Fluorescent high-density labeling of DNA: error-free substitution for a normal nucleotide

GPR37 protein trafficking to the plasma membrane regulated by prosaposin and GM1 gangliosides promotes cell viability

The subcellular distribution of the G protein-coupled receptor GPR37 affects cell viability and is implicated in the pathogenesis of parkinsonism. Intracellular accumulation and aggregation of GPR37 cause cell death, whereas GPR37 located in the plasma membrane provides cell protection. We define here a pathway through which the recently identified natural ligand, prosaposin, promotes plasma membrane association of GPR37. Immunoabsorption of extracellular prosaposin reduced GPR37(tGFP) surface density and decreased cell viability in catecholaminergic N2a cells. We found that GPR37(tGFP) partitioned in GM1 ganglioside-containing lipid rafts in the plasma membrane of live cells. This partitioning required extracellular prosaposin and was disrupted by lipid raft perturbation using methyl-β-cyclodextrin or cholesterol oxidase. Moreover, complex formation between GPR37(tGFP) and the GM1 marker cholera toxin was observed in the plasma membrane. These data show functional association between GPR37, prosaposin, and GM1 in the plasma membrane. These results thus tie together the three previously defined components of the cellular response to insult. Our findings identify a mechanism through which the receptor's natural ligand and GM1 may protect against toxic intracellular GPR37 aggregates observed in parkinsonism.

Exonucleolytic degradation of high-density labeled DNA studied by fluorescence correlation spectroscopy

The exonucleolytic degradation of high-density labeled DNA by exonuclease III was monitored using two-color fluorescence correlation spectroscopy (FCS). One strand of the double stranded template DNA was labeled on either one or two base types and additionally at one end via a 5' Cy5 tagged primer. Exonucleolytic degradation was followed via the diffusion time, the brightness of the remaining DNA as well as the concentration of released labeled bases. We found a hydrolyzation rate of about 11 to 17 nucleotides per minute per enzyme (nt/min/enzyme) for high-density labeled DNA, which is by a factor of about 4 slower than for unlabeled DNA. The exonucleolytic degradation of a 488 base pair long double stranded DNA resulted in a short double stranded DNA segment of 112 ± 40 base pairs (bp) length with two single-stranded tails.

Synthesis and enzymatic incorporation of modified deoxyuridine triphosphates

We describe the synthesis of 2'-deoxyuridine-5'-triphosphate derivatives bearing linkers of varying length, bulk and flexibility, at position 5 of the pyrimidine base. Nucleotide analogues with terminal functional groups are of interest due to their application potential for the functional labelling of DNA strands. In the course of the synthesis of the nucleotide analogues, the methodology for the Yoshikawa phosphorylation procedure was optimised, resulting in an approach which reduces the amount of side-products and is compatible with labile functional groups attached to the base. The effect of linker composition on the enzymatic incorporation into DNA was systematically investigated using two different DNA polymerases. Deep Vent(R) exo(-) from the B-polymerase family accepted most nucleotide analogues as substrates, while Taq from the A-family was slightly less proficient. Both polymerases had difficulties incorporating 5-(3-amino-prop-1-ynyl)-2'-deoxyuridine triphosphate. A molecular model of the active site of the polymerase was used to rationalise why this nucleotide was not accepted as a substrate.

Polymerase engineering: towards the encoded synthesis of unnatural biopolymers

DNA is not only a repository of genetic information for life, it is also a unique polymer with remarkable properties: it associates according to well-defined rules, it can be assembled into diverse nanostructures of defined geometry, it can be evolved to bind ligands and catalyse chemical reactions and it can serve as a supramolecular scaffold to arrange chemical groups in space. However, its chemical makeup is rather uniform and the physicochemical properties of the four canonical bases only span a narrow range. Much wider chemical diversity is accessible through solid-phase synthesis but oligomers are limited to <100 nucleotides and variations in chemistry can usually not be replicated and thus are not amenable to evolution. Recent advances in nucleic acid chemistry and polymerase engineering promise to bring the synthesis, replication and ultimately evolution of nucleic acid polymers with greatly expanded chemical diversity within our reach.

Laboratory production of 100 base pair DNA molecular weight markers

DNA molecular weight markers are routinely used in agarose gel electrophoresis. Here we report a method called PCR-synthesized marker (PSM) to generate DNA molecular rulers by PCR in the laboratory. This strategy can also be used to produce 100 bp RNA molecular weight markers by run-off transcription.

