Your search keyword '"Novoa, Eva"' showing total 9 results

1. Native RNA nanopore sequencing reveals antibiotic-induced loss of rRNA modifications in the A- and P-sites.

Author

Delgado-Tejedor A, Medina R, Begik O, Cozzuto L, López J, Blanco S, Ponomarenko J, and Novoa EM

Subjects

Sequence Analysis, RNA methods, RNA Processing, Post-Transcriptional drug effects, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli drug effects, Algorithms, Nanopore Sequencing methods, Anti-Bacterial Agents pharmacology, RNA, Ribosomal genetics, RNA, Ribosomal metabolism, RNA, Bacterial genetics, RNA, Bacterial metabolism, Ribosomes metabolism, Ribosomes drug effects

Abstract

The biological relevance and dynamics of mRNA modifications have been extensively studied; however, whether rRNA modifications are dynamically regulated, and under which conditions, remains unclear. Here, we systematically characterize bacterial rRNA modifications upon exposure to diverse antibiotics using native RNA nanopore sequencing. To identify significant rRNA modification changes, we develop NanoConsensus, a novel pipeline that is robust across RNA modification types, stoichiometries and coverage, with very low false positive rates, outperforming all individual algorithms tested. We then apply NanoConsensus to characterize the rRNA modification landscape upon antibiotic exposure, finding that rRNA modification profiles are altered in the vicinity of A and P-sites of the ribosome, in an antibiotic-specific manner, possibly contributing to antibiotic resistance. Our work demonstrates that rRNA modification profiles can be rapidly altered in response to environmental exposures, and provides a robust workflow to study rRNA modification dynamics in any species, in a scalable and reproducible manner., Competing Interests: Competing interests: E.M.N. is a member of the Scientific Advisory Board of IMMAGINA Biotech. E.M.N. has received travel and accommodation expenses to speak at Oxford Nanopore Technologies conferences. A.D.-T. and O.B. have received travel bursaries from ONT to present their work in conferences. The remaining authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

2. Quantitative analysis of tRNA abundance and modifications by nanopore RNA sequencing.

Author

Lucas MC, Pryszcz LP, Medina R, Milenkovic I, Camacho N, Marchand V, Motorin Y, Ribas de Pouplana L, and Novoa EM

Subjects

RNA, RNA, Transfer chemistry, Sequence Analysis, RNA methods, Nanopore Sequencing, Nanopores

Abstract

Transfer RNAs (tRNAs) play a central role in protein translation. Studying them has been difficult in part because a simple method to simultaneously quantify their abundance and chemical modifications is lacking. Here we introduce Nano-tRNAseq, a nanopore-based approach to sequence native tRNA populations that provides quantitative estimates of both tRNA abundances and modification dynamics in a single experiment. We show that default nanopore sequencing settings discard the vast majority of tRNA reads, leading to poor sequencing yields and biased representations of tRNA abundances based on their transcript length. Re-processing of raw nanopore current intensity signals leads to a 12-fold increase in the number of recovered tRNA reads and enables recapitulation of accurate tRNA abundances. We then apply Nano-tRNAseq to Saccharomyces cerevisiae tRNA populations, revealing crosstalks and interdependencies between different tRNA modification types within the same molecule and changes in tRNA populations in response to oxidative stress., (© 2023. The Author(s).)

Published

2024

3. Nanopore Direct RNA Sequencing Data Processing and Analysis Using MasterOfPores.

Author

Cozzuto L, Delgado-Tejedor A, Hermoso Pulido T, Novoa EM, and Ponomarenko J

Subjects

Software, RNA genetics, Saccharomyces cerevisiae genetics, High-Throughput Nucleotide Sequencing, Sequence Analysis, RNA, Nanopore Sequencing, Nanopores

Abstract

This chapter describes MasterOfPores v.2 (MoP2), an open-source suite of pipelines for processing and analyzing direct RNA Oxford Nanopore sequencing data. The MoP2 relies on the Nextflow DSL2 framework and Linux containers, thus enabling reproducible data analysis in transcriptomic and epitranscriptomic studies. We introduce the key concepts of MoP2 and provide a step-by-step fully reproducible and complete example of how to use the workflow for the analysis of S. cerevisiae total RNA samples sequenced using MinION flowcells. The workflow starts with the pre-processing of raw FAST5 files, which includes basecalling, read quality control, demultiplexing, filtering, mapping, estimation of per-gene/transcript abundances, and transcriptome assembly, with support of the GPU computing for the basecalling and read demultiplexing steps. The secondary analyses of the workflow focus on the estimation of RNA poly(A) tail lengths and the identification of RNA modifications. The MoP2 code is available at https://github.com/biocorecrg/MOP2 and is distributed under the MIT license., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

