most probable configuration, three Na+ ions occupy the so-called Sext, SCa, and Sint sites, whereas the Smid site is occupied by one water molecule and one H+, which protonates an adjacent aspartate side chain (D240). Experimental measurements of Na+/Ca2+ and Ca2+/Ca2+ exchange by wild-type and mutagenized NCX_Mj confirm that transport of both Na+ and Ca2+ requires protonation of D240, and that this side chain does not coordinate either ion at Smid. These results imply that the ion exchange stoichiometry of NCX_Mj is 3:1 and that translocation of Na+ across the membrane is electrogenic, whereas transport of Ca2+ is not. Altogether, these findings provide the basis for further experimental and computational studies of the conformational mechanism of this exchanger.

A Common Ca2+-Driven Interdomain Module Governs Eukaryotic NCX Regulation

Na+/Ca2+ exchanger (NCX) proteins mediate Ca2+-fluxes across the cell membrane to maintain Ca2+ homeostasis in many cell types. Eukaryotic NCX contains Ca2+-binding regulatory domains, CBD1 and CBD2. Ca2+ binding to a primary sensor (Ca3-Ca4 sites) on CBD1 activates mammalian NCXs, whereas CALX, a Drosophila NCX ortholog, displays an inhibitory response to regulatory Ca2+. To further elucidate the underlying regulatory mechanisms, we determined the 2.7 Å crystal structure of mammalian CBD12-E454K, a two-domain construct that retains wild-type properties. In conjunction with stopped-flow kinetics and SAXS (small-angle X-ray scattering) analyses of CBD12 mutants, we show that Ca2+ binding to Ca3-Ca4 sites tethers the domains via a network of interdomain salt-bridges. This Ca2+-driven interdomain switch controls slow dissociation of “occluded” Ca2+ from the primary sensor and thus dictates Ca2+ sensing dynamics. In the Ca2+-bound conformation, the interdomain angle of CBD12 is very similar in NCX and CALX, meaning that the interdomain distances cannot account for regulatory diversity in NCX and CALX. Since the two-domain interface is nearly identical among eukaryotic NCXs, including CALX, we suggest that the Ca2+-driven interdomain switch described here represents a general mechanism for initial conduction of regulatory signals in NCX variants.

KCNQ1 Channels Do Not Undergo Concerted but Sequential Gating Transitions in Both the Absence and the Presence of KCNE1 Protein

Background: The gating mechanisms of KCNQ1 channels are poorly understood. Results: A thermodynamic mutant cycle analysis indicates that each subunit produces an incremental contribution to channel gating. Conclusion: KCNQ1 channels do not undergo concerted but sequential gating transitions in both the absence and the presence of KCNE1. Significance: Contrary to Shaker channels, KCNQ1 channel gating is not concerted and weakly cooperative. The co-assembly of KCNQ1 with KCNE1 produces IKS, a K+ current, crucial for the repolarization of the cardiac action potential. Mutations in these channel subunits lead to life-threatening cardiac arrhythmias. However, very little is known about the gating mechanisms underlying KCNQ1 channel activation. Shaker channels have provided a powerful tool to establish the basic gating mechanisms of voltage-dependent K+ channels, implying prior independent movement of all four voltage sensor domains (VSDs) followed by channel opening via a last concerted cooperative transition. To determine the nature of KCNQ1 channel gating, we performed a thermodynamic mutant cycle analysis by constructing a concatenated tetrameric KCNQ1 channel and by introducing separately a gain and a loss of function mutation, R231W and R243W, respectively, into the S4 helix of the VSD of one, two, three, and four subunits. The R231W mutation destabilizes channel closure and produces constitutively open channels, whereas the R243W mutation disrupts channel opening solely in the presence of KCNE1 by right-shifting the voltage dependence of activation. The linearity of the relationship between the shift in the voltage dependence of activation and the number of mutated subunits points to an independence of VSD movements, with each subunit incrementally contributing to channel gating. Contrary to Shaker channels, our work indicates that KCNQ1 channels do not experience a late cooperative concerted opening transition. Our data suggest that KCNQ1 channels in both the absence and the presence of KCNE1 undergo sequential gating transitions leading to channel opening even before all VSDs have moved.

