Multiple routes and regulation by tyrosine phosphorylation characterize the ATP-dependent transport of 2,4-dinitrophenyl S-glutathione in inside-out vesicles from human erythrocytes.

ATP-dependent efflux routes for 2,4-dinitrophenyl S-glutathione (DNP-SG) were investigated using inside-out vesicles from human erythrocytes. Nonlinear double-reciprocal plots of transport at substrate concentrations ranging from 0.07 to 500 micro;m indicated that multiple transport routes were operative. Sensitivity to naphthyl glucuronide separated [3H]DNP-SG transport into two low-affinity components which by computer analysis exhibited Km values of 330 and 1400 micro;m, respectively. At low substrate concentrations, two high-affinity routes were observed. The predominant activity (hMOAT3a) exhibited a Km of 0.18 micro;m (Vmax = 22 pmol/min/mg protein), whereas the second activity (MOAT3b) had a Km of 0.58 micro;m (Vmax = 16 pmol/min/mg protein). High-affinity transport of DNP-SG increased substantially (2.5-fold) in vesicles preincubated with genistein or other tyrosine kinase inhibitors. Kinetic analyses in vesicles pretreated with 50 micro;m genistein showed that increased transport resulted from the appearance of a new activity (hMOAT3c) with a Km of 0.85 micro;m and a substantially elevated Vmax (80 pmol/min/mg protein). At varying concentrations of genistein, a progression was observed that was consistent with the conversion of hMOAT3b to hMOAT3a and hMOAT3a to hMOAT3c. Phenylarsine oxide, a phosphotyrosine phosphatase inhibitor, produced an opposite progression. Specificity studies showed that hMOAT3a exhibited the highest affinity for various anionic conjugates, and had a notable binding preference for glutathione disulfide. The relative effectiveness of the various inhibitors was similar for hMOAT3a, hMOAT3b, and hMOAT3c, as well as for a corresponding mMOAT3 activity from L1210 mouse cells. The results show that human erythrocytes contain multiple ATP-dependent efflux systems for DNP-SG and that separation of these systems can be achieved on the basis of substrate Km value and inhibitor and activator specificity. High-affinity transport can proceed via three activities which appear to be subforms of a single system with differing levels of tyrosine phosphorylation. Multiple hMOAT3 subforms provide flexibility for extruding various anionic conjugates and may have evolved in erythrocytes to expedite the efflux of GS-SG.

MOAT4, a novel multispecific organic-anion transporter for glucuronides and mercapturates in mouse L1210 cells and human erythrocytes.

Glucuronides and mercapturates were examined as possible high-affinity substrates for a low-affinity ATP-dependent transport system for 2,4-dinitrophenyl S-glutathione (DNP-SG) in mouse L1210 cells. Initial inhibitor studies with inside-out vesicles revealed that the low-affinity transport of [3H]DNP-SG (Km 450 microM) exhibits a high sensitivity to N-acetyl 2,4-dinitrophenyl cysteine (NAc-DNP-Cys) (Ki 5.0 microM) and alpha-naphthyl beta-D-glucuronide (naphthyl glucuronide) (Ki 8.5 microM). Direct transport measurements showed the presence of ATP-dependent uptake activities for NAc-DNP-[35S]Cys and naphthyl [14C] glucuronide, and Km values for half-maximal transport were comparable to the Ki values of these compounds for inhibition of [3H]DNP-SG transport. Transport of [3H]DNP-SG, NAc-DNP-[35S]Cys and naphthyl [14C]glucuronide each showed the same sensitivity to various anions and anion conjugates. Inhibition was competitive and was most potent for bilirubin ditaurate, indoprofen, 4-biphenylacetic acid, 4-acridine 4 beta-D-glucuronide, N-acetyl leukotriene E4, 17 beta-oestradiol 3 beta-D-glucuronide and taurolithocholate 3-sulphate. Inside-out vesicles from human erythrocytes contain a comparable ATP-dependent transport system. These results show that NAc-DNP-Cys and naphthyl glucuronide are high-affinity substrates for a single system identified previously as a low-affinity transporter of DNP-SG. Substrate and inhibitor studies identify this system as a novel multispecific organic-anion transport system (MOAT4) that accommodates glucuronides and mercapturates and is distinct from other MOAT transporters. Human erythrocytes contain an additional ATP-dependent system for NAc-DNP-Cys (Km 33 microM) that does not transport monoglucuronides.

