Single-base discrimination mediated by proofreading 3' phosphorothioate-modified primers

Colorimetry-Based Phosphate Measurement for Polymerase Elongation

DNA detection, which includes the measurement of variants in sequences or the presence of certain genes, is widely used in research and clinical diagnosis. Both require DNA-dependent DNA polymerase-catalyzed strand extension. Currently, these techniques rely heavily on the instruments used to visualize the results. This study introduced a simple and direct colorimetric method to measure polymerase-directed elongation. First, pyrophosphate (PPi), a by-product of strand extension, is converted into phosphate (Pi). Phosphate levels were measured using either Mo-Sb or BIOMOL Green reagent. This study showed that this colorimetry can distinguish single-base variants and detect PCR products in preset stringent conditions, implicating the potential value of this strategy to detect DNA.

A simple and rapid approach for human herpesvirus type 8 subtype characterization using single base extension

Sequence analysis of the ORFK1 of human herpesvirus type 8 (HHV-8) allows the identification of six major subtypes (A-F), which are related to human migrations and the clinical progression of Kaposi's sarcoma. Sequencing and subsequent phylogenetic analysis of ORFK1 is considered to be the most reliable method for HHV-8 genotyping. However, it exhibits challenges and limitations. Herein, we designed and validated a single base extension (SBE) protocol for characterization of HHV-8 ORFK1 subtypes. A nested polymerase chain reaction (PCR) protocol was carried out to amplify a small 294-bp PCR product encompassing four single nucleotide polymorphisms at positions 360, 406, 465 and 527 of the HHV-8 genome. Finally, a multiplex SBE technique was developed and validated in 20 samples previously genotyped by phylogenetic analysis. The patterns obtained in this reaction could successfully discriminate between ORFK1 subtypes. The typing results obtained completely matched with those of the 'gold standard' method in all analysed samples. This method can reliably identify HHV-8 subtypes A, B and C, which are the most prevalent ones worldwide, and the remaining subtypes (D, E and F). SBE can be useful as an efficient, rapid and low-cost screening method for viral genotyping in a single tube, particularly samples with low-quality DNA, and with easy data interpretation.

Development of duplex-crossed allele-specific PCR targeting of TPMT*3B and *3C using crossed allele-specific blockers to eliminate non-specific amplification

Prospective testing for variants in the thiopurine S-methyltransferase (TPMT) is considered a key process in the development of thiopurine therapy. This testing is done to avoid toxicity and side effects in the management of diverse immunological and malignant conditions. Real-time fluorescent PCR techniques using duplex-crossed allele-specific primers in a single tube (DCAS-PCR) were developed in this study to genotype the common loss-of-function TPMT*3B c.460G > A (rs1800460) and TPMT*3C c.719A > G (rs1142345) usually occurring in individuals of Chinese ethnicity. In this method, several integrated strategies were used to completely eliminate the non-specific amplification that is commonly presented in traditional allele-specific (AS) PCR. These strategies include using AS-primers (ASP) that both are artificially mismatched in the penultimate positions and phosphorothioate modifications in the 5'-termini positions. In the assay, an AS-blocker was used, locus-specific TaqMan (LST) probes were used and we used at least two fragments were simultaneously amplified in a single tube which satisfy the thermodynamic characteristics of DNA polymerase to eliminate non-specific amplification. In a group of 200 unselected subjects, the results showed that 8 samples were heterozygous of TPMT*3C, and all samples possessed wild-type TPMT*3B. There was no non-specific amplification, and the genotypes were 100% consistent with Sanger sequencing.

Sensitive and selective detections of codon 12 and 13 KRAS mutations in a single tube using modified wild-type blocker

