Sequence determination of nucleic acids containing 5-methylisocytosine and isoguanine: identification and insight into polymerase replication of the non-natural nucleobases

Nucleobase analogs 5-methylisocytosine (^MeisoC) and isoguanine (isoG) form a non-natural base pair in duplex nucleic acids with base pairing specificity orthogonal to the natural nucleobase pairs. Sequencing reactions were conducted with oligodeoxyribonucleotides (ODNs) containing d^MeisoC and disoG using modified pyrosequencing and dye terminator methods. Modified dye terminator sequencing was generally useful for the sequence identification of ODNs containing the non-natural nucleobases. The two sequencing methods were also used to monitor nucleotide incorporation and subsequent extension by Family A polymerases used in the sequencing methods with a six-nucleobase system that includes d^MeisoC and disoG. Nucleic acids containing the six-nucleobase system could be replicated well, but not as well as natural nucleic acids, especially in regions of high d^MeisoC–disoG content. Challenges in replication with d^MeisoC–disoG are consistent with nucleobase tautomerism in the insertion step and disrupted minor groove nucleobase pair–polymerase contacts in subsequent extension.     

A branched DNA signal amplification assay for quantification of nucleic acid targets below 100 molecules/ml.

The branched DNA hybridization assay has been improved by the inclusion of the novel nucleotides, isoC and isoG, in the amplification sequences to prevent non-specific hybridization. The novel isoC, isoG-containing amplification sequences have no detectable interaction with any natural DNA sequence. The control of non-specific hybridization in turn permits increased signal amplification. Addition of a 14 site preamplifier was found to increase the signal/noise ratio 8-fold. A set of 74 oligonucleotide probes was designed to the consensus HIV POL sequence. The detection limit of this new HIV branched DNA amplifier assay was approximately 50 molecules/ml. The assay was used to measure viral load in 87 plasma samples of HIV- infected patients on triple drug therapy whose RNA titers were <500 molecules/ml. In all 11 patients viral load eventually declined to below the detection limit with the new assay.     

Parallel-Stranded Oligonucleotides with Alternating d(A-isoG)/d(T·C) and d(A·G)/d(T·m5isoC) Sequences

Abstract

Parallel-stranded (ps) DNA hairpins with alternating d(A-isoG)/d(T·C) (designated as ps-t1) and d(A·G)/d(T·m⁵isoC) (ps-t2) sequences were studied by means of UV, CD and fluorescence spectroscopy. The thermostability of d(A·G)/d(T·m⁵isoC) sequence was close to that of aps d(G·A)/d(T·C). The stability of the ps d(A·isoG)/d(T·C) sequence was even higher than that of a related anti-parallel-stranded (aps) d(G·A)/d(T·C) sequence, being unique for ps DNAs studied so far.     

Optimal alphabets for an RNA world

Experiments have shown that the canonical AUCG genetic alphabet is not the only possible nucleotide alphabet. In this work we address the question ''is the canonical alphabet optimal?'' We make the assumption that the genetic alphabet was determined in the RNA world. Computational tools are used to infer the RNA secondary structure (shape) from a given RNA sequence, and statistics from RNA shapes are gathered with respect to alphabet size. Then, simulations based upon the replication and selection of fixed-sized RNA populations are used to investigate the effect of alternative alphabets upon RNA''s ability to step through a fitness landscape. These results show that for a low copy fidelity the canonical alphabet is fitter than two-, six- and eight-letter alphabets. In higher copy-fidelity experiments, six-letter alphabets outperform the four-letter alphabets, suggesting that the canonical alphabet is indeed a relic of the RNA world.     

Structure of bacillomycin F, a new peptidolipid antibiotic of the iturin group

The structure of a new antibiotic of the iturin group, bacillomycin F, has been demonstrated. It is a mixture of homologous peptidolipids, essentially C51H80N12O14 and C52N82N12O14. The lipid moiety consists of minor isoC15, anteisoC15 beta-amino acids and major isoC16, isoC17 and anteisoC17 beta-amino acids. The peptide sequence was determined by studying the peptides obtained after mild HCl hydrolysis and by Edman degradation of bacillomycin F treated with N-bromosuccinimide. The sequence was confirmed by two-dimensional NMR spectrometry and fast-atom-bombardment mass spectrometry gave the molecular masses of the homologous compounds. Bacillomycin F is a cyclic peptidolipid; its complete structure is given in the paper.     

