Abstract
The continuously growing interest in small regulatory RNA exploration is one of the important factors that have inspired the recent development of new high throughput techniques such as DNA microarrays or next generation sequencing. Each of these methods offers some significant advantages but at the same time each of them is expensive, laborious and challenging especially in terms of data analysis. Therefore, there is still a need to develop new analytical methods enabling the fast, simple and cost-effective examination of the complex RNA mixtures. Recently, increasing attention has been focused on the RNA degradome as a potential source of riboregulators. Accordingly, we attempted to employ a two-dimensional gel electrophoresis as a quick and uncomplicated method of profiling RNA degradome in plant or human cells. This technique has been successfully used in proteome analysis. However, its application in nucleic acids studies has been very limited. Here we demonstrate that two dimensional electrophoresis is a technique which allows one to quickly and cost-effectively identify and compare the profiles of 10–90 nucleotide long RNA accumulation in various cells and organs.
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Introduction
The maturation, quality control and turnover of all types of transcripts are inseparably connected with RNA degradation. It secures a balance between RNA synthesis and RNA decay and provides cell homeostasis. For fulfilling its role RNA degradation has to be confined to a specific set of molecules, those unnecessary at given conditions, dysfunctional, or defective. On the other hand the RNA molecules essential for proper cell functioning should stay intact. This appears to be accomplished by strict and complex control mechanisms. Another inherent feature of RNA degradation is its high efficiency, which often precludes the identification of any intermediary products [1]. A rapid removal of any redundant RNA fragments is clearly advantageous since they have a potential to interfere with gene expression pathways [2, 3]. However, there is accumulating evidence that the degradation of several types of mature RNAs (among them tRNA, rRNA and snoRNA) can yield stable intermediates [4–6]. What is more, it has been shown that at least some of these intermediates display regulatory functions [7, 8]. These findings promote further research of stable intermediates of RNA degradation. All together these intermediates collectively constitute the RNA degradome. In consequence, demand for new methods of RNA degradome analysis is still increasing. Certainly, numerous approaches used for non-coding RNA characterization can be employed for this purpose. They cover a variety of techniques including the cloning and sequencing of RNA or hybridization-based methods such as northern blot and microarrays [9]. At present, next generation sequencing appears to prevail as the method of choice due to the great potential offered by available platforms [10]. Unfortunately, massive sequencing methods are laborious and expensive. They are perfect for a very detailed analysis of RNA degradome but too sophisticated for fast screening or comparison of several RNA degradomes. The latter can be done with DNA microarrays, provided that either all components of examined RNA degradomes were earlier cloned and sequenced or tiling microarrays covering the whole genome are available. Here we showed that two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) can be employed for analyzing high copy number RNA degradants isolated from plant and human cells. The collected data indicate that one can use 2D-PAGE to determine whether and to what extent the pattern of RNA degradant accumulation is tissue- or cell-specific. What is also important, the described method is relatively simple, quick and cost-effective. It seems that 2D-PAGE can also be used instead of one-dimensional electrophoresis to facilitate the fractionation of RNA degradome for more profound sequencing studies.
Materials and methods
Plants growth
Arabidopsis thaliana (ecotype Columbia-0) were grown in peat-filled pots at 22°C during the day and 20°C at night in a 8/16 h light/dark photoperiod [11]. Leaf and root samples collected from 5-week-old plants were immediately frozen in liquid nitrogen and stored at −80°C. Lupinus luteus L. cv. Ventus were grown in perlite-filled pots at 24/26°C during the day and 21/23°C at night in a 16/8 h light/dark photoperiod. A detailed description of growth conditions, lupin Bradyrhizobium inoculation and medium contents was previously published by Strozycki and coworkers [12, 13]. Non-infected, ~5 cm long lupine roots were collected 9 days after germination. Symbiotic nodules were collected from lupine roots 9 days post-infection with Bradyrhizobium. Both root and nodule samples were immediately frozen in liquid nitrogen and stored at −80°C.
HeLa and HL60 cell line cultivation
HeLa cells were cultured at 37°C with 5% CO2 in Dulbecco’s modified Eagle medium (DMEM) (Gibco) supplemented with 10% fetal bovine serum (Sigma) and gentamycin (100 μg/ml). Cells were harvested in the logarithmic growth phase by trypsin/EDTA treatment and counted using Coulter Counter. They were then centrifuged, washed with PBS, immediately frozen in liquid nitrogen (106 cells per tube) and stored at −80°C. HL60 cells were cultured at 37°C with 5% CO2 in RPMI 1640 medium (Gibco) supplemented with 10% fetal bovine serum (Sigma) and gentamycin (100 μg/ml). Cells were harvested in the logarithmic growth phase and counted using Coulter Counter, then centrifuged, washed with PBS, immediately frozen in liquid nitrogen (106 cells per tube) and stored at −80°C.
