Unmethylated RNA Research Articles

Ligation-driven hyperbranched DNA assembly for label-free and sequence-specific measurement of RNA N6-methyladenosine in human breast tissues

N6-methyladenosine (m6A) is a critical post-transcriptional regulator, and it is linked to various biological functions (e.g., degradation, export, and translation) and multiple human diseases (e.g., cancers, immune disorders, and neurodegenerative diseases). The current methods for sequence-specific detection of m6A usually suffer from radioactive risk, large sample consumption, washing/separation steps, and false-positive signal. Herein, we develop a ligation-driven hyperbranched DNA assembly-based fluorescent biosensor for label-free and sequence-specific detection of m6A. In this assay, the unmethylated RNA can be identified and cleaved by m6A-sensitive endoribonuclease MazF. The retained intact m6A-RNA is complementary to the padlock probe to form a circular DNA, subsequently initiating ligation-driven hyperbranched rolling circle amplification (HRCA). The obtained HRCA products can be simply quantified with SYBR Gold as a fluorescent indicator. This method can be homogeneously carried out in an isothermal, label-free and antibody-free manner. The limit of detection can reach 0.079 pM. Moreover, this method can differentiate even 0.01 % m6A level in excess coexisting interferences, monitor cellular m6A RNA level with single-cell sensitivity, and differentiate m6A level in breast tumor tissues and normal adjacent tissues, with promising applications in m6A-releated epigenetic research and clinical diagnosis.

PBOX-sRNA-seq uncovers novel features of miRNA modification and identifies selected 5'-tRNA fragments bearing 2'-O-modification.

The concomitant cloning of RNA degradation products is a major concern in standard small RNA-sequencing practices. This not only complicates the characterization of bona fide sRNAs but also hampers cross-batch experimental replicability and sometimes even results in library construction failure. Given that all types of plant canonical small RNAs possess the 3' end 2'-O-methylation modification, a new small RNA sequencing (sRNA-seq) method, designated as PBOX-sRNA-seq, has been developed specifically to capture this modification. PBOX-sRNA-seq, as its name implies, relies on the sequential treatment of RNA samples with phenylboronic acid-polyacrylamide gel electrophoresis (PBA-PAGE) and sodium periodate (NaIO4) oxidation, before sRNA library construction and sequencing. PBOX-sRNA-seq outperformed separate treatments (i.e. PBA-PAGE only or NaIO4 only) in terms of the depletion of unmethylated RNA species and capture 2'-O-modified sRNAs with extra-high purity. Using PBOX-sRNA-seq, we discovered that nascent miRNA-5p/-3p duplexes may undergo mono-cytidylation/uridylation before 2'-O-methylation. We also identified two highly conserved types of 5'-tRNA fragments (tRF) bearing HEN1-independent 2'-O modification (mainly the 13-nt tRF-5aAla and the 26-nt tRF-5bGly). We believe that PBOX-sRNA-seq is powerful for both qualitative and quantitative analyses of sRNAs in plants and piRNAs in animals.

In vitro selection of N 1-methyladenosine-sensitive RNA-cleaving deoxyribozymes with 105-fold selectivity over unmethylated RNA.

RNA-cleaving DNAzymes (RCDs) are catalytically active DNA molecules that cleave a wide range of RNA targets with extremely high sequence-selectivity, but none is able to faithfully discriminate methylated from unmethylated RNA (typically <30-fold). We report the first efforts to isolate RCDs from a random-sequence DNA pool by in vitro selection that cleave RNA/DNA chimera containing N 1-methyladenosine (m1A), one of the most prevalent RNA modifications that plays important regulatory roles in gene expression and human cancers. A cis-acting deoxyribozyme, RCD1-S2m1A, exhibits an observed rate constant (k obs) of 5.3 × 10-2 min-1, resulting in up to 105-fold faster cleavage of the m1A-modified versus unmethylated RNA. Furthermore, a trans-acting fluorogenic deoxyribozyme was constructed by labeling a fluorophore and a quencher at the 5' and 3' ends of the chimeric substrate, respectively. It permits the synchronization of RNA-cleaving with real-time fluorescence signaling, thus allowing the selective monitoring of ALKBH3-mediated demethylation and inhibitor screening in living cells.

