Immobilon-Ny+ nucleic acid blotting membrane: an advanced nylon membrane optimized for superior fixation and reprobing

The use of charged nylon membranes in nucleic acid blotting applications has become an important factor in the success of hybridization-based assays. Retention of nucleic acids on these membranes is promoted by baking at 80 degrees C under vacuum or by exposure to short wavelength UV light, with the latter method preferred. Immobilon-Ny+ is an advanced, positively charged nylon membrane that has been optimized to show superior retention of target DNA and RNA under hybridization conditions. Higher signal levels are obtained in these assays compared to competitive membranes, even after 13 cycles of probing. This report illustrates the superior performance of Immobilon-Ny+ in 32P and chemiluminescent hybridization assays on blotted DNA and RNA.     

'Northern Cross' hybridization for rapid identification of exon-containing restriction fragments

The Northern Cross method allows direct comparison of restriction digests of cDNA and genomic clones to RNA populations by a specialized form of hybridization. This technique is based on the use of Northern and Southern blotting techniques and requires the use of two nylon membranes of differing chemical characteristics. A nylon membrane containing permanently affixed, electrophoretically fractionated RNAs is contact-hybridized at a right angle to a second, chemically different nylon membrane containing transiently bound, fractionated labeled DNA fragments. RNA and DNA bands possessing homology will hybridize where they cross, forming an autoradiographically detectable spot. This Northern Cross procedure proportionately represents the amounts of different RNAs derived from a particular sequence in a manner similar to what would have been observed in a Northern blot. This method, which can be used in the analysis of even relatively rare RNA species, permits rapid and fairly inexpensive identification of exon-containing fragments or determination of the relationship between related, multiple RNA species.     

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.     

Robust and sensitive nylon hybridization membrane suitable for high-throughput robotic arraying applications

An important aspect of automated macroarraying is the suitability of the nylon membrane selected on which samples are to be arrayed. PerForma is a positively charged nylon membrane that has been developed specificallyfor automated macroarraying. Tests usingfluorescent hybridization detection methods have shown that immobilized DNA amounts as low as 0.25 pg can be detected and that positive signals are obtainable after 21 stripping cycles. This report describes the improved colony growth, improved handling characteristics, increased hybridization detection sensitivity, and increased stripping and reprobing capability obtained using PerForma.     

Highly sensitive fluorescent-labeled probes and glass slide hybridization for the detection of plant RNA viruses and a viroid

In this study, a modified method of the conventional RNA dot-blot hybridization was established, by replacing ~(32)p labels with CY5 labels and replacing nylon membranes with positive-charged glass slides, for detecting plant RNA viruses and a viroid. The modified RNA dot-blot hybridization method was named glass slide hybridization. The optimum efficiency of RNA binding onto the surfaces of activated glass slide was achieved using aminosilane-coated glass slide as a solid matrix and 5×saline sodium citrate (SSC) as a spotting solution. Using a CY5-labeled DNA probe prepared through PCR amplification, the optimized glass slide hybridization could detect as little as 1.71 pg of tobacco mosaic virus (TMV) RNA. The sensitivity of the modified method was four times that of dot-blot hybridization on nylon membrane with a ~(32)P-labeled probe. The absence of false positive within the genus Potyvirus [potato virus A, potato virus Y (PVY) and zucchini yellow mosaic virus] showed that this method was highly specific. Furthermore, potato spindle tuber viroid (PSTVd) was also detected specifically. A test of 40 field potato samples showed that this method was equivalent to the conventional dot-blot hybridization for detecting PVY and PSTVd. To our knowledge, this is the first report of using dot-blot hybridization on glass slides with fluorescent-labeled probes for detecting plant RNA viruses and a viroid.     

A procedure for Northern blot analysis of native RNA

We describe a modification of the Northern technique that allows the detection of RNA either native and/or containing hidden breaks. We found that the highest sensitivity of the hybridization signals was obtained after denaturation of the RNA in the gel prior to its transfer onto a nylon membrane (GeneScreen) followed by uv irradiation. The sensitivity of the method using native RNA was found to be equivalent to that obtained with denatured RNA.     

