Lawrence A. Chasin

Effect of gamma rays at the dihydrofolate reductase locus: Deletions and inversions

A series 11 gamma-ray-induced mutants at the dihydrofolate reductase (dhfr)locus in Chinese hamster ovary cells has been examined for the types of DNA sequence change brought about by this form of ionizing radiation. All 11 mutants were found to have suffered major structural changes affecting the dhfrgene. In eight of the mutants, all or part of the dhfrgene has been deleted. The extent of these deletions was examined in seven of these mutants and, for comparison, in two deletion mutants that were induced by UV irradiation. For this purpose, probes from an overlapping set of cosmids that span 210 kb of DNA in this region were used. Three of seven gamma-ray-induced mutants and one UV-induced mutant were shown to have deleted the entire 210-kb region. In the remaining mutants, endpoints ranging from within the dhfrgene to 100 kb downstream were observed. No upstream endpoints were detected, so that an upper limit on the size of these large deletions could not be assigned. Three of the 11 gamma-ray-induced mutants contained an interruption in the dhfrgene without any detectable loss of sequence. Restriction analysis of these interrupted mutants showed that at least 8–14 kb of “foreign” DNA sequence became joined to the gene at the point of disruption. Cytogenetic analysis of these mutants showed that in two cases an inversion of the banding pattern on chromosome Z-2 had taken place. The inverted dhfrmutants contain very low amounts of dhfrRNA sequences, and the 5′ end of an inversion mutant gene exhibits the same pattern of DNA methylation and DNase I-hypersensitivity as the wild-type gene. Our results suggest that ionizing radiation causes primarily, if not exclusively, large deletions and inversions in mammalian cells.

Comparison of multiple vertebrate genomes reveals the birth and evolution of human exons

Orthologous gene structures in eight vertebrate species were compared on a genomic scale to detect the birth and maturation of new internal exons during the course of evolution. We found that 40% of new human exons are alternatively spliced, and most of these are cassette exons (exons that are either included or skipped in their entirety) with low inclusion rates. This proportion decreases steadily as older and older exons are examined, even as splicing efficiency increases. Remarkably, the great majority of new cassette exons are composed of highly repeated sequences, especially Alu. Many new cassette exons are 5′ untranslated exons; the proportion that code for protein increases steadily with age. New protein-coding exons evolve at a high rate, as evidenced by the initially high substitution rates (Ks and Ka), as well as the SNP density compared with older exons. This dynamic picture suggests that de novo recruitment rather than shuffling is the major route by which exons are added to genes, and that species-specific repeats could play a significant role in recent evolution.

Mutations affecting adenine phosphoribosyl transferase activity in Chinese hamster cells

Abstract Mutants of Chinese hamster ovary cells that were resistant to the adenine analog 2, 6-diaminopurine generally were deficient in the enzyme adenine phosphoribosyl transferase. Such mutants did not occur spontaneously, and were rare even after mutagenesis, presumably because two active genes in this pseudodiploid line must be affected for the recessive drug-resistant phenotype to be expressed. Revertants of one such double mutant were selected on the basis of their ability to utilize adenine as a purine source. These revertants contained reduced levels of enzyme activity and were presumed to be heterozygous for the enzyme structural gene. Forward mutation to diaminopurine resistance, starting with these heterozygous revertants, occurred at a rate 1,000 times greater than that found for the original homozygous cells. The results agree with predictions based on the idea that mutations in the structural gene for the enzyme are responsible for the drug-resistant character of these variants.

Anchorage of the Chinese hamster dihydrofolate reductase gene to the nuclear scaffold occurs in an intragenic region

We have identified a region near the center of the dihydrofolate reductase gene dhfr in Chinese hamster ovary cells that is attached to nuclear scaffolds isolated by extraction with lithium diiodosalicylate. Detailed analysis presented here reveals the presence of only two closely linked sites in 35,000 base-pairs scanned that mediate attachment of the dhfr gene to the nuclear scaffold. Sequence analysis of one of the sites reveals a high A + T content, the presence of cleavage consensus sequences for topoisomerase II, and direct and inverted repeated sequence motifs that are localized to a small region of the attachment site. Attachment of these two regions to the nuclear scaffold is observed in wild-type, hemizygous, and amplified cell lines. Attachment is also retained in dhfr mutants isolated in our laboratory, in which chromosomal lesions have occurred directly adjacent to the scaffold-associated regions. These two regions are not bound to scaffolds prepared from isolated metaphase chromosomes, suggesting that attachment of the dhfr gene is lost during mitosis.