'True' single-molecule molecule observations by fluorescence correlation spectroscopy and two-color fluorescence cross-correlation spectroscopy

Fluorescence correlation spectroscopy (FCS) and two-color fluorescence cross-correlation spectroscopy (FCCS) are a measure of fluctuations of detected light as a fluorescence molecule diffuses through a femtoliter detection volume caused by a tightly focused laser and confocal optics. Fluorescence from a single molecule can easily be distinguished from the slight background associated with a femtoliter of solvent. At a solution concentration of about 1 nM, the probability that there is an analyte molecule in the probe volume is less than one. Although fluorescence from individual molecules is collected, the data are analyzed by autocorrelation or two-color cross-correlation functions that are the average of thousands of molecules. Properties of single molecules are not obtained. I have been working on problems and opportunities associated with very dilute solutions. The molecule in the confocal probe volume is most probably the molecule that just diffused out, turned around, and diffused back in, i.e., reentered. For the first time, some theoretical results of the novel theory of the meaningful time are presented that enable study of just one single molecule over extended periods of times without immobilization or hydrodynamic focusing. Reentries that may also be called reoccurrences or encounters of a single molecule are significant because during measurement times they give rise to fluctuation phenomena such as molecule number fluctuations. Likewise, four criteria have been developed that can be used to verify that there is only one "selfsame" molecule in the laser probe volume during the experiment: (Földes-Papp, Z., 2006. What it means to measure a single molecule in a solution by fluorescence fluctuation spectroscopy. Exp. Mol. Pathol. 80 (3) 209-218).

Effects of a modified dye-labeled nucleotide spacer arm on incorporation by thermophilic DNA polymerases

The ability of eight commercially available thermophilic DNA polymerases to sequentially incorporate fluorescently labeled nucleotides sequentially was analyzed by a gel based primer extension assay. Cy5-dUTP or a variant nucleotide in which the linker had been lengthened by 14 atoms between the dye and the nucleobase were compared. We found that the Cy5-dUTP with a longer linker resulted in longer primer extension lengths. Furthermore, some of the assayed polymerases are capable of extending the primer to the full or near full length of 30 nucleotides using dye-labeled nucleotides exclusively.

High-density polymerase-mediated incorporation of fluorochrome-labeled nucleotides

DNA-polymerase-mediated incorporation of different fluorochrome-labeled nucleotides (FdNTPs) was investigated with the goals of optimizing the high-density labeling of probes and exploring DNA sequencing strategies that rely on the controlled, sequential addition of such compounds. By systematically evaluating variables--including polymerase type, buffer conditions, and fluorochrome chemistries--a rational strategy for the sequential addition of labeled nucleotides to a DNA template was demonstrated. A simple structural model of the polymerase-DNA template complex that considered the fluorochrome moiety of the FdNTPs and the linker length also guided this strategy. Complementary results that portend the use of simple photobleaching to enable the reliable quantitation of consecutive additions are presented.

Incorporation of reporter-labeled nucleotides by DNA polymerases

The incorporation of fluorescently labeled nucleotides into DNA by DNA polymerases has been used extensively for tagging genes and for labeling DNA. However, we lack studies comparing polymerase efficiencies for incorporating different fluorescently labeled nucleotides. We analyzed the incorporation of fluorescent deoxynucleoside triphosphates by 10 different DNA polymerases, representing a cross-section of DNA polymerases from families A, B, and reverse transcriptase. The substitution of one or more different reporter-labeled nucleotides for the cognate nucleotides was initially investigated by using an in vitro polymerase extension filter-binding assay with natural DNA as a template. Further analysis on longer DNA fragments containing one or more nucleotide analogs was performed using a newly developed extension cut assay. The results indicate that incorporation of fluorescent nucleotides is dependent on the DNA polymerase, fluorophore, linker between the nucleotide and the fluorophore, and position for attachment of the linker and the cognate nucleotide. Of the polymerases tested, Taq and Vent exo DNA polymerases were most efficient at incorporating a variety of fluorescently labeled nucleotides. This study suggests that it should be feasible to copy DNA with reactions mixtures that contain all four fluorescently labeled nucleotides allowing for high-density labeling of DNA.

Advances in sequencing technology

Faster sequencing methods will undoubtedly lead to faster single nucleotide polymorphism (SNP) discovery. The Sanger method has served as the cornerstone for genome sequence production since 1977, close to almost 30 years of tremendous utility [Sanger, F., Nicklen, S., Coulson, A.R, DNA sequencing with chain-terminating inhibitors, Proc. Natl. Acad. Sci. U.S.A. 74 (1977) 5463-5467]. With the completion of the human genome sequence [Venter, J.C. et al., The sequence of the human genome, Science 291 (2001) 1304-1351; Lander, E.S. et al., Initial sequencing and analysis of the human genome, Nature 409 (2001) 860-921], there is now a focus on developing new sequencing methodologies that will enable "personal genomics", or the routine study of our individual genomes. Technologies that will lead us to this lofty goal are those that can provide improvements in three areas: read length, throughput, and cost. As progress is made in this field, large sections of genomes and then whole genomes of individuals will become increasingly more facile to sequence. SNP discovery efforts will be enhanced lock-step with these improvements. Here, the breadth of new sequencing approaches will be summarized including their status and prospects for enabling personal genomics.

