The distribution of interspersed repetitive DNA sequences in the human genome

The distribution of interspersed repetitive DNA sequences in the human genome has been investigated, using a combination of biochemical, cytological, computational, and recombinant DNA approaches. "Low-resolution" biochemical experiments indicate that the general distribution of repetitive sequences in human DNA can be adequately described by models that assume a random spacing, with an average distance of 3 kb. A detailed "high-resolution" map of the repetitive sequence organization along 400 kb of cloned human DNA, including 150 kb of DNA fragments isolated for this study, is consistent with this general distribution pattern. However, a higher frequency of spacing distances greater than 9.5 kb was observed in this genomic DNA sample. While the overall repetitive sequence distribution is best described by models that assume a random distribution, an analysis of the distribution of Alu repetitive sequences appearing in the GenBank sequence database indicates that there are local domains with varying Alu placement densities. In situ hybridization to human metaphase chromosomes indicates that local density domains for Alu placement can be observed cytologically. Centric heterochromatin regions, in particular, are at least 50-fold underrepresented in Alu sequences. The observed distribution for repetitive sequences in human DNA is the expected result for sequences that transpose throughout the genome, with local regions of "preference" or "exclusion" for integration.     

Transforming DNA sequences present in human prolactin-secreting pituitary tumors.

Five human PRL-secreting pituitary tumors were tested for the presence of DNA-transforming sequences. After calcium phosphate transfection to NIH-3T3 mouse fibroblast cells, DNA samples derived from two prolactinomas induced foci of morphologically transformed cells which subsequently grew in soft agar. After retransfection of transformant DNA, resulting secondary transformants elicited rapidly growing solid tumors in nude mice. Southern analysis of transformant DNA revealed the integration of Alu-positive human DNA sequences into the mouse fibroblast NIH-3T3 cells, as judged by hybridization to a Blur-8 probe. The Alu signal became increasingly more difficult to detect with the multiple passaging (greater than 20) of transformant cells in culture. Alu polymerase chain reaction (PCR) was, therefore, used to selectively amplify human DNA sequences from the NIH-3T3 rodent background. PCR using a human Alu-specific primer resulted in amplification of an Alu-containing DNA region within these transformants. The transformant DNA did not hybridize to human genomic probes for genes known to evoke focus formation in this assay, including H-ras, K-ras, N-ras, trk, ret, ros, or met. Further identification of the Alu-containing region revealed that it contained sequences from the human hst gene, a member of the fibroblast growth factor family. The presence of human hst was demonstrated by strong hybridization to a 40-mer oligonucleotide probe to the second exon of hst, by amplification of this region with human hst-nested amplimers within the first and second introns, and finally by direct sequencing.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of human DNA fragments with nucleotide sequence homologies with the simian virus 40 regulatory region.

A recombinant library of human DNA sequences was screened with a segment of simian virus 40 (SV40) DNA that spans the viral origin of replication. One hundred and fifty phage were isolated that hybridized to this probe. Restriction enzyme and hybridization analyses indicated that these sequences were partially homologous to one another. Direct DNA sequencing of two such SV40-hybridizing segments indicated that this was not a highly conserved family of sequences, but rather a set of DNA fragments that contained repetitive regions of high guanine plus cytosine content. These sequences were not members of the previously described Alu family of repeats and hybridized to SV40 DNA more strongly than do Alu family members. Computer analyses showed that the human DNA segments contained multiple homologies with sequences throughout the SV40 origin region, although sequences on the late side of the viral origin contained the strongest cross-hybridizing sequences. Because of the number and complexity of the matches detected, we could not determine unambiguously which of the many possible heteroduplexes between these DNAs was thermodynamically most favored. No hybridization of these human DNA sequences to any other segment of the SV40 genome was detected. In contrast, the human DNA segments isolated cross-hybridized with many sequences within the human genome. We tested for the presence of several functional domains on two of these human DNA fragments. One SV40-hybridizing fragment, SVCR29, contained a sequence which enhanced the efficiency of thymidine kinase transformation in human cells by approximately 20-fold. This effect was seen in an orientation-independent manner when the sequence was present at the 3' end of the chicken thymidine kinase gene. We propose that this segment of DNA contains a sequence analogous to the 72-base-pair repeats of SV40. The existence of such an "activator" element in cellular DNA raises the possibility that families of these sequences may exist in the mammalian genome.     

Interspersed repeated sequences in the African green monkey genome that are homologous to the human Alu family.

