A PCR-based method for manipulation of the vaccinia virus genome that eliminates the need for cloning.

A general method is described for altering specific genes of vaccinia virus (VV). We demonstrate and evaluate the procedure by gene inactivation, using a dominant selectable marker in conjunction with recombinant polymerase chain reaction (PCR). Primers based on the sequence of the target gene enable amplification of flanking arms and their subsequent attachment to the gpt cassette that confers resistance to mycophenolic acid. Linear PCR constructs are transfected into cells infected with wild-type vaccinia virus. Mutant viruses with gpt inserted into the target gene by homologous recombination are then selected by growth in the presence of MPA. This technique was applied to the vaccinia virus thymidine kinase gene and compared to the traditional method of constructing gpt-containing plasmids by cloning. The PCR scheme was found to be highly efficient and could theoretically be used to insert any foreign DNA element into any nonessential target gene for which partial or complete sequence information is available. The procedure can potentially be used for a wide variety of genetic modifications, including the insertion of foreign genes, with poxviruses and other DNA viruses. Genomes of microorganisms, such as bacteria and yeast that can be transformed with linear DNA, are also candidates for manipulation by this methodology.     

Gene conversion as a secondary mechanism of short interspersed element (SINE) evolution.

The Alu repetitive family of short interspersed elements (SINEs) in primates can be subdivided into distinct subfamilies by specific diagnostic nucleotide changes. The older subfamilies are generally very abundant, while the younger subfamilies have fewer copies. Some of the youngest Alu elements are absent in the orthologous loci of nonhuman primates, indicative of recent retroposition events, the primary mode of SINE evolution. PCR analysis of one young Alu subfamily (Sb2) member found in the low-density lipoprotein receptor gene apparently revealed the presence of this element in the green monkey, orangutan, gorilla, and chimpanzee genomes, as well as the human genome. However, sequence analysis of these genomes revealed a highly mutated, older, primate-specific Alu element was present at this position in the nonhuman primates. Comparison of the flanking DNA sequences upstream of this Alu insertion corresponded to evolution expected for standard primate phylogeny, but comparison of the Alu repeat sequences revealed that the human element departed from this phylogeny. The change in the human sequence apparently occurred by a gene conversion event only within the Alu element itself, converting it from one of the oldest to one of the youngest Alu subfamilies. Although gene conversions of Alu elements are clearly very rare, this finding shows that such events can occur and contribute to specific cases of SINE subfamily evolution.     

Xenobiotic responsive element in the 5'-upstream region of the human P-450c gene.

The nucleotide sequence of the 5'-upstream region up to about -4.1 kb of the human P-450c gene was determined. Two kinds of repetitive sequences were located; one was the Alu sequence which was inserted at three positions (-3127 to -3038, -3017 to -2770, and -2167 to -1851), and the other was the SINE-R element located just upstream of the most distal Alu sequences. The region other than the two repeated sequences showed an overall similarity of 70% to that of the rat P-450c gene. Survey of XRE or its homologues, responsible for the inducible expression of the rat P-450c gene, revealed eight XRE core sequences in this region of the human P-450c gene. Three of them were carried in the Alu sequences. A fusion gene which was constructed by ligating the upstream region of the human P-450c gene to the chloramphenicol acetyltransferase (CAT) gene expressed the CAT activity in response to the inducer, methylcholanthrene, when transfected into Hepa-1 cells. Stepwise decrease in CAT activity in three regions was observed as the 5'-upstream sequence containing XRE motifs was removed. However, the XRE core sequence in the Alu sequences seemed inactive, because elimination of the three elements in the Alu sequences did not affect the expressed CAT activity. In accordance with this observation, competition experiments using gel mobility shift assay showed that XRE core sequences in the Alu sequences could not compete with the XRE sequence for the inducer-bound receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of pre-insertion loci of de novo L1 insertions

