The inhibition of CHO-K1-BH4 cell proliferation and induction of chromosomal aberrations by brevetoxins in vitro.

Brevetoxins (PbTxs) are highly potent trans-syn polyether neurotoxins produced during blooms of several species of marine dinoflagellates, most notably Karenia brevis. These neurotoxins act on voltage-sensitive sodium channels prolonging the active state. During red tides, the commercial fishing and tourism industries experience millions of dollars of lost revenue. Human consumption of shellfish contaminated with PbTxs results in neurotoxic shellfish poisoning (NSP). Additionally, blooms of K. brevis are potentially responsible for adverse human health effects such as respiratory irritation and airway constriction in coastal residents. There is little information regarding the full range of potential toxic effects caused by PbTxs. Recent evidence suggests that PbTxs are genotoxic substances. The purpose of this study was to determine if PbTxs could induce chromosomal aberrations and inhibit cellular proliferation in CHO-K1-BH4 cells, and if so, could the damage be negated or reduced by the PbTx antagonist brevenal. Results from the chromosomal aberrations assay demonstrated that PbTxs are potent inducers of CHO-K1-BH4 chromosome damage. Results from the inhibition of cellular proliferation assays demonstrated that PbTxs inhibit the ability of CHO-K1-BH4 cells to proliferate, an effect which can be reduced with brevenal.

Brevetoxin derivatives that inhibit toxin activity.

BACKGROUND: The brevetoxins are marine neurotoxins that interfere with the normal functions of the voltage-gated Na(+) channel. We have identified two brevetoxin derivatives that do not exhibit pharmacological properties typical of the brevetoxins and that function as brevetoxin antagonists. RESULTS: PbTx-3 and benzoyl-PbTx-3 elicited Na(+) channel openings during steady-state depolarizations; however, two PbTx-3 derivatives retained their ability to bind to the receptor, but did not elicit Na(+) channel openings. alpha-Naphthoyl-PbTx-3 acted as a PbTx-3 antagonist but did not affect Na(+) channels that were not exposed to PbTx-3. beta-Naphthoyl-PbTx-3 reduced openings of Na(+) channels that were not exposed to PbTx-3. CONCLUSIONS: Some modifications to the brevetoxin molecule do not alter either the binding properties or the activity of these toxins. Larger modifications to the K-ring sidechain do not interfere with binding but have profound effects on their pharmacological properties. This implies a critical function for the K-ring sidechain of the native toxin.

The relationship of brevetoxin 'length' and A-ring functionality to binding and activity in neuronal sodium channels.

BACKGROUND: Brevetoxins are polyether ladder toxins that are ichthyotoxic at nanomolar concentrations. They bind to voltage-gated sodium channels, causing four distinct electrophysiological effects: (i) a shift of activation potential; (ii) occurrence of subconductance states; (iii) induction of longer mean open times of the channel; and (iv) inhibition of channel inactivation. We set out to determine whether these functions all require the same structural elements within the brevetoxin molecules. RESULTS: Several synthetically prepared structural analogs of brevetoxin B were examined in synaptosome receptor binding assays and by functional electrophysiological measurements. A truncated analog is not ichthyotoxic at micromolar concentrations, shows decreased receptor-binding affinity, and causes only a shift of activation potential without affecting mean open times or channel inactivation. An analog with the A-ring carbonyl removed binds to the receptor with nanomolar affinity, produces a shift of activation potential and inhibits inactivation, but does not induce longer mean open times. An analog in which the A-ring diol is reduced shows low binding affinity, yet populates five subconductance states. CONCLUSIONS: Our data are consistent with the hypothesis that binding to sodium channels requires an elongated cigar-shaped molecule, approximately 30 A long. The four electrophysiological effects of the brevetoxins are not produced by a single structural feature, however, since they can be decoupled by using modified ligands, which are shown here to be partial sodium channel agonists. We propose a detailed model for the binding of brevetoxins to the channel which explains the differences in the effects of the brevetoxin analogs. These studies also offer the potential for developing brevetoxin antagonists.

Brevetoxins bind to multiple classes of sites in rat brain synaptosomes.

