Mutation detection and single-molecule counting using isothermal rolling-circle amplification

Nucleotide sequence-based multitarget identification

MULTIGEN technology (T. Vinayagamoorthy, U.S. patent 6,197,510, March 2001) is a modification of conventional sequencing technology that generates a single electropherogram consisting of short nucleotide sequences from a mixture of known DNA targets. The target sequences may be present on the same or different nucleic acid molecules. For example, when two DNA targets are sequenced, the first and second sequencing primers are annealed to their respective target sequences, and then a polymerase causes chain extension by the addition of new deoxyribose nucleotides. Since the electrophoretic separation depends on the relative molecular weights of the truncated molecules, the molecular weight of the second sequencing primer was specifically designed to be higher than the combined molecular weight of the first sequencing primer plus the molecular weight of the largest truncated molecule generated from the first target sequence. Thus, the series of truncated molecules produced by the second sequencing primer will have higher molecular weights than those produced by the first sequencing primer. Hence, the truncated molecules produced by these two sequencing primers can be effectively separated in a single lane by standard gel electrophoresis in a single electropherogram without any overlapping of the nucleotide sequences. By using sequencing primers with progressively higher molecular weights, multiple short DNA sequences from a variety of targets can be determined simultaneously. We describe here the basic concept of MULTIGEN technology and three applications: detection of sexually transmitted pathogens (Neisseria gonorrhoeae, Chlamydia trachomatis, and Ureaplasma urealyticum), detection of contaminants in meat samples (coliforms, fecal coliforms, and Escherichia coli O157:H7), and detection of single-nucleotide polymorphisms in the human N-acetyltransferase (NAT1) gene (S. Fronhoffs et al., Carcinogenesis 22:1405-1412, 2001).

Approaching real-time molecular diagnostics: single-pair fluorescence resonance energy transfer (spFRET) detection for the analysis of low abundant point mutations in K-ras oncogenes

The aim of this study was to develop new strategies for analyzing molecular signatures of disease states approaching real-time using single pair fluorescence resonance energy transfer (spFRET) to rapidly detect point mutations in unamplified genomic DNA. In addition, the detection process was required to discriminate between normal and mutant (minority) DNAs in heterogeneous populations. The discrimination was carried out using allele-specific primers, which flanked the point mutation in the target gene and were ligated using a thermostable ligase enzyme only when the genomic DNA carried this mutation. The allele-specific primers also carried complementary stem structures with end-labels (donor/acceptor fluorescent dyes, Cy5/Cy5.5, respectively), which formed a molecular beacon following ligation. We coupled ligase detection reaction (LDR) with spFRET to identify a single base mutation in codon 12 of a K-ras oncogene that has high diagnostic value for colorectal cancers. A simple diode laser-based fluorescence system capable of interrogating single fluorescent molecules undergoing FRET was used to detect photon bursts generated from the molecular beacon probes formed upon ligation. LDR-spFRET provided the necessary specificity and sensitivity to detect single-point mutations in as little as 600 copies of human genomic DNA directly without PCR at a level of 1 mutant per 1000 wild type sequences using 20 LDR thermal cycles. We also demonstrate the ability to rapidly discriminate single base differences in the K-ras gene in less than 5 min at a frequency of 1 mutant DNA per 10 normals using only a single LDR thermal cycle of genomic DNA (600 copies). Real-time LDR-spFRET detection of point mutations in the K-ras gene was accomplished in PMMA microfluidic devices using sheath flows.

Protein expression profiling arrays: tools for the multiplexed high-throughput analysis of proteins

The completion of the human genome sequence has led to a rapid increase in genetic information. The invention of DNA microarrays, which allow for the parallel measurement of thousands of genes on the level of mRNA, has enabled scientists to take a more global view of biological systems. Protein microarrays have a big potential to increase the throughput of proteomic research. Microarrays of antibodies can simultaneously measure the concentration of a multitude of target proteins in a very short period of time. The ability of protein microarrays to increase the quantity of data points in small biological samples on the protein level will have a major impact on basic biological research as well as on the discovery of new drug targets and diagnostic markers. This review highlights the current status of protein expression profiling arrays, their development, applications and limitations.

Multiplexed genotyping with sequence-tagged molecular inversion probes

We report on the development of molecular inversion probe (MIP) genotyping, an efficient technology for large-scale single nucleotide polymorphism (SNP) analysis. This technique uses MIPs to produce inverted sequences, which undergo a unimolecular rearrangement and are then amplified by PCR using common primers and analyzed using universal sequence tag DNA microarrays, resulting in highly specific genotyping. With this technology, multiplex analysis of more than 1,000 probes in a single tube can be done using standard laboratory equipment. Genotypes are generated with a high call rate (95%) and high accuracy (>99%) as determined by independent sequencing.

Competitive assay formats for high-throughput affinity arrays

The authors describe a novel method for the quantitation of differential levels of biomolecules using unlabeled samples and protein-binding arrays for assessing differential expression. Traditional affinity arrays, whether in microplates or protein microarrays, suffer from a few common problems-a shortage of characterized antibodies and highly variable affinities for those available. Also, the assayed proteins could be present in a wide range of concentrations and physicochemical properties, so that it becomes an onerous task to optimize assay conditions for each antibody-antigen pair. Currently, this restricts parallel affinity assays to a low number of carefully selected antibodies and restricts the development of highly multiplexed parallel affinity assays. A displacement strategy allows the use of a much wider range of antibodies, reducing the requirement for matched affinities. The competitive assays described here also show a much higher tolerance for nonspecific background noise. The range of assayed protein concentrations is only limited by the sensitivity of the detection system used.

