High-throughput genotyping of single nucleotide polymorphisms with rolling circle amplification.

BACKGROUND: Single nucleotide polymorphisms (SNPs) are the foundation of powerful complex trait and pharmacogenomic analyses. The availability of large SNP databases, however, has emphasized a need for inexpensive SNP genotyping methods of commensurate simplicity, robustness, and scalability. We describe a solution-based, microtiter plate method for SNP genotyping of human genomic DNA. The method is based upon allele discrimination by ligation of open circle probes followed by rolling circle amplification of the signal using fluorescent primers. Only the probe with a 3' base complementary to the SNP is circularized by ligation. RESULTS: SNP scoring by ligation was optimized to a 100,000 fold discrimination against probe mismatched to the SNP. The assay was used to genotype 10 SNPs from a set of 192 genomic DNA samples in a high-throughput format. Assay directly from genomic DNA eliminates the need to preamplify the target as done for many other genotyping methods. The sensitivity of the assay was demonstrated by genotyping from 1 ng of genomic DNA. We demonstrate that the assay can detect a single molecule of the circularized probe. CONCLUSIONS: Compatibility with homogeneous formats and the ability to assay small amounts of genomic DNA meets the exacting requirements of automated, high-throughput SNP scoring.

Rapid amplification of plasmid and phage DNA using Phi 29 DNA polymerase and multiply-primed rolling circle amplification.

We describe a simple method of using rolling circle amplification to amplify vector DNA such as M13 or plasmid DNA from single colonies or plaques. Using random primers and phi29 DNA polymerase, circular DNA templates can be amplified 10,000-fold in a few hours. This procedure removes the need for lengthy growth periods and traditional DNA isolation methods. Reaction products can be used directly for DNA sequencing after phosphatase treatment to inactivate unincorporated nucleotides. Amplified products can also be used for in vitro cloning, library construction, and other molecular biology applications.

Role of the adenovirus DNA-binding protein in in vitro adeno-associated virus DNA replication.

A basic question in adeno-associated virus (AAV) biology has been whether adenovirus (Ad) infection provided any function which directly promoted replication of AAV DNA. Previously in vitro assays for AAV DNA replication, using linear duplex AAV DNA as the template, uninfected or Ad-infected HeLa cell extracts, and exogenous AAV Rep protein, demonstrated that Ad infection provides a direct helper effect for AAV DNA replication. It was shown that the nature of this helper effect was to increase the processivity of AAV DNA replication. Left unanswered was the question of whether this effect was the result of cellular factors whose activity was enhanced by Ad infection or was the result of direct participation of Ad proteins in AAV DNA replication. In this report, we show that in the in vitro assay, enhancement of processivity occurs with the addition of either the Ad DNA-binding protein (Ad-DBP) or the human single-stranded DNA-binding protein (replication protein A [RPA]). Clearly Ad-DBP is present after Ad infection but not before, whereas the cellular level of RPA is not apparently affected by Ad infection. However, we have not measured possible modifications of RPA which might occur after Ad infection and affect AAV DNA replication. When the substrate for replication was an AAV genome inserted into a plasmid vector, RPA was not an effective substitute for Ad-DBP. Extracts supplemented with Ad-DBP preferentially replicated AAV sequences rather than adjacent vector sequences; in contrast, extracts supplemented with RPA preferentially replicated vector sequences.

cDNA cloning and gene mapping of human homologs for Schizosaccharomyces pombe rad17, rad1, and hus1 and cloning of homologs from mouse, Caenorhabditis elegans, and Drosophila melanogaster.

Mutations in DNA repair/cell cycle checkpoint genes can lead to the development of cancer. The cloning of human homologs of yeast DNA repair/cell cycle checkpoint genes should yield candidates for human tumor suppressor genes as well as identifying potential targets for cancer therapy. The Schizosaccharomyces pombe genes rad17, rad1, and hus1 have been identified as playing roles in DNA repair and cell cycle checkpoint control pathways. We have cloned the cDNA for the human homolog of S. pombe rad17, RAD17, which localizes to chromosomal location 5q13 by fluorescence in situ hybridization and radiation hybrid mapping; the cDNA for the human homolog of S. pombe rad1, RAD1, which maps to 5p14-p13.2; and the cDNA for the human homolog of S. pombe hus1, HUS1, which maps to 7p13-p12. The human gene loci have previously been identified as regions containing tumor suppressor genes. In addition, we report the cloning of the cDNAs for genes related to S. pombe rad17, rad9, rad1, and hus1 from mouse, Caenorhabditis elegans, and Drosophila melanogaster. These include Rad17 and Rad9 from D. melanogaster, hpr-17 and hpr-1 from C. elegans, and RAD1 and HUS1 from mouse. The identification of homologs of the S. pombe rad checkpoint genes from mammals, arthropods, and nematodes indicates that this cell cycle checkpoint pathway is conserved throughout eukaryotes.

