Hydrogen peroxide cytotoxicity under conditions of normal or reduced catalase activity in H2O2-sensitive and -resistant Chinese hamster ovary (CHO) cell variants

H2O2-sensitive and -resistant sublines of Chinese Hamster Ovary (CHO) cells were tested for their sensitivity to the growth inhibitory effect elicited by increasing concentrations of the oxidant under conditions of normal or reduced catalase activity. Experimental results have demonstrated that, under conditions of reduced catalase activity, the cytotoxic action of H2O2 was differentially regulated in resistant and sensitive cells. Indeed, the parental cell line and cells resistant to low concentrations of H2O2 (V 250 cells) depended on catalase to a lower extent than did highly resistant cells (V 850 cells). It is interesting to note that V 250 cells had more catalase, on a per million cell basis, than V 850 cells. We conclude that acquired resistance to oxidative stress is not entirely dependent on catalase and that the contribution of catalase depends on the degree of resistance to the oxidant.     

Human immunodeficiency virus type 1 proteinase resistance to symmetric cyclic urea inhibitor analogs

Resistant virus was isolated from virus propagated in cell culture in the presence of the human immunodeficiency virus type 1 (HIV-1) proteinase inhibitor DMP 323, Ro 31-8959, or A-75925. The proteinase gene of resistant virus was sequenced, and key mutations (G48V, V82A, I84V, L90M, and G48V/L90M) were introduced into clones used for the expression, purification, and further characterization of the enzyme. The mutant enzymes were all less active than the wild-type enzyme, as judged by k(cat) and k(cat)/Km values. L90M had a lower Km than the wild type, whereas the G48V/L90M double mutant had an increased Km compared with that of the wild type, contributing to a 10-fold reduction in the k(cat)/Km. Vitality values were used to show that the enzyme of the I84V mutant is the enzyme most resistant to the two cyclic urea inhibitors DMP 323 and AHA 008. Virus with the same mutation is also resistant, although the double mutation L10F/I84V confers even greater resistance. All of these mutants are more resistant to DMP 323 than to AHA 008. The resistance of the I84V mutant may be attributed to a loss of van der Waals interactions with the inhibitor, since the larger amino acid side chain involved in the interaction is replaced by a smaller side chain. This is supported by the lower level of resistance to AHA 008 that was observed. The phenyl groups of AHA 008 should protrude deeper into the S1 and S1' subsites than those of the smaller compound DMP 323, reducing the loss of interaction energy. These results reveal that small structural modifications of inhibitors that do not affect the inhibitory effect on wild-type virus can influence the inhibition of resistant strains. This is of importance for optimizing drugs with respect to their potency and resistance.     

Mechanisms of resistance in a human cell line exposed to sequential topoisomerase poisoning

Camptothecins are a new class of anticancer drugs that target DNA topoisomerase I; current efforts are directed toward elucidating optimal combinations of these drugs with other antineoplastic agents. A rationale for the use of sequential therapy involving the combination of camptothecins with topoisomerase II-targeting drugs, such as etoposide, has arisen from observations of increased topoisomerase II protein levels in cell lines resistant to camptothecin. In an effort to understand potential mechanisms of resistance to this strategy, we developed a U-937 cell subline, denoted RERC, that is capable of surviving exposure to sequential topoisomerase poisoning. The RERC cells are 200-fold resistant to camptothecin, 8-fold resistant to etoposide, and 10-fold hypersensitive to cisplatin compared to the parental U-937 cells. Biochemical analyses indicate that the resistant phenotype involves alterations in both topoisomerase I and topoisomerase IIalpha. Topoisomerase I catalytic activity in the resistant cells is similar to that of the parental line but is resistant to camptothecin. Moreover, the resistant cells express a single mRNA species of topoisomerase I that codes for a mutation in codon 533. In addition, topoisomerase IIalpha protein levels are decreased 10-fold in the resistant line, coincident with a two-fold decrease in the expression of topoisomerase IIalpha mRNA. Collectively, these results indicate that resistance to sequential topoisomerase poisoning may involve a reduction in total cellular topoisomerase activity.     

