Multiplex ligation-dependent probe amplification using a completely synthetic probe set

The recent development of multiplex ligation-dependent probe amplification (MLPA) has provided an efficient and reliable assay for dosage screening of multiple loci in a single reaction. However, a drawback to this method is the time-consuming process of generating a probe set by cloning in single-stranded bacteriophage vectors. We have developed a synthetic probe set to screen for deletions in a region spanning 18.5 Mb within chromosome 3q. In a pilot study, we tested 15 synthetic probes on 4 control samples and on 2 patients previously found to possess a heterozygous deletion in the region 3q26-q28. These synthetic probes detected deletions at all previously known deleted loci. Furthermore, using synthetic probes, the variability of results within samples was similar to that reported for commercially available M13-derived probes. Our results demonstrate that this novel approach to MLPA provides a generic solution to the difficulties of probe development by cloning; such synthetically generated probes may be used to screen a large number of loci in a single reaction. We conclude that the use of synthetic probes for MLPA is a rapid, robust, and efficient alternative for research (and potentially diagnostic) deletion and duplication screening of multiple genomic loci.     

Real-time colorimetric detection of target DNA using isothermal target and signaling probe amplification and gold nanoparticle cross-linking assay

We describe a facile gold nanoparticle (AuNP)-mediated colorimetric method for real-time detection of target DNA in conjugation with our unique isothermal target and signaling probe amplification (iTPA) method, comprising novel ICA (isothermal chain amplification) and CPT (cycling probe technology). Under isothermal conditions, the iTPA simultaneously amplifies the target and signaling probe through two displacement events induced by a combination of four specially designed primers, the strand displacement activity of DNA polymerase, and the RNA degrading activity of RNase H. The resulting target amplicons are hybridized with gold nanoparticle cross-linking assay (GCA) probes having a DNA-RNA-DNA chimeric form followed by RNA cleavage by RNase H in the CPT step. The intact GCA probes were designed to cross-link two sets of DNA-AuNPs conjugates in the absence of target DNA, inducing aggregation (blue color) of AuNPs. On the contrary, the presence of target DNA leads to cleavage of the GCA probes in proportion to the amount of amplified target DNA and the solution remains red in color without aggregation of AuNPs. Relying on this strategy, 10(2) copies of target Chlamydia trachomatis plasmid were successfully detected in a colorimetric manner. Importantly, all the procedures employed up to the final detection of the target DNA were performed under isothermal conditions without requiring any detection instruments. Therefore, this strategy would greatly benefit convenient, real-time monitoring technology of target DNA under restricted environments.     

Determination of interactions between structured nucleic acids by fluorescence resonance energy transfer (FRET): selection of target sites for functional nucleic acids.

We previously developed a method for monitoring the integrity of oligonucleotides in vitro and in vivo by quantitating fluorescence resonance energy transfer (FRET) between two different fluorochromes attached to a single oligonucleotide. As an extension of this analysis, we examined changes in the extent of FRET in the presence or absence of target nucleic acids with a specific sequence and a higher-ordered structure. In this system FRET was maximal when probes were free in solution and a decrease in FRET was evidence of successful hybridization. We used a single-stranded oligodeoxyribonucleotide labeled at its 5'-end and its 3'-end with 6-carboxyfluorescein and 6-carboxytetramethylrhodamine, respectively. Incubation of the probe with a single-stranded complementary oligonucleotide reduced the FRET. Moreover, a small change in FRET was also observed when the probe was incubated with an oligonucleotide in which the target site had been embedded in a stable hairpin structure. The decrease in the extent of FRET depended on the length of the stem region of the hairpin structure and also on the higher-ordered structure of the probe. These results indicate that this spectrofluorometric method and FRET probes can be used to estimate the efficacy of hybridization between a probe and its target site within highly ordered structures. This conclusion based on changes in FRET was confirmed by gel-shift assays.     

Telomerase catalyzed fluorescent probes for sensitive protein profiling based on one-dimensional microfluidic beads array

A nucleic acid-based signal amplified method for multiple proteins detection based on one-dimensional beads array using telomerase catalyzed fluorescent probes has been developed in this paper. The biotin labeled fluorescent probes were synthesized by telomerase in homogeneous solution. Approximately 360-480 fluorescein molecules were inserted in each probe. The limit of detection for p53 protein is 1.1 pM (S/N=3) and a 3 orders of linear dynamic range is obtained. The sensitivity is nearly two orders higher than the two-site "sandwich" immunoassay using the same platform. Using this method, cellular p53 protein contents of as few as 85 CNE2 cells per mul sample can be determined specifically. The expression changes of p53, c-myc and beta-actin in CNE2 cells were further examined as a function of anti-cancer drug treatment, and the results are consistent with our previous reports. Compared with immuno-polymerase chain reaction and immuno-rolling circle amplification, this method is simple, fast, cheap and suitable for multi-protein analysis. The multiplexed proteins profiling of cellular samples should facilitate the new opportunities to the fundamental research of tumor development and progression, especially to the low abundant tumor-associated proteins analysis.     

