Localization and molecular interactions of mitoxantrone within living K562 cells as probed by confocal spectral imaging analysis

Studying mechanisms of drug antitumor action is complicated by the lack of noninvasive methods enabling direct monitoring of the state and interactions of the drugs within intact viable cells. Here we present a confocal spectral imaging (CSI) technique as a method of overcoming this problem. We applied this method to the examination of localization and interactions of mitoxantrone (1, 4-dihydroxy-5, 8-bis-[([2-(2-hydroxyethyl)-amino]ethyl)amino]-9,10-anthracenedione dihydrochloride), a potent antitumor drug, in living K562 cells. A two-dimensional set of fluorescence spectra of mitoxantrone (MITOX) recorded with micron resolution within a drug-treated cell was analyzed to reveal formation of drug-target complexes and to create the maps of their intracellular distribution. The analysis was based on detailed in vitro modeling of drug-target (DNA, RNA, DNA topoisomerase II) interactions and environmental effects affecting drug fluorescence. MITOX exposed to aqueous intracellular environment, MITOX bound to hydrophobic cellular structures, complexes of MITOX with nucleic acids, as well as the naphtoquinoxaline metabolite of MITOX were simultaneously detected and mapped in K562 cells. These states and complexes are known to be immediately related to the antitumor action of the drug. The results obtained present a basis for the subsequent quantitative analysis of concentration and time-dependent accumulation of free and bound MITOX within different compartments of living cancer cells.     

Determination of covalent binding to intact DNA, RNA, and oligonucleotides by intercalating anticancer drugs using high-performance liquid chromatography. Studies with doxorubicin and NADPH cytochrome P-450 reductase.

An HPLC method is described which can determine covalent binding to intact nucleic acid by intercalating anticancer drugs and at the same time remove noncovalently bound intercalated drug. The method uses a column containing a nonporous 2-microns DEAE anion-exchange resin capable of chromatographing nucleic acids greater than 50,000 bases in size in under 1 h. After priming with 1 mg of DNA, the column behaves as an intercalator affinity column, strongly retaining the drug while allowing the nucleic acid to pass through normally. Retained drug is released with an injection of 0.1 M potassium hydroxide. Incubations were performed with the intercalator doxorubicin, which is also believed to bind covalently to DNA. When [14C]doxorubicin was mixed with DNA, at a concentration where all the drug would bind by intercalation, the column retained 82% of the total radioactivity, only 18% migrated with the nucleic acid. If the DNA was mildly denatured by treatment with 2 M sodium chloride at 50 degrees C for 45 min before chromatography, then 99.8% of total radioactivity was retained, only background counts migrated with the nucleic acid, as was the case with single-stranded DNA and RNA without any treatment. Purified NADPH cytochrome P-450 reductase was used to activate doxorubicin. DNA inhibited the metabolism of the drug by the enzyme, no covalent binding occurred with RNA, low levels occurred with single-stranded DNA (34 pmol/100 micrograms), and the highest levels were recorded with oligonucleotides (243 pmol/100 micrograms). The assay was sufficiently sensitive to measure covalent binding to DNA extracted from MCF-7 human breast cancer cells treated with 50 microM [14C]doxorubicin (18.6 pmol/100 micrograms). Thus, covalent binding to DNA, RNA, and oligonucleotides by intercalators can be measured quickly (20 min) without the need to either digest the nucleic acid or subject it to long sample preparation techniques.     