The brevetoxins (PbTx series), neurotoxins produced by the marine dinoflagellate Ptychodiscus brevis, cause dose-dependent activation of the voltage-sensitive sodium channel (VSSC). Saturation binding studies employing adult rat brain synaptosomes suggest the existence of a high affinity/low capacity (HA/LC) and a second, lower affinity/higher capacity (LA/HC) class of binding site. LIGAND analysis of saxitoxin and brevetoxin saturation binding data yields a statistically identical Bmax for the brevetoxin high affinity/low capacity (HA/LC) site (1.9 +/- 0.98 pmol/mg protein) and for saxitoxin (1.72 +/- 0.78 pmol/mg protein; P less than 0.001). The stoichiometry of HA/LC brevetoxin binding and saxitoxin binding approaches 1:1. Covalent modification of synaptosomes with a brevetoxin photoaffinity probe preferentially blocks the HA/LC binding site. Hill plots of saturation binding data yield a coefficient of 1.0 +/- 0.02, demonstrating a lack of cooperativity between brevetoxin binding site classes. Kd and Bmax for toxin binding are independent of membrane polarity, intimating that the observed low affinity/high capacity (LA/HC) binding characteristics are not due to modification of the HA/LC site, and strongly argue for the presence of multiple brevetoxin binding site classes. Half-maximal binding at the LA/HC site, and strongly argue for the presence of multiple brevetoxin binding site classes. Half-maximal binding at the LA/HC site occurs at concentration ranges for which the brevetoxins allosterically modulate binding of other natural toxins to their specific sites.

Brevetoxin derivatives act as partial agonists at neurotoxin site 5 on the voltage-gated Na+ channel.

Brevetoxins (PbTx-1 to PbTx-10) are potent lipid-soluble polyether neurotoxins produced by the marine dinoflagellate Karina brevis, an organism associated with 'red tide' blooms in the Gulf of Mexico. Ingestion of shellfish contaminated with K. brevis produces neurotoxic shellfish poisoning (NSP) in humans. NSP symptoms emanate from brevetoxin activation of neurotoxin site 5 on voltage-gated sodium channels (VGSC) [Toxicon 20 (1982) 457]. In primary cultures of rat cerebellar granule neurons (CGN), brevetoxins produce acute neuronal injury and death. The ability of a series of naturally occurring and synthetic brevetoxins to trigger Ca(2+) influx in CGN was explored in the present study. Intracellular Ca(2+) concentration was monitored in fluo-3-loaded CGN using a fluorescent laser imaging plate reader. The naturally occurring derivatives PbTx-1, PbTx-2 and PbTx-3 all produced a rapid and concentration-dependent increase in cytosolic [Ca(2+)]. The maximum response to PbTx-1 was approximately two-fold greater than that of either PbTx-2 or PbTx-3. Two synthetic derivatives of PbTx-3, alpha-naphthoyl-PbTx-3 and beta-naphthoyl-PbTx-3, were also tested. Both alpha- and beta-naphthoyl-PbTx-3 stimulated a rapid and concentration-dependent Ca(2+) influx that was, however, less efficacious than that of PbTx-3. These data indicate that, analogous to neurotoxin site 2 ligands, activators of neurotoxin site 5 display a range of efficacies, with PbTx-1 being a full agonist and other derivatives acting as partial agonists.

An enzyme immunoassay for the detection of Florida red tide brevetoxins.

A non-competitive solid-phase enzyme immunoassay for detection of brevetoxins in various matrices has been developed. The assay utilizes antibodies raised in a goat against brevetoxin PbTx-3-keyhole limpet hemocyanin conjugates with specific purification of brevetoxin antibodies through protein G and brevetoxin affinity columns, and rabbit anti-goat antibodies covalently linked to horseradish peroxidase. The assay was used specifically to detect brevetoxins in both cell culture and contaminated tissues. Sensitivity of the assay is 0.04 picomolar, and toxin can be quantified from 0.04 pM to 0.4 pM brevetoxin per well in microtiter plates by comparison with standard curves.

Variations in major toxin composition for six clones of Ptychodiscus brevis.

Extracts from six clones of Ptychodiscus brevis (formerly known as Gymnodinium breve) were analyzed by high performance liquid chromatography for the presence of brevetoxins PbTx-1, PbTx-2, and PbTx-3. Analyses indicated a wide clonal variability of the three toxin fractions in logarithmic phase cultures when normalized on a per cell basis. It appears that a much wider variability exists in toxin content for different P. brevis clones than exists in replicate extraction of multiple cultures of the diploid clone originally isolated by Wilson.