The dominant family of interspersed repetitive DNA sequences in the human genome has been termed the Alu family. We have found that more than 75% of the lambda phage in a recombinant library representing an African green monkey genome hybridize with a human Alu sequence under stringent conditions. A group of clones selected from the monkey library with probes other than the Alu sequence were analyzed for the presence and distribution of Alu family sequences. The analyses confirm the abundance of Alu sequences and demonstrate that more than one repeat unit is present in some phages. In the clones studied, the Alu units are separated by an average of 8 kilobase pairs of unrelated sequences. The nucleotide sequence of one monkey Alu sequence is reported and shown to resemble the human Alu sequences closely. Hence, the sequence, dispersion pattern, and copy number of the Alu family members are very similar in the African green monkey and human genomes. Among the clones investigated were two that contain segments of the satellite DNA term alpha-component joined to non alpha-component DNA. The experiments indicate that in the monkey genome Alu sequences can occur close to regions of alpha-component DNA.     

Identification of an Indian muntjac DNA fragment preferentially hybridizing to the X-chromosome

Upon digestion of DNA from male and female Indian muntjac (Muntiacus muntjak) fibroblasts with the restriction enzyme Hae III or Alu I, a prominent fragment of DNA (greater than 20 kb in length) was observed. This excluded DNA (ex-DNA) appeared not to contain sequences recognized by a variety of restriction enzymes and constituted about 0.6% of the total DNA in the female genome. For equal amounts of DNA digested, female DNA contained more of this material. In situ hybridization indeed revealed strong hybridization of the ex-DNA to the entire X chromosome with a few less intense sites of hybridization on other chromosomes. Hybridization studies against total muntjac DNA indicated the presence of repetitive sequences in the ex-DNA. These repetitive sequences did not cross-hybridize with human or mouse DNA.     

Differences in the localization of Alu-repeats in various chromosomes of peripheral blood cells from normal donors and bone marrow cells from patients with acute leukemia

The dispersion of the Alu-family DNA repeats in phytohemagglutinin-stimulated lymphocytes from peripheral blood of normal donors as well as in nonstimulated bone marrow cells of four patients suffering from acute leukemia was studied by hybridization on metaphase chromosomes in situ. DNA of bacteriophage lambda CAR42 clone containing the insertion of at least 8 copies of Alu-family DNA-repeats and labelled with tritium was used as a probe in hybridization. All patients with acute leukemia had the same pattern of changes in hybridization of the bone marrow cells. It consists of silver grains clustering over 3q26, 8p12, 14q24. The pattern may reflect amplification transposition of Alu-family DNA repeats in the human genome connected with cellular differentiation or malignant transformation of blood cells.     

Drosophila P element integration in the mouse

A recombinant plasmid containing the Drosophila melanogaster P element transposon was microinjected into mouse zygotes. Dot-blot analysis indicated that one of the newborns contained a single copy of the microinjected DNA per haploid mouse genome equivalent; two other newborns had integrated multiple copies of the P element construct. Southern mapping revealed that the entire plasmid, including both pBR322 sequences and P element sequences, had integrated in each of the three animals. In the two mice carrying multiple copies of the microinjected DNA, the copies appear to be linked in a tandem head-to-tail array. Therefore, in each of the three newborns integration of P element sequences has occurred by a mechanism which is distinct from that observed when the same plasmid is injected into Drosophila embryos. Analysis of DNA from the offspring of one of the transgenic mice showed no indication of transposition of P element sequences.     

Molecular characterization of a mouse genomic element mobilized by advanced glycation endproduct modified-DNA (AGE-DNA).

BACKGROUND: DNA modified by advanced glycation endproducts (AGEs) undergoes a high frequency of insertional mutagenesis. In mouse lymphoid cells, these mutations are due in part to the transposition of host genomic elements that contain a DNA region homologous to the Alu family of repetitive elements. One particular 853 bp insertion, designated INS-1, was identified previously as a DNA element common to plasmids recovered from multiple, independent lymphoid cell transfections. MATERIALS AND METHODS: To characterize the genomic origin of this element, we used a 281-bp region of non-Alu-containing INS-1 sequence, designated. CORE, as a probe in Southern hybridization and for screening a bacteriophage mouse genomic DNA library. The resultant clones were sequenced and localized within the mouse genome. RESULTS: Two distinct genomic clones of 15 kB and 17 kB in size were isolated. A 522-bp unique region common to INS-1 and corresponding to the CORE sequence was identified in each clone. In both cases, CORE was found to be surrounded by repetitive DNA sequences: a 339-bp MT repeat at the 5' end, and a 150-bp B1 repeat at the 3' end. The CORE sequence was localized to mouse chromosome 1. CONCLUSIONS: These studies revealed that the CORE region of INS is present in low copy number but is associated with known repetitive DNA elements. The presence of these repetitive elements may facilitate the transposition of CORE by recombination or other, more complex rearrangement events, and explain in part the origin of AGE-induced insertional mutations.     

