Hybridization of Random-Primed DNA Probes
Jonathan Houseley, Cristina Cruz
Abstract
Over the past decade a plethora of noncoding RNAs (ncRNAs) have been identified, initiating an explosion in RNA research. Although RNA sequencing methods provide unsurpassed insights into ncRNA distribution and expression, detailed information on structure and processing are harder to extract from sequence data. In contrast, northern blotting methods provide uniquely detailed insights into complex RNA populations but are rarely employed outside specialist RNA research groups. Such techniques are generally considered difficult for nonspecialists, which is unfortunate as substantial technical advances in the past few decades have solved the major challenges. Here we present simple, reproducible and highly robust protocols for separating glyoxylated RNA on agarose gels and heat denatured RNA on polyacrylamide–urea gels using standard laboratory electrophoresis equipment. We also provide reliable transfer and hybridization protocols that do not require optimization for most applications. Together, these should allow any molecular biology lab to elucidate the structure and processing of ncRNAs of interest.
Introduction
Northern blotting methods allow for simultaneous quantification and molecular weight determination of RNA. Although superseded by qPCR and sequencing methods for routine mRNA quantification, northern blotting is the method of choice when complex mixtures of overlapping species are under investigation. This is particularly true when studying RNA processing by complexes such as the exosome, and generally aids in resolving the behavior of differentially expressed RNA isoforms. Historically, northern analysis has been something of a black art; running a high-quality formaldehyde gel required substantial skill and a little luck, while radioactive probing of RNA membranes often resulted in terrible cross-hybridization and invisible signals. Fortunately, technology has moved on such that modern northern analysis methods are simple and robust.
Electrophoretic separation of single-stranded RNA is more complex than double-stranded DNA as RNA forms strong secondary structures that impede separation by molecular weight in a gel matrix. For analysis of high molecular weight RNA in agarose gels, chemical modification of guanine is the preferred method to melt secondary structure, which disrupts C:G base pairing and allows single stranded RNA to migrate according to size. Although formaldehyde has been widely used for this purpose [1], it is not ideal due to issues with sample migration and batch-to-batch variation. Furthermore formaldehyde gels release toxic formaldehyde gas; this did not overly concern early investigators eager to replace the hideously toxic denaturant methyl mercury used in the first northern blotting protocols [2,3], but is clearly a problem in modern labs. To circumvent these issues glyoxal was long ago suggested as an effective RNA denaturant [4], but originally required technically awkward buffer recirculation. This problem was solved by the introduction of BPTE running buffer, which allows agarose gels of glyoxylated RNA to be run with no more difficulty than a normal DNA agarose gel [5].
High-resolution separation of small RNA fragments (~20–250 bp) is best performed on denaturing acrylamide gels, which rely on heat and urea rather than chemical modification to prevent secondary structure formation. The technique is identical to traditional sequencing gel electrophoresis [6], however, the apparatus used for sequencing is not practical for northern blotting and standard protein gel electrophoresis systems are well-suited for this purpose. Helpfully, many of the complications inherent to running a high quality sequencing gel can be safely ignored unless base-pair resolution is required.
Separated RNA is transferred to a membrane by capillary transfer for agarose gels or using an electroblotting system for acrylamide gels [7,8,9]. Various different membranes and transfer conditions have been described but we find charged nylon membrane best for all standard applications [10], and observe little difference between transfer methods. Similarly, many combinations of probes and hybridization buffers can be used to detect RNA species, each having their own strengths and weaknesses. Here we provide a protocol for using RNA probes transcribed from PCR products; in our hands these are both the most reliable and the most sensitive, and as such are the probe of choice for new users [11,12,13,14]. We also provide probing conditions for use of synthetic oligonucleotides, which are widely used in RNA processing analysis since they provide unparalleled resolution of intermediates, and for random-primed DNA probes.
The source of RNA used for northern blotting is rarely critical as long as it is of high quality ( see Note 1 ), and therefore in this chapter we focus purely on the gel systems and hybridization methods.
Before start
It is recommended to read through the guidelines before starting any work with RNA.
Steps
Hybridization of Random-Primed DNA Probes
DNA probes lack the strand specificity of RNA or oligonucleotide probes, but are much more sensitive than oligonucleotides and are easier to strip than RNA probes.
Ensure that the hybridization bottles and internal seals are in good condition to avoid radioactive buffer leaking during hybridization.
Prewarm a bottle of ULTRAHyb to 68°C until the SDS fully dissolves (0h 15m 0s–0h 20m 0s).
Wet the membrane with 0.1× SSC 0.1% SDS. Roll it up with the RNA facing inward, drop it into the hybridization bottle and slowly turn the bottle to unroll the membrane against the side of the bottle.
Prehybridize for 1h 0m 0s at 42°C with 7.5mL.
Dilute 25ng to 37µL with water in a screw-cap tube.
Heat at 100°C for 0h 5m 0s.
Snap-chill on ice water for 0h 2m 0s–0h 3m 0s, centrifuge briefly.
Add 10µL and 1µL, followed by 2µL.
Mix well by pipetting and incubate 1h 0m 0s–3h 0m 0s at 37°C.
Clean the probe through a column as for an RNA probe (as detailed in the following substeps).
Flick a mini Quick Spin column inverted and then correct way up to get the sepharose to the bottom, remove top then bottom cap (see product instructions).
Place the column in a 2 mL microcentrifuge tube, spin at 1000x g, discard tube and place the column in a new 1.5 mL screw cap tube.
Dilute the probe with water to 50µL and then pipette carefully on to the centre of the sepharose matrix in the column.
Centrifuge at 1000x g.
Test incorporation by briefly holding the probe and column at equal distances from the Geiger counter. Use tweezers for this. At least 50% of the label should be incorporated, which means the Geiger counter will read the same signal from both column and probe. Discard the column to the radioactive waste.
Heat probe at 100°C for 0h 5m 0s.
Snap-chill on ice water for 0h 2m 0s–0h 3m 0s, centrifuge briefly.
Add the probe to the hybridization bottle while vertical so that it falls directly into the hybridization buffer and incubate at 42°C.
Pour the probe into a 50 mL tube (Falcon/Corning type) and dispose. Reuse of random primed probes is not recommended.
See Section "Hybridization of RNA Probes" for washing and exposing directions:
Perform a single low stringency wash with 6× SSC for 0h 10m 0s at 42°C.
Perform a single high stringency wash with preheated 2× SSC 0.1% SDS at 42°C for 0h 10m 0s.
Perform one last wash for 0h 10m 0s with 50mL at Room temperature.
