Chemi-Northern: a versatile chemiluminescent northern blot method for analysis and quantitation of RNA molecules.

This report describes a chemiluminescence-based detection method for RNAs on northern blots, designated Chemi-Northern. This approach builds on the simplicity and versatility of northern blotting, while dispensing of the need for expensive and cumbersome radioactivity. RNAs are first separated by denaturing gel electrophoresis, transferred to a nylon membrane, and then hybridized to a biotinylated RNA or DNA antisense probe. Streptavidin conjugated with horseradish peroxidase and enhanced chemiluminescence substrate are then used to detect the probe bound to the target RNA. Our results demonstrate the versatility of this method in detecting natural and engineered RNAs expressed in cells, including messenger and noncoding RNAs. We show that Chemi-Northern detection is sensitive and fast, detecting attomole amounts of RNA in as little as 1 sec, with high signal intensity and low background. The dynamic response displays excellent linearity. Using Chemi-Northern, we measure the reproducible, statistically significant reduction of mRNA levels by human sequence-specific RNA-binding proteins, PUM1 and PUM2. Additionally, we measure the interaction of the poly(A) binding protein, PABPC1, with polyadenylated mRNA. Thus, the Chemi-Northern method provides a versatile, simple, and cost-effective method to enable researchers to analyze expression, processing, binding, and decay of RNAs.

Measuring Poly-Adenosine Tail Length of RNAs by High-Resolution Northern Blotting Coupled with RNase H Cleavage.

The poly-adenosine, or poly(A) tail, plays key roles in controlling the stability and translation of messenger RNAs in all eukaryotes, and, as such, facile assays that can measure poly(A) length are needed. This chapter describes an approach that couples RNase H-mediated cleavage of an RNA of interest with high-resolution denaturing gel electrophoresis and northern blot-based detection. Major advantages of this method include the ability to directly measure the abundance of any RNA and the length of its poly(A) tail without amplification steps. The assay provides high specificity, sensitivity, and reproducibility for accurate quantitation using standard molecular biology equipment and reagents. Overall, the high-resolution northern blotting approach offers a cost-effective means of poly(A) RNA analysis that is especially useful for small numbers of transcripts and comparisons between experimental conditions or time points.

Discovery of the major 15-30 nt mammalian small RNAs, their biogenesis and function.

Small RNAs (sRNAs) within 15-30 nt such as miRNA, tsRNA, srRNA with 3'-OH have been identified. However, whether these sRNAs are the major 15-30 nt sRNAs is still unknown. Here we show about 90% mammalian sRNAs within 15-30 nt end with 2',3'-cyclic phosphate (3'-cP). TANT-seq was developed to simultaneously profile sRNAs with 3'-cP (sRNA-cPs) and sRNA-OHs, and huge amount of sRNA-cPs were detected. Surprisingly, sRNA-cPs and sRNA-OHs usually have distinct sequences. The data from TANT-seq were validated by a novel method termed TE-qPCR, and Northern blot. Furthermore, we found that Angiogenin and RNase 4 contribute to the biogenesis of sRNA-cPs. Moreover, much more sRNA-cPs than sRNA-OHs bind to Ago2, and can regulate gene expression. Particularly, snR-2-cP regulates Bcl2 by targeting to its 3'UTR dependent on Ago2, and subsequently regulates apoptosis. In addition, sRNA-cPs can guide the cleavage of target RNAs in Ago2 complex as miRNAs without the requirement of 3'-cP. Our discovery greatly expands the repertoire of mammalian sRNAs, and provides strategies and powerful tools towards further investigation of sRNA-cPs.

Total Bacterial RNA Isolation and Northern Blotting Analysis.

The study of bacterial gene expression during infection provides vital information for researchers to understand bacterial pathogenesis and infection. The ability to obtain clean and undegraded RNA could be challenging and daunting and remains the most crucial experimental step prior to downstream analyses, such as Northern blotting, quantitative PCR (qPCR), and RNA-seq.This chapter describe two methods (acid guanidinium thiocyanate (TRIzol) phenol-chloroform and hot phenol) commonly used to isolate total bacterial RNA and are suitable for both Gram-positive and Gram-negative bacteria. Procedures such as RNA quantification and DNase treatment are also included to ensure amount and quality of the RNA samples. The second part of the chapter includes a method used to analyze bacterial gene expression (Northern blotting), two methods to generate radioactive probes, as well as target detection using a phosphorimager.

