Number Of DNA Molecules Research Articles

The Long and Winding Road: On-Demand DNA Synthesis in High Demand

The Long and Winding Road: On-Demand DNA Synthesis in High Demand

Iodide etching for one-step quantitative assay of the number of DNA molecules capped on gold nanoparticles.

Developing a direct method to easily quantify the number of DNA capped on gold nanoparticles (GNPs) is of great significance. Herein, we found that the high concentration of iodine ion (I-) can not only replace the ligands on the surface of GNPs but can also completely etch the particles by virtue of its strong reducibility. According to this finding, a mild, cost-effective, environment-friendly, and non-toxic strategy was constructed to directly and accurately estimate the amount of DNA coupled on GNPs. Due to nanometal surface energy transfer (NSET) that happened between the DNA-FAM donor and the GNPs receptor, the fluorescence was quenched; after incubating with the etching reagent 6 M I-, the recuperative fluorescence was detected directly. This method can easily estimate the number of DNA attached on the GNPs surface by one step. In a nutshell, it is a smart strategy to apply iodide etching for DNA quantification on the surface of GNPs, which breaks through the drawbacks of traditional DNA quantification strategies such as pollution, being expensive and even dangerous. This strategy takes a solid step forward for the refinement and optimization of DNA quantification and can also be more effective in detecting the number of other molecules capped on the GNPs surface, indicating that the iodide etching method is greatly helpful in bio-detection assays and nanoparticle-based therapeutics.

A Femtoliter Droplet Array for Massively Parallel Protein Synthesis from Single DNA Molecules.

Advances in spatial resolution and detection sensitivity of scientific instrumentation make it possible to apply small reactors for biological and chemical research. To meet the demand for high-performance microreactors, we developed a femtoliter droplet array (FemDA) device and exemplified its application in massively parallel cell-free protein synthesis (CFPS) reactions. Over one million uniform droplets were readily generated within a finger-sized area using a two-step oil-sealing protocol. Every droplet was anchored in a femtoliter microchamber composed of a hydrophilic bottom and a hydrophobic sidewall. The hybrid hydrophilic-in-hydrophobic structure and the dedicated sealing oils and surfactants are crucial for stably retaining the femtoliter aqueous solution in the femtoliter space without evaporation loss. The femtoliter configuration and the simple structure of the FemDA device allowed minimal reagent consumption. The uniform dimension of the droplet reactors made large-scale quantitative and time-course measurements convincing and reliable. The FemDA technology correlated the protein yield of the CFPS reaction with the number of DNA molecules in each droplet. We streamlined the procedures about the microfabrication of the device, the formation of the femtoliter droplets, and the acquisition and analysis of the microscopic image data. The detailed protocol with the optimized low running cost makes the FemDA technology accessible to everyone who has standard cleanroom facilities and a conventional fluorescence microscope in their own place.

Investigation of thermal properties of DNA structure with precise atomic arrangement via equilibrium and non-equilibrium molecular dynamics approaches

Background and ObjectiveThermal conductivity of Deoxyribonucleic acid molecules is important for nanotechnology applications. Theoretical simulations based on simple models predict thermal conductivity for these molecular structures. MethodsIn this work, we calculate the thermal properties of Deoxyribonucleic acid with precise atomic arrangement via equilibrium and non-equilibrium molecular dynamics approaches. In these methods, each Deoxyribonucleic acid molecule is represented by C, N, O, and P atoms and implemented dreidng potential to describe their atomic interactions. ResultsOur calculated rate for thermal conductivity via equilibrium and non-equilibrium molecular dynamics methods is 0.381 W/m K and 0.373 W/m K, respectively. By comparing results from these two methods, it was found that the results from equilibrium and non-equilibrium molecular dynamics methods are identical, approximately. On the other hand, the number of DNA molecules and the equilibrium temperature of the simulated structures were important factors in their thermal conductivity rates, and their thermal conductivity was calculated at 0.323 W/m K–0.381 W/m K intervals for equilibrium and 0.303 W/m K–0.373 W/m K interval for non-equilibrium calculations. ConclusionsThese results are in good agreement with thermal conductivity calculation with other research groups.