Antibody-free photoelectrochemical strategy for simultaneous detection of methylated RNA, METTL3/METTL14 protein and MazF protein based on enhanced photoactivity of MoSe2–BiOI nanocomposite

Taking advantages of the catalytic activity of METTL3/METTL14 protein towards adenine methylation in RNA sequence and the specific digestion activity of MazF protein towards unmethylated RNA sequence containing ACA bases, a novel photoelectrochemical biosensor was constructed for simultaneous detection of RNA methylation, METTL3/METTL14 protein and MazF protein. MoSe2–BiOI nanocomposite was prepared and considered as photoactive material, catalytic hairpin assembly strategy and in situ generation of electron donors catalyzed by polyaspartic acid-loaded alkaline phosphatase technique were employed as signal amplification. Under the optimum conditions, the detection ranges of methylated RNA, METTL3/METTL14 protein and MazF protein were 0.001–50 nM, 0.001–25 ng/μL, and 0.001–10 U/mL, respectively. The corresponding detection limits were 0.46 pM, 0.51 pg/μL and 0.42 U/μL with S/N = 3. In addition, the effect of drugs and composite pollutants on the activities of MazF proteins was assessed, proving the applicability of the developed method in the field of drug screening for MazF-related diseases. Moreover, the effects of pollutants on the activity of METTL3/METTL14 were also preliminarily explored, providing new information on pathogenic mechanism of pollutants.

RBM45 is an m6A-binding protein that affects neuronal differentiation and the splicing of a subset of mRNAs.

SUMMARYN6-methyladenosine (m6A) is deposited co-transcriptionally on thousands of cellular mRNAs and plays important roles in mRNA processing and cellular function. m6A is particularly abundant within the brain and is critical for neurodevelopment. However, the mechanisms through which m6A contributes to brain development are incompletely understood. RBM45 acts as an m6A-binding protein that is highly expressed during neurodevelopment. We find that RBM45 binds to thousands of cellular RNAs, predominantly within intronic regions. Rbm45 depletion disrupts the constitutive splicing of a subset of target pre-mRNAs, leading to altered mRNA and protein levels through both m6A-dependent and m6A-independent mechanisms. Finally, we find that RBM45 is necessary for neuroblastoma cell differentiation and that its depletion impacts the expression of genes involved in several neurodevelopmental signaling pathways. Altogether, our findings show a role for RBM45 in controlling mRNA processing and neuronal differentiation, mediated in part by the recognition of methylated RNA.

Quantification of methylation efficiency at a specific N6-methyladenosine position in rRNA by using BNA probes.

We found that insertion of artificial nucleic acid analogs, such as bridged nucleic acid (BNA), into DNA probes increases the difference in melting temperature between N6-methyladenosine (m6A)-containing RNA and unmethylated RNA. By applying this principle, we quantified methylation efficiency at m6A sites in E. coli 23S rRNA with high accuracy.

MRNA Capping Enzyme Requirement forCaenorhabditis elegans Viability

Capping of the initiated 5' ends of RNA polymerase II products is evolutionarily and functionally conserved from yeasts to humans. The m(7)GpppN cap promotes RNA stability, processing, transport, and translation. Deletion of capping enzymes in yeasts was shown to be lethal due to rapid exonucleolytic degradation of uncapped transcripts or failure of capped but unmethylated RNA to initiate protein synthesis. Using RNA interference and Caenorhabditis elegans we have found that RNA capping is also essential for metazoan viability. C. elegans bifunctional capping enzyme was cloned, and capping activity by the expressed protein as well as growth complementation of yeast deletion strains missing either RNA triphosphatase or guanylyltransferase required terminal sequences not present in the previously isolated cel-1 clone. By RNA interference analysis we show that cel-1 is required for embryogenesis. cel-1(RNAi) embryos formed cytoplasmic granules characteristic of a phenocluster of RNA processing genes and died early in development.

Internal ribosome entry site within hepatitis C virus RNA.

