Detection of Rifampicin Resistance in Mycobacterium tuberculosis by Padlock Probes and Magnetic Nanobead-Based Readout

Control of the global epidemic tuberculosis is severely hampered by the emergence of drug-resistant Mycobacterium tuberculosis strains. Molecular methods offer a more rapid means of characterizing resistant strains than phenotypic drug susceptibility testing. We have developed a molecular method for detection of rifampicin-resistant M. tuberculosis based on padlock probes and magnetic nanobeads. Padlock probes were designed to target the most common mutations associated with rifampicin resistance in M. tuberculosis, i.e. at codons 516, 526 and 531 in the gene rpoB. For detection of the wild type sequence at all three codons simultaneously, a padlock probe and two gap-fill oligonucleotides were used in a novel assay configuration, requiring three ligation events for circularization. The assay also includes a probe for identification of the M. tuberculosis complex. Circularized probes were amplified by rolling circle amplification. Amplification products were coupled to oligonucleotide-conjugated magnetic nanobeads and detected by measuring the frequency-dependent magnetic response of the beads using a portable AC susceptometer.     

Detection of denitrification genes by in situ rolling circle amplification‐fluorescence in situ hybridization to link metabolic potential with identity inside bacterial cells

A target‐primed in situ rolling circle amplification (in situ RCA) protocol was developed for detection of single‐copy genes inside bacterial cells and optimized with Pseudomonas stutzeri, targeting nitrite and nitrous oxide reductase genes (nirS and nosZ). Two padlock probes were designed per gene to target both DNA strands; the target DNA was cut by a restriction endonuclease close to the probe binding sites, which subsequently were made accessible by 5′‐3′ exonucleolysis. After hybridization, the padlock probe was circularized by ligation and served as template for in situ RCA, primed by the probe target site. Finally, the RCA product inside the cells was detected by standard fluorescence in situ hybridization (FISH). The optimized protocol showed high specificity and signal‐to‐noise ratio but low detection frequency (up to 15% for single‐copy genes and up to 43% for the multi‐copy 16S rRNA gene). Nevertheless, multiple genes (nirS and nosZ; nirS and the 16S rRNA gene) could be detected simultaneously in P. stutzeri. Environmental application of in situ RCA‐FISH was demonstrated on activated sludge by the differential detection of two types of nirS‐defined denitrifiers; one of them was identified as Candidatus Accumulibacter phosphatis by combining in situ RCA‐FISH with 16S rRNA‐targeted FISH. While not suitable for quantification because of its low detection frequency, in situ RCA‐FISH will allow to link metabolic potential with 16S rRNA (gene)‐based identification of single microbial cells.     

Use of Rolling Circle Amplification to Rapidly Identify Species of Cladophialophora Potentially Causing Human Infection

The genus Cladophialophora comprises etiologic agents of disease in immunocompetent patients, ranging from mild cutaneous colonization to cerebral encephalitis, in addition to saprobic species. Due to the high degree of phenotypic similarity between closely related species of the genus, identification problems are imminent. In the present study, we described rapid and sensitive rolling circle amplification (RCA) method based on species-specific padlock probes targeted for the internal transcribed spacer regions of rDNA. ITS regions of 12 Cladophialophora species were sequenced, and subsequently, 10 specific padlock probes were designed for the detection of single nucleotide polymorphisms. The majority of circularizable padlock probes were designed based on single nucleotide polymorphisms (SNPs), while for C. bantiana, C. immunda and C. devriesii were characterized by two or more nucleotides. Individual species-specific probes correctly identified in all ten Cladophialophora species correctly by visualization on 1.2 % agarose gels used to verify specificity of probe-template binding; no cross-reactivity was observed. Simplicity, sensitivity, robustness and low costs provide RCA a distinct place among isothermal techniques for DNA diagnostics. However, restriction and specificity and sensitivity should be lowered and increased, respectively, to be useful for a wide variety of clinical applications.     