Defining tissue requirements for a reliable detection of tumor mutational burden (TMB) in clinical FFPE samples.

e14265 Background: In the context of immuno-oncology related cancer treatment, tumor mutational burden (TMB) is currently explored as a predictive biomarker for several human malignancies. Several sequencing assays are increasingly commercially available. Established methodologies require rather large amounts of DNA input (in the range of 100 ng) which, however, are frequently not available from small biopsies. We aim to investigate how tissue size and DNA input influence TMB scores. Methods: DNA from 20 specimens (12 biopsies of non-small cell lung cancer (NSCLC); 8 surgical resection specimens from NSCLC, colorectal cancer and endometrial carcinomas) was manually extracted by using the Qiagen GeneRead DNA FFPE kit. Cases were selected to provide a wide range of relative tumor cell content (from < 10% to > 50%) and to include microsatellite-stable and –instable (MSI) cases. Samples were analyzed in triplicates from predefined numbers of unstained sections of a standardized tissue size. DNA quantification was done fluorometrically and by qPCR. Up to 40 ng of DNA were analyzed with the QIASeq TMB Panel (incl. MSI primer boosters; Qiagen). Sequencing was done on an Illumina NextSeq platform, TMB scores and MSI status were determined by using the CLC workbench 5.0.1 (Qiagen). Results: Biopsy samples generated less numbers of DNA molecules (as detected by unique molecular identifiers, UMIs) and less overall reads compared to resection samples. UMI coverage was > 500x in all samples with > 15 ng DNA input. TMB scores were highly reproducible among all samples with > 15 ng DNA but differed significantly among samples with limited DNA input. Interestingly, TMB scores were inversely correlated with DNA input among those samples with < 15ng. Thus, valid TMB scores could also be obtained from only one slice of 1 cm2 tissue from tumor resections or 3 slices of an endoscopic biopsy (each of 5µm thickness). All pre-characterized MSI carcinomas could be detected correctly. Conclusions: We provide first evidence that TMB can be reliably determined also in small biopsies yielding limited DNA content. However, false high TMB scores can occur in samples with < 15ng DNA input. Our results contribute to the definition of minimum requirements (tissue size and DNA input) for valid TMB measurement on clinical FFPE samples.

Ancestral inference for branching processes in random environments and an application to polymerase chain reaction

Branching processes in random environments arise in a variety of applications such as biology, finance, and other contemporary scientific areas. Motivated by these applications, this article investigates the problem of ancestral inference. Specifically, the article develops point and interval estimates for the mean number of ancestors initiating a branching process in i.i.d. random environments and establishes their asymptotic properties when the number of replications diverges to infinity. These results are then used to quantitate the number of DNA molecules in a genetic material using data from polymerase chain reaction experiments. Numerical experiments and data analyses are included to support the proposed methods. An R software package for implementing the methods of this manuscript is also included.