High accuracy genotyping directly from genomic DNA using a rolling circle amplification based assay

BACKGROUND

Rolling circle amplification of ligated probes is a simple and sensitive means for genotyping directly from genomic DNA. SNPs and mutations are interrogated with open circle probes (OCP) that can be circularized by DNA ligase when the probe matches the genotype. An amplified detection signal is generated by exponential rolling circle amplification (ERCA) of the circularized probe. The low cost and scalability of ligation/ERCA genotyping makes it ideally suited for automated, high throughput methods.

RESULTS

A retrospective study using human genomic DNA samples of known genotype was performed for four different clinically relevant mutations: Factor V Leiden, Factor II prothrombin, and two hemochromatosis mutations, C282Y and H63D. Greater than 99% accuracy was obtained genotyping genomic DNA samples from hundreds of different individuals. The combined process of ligation/ERCA was performed in a single tube and produced fluorescent signal directly from genomic DNA in less than an hour. In each assay, the probes for both normal and mutant alleles were combined in a single reaction. Multiple ERCA primers combined with a quenched-peptide nucleic acid (Q-PNA) fluorescent detection system greatly accellerated the appearance of signal. Probes designed with hairpin structures reduced misamplification. Genotyping accuracy was identical from either purified genomic DNA or genomic DNA generated using whole genome amplification (WGA). Fluorescent signal output was measured in real time and as an end point.

CONCLUSIONS

Combining the optimal elements for ligation/ERCA genotyping has resulted in a highly accurate single tube assay for genotyping directly from genomic DNA samples. Accuracy exceeded 99 % for four probe sets targeting clinically relevant mutations. No genotypes were called incorrectly using either genomic DNA or whole genome amplified sample.

Digital genotyping and haplotyping with polymerase colonies

Polymerase colony (polony) technology amplifies multiple individual DNA molecules within a thin acrylamide gel attached to a microscope slide. Each DNA molecule included in the reaction produces an immobilized colony of double-stranded DNA. We genotype these polonies by performing single base extensions with dye-labeled nucleotides, and we demonstrate the accurate quantitation of two allelic variants. We also show that polony technology can determine the phase, or haplotype, of two single- nucleotide polymorphisms (SNPs) by coamplifying distally located targets on a single chromosomal fragment. We correctly determine the genotype and phase of three different pairs of SNPs. In one case, the distance between the two SNPs is 45 kb, the largest distance achieved to date without separating the chromosomes by cloning or somatic cell fusion. The results indicate that polony genotyping and haplotyping may play an important role in understanding the structure of genetic variation.

Atomic force microscopy analysis of rolling circle amplification of plasmid DNA

Rolling circle amplification (RCA) of plasmid DNA using random hexamers and bacteriophage phi29 DNA polymerase is an increasingly applied technique for amplifying template DNA for DNA sequencing. We analyzed this RCA reaction at a single-molecular level by atomic force microscopy (AFM) and found that multibranched amplified products containing tandem repeats of a circle unit are formed within 1 h. We also used the RCA product of a GFP expression vector for the protein expression in cells, and found that the crude RCA product from one bacterial colony is sufficient for the GFP expression. Thus, the RCA reaction is useful in amplifying DNA for both DNA sequencing and protein expression.

Isothermal reactions for the amplification of oligonucleotides

We have devised a class of isothermal reactions for amplifying DNA. These homogeneous reactions rapidly synthesize short oligonucleotides (8-16 bases) specified by the sequence of an amplification template. Versions of the reactions can proceed in either a linear or an exponential amplification mode. Both of these reactions require simple, constant conditions, and the rate of amplification depends entirely on the molecular parameters governing the interactions of the molecules in the reaction. The exponential version of the reaction is a molecular chain reaction that uses the oligonucleotide products of each linear reaction to create producers of more of the same oligonucleotide. It is a highly sensitive chain reaction that can be specifically triggered by given DNA sequences and can achieve amplifications of >10(6)-fold. Several similar reactions in this class are described here. The robustness, speed, and sensitivity of the exponential reaction suggest it will be useful in rapidly detecting the presence of small amounts of a specific DNA sequence in a sample, and a range of other applications, including many currently making use of the PCR.

Light-directed 5'-->3' synthesis of complex oligonucleotide microarrays

Light-directed synthesis of high-density microarrays is currently performed in the 3'-->5' direction due to constraints in existing synthesis chemistry. This results in the probes being unavailable for many common types of enzymatic modification. Arrays that are synthesized in the 5'-->3' direction could be utilized to perform parallel genotyping and resequencing directly on the array surface, dramatically increasing the throughput and reducing the cost relative to existing techniques. In this report we demonstrate the use of photoprotected phosphoramidite monomers for light-directed array synthesis in the 5'-->3' direction, using maskless array synthesis technology. These arrays have a dynamic range of >2.5 orders of magnitude, sensitivity below 1 pM and a coefficient of variance of <10% across the array surface. Arrays containing >150,000 probe sequences were hybridized to labeled mouse cRNA producing highly concordant data (average R(2) = 0.998). We have also shown that the 3' ends of array probes are available for sequence-specific primer extension and ligation reactions.

Amplifying whole insect genomes with multiple displacement amplification

Many applications in insect genetics require repeated analyses on individual organisms. These include population genetic and genomics, linkage mapping, molecular systematics and map-based positional cloning. However, using the polymerase chain reaction, a limited number of analyses are possible with DNA isolated from whole bodies or parts of small or preserved specimens. We describe the optimization of a new technique, Multiple Displacement Amplification, for 100-400-fold amplification of whole mosquito genomes. We demonstrate that MDA amplifies genomic DNA directly from an adult leg or from organisms as small as a first instar mosquito larva. Genetic polymorphisms revealed at individual loci are the same whether using the original genomic DNA or MDA DNA as a template.