The human Long Interspersed Element-1 (LINE-1) and the Short Interspersed Element (SINE) Alu comprise 28% of the human genome. They share the same L1-encoded endonuclease for insertion, which recognizes an A+T-rich sequence. Under a simple model of insertion distribution, this nucleotide preference would lead to the prediction that the populations of both elements would be biased towards A+T-rich regions. Genomic L1 elements do show an A+T-rich bias. In contrast, Alu is biased towards G+C-rich regions when compared to the genome average. Several analyses have demonstrated that relatively recent insertions of both elements show less G+C content bias relative to older elements. We have analyzed the repetitive element and G+C composition of more than 100 pre-insertion loci derived from de novo L1 insertions in cultured human cancer cells, which should represent an evolutionarily unbiased set of insertions. An A+T-rich bias is observed in the 50 bp flanking the endonuclease target site, consistent with the known target site for the L1 endonuclease. The L1, Alu, and G+C content of 20 kb of the de novo pre-insertion loci shows a different set of biases than that observed for fixed L1s in the human genome. In contrast to the insertion sites of genomic L1s, the de novo L1 pre-insertion loci are relatively L1-poor, Alu-rich and G+C neutral. Finally, a statistically significant cluster of de novo L1 insertions was localized in the vicinity of the c-myc gene. These results suggest that the initial insertion preference of L1, while A+T-rich in the initial vicinity of the break site, can be influenced by the broader content of the flanking genomic region and have implications for understanding the dynamics of L1 and Alu distributions in the human genome.     

Studying DNA mutations in human cells with the use of an integrated HSV thymidine kinase target gene

A shuttle vector carrying the origin of SV40 replication, the thymidine kinase (tk) gene of herpes simplex virus and the E. coli xanthine guanine phosphoribosyl transferase (gpt) gene has been introduced into human TK- cells. A transformed cell line containing only one stably integrated copy of the shuttle vector was used to study mutations in the introduced tk gene at the molecular level. Without selection for gpt expression, spontaneous TK- mutants arose at a frequency of approximately 10(-4)/generation, and were caused by deletion of plasmid sequences. However, when selection for expression of the gpt gene was applied, the background level of mutations at the tk gene was below 4.10(-6). From this cell line, TK- mutants were obtained after treatment with N-ethyl-N-nitrosourea (ENU). COS fusion appeared to be an efficient method for rescue and amplification of the integrated shuttle vector from the human chromosome. After further amplification and analysis in E. coli, rescued tk genes were easily identified and were shown to be physically unaltered by the rescue procedure. In contrast to rescued tk genes from TK+ cells, those obtained from the ENU-induced TK- mutants were unable to complement thymidine kinase-negative E. coli cells. Two such tk mutations were mapped in E. coli by marker rescue analysis. A GC----AT transition was the cause of both mutations. We show here that plasmid rescue by COS fusion is a reliable system for studying gene mutations in human cells, since no sequence changes occurred in rescued DNA except for the 2 ENU-induced sequence changes.     

Evolution of an Alu DNA element of type Sx in the lineage of primates and the origin of an associated tetranucleotide microsatellite.

A 394-bp DNA fragment, which in human is on chromosome 6 near the MOG (myelin oligodendrocyte glycoprotein) gene and encompasses an Alu element and an associated tetranucleotide microsatellite, was sequenced from a large range of primate species to follow its evolutionary divergence and to understand the origin of the microsatellite. This Alu element is found at the same orthologous position in all primates sequenced, but the tetranucleotide repeat is present only in Catarrhini between the 3'-oligo(dA) of the Alu element and the 3' flanking direct repeat. Little intraspecific variation was found. Sequence identity values for this orthologous primate Alu averaged 90% (82-99%) with transitions comprising between 70% and 100% of the observed nucleotide substitutions. Although the insertion of the Alu element predates the separation of these species, the original sequence of the site of integration can still be identified. This identification of the direct repeats suggests an active role of the oligo(dA) of the Alu element in the origin of the tetranucleotide repeats. The microsatellite probably appeared after the insertion of the Alu element, early in the lineage leading to the common ancestor of the hominoids and the Old World monkeys.     

A dimorphic Alu Sb-like insertion in COL3A1 is ethnic-specific

Alu elements are a class of repetitive DNA sequences found throughout the human genome that are thought to be duplicated via an RNA intermediate in a process termed retroposition. Recently inserted Alu elements are closely related, suggesting that they are derived from a single source gene or closely related source genes. Analysis of the type III collagen gene (COL3A1) revealed a polymorphic Alu insertion in intron 8 of the gene. The Alu insertion in the COL3A1 gene had a high degree of nucleotide identity to the Sb family of Alu elements, a family of older Alu elements. The Alu sequence was less similar to the consensus sequence for the PV or Sb2 subfamilies, subfamilies of recently inserted Alu elements. These data support the observations that at least three source genes are active in the human genome, one of which is distinct from the PV and Sb2 subfamilies and predates either of these two subfamilies. Appearance of the Alu insertion in different ethnic populations suggests that the insertion may have occurred in the last 100,000 years. This Alu insert should be a useful marker for population studies and for marking COL3A1 alleles.     