Improved northern blot method for enhanced detection of small RNA

This protocol describes an improved northern blot method that enhances detection of small RNA molecules (<40 nt) including regulatory species such as microRNA (miRNA), short-interfering RNA (siRNA) and Piwi-interacting RNA. Northern blot analysis involves the separation of RNA molecules by denaturing gel electrophoresis followed by transfer and cross-linking of the separated molecules to nylon membrane. RNA of interest is then detected by hybridization with labeled complementary nucleic acid probes. We have replaced conventional UV-cross-linking of RNA to nylon membranes with a novel, 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC)-mediated, chemical cross-linking step that enhances detection of small RNA by up to 50-fold. This requires no specialized equipment, is relatively inexpensive and is technically straightforward. Northern blotting can be done in 2 d, but detection of a specific RNA can vary from minutes to days. Although chemical cross-linking takes longer (15 min to 2 h) than UV cross-linking, improved sensitivity means shorter periods of exposure are required to detect signal after hybridization.     

Immobilization of DNA on microporous membranes using UV-irradiation]

Various techniques of DNA immobilization onto nitrocellulose and nylon microporous membranes have been compared. Despite a strong primary adsorption of DNA onto these membranes during blotting procedures, poor retention of the target DNA and low hybridization signals are obtained after hybridization and washings. Covalent cross-linking of DNA upon UV irradiation leads to a quantitative immobilization of target DNA. Quantum yield of DNA photoimmobilization estimated for a single base in DNA is about 10(-4). UV irradiation dose sufficient for immobilization of DNA fragment of a known length can be calculated by the formula Ilc = (22.3 +/- 4.8) c/l, where l is the DNA fragment length (in base pairs), c is the DNA part (%) to be immobilized. The UV irradiation dose about 0.6-0.8 kJ/m2 is optimal for most hybridization experiments. Doses higher than 0.8-1 kJ/m2 may cause a loss in the hybridization efficiency. Under optimal immobilization conditions, hybridization signals increasing five-fold for nitrocellulose membranes and fifty-fold for uncharged nylon membranes as compared with baking these membranes in vacuum.     

Carbodiimide-mediated cross-linking of RNA to nylon membranes improves the detection of siRNA, miRNA and piRNA by northern blot

The northern blot, or RNA gel blot, is a widely used method for the discovery, validation and expression analysis of small regulatory RNA such as small interfering RNA (siRNA), microRNA (miRNA) and piwi-interacting RNA (piRNA). Although it is straightforward and quantitative, the main disadvantage of a northern blot is that it detects such RNA less sensitively than most other approaches. We found that the standard dose of UV used in northern blots was not the most efficient at immobilizing small RNA of 20–40nt on nylon membranes. However, increasing the dose of UV reduced the detection of miRNA by hybridization in northern blotting experiments. We discovered that using the soluble carbodiimide, EDC, to cross-link RNA to nylon membranes greatly improved the detection of small RNA by hybridization. Compared to standard UV cross-linking procedures, EDC cross-linking provided a 25–50-fold increase in the sensitivity of detection of siRNA from plants and miRNA or piRNA from mammalian cells. All types of hybridization probes tested benefited from the new cross-linking procedure. Cross-linking was dependent on a terminal phosphate and so, should be applicable to other related categories of small RNA.     

Quantitative molecular hybridization on nylon membranes

A study of DNA hybridization to DNA covalently bound to nylon membranes was made in order to develop a quantitative method for molecular hybridization using a nylon-based matrix. Chloroplast DNA was covalently attached to nylon membranes by irradiation at 254 nm. Under hybridization conditions the initial rate of DNA loss from the nylon membranes was 5-10% per 24 h, while under comparable conditions DNA bound to nitrocellulose membranes was lost at a rate of 38 to 61% per 24 h. Several sets of hybridization conditions were examined to select one giving reasonable hybridization rates and minimal loss of bound DNA. Under the conditions selected [Denhardt's solution (D. Denhardt, 1966, Biochem. Biophys. Res. Commun. 23, 641-646), 0.5 M NaCl, 0.1% sodium dodecyl sulfate, and 31.4% formamide at 50 degrees C for 92 h], hybridization was observed to be 29% more efficient on nylon membranes than on nitrocellulose. Several attempts to remove previously hybridized DNA from nylon membranes proved only partially successful. Reuse of the membranes, therefore, was of limited value. Quantitative hybridization of total radiolabeled tobacco cellular DNA to cloned tobacco chloroplast DNA attached to nylon yielded results similar to those previously reported using nitrocellulose membranes. However, use of nylon membranes greatly facilitated the manipulations required in the procedure.     

