Functional analysis of chimeric genes obtained by exchanging homologous domains of the mouse mdr1 and mdr2 genes.

A full-length cDNA clone for the mouse mdr1 gene can confer multidrug resistance when introduced by transfection into otherwise drug-sensitive cells. In the same assay, a full-length cDNA clone for a closely related member of the mouse mdr gene family, mdr2, fails to confer multidrug resistance. To identify the domains of mdr1 which are essential for multidrug resistance and which may be functionally distinct in mdr2, we have constructed chimeric cDNA molecules in which discrete domains of mdr2 have been introduced into the homologous region of mdr1 and analyzed these chimeras for their capacity to transfer drug resistance. The two predicted ATP-binding domains of mdr2 were found to be functional, as either could complement the biological activity of mdr1. Likewise, a chimeric molecule in which the highly sequence divergent linker domain of mdr2 had been introduced in mdr1 could also confer drug resistance. However, the replacement of either the amino- or carboxy-terminus transmembrane (TM) domain regions of mdr1 by the homologous segments of mdr2 resulted in inactive chimeras. The replacement of as few as two TM domains from either the amino (TM5-6) or the carboxy (TM7-8) half of mdr1 by the homologous mdr2 regions was sufficient to destroy the activity of mdr1. These results suggest that the functional differences detected between mdr1 and mdr2 in our transfection assay reside within the predicted TM domains.     

Two members of the mouse mdr gene family confer multidrug resistance with overlapping but distinct drug specificities.

We report the cloning and functional analysis of a complete clone for the third member of the mouse mdr gene family, mdr3. Nucleotide and predicted amino acid sequence analyses showed that the three mouse mdr genes encode highly homologous membrane glycoproteins, which share the same length (1,276 residues), the same predicted functional domains, and overall structural arrangement. Regions of divergence among the three proteins are concentrated in discrete segments of the predicted polypeptides. Sequence comparison indicated that the three mouse mdr genes were created from a common ancestor by two independent gene duplication events, the most recent one producing mdr1 and mdr3. When transfected and overexpressed in otherwise drug-sensitive cells, the mdr3 gene, like mdr1 and unlike mdr2, conferred multidrug resistance to these cells. In independently derived transfected cell clones expressing similar amounts of either MDR1 or MDR3 protein, the drug resistance profile conferred by mdr3 was distinct from that conferred by mdr1. Cells transfected with and expressing MDR1 showed a marked 7- to 10-fold preferential resistance to colchicine and Adriamycin compared with cells expressing equivalent amounts of MDR3. Conversely, cells transfected with and expressing MDR3 showed a two- to threefold preferential resistance to actinomycin D over their cellular counterpart expressing MDR1. These results suggest that MDR1 and MDR3 are membrane-associated efflux pumps which, in multidrug-resistant cells and perhaps normal tissues, have overlapping but distinct substrate specificities.     

Discrete mutations introduced in the predicted nucleotide-binding sites of the mdr1 gene abolish its ability to confer multidrug resistance.

In cells stably transfected and overexpressing the mouse mdr1 gene, multidrug resistance is associated with an increased ATP-dependent drug efflux. Analysis of the predicted amino acid sequence of the MDR1 protein revealed the presence of two putative nucleotide-binding sites (NBS). To assess the functional importance of these NBS in the overall drug resistance phenotype conferred by mdr1, we introduced amino acid substitutions in the core consensus sequence for nucleotide binding, GXGKST. Mutants bearing the sequence GXAKST or GXGRST at either of the two NBS of mdr1 and a double mutant harboring the sequence GXGRST at both NBS were generated. The integrity of the two NBS was essential for the biological activity of mdr1, since all five mutants were unable to confer drug resistance to hamster drug-sensitive cells in transfection experiments. Conversely, a lysine-to-arginine substitution outside the core consensus sequence had no effect on the activity of mdr1. Failure to reduce intracellular accumulation of [3H]vinblastine paralleled the loss of activity in cell clones expressing mutant MDR1 proteins. However, the ability to bind the photoactivatable ATP analog 8-azido ATP was retained in the five inactive MDR1 mutants. This result implies that an essential step subsequent to ATP binding is impaired in these mutants, possibly ATP hydrolysis or secondary conformational changes induced by ATP-binding or hydrolysis. Our results suggest that the two NBS function in a cooperative fashion, since mutations in a single NBS completely abrogated the biological activity of mdr1.     