It was hypothesized that in the WTB-PCR system, the greater number of cycles, associated with the thermodynamic driving force of DNA polymerase resulted in artificial introduction of mutant nucleotides in amplicons. In the current study, universal WTB-PCR was developed to overcome these limitations, in which two strategies were used: phosphorothioate modifications were made at the 5'-termini bases of the WTB oligonucleotides, and amplification of referenced internal positive controller (RIPC) fragments was performed. The results showed that universal WTB-PCR could detect single-copy KRAS mutant alleles with higher selectivity (i.e., 0.01%), and with greater ability to eliminate non-specific amplification of KRAS wild-type alleles in amounts up to 200 ng. Moreover, the introduction of referenced internal positive controller (RIPC) fragments prevented false-negative results caused by inadequate amounts of input sample DNA, and allowed for quantitative analysis of the mutation levels in each FFPE sample. In clinical application in 50 samples of FFPE tissue sections from mCRC patients, 70% (35/50) showed various mutations at codons 12 and 13 of KRAS genes; 30% (15/50) could be detected by traditional PCR without WTB oligonucleotides. In conclusion, universal WTB-PCR is a rapid, simple and low-cost method for detection of low-abundance KRAS mutations in mCRC patients.

The Endophytic Mycobiome of European Ash and Sycamore Maple Leaves - Geographic Patterns, Host Specificity and Influence of Ash Dieback

The European ash (Fraxinus excelsior) is threatened by the introduced ascomycete Hymenoscyphus fraxineus, the causal agent of ash dieback. Endophytic fungi are known to modulate their host's resistance against pathogens. To understand possible consequences of ash dieback on the endophytic mycobiome, F. excelsior leaves were collected in naturally regenerated forests and the fungal communities analyzed by classic culture and Illumina amplicon sequencing using a newly developed and validated fungal-specific primer. Collections were done in the area infested by ash dieback north of the Alps, and in the disease free area on the south side. Sycamore maple (Acer pseudoplatanus) was additionally collected, as well as the flowering ash (F. ornus), which occurs naturally in the south and shows tolerance to ash dieback. Both cultivation and amplicon sequencing revealed characteristic endophytic fungal communities dominated by several strictly host specific Venturia species. On A. pseudoplatanus, a hitherto undescribed Venturia species was identified. Due to its dominance on F. excelsior, V. fraxini is unlikely to go extinct in case of reduced host densities. A majority of species was not strictly host specific and is therefore likely less affected by ash dieback in the future. Still, shifts in community structure and loss of genetic diversity cannot be excluded. The potentially endangered endophyte Hymenoscyphus albidus was rarely found. In addition to host specificity, species with preferences for leaf laminae or petioles were found. We also detected considerable geographical variation between sampling sites and clear differences between the two sides of the Alps for endophytes of F. excelsior, but not A. pseudoplatanus. Since sycamore maple is not affected by an epidemic, this could point toward an influence of ash dieback on ash communities, although firm conclusions are not possible because of host preferences and climatic differences. Furthermore, the mycobiota of F. excelsior trees with or without dieback symptoms were compared, but no clear differences were detected. Besides methodical refinement, our study provides comprehensive data on the ash mycobiome that we expect to be subject to changes caused by an emerging disease of the host tree.

Donor plasmid design for codon and single base genome editing using zinc finger nucleases

In recent years, CompoZr zinc finger nuclease (ZFN) technology has matured to the point that a user-defined double strand break (DSB) can be placed at virtually any location in the human genome within 50 bp of a desired site. Such high resolution ZFN engineering is well within the conversion tract limitations demarcated by the mammalian DNA repair machinery, resulting in a nearly universal ability to create point mutations throughout the human genome. Additionally, new architectures for targeted nuclease engineering have been rapidly developed, namely transcription activator like effector nucleases (TALENs) and clustered regularly interspaced short palindromic repeats (CRISPR)/Cas systems, further expanding options for placement of DSBs. This new capability has created a need to explore the practical limitations of delivering plasmid-based information to the sites of chromosomal double strand breaks so that nuclease-donor methods can be widely deployed in fundamental and therapeutic research. In this chapter, we explore a ZFN-compatible donor design in the context of codon changes at an endogenous locus encoding the human RSK2 kinase.

A simple ABO genotyping by PCR using sequence-specific primers with mismatched nucleotides

In forensics, the specific ABO blood group is often determined by analyzing the ABO gene. Among various methods used, PCR employing sequence-specific primers (PCR-SSP) is simpler than other methods for ABO typing. When performing the PCR-SSP, the pseudo-positive signals often lead to errors in ABO typing. We introduced mismatched nucleotides at the second and the third positions from the 3'-end of the primers for the PCR-SSP method and examined whether reliable typing could be achieved by suppressing pseudo-positive signals. Genomic DNA was extracted from nail clippings of 27 volunteers, and the ABO gene was examined with PCR-SSP employing primers with and without mismatched nucleotides. The ABO blood group of the nail clippings was also analyzed serologically, and these results were compared with those obtained using PCR-SSP. When mismatched primers were employed for amplification, the results of the ABO typing matched with those obtained by the serological method. When primers without mismatched nucleotides were used for PCR-SSP, pseudo-positive signals were observed. Thus our method may be used for achieving more reliable ABO typing.