Allelic dimorphism in the human tissue-type plasminogen activator (TPA) gene as a result of an Alu insertion/deletion event

Summary Polymerase chain reaction and direct sequencing were used to investigate an amplified DNA fragment containing the suspected polymorphic site of all known intragenic restriction fragment length polymorphisms (RFLPs) within the human tissue-type plasminogen activator (TPA) gene. Sequence data obtained showed that these RFLPs were all generated by the presence or absence of one of the two Alu sequences located in intron h of the human TPA gene. Furthermore, one of the direct repeats flanking this Alu sequence was absent in the minor allele. In addition to indicating the presence of an Alu insertion in an ancestral human TPA gene, these findings suggest a slip-replication mechanism for the deletion of this Alu repeat, once inserted into the gene. As both alleles have been observed in similar frequencies among different ethnic groups, the insertion or subsequent deletion of this Alu sequence in the human TPA gene must have occurred early in human evolution.     

Molecular analysis of an IS200 insertion in the gpt gene of Salmonella typhimurium LT2.

A strain of Salmonella typimurium LT2 has been isolated which carries an insertion of approximately 700 bp in the gpt gene. The insertion in the gpt gene was shown to be the Salmonella-specific element IS200. The mutation in strain CR1 arose without selection during storage and is only the second phenotypically identified mutation caused by the insertion of IS200.     

A human dihydrofolate reductase intronless pseudogene with an Alu repetitive sequence: multiple DNA insertions at a single chromosomal site

A dihydrofolate reductase (DHFR) pseudogene, hDHFR-psi 3 has been isolated from a human genomic DNA fragment library. Sequence analysis of this gene revealed a lack of introns and the presence of a tract of nine adenines, 90 bp downstream from the end of the coding sequence. These features suggest that hDHFR-psi 3 was derived from a processed RNA molecule that has been converted into DNA and inserted into a chromosome, analogous to the origin of three intronless human DHFR genes previously described. An interesting feature of hDHFR-psi 3 is the presence of a member of the Alu moderately repetitive DNA sequence family within the DHFR coding region. This Alu element is flanked by a 16 bp directly repeated DNA segment derived from DHFR coding sequences. The Alu element apparently has been inserted into the intronless DHFR pseudogene and thus, there have been two insertions at a single chromosomal locus. The hDHFR-psi 3 contains only the 3' half of the DHFR coding sequence. Immediately upstream from the directly repeated sequence before the Alu element is an adenine-rich tract. The DNA farther upstream is moderately repetitive and is related to neither DHFR nor Alu DNA sequence. Therefore, it seems possible that a third insertion has occurred at the same site further disrupting the hDHFR coding sequences.     

Characterization of pre-insertion loci of de novo L1 insertions

The human Long Interspersed Element-1 (LINE-1) and the Short Interspersed Element (SINE) Alu comprise 28% of the human genome. They share the same L1-encoded endonuclease for insertion, which recognizes an A+T-rich sequence. Under a simple model of insertion distribution, this nucleotide preference would lead to the prediction that the populations of both elements would be biased towards A+T-rich regions. Genomic L1 elements do show an A+T-rich bias. In contrast, Alu is biased towards G+C-rich regions when compared to the genome average. Several analyses have demonstrated that relatively recent insertions of both elements show less G+C content bias relative to older elements. We have analyzed the repetitive element and G+C composition of more than 100 pre-insertion loci derived from de novo L1 insertions in cultured human cancer cells, which should represent an evolutionarily unbiased set of insertions. An A+T-rich bias is observed in the 50 bp flanking the endonuclease target site, consistent with the known target site for the L1 endonuclease. The L1, Alu, and G+C content of 20 kb of the de novo pre-insertion loci shows a different set of biases than that observed for fixed L1s in the human genome. In contrast to the insertion sites of genomic L1s, the de novo L1 pre-insertion loci are relatively L1-poor, Alu-rich and G+C neutral. Finally, a statistically significant cluster of de novo L1 insertions was localized in the vicinity of the c-myc gene. These results suggest that the initial insertion preference of L1, while A+T-rich in the initial vicinity of the break site, can be influenced by the broader content of the flanking genomic region and have implications for understanding the dynamics of L1 and Alu distributions in the human genome.     

