A comparison of substrates for quantifying the signal from a nonradiolabeled DNA probe.

A method for measuring the amount of a nonradiolabeled DNA probe using four detection substrates is described. In preliminary experiments, digoxygenin-labeled DNA was bound to neutral, nylon membranes and detected with anti-digoxygenin antibodies conjugated to alkaline phosphatase. Four substrates [4-nitrophenyl phosphate, 4-methylumbelliferyl phosphate, AttoPhos, and adamantyl 1, 2-dioxetane phosphate (AMPPD)] were assessed for use in a quantitative hybridization assay. Only AttoPhos and AMPPD were found to have detection limits in the low picogram range and to respond linearly to DNA concentrations ranging from 0 to 1250 pg. In subsequent experiments, a 200-bp DNA probe cloned from the marine bacterium Pseudomonas perfectomarina 23S rRNA gene was hybridized to P. perfectomarina genomic DNA and total RNA. The amount of hybridized probe was determined using AttoPhos. Finally, a digoxygenin-labeled oligonucleotide was probed against genomic DNA. Linearity with respect to DNA concentration was observed using both the 200-bp fragment and the oligonucleotide as probes with a final target detection limit of 166 fg. This study demonstrates the substrate AttoPhos can be used to quantify the amount of nonradiolabeled probe hybridized to target with sufficient sensitivity for very dilute samples, such as environmental samples.     

Reusing nylon membranes for radioactive hybridizations

We describe a procedure for recycling nylon hybridization membranes, enabling their repeated use for radioactive Southern hybridization analysis of different DNA samples. Following hybridization and probe removal, nylon membranes containing covalently linked DNAs were treated with 0.55% sodium hypochlorite. This destroyed the DNA, thereby preventing it from participating in further hybridization and enabling the membranes to be used subsequently for binding new DNA samples. With this procedure, we were able to reuse a single membrane as many as 13 times, with no detectable loss in signal. This method was shown to be effective for membranes supplied by three different manufacturers.     

Sensitive chemiluminescent detection of digoxigenin-labeled nucleic acids: a fast and simple protocol and its applications.

A fast and simple protocol for the chemiluminescent detection of digoxigenin-labeled nucleic acids with anti-digoxigenin antibody Fab fragments coupled to alkaline phosphatase and 3-(4-methoxyspiro[1,2-dioxetane-3,2'-tricyclo-[3.3.1.1 (3,7)]decan]-4- yl)phenyl phosphate as substrate is described. The washing and blocking procedure was optimized to yield low background even on positively charged nylon membranes. The sensitivity of the system is equal or better than radioactive methods. Exposure to x-ray or Polaroid film for up to 30 minutes is sufficient for the detection of 70 femtograms of homologous DNA. Human single-copy genes are detected in Southern blots of as low as 0.3 microgram total placental DNA. Blots can be reprobed multiple times very easily. The advantages of the digoxigenin system are high sensitivity, absence of background and ease of reprobing and are illustrated by applications for single-copy gene detection in genomic blots of human DNA, Northern hybridizations to rare mRNA, detection of E. coli genes on blots of genomic digests after pulse field gel electrophoresis, as well as for nonradioactive DNA sequencing blots with digoxigenin-labeled primers.     

A sulfone group-labeled TEM-DNA probe: comparison with a 32P-labeled probe in dot-hybridization

A non-radioactive DNA probe for the TEM-type beta-lactamase gene was obtained by using the 'Chemiprobe' system. It was used along with a 32P-labeled TEM probe to screen for TEM beta-lactamase gene in 107 bacterial isolates representing 7 Gram-negative genera and previously classified as TEM-positive or negative. The DNA to be tested was extracted from these bacterial isolates by the Birnboim-Doly method and, after blotting into charged nylon membranes, it was submitted to hybridization with either the TEM 'Chemiprobe' or the 32P-TEM probe. The TEM 'Chemiprobe' could detect as few as 25 pg specific DNA if it was used at a concentration of 5 ng per cm2 of membrane. The results obtained by both probes were concordant in 93.5% of the entire sample. The TEM 'Chemiprobe' was specific since only one false positive was observed. Furthermore, it appeared at least as sensitive as the 32P-labeled TEM probe. As the dot-hybridization with the sulfone-labeled probe was sensitive, simple and easy to perform, it will be useful for large-scale screening in clinical laboratory.     

