Veratridine binding to a transmembrane helix of sodium channel Nav1.4 determined by solid-state NMR.

The multi-step ligand action to a target protein is an important aspect when understanding mechanisms of ligand binding and discovering new drugs. However, structurally capturing such complex mechanisms is challenging. This is particularly true for interactions between large membrane proteins and small molecules. One such large membrane of interest is Nav1.4, a eukaryotic voltage-gated sodium channel. Domain 4 segment 6 (D4S6) of Nav1.4 is a transmembrane α-helical segment playing a key role in channel gating regulation, and is targeted by a neurotoxin, veratridine (VTD). VTD has been suggested to exhibit a two-step action to activate Nav1.4. Here, we determine the NMR structure of a selectively 13C-labeled peptide corresponding to D4S6 and its VTD binding site in lipid bilayers determined by using magic-angle spinning solid-state NMR. By 13C NMR, we obtain NMR structural constraints as 13C chemical shifts and the 1H-2H dipolar couplings between the peptide and deuterated lipids. The peptide backbone structure and its location with respect to the membrane are determined under the obtained NMR structural constraints aided by replica exchange molecular dynamics simulations with an implicit membrane/solvent system. Further, by measuring the 1H-2H dipolar couplings to monitor the peptide-lipid interaction, we identify a VTD binding site on D4S6. When superimposed to a crystal structure of a bacterial sodium channel NavRh, the determined binding site is the only surface exposed to the protein exterior and localizes beside the second-step binding site reported in the past. Based on these results, we propose that VTD initially binds to these newly-determined residues on D4S6 from the membrane hydrophobic domain, which induces the first-step channel opening followed by the second-step blocking of channel inactivation of Nav1.4. Our findings provide new detailed insights of the VTD action mechanism, which could be useful in designing new drugs targeting D4S6.

Simple and accurate single base resolution analysis of 5-hydroxymethylcytosine by catalytic oxidative bisulfite sequencing using micelle incarcerated oxidants.

Oxidation of 5-methylcytosine (5mC) is catalyzed by ten-eleven translocation (TET) enzymes to produce 5-hydroxymethylcytosine (5hmC) and following oxidative products. The oxidized nucleotides were shown to be the intermediates for DNA demethylation, as the nucleotides are removed by base excision repair system initiated by thymine DNA glycosylase. A simple and accurate method to determine initial oxidation product 5hmC at single base resolution in genomic DNA is necessary to understand demethylation mechanism. Recently, we have developed a new catalytic oxidation reaction using micelle-incarcerated oxidants to oxidize 5hmC to form 5-formylcytosine (5fC), and subsequent bisulfite sequencing can determine the positions of 5hmC in DNA. In the present study, we described the optimization of the catalytic oxidative bisulfite sequencing (coBS-seq), and its application to the analysis of 5hmC in genomic DNA at single base resolution in a quantitative manner. As the oxidation step showed quite low damage on genomic DNA, the method allows us to down scale the sample to be analyzed.

Selective oxidation of 5-hydroxymethylcytosine with micelle incarcerated oxidants to determine it at single base resolution.

5-Methylcytosine (5mC) is oxidized by ten-eleven translocation (TET) enzymes. This process followed by thymine DNA glycosylase is proposed to be the mechanism for methylcytosine demethylation. 5-Hydroxymethylcytosine (5hmC) is one of the most important key oxidative metabolites in the demethylation process, and therefore, simple and accurate method to determine 5hmC at single base resolution is desired. In the present study, we developed a mild catalytic oxidation of 5-hmC using micelle incarcerated oxidants that enables to determine the position of 5hmC at single base resolution.

Identification of okadaic acid binding protein 2 in reconstituted sponge cell clusters from Halichondria okadai and its contribution to the detoxification of okadaic acid.

