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# Identification of non-canonical ORFs and their potential biological function
Cristóbal Gallardo
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??? Presenter notes contain extra information which might be useful if you intend to use these slides for teaching. Press `P` again to switch presenter notes off Press `C` to create a new window where the same presentation will be displayed. This window is linked to the main window. Changing slides on one will cause the slide to change on the other. Useful when presenting. --- ## Requirements Before diving into this slide deck, we recommend you to have a look at: - [Introduction to Galaxy Analyses](/training-material/topics/introduction) - [Sequence analysis](/training-material/topics/sequence-analysis) - Quality Control: [
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hands-on](/training-material/topics/sequence-analysis/tutorials/mapping/tutorial.html) --- ## Index of contents 1. Introduction 2. Galaxy workflow --- ## Introduction - What do we mean by non-canonical ORFs? - Why study non-canonical ORFs? - Why have not been yet characterized? - How identify non-canonical ORFs? --- ## What do we mean by non-canonical ORFs? ![Definition of canonical](/training-material/topics/transcriptomics/images/differential_isoform/slides/cambridge_dictionary.png) .footnote[Source: [Cambridge dictionary](https://dictionary.cambridge.org/dictionary/english/canonical)] --- ## What do we mean by non-canonical ORFs? ![Mean Ribo-Seq expression and Ribo-Seq expression standard deviation (SD) have been plotted for human lymphoblastoid cells from RPFdbV2.](/training-material/topics/transcriptomics/images/differential_isoform/slides/expression_distribution.png) .footnote[Source: <span class="citation"><a href="https://doi.org/10.1038/s41525-020-00167-4">Erady <i>et al.</i> 2021</a></span>] --- ## What do we mean by non-canonical ORFs? ![The dark proteome: translation from noncanonical open reading frames.](/training-material/topics/transcriptomics/images/differential_isoform/slides/dark_proteome.png) --- ## Why study non-canonical ORFs? - Potentially novel <b>prognostic and diagnostic markers</b> - The vast majority <b>have not been investigated</b> - Particulary attractive as <b>allosteric celullar regulators</b> --- ## Why study non-canonical ORFs? ![Noncanonical open reading frames enconde functional proteins essential for cancer cell survival.](/training-material/topics/transcriptomics/images/differential_isoform/slides/non-canonical_nature.png) --- ## Why study non-canonical ORFs? ![Translation and natural selection of micropeptides from lon non-canonical RNAs.](/training-material/topics/transcriptomics/images/differential_isoform/slides/non-canonical_nature2.png) --- ## Why have not been characterized? - Arbitrary thresholds on ORF lengths - Peptides smaller than 100 aminoacids are usually discarted - Frequently annotated as non-coding RNAs - Propensity for structural disorder - Discarted as intrinsically disordered proteins (IDPs) --- ## Why study small peptides? ![The large unexplored biology of small proteins in pro and eukaryotes.](/training-material/topics/transcriptomics/images/differential_isoform/slides/small_peptides.png) --- ## Why study small peptides? ![Short peptides regulate gene expression.](/training-material/topics/transcriptomics/images/differential_isoform/slides/short_peptides.png) --- ## Why study small peptides? ![Example of small peptides biological function.](/training-material/topics/transcriptomics/images/differential_isoform/slides/small_peptides_examples.png) .footnote[Source: <span class="citation"><a href="https://doi.org/10.1111/febs.15845">Steinberg and Koch 2021</a></span>] --- ## Annotated as non-coding RNAs? ![Coding or non-coding? This is the question.](/training-material/topics/transcriptomics/images/differential_isoform/slides/question.jpg) --- ## Annotated as non-coding RNAs? ![The small peptide world in long noncoding RNAs.](/training-material/topics/transcriptomics/images/differential_isoform/slides/small_non_coding.png) --- ## Annotated as non-coding RNAs? ![SPENCER: a comprehensive database for small peptides encoded by noncanical RNAs in cancer patients.](/training-material/topics/transcriptomics/images/differential_isoform/slides/spencer_datase.png) --- ## Why study intrinsically disordered proteins (IDP)? ![Why study intrinsically disordered proteins?](/training-material/topics/transcriptomics/images/differential_isoform/slides/disordered_regions.png) .footnote[Source: <span class="citation"><a href="https://doi.org/10.1126/science.1228775">Babu <i>et al.