MirGeneDB 2.0: The metazoan microRNA complement

Fromm, Bastian; Domańska, Diana; Høye, Eirik; Ovchinnikov, Vladimir; Kang, Wenjing; Aparicio‐Puerta, Ernesto; Johansen, Morten; Flatmark, Kjersti; Mathelier, Anthony; Hovig, Eivind; Hackenberg, Michael; Friedländer, Marc R.; Peterson, Kevin J.

doi:10.1101/258749

Cited by 69 publications

(114 citation statements)

References 74 publications

(88 reference statements)

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“…Only three lines are mandatory: the mirGFF3 format version, the database used for annotation, and the sample name ( Figure 1A). The database line can point to any of the already published resources: miRBase [49], miRCarta [50], miRGeneDB [51], or a custom database.…”

Section: Resultsmentioning

confidence: 99%

Unification of miRNA and isomiR research: the mirGFF3 format and the mirtop API

Desvignes

Loher

Eilbeck

et al. 2018

Preprint

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Background:MicroRNAs (miRNAs) are small RNA molecules (~22 nucleotide long) involved in posttranscriptional gene regulation. Advances in high-throughput sequencing technologies led to the discovery of isomiRs, which are miRNA sequence variants. While many miRNA-seq analysis tools exist, a lack of consensus on miRNA/isomiR analyses exists, and the resulting diversity of output formats hinders accurate comparisons between tools and precludes data sharing and the development of common downstream analysis methods. Conclusions:Collectively a comprehensive isomiR categorization system, along with the accompanying mirGFF3 and mirtop API provide a complete solution for the standardization of miRNA and isomiR analysis, enabling data sharing, reporting, comparative analyses, and benchmarking, while promoting the development of common miRNA methods focusing on downstream steps to miRNA detection, annotation, and quantification.

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Section: Resultsmentioning

confidence: 99%

Unification of miRNA and isomiR research: the mirGFF3 format and the mirtop API

Desvignes

Loher

Eilbeck

et al. 2018

Preprint

Self Cite

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“…Adapters and random base linkers were removed with Cutadapt version 1.14 and trimmed FASTQ files were processed using both miRge and a miRBase v21 miRNA library and miRge 2.0 with a MirGeneDB library of miRNAs. [21][22][23][24] Using the more restrictive MirGeneDB dataset, we identified between 260 and 321 miRNAs for each sample. Setting the minimum threshold to 10 RPM for a given miRNA, the range was 236-285 miRNAs per sample, with 203 miRNAs consistently above 10 RPM.…”

Section: Xmd-mirna-seq Resultsmentioning

confidence: 99%

xMD-miRNA-seq to generate near in vivo miRNA expression estimates in colon epithelial cells

Rosenberg

Wright

Fox-Talbot

et al. 2018

Preprint

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Accurate, RNA-seq based, microRNA (miRNA) expression estimates from primary cells have recently been described. However, this in vitro data is mainly obtained from cell culture, which is known to alter cell maturity/differentiation status, significantly changing miRNA levels. What is needed is a robust method to obtain in vivo miRNA expression values directly from cells. We introduce expression microdissection miRNA small RNA sequencing (xMD-miRNA-seq), a method to isolate cells directly from formalin fixed paraffin-embedded (FFPE) tissues. xMD-miRNA-seq is a low-cost, high-throughput, immunohistochemistry-based method to capture any cell type of interest. As a proof-of-concept, we isolated colon epithelial cells from two specimens and performed low-input small RNA-seq. We generated up to 600,000 miRNA reads from the samples. Isolated epithelial cells, had abundant epithelialenriched miRNA expression (miR-192; miR-194; miR-200b; miR-200c; miR-215; miR-375) and overall similar miRNA expression patterns to other epithelial cell populations (colonic enteroids and flowisolated colon epithelium). xMD-derived epithelial cells were generally not contaminated by other adjacent cells of the colon as noted by t-SNE analysis. xMD-miRNA-seq allows for simple, economical, and efficient identification of cell-specific miRNA expression estimates. Further development will enhance rapid identification of cell-specific miRNA expression estimates in health and disease for nearly any cell type using archival FFPE material.

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“…We chose two evolutionary very distant organisms that are not known to interact with one another, do not share common miRNAs, but share a similar number of genes: Arabidopsis thaliana ( A. thaliana ) (thale cress) and Rattus norvegicus ( R. norvegicus ) (brown rat). For each of these organisms we chose 20 highly confident miRNAs, which were used for target prediction in a reciprocal manner (self‐miRNA vs self‐transcripts, and self‐miRNAs vs non‐self‐transcripts) (Figure A). The number of predicted targets of each miRNA was normalized to the number of nucleotides in the transcriptome of each dataset.…”

Section: The Majority Of Predicted Targets Are Falsementioning

confidence: 99%

“…The number of targets is presented as targets per mega base (targets per Mb). Rat miRNAs with high confidence were chosen from MirGeneDB2.0 . Arabidopsis highly confident miRNAs were chosen according to Axtell et al and Arribas‐Hernandez et al The data used for these analyses are available at https://figshare.com/s/7db0263cf3e3085443b6.…”

Section: The Majority Of Predicted Targets Are Falsementioning

confidence: 99%

Too Many False Targets for MicroRNAs: Challenges and Pitfalls in Prediction of miRNA Targets and Their Gene Ontology in Model and Non‐model Organisms

2019

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Short (“seed”) or extended base pairing between microRNAs (miRNAs) and their target RNAs enables post‐transcriptional silencing in many organisms. These interactions allow the computational prediction of potential targets. In model organisms, predicted targets are frequently validated experimentally; hence meaningful miRNA‐regulated processes are reported. However, in non‐models, these reports mostly rely on computational prediction alone. Many times, further bioinformatic analyses such as Gene Ontology (GO) enrichment are based on these in silico projections. Here such approaches are reviewed, their caveats are highlighted and the ease of picking false targets from predicted lists is demonstrated. Discoveries that shed new light on how miRNAs evolved to regulate targets in various phyletic groups are discussed, in addition to the pitfalls of target identification in non‐model organisms. The goal is to prevent the misuse of bioinformatic tools, as they cannot bypass the biological understanding of miRNA–target regulation.

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MirGeneDB 2.0: The metazoan microRNA complement

Cited by 69 publications

References 74 publications

Unification of miRNA and isomiR research: the mirGFF3 format and the mirtop API

Unification of miRNA and isomiR research: the mirGFF3 format and the mirtop API

xMD-miRNA-seq to generate near in vivo miRNA expression estimates in colon epithelial cells

Too Many False Targets for MicroRNAs: Challenges and Pitfalls in Prediction of miRNA Targets and Their Gene Ontology in Model and Non‐model Organisms

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