An altered pattern of cross-resistance in multidrug-resistant human cells results from spontaneous mutations in the mdr1 (P-glycoprotein) gene

Multidrug resistance in human cells results from increased expression of the mdr1 (P-glycoprotein) gene. Although the same gene is activated in cells selected with different drugs, multidrug-resistant cell lines can be preferentially resistant to their selecting agent. The mdr1 cDNA sequence from vinblastine-selected KB cells, which are uniformly resistant to different lipophilic drugs, was compared with the corresponding sequence from colchicine-selected KB cells preferentially resistant to colchicine. These sequences differ at three positions, resulting in a single amino acid change in P-glycoprotein. These differences result from mutations that occurred during colchicine selection. The appearance of these mutations coincides with the emergence of preferential resistance to colchicine. We have constructed biologically active mdr1 cDNA clones that express either wild-type or mutant P-glycoprotein. Multi-drug-resistant transfectants obtained with the mutant sequence were characterized by increased relative resistance to colchicine compared with transfectants obtained with wild-type sequence. mdr1 mutations are therefore responsible for preferential resistance to colchicine in multidrug-resistant KB cells.     

Characterization of Drug Resistance-Associated Mutations in the Human Cytomegalovirus DNA Polymerase Gene by Using Recombinant Mutant Viruses Generated from Overlapping DNA Fragments

A number of specific point mutations in the human cytomegalovirus (HCMV) DNA polymerase (UL54) gene have been tentatively associated with decreased susceptibility to antiviral agents and consequently with clinical failure. To precisely determine the roles of UL54 mutations in HCMV drug resistance, recombinant UL54 mutant viruses were generated by using cotransfection of nine overlapping HCMV DNA fragments into permissive fibroblasts, and their drug susceptibility profiles were determined. Amino acid substitutions located in UL54 conserved region IV (N408D, F412C, and F412V), region V (A987G), and δ-region C (L501I, K513E, P522S, and L545S) conferred various levels of resistance to cidofovir and ganciclovir. Mutations in region II (T700A and V715M) and region VI (V781I) were associated with resistance to foscarnet and adefovir. The region II mutations also conferred moderate resistance to lobucavir. In contrast to mutations in other UL54 conserved regions, those residing specifically in region III (L802M, K805Q, and T821I) were associated with various drug susceptibility profiles. Mutations located outside the known UL54 conserved regions (S676G and V759M) did not confer any significant changes in HCMV drug susceptibility. Predominantly an additive effect of multiple UL54 mutations with respect to the final drug resistance phenotype was demonstrated. Finally, the influence of selected UL54 mutations on the susceptibility of viral DNA replication to antiviral drugs was characterized by using a transient-transfection-plus-infection assay. Results of this work exemplify specific roles of the UL54 conserved regions in the development of HCMV drug resistance and may help guide optimization of HCMV therapy.     

Identification of a region within the Na,K-ATPase alpha subunit that contributes to differential ouabain sensitivity.

To analyze determinants within the Na,K-ATPase alpha subunit that contribute to differential ouabain sensitivity, we constructed and expressed a panel of chimeric cDNA molecules between ouabain-resistant and ouabain-sensitive alpha subunit cDNAs. When introduced into ouabain-sensitive monkey CV-1 cells, ouabain-resistant rat alpha 1 subunit cDNA and chimeras in which the 5' end of ouabain-sensitive human alpha 1 or rat alpha 2 subunit cDNA was replaced by the 5' end of rat alpha 1 subunit cDNA conferred resistance to 100 microM ouabain. Monkey cells transfected with the reciprocal chimeras were unable to survive selection in 1 microM ouabain. Rat alpha 2 subunit cDNA and a chimera in which the 5' end of rat alpha 1 subunit cDNA was replaced by the 5' end of rat alpha 2 subunit cDNA conferred resistance to 0.5 microM ouabain. These results suggest that determinants of ouabain resistance reside within the amino-terminal portions of the rat alpha 1 and alpha 2 subunits. Expression of chimeric alpha subunit cDNAs should prove useful for elucidating the structural basis of Na,K-ATPase function.     