MP87-01 RECURRENT MITOCHONDRIAL DNA MUTATION FOUND IN BONE METASTASES

You have accessJournal of UrologyProstate Cancer: Advanced (including Drug Therapy) IV1 Apr 2018MP87-01 RECURRENT MITOCHONDRIAL DNA MUTATION FOUND IN BONE METASTASES Carrie Sun, Colm Morrissey, John Petros, and Rebecca Arnold Carrie SunCarrie Sun More articles by this author , Colm MorrisseyColm Morrissey More articles by this author , John PetrosJohn Petros More articles by this author , and Rebecca ArnoldRebecca Arnold More articles by this author View All Author Informationhttps://doi.org/10.1016/j.juro.2018.02.2901AboutPDF ToolsAdd to favoritesDownload CitationsTrack CitationsPermissionsReprints ShareFacebookTwitterLinked InEmail INTRODUCTION AND OBJECTIVES We have previously described a single DNA base alteration in the mitochondrially encoded ND3 gene (A10398G; Thr114Ala) that occurs as a bone metastasis-specific alteration in the majority of 13 prostate cancer patients with bone metastasis (Bone 78 (2015) 81-86). The objective of this study was to define the incidence of this single base alteration in an expanded series of patients and to determine whether the prostate primary also harbored this mutation or if it occurred de-novo in the bone using an ultra-sensitive assay. METHODS We developed a digital drop PCR (ddPCR) fluorescent assay using the RainDance platform designed to quantitatively interrogate the mitochondrial DNA (mtDNA) nucleotide position 10398 missense mutation. Clinical specimens from a rapid autopsy program included 39 patients with multiple tissues available including the prostate primary, soft tissue metastases, bone metastases and normal tissue controls. The number of DNA molecules with the wild type and mutant base were counted and mutation levels compared between normal tissue, primary tumor and metastatic sites. RESULTS Of 39 patients with bone metastasis that were evaluated, 20 (51%) had significantly increased levels of the 10398 missense mutation in the mitochondrially encoded ND3 gene compared to normal uninvolved tissue. The increase ranged from 2.5-59 fold in the bone. On average, 200,000 DNA molecules were counted from each tissue examined. Because of the ultra-sensitive nature of the ddPCR assay used, we also identified the same base alteration in 2 lymph node metastases and one adrenal metastasis. Of the 3 primary prostate tissues examined that gave adequate results, 2 did not have an increased alteration at the 10398 position compared to normal tissue and one did. Of the two prostate primaries without the mutation, neither bone metastasis had the mutation. In the patient whose prostate primary tumor had mutation (2.2=fold increase over normal tissue), the bone metastasis also had the mutation (36-fold increase over normal tissue). CONCLUSIONS In this expanded cohort of 39 patients with prostate cancer bone metastases, the majority (51%) had a substantially increased level of missense mutation at the 10398 nucleotide position of the mitochondrial genome in the bone metastasis. This mutational hot-spot is unprecedented in frequency in prostate cancer and implies a strong selective pressure for bone metastatic cells that had acquired this mutation in the ND3 gene of respiratory complex 1. A smaller number of soft-tissue metastases also demonstrated enrichment of this mutation. While the small number of primary prostate cancers available for analysis preclude any firm conclusions, the two cases without the mutation also did not have the mutation in the bone metastasis while the one with the mutation in the prostate primary demonstrated a 36-fold increase of the mutation in the bone metastasis. It is therefore possible that the mutation arises in the prostate and is selected for in the bone metastasis. This finding that the exact same missense mutation is present in over 50% of patients prostate cancer bone metastases far exceeds any somatic mutation previously reported in prostate cancer suggesting functional importance. © 2018FiguresReferencesRelatedDetails Volume 199Issue 4SApril 2018Page: e1187 Advertisement Copyright & Permissions© 2018MetricsAuthor Information Carrie Sun More articles by this author Colm Morrissey More articles by this author John Petros More articles by this author Rebecca Arnold More articles by this author Expand All Advertisement Advertisement PDF downloadLoading ...

Correction: Direct Sequencing from the Minimal Number of DNA Molecules Needed to Fill a 454 Picotiterplate

This work was funded by grant CP09/00049 Miguel Servet, Instituto de Salud Carlos III, Spain to GD; by projects SAF2009-13032-C02-01 and SAF 2012-31187 (AM), BFU2009-12895-CO2-01 and SAF2010-16240 (FC) from the Spanish Ministry for Science and Innovation (MCINN), FU2008-04501-E from Spanish Ministry for Science and Innovation(MCINN) in the frame of ERA-Net PathoGenoMics and Prometeo/2009/092 from Conselleria D’Educacio Generalitat Valenciana, Spain, to AM. MD is recipient of a fellowship from Spanish Ministry of Education FPU2010. MGG was supported by a predoctoral fellowship from the Spanish Ministry of Science and Innovation (Grant number BES-2008-006029).