Identification and initial characterization of Hfq-associated sRNAs in Histophilus somni strain 2336.

Small RNAs (sRNA), in association with the global chaperone regulator Hfq, positively or negatively regulate gene expression in bacteria. For this study, Histophilus somni sRNAs that bind to Hfq were identified and then partially characterized. The Hfq-associated sRNAs in H. somni were isolated and identified by co-immunoprecipitation using anti-Hfq antibody, followed by sRNA sequencing. Sequence analysis of the sRNA samples identified 100 putative sRNAs, out of which 16 were present in pathogenic strain 2336, but not in non-pathogenic strain 129Pt. Bioinformatic analyses suggested that the sRNAs HS9, HS79, and HS97 could bind to many genes putatively involved in virulence/biofilm formation. Furthermore, multi-sequence alignment of the sRNA regions in the genome revealed that HS9 and HS97 could interact with sigma 54, which is a transcription factor linked to important bacterial traits, including motility, virulence, and biofilm formation. Northern blotting was used to determine the approximate size, abundance and any processing events attributed to the sRNAs. Selected sRNA candidates were confirmed to bind Hfq, as determined by electrophoretic mobility shift assays using sRNAs synthesized by in vitro transcription and recombinant Hfq. The exact transcriptional start site of the sRNA candidates was determined by RNA ligase-mediated rapid amplification of cDNA ends, followed by cloning and sequencing. This is the first investigation of H. somni sRNAs that show they may have important regulatory roles in virulence and biofilm formation.

Detection of miRNAs.

MicroRNAs (miRNAs) are small, noncoding RNAs that regulate gene expression. They play an important role in many biological processes including human diseases. However, miRNAs are challenging to detect due to their short sequence length and low copy number. A number of conventional (e.g., Northern blot, microarray, and RT-qPCR) and emerging (e.g., nanostructured materials and electrochemical methods) techniques have been developed to detect miRNA, each with their own strengths and weaknesses. Some of these techniques have been combined to detect miRNAs as disease biomarkers in point-of-care (POC) settings. Nonetheless, there is still potential for further innovation to facilitate the detection of miRNAs.

Detection of MicroRNAs by Northern Blot.

Small RNAs (sRNAs) are key regulators of transcriptomes and proteomes of organisms through their sequence-specific interaction with complementary RNA targets. sRNAs can be classified according to their origin and mode of action into different classes such as: microRNAs (miRNAs), small interfering RNAs (siRNAs) and PIWI-interacting RNAs (piRNAs). The abundance and specific spatio-temporal expression of many sRNAs, especially miRNAs, is relevant for their biological function. Northern blotting is a widely used technique to study sRNAs because it is quantitative, relatively inexpensive, and readily available for most laboratories. This chapter describes the protocols for radioactive and non-radioactive sRNA Northern blot analysis, which includes RNA extraction, polyacrylamide gel electrophoresis, membrane transfer, hybridisation and detection of sRNA using oligonucleotide probes. The protocol is described to prepare most of the reagents needed in the lab, but also timesaving commercial reagent alternatives are included. Suggestions and nuances obtained from experience are included as Notes.

Molecular Characteristics of Subgenomic RNAs and the Cap-Dependent Translational Advantage Relative to Corresponding Genomic RNAs of Tomato spotted wilt virus.

Tomato spotted wilt virus (TSWV) causes severe viral diseases on many economically important plants of Solanaceae. During the infection process of TSWV, a series of 3'-truncated subgenomic RNAs (sgRNAs) relative to corresponding genomic RNAs were synthesized, which were responsible for the expression of some viral proteins. However, corresponding genomic RNAs (gRNAs) seem to possess the basic elements for expression of these viral proteins. In this study, molecular characteristics of sgRNAs superior to genomic RNAs in viral protein expression were identified. The 3' ends of sgRNAs do not cover the entire intergenic region (IGR) of TSWV genomic RNAs and contain the remarkable A-rich characteristics. In addition, the 3' terminal nucleotides of sgRNAs are conserved among different TSWV isolates. Based on the eIF4E recruitment assay and subsequent northern blot, it is suggested that the TSWV sgRNA, but not gRNA, is capped in vivo; this is why sgRNA is competent for protein expression relative to gRNA. In addition, the 5' and 3' untranslated region (UTR) of sgRNA-Ns can synergistically enhance cap-dependent translation. This study further enriched the understanding of sgRNAs of ambisense RNA viruses.