Isolation of human and fission yeast homologues of the budding yeast origin recognition complex subunit ORC5: human homologue (ORC5L) maps to 7q22.

Orc5p is a subunit of the origin recognition complex in the budding yeast Saccharomyces cerevisiae, which has been shown to play a critical role in both chromosomal DNA replication and transcriptional silencing. We have cloned cDNAs from both human and fission yeast Schizosaccharomyces pombe that encode proteins homologous to the budding yeast and Drosophila Orc5p. Human Orc5p showed 35.1, 22.3, and 19.4% identity to the Drosophila, S. pombe, and S. cerevisiae Orc5p, respectively. We have localized the human ORC5 gene (ORC5L) to chromosome 7 using Southern and PCR analysis of DNA isolated from a panel of human/rodent somatic cell hybrids and mapped the gene locus to 7q22 using fluorescence in situ hybridization. We have identified a YAC clone that contains human ORC5L and maps to chromosome band 7q22.1. We have identified the S. pombe ORC5 gene and located it in a cosmid mapped on chromosome II.

Two steps to binding replication origins? DNA-protein interactions.

Recent structural studies of the Epstein-Barr virus EBNA1 protein bound to DNA suggest that it binds to DNA replication origins in a two-step process; the first step involves recognition of the correct sequence and the second initiates structural changes in the DNA.

In vitro reconstitution of human replication factor C from its five subunits.

Replication factor C (RFC, also called Activator I) is part of the processive eukaryotic DNA polymerase holoenzymes. The processive elongation of DNA chains requires that DNA polymerases are tethered to template DNA at primer ends. In eukaryotes the ring-shaped homotrimeric protein, proliferating cell nuclear antigen (PCNA), ensures tight template-polymerase interaction by encircling the DNA strand. Proliferating cell nuclear antigen is loaded onto DNA through the action of RFC in an ATP-dependent reaction. Human RFC is a protein complex consisting of five distinct subunits that migrate through SDS/polyacrylamide gels as protein bands of 140, 40, 38, 37, and 36 kDa. All five genes encoding the RFC subunits have been cloned and sequenced. A functionally identical RFC complex has been isolated from Saccharomyces cerevisiae and the deduced amino acid sequences among the corresponding human and yeast subunits are homologous. Here we report the expression of the five cloned human genes using an in vitro coupled transcription/translation system and show that the gene products form a complex resembling native RFC that is active in supporting an RFC-dependent replication reaction. Studies on the interactions between the five subunits suggest a cooperative mechanism in the assembly of the RFC complex. A three-subunit core complex, consisting of p36, p37, and p40, was identified and evidence is presented that p38 is essential for the interaction between this core complex and the large p140 subunit.

Assignment of the 36.5-kDa (RFC5), 37-kDa (RFC4), 38-kDa (RFC3), and 40-kDa (RFC2) subunit genes of human replication factor C to chromosome bands 12q24.2-q24.3, 3q27, 13q12.3-q13, and 7q11.23.

Replication factor C is a multimeric primer-recognition protein consisting of five subunits (p145, p40, p38, p37, and p36.5) and is essential for the processive elongation of DNA chains catalyzed by DNA polymerase delta or epsilon in human cells. We have mapped the locations on human chromosomes of the genes coding for the four smaller subunits [p36.5 (RFC5), p37 (RFC4), p38 (RFC3), and p40 (RFC2)] using both PCR amplification from DNAs of a panel of somatic hybrids and fluorescence in situ hybridization to bands 12q24.2-q24.3, 3q27, 13q12.3-q13, and 7q11.23, respectively.

Cdk-interacting protein 1 directly binds with proliferating cell nuclear antigen and inhibits DNA replication catalyzed by the DNA polymerase delta holoenzyme.

Cdk-interacting protein 1 (Cip1) is a p53-regulated 21-kDa protein that inhibits several members of the cyclin-dependent kinase (CDK) family. It was initially observed in complexes containing CDK4, cyclin D, and proliferating cell nuclear antigen (PCNA). PCNA, in conjunction with activator 1, acts as a processivity factor for eukaryotic DNA polymerase (pol) delta, and these three proteins constitute the pol delta holoenzyme. In this report, we demonstrate that Cip1 can also directly inhibit DNA synthesis in vitro by binding to PCNA. Cip1 efficiently inhibits simian virus 40 replication dependent upon pol alpha, activator 1, PCNA, and pol delta, and this inhibition can be overcome by additional PCNA. Simian virus 40 DNA replication, catalyzed solely by high levels of pol alpha-primase complex, is unaffected by Cip1. Using the surface plasmon resonance technique, a direct physical interaction of PCNA and Cip1 was detected. We have observed that Cip1 efficiently inhibits synthesis of long (7.2 kb) but not short (10 nt) templates, suggesting that its association with PCNA is likely to impair the processive movement of pol delta during DNA chain elongation, as opposed to blocking assembly of the pol delta holoenzyme. The implications of the Cip1-PCNA interaction with respect to regulation of DNA synthesis, cell cycle checkpoint control, and DNA repair are discussed.