Digital droplet PCR for precise quantification of human T-lymphotropic virus 1 proviral loads

Elevated HTLV-1 proviral load (PVL) is thought to be the major risk factor for developing HAM/TSP in HTLV-1 infected subjects, and a high cerebrospinal fluid (CSF) to peripheral blood mononuclear cells (PBMCs) PVL ratio might be diagnostic of the condition. However, the standard method for quantification of HTLV-1 PVL, Real time PCR, has multiple limitations: the inter-assay variability increases at low PVL and low cell numbers in CSF often precludes accurate quantification. Thus, we are evaluating a novel technique, Digital Droplet PCR (ddPCR), as a potentially more reliable tool. For ddPCR, DNA samples are partitioned into thousands of nanoliter -sized droplets, amplified on a thermocycler, queried for fluorescent signal and normalized to a housekeeping gene. Due to the high number of DNA molecules and number of “independent” events (droplets), Poisson algorithms are used to determine absolute copy numbers and are independent of a standard curve. Our results suggest that ddPCR is very accurate: Intraassay variability evaluated by calculating the coefficient of variation of ten replicates of three samples of DNA in three different ranges of PVL (low 10%) was 13.0%, 7.1% and 9.5%, respectively. Interassay variability, was evaluated by calculating the CV of duplicates of PVL from three independent runs and three independent extractions was 4.5% with a standard deviation of 0.008. Additionally, ddPCR is reliable in quantifying PVL in the CSF where we have confirmed and extended previous observations of increased HTLV-I PVL in CSF of HAM/TSP compared to the periphery.

Viral diagnostics in the era of digital polymerase chain reaction

Unlike quantitative polymerase chain reaction (qPCR), digital PCR (dPCR) achieves sensitive and accurate absolute quantitation of a DNA sample without the need for a standard curve. A single PCR reaction is divided into many separate reactions that each have a positive or negative signal. By applying Poisson statistics, the number of DNA molecules in the original sample is directly calculated from the number of positive and negative reactions. The recent availability of multiple commercial dPCR platforms has led to increased interest in clinical diagnostic applications, such as low viral load detection and low abundance mutant detection, where dPCR could be superior to traditional qPCR. Here we review current literature that demonstrates dPCR's potential utility in viral diagnostics, particularly through absolute quantification of target DNA sequences and rare mutant allele detection.

Paul Doty and the Modern Era of DNA as a Molecule

In april of 1959 The Journal of Molecular Biology was launched. Word of this imminent journal had spread, and manuscripts were promptly readied and sent. The first one to be accepted and published was from the laboratory of the Harvard physical chemist, Paul Doty, and addressed the organization of DNA and protein in isolated chromatin. This prescient paper serves as a point of departure for remembering Paul Doty (1920– 2011) and all that he meant in the foundational years of molecular biology and thereafter (Fig. 1). When it was first discovered by Friedrich Miescher in 1865 as the substance “nuclein,” chromatin behaved as a proteinaceous substance (hence, the suffix “in,” borne by both terms), despite its obvious content of another component that contained phosphorus and nitrogen, later recognized as DNA. For nearly one century, the biochemical composition of chromatin remained ill-defined. The basic proteins, termed histones, were discovered by Albrecht Kossel in 1884, but their relationship to chromatin remained unclear. In the 1940s, Alexander Dounce, at the University of Rochester, rekindled the isolation of chromatin, as did the laboratories of James Bonner at Caltech and Alfred Mirsky at Rockefeller a bit later. These preparations were obtained as viscous gels, and there were uncertainties as to whether this feature was simply a signature of the long DNA or perhaps implied an adventitious coacervate formed during the extraction process. It is to be borne in mind that at those times, the discovery of the structure of DNA was yet to be made, and issues such as the length and number of DNA molecules per chromosome were unknown. Even if DNA and its associated proteins could be isolated at reasonable purity, there was no existing information by which to predict its biophysical properties, such as molecular mass (although broken from chromosomes to be sure), the persistence length of the fragments as a possible clue to the uniformity or spatial irregularity of bound proteins along the DNA, and so on. As an experienced physical chemist of polymers, in the mid-1950s Doty was keenly aware of how little was known about how DNA was organized with proteins in chromosomes. He was not alone in this awareness, but unlike others, he did something about the situation. Geoffrey Zubay in Doty’s lab achieved a soluble preparation of chromatin, and at that moment, he and his mentor knew that they could interrogate it as a particle. Inter alia, they determined the molecular weight of the chromatin pieces from light scattering, and they used optical rotatory dispersion to estimate the -helical content of the chromatin proteins. No publication had had as much influence in the epistemology of chromatin for the simple reason that Zubay and Doty were the first to study chromatin as a particle. The very first paper the Journal of Molecular Biology published might have been from any lab, on anything. It is a tribute to Paul Doty’s prescience, and now to his memory, that the first paper in the inaugural issue of JMB was so far-reaching (1). Doty and colleagues displayed prescience all throughout his career. He attracted brilliant students, postdocs, and visiting scientists. Julius Marmur perfected the isolation of very large DNA from Escherichia coli as a recipe that even inexperienced students could do (as I and thousands of others did in the 1960s). Doty’s lab was among the first to envision that the two strands of DNA could be melted apart and rejoined, forming the basis of all nucleic acid