A New Biotin Labeling and High-Molecular-Weight RNA Northern Method and Its Application in Viral RNA Detection.

Viruses cause severe crop losses. Studying the interaction between viruses and plants is very important for development of control measures. Northern blot is a well-accepted but very challenging technique to monitor the infection of viruses. Here, we modified the high-molecular-weight (hmw)RNA Northern blot experiment process, utilizing vertical electrophoresis to separate the RNA with denatured agarose gel. This protocol is compatible with regular equipment for Western blots and small RNA Northern blots and requires less input of total RNA. A new method to label the probe with biotin was also developed, which requires commonly used T4 DNA polymerase and detects viral RNA with high sensitivity. These new protocols made hmwRNA Northern blot cost-effective and easy-to-operate, very suitable for studying virus-host interactions.

Analysis of RNA by Northern Blotting.

Northern hybridization is used to measure the amount and size of RNAs transcribed from eukaryotic genes and to estimate their abundance. No other method is capable of obtaining these pieces of information simultaneously from a large number of RNA preparations; northern analysis is therefore fundamental to studies of gene expression in eukaryotic cells. To prepare a northern blot for hybridization, RNA must be separated according to size through a denaturing agarose or polyacrylamide gel and transferred to a solid support in a way that preserves its topological distribution within the gel. These important steps in northern analysis are discussed here.

Modified Northern blot protocol for easy detection of mRNAs in total RNA using radiolabeled probes.

BACKGROUND: Northern blotting is still used as a gold standard for validation of the data obtained from high-throughput whole transcriptome-based methods. However, its disadvantages of lower sensitivity, labor-intensive operation, and higher quality of RNA required limit its utilization in a routine molecular biology laboratory to monitor gene expression at RNA level. Therefore, it is necessary to optimize the traditional Northern protocol to make the technique more applicable for standard use. RESULTS: In this paper, we report modifications and tips used to improve the traditional Northern protocol for the detection of mRNAs in total RNA. To maximize the retention of specifically bound radiolabeled probes on the blot, posthybridization washes were performed under only with moderate-stringency until the level of radioactivity retained on the filter decreased to 20~50 counts per second, rather than normally under high and low stringency sequentially for scheduled time or under only high stringent condition. Successful detection of the low-expression gene using heterologous DNA probes in 20 µg of total RNA after a two-day exposure suggested an improvement in detection sensitivity. Quantitatively controlled posthybridization washes combined with an ethidium bromide-prestaining RNA procedure to directly visualize prestained RNA bands at any time during electrophoresis or immediately after electrophoresis, which made the progress of the Northern procedure to be monitored and evaluated step by step, thereby making the experiment reliable and controllable. We also report tips used in the modified Northern protocol, including the moderate concentration of formaldehyde in the gel, the accessory capillary setup, and the staining jar placed into an enamel square tray with a lid used for hybridization. Using our modified Northern protocol, eight rounds of rehybridization could be performed on a single blot. The modification made and tips used ensured the efficient proceeding of the experiment and the resulting good performance, but without using special reagents or equipment. CONCLUSIONS: The modified Northern protocol improved detection sensitivity and made the experiment easy, less expensive, reliable, and controllable, and can be employed in a routine molecular biology laboratory to detect low-expressed mRNAs with heterologous DNA probes in total RNA.

A versatile tRNA modification-sensitive northern blot method with enhanced performance.

