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Table of Contents

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Go to the following page https://posit.co/download/rstudio-desktop/ and follow the instructions provided to install first R and then Rstudio.

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The basis for the differential expression analysis is a count table of sequence reads mapped to defined gene regions per sample. There are a variety of methods to generate this count table, but for this exercise, we will be using the output from the Nextflow nfcore/rnaseq analysis you completed in the previous workshop sessions.

To access this count table:

Go to the W:\training\rnaseq\runs\run3_RNAseq\results folder that contains the results from running the nfcore/rnaseq pipeline. The output folders from task 3 look like this:

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The count table can be found in the star_salmon folder. A list of files and folders in the star_salmon folder will look like this:

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  1. Preparing your data. Two data files are needed for this analysis: a samples table and your count table

  2. Install required R packages (only need to run once) - after installation, we only need to load the packages. NOTE: If using an rVDI virtual machine, the R packages are already installed

  3. Load required R packages. Unlike installing the packages, this needs to be done every time you run the analysis

  4. Import your data files (count table and samples table)into R

  5. Checking for outliers and batch effects

    1. PCA plot

    2. Pairwise samples heatmap

  6. Identify differentially expressed (DE) genes using DESeq2

    1. Annotating your DE genes

    2. Volcano plot

    3. DE genes heatmap

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a. First create a new folder in H:\workshop\RNAseq . Call it something suitable, such as ‘DE_analysis_workshop’

b. Create a sub folder subfolder here called ‘data’. This is where your two data files will be stored

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Code Block
gene_id	gene_name	SRR20622172	SRR20622173	SRR20622174	SRR20622175	SRR20622176	SRR20622177	SRR20622178	SRR20622179	SRR20622180
ENSMUSG00000000001	Gnai3	7086	4470	2457.002	2389	6398	2744	2681	3961	4399
ENSMUSG00000000003	Pbsn	0	0	0	0	0	0	0	0	0
ENSMUSG00000000028	Cdc45	1232.999	827	42	57	1036	55	78	88	89
ENSMUSG00000000031	H19	200	139	2	0	143.622	1	17.082	24	16.077
ENSMUSG00000000037	Scml2	70	57.001	8	8	66.999	16	23	27.999	29
ENSMUSG00000000049	Apoh	0	0	1	0	2	2	1	3	0
ENSMUSG00000000056	Narf	1933	1480	519	497	1730	539	365	458	536
ENSMUSG00000000058	Cav2	6008	3417	1347.001	1344	5482	1367	2669.001	4358	4365.832
ENSMUSG00000000078	Klf6	3809	2732	4413.001	3483.978	3559	4491	3209	3980	4626

d. In the same W:\training\rnaseq\runs\run3_RNAseq\results\star_salmon directory there will be a file called metadata.xlsx . Copy this file to your ‘data’ folder as well. This file will normally need to be manually created by you to match your sample IDs and treatment groups, but we created this file already for you to use. This samples table needs 3 columns called ‘sample_name’, containing the sample names seen in the count table (column names), ‘sample_ID’, which is the (less messy) names you want to call the samples in this analysis workflow, and ‘group’, which contains the treatment groups each sample belongs to. The contents of this file look like this:

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4. Import your data files into R

In this section, we will import your count table and samples table into R.

You’ll need to change the ‘setwd' line to your working directory. Click ‘Session’ → ‘Set working directory’ → ‘Choose working directory’ and then choose the analysis workshop directory you created previously , that contains your R script file and the 'Data’ directory.

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5. Checking for outliers and batch effects

In this section, we will create PCA plots and heatmaps to examine the relationships between samples. Outlier samples and batch effects can heavily bias your results and should be addressed (e.g. removal of outlier samples from the dataset) before any differential expression analysis is completed.

First, we need to prepare the data for plotting. Copy, paste, and run the following code in your R script. you will need to input which treatment groups you wish to plot (plotgroups <-) from the set of available treatment groups (which you can find out with unique(meta$group).

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