Molecular cloning of genomic DNA segments partially coding for human thymidylate synthase from the mouse cell transformant

Mouse cells deficient in the enzyme thymidylate synthase [TS; EC 2.1.1.45] were serially transformed with human DNA to yield primary and secondary transformants which produced human TS [Ayusawa, D., Shimizu, K., Koyama, H., Takeishi, K., & Seno, T. (1983) J. Biol. Chem. 258, 48-53]. Southern blot hybridization of their genomic DNA showed that six secondary transformants examined contained in common a 5.5 kb EcoRI fragment hybridized with a human Alu sequence. From the secondary transformant genomic library constructed with phage lambda Charon 4A, two recombinant phage clones carrying Alu sequences were isolated. Restriction endonuclease mapping revealed that the insert DNAs of the two phage clones overlapped and covered a region of 19 kb in total. Within this region at least six Alu sequences were located. A 2.0 kb DNA fragment, prepared from an EcoRI fragment subcloned in plasmid pBR322 and free of Alu sequences, hybridized to a single band on RNA blots of primary and secondary transformant poly(A)+ RNA, but not to RNA of mouse wild-type and recipient cell lines. The relative amount of the presumed human TS mRNA was linearly correlated with the relative activity of human TS in various types of mouse transformant cells. These results indicate that these two phage clones contain genomic DNA sequences encoding human TS.     

Induction of complete segregation of cellular DNA and non-encapsidated viral genomes in herpes simplex virus type 1 infected HeLa cells as revealed by in situ hybridization

The intranuclear distribution of human Alu elements and herpes simplex virus type 1 (HSV-1) genomes was examined in HeLa cells by post-embedding in situ hybridization using in parallel appropriate biotinylated DNA probes. The bound probes were detected by direct immunogold labeling. In non-infected cells, human Alu elements detected by BLUR 8 were randomly scattered over the masses and strands of chromatin throughout the mucleus. The marked asynchrony of the HSV-1 cycle in individual HeLa cells of 17 h infected cultures allowed us to study the respective distributions of cell and viral DNA during the course of the infectious cycle. Labeling of human Alu elements revealed that cellular DNA had become confined to the border of infected nuclei without extension of cellular DNA fibers into the newly formed electron-translucent regions that occupied the centers of the infected nuclei. Labeling of HSV-1 DNA detected by a viral DNA probe revealed that non-encapsidated viral genomes were present exclusively within this centrally located viral region whereas encapsidated HSV-1 genomes, which were more widely distributed in the infected cell, were seen within the marginated host chromatin as well as the central viral region. Therefore, HSV-1 infection induces a regrouping of human Alu elements, that is, of host chromatin at the nuclear border. Non-encapsidated HSV-1 genomes and cellular DNA do not co-localize. Instead, they always constitute two adjacent compartments without spatial interrelationships.     

Comparative analysis of B1- and B2-like repetitive sequences in DNA from different organisms

Sequences homologous to short repeated elements of the mouse genome, B1 and B2, were detected in DNA of different organisms by dot-hybridization. The sequences B1 and B2 hybridized most efficiently with DNA of Myomorpha rodents and primates. The hybridization was also observed with DNA of all other eukaryotes studied, however, it is probably caused by an existence of short homologies with the B1 and B2 sequences only. The effective hybridization of the B1 sequence with DNA of primates is apparently explained by a presence of numerous copies of Alu sequence in their genomes. A repeated sequence of the human DNA that is able to hybridize with B2 sequence was cloned. It was designated as HsB2 sequence. There are about 5000 copies of this sequence in the human genome. To estimate the degree of homology, the melting temperature of hybrids of sequences B1 and B2 with DNA of rodents and some other mammals was measured. It was found that the degree of homology of B2 sequence (but not B1) correlated well with the phylogenetic relationship of the organisms. Perhaps, the difference of evolution of these sequences results from their structural and functional peculiarities.     

