Scanning of nucleic acids by in vitro amplification: new developments and applications

AMPLON: Amplifying DNA with Multiarm Priming and Looping Optimization of Nucleic Acid

Nucleic acid amplification, the bedrock of biotechnology and molecular diagnostics, surges in applications-especially isothermal approaches-heightening the demand for advanced and precisely engineered methods. Here, a novel approach for amplifying DNA with multiarm priming and looping optimization of nucleic acid (AMPLON) is presented. AMPLON relies on a novel polymeric material with unique set of multiarm polyethylene glycol-DNA primers for efficient DNA amplification under isothermal conditions. Each arm carries single-stranded DNA complementing the sense or antisense sequence of the target DNA. The amplification reaction begins with antisense arms binding to the target DNA, forming a template for sense-carrying arms to direct multiarm large DNA amplicon synthesis through successive DNA looping and unlooping steps. Using human immunodeficiency virus type 1 (HIV-1) as a model clinical target, AMPLON exhibits high sensitivity, detecting target concentrations as low as 100 copies mL-1. Compared to a quantitative real-time polymerase chain reaction assay using sensitive primers, AMPLON reliably identifies HIV-1 RNA in plasma samples (n = 20) with a significant agreement rate of 95%. With its ability to achieve highly specific and sensitive target amplification within 30 min, AMPLON holds immense potential to transform the field of nucleic acid research and unleashing new possibilities in medicine and biotechnology.

Guidelines for the validation and application of typing methods for use in bacterial epidemiology

For bacterial typing to be useful, the development, validation and appropriate application of typing methods must follow unified criteria. Over a decade ago, ESGEM, the ESCMID (Europen Society for Clinical Microbiology and Infectious Diseases) Study Group on Epidemiological Markers, produced guidelines for optimal use and quality assessment of the then most frequently used typing procedures. We present here an update of these guidelines, taking into account the spectacular increase in the number and quality of typing methods made available over the past decade. Newer and older, phenotypic and genotypic methods for typing of all clinically relevant bacterial species are described according to their principles, advantages and disadvantages. Criteria for their evaluation and application and the interpretation of their results are proposed. Finally, the issues of reporting, standardisation, quality assessment and international networks are discussed. It must be emphasised that typing results can never stand alone and need to be interpreted in the context of all available epidemiological, clinical and demographical data relating to the infectious disease under investigation. A strategic effort on the part of all workers in the field is thus mandatory to combat emerging infectious diseases, as is financial support from national and international granting bodies and health authorities.

DNA polymorphism in the living fossil Ginkgo biloba from the eastern United States

Random amplified polymorphic DNA (RAPD) analysis is a valuable tool in studying inter- and intra-specific genetic variations, patterns of gene expression, and for the identification of specific genes using nearly isogenic variants. Here we used RAPD analysis to study the genetic variation in Ginkgo biloba grown in the eastern United States. Our results support the evidence that Southern blot hybridization of RAPD using probes made from cloned DNA fragments allows a more accurate analysis of the RAPD pattern than dye-stained gels or Southern blot hybridization of RAPD blots using probes made from purified PCR products. Using these techniques, we observed a high degree of relatedness among plants grown in certain localities although significant genetic variation may exist in the species, and could be a possible explanation for the observed variations in the efficacy of medications derived from G. biloba extract.

RAPD markers as predictors of infectious hypodermal and hematopoietic necrosis virus (IHHNV) resistance in shrimp (Litopenaeus stylirostris)

Random amplified polymorphic DNA (RAPD) fingerprints of two shrimp populations (Litopenaeus stylirostris) were compared to find genetic marker(s) that may be associated with infectious hypodermal and hematopoietic necrosis virus (IHHNV) resistance or susceptibility. Of the 100 10-mer random primers and 100 intersimple-sequence repeat (ISSR) primers screened, five provided markers specific to the Super Shrimp population and three provided markers specific to the wild caught population. The two populations were further characterized for relative viral load (reported as cycle threshold, CT) using real-time quantitative PCR with primers specific to the IHHNV genome. The beta-actin gene was amplified to serve as a control for normalization of the IHHNV viral load. The mean viral load was significantly lower (C(T) = 34.58; equivalent to 3.3 x 10(1) copies of IHHNV genome/ng DNA) in Super Shrimp than in the wild caught population (CT = 23.49; equivalent to 4.2 x 10(4) copies/ng DNA; P < 0.001; CT values are inversely related to viral load). A preliminary prediction model was created with Classification and Regression Tree (CART) software (Salford Systems, San Diego, Calif.), where the resultant decision tree uses the presence or absence of seven RAPD markers as predictors of the relative viral load.

Bacterial comparative genomic hybridization: a method for directly identifying lateral gene transfer

Horizontally transferred DNA is largely responsible for the dissemination of virulence traits amongst bacteria. Rapid identification of acquired DNA remains difficult as whole-genome sequencing of outbreak strains is impractical, and microarray-based approaches, while powerful, are limited to genes present only in the reference strains. Here we present a novel bacterial comparative genomic hybridization method that directly compares the genomes of related strains at sub-kilobase resolution in order to identify acquired DNA. Bacterial comparative genomic hybridization utilizes the concept of metaphase chromosome comparative genomic hybridization, and exploits the resolving power of two-dimensional DNA electrophoresis. Comparison of isogenic variants of the pathogen Pseudomonas aeruginosa detected a single-copy gene insertion responsible for gentamicin resistance.