The 22 mitochondrial and ∼45 cytosolic tRNAs in human cells contain several dozen different post-transcriptional modified nucleotides such that each carries a unique constellation that complements its function. Many tRNA modifications are linked to altered gene expression, and deficiencies due to mutations in tRNA modification enzymes (TMEs) are responsible for numerous diseases. Easily accessible methods to detect tRNA hypomodifications can facilitate progress in advancing such molecular studies. Our laboratory developed a northern blot method that can quantify relative levels of base modifications on multiple specific tRNAs ∼10 yr ago, which has been used to characterize four different TME deficiencies and is likely further extendable. The assay method depends on differential annealing efficiency of a DNA-oligo probe to the modified versus unmodified tRNA. The signal of this probe is then normalized by a second probe elsewhere on the same tRNA. This positive hybridization in the absence of modification (PHAM) assay has proven useful for i6A37, t6A37, m3C32, and m2,2G26 in multiple laboratories. Yet, over the years we have observed idiosyncratic inconsistency and variability in the assay. Here we document these for some tRNAs and probes and illustrate principles and practices for improved reliability and uniformity in performance. We provide an overview of the method and illustrate benefits of the improved conditions. This is followed by data that demonstrate quantitative validation of PHAM using a TME deletion control, and that nearby modifications can falsely alter the calculated apparent modification efficiency. Finally, we include a calculator tool for matching probe and hybridization conditions.

Gel Blot Hybridization for Viroids.

Northern blot analysis reveals information about RNA identity, size, and abundance. This technique has become an essential tool for the knowledge developed about viroids and also an excellent method for viroid detection. Here we describe the methodology of a Northern blot based in polyacrylamide gel electrophoresis under denaturing conditions, hybridized with a viroid full-length riboprobe labeled with chemiluminescence. Viroid detection with this approach entails positive signals, specific migration, and the differentiation of their circular and linear forms.

Detection of Viroid RNA and vd-siRNA in N. benthamiana Plants: Northern Blot Analyses for Viroid and vd-siRNAs.

Viroids are considered the most minimalistic group of pathogens. Despite their presumed inability to encode for proteins, viroids induce several diseases in plants of primary economic importance. The production of viroid derived siRNAs (vd-siRNAs) of 21-24 nt, accompanies viroid infections in plants and results from the activation of the RNA silencing mechanism and specifically the function of Dicer endonucleases. A comprehensive set of experiments for the study and thorough analysis of viroid-infected plants has been developed. Here we present a detailed experimental plan including optimized protocols for plant infection by agroinfiltration, RNA extraction, and northern blot hybridization for the detection of both viroid genomic RNA and vd-siRNAs.

Primer extension coupled with fragment analysis for rapid and quantitative evaluation of 5.8S rRNA isoforms.

The ribosomal RNA 5.8S is one of the four rRNAs that constitute ribosomes. In human cells, like in all eukaryotes, it derives from the extensive processing of a long precursor containing the sequence of 18S, 5.8S and 28S rRNAs. It has been confirmed also in human cells the presence of three isoforms of 5.8S rRNA: one more abundant called 5.8S short, one called 5.8S long bearing 5 extra-nucleotides at its 5' end and one 10 nucleotide shorter called 5.8S cropped. So far, little is known about 5.8S long specific role in cell biology and its function in human pathology. The lack of studies on the three 5.8S isoforms could be due to the techniques usually applied to study ribosome biogenesis, such as Northern blot with radioactively labelled probes, that require strict protective measures, and abundant and high-quality samples. To overcome this issue, we optimized a method that combines primer extension with a fluorescently labeled reverse primer designed on the 3' of 5.8S rRNA sequence and fragment analysis. The resulting electropherogram shows the peaks corresponding to the three isoforms of 5.8S rRNA. The estimation of the area underneath the peaks allows to directly quantify the isoforms and to express their relative abundance. The relative abundance of 5.8S long and 5.8S short remains constant using scalar dilution of RNA and in samples subjected to partial degradation. 5.8S cropped abundance varies significantly in lower concentrate RNA samples. This method allows to analyze rapidly and safely the abundance of 5.8S rRNA isoforms in samples that have been so far considered not suitable such as poorly concentrated samples, RNA derived from frozen tissue or unique samples.

Total RNA Extraction from Saccharomyces cerevisiae Using Hot Acid Phenol.

Isolation of RNA from yeast is complicated by the need to first break the thick, rigid cell wall. The protocol provided here uses a cycle of heating and freezing of cells in the presence of phenol and the detergent sodium dodecyl sulfate (SDS). The extraction is performed in the presence of low salt so that, following separation of the aqueous and phenol phases by centrifugation, DNA can be collected from the interface while RNA remains in the aqueous phase. This protocol should yield ∼50-250 µg of RNA from 10 mL of culture. The RNA isolated using this approach is suitable for most follow-up applications such as northern blot hybridization, reverse transcriptase-polymerase chain reaction (RT-PCR), and cDNA construction.