Studies of a novel repetitive sequence family in the genome of mice

A new middle repetitive sequence is described in the mouse genome. It has been revealed with a recombinant clone isolated from a Mus musculus BamHI gene library constructed in pBR322 and containing an insertion of 1.73 kb. When digests of genomic DNA were subjected to Southern blot hybridization, using the 1.73-kb insert as probe, we obtained a light smear and discrete bands, indicating a dispersion in the mouse genome of this sequence. This 1.73-kb sequence seems to be a part of a greater repetitive sequence at least 6 kb in length. The sizes of the bands hybridizing with the 1.73-kb insert are similar when compared between different laboratory strains but differ remarkably between the two species M. musculus and Mus caroli. We have shown also a great variation in the copy number of the sequence studied between these two species. When rat DNA is probed with the 1.73-kb insert, no hybridization is observed. Subcloning of the 1.73-kb sequence in three fragments has pointed out that the reiteration was not homogeneous along the 1.73-kb sequence. The 1.73-kb clone was sequenced and compared with other interspersed repetitive sequences, previously described in the rodent genome, and no homology was found.     

Existence of host DNA sequences in schistosomes--horizontal and vertical transmission

The localization of repetitive DNA sequences in the mouse genome such as mouse type 2 Alu sequence (B2) and mouse retrovirus-related sequences was shown in the body of adult Schistosoma japonicum and Schistosoma mansoni by applying an in situ PCR and hybridization technique. Using the same method, mouse major histocompatibility complex (MHC) class I sequence was also found in schistosomes. Furthermore, mouse MHC class I sequence and type A retroviral sequence were detected in S. japonicum and S. mansoni cercarial DNA by blot hybridization. These findings indicated that horizontal and vertical transmission of host DNA sequences occurred in schistosomes. The incorporation and propagation of host sequences in schistosomes and the roles played by such host sequences form the focus of this brief review.     

Structural organization and biological activity of molecular clones of the integrated genome of a BALB/c mouse sarcoma virus.

BALB/c mouse sarcoma virus (BALB-MSV) is a spontaneously occurring transforming retrovirus of mouse origin. The integrated form of the viral genome was cloned from the DNA of a BALB-MSV-transformed nonproducer NRK cell line in the Charon 9 strain of bacteriophage lambda. In transfection assays, the 19-kilobase-pair (kbp) recombinant DNA clone transformed NIH/3T3 mouse cells with an efficiency of 3 X 10(4) focus-forming units per pmol. Such transformants possessed typical BALB-MSV morphology and released BALB-MSV after helper virus superinfection. A 6.8-kbp DNA segment within the 19-kbp DNA possessed restriction enzyme sites identical to those of the linear BALB-MSV genome. Long terminal repeats of approximately 0.6 kbp were localized at either end of the viral genome by the presence of a repeated constellation of restriction sites and by hybridization of segments containing these sites with nick-translated Moloney murine leukemia virus long terminal repeat DNA. A continuous segment of at least 0.6 and no more than 0.9 kbp of helper virus-unrelated sequences was localized toward the 3' end of the viral genome in relation to viral RNA. A probe composed of these sequences detected six EcoRI-generated DNA bands in normal mouse cell DNA as well as a smaller number of bands in rat and human DNAs. These studies demonstrate that BALB-MSV, like previously characterized avian and mammalian transforming retroviruses, arose by recombination of a type C helper virus with a well-conserved cellular gene.     

Oligonucleotide-primed in situ DNA synthesis (PRINS): a method for chromosome mapping, banding, and investigation of sequence organization

Oligonucleotides were annealed to complementary sequences in fixed human metaphase chromosomes and extended with DNA polymerase. The newly synthesized fragments were labeled by incorporating bio-11-dUTP instead of TTP, and the sites of synthesis were detected by immunocytochemistry, using fluorochromes as the reporter molecules. We have obtained clear localization with oligonucleotides from alphoid (centromeric sequences), simple sequence (satellite) DNAs, a variety of Alu-dispersed repeated sequences, and oligonucleotides derived from the Tetrahymena and Trypanosoma telomere-specific sequences. The simple sequence and alphoid oligonucleotides gave results at least comparable to those obtained using the whole molecule as a probe for in situ hybridization, whereas the Alu oligonucleotides produced a diversity of results which depended on the absolute length and location of the oligonucleotide within the Alu sequence. The telomere-specific oligomers also produced a variety of results. The G-rich Trypanosoma oligomer and its complementary C-rich sequence produced strong telomeric signals and some interstitial signals on mouse chromosomes, but only weak telomeric signals on human chromosomes. The G-rich Tetrahymena oligomer produced detectable telomeric signals on human chromosomes. The technique appears to be a valuable extension of present tools for mapping and examining the organization of DNA sequences within chromosomes.     

Hypervariable DNA fingerprinting in Escherichia coli: minisatellite probe from bacteriophage M13.