Multiple pollinator visits to Mimulus ringens (Phrymaceae) flowers increase mate number and seed set within fruits

The timing and effectiveness of pollinator visitation to flowers is an important factor influencing mating patterns and reproductive success. Multiple pollinator probes to a flower may increase both the quantity and genetic diversity of progeny, especially if single probes deposit insufficient pollen for maximal seed set or if the interval between probes is brief. When pollen carryover is limited, sequential pollen loads may also differ markedly in sire representation. We hypothesized that these conditions help explain high levels of multiple paternity in Mimulus ringens fruits. We documented all bee visits to individual flowers, quantified resulting seed set, and determined paternity for 20 seeds per fruit. Most (76%) flowers received multiple probes, and the interval between probes was usually <30 min. Flowers probed multiple times produced 44% more seeds than flowers probed once. All fruits were multiply sired. Flowers receiving a single probe averaged 3.12 outcross sires per fruit, indicating that single probes deposit pollen from several donors. Multiple paternity was even greater after three or more probes (4.92 outcross sires), demonstrating that sequential visits bring pollen from donors not represented in the initial probe.     

Squeezed flow preconcentration for probe tip biosensors

The preconcentration of analytes improves sensing using probe tips. In this work, we report a method based on creating a squeeze flow between a cylinder and circular coverslip to preconcentrate material at the liquid–gas interface while allowing a probe tip to be readily inserted there. In verification tests using enhanced green fluorescent protein, this capacity is proven. We estimated a 9.7 times increase in probability for fluorophores to be picked up at the tip using inference from fluorescence intensity distributions found. The method is expeditious, simple, and inexpensive, and it does not require any electrical energy source to operate.     

The making of strand-specific M13 probes

A novel approach has been developed for the preparation of highly radioactive, strand-specific M13 probes. A universal primer, complementary to the region 5' to the multiple cloning sites of M13mp7, was used to initiate the DNA synthesis of the complementary strand of the M13 sequence downstream from the inserted sequence. The synthesis of the (?) strand, which was labeled with a radioactively labeled precursor, did not proceed to completion so that the inserted sequence was kept single-stranded. Thus, a partially double-stranded probe that had the specificity of this inserted sequence was obtained. As an example for the application of single-stranded specific hybridization probes, an M13mp7 subclone of a zein cDNA clone of maize (A30) was labeled and used in a dot hybridization test to select from the hundreds of M13mp7 subclones of the zein genomic clone, 24, the sequences complementary to the probe. The specificity of the probe was confirmed by dideoxy chain terminator sequencing experiments.     

Self-assembled monolayer coating of biological probes to avoid protein adhesion

Probes designed to locally illuminate structures within plant cells are described. The probes studied are etch-sharpened single mode optical fibers, coated with aluminum, similar to probes used for near-field scanning optical microscopy. We find that cellular material adheres to the probes that are not coated with a self-assembled monolayer octadecyltrichlorosilane. The hydrophobic monolayer coating enabled these probes to be inserted into and removed from plant cells with no protein adhesion to the probes. This allows probe reinsertion and it causes less damage to the target cell, greatly facilitating in vivo optical study of cells.     

Competitive reporter monitored amplification (CMA)--quantification of molecular targets by real time monitoring of competitive reporter hybridization

Background

State of the art molecular diagnostic tests are based on the sensitive detection and quantification of nucleic acids. However, currently established diagnostic tests are characterized by elaborate and expensive technical solutions hindering the development of simple, affordable and compact point-of-care molecular tests.

Methodology and Principal Findings

The described competitive reporter monitored amplification allows the simultaneous amplification and quantification of multiple nucleic acid targets by polymerase chain reaction. Target quantification is accomplished by real-time detection of amplified nucleic acids utilizing a capture probe array and specific reporter probes. The reporter probes are fluorescently labeled oligonucleotides that are complementary to the respective capture probes on the array and to the respective sites of the target nucleic acids in solution. Capture probes and amplified target compete for reporter probes. Increasing amplicon concentration leads to decreased fluorescence signal at the respective capture probe position on the array which is measured after each cycle of amplification. In order to observe reporter probe hybridization in real-time without any additional washing steps, we have developed a mechanical fluorescence background displacement technique.