Novel amplification of DNA in a hairpin structure: towards a radical elimination of PCR errors from amplified DNA

Errors introduced during PCR amplification set a selectivity limit for microsatellite analysis and molecular mutation detection methods since polymerase misincorporations invariably get confused with genuine mutations. Here we present hairpin-PCR, a new form of PCR that completely separates genuine mutations from polymerase misincorporations. Hairpin-PCR operates by converting a DNA sequence to a hairpin following ligation of oligonucleotide caps to DNA ends. We developed conditions that allow a DNA hairpin to be efficiently PCR-amplified so that, during DNA synthesis, the polymerase copies both DNA strands in a single pass. Consequently, when a misincorporation occurs it forms a mismatch following DNA amplification, and is distinguished from genuine mutations that remain fully matched. Error-free DNA can subsequently be isolated using one of many approaches, such as dHPLC or enzymatic depletion. We present feasibility for the main technical steps involved in this new strategy, conversion of a sequence to a hairpin that can be PCR-amplified from human genomic DNA, exponential amplification from picogram amounts, conversion of misincorporations to mismatches and separation of homoduplex from heteroduplex hairpins using dHPLC. The present hairpin-PCR opens up the possibility for a radical elimination of PCR errors from amplified DNA and a major improvement in mutation detection.

Protein chip technology

Microarray technology has become a crucial tool for large-scale and high-throughput biology. It allows fast, easy and parallel detection of thousands of addressable elements in a single experiment. In the past few years, protein microarray technology has shown its great potential in basic research, diagnostics and drug discovery. It has been applied to analyse antibody-antigen, protein-protein, protein-nucleic-acid, protein-lipid and protein-small-molecule interactions, as well as enzyme-substrate interactions. Recent progress in the field of protein chips includes surface chemistry, capture molecule attachment, protein labeling and detection methods, high-throughput protein/antibody production, and applications to analyse entire proteomes.

Whole genome analysis of genetic alterations in small DNA samples using hyperbranched strand displacement amplification and array-CGH

Structural genetic alterations in cancer often involve gene loss or gene amplification. With the advent of microarray approaches for the analysis of the genome, as exemplified by array-CGH (Comparative Genomic Hybridization), scanning for gene-dosage alterations is limited only by issues of DNA microarray density. However, samples of interest to the pathologist often comprise small clusters of just a few hundred cells, which do not provide sufficient DNA for array-CGH analysis. We sought to develop a simple method that would permit amplification of the whole genome without the use of thermocycling or ligation of DNA adaptors, because such a method would lend itself to the automated processing of a large number of tissue samples. We describe a method that permits the isothermal amplification of genomic DNA with high fidelity and limited sequence representation bias. The method is based on strand displacement reactions that propagate by a hyperbranching mechanism, and generate hundreds, or even thousands, of copies of the genome in a few hours. Using whole genome isothermal amplification, in combination with comparative genomic hybridization on cDNA microarrays, we demonstrate the ability to detect gene losses in yeast and gene dosage imbalances in human breast tumor cell lines. Although sequence representation bias in the amplified DNA presents potential problems for CGH analysis, these problems have been overcome by using amplified DNA in both control and tester samples. Gene-dosage alterations of threefold or more can be observed with high reproducibility with as few as 1000 cells of starting material.

Multiplexed protein profiling on antibody-based microarrays by rolling circle amplification

Multiplexed immunoassays on antibody-based protein microarrays are an attractive solution for analyzing biological responses in normal and diseased states. Recently, the feasibility and utility of these assays has been established as concerns about specificity and sensitivity are being overcome by careful quality control and amplification technologies such as rolling circle amplification (RCA). RCA-amplified protein chips can now profile up to 150 proteins in various substrates including serum, plasma, and supernatants with high sensitivity, broad dynamic range and good reproducibility. Diagnostic utility of RCA-amplified protein chips has been shown for multiplexed allergen testing. When allied with multivariate statistical analysis, RCA protein chips have the potential to identify multiplexed biomarker classifiers for disease diagnosis and drug response.

Lateral-flow and up-converting phosphor reporters to detect single-stranded nucleic acids in a sandwich-hybridization assay

Up-converting Phosphor Technology (UPT) particles were used as reporters in lateral-flow (LF) assays to detect single-stranded nucleic acids. The 400-nm phosphor particles exhibit strong visible luminescence upon excitation with infrared (IR) light resulting in the total absence of background autofluorescence from other biological compounds. A sandwich-type hybridization assay was applied using two sequence-specific oligonucleotides. One of the oligonucleotides probes was covalently bound to the UPT particle (reporter) for direct labeling and detection, whereas the second oligonucleotide probe contained biotin for capture by avidin during LF. The whole procedure of hybridization, UPT-LF detection, and analysis required a minimum time of 20 min. Moreover, aiming at minimal equipment demands, the hybridization conditions were chosen such that the entire assay could be performed at ambient temperature. During lateral flow, only targets hybridized to both capture and detection oligonucleotide were trapped and detected at an avidin capture line on the LF strip. Analysis (IR scanning) of the strips was performed in an adapted microtiter plate reader provided with a 980-nm IR laser for excitation of the phosphor particles (a portable reader was also available). Visible luminescence was measured and presented as relative fluorescence units (RFU) allowing convenient quantitation of the phosphor signal. With the assay described here as little as 0.1 fmol of a specific single-stranded nucleic acid target was detected in a background of 10 microg fish sperm DNA.