Okadaic acid (OA) and OA binding protein 2 (OABP2) were previously isolated from the marine sponge Halichondria okadai. Because the amino acid sequence of OABP2 is completely different from that of protein phosphatase 2A, a well-known target of OA, we have been investigating the production and function of OABP2. In the present study, we hypothesized that OABP2 plays a role in the detoxification of OA in H. okadai and that the OA concentrations are in proportional to the OABP2 concentrations in the sponge specimens. Based on the OA concentrations and the OABP2 concentrations in the sponge specimens collected in various places and in different seasons, however, we could not determine a positive correlation between OA and OABP2. We then attempted to determine distribution of OA and OABP2 in the sponge specimen. When the mixture of dissociated sponge cells and symbiotic species were separated with various pore-sized nylon meshes, most of the OA and OABP2 was detected from the same 0-10 µm fraction. Next, when sponge cell clusters were prepared from a mixture of dissociated sponge cells and symbiotic species in the presence of penicillin and streptomycin, we identified the 18S rDNA of H. okadai and the gene of OABP2 in the analysis of genomic DNA but could not detect OA by LC-MS/MS. We thus concluded that the sponge cells express OABP2, and that OA was not apparently present in the sponge cells but could be colocalized with OABP2 in the sponge cells at a concentration less than the limit of detection.

Crystal Structure of Okadaic Acid Binding Protein 2.1: A Sponge Protein Implicated in Cytotoxin Accumulation.

Okadaic acid (OA) is a marine polyether cytotoxin that was first isolated from the marine sponge Halichondria okadai. OA is a potent inhibitor of protein serine/threonine phosphatases (PP) 1 and 2A, and the structural basis of phosphatase inhibition has been well investigated. However, the role and mechanism of OA retention in the marine sponge have remained elusive. We have solved the crystal structure of okadaic acid binding protein 2.1 (OABP2.1) isolated from H. okadai; it has strong affinity for OA and limited sequence homology to other proteins. The structure revealed that OABP2.1 consists of two α-helical domains, with the OA molecule deeply buried inside the protein. In addition, the global fold of OABP2.1 was unexpectedly similar to that of aequorin, a jellyfish photoprotein. The presence of structural homologues suggested that, by using similar protein scaffolds, marine invertebrates have developed diverse survival systems adapted to their living environments.

Brevisulcatic acids, marine ladder-frame polyethers from the red tide dinoflagellate Karenia brevisulcata in New Zealand.

The isolation and structural determination of new marine ladder-frame polyethers, brevisulcatic acids-1 (1) and -4 (2) are reported. Brevisulcatic acids were isolated from the dinoflagellate Karenia brevisulcata, which was identified as the causative species of a major red tide event in New Zealand in 1998. The ether ring composition and a ß-hydroxy, γ-methylene valeric acid side chain of 1 and 2 are common, but 2 has a γ-lactone as the 5-membered A-ring while 1 is the seco acid analogue. Compound 2 has structural and bioactivity similarities to brevetoxin A.

Interaction analysis of a ladder-shaped polycyclic ether and model transmembrane peptides in lipid bilayers by using Förster resonance energy transfer and polarized attenuated total reflection infrared spectroscopy.

Ladder-shaped polycyclic ethers (LSPs) are predicted to interact with membrane proteins; however, the underlying mechanism has not been satisfactorily elucidated. It has been hypothesized that LSPs possess non-specific affinity to α-helical segments of transmembrane proteins. To verify this hypothesis, we constructed a model LSP interaction system in a lipid bilayer. We prepared 5 types of α-helical peptides and reconstituted them in liposomes. The reconstitution and orientation of these peptides in the liposomes were examined using polarized attenuated total reflection infrared (ATR-IR) spectroscopy and gel filtration. The results revealed that 4 peptides were retained in liposomes, and 3 of them formed stable transmembrane structures. The interaction between the LSP and the peptides was investigated using Förster resonance energy transfer (FRET). In the lipid bilayer, the LSP strongly recognized the peptides that possessed aligned hydrogen donating groups with leucine caps. We propose that this leucine-capped 16-amino acid sequence is a potential LPS binding motif.

Structure-activity relationships of the truncated norzoanthamines exhibiting collagen protection toward anti-osteoporotic activity.

The marine alkaloid norzoanthamine is a candidate drug for osteoporosis treatment. Due to its structural complexity, simplified analogues possessing similar biological activities are needed for further research. Recently, we found that the bisaminal unit, representing two-thirds of the original structure, is a bioactive equivalent. We synthesized three kinds of further truncated norzoanthamines and evaluated their collagen protection activities. No analog with collagen protection activity comparable to that of the bisaminal unit was found. Thus, we confirmed the importance of the bisaminal unit for the collagen protection activity. Furthermore, we found that the recognition tolerance of the substrate collagen is relatively large by comparing both enantiomers.

