Construction and characterization of Chinese hamster cell EmtA EmtB double mutants.

Starting with hybrid cell lines between a Chinese hamster cell EmtA mutant and a Chinese hamster cell EmtB mutant, we have constructed cell lines that are homozygous for mutant alleles at both the emtA locus and the emtB locus, by using a two-step segregation protocol. The EmtA EmtB double mutants are approximately 10-fold more resistant to emetine inhibition than either of the parental mutants. Having both the EmtA mutation and the EmtB mutation expressed in the same cell also results in a level of resistance to cryptopleurine that is significantly higher than a simple additive effect of the two mutations alone. Analysis of ribosomal proteins by two-dimensional polyacrylamide gel electrophoresis demonstrated that a parental hybrid and a first-step segregant, which has lost the wild-type emtA allele, synthesize both a normal and an altered form of ribosomal protein S14, whereas an EmtA EmtB double mutant synthesizes only the altered form of this ribosomal protein. This result confirms that the emtB locus is the structural gene for ribosomal protein S14. Our results also suggest that the products of the emtA and emtB loci interact directly, indicating that the emtA locus, like the emtB locus, encodes a component of the ribosome.     

Biochemical evidence for multiple independent emetine resistance genes in Chinese hamster cells.

Hybridization-complementation studies indicated that mutations in multiple genes can render Chinese hamster cells resistant to the alkaloid translation inhibitor emetine. Two of the genes, emtA and emtB, recognized in Chinese hamster lung and ovary cell lines, respectively, are known to affect the ribosomes of the cells directly. Although mutations in a third gene, emtC, affect the translation apparatus of Chinese hamster peritoneal cells in vitro (Wasmuth et al., Mol. Cell. Biol. 1:58-65, 1981), the molecular product of the emtC locus remains to be determined. To study the molecular basis for genetic complementation among emetine-resistant Chinese hamster cell mutants, we analyzed ribosomal proteins elaborated by complementing, emetine-sensitive hybrid clones (EmtB X EmtA and EmtB X EmtC) and by emetine-resistant clones that segregated from the hybrids. The electrophoretic forms of ribosomal protein S14 (the emtB gene product) elaborated by these clones indicated that the EmtA and EmtC phenotypes are independent of the emtB locus and that the emtA and emtC loci are not chromosomally linked to emtB.     

A Drosophila ribosomal protein functions in mammalian cells.

A cDNA expression vector encoding Drosophila ribosomal protein S14 was transfected into cultured Chinese hamster ovary (CHO) cells that harbor a recessive RPS14 emetine resistance mutation. Transformants synthesized the insect mRNA and polypeptide and consequently displayed an emetine-sensitive phenotype. These observations indicate that the insect protein was accurately expressed and correctly assembled into functional mammalian 40S ribosomal subunits.     

The Chinese hamster cell emetine resistance gene. Analysis of cDNA and genomic sequences encoding ribosomal protein S14

We used an intersecting pool strategy to recognize chimeric plasmids containing Chinese hamster ribosomal protein cDNAs. The screening procedure involved hybridization-selection of messenger RNAs, cell-free translation of selected mRNAs, and electrophoresis of polypeptide products on one- and two-dimensional polyacrylamide gels. The protocol was designed to recognize ribosomal protein S14 cDNAs specifically. Of 500 chimeric plasmids screened, two possessed cDNAs complementary to S14 mRNA and 18 contained sequences complementary to other ribosomal protein messages. Previously we demonstrated that mutations affecting Chinese hamster ovary cell ribosomal protein S14 are responsible for genetic resistance to the translational inhibitor emetine (emt b). Because emetine-resistant mutant and wild type Chinese hamster ovary cells elaborate mRNAs that encode electrophoretically distinguishable forms of S14 protein, we were able to identify S14 cDNA clones unambiguously. The data described here indicate that: 1) clone pCS14-1 contains most, if not all, of the S14 coding sequence as a cDNA; 2) S14 mRNA is approximately 0.01% of a Chinese hamster cell's polyadenylated messenger RNA; and 3) genomic DNA-encoding ribosomal protein S14 is a low, perhaps single, copy sequence with a complex structure, including several, long intervening sequences.     

Genetic and biochemical distinction among Chinese hamster cell emtA, emtB, and emtC mutants.