Single nucleotide polymorphism genotyping using locked nucleic acid (LNA)

Locked nucleic acid (LNA) is a new class of bicyclic high affinity DNA analogs. LNA-containing oligonucleotides confer significantly increased affinity against their complementary DNA targets, increased mismatch discrimination (delta Tm) and allow full control of the melting point of the hybridization reaction. LNA chemistry is completely compatible with the traditional DNA phosphoramidite chemistry and therefore LNA-DNA mixmer oligonucleotides can be designed with complete freedom for optimal performance. These properties render LNA oligonucleotides very well suited for SNP genotyping and have enabled several approaches for enzyme-independent SNP genotyping based on allele-specific hybridization. In addition, allele-specific PCR assays relying on enzymatically-enhanced discrimination can be improved using LNA-modified oligonucleotides. The use of LNA transforms enzyme-independent genotyping approaches into experimentally simple, robust and cost-effective assays, which are highly suited for genotyping in clinical and industrial settings.

Techniques patents for SNP genotyping

Single nucleotide polymorphisms (SNPs) are the most abundant form of genetic variation in the human genome, accounting for more than 90% of all differences between individuals. Many complex phenotypes in humans have a significant genetic component and most of the variability is therefore likely to stem from differences in patterns of SNPs. Association studies involving the large-scale analysis of SNPs can help to identify genes affecting many human phenotype variations, including complex diseases and drug responses. SNPs therefore play a major role in all stages of the drug development process, from target identification through to clinical trials. SNPs are also the basis of pharmacogenomics, the tailoring of medicines to suit an individual's genome. Given the potential impact of SNPs on healthcare, the biotechnology industry has focussed urgently on the development of high-throughput methods for SNP genotyping. All genotyping methods are a mix and match of different allele discrimination and signal detection technologies and as such may represent the intellectual property of several individuals or organizations. In this review, we explore the patent issues surrounding SNP genotyping and how this is influencing large scale, commercially valuable projects involving SNPs.

Practical applications of rolling circle amplification of DNA templates

Since its recent implementation at one of the world's largest high-throughput sequencing centers, the utility of MP-RCA for DNA sequencing has been thoroughly validated. However, applications of this technology extend far beyond DNA sequencing. While many of these applications have been explored in this chapter, the future will undoubtedly add to this growing list.

Optimization of Rolling-Circle Amplified Protein Microarrays for Multiplexed Protein Profiling

Protein microarray-based approaches are increasingly being used in research and clinical applications to either profile the expression of proteins or screen molecular interactions. The development of high-throughput, sensitive, convenient, and cost-effective formats for detecting proteins is a necessity for the effective advancement of understanding disease processes. In this paper, we describe the generation of highly multiplexed, antibody-based, specific, and sensitive protein microarrays coupled with rolling-circle signal amplification (RCA) technology. A total of 150 cytokines were simultaneously detected in an RCA sandwich immunoassay format. Greater than half of these proteins have detection sensitivities in the pg/mL range. The validation of antibody microarray with human serum indicated that RCA-based protein microarrays are a powerful tool for high-throughput analysis of protein expression and molecular diagnostics.

A cytogenetic footprint for mammary carcinomas induced by PhIP in rats

2-Amino-1-methyl-6-phenylimidazo [4,5-b] pyridine (PhIP), a mutagen/carcinogen belonging to the class of heterocyclic amines (HCAs) found in cooked meats, is a mammary gland carcinogen in rats and has been implicated in the etiology of certain human cancers including breast cancer. To gain insight into the genomic alterations associated with PhIP-induced mammary gland carcinogenesis, we used comparative genomic hybridization (CGH) to examine chromosomal abnormalities in rat mammary carcinomas induced by PhIP, and for comparison, by DMBA (7, 12-dimethylbenz[a]anthracene), a potent experimental mammary carcinogen. There was a consistent and characteristic pattern of chromosome-region loss in PhIP-induced carcinomas that clearly distinguished them from carcinomas induced by DMBA.

Sequence variation and the biological function of genes: methodological and biological considerations

Single nucleotide polymorphisms (SNPs) are expected to facilitate the chromosomal mapping and eventual cloning of genetic determinants of complex quantitative phenotypes. To date, more than 2.5 million non-redundant human SNPs have been reported in the public domain, of which approximately 100000 have been validated by either independent investigators or by independent methods. Equally impressive is the myriad of methods developed for allelic discrimination. Nevertheless, reports of successful applications of SNPs to genome-wide linkage analysis of both mono- and polygenic traits are rare and limited to a few model organisms, that provide affordable platforms to test both novel methodological and biological concepts at a whole-genome scale under conditions that can be reasonably controlled. Progress in the analysis of SNPs needs to be complemented by methods that allow the systematic elucidation of both primary and secondary phenotypes of genes. Importantly, observations made in one species may very well be of immediate applicability to other species including human. This is particularly true for conserved biological processes such as mitochondrial respiration and DNA repair.

Progress in high throughput SNP genotyping methods

Most current single nucleotide polymorphism (SNP) genotyping methods are still too slow and expensive for routine use in large association studies with hundreds or more SNPs in a large number of DNA samples. However, SNP genotyping technology is rapidly progressing with the emergence of novel, faster and cheaper methods as well as improvements in the existing methods. In this review, we focus on technologies aimed at high throughput uses, and discuss the technical advances made in this field in the last few years. The rapid progress in technology, in combination with the discovery of millions of SNPs and the development of the human haplotype map, may enable whole genome association studies to be initiated in the near future.