Confocal raman microspectroscopy and imaging study of theraphthal in living cancer cells

Binary systems combining a transition metal complex and ascorbate have been proposed recently for catalytic therapy of malignant tumors. The killing effect on tumor cells is achieved by production of free radicals in the course of accelerated oxidation of ascorbate by dioxygen in the presence of transition metal complexes. Further progress in the development of binary catalytic systems (BCSs) requires a special method for their investigation in cells and tissues, because neither component of BCSs fluoresces. Here a resonance Raman confocal spectral imaging (RR CSI) technique was introduced as a unique approach to monitor quantitatively the transition metal complexes within living cells. Intracellular accumulation, localization, and retention of theraphthal (TP), a catalyst of the advanced TP/ascorbate BCS, were investigated in A549 cells with the RR CSI technique. The cellular analysis was complemented with the detailed study of molecular interactions of TP in solution and environmental factors affecting the RR spectrum of TP. TP does not penetrate into membranes, it binds very weakly to DNA and RNA, but it readily forms complexes with proteins. Binding with Ca(2+) cations and decreasing pH below 6 induce aggregation of TP. By analyzing RR spectra recorded from every point within a TP-treated cell, three states of the agent were discriminated, namely, monomeric TP in polar environment, TP bound to proteins, and aggregated TP. Their cytoplasmic and nuclear distributions were mapped at different stages of uptake and efflux. By introducing organelle-selective fluorescent probes into drug-treated cells and measuring intracellular localization of both the probe and the drug, compartmentation of TP was revealed. Cell growth suppression by the TP/ascorbate system was measured, and probable molecular and organelle targets of radical damage were characterized.     

Monoazido analog of ethidium as a chromatin probe: Binding to DNA

Two photoaffinity analogs of ethidium, 8-azido-3-amino, and 3-azido-8-amino-5-ethyl-6-phenylphenanthridinium chloride, have been used to probe the structure of mammalian chromatin and its interactions with the ethidium moiety. The monoazido analogs were established as suitable probes by comparing their interactions with chromatin and pure DNA prepared from chromatin to those of the parent ethidium bromide. Scatchard analysis of the binding data determined from spectrophotometric titrations showed that the analogs interacted with both nucleic acids in a manner similar to the parent compound. The effect of chromatin proteins on the interaction of the ethidium moiety with intact chromatin was investigated directly. By exposing the noncovalent complex to visible light, the monoazido analog was attached covalently in its interaction sites within chromatin, and the amount of drug bound covalently to DNA was determined for both protein-free DNA and chromatin. Using saturating concentrations of drug, DNA within intact chromatin was found to be associated with only half as much drug as DNA extracted from its protein prior to drug exposure. The distribution of drug bound within chromatin was determined following the attachment of the monoazido analog (by photoactivation) to chromatin that had undergone limited nuclease digestion. Several distinct populations isolated by size fractionation and quantitative measurements revealed that (1) both the core particles and the spacer-containing particles contained bound drug, reflecting high-affinity binding sites; and (2) chromatin particles containing 150 DNA base pairs (putatively nucleosome core structures) contained less total bound drug at high drug concentrations than those particles having intact spacer DNA.     

A microspectrofluorometric study of the effect of anthralin, an antipsoriatic drug, on cellular structures and metabolism

The microspectrofluorometric approach has been used to investigate in single living cells in culture fundamental questions raised by the use of anthralin, a potent antipsoriatic drug. This method allows fluorescence determinations on the intracellular fate of the drug as well as the recognition of structural and metabolic alterations induced by the drug. In the absence of demonstrable adduct formation with DNA, the antipsoriatic, i.e. antiproliferative effect of anthralin, has been attributed to its action at the level of mitochondria or at the level of glucose-6-phosphate dehydrogenase which initiates the pentose phosphate shunt (cf. its prominent role in nucleic acid synthesis). Upon addition of 2.3 to 23 microM anthralin to the L cell culture, the characteristic structure of the anthralin anion fluorescence spectrum is recognized almost immediately in the cytoplasm (much weaker in the nucleus) but disappears within minutes. The vital mitochondrial fluorescence probe dimethylaminostyryl-pyridinium-methyl-iodine reveals striking structural alterations of the mitochondria within 15 min after addition of the drug. At the same time, there is a stimulation of the transient NAD(P)+ reduction observed upon microinjection into the L cell of the Krebs' cycle substrate malate, or the pentose cycle substrate 6-phosphogluconate. Specially, the injection of the latter to anthralin-treated cells suggests that upon release of the mitochondrial control, there is a tremendous disruption of metabolic activity which could have profound consequences on the proliferative activity of the cell. These findings, while they open new possibilities for the intracellular evaluation of therapeutic agents, create also a challenge in understanding the complex and dynamic interrelationships between intracellular organelles and bioenergetic or biosynthetic pathways.     