L-RCA (ligation-rolling circle amplification): a general method for genotyping of single nucleotide polymorphisms (SNPs)

A flexible, non-gel-based single nucleotide polymorphism (SNP) detection method is described. The method adopts thermostable ligation for allele discrimination and rolling circle amplification (RCA) for signal enhancement. Clear allelic discrimination was achieved after staining of the final reaction mixtures with Cybr-Gold and visualisation by UV illumination. The use of a compatible buffer system for all enzymes allows the reaction to be initiated and detected in the same tube or microplate well, so that the experiment can be scaled up easily for high-throughput detection. Only a small amount of DNA (i.e. 50 ng) is required per assay, and use of carefully designed short padlock probes coupled with generic primers and probes make the SNP detection cost effective. Biallelic assay by hybridisation of the RCA products with fluorescence dye-labelled probes is demonstrated, indicating that ligation-RCA (L-RCA) has potential for multiplexed assays.     

Rapid Identification of Seven Waterborne <Emphasis Type="Italic">Exophiala</Emphasis> Species by RCA DNA Padlock Probes

The black yeast genus Exophiala includes numerous potential opportunistic species that potentially cause systematic and disseminated infections in immunocompetent individuals. Species causing systemic disease have ability to grow at 37–40 °C, while others consistently lack thermotolerance and are involved in diseases of cold-blooded, waterborne vertebrates and occasionally invertebrates. We explain a fast and sensitive assay for recognition and identification of waterborne Exophiala species without sequencing. The ITS rDNA region of seven Exophiala species (E. equina, E. salmonis, E. opportunistica, E. pisciphila, E. aquamarina, E. angulospora and E. castellanii) along with the close relative Veronaea botryosa was sequenced and aligned for the design of specific padlock probes for the detection of characteristic single-nucleotide polymorphisms. The assay demonstrated to successfully amplify DNA of target fungi, allowing detection at the species level. Amplification products were visualized on 1% agarose gels to confirm specificity of probe–template binding. Amounts of reagents were reduced to prevent the generation of false positive results. The simplicity, tenderness, robustness and low expenses provide padlock probe assay (RCA) a definite place as a very practical method among isothermal approaches for DNA diagnostics.     

Detection of single-nucleotide polymorphisms in the <Emphasis Type="Italic">p53</Emphasis> gene by LDR/RCA in hydrogel microarrays

To find single-nucleotide polymorphisms (SNPs) in the human genome, three modern technologies of molecular genetic analysis were combined: the ligase detection reaction (LDR), rolling circle amplification (RCA), and immobilized microarray of gel elements (IMAGE). SNPs were detected in target DNA by selective ligation of allele-specific nucleotides in microarrays. The ligation product was assayed in microarray gel pads by RCA. Two variants of microarray analysis were compared. One included selective ligation of short oligonu-cleotides immobilized in a microarray with subsequent amplification with a preformed circular probe (a common circle). The probe was especially designed for human genome research. The other variant employed immobilized allele-specific padlock probes, which could be circularized as a result of selective ligation. Codon 72 SNP of the human p53 gene was used as a model. RCA in microarrays proved to be a quantitative assay and, in combination with LDR, allowed efficient discrimination of alleles. The principles and prospects of LDR/RCA in microarrays are discussed.Translated from Molekulyarnaya Biologiya, Vol. 39, No. 1, 2005, pp. 30–39.Original Russian Text Copyright © 2005 by Kashkin, Strizhkov, Gryadunov, Surzhikov, Grechishnikova, Kreindlin, Chupeeva, Evseev, Turygin, Mirzabekov.     

PCR-generated padlock probes detect single nucleotide variation in genomic DNA

Circularizing oligonucleotide probes, so-called padlock probes, have properties that should prove valuable in a wide range of genetic investigations, including in situ analyses, genotyping and measurement of gene expression. However, padlock probes can be difficult to obtain by standard oligonucleotide synthesis because they are relatively long and require intact 5′- and 3′-end sequences to function. We describe a PCR-based protocol for flexible small-scale enzymatic synthesis of such probes. The protocol also offers the advantage over chemical synthesis that longer probes can be made that are densely labeled with detectable functions, resulting in an increased detection signal. The utility of probes synthesized according to this protocol is demonstrated for the analysis of single nucleotide variations in human genomic DNA both in situ and in solution.     