Reconstitution of functional human single-stranded DNA-binding protein from individual subunits expressed by recombinant baculoviruses.

Human single-stranded DNA-binding protein (HSSB), also known as replication protein A, is composed of a 70-kDa single-stranded DNA-binding subunit (p70) and 34-kDa and 11-kDa (p34 and p11, respectively) subunits of unknown functions. We have examined interactions among the HSSB subunits in vivo by coinfecting insect cells with different combinations of recombinant baculoviruses encoding p70, p34, or p11. In vivo, coexpressed p34 and p11 subunits formed stable complexes, whereas neither p34 nor p11 formed stable complexes with p70. In cells coinfected with viruses expressing all three subunits, the stable heterotrimer formed, which, when purified, replaced HSSB isolated from HeLa cells in various assays, including simian virus 40 DNA replication in vitro. These data suggest that, in the assembly of functionally active HSSB, formation of the p34-p11 complex precedes p70 addition to the complex.

Mapping of the 70 kDa, 34 kDa, and 11 kDa subunit genes of the human multimeric single-stranded DNA binding protein (hSSB/RPA) to chromosome bands 17p13, 1p35-p36.1, and 7p21-p22.

Human single-stranded DNA binding protein (hSSB/RPA) is a multimeric single-stranded DNA binding protein consisting of three subunits of 70 kDa, 34 kDa, and 11 kDa. Human SSB was isolated from HeLa cells as an essential factor for the in vitro replication of simian virus 40 DNA. We and others have isolated and sequenced cDNAs for each subunit of the SSB. The chromosome on which each gene is located was determined through the analysis of a panel of human/hamster somatic cell hybrids using the polymerase chain reaction with pairs of synthetic oligonucleotide primers from the 3'-untranslated sequences of the genes. Genomic clones for each gene were isolated from a genomic cosmid library prepared from human lymphoblastoid cells. Using those clones as probes, we have carried out fluorescence in situ hybridization to human metaphase chromosomes and have mapped the 70 kDa subunit gene to 17p13, the 34 kDa subunit gene to 1p35-p36.1, and the 11 kDa subunit gene to 7p21-p22. Since hSSB participates in replication, recombination and repair of DNA, the physical mapping of hSSB genes may aid in the identification of human hereditary diseases associated with aberrant DNA reactions caused by genetic alterations of the hSSB.

The simian virus 40 T antigen double hexamer assembles around the DNA at the replication origin.

An initial step in the replication of simian virus (SV40) DNA is the ATP-dependent formation of a double hexamer of the SV40 large tumor (T) antigen at the SV40 DNA replication origin. In the absence of DNA, T antigen assembled into hexamers in the presence of magnesium and ATP. Hexameric T antigen was stable and could be isolated by glycerol gradient centrifugation. The ATPase activities of hexameric and monomeric T antigen isolated from parallel glycerol gradients were identical. However, while monomeric T antigen was active in the ATP-dependent binding, untwisting, unwinding, and replication of SV40 origin-containing DNA, hexameric T antigen was inactive in these reactions. Isolated hexamers incubated at 37 degrees C in the presence of ATP remained intact, but dissociated into monomers when incubated at 37 degrees C in the absence of ATP. This dissociation restored the activity of these preparations in the DNA replication reaction, indicating that hexameric T antigen is not permanently inactivated but merely assembled into a nonproductive structure. We propose that the two hexamers of T antigen at the SV40 origin assemble around the DNA from monomer T antigen in solution. This complex untwists the DNA at the origin, melting specific DNA sequences. The resulting single-stranded regions may be utilized by the T antigen helicase activity to initiate DNA unwinding bidirectionally from the origin.

Simian virus 40 large T antigen untwists DNA at the origin of DNA replication.