Identification of efflux systems for large anions and anionic conjugates as the mediators of methotrexate efflux in L1210 Cells.

Two ATP-dependent efflux systems for methotrexate have been identified in inside-out vesicles from an L1210 mouse cell variant with a defective influx carrier for methotrexate. Transport at 40 muM [3H]methotrexate was separated by inhibitors into two components comprising 62 and 38% of total transport activity. The predominant route was inhibited by low concentrations of indoprofen (Ki=2.5 muM, 4-biphenylacetic acid (Ki=5.3 muM), and flurbiprofen (Ki=5.2 muM, whereas the second component showed a high sensitivity to the glutathione conjugates of bromosulfophthalein (Ki=0.08 muM), ethacrynic acid (Ki=0.52 muM, and 1-chloro-2,4-dinitrobenzene (Ki=0.77 muM). Bilirubin ditaurate was a potent inhibitor of both transport components (Ki=1.5 and 0.17 muM, respectively). Separation of transport activities without interference from the other route was achieved by adding an excess (100 muM) of either the glutathione conjugate of ethacrynic acid or biphenylacetic acid. Double-reciprocal plots of transport at various substrate concentrations gave Km values of 170 and 250 muM for methotrexate transport via the anion-sensitive and conjugate-sensitive routes, respectively. A comparison of inhibitor specificities indicated that the anion-sensitive transport activity in vesicles represents efflux system II for methotrexate in intact cells and is the same system identified previously in vesicles as an anion/anion conjugate pump. The conjugate-sensitive activity corresponds to efflux system I for methotrexate in intact cells and is the same system identified in vesicles as the high-affinity glutathione conjugate pump.

5'-Cholesteryl-phosphorothioate oligodeoxynucleotides: potent inhibition of methotrexate transport and antagonism of methotrexate toxicity in cells containing the reduced-folate carrier.

Polyanionic 5'-cholesteryl-phosphorothioate oligodeoxynucleotides of varying polymer length and nucleobase composition were examined for an effect on methotrexate transport via the reduced-folate carrier of L1210 mouse cells. Methotrexate transport was inhibited by each of the oligodeoxynucleotide analogs tested. Inhibition was most pronounced (IC50 = 0.21 microM, standard assay) for a 5'-cholesteryl heteropolymer consisting of 15 phosphorothioate deoxynucleotides with alternating deoxycytosine and deoxyadenosine (Chol-PS-d(CA)7C). Homopolymers with 15 deoxycytosine (Chol-PS-dC15) or deoxythymidine (Chol-PS-dT15) residues were approximately 2-fold less inhibitory than Chol-PS-d(CA)7C. The relative potency of transport inhibition by deoxycytosine oligomers of varying length was: Chol-PS-dC5 > Chol-PS-dC15 > Chol-PS-dC28 > Chol-PS-dC3. Substantial inhibition was retained in cells preincubated with inhibitors and washed prior to transport determinations and the inhibitor sensitivity could be increased substantially by reducing the concentration of cells. Mixed competitive and non-competitive inhibition was observed for each analog. In standard high-folate medium, Chol-PS-oligodeoxynucleotides (5.0 microM) had minimal effects on the growth of L1210 cells, but antagonized the cytotoxicity of methotrexate. The response to methotrexate (IC50 = 12 nM) decreased to the greatest extent (20.8-fold) in the presence of Chol-PS-d(CA)7C (IC50 = 250 nM). Under limiting folate conditions, Chol-PS-d(CA)7C alone inhibited cells growth by a process which could be reversed by folic acid. The results show that Chol-PS-oligodeoxynucleotides are among the most potent known inhibitors of the reduced-folate carrier. Direct growth inhibition of folate-deficient cells and antagonism of methotrexate cytotoxicity indicate that Chol-PS-oligodeoxynucleotides retain the ability to inhibit the reduced-folate carrier for several days in cultured cells.

Suramin sodium: pronounced effects on methotrexate transport and anti-folate activity in cultured tumor cells.