The mechanism of initiation of translation on hepatitis C virus (HCV) RNA was investigated in vitro. HCV RNA was transcribed from the cDNA that corresponded to nucleotide positions 9 to 1772 of the genome by using phage T7 RNA polymerase. Both capped and uncapped RNAs thus transcribed were active as mRNAs in a cell-free protein synthesis system with lysates prepared from HeLa S3 cells or rabbit reticulocytes, and the translation products were detected by anti-gp35 antibodies. The data indicate that protein synthesis starts at the fourth AUG, which was the initiator AUG at position 333 of the HCV RNA used in this study. Efficiency of translation of the capped methylated RNA appeared to be similar to that of the capped unmethylated RNA. However, a capped methylated RNA showed a much higher activity as mRNA than did the capped unmethylated RNA in rabbit reticulocyte lysates when the RNA lacked a nucleotide sequence upstream of position 267. The results strongly suggest that HCV RNA carries an internal ribosome entry site (IRES). Artificial mono- and dicistronic mRNAs were prepared and used to identify the region that carried the IRES. The results indicate that the sequence between nucleotide positions 101 and 332 in the 5' untranslated region of HCV RNA plays an important role in efficient translation. Our data suggest that the IRES resides in this region of the RNA. Furthermore, an IRES in the group II HCV RNA was found to be more efficient than that in the group I HCV RNA.

Mono- and dimethylating activities and kinetic studies of the ermC 23 S rRNA methyltransferase

The ermC 23 S rRNA methyltransferase converts a single adenine residue to N6,N6-dimethyladenine, both in vivo and in vitro. The ermC methyltransferase was demonstrated to produce both N6-mono and N6,N6-dimethylated adenine residues in Bacillus subtilis 23 S rRNA during the course of the reaction in vitro. An almost total conversion of monomethylated intermediates into dimethylated products was observed upon completion of the reaction. Data presented here demonstrate that the addition of the two methyl groups to each 23 S rRNA molecule takes place through a monomethylated intermediate and suggest that the enzyme dissociates from its RNA substrate between the two consecutive methylation reactions. The enzyme is able to utilize monomethylated RNA as substrate for the addition of a second methyl group with an efficiency approximately comparable to that obtained when unmethylated RNA was the initial substrate. Initial-rate data and inhibition studies suggest that the ermC methylase reaction involves a sequential mechanism occurring by two consecutive Random Bi Bi reactions.

Characteristics of a Coupled Cell‐Free Transcription and Translation System Directed by Vaccinia Cores

1. A coupled transcription and translation system is described in which protein synthesis is directed by mRNA synthesised in situ by vaccinia virus cores. The cell-free system is based on a micrococcal-nuclease-treated reticulocyte lysate. 2. The polypeptides made in vitro include many authentic early vaccinia proteins, but also other proteins which were not detected in infected cells. 3. Concentrations of cores which inhibit host cell protein synthesis in vivo caused a delayed inhibition of translation in vitro; this was partly, but not entirely, due to dsRNA associated with the cores. 4. The mRNA made was methylated by core enzymes. Inhibition of methylation reduced the rate of translation tenfold; unmethylated RNA bound ribosomes poorly, but was nevertheless translated faithfully.

Identification of features in 5′ terminal fragments from reovirus mRNA which are important for ribosome binding