Effect of temperature and water activity on the production of fumonisins by Aspergillus niger and different Fusariumspecies

Background

Amino acid substitutions in the target enzyme Erg11p of azole antifungals contribute to clinically-relevant azole resistance in Candida albicans. A simple molecular method for rapid detection of ERG11 gene mutations would be an advantage as a screening tool to identify potentially-resistant strains and to track their movement. To complement DNA sequencing, we developed a padlock probe and rolling circle amplification (RCA)-based method to detect a series of mutations in the C. albicans ERG11 gene using "reference" azole-resistant isolates with known mutations. The method was then used to estimate the frequency of ERG11 mutations and their type in 25 Australian clinical C. albicans isolates with reduced susceptibility to fluconazole and in 23 fluconazole-susceptible isolates. RCA results were compared DNA sequencing.

Results

The RCA assay correctly identified all ERG11 mutations in eight "reference" C. albicans isolates. When applied to 48 test strains, the RCA method showed 100% agreement with DNA sequencing where an ERG11 mutation-specific probe was used. Of 20 different missense mutations detected by sequencing in 24 of 25 (96%) isolates with reduced fluconazole susceptibility, 16 were detected by RCA. Five missense mutations were detected by both methods in 18 of 23 (78%) fluconazole-susceptible strains. DNA sequencing revealed that mutations in non-susceptible isolates were all due to homozygous nucleotide changes. With the exception of the mutations leading to amino acid substitution E266D, those in fluconazole-susceptible strains were heterozygous. Amino acid substitutions common to both sets of isolates were D116E, E266D, K128T, V437I and V488I. Substitutions unique to isolates with reduced fluconazole susceptibility were G464 S (n = 4 isolates), G448E (n = 3), G307S (n = 3), K143R (n = 3) and Y123H, S405F and R467K (each n = 1). DNA sequencing revealed a novel substitution, G450V, in one isolate.

Conclusion

The sensitive RCA assay described here is a simple, robust and rapid (2 h) method for the detection of ERG11 polymorphisms. It showed excellent concordance with ERG11 sequencing and is a potentially valuable tool to track the emergence and spread of azole-resistant C. albicans and to study the epidemiology of ERG11 mutations. The RCA method is applicable to the study of azole resistance in other fungi.     

Rapid identification and detection of pine pathogenic fungi associated with mountain pine beetles by padlock probes

Fifteen million hectares of pine forests in western Canada have been attacked by the mountain pine beetle (Dendroctonus ponderosae; MPB), leading to devastating economic losses. Grosmannia clavigera and Leptographium longiclavatum, are two fungi intimately associated with the beetles, and are crucial components of the epidemic. To detect and discriminate these two closely related pathogens, we utilized a method based on ligase-mediated nucleotide discrimination with padlock probe technology, and signal amplification by hyperbranched rolling circle amplification (HRCA). Two padlock probes were designed to target species-specific single nucleotide polymorphisms (SNPs) located at the inter-generic spacer 2 region and large subunit of the rRNA respectively, which allows discrimination between the two species. Thirty-four strains of G. clavigera and twenty-five strains of L. longiclavatum representing a broad geographic origin were tested with this assay. The HRCA results were largely in agreement with the conventional identification based on morphology or DNA-based methods. Both probes can also efficiently distinguish the two MPB-associated fungi from other fungi in the MPB, as well as other related fungi in the order Ophiostomatales. We also tested this diagnostic method for the direct detection of these fungi from the DNA of MPB. A nested PCR approach was used to enrich amplicons for signal detection. The results confirmed the presence of these two fungi in MPB. Thus, the padlock probe assay coupled with HRCA is a rapid, sensitive and reproducible method for the identification and detection of these ophiostomatoid fungi.     