Validation and estimation of parameters for a general probabilistic model of the PCR process.

Earlier work rigorously derived a general probabilistic model for the PCR process that includes as a special case the Velikanov-Kapral model where all nucleotide reaction rates are the same. In this model, the probability of binding of deoxy-nucleoside triphosphate (dNTP) molecules with template strands is derived from the microscopic chemical kinetics. A recursive solution for the probability function of binding of dNTPs is developed for a single cycle and is used to calculate expected yield for a multicycle PCR. The model is able to reproduce important features of the PCR amplification process quantitatively.With a set of favorable reaction conditions, the amplification of the target sequence is fast enough to rapidly outnumber all side products. Furthermore, the final yield of the target sequence in a multicycle PCR run always approaches an asymptotic limit that is less than one. The amplification process itself is highly sensitive to initial concentrations and the reaction rates of addition to the template strand of each type of dNTP in the solution. This paper extends the earlier Saha model with a physics based model of the dependence of the reaction rates on temperature, and estimates parameters in this new model by nonlinear regression. The calibrated model is validated using RT-PCR data.     

Isoguanine quartets formed by d(T4isoG4T4): tetraplex identification and stability.

The self-aggregation of the oligonucleotide d(T4isoG4T4) (1) is investigated. Based on ion exchange HPLC experiments and CD spectroscopy, a tetrameric structure is identified. This structure was formed in the presence of sodium ions and shows almost the same chromatographic mobility on ion exchange HPLC as d(T4G4T4) (2). The ratio of aggregate versus monomer is temperature dependent and the tetraplex of [d(T4isoG4T4)]4 is more stable than that of [d(T4G4T4)]4. A mixture of d(T4isoG4T4) and d(T4G4T4) forms mixed tetraplexes containing strands of d(T4isoG4T4) and d(T4G4T4).     

Characterization of a dITPase from the hyperthermophilic archaeon <Emphasis Type="Italic">Thermococcus onnurineus</Emphasis> NA1 and its application in PCR amplification

In this study, we found that deoxyinosine triphosphate (dITP) could inhibit polymerase chain reaction (PCR) amplification of various family B-type DNA polymerases, and 0.93% dITP was spontaneously generated from deoxyadenosine triphosphate during PCR amplification. Thus, it was hypothesized that the generated dITP might have negative effect on PCR amplification of family B-type DNA polymerases. To overcome the inhibitory effect of dITP during PCR amplification, a dITP pyrophosphatase (dITPase) from Thermococcus onnurineus NA1 was applied to PCR amplification. Genomic analysis of the hyperthermophilic archaeon T. onnurineus NA1 revealed the presence of a 555-bp open reading frame with 48% similarity to HAM1-like dITPase from Methanocaldococcus jannaschii DSM2661 (NP_247195). The dITPase-encoding gene was cloned and expressed in Escherichia coli. The purified protein hydrolyzed dITP, not deoxyuridine triphosphate. Addition of the purified protein to PCR reactions using DNA polymerases from T. onnurineus NA1 and Pyrococcus furiosus significantly increased product yield, overcoming the inhibitory effect of dITP. This study shows the first representation that removing dITP using a dITPase enhances the PCR amplification yield of family B-type DNA polymerase.     

一种用于优化PCR引物设计的短链DNA熔点分析方法

目前,PCR引物设计主要依赖于软件对引物熔点的模拟计算,而PCR退火条件的优化需进行不同条件下的扩增实验。为开发一种可高效、精确评价引物和确定退火条件的方法,本研究采用高分辨率熔解曲线（high resolution melting,HRM）测定技术直接分析短链DNA的熔点,用于引物优劣性的评价,并为退火条件的优化提供参考。本文用HRM法直接测定了非完全互补的双链DNA以及DNA发卡结构的熔点,结果显示：（1）与完全互补的双链DNA相比,较为稳定的单碱基错配A?G、G?G和T?G的熔点只降低2℃ ~ 3℃,部分双碱基错配的熔点只降低4℃ ~ 6℃,单碱基突出熔点只降低4℃~ 5℃。因此,如果采用的退火温度不当,部分错配的非目的模板可能会被扩增。（2）即使发卡结构的茎干区只有6 bp,当其环区碱基少于10 nt时,其熔点也可达到60℃以上。此外,环区的长度对发卡熔点也有较大影响。根据本研究结果发现,引物设计时应尽量避免模板引物结合区同其邻近的30 nt碱基有6 bp以上的互补部分。综上所述,本研究证明HRM熔点法是一种高效评价引物及确定退火温度的方法。     

