Invading the yeast nucleus: a nuclear localization signal at the C terminus of Ty1 integrase is required for transposition in vivo.

Retrotransposon Ty1 faces a formidable cell barrier during transposition--the yeast nuclear membrane which remains intact throughout the cell cycle. We investigated the mechanism by which transposition intermediates are transported from the cytoplasm (the presumed site of Ty1 DNA synthesis) to the nucleus, where they are integrated into the genome. Ty1 integrase has a nuclear localization signal (NLS) at its C terminus. Both full-length integrase and a C-terminal fragment localize to the nucleus. C-terminal deletion mutants in Ty1 integrase were used to map the putative NLS to the last 74 amino acid residues of integrase. Mutations in basic segments within this region decreased retrotransposition at least 50-fold in vivo. Furthermore, these mutant integrase proteins failed to localize to the nucleus. Production of virus-like particles, reverse transcriptase activity, and complete in vitro Ty1 integration resembled wild-type levels, consistent with failure of the mutant integrases to enter the nucleus.

A transposon-based strategy for sequencing repetitive DNA in eukaryotic genomes.

Repetitive DNA is a significant component of eukaryotic genomes. We have developed a strategy to efficiently and accurately sequence repetitive DNA in the nematode Caenorhabditis elegans using integrated artificial transposons and automated fluorescent sequencing. Mapping and assembly tools represent important components of this strategy and facilitate sequence assembly in complex regions. We have applied the strategy to several cosmid assembly gaps resulting from repetitive DNA and have accurately recovered the sequences of these regions. Analysis of these regions revealed six novel transposon-like repetitive elements, IR-1, IR-2, IR-3, IR-4, IR-5, and TR-1. Each of these elements represents a middle-repetitive DNA family in C. elegans containing at least 3-140 copies per genome. Copies of IR-1, IR-2, IR-4, and IR-5 are located on all (or most) of the six nematode chromosomes, whereas IR-3 is predominantly located on chromosome X. These elements are almost exclusively interspersed between predicted genes or within the predicted introns of these genes, with the exception of a single IR-5 element, which is located within a predicted exon. IR-1, IR-2, and IR-3 are flanked by short sequence duplications resembling the target site duplications of transposons. We have established a website database (http:(/)/www.welch.jhu.edu/approximately devine/RepDNAdb.html) to track and cross-reference these transposon-like repetitive elements that contains detailed information on individual element copies and provides links to appropriate GenBank records. This set of tools may be used to sequence, track, and study repetitive DNA in model organisms and humans.

Severe growth defect in a Schizosaccharomyces pombe mutant defective in intron lariat degradation.

The cDNAs and genes encoding the intron lariat-debranching enzyme were isolated from the nematode Caenorhabditis elegans and the fission yeast Schizosaccharomyces pombe based on their homology with the Saccharomyces cerevisiae gene. The cDNAs were shown to be functional in an interspecific complementation experiment; they can complement an S. cerevisiae dbr1 null mutant. About 2.5% of budding yeast S. cerevisiae genes have introns, and the accumulation of excised introns in a dbr1 null mutant has little effect on cell growth. In contrast, many S. pombe genes contain introns, and often multiple introns per gene, so that S. pombe is estimated to contain approximately 40 times as many introns as S. cerevisiae. The S. pombe dbr1 gene was disrupted and shown to be nonessential. Like the S. cerevisiae mutant, the S. pombe null mutant accumulated introns to high levels, indicating that intron lariat debranching represents a rate-limiting step in intron degradation in both species. Unlike the S. cerevisiae mutant, the S. pombe dbr1::leu1+ mutant had a severe growth defect and exhibited an aberrant elongated cell shape in addition to an intron accumulation phenotype. The growth defect of the S. pombe dbr1::leu1+ strain suggests that debranching activity is critical for efficient intron RNA degradation and that blocking this pathway interferes with cell growth.

Integration of the yeast retrotransposon Ty1 is targeted to regions upstream of genes transcribed by RNA polymerase III.

Retroviruses and their relatives, the LTR-containing retrotransposons, integrate newly replicated cDNA copies of their genomes into the genomes of their hosts using element-encoded integrases. Although target site selection is not well understood for this general class of elements, it is becoming clear that some elements target their integration events to very specific regions of their host genomes. Evidence is accumulating that the yeast retrotransposon Ty1 behaves in this manner. Ty1 is found frequently adjacent to tRNA genes in the yeast genome and experimental evidence implicates these regions as preferred integration sites. To determine the basis for Ty1 targeting, we developed an in vivo integration assay using a Ty1 donor plasmid and a second target plasmid that could be used to measure the relative frequency of Ty1 integration into sequences cloned from various regions of the yeast genome. Targets containing genes transcribed by RNA polymerase III (Pol III) were up to several hundredfold more active as integration targets than "cold" sequences lacking such genes. High-frequency targeting was dependent on Pol III transcription, and integration was "region specific," occurring exclusively upstream of the transcription start sites of these genes. Thus, Ty1 has evolved a powerful targeting mechanism, requiring Pol III transcription to integrate its DNA at very specific locations within the yeast genome.