Molecular Barcode Sequencing of the Whole Ligand Binding Domain of the ESR1 Gene in Cell-Free DNA from Patients with Metastatic Breast Cancer

ESR1 mutations in breast cancer are known as one of the mechanisms of resistance to aromatase inhibitors. These mutations often occur in the hotspot regions in the ligand binding domain (LBD), but comprehensive mutational analysis has shown that mutations are observed throughout the whole LBD. We previously developed a molecular barcode sequencing (MB-NGS) technique to detect ESR1 hotspot mutations in plasma with high sensitivity. In this study, we have developed a multiplex MB-NGS assay that covers the whole LBD of ESR1. The assay demonstrated that the background errors in the plasma DNA of 10 healthy controls were below 0.1%; thus, the limit of detection was set at 0.1%. We analyzed the plasma DNA of 54 patients with estrogen receptor–positive metastatic breast cancer. Seventeen mutations were detected in 13 patients (24%), with variant allele frequencies ranging from 0.13% to 10.67%, including six rare mutations with a variant allele frequency <1.0% and a novel nonhotspot mutation (A312V). Three patients had double mutations located in the same amplicons, and it was revealed that the double mutations were located in different alleles. ESR1 hotspot mutations were associated with a longer duration of aromatase inhibitor treatment under metastatic conditions and to liver metastasis. The multiplex MB-NGS assay is useful for the sensitive and comprehensive detection of mutations throughout the whole LBD of ESR1. Our assay can be applied to any specific target region of interest using tailor-made primers and can result in minimized sequencing volume and cost.     

Parallel Visualization of Multiple Protein Complexes in Individual Cells in Tumor Tissue

Cellular functions are regulated and executed by complex protein interaction networks. Accordingly, it is essential to understand the interplay between proteins in determining the activity status of signaling cascades. New methods are therefore required to provide information on different protein interaction events at the single cell level in heterogeneous cell populations such as in tissue sections. Here, we describe a multiplex proximity ligation assay for simultaneous visualization of multiple protein complexes in situ. The assay is an enhancement of the original proximity ligation assay, and it is based on using proximity probes labeled with unique tag sequences that can be used to read out which probes, from a pool of probes, have bound a certain protein complex. Using this approach, it is possible to gain information on the constituents of different protein complexes, the subcellular location of the complexes, and how the balance between different complex constituents can change between normal and malignant cells, for example. As a proof of concept, we used the assay to simultaneously visualize multiple protein complexes involving EGFR, HER2, and HER3 homo- and heterodimers on a single-cell level in breast cancer tissue sections. The ability to study several protein complex formations concurrently at single cell resolution could be of great potential for a systems understanding, paving the way for improved disease diagnostics and possibilities for drug development.A far greater understanding of proteins interacting in complexes in cells and tissues is needed to explain the functional states of cells. Accordingly, there is a pressing need for improved methods to study protein interaction complexes to explain disease mechanisms; however, suitable methods have been lacking, particularly for clinical material. As an example, proteins in the epidermal growth factor receptor (EGFR)¹ family have traditionally been used as clinical markers. However, in many cases this has proven of limited prognostic value, and activity markers such as receptor interactions are attracting increasing interest (1, 2). Methods such as FRET-based detection (3) or the VeraTag assay (4) can be used to investigate protein complex formations in patient tissues. However, such techniques are not suitable to measure several concurrent protein complexes as required to characterize the balance between different segments of a signaling pathway or between different pathways. FRET-based methods are difficult to use with clinical material and have very limited multiplexing capabilities. The VeraTag assay can be multiplexed, but it fails to provide spatial information of the complexes and thus cannot distinguish between cancer cells and surrounding stroma. Similarly, bulk measures of protein complexes via e.g. co-immunoprecipitation and mass spectrometry (5) disregard cell-to-cell variations and the subcellular distributions of protein complexes. Moreover, such methods are poorly suited for analyzing precious clinical material as too much sample material is needed for the analysis.To enable parallel analyses directly in tumor tissue of multiple protein complexes involved in signaling pathways, we have developed a multiplex version of the in situ proximity ligation assay (PLA)¹ (6). In situ PLA has previously been used for localized detection of proteins, protein complexes, and post-translational modifications in cells and tissues (6). Because of its intrinsic requirement for dual target recognition by pairs of antibodies and the use of rolling circle amplification (RCA) to substantially amplify signals, the assay allows detection of endogenous protein complexes or post-translational modifications in fixed cells and tissue sections (7, 8) or Western blot membranes (9). The basis of in situ PLA is the detection of a target molecule through the use of a pair of PLA probes, i.e. target-specific affinity reagents such as antibodies to which DNA oligonucleotides have been attached (Fig. 1). We describe herein how tag sequences in the oligonucleotides of each PLA probe, uniquely identifying these probes, can be propagated into the single-stranded RCA products that result when two PLA probes have bound complex-forming proteins. The amplified tags in the RCA products can then be visualized using detection oligonucleotides, labeled with different fluorophores, to uniquely recognize the tag sequences. This multiplex readout makes it possible to compare levels of protein complexes between individual cells by identifying the PLA probes that gave rise to the signals.Open in a separate windowFig. 1.Parallel detection of protein complexes using multiplex in situ PLA. Groups of PLA probes are used to detect all binary complexes between a protein X and any of the proteins A–C. Using oligonucleotides attached to specific antibodies as templates, two linear connector oligonucleotides and one probe-specific tag oligonucleotide are enzymatically joined into a DNA circle that subsequently templates RCA. The RCA products, whose repeated sequences identify the protein in complex with protein X, can be visualized by hybridization of three tag-specific detection oligonucleotides labeled with distinct fluorophores.To test our probe design, we targeted the well characterized EGFR family. This family consists of four transmembrane tyrosine kinase receptors (EGFR, HER2, HER3, and HER4), involved in the regulation of fundamental cellular functions such as cell growth, survival, death, differentiation, and proliferation (10). Increased expression, or aberrant regulation, of the receptors has been implicated in a broad range of human malignancies, including breast cancer, where overexpression of HER2 is associated with a poor prognosis (11). Members of the EGFR family can interact in different constellations, with HER2 as the preferred interaction partner (12), activating several signaling pathways. These interactions between different members of the EGFR family and with associated proteins have been studied extensively in many different types of cells and tissues with a range of methods (2–4, 13), including in situ PLA (14–17).Using multiplex in situ PLA, we successfully visualized multiple protein complexes in cultured cells and in fresh frozen tissue sections, illustrating the potential to study the balance between alternative protein complexes in clinical specimens to identify cellular phenotypes.     