Suramin is an experimental anti-neoplastic agent which has shown promising activity against prostatic carcinoma and lymphoma in clinical trials. To elucidate its mechanism of action, suramin was examined for an effect on the transport of folate compounds by tumor cells. Influx of the anti-folate methotrexate via the reduced-folate carrier system of CCRF-CEM cells was found to be highly sensitive to inhibition by suramin but not to various other arylsulfonic acids. Inhibition by suramin was competitive, and the inhibition constant Ki was 1.3 microM, a value 3-fold lower than the Kt for half-maximal influx of methotrexate. Folate binding to the membrane-associated folate-binding protein of KB cells was not affected by suramin. Growth studies revealed that the response of human CCRF-CEM, KB, PC-3 and MCF-7 cells to methotrexate was antagonized from 6- to 17-fold by pharmacological levels (10-200 microM) of suramin. Conversely, growth inhibition was additive or synergistic when suramin was combined with metoprine, a lipophilic anti-folate which enters cells by diffusion. Synergism was observed between metoprine and suramin in CCRF-CEM cells, which take up folate exclusively through the reduced-folate carrier (inhibitable by suramin), whereas additivity was observed for KB cells, which rely largely on the folate-binding protein (unaffected by suramin) for folate import. Our results indicate that inhibition of cellular transport of folate compounds may explain part of the anti-neoplastic effects of suramin on tumor cells.

ATP-dependent efflux of 2,4-dinitrophenyl-S-glutathione. Properties of two distinct transport systems in inside-out vesicles from L1210 cells and a variant subline with altered efflux of methotrexate and cholate.

The transport of 2,4-dinitrophenyl-S-glutathione (DNP-SG) into inside-out vesicles from L1210 cells was employed to identify and characterize ATP-dependent efflux routes for DNP-SG. Measurements of ATP-dependent uptake at varying concentrations of [3H]DNP-SG revealed the presence of two distinct transport systems. Transport at low substrate concentrations occurred predominantly via a high affinity system (Km = 0.63 microM), whereas a low affinity system (Km = 450 microM) predominated at high concentrations of substrate. The high affinity system was characterized by a potent inhibition by the glutathione conjugates of bromosulfophthalein (Ki = 0.09 microM) and ethacrynic acid (Ki = 0.44 microM), leukotriene C4 (Ki = 0.20 microM), and the taurate diconjugate of bilirubin (Ki = 0.10 microM). The low affinity transport system for DNP-SG exhibited a high affinity for bilirubin ditaurate (Ki = 1.8 microM), indoprofen (Ki = 3.0 microM), and biphenylacetic acid (Ki = 5.9 microM). Different results were obtained with an L1210/C7 variant which has a defect in the efflux of methotrexate and cholate. Vesicles from the latter cells contain the same low affinity transport activity as parental cells, but the high affinity route is absent and has been replaced by a system with an intermediate affinity for DNP-SG (Km = 4.5 microM). These results indicate that L1210 cells contain two unidirectional efflux pumps for DNP-SG with substantial differences in inhibitor sensitivity. The high affinity system shows a binding preference for glutathione conjugates but can also accommodate large anionic conjugates, whereas the low affinity system has a binding preference for large organic anions. Results with the variant cells support the hypothesis that the high affinity transport system for DNP-SG also mediates the unidirectional efflux of methotrexate and cholate in intact L1210 cells.

Distinct systems mediate the unidirectional efflux of methotrexate and cholate in human CCRF-CEM cells.

Human CCRF-CEM cells were shown to contain energy-dependent and unidirectional efflux systems for the extrusion of methotrexate and cholate. Efflux activity was sensitive to temperature and to energy deprivation by treatment with antimycin A and to various other compounds which do not affect energy metabolism. A comparison of inhibitor sensitivities revealed that methotrexate and cholate efflux exhibit substantial differences in half-maximal inhibition (IC50) by indomethacin, reserpine, ethacrynic acid, ketoprofen, probenecid, and bromosulfophthalein, although these systems could not be distinguished by their responses to prostaglandin A1, meclofenamic acid, indoprofen, and biphenylacetic acid. Comparisons between cell lines showed that methotrexate efflux in CCRF-CEM cells exhibits an inhibitor response comparable to a secondary efflux system for methotrexate in L1210 cells (system II), whereas the inhibitor response of cholate efflux in CCRF-CEM cells resembles efflux system I in L1210 cells, the primary efflux route for both methotrexate and cholate. These results indicate that CCRF-CEM cells contain similar but separate systems for the efflux of methotrexate and cholate. CCRF-CEM cells thus differ from L1210 cells in that the latter mediate the efflux of methotrexate and cholate primarily via a single system.

Functional implications from the effects of 1-chloro-2,4-dinitrobenzene and ethacrynic acid on efflux routes for methotrexate and cholate in L1210 cells.