Gene amplification and vector engineering to achieve rapid and high-level therapeutic protein production using the Dhfr-based CHO cell selection system

Demand is increasing for therapeutic biopharmaceuticals such as monoclonal antibodies. Achieving maximum production of these recombinant proteins under developmental time constraints has been a recent focus of study. The majority of these drugs are currently produced in altered Chinese hamster ovary (CHO) cells due to the high viability and the high densities achieved by these cells in suspension cultures. However, shortening the process of developing and isolating high-producing cell lines remains a challenge. This article focuses on current expression systems used to produce biopharmaceuticals in CHO cells and current methods being investigated to produce biopharmaceuticals more efficiently. The methods discussed include modified gene amplification methods, modifying vectors to improve expression of the therapeutic gene and improving the method of selecting for high-producing cells. Recent developments that use gene targeting as a method for increasing production are discussed.

Retinoblastoma protein associates with SP1 and activates the hamster dihydrofolate reductase promoter

The dihydrofolate reductase (dhfr) promoter is powerfully activated by the transcription factor Sp1. It has been suggested that Sp1 is a potential target for transcriptional regulation by the cell cycle regulator retinoblastoma protein (Rb), and so we have explored this possibility using the hamster dhfr gene as a model. By the use of DNA probes from the hamster dhfr gene promoter, containing the most proximal GC box (minimal promoter), and nuclear extracts from cultured hamster cells (CHO K1), we show that polyclonal and monoclonal antibodies against Rb supershift the binding of Sp1. Nuclear extract immunoprecipitation with anti-Rb followed by Western analysis using anti-Sp1 also shows that Rb is complexed to Sp1. Complementary Immunoprecipitation/WB analysis shows both forms of Rb protein in the anti-Sp1 immunoprecipitates. Moreover, nuclear extract immunodepletion of Rb abolishes Sp1 gel-shift. The interaction between Rb and Sp1 is maintained in all the phases of the cell cycle. Transient overexpression of Rb in dhfr negative cells co-transfected with a dhfr minigene driven by its minimal promoter increases DHFR activity and potentiates transcription when overexpressing Sp1. Both effects are severely reduced when the co-transfections are performed with a homologous dhfr minigene containing a single point mutation in the GC box. Thus, the activation by Rb of the dhfr gene may be exerted through Sp1. Stable transfectants of pCMVRb in K1 cells show an increase in both mRNA and DHFR activity. It is concluded that Sp1 is physically associated with Rb, and that this association increases Sp1-mediated transcription of the hamster dhfr gene.

Direct selection for mutations affecting specific splice sites in a hamster dihydrofolate reductase minigene.

A Chinese hamster cell line containing an extra exon 2 (50 bp) inserted into a single intron of a dihydrofolate reductase (dhfr) minigene was constructed. The extra exon 2 was efficiently spliced into the RNA, resulting in an mRNA that is incapable of coding for the DHFR enzyme. Mutations that decreased splicing of this extra exon 2 caused it to be skipped and so produced normal dhfr mRNA. In contrast to the parental cell line, the splicing mutants display a DHFR-positive growth phenotype. Splicing mutants were isolated from this cell line after treatment with four different mutagens (racemic benzo[c]phenanthrene diol epoxide, ethyl methanesulfonate, ethyl nitrosourea, and UV irradiation). By polymerase chain reaction amplification and direct DNA sequencing, we determined the base changes in 66 mutants. Each of the mutagens generated highly specific base changes. All mutations were single-base substitutions and comprised 24 different changes distributed over 16 positions. Most of the mutations were within the consensus sequences at the exon 2 splice donor, acceptor, and branch sites. The RNA splicing patterns in the mutants were analyzed by quantitative reverse transcription-polymerase chain reaction. The recruitment of cryptic sites was rarely seen; simple exon skipping was the predominant mutant phenotype. The wide variety of mutations that produced exon skipping suggests that this phenotype is the typical consequence of splice site damage and supports the exon definition model of splice site selection. A few mutations were located outside the consensus sequences, in the exon or between the branch point and the polypyrimidine tract, identifying additional positions that play a role in splice site definition. That most of these 66 mutations fell within consensus sequences in this near-saturation mutagenesis suggests that splicing signals beyond the consensus may consist of robust RNA structures.

