Markedly altered membrane transport and intracellular binding of vincristine in multidrug-resistant Chinese hamster cells selected for resistance to vinca alkaloids

Studies of a multidrug-resistant variant (DC-3F/VCRd-5L) of Chinese hamster lung cells selected for resistance to vinca alkaloids revealed marked alterations in transport and intracellular binding of [3H]vincristine compared to parental DC-3F cells. Influx of [3H]vincristine in DC-3F cells appears to be an equilibrating, but mediated, process. Although saturation kinetics for [3H]vincristine influx were not demonstrated, an extremely high temperature-dependence (Q10 27-37 degrees C = 5-6) and trans-inhibition of influx following preloading of cells with nonradioactive vincristine argue in favor of a carrier-mediated process. Efflux of [3H]vincristine from parental cells conformed to first-order kinetics (t1/2 37 degrees = 3.6 +/- 0.4) and exhibited a lower temperature-dependence (Q10 27-37 degrees C = 3-3.5) than influx. In variant vs. parental cells, influx of [3H]vincristine was reduced 24-fold and efflux was increased two-fold, accounting for the large (approximately 48-fold) reduction in steady-state level of exchangeable drug accumulating in variant cells. Otherwise, transport of [3H]vincristine in these cells showed characteristics similar to parental DC-3F cells. Also, the rate and amount of intracellular binding of [3H]vincristine in variant cells was almost 40-fold lower than in parental cells. These alterations in influx and efflux of [3H]vincristine and its intracellular binding appear to account, at least to a major extent, for the high level of resistance (2,750-fold) of this variant to vinca alkaloids. In contrast, cross-resistance of this variant to daunomycin (178-fold) could be explained only minimally by a transport alteration. Only a two-fold increase in efflux of [3H]daunomycin was demonstrated in variant vs. parental cells along with some decrease in intracellular binding. Influx of [3H]daunomycin was unaltered. In view of these results, we conclude that these two agents most likely do not share the same route for entry in these cells but might share the same efflux route.     

Altered molecular properties of tubulin in a multidrug-resistant variant of Chinese hamster cells selected for resistance to vinca alkaloids

The basis for the markedly altered intracellular binding of [3H]vincristine in a multidrug-resistant variant (DC-3F/VCRd-5L) of Chinese hamster lung cells (DC-3F) was investigated. Binding of [3H]vincristine by protein in cytosol derived from each cell type exhibited a differing requirement for GTP in MgCl2 containing buffer of low-ionic strength. Binding of [3H]vincristine occurred to cytosolic protein derived from both variant and parental DC-3F cells, but after removal of GTP, binding only occurred to cytosolic protein from parental cells regardless of the presence of added GTP. Although binding by cytosolic protein from parental DC-3F cells did not require GTP, the addition of 0.1 mM GTP increased by two-fold the rate and extent of binding. When cytosol from variant and parental DC-3F cells was incubated with low concentrations of [3H]vincristine in high-ionic strength buffer and analyzed by molecular-sieve HPLC, most of the protein binding [3H]vincristine in parentally derived cytosol eluted as Mr 110,000-115,000 daltons, corresponding to that for dimeric tubulin. The same binding species was not detected in cytosol derived from variant cells. However, these same fractions derived with both parental and variant cytosols contained tubulin as shown by SDS-PAGE and immunoblotting. A smaller peak of [3H]vincristine binding and an amount of tubulin equal to that found in later fractions were found in the void volume during the same HPLC elution runs with cytosol from both variant and parental DC-3F cells. Evidence was also obtained for differences between parental and variant DC-3F cells in beta-tubulin isoforms following isoelectric focusing and immunoblotting. Parental-cell cytosol contains a single isoform of beta-tubulin. However, in variant cell cytosol the same isoform and, in addition, three more basic isoforms were found. These alterations in [3H]vincristine binding and in isoform compositions of beta-tubulin in variant versus parental DC-3F cells may have importance in regard to vincristine resistance in DC-3F cells.     

