---
title: "RiboDiPA R package"
author: "Keren Li, Matthew Hope, Xiaozhong A. Wang, Ji-Ping Wang"
date: "`r Sys.Date()`"
output: 
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        highlight: pygments
        geometry: margin=2cm
        toc: true
        fig_width: 5
vignette: >
    %\VignetteIndexEntry{RiboDiPA}
    %\VignetteEngine{knitr::rmarkdown}
    %\VignetteEncoding{UTF-8}
---
<style>
    body .main-container {
        max-width: 850px;
    }
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#### Maintainer: Ji-Ping Wang, <<jzwang@northwestern.edu>>


```{r setup, include = FALSE}
library(RiboDiPA)
knitr::opts_chunk$set(
    collapse = TRUE,
    comment = "#>"
)
```

**Reference for Method**:
Li K., Hope C.M., Wang X.A., Wang J.-P. (2020) "RiboDiPA: A novel tool for
differential pattern analysis in Ribo-seq data." *Nucleic Acid Research*,
2020,48(21), gkaa1049, https://doi.org/10.1093


\doublespacing

## What is RiboDiPA?

Ribosome profiling (also known as Ribo-seq) is a next-generation sequencing 
technique to investigate the translational activities of ribosomes across a 
wide variety of contexts.  Ribo-seq data not only provide the abundance of 
ribosomes bound to transcripts in the form of counts of ribosome protected 
fragments (RPFs), but also positional information across transcripts that 
could be indicative of differences in translational regulation.

**RiboDiPA**, short for **Ribo**some **Di**ferential **P**attern **A**nalysis,
is a bioinformatics pipeline developed for analysis of the pattern of Ribo-seq
footprint data. RiboDiPA is released as an R package to support statistical 
inference of translational differences between conditions. Briefly, this 
involves mapping Ribo-seq data to P-site counts along a total transcript of 
a gene, followed by binning these counts and performing bin-wise and gene-wise
statistical testing for differential patterns.

## RiboDiPA pipeline

RiboDiPA is an R package that utilizes parallel computing functionality with 
some core functions written in C++, released as part of the Bioconductor 
suite of tools.

## Installation 
```{r, warning=FALSE, message=FALSE, eval=FALSE}
if(!requireNamespace("BiocManager", quietly = TRUE))
    install.packages("BiocManager")
BiocManager::install("RiboDiPA")
```


## Input files  

1) Ribo-seq alignment files (BAM), one per sample.
2) Gene Transfer Format (GTF) file for the reference genome of interest.

## RiboDiPA main features

The RiboDiPA R package executes four major functions to perform differential 
pattern analysis of Ribo-seq data, with optional visualization of results. 
An overview of the process can be seen in Figure 1: 

<center>

![Figure 1](Figure1.png){width=70%} 

</center>

\newline\newline

a) **GTF file parsing and exon merging**: For a given gene, all exons 
annotated in the GTF file are merged into a total transcript. This provides
a global picture of changes across conditions for a gene, as the total 
transcript will capture changes in ribosome occupancy even when transcript
isoform usage might change across conditions.

b) **BAM file processing and P-site mapping**: The Ribo-seq alignment 
files (.bam) are processed to calculate the P-site position for each RPF, 
with adaptable rules that users’ can specify to call P-sites from the data. 
The mapped P-site frequency at each nucleotide position along the total 
transcript is compiled for each gene of each sample.

c) **Data binning**: To overcome the inherent sparseness of Ribo-seq data,
P-site positions are merged into bins using one of three methods: 1) an 
adaptive bin-width method that varies by gene, based on the Freedman-Diaconis
rule 2) a fixed bin width method (as small as a single codon) that the user 
may specify, or 3) binning  by exon, using boundaries specified in the GTF 
file. 

d) **Differential pattern analysis**: Pattern analysis of genes is performed
on binned data for a given gene, comparing bin by bin across conditions to
identify regions with statistically significant differences. The results of
this testing are output as $p$-values and $q$-values for each gene. 
Additionally, a supplementary statistic, the $T$-value, is also produced to 
identify genes with a larger changes across conditions among significant 
genes, and is calculated based on a singular value decomposition procedure. 
$T$-value is intended to account for both the magnitude and number of 
differential bins, thus providing a way to prioritize subsets of significant 
genes for further investigation.

Optionally: **Visualization of Ribo-seq footprints**: RiboDiPA also provides 
functionality for the visualization of mapped P-site frequency data for a 
given gene, as well as the binned data directly used for testing, with 
significantly different bins marked.

## The RiboDiPA pipeline

The following vignette is intended to provide a walkthrough for running 
the RiboDiPA R package, pointing out both the main workflow and optional
functionality for users. It presumes that you have successfully installed
RiboDiPA package from Bioconductor.