Efficiency of antigen presentation after antigen targeting to surface IgD, IgM, MHC, Fc gamma RII, and B220 molecules on murine splenic B cells

Bispecific heteroconjugate antibodies can bind soluble protein Ag to APC and thereby enhance Ag presentation. We used such antibodies to bind hen egg lysozyme (HEL) to various structures on the surface of normal splenic B cells to determine which structures would provide the best targets for enhanced presentation. We found that HEL was presented efficiently to hybridoma T cells if bound to sIgD, sIgM, or class I or II MHC molecules, but not at all if bound to Fc gamma RII, or B220 molecules on B cells. The efficiency of presentation of HEL was measured as a function of the amount of 125I-HEL bound per cell. HEL was presented with 5 to 10 times greater efficiency when bound to sIg, than when bound to MHC molecules. When compared on the basis of the amount of HEL bound, sIgD and sIgM functioned equally as target structures, as did class I and class II MHC molecules. Large amounts of HEL bound to B220, but no presentation resulted, indicating that focusing HEL to the APC surface was not sufficient for presentation to occur. HEL was internalized rapidly and in large amounts when bound to sIgD or sIgM, but slowly and in small amounts, when bound to class I or class II MHC molecules. Thus, a rapid rate of internalization may in part explain the high efficiency of Ag presentation after binding to sIg. However, the small amount of HEL internalized via MHC molecules was utilized efficiently for presentation. These results indicate that sIgM and sIgD serve equally on normal B cells to focus and internalize Ag and enhance Ag presentation, but that class I or class II MHC molecules can also be used to internalize Ag and enhance Ag presentation, perhaps by a separate intracellular processing pathway.     

Cycloheximide induces accumulation of vasoactive intestinal peptide (VIP) binding sites at the cell surface of a human colonic adenocarcinoma cell line (HT29-D4). Evidence for the presence of an intracellular pool of VIP receptors

Incubation of monolayers of HT29-D4 cells (a clone of the human colonic adenocarcinoma cell line HT29) in the presence of 17.5 microM cycloheximide resulted in an increase in the number of vasoactive intestinal peptide (VIP) binding sites at the cell surface without any change in the affinity of receptor for its ligand. The increase in 125I-VIP-binding capacity was dose-dependent between 0.35 microM and 17.5 microM cycloheximide and was correlated with the inhibition of protein biosynthesis. At higher concentrations of drug (17.5-100 microM) a plateau corresponding to a twofold increase in VIP-binding capacity was reached independently of the extent of protein synthesis inhibition. We found that VIP receptors of HT29-D4 cells with such an enhanced binding capacity behaved like those of control cells with respect to receptor internalization and recycling (i.e. the cycle of occupied receptors was insensitive to cycloheximide). After inactivation of 90% of cell-surface VIP receptors by alpha-chymotrypsin, we observed a biphasic kinetic of reappearance of VIP-binding sites. 40% of VIP-binding sites reappeared very quickly (less than 5 min) and 100% within 17 h. The fast recovery of VIP receptors was probably due to the deployment of new binding sites from an intracellular pool. The rate and extent of recovery of these receptors were similar in control cells and in cycloheximide-treated cells. However, the slow recovery was inhibited in cycloheximide-treated cells probably because a pool of immature receptors was depleted by the drug before the alpha-chymotrypsin treatment. Our data are consistent with the existence of two different intracellular pathways of occupied and unoccupied VIP receptors.     