The binding of vincristine, vinblastine and colchicine to tubulin

Preparations of tubulin were examined for their ability to bind vincristine, vinblastine, and colchicine, as measured by adsorption on DEAE impregnated filter paper. Vincristine and vinblastine were found to bind very rapidly with tubulin (<5 min), while colchicine took considerably longer (>4 hr). When varying concentrations of the alkaloids were employed, and the data examined on a Scatchard plot, it was found that colchicine had an association constant of 1.8 × 10⁶ liters/mole, while vinblastine and vincristine had constants of 6.0 × 10⁶ liters/mole and 8.0 × 10⁶ liters/mole respectively. In addition, it was found that the ratio of molar binding of colchicine was always twice that of vinblastine or vincristine.     

Carboxyl terminal tyrosine metabolism of alpha tubulin and changes in cell shape: Chinese hamster ovary cells

Chinese hamster ovary cells maintained in their epithelial-like form do not incorporate tyrosine post-translationally into α tubulin even though a significant fraction of the soluble tubulin is tyrosinated and tubulin: tyrosine ligase is present. Incubation with dibutyryl cyclic AMP + testosterone, which leads to a change in cell shape, immediately activates this metabolic pathway. Podophyllotoxin, which prevents the conversion to a fibroblast-like morphology, significantly inhibits this activation.     

Cadmium-resistant Chinese hamster V79 cells with decreased accumulation of cadmium

Cells resistant to 3 x 10(-5) M CdCl2 (Cdr cells) were isolated from cultures of Chinese hamster V79 cells by a procedure that involved stepwise increase in the concentration of Cd2+ and subsequent mass selection. Cdr cells grew as fast as wild-type cells (Cds) in medium without cadmium. Cdr cells were not cross-resistant to other divalent metal ions, such as Hg2+, Ni2+, Pb2+, and Zn2+. Both Cds and Cdr cells induced similar levels of metallothioneins (MT) in response to zinc. Depletion of glutathione (GSH) did not significantly influence the sensitivity of Cdr cells to Cd2+ but markedly enhanced the sensitivity to Cd2+ of Cds cells. Furthermore, the rate of synthesis of GSH after depletion did not differ greatly between sensitive and resistant cells. The rate of uptake of 109Cd2+ by Cdr cells was only 10-15% that by Cds cells. The difference in rates of uptake between Cds and Cdr cells was observed irrespective of the presence or absence of serum in the culture medium. These results indicate that, in this system, resistance to Cd2+ is attributable neither to increased inducibility of MT nor to increases in intracellular levels of GSH, and that only a decrease in the rate of uptake of Cd2+ contributes to the acquisition of resistance to Cd2+. Uptake of Cd2+ by cells was dependent on temperature and the rate of uptake of Cd2+ by Cdr cells was lower at all temperatures examined than the rate of uptake by Cds cells. Cycloheximide did not suppress the uptake of Cd2+, suggesting that uptake does not require synthesis of cell proteins de novo. Preincubation of cells with N-ethylmaleimide suppressed the uptake of Cd2+ to some extent, a result that suggests the involvement of surface SH groups in the uptake of Cd2+ by these cells.     

Spontaneous mutation rate to thioguanine resistance is decreased in polyploid hamster cells

The mutation rate to thioguanine resistance was 3.11 X 10(-6) in a near diploid V79 hamster cell line and 7.58 X 10(-8) in a near tetraploid derivative produced with colchicine. The specific activities of glucose-6-phosphate dehydrogenase and phosphoglycerate kinase of the tetraploid line were greater than that of the diploid which suggests that twice the number of active X chromosomes were present in the tetraploid. These results are compatible with the hypothesis that spontaneous variants resistant to thioguanine arise through mutation and chromosomal segregation, as has been suggested for induced mutations in tetraploid hamster cells.     

Tetracycline-regulated overexpression of glycosyltransferases in Chinese hamster ovary cells.