Extensive restriction-fragment-length polymorphism was revealed in Escherichia coli strains by using a region of the bacteriophage M13 genome as a DNA hybridization probe. This variation was observed across natural strains, in clinical samples, and to a lesser extent in laboratory strains. The sequence in M13 which revealed this fingerprint pattern was a region of the gene III coat protein, which contains two clusters of a 15-base-pair repeat. Oligonucleotides made to a consensus of these repeats also revealed the fingerprint profile. While this consensus sequence has significant homology to the lambda chi site sequence, an oligonucleotide made of the chi sequence did not reveal polymorphic fingerprint patterns in E. coli. The strain variation revealed by the M13 and M13-derived oligonucleotide probes will be useful for bacterial characterization and should find use in studies of bacterial evolution and population dynamics. The findings raise questions about what these repeated sequences are and why they are so variable.     

Integrated Moloney murine leukemia virus DNA studied by using complementary DNA which does not recognize endogenous related sequences

By preannealing a radioactive, representative Moloney murine leukemia virus (M-MuLV) cDNA with large excesses of AKR 70S viral RNA, an M-MuLV-specific cDNA has been prepared. When hybridized to restriction enzyme fragments of M-MuLV-infected mouse cell DNA, the preannealed probe recognizes integrated M-MuLV DNA and does not recognize endogenous related DNA sequences found in uninfected mouse cells. The viral DNA sequences recognized by the preannealed probe are spread throughout the viral genome, although some sequences are recognized less efficiently. By using this preannealed probe, multiple integrations of M-MuLV DNA have been detected in infected fibroblasts and in an M-MuLV-induced tumor. Integrated viral DNA fragments smaller than the complete viral genome have also been detected. By using this preannealed probe to examine a mass-infected culture of mouse fibroblasts, no evidence for a strongly preferred site for M-MuLV integration could be found.     

A new family of widely propagated MB1-repeats in the human genome

A new family of repeats--i.e. MB1 repeats family--the number of copies of which per a human genome constitutes a few hundreds of thousands of copies has been revealed in a human gemone by computer analysis of a noncanonical similarity of nucleic acid sequences. The numbers of that family of repeats have also been revealed in the genomes of mouse and rat, they have been identified as mirror--reflected copies--in purines and pyrimidines--of B1 repeats in the genome of mouse and the Alu repeats in the human genome. The MB1 repeats tend to remain most similar at a length of 70 b.p. They are not flanked by short repeats, neither contain poly(A) region at the 3' end, by which they differ from the repeats of the SINE family. It has been assumed that the member of the Alu repeats family and the MB1 repeats family can form a so called H-form of DNA. The mirror-reflected repeat family could have been formed by replication of parallel DNA strands.     

Evidence for circular permutation of the prophage genome of Bacillus subtilis bacteriophage phi 105.

Analysis of DNA extracted from Bacillus subtilis lysogenic for bacteriophage phi 105 was performed by restriction endonuclease digestion and Southern hybridization using mature phi 105 DNA as a probe. The data revealed that the phi 105 prophage is circularly permuted. Digests using the enzymes EcoRI, SmaI, PstI, and HindIII localized the bacteriophage attachment site (att) to a region 63.4 to 65.7% from the left end of the mature bacteriophage genome. The phi 105 att site-containing SmaI C, PstI J, and HindIII L fragments were not present in digests of phi 105 prophage DNA. phi 105-homologous "junction" fragments were visualized by probing digests of prophage DNA with the purified PstI J fragment isolated from the mature bacteriophage genome. The excision of the phi 105 prophage was detected by observing the appearance of the mature PstI J fragment and the concomitant disappearance of a junction fragment during the course of prophage induction.     

A human dimorphism resulting from loss of an Alu.

The molecular phylogeny of Alu and other repeated sequences in the human genome provides clues to events during primate evolution. A subclass of human Alu's has been previously identified as dimorphic insertions within members of the medium reiteration frequency (mer) class of repeats, reflecting the complicated sequence of insertion and radiation events leading to the current human genome structure. One dimorphic Alu is located within a previously unidentified mer family member, in the first intron of the human T4 (CD4) gene. The insertion (Alu+ allele) has a frequency of approximately 70% in Europeans and Africans and is homozygous in 20 Asian samples. Polymerase chain reaction amplification, direct DNA sequencing, and Southern analysis using oligonucleotide probes revealed that the Alu- allele was derived from the Alu+ allele by loss of part of the inserted sequence. Comparison with a tightly linked marker within the human genome and studies of baboon DNA samples revealed that the original insertion was a relatively early event in primate evolution, but that the Alu sequence loss leading to the dimorphism has occurred much more recently. Loss of Alu insertions therefore represents one mechanism for the generation of human Alu dimorphisms.