1-Chloro-2,4-dinitrobenzene (CDNB) and ethacrynic acid were examined for the ability to inhibit unidirectional efflux routes in L1210 cells that extrude both methotrexate and cholate (system I) and methotrexate alone (system II). These electrophiles were selected for study because of their known ability to undergo rapid intracellular conversion to glutathione conjugates. CDNB produced typical inhibitor kinetics and was a moderate inhibitor of both system I (IC50 = 4.8 microM) and system II (IC50 = 7.5 microM) with methotrexate as the substrate. However, a complex response was observed when cholate was employed as an alternative substrate for system I. Cholate efflux was stimulated initially at low levels of CDNB, but then slowed to a net inhibition as CDNB concentrations exceeded 10 microM. The latter characteristics for CDNB were not observed with ethacrynic acid, which produced a comparable inhibition of efflux system I regardless of the substrate employed (IC50 = 4.6 microM). Efflux measurements in an L1210/C7 variant which lacks system I confirmed that CDNB stimulates the activity of a substantial and unique efflux activity for cholate (system III). The inhibition of system I and II by CDNB and ethacrynic acid was not reversed by a wash step but required inhibitor removal and subsequent incubation at 37 degrees C. This slow reversal was attributed to a time-dependent clearance of inhibitory glutathione conjugates. A correlation between efflux systems for anions and anionic glutathione conjugates was demonstrated further by the ability of prostaglandin A1 and indomethacin, two potent inhibitors of methotrexate and cholate efflux, to inhibit the efflux of 2,4-dinitrophenyl-S-glutathione. These results support the hypothesis that efflux systems for methotrexate and cholate in L1210 cells are part of a family of efflux pumps which function in vivo to extrude various anions and anionic glutathione conjugates.

Altered expression of unidirectional extrusion routes for methotrexate and cholate in an efflux variant of L1210 cells.

The specificity and function of two unidirectional anion-efflux pumps in mouse L1210 cells were evaluated using a variant cell line selected for growth in the presence of cholate and bromosulfophthalein. Transport analysis revealed that cholate efflux in the variant L1210/C7 cell line had declined 8-fold, due to the loss of a bromosulfophthalein-sensitive efflux system, the major extrusion route for cholate in parental cells. Efflux measurements showed further that a bromosulfophthalein-sensitive efflux system for methotrexate was also absent in L1210/C7 cells. Total unidirectional efflux of methotrexate, however, was similar in the variant and parental cells, since the loss in the bromosulfophthalein-sensitive system was compensated by a rise in a second probenecid-sensitive route. The latter was identified from inhibitor studies to be the same system which acts as a minor efflux route for methotrexate in parental cells. These results support the hypothesis that L1210 cells contain a bromosulfophthalein-sensitive efflux system which mediates the unidirectional extrusion of either methotrexate or cholate, and a second probenecid-sensitive route which differs from the bromosulfophthalein-sensitive system in inhibitor specificity and also in its ability to transport methotrexate but not cholate.

Separation and inhibitor specificity of a second unidirectional efflux route for methotrexate in L1210 cells.

L1210 cells mediate the unidirectional and energy-dependent efflux of methotrexate. Efflux occurs primarily via a system which has a high sensitivity to prostaglandin A1, vincristine, reserpine, verapamil, and bromosulfophthalein, but evidence has also been obtained for a second efflux component with a lower response to these inhibitors. Pretreatment of L1210 cells with low concentrations of vincristine reduces methotrexate efflux by three fold and uncovers a second efflux component with an inhibitor specificity which is distinctly different from the primary efflux route. Vincristine treatment increased by 8-20-fold the concentration required for half-maximal efflux inhibition by prostaglandin A1, reserpine, bromosulfophthalein, and verapamil but had no effect on inhibition by probenecid, quinidine, or carbonylcyanide m-chlorophenylhydrazone. A selective block in the primary efflux system and retention of the second component was also achieved in cells exposed to low concentrations of prostaglandin A1 or bromosulfophthalein. These results support prior conclusions that L1210 cells contain both a primary and secondary unidirectional efflux route for methotrexate. The second system has been difficult to detect and quantitate since it comprises only 25% of total unidirectional efflux and shows a relatively low response to various efflux inhibitors.

Effects of trypanothione on the biological activity of irradiated transforming DNA.