DNA replication and strand asymmetry in prokaryotic and mitochondrial genomes

Different patterns of strand asymmetry have been documented in a variety of prokaryotic genomes as well as mitochondrial genomes. Because different replication mechanisms often lead to different patterns of strand asymmetry, much can be learned of replication mechanisms by examining strand asymmetry. Here I summarize the diverse patterns of strand asymmetry among different taxonomic groups to suggest that (1) the single-origin replication may not be universal among bacterial species as the endosymbionts Wigglesworthia glossinidia, Wolbachia species, cyanobacterium Synechocystis 6803 and Mycoplasma pulmonis genomes all exhibit strand asymmetry patterns consistent with the multiple origins of replication, (2) different replication origins in some archaeal genomes leave quite different patterns of strand asymmetry, suggesting that different replication origins in the same genome may be differentially used, (3) mitochondrial genomes from representative vertebrate species share one strand asymmetry pattern consistent with the strand-displacement replication documented in mammalian mtDNA, suggesting that the mtDNA replication mechanism in mammals may be shared among all vertebrate species, and (4) mitochondrial genomes from primitive forms of metazoans such as the sponge and hydra (representing Porifera and Cnidaria, respectively), as well as those from plants, have strand asymmetry patterns similar to single-origin or multi-origin replications observed in prokaryotes and are drastically different from mitochondrial genomes from other metazoans. This may explain why sponge and hydra mitochondrial genomes, as well as plant mitochondrial genomes, evolves much slower than those from other metazoans.

A novel genotyping technique for distinguishing between Flavobacterium psychrophilum isolates virulent and avirulent to ayu, Plecoglossus altivelis altivelis (Temminck & Schlegel)

We developed a simple genotyping method for Flavobacterium psychrophilum for analysing two single nucleotide polymorphisms (SNPs) in the gyrA gene and to distinguish between isolates that are virulent and avirulent to ayu, Plecoglossus altivelis altivelis (Temminck & Schlegel). The genotyping method is an on/off switch assay and is based on the polymerase chain reaction technique with phosphorothioated primers. We classified 232 isolates from four families of fish (i.e. Plecoglossidae, Osmeridae, Cyprinidae and Salmonidae) into four genotypes (G-C, A-T, A-C and G-T). The G-C type isolates exhibited strong pathogenicity to ayu, whereas the A-T and G-T types did not show any pathogenicity to this species. The A-C type exhibited no or weak pathogenicity to ayu. These results indicate that genotyping F. psychrophilum isolates with two SNPs from gyrA can clearly distinguish between isolates potentially harmful to ayu (G-C type) and those that are potentially not harmful or less harmful (A-C, A-T and G-T type). The on/off switch assay provides a quick, simple, and very powerful DNA genotyping technique for F. psychrophilum isolates.

Discrimination of A1555G and C1494T point mutations in the mitochondrial 12S rRNA gene by on/off switch