Detection of Long Non-coding RNA Expression by Non-radioactive Northern Blots.

With the advances in sequencing technology and transcriptome analysis, it is estimated that up to 75% of the human genome is transcribed into RNAs. This finding prompted intensive investigations on the biological functions of non-coding RNAs and led to very exciting discoveries of microRNAs as important players in disease pathogenesis and therapeutic applications. Research on long non-coding RNAs (lncRNAs) is in its infancy, yet a broad spectrum of biological regulations has been attributed to lncRNAs. As a novel class of RNA transcripts, the expression level and splicing variants of lncRNAs are various. Northern blot analysis can help us learn about the identity, size, and abundance of lncRNAs. Here we describe how to use northern blot to determine lncRNA abundance and identify different splicing variants of a given lncRNA.

A Comprehensive Analysis of Northern versus Liquid Hybridization Assays for mRNAs, Small RNAs, and miRNAs Using a Non-Radiolabeled Approach.

Northern blotting (NB), a gold standard for RNA detection, has lost its charm due to its hands-on nature, need for good quality RNA, and radioactivity. With the emergence of the field of microRNAs (miRNAs), the necessity for sensitive and quantitative NBs has again emerged. Here, we developed highly sensitive yet non-radiolabeled, fast, economical NB, and liquid hybridization (LH) assays without radioactivity or specialized reagents like locked nucleic acid (LNA)- or digoxigenin-labeled probes for mRNAs/small RNAs, especially miRNAs using biotinylated probes. An improvised means of hybridizing oligo probes along with efficient transfer, cross-linking, and signal enhancement techniques was employed. Important caveats of each assay were elaborated upon, especially issues related to probe biotinylation, use of exonuclease, and bioimagers not reported earlier. We demonstrate that, while the NBs were sensitive for mRNAs and small RNAs, our LH protocol could efficiently detect these and miRNAs using less than 10-100 times the total amount of RNA, a sensitivity comparable to radiolabeled probes. Compared to NBs, LH was a faster, more sensitive, and specific approach for mRNA/small RNA/miRNA detection. A comparison of present work with six seminal studies is presented along with detailed protocols for easy reproducibility. Overall, our study provides effective platforms to study large and small RNAs in a sensitive, efficient, and cost-effective manner.

Analysis of Queuosine tRNA Modification Using APB Northern Blot Assay.

Queuosine (Q) is a hypermodified base that occurs at the wobble position of transfer RNAs (tRNAs) with a GUN anticodon. Q-tRNA modification is widespread among eukaryotes, yet bacteria are the original source of Q. Eukaryotes acquire Q from their diet, or from the gut microbiota (in multicellular organisms). Despite decades of study, the detailed roles of Q-tRNA modification remain to be elucidated, especially regarding its specific mechanisms of action. Here, we describe a method for the fast and reliable detection of Q-tRNA modification levels in individual tRNAs using a few micrograms of total RNA as starting material. The methodology is based on the co-polymerization of boronic acid (N-acryloyl-3-aminophenylboronic acid (APB)) in polyacrylamide gels, and on the interplay between this derivative and free cis-diol groups of the tRNA. During electrophoresis, the cis-diol groups slow down the Q-modified tRNA, which then can be separated from unmodified tRNA and quantified using Northern blot analysis.

Empirical Validation of Overlapping Virus lncRNAs and Coding Transcripts by Northern Blot.

Viruses, like their metazoan hosts, have evolved to utilize intricate transcriptional mechanisms to generate a vast array of both coding and noncoding RNA transcripts. The resolution of specific noncoding RNA transcripts produced by viruses, particularly herpesviruses, presents a particularly difficult challenge due to their highly dense dsDNA genomes and their complex, overlapping, and context-dependent network of transcripts. While new long read sequencing platforms have facilitated the resolution of some noncoding transcripts from virus genomes, empirical molecular validation of transcripts from individual regions is essential. Herein, we demonstrate that the use of strand specific northern blots is essential for true validation of specific viral noncoding RNAs, and provide here a detailed molecular method for such an approach.