Controllable Nanoreactor Confined to Atomic Force Microscopy Tips and Its Application in Low Copy DNA Ligation

Less molecules reaction, especially at the single molecule level, plays an important role in biochemical or chemical research. It is also significant to achieve low copy or single molecule DNA ligation during the whole genome project. In this paper, a new type of nanoreactor was constructed around atomic force microscopy (AFM) tips under certain humidity, where DNA molecules can be limited to a special space through water meniscus, so the probability of molecules collision was increased and the efficiency of DNA ligation was greatly enhanced. Combined with the nanomanipulation based on AFM, controllable nanoreactor may provide a new tool to single molecule reaction. Low copy DNA ligation was successfully achieved by this method. Results showed the number of DNA molecules involved in the nanoreactor can not be more than sixty. This method will found a base for the ultimate realization of single-molecule DNA ligation.

Analysis of the Size Distributions of Fetal and Maternal Cell-Free DNA by Paired-End Sequencing

Noninvasive prenatal diagnosis with cell-free DNA in maternal plasma is challenging because only a small portion of the DNA sample is derived from the fetus. A few previous studies provided size-range estimates of maternal and fetal DNA, but direct measurement of the size distributions is difficult because of the small quantity of cell-free DNA. We used high-throughput paired-end sequencing to directly measure the size distributions of maternal and fetal DNA in cell-free maternal plasma collected from 3 typical diploid and 4 aneuploid male pregnancies. As a control, restriction fragments of lambda DNA were also sequenced. Cell-free DNA had a dominant peak at approximately 162 bp and a minor peak at approximately 340 bp. Chromosome Y sequences were rarely longer than 250 bp but were present in sizes of <150 bp at a larger proportion compared with the rest of the sequences. Selective analysis of the shortest fragments generally increased the fetal DNA fraction but did not necessarily increase the sensitivity of aneuploidy detection, owing to the reduction in the number of DNA molecules being counted. Restriction fragments of lambda DNA with sizes between 60 bp and 120 bp were preferentially sequenced, indicating that the shotgun sequencing work flow introduced a bias toward shorter fragments. Our results confirm that fetal DNA is shorter than maternal DNA. The enrichment of fetal DNA by size selection, however, may not provide a dramatic increase in sensitivity for assays that rely on length measurement in situ because of a trade-off between the fetal DNA fraction and the number of molecules being counted.

Digital Restriction Enzyme Analysis of Methylation (DREAM) by Next Generation Sequencing Yields High Resolution Maps of DNA Methylation.