Thymidine triphosphate synthesis in senescent WI38 cells : Relationship to loss of replicative capacity

The effect of in vitro age on thymidine triphosphate (TTP) synthesis was assessed in WI38 cultures according to the following measurements: (1) thymidine kinase activity of broken cell preparations; (2) in situ incorporation of [3H]thymidine into acid-soluble material; and (3) total intracellular TTP content as determined by an enzymatic assay. All three parameters were maximal in exponentially proliferating populations and minimal in quiescent monolayers; no significant differences between young and old cultures were observed despite the reduced replicative capacity of the latter. The addition of serum to density-arrested cultures induced both TTP synthesis and DNA replication after a lag of approx. 12 h; although a greater percentage of young cells initiated replication as compared with old, pool sizes expanded to a similar extent in both populations. Pool expansion did not require entry into S phase; the pool sizes of control and cytosyl arabinoside-treated cultures were comparable. These findings suggest that senescent cells retain the ability to synthesize TTP, even though they are incapable of replicating DNA. Because TTP synthesis is a cell cycle-dependent event that normally begins in late G1, senescent cells might be blocked in the latter portion of the prereplicative phase and not in G0 as are quiescent cells.     

An unnatural base pair system for efficient PCR amplification and functionalization of DNA molecules

Toward the expansion of the genetic alphabet, we present an unnatural base pair system for efficient PCR amplification, enabling the site-specific incorporation of extra functional components into DNA. This system can be applied to conventional PCR protocols employing DNA templates containing unnatural bases, natural and unnatural base triphosphates, and a 3′→5′ exonuclease-proficient DNA polymerase. For highly faithful and efficient PCR amplification involving the unnatural base pairing, we identified the natural-base sequences surrounding the unnatural bases in DNA templates by an in vitro selection technique, using a DNA library containing the unnatural base. The system facilitates the site-specific incorporation of a variety of modified unnatural bases, linked with functional groups of interest, into amplified DNA. DNA fragments (0.15 amol) containing the unnatural base pair can be amplified 10⁷-fold by 30 cycles of PCR, with <1% total mutation rate of the unnatural base pair site. Using the system, we demonstrated efficient PCR amplification and functionalization of DNA fragments for the extremely sensitive detection of zeptomol-scale target DNA molecules from mixtures with excess amounts (pmol scale) of foreign DNA species. This unnatural base pair system will be applicable to a wide range of DNA/RNA-based technologies.     

Recognition of an expanded genetic alphabet by type-II restriction endonucleases and their application to analyze polymerase fidelity

To explore the possibility of using restriction enzymes in a synthetic biology based on artificially expanded genetic information systems (AEGIS), 24 type-II restriction endonucleases (REases) were challenged to digest DNA duplexes containing recognition sites where individual Cs and Gs were replaced by the AEGIS nucleotides Z and P [respectively, 6-amino-5-nitro-3-(1'-β-D-2'-deoxyribofuranosyl)-2(1H)-pyridone and 2-amino-8-(1'-β-D-2'-deoxyribofuranosyl)-imidazo[1,2-a]-1,3,5-triazin-4(8H)-one]. These AEGIS nucleotides implement complementary hydrogen bond donor-donor-acceptor and acceptor-acceptor-donor patterns. Results allowed us to classify type-II REases into five groups based on their performance, and to infer some specifics of their interactions with functional groups in the major and minor grooves of the target DNA. For three enzymes among these 24 where crystal structures are available (BcnI, EcoO109I and NotI), these interactions were modeled. Further, we applied a type-II REase to quantitate the fidelity polymerases challenged to maintain in a DNA duplex C:G, T:A and Z:P pairs through repetitive PCR cycles. This work thus adds tools that are able to manipulate this expanded genetic alphabet in vitro, provides some structural insights into the working of restriction enzymes, and offers some preliminary data needed to take the next step in synthetic biology to use an artificial genetic system inside of living bacterial cells.     