Positive selection acting on splicing motifs reflects compensatory evolution

We have used comparative genomics to characterize the evolutionary behavior of predicted splicing regulatory motifs. Using base substitution rates in intronic regions as a calibrator for neutral change, we found a strong avoidance of synonymous substitutions that disrupt predicted exonic splicing enhancers or create predicted exonic splicing silencers. These results attest to the functionality of the hexameric motif set used and suggest that they are subject to purifying selection. We also found that synonymous substitutions in constitutive exons tend to create exonic splicing enhancers and to disrupt exonic splicing silencers, implying positive selection for these splicing promoting events. We present evidence that this positive selection is the result of splicing-positive events compensating for splicing-negative events as well as for mutations that weaken splice-site sequences. Such compensatory events include nonsynonymous mutations, synonymous mutations, and mutations at splice sites. Compensation was also seen from the fact that orthologous exons tend to maintain the same number of predicted splicing motifs. Our data fit a splicing compensation model of exon evolution, in which selection for splicing-positive mutations takes place to counter the effect of an ongoing splicing-negative mutational process, with the exon as a whole being conserved as a unit of splicing. In the course of this analysis, we observed that synonymous positions in general are conserved relative to intronic sequences, suggesting that messenger RNA molecules are rich in sequence information for functions beyond protein coding and splicing.

Mutant alleles for hypoxanthine phosphoribosyltransferase: Codominant expression, complementation, and segregation in hybrid Chinese hamster cells

Chinese hamster ovary cell mutants resistant to the purine analogs 6-thioguanine or 8-azaguanine have been isolated following mutagenesis with ethyl methane sulfonate. The activities of hypoxanthine phosphoribosyl-transferase (HPRT) in three such mutants have been found to exhibit an increased Kmfor the substrate 5-phosphoribosyl-1-pyrophosphate. The isoelectric point of the mutant enzyme activity has also changed in two mutants. Hybrid cells containing one mutant and one wild-type allele express both genes. Segregants that have lost only the wild-type allele can be selected on the basis of drug resistance. Two mutants exhibiting different alterations in HPRT activity can complement in a hybrid cell to yield a wild-type growth pattern and enzyme activity with intermediate electrophoretic and kinetic properties. The results suggest intracistronic complementation between structural gene mutants of HPRT.

Transformation of the gene for hypoxanthine phosphoribosyltransferase.

Purified DNA from wild-type Chinese ovary (CHO) cells has been used to transform three hypoxanthine phosphoribosyltransferase (HPRT) deficient murine cell mutants to the enzyme positive state. Transformants appeared at an overall frequency of 5×10−8 colonies/treated cell and expressed CHO HPRT activity as determined by electrophoresis. One gene recipient, B21, was a newly isolated mutant of LMTK− deficient in both HPRT and thymidine kinase (TK) activities. Transformation of B21 to HPRT+ occurred at 1/5 the frequency of transformation to TK+; the latter was, in turn, an order of magnitude lower than that found in the parental LMTK− cells, 3×10−6. Thus both clonal and marker-specific factors play a role in determining transformability. The specific activity of HPRT in transformant extracts ranged from 0.5 to 5 times the CHO level. The rate of loss of the transformant HPRT+ phenotype, as measured by fluctuation analysis, was 10−4/cell/generation. While this value indicates stability compared to many gene transferents, it is much greater than the spontaneous mutation rate at the indigenous locus. The ability to transfer the gene for HPRT into cultured mammalian cells may prove useful for mutational and genetic mapping studies in this well-studied system.