AT-rich islands in genomic DNA as a novel target for AT-specific DNA-reactive antitumor drugs.

Interstrand cross-links at T(A/T)4A sites in cellular DNA are associated with hypercytotoxicity of an anticancer drug, bizelesin. Here we evaluated whether these lethal effects reflect targeting critical genomic regions. An in silico analysis of human sequences showed that T(A/T)4A motifs are on average scarce and scattered. However, significantly higher local motif densities were identified in distinct minisatellite regions (200-1000 base pairs of approximately 85-100% AT), herein referred to as "AT islands." Experimentally detected bizelesin lesions agree with these in silico predictions. Actual bizelesin adducts clustered within the model AT island naked DNA, whereas motif-poor sequences were only sparsely adducted. In cancer cells, bizelesin produced high levels of lesions (approximately 4.7-7.1 lesions/kilobase pair/microM drug) in several prominent AT islands, compared with markedly lower lesion levels in several motif-poor loci and in bulk cellular DNA (approximately 0.8-1.3 and approximately 0.9 lesions/kilobase pair/microM drug, respectively). The identified AT islands exhibit sequence attributes of matrix attachment regions (MARs), domains that organize DNA loops on the nuclear matrix. The computed "MAR potential" and propensity for supercoiling-induced duplex destabilization (both predictive of strong MARs) correlate with the total number of bizelesin binding sites. Hence, MAR-like AT-rich non-coding domains can be regarded as a novel class of critical targets for anticancer drugs.

Gene flow of unique sequences between Mus musculus domesticus and Mus spretus.

Allelic diversity has been examined from a variety of Mus musculus subspecies and Mus spretus strains by sequencing at a 453-bp unique sequence locus. One M. m. domesticus classic inbred strain, C57BL/KsJ, contained a sequence identical to that in the M. spretus wild-derived inbred strain SEG, and other wild M. spretus isolates. Such a result should have been precluded by the expected divergence between the species unless there has been interspecies gene flow. Examination of C57BL/KsJ for M. spretus-specific repetitive sequences shows that it is neither a mis-identified spretus strain nor a domesticus/spretus hybrid. Thus, in addition to the previously reported presence of small amounts of Mus spretus-specific repetitive DNA in M. m. domesticus, there is a detectable flow of unique sequence between the two species. There was also ancestral polymorphism observed among the spretus alleles. The difficulty of distinguishing ancestral polymorphism from horizontal transfer is discussed.

LINE-1 (L1) lineages in the mouse.

Recently, a rapidly amplifying family of mouse LINE-1 (L1) has been identified and named T(F). The evolutionary context surrounding the derivation of the T(F) family was examined through phylogenetic analysis of sequences in the 3' portion of the repeat. The Mus musculus domesticus T(F) family was found to be the terminal subfamily of the previously identified L1Md4 lineage. The L1Md4 lineage joins the other prototypical mouse LINE-1 lineage (the L1MdA2 lineage) approximately 1 MYA at about the time of the common ancestor of M. m. domesticus, Mus spicilegus, and Mus spretus. However, the T(F) family from M. m. domesticus was found to join to the previously reported M. spretus Ms475 and Ms7024 LINE-1 families at just 0.5 MYA, indicating horizontal transfer. The T(F) family from M. m. domesticus was then found to be even more recently related to LINE-1's from another species, M. spicilegus. A separate spretus A2 lineage was found through a directed search of a PCR library. This lineage, in contrast to the spretus T(F) lineage, does join domesticus at about 1 MYA, as would be expected in the absence of horizontal transfer. A third major family was also found that splits off from the L1Md4 lineage shortly after its departure from the L1MdA2 lineage. The new family, named the Z family, was found to contain the de novo LINE-1 inserts causing the beige and med mutations. Whether the split with the Z family was before or after the recombination that introduced the F-type promoters and defined the inception of T(F) as a lineage is unclear. In enumerating copies of the various LINE-1 families, we found that T(F) 3' ends were not much more numerous than the reported number of 5' ends, suggesting that T(F) may not be subjected to the 90% truncation pattern typical of LINE-1 as a whole.

MuERVC: a new family of murine retrovirus-related repetitive sequences and its relationship to previously known families.

Characterization of a new murine endogenous retrovirus-related sequence named MuERVC-C105 is reported. This sequence was found to be most similar to the murine leukemia C-type retroviruses and to murine defective endogenous retrovirus-like families MuRRS and MuRVY, although MuERVC-C105 has a novel LTR. MuERVC-C105, like MuRRS and MuRVY, represents a family of retrovirus-like sequences characterized by many defects in its reading frames. Phylogenetic analyses, in particular analysis of nonsynonymous and synonymous nucleotide substitutions in the descent of these sequences, revealed that the MuERVC-C105, MuRRS, and MuRVY families were each derived from a different nondefective retroviral ancestor, thus justifying the new family name MuERVC. These nondefective ancestors cluster together with Gibbon Ape Leukemia Virus, but were nearly as distinct from each other as are other subgroups of murine leukemia virus (MoMLV, BaEV, GALV). The analysis further indicated that, in spite of the high density of defects in these three families, most of their divergence from their common ancestor was as nondefective retroviruses.