Abstract 567Methylation of CpG dinucleotides in DNA is a key epigenetic feature important for × chromosome inactivation, silencing of retrotransposons and genomic imprinting. DNA methylation undergoes complex changes in leukemia, most notably methylation of CpG islands at promoters and associated gene silencing. The direct comparison of epigenomes in normal and neoplastic blood cells will likely increase our understanding of the complex pathology of leukemia. We have developed a digital restriction enzyme analysis of methylation (DREAM) for quantitative mapping of DNA methylation with high resolution on the genome-wide scale. To perform the analysis, genomic DNA is sequentially digested with a pair of enzymes recognizing the same restriction site (CCCGGG) containing a CpG dinucleotide. The first enzyme, SmaI, cuts only at unmethylated CpG and leaves blunt ends. The second enzyme, XmaI, is not blocked by methylation and leaves a short 5' overhang. The enzymes thus create methylation-specific signatures at ends of digested DNA fragments. These are deciphered by next generation sequencing. Methylation levels for each sequenced restriction site are calculated based on the numbers of DNA molecules with the methylated or unmethylated signatures. Using the DREAM method and sequencing on the Illumina Gene Analyzer II platform, we analyzed DNA methylation in a normal adult blood sample. We acquired 32.5 million sequence tags; of these, 16.6 million were mapped to SmaI/XmaI sites unique in the human genome. With a threshold of minimum 5-fold coverage, we obtained quantitative information on the DNA methylation level of 85,171 CpG sites (23% of all genomic SmaI/XmaI sites) in 21,240 genes. The accuracy of DREAM methylation data was validated by a strong correlation with the bisulfite pyrosequencing analysis of 49 genes (R=0.83) and of spiked in plasmid DNA. In normal blood, methylation was strikingly bimodal with 39% sites showing methylation levels below 5% and 28% sites being hypermethylated at levels >95%. Methylation was largely absent within CpG islands (CGI) and more prevalent outside (non-CGI). Close to transcription start sites (within 500 bp), methylation >75% was found only in 0.65% of CGIs compared to 14% in non-CGIs (P<0.001). The methylated CGI promoters were significantly enriched for genes expressed in spermatogenesis and likely correspond to a class of potential cancer-testis antigens previously identified. Away from transcription start sites (>2 kb), methylation >75% was found in 24% of CGIs compared to 72% of non-CGIs (P<0.001). Transcription end regions were methylated in 20% in CGIs compared to 68% in non-CGIs (P<0.001). Also, we observed that 1.4% of CGIs had evidence of half methylation (35-65%), representing potentially imprinted genes. Indeed, this class includes known imprinted regions at chromosomes 8q24.3 and 11p15. Finally, we compared non-CGI promoters showing significant methylation to those free of methylation. Unmethylated promoters were more likely to be expressed in normal blood, and to encode for genes involved in metabolic processes and their regulation. In conclusion, high resolution quantitative methylation analysis is feasible using the DREAM method, and reveals important classes of genes based on methylation in normal blood. Disclosures:No relevant conflicts of interest to declare.

Noninvasive prenatal diagnosis of monogenic diseases by digital size selection and relative mutation dosage on DNA in maternal plasma

Prenatal diagnosis of monogenic diseases, such as cystic fibrosis and beta-thalassemia, is currently offered as part of public health programs. However, current methods based on chorionic villus sampling and amniocentesis for obtaining fetal genetic material pose a risk to the fetus. Since the discovery of cell-free fetal DNA in maternal plasma, the noninvasive prenatal assessment of paternally inherited traits or mutations has been achieved. Due to the presence of background maternal DNA, which interferes with the analysis of fetal DNA in maternal plasma, noninvasive prenatal diagnosis of maternally inherited mutations has not been possible. Here we describe a digital relative mutation dosage (RMD) approach that determines if the dosages of the mutant and wild-type alleles of a disease-causing gene are balanced or unbalanced in maternal plasma. When applied to the testing of women heterozygous for the CD41/42 (-CTTT) and hemoglobin E mutations on HBB, digital RMD allows the fetal genotype to be deduced. The diagnostic performance of digital RMD is dependent on interplay between the fractional fetal DNA concentration and number of DNA molecules in maternal plasma. To achieve fetal genotype diagnosis at lower volumes of maternal plasma, fetal DNA enrichment is desired. We thus developed a digital nucleic acid size selection (NASS) strategy that effectively enriches the fetal DNA without additional plasma sampling or experimental time. We show that digital NASS can work in concert with digital RMD to increase the proportion of cases with classifiable fetal genotypes and to bring noninvasive prenatal diagnosis of monogenic diseases closer to reality.