The SIR2 gene family, conserved from bacteria to humans, functions in silencing, cell cycle progression, and chromosome stability.

Genomic silencing is a fundamental mechanism of transcriptional regulation, yet little is known about conserved mechanisms of silencing. We report here the discovery of four Saccharomyces cerevisiae homologs of the SIR2 silencing gene (HSTs), as well as conservation of this gene family from bacteria to mammals. At least three HST genes can function in silencing; HST1 overexpression restores transcriptional silencing to a sir2 mutant and hst3 hst4 double mutants are defective in telomeric silencing. In addition, HST3 and HST4 together contribute to proper cell cycle progression, radiation resistance, and genomic stability, establishing new connections between silencing and these fundamental cellular processes.

Efficient integration of artificial transposons into plasmid targets in vitro: a useful tool for DNA mapping, sequencing and genetic analysis.

We have developed efficient methods for creating artificial transposons and inserting these transposons into plasmid targets in vitro, primarily for the purpose of DNA mapping and sequencing. A novel plasmid has been engineered to convert virtually any DNA sequence, or combination of sequences, into an artificial transposon; hence, custom transposons containing any desired feature can be easily designed and constructed. Such transposons are then efficiently inserted into plasmid targets, in vitro, using the integrase activity present in yeast Ty1 virus-like particles. A single in vitro integration reaction, which resembles a simple restriction digestion in the complexity of the reaction, gives rise to thousands of recoverable insertion events within DNA target molecules; this frequency approaches one insertion per phosphodiester bond in typical plasmids. Importantly, transposon insertions are recovered from all regions of DNA inserts carried on plasmid targets, indicating that integration is a random or nearly-random process. Because of its versatility, this technology offers a generalized method of generating recombinant DNA molecules of a desired structure. We have adapted this system for DNA sequencing by developing a customized artificial transposon to insert new primer binding sites into internal regions of DNA inserts carried on cloning vectors. Transposon insertions have been generated throughout several different yeast and human DNA inserts carried on plasmids, allowing the efficient recovery of sequence information from these inserts. Our results demonstrate the overall utility of this method for both small and large-scale DNA sequencing, as well as general DNA restructuring, and indicate that it could be adapted for use with a number of additional applications including functional genetic analysis.

Diversity of multidrug resistance in mammalian cells.

Mammalian cells displaying the multidrug resistance (mdr) phenotype are refractory to the toxic effects of a group of unrelated natural product drugs, many of which are used for cancer chemotherapy. The pattern of cross-resistance can be extremely variable among independently selected cell lines, even though such cells are often exposed to only a single drug. The overexpression of P-glycoprotein (pgp), a 150-180-kDa drug efflux pump, has been shown to confer mdr to otherwise drug-sensitive cells; however, the variable nature of cross-resistance indicates that normal pgps alone are unlikely to account for all of the observed cross-resistance phenotypes. In this report, we examined possible factors contributing to cross-resistance diversity in mammalian cells. We show that drug-resistant Chinese hamster lung cells selected during relatively short periods of drug exposure in vitro (less than 6-8 weeks) routinely overexpressed endogenous pgps and predominantly showed a cross-resistance pattern that was similar to that conferred by the introduction and overexpression of the hamster wild-type pgp1 cDNA alone. Longer drug exposure periods at higher drug concentrations, however, led to the selection of cell lines with altered cross-resistance properties. Like the short term clones, these cell lines all overexpressed endogenous pgp. In one case, the altered phenotype was shown to be caused by the acquisition of point mutations within codons 338 and 339 of the pgp1 gene, leading to two adjacent amino acid substitutions within the encoded pgp. Although the basis for the remaining altered phenotypes remains unknown, these results indicate that additional genetic alterations beyond those responsible for the initial acquisition of mdr emerge in the face of increased selective pressure, thus further modifying or complementing the cross-resistance phenotype initially conferred by wild-type pgp.

Functional studies with a full-length P-glycoprotein cDNA encoded by the hamster pgp1 gene.