Assessment of the distribution of nucleic acid intercalators in yeast cells by the pseudospectral image analysis

The intracellular location of nucleic acid intercalators (NAI) in live (not fixed) Saccharomyces cerevisiae cells has been studied using fluorescence microscopy combined with computer pseudospectral image analysis. Three NAI: the anthracycline anticancer drug doxorubicin and the nucleic acid dyes ethidium bromide (E) and 4',6-diamidino-2-phenylindole (DAPI) were used. All three NAI were shown to be localized in nuclei and mitochondria. In contrast to DAPI, which interacted only with DNA, a large fraction of doxorubicin and ethidium bromide apparently bound to mitochondrial membranes. Upon combined application, a competition between these intercalators for binding sites in the nuclear and mitochondrial DNA occurred. It was concluded that this approach may be used in designing new DNA-targeted drugs and in preliminary studies of their interaction with eukaryotic cells.     

Assessment of the distribution of nucleic acid intercalators in yeast cells by pseudospectral image analysis

The intracellular location of nucleic acid intercalators (NAI) in native (not fixed) Saccharomyces cerevisiae cells has been studied using fluorescence microscopy combined with computer pseudospectral image analysis. Three NAI: anthracycline anticancer drug doxorubicin and nucleic acid dyes ethidium bromide and 4′,6-diamidino-2-phenylindole (DAPI) were used. All three NAI were shown to be localized in nuclei and mitochondria. In contrast to DAPI, which interacted only with DNA, a large fraction of doxorubicin and ethidium bromide apparently bound to mitochondrial membranes. Upon combined application, competition between these intercalators for binding sites in the nuclear and mitochondrial DNA occurred. It was concluded that this approach may be used in designing new DNA-targeted drugs and in preliminary studies of their interaction with eukaryotic cells.     

Cation permeation through connexin 43 hemichannels is cooperative, competitive and saturable with parameters depending on the permeant species

Kinetics of permeation through connexin 43-EGFP hemichannels (Cx43-EGFP HCs) were evaluated in divalent cation-free solutions, which enhance HC open probability and thus, allow measurements during initial velocity. Three cations that become fluorescent upon binding to intracellular nucleic acids [ethidium (Etd), propidium (Prd) and 4′,6-diamidino-2-phenylindole (DAPI)] and Cx43-EGFP or Cx43 wild type HeLa cell transfectants (Cx43-EGFP- and Cx43-WT-HeLa cells, respectively) were used. Levels of Cx43-EGFP at the cell periphery and rate of dye uptake were directly related. The rate of uptake of each dye reached saturation consistent with a facilitated transport mechanism. Before saturation, the relation between rate of uptake and concentration of each dye was sigmoidal with Hill coefficients >1, indicating positive cooperativity of transport at low concentrations. The maximal rate of Etd uptake was not affected by the presence of DAPI and vice versa, but under each condition the apparent affinity constant of the main permeant molecule increased significantly consistent with competitive inhibition or competition for binding sites within the channel. Moreover, Cx43-EGFP and Cx43-WT HCs had similar permeability properties, indicating that EGFP bound to the C-terminal of Cx43 does not significantly alter the permeability of Cx43 HCs to positively charged molecules. Thus, competitive inhibition of permeation through hemichannels might contribute to cellular retention of essential molecules and/or uptake inhibition of toxic compounds.     