Specifically associated PCR products probed by coincident detection of two-color cross-correlated fluorescence intensities in human gene polymorphisms of methylene tetrahydrofolate reductase at site C677T: a novel measurement approach without follow-up mathematical analysis

Whole blood samples of known methylene tetrahydrofolate reductase (MTHFR) genotypes from 24 individuals were examined at site C677T. Their amplified DNA products were assessed by two-color fluorescence cross-correlation measurements and agarose gel electrophoresis/capillary gel electrophoresis. DNA subpopulations were identified which were not associated with the proper genotype by primer combinations and cycling conditions called multiplexes. We confirmed that DNA analysis by two-color fluorescence cross-correlation measurements allowed the detection of fluorescence signals specifically associated with the proper genotypes in a mixture of amplified nontarget DNA molecules without DNA sizing. The measurement approach does not require complex, follow-up mathematical analysis and is applicable to any single nucleotide polymorphisms. The simple immunogenetic model showed how the approach works to reveal specific DNA target by preventing detection of nontarget DNA. Under those experimental conditions, a new ultrasensitive, and specific method for clinical immunologists is born.

A new concept for ultrasensitive fluorescence measurements of molecules in solution and membrane: 2. The individual immune molecule

In the accompanying original article, the universal theoretical and experimental framework was developed for quantifying one and the same single (selfsame), individual fluorescent-tagged biological molecule without immobilization, hydrodynamic flow or photon burst analysis of fluorescence intensity traces. In the present original article, we describe an application to the detection and identification of circulating anti-glomerular basement membrane antibodies (BMAs) in Goodpasture syndrome. The same single, individual two-color molecule complex was observed among many other molecules. The molecule consisted of the green-tagged antigen, sandwiched autoantibody and red-tagged secondary (detecting) antibody. A 200-fold increase in sensitivity was obtained as compared to the conventional ELISAs on solid phase. This novel concept has several advantages, namely (i) the sensitivity to detect an individual molecule in solution; (ii) the association of the signal with the reaction event, independent of any immobilization procedure and the artifacts thereof; (iii) the assessment of the broad field of natural antibodies. The theoretical and experimental results obtained bring advanced ultrasensitive analytics to the direct investigation of one and the same single, individual immune molecules as exemplified by the experiments performed with Goodpasture antibody. The novel universal theoretical and experimental framework for continuous measuring the same single, individual immune molecule can be readily transferred to other applications.

A new concept for ultrasensitive fluorescence measurements of molecules in solution and membrane:

Just because there is an average of one molecule in the observation volume of a solution or membrane (single-phase), one cannot say that this is an individual molecule since many different single molecules measured one by one or the same single, individual molecule not leaving the detection volume on time average can cause a single-molecule event. The latter case is of interest and allows the continuous observation of one and the same single molecule without averaging over many 'different' single molecules. For the first time a universal theoretical and experimental framework is presented for the continuous observation of the same single, individual molecule without immobilization, hydrodynamic flow, or burst size histograms of fluorescence intensity traces. In this original article, the stochastic approach is derived and its main characteristics are demonstrated with the free fluorophore rhodamine-green in solution for simpler experimental realization. Single (solution)-phase single-molecule fluorescence auto- (or two-color cross-) correlation spectroscopy (SPSM-FCS) is used as a specific application in order to count the absolute number of molecules in the observation volume. The absolute number of molecules, the diffusion coefficient of the single fluorescent molecule, the lower limit of distance, and the molar concentration of the bulk phase (solution) were directly obtained from the measured auto- or (cross)-correlation curves of the SPSM-FCS experiments. For this purpose, the detection volume that was measured was less then 1 fl (10(-15) l). Then, a concentration of the bulk solution was chosen in such a way that the probability of detecting more than one molecule in the detection volume was very small. The Poisson probability was experimentally determined for the absolute number of molecules depending upon a specified bulk concentration. From the diffusion coefficient of the molecule, it was found that the probability of the molecule diffusing out of the probe volume during the measurements was negligibly small.