Complexation of Lipofectamine and Cholesterol-Modified DNA Sequences Studied by Single-Molecule Fluorescence Techniques

Lipoplex formation for normal and cholesterol-modified oligonucleotides is investigated by fluorescence correlation spectroscopy (FCS). To overcome the problems related to the fitting of autocorrelation curves when fluorescence bursts are present, the baseline fluorescence levels and the fluorescence bursts in the same trace were separately analyzed. This approach was not previously used in FCS studies of lipoplexes and allowed a more detailed characterization of this heterogeneous system. From the baseline levels, the number of free/bound DNA molecules and the presence of tens to hundreds of nanometer-sized lipoplexes were estimated using various mathematical models. Analysis of the fluorescent bursts provided an indication about the sizes of the lipoplexes, the number of DNA molecules in these aggregates, and the relative amount of lipids in each aggregate. An explanation for the higher transfection efficiency previously reported for one of the cholesterol-modified oligonucleotide compounds was found in relation to the formation of large size lipoplexes.

DNA computing model of the 0-1 programming problem

DNA computing aims at using nucleic acids for computing. Since micromolar DNA solutions can act as billions of parallel nanoprocessors, DNA computers can in theory solve optimization problems that require vast search spaces. However, the actual parallelism currently being achieved is at least a hundred million-fold lower than the number of DNA molecules used. This is due to the quantity of DNA molecules of one species that is required to produce a detectable output to the computations. In order to miniaturize the computation and considerably reduce the amount of DNA needed, we proposed that fluorescence labeling techniques can be applied to DNA computing. In the paper, we solved the simple 0-1 programming problem with fluorescence labeling techniques based on surface chemistry. It is attempt to apply DNA computing to programming problem.

Biomedical Applications of Colloidal Nanocrystals

Biomedical Applications of Colloidal Nanocrystals

Conductivity of DNA probed by conducting–atomic force microscopy: Effects of contact electrode, DNA structure, and surface interactions

We studied the electrical conductivity of DNA molecules with conducting–atomic force microscopy as a function of the chemical nature of the substrate surfaces, the nature of the electrical contact, and the number of DNA molecules (from a few molecules to ropes and large fibers containing up to ∼106 molecules). Independent of the chemical nature of the surface (hydrophobic or hydrophilic, electrically neutral or charged), we find that DNA is highly resistive. From a large number of current-voltage curves measured at several distances along the DNA, we estimate a conductivity of about 10−6–10−5Scm−1 per DNA molecule. For single DNA molecules, this highly resistive behavior is correlated with its flattened conformation on the surface (reduced thickness, ∼0.5–1.5nm, compared to its nominal value, ∼2.4nm). We find that intercalating an organic semiconductor buffer film between the DNA and the metal electrode improves the reliability of the contact, while direct metal evaporation usually destroys the DNA and prevents any current measurements. After long exposure under vacuum or dry nitrogen, the conductivity strongly decreases, leading to the conclusion that water molecules and ions in the hydration shell of the DNA play a major role.

Kinetic Outlier Detection (KOD) in real-time PCR.

Real-time PCR is becoming the method of choice for precise quantification of minute amounts of nucleic acids. For proper comparison of samples, almost all quantification methods assume similar PCR efficiencies in the exponential phase of the reaction. However, inhibition of PCR is common when working with biological samples and may invalidate the assumed similarity of PCR efficiencies. Here we present a statistical method, Kinetic Outlier Detection (KOD), to detect samples with dissimilar efficiencies. KOD is based on a comparison of PCR efficiency, estimated from the amplification curve of a test sample, with the mean PCR efficiency of samples in a training set. KOD is demonstrated and validated on samples with the same initial number of template molecules, where PCR is inhibited to various degrees by elevated concentrations of dNTP; and in detection of cDNA samples with an aberrant ratio of two genes. Translating the dissimilarity in efficiency to quantity, KOD identifies outliers that differ by 1.3-1.9-fold in their quantity from normal samples with a P-value of 0.05. This precision is higher than the minimal 2-fold difference in number of DNA molecules that real-time PCR usually aims to detect. Thus, KOD may be a useful tool for outlier detection in real-time PCR.