Cell-permeable peptides induce dose- and length-dependent cytotoxic effects

We have explored the threshold of tolerance of three unrelated cell types to treatments with potential cytoprotective peptides bound to Tat(48-57) and Antp(43-58) cell-permeable peptide carriers. Both Tat(48-57) and Antp(43-58) are well known for their good efficacy at crossing membranes of different cell types, their overall low toxicity, and their absence of leakage once internalised. Here, we show that concentrations of up to 100 microM of Tat(48-57) were essentially harmless in all cells tested, whereas Antp(43-58) was significantly more toxic. Moreover, all peptides bound to Tat(48-57) and Antp(43-58) triggered significant and length-dependent cytotoxicity when used at concentrations above 10 microM in all but one cell types (208F rat fibroblasts), irrespective of the sequence of the cargo. Absence of cytotoxicity in 208F fibroblasts correlated with poor intracellular peptide uptake, as monitored by confocal laser scanning fluorescence microscopy. Our data further suggest that the onset of cytotoxicity correlates with the activation of two intracellular stress signalling pathways, namely those involving JNK, and to a lesser extent p38 mitogen-activated protein kinases. These responses are of particular concern for cells that are especially sensitive to the activation of stress kinases. Collectively, these results indicate that in order to avoid unwanted and unspecific cytotoxicity, effector molecules bound to Tat(48-57) should be designed with the shortest possible sequence and the highest possible affinity for their binding partners or targets, so that concentrations below 10 microM can be successfully applied to cells without harm. Considering that cytotoxicity associated to Tat(48-57)- and Antp(43-58) bound peptide conjugates was not restricted to a particular type of cells, our data provide a general framework for the design of cell-penetrating peptides that may apply to broader uses of intracellular peptide and drug delivery.     

Study of localization and molecular interactions of biologically active compounds in living cells and tissue slices based on confocal microspectroscopy and reconstruction of the spectral images

The confocal spectral imaging (CSI) technique is described, its basic principles are considered, and a brief review of its applications to the study of biologically active compounds (BAC) within living cells and in tissue slices is presented. This technique is based on measurements and analysis of fluorescence or resonance Raman spectra in each point of the specimen under microscope with a three-dimensional resolution of about cubic micrometer. This technique is applicable to the study of stained fluorescent and nonfluorescent compounds. Unlike the conventional approaches based on the optical microscopy, the CSI technique opens the opportunity for the identification of complexes and microenvironment of BAC in intact cells and thin tissue slices (slices or sections), as well as for the analysis of localization and distribution of compounds of interest and their complexes in cellular organelles and tissue structures. The use of CSI technique in combination with the conventional biochemical and cytological methods makes it possible to significantly expand the informativeness of investigation of modes of action of new BAC.     

Structure, dynamics and hydration of the nogalamycin-d(ATGCAT)2Complex determined by NMR and molecular dynamics simulations in solution.

The structure of the 1:1 nogalamycin:d(ATGCAT)2 complex has been determined in solution from high-resolution NMR data and restrained molecular dynamics (rMD) simulations using an explicit solvation model. The antibiotic intercalates at the 5'-TpG step with the nogalose lying along the minor groove towards the centre of the duplex. Many drug-DNA nuclear Overhauser enhancements (NOEs) in the minor groove are indicative of hydrophobic interactions over the TGCA sequence. Steric occlusion prevents a second nogalamycin molecule from binding at the symmetry-related 5'-CpA site, leading to the conclusion that the observed binding orientation in this complex is the preferred orientation free of the complication of end-effects (drug molecules occupy terminal intercalation sites in all X-ray structures) or steric interactions between drug molecules (other NMR structures have two drug molecules bound in close proximity), as previously suggested. Fluctuations in key structural parameters such as rise, helical twist, slide, shift, buckle and sugar pucker have been examined from an analysis of the final 500 ps of a 1 ns rMD simulation, and reveal that many sequence-dependent structural features previously identified by comparison of different X-ray structures lie within the range of dynamic fluctuations observed in the MD simulations. Water density calculations on MD simulation data reveal a time-averaged pattern of hydration in both the major and minor groove, in good agreement with the extensive hydration observed in two related X-ray structures in which nogalamycin is bound at terminal 5'-TpG sites. However, the pattern of hydration determined from the sign and magnitude of NOE and ROE cross-peaks to water identified in 2D NOESY and ROESY experiments identifies only a few "bound" water molecules with long residence times. These solvate the charged bicycloaminoglucose sugar ring, suggesting an important role for water molecules in mediating drug-DNA electrostatic interactions within the major groove. The high density of water molecules found in the minor groove in X-ray structures and MD simulations is found to be associated with only weakly bound solvent in solution.     