Toxicity of two toxins from the Florida red tide marine dinoflagellate, Ptychodiscus brevis.

The purification and crystallization of T17, a toxin from Ptychodiscus brevis, is reported. The toxicity of this compound and a second toxin known as T34 are compared by i.v., i.p. and oral administration in mice. Both toxins produce symptoms characteristic of muscarnic stimulants; hypersalivation, rhinorrhea and excessive urination and defecation being the most commonly observed. T17, which is orally toxic, is believed to be the agent responsible for Neurotoxic Shellfish Poisoning.

Binding of brevetoxins and ciguatoxin to the voltage-sensitive sodium channel and conformational analysis of brevetoxin B.

The marine toxins known generically as brevetoxins, as well as their structural relative ciguatoxin, are known as polyether ladder toxins, and bind uniquely to site 5 of the voltage-sensitive sodium channel. Rat brain synaptosome binding data show similarities in binding affinity for brevetoxins having the same structural (ladder) backbone, but different affinities between brevetoxins having different backbones. Ciguatoxin has a different backbone from the brevetoxins, but binds even more strongly to the same site. Could the flexibility of the backbone be related to their relative toxicities? As part of an effort to identify the common pharmacophore for the toxins, Monte Carlo methods were used to generate conformational models of the polyether ladder toxin brevetoxin B (PbTx-2) which shows significant flexibility at the juncture of the two 7-membered rings.

Specific antibodies directed against toxins of Ptychodiscus brevis (Florida's red tide dinoflagellate).

Specific antibodies directed against Ptychodiscus brevis 'brevetoxins' have been produced in a goat. The haptenic toxin T34 was chemically reduced to toxin T17, covalently-linked to succinic acid via anhydride coupling, and coupled to bovine serum albumin using standard carbodiimide condensation procedures. The hapten coupling efficiency ranged from 10.4 to 13.5 moles of toxin bound per mole of protein. Antibody titers were directly related to the frequency of immunization, and weekly intervals appeared optimum for maintaining adequate titers. [3H]Brevetoxin T17 is displaced in a competitive manner from the antibody-antigen complexes by unlabeled toxin, but the antibodies do not distinguish between T17 and T34. The sensitivity achieved, using purified brevetoxins as competitive inhibitors of [3H]T17 binding, was 600 picograms. The assay linearity ranged from 1.5 to 48 ng.

Brevetoxin PbTx-2 immunology: differential epitope recognition by antibodies from two goats.

The epitopic regions of the brevetoxin PbTx-3 molecule, produced by the marine dinoflagellate Ptychodiscus brevis, have been identified by structural modification at three distinct regions of the toxin. These are: the A-ring lactone region of the molecule, the K-ring side-chain and the H-ring. The modified PbTx-3 derivatives were tested for their ability to bind brevetoxin goat antisera directed against the PbTx-3 molecule, by radioimmunoassay. The results showed that at least two major epitopes and one minor epitope are recognized: the A-ring lactone region of the molecule and the K-ring side-chain, and the H-ring. The results illustrate the variety of antibodies which may be produced, even within a species, and suggests that epitope characterization is important in the development of assays which are to be employed in seafood safety issues.

Bronchoconstriction caused by Florida red tide toxins.

T17, a toxin purified from laboratory cultures of Florida's redtide organism, Ptychodiscus brevis (formerly Gymnodinium breve), produces bronchoconstriction in anesthetized artificially-ventilated guinea pigs. Bronchoconstriction, measured as a resistance to mechanical pulmonary inflation, was antagonized by atropine, but not by interruption of vagal nerve stimulation or diaphragm dissection.

Brevetoxin: tissue distribution and effect on cytochrome P450 enzymes in fish.

As part of our investigation of the metabolism of brevetoxin (PbTx) in fish, we initiated a two-part study to determine the toxin's tissue distribution and its ability to induce xenobiotic metabolizing enzymes. In the first study, gulf toadfish (Opsanus beta) were administered 14C-PbTx-3 orally in a fishmeal slurry and sacrificed 72 hr later. Radioactivity was greatest in the hepatobiliary system (40% of body burden), representing the key role this system plays in the detoxification and elimination of brevetoxin. Muscle tissue contained 27%, followed by gastrointestinal tract (25%). To investigate the effects of PbTx on xenobiotic metabolizing enzymes, immature redfish (Scianops ocellatus) were given two doses of brevetoxin (1.5 or 2.5 micrograms/100 g body weight) or cod liver oil in a fishmeal slurry by gavage. The activities of two hepatic P450 enzymes, ethoxyresorufin O-deethylase (EROD) and pentoxyresorufin O-depentylase (PROD), as well as the cytosolic enzyme, glutathione S-transferase (GST), were measured. At the higher dose, PbTx significantly increased EROD activity. These results suggest that brevetoxin is capable of inducing an important xenobiotic metabolizing enzyme (EROD).