The glycosylation patterns of recombinant therapeutic glycoproteins can be engineered by overexpression of glycosyltransferases in the host cells used for glycoprotein production. Most prior glycosylation engineering experiments have involved constitutive expression of cloned glycosyltransferases. Here we use tetracycline-regulated expression of two glycosyltransferases, N-acetylglucosaminlytransferases III and V (GnTIII and GnTV) to manipulate glycoform biosynthesis in Chinese hamster ovary (CHO) cells and to study the effect of glycosyltransferase overexpression on this host. The amount of GnTIII and GnTV in these cells, and the glycosylation patterns of several cellular glycoproteins, could be controlled simply by manipulating the concentration of tetracycline in the culture medium. Using this system, it was found that overexpression of either GnTIII or GnTV to high levels led to growth inhibition and was toxic to the cells, indicating that this may be a general feature of glycosyltransferase overexpression. This phenomenon has not been reported previously, probably due to the widespread use of constitutive promoters, and should be taken into account when designing vectors for glycosylation engineering. The growth inhibition effect sets an upper limit to the level of glycosyltransferase overexpression, and may thereby also limit the maximum extent of in vivo modification of poorly accessible glycosylation sites. Also, such inhibition implies a bound on constitutive glycosyltransferase expression which can be cloned.     

Characterization of prmt7alpha and beta isozymes from Chinese hamster cells sensitive and resistant to topoisomerase II inhibitors

By selection of genetic suppressor elements (GSEs) conferring resistance to topoisomerase II inhibitors in Chinese hamster cells (DC-3F), we identified a gene encoding two proteins of 78 and 82 kDa which belong to the protein arginine methyltransferase (PRMT) family. Down-regulation of these enzymes (named PRMT7alpha and beta), either induced by an antisense GSE or as observed in the 9-OH-ellipticine (9-OH-E) resistant mutant DC-3F/9-OH-E, was responsible for cell resistance to various DNA damaging agents. Alternative splicing alterations in the 5'-terminal region and changes of the polyadenylation site of PRMT7 mRNAs were observed in these resistant mutant cells. PRMT7alpha and beta are isoforms of a highly conserved protein containing two copies of a module common to all PRMTs, comprising a Rossmann-fold domain and a beta-barrel domain. The C-terminal repeat appears to be degenerate and catalytically inactive. PRMT7alpha and beta form homo- and hetero-dimers but differ by their sub-cellular localization and in vitro recognize different substrates. PRMT7beta was only observed in Chinese hamster cells while mouse 10T1/2 fibroblasts only contain PRMT7alpha. Surprisingly, in human cells the anti-PRMT7 antibody essentially recognized an approximately 37 kDa peptide, which is not formed during extraction, and a faint band at 78 kDa. Analysis of in vitro and in vivo methylation patterns in cell lines under- or over-expressing PRMT7alpha and beta detected a discrete number of proteins which methylation and/or expression are under the control of these enzymes.     

Turnover of tubulin and the N site GTP in Chinese hamster ovary cells

Radioactively labeled tubulin from Chinese hamster ovary (CHO) cells can be isolated by co-polymerization with nonradioactive porcine brain microtubule protein. 75% of the soluble tubulin in CHO extracts co-polymerizes with the porcine protein through several cycles, without preferential loss of either CHO or porcine subunits. After phosphocellulose chromatography of the co-polymerized microtubules, the CHO tubulin is radiochemically homogeneous, as judged by SDS-polyacrylamide gel electrophoresis. CHO tubulin purified in this way has 1 mole of nucleotide per mole of protein noncovalently bound at the non-exchangeable or N site. This-layer chromatography indicates that the N site nucleotide is entirely ribo-GTP. Label and chase experiments show that the N site GTP exchanges intracellularly with a half-time of 33 hr in growing cells which have a generation time of 17 hr, while the tubulin polypeptides are degraded with a half-time of 48 hr. Intracellular hydrolysis of the gamma-phosphate of the N site nucleotide can be detected but occurs very slowly, with a half-time of 24 hr. These results suggest that the N site nucleotide may function in vivo as a stable structural co-factor of the tubulin molecule and render improbable the possibility that it has a regulatory role in microtubule assembly.     