Genetic and biochemical experiments have enabled us to more clearly distinguish three genetic loci, emtA, emtB, and emtC, all of which can be altered to give rise to resistance to the protein synthesis inhibitor, emetine, in cultured Chinese hamster cells. Genetic experiments have demonstrated that, unlike the emtB locus, neither the emtA locus nor the emtC locus is linked to chromosome 2 in Chinese hamster cells, clearly distinguishing the latter two genes from emtB. emtA mutants can also be distinguished, biochemically, from emtB and emtC mutants based upon different degrees of cross-resistance to another inhibitor of protein synthesis, cryptopleurine. Two-dimensional gel electrophoretic analysis of ribosomal proteins failed to detect any electrophoretic alterations in ribosomal proteins from emtA or emtC mutants that could be correlated with emetine resistance. However, a distinct electrophoretic alteration in ribosomal protein S14 was observed in an emtB mutant. In addition, the parental Chinese hamster peritoneal cell line of an emtC mutant, and the emtC mutant itself, are apparently heterozygous for an electrophoretic alteration in ribosomal protein L9.     

Resistance against cycloheximide in cell lines from Chinese hamster and human cells is conferred by the large subunit of cytoplasmic ribosomes

Summary Cell lines from Chinese hamster ovary [CHO-K1-D3] and human fibroblast cells [46, XX, 18p-] were mutagenized with N-nitrosomethylurea followed by a selection for cycloheximide resistance. Two mutants resistant against the durg were selected from either wildtype. 80S ribosomes and their ribosomal subunits were isolated from all mutant and wildtype cells. 80S ribosomes reassociated from the isolated subunits were as active as isolated 80S couples in the poly (U) dependent poly (Phe) synthesis. Hybrid 80S ribosomes constructed from subunits of the various cell lines of the same species were fully active, whereas the interspecies 80S hybrids were not active at all in poly (Phe) synthesis.Hybrid 80S ribosomes from subunits of mutant and the ocrresponding wildtype cells were tested in the poly (U) assay in the presence and absence of cycloheximide. The results strikingly indicate that in all four mutant cell lines the resistance against cycloheximide is conferred by the large subunit of cytoplasmic ribosomes.Abbreviations CHM Cycloheximide - CHO Chinese hamster ovarien - FBS foetal bovine serum - Eagle MEM Eagle minimal essential medium - EMS Ethyl-metansulfonate - NMU N-nitrosomethylurea     

Mutants of CHO cells resistant to the protein synthesis inhibitors, cryptopleurine and tylocrebrine: genetic and biochemical evidence for common site of action of emetine, cryptopleurine, tylocrebine, and tubulosine

Stable mutants resistant to the protein synthesis inhibitors cryptopleurine and tylocrebine can be isolated in Chinese hamster ovary (CHO) cells, in a single step. The frequency of occurrence of cryptopleurine (CryR) and tylocrebrine (TylR) resistant mutants in normal and mutagenized cell populations is similar to that observed for emetine resistant (EmtR) mutants. The CryR, TylR, and EmtR mutants exhibit strikingly similar cross-resistance to the three drugs used for selection, to tubulosine and also to two emetine derivatives cephaeline and dehydroemetine, based on assays of in vivo cytotoxicity and on assays of protein synthesis in cell-free extracts. The identity of cross-resistance patterns of the CryR, TylR, and EmtR mutants indicates that the resistance to all these compounds results from the same primary lesion, which in the case of EmtR cells has been shown to affect the 40S ribosomal subunit. This conclusion is strongly supported by the failure of EmtR, TylR, and CryR mutants to complement each other in somatic cell hybrids. Based on these results it is suggested that the above group of compounds possesses common structural determinants which are responsible for their activity. The above mutants, however, do not show any cross-resistance to other inhibitors of protein synthesis such as cycloheximide, trichodermin, anisomycin, pactamycin, and sparsomycin, either in vivo or in vitro, indicating that the site of action of these inhibitors is different from that of the emetine-like compounds.     