Ribosome protection by ABC‐F proteins—Molecular mechanism and potential drug design

Members of the ATP‐binding cassette F (ABC‐F) proteins confer resistance to several classes of clinically important antibiotics through ribosome protection. Recent structures of two ABC‐F proteins, Pseudomonas aeruginosa MsrE and Bacillus subtilis VmlR bound to ribosome have shed light onto the ribosome protection mechanism whereby drug resistance is mediated by the antibiotic resistance domain (ARD) connecting the two ATP binding domains. ARD of the E site bound MsrE and VmlR extends toward the drug binding region within the peptidyl transferase center (PTC) and leads to conformational changes in the P site tRNA acceptor stem, the PTC, and the drug binding site causing the release of corresponding drugs. The structural similarities and differences of the MsrE and VmlR structures likely highlight an universal ribosome protection mechanism employed by antibiotic resistance (ARE) ABC‐F proteins. The variable ARD domains enable this family of proteins to adapt the protection mechanism for several classes of ribosome‐targeting drugs. ARE ABC‐F genes have been found in numerous pathogen genomes and multi‐drug resistance conferring plasmids. Collectively they mediate resistance to a broader range of antimicrobial agents than any other group of resistance proteins and play a major role in clinically significant drug resistance in pathogenic bacteria. Here, we review the recent structural and biochemical findings on these emerging resistance proteins, offering an update of the molecular basis and implications for overcoming ABC‐F conferred drug resistance.     

Extragenic Suppression and Synthetic Lethality among Chlamydomonas Reinhardtii Mutants Resistant to anti-Microtubule Drugs

The antimicrotubule agents oryzalin (ORY), colchicine (COL) and taxol (TAX) were used to select three recessive, conditional lethal (ts-) mutants which defined two new essential loci, ory1 and cor1. The two ory1 mutants conferred resistance to ORY, TAX, and COL; the cor1 mutant conferred resistance only to COL. Each of the mutants displayed wild-type sensitivity to a number of unrelated inhibitors. Assembly and disassembly of flagellar microtubules in the ory1 mutants displayed wild-type sensitivity to ORY and COL, suggesting that the ory1 gene product either does not participate in these processes or the ory1 gene product alone is not sufficient to confer resistance. The ory1 locus mapped to linkage group X; cor1 was mapped to the left arm of linkage group XII. A synthetic lethal interaction was observed between ory1 and cor1 mutations, i.e., inferred ory1 cor1 double mutants were inviable at the permissive temperature. The conditional lethal phenotype of ory1-1 was used to select many spontaneous TS+ revertants, which arose at high frequencies. Genetic and phenotypic characterization of the revertants demonstrated that (1) the revertants fell into four phenotypic classes, including some which conferred supersensitivity to ORY and others which conferred cold-sensitive lethality, (2) reversion was caused in most or all cases by extragenic suppressors, (3) suppressor mutations displayed complex behavior in heterozygous (sup/+) diploids, (4) many different loci may be capable of suppressing ory1 mutants, and (5) suppressors of ory1-1 efficiently suppressed an independently isolated allele, ory1-2. Taken together the ory1, cor1, and suppressor mutations identify a number of interacting loci involved in essential cellular processes which are specifically susceptible to antimicrotubule agents.     

Lipophilic cations: a group of model substrates for the multidrug-resistance transporter.