Influence of guanine nucleotides on vincristine binding in tumor cytosols and purified tubulin: evidence for an inhibitor of vincristine binding

In cytosols from human rhabdomyosarcoma xenografts, the formation of vincristine (VCR)-tubulin complex and its stability were increased by GTP (Bowman et al.: Biochem. Biophys. Res. Commun., 135:695-700, 1986). We have further examined this modulation to determine whether a) GTP was protecting the VCR binding site from denaturation, b) the enhancement of complex formation was guanosine specific, and c) whether this influence was a direct interaction between GTP, VCR, and tubulin, or was mediated through another factor. In GTP-depleted cytosols from tumor xenografts HxRH18 and HxRh12, VCR binding activity was stable for at least 2 hours at 37 degrees C, indicating that the enhancement of complex formation and stability was not due to protection of tubulin integrity as measured by VCR binding; 10 nM GTP increased complex formation slightly, with complex formation increasing as GTP concentrations were increased to 5 microM, where maximum effect was observed. GTP and GDP (0.1 mM) both increased complex formation three-fold, while GMP, GMP-PNP, and ITP increased formation 1.5-fold. IMP, CTP, and ATP had no significant effect. Therefore, the modulation of VCR binding was relatively specific for the guanine nucleotides GDP and GTP. Microtubule protein, purified from Rh18 and Rh12 tumors by cycles of polymerization-depolymerization, bound VCR rapidly and binding was not influenced by GTP. This suggested that GTP modulation of VCR binding in cytosols was through a soluble factor lost in tubulin purification. In experiments with cytosol fractionated by molecular weight, there was inhibition of VCR binding activity by fractions with an mw range 20-50 kD. This inhibition was decreased by 25% by the addition of GTP. These data suggest that in tumor cytosols there may be competition between VCR and a natural ligand that is modulated by GTP. Two potential models for VCR binding are proposed.     

Resistance to antimitotic drugs in Chinese hamster ovary cells correlates with changes in the level of polymerized tubulin.

A sensitive and reproducible method to measure relative levels of polymerized and soluble tubulin in cells has been developed. This method involves metabolically labeling cells with radioactive amino acids followed by lysis in a microtubule-stabilizing buffer, centrifugation to separate soluble from polymerized tubulin, resolution of the proteins in each fraction by two-dimensional gel electrophoresis, and quantitation of the tubulin by liquid scintillation counting of spots excised from the gel. Several buffers were evaluated for their reproducibility and efficacy in preserving the state of in vivo microtubule assembly at the time of cell lysis, and the ability of the technique to measure drug-induced changes in tubulin polymerization was determined. Results using this method indicate that Chinese hamster ovary cells maintain approximately 40% of the cellular tubulin in an assembled form. Dose-dependent decreases in tubulin polymerization could be measured in Colcemid-treated cells, while dose-dependent increases in assembly were measured in taxol-treated cells. The results with taxol indicate that, following the increase in microtubule polymerization, there is a time-dependent bundling of microtubules that occurs without further increases in the extent of tubulin assembly. Examination of drug-resistant Chinese hamster ovary cells reveals that Colcemid-resistant mutants maintain more tubulin in the polymerized state (approximately 50%), while taxol-resistant mutants maintain less assembled tubulin (about 28%). Similar changes occur regardless of whether the mutant cells have an alteration in alpha- or in beta-tubulin. A model to explain these results is discussed.     