Fluorescent oligonucleotide ligation technology for identification of ras oncogene mutations

A mutation detection strategy based on multiplex PCR followed by multiplex allele-specific oligonucleotide probe ligation was developed to detect single nucleotide substitutions in ras oncogenes, a common genetic abnormality in many human cancers. Mutation-specific probes are synthesized for each possible single-base, nonsilent mutation in codons 12, 13, and 61 of H-, K-, and N-ras oncogenes. Mutations are identified by competitive oligonucleotide probe ligation to detect normal and /or mutant genotypes in one reaction. Three probes (one common and two allelic probes) are needed for analysis of each mutation. Probes hybridized to target ras oncogene DNA are joined by a thermostable ligase if there are no mismatches at their junctions; temperature cycling results in a linear increase in product. Common probes are labeled with fluorochromes, and allelic probes each have different lengths. Ligation products are analyzed by denaturing polyacrylamide gel electrophoresis on a fluorescent DNA sequencer. We have applied this technology to identify ras mutations in pancreatic cancers and lung cancers and in patients with myelodysplastic syndromes and leukemias.     

Detection and identification of opportunistic Exophiala species using the rolling circle amplification of ribosomal internal transcribed spacers

Deep infections by melanized fungi deserve special attention because of a potentially fatal, cerebral or disseminated course of disease in otherwise healthy patients. Timely diagnostics are a major problem with these infections. Rolling circle amplification (RCA) is a sensitive, specific and reproducible isothermal DNA amplification technique for rapid molecular identification of microorganisms. RCA-based diagnostics are characterized by good reproducibility, with few amplification errors compared to PCR. The method is applied here to species of Exophiala known to cause systemic infections in humans. The ITS rDNA region of five Exophiala species (E. dermatitidis, E. oligosperma, E. spinifera, E. xenobiotica, and E. jeanselmei) was sequenced and aligned in view of designing specific padlock probes to be used for the detection of single nucleotide polymorphisms (SNPs) of the Exophiala species concerned. The assay proved to successfully amplify DNA of the target fungi at the level of species; while no cross-reactivity was observed. Amplification products were visualized on 1% agarose gels to verify the specificity of probe-template binding. Amounts of reagents were minimized to avoid the generation of false positive results. The sensitivity of RCA may help to improve early diagnostics of these difficult to diagnose infections.     