Conclusions and Significance

The system presented in this paper enables simultaneous detection and quantification of multiple targets. Moreover, the presented fluorescence background displacement technique provides a generic solution for real time monitoring of binding events of fluorescently labelled ligands to surface immobilized probes. With the model assay for the detection of human immunodeficiency virus type 1 and 2 (HIV 1/2), we have been able to observe the amplification kinetics of five targets simultaneously and accommodate two additional hybridization controls with a simple instrument set-up. The ability to accommodate multiple controls and targets into a single assay and to perform the assay on simple and robust instrumentation is a prerequisite for the development of novel molecular point of care tests.     

DNA breakage detection-fish (DBD-FISH): effect of unwinding time

DBD-FISH is a new procedure that allows detection and quantification of DNA breakage in situ within specific DNA target sites. Cells embedded in an agarose matrix on a slide are treated in an alkaline unwinding solution to transform DNA breaks into single-stranded DNA (ssDNA). After removal of proteins, DNA probes are hybridized and detected. DNA breaks increase the ssDNA and relax supercoiling of DNA loops, so more probe hybridizes, thereby increasing the surface area and fluorescence intensity of the FISH signal. The probe selects the chromatin area to be analysed.In order to restrict the extension of unwound ssDNA to a region closer to the origin of the DNA break, human leukocytes were processed for DBD-FISH with a whole genome probe, after a 10 Gy dose of X-rays, for various unwinding times: 5, 2 min and 30s. Two cell populations were detected after 30s, but not with the 5 or 2 min unwinding times. One cell group had small to medium haloes corresponding to the relaxation of DNA supercoiling after DAPI staining, and strong DBD-FISH labelling of induced DNA breaks, whereas the other cell group showed big haloes of DNA loop unfolding and an absence of DBD-FISH labelling. The latter group was similar to cells processed by DBD-FISH without the unwinding step. Thus, they should correspond to cells unaffected by the alkaline unwinding solution, possibly because very brief unwinding times do not allow the diffusion of the alkali into the cells deep within the gel, thus biasing the results. Taking this into account, 2 min seems to be the minimum unwinding time required for an accurate detection of a signal by DBD-FISH.     

Mapping global angular transitions of proteins in assemblies using multiple extrinsic reporter groups.

The fluorescence polarization intensities from fluorescent probes and the electron paramagnetic resonance spectra from spin probes, specifically modifying elements of a biological assembly such as myosin sulfhydryl 1 (SH1) in muscle fibers, are interpreted in terms of probe order parameters using a model-independent method. The probe order parameters are related to each other by an Euler rotation of coordinates. We use this relationship to link the sets of order parameters from the different probes and in so doing create a system of equations that can be solved using only the information available from the experimental data. The solution yields the Euler angles relating the different probe coordinate frames and a larger set of probe order parameters than can be directly detected experimentally. The Euler angles are used to display the relative orientation of the probe molecular frames. The order parameters give rise to probe angular distributions that are at the theoretical limit of resolution. We demonstrate the utility of this analytical method by investigating the rotation of myosin SH1 from its orientation in rigor upon the binding of the nucleotide MgADP to the myosin cross-bridge. Our findings, discussed in the accompanying paper, suggest that the rigor-to-MgADP cross-bridge angular transition consists predominantly of a rotation about the hydrodynamic axis of symmetry of the cross-bridge, i.e., its torsional degree of freedom [Ajtai, K., Ringler, A., & Burghardt, T. P. (1992) Biochemistry (following paper in this issue)].     

Tryptophan imaging of membrane proteins

A theoretical analysis of resonance energy transfer between protein tryptophan and the n-(9-anthroyloxy) (AO) fatty acid probes has been carried out to evaluate its potential use in determining the tryptophan distribution in membrane proteins. The F?rster theory for two-dimensional energy transfer was formulated to calculate multiple donor (tryptophan) transfer efficiencies to ensembles of AO probes at different depths in the bilayer. The variation of transfer efficiency with AO probe depth is found to be a sensitive function of tryptophan position and the protein radius but not the dipole-dipole orientation factor or the decay heterogeneity of the donor. For single tryptophan-containing proteins the model predicts that the tryptophan position can be determined with a precision of about 2 A. Although for multiple tryptophans there is appreciable deterioration in resolution, it is still possible to determine the essential features of the distribution such as its first two moments. The positions determined by this method are the projections of the tryptophan positions on a plane perpendicular to the membrane surface, since the probes distribute uniformly around the protein. To analyze the data, a Monte Carlo approach has been developed to search for tryptophan distributions compatible with the observed efficiencies and to display the results in terms of a tryptophan density map. It is shown that even for cases in which little is known about the quantum yield distribution, significant information can be determined about the tryptophan spatial distribution.     