The molecular basis of emetine resistance in chinese hamster ovary cells: Alteration in the 40S ribosomal subunit

The molecular basis of resistance to the protein synthesis inhibitor emetine has been examined in cell-free, protein-synthesizing extracts derived from normal and emetine-resistant (Emt^R) mutants. We had earlier shown that protein synthesis in extracts of the mutant cells was resistant to the inhibitory action of the emetin. When extracts from a wild-type and mutant cell line were fractionated into supernatant (S-100) and polyribosome fractions and mixed in different combinations, resistance to emetine was found to be associated with the mutant polyribosome fraction. Further fractionation of wild-type and mutant polyribosomes into 40S and 60S ribosomal subunits and mixing them in various combinations with an S-100 fraction from the wild-type cell indicates that resistance of mutant cells to emetine involves an alteration in the 40S ribosomal subunit.The behavior of Emt^R has also been examined in somatic cell hybrids. Studies of Emt^R × Emt^S hybrid cell lines in vivo and in vitro show that Emt^R is phenotypically recessive to Emt^S, which is consistent with the ribosomal location of the genetic change.     

A temperature-sensitive mutation affecting the mammalian 60 S ribosome.

A temperature-sensitive Chinese hamster cell mutant, ts14, is unable to synthesize protein in tissue culture at 39 degrees. That mutant's protein biosynthetic machinery has been characterized in cell-free, biologically active extracts. Similar to the mutant's phenotype in tissue culture, ts14 extracts cease protein synthesis in vitro within 15 min at 40 degrees. In contrast, at 25 degrees both ts14 and wild type extracts synthesize protein for more than 2 hours. Fractionation of mutant extracts and complementation with comparable wild type preparations indicate that ts14 possesses a thermolabile component associated with its polyribosomes. In preparation of ts14 ribosomes that are free of mRNA and bound protein factors, the defective factor is complemented functionally only by 60 S ribosomal subunits prepared from the wild type parent. Sedimentation analyses in sucrose gradients demonstrate that ts14's mutation specifically affects stability of the mutant's 60 S ribosome. Treatment with high ionic strength buffers preferentially disrupts the mutant's 60 S ribosomal subunit and results in preparations of mutant ribosomes that contain biologically active 40 S subunits only. These studies demonstrate the applicability of a genetic approach to analyzing structure-function relationships in the eukaryotic ribosome.     

Isolation and preliminary characterization of bleomycin-resistant mutants from Chinese hamster ovary cells

Stable mutants resistant to an anticancer antibiotic, bleomycin-A2, were selected in Chinese hamster ovary (CHO) cell either spontaneously or after ethylmethane sulfonate mutagenesis. Fluctuation analysis showed that bleomycin resistance occurs in CHO at a rate of 6.50--6.58 x 10(-7) mutations per cell per generation. Bleomycin-A2-resistant cell lines exhibited increased resistance to bleomycin analogs--bleomycin-A5, -B2, -B4, and pepleomycin. Colchicine, mitomycin C, and ultraviolet light irradiation inhibited colony formation equally in CHO cells and in bleomycin-resistant mutants. Cell-cell hybridization tests showed that bleomycin-resistance behaves as a dominant trait. Bleomycin-inactivating activity in the mutant cell extracts was three to fourfold higher than that in extracts of the parental CHO cell.     

Yeast virus propagation depends critically on free 60S ribosomal subunit concentration.

Over 30 MAK (maintenance of killer) genes are necessary for propagation of the killer toxin-encoding M1 satellite double-stranded RNA of the L-A virus. Sequence analysis revealed that MAK7 is RPL4A, one of the two genes encoding ribosomal protein L4 of the 60S subunit. We further found that mutants with mutations in 18 MAK genes (including mak1 [top1], mak7 [rpl4A], mak8 [rpl3], mak11, and mak16) had decreased free 60S subunits. Mutants with another three mak mutations had half-mer polysomes, indicative of poor association of 60S and 40S subunits. The rest of the mak mutants, including the mak3 (N-acetyltransferase) mutant, showed a normal profile. The free 60S subunits, L-A copy number, and the amount of L-A coat protein in the mak1, mak7, mak11, and mak16 mutants were raised to the normal level by the respective normal single-copy gene. Our data suggest that most mak mutations affect M1 propagation by their effects on the supply of proteins from the L-A virus and that the translation of the non-poly(A) L-A mRNA depends critically on the amount of free 60S ribosomal subunits, probably because 60S association with the 40S subunit waiting at the initiator AUG is facilitated by the 3' poly(A).     