RNA extraction
RNA samples enriched in molecules shorter than 200 nt were isolated from (i) A. thaliana leaves, (ii) L. luteus roots and nodules, and (iii) HeLa or HL60 cells using the mirVana miRNA Isolation Kit (Ambion). Subsequently, 1 μg of RNA was labeled with γ 32P ATP using T4 PNK Kinase (Fermentas) and subjected to electrophoresis in polyacrylamide gel.
2D-PAGE of small RNAs
2D-PAGE was performed under: non-denaturing conditions (without urea), semi-denaturing conditions (4 M urea) or denaturing conditions (7 M urea). With minor modifications, we followed the procedure elaborated by Fradin et al. [14] (see also Online Resource Fig. 1). A 10% polyacrylamide gel (10% of acrylamide:bisacrylamide 19:1 solution; 1× buffer TBE pH = 8.3; 0/4/7 M urea, respectively; 0.1% APS; 0.1% TEMED) was used for first dimension electrophoresis (1D-PAGE). The size of the gel was 60 × 30 × 0.04 cm. 1D-PAGE was performed in 1× TBE buffer (pH = 8.3) at 300 V for 24–28 h at room temperature. A ~25 × 2.5 cm gel slice containing RNAs ranging in size between ~12 and ~120 nt was cut out from the gel (the length of RNA molecules was estimated based on the location of bromophenol blue and xylene cyanol), placed between new electrophoresis glasses, parallel to their shorter edge, and embedded in a freshly prepared 10% polyacrylamide gel (up to ~1 cm below the slice). The remaining space between electrophoresis glass plates was filled with a freshly prepared 20% polyacrylamide gel (20% of acrylamide:bisacrylamide 19:1 solution; 1× buffer TBE pH = 8.3; 0/4/7 M urea, respectively; 0.1% APS; 0.1% TEMED). The size of the 2D gel was as follows: 40 × 30 × 0.04 cm. Second dimension electrophoresis was performed at 500 V for 23–24 h at room temperature. The gel was exposed to a phosphor screen which was subsequently scanned by a Fuji FLA-5100 imaging system.
Cloning of RNA extracted from a gel
After 2D-PAGE, RNA molecules accumulating to highest levels were visualized by autoradiography. Selected spots were excised from the gel, gel fragments were collected in one tube, and RNA was eluted (overnight in 0.3 NaCl). Gel extracted RNA was precipitated with ethanol and used for cDNA library construction (see also Online Resource Fig. 2).
A cDNA library of small RNAs was prepared based on the protocols elaborated earlier by Lau et al. [15], Chappell et al. [16] and Lee and Ambros [17]. The following adapter and primers were used for RNA cloning: 3′ End Donor Oligo (available from IDT Inc.—miRNA cloning linker) 5′-AppCTGTAGGCACCATCAddA-3′, 3′ RT/PCR Primer 5′-ATTGATGGTGCCTAC-3′, 5′ RT/PCR Primer 5′-ATCGTAGGCACCTGAAAGGG-3′. Gel purified RNAs were ligated with a 3′ End Donor oligonucleotide. The latter contains the BanI restriction site, has a blocked 3′-hydroxyl terminus (with dideoxyA) and a pre-activated 5′ terminus (by 5′–5′ diphosphate A addition—5′ adenylation). The ligation was performed using T4 RNA ligase (Promega) in the absence of ATP. Ligation products were separated in a 10% denaturing polyacrylamide gel (to remove the excess of the 3′-adapter) and eluted from the gel overnight in 0.3 M NaCl at 4°C. Eluted RNA was precipitated with ethanol, dissolved in RNase-free water and subjected to reverse transcription. The reverse transcription reaction was performed using Superscript II Reverse Transcriptase (Invitrogen) and 3′RT/PCR primer. This enzyme displays terminal transferase activity and adds three C residues at the 3′ end of the newly synthesized cDNA. For the synthesis of the second strand (carried out in the same tube) and consecutive PCR amplification the primer with three G at the 3′ end and the BanI restriction site (5′RT/PCR primer) was used. The final RT-PCR products were purified (by phenol–chloroform extraction), digested with BanI and subsequently concatamerized using T4 DNA ligase (Promega). The gel-purified concatamers (low melting point agarose) were ligated into TOPO-TA cloning vector. TOP10 electrocompetent cells were transformed with the ligation products and grown on a selective medium. Plasmids containing inserts were isolated from the individual colonies and sequenced using ABI PRISM 310 Genetic Analyzer.