Development and amplification of multiple co-dominant genetic markers from single spores of arbuscular mycorrhizal fungi by nested multiplex PCR

Multiple co-dominant genetic markers from single spores of the arbuscular mycorrhizal (AM) fungi Glomus mosseae, Glomus caledonium, and Glomus geosporum were amplified by nested multiplex PCR using a combination of primers for simultaneous amplification of five loci in one PCR. Subsequently, each marker was amplified separately in nested PCR using specific primers. Polymorphic loci within the three putative single copy genes GmFOX2, GmTOR2, and GmGIN1 were characterized by sequencing and single strand conformation polymorphisms (SSCP). Primers specific for the LSU rDNA D2 region were included in the multiplex PCR to ensure correct identification of the Glomus spp. spores. Single AM fungal spores were characterized as multilocus genotypes by combining alleles of each amplified locus. Only one copy of each putative single copy gene could be amplified from each spore, indicating that spores are homokaryotic. All isolates of G. mosseae had unique genotypes. The amplification of multiple co-dominant genetic markers from single spores by the nested multiplex PCR approach provides an important tool for future studies of AM fungi population genetics and evolution.     

Hypermutagenic PCR involving all four transitions and a sizeable proportion of transversions.

Very complex mutant libraries of the dihydrofolate reductase (DHFR) gene encoded by the Escherichia coli plasmid R67 were created using hypermutagenic PCR with biased deoxynucleotide triphosphate (dNTP) concentrations. Exploiting the particular stability of the G:T mismatch, the DHFR gene could be enriched in A+T by employing biased deoxypyrimidine triphosphate concentrations, i.e. [dTTP] > [dCTP]. A sizeable fraction of hypermutants were functional. A combination of [dTTP] > [dCTP] and [dGTP] > [dATP] biases generated mutations at unexpectedly low frequencies. This could be overcome by the addition of Mn2+ cations. Overall mutation frequencies of 10% per amplification (range 4-18% per clone) could be attained. All four transitions and a smaller number of transversions were produced throughout the gene. PCR mutagenesis could be so extensive as to inactivate all amplified versions of the gene.     

Polymerase chain reaction: a Markov process approach

A probabilistic approach to the kinetics of the polymerase chain reaction (PCR) is developed. The approach treats the primer extension step of PCR as a microscopic Markov process in which the molecules of deoxy-nucleoside triphosphate (dNTP) are bound to the 3' end of the primer strand one at a time. The binding probability rates are prescribed by combinatorial rules in accord with the microscopic chemical kinetics. As an example, a simple model based on this approach is proposed and analysed, and an exact solution for the probability distribution of lengths of synthesized DNA strands is found by analytical means. Using this solution, it is demonstrated that the model is able to reproduce the main features of PCR, such as extreme sensitivity to the variation of control parameters and the existence of an amplification plateau. A multidimensional optimization technique is used to find numerically the optimum values of control parameters which maximize the yield of the target sequence for a given PCR run while minimizing the overall run time.     

Plasmodium vivax: microsatellite analysis of multiple-clone infections

We used mixtures of genomic DNA from two genetically distinct isolates from Brazil, 42M and 312M, to investigate how accurately 12-locus microsatellite typing describes the overall genetic diversity and characterizes multilocus haplotypes in multiple-clone Plasmodium vivax infections. We found varying PCR amplification efficiencies of microsatellite alleles; for example, from the same 1:1 mixture of 42M and 312M DNA we amplified predominantly 312M-type alleles at 10 loci and 42M-type alleles at 2 loci. All microsatellite alleles were accurately scored in 1:0.5 and 1:0.25 312M:42M DNA mixtures, even when minor peak heights did not meet previously suggested criteria for minor allele detection in multiple-clone infections. Relative proportions of major and minor alleles were unaffected by multiple displacement amplification of template DNA prior to PCR-based microsatellite typing. Although microsatellite typing may detect minor alleles in clone mixtures, amplification biases may lead to inaccurate assignment of predominant haplotypes in multiple-clone P. vivax infections.     