4. ModPhred: an integrative toolkit for the analysis and storage of nanopore sequencing DNA and RNA modification data.

Author

Pryszcz LP and Novoa EM

Subjects

Sequence Analysis, DNA methods, Software, DNA, RNA, High-Throughput Nucleotide Sequencing, Nanopore Sequencing, Nanopores

Abstract

Motivation: DNA and RNA modifications can now be identified using nanopore sequencing. However, we currently lack a flexible software to efficiently encode, store, analyze and visualize DNA and RNA modification data., Results: Here, we present ModPhred, a versatile toolkit that facilitates DNA and RNA modification analysis from nanopore sequencing reads in a user-friendly manner. ModPhred integrates probabilistic DNA and RNA modification information within the FASTQ and BAM file formats, can be used to encode multiple types of modifications simultaneously, and its output can be easily coupled to genomic track viewers, facilitating the visualization and analysis of DNA and RNA modification information in individual reads in a simple and computationally efficient manner., Availability and Implementation: ModPhred is available at https://github.com/novoalab/modPhred, is implemented in Python3, and is released under an MIT license. Docker images with all dependencies preinstalled are also provided., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2021. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2021

5. Computational methods for RNA modification detection from nanopore direct RNA sequencing data.

Author

Furlan M, Delgado-Tejedor A, Mulroney L, Pelizzola M, Novoa EM, and Leonardi T

Subjects

Animals, Humans, Software, Algorithms, Computational Biology methods, Nanopore Sequencing methods, RNA chemistry, RNA genetics, RNA Processing, Post-Transcriptional, Transcriptome

Abstract

The covalent modification of RNA molecules is a pervasive feature of all classes of RNAs and has fundamental roles in the regulation of several cellular processes. Mapping the location of RNA modifications transcriptome-wide is key to unveiling their role and dynamic behaviour, but technical limitations have often hampered these efforts. Nanopore direct RNA sequencing is a third-generation sequencing technology that allows the sequencing of native RNA molecules, thus providing a direct way to detect modifications at single-molecule resolution. Despite recent advances, the analysis of nanopore sequencing data for RNA modification detection is still a complex task that presents many challenges. Many works have addressed this task using different approaches, resulting in a large number of tools with different features and performances. Here we review the diverse approaches proposed so far and outline the principles underlying currently available algorithms.

Published

2021

6. Quantitative profiling of pseudouridylation dynamics in native RNAs with nanopore sequencing.

Author

Begik O, Lucas MC, Pryszcz LP, Ramirez JM, Medina R, Milenkovic I, Cruciani S, Liu H, Vieira HGS, Sas-Chen A, Mattick JS, Schwartz S, and Novoa EM

Subjects

Algorithms, Gene Expression Profiling, Intramolecular Transferases metabolism, Mitochondria genetics, Pseudouridine genetics, RNA genetics, RNA Processing, Post-Transcriptional genetics, RNA, Fungal genetics, RNA, Fungal metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Ribosomal genetics, RNA, Ribosomal metabolism, Saccharomyces cerevisiae genetics, Software, Stress, Physiological genetics, Nanopore Sequencing methods, Pseudouridine metabolism, RNA metabolism, Sequence Analysis, RNA methods

Abstract

Nanopore RNA sequencing shows promise as a method for discriminating and identifying different RNA modifications in native RNA. Expanding on the ability of nanopore sequencing to detect N 6 -methyladenosine, we show that other modifications, in particular pseudouridine (Ψ) and 2'-O-methylation (Nm), also result in characteristic base-calling 'error' signatures in the nanopore data. Focusing on Ψ modification sites, we detected known and uncovered previously unreported Ψ sites in mRNAs, non-coding RNAs and rRNAs, including a Pus4-dependent Ψ modification in yeast mitochondrial rRNA. To explore the dynamics of pseudouridylation, we treated yeast cells with oxidative, cold and heat stresses and detected heat-sensitive Ψ-modified sites in small nuclear RNAs, small nucleolar RNAs and mRNAs. Finally, we developed a software, nanoRMS, that estimates per-site modification stoichiometries by identifying single-molecule reads with altered current intensity and trace profiles. This work demonstrates that Nm and Ψ RNA modifications can be detected in cellular RNAs and that their modification stoichiometry can be quantified by nanopore sequencing of native RNA., (© 2021. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2021

7. EpiNano: Detection of m 6 A RNA Modifications Using Oxford Nanopore Direct RNA Sequencing.

Author

Liu H, Begik O, and Novoa EM

Subjects

Escherichia coli genetics, Nanopores, Nanopore Sequencing methods, RNA genetics, RNA Processing, Post-Transcriptional genetics, Sequence Analysis, RNA methods