Artificial human telomeres from DNA nanocircle templates

Human telomerase is a reverse-transcriptase enzyme that synthesizes the multikilobase repeating hexamer telomere sequence (TTAGGG)n at the ends of chromosomes. Here we describe a designed approach to mimicry of telomerase, in which synthetic DNA nanocircles act as essentially infinite catalytic templates for efficient synthesis of long telomeres by DNA polymerase enzymes. Results show that the combination of a nanocircle and a DNA polymerase gives a positive telomere-repeat amplification protocol assay result for telomerase activity, and similar to the natural enzyme, it is inhibited by a known telomerase inhibitor. We show that artificial telomeres can be engineered on human chromosomes by this approach. This strategy allows for the preparation of synthetic telomeres for biological and structural study of telomeres and proteins that interact with them, and it raises the possibility of telomere engineering in cells without expression of telomerase itself. Finally, the results provide direct physical support for a recently proposed rolling-circle mechanism for telomerase-independent telomere elongation.

Protein microarrays and proteomics

The system-wide study of proteins presents an exciting challenge in this information-rich age of whole-genome biology. Although traditional investigations have yielded abundant information about individual proteins, they have been less successful at providing us with an integrated understanding of biological systems. The promise of proteomics is that, by studying many components simultaneously, we will learn how proteins interact with each other, as well as with non-proteinaceous molecules, to control complex processes in cells, tissues and even whole organisms. Here, I discuss the role of microarray technology in this burgeoning area.

Protein chips: from concept to practice

A series of exciting reports over the past two years has established the usefulness of protein chips and made important advances in preparing protein arrays. However, several technical challenges must still be addressed to make these tools available to the wider community of researchers. Here, we discusses these challenges and survey recent opportunities for creating quantitative assays, preparing and immobilizing large numbers of proteins, using detection methods to analyze the results of chip-based experiments, and using informatics tools to interpret these results.

Isothermal strand-displacement amplification applications for high-throughput genomics

Amplification of source DNA is a nearly universal requirement for molecular biology applications. The primary methods currently available to researchers are limited to in vivo amplification in Escherichia coli hosts and the polymerase chain reaction. Rolling-circle DNA replication is a well-known method for synthesis of phage genomes and recently has been applied as rolling circle amplification (RCA) of specific target sequences as well as circular vectors used in cloning. Here, we demonstrate that RCA using random hexamer primers with 29 DNA polymerase can be used for strand-displacement amplification of different vector constructs containing a variety of insert sizes to produce consistently uniform template for end-sequencing reactions. We show this procedure to be especially effective in a high-throughput plasmid production sequencing process. In addition, we demonstrate that whole bacterial genomes can be effectively amplified from cells or small amounts of purified genomic DNA without apparent bias for use in downstream applications, including whole genome shotgun sequencing.

Single-nucleotide sequence discrimination in situ using padlock probes

DNA ligases are very sensitive to mismatches at the DNA ends to be joined through ligation. This mechanism has been exploited to distinguish DNA sequence variants in situ using so-called padlock probes. Padlock probes are linear oligonucleotides with target-complementary sequences at both ends, and an on-target-complementary segment in between. The end sequences are brought next to each other upon hybridization to the target DNA sequence, and if the ends are perfectly matched to the target sequence, they can be joined by a DNA ligase. Padlock probes detect target sequences with very high specificity, because both probe segments must hybridize to the target for circularization to occur. This unit presents a protocol for discrimination between closely similar DNA sequences in situ using padlock probes. A discussion of methods for greatly amplifying the signal from circularized probes is also included.DNA ligases are very sensitive to mismatches at the DNA ends to be joined through ligation.

SNP typing by apyrase-mediated allele-specific primer extension on DNA microarrays

This study reports the development of a microarray-based allele-specific extension method for typing of single nucleotide polymorphisms (SNPs). The use of allele-specific primers has been employed previously to identify single base variations but it is acknowledged that certain mismatches are not refractory to extension. Here we have overcome this limitation by introducing apyrase, a nucleotide-degrading enzyme, to the extension reaction. We have shown previously that DNA polymerases exhibit slower reaction kinetics when extending a mismatched primer compared with a matched primer. This kinetic difference is exploited in the apyrase-mediated allele-specific extension (AMASE) assay, allowing incorporation of nucleotides when the reaction kinetics are fast but degrading the nucleotides before extension when the reaction kinetics are slow. Here we show that five homozygous variants (14% of the total number of variants) that were incorrectly scored in the absence of apyrase were correctly typed when apyrase was included in the extension reaction. AMASE was performed in situ on the oligonucleotide microarrays using fluorescent nucleotides to type 10 SNPs and two indels in 17 individuals generating approximately 200 genotypes. Cluster analysis of these data shows three distinct clusters with clear-cut boundaries. We conclude that SNP typing on oligonucleotide microarrays by AMASE is an efficient, rapid and accurate technique for large-scale genotyping.

Single nucleotide polymorphism seeking long term association with complex disease

Successful investigation of common diseases requires advances in our understanding of the organization of the genome. Linkage disequilibrium provides a theoretical basis for performing candidate gene or whole-genome association studies to analyze complex disease. However, to constructively interrogate SNPs for these studies, technologies with sufficient throughput and sensitivity are required. A plethora of suitable and reliable methods have been developed, each of which has its own unique advantage. The characteristics of the most promising genotyping and polymorphism scanning technologies are presented. These technologies are examined both in the context of complex disease investigation and in their capacity to face the unique physical and molecular challenges (allele amplification, loss of heterozygosity and stromal contamination) of solid tumor research.