Mus spretus LINE-1s in the Mus musculus domesticus inbred strain C57BL/6J are from two different Mus spretus LINE-1 subfamilies.

A LINE-1 element, LIC105, was found in the Mus musculus domesticus inbred strain, C57BL/6J. Upon sequencing, this element was found to belong to a M. spretus LINE-1 subfamily originating within the last 0.2 million years. This is the second spretus-specific LINE-1 subfamily found to be represented in C57BL/6J. Although it is unclear how these M. spretus LINE-1s transferred from M. spretus to M. m. domesticus, it is now clear that at least two different spretus LINE-1 sequences have recently transferred. The limited divergence between the C57BL/6J spretus-like LINE-1s and their closest spretus ancestors suggests that the transfer did not involve an exceptionally long lineage of sequential transpositions.

Mus spretus LINE-1 sequences detected in the Mus musculus inbred strain C57BL/6J using LINE-1 DNA probes.

The inbred mouse strain, C57BL/6J, was derived from mice of the Mus musculus complex. C57BL/6J can be crossed in the laboratory with a closely related mouse species, M. spretus to produce fertile offspring; however there has been no previous evidence of gene flow between M. spretus and M. musculus in nature. Analysis of the repetitive sequence LINE-1, using both direct sequence analysis and genomic Southern blot hybridization to species-specific LINE-1 hybridization probes, demonstrates the presence of LINE-1 elements in C57BL/6J that were derived from the species M. spretus. These spretus-like LINE-1 elements in C57BL/6J reveal a cross to M. spretus somewhere in the history of C57BL/6J. It is unclear if the spretus-like LINE-1 elements are still embedded in flanking DNA derived from M. spretus or if they have transposed to new sites. The number of spretus-like elements detected suggests a maximum of 6.5% of the C57BL/6J genome may be derived from M. spretus.

The dynamics of murine LINE-1 subfamily amplification.

We have examined the dynamics of replication of the mouse LINE-1 retrotransposon within a single large expanding LINE-1 family found in a particular population of Mus spretus. This family has reached thousands of copies per haploid genome within 0.1 to 0.2 Myr and accounts for most, if not all, LINE-1 replication since 0.4 Myr ago. The family shows only one split into two clades during this time. From these data we propose a model that links the evolution of LINE-1 to the dynamics of its migration among mouse populations. We hypothesize that selected LINE-1 elements, referred to as master sequences, each amplify a subfamily within a distinct mouse population before migrating into the global mouse population. When these master sequences come in contact with each other by migration, generally one continues to expand at the expense of the other. We further discuss potential tests of this model.

Shared sequence variants of Mus spretus LINE-1 elements tracing dispersal to within the last 1 million years.

LINE-1 repetitive sequences contain a record of an evolving population of transposons within the mammalian genome. Of the 100,000 copies of LINE-1 sequences per genome there are many shared sequence variants representing changes occurring within the propagating LINE-1 elements themselves, rather than changes that occur during retrotransposition or after an element inserts in the genome. These shared sequence variants define families of LINE-1 elements which have spread within specific periods of time. We have been interested in studying events in LINE-1 evolution since the speciation of Mus spretus and Mus domesticus approximately 3 million years (Myr) ago. To do this, we have collected LINE-1 sequences that have shared sequence variants specific to M. spretus. The sampled LINE-1 elements were sequenced at their extreme 3' ends, where the density of sequence variants is highest. The new sequences define six new M. spretus-specific sequence variants. Of these, we have found one that could be used to screen for LINE-1 elements arising in the last 1 Myr, which we argue is a critical sample for understanding the dynamics of LINE-1 propagation.

Mus spretus-specific LINE-1 DNA probes applied to the cloning of the murine pearl locus.

LINE-1 is the major family of long, interspersed, repetitive DNA sequences found in mammalian genomes. The mouse species Mus spretus contains large LINE-1 subfamilies that are distinguishable from the LINE-1 elements of laboratory Mus domesticus strains by their content of particular nucleotide differences. Oligonucleotides containing these differences act as M. spretus-specific LINE-1 hybridization probes. We have used these probes as a novel genetic tool in conjunction with an interspecific hybrid congenic mouse, in which the M. spretus allele of the pearl gene has been transferred onto a M. domesticus background. From a lambda library prepared from this congenic mouse, four clones were isolated by hybridization to the M. spretus-specific probes. After derivation of genetic markers from these clones, two of them were found to be linked to the pearl gene. These markers are the first two of up to 75 that could be isolated to support cloning the pearl gene. Considering the interspersed nature of LINE-1, we propose that species-specific LINE-1 probes could also be used to isolate markers for many other target genes.