Two classes of ouabain receptors in chick ventricular cardiac cells and their relation to (Na+,K+)-ATPase inhibition, intracellular Na+ accumulation, Ca2+ influx, and cardiotonic effect

The biochemical and pharmacological properties of the (Na+,K+)-ATPase have been studied at different stages of chick embryonic heart development in ovo and under cell culture conditions. The results show the existence of two families of ouabain binding sites: a low affinity binding site with a dissociation constant (Kd) of 2-6 microM for the ouabain-receptor complex and a high affinity binding site with a Kd of 26-48 nM. Levels of high affinity sites gradually decrease during cardiac ontogenesis to reach a plateau near 14 days of development. Conversely the number of low affinity binding sites is essentially invariant between 5 days and hatching. Cultured cardiac cells display the same binding characteristics as those found in intact ventricles. Inhibition of 86Rb+ uptake in cultured cardiac cells and an increase in intracellular Na+ concentration, due to (Na+,K+)-ATPase blockade, occur in a ouabain concentration range corresponding to the saturation of the low affinity ouabain site. Ouabain-stimulated 45Ca2+ uptake increases in parallel with the increase in the intracellular Na+ concentration. It is suppressed in Na+-free medium or when Na+ is replaced by Li+ suggesting that the increase is due to the indirect activation of the Na+/Ca2+ exchange system in the plasma membrane. Dose-response curves for the inotropic effects of ouabain on papillary muscle and on ventricular cells in culture indicate that the development of the cardiotonic properties is parallel to the saturation of the low affinity binding site for ouabain. Therefore, inhibition of the cardiac (Na+,K+)-ATPase corresponding to low affinity ouabain binding sites seems to be responsible for both the cardiotonic and cardiotoxic effects of the drug.     

The effect of CaCl2 and verapamil on the binding of cisplatin to cultures of normal and transformed human fibroblasts

Normal and transformed human fibroblasts were treated for either 1 sec or 1 h with the antitumor drug cis-dichlorodiamine platinum (cisplatin). The dose response of drug binding and cell survival was determined for cells treated with the drug in the presence or absence of 3.0 mM CaCl2. The levels of drug initially bound to both cell types was similar and was not affected by the presence of Ca2+. The dividing non-transformed cells were most sensitive to killing by short treatment with cisplatin compared to the transformed cells or the confluent non-transformed cultures. After 1 h of cisplatin treatment, the levels of drug bound to the cells were significantly less than that recovered after the shorter treatment. This time-dependent loss of cisplatin was inhibited both by CaCl2 and by the calcium channel blocking agent, verapamil. The higher levels of cisplatin bound after 1 h in the presence of these agents, however, did not in all cases result in decreased survival; the effects were dependent on cell type and on whether the cells were dividing or confluent. Analysis of cisplatin binding to cell cultures indicated that initially the cisplatin was weakly attached to the pericellular and substratum attached material but that with time, the drug bound to this material decreased. This time-dependent removal from the extracellular matrix was much less in the transformed cell cultures and was inhibited by calcium. We propose that the major site of interaction of cisplatin with these cells is in the extracellular matrix and with time the cultures alter their extracellular matrix to decrease this binding. This removal process appears to involve calcium or calcium transport since CaCl2 and verapamil both block these changes.     

Lipsome-formulated enzymes for organophosphate scavenging: butyrylcholinesterase and Demeton-S

Butyrylcholinesterase-encapsulating bioadhesive liposomes are investigated as prophylactic scavengers of organophosphates for local administration to skin, eyes, airways, and lungs-gates through which organophosphates penetrate living systems. The systems were optimized with respect to: encapsulation efficiency; type of bioadhesive ligand bound to liposomes (collagen or hyaluronan); ligand density at the liposomal surface; retention of encapsulated-enzyme activity; protection of encapsulated enzyme from proteolysis; and scavenging the model organophosphate Demeton-S (DS). Monolayers of PC-12 cells were selected for feasibility testing based on: high affinity binding of the bioadhesive liposomes-DeltaG0 release upon binding ranged from -9 to -12 kcal/mol ligand; ability to mimic an organophosphate attack upon intact cells and measuring its impact on intracellular acetylcholinesterase. Under attack, unprotected cells lost 80-90% of intracellular enzyme activity. The loss was reduced to 20-30% for protected cells (pre-treated with the formulations), at the expense of liposomal Butyrylcholinesterase. These results support our prophylactic approach.     