Repetitive nucleotide sequence insertions into a novel calmodulin-related gene and its processed pseudogene

A gene containing a transposon-like human repeat element, called THE 1, has been isolated and characterized. The gene, termed T+, encodes a polypeptide resembling known calcium-binding proteins. The THE 1 element is present in the 3'-untranslated region of its message. The cDNA clone corresponding to the gene's mRNA product led to the identification of this gene. A processed RNA pseudogene related to the authentic gene has also been isolated. In addition to intron processing, this pseudogene differs from the gene in that it contains an interspersed Alu repeat instead of a THE 1 element in the 3'-untranslated region. Thus, we compare a site containing a THE 1 element to an ancestrally related transposon-less target site. The comparison suggests a retroviral-related mechanism of THE 1 insertion. This system is unusual in that the parent gene is associated with three distinct retrotransposition events: the parent gene was converted to a processed RNA pseudogene, an Alu repeat inserted into the pseudogene, and a THE 1 element inserted into the parent gene.     

PROGINS Alu insertion and human genomic diversity

A polymorphic Alu element belonging to the young Ya5 subfamily of Alu repeats located in the progesterone receptor gene has been characterized. Using a polymerase chain reaction (PCR)-based assay, the genetic diversity associated with the PROGINS Alu repeat was determined in a diverse array of human populations. The level of insertion polymorphism associated with PROGINS suggests that it will be a useful marker for the study of human evolution. In addition, we determined the distribution of the PROGINS Alu insertion in two groups of women from greater New Orleans, LA with breast cancer. The PROGINS Alu insertion was not associated with breast cancer in the populations tested.     

Evolution of a polymorphic regulatory element in interferon-gamma through transposition and mutation

Mammalian transposable elements have intrinsic regulatory elements that can activate neighboring genes, and it is speculated that they can also carry extrinsic transactivating DNA sequences to new genomic locations. We have identified a polymorphic segment of the human interferon-gamma promoter region where two adjacent binding sites for NF-kappaB and NFAT originated from the insertion of an Alu element approximately 22-34 MYA. Both binding sites lie outside the Alu consensus sequence but within the boundaries of the insertion, suggesting that this segment of DNA was comobilized when the Alu element moved from another part of the genome. Sequence comparisons and examination of DNA-protein interactions across nine different primate species indicate that the inserted sequence contained the intact NFAT binding site, whereas the ability to bind NF-kappaB evolved through a series of mutations after the insertion. These observations are consistent with the notion that retropseudogenes can comobilize intact regulatory sequences to new locations and thereby influence the evolution of gene regulatory networks; however, the extent to which such events have shaped the evolution of gene regulation remains unknown.     

HIGM syndrome caused by insertion of an AluYb8 element in exon 1 of the <Emphasis Type="Italic">CD40LG</Emphasis> gene

A new mutation of the CD40LG gene that encodes the CD40 ligand molecule was characterized in a young patient harboring a hyper-IgM with immunodeficiency syndrome. Inactivation of CD40LG gene resulted from the insertion of an AluYb8 element in exon 1 responsible for a total deficiency of CD40 ligand expression by T lymphocytes. Maternal transmission of the X-linked mutation was confirmed by gene-specific polymerase chain reaction. This is the 17th case report concerning a human genetic disease caused by an Alu element insertion in a coding sequence.     

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.     

Recent insertion of an alu sequence in the beta-globin gene cluster of the gorilla

We present the nucleotide sequence of a new Alu family member that lies between the delta- and beta-globin genes in gorilla DNA. The sequence exhibits 91% similarity with a consensus sequence of the Alu family. It is flanked by a perfect repetition of a 16-nucleotide target sequence and terminates with 24 adenylic residues. As this sequence is absent at this locus in other primate DNAs, its insertion occurred less than 8 million years ago, thus supporting the idea that Alu sequences are still mobile elements in the hominoid genome.