Molecular detection of Gluconacetobacter sacchari associated with the pink sugarcane mealybug Saccharicoccus sacchari (Cockerell) and the sugarcane leaf sheath microenvironment by FISH and PCR

Molecular tools for the detection of the newly described acetic acid bacterium Gluconacetobacter sacchari from the pink sugarcane mealybug, Saccharicoccus sacchari Cockerell (Homiptera: Pseudococcidae), and in the sugarcane leaf sheath microenvironment were developed. G. sacchari specific 16S rRNA-targeted oligonucleotide primers were designed and used in PCR amplification of G. sacchari DNA directly from mealybugs, and in a nested PCR to detect low numbers of the bacteria from sugarcane leaf sheath fluid and cane internode scrapings. A sensitivity level of detection of 40-400 cells/reaction was obtained using PCR from exponentially grown bacterial cultures and of 1-10 cells in cane internode scrapings and leaf sheath fluid samples using nested PCR. The specificity of the primer set was demonstrated by the lack of amplification product formation in PCR by closely related acetic acid bacteria, including Gluconacetobacter liquefaciens, and Gluconacetobacter diazotrophicus. A Cy3 labeled probe for G. sacchari was designed and shown to be specific for the species. Investigation of the mealybug microenvironment by whole cell fluorescent in situ hybridization revealed that G. sacchari appears to represent only a minor proportion of the population of the microbiota in the mealybugs tested. This study has shown the usefulness of 16S rRNA-based molecular tools in the identification and detection of G. sacchari from environmental samples and will allow these tools to be used in further ecological research.     

Monitoring of cultivar identity in tissue culture-derived date palms using RAPD and AFLP analysis

In the present study, two polymerase chain reaction (PCR)-based methods namely, randomly amplified polymophic DNA (RAPD) and amplification fragment length polymorphism (AFLP) were employed to assess genetic variations, which may appeared, in tissue culture-derived date palm (Phoenix dactylifera) offshoots. Analysis of RAPD banding patterns generated by PCR amplification using 37 random primers gave no evidences for somaclonal variations and the percentage of polymorphic bands in a total of 259 scored bands was zero. Meanwhile, analysis of AFLP banding patterns generated using 13 primer combinations pointed to minor genetic variations in the AFLP banding patterns. The percentage of genetic variations (polymorphism) in tissue culture-derived date palm offshoots belonging to cultivars Sakkoty, Gandila and Bertamoda was 2.6, 0.79 and 1 %, respectively, as revealed by AFLP analysis. The low percentage of genetic variations confirms the genetic stability of tissue culture-derived dry date palm cultivars.     

Replacing PCR with COLD-PCR enriches variant DNA sequences and redefines the sensitivity of genetic testing

PCR is widely employed as the initial DNA amplification step for genetic testing. However, a key limitation of PCR-based methods is the inability to selectively amplify low levels of mutations in a wild-type background. As a result, downstream assays are limited in their ability to identify subtle genetic changes that can have a profound impact in clinical decision-making and outcome. Here we describe co-amplification at lower denaturation temperature PCR (COLD-PCR), a novel form of PCR that amplifies minority alleles selectively from mixtures of wild-type and mutation-containing sequences irrespective of the mutation type or position on the sequence. We replaced regular PCR with COLD-PCR before sequencing or genotyping assays to improve mutation detection sensitivity by up to 100-fold and identified new mutations in the genes encoding p53, KRAS and epidermal growth factor in heterogeneous cancer samples that had been missed by the currently used methods. For clinically relevant microdeletions, COLD-PCR enabled exclusive amplification and isolation of the mutants. COLD-PCR will transform the capabilities of PCR-based genetic testing, including applications in cancer, infectious diseases and prenatal identification of fetal alleles in maternal blood.     

Influence of PCR parameters on amplifications of HIV-1 DNA: establishment of limiting sensitivity

We have investigated the optimal reaction conditions and the limiting sensitivity for detection of HIV-1 DNA by PCR. The amplification systems studied were gag (SK38/SK39); pol (P3/P4); and two other systems described here for the first time, LTR (LTR1/LTR2) and nef (Nef1/Nef2), which amplify fragments of 115 bp, 308 bp, 632 bp and 643 bp, respectively. Two PCR profiles were assayed, and the requirements for deoxynucleoside triphosphate and MgCl2 concentrations for each amplification reaction were determined. Optimal reaction conditions were oriented toward selecting maximal amplification of the expected size fragment. Limiting sensitivity was estimated by testing the decreasing copy number of a plasmid containing HIV-1 genome and obtaining a positive amplification signal with at least 5, 5, 10 and 5 copies for LTR, gag, pol and nef, respectively. We conclude that the establishment of the detection sensitivity on a PCR is an important parameter to be considered for the interpretation of results on HIV-1 infection.