Quantifying RNA–protein interactions in situ using modified-MTRIPs and proximity ligation

The stabilization, translation and degradation of RNA are regulated by interactions between trans-acting factors, such as microRNA and RNA-binding proteins (RBP). In order to investigate the relationships between these events and their significance, a method that detects the localization of these interactions within a single cell, as well as their variability across a cell population, is needed. To visualize and quantify RNA–protein interactions in situ, we developed a proximity ligation assay (PLA) that combined peptide-modified, multiply-labelled tetravalent RNA imaging probes (MTRIPs), targeted to sequences near RBP binding sites, with proximity ligation and rolling circle amplification (RCA). Using this method, we detected and quantified, with single-interaction sensitivity, the localization and frequency of interactions of the human respiratory syncytial virus (hRSV) nucleocapsid protein (N) with viral genomic RNA (gRNA). We also described the effects of actinomycin D (actD) on the interactions of HuR with β-actin mRNA and with poly(A)+ mRNA at both native and increased HuR expression levels.     

Rapid Identification of Black Grain Eumycetoma Causative Agents Using Rolling Circle Amplification

Accurate identification of mycetoma causative agent is a priority for treatment. However, current identification tools are far from being satisfactory for both reliable diagnosis and epidemiological investigations. A rapid, simple, and highly efficient molecular based method for identification of agents of black grain eumycetoma is introduced, aiming to improve diagnostic in endemic areas. Rolling Circle Amplification (RCA) uses species-specific padlock probes and isothermal DNA amplification. The tests were based on ITS sequences and developed for Falciformispora senegalensis, F. tompkinsii, Madurella fahalii, M. mycetomatis, M. pseudomycetomatis, M. tropicana, Medicopsis romeroi, and Trematosphaeria grisea. With the isothermal RCA assay, 62 isolates were successfully identified with 100% specificity and no cross reactivity or false results. The main advantage of this technique is the low-cost, high specificity, and simplicity. In addition, it is highly reproducible and can be performed within a single day.     

Novel application of Phi29 DNA polymerase: RNA detection and analysis in vitro and in situ by target RNA-primed RCA

We present a novel Phi29 DNA polymerase application in RCA-based target RNA detection and analysis. The 3′→5′ RNase activity of Phi29 DNA polymerase converts target RNA into a primer and the polymerase uses this newly generated primer for RCA initiation. Therefore, using target RNA-primed RCA, padlock probes may be targeted to inner RNA sequences and their peculiarities can be analyzed directly. We demonstrate that the exoribonucleolytic activity of Phi29 DNA polymerase can be successfully applied in vitro and in situ. These findings expand the potential for detection and analysis of RNA sequences distanced from 3′-end.     

Detection of single base polymorphism in p53 gene by ligase detection reaction and rolling circle amplification on microarrays

We combined three modern technologies of single base polymorphism detection in human genome: ligase detection reaction, rolling circle amplification and IMAGE hydro-gel microarrays. Polymorphism in target DNA was tested by selective ligation on microarray. Product of the ligase reaction was determined in microarray gel pads by rolling circle amplification. Two different methods were compared. In first, selective ligation of short oligonucleotides immobilized on microarray was used with subsequent amplification on preformed circle probe ("common circle"). The circle probe was designed especially for human genome research. In second variant, allele-specific padlock probes that may be circularized by selective ligation were immobilized on microarray. Polymorphism of codon 72 in human p53 gene was used as a biological model. It was shown that LDR/RCA on microarray is a quantitative reaction and gives high discrimination of alleles. Principles and perspectives of selective ligation and rolling circle amplification are being discussed.     