Differential mRNA fingerprinting by preferential amplification of coding sequences

The need for rapid identification of differentially expressed genes will persist even after the complete human genomic sequence becomes available. The most popular method for identifying differentially expressed genes acquires expressed sequence tags (ESTs) from the extreme 3' non-coding end of mRNAs. Such ESTs have limitations for downstream applications. We have developed a method, termed preferential amplification of coding sequences (PACS), that was applied to identify differentially expressed coding sequence tags (dCSTs) between osteoblasts and osteosarcoma cells. PACS was achieved by PCR with a set of primers to anchor at sequences complementary to AUG sequences in mRNAs and another set of primers to anchor at a PCR-amplifiable distance from AUG sequences. An initial screen identified 103 candidate dCSTs after screening approximately 15% of the expressed genes between the two cell types. Of these sequences, 27 represent CSTs of known genes and two are from 3'-ESTs of known mRNAs. Thus, PACS identified CSTs approximately 13.5 times more often than it identified 3' ESTs, attesting to the objective of the method. Since many of the dCSTs represent known genes, their identity and potential relevance to osteosarcoma could be immediately hypothesized. Differential expression of many of the dCSTs was further demonstrated by northern blotting or RT-PCR. Since PACS is not dependent on the existence of a poly A tail on an mRNA, it should have application to identify dCSTs for both prokaryotic and eukaryotic organisms. Additionally, PACS should aid in the identification of cell-specific or tissue-specific genes and bidirectional acquisition of cDNA sequence enabling rapid retrieval of full-length cDNA sequence of novel genes.

PCR-detected genome polymorphism in malignant cell growth

In this chapter, we analyze the problem of genetic polymorphism in tumorigenesis, which determines basic capacities of tumors. The study of genome polymorphism with modified PCR methods allows the detection of various forms of polymorphism in tumor cells. This method has made it possible to determine association of DNA polymorphism with conditions of oncogenes, antioncogenes, and genes of apoptosis and with their allelic states. A special type of nonspecific DNA polymorphism that resulted from an increase in the mutation number in the cancer cell genome was discovered. This phenomenon was called the microsatellite mutator phenotype. Because the type of DNA polymorphism correlates with various biological capacities of malignant tumors and has an important prognostic significance, the analysis of DNA polymorphism in benign and malignant tumors of different histogenesis will play an important role both in theoretical studies of cancer and in oncological practice. A modified B1-PCR was used to study the genome polymorphism in the mouse tumor cells. The gain of the band 470 bp and the loss of the band 600 bp were revealed in the hepatoma cell line MH-22a as compared with liver cells of C3HA mice. The differentiation of teratocarcinoma EC F9 cells to endoderm-like cells was not accompanied by any changes in the B1-AF DNA fingerprint.

Characterization of Iberian pig genotypes using AFLP markers

The use of the AFLP (amplified fragment length polymorphism) technique for the characterization of highly inbred Iberian pig breed genotypes and the detection of strain-specific polymorphisms is demonstrated. Twelve different primer combinations were used on individual DNA samples from animals belonging to two black hairless Iberian pig strains, Guadyerbas and Coronado. These amplification reactions allowed the detection of more than 1700 amplification products of which 26 were identified as strain-specific markers, present in all individuals of one strain and absent in the other. Comparison of male and female amplification products within one strain also allowed the identification of 8 male-specific amplified bands. AFLP showed a great power of marker detection due to a high multiplex ratio and high reproducibility. Comparison of similarity and co-ancestry coefficient matrices also showed the usefulness of AFLP markers to estimate genetic relationships between individuals pigs.

High genome-wide mutation rates in vegetatively propagated bermudagrass

A cascade DNA amplification strategy that generates arbitrary signatures from amplification profiles (ASAP) was used to measure genome-wide mutation rates in bermudagrass (Cynodon). ASAP quantified nucleotide changes that were induced by irradiation, genetic instabilities and normal vegetative growth of cultivars and accessions of sterile interspecific hybrids. DNA sequence divergence between cultivar 'Tifway' and its gamma radiation-induced mutant 'Tifway II' (0.70 +/- 0.66%) was comparable to estimates in radiation-induced mutants and spontaneous sports of chrysanthemum (Chrysanthemum morifolium Ramat.). A similar divergence in sequence (0.95 +/- 0.20%) was observed in the pairwise comparison of 17 nondisjunctive 'Tifgreen' and 'Tifdwarf' accessions. Mutation during normal Tifdwarf vegetative growth was evaluated by planting sprigs and sampling their offspring. Somatic sequence divergence levels (0.004 +/- 0.007%) resulted in a mutation rate of 1.05 x 10-8 per nucleotide per generation, assuming that a bermudagrass sprig constitutes a generation of growth. These rates were comparable to those found in germinal cells and individuals of either human or Drosophila melanogaster, supporting the notion that eukaryotic evolution is generation rather than time dependent. The high accumulation of somatic mutations (10 per triploid genome) is consistent with a model whereby mutation load in a population exhibiting obligate vegetative reproduction is substantially higher than in a population under sexual or asexual reproduction. These constraints could be the cause of reported genetic instabilities in the Tifgreen-Tifdwarf complex. Finally, a long-term rate measured across accessions and indicative of the accumulation of mutations in 17 Tifgreen-Tifdwarf populations (µ = 1.02 x 10-8 per nucleotide per generation) was strikingly congruent with the bermudagrass vegetative mutation rate, suggesting absence of evolutionary constraints in the sampled genomic regions. Mutation rates calculated from across-accesions divergence estimates (5.18 +/- 0.53%) indicated that plant material was evolving 100 times faster (3.8 x 10-7 changes per nucleotide per year) than a molecular clock rate estimate for grasses, probably resulting from the compound effect of clonal growth and life span of the hybrid plant material.

