m6A-label-seq: A metabolic labeling protocol to detect transcriptome-wide mRNA N6-methyladenosine (m6A) at base resolution

An RNA Methylation-Sensitive AIEgen-Aptamer Reporting System for Quantitatively Evaluating m6A Methylase and Demethylase Activities

N6-Methyladenosine (m6A) chemical modification determines the fate of the mammalian cellular mRNA to modulate crucial physiological and pathological processes. Dysregulations of m6A methylase and demethylase have been linked to cancer diseases. Therefore, evaluations of enzyme mutants' activities and related inhibitors for discovery of targeted therapeutic strategies are very necessary. Here, we report an RNA methylation-sensitive fluorescent aptamer reporting assay to measure the catalytic activities of m6A enzymes under various conditions. The rationale is that when an RNA aptamer, named A-Pepper, is methylated at a specific adenosine position to generate m6A-Pepper, the latter displays stronger fluorescence than the former upon binding the ligand, which is an aggregation-induced emission-active luminogen. The fluorescence signal enhancement is linearly proportional to the RNA methylation extent, which is equivalent to the methylase activity. On the contrary, the m6A demethylase activity is measured through calculating the fluorescence signal decrease caused by the switching from m6A-Pepper to A-Pepper. The assay has been successfully applied to quantitatively evaluate the mutation and inhibitor effects on the activities of m6A methylases METTL3/METTL14 and demethylase FTO, and the obtained results are well-consistent with those quantified by the expensive and time-consuming golden standard LC-MS/MS. Our work provides a simple tool capable of detecting m6A enzymes' activities and screening their inhibitors in a rapid, quantitative, cost-effective, and high-throughput manner.

Analysis approaches for the identification and prediction of N6-methyladenosine sites

The global dynamics in a variety of biological processes can be revealed by mapping transcriptional m⁶A sites, in particular full-transcriptome m⁶A. And individual m⁶A sites have contributed to biological function, which can be evaluated by stoichiometric information obtained from the single nucleotide resolution. Currently, the identification of m⁶A sites is mainly carried out by experiment and prediction methods, based on high-throughput sequencing and machine learning model respectively. This review summarizes the recent topics and progress made in bioinformatics methods of deciphering the m⁶A methylation, including the experimental detection of m⁶A methylation sites, techniques of data analysis, the way of predicting m⁶A methylation sites, m⁶A methylation databases, and detection of m⁶A modification in circRNA. At the end, the essay makes a brief discussion for the development perspective in this area.

MePMe-seq: antibody-free simultaneous m6A and m5C mapping in mRNA by metabolic propargyl labeling and sequencing

Internal modifications of mRNA have emerged as widespread and versatile regulatory mechanism to control gene expression at the post-transcriptional level. Most of these modifications are methyl groups, making S-adenosyl-L-methionine (SAM) a central metabolic hub. Here we show that metabolic labeling with a clickable metabolic precursor of SAM, propargyl-selenohomocysteine (PSH), enables detection and identification of various methylation sites. Propargylated A, C, and G nucleosides form at detectable amounts via intracellular generation of the corresponding SAM analogue. Integration into next generation sequencing enables mapping of N6-methyladenosine (m6A) and 5-methylcytidine (m5C) sites in mRNA with single nucleotide precision (MePMe-seq). Analysis of the termination profiles can be used to distinguish m6A from 2'-O-methyladenosine (Am) and N1-methyladenosine (m1A) sites. MePMe-seq overcomes the problems of antibodies for enrichment and sequence-motifs for evaluation, which was limiting previous methodologies. Metabolic labeling via clickable SAM facilitates the joint evaluation of methylation sites in RNA and potentially DNA and proteins.

From form to function: m6A methylation links mRNA structure to metabolism

Reversible N6-methyladenosine (m6A) RNA modification is a posttranscriptional epigenetic modification of the RNA that regulates many key aspects of RNA metabolism and function. In this review, we highlight major recent advances in the field, with special emphasis on the potential link between m6A modifications and RNA structure. We will also discuss the role of RNA methylation of neuronal transcripts, and the emerging evidence of a potential role in RNA transport and local translation in dendrites and axons of transcripts involved in synaptic functions and axon growth.

m6A RNA modifications: Key regulators of normal and malignant hematopoiesis

Post-transcriptional RNA modifications determine RNA fate by influencing numerous processes such as translation, decay and localization. One of the most abundant RNA modifications is N6-methyladenoside (m6A), which has been shown to be important in healthy as well as malignant hematopoiesis. Several proteins representing key players in m6A RNA biology, such as m6A writers, erasers and readers, were recently reported to be essential for hematopoietic stem cell (HSC) function. In leukemia, expression of m6A regulators has been shown to be increased, opening up potential opportunities for therapeutic exploitation by targeting them in blood malignancies. These recent discoveries were the focus of the Fall 2021 International Society for Experimental Hematology New Investigators webinar. We review here the latest findings in the field of mRNA modifications in normal and malignant hematopoiesis and how this might open up novel therapeutic options.

New Chromatin Run-On Reaction Enables Global Mapping of Active RNA Polymerase Locations in an Enrichment-free Manner

The development of a simple and cost-effective method to map the distribution of RNA polymerase II (RNPII) genome-wide at a high resolution is highly beneficial to study cellular transcriptional activity. Here we report a mutation-based and enrichment-free global chromatin run-on sequencing (mGRO-seq) technique to locate active RNPII sites genome-wide at near-base resolution. An adenosine triphosphate (ATP) analog named N⁶-allyladenosine triphosphate (a⁶ATP) was designed and could be incorporated into nascent RNAs at RNPII-located positions during a chromatin run-on reaction. By treatment of the run-on RNAs with a mild iodination reaction and subjection of the products to reverse transcription into complementary DNA (cDNA), base mismatch occurs at the original a⁶A incorporation sites, thus making the RNPII locations detected in the high-throughput cDNA sequencing. The mGRO-seq yields both the map of RNPII sites and the chromatin RNA abundance and holds great promise for the study of single-cell transcriptional activity.

Targeted Manipulation of Cellular RNA m6A Methylation at the Single-Base Level

Development of tools for precise manipulation of cellular mRNA m6A methylation at the base level is highly required. Here, we report an RNA-guided RNA modification strategy using a fusion protein containing deactivated nuclease Cas13b and m6A methyltransferase METTL14, namely, dCas13b-M14, which is designedly positioned in the cytoplasm. dCas13b-M14 naturally heterodimerizes with endogenous METTL3 to form a catalytic complex to methylate specific cytoplasmic mRNA under a guide RNA (gRNA). We developed assays to screen and validate the guiding specificity of varied gRNAs at single-base resolution. With an optimum combination of dCas13b-M14 and gRNAs inside cells, we have successfully tuned methylation levels of several selected mRNA m6A sites. The off-target effect was evaluated by whole transcriptome m6A sequencing, and a very minor perturbation on the methylome was revealed. Finally, we successfully utilized the editing tool to achieve de novo methylations on five selected mRNA sites. Together, this study paves the way for studying position-dependent roles of m6A methylation in a particular transcript.