The objective of this study was to apply the "on/off" switch consisting of 3' phosphorothioate-modified allele specific primers and exo(+) polymerase in single base discrimination of A1555G and C1494T mutations in the highly conserved sites of the mitochondrial 12S rRNA. The two point mutations are the hotspot mutations associated with either aminoglycoside antibiotics induced deafness or inherited nonsyndromic hearing loss. The PCR products of mitochondrial DNA (mtDNA) 12S rRNA gene were inserted into the pMD19-T vector for transformation into Escherichia coli JM109 competent cells for preparing wild-type pMD19-T/mt vector. Inverse PCR was carried out for mtDNA 12S rRNA gene C1494T and A1555G mutagenesis and DpnI endonuclease degradating methylated pMD19-T/mt vector existing in the inverse PCR products was carried out to construct the mutation-type pMD19-T/mtM vector. These constructed vectors were confirmed by DNA sequencing. Allelic specific primers targeting wild-type and mutation-type templates were designed with 3' terminal phosphorothioate modification. Two-directional primer extension was performed using Pfu polymerases. Amplified by exo(+) polymerase, allelic specific primers perfectly matching wild-type allele were extended while no products were produced from primers targeting point-mutated deafness-related allele. Similarly, allelic specific primers perfectly matching point-mutated deafness-related mutation-type allele were extended and no products were yielded from primers targeting wild-type allele. No specific product was observed in the primer extension reaction mediated by on/off switch in screening the mtDNA 12S rRNA gene harboring either C1494T or A1555G mutation in 40 healthy volunteers tested. These data suggest that the "off switch" mediated by exo(+) polymerase is highly reliable in the diagnosis of monogenic diseases and the novel "on/off" switch has enormous applications in systematic and extended screening of the12S rRNA gene A1555G and C1494T mutations. The established assay can be widely used not only for hearing loss patients but also for normal subjects before the use of aminoglycoside antibiotics.

Realtime exonuclease-mediated allelic discrimination (READ): a simple homogeneous genotyping assay for SNPs at the ABC gene loci

AIMS

Members of the ATP-binding-cassette transporter family are implicated in the traffic of drugs/xenobiotics. Several SNPs in these ATP-binding-cassette genes were previously identified to show evidence of recent positive selection. These recent positive selection SNPs may confer functional effects and account for variation in drug response. To facilitate association studies between these SNPs and drug response, we report the development of a homogeneous (realtime exonuclease-mediated allelic discrimination) assay to genotype these SNPs.

MATERIALS & METHODS

Realtime exonuclease-mediated allelic discrimination involves real-time PCR using a proof-reading enzyme and simultaneous genotype determination by product presence/absence as detected using SYBR Green I stain.

RESULTS

A total of 29 recent positive selection SNPs from 17 ATP-binding-cassette transporter genes were evaluated. Of the 777 eealtime exonuclease-mediated allelic discrimination assays, 773 genotypes (approximately 99.5%) were concordant with the Perlegen data and other genotyping methods.

CONCLUSION

Therefore, this simple, robust, rapid, cost-effective single-step, closed-tube assay with a scalable and automatable platform has potential applications in population genetic screening and association studies.

DNA oligonucleotides containing stereodefined phosphorothioate linkages in selected positions

This unit describes a method for the synthesis of DNA chimeric PO/PS-oligonucleotides with a stereodefined phosphorothioate bond in the selected position. Diastereomerically pure 5'-O-DMTr-N-protected-deoxyribonucleoside-3'-O-(2-thio-spiro-4,4-pentamethylene-1,3,2-oxathiaphospholane)s obtained according to the previously described protocol (UNIT 4.17) are transformed via a stereospecific 1,3,2-oxathiaphospholane-ring opening condensation into the corresponding dinucleoside phosphorothioates. Such dimers cannot be introduced into an oligonucleotide chain via the phosphoramidite approach since the unprotected P-S(-) bond is easily oxidized during routine I(2)/Py/water oxidation of the phosphite function. In the methodology described here, the reversible alkylation of the PS function is applied. Subsequently, the 3'-phosphoramidites of such PS-protected dimers prepared in situ are used for routine synthesis of chimeric PO/PS-oligonucleotides according to the phosphoramidite method. The presence of the alkylated PS-function requires modified conditions for oligonucleotide deprotection and cleavage from the solid support. Detailed procedures for the synthesis of PS-dimers and their incorporation into an oligonucleotide chain, as well as deprotection/purification steps are presented.