Simian virus 40 large tumor antigen (SV40 T antigen) untwists DNA at the SV40 replication origin. In the presence of ATP, T antigen shifted the average linking number of an SV40 origin-containing plasmid topoisomer distribution. The loss of up to two helical turns was detected. The reaction required the presence of the 64-base pair core origin of replication containing T antigen DNA binding site II; binding site I had no effect on the untwisting reaction. The presence of human single-stranded DNA binding protein (SSB) slightly reduced the degree of untwisting in the presence of ATP. ATP hydrolysis was not required since untwisting occurred in the presence of nonhydrolyzable analogs of ATP. However, in the presence of a nonhydrolyzable analog of ATP, the requirement for the SV40 origin sequence was lost. The origin requirement for DNA untwisting was also lost in the absence of dithiothreitol. The origin-specific untwisting activity of T antigen is distinct from its DNA helicase activity, since helicase activity does not require the SV40 origin but does require ATP hydrolysis. The lack of a requirement for SSB or ATP hydrolysis and the reduction in the pitch of the DNA helix by just a few turns at the replication origin distinguishes this reaction from the T antigen-mediated DNA unwinding reaction, which results in the formation of a highly underwound DNA molecule. Untwisting occurred without a lag after the start of the reaction, whereas unwound DNA was first detected after a lag of 10 min. It is proposed that the formation of a multimeric T antigen complex containing untwisted DNA at the SV40 origin is a prerequisite for the initiation of DNA unwinding and replication.

Differential induction of structural changes in the simian virus 40 origin of replication by T antigen.

The ATP-dependent binding of the simian virus 40 (SV40) large tumor antigen (T antigen) to the SV40 origin of replication (ori) results in the structural distortion of two critical elements within flanking regions of ori and the untwisting of the DNA helix. We examined the effect of changes in temperature, ATP concentration, and other reaction parameters on the generation of these DNA structural changes. We found that induction of the two localized structural transitions were highly and differentially sensitive to reaction conditions. Significant distortion of the early palindrome element, shown previously to result from DNA melting, required low levels of ATP (10 to 30 microM) but temperatures above 25 degrees C. Distortion of the AT tract occurred at low temperatures (5 degrees C) but required relatively high concentrations of ATP (greater than 300 microM). Thus, T antigen can induce structural changes within one critical element of ori without generating significant structural distortion within the second element. The response of ori untwisting to reaction conditions generally increased in parallel with or fell intermediate between the inductions of localized structural transitions. We suggest that ori untwisting and localized structural distortions are interdependent consequences of T-antigen binding to ori. These results suggest a model for the structural events occurring during the initial steps of SV40 DNA replication.

ATP-dependent assembly of double hexamers of SV40 T antigen at the viral origin of DNA replication.

Simian virus 40 (SV40) replicates in nuclei of human and monkey cells. One viral protein, large tumour (T) antigen, is required for the initiation of DNA replication. The development of in vitro replication systems which retain this property has facilitated the identification of the cellular components required for replication. T antigen recognizes the pentanucleotide 5'-GAGGC-3' which is present in four copies within the 64 base-pairs (bp) of the core origin. In the presence of ATP it binds with increased affinity forming a distinctive, bilobed structure visible in electron micrographs. As a helicase, it unwinds SV40 DNA bidirectionally from the origin. We report here that in vitro and in the presence of ATP, T antigen assembles a double hexamer, centred on the core origin and extending beyond it by 12 bp in each direction. The assembly of this dodecamer initiates an untwisting of the duplex by 2-3 turns. In the absence of ATP, a tetrameric structure is the largest found at the core origin. In the absence of DNA, but in the presence of ATP or its non-hydrolysable analogues, T antigen assembles into hexamers. This suggests that ATP effects an allosteric change in the monomer. The change alters protein-protein interactions and allows the assembly of a double hexamer, which initiates replication at the core origin.

An inhibitor of the in vitro elongation reaction of simian virus 40 DNA replication is overcome by proliferating-cell nuclear antigen.

The replication of simian virus 40 (SV40) origin-containing DNA has been reconstituted by using SV40 large tumor (T) antigen and cellular proteins purified from HeLa cells. This replication reaction is unaffected by proliferating-cell nuclear antigen (PCNA). In contrast, PCNA has been reported to stimulate SV40 DNA synthesis carried out with crude fractions [Prelich, G., Kostura, M., Marshak, D. R., Mathews, M. B. & Stillman, B. (1987) Nature (London) 326, 471-475]. This difference is caused by the presence of a protein in crude fractions that inhibits the elongation of nascent DNA chains during replication. In the presence of PCNA, crude fractions containing this elongation inhibition factor can extend DNA chains. We describe the partial purification of this inhibitor and show that its addition limited SV40 DNA replication to the synthesis of short chains, an effect reversed by the addition of PCNA. However, the reversal of the inhibition by PCNA in the SV40 system required additional protein fractions distinct from PCNA and the enzymes constituting the purified system. These results suggest that the PCNA-mediated effect on SV40 DNA replication may be indirect. Such an interplay between negative and positive regulatory functions including PCNA may contribute to the control of DNA synthesis characteristic of the eukaryotic cell cycle.