From PCR to RCA: a surgical trainee's guide to the techniques of genetic amplification

With the advent of evidence-based medicine and the Calman-Hine Report, more and more surgical trainees are undertaking a period of research, either before entering or during their Specialist Registrar training. Many will encounter concepts in science uncommon in daily clinical settings. This paper will elucidate the techniques of genetic amplification available today with their potential for usage in clinical research.

High throughput genotyping technologies for pharmacogenomics

Genetic differences between individuals play a role in determining susceptibility to diseases as well as in drug response. The challenge today is first to discover the range of genetic variability in the human population and then to define the particular gene variants, or alleles, that contribute to clinically important outcomes. Consequently, high throughput, automated methods are being developed that allow rapid scoring of microsatellite alleles and single nucleotide polymorphisms (SNPs). Many detection technologies are being used to accomplish this goal, including electrophoresis, standard fluorescence, fluorescence polarization, fluorescence resonance energy transfer, and mass spectrometry. SNP alleles may be distinguished by any one of several methods, including single nucleotide primer extension, allele-specific hybridization, allele-specific primer extension, oligonucleotide ligation assay, and invasive signal amplification. Newer methods require less sample manipulation, increase sensitivity, allow more flexibility, and decrease reagent costs. Recent developments show promise for continuing these trends by combining amplification and detection steps and providing flexible, miniaturized platforms for genotyping.

Real-time monitoring of rolling-circle amplification using a modified molecular beacon design

We describe a method to monitor rolling-circle replication of circular oligonucleotides in dual-color and in real-time using molecular beacons. The method can be used to study the kinetics of the polymerization reaction and to amplify and quantify circularized oligonucleotide probes in a rolling-circle amplification (RCA) reaction. Modified molecular beacons were made of 2'-O-Me-RNA to prevent 3' exonucleolytic degradation by the polymerase used. Moreover, the complement of one of the stem sequences of the molecular beacon was included in the RCA products to avoid fluorescence quenching due to inter-molecular hybridization of neighboring molecular beacons hybridizing to the concatemeric polymerization product. The method allows highly accurate quantification of circularized DNA over a broad concentration range by relating the signal from the test DNA circle to an internal reference DNA circle reporting in a distinct fluorescence color.

Integration of DNA ligation and rolling circle amplification for the homogeneous, end-point detection of single nucleotide polymorphisms

Association studies using common sequence variants or single nucleotide polymorphisms (SNPs) may provide a powerful approach to dissect the genetic inheritance of common complex traits. Such studies necessitate the development of cost-effective, high throughput technologies for scoring SNPs. The method described in this paper for the co-detection of both alleles of a SNP in a single homogeneous reaction combines the specificity of a high fidelity DNA ligation step with the power of rolling circle amplification. The incorporation of Amplifluor energy transfer primers enables signal detection in a homogeneous format, making this approach highly amenable to automation. The adaptation of the genotyping method for high throughput screening using conventional liquid handling systems is described.

Temperature dependence of thermodynamic properties for DNA/DNA and RNA/DNA duplex formation

A clear difference in the enthalpy changes derived from spectroscopic and calorimetric measurements has recently been shown. The exact interpretation of this deviation varied from study to study, but it was generally attributed to the non-two-state transition and heat capacity change. Although the temperature-dependent thermodynamics of the duplex formation was often implied, systemic and extensive studies have been lacking in universally assigning the appropriate thermodynamic parameter sets. In the present study, the 24 DNA/DNA and 41 RNA/DNA oligonucleotide duplexes, designed to avoid the formation of hairpin or slipped duplex structures and to limit the base pair length less than 12 bp, were selected to evaluate the heat capacity changes and temperature-dependent thermodynamic properties of duplex formation. Direct comparison reveals that the temperature-independent thermodynamic parameters could provide a reasonable approximation only when the temperature of interest has a small deviation from the mean melting temperature over the experimental range. The heat capacity changes depend on the base composition and sequences and are generally limited in the range of -160 to approximately -40 cal.mol-1.K-1 per base pair. In contrast to the enthalpy and entropy changes, the free energy change and melting temperature are relatively insensitive to the heat capacity change. Finally, the 16 NN-model free energy parameters and one helix initiation at physiological temperature were extracted from the temperature-dependent thermodynamic data of the 41 RNA/DNA hybrids.

Accelerated reaction by loop-mediated isothermal amplification using loop primers

Loop-mediated isothermal amplification (LAMP) is a novel nucleic acid amplification method that amplifies DNA with high specificity, efficiency and rapidity under isothermal conditions using a set of four specially designed primers and a DNA polymerase with strand displacement activity. We have developed a method that accelerates the LAMP reaction by using additional primers, termed loop primers. Loop primers hybridize to the stem-loops, except for the loops that are hybridized by the inner primers, and prime strand displacement DNA synthesis. Although both inner and loop primers react via the loops, they do so by different mechanisms. The LAMP method presented here uses loop primers to achieve reaction times of less than half that of the original LAMP method. Since the total time of analysis including detection is less than 1h, this new method should facilitate genetic analysis, including genetic diagnosis in the clinical laboratory.

Novel and alternate SNP and genetic technologies

There are many different genotyping technologies and chemistries. Other articles in this special issue focus on nanotechnology, bioinformatics, DNA chips and genotyping methods. This article focuses on four method categories not featured elsewhere in this, or the following special issue: (1) melting curve-based technologies such as dynamic allele-specific hybridization (DASH), melting curve single nucleotide polymorphism (McSNP), fluorescent resonance energy transfer (FRET), hybridization-based melting curves, and homogeneous assay formats based on melting curves; (2) non-PCR-dependent assays such as the oligonucleotide ligation assay and Invader, and isothermal amplification techniques such as rolling circle amplification; (3) rapid whole genome sequencing with methods such as the use of single molecule arrays and molecular resonance sequencing; (4) and other promising novel technologies.