Mechanism of conjugation and recombination in bacteria XVI

Summary Protein synthesis by ribosomes from several cryptopleurine-resistant yeast mutants is also resistant to emetine and tubulosine. These mutants can be classified into two different types: Class I mutants which display high levels of resistance to emetine and tubulosine and Class II mutants that are only weakly resistant to tubulosine and are slightly more sensitive to emetine than those of Class I. Apparently all mutants have similar levels of resistance to cryptopleurine. The distinct phenotypes of Class I and Class II strains are expressed through their 40S ribosomal subunit. Genetic analysis has shown that the mutations to cryptopleurine resistance are allelic and that in a particular case (strain CRY6) the pleiotropic phenotype is a result of the expression of the cryl locus. It is suggested that Class I and Class II mutants arise from two independent mutational events within the cryl allele. in heterozygous (+/cryl) diploids both the sensitive and the resistant genes are expressed as shown by studies of the action of cryptopleurine on polyphenylalanine-synthesizing system derived from each parental sensitive and resistant haploid strain and heterozygous diploid strains. The apparent dominance of sensitivity over resistance which may be observed in vivo in heterozygous (+/cryl) diploids has been explained in terms of the mode of action of the inhibitors.     

Qsr1p, a 60S ribosomal subunit protein, is required for joining of 40S and 60S subunits.

QSR1 is a recently discovered, essential Saccharomyces cerevisiae gene, which encodes a 60S ribosomal subunit protein. Thirty-one unique temperature-sensitive alleles of QSR1 were generated by regional codon randomization within a conserved 20-amino-acid sequence of the QSR1-encoded protein. The temperature-sensitive mutants arrest as viable, large, unbudded cells 24 to 48 h after a shift to 37 degrees C. Polysome and ribosomal subunit analysis by velocity gradient centrifugation of lysates from temperature-sensitive qsr1 mutants and from cells in which Qsr1p was depleted by down regulation of an inducible promoter revealed the presence of half-mer polysomes and a large pool of free 60S subunits that lack Qsr1p. In vitro subunit-joining assays and analysis of a mutant conditional for the synthesis of Qsr1p demonstrate that 60S subunits devoid of Qsr1p are unable to join with 40S subunits whereas 60S subunits that contain either wild-type or mutant forms of the protein are capable of subunit joining. The defective 60S subunits result from a reduced association of mutant Qsr1p with 60S subunits. These results indicate that Qsr1p is required for ribosomal subunit joining.     

The carboxy-terminal extension of yeast ribosomal protein S14 is necessary for maturation of 43S preribosomes

Eukaryotic ribosomal proteins are required for production of stable ribosome assembly intermediates and mature ribosomes, but more specific roles for these proteins in biogenesis of ribosomes are not known. Here we demonstrate a particular function for yeast ribosomal protein rpS14 in late steps of 40S ribosomal subunit maturation and pre-rRNA processing. Extraordinary amounts of 43S preribosomes containing 20S pre-rRNA accumulate in the cytoplasm of certain rps14 mutants. These mutations not only reveal a more precise function for rpS14 in ribosome biogenesis but also uncover a role in ribosome assembly for the extended tails found in many ribosomal proteins. These studies are one of the first to relate the structure of eukaryotic ribosomes to their assembly pathway-the carboxy-terminal extension of rpS14 is located in the 40S subunit near the 3' end of 18S rRNA, consistent with a role for rpS14 in 3' end processing of 20S pre-rRNA.     

Binding of erythromycin to the 50S ribosomal subunit is affected by alterations in the 30S ribosomal subunit