The presence of humic substances and DNA in RNA extracts affects hybridization results

RNA extracts obtained from environmental samples are frequently contaminated with coextracted humic substances and DNA. It was demonstrated that the response in rRNA-targeted oligonucleotide probe hybridizations decreased as the concentrations of humic substances and DNA in RNA extracts increased. The decrease in hybridization signal in the presence of humic substances appeared to be due to saturation of the hybridization membrane with humic substances, resulting in a lower amount of target rRNA bound to the membrane. The decrease in hybridization response in the presence of low amounts of DNA may be the result of reduced rRNA target accessibility. The presence of high amounts of DNA in RNA extracts resulted in membrane saturation. Consistent with the observations for DNA contamination, the addition of poly(A) to RNA extracts, a common practice used to prepare RNA dilutions for membrane blotting, also reduced hybridization signals, likely because of reduced target accessibility and membrane saturation effects.     

The Presence of Humic Substances and DNA in RNA Extracts Affects Hybridization Results

RNA extracts obtained from environmental samples are frequently contaminated with coextracted humic substances and DNA. It was demonstrated that the response in rRNA-targeted oligonucleotide probe hybridizations decreased as the concentrations of humic substances and DNA in RNA extracts increased. The decrease in hybridization signal in the presence of humic substances appeared to be due to saturation of the hybridization membrane with humic substances, resulting in a lower amount of target rRNA bound to the membrane. The decrease in hybridization response in the presence of low amounts of DNA may be the result of reduced rRNA target accessibility. The presence of high amounts of DNA in RNA extracts resulted in membrane saturation. Consistent with the observations for DNA contamination, the addition of poly(A) to RNA extracts, a common practice used to prepare RNA dilutions for membrane blotting, also reduced hybridization signals, likely because of reduced target accessibility and membrane saturation effects.     

Optimization of DNA blot hybridization conditions for various types of membranes]

A set of experiments has been conducted to choose the optimal conditions for DNA transfer and fixation on two types of the nitrocellulose, three types of nylon membranes and on capron filters. The buffer capillary transfer systems, electroblotting and gel hybridization are analyzed. Two techniques for DNA binding have been tested under different transfer conditions for all the membrane types: a vacuum fixation at 80 degrees C and a UV-exposure. The results indicate the critical dependence of the efficiency of blot-hybridization on the conditions of UV-treatment. The UV-exposure longer or shorter than the optimal one resulted in a loss of the hybridization efficiency. The optimal DNA-transfer and fixation conditions are recommended for all the membranes tested. The dependence of the optimal transfer and binding conditions on the specific characteristics of different membrane types was demonstrated for maximal sensitivity of the blot-hybridization.     

Long-lived southern blots using RNA probes

Conditions for preparation and hybridization of Southern blots are described which assure reusability through 15 to 25 cycles. The procedure relies on the use of charge-modified nylon membranes and^[32P]-labelled RNA probes.     

Loading and transfer control for Northern hybridization.

We report a simple and inexpensive method to quantitate loading and transfer of RNA and to examine RNA integrity for use with Northern hybridization. This technique involves quantitation by computer-assisted video densitometry of a negative photograph of 28S and 18S rRNA from ethidium bromide-stained RNA fixed to nylon membranes. This method eliminates the issue of variability of expression of "housekeeping" genes and the need for a second round of hybridization to quantitate control probes.     

Parameters affecting hybridization of nucleic acids blotted onto nylon or nitrocellulose membranes

Nine different nylon and nitrocellulose membranes were compared utilizing four different methods of attaching the nucleic acid target. Nylon membranes repeatedly demonstrated increased sensitivity as compared to nitrocellulose membranes. Sensitivity could also be enhanced by mildly denaturing the target prior to attachment onto the membrane. This was achieved by either UV cross-linking or baking.     

Group-specific 16S rRNA hybridization probes for determinative and community structure studies of Butyrivibrio fibrisolvens in the rumen.

Oligonucleotide probes covering three phylogenetically defined groups of Butyrivibrio spp. were successfully designed and tested. The specificity of each probe was examined by hybridization to rRNAs from an assortment of B. fibrisolvens isolates as well as additional ruminal and nonruminal bacteria. The sensitivity of the hybridization method was determined by using one of the probes (probe 156). When RNA was extracted from a culture of OB156, the probe was able to detect target cells at densities as low as 10(4) cells/ml. When 10(4) or more target cells/ml were added to cattle rumen samples, detectable hybridization signals were obtained with 1,000 ng of total RNA loaded onto the nylon membrane. In contrast, the sensitivity was reduced to 10(6) target cells/ml at 100 ng of RNA per slot. The probes were used to type 19 novel Butyrivibrio isolates. The phylogenetic placement was confirmed by partial 16S rRNA gene sequencing. The use of the probes in community-based studies indicated that the Butyrivibrio groups examined in this paper did not represent a significant portion of the bacterial 16S rRNA pool in the rumen of the cattle, sheep, and deer examined.