Abstract

RNA modifications play pivotal roles in the RNA life cycle and RNA fate, and are now appreciated as a major posttranscriptional regulatory layer in the cell. In the last few years, direct RNA nanopore sequencing (dRNA-seq) has emerged as a promising technology that can provide single-molecule resolution maps of RNA modifications in their native RNA context. While native RNA can be successfully sequenced using this technology, the detection of RNA modifications is still challenging. Here, we provide an upgraded version of EpiNano (version 1.2), an algorithm to predict m 6 A RNA modifications from dRNA-seq datasets. The latest version of EpiNano contains models for predicting m 6 A RNA modifications in dRNA-seq data that has been base-called with Guppy. Moreover, it can now train models with features extracted from both base-called dRNA-seq FASTQ data and raw FAST5 nanopore outputs. Finally, we describe how EpiNano can be used in stand-alone mode to extract base-calling "error" features and current intensity information from dRNA-seq datasets. In this chapter, we provide step-by-step instructions on how to produce in vitro transcribed constructs to train EpiNano, as well as detailed information on how to use EpiNano to train, test, and predict m 6 A RNA modifications in dRNA-seq data.

Published

2021

8. Molecular barcoding of native RNAs using nanopore sequencing and deep learning.

Author

Smith MA, Ersavas T, Ferguson JM, Liu H, Lucas MC, Begik O, Bojarski L, Barton K, and Novoa EM

Subjects

Algorithms, Deep Learning, Nanopore Sequencing methods, Sequence Analysis, RNA methods

Abstract

Nanopore sequencing enables direct measurement of RNA molecules without conversion to cDNA, thus opening the gates to a new era for RNA biology. However, the lack of molecular barcoding of direct RNA nanopore sequencing data sets severely affects the applicability of this technology to biological samples, where RNA availability is often limited. Here, we provide the first experimental protocol and associated algorithm to barcode and demultiplex direct RNA nanopore sequencing data sets. Specifically, we present a novel and robust approach to accurately classify raw nanopore signal data by transforming current intensities into images or arrays of pixels, followed by classification using a deep learning algorithm. We demonstrate the power of this strategy by developing the first experimental protocol for barcoding and demultiplexing direct RNA sequencing libraries. Our method, DeePlexiCon, can classify 93% of reads with 95.1% accuracy or 60% of reads with 99.9% accuracy. The availability of an efficient and simple multiplexing strategy for native RNA sequencing will improve the cost-effectiveness of this technology, as well as facilitate the analysis of lower-input biological samples. Overall, our work exemplifies the power, simplicity, and robustness of signal-to-image conversion for nanopore data analysis using deep learning., (© 2020 Smith et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

9. EpiNano: detection of m6A RNA modifications using Oxford nanopore direct RNA sequencing

Author

Liu, Huanle, Begik, Oguzhan, and Novoa, Eva Maria

Subjects

Oxford Nanopore Technologies, Direct RNA sequencing, Support vector machine, Nanopore sequencing, N6-methyladenosine, Base-calling “errors”, In vitro transcription, RNA modification, Native RNA

Abstract

RNA modifications play pivotal roles in the RNA life cycle and RNA fate, and are now appreciated as a major posttranscriptional regulatory layer in the cell. In the last few years, direct RNA nanopore sequencing (dRNA-seq) has emerged as a promising technology that can provide single-molecule resolution maps of RNA modifications in their native RNA context. While native RNA can be successfully sequenced using this technology, the detection of RNA modifications is still challenging. Here, we provide an upgraded version of EpiNano (version 1.2), an algorithm to predict m6A RNA modifications from dRNA-seq datasets. The latest version of EpiNano contains models for predicting m6A RNA modifications in dRNA-seq data that has been base-called with Guppy. Moreover, it can now train models with features extracted from both base-called dRNA-seq FASTQ data and raw FAST5 nanopore outputs. Finally, we describe how EpiNano can be used in stand-alone mode to extract base-calling "error" features and current intensity information from dRNA-seq datasets. In this chapter, we provide step-by-step instructions on how to produce in vitro transcribed constructs to train EpiNano, as well as detailed information on how to use EpiNano to train, test, and predict m6A RNA modifications in dRNA-seq data. We thank all members of the Novoa lab for their valuable insights and discussion. We thank Rebeca Medina for obtaining the TapeStation image used for Fig. 1. OB is supported by an international PhD fellowship (UIPA) from the University of New South Wales. This work was supported by the Australian Research Council (DP180103571 to EMN) and the Spanish Ministry of Economy, Industry and Competitiveness (MEIC) (PGC2018-098152-A-100 to EMN). We acknowledge the support of the MEIC to the EMBL partnership, Centro de Excelencia Severo Ochoa, and CERCA Program/Generalitat de Catalunya.

Published

2021