DNA polymerase III holoenzyme from Thermus thermophilus identification, expression, purification of components, and use to reconstitute a processive replicase

DNA replication in bacteria is performed by a specialized multicomponent replicase, the DNA polymerase III holoenzyme, that consist of three essential components: a polymerase, the beta sliding clamp processivity factor, and the DnaX complex clamp-loader. We report here the assembly of the minimal functional holoenzyme from Thermus thermophilus (Tth), an extreme thermophile. The minimal holoenzyme consists of alpha (pol III catalytic subunit), beta (sliding clamp processivity factor), and the essential DnaX (tau/gamma), delta and delta' components of the DnaX complex. We show with purified recombinant proteins that these five components are required for rapid and processive DNA synthesis on long single-stranded DNA templates. Subunit interactions known to occur in DNA polymerase III holoenzyme from mesophilic bacteria including delta-delta' interaction, deltadelta'-tau/gamma complex formation, and alpha-tau interaction, also occur within the Tth enzyme. As in mesophilic holoenzymes, in the presence of a primed DNA template, these subunits assemble into a stable initiation complex in an ATP-dependent manner. However, in contrast to replicative polymerases from mesophilic bacteria, Tth holoenzyme is efficient only at temperatures above 50 degrees C, both with regard to initiation complex formation and processive DNA synthesis. The minimal Tth DNA polymerase III holoenzyme displays an elongation rate of 350 bp/s at 72 degrees C and a processivity of greater than 8.6 kilobases, the length of the template that is fully replicated after a single association event.

Comprehensive human genome amplification using multiple displacement amplification

Fundamental to most genetic analysis is availability of genomic DNA of adequate quality and quantity. Because DNA yield from human samples is frequently limiting, much effort has been invested in developing methods for whole genome amplification (WGA) by random or degenerate oligonucleotide-primed PCR. However, existing WGA methods like degenerate oligonucleotide-primed PCR suffer from incomplete coverage and inadequate average DNA size. We describe a method, termed multiple displacement amplification (MDA), which provides a highly uniform representation across the genome. Amplification bias among eight chromosomal loci was less than 3-fold in contrast to 4-6 orders of magnitude for PCR-based WGA methods. Average product length was >10 kb. MDA is an isothermal, strand-displacing amplification yielding about 20-30 microg product from as few as 1-10 copies of human genomic DNA. Amplification can be carried out directly from biological samples including crude whole blood and tissue culture cells. MDA-amplified human DNA is useful for several common methods of genetic analysis, including genotyping of single nucleotide polymorphisms, chromosome painting, Southern blotting and restriction fragment length polymorphism analysis, subcloning, and DNA sequencing. MDA-based WGA is a simple and reliable method that could have significant implications for genetic studies, forensics, diagnostics, and long-term sample storage.

Multiplexed protein profiling on microarrays by rolling-circle amplification

Fluorescent-sandwich immunoassays on microarrays hold appeal for proteomics studies, because equipment and antibodies are readily available, and assays are simple, scalable, and reproducible. The achievement of adequate sensitivity and specificity, however, requires a general method of immunoassay amplification. We describe coupling of isothermal rolling-circle amplification (RCA) to universal antibodies for this purpose. A total of 75 cytokines were measured simultaneously on glass arrays with signal amplification by RCA with high specificity, femtomolar sensitivity, 3 log quantitative range, and economy of sample consumption. A 51-feature RCA cytokine glass array was used to measure secretion from human dendritic cells (DCs) induced by lipopolysaccharide (LPS) or tumor necrosis factor-alpha (TNF-alpha). As expected, LPS induced rapid secretion of inflammatory cytokines such as macrophage inflammatory protein (MIP)-1beta, interleukin (IL)-8, and interferon-inducible protein (IP)-10. We found that eotaxin-2 and I-309 were induced by LPS; in addition, macrophage-derived chemokine (MDC), thymus and activation-regulated chemokine (TARC), soluble interleukin 6 receptor (sIL-6R), and soluble tumor necrosis factor receptor I (sTNF-RI) were induced by TNF-alpha treatment. Because microarrays can accommodate approximately 1,000 sandwich immunoassays of this type, a relatively small number of RCA microarrays seem to offer a tractable approach for proteomic surveys.

Making ends meet in genetic analysis using padlock probes

Padlock probes are molecular tools that combine highly specific target sequence recognition with the potential for multiplexed analysis of large sets of target DNA or RNA sequences. In this brief review, we exemplify the ability of these probes to distinguish single-nucleotide target sequence variants. We further discuss means to detect the location of target sequences in situ, and to amplify reacted padlock probes via rolling-circle replication, as well as to sort reaction products on tag-arrays. We argue that the probes have the potential to render high-throughput genetic analyses precise and affordable.

Pharmacogenetic tactics and strategies: implications for paediatrics

Genetic diversity exerts profound effects on variation in human drug response in adults, but comparatively little research that specifically relates to genetically abnormal responses in infancy and childhood has been reported. Specific genetic changes in human enzymes, receptors and other proteins that are implicated in drug response and their associated phenotypic correlates provide needed data for construction of profiles individualised to predict susceptibility to adverse drug reactions. If therapy adheres to such guidelines, failure to respond to drug therapy and drug toxicity among genetically susceptible persons can be greatly minimised or averted.