Truncated norzoanthamine exhibiting similar collagen protection activity, toward a promising anti-osteoporotic drug.

The marine alkaloid, norzoanthamine, is considered to be a promising drug for osteoporosis treatment. Due to its rarity and complicated structure, a practical supply method must be developed. Here, we designed a truncated norzoanthamine, which has two-thirds of the original structure, and found that it exhibited similar collagen protection activity.

Origins of oxygen atoms in a marine ladder-frame polyether: evidence of monooxygenation by 18O-labeling and using tandem mass spectrometry.

Yessotoxin is a ladder-frame polyether produced by the dinoflagellate Protoceratium reticulatum. Previous labeling experiments using (13)C-acetate established the unique assembly of the carbon chain from intact and cleaved acetate units. The origins of ether and hydroxy oxygens in the molecule, which would yield further information regarding the assembly of the ladder-frame structure, have yet to be established. In this study, we describe the incorporation of (18)O in one experiment where the dinoflagellate was cultured under (18)O(2) atmosphere and in a second where the culture media was supplemented with [(18)O(2)]acetate. Labeled yessotoxin obtained from these experiments was subjected to collision-induced dissociation tandem mass spectrometry to determine the positions of (18)O-incorporation pattern in the molecule. Detailed analyses of product ions from the fragmentation processes led to the identification of (18)O-labeled positions and the incorporation ratios. The data revealed that the ether oxygens were labeled from (18)O(2) and the hydroxy oxygen on C32 was derived from [(18)O(2)]acetate. These results support a proposed biosynthetic mechanism of marine ladder-frame polyethers that a polyene precursor was oxidized by a monooxygenase after acetate condensation.

Solution NMR analysis of the binding mechanism of DIVS6 model peptides of voltage-gated sodium channels and the lipid soluble alkaloid veratridine.

Voltage-gated sodium channels (VGSCs) are responsible for generating action potentials in nervous systems. Veratridine (VTD), a lipid soluble alkaloid isolated from sabadilla lily seed, is believed to bind to segment 6 of VGSCs and act as a partial agonist. However, high resolution structural interaction mechanism between VGSCs and VTD is difficult to elucidate because of the large size and membrane localization of VGSCs. Here, the authors designed model peptides corresponding to domain IV segment 6 (DIVS6) of rat skeletal muscle Na(v)1.4 and analyzed the complex of the model peptides and VTD by solution NMR analysis to obtain structural information of the interaction. The model peptides successfully formed an α-helices, which is the suspected native conformation of DIVS6, in aqueous 2,2,2-trifluoroethanol, a membrane-mimicking solvent. The VTD binding residues of the model peptide were identified using the NMR titration experiments with VTD, including a newly discovered VTD binding residue Leu14 (µ1-L1580 in Na(v)1.4), which has not been reported by point mutation studies. Mapping of VTD binding residues on the model peptide revealed the hydrophobic interaction surface. NMR titration experiments with a non-toxic analog of VTD, veracevine, also indicated that the steroidal backbone of VTD interacts with the hydrophobic interaction surface of DIVS6 and that the 3-acyl group of VTD possibly causes neurotoxicity by interacting with domain I segment 6 and/or domain IV segment 4.

Brevisulcenal-F: a polycyclic ether toxin associated with massive fish-kills in New Zealand.

A novel marine toxin, brevisulcenal-F (KBT-F, from karenia brevisulcata toxin) was isolated from the dinoflagellate Karenia brevisulcata. A red tide of K. brevisulcata in Wellington Harbour, New Zealand, in 1998 was extremely toxic to fish and marine invertebrates and also caused respiratory distress in harbor bystanders. An extract of K. brevisulcata showed potent mouse lethality and cytotoxicity, and laboratory cultures of K. brevisulcata produced a range of novel lipid-soluble toxins. A lipid soluble toxin, KBT-F, was isolated from bulk cultures by using various column chromatographies. Chemical investigations showed that KBT-F has the molecular formula C(107)H(160)O(38) and a complex polycyclic ether nature. NMR and MS/MS analyses revealed the complete structure for KBT-F, which is characterized by a ladder-frame polyether scaffold, a 2-methylbut-2-enal terminus, and an unusual substituted dihydrofuran at the other terminus. The main section of the molecule has 17 contiguous 6- and 7-membered ether rings. The LD(50) (mouse i.p.) for KBT-F was 0.032 mg/kg.