Oligonucleotide derivatives in the hybridization analysis of nucleic acids. I. Covalent immobilization of oligonucleotide probes on nylon

The characteristics of the UV-induced immobilization of oligonucleotides on nylon membranes and the efficiency of the enzymatic labeling of immobilized probes in heterophase identifying specific DNA sequences were studied. Oligonucleotides bound to short terminal oligothymidylates (up to 10 nt) through a flexible linker based on diethylene glycol phosphodiester are proposed as probes for immobilization on nylon. The presence of this fragment allows one to enhance the immobilization efficiency and reduce the UV-dependent degradation of the sequence-specific part of the probe by decreasing the irradiation dose needed for DNA immobilization. The optimal dose of UV irradiation is evaluated to be ∼0.4 J/cm² at 254 nm, which provides a high level of the hybridization signal for immobilized probes of various nucleotide sequences. It was found that nylon amide groups play a key role in the photoinduced fixation of oligonucleotides to the polymer surface, while its primary amino groups were not as responsible for the covalent binding of DNA as previously thought. Various additives in the membrane wetting solution were demonstrated to influence both the efficiency of the UV-induced immobilization and the functional integrity of immobilized probes. Other radical generating systems alternative to UV irradiation are shown to provide the immobilization of oligonucleotides on nylon membranes.     

Re-probing DNA blots: Wet is better than dry storage of uncharged nylon membranes after removing probes

DNA immobilized on a nylon membrane can be re-probed multiple times with different probes. Protocols typically recommend that DNA blots be stored either dry at room temperature or wet at 4 or −20°C after a probe is removed. This study shows substantial differences in the effect of these storage options on the performance of uncharged nylon membranes in subsequent hybridizations. Uncharged membranes, air-dried and stored at room temperature after probe removal, could not be successfully re-probed. However, excellent rehybridization results were obtained following probe removal when wet membranes were wrapped in plastic and stored at −20°C.     

Brain blotting: a method to detect multiple DNA copies in specific brain regions

We developed a method to detect multiple DNA copies (both cellular and viral) in specific brain regions by blotting thick frozen sections onto nylon membranes. This was achieved by "printing" the frozen sections on standard blotting paper immediately after cryotome sectioning and performing blotting according to the standard Southern technique. A "replica" of the blotted section was obtained by keeping on the glass slide the next frozen section cut, which was then stained for conventional histopathological analysis and the cell nuclei counted to give an estimate of the total amount of DNA present in each section. The blotted membranes were then denatured and hybridized with a nick-translated Alu probe either at 42 degrees C with 50% formamide or at 68 degrees C without formamide. Brain sections from mice infected with Herpes simplex virus 1 (HSV1), blotted and hybridized with a nick-translated HSV1 probe, clearly showed the focal nature of the Herpes simplex infection, which was also demonstrated immunohistologically using a virus specific antiserum. This method of DNA detection, conveniently modified, might also be used to detect nuclear and cytoplasmic RNAs in specific coronal sections of whole brain before localization at high power by standard in situ techniques.     

Classical dot–blot format implemented as an amperometric hybridisation genosensor

A new electrochemical hybridisation genosensor has been designed. This genosensor is based on a concept adapted from classical dot–blot DNA analysis, but implemented in an electrochemical biosensor configuration. The use of amperometric transduction and the enzyme label method—that increases the genosensor sensitivity—are the main features of this new approach. The analytical procedure consists of five steps: DNA target immobilisation by adsorption onto a nylon membrane, hybridisation between DNA target and biotin–DNA probe, complexation reaction between biotin-DNA probe and an enzyme (horseradish peroxidase) streptavidin conjugate; integration of the modified membrane onto an electrochemical transducer; and finally, amperometric detection using a suitable substrate for the enzyme labelled duplex. Besides the adapted dot–blot format, a competitive assay in which the target is in solution is reported as well. This procedure, based on amperometric transduction, represents certain advantages with respect to dot–blot analysis: labelled hybrid detection is far simpler, quicker and requires more ordinary or simple reactives; the response obtained is a direct analytical signal via low-cost instrumentation, a nonisotopic labelling is used, and the membranes can be reused. These characteristics are ideal in implementing the procedure developed in kit form.     