Sequence variation in genes and genomic DNA: methods for large-scale analysis

The large-scale typing of sequence variation in genes and genomic DNA presents new challenges for which it is not clear that current technologies are sufficiently sensitive, robust, or scalable. This review surveys the current platform technologies: separation-based approaches, which include mass spectrometry; homogeneous assays; and solid-phase/array-based assays. We assess techniques for discovering and typing variation on a large scale, especially that of single-nucleotide polymorphisms. The in-depth focus is the DNA chip/array platform, and some of the published large-scale studies are closely examined. The problem of large-scale amplification is addressed, and emerging technologies for present and future needs are indicated.

Solid-phase profiling of proteins

Protein array technologies refer to any fabrication and use of any arrays containing multiple proteins captured on solid surfaces. This valuable tool is used for high-throughput protein-protein interaction studies, protein marker discovery and other applications. This unit provides basic protocols for biomarker discovery and protein-protein interactions. Different kinds of recently emerged protein array technologies and related detection methods are reviewed.

Measuring proteins on microarrays

A prerequisite of proteomics is the ability to quantify many selected proteins simultaneously. Immunoassays on microarrays are an attractive solution, as equipment and antibodies are available and assays are simple, scalable and reproducible. Recently, considerable progress has been made in this area as evidenced by increased sensitivity and coverage (degree of multiplexing). Routine use of antibody microarrays in research and diagnostic settings will require increased availability of binding reagents, novel signal amplification procedures, inexpensive and robust platforms for microarray production and detection, and turn-key systems for running high-throughput assays.

Rolling-circle amplification under topological constraints

We have performed rolling-circle amplification (RCA) reactions on three DNA templates that differ distinctly in their topology: an unlinked DNA circle, a linked DNA circle within a pseudorotaxane-type structure and a linked DNA circle within a catenane. In the linked templates, the single-stranded circle (dubbed earring probe) is threaded, with the aid of two peptide nucleic acid openers, between the two strands of double-stranded DNA (dsDNA). We have found that the RCA efficiency of amplification was essentially unaffected when the linked templates were employed. By showing that the DNA catenane remains intact after RCA reactions, we prove that certain DNA polymerases can carry out the replicative synthesis under topological constraints allowing detection of several hundred copies of a dsDNA marker without DNA denaturation. Our finding may have practical implications in the area of DNA diagnostics.

Methods for genotyping single nucleotide polymorphisms

One of the fruits of the Human Genome Project is the discovery of millions of DNA sequence variants in the human genome. The majority of these variants are single nucleotide polymorphisms (SNPs). A dense set of SNP markers opens up the possibility of studying the genetic basis of complex diseases by population approaches. In all study designs, a large number of individuals must be genotyped with a large number of markers. In this review, the current status of SNP genotyping is discussed in terms of the mechanisms of allelic discrimination, the reaction formats, and the detection modalities. A number of genotyping methods currently in use are described to illustrate the approaches being taken. Although no single genotyping method is ideally suited for all applications, a number of good genotyping methods are available to meet the needs of many study designs. The challenges for SNP genotyping in the near future include increasing the speed of assay development, reducing the cost of the assays, and performing multiple assays in parallel. Judging from the accelerated pace of new method development, it is hopeful that an ideal SNP genotyping method will be developed soon.

Bayesian haplotype inference for multiple linked single-nucleotide polymorphisms

Haplotypes have gained increasing attention in the mapping of complex-disease genes, because of the abundance of single-nucleotide polymorphisms (SNPs) and the limited power of conventional single-locus analyses. It has been shown that haplotype-inference methods such as Clark's algorithm, the expectation-maximization algorithm, and a coalescence-based iterative-sampling algorithm are fairly effective and economical alternatives to molecular-haplotyping methods. To contend with some weaknesses of the existing algorithms, we propose a new Monte Carlo approach. In particular, we first partition the whole haplotype into smaller segments. Then, we use the Gibbs sampler both to construct the partial haplotypes of each segment and to assemble all the segments together. Our algorithm can accurately and rapidly infer haplotypes for a large number of linked SNPs. By using a wide variety of real and simulated data sets, we demonstrate the advantages of our Bayesian algorithm, and we show that it is robust to the violation of Hardy-Weinberg equilibrium, to the presence of missing data, and to occurrences of recombination hotspots.

Recognition of guanine-guanine mismatches by the dimeric form of 2-amino-1,8-naphthyridine

Dimeric 2-amino-1,8-naphthyridine selectively binds to a G-G mismatch with high affinity (K(d) = 53 nM). We have investigated a binding mechanism of naphthyridine dimer 2 to a G-G mismatch by spectroscopic studies, thermodynamic analysis, and structure-activity studies for the thermal stabilization of the mismatch. 1H NMR spectra of a complex of 2 with 9-mer duplex d(CATCGGATG)2 containing a G-G mismatch showed that all hydrogens in two naphthyridine rings of 2 were observed upfield compared to those of 2 in a free state. The 2D-NOESY experiments showed that each naphthyridine of 2 binds to a guanine in the G-G mismatch within the pi-stack. In CD spectra, a large conformational change of the G-G mismatch-containing duplex was observed upon complex formation with 2. Isothermal calorimetry titration of 2 binding to the G-G mismatch showed that the stoichiometry for the binding is about 1:1 and that the binding is enthalpy-controlled. It is clarified by structure-activity studies that show (i) the linker connecting two naphthyridine rings was essential for the stabilization of the G-G mismatch, (ii) the binding efficiency was very sensitive to the linker structure, and (iii) the binding of two naphthyridines to each one of two Gs in the G-G mismatch is essential for a strong stabilization. These results strongly supported the intercalation of both naphthyridine rings of 2 into DNA base pairs and the formation of a hydrogen bonded complex with the G-G mismatch.