Ophiobolin O and 6-epi-ophiobolin O, two new cytotoxic sesterterpenes from the marine derived fungus Aspergillus sp.

Two new sesterterpenes, ophiobolin O (1) and 6-epi-ophiobolin O (2), together with the known ophiobolins G (3), H (4), and K (5), and 6-epi-ophiobolin K (6) were isolated from the marine derived fungus Aspergillus sp. The structures of these compounds were elucidated based on chemical and physicochemical evidence, including MS, UV, IR and NMR spectra. T h e stereochemistry of 1 was further confirmed by catalytic reaction of 5 with p-TsOH as acatalyst. Compounds 1 to 6 showed cytotoxicity against mouse leukemia cell line P388, with IC50 values of 4.7, 9.3, 24.6, 105.7, 13.3 and 24.9 microM, respectively.

Two new indole alkaloids, 2-(3,3-dimethylprop-1-ene)-costaclavine and 2-(3,3-dimethylprop-1-ene)-epicostaclavine, from the marine-derived fungus Aspergillus fumigatus.

Two new indole alkaloids, 2-(3,3-dimethylprop-1-ene)-costaclavine (1) and 2-(3,3-dimethylprop-1-ene)-epicostaclavine (2), together with the known compounds costaclavine (3), fumgaclavine A (4) and C (5), were isolated from the marine-derived fungus Aspergillus fumigatus. The planar structures of the two new compounds were elucidated on the basis of chemical and physicochemical evidence including MS, UV, IR and NMR spectra. Their stereochemistry was studied by NOESY, (1)H-(1)H coupling constant and CD spectra. The compounds 1, 2, 3 and 5 showed weak cytotoxicity against a mouse leukemia cell line (P388).

Prorocentrol, a polyoxy linear carbon chain compound isolated from the toxic dinoflagellate Prorocentrum hoffmannianum.

A polyoxy linear carbon chain compound, prorocentrol (1), was isolated from cultured cells of the dinoflagellate Prorocentrum hoffmannianum, which produces a polyether carboxylic acid, okadaic acid. The structure of 1 was elucidated by detailed analyses of 2D NMR spectra. Compound 1 possesses 30 hydroxy groups, 1 ketone, and 8 double bonds on the C65-linear carbon chain. Its partial relative configuration was deduced by the proton-proton and long-range carbon-proton coupling constants, and compound 1 showed moderate cytotoxicity and antidiatom activity.

Total synthesis of (-)-brevisin: a concise synthesis of a new marine polycyclic ether.

The first and highly efficient total synthesis of (-)-brevisin has been achieved. The title compound was synthesized in only 29 steps (longest linear sequence) from commercially available starting materials. The synthesis provided over 70 mg of a marine polycyclic ether compound.

Binding of diarrheic shellfish poisoning toxins to okadaic acid binding proteins purified from the sponge Halichondria okadai.

Okadaic acid (OA) and dinophysistoxin-1 (DTX1) cause diarrheic shellfish poisoning. This article examines the biochemical interactions of the two toxins with novel okadaic acid binding proteins (OABPs) 2.1 and 2.3, originally isolated from the marine sponge Halichondria okadai. First, recombinant OABPs 2.1 and 2.3 were expressed in Escherichia coli BL21 (DE3) cells. Binding assays using [24-(3)H]OA and the recombinant OABP 2.1 or 2.3 demonstrated the dissociation constant K(d) of 1.30±0.56 nM and 1.54±0.35 nM, respectively. Binding of [24-(3)H]okadaic acid to recombinant OABP2.1 was almost equally replaced with OA and DTX1. OA-induced cytotoxicity in mouse leukemia P388 cells was inhibited in the presence of the recombinant OABPs 2.1 and 2.3 with an EC(50) of 92±8.4 nM and 87±13 nM, respectively. These results suggest that the blockage of OA-induced cytotoxicity by OABPs 2.1 and 2.3 may be involved in regulating symbiotic relationships present in the sponge H. okadai.