Synthesis of nucleic acid probes on membrane supports: a procedure for the removal of unincorporated precursors

We have used DNA bound to small pieces of nylon membrane for the synthesis of radioactive probes. The DNA to be used for generating the probe(s) is first bound to nylon membranes and then introduced into the reaction mix. The labeling reaction takes place on the membrane and therefore allows easy removal of unincorporated precursors by simple washing for 1-2 min. The clean labeled probe is eluted from the membrane in formamide or in water and is ready for use. This DNA-membrane can be stored for reuse. Synthesis of probes on a solid support such as nylon membrane thus circumvents problems associated with chromatographic manipulations needed for the separation of labeled DNA from unicorporated precursors. Probes synthesized in this manner are as efficient in detecting nucleic acid sequences as those synthesized in solution.     

Digital chemiluminescence imaging of DNA sequencing blots using a charge-coupled device camera.

Digital chemiluminescence imaging with a cryogenically cooled charge-coupled device (CCD) camera is used to visualize DNA sequencing fragments covalently bound to a blotting membrane. The detection is based on DNA hybridization with an alkaline phosphatase(AP) labeled oligodeoxyribonucleotide probe and AP triggered chemiluminescence of the substrate 3-(2'-spiro-adamantane)-4-methoxy-4-(3"-phosphoryloxy)phenyl- 1,2-dioxetane (AMPPD). The detection using a direct AP-oligonucleotide conjugate is compared to the secondary detection of biotinylated oligonucleotides with respect to their sensitivity and nonspecific binding to the nylon membrane by quantitative imaging. Using the direct oligonucleotide-AP conjugate as a hybridization probe, sub-attomol (0.5 pg of 2.7 kb pUC plasmid DNA) quantities of membrane bound DNA are detectable with 30 min CCD exposures. Detection using the biotinylated probe in combination with streptavidin-AP was found to be background limited by nonspecific binding of streptavidin-AP and the oligo(biotin-11-dUTP) label in equal proportions. In contrast, the nonspecific background of AP-labeled oligonucleotide is indistinguishable from that seen with 5'-32P-label, in that respect making AP an ideal enzymatic label. The effect of hybridization time, probe concentration, and presence of luminescence enhancers on the detection of plasmid DNA were investigated.     

A label-free electrochemiluminescence aptasensor for thrombin based on novel assembly strategy of oligonucleotide and luminol functionalized gold nanoparticles

In the work, a label-free electrochemiluminescence (ECL) aptasensor for the sensitive and selective detection of thrombin was constructed based on target-induced direct ECL signal change by virtue of a novel assembly strategy of oligonucleotide and luminol functionalized gold nanoparticles (luminol-AuNPs). It is the first label-free ECL biosensor based on luminol and its analogs functionalized AuNPs. Streptavidin AuNPs coated with biotinylated DNA capture probe 1 (AuNPs-probe 1) were firstly assembled onto an gold electrode through 1,3-propanedithiol. Then luminol-AuNPs co-loaded with thiolated DNA capture probe 2 and thiolated thrombin binding aptamer (TBA) (luminol-AuNPs-probe 2/TBA) were assembled onto AuNPs-probe 1 modified electrode through the hybridization between capture probes 1 and 2. The luminol-AuNPs-probe 2/TBA acted as both molecule recognition probe and sensing interface. An Au/AuNPs/ds-DNA/luminol-AuNPs/TBA multilayer architecture was obtained. In the presence of target thrombin, TBA on the luminol-AuNPs could capture the thrombin onto the electrode surface, which produced a barrier for electro-transfer and influenced the electro-oxidation reaction of luminol, leading to a decrease in ECL intensity. The change of ECL intensity indirectly reflected the concentration of thrombin. Thus, the approach showed a high sensitivity and a wider linearity for the detection of thrombin in the range of 0.005-50nM with a detection limit of 1.7pM. This work reveals that luminol-AuNPs are ideal platform for label-free ECL bioassays.     