Single-cell partition analysis—A direct fluorescence technique for examining ligand-macromolecule interactions

Single-cell partition analysis is described as a novel technique for examining ligand-macromolecule interactions. This procedure is a combination of the classical fluorescence titration technique and phase-partition techniques and allows three separate methods for calculating and comparing both free and bound drug concentrations. The value of this technique is demonstrated by the comparison of the binding properties of the potent antitumor antibiotic adriamycin and ethidium bromide to nucleic acids. Binding isotherms of both drugs were obtained at low r (concentration of bound drug per base pair) values, showing strikingly different results, thus allowing insight to be gained into the cooperative binding of these drugs to DNA.     

Characterization of the binding of S-adenosyl-L-methionine to plasma membranes of HL-60 promyelocytic leukemia cells

S-Adenosyl-L-methionine (AdoMet) has been found to bind specifically to the plasma membrane of promyelocytic leukemia cells, HL-60. The Kd for AdoMet is 4.2.10(-6) M and the Bmax is 4.0.10(-12) mol/10(7) HL-60 cells. The binding is not related to the adenosine receptor since neither adenosine, ADP, nor ATP affect the ligand-receptor reaction. When HL-60 cells were incubated with physiological concentrations of [methyl-3H]AdoMet (20 microM) at 36 degrees C, AdoMet did not equilibrate with the intracellular pool, nor were any [3H]methyl groups incorporated into nucleic acids or proteins. In contrast, significant amounts of [3H]methyl groups were incorporated into membrane phospholipids. When cells were incubated with 20 microM [methyl-3H]AdoMet, [3H]methyl groups were transferred to phosphatidylethanolamine, -monomethylethanolamine, and -dimethylethanolamine yielding phosphatidylcholine. However, the rate of methyl transfer with AdoMet was only 22% of that observed when cells were incubated with a comparable amount of [methyl-3H]methionine. Both the binding of AdoMet and the methylation of phospholipids were inhibited by exogenous S-adenosyl-L-homocysteine. Therefore, the binding may be linked to a phospholipid methyltransferase.     

Fasciola hepatica: action in vitro of triclabendazole on immature and adult stages

Under in vitro conditions in a balanced salt solution, triclabendazole was found to accumulate in significant amounts in both immature (3 week old) and adult Fasciola hepatica. A viable parasite was needed to concentrate the drug, but a high percentage of the compound was also bound by the dead worm. The drug could penetrate into liver flukes even when the oral route had been closed off by ligation, indicating that the drug can be taken up by transtegumentary absorption. A 24 hr exposure to triclabendazole, at 10-25 microM concentrations, was found to result in a strong inhibition of the parasite's motility. This effect was paralleled by dramatic changes in the worm's resting tegumental membrane potential. The onset of these actions was found to develop very slowly, and high drug levels had to accumulate within the parasite to initiate its immobilization. In addition to drug concentration and incubation time, physiological alterations observed were also dependent on other culture conditions, such as the presence or absence of serum albumin and the drug tissue/medium ratio. Biochemical examinations showed that triclabendazole significantly stimulated glucose derived acetate and propionate formation by adult liver flukes. Adenosine triphosphate levels were not changed even in the presence of high triclabendazole concentrations (25 microM). Likewise, the activities of various membrane associated adenosine triphosphatases were not altered by the drug. However, the ability of the drug to inhibit colchicine binding to microtubular protein purified from adult liver flukes suggested an interference of the drug with microtubular structure and function.(ABSTRACT TRUNCATED AT 250 WORDS)