</i> 2012</a></span>] --- ## Disorder-Function Paradigm ![Disorder-Function paradigm.](/training-material/topics/transcriptomics/images/differential_isoform/slides/disorder_article.png) --- ## Disorder-Function Paradigm ![Expanding the paradigm: intrinsically disordered proteins and allosteric regulation.](/training-material/topics/transcriptomics/images/differential_isoform/slides/intrinsically_disordered.png) --- ## Disorder-Function Paradigm ![Intrinsically disordered proteins/regions and insight into their biomolecular interaction.](/training-material/topics/transcriptomics/images/differential_isoform/slides/disorder_protein.jpg) .footnote[Source: <span class="citation"><a href="https://doi.org/10.1016/j.bpc.2022.106769">Chakrabarti and Chakravarty 2022</a></span>] --- ## How identify non-canonical ORFs? ![How to identify non-canonical ORFs.](/training-material/topics/transcriptomics/images/differential_isoform/slides/scientist.jpg) --- ## How identify non-canonical ORFs? ![IsoformSwitchAnalyzeR: analysis of changes in genome-wide patterns of alternative splicing and its functional consequences.](/training-material/topics/transcriptomics/images/differential_isoform/slides/isoform_switching.png) --- ## How identify non-canonical ORFs? ![Illustration of isoform switch](/training-material/topics/transcriptomics/images/differential_isoform/slides/isoform_switching.jpg) --- ## Galaxy Workflow ![Galaxy workflow.](/training-material/topics/transcriptomics/images/differential_isoform/slides/galaxy_training.png) Full detailed explanation in the [Genome-wide alternative splicing analysis](/training-material/topics/transcriptomics/tutorials/differential-isoform-expression/tutorial.html) Galaxy training. --- ## Galaxy Workflow ![Full workflow image.](/training-material/topics/transcriptomics/images/differential_isoform/full_workflow.png) Full detailed explanation in the [Genome-wide alternative splicing analysis](/training-material/topics/transcriptomics/tutorials/differential-isoform-expression/tutorial.html) Galaxy training. --- ## Galaxy Workflow ![Workflow summary.](/training-material/topics/transcriptomics/images/differential_isoform/galaxyworkflow.drawio.png) --- ## Initial QC assessment ![QC step.Identify potential artifacts that may impact the interpretation of downstream analysis.](/training-material/topics/transcriptomics/images/differential_isoform/fastqc_per_base_sequence_quality.png) Identify potential artifacts that may impact the interpretation of downstream analysis. --- ## Mapping and identication of novel splicing sites with RNASTAR ![Mapping step with RNASTAR. Two-pass alignment enables sequence reads to span novel splice junctions by fewer nucleotides, conferring greater read depth and providing significantly more accurate quantification of novel splice junctions.](/training-material/topics/transcriptomics/images/differential_isoform/slides/STAR_pipeline.drawio.png) Two-pass alignment enables sequence reads to span novel splice junctions by fewer nucleotides, conferring greater read depth and providing significantly more accurate quantification of novel splice junctions. --- ## Post-mapping QC assessment with RSeQC ![Post-mapping QC. RSeQC is a toolkit for generating RNA-seq-specific quality control metrics. The figure corresponds to RSeQC junction saturation of known (A) and novel (B) splicing sites.](/training-material/topics/transcriptomics/images/differential_isoform/rseqc_junction_saturation_plot.png) RSeQC is a toolkit for generating RNA-seq-specific quality control metrics. The figure corresponds to RSeQC junction saturation of known (A) and novel (B) splicing sites. --- ## Reference-based transcriptome assembly and quantification with StringTie ![Transcriptome assembly and quantification with StringTie. StringTie is a fast and highly efficient assembler of RNA-seq alignments into potential transcripts.](/training-material/topics/transcriptomics/images/differential_isoform/slides/stringtie_pipeline.png) StringTie is a fast and highly efficient assembler of RNA-seq alignments into potential transcripts. --- ## Post-assembly QC assessment with rnaQUAST ![Post-assembly QC. rnaQUAST, which will provide us diverse completeness/correctness statistics very useful in order to identify and address potential errors or gaps in the assembly process. The figure is a rnaQUAST cummulative isoform plot.](/training-material/topics/transcriptomics/images/differential_isoform/rnaQUAST_cumulative_isoform.png) rnaQUAST, which will provide us diverse completeness/correctness statistics very useful in order to identify and address potential errors or gaps in the assembly process. The figure is a rnaQUAST cummulative isoform plot. --- ## Isoform switching and functional analysis with IsoformSwitchAnalyzeR ![Isoform switching and functional analysis. IsoformSwitchAnalyzieR performs the differential isoform usage analysis by using DEXSeq.](/training-material/topics/transcriptomics/images/differential_isoform/slides/isoformswitch_pipeline.png) IsoformSwitchAnalyzieR performs the differential isoform usage analysis by using DEXSeq. --- ## Isoform switching and functional analysis with IsoformSwitchAnalyzeR ![IsoformSwitchAnalyzeR consequences plot.](/training-material/topics/transcriptomics/images/differential_isoform/isoformSwitchAnalyzer_consequences_isoform.png) To analyze large-scale patterns in predicted IS consequences, IsoformSwitchAnalyzeR computes all isoform switching events resulting in a gain/loss of a specific consequence (e.g. protein domain gain/loss) --- ## Thank You! This material is the result of a collaborative work. Thanks to the [Galaxy Training Network](https://training.galaxyproject.org) and all the contributors!
Author(s)
Cristóbal Gallardo
Editor(s)
Lucille Delisle
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