Amplified Chemiluminescence Detection of DNA by Strand-Displacement Polymerization Target Recycling and G-quadruplexes/Hemin DNAzyme Catalysis

A new strategy based on strand-displacement polymerization target recycling and G-quadruplex DNAzyme catalysis was developed for amplified chemiluminescence detection of DNA. The amplified detection was achieved by using the system consisted of hairpin DNA probe, G-rich DNA, primer, and polymerase Klenow fragment exo^?. When the target DNA was introduced the system, the hairpin structure of DNA probe was opened by the hybridizing of target DNA with its complementary sequence, the primer hybridized then with DNA probe and initiated polymerase-aided strand-displacement polymerization reaction, resulting in the release of target DNA and G-rich DNA. The released target DNA again hybridizes with another DNA probe to trigger the next polymerase-aided strand-displacement polymerization, generating large numbers of G-rich DNA. The G-rich DNA assembles with hemin to form the G-quadruplexes/hemin DNAzyme, which can catalyze oxidation of luminol by H₂O₂, generating chemiluminescence. This unique amplifying strategy gives a detection limit down to 2.5 pM, which is at least two to three orders of magnitude lower than that of unamplified DNA detection methods.     

Male-specific DNA sequences in pigs

One hundred primers (Operon kits OPAA, OPAO, OPAV, OPC, and OPE series) were used for random amplified polymorphic DNA (RAPD) fingerprinting to determine male-specific fragments. Seventy-four percent of the primers yielded Yorkshire polymorphic fragments. One of these primers, OPAV-18, produced a novel 1098-bp DNA fragment found only in tested males. This male-specific fragment was isolated and constructed into plasmids for nucleotide sequencing. Two primers (5'-TTGCTCACGG TAGATAACAA GAGAG-3' and 5'-TTGCTCACGG ACCAGGTAGG GAATG-3') were designed according to the cloned male-specific sequence to amplify the male-specific band using polymerase chain reaction (PCR) for pig sexing. Sex-specific bands in the PCR gel products were represented in males but none were found in females when Yorkshire, Duroc, and Landrace genomic DNA samples were amplified with these two primers by PCR. The PCR products in the gel were transferred to nylon membranes and hybridized with a 32P-dCTP labeled probe of the cloned male-specific DNA fragment. There was a clear hybridization signal in samples from all of the male pigs, but not from those of female pigs. Male and female genomic DNA samples from these pigs were spotted onto nylon membranes and hybridized with the male-specific probe. The probe hybridized strongly to males only. A high degree of sequence homology was found among the novel male-specific DNA sequences in Yorkshire, Duroc and Landrace. The sex of these three breeds of pigs could be easily and effectively determined using these two primers.     

Immunoassays for carbodiimide modified DNA-detection of unpairing transitions in supercoiled ColE1 DNA.

The water soluble reagent N-cyclohexyl-N'-beta-(4-methylmorpholinium) ethyl carbodiimide-p-toluene sulphonate (CMC) can be used to probe for unpaired and mismatched sites in DNA. Polyclonal antibodies for CMC modified DNA were produced in order to develop immunological assays for the localization and quantitation of CMC adducts. Immunoslot blot analysis of modified DNA exhibited antibody binding proportional to the extent of CMC modification with adduct detection in the femtamole range. Unmodified DNA did not cross react under the conditions of the assay. The distribution of CMC reactivity for supercoiled ColE1 DNA modified at 100, 200 and 300 mM NaCl was determined by immunoanalysis of EcoRI-Hae2-NruI restriction fragments Southern transferred to nylon membranes. Reactivity above random expectation occurred in the A2-II fragment which can be accounted for by its high A-T content of 71.3%. Reactivity below random expectation occurred in the C fragment which can be accounted for by its low AT content of 43%. CMC modification for the other restriction fragments appeared random.     

Construction of DNA-probes and their immunochemical detection using nonradioactive hybridization tests

Simple and efficient chemical approaches to preparation of DNA probes carrying 2,4-dinitrophenyl, dansyl or biotin residues were developed. The residues were introduced using following DNA derivatization procedures: a) transamination of cytidine residues with O-(4-aminobutyl)hydroxylamine; b) mercuration of pyrimidine residues followed by beta-mercaptoethanol modification. It was shown that 2,4-dinitrophenyl-containing DNA probes can be used for nonradioactive hybridization detection of nucleic acids. DNP-DNA: DNA complexes were detected using mouse antibodies specific to 2,4-dinitrophenyl groups, which were developed with peroxidase-conjugated antimouse immunoglobulins. Peroxidase-catalyzed chemoluminescent reaction of luminol oxidation with hydrogen peroxide allowed to detect 10 picograms of the dinitrophenylated single-stranded DNA probe.     