Four types of experiments were carried out with reovirus messenger RNAs or with 5′ terminal fragments of known sequence to identify features in mRNA which appear to be important for formation of initiation complexes with ribosomes. With a number of reovirus mRNAs, 40S initiation complexes had been previously shown to protect a significantly larger segment of the RNA (including the 5′ terminal m7G) than that protected by 80S initiation complexes. Each 80S-protected sequence had an AUG codon and was a subset of the 40S-protected sequence from the same message. When 40S- and 80S-protected fragments were tested for ability to rebind to ribosomes, the 80S-protected fragments showed considerably lower binding ability, implying that the “extra” sequences protected by 40S initiation complexes contribute to ribosome attachment. Nevertheless, wheat germ ribosomes select the same 5′ terminal initiation site in each reovirus mRNA, irrespective of the presence or absence of m7G on the message. This was demonstrated by comparing fingerprints of the ribosome-protected regions obtained with methylated versus unmethylated RNA. The contribution of m7G to formation of initiation complexes is therefore quantitative rather than qualitative. Limited T1 RNAase digestion of isolated 5′ terminal fragments from several reovirus messages generated a series of smaller fragments which were analyzed for ability to rebind to ribosomes. Partial digestion products up to 30 nucleotides in length which retained the 5′ cap but not the AUG codon were unable to associate stably with ribosomes, whereas every AUG-containing fragment that was analyzed was able to form initiation complexes. The efficiency of binding of certain AUG-containing fragments, however, was reduced by removal of either the 5′ terminal region, including the cap, or of sequences comprising the beginning of the coding region, on the 3′ side of the AUG. Complex formation between messenger RNA and ribosomes was inhibited by the trinucleotide AUG, but not by various other oligonucleotides. Although the inhibition was specific, a vast excess of trinucleotide was required for moderate inhibition of 80S complex formation, and the same concentration of AUG failed to inhibit formation of 40S initiation complexes.

High molecular weight virion-associated RNA of vaccinia. A possible precursor to 8 to 12 S mRNA.

The high molecular weight virion-associated RNA synthesized by vaccinia in vitro can be cleaved into smaller components, some of which are extruded from the virus as 8 to 12 S RNA. The high molecular weight virion-associated RNA fails to bind appreciably (5%) to poly(U) filters indicating that it is not polyadenylated. Its cleavage products will, however, bind to poly(U) (40 to 50%) after processing in the presence of ATP. The high molecular weight virion-associated RNA is methylated by the virus, and purified unmethylated RNA can be methylated by detergent-solubilized extracts of vaccinia virus cores. In the presence of GTP, methylation is stimulated 3-fold. The level of methylation of purified unmethylated high molecular weight RNA achieved by soluble core extracts is approximately 80% of the level of methylation achieved with purified unmethylated 8 to 12 S viral RNA, suggesting that more residues than the primary 5' termini became methylated. Approximately 85% of the methylated RNA binds to poly(U) when purified high molecular weight RNA is processed with soluble core extracts in the presence of S-adenosyl[methyl-3H]methionine, GTP, and ATP, conditions which also cleave the RNA. Nucleic acid hybridization-competition studies indicate that virion-extruded 8 to 12 S mRNA contains sequences found in the high molecular weight virion-associated RNA.

The effect of 5-bromodeoxyuridine on chick embryo limb bud mesenchyme in organ culture

The thymidine analogue 5-bromodeoxyuridine (BrdU) prevents chondrogenesis in organ cultures of limb bud mesenchyme of 3 1 2 day chick embryos. The biologically active levels of BrdU inhibit both DNA and RNA synthesis, but the synthesis of methylated RNA is inhibited less than that of unmethylated RNA. If cell division is partially synchronized the ratio of incorporation of BrdU to thymidine is greater during the first few minutes of the S period than for unsynchronized cells. The results suggest that BrdU may be preferentially incorporated into the starting points of replicons and that this may affect subsequent transcription necessary for chondrogenesis.

The behaviour of heterogeneous nuclear ribonucleic acid in partially and completely denaturing conditions.

It is shown that the heterogeneous nuclear RNA (HnRNA) synthesized in the presence of actinomycin and at low and high temperatures sediments in low-ionic-strength sucrose gradients between the rRNA components, similar to the unmethylated RNA synthesized under ;step-down' conditions. If the ionic strength is increased then the HnRNA sediments more rapidly than 28S rRNA, with a large proportion about the 45S precursor rRNA position. Initially this was thought to be due to aggregation of the HnRNA; however, centrifugation and electrophoresis in completely denaturing conditions suggest that the molecular weight of this species of RNA is very large The experiments reveal that HnRNA is conformationally unstable relative to the nucleolar RNA and that the slower sedimentation rate of HnRNA in 5mm-EDTA-Tris base-sucrose gradients reflects the greater expansion of the HnRNA relative to the nucleolar RNA. The implications of this finding are discussed.