The possibility that simple lipophilic cations such as tetraphenylphosphonium (TPA+), triphenylmethylphosphonium (TPMP+), and diphenyldimethylphosphonium (DDP+) are substrates for the multidrug-resistance transport protein, P-glycoprotein, was tested. Hamster cells transfected with and overexpressing mouse mdr1 or mouse mdr3 exhibit high levels of resistance to TPP+ and TPA+ (20-fold) and somewhat lower levels of resistance to TPMP+ and DDP+ (3-12-fold). Transfected cell clones expressing mdr1 or mdr3 mutants with decreased activity against drugs of the MDR spectrum (e.g., Vinca alkaloids and anthracyclines) also show reduced resistance to lipophilic cations. Studies with radiolabeled TPP+ and TPA+ demonstrate that increased resistance to cytotoxic concentrations of these lipophilic cations is correlated quantitatively with a decrease in intracellular accumulation in mdr1- and mdr3-transfected cells. This decreased intracellular accumulation is shown to be strictly dependent on intact intracellular nucleotide triphosphate pools and is reversed by verapamil, a known competitive inhibitor of P-glycoprotein. Taken together, these results demonstrate that lipophilic cations are a new class of substrates for P-glycoprotein and can be used to study its mechanism of action in homologous and heterologous systems.     

PY motifs of Rod1 are required for binding to Rsp5 and for drug resistance

In Saccharomyces cerevisiae, the overexpression of ROD1 confers resistance to o-dinitrobenzene (o-DNB), a representative of target drugs of glutathione S-transferase. The roles of Rod1 in drug resistance have remained to be determined. We isolated the rog3 mutation as a suppressor mutation of the temperature sensitivity of the strain, in that two of the total four glycogen synthase kinase 3 homologs were deleted. Rog3 is homologous to Rod1, and its overexpression also conferred resistance to o-DNB. Furthermore, these two proteins have PY-motifs, and bound to Rsp5, a hect-type ubiquitin ligase. The rsp5-101 mutant showed sensitivity to o-DNB as did the rod1 mutant, a mutant Rod1 containing altered PY motifs was defective in ability to bind to Rsp5 and in conferring o-DNB resistance. These results suggest that interaction of Rod1 and Rsp5 is important for drug resistance.     

Aminoglycoside-3″-adenyltransferase confers resistance to spectinomycin and streptomycin in Nicotiana tabacum

The bacterial gene aad A encodes the enzyme aminoglycoside-3-adenyltransferase that confers resistance to spectinomycin and streptomycin in Escherichia coli. Chimeric genes have been constructed for expression in plants, and were introduced into Nicotiana tabacum by Agrobacterium binary transformation vectors. Spectinomycin or streptomycin in selective concentrations prevent greening of N. tabacum calli. Transgenic clones, however, formed green calli on selective media containing spectinomycin, streptomycin, or both drugs. Resistance was inherited as a dominant Mendelian trait in the seed progeny. Resistance conferred by the chimeric aad A gene can be used as a color marker similar to the resistance conferred by the streptomycin phosphotransferase gene to streptomycin.     

Type II collagen-induced murine arthritis: induction of arthritis depends on antigen-presenting cell function as well as susceptibility of host to an anticollagen immune response.

Two sets of ((resistant x susceptible) F1----parent) and (parent----F1) chimeric mice were prepared. In the chimeric combinations involving BALB/c and DBA/1 mice, all (F1----F1) chimeras developed arthritis as well as potent anticollagen responses after immunization with collagen, whereas all (F1----BALB/c) and (BALB/c----F1) chimeras induced neither arthritis nor immune responses. This type of F1 T cells could be activated with APC from DBA/1 but not from BALB/c mice. Thus, the failure of the [F1 in equilibrium with BALB/c] chimeras to mount anticollagen responses was due to a defect at the APC level. Another arthritis-resistant strain, C57BL/6, exhibited adequate APC function, but reduced T cell responsiveness, representing an intermediate responder. In the chimeric combinations involving C57BL/6 and DBA/1 mice, (F1----F1) and (C57BL/6----C57BL/6) chimeras developed very high and very low incidence of arthritis, respectively. (C57BL/6----F1) chimeras developed an appreciable incidence of arthritis under conditions in which this group of chimeras generated intermediate levels of anticollagen responses. In contrast, (F1----C57BL/6) chimeras developed low incidence of disease despite induction of strong responses. Moreover, cells from collagen-immunized (F1----C57BL/6) chimeras, when transferred into T cell-depleted B cell mice of F1 or C57BL/6 strain, produced comparable immune responses in both groups but induced much more severe arthritis in F1 than in C57BL/6 recipients. These results indicate that: i) two types of arthritis-resistant strains can be identified, each of which has anticollagen APC defect as a low responder and reduced T cell responsiveness as an intermediate responder and ii) a discrepancy between the degree of anticollagen responses and clinical arthritis is attributed to the differential susceptibility to anticollagen immune responses.     