Held et al. (1984a,b) demonstrated previously that glutathione (GSH), a negatively charged thiol, is significantly less efficient in the hydrogen atom donation repair reaction with radicals induced by radiation in transforming DNA (t-DNA) than are other thiol compounds. Fahey et al. (1991a,b) postulated that the charge on thiols can influence their ability to radioprotect DNA. GSH, which is excluded from the vicinity of DNA due to its negative charge, is less protective than neutral or positively charged thiols. We have investigated this phenomenon further with trypanothione, the conjugate of glutathione and spermidine, N1,N8-bis (L-gamma-glutamyl-L-hemicystinyl-glycyl)-spermidine. Trypanothione exists in aerobic solution largely as the disulphide (T(S)2) but is maintained in the cell in the reduced form (T(SH)2) by means of an NADPH-dependent flavo-enzyme, trypanothione reductase (TR). Experimental data show that T(S)2 in the presence of TR radioprotects t-DNA in the absence of oxygen much better than GSH or spermidine alone or in combination. Little radioprotection by T(S)2 is seen when TR is not present. The results obtained with reduced trypanothione at low concentrations suggest that radioprotection of t-DNA in hypoxia occurs predominantly by H atom donation and slightly by .OH radical scavenging, and the protection is greater than that by GSH or spermidine because the polyamine moiety in trypanothione allows a greater concentration of GSH near the DNA molecule.

Cloning, sequencing, and demonstration of polymorphism in trypanothione reductase from Crithidia fasciculata.

Trypanothione reductase (TR) is a target for drug design since it is unique to trypanosomatids, substituting for the otherwise ubiquitous enzyme, glutathione reductase. We report the cloning and sequencing of several cDNAs and genes encoding Crithidia fasciculata TR, the structure of which has recently been solved by crystallography. Single base polymorphisms are detected in cDNAs (containing 80% of the coding sequence) and two different genomic clones, including a glutamine to glutamate change in the C-terminal region of the TR coding region; other nucleotide changes are silent. Homology (from genomic clones, both of which contained signals appropriate for expression) to the Trypanosoma congolense gene was 63% at the nucleic acid level, with 68% amino acid identity; the significance of homologies to human and Escherichia coli glutathione reductase sequences is discussed. Polymorphic sites in the genomic clones included sites found in the cDNAs, indicating that differences existing in the genomic sequence are real, and propagated to RNA.

Engineering the substrate specificity of glutathione reductase toward that of trypanothione reduction.

Glutathione reductase (EC 1.6.4.2; CAS registry number 9001-48-3) and trypanothione reductase (CAS registry number 102210-35-5), which are related flavoprotein disulfide oxidoreductases, have marked specificities for glutathione and trypanothione, respectively. A combination of primary sequence alignments and molecular modeling, together with the high-resolution crystal structure of human glutathione reductase, identified certain residues as potentially being responsible for substrate discrimination. Site-directed mutagenesis of Escherichia coli glutathione reductase was used to test these predictions. The mutation of Asn-21 to Arg demonstrated that this single change was insufficient to generate the greater discrimination against trypanothione shown by human glutathione reductase compared with the E. coli enzyme. However, the mutation of Ala-18, Asn-21, and Arg-22 to the amino acid residues (Glu, Trp, and Asn, respectively) in corresponding positions in Trypanosoma congolense trypanothione reductase confirmed that this region of polypeptide chain is intimately involved in substrate recognition. It led to a mutant form of E. coli glutathione reductase that possessed essentially no activity with glutathione but that was able to catalyze trypanothione reduction with a kcat/Km value that was 10% of that measured for natural trypanothione reductases. These results should be of considerable importance in the design of trypanocidal drugs targeted at the differences between glutathione and trypanothione metabolism in trypanosomatids and their hosts.

X-ray structure of trypanothione reductase from Crithidia fasciculata at 2.4-A resolution.

Trypanosomes and related protozoan parasites lack glutathione reductase and possess instead a closely related enzyme that serves as the reductant of a bis(glutathione)-spermidine conjugate, trypanothione. The human and parasite enzymes have mutually exclusive substrate specificities, providing a route for the design of therapeutic agents by specific inhibition of the parasite enzyme. We report here the three-dimensional structure of trypanothione reductase from Crithidia fasciculata and show that it closely resembles the structure of human glutathione reductase. In particular, the core structure surrounding the catalytic machinery is almost identical in the two enzymes. However, significant differences are found at the substrate binding sites. A cluster of basic residues in glutathione reductase is replaced by neutral, hydrophobic, or acidic residues in trypanothione reductase, consistent with the nature of the spermidine linkage and the change in overall charge of the substrate from -2 to +1, respectively. The binding site is more open in trypanothione reductase due to rotations of about 4 degrees in the domains that form the site, with relative shifts of as much as 2-3 A in residue positions. These results provide a detailed view of the residues that can interact with potential inhibitors and complement previous modeling and mutagenesis studies on the two enzymes.