Summary Expression of resistance to erythromycin in Escherichia coli, caused by an altered L4 protein in the 50S ribosomal subunit, can be masked when two additional ribosomal mutations affecting the 30S proteins S5 and S12 are introduced into the strain (Saltzman, Brown, and Apirion, 1974). Ribosomes from such strains bind erythromycin to the same extent as ribosomes from erythromycin sensitive parental strains (Apirion and Saltzman, 1974).Among mutants isolated for the reappearance of erythromycin resistance, kasugamycin resistant mutants were found. One such mutant was analysed and found to be due to undermethylation of the rRNA. The ribosomes of this strain do not bind erythromycin, thus there is a complete correlation between phenotype of cells with respect to erythromycin resistance and binding of erythromycin to ribosomes.Furthermore, by separating the ribosomal subunits we showed that 50S ribosomes bind or do not bind erythromycin according to their L4 protein; 50S with normal L4 bind and 50S with altered L4 do not bind erythromycin. However, the 30s ribosomes with altered S5 and S12 can restore binding in resistant 50S ribosomes while the 30S ribosomes in which the rRNA also became undermethylated did not allow erythromycin binding to occur.Thus, evidence for an intimate functional relationship between 30S and 50S ribosomal elements in the function of the ribosome could be demonstrated. These functional interrelationships concerns four ribosomal components, two proteins from the 30S ribosomal subunit, S5, and S12, one protein from the 50S subunit L4, and 16S rRNA.     

Functional interdependence among ribosomal elements as revealed by genetic analysis

Summary Escherichia coli strains with preexisting ribosomal mutations were used in order to isolate further ribosomal mutations. The ribosomal mutations used were resistance to erythromycin, spectinomycin, streptomycin or kasugamycin. These mutations cause alteration of specific ribosomal elements, L4, S5, S12 proteins and 16S rRNA respectively. Mutations have been introduced into strains carrying one, two or three of these mutations. Strains with all possible combinations of these four mutations were constructed. The phenotypes of all isolated mutants were tested, and frequently the strains lost one or more of their pre-existing resistances.Thus, functional interactions were revealed among proteins, as well as RNA and proteins within the 30 S ribosomal subunit and as well as between the 30 S and the 50 S ribosomal subunits.     

Identification and characterization of a third complementation group of emetine-resistant Chinese hamster cell mutants.

We have isolated emetine-resistant cell lines from Chinese hamster peritoneal fibroblasts and have shown that they represent a third distinct class or complementation group of emetine-resistant mutants, as determined by three different criteria. These mutants, like those belonging to the two other complementation groups we have previously defined, which were isolated from Chinese hamster lung and Chinese hamster ovary cells, have alterations that directly affect the protein biosynthetic machinery. So far, there is absolute cell line specificity with respect to the three complementation groups, in that all the emetine-resistant mutants we have isolated from Chinese hamster lung cells belong to one complementation group, all those we have isolated from Chinese hamster ovary cells belong to a second complementation group, and all those isolated from Chinese hamster peritoneal cells belong to a third complementation group. Thus, in cultured Chinese hamster cells, mutations in at least three different loci, designated emtA, emtB, and emtC, encoding for different components of the protein biosynthetic machinery, can give rise to the emetine-resistant phenotype.     

Compensatory evolution reveals functional interactions between ribosomal proteins S12, L14 and L19

Certain mutations in S12, a ribosomal protein involved in translation elongation rate and translation accuracy, confer resistance to the aminoglycoside streptomycin. Previously we showed in Salmonella typhimurium that the fitness cost, i.e. reduced growth rate, due to the amino acid substitution K42N in S12 could be compensated by at least 35 different mutations located in the ribosomal proteins S4, S5 and L19. Here, we have characterized in vivo the fitness, translation speed and translation accuracy of four different L19 mutants. When separated from the resistance mutation located in S12, the three different compensatory amino acid substitutions in L19 at position 40 (Q40H, Q40L and Q40R) caused a decrease in fitness while the G104A change had no effect on bacterial growth. The rate of protein synthesis was unaffected or increased by the mutations at position 40 and the level of read-through of a UGA nonsense codon was increased in vivo, indicating a loss of translational accuracy. The mutations in L19 increased sensitivity to aminoglycosides active at the A-site, further indicating a perturbation of the decoding step. These phenotypes are similar to those of the classical S4 and S5 ram (ribosomal ambiguity) mutants. By evolving low-fitness L19 mutants by serial passage, we showed that the fitness cost conferred by the L19 mutations could be compensated by additional mutations in the ribosomal protein L19 itself, in S12 and in L14, a protein located close to L19. Our results reveal a novel functional role for the 50 S ribosomal protein L19 during protein synthesis, supporting published structural data suggesting that the interaction of L14 and L19 with 16 S rRNA could influence function of the 30 S subunit. Moreover, our study demonstrates how compensatory fitness-evolution can be used to discover new molecular functions of ribosomal proteins.