Neuromuscular blocking action of two brevetoxins from the Florida red tide organism Ptychodiscus brevis.

The action of Ptychodiscus brevis "brevetoxins" T17 and T34 on rat phrenic nerve-stimulated hemidiaphragm contraction is reported. The potency of T34 is greater than the potency of T17, but both cause a complete block of neuromuscular transmission in the nM to pM concentration ranges. Preparations exposed to low concentrations of T17 can recover in the presence of the toxin, whereas the effects of T34 are irreversible. The initial contracture produced by each is prevented by tetrodotoxin or curare. Neuromuscular block does not appear to be due to acetylcholine depletion, as determined by electron microscope examination of the neuromuscular junctions of blocked preparations. Persistent nerve depolarization is believed to be responsible for the neuromuscular block.

Brevetoxin binding: molecular pharmacology versus immunoassay.

Brevetoxin PbTx-3 isolated from Florida's red tide dinoflagellate Ptychodiscus brevis has been produced recently in tritiated form by reductive tritiation of brevetoxin PbTx-2. Tritiated PbTx-3 has been used as a specific probe in competitive radioimmunoassays developed to detect brevetoxins in food sources, and this probe has also been utilized to characterize the brevetoxin binding component in rat brain synaptosomes. Brevetoxins PbTx-2 and PbTx-3, possessing the same structural backbone (type-1) as the tritiated probe, and PbTx-1 and PbTx-7, possessing a second structural backbone (type-2), have been compared quantitatively in their individual abilities to competitively displace tritiated PbTx-3 from its specific binding site in each assay. Type-1 toxins displaced labeled probe with ED50 values of 20-22 nM and 12-17 nM in radioimmunoassay and synaptosomes, respectively. Type-2 toxins displaced labeled probe with ED50 values of 92-93 nM and 3.5-4.1 nM in RIA and synaptosomes, respectively. Synaptosome assays reflect potency of each toxin examined, while radioimmunoassay reflects structural similarities to the immunizing toxin PbTx-3.

Brevetoxin modulates neuronal sodium channels in two cell lines derived from rat brain.

Single Na+ channel currents were recorded from cell-attached membrane patches from two neuronal cell lines derived from rat brain, B50 and B104, and compared before and after exposure of the cells to purified brevetoxin, PbTx-3. B50 and B104 Na+ channels usually exhibited fast activation and inactivation as is typical of TTX-sensitive Na+ channels. PbTx-3 modified channel gating in both cell lines. PbTx-3 caused (1) significant increases in the frequency of channel reopening, indicating a slowing of channel inactivation, (2) a change in the voltage dependence of the channels, promoting channel opening during steady-state voltage clamp of the membrane at voltages throughout the activation range of Na+ currents, but notably near the resting potential of these cells (-60 - -50 mV), and (3) a significant, 6.7 mV hyperpolarized shift in the threshold potential for channel opening. Na+ channel slope conductance did not change in PbTx-3-exposed B50 and B104 neurons. These effects of Pbx-3 may cause hyperexcitability as well as inhibitory effects in intact brain.

Uptake, tissue distribution, and excretion of brevetoxin 3 administered to rats by intratracheal instillation.