A dual-probe hybridization method for reducing variability in single nucleotide polymorphism analysis with oligonucleotide microarrays

DNA microarray technology has become powerful and popular in mutation/single nucleotide polymorphism (SNP) discovery and genotyping. However, this method is often associated with considerable signal noise of nonbiological origin that may compromise the data quality and interpretation. To achieve a high degree of reliability, accuracy, and sensitivity in data analysis, an effective normalization method to minimize the technical variability is highly desired. In the current study, a simple and robust normalization method is described. The method is based on introduction of a reference probe coimmobilized with SNP probes on the microarray for a dual-probe hybridization (DPH) reaction. The reference probe is used as an intraspot control for the customized microarrays. Using this method, the interassay coefficient of variation (CV) was reduced significantly by approximately 10%. After DPH normalization, the CVs and ranges of the ratios were reduced by two to five times. The relative magnitudes of variation of different sources were also analyzed by analysis of variance. Glass slides were shown to contribute the most to the variance, whereas sampling and residual errors had relatively modest contribution. The results showed that this DPH-based spot-dependent normalization method is an effective solution for reducing experimental variation associated with microarray genotyping data.     

A comparison of solution and membrane-bound DNA × DNA hybridization,as used to infer phylogeny

A new method of membrane-bound DNA × DNA hybridization was devised to accommodate the study of small quantities of DNA obtained from museum specimens for phylogeny reconstruction. Membranebound, single-stranded target genomic DNAs were competitively hybridized with a total genomic DNA probe to form hybrid duplexes required for the DNA dissociation experiments. We compared the thermal elution profiles derived from dissociating duplexes made with probes of whole genomic, single-copy, and repetitive DNA, as well as solution DNA × DNA hybridization using sc tracer. Quantitatively, pairwise indices of genetic distance derived from duplexes made with genomic probes depended entirely on hybridization of repetitive sequences, but a parallel set of experiments using repetitive and sc probes produced qualitatively similar results. The indices of genetic distance generated by the membrane-bound hybrids form an internally consistent, resolved tree which is in agreement with the solution DNA × DNA hybridization trials and traditional views of the phylogeny of the taxa under study.Correspondence to: P. Houde     

An optimized microarray platform for assaying genomic variation in <Emphasis Type="Italic">Plasmodium falciparum</Emphasis> field populations

We present an optimized probe design for copy number variation (CNV) and SNP genotyping in the Plasmodium falciparum genome. We demonstrate that variable length and isothermal probes are superior to static length probes. We show that sample preparation and hybridization conditions mitigate the effects of host DNA contamination in field samples. The microarray and workflow presented can be used to identify CNVs and SNPs with 95% accuracy in a single hybridization, in field samples containing up to 92% human DNA contamination.     

Probe design rules and effective enzymes for endonuclease-based detection of nucleic acids

Junction probe (JP) platform is an isothermal endonuclease-based detection assay for both RNA and DNA. Herein, we screen 31 REAse and identify effective restriction endonucleases that can be used for JP detection. Secondly, we investigate how different probe architectures affect JP cleavage rates and conclude that although molecular beacon (MB) JP probes give less background noise than linear JP probes, the cleavage of MB JP probes are slower than linear JP probes.     

PCR in situ followed by microdissection allows whole chromosome painting probes to be made from single microdissected chromosomes

Whole-chromosome painting probes (WCPs) and chromosome-arm painting probes (CAPs) are an integral part of the cytogenetic analysis of chromosome abnormalities. While these are routinely made by chromosome microdissection, multiple copies of the dissected region have been necessary to achieve a library sufficiently complex to provide adequate painting. Performing multiple dissections of chromosomes or chromosome regions is time consuming and occasionally impossible, such as when working with species whose banded karyotype is not well defined. We have developed a method whereby chromosome paints can be reliably generated by dissecting single chromosomes. The technique consists of performing degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR) in situ on the chromosomes, prior to dissection. Enough amplification occurs to enable a single dissected chromosome to be used to create a painting probe sufficiently complex for use in fluorescence in situ hybridization (FISH). The amplification products remain localized on the chromosomes; this allows region-specific chromosome paints to be made. We detail this novel technique and show whole-chromosome, arm-specific, and contiguous region-specific probes for human and rat, each created from single dissected fragments of chromatin. Received: 14 January 1999 / Accepted: 28 January 1999