The sequences of short RNAs extracted from gel were determined and their precursor RNA molecules were identified by a BLAST search against A. thaliana genome in the NCBI database (http://www.ncbi.nih.gov/BLAST/).
Results
The first step of our studies focused on 2D-PAGE optimization to ensure the best separation of short RNA molecules. To this end, we designed four RNA oligonucleotides named Oligo1–4. All of them were 40 nt long but they differed in sequence, molecular mass, or secondary structure (Fig. 1). Oligo-1 had the highest molecular mass and was composed of 20 G and 20 A. Oligo-3, with the lowest molecular mass contained 8 A and 32 C. Oligo-2 and Oligo-4 were composed of the same nucleotides: 10 G, 10 C, 20 A. They had the same molecular mass but their sequences were different. As a result, Oligo-2 did not form any stable secondary structure at 37°C (similarly to Oligo-1 and Oligo-3) while Oligo-4 adopted a stable hairpin structure at the same temperature. All four oligonucleotides were labeled with 32P at the 5′-end, mixed in equimolar concentration, and subjected to 2D-PAGE under various conditions (in native, semi-denaturing and denaturing gels). The chemically synthesized oligonucleotides were not gel-purified post synthesis, neither prior- nor post-labeling with 32P. As a result, the main product (40 nt oligonucleotide) was always accompanied by a small amount of shorter oligonucleotides. The latter could be observed during 2D-PAGE experiments. In this way we could better estimate the efficiency of RNA separation under different conditions.
The undertaken experiments demonstrated that 2D-PAGE can be used for the analysis of short RNA molecules even if their length or molecular mass is quite similar. As it could be expected, the obtained pattern of RNA separation strongly depended on the applied conditions. In all cases, oligonucleotides of different molecular mass were well separated by 1D- and 2D-PAGE (Fig. 2). The application of native gel for electrophoresis in the first or second dimension permitted us to distinguish among oligonucleotides with the same molecular mass but different secondary structures.
In the next series of experiments we attempted to determine whether 2D-PAGE enables an effective analysis of complex mixtures containing short RNA molecules. Taking into account the above observations we used three combinations of gels: native/denaturing, denaturing/native and semi-denaturing/semi-denaturing. The fraction of RNA enriched in molecules shorter than 200 nt was isolated from leaves of A. thaliana. After 5′-labelling with 32P (exchange reaction) the RNA samples were subjected to 2D-PAGE. The obtained patterns of separation were markedly different and highly reproducible (Fig. 3). In contrast to the results obtained for Oligo1-4, 2D electrophoresis in native/denaturing and denaturing/native gels did not produce expected highly resolved autoradiograms (Fig. 3a, c). Instead, the gels contained a small number of well-defined spots. The other spots were poorly split and often fuzzy. The analyzed mixtures of short RNAs were best separated when semi-denaturing gels were applied for electrophoresis in both dimensions. In the corresponding autoradiograms the highest number of well separated spots was detected (Fig. 3b).
The data presented above suggested that 2D-PAGE can be used for the analysis of complex mixtures composed of short RNA molecules. Unfortunately, we did not know whether the observed RNAs were indeed the products of degradation. Recent studies indicated that the fraction of RNA between 30 and 80 nt can be especially rich in this type of molecules (longer than siRNA/miRNA and shorter than tRNA) [4, 6, 18–25]. Accordingly, we attempted to determine the nature of the selected RNA visualized in 2D gels. The RNAs extracted from the 20 most intense spots (Fig. 3b) were mixed together and amplified by RT-PCR. The obtained cDNA was concatamerized, cloned and sequenced. The sequencing of 150 clones let us to identify 20 RNAs. Their length ranged from 19 to 86 nt but half of them (10) were 28–38 nt long. A computational analysis involving A. thaliana genome database revealed that the majority of the sequenced cDNA clones (19) represented the products of tRNA (9), rRNA (8), mRNA (1) and snRNA (1) degradation (Table 1). One molecule was classified as an unknown transcript of the intergenic region. Several mismatches to the A. thaliana genomic sequence were detected during BLAST search. Since they appeared only in tRNA-derivatives, it is highly plausible that these mismatches reflect modified bases in tRNA.