Significance of stereochemistry of 3'-terminal phosphorothioate-modified primer in DNA polymerase-mediated chain extension

Influence of stereochemistry of the 3'-terminal phosphorothioate (PS)-modified primers was studied in a single base extension (SBE) assay to evaluate any improvements in specificity. SBE reactions were catalyzed by members of the high fidelity Pfu family of DNA polymerases with (exo+) or without (exo-) 3' --> 5' exonucleolytic activity. The diastereomerically pure PS-labeled primers used in these studies were obtained either by the stereospecific chemical synthesis invented in our laboratory or by the more conventional ion-exchange chromatographic method for separation of a mixture of diastereomers (R(P) and S(P)). When the SBE reaction was performed in the presence of mispaired 2'-deoxyribonucleoside triphosphates (dNTPs), the "racemic" 3'-phosphorothioate primer mixture resulted in a lower level of 3' --> 5' exonuclease-mediated cleavage products in comparison to the SBE reactions carried out with the corresponding unmodified primer. When the diastereomerically pure RP 3'-phosphorothioate primer was examined, the results were largely the same as for the racemic 3'-phosphorothioate primer mixture. In contrast, a 3'-PS primer of S(P) configuration displayed significantly improved performance in the SBE reaction. This included the lack of 3' --> 5' proofreading products, less mispriming, and improved yield of incorporation of the correct nucleotide.

Enhanced discrimination of single nucleotide polymorphism in genotyping by phosphorothioate proofreading allele-specific amplification

There is a significant demand for sensitive, inexpensive, and flexible genotyping techniques that can be accomplished with reasonable throughput. Allele-specific amplification (ASA) has the advantage of combining the amplification and discrimination steps into a single reaction. However, mismatch amplification that occurs during traditional ASA limits its application for genotyping. Here, a modified ASA termed phosphorothioate proofreading allele-specific amplification (PP-ASA) is developed, for single nucleotide polymorphism (SNP) genotyping analysis. Using both 3' end phosphorothioate modification of primers and DNA polymerase with proofreading activity completely eliminated mismatch amplifications, therefore enhancing discrimination between alleles for genotyping. The conditions for PP-ASA were optimized for template concentration and amplification cycle number as both were found to be critical for accurate genotyping. The utility of PP-ASA was assessed using both plasmid and genomic DNAs as templates and validated by polymerase chain reaction (PCR)-restriction fragment length polymorphism analysis of 60 human DNA samples for two distinct SNPs. PP-ASA represents a reliable, flexible, and inexpensive assay for SNP genotyping; it could be integrated to chip- or PCR-array-based assays to improve the throughput and reduce the cost for SNP analyses.

Proofreading genotyping assays mediated by high fidelity exo+ DNA polymerases

DNA polymerases with 3'-5' proofreading function mediate high fidelity DNA replication but their application for mutation detection was almost completely neglected before 1998. The obstacle facing the use of exo(+) polymerases for mutation detection could be overcome by primer-3'-termini modification, which has been tested using allele-specific primers with 3' labeling, 3' exonuclease-resistance and 3' dehydroxylation modifications. Accordingly, three new types of single nucleotide polymorphism (SNP) assays have been developed to carry out genome-wide genotyping making use of the fidelity advantage of exo(+) polymerases. Such SNP assays might also provide a novel approach for re-sequencing and de novo sequencing. These new mutation detection assays are widely adaptable to a variety of platforms, including real-time PCR, multi-well plate and microarray technologies. Application of exo(+) polymerases to genetic analysis could accelerate the pace of personalized medicine.

Inhibition of non-homologous end joining and integration of DNA upon transformation of Rhizopus oryzae

Site-directed integration of DNA in the fungus Rhizopus has long been problematic because linearized plasmids used for transformation tend to replicate in high-molecular-weight concatenated structures, and rarely integrate into the chromosome. This work examines the methods that might interfere with the multimerization process, select against plasmids that had recircularized, and encourage strand invasion, hopefully leading to plasmid integration. In vitro methods were used to determine if the structure of the double-strand break had any effect on the ability to rejoin plasmid ends. In cell-free extracts, little difference in end-joining activity was found between linearized plasmids with 5' overhangs, 3' overhangs, or blunt ends. In addition, dephosphorylation of ends had no effect. Transformation of plasmids prepared in the same ways confirmed that they were easily religated in vivo, with almost all prototrophic isolates retaining autonomously replicated plasmids. It was possible to block religation by modifying the free ends of the linearized plasmids using oligonucleotide adapters which were blocked at the 3'-OH position and contained phosphorothioate nucleotides to make them nuclease-resistant. However, gene replacement, with repair of the auxotrophic mutation in the host chromosome, was the predominant event observed upon the transformation of these plasmids. The highest rates of integration were obtained with a plasmid containing a truncated, non-functional pyrG gene. Autonomous replication of this plasmid did not support prototrophic growth, but homologous recombination into the chromosome restored the function of the endogenous pyrG gene. All of the transformants obtained with this selective construct were found to have integrated the plasmid, with multicopy insertion being common.