Retroviral transfer of a chimeric multidrug resistance-adenosine deaminase gene

A fusion between a selectable multidrug resistance (MDR1) cDNA and an adenosine deaminase (ADA) cDNA concomitantly confers multidrug resistance and ADA activity on transfected cells. We have produced a Harvey murine sarcoma virus-derived, replication-defective, recombinant retrovirus to transduce this chimeric MDR-ADA gene efficiently into a great variety of cells. Infection with the MDR-ADA retrovirus conferred the multidrug resistance phenotype on drug-sensitive cells, therefore allowing selection in the presence of colchicine. Colchicine-resistant cells synthesized large amounts of a membrane-associated 210-kDa MDR-ADA fusion protein that preserved both MDR and ADA functional activities. To monitor expression of the chimeric gene in vivo, Kirsten virus-transformed NIH cells were infected with the MDR-ADA retrovirus, and after drug-selection, injected into athymic nude mice. Tumors developed that contained the bifunctionally active MDR-ADA fusion protein. When these mouse tumor cells were placed in tissue culture without the selecting drug, they did not lose the bifunctionally active MDR-ADA fusion protein. The replication-defective, recombinant MDR-ADA retrovirus should be useful to stably introduce the chimeric MDR-ADA gene into a variety of cell types for biological experiments in vitro and in vivo.     

Engineering of chimeric class II polyhydroxyalkanoate synthases

PHA synthase is a key enzyme involved in the biosynthesis of polyhydroxyalkanoates (PHAs). Using a combinatorial genetic strategy to create unique chimeric class II PHA synthases, we have obtained a number of novel chimeras which display improved catalytic properties. To engineer the chimeric PHA synthases, we constructed a synthetic phaC gene from Pseudomonas oleovorans (phaC1Po) that was devoid of an internal 540-bp fragment. Randomly amplified PCR products (created with primers based on conserved phaC sequences flanking the deleted internal fragment) were generated using genomic DNA isolated from soil and were substituted for the 540-bp internal region. The chimeric genes were expressed in a PHA-negative strain of Ralstonia eutropha, PHB(-)4 (DSM 541). Out of 1,478 recombinant clones screened for PHA production, we obtained five different chimeric phaC1Po genes that produced more PHA than the native phaC1Po. Chimeras S1-71, S4-8, S5-58, S3-69, and S3-44 exhibited 1.3-, 1.4-, 2.0-, 2.1-, and 3.0-fold-increased levels of in vivo activity, respectively. All of the mutants mediated the synthesis of PHAs with a slightly increased molar fraction of 3-hydroxyoctanoate; however, the weight-average molecular weights (Mw) of the PHAs in all cases remained almost the same. Based upon DNA sequence analyses, the various phaC fragments appear to have originated from Pseudomonas fluorescens and Pseudomonas aureofaciens. The amino acid sequence analyses showed that the chimeric proteins had 17 to 20 amino acid differences from the wild-type phaC1Po, and these differences were clustered in the same positions in the five chimeric clones. A threading model of PhaC1Po, developed based on homology of the enzyme to the Burkholderia glumae lipase, suggested that the amino acid substitutions found in the active chimeras were located mostly on the protein model surface. Thus, our combinatorial genetic engineering strategy proved to be broadly useful for improving the catalytic activities of PHA synthase enzymes.