Resistance to tomudex (ZD1694): multifactorial in human breast and colon carcinoma cell lines

ZD1694 (Tomudex; TDX) is a quinazoline antifolate that, when polyglutamated, is a potent inhibitor of thymidylate synthase (TS), the enzyme that converts dUMP to dTMP. Continuous exposure of MCF-7 breast and NCI H630 colon cells to TDX, with stepwise increases in TDX up to 2.0 microM, resulted in stably resistant cell lines (MCFTDX and H630TDX) that were highly resistant to TDX. Initial studies revealed 34-fold increase in TS protein levels in MCFTDX and a 52-fold increase in TS levels in H630TDX cell lines. Despite continued exposure of these cells to 2.0 microM TDX, TS protein and TS mRNA expression decreased to parental levels in H630TDX cells, whereas in MCFTDX cells TS mRNA expression and TS protein levels remained elevated. Southern blot analysis revealed a 20-fold TS gene amplification in the MCFTDX cell line. TDX uptake was 2-fold higher in resistant MCFTDX cells than in parental MCF-7 cells, whereas in H630TDX cells TDX uptake was 50-fold less than that observed in parental H630 cells. In contrast, no change in the transport of either leucovorin or methotrexate into H630TDX cells was noted when compared with the H630 parental cells. In H630TDX cells, folylpolyglutamate synthetase (FPGS) activity was 48-fold less compared to parent H630 cells; however, FPGS mRNA expression was similar in both lines. H630TDX cells were also highly resistant to ZD9331, a novel quinazoline TS inhibitor that does not require polyglutamation, suggesting that defective transport by the reduced folate carrier was also an important mechanism of resistance in these cells. In MCFTDX and H630TDX resistant cells, several mechanisms of resistance are apparent: one increased TS expression; the others evolved over time from increased TS expression to decreased FPGS levels and decreased TDX transport.     

Reduced expression of the ICE-related protease CPP32 is associated with radiation-induced cisplatin resistance in HeLa cells

Low-dose fractionated gamma-irradiation (three cycles of 5 x 2 Gy) induced cisplatin resistance in HeLa cells. The drug resistance was modest (Rf of about 2) and stable, similar to that found previously in murine cells after irradiation. In the drug-resistant HeLa-C3 cells, flow cytometric analysis revealed a decreased number of apoptotic cells compared with the parental cells. Drug resistance was associated with considerably enhanced expression of the p53 suppressor protein in HeLa-C3 cells after cisplatin exposure but seemed not to be regulated by the bcl-2-dependent pathway. Cisplatin resistance correlated with reduced expression of ICE-related proteases (interleukin-1beta-converting enzyme). Basal levels of the 45-kDa precursor ICE protein were reduced in HeLa-C3 cells, while those of the mature 60-kDa heterotetramer were similar. The CPP32 protease, a member of the ICE family with structural homology but different substrate specificity, was expressed at a lowered level. After drug exposure, there was a slight increase of CPP32 in HeLa-C3 cells, equivalent to about 45% of the level attained in the parental cells. This is in contrast to the CPP32 levels measured after irradiation, which were similar in sensitive and in resistant cells. As the radiosensitivity is unchanged in both cell lines, these results suggest that cisplatin resistance in HeLa-C3 cells is associated with alterations of a CPP32-linked apoptotic pathway, which is affected by the damage caused by cisplatin but not by irradiation. Whether these changes are dependent on the observed p53 modifications is now being studied in resistant clones.     

Effect of continuous rotational therapy on intracranial pressure in the severely brain-injured patient