Structural Features of Ion Transport and Allosteric Regulation in Sodium-Calcium Exchanger (NCX) Proteins

Na+/Ca2+ exchanger (NCX) proteins extrude Ca2+ from the cell to maintain cellular homeostasis. Since NCX proteins contribute to numerous physiological and pathophysiological events, their pharmacological targeting has been desired for a long time. This intervention remains challenging owing to our poor understanding of the underlying structure-dynamic mechanisms. Recent structural studies have shed light on the structure-function relationships underlying the ion-transport and allosteric regulation of NCX. The crystal structure of an archaeal NCX (NCX_Mj) along with molecular dynamics simulations and ion flux analyses, have assigned the ion binding sites for 3Na+ and 1Ca2+, which are being transported in separate steps. In contrast with NCX_Mj, eukaryotic NCXs contain the regulatory Ca2+-binding domains, CBD1 and CBD2, which affect the membrane embedded ion-transport domains over a distance of ~80 Å. The Ca2+-dependent regulation is ortholog, isoform, and splice-variant dependent to meet physiological requirements, exhibiting either a positive, negative, or no response to regulatory Ca2+. The crystal structures of the two-domain (CBD12) tandem have revealed a common mechanism involving a Ca2+-driven tethering of CBDs in diverse NCX variants. However, dissociation kinetics of occluded Ca2+ (entrapped at the two-domain interface) depends on the alternative-splicing segment (at CBD2), thereby representing splicing-dependent dynamic coupling of CBDs. The HDX-MS, SAXS, NMR, FRET, equilibrium 45Ca2+ binding and stopped-flow techniques provided insights into the dynamic mechanisms of CBDs. Ca2+ binding to CBD1 results in a population shift, where more constraint conformational states become highly populated without global conformational changes in the alignment of CBDs. This mechanism is common among NCXs. Recent HDX-MS studies have demonstrated that the apo CBD1 and CBD2 are stabilized by interacting with each other, while Ca2+ binding to CBD1 rigidifies local backbone segments of CBD2, but not of CBD1. The extent and strength of Ca2+-dependent rigidification at CBD2 is splice-variant dependent, showing clear correlations with phenotypes of matching NCX variants. Therefore, diverse NCX variants share a common mechanism for the initial decoding of the regulatory signal upon Ca2+ binding at the interface of CBDs, whereas the allosteric message is shaped by CBD2, the dynamic features of which are dictated by the splicing segment.

Population Shift Underlies Ca2+-induced Regulatory Transitions in the Sodium-Calcium Exchanger (NCX)

Background: Ca2+ binding to the regulatory two-domain tandem (CBD12) activates ion transport in NCX. Results: Ca2+ binding to high affinity sites of CBD12 results in a population shift, where more constraint conformational states become highly populated. Conclusion: Ca2+-induced population shift governs NCX activation with no significant contribution of global conformational changes in CBD alignment. Significance: Population shift may represent a general mechanism for regulating NCX. In eukaryotic Na+/Ca2+ exchangers (NCX) the Ca2+ binding CBD1 and CBD2 domains form a two-domain regulatory tandem (CBD12). An allosteric Ca2+ sensor (Ca3–Ca4 sites) is located on CBD1, whereas CBD2 contains a splice-variant segment. Recently, a Ca2+-driven interdomain switch has been described, albeit how it couples Ca2+ binding with signal propagation remains unclear. To resolve the dynamic features of Ca2+-induced conformational transitions we analyze here distinct splice variants and mutants of isolated CBD12 at varying temperatures by using small angle x-ray scattering (SAXS) and equilibrium 45Ca2+ binding assays. The ensemble optimization method SAXS analysis demonstrates that the apo and Mg2+-bound forms of CBD12 are highly flexible, whereas Ca2+ binding to the Ca3–Ca4 sites results in a population shift of conformational landscape to more rigidified states. Population shift occurs even under conditions in which no effect of Ca2+ is observed on the globally derived Dmax (maximal interatomic distance), although under comparable conditions a normal [Ca2+]-dependent allosteric regulation occurs. Low affinity sites (Ca1–Ca2) of CBD1 do not contribute to Ca2+-induced population shift, but the occupancy of these sites by 1 mm Mg2+ shifts the Ca2+ affinity (Kd) at the neighboring Ca3–Ca4 sites from ∼ 50 nm to ∼ 200 nm and thus, keeps the primary Ca2+ sensor (Ca3–Ca4 sites) within a physiological range. Thus, Ca2+ binding to the Ca3–Ca4 sites results in a population shift, where more constraint conformational states become highly populated at dynamic equilibrium in the absence of global conformational transitions in CBD alignment.