Targeted cloning of a subfamily of LINE-1 elements by subfamily-specific LINE-1-PCR.

Subfamily-specific LINE-1 PCR (SSL1-PCR) is the targeted amplification and cloning of defined subfamilies of LINE-1 elements and their flanking sequences. The targeting is accomplished by incorporating a subfamily-specific sequence difference at the 3' end of a LINE-1 PCR primer and pairing it with a primer to an anchor ligated within the flanking region. SSL1-PCR was demonstrated by targeting amplification of a Mus spretus-specific LINE-1 subfamily. The amplified fragments were cloned to make an SSL1-PCR library, which was found to be 100-fold enriched for the targeted elements. PCR primers were synthesized based on the sequence flanking the LINE-1 element of four different clones. Three of the clones were recovered from Mus spretus DNA. A fourth clone was recovered from a congenic mouse containing both Mus spretus and Mus domesticus DNA. Amplification between these flanking primers and LINE-1 PCR primers produced a product in Mus spretus and not in Mus domesticus. These dimorphisms were further verified to be due to insertion of Mus spretus-specific LINE-1 elements into Mus spretus DNA and not into Mus domesticus DNA.

Recombinant bovine rhodanese: purification and comparison with bovine liver rhodanese.

Recombinant bovine rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1) has been purified to homogeneity from Escherichia coli BL21(DE3) by cation-exchange chromatography. Recombinant and bovine liver rhodanese coelectrophorese under denaturing conditions, with an apparent subunit molecular weight of 33,000. The amino terminal seven residues of the recombinant protein are identical to those of the bovine enzyme, indicating that E. coli also removes the N-terminal methionine. The Km for thiosulfate is the same for the two proteins. The specific activity of the recombinant enzyme is 12% higher (816 IU/mg) than that of the bovine enzyme (730 IU/mg). The two proteins are indistinguishable as to their ultraviolet absorbance and their intrinsic fluorescence. The ability of the two proteins to refold from 8 M urea to enzymatically active species was similar both for unassisted refolding, and when folding was assisted either by the detergent, lauryl maltoside or by the E. coli chaperonin system composed of cpn60 and cpn10. Bovine rhodanese is known to have multiple electrophoretic forms under native conditions. In contrast, the recombinant protein has only one form, which comigrates with the least negatively charged of the bovine liver isoforms. This is consistent with the retention of the carboxy terminal residues in the recombinant protein that are frequently removed from the bovine liver protein.

LINE-1 repetitive DNA probes for species-specific cloning from Mus spretus and Mus domesticus genomes.

Mus domesticus and Mus spretus mice are closely related subspecies. For genetic investigations involving hybrid mice, we have developed a set of species-specific oligonucleotide probes based on the detection of LINE-1 sequence differences. LINE-1 is a repetitive DNA family whose many members are interspersed among the genes. In this study, library screening experiments were used to fully characterize the species specificity of four M. domesticus LINE-1 probes and three M. spretus LINE-1 probes. It was found that the nucleotide differences detected by the probes define large, species-specific subfamilies. We show that collaborative use of such probes can be employed to selectively detect thousands of species-specific library clones. Consequently, these probes could be exploited to monitor and access almost any given species-specific region of interest within hybrid genomes.

Temporal and topological clustering of diverged residues among enterobacterial dihydrofolate reductases.

The complete nucleotide and encoded amino acid sequences were determined for the dihydrofolate reductase (DHFR) from the bacteria Enterobacter aerogenes and Citrobacter freundii. These were compared with the closely related Escherichia coli DHFR sequence. The ancestral DHFR sequence common to these three species was reconstructed. Since that ancestor there have been seven, nine, and one amino acid replacements in E. coli, E. aerogenes, and C. freundii, respectively. In E. coli, five of its seven replacements were located in the beta-sheet portion of the protein, and all seven were located in a single restricted region of the protein. In E. aerogenes, all nine of its replacements were located within surface residues, with five clustered in a region topologically distinct from the E. coli cluster. The replaced side chains are sometimes in direct contact but more often are separated by an intervening side chain. It is argued that the temporal clustering of replacements is typical for the evolution of most proteins and that the associated topological clustering gives a picture of how evolutionary change is accommodated by protein structure.

Systematic identification of LINE-1 repetitive DNA sequence differences having species specificity between Mus spretus and Mus domesticus.