Deoxycytidine kinase activity (dCk) was monitored in cell lines from a rat acute myeloid leukemia model of acquired resistance to cytosine arabinoside (AraC) and decitabine (DAC). In both AraC-resistant cell lines (RCL/A and its subclone RA/7), as well as in a DAC-resistant cell line (RCL/D) which we generated from the drug-sensitive RCL/0 cell line, a total deficiency of dCk activity and a cross-resistance for AraC and DAC was demonstrated. Furthermore, the metabolization of deoxycytidine (dC) was severely impaired in all these cell lines. Km values for dC (9.4 microM in RCL/0 cells) had increased 70- to 100-fold in RCL/D (Km = 673.2 microM), in RCL/A (Km = 947.2 microM) and in RA/7 (Km = 817.5 microM). Vmax values were unaltered in RCL/D and RA/7, and twofold increased in RCL/A. Addition of hydroxyurea (HU) to cell cultures stimulated dCk salvage pathway activity in RCL/0 cells for dC, AraC, and DAC by increasing Vmax values approximately 160% leaving Km constants unchanged. In all resistant cell lines, HU pre-incubation did not influence the level of dCk activity, leaving Km and Vmax values unaltered. These data indicate that deficiency of dCk activity is crucial in the mechanism of drug resistance in this model.     

Catalytic and framework mutations in the neuraminidase active site of influenza viruses that are resistant to 4-guanidino-Neu5Ac2en

Here we report the isolation of influenza virus A/turkey/Minnesota/833/80 (H4N2) with a mutation at the catalytic residue of the neuraminidase (NA) active site, rendering it resistant to the novel NA inhibitor 4-guanidino-Neu5Ac2en (GG167). The resistance of the mutant stems from replacement of one of three invariant arginines (Arg 292-->Lys) that are conserved among all viral and bacterial NAs and participate in the conformational change of sialic acid moiety necessary for substrate catalysis. The Lys292 mutant was selected in vitro after 15 passages at increasing concentrations of GG167 (from 0.1 to 1,000 microM), conditions that earlier gave rise to GG167-resistant mutants with a substitution at the framework residue Glu119. Both types of mutants showed similar degrees of resistance in plaque reduction assays, but the Lys292 mutant was more sensitive to the inhibitor in NA inhibition tests than were mutants bearing a substitution at framework residue 119 (Asp, Ala, or Gly). Cross-resistance to other NA inhibitors (4-amino-Neu5Ac2en and Neu5Ac2en) varied among mutants resistant to GG167, being lowest for Lys292 and highest for Asp119. All GG167-resistant mutants demonstrated markedly reduced NA activity, only 3 to 50% of the parental level, depending on the particular amino acid substitution. The catalytic mutant (Lys292) showed a significant change in pH optimum of NA activity, from 5.9 to 5.3. All of the mutant NAs were less stable than the parental enzyme at low pH. Despite their impaired NA activity, the GG167-resistant mutants grew as well as parental virus in Madin-Darby canine kidney cells or in embryonated chicken eggs. However, the infectivity in mice was 500-fold lower for Lys292 than for the parental virus. These findings demonstrate that amino acid substitution in the NA active site at the catalytic or framework residues, followed by multiple passages in vitro, in the presence of increasing concentrations of the NA inhibitor GG167, generates GG167-resistant viruses with reduced NA activity and decreased infectivity in animals.     

Mechanisms responsible for resistance of sublines derived from leukemia cell lines to an antitumor agent 9-beta-D-arabinofuranosyl-2-fluoroadenine

An agent 9-beta-D-arabinofuranosyl-2-fluoroadenine (2-F-Ara-A) is a main metabolite of fludarabine, a fluorinated purine analogue with antitumor activity in lymphoproliferative malignancies. In this study, the mechanism responsible for the resistance of cancer cells to fludarabine was examined using the 2-F-Ara-A-resistant sublines JOK-1/F-Ara-A and L1210/F-Ara-A from a human hairy leukemic cell line (JOK-1) and a mouse leukemic cell line (L1210) respectively, which were established by continuous treatment of the parental cell lines with 2-F-AraA. JOK-1/F-Ara-A and L1210/F-Ara-A cells were more than 55 and 29 times more resistant to 2-F-Ara-A than were their parent cell lines, and showed a high cross-resistance to 1-beta-D-arabinofuranosylcytosine but not to doxorubicin or vincristine. These resistant sublines intracellularly accumulated almost the same amount of 2-F-Ara-A as did their parent cell lines. However, the amount of 2-F-Ara-ATP, a cytotoxic metabolite of 2-F-Ara-A, decreased by 2.6% (JOK-1/F-Ara-A C3), 6% (L1210/F-Ara-A C1) and 3.7% (L1210/F-Ara-A C7) relative to the levels in the parent cell lines. Enzymatically, these resistant cells hardly activated deoxycytidine (dCyd) and 2-F-Ara-A. In addition, the abilities to phosphorylate deoxyadenosine and deoxyguanosine were also decreased in the resistant cells in comparison with the parent cells. These findings suggest that the deficiency in activity of dCyd kinase may contribute to the resistance of 2-F-Ara-A.     