Finally, we tried to determine whether 2D-PAGE can be used to identify specific profiles of RNA degradation in various cells/tissues/organs or in the same type of cells/tissues/organs but growing in different conditions. For this purpose, fractions of RNA enriched in molecules shorter than 200 nt were extracted from different plant organs and from human cell lines and subjected to 2D-PAGE under semi-denaturing conditions.
The exemplary autoradiograms presented in Figs. 3, 4 and 5 suggest that the generated patterns of RNA degradant accumulation are cell- or organo-specific. In Fig. 4 we compared RNA extracted from L. luteus roots (Fig. 4a) and from young nodules forming on L. luteus roots infected with symbiotic bacteria (Fig. 4b). In Fig. 5 RNA isolated from HeLa and HL60 cell lines were compared. In both cases significant qualitative and quantitative differences in individual RNA accumulation were observed. In general, the obtained results indicate that 2D-PAGE is a very effective fast and cheap technique that can be applied for the analysis of high copy number RNA degradants. It can be an interesting alternative to other classic techniques such as northern blot hybridization or standard sequencing.
Discussion
Although developed over 30 years ago and successfully applied for fractionation of tRNA and structural analysis of viral RNA [14, 26–29] the 2D-PAGE technique had not found many applications in RNA-related areas. Recently it has been shown that this method is suitable for the analysis of oligonucleotide mixtures [9, 30, 31]. In this study, we demonstrated that 2D-PAGE can be successfully applied for analyzing RNA degradants ranging in size from ~10 to ~90 nt.
The experiments carried out in distinct electrophoretic conditions revealed that 2D-PAGE enables an effective fractionation of RNA molecules even if they have the same length but different base composition or secondary structure. Our results indicate that the application of native gels in the first or second dimension is the best choice for analyzing a limited number of small-sized RNA molecules. We also observed that 2D-PAGE under semi-denaturing/semi-denaturing conditions is the best option if one wishes to examine very complex and diversified pools of RNA extracted from cells/tissues/organs. The electrophoresis in native gels preserves the intra- and intermolecular interactions. As a result, the analyzed RNAs are not well resolved because they can adopt various conformations or form multimolecular complexes. In contrast, under semi-denaturing conditions only very stable structures can be preserved. As a result the majority of RNA molecules migrate as individual well-separated spots.
Recently, it has been shown that some of RNA degradation intermediates can accumulate in cells instead of being hydrolyzed to single nucleotides [4, 6, 18–25]. Accordingly, we hypothesized that a large fraction of RNA molecules observed in 2D gels (especially, molecules shorter than tRNAs and longer than miRNAs) might be products of RNA degradation. Cloning and sequencing of RNAs extracted from the most intensive spots confirmed our assumption. It turned out that out of 20 analyzed RNAs, 19 could be classified as degradants. They were identified as fragments of tRNA, rRNA, mRNA and snRNA. The obtained results also suggest that the composition of RNA degradome can be cell/tissue/organo-specific. It seems that the profiling of RNA degradant accumulation can provide some information about physiological or pathological processes occurring in examined cells or organisms. Therefore, RNA degradome components could be considered as potential biomarkers in monitoring developmental processes, stress responses, or host–pathogen interactions.
In general, it seems that 2D-PAGE is an effective tool for analyzing high copy number RNA degradants. The undertaken studies disclosed many advantages of this technique. It permits fast comparison of RNA degradomes isolated from cell lines, tissues or organs. Unlike northern blots or DNA microarrays it does not require sequencing of individual degradants prior to their analysis. In addition, it restricts the number of analyzed individuals to those accumulating to relatively high levels. 2D-PAGE also allows us to quickly monitor changes occurring in RNA degradome under the influence of endogenous or exogenous factors. Finally, this method can be used to identify novel classes of small RNAs analogous to the already found sno-derived RNA degradants [5] or tRNA-derived RNA degradants [8, 32].
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Acknowledgments
This work was supported by the Polish Government through a grant from the Ministry of Science and Higher Education [PBZ-MNiI-2/1/2005 to M.F.]. The authors would like to thank Dr. Zbigniew Michalski and Justyna Serba for their excellent technical assistance.
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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Nowacka, M., Jackowiak, P., Rybarczyk, A. et al. 2D-PAGE as an effective method of RNA degradome analysis. Mol Biol Rep 39, 139–146 (2012). https://doi.org/10.1007/s11033-011-0718-1
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DOI: https://doi.org/10.1007/s11033-011-0718-1