LINE-1 is a family of repetitive DNA sequences interspersed among mammalian genes. In the mouse haploid genome there are about 100,000 LINE-1 copies. We asked if the subspecies Mus spretus and Mus domesticus have developed species-specific LINE-1 subfamilies. Sequences from 14 M. spretus LINE-1 elements were obtained and compared to M. domesticus LINE-1 sequences. Using a molecular phylogenetic tree we identified several differences shared among a subset of young repeats in one or the other species as candidates for species-specific LINE-1 variants. Species specificity was tested using oligonucleotide probes complementary to each putative species-specific variant. When hybridized to genomic DNAs, single-variant probes detected an expanded number of elements in the expected mouse. In the other species these probes detected a smaller number of matches consistent with the average rate of random divergence among LINE-1 elements. It was further found that the combination of two species-specific sequence differences in the same probe reduced the detection background in the wrong species below our detection limit.

Expression of cloned bovine adrenal rhodanese.

A cDNA for the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) has been cloned from a bovine adrenal library. An initiator methionine codon precedes the amino-terminal amino acid found in the isolated protein. Rhodanese is synthesized in the cytoplasm and transferred to the mitochondrial matrix. Thus, any amino-terminal sequence required for organelle import is retained in the mature protein. Furthermore, the DNA sequence shows that there are three additional amino acids, Gly-Lys-Ala, at the carboxyl terminus that are not found by protein sequencing. Additionally, comparison of the published amino acid sequence with that encoded by the open reading frame revealed three differences in the amino acid sequence. Comparison of the bovine and chicken liver sequences shows an overall level of 70% sequence homology, but there is complete identity of all residues that have been implicated in the function of the enzyme. When two mammalian cells, cos-7 and 293 cells, were transiently transfected with a plasmid containing the rhodanese coding region, rhodanese activity in lysates increased approximately 20-fold. Fluorograms of denaturing polyacrylamide gels detected a large increase in a polypeptide that co-migrated with the native protein and reacted with anti-rhodanese antibodies. Nondenaturing gels showed two active species that co-migrated with the two major electrophoretic forms purified by current procedures. Escherichia coli, transformed with a plasmid containing the rhodanese coding region, showed a 15-fold increase in rhodanese activity over baseline values. When the E. coli recombinant protein was analyzed on a nondenaturing gel, only one species was observed that co-electrophoresed with the more electropositive variant seen in purified bovine liver rhodanese. This single variant could be converted by carboxypeptidase B digestion to a form of the enzyme that co-migrated with the more electronegative species isolated from bovine liver. Thus, two major, enzymatically active electrophoretic variants, commonly observed in mammalian cells, can be accounted for by carboxyl-terminal processing without recourse to other post-translational modifications.

Sequencing and enhanced expression of the gene encoding diadenosine 5',5'''-P1, P4-tetraphosphate (Ap4A) phosphorylase in Saccharomyces cerevisiae.

The gene, DTP, coding for diadenosine 5',5'''-P1, P4-tetraphosphate (Ap4A) phosphorylase was isolated from a Saccharomyces cerevisiae genomic DNA library in lambda gt11. In yeast and Escherichia coli transformed with the multicopy vector, YEp352, containing the cloned DTP gene, the Ap4A phosphorylase was produced at levels nine- to 17-fold higher than in untransformed hosts. The nucleotide (nt) sequence was determined. The gene codes for a polypeptide chain of 321 amino acids (aa). Two-aa sequence motifs of possible significance were identified: a potential adenine nt binding site and a potential phosphorylation site. The DTP gene is located on yeast chromosome III and is present as a single copy. Although multicopy vector expression increased the Ap4A phosphorylase activity ninefold above the endogenous activity in transformed yeast, the intracellular concentration of Ap4A did not decrease and the growth rate of the yeast was unchanged.

Site-directed mutagenesis of Escherichia coli succinyl-CoA synthetase. beta-Cys325 is a nonessential active site residue.

Chemical modification experiments have shown that sulfhydryl groups play an important role in the mechanism of action of Escherichia coli succinyl-CoA synthetase. One of these sulfhydryl groups has been localized in the beta-subunit of the enzyme using the coenzyme A affinity analog, CoA disulfide-S,S-dioxide (Collier, G. E., and Nishimura, J. S. (1978) J. Biol. Chem. 253, 4938-4943). Recently, it has been shown that the reactive sulfhydryl group resides in Cys325 (Nishimura, J. S., Mitchell, T., Ybarra, J., and Matula, J. M., submitted to Eur. J. Biochem. for publication). In the present study, we have changed Cys325 to a glycine residue using the technique of site-directed mutagenesis and have purified the mutant enzyme to homogeneity. The resulting mutant enzyme is 83% as active as wild type enzyme. In contrast to wild type succinyl-CoA synthetase, the mutant is refractory to chemical modification by CoA disulfide-S,S-dioxide and methyl methanethiolsulfonate. It is also less reactive with N-ethylmaleimide. Thus, beta-Cys325 is a nonessential active site residue.