Cross-resistance to antifolates in multidrug resistant cell lines with P-glycoprotein or multidrug resistance protein expression

Resistance to some (lipophilic) antifolates has been associated with P-glycoprotein (P-gp)-mediated multidrug resistance (MDR). A possible relationship with non-P-gp MDR has not been established. We studied resistance to antifolates in SW-1573 human lung carcinoma cells, a P-gp overexpressing variant SW-1573/2R160 and a multidrug resistance protein (MRP) overexpressing variant SW-1573/2R120. In this study, thymidylate synthase (TS) inhibitors with different properties concerning the efficiency of membrane transport and the efficiency of polyglutamylation were tested for cross-resistance in SW-1573/2R120 and SW-1573/2R160 cells. Growth inhibition patterns in this cell line panel were measured by the Sulforhodamine B (SRB) assay. Resistance factors for TS inhibitors were: 2.4 and 0.4 for 5-fluorouracil (5FU), 18.8 and 8.8 for ZD1694, 17 and 0.7 for AG337, and 40 and 8.3 for BW1843U89 in SW-1573/2R160 and SW-1573/2R120, respectively. This study showed changes in the TS enzyme kinetics during the induction of doxorubicin resistance in both SW-1573 variants, resulting in 2-fold lower Km values for 2'-deoxyuridine-5'-monophosphate (dUMP) in both resistant variants compared to the parental cell line. TS activity, TS protein induction and TS mRNA expression all had 2-fold increased in the SW-1573/2R120 compared to the SW-1573/2R160. 3H-MTX influx was 2-fold lower in SW-1573/2R160 cells compared to SW-1573/2R120 and SW-1573 cells. In the SW-1573/2R160 cell line, an aberrant intracellular trafficking towards the target TS was observed, compared to SW-1573/2R120 and SW-1573 cells as measured by the TS in situ assay. The rate of TS inhibition by the TS inhibitors used in this study was similar in all cell lines. In conclusion, collateral sensitivity to 5FU and the lipophilic AG337 and cross-resistance to other antifolates were observed in non-P-gp MDR SW-1573/2R120 cells, as well as resistance to all antifolates in P-gp SW-1573/2R160 cells. The mechanism of resistance in SW-1573/2R160 cells possibly involves reduced influx and changes in intracellular trafficking routes. For the SW-1573/2R120 cell line, several changes related to the TS enzyme possibly play a role in the observed cross-resistance and collateral sensitivity pattern.     

Characterisation of the unusual expression of cross resistance to cisplatin in a series of etoposide-selected resistant sublines of the SuSa testicular teratoma cell line

Three etoposide-selected resistant sublines of the SuSa testicular teratoma cell line expressing 9-, 21- and 33-fold levels of resistance, proved increasingly cross resistant to cisplatin with levels approximating to 3-, 4- and 6-fold in sublines VPC2, VPC3 and VPC4, respectively. Cisplatin resistance was not associated with any significant modifications in levels of total glutathione or associated enzyme activities. Decreased platinum (Pt) accumulation was detected, although this did not correlate either with total platination levels judged immunochemically or with peak induction of interstrand crosslinks (ISC) determined by alkaline elution. Following exposure to cisplatin in the least resistant subline, VPC2, total platination levels were markedly decreased (3-fold) relative to those of the parental cells, whilst peak ISC levels were markedly increased (4-fold). In the most highly resistant subline, VPC4, peak levels of ISCs were even higher (9-fold), although total platination levels remained comparable with those in parental cells. Both VPC2 and VPC4 cells appeared highly proficient in removing ISCs, unlike the parental cells. However, whilst VPC2 cells appeared to share deficient removal of the intrastrand platinated lesions with parental cells, VPC4 cells proved proficient in removing specific adducts in the sequence pApG. This unusual expression of cross resistance to cisplatin in a series of etoposide-selected resistant sublines derived from an inherently repair deficient parental cell line, SuSa, therefore appears to be associated with enhanced removal of the specific intrastrand crosslinks in the sequence pApG and/or of DNA-DNA ISCs. Similar mechanisms have been implicated in two other cisplatin resistant SuSa sublines selected following in vitro exposure to the drug itself or to fractionated X-irradiation.     