Hemoglobin degradation in the human malaria pathogen Plasmodium falciparum: a catabolic pathway initiated by a specific aspartic protease.

Hemoglobin is an important nutrient source for intraerythrocytic malaria organisms. Its catabolism occurs in an acidic digestive vacuole. Our previous studies suggested that an aspartic protease plays a key role in the degradative process. We have now isolated this enzyme and defined its role in the hemoglobinolytic pathway. Laser desorption mass spectrometry was used to analyze the proteolytic action of the purified protease. The enzyme has a remarkably stringent specificity towards native hemoglobin, making a single cleavage between alpha 33Phe and 34Leu. This scission is in the hemoglobin hinge region, unraveling the molecule and exposing other sites for proteolysis. The protease is inhibited by pepstatin and has NH2-terminal homology to mammalian aspartic proteases. Isolated digestive vacuoles make a pepstatin-inhibitable cleavage identical to that of the purified enzyme. The pivotal role of this aspartic hemoglobinase in initiating hemoglobin degradation in the malaria parasite digestive vacuoles is demonstrated.

Purification and characterization of dihydroorotate dehydrogenase from the rodent malaria parasite Plasmodium berghei.

Dihydroorotate dehydrogenase (DHODase) has been purified 400-fold from the rodent malaria parasite Plasmodium berghei to apparent homogeneity by Triton X-100 solubilization followed by anion-exchange, Cibacron Blue F3GA-agarose affinity, and gel filtration chromatography. The purified enzyme has a molecular mass of 52 +/- 2 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and of 55 +/- 6 kDa by gel filtration chromatography, and it has a pI of 8.2. It is active in monomeric form, contains 2.022 mol of iron and 1.602 acid-labile sulfurs per mole of enzyme, and does not contain a flavin cofactor. The purified DHODase exhibits optimal activity at pH 8.0 in the presence of the ubiquinone coenzyme CoQ6, CoQ7, CoQ9, or CoQ10. The Km values for L-DHO and CoQ6 are 7.9 +/- 2.5 microM and 21.6 +/- 5.5 microM, respectively. The kcat values for both substrates are 11.44 min-1 and 11.70 min-1, respectively. The reaction product orotate and an orotate analogue, 5-fluoroorotate, are competitive inhibitors of the enzyme-catalyzed reaction with Ki values of 30.5 microM and 34.9 microM, respectively. The requirement of the long-chain ubiquinones for activity supports the hypothesis of the linkage of pyrimidine biosynthesis to the electron transport system and oxygen utilization in malaria by DHODase via ubiquinones [Gutteridge, W. E., Dave, D., & Richards, W. H. G. (1979) Biochim. Biophys. Acta 582, 390-401].

An iron-carboxylate bond links the heme units of malaria pigment.

The intraerythrocytic malaria parasite uses hemoglobin as a major nutrient source. Digestion of hemoglobin releases heme, which the parasite converts into an insoluble microcrystalline material called hemozoin or malaria pigment. We have purified hemozoin from the human malaria organism Plasmodium falciparum and have used infrared spectroscopy, x-ray absorption spectroscopy, and chemical synthesis to determine its structure. The molecule consists of an unusual polymer of hemes linked between the central ferric ion of one heme and a carboxylate side-group oxygen of another. The hemes are sequestered via this linkage into an insoluble product, providing a unique way for the malaria parasite to avoid the toxicity associated with soluble heme.

Evidence for cAMP and cholate extrusion in C6 rat glioma cells by a common anion efflux pump.