Suppression of exonucleolytic degradation of double-stranded DNA and inhibition of Exonuclease III by PNA

Degradation of double-stranded DNA by Exonuclease III in the presence of complementary anti-parallel PNA was studied. It was found for the first time that the PNA suppresses the degradation of dsDNA in a sequence-specific manner as well as inhibits the activity of Exonuclease III in a non-specific way.

Incorporation of reporter molecule-labeled nucleotides by DNA polymerases. II. High-density labeling of natural DNA

The modification of nucleic acids using nucleotides linked to detectable reporter or functional groups is an important experimental tool in modern molecular biology. This enhances DNA or RNA detection as well as expanding the catalytic repertoire of nucleic acids. Here we present the evaluation of a broad range of modified deoxyribonucleoside 5'-triphosphates (dNTPs) covering all four naturally occurring nucleobases for potential use in DNA modification. A total of 30 modified dNTPs with either fluorescent or non-fluorescent reporter group attachments were systematically evaluated individually and in combinations for high-density incorporation using different model and natural DNA templates. Furthermore, we show a side-by-side comparison of the incorporation efficiencies of a family A (Taq) and B (Vent(R) exo-) type DNA polymerase using the differently modified dNTP substrates. Our results show superior performance by a family B-type DNA polymerase, Vent(R) exo-, which is able to fully synthesize a 300 bp DNA product when all natural dNTPs are completely replaced by their biotin-labeled dNTP analogs. Moreover, we present systematic testing of various combinations of fluorescent dye-modified dNTPs enabling the simultaneous labeling of DNA with up to four differently modified dNTPs.

Progress towards single-molecule DNA sequencing: a one color demonstration

Single molecules of fluorescently labeled nucleotides were detected during the cleavage of individual DNA fragments by a processive exonuclease. In these experiments, multiple (10-100) strands of DNA with tetramethyl rhodamine labeled dUMP (TMR-dUMP) incorporated into the sequence were anchored in flow upstream of the detection region of an ultra sensitive flow cytometer. A dilute solution of Exonuclease I passed over the microspheres. When an exonuclease attached to a strand, processive digestion of that strand began. The liberated, labeled bases flowed through the detection region and were detected at high efficiency at the single-molecule level by laser-induced fluorescence. The digestion of a single strand of DNA by a single exonuclease was discernable in these experiments. This result demonstrates the feasibility of single-molecule DNA sequencing. In addition, these experiments point to a new and practical means of arriving at a consensus sequence by individually reading out identical sequences on multiple fragments.

A new dimension for the development of fluorescence-based assays in solution: from physical principles of FCS detection to biological applications

Ultrasensitive detection methods such as laser-induced fluorescence represent the current state-of-the-art in analytics. Single-molecule detection in solution has received a remarkable amount of attention in the last few years because of its applicability to life sciences. Studies have been performed on the fundamentals of the detection processes themselves and on some biological systems. Fluorescence correlation spectroscopy (FCS) is the link for ultrasensitive multicomponent analysis, showing possibilities for experiments on molecular interactions. Based on the theoretical background of FCS, this article gives full explanation of FCS and an update of highlights in experimental biology and medicine studied by FCS. We focus on a repertoire of diverse immunoglobulin specificities, a ribosome display system, single-molecule DNA sequencing, and a mutant enzyme generated by random mutagenesis of amino acids. We describe the usefulness and the enormous potential of the methodology. Further, this contribution clearly indicates that FCS is a valuable tool for solution-phase single-molecule (SPSM) experiments in immunobiology and medicine. In experiments with the Goodpasture autoantibody, we worked out conditions for the design of experiments on a complex single molecule in solution. The possibility to use SPSM-FCS as a quantitation methodology opens up other important applications beyond the scope of this article. Original results extending the published studies are presented for the rational foundation of SPSM-FCS. In this original contribution, we deal with experimental systems for biology and medicine where the number of molecules in solution is very small. This article is mandatory for gaining confidence in the interpretation of experimental SPSM-FCS results on the selfsame, individual single molecule in solution.

Detection of single molecules: solution-phase single-molecule fluorescence correlation spectroscopy as an ultrasensitive, rapid and reliable system for immunological investigation

More sensitive techniques in molecular and clinical immunology are essential for the development of reproducible profiles. We have developed a novel methodology named solution-phase single-molecule fluorescence correlation spectroscopy (SPSM-FCS) that fulfils these demands. It is based on the quantification of the probability density of single molecule events in solution is necessary. For example, the Brownian motion of the fluorophore rhodamine-green is detected. Counting about 100,000 photon counts per second and per molecule permits the identification of one single compound. In order to study the applicability of SPSM-FCS in immunology, we have detected and identified a larger nonfluorescent substance in a very complex mixture. The 'unknown' molecules studied were the autoantibodies in serum samples directed against the antigen alpha 3 chain of type IV collagen. In both systems, we were able to characterize the probability density of single fluorescent molecules by means of the averaged absolute molecule number without any calibration. The specific molecules exhibited a Poisson distribution in solution in terms of their 'critical' bulk concentration below about 1 nM. This proof of principle indicates how the SPSM-FCS methodology could be used in immunoassays.