11 beta-hydroxysteroid dehydrogenases of the choriocarcinoma cell line JEG-3 and their inhibition by glycyrrhetinic acid and other natural substances

Mineralocorticoid receptor (MR) selectivity for aldosterone is thought to be exerted by enzymes which inactivate competing glucocorticoids before they bind the receptor. Two different 11 beta-hydroxysteroid dehydrogenases (11 beta-HSD) have been described. 11 beta-HSD-1 is NADP(+)-dependent and has a Km in the micromolar range and bidirectional activity. 11 beta-HSD-2 is NAD(+)-dependent, has a Km in the nanomolar range, exhibits only oxidase activity, and colocalizes with the MR in the kidney, so is likely to serve as the gatekeeper for the MR. We have further characterized 11 beta-HSD activity in JEG-3 cells, a cell line derived from a human choriocarcinoma which was reported to have only the high affinity, NAD(+)-dependent 11 beta-HSD-2. We found that the Km for the conversion of corticosterone to 11-dehydrocorticosterone in intact cells and homogenates was about 16 nM. NAD(+)-dependent corticosterone conversion was equal in the nuclear and mitochondrial fractions and less, but significant, in the microsomal fraction. A high affinity, Km = 40 nM, NADP(+)-dependent enzyme was also found in homogenates. The subcellular distribution of this high affinity activity was greatest in the mitochondria, less in the nuclei, and even less, but still significant, in microsomes. Because of its cofactor dependency, high affinity, and different subcellular distribution, we suggest that this enzyme is neither the 11 beta-HSD-1 nor the 11 beta-HSD-2 and have named it 11 beta-HSD-3. Conversion of 11-dehydrocorticosterone to corticosterone did not occur in intact cells or in homogenates incubated with NADH or NADPH. Enzyme activity in intact cells was inhibited by glycyrrhetinic acid, carbenoxolone, progesterone, 5 beta-dihydroprogesterone, and 5 alpha-dihydroprogesterone, but not bile acids.     

Glycosylation defect in Lec1 Chinese hamster ovary mutant is due to a point mutation in N-acetylglucosaminyltransferase I gene

The Lec1 Chinese hamster ovary (CHO) mutant is a leuco-phytohemagglutinin resistant cell line unable to synthesize complex and hybrid N-glycans due to the lack of N-acetylglucosaminyltransferase I (GnTI) activity. Here we have identified the lec1 mutation. Using specific antibodies to GnTI we demonstrate that Lec1 cells synthesize an inactive GnTI protein identical in size to the wild-type CHO enzyme. We have cloned and sequenced the gene coding GnTI from parental CHO and Lec1 mutant cells. Comparison of GnTI sequences detected three mutations within the luminal domain of Lec1 GnTI, each resulting in an amino acid substitution. The effect of each mutation on enzyme activity was analyzed by site-directed mutagenesis of wild-type rabbit GnTI and transient expression in COS cells. One of the three mutations (Cys123 --> Arg123) resulted in complete loss of activity, whereas the other two mutations had no apparent effect on enzyme activity. This conclusion was confirmed by expression of GnTI mutants in the GnTI null background of Saccharomyces cerevisiae. Both Lec1 GnTI and the GnTI mutant (Cys123 --> Arg123) are correctly localized to the Golgi apparatus, indicating that the inactive GnTI molecules are sufficiently well folded for efficient transport from the endoplasmic reticulum. These results demonstrate that the lec1 mutation is a point mutation and that Cys123 is a critical residue for GnTI activity.     