A ligation assay for multiplex analysis of CpG methylation using bisulfite-treated DNA

Aberrant methylation of promoter CpG islands is causally linked with a number of inherited syndromes and most sporadic cancers, and may provide valuable diagnostic and prognostic biomarkers. In this report, we describe an approach to simultaneous analysis of multiple CpG islands, where methylation-specific oligonucleotide probes are joined by ligation and subsequently amplified by polymerase chain reaction (PCR) when hybridized in juxtaposition on bisulfite-treated DNA. Specificity of the ligation reaction is achieved by (i) using probes containing CpGpCpG (for methylated sequences) or CpApCpA (for unmethylated sequences) at the 3′ ends, (ii) including three or more probes for each target, and (iii) using a thermostable DNA ligase. The external probes carry universal tails to allow amplification of multiple ligation products using a common primer pair. As proof-of-principle applications, we established duplex assays to examine the FMR1 promoter in individuals with fragile-X syndrome and the SNRPN promoter in individuals with Prader-Willi syndrome or Angelman syndrome, and a multiplex assay to simultaneously detect hypermethylation of seven genes (ID4, APC, RASSF1A, CDH1, ESR1, HIN1 and TWIST1) in breast cancer cell lines and tissues. These data show that ligation of oligonucleotide probes hybridized to bisulfite-treated DNA is a simple and cost-effective approach to analysis of CpG methylation.     

A Universal Approach to Prepare Reagents for DNA-Assisted Protein Analysis

The quality of DNA-labeled affinity probes is critical in DNA-assisted protein analyses, such as proximity ligation and extension assays, immuno-PCR, and immuno-rolling circle amplification reactions. Efficient, high-performance methods are therefore required for isolation of pure conjugates from reactions where DNA strands have been coupled to antibodies or recombinant affinity reagents. Here we describe a universal, scalable approach for preparing high-quality oligonucleotide-protein conjugates by sequentially removing any unconjugated affinity reagents and remaining free oligonucleotides from conjugation reactions. We applied the approach to generate high-quality probes using either antibodies or recombinant affinity reagents. The purified high-grade probes were used in proximity ligation assays in solution and in situ, demonstrating both augmented assay sensitivity and improved signal-to-noise ratios.     

HRCA技术在转基因植物检测中的应用

超分支滚环扩增技术（Hyperbranched rolling cycle amplification, HRCA）在近几年中逐渐引起人们的注意,并越来越多的用于基础研究和实际检测中。在本文中我们对该技术在转基因植物检测中的应用情况作了较全面的探索;根据4种转基因植物中常用的外源基因或DNA片段设计了4条锁式探针（Padlock probe）,利用质粒pKK2328中的一段序列作为锁式探针中的共同连接部分,并根据该共同的连接部分序列设计一对通用的HRCA引物;利用同位素标记的锁式探针对HRCA反应中的连接一步的特异性研究表明,只有当锁式探针和相应的检测靶DNA同时存在于连接体系中时,锁式探针才能被有效地进行连接,从线性分子变为环型分子,在没有相应靶DNA存在时锁式探针仅以线性形式存在;连接时间的研究表明,如果所检测的靶DNA是质粒或较短的DNA片段时,较短的连接时间（5～10min）就可以取得理想的最终检测效果,如果检测的靶DNA是复杂的植物基因组DNA时,连接时间需要较大程度的延长（30～60min）才能取得理想的最终检测结果;HRCA的反应时间研究表明,较长的反应时间可以明显增加最终产物的量;对Bst DNA聚合酶大片段酶用量的研究表明,在其它条件不变的情况下酶的用量可以在较大的范围内变化（0.5u～4u）而不影响最终检测结果;在上述研究的基础上,对转基因烟草进行实际检测,取得了与预期一致的理想结果。为了提高检测效率,仿效复合式PCR（Multiplex PCR,MPCR）的原理采用复合式HRCA（Multiplex HRCA, MHRCA）方法对转基因烟草进行检测,并利用反向点杂交进行结果分析,取得同预期完全一致的结果。我们的研究表明HRCA方法完全可以用于转基因植物的检测,而且其使用比MPCR技术更方便,效率更高。