Hamster cells grown in culture may, like human and mouse cells, develop multidrug resistance (MDR) when exposed to certain cytotoxic chemotherapeutic agents. Several phenotypic features that are characteristic of MDR have been described; these include (1) resistance to many structurally and functionally unrelated drugs that have different cellular targets and modes of action; (2) reversal of MDR by certain agents, including verapamil and cyclosporin A; and (3) reduced intracellular drug accumulation relative to that of drug-sensitive cells. In this report we show that the introduction and overexpression of the hamster pgp1 cDNA confers to otherwise drug-sensitive cells an MDR phenotype with these features. Moreover, pgp1 transfectants showed varying degrees of resistance to anthracycline analogues, indicating that structural analogues of commonly used anticancer agents are capable of circumventing drug resistance conferred by pgp.

Amino acid substitutions in the sixth transmembrane domain of P-glycoprotein alter multidrug resistance.

Eukaryotic cells can display resistance to a wide range of natural-product chemotheraputic agents by the expression of P-glycoprotein (pgp), a putative plasma membrane transporter that is thought to mediate the efflux of these agents from cells. We have identified, in cells selected for multidrug resistance with actinomycin D, a mutant form of pgp that contains two amino acid substitutions within the putative sixth transmembrane domain. In transfection experiments, this altered pgp confers a cross-resistance phenotype that is altered significantly from that conferred by the normal protein, displaying maximal resistance to actinomycin D. These results strongly implicate the sixth transmembrane domain in the mechanism of pgp drug recognition and efflux. Moreover, they indicate a close functional homology between pgp and the cystic fibrosis transmembrane regulator in which the sixth transmembrane domain has also been shown to influence substrate specificity.

Full length and alternatively spliced pgp1 transcripts in multidrug-resistant Chinese hamster lung cells.

In an effort to better understand the preferential resistance to actinomycin D displayed by the multidrug-resistant Chinese hamster lung cell line DC-3F/ADX, we have cloned from those cells a number of cDNAs representing p-glycoprotein gene transcripts. Of the 12 clones isolated, all represent pgp1 transcripts and one, pADX165, contains a 4304-base pair insert with an open reading frame encoding a 1276-amino acid protein that is the homolog of the mouse mdr3/mdr1a gene product. A domain by domain comparison of this protein with p-glycoproteins capable of supporting multidrug resistance, i.e. human mdr1, mouse mdr1/mdr1b, and mouse mdr3/mdr1a, shows that, in addition to the ATP binding sites, the second, fourth, and eleventh transmembrane domains and the four small intracellular loops, IC-1, IC-2, IC-4, and IC-5, are highly conserved and are therefore likely to be important for the maintenance of p-glycoprotein function. Of the remaining 11 cDNA clones, 9 were found to be truncated versions of pADX165. Two others, however, pADX185 and pADX124, contained internal deletions resulting in open reading frames capable of encoding lnovel forms of p-glycoprotein. S1 nuclease and RNase protection analysis demonstrated that these cDNAs represent transcripts present in a number of different multidrug-resistant Chinese hamster lung cell lines. Hence, both are considered to be splicing variants of the hamster pgp1 gene primary transcript.

12th codon mutation resulting in c-N-ras activation in acute myelogenous leukemia.

Activation of the cellular oncogene c-N-ras has been frequently observed in DNA from leukemic cells in acute myeloid leukemia (AML). Ras gene activation sufficient to mediate in vitro transformation and rodent tumorigenesis usually results from point mutations and amino acid substitutions in the 12th or 61st codons. In AML and the related myelodysplastic syndromes, amino acid substitution at the 13th codon has been observed. An activated c-N-ras gene from a 45-year-old patient with AML was isolated by transfection analysis and subjected to molecular cloning and sequence analysis. A point mutation of the 12th codon (GGT to GAT) resulting in aspartic acid substitution for glycine was observed. In other neoplasms such as colon cancer, specific ras mutations occur predominantly (e.g., K-ras, codon 12). This predominance has been of demonstrable value in analyzing large cohorts for ras activation with techniques that are rapid and economical, such as oligonucleotide hybridization. It had previously been thought that such a predominance for activation of c-N-ras at codon 13 existed in AML; however, this study in concert with others underscores the importance of 12th codon c-N-ras mutations, along with 13th and 61st codon mutations in the molecular pathogenesis of AML. Guanylate to adenylate transition mutations are commonly observed in AML and may provide insight into potential environmental leukemogens. Addressing all commonly prevalent ras activating mutations bears impact in the future design of molecular surveys of the role of ras activation in leukemogenesis.