Lack of cross-resistance with gemcitabine and cytarabine in cladribine-resistant HL60 cells with elevated 5'-nucleotidase activity

Cross-resistance patterns between chemotherapeutic agents have implications for the treatment of hematologic and other diseases. Previous in vitro models have shown cross-resistance between the purine analog 2-chlorodeoxyadenosine (cladribine) and the pyrimidine analogs 2',2'-difluorodeoxycytidine (gemcitabine) and 1-beta-D-arabinofuranosylcytosine (cytosine arabinoside, cytarabine) with reduced deoxycytidine kinase (dCK) activity as the underlying determinant of resistance. In this study, we continuously exposed the human promyelocytic leukemia cell line HL60 to as much as 1024 nM cladribine. After limiting dilution, the cladribine concentrations that caused 50% growth inhibition (IC50) of the two clones R13 and R23 were 33.3- and 18.7-fold, respectively, higher than the IC50 of the parental HL60 cells (8.7+/-1.3 nM). These cladribine-resistant clones, however, showed no cross-resistance to gemcitabine and only 3.3- and 2.7-fold resistance to cytarabine, respectively. Characterization of both clones revealed stably elevated levels of purine-specific "high-Michaelis constant (Km)" 5'-nucleotidase (5'-NT) messenger RNA expression and specific activity, whereas pyrimidine-specific "low-Km" 5'-NT activity was undetectable, and dCK activity was only marginally decreased in R13. Thus, the ratio of dCK (specific for cladribine) to high-Km 5'-NT activity in R13 and R23 was reduced to 65.3% and 63.7%, respectively. These results show that changes of high-Km 5'-NT activity can induce cladribine resistance, without cross-resistance to gemcitabine.     

Is rhodamine 123 an appropriate fluorescent probe to assess P-glycoprotein mediated multidrug resistance in vinblastine-resistant CHO cells?

Cellular drug resistance, which involves several mechanisms such as P-glycoprotein (P-gp) overexpression, kinetic and metabolic quiescence, or the increase in the intracellular levels of glutathione, limits the effectiveness of cancer treatment. It has been reported that functional assessment of the cationic dye rhodamin 123 (Rho123) efflux reveals accurately the drug-resistant phenotype. To study cellular drug resistance, we have obtained a CHO-K1 derived cell line resistant to vinblastine by means of multistep selection. This cell line (CHOVBR) displays high reactivity with a monoclonal antibody (MAb) (C219) directed against an internal domain of P-gp, and an active Rho123 efflux, as shown by parallel flow cytometric and fluorometric assays. However, under similar experimental conditions, the drug-sensitive parental cell line CHO-K1 (as well as the myeloblastic KG1 and KG1a cell lines), was also able to pump Rho123 out. These parental CHO-K1 cells had a very low reactivity against the C219 Mab, as confirmed by Western blot analysis. Both vinblastine and verapamil inhibited Rho123 efflux in CHO-K1 cells, but had no effect on CHOVBR cultures. Also, deprivation of vinblastine for one month did not affect Rho123 efflux in these cells. Our results suggest that the activity of P-gp appears to be essential, but not sufficient to confer drug resistance, and that Rho123-based functional assays of drug resistance should be evaluated for each cellular experimental model.     

Inhibitor-resistant OXY-2-derived beta-lactamase produced by Klebsiella oxytoca

Klebsiella oxytoca strains are generally moderately resistant to amoxicillin and ticarcillin due to the activities of the chromosomally encoded OXY-1 and OXY-2 class A beta-lactamase families. These enzymes have the ability to hydrolyze not only penicillins but also cephalosporins, including cefuroxime, ceftriaxone, and aztreonam, and are inhibited by clavulanic acid. A Klebsiella oxytoca strain was isolated from a culture of blood from a patient who had been treated with amoxicillin-clavulanate (3 g/day) for 10 days 1 month earlier. This strain harbored an unusual phenotype characterized by resistance to amoxicillin-clavulanate. It produced an OXY-2-type beta-lactamase (pI 6.3), as confirmed by PCR amplification with primers specific for the OXY-2-encoding gene. Gene sequencing revealed a point mutation (A-->G) corresponding to the amino acid substitution Ser-->Gly at position 130. This mutant enzyme was poorly inhibited by inhibitors, and its kinetic constants compared to those of the parent enzyme were characterized by an increased Km value for ticarcillin, with a drastically reduced activity against cephalosporins, as is observed with inhibitor-resistant TEM enzymes. The substitution Ser-->Gly-130 was previously described in the inhibitor-resistant beta-lactamase SHV-10 derived from an SHV-5 variant, but this is the first report of such a mutant in OXY enzymes from K. oxytoca.     