A new sensitive non-isotopic method using sulfonated probes to detect picogram quantities of specific DNA sequences on blot hybridization

The use of non-radioactive systems to detect target DNA or RNA displays many advantages such as safe manipulation, potential use in non-specialized scientific area and prolonged lifetime of the probes (one year or more). We here describe a method we have improved and optimized using sulfonated DNA probes for hybridization on dot and Southern blots. Sulfonation is an easy chemical modification procedure which does not require enzymatic coctail as does nick-translation. Sensitivity of this method has been particularly improved by using a new blocking solution, containing heparin, which allows easy and fast detection of picogram quantities of DNA. This method allows the use of nitrocellulose as well as nylon membranes with very low background. Equal resolution is obtained in comparative experiments involving both sulfonated and 32P-radiolabelled probes. Single copy gene sequences are readily detected in nuclear DNA. These results allow the use of this procedure for restriction fragment length polymorphism (RFLP) studies.     

A highly sensitive and temporal visualization system for gaseous ethanol with chemiluminescence enhancer

A two‐dimensional gaseous ethanol visualization system has been developed and demonstrated using a horseradish peroxidase–luminol–hydrogen peroxide system with high‐purity luminol solution and a chemiluminescence (CL) enhancer. This system measures ethanol concentrations as intensities of CL via the luminol reaction. CL was emitted when the gaseous ethanol was injected onto an enzyme‐immobilized membrane, which was employed as a screen for two‐dimensional gas visualization. The average intensity of CL on the substrate was linearly related to the concentration of standard ethanol gas. These results were compared with the CL intensity of the CCD camera recording image in the visualization system. This system is available for gas components not only for spatial but also for temporal analysis in real time. A high‐purity sodium salt HG solution (L‐HG) instead of standard luminol solution and an enhancer, eosin Y (EY) solution, were adapted for improvement of CL intensity of the system. The visualization of gaseous ethanol was achieved at a detection limit of 3 ppm at optimized concentrations of L‐HG solution and EY. Copyright © 2011 John Wiley & Sons, Ltd.     

柑桔溃疡病菌滚环扩增检测体系的建立

根据柑桔溃疡病菌(Xanthomonas axonopodis pv.citri,Xac)独有的蛋白基因序列和锁式探针公共连接序列分别设计特异性的锁式探针及其扩增引物,优化系列反应条件,建立了特异性的柑桔溃疡病菌滚环扩增体系.初步检测结果表明该体系能够特异性地检出Xac的菌体细胞及其DNA,而检测不出供试的其它植物病原细菌和柑桔叶面常见的多种附生细菌;对Xac靶片段克隆质粒DNA的检测灵敏度为10 2 copy/μL,对Xac菌悬液的检测灵敏度为20 cfu/μL,比常规PCR的检测灵敏度稍高.用滚环扩增技术和常规PCR技术对田间采集的实际样品进行了检测,两种方法的检测结果没有显著差异(P＞0.01).由于锁式探针的公共连接序列对扩增的条件要求一致,本体系的建立可以为植物病原微生物多靶标检测和病害检疫检验提供新的技术支撑.     

Comparison of membranes and glass slides for 16S rDNA array analyses of microbial communities by sequence-specific labeling of DNA probes

Analyses of complex microbial communities are becoming increasingly important. Bottlenecks in these analyses, however, are the tools to actually describe the biodiversity. Novel protocols for a DNA array based analyzes of microbial communities are presented. In these protocols, the specificity obtained by sequence-specific labeling of DNA probes is combined with the possibility of detecting several different probes simultaneously by DNA array hybridization. The gene encoding 16S ribosomal RNA was chosen as the target in these analyses. This gene contains both universally conserved regions, and regions with relatively high variability. The universally conserved regions are used for PCR amplification primers, while the variable regions are used for the specific probes. Arrays prepared on positively charged nylon membranes and coated glass slides were compared. The advantage of using membranes is that chromogenic signal amplification can be used for the detection. Furthermore, the chromogenic detection does not require any sophisticated equipment. The advantage of the glass slides is that multiple fluorescence colors can be detected simultaneously, and that internal controls can be used for normalization. This approach is also suited for high throughput screenings.     

Southern transfer of native DNA using nylon membranes

Transfer of native or denatured DNA from gels or filter manifolds was compared using nylon or nitrocellulose membranes. The results were comparable when denatured DNA was used, but only nylon membranes were able to retain native DNA. Although retention of the native DNA was less efficient the bound DNA could be rapidly denatured in situ, avoiding the need to soak gels in alkaline denaturation solution and neutralizing buffer.