Hybridization of glass-tethered oligonucleotide probes to target strands preannealed with labeled auxiliary oligonucleotides

In this article we introduce a strategy of preannealing labeled auxiliary oligonucleotides to single-stranded target DNA, prior to hybridization of the DNA target to oligonucleotide arrays (genosensors) formed on glass slides for the purpose of mutation analysis. Human genomic DNA samples from normal individuals and cystic fibrosis (CF) patients (including homozygous delta F508 and heterozygous delta F508/wild type (wt) in the region examined) were used. A PCR fragment of length 138 bp (wt) or 135 bp (mutant) was produced from exon 10 in the cystic fibrosis transmembrane conductance regulator (CFTR) gene, using a new pair of polymerase chain reaction (PCR) primers. This fragment contains four of the most frequent mutation sites causing the disease (Q493X, delta I507, delta F508, and V520F). Each of these mutations was tested using a pair of nonamer (9-mer) probes covalently attached to glass slides, representing the normal (wt) and the mutant alleles. Single-stranded target DNA was isolated from the PCR fragment using one PCR primer labeled with biotin and a streptavidin minicolumn to capture the biotin-labeled strand. Prior to hybridization to the 9-mer array on a glass slide, the unlabeled target strand was preannealed with one, three, or four auxiliary oligonucleotides, at least one being labeled with 32P. As observed previously in several laboratories, the discrimination between normal (wt) and mutant alleles at each site using oligonucleotide array hybridization ranged from very good to poor, depending on the number and location of mismatches between probe and target. Terminal mismatches along the probe were difficult to discriminate, internal mismatches were more easily discriminated, and multiple mismatches were very well discriminated. An exceptionally intense hybridization signal was obtained with a 9-mer probe that hybridized contiguously (in tandem) with one auxiliary oligonucleotide preannealed to the target DNA. The increased stability is apparently caused by strong base stacking interactions between the "capture probe" and the auxiliary oligonucleotide. The presence of the delta F508 mutation was detected with this system, including discrimination between homozygous and heterozygous conditions. Base mismatch discrimination using the arrayed 9-mer probes was improved by increasing the temperature of hybridization from 15 to 25 degrees C. Auxiliary oligonucleotides, preannealed to the single-stranded template, may serve several purposes to enable a more robust genosensor-based DNA sequence analysis: 1. A convenient means of introducing label into the target DNA molecule. 2. Disruption of interfering short-range secondary structure in the region of analysis. 3. Covering up of redundant binding sites in the target strand (i.e., where a given probe has more than one complement within the target). 4. Tandem hybridization with the capture probe (providing contiguous stacking) as a means for achieving efficient mismatch discrimination at the terminal position of the capture probe (adjacent to the auxiliary oligonucleotide). By use of multiple auxiliary oligonucleotides, all of the above benefits can be derived simultaneously.

Mutation detection by ligation to complete n-mer DNA arrays

A new approach to comparative nucleic acid sequence analysis is described that uses the ligation of DNA targets to high-density arrays containing complete sets of covalently attached oligonucleotides of length eight and nine. The combination of enzymatic or chemical ligation with a directed comparative analysis avoids many of the intrinsic difficulties associated with hybridization-based de novo sequence reconstruction methods described previously. Double-stranded DNA targets were fragmented and labeled to produce quasirandom populations of 5' termini suitable for ligation and detection on the arrays. Kilobase-size DNA targets were used to demonstrate that complete n-mer arrays can correctly verify known sequences and can determine the presence of sequence differences relative to a reference. By use of 9-mer arrays, sequences of 1.2-kb targets were verified with >99.9% accuracy. Mutations in target sequences were detected by directly comparing the intensity pattern obtained for an unknown with that obtained for a known reference sequence. For targets of moderate length (1.2 kb), 100% of the mutations in the queried sequences were detected with 9-mer arrays. For higher complexity targets (2.5 and 16.6 kb), a relatively high percentage of mutations (90% and 66%, respectively) were correctly identified with a low false-positive rate of <0.03 percent. The methods described provide a general approach to analyzing nucleic acid samples on the basis of the interpretation of sequence-specific patterns of hybridization and ligation on complete n-mer oligonucleotide arrays.