Single-base discrimination mediated by proofreading inert allele specific Primers

The role of 3' exonuclease excision in DNA polymerization was evaluated for primer extension using inert allele specific primers with exonuclease-digestible ddNMP at their 3' termini. Efficient primer extension was observed in amplicons where the inert allele specific primers and their corresponding templates were mismatched. However, no primer-extended products were yielded by matched amplicons with inert primers. As a control, polymerase without proofreading activity failed to yield primer-extended products from inert primers regardless of whether the primers and templates were matched or mismatched. These data indicated that activation was undertaken for the inert allele specific primers through mismatch proofreading. Complementary to our previously developed SNP-operated on/off switch, in which DNA polymerization only occurs in matched amplicon, this new mutation detection assay mediated by exo(+) DNA polymerases has immediate applications in SNP analysis independently or in combination of the two assays.

Superb nucleotide discrimination by a novel on/off switch for DNA polymerization and its applications

With the use of polymerases having 3' to 5' exonuclease activity and 3' phosphorothioate-modified allele-specific primers, we recently devised a SNP-operated on/off switch controlling DNA polymerization. One advantage of this novel on/off switch is its adaptability to arrayed primer extension. To further expand its application in genetic analysis, this new on/off switch was evaluated in discrimination of the match/mismatch status of single nucleotides upstream from the primer 3' terminal. A set of seven amplicons was developed with the templates differing from each other by a single nucleotide. Using this set of amplicons, the new on/off switch was shown to be able to efficiently discriminate single nucleotide polymorphisms from the primer 3' terminus to the -6 position from the primer 3' terminus. These data, illustrating the broad single nucleotide discrimination ability of this novel on/off switch, explain why the SNP-operated on/off switch is powerful in SNP analysis, and also indicate useful applications to genetic analysis additional to SNP assay. First, these data broaden the application of the novel on/off switch in the analysis of mutations other than SNPs. Second, it raises a nucleotide-walking algorithm suitable for de novo array-based sequencing analysis.

Exo+ proofreading polymerases mediate genetic analysis and its application in biomedical studies

Polymerases with a proofreading function in their internal 3' to 5' exonuclease possess high fidelity for DNA replication both in vivo and in vitro. The obstacle facing Exo+ polymerases for single nucleotide polymorphism (SNP) detection could be bypassed by using primer-3'-termini modification. This hypothesis has been well tested using three types of modified allele specific primers with: 3' labeling, 3' to 5' exonuclease resistance, and 3' dehydroxylation. Accordingly, three new SNP assaying methods have been developed to carry out genome-wide genotyping, taking advantage of the enzymatic properties of Exo+ polymerases. These new mutation detection assays are widely adaptable to a variety of platforms, including multi-well plate and microarray technologies. Application of Exo+ polymerases to genetic analysis, including genotyping that is mostly relevant to pharma-cogenetics, high-fidelity gene expression profiling, rare mutation detection and mutation load assay, will help to accelerate the pace of personalized medicine. In this review paper, we will first introduce three new assays that we have recently developed, and then describe a number of their applications in pharmacogenetics and in other biomedical studies.

SNP discrimination through proofreading and OFF-switch of exo+ polymerase

Single nucleotide polymorphisms (SNPs) are useful physical markers for genetic studies as well as the cause of some genetic diseases. To develop more reliable SNP assays, we examined the underlying molecular mechanisms by which deoxyribonucleic acid (DNA) polymerases with 3' exonuclease activity maintain the high fidelity of DNA replication. In addition to mismatch removal by proofreading, we have discovered a premature termination of polymerization mediated by a novel OFF-switch mechanism. Two SNP assays were developed, one based on proofreading using 3' end-labeled primer extension and the other based on the newly identified OFF-switch, respectively. These two new assays are well suited for conventional techniques, such as electrophoresis and microplates detection systems as well as the sophisticated microchips. Application of these reliable SNP assays will greatly facilitate genetic and biomedical studies in the postgenome era.