C6 rat glioma cells were investigated for a shared unidirectional efflux system for cAMP and cholate. [3H]Cholate was accumulated (at pH 7.3) by scraped C6 cell monolayers via a process which was rapid initially and then slowed to a steady state after 10 min at 37 degrees C. Release of the accumulated label was also rapid (t1/2 = 2 min), was essentially complete within 15 min, and exhibited energy dependence since it could be blocked by antimycin A. Half-maximal inhibition by antimycin A occurred at 0.87 microM, and maximal inhibition exceeded 90%. Various other compounds also inhibited [3H]cholate efflux. The most effective was prostaglandin A1, which reduced efflux half-maximally at a concentration of 0.14 microM. Other inhibitors, prostaglandin B1, verapamil, probenecid, and bromosulfophathalein, produced half-maximal inhibition at 5.3, 42, 78, and 110 microM, respectively. Cholate efflux was also blocked by 40 microM vincristine. Initial influx of [3H]cholate was not affected by antimycin A, prostaglandin A1, or vincristine and hence was attributed to a process separate from efflux. C6 rat glioma cells also have the ability to produce high intracellular levels of cAMP in response to isoproterenol and to release cAMP into the medium via a carrier-mediated efflux system. When measured under the same conditions employed for cholate efflux, the efflux of cAMP was found to be sensitive to each of the inhibitors of cholate efflux. Moreover, plots of cAMP efflux versus varying concentrations of prostaglandin A1, antimycin A, prostaglandin B1, verapamil, and probenecid showed similar response curves and comparable values for half-maximal These results indicate that C6 rat glioma cells contain a unidirectional efflux pump for cholate and that this same system also appears to mediate the unidirectional efflux of cAMP. These findings support the hypothesis that various cells contain efflux pumps which exhibit a broad specificity for large organic anions of diverse structure and that the function of these efflux pumps resides primarily in cellular anion detoxification. Analogous efflux pumps for hydrophobic drugs are overproduced in tumor cells exhibiting multidrug resistance.

Preliminary crystallographic analysis of trypanothione reductase from Crithidia fasciculata.

Trypanothione reductase, a flavoprotein disulfide reductase specific to trypanosomatid parasites, has been crystallized by vapor diffusion of a protein solution (10 mg/ml) against 22% polyethylene glycol (average Mr 8000) containing 100 mM-ammonium sulfate. Crystals of a size suitable for structure determination by X-ray diffraction have been obtained by seeding protein solutions with smaller crystals. The space-group is P21 (a = 60.9 A, b = 161.8 A, c = 58.4 A, beta = 99.1 degrees). The molecular mass and volume of the unit cell suggest that there is a dimer of the enzyme in the asymmetric unit, and this is confirmed by self-rotation functions calculated using data to 4.5 A resolution. The crystals diffract to beyond 3 A resolution. Crystals of another P21 form (a = 91.3 A, b = 114.4 A, c = 92.0 A, beta = 141.3 degrees) are observed to grow under similar conditions.

Pyrimidine biosynthesis in parasitic protozoa: purification of a monofunctional dihydroorotase from Plasmodium berghei and Crithidia fasciculata.

Dihydroorotase (DHOase) catalyzes the reversible cyclization of N-carbamoyl-L-aspartate (L-CA) to L-5,6-dihydroorotate (L-DHO), which is the third enzyme in de novo pyrimidine biosynthesis. The enzyme was purified from two parasitic protozoa, Crithidia fasciculata (about 16,000-fold) and Plasmodium berghei (about 790-fold). The C. fasciculata enzyme had a native molecular weight (Mr) of 42,000 +/- 5000, determined by gel filtration chromatography, and showed a single detectable protein band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) with Mr 44,000 +/- 3000. The DHOase from P. berghei had a native molecular weight of 40,000 +/- 4000 and a subunit molecular weight on SDS-PAGE of 38,000 +/- 3000. The DHOase from both parasites, in contrast to the mammalian enzyme which resides on a trifunctional protein of the first two enzymes of the pathway, carbamoyl-phosphate synthase and aspartate transcarbamylase, is monomeric and has no oligomeric structure as studied by chemical cross-linking with dimethyl suberimidate. The rate of cyclization of L-CA by the C. fasciculata enzyme was relatively high at acidic pH, decreasing to a very low rate at alkaline pH. In contrast, the rate of ring cleavage of L-DHO was very low at acidic pH and increased to a higher rate at alkaline pH. These pH-activity profiles gave an intersection at pH 6.6. The Km and kcat for L-CA were 0.846 +/- 0.017 mM and 39.2 +/- 6.4 min-1, respectively; for L-DHO, they were 25.85 +/- 2.67 microM and 258.6 +/- 28.5 min-1.(ABSTRACT TRUNCATED AT 250 WORDS)