Sick euthyroid syndrome is associated with decreased TR expression and DNA binding in mouse liver

Infection is associated with low serum thyroid hormones and thyrotropin levels. Here we demonstrate that infection also reduces thyroid hormone receptor (TR) expression. In gel shift experiments, retinoid X receptor (RXR)/TR DNA binding was reduced in mouse liver by 60 and 77%, respectively, 4 and 16 h after lipopolysaccharide (LPS) administration. Surprisingly, LPS did not decrease either TR-alpha or TR-beta protein levels at 4 h, but by 16 h TR-alpha(1), TR-alpha(2), and TR-beta levels were reduced by 55, 87, and 41%, respectively. We previously reported that LPS rapidly decreases RXR protein levels in liver. Therefore, we added RXR-beta to hepatic nuclear extracts prepared 4 h after LPS treatment, which restored RXR/TR DNA binding to a level comparable to that of controls. A similar experiment conducted on extracts prepared 16 h after LPS administration did not restore RXR/TR DNA binding. We propose that decreased RXR expression is limiting for RXR/TR DNA binding at 4 h, whereas the reduction in both TR and RXR levels results in further decreased binding at 16 h.     

Preferential binding of cisplatin to mitochondrial DNA of Chinese hamster ovary cells

Some chemical carcinogens localize preferentially in mitochondrial DNA (mtDNA) when compared with genomic DNA (gDNA). Here we compare the ability of cisplatin (cis-diamminedichloroplatimum[II]) to induce DNA adducts in both genomic and mtDNA of Chinese hamster ovary (CHO) cells in culture. Cytotoxicity was examined by cell survival 4, 8 and 24 h afer exposure to 50 μM cisplatin. Cisplatin-DNA adducts were measured in DNA from nuclear and mitochondrial fractions by dissociation-enhanced lanthanide fluoroimmunoassay (DELFIA), a sensitive competitive microtiter-based immunoassay utilizing antiserum elicited against cisplatin-modified DNA. An additional comparison of cisplatin-DNA binding in both compartments was performed by immunoelectron microscopy using the cisplatin-DNA antiserum and colloidal gold. DELFIA analysis of cisplatin-DNA adducts in gDNA and mtDNA showed a six-fold higher incorporation of drug into mtDNA as compared to gDNA. Morphometric studies of colloidal gold distribution in photomicrographs of CHO cells showed mtDNA to contain a four-fold higher concentration of cisplatin as compared to nuclear DNA. Therefore, both methods demonstrated a preferential binding of cisplatin to mtDNA versus gDNA.     

Tyrosyltubulin ligase and colchicine binding activity in synchronized Chinese hamster cells

Tyrosyltubulin ligase (TTL) was found to be present in CHO and V79 Chinese hamster cells grown in tissue culture. The enzyme is soluble and requires potassium, magnesium, and ATP for maximum activity and requires tubulin as a substrate. TTL was analyzed through the cell cycle of V79 and CHO Chinese hamster cells. The enzyme showed two peaks of activity in V79 cells at 4 h and 7 h after mitotic selection, corresponding to the early S and mid to late S phases of the cell cycle. In CHO cells the enzyme displayed a major peak of activity at mid S and a minor peak or plateau during early S. Tubulin, as measured by (3H)colchicine binding, was shown to increase through S phase and reach a maximum late in the cycle during G2 approx. 3 h after maximum TTL activity.     

Chromosome aberrations associated with CAD gene amplification in Chinese hamster cultured cells

Eleven sublines with increasing resistance to N-phosphonacetyl-L-aspartate (PALA) were isolated from the V79,B7 Chinese hamster cell line. Aspartate transcarbamylase activity and CAD gene copy number increased with increasing resistance of sublines. In situ hybridization with a DNA probe for the CAD gene showed that the amplified sequences resided in the terminal region of a marker chromosome with elongated q arms. This region stained homogeneously after G-banding. A high incidence of both numerical and structural chromosome aberrations was found in PALA-resistant cells. In hyperdiploid and polyploid cells, containing 2 copies of the marker chromosome, dicentrics were found at a very high frequency. As indicated by in situ hybridization and G-banding, they originated from a rearrangement involving 2 homologous marker chromosomes.