Quantitative two-color fluorescence cross-correlation spectroscopy in the analysis of polymerase chain reaction

We present results of an approach in which low-density labeled DNA itself provides an amplification of the cross-correlated fluorescent signal in the two-color cross-correlation function. Tetramethylrhodamine-4-dUTP and Cy5-dCTP are incorporated by polymerase chain reaction at multiple positions of the same 217 bp target DNA. We call this novel approach the 'two-color FCS signal amplification'. The signal amplification is an example for interactions of two ligands with different colors at multiple positions of the same target.

Ultrasensitive detection and identification of fluorescent molecules by FCS: impact for immunobiology

An experimental application of fluorescence correlation spectroscopy is presented for the detection and identification of fluorophores and auto-Abs in solution. The recording time is between 2 and 60 sec. Because the actual number of molecules in the unit volume (confocal detection volume of about 1 fl) is integer or zero, the fluorescence generated by the molecules is discontinuous when single-molecule sensitivity is achieved. We first show that the observable probability, N, to find a single fluorescent molecule in the very tiny space element of the unit volume is Poisson-distributed below a critical bulk concentration c*. The measured probability means we have traced, for example, 5 x 10(10) fluorophore molecules per ml of bulk solution. The probability is related to the average frequency, C, that the volume of detection contains a single fluorescent molecule and to the concentration, c, of the bulk solution. The analytical sensitivity of an assay is calculated from the average frequency C. In the Goodpasture experiment, we determined as analytical sensitivity a probability of 99.1% of identifying one single immune complex. Under these conditions, a single molecule event is proven. There exist no instrumental assumptions of our approach on which the experiment itself, the theoretical background, or the conclusion are based. Our results open up a broad field for analytics and diagnostics in solution, especially in immunology.

Fluorescently labeled model DNA sequences for exonucleolytic sequencing

We describe here the enzyme-catalyzed, low-density labeling of DNAs with fluorescent dyes. Firstly, for "natural" template DNAs, dNTPs were partially substituted in the labeling reactions by the respective fluorophore-bearing analogs. The DNAs were labeled by PCR using Taq DNA polymerase. The covalent incorporation of dye-dNTPs decreased in the following order: rhodamine-green-5-dUTP (Molecular Probes, the Netherlands), tetramethylrhodamine-4-dUTP (FluoroRed, Amersham Pharmacia Biotech), Cy5-dCTP (Amersham Pharmacia Biotech). Exonucleolytic degradation by the 3'-->5' exonuclease activity of T7 DNA polymerase (wild type) in the presence of excess reduced thioredoxin proceeded to complete breakdown of the labeled DNAs. The catalytic cleavage constants determined by fluorescence correlation spectroscopy were between 0.5 and 1.5 s(-1) at 16 degrees C, normalized for the covalently incorporated dye-nucleotides. Secondly, rhodamine-green-X-dUTP (Roche Diagnostics), tetramethylrhodamine-6-dUTP (Roche Diagnostics), and Cy5-dCTP were covalently incorporated into the antisense strand of "synthetic" 218-b DNA template constructs (master sequences) at well defined positions, starting from the primer binding site, by total substitution for the naturally occurring dNTPs. The 218-b DNA constructs were labeled by PCR with a thermostable 3'-->5' exonuclease deficient mutant of the Tgo DNA polymerase which we have selected. The advantage of the special, synthetic DNA constructs as compared to natural DNAs lies in the possibility of obtaining tailor-made nucleic acids, optimized for testing the performance of exonucleolytic sequencing. The number of incorporated fluorescent nucleotides determined by complete exonucleolytic degradation and fluorescence correlation spectroscopy were six out of six possible incorporations for rhodamine-green-X-dUTP and tetramethylrhodamine-6-dUTP, respectively. Their covalent and base-specific incorporations were confirmed by the novel analysis methodology of re-sequencing (i.e. mobility-shift gel electrophoresis, reversion-PCR and re-sequencing) first developed in the paper Földes-Papp et al. (2001) and in this paper. This methodology was then used by other groups within the whole sequencing project.