Brevetoxins are cyclic polyether neurotoxins produced by the marine dinoflagellate Ptychodiscus brevis. Blooms of P. brevis (red tides) are toxic to fish, marine mammals, and humans. Humans exposed to seaspray aerosols containing brevetoxins may experience respiratory tract irritation. Because a major route of human exposure to brevetoxins is via the respiratory tract, the objective of this study was to examine the toxicokinetics of brevetoxin 3 (PbTx-3) administered to the lung by intratracheal instillation. Twenty-one male F344/Crl BR rats, 12 wk of age, were administered 3H-PbTx-3 (1 microCi, 6.6 microg PbTx-3/kg) by intratracheal instillation. Groups of 3 rats were sacrificed at 0.5, 3, 6, 24, 48, and 96 h after exposure, and tissues were collected. Three additional rats were placed in glass metabolism cages for collection of urine and feces over a 7-d period. PbTx-3-associated activity was cleared rapidly from the lung and distributed throughout the body, chiefly to the carcass, intestines, and liver. Blood, brain, and fat contained the lowest percentages of the administered dose. Although a majority of the PbTx-3 was cleared rapidly from lung, liver, and kidneys, approximately 20% of the initial concentration present in each organ was retained for 7 d. Concentrations of PbTx-3 in brain and fat were low, but remained relatively constant over time. Approximately twice as much PbTx-3-associated activity was excreted in feces than in urine, with the majority of excretion occurring within 48 h after instillation. The results of this study indicate that over 80% of the PbTx-3 is rapidly absorbed from the lung to the blood and distributed to all tissues. The tissues containing the greatest amount of PbTx-3-associated activity reflect the compound's site of deposition, storage compartment, and major route of metabolism and excretion. These results illustrate that brevetoxin exposure by the respiratory route results in systemic distribution of brevetoxin and suggest that the initial respiratory irritation and bronchoconstriction may only be a part of the overall toxicological consequences associated with brevetoxin inhalation.

Detection of marine toxins using reconstituted sodium channels.

Specific binding of the marine toxins saxitoxin, tetrodotoxin, and brevetoxin to the rat brain sodium channel is demonstrated using purified sodium channels reconstituted into phospholipid vesicles. Restoration of sodium channel function and binding activity by incorporation into phospholipid vesicles provides the only rigorous proof that the purified protein contains the neurotoxin receptor sites. In addition, reconstitution provides a valuable experimental preparation for biochemical analysis of neurotoxin binding sites and may facilitate the development of a specific toxin detection system.

Radioimmunoassay for PbTx-2-type brevetoxins: epitope specificity of two anti-PbTx sera.

Antiserum against PbTx-2-type brevetoxins was produced by immunizing rabbits with a PbTx-2-bovine serum albumin (BSA) conjugate. This serum had a higher affinity, but lower titer, than our current goat serum. Using 4 natural brevetoxins and 6 synthetic derivatives as competitors in our brevetoxin radioimmunoassay, we determined the epitope specificity of both sera. Modification of the backbone structure at C-42 on the K-ring had little or no effect on the antigen-binding capability of either serum. Reduction of the double bond between C-2 and C-3 on the A-ring by reduction of the lactone decreased binding 500 to 750-fold. Epoxidation of the double bond between C-27 and C-28 on the H-ring did not affect binding, which suggested that the goat serum is specific for the A-ring region of the brevetoxin backbone. In contrast, modifying the A-ring had no effect on rabbit serum binding. However, epoxidation of the H-ring decreased binding 5 to 20-fold, which suggested that the rabbit antiserum is specific for the H-ring region of the molecule. These results suggest that assays utilizing only one antibody may not adequately detect toxin metabolites if molecules are altered in the critical region of antibody recognition.

Modified immunoassays for polyether toxins: implications of biological matrixes, metabolic states, and epitope recognition.

Polyether marine toxins are responsible for the seafood intoxication phenomena known as neurotoxic shellfish poisoning (due to brevetoxins), ciguatera (due to ciguatoxin), and diarrheic shellfish poisoning (due to okadaic acid). Using traditional techniques of hapten (pure toxin) conjugation to protein to create complete antigen, animal immunization and antibody isolation, and specific antibody subpopulation purification, discriminating antibodies have been isolated that detect brevetoxins and ciguatoxin, but not okadaic acid, in a dose-dependent fashion. Using microorganic chemistry and purified toxins, a unique set of tools has been created for the study of polyether ladder toxin accumulation; depuration; and specific site localization in tissues, food sources, and clinical samples. Developed test protocols can detect toxin in dinoflagellate cells, in extracts from food sources, in seawater and culture media, and in human serum samples. Enzyme-linked immunosorbent assay protocols developed for eventual collaborative testing have been successful in limited applications within the laboratory (correlation coefficient of 0.92 excluding 2 outliers), and alternative formats are being developed to optimize the basic test for use in research laboratories, regulatory laboratories, and field inspections.