Distribution and possible function of the marine alkaloid, norzoanthamine, in the zoanthid Zoanthus sp. using MALDI imaging mass spectrometry.

The role of the marine alkaloid, norzoanthamine, in the colonial zoanthid Zoanthus sp. was previously unknown. High concentrations of norzoanthamine are present in the epidermal tissue of Zoanthus sp., as determined using protonated molecular ion peak mapping of norzoanthamine by matrix-assisted laser desorption/ionization mass spectrometry and high-performance liquid chromatography quantification. Sodium dodecylsulfate polyacrylamide gel electrophoresis experiments indicate that norzoanthamine increases the resistance of collagen to damage from UV light, probably not via UV light absorption, but by strengthening collagen itself, thus suggesting that collagen strengthening may be the function of norzoanthamine in Zoanthus sp.

Skeletal protein protection: the mode of action of an anti-osteoporotic marine alkaloid, norzoanthamine.

Bone is composed of mineralized collagen fibrils. A marine alkaloid, norzoanthamine, accelerates the formation of a collagen-hydroxyapatite composite and enhances collagen release from an immobilized matrix vesicle model. Norzoanthamine recognizes a peptide chain nonspecifically and stabilizes its secondary structure, and collagen has polyvalent binding sites for norzoanthamine. This collagen-norzoanthamine supramolecular association is considered to be one of the most significant modes of action for enhancement of bone formation. The facts that norzoanthamine is nontoxic and that it has a collagen protective activity indicate that it may provide significant therapeutic benefits. In particular, it may be a promising drug candidate for osteoporosis treatment and prevention. Interestingly, norzoanthamine suppressed the proteolysis of not only collagen but also elastin and bovine serum albumin, so it apparently has a universal protective effect of guarding extracellular matrix proteins from degradation. This result suggests that norzoanthamine protect skeletal proteins in the host animal body from external stresses and possibly enhance survival.

Computationally and experimentally derived general rules for fragmentation of various glycosyl bonds in sodium adduct oligosaccharides.

Mechanisms of fragmentation of glycosyl bond linkages in various saccharides were investigated by using computational calculations to find general rules of fragmentation of sodiated oligosaccharides in mass spectrometry. The calculations revealed that alpha-Glc, alpha-Gal, beta-Man, alpha-Fuc, beta-GlcNAc, and beta-GalNAc linkages were cleaved more easily than beta-Glc, beta-Gal, and alpha-Man linkages because the transition states of the former were stabilized by the anomeric effect. The 1-6 linkage was more stable than the others, since saccharides with flexible 1-6 linkages were more stabilized in energy than the other linkages by the sodium cation. The sialyl linkage was the most labile of all the linkages investigated. Comparison of activation energies and binding affinities to the sodium cation revealed an increase in activation energy in proportion to the increment in binding affinity. The calculated stabilities of glycosyl bonds were: alpha-Man (Manalpha1-3Man, Manalpha1-4Man, Manalpha1-6Man) > beta-Gal (Galbeta1-4Gal) > alpha-GalNAc (GalNAcalpha1-4GalNAc) > beta-Man (Manbeta1-4GlcNAc) > alpha-Gal (Galalpha1-3Gal, Galalpha1-4Gal, Galalpha1-6Gal) > beta-Man (Manbeta1-4Man) > beta-GalNAc (GalNAcbeta1-4GalNAc) > alpha-Fuc (Fucalpha1-6GlcNAc) > alpha-Fuc (Fucalpha1-4GlcNAc) > beta-GlcNAc (GlcNAcbeta1-4GlcNAc) > alpha-Fuc (Fucalpha1-3GlcNAc) > alpha-NeuNAc (NeuNAcalpha2-3Gal, NeuNAcalpha2-6Gal); this result was close to the experimentally deduced trend. These theoretically and experimentally derived general rules for fragmentation should be useful for analyzing the experimentally obtained mass spectra of oligosaccharides.