Monomers of human beta 1 beta 1 alcohol dehydrogenase exhibit activity that differs from the dimer

A previously unreported enzymatic activity is described for monomers of the beta 1 beta 1 isoenzyme of human alcohol dehydrogenase that were prepared from dimeric enzyme by freeze-thaw in liquid nitrogen. Whereas the dimeric enzyme has optimal activity at low substrate concentrations (2.5 mM ethanol, 50 microM NAD+; "low Km" activity), the monomer has its highest activity at high substrate concentrations (1.5 M ethanol, 2.5 mM NAD+; "high Km" activity). While the activity of the monomer does not appear to be saturated at 1.5 M ethanol, its maximal activity at this high ethanol concentration exceeds the Vmax of the dimer by about 3-fold. The apparent Km of NAD+ with monomers is 270 microM, and no activity could be detected with nicotinamide mononucleotide as cofactor. During gel filtration the high Km activity elutes at a lower apparent molecular weight position than the dimer. The kinetics of monomer-to-dimer reassociation are consistent with a second-order process with a rate constant of 240 M-1 s-1. The reassociation rate is markedly enhanced by the presence of NAD+. During refolding of beta 1 beta 1 following denaturation in 6 M guanidine hydrochloride, an enzyme species with high Km activity and spectral properties similar to the freeze-thaw monomer is observed, indicating that a catalytically active monomer is an intermediate in the refolding pathway. The enzymatic activity of the monomer implies that the intersubunit contacts of beta 1 beta 1 are not crucial in establishing a catalytically competent enzyme. However, the differences in specific activity and Km between monomer and dimer suggest that dimerization may serve to modulate the catalytic properties.     

Cyclosporin A has low potency as a calcineurin inhibitor in cells expressing high levels of P-glycoprotein

Cyclosporin A (CsA) is a widely-used immunosuppressant drug whose therapeutic and toxic actions are mediated through inhibition of calcineurin (CN), a calcium- and calmodulin-dependent phosphatase. Inhibition of CN by CsA requires drug binding to its protein cofactor in the inhibition, cyclophilin. Because cyclophilin is a high affinity target for CsA it is expected that this protein can act as a reservoir for the drug in the cell and may be able to inhibit cellular efflux of CsA. P-glycoprotein (P-gp) is known to increase the rate of CsA efflux from CsA loaded cells but it is not clear if the P-gp drug efflux pump can compete effectively with cyclophilin at therapeutically relevant concentrations of CsA. To test the hypothesis that increased expression of P-gp confers protection against CsA-dependent inhibition of CN phosphatase activity, KB-V cells expressing varying levels of P-gp were analyzed to determine the potency of CsA as a CN inhibitor. When intact cells were treated with CsA, a positive correlation was observed between P-gp expression and resistance to CsA-dependent inhibition of CN: the IC50 is approximately 20-fold higher in the multidrug resistant epidermal carcinoma cell line, KB-V, which expresses P-gp at a high level than in the parental, KB, cell line expressing very low levels of P-gp. The resistance displayed by KB-V cells is abrogated by co-administration of the P-gp inhibitor verapamil, whereas verapamil has no effect on CsA potency in control KB cells. In cell lysates from KB-V cells with different amounts of P-gp CsA exhibits equivalent potency, indicating that the difference in sensitivity to CsA among the cell types requires maintenance of cell integrity. These observations support the view that resistance to CN inhibition by CsA occurs in cells with moderately elevated P-gp activity. Therefore, P-gp activity appears to be an important determinant of CsA cellular specificity for both therapeutic and toxic effects.