The data provided for the purposes of the vignette are adapted from Kasari
et al, and represent a high-quality dataset collected in yeast. These data 
compare wild type cells to cells depleted for New1, which was shown by the
authors to be a regulator involved in translation termination. As is often 
the case for data included in vignettes, the provided files are subsets of 
the full data set, and are intended to illustrate the functionality of 
RiboDiPA. We note that a typical full-scale analysis of real data for most
users will be computing intensive. The computing time depends upon the 
number of samples, the sequencing depth of the samples, and the complexity 
of the organism, in terms of number of genes and exons. For example, the total
computing time of the wild type versus New1 comparison (4 samples) on a 
20-core node is about 10 minutes. RiboDiPA utilizes the parallel computing 
functionality of R and automatically detects the number of cores available 
to run jobs in parallel and improve performance. While a personal computer 
is more than sufficient for the illustration purposes of this vignette, for
optimal performance with real data, we recommend that users run RiboDiPA on
a server or computing cluster.

### 0. Ribo-DiPA Wrapper Function

For users' convenience, we have provided a wrapper function to permit 
execution of the Ribo-DiPA pipeline, which minimally requires a GTF file 
and BAM files, separated by experiment and replicate.

```{r, warning=FALSE, message=FALSE}
## Download sample files from GitHub
library(BiocFileCache)
file_names <- c("WT1.bam", "WT2.bam", "MUT1.bam", "MUT2.bam", "eg.gtf")
url <- "https://github.com/jipingw/RiboDiPA-data/raw/master/"
bfc <- BiocFileCache()
bam_path <- bfcrpath(bfc,paste0(url,file_names))
```
This will produce a list of four BAM files: WT1.bam, WT2.bam, MUT1.bam, 
and MUT2.bam, which represent two biological replicates each of wild type 
cells and New1 mutant cells, respectively. These BAM files were subset on 
the interval chrIV:553,166-581,762 using samtools, which is a roughly 30kb
region that contains 16 genes. Alternatively, users can declare the names 
of their BAM files directly in a vector.

We recommend that users utilize the identical GTF file used to produce the 
experimental alignments. For example, a GTF file sourced from Ensembl will
not work with BAM files aligned with a GTF file sourced from UCSC. The GTF 
file, "eg.gtf", provided in the package is adapted from Ensembl, Saccharomyces
cerevisiae release R64-1-1, and only contains features on chromosome IV.
Users may also declare their GTF file directly.

```{r, warning=FALSE, message=FALSE}
## Make the class label for the experiment
classlabel <- data.frame(
    condition = c("mutant", "mutant", "wildtype", "wildtype"),
    comparison = c(2, 2, 1, 1)
)
rownames(classlabel) <- c("mutant1","mutant2","wildtype1","wildtype2")
```
The class label determines the comparison performed by RiboDiPA, and minimally 
requires a column named `comparison` which labels the reference condition 
"1" and the treatment condition "2", with the option of including conditions 
that should not be compared labeled with "0". In this case "wildtype" 
represents the reference condition, and "mutant" represents the treatment.

```{r, warning=FALSE, message=FALSE}
## Run the RiboDiPA pipeline with default parameters
result.wrp <- RiboDiPA(bam_path[1:4], bam_path[5], classlabel, cores = 2)
```
The `RiboDiPA()` function is a wrapper function that calls all other necessary
functions in the package. The default approaches for this wrapper are to do
automatic generation of P-site offsets and adaptive binning of the mapped
P-sites, although all parameters available in the other functions of the 
package are available to be modified in the wrapper. 

The argument `cores` specifies the number of CPU cores to be used in the 
calculation. The user should replace it by the maximum number of available
cores for maximum computing efficiency (or leave it unspeficied, in which 
case,  the number of cores is set to the value of 
`detectCores(logical = FALSE)`).

```{r}
## View the table of output from RiboDiPA
head(result.wrp$gene[order(result.wrp$gene$qvalue), ])
```
The `RiboDiPA()` function outputs a list of genes with their $T$-value, 
$p$-value, and adjusted $p$-values indicated, stored in the value `gene`, 
along with other intermediate data objects used in the calculation. In most
cases, we expect that users will sort by the adjusted $p$-value in order to
see the most significant genes genome-wide, which we show above. Genes 
YDR049-YDR065 are located within the interval selected for this vignette, 
and we can clearly see highly significant gene hits with TPI1 and RPS13 
(YDR050C and YDR064W, respectively), with $q$-values of 
`r formatC(result.wrp$gene["YDR050C", "qvalue"], format = "e", digits = 2)`
and 
`r formatC(result.wrp$gene["YDR064W", "qvalue"], format = "e", digits = 2)`.

In subsequent sections we will walk 
through the corresponding functions in more detail.

### 1. P-site mapping
A P-site is the exact position on mRNA that has been translated by the 
ribosome, where the growing nascent chain of the polypeptide (covalently
attached to tRNA) is located. In practice, RPFs that have been aligned to
the genome have different lengths, therefore a procedure is required to 
map a given RPF to a P-site position to get a clear picture of ribosome 
translational activity. 

The `psiteMapping()` function will take the input
data, and use user-specified rules to map RPFs to P-sites, or generate 
those rules automatically using the procedure described in Lauria et al
(2018). Additionally, if there are multiple transcript isoforms in a 
sample that utilize the same exon in the genome, in can be difficult (or 
impossible) to assign a given RPF to a particular transcript in a Ribo-seq
experiment. RiboDiPA circumvents this problem by combining all exons into
a "total transcript" and performs testing at the gene level. Therefore, 
in addition to the P-site offset generation and mapping, the `psiteMapping()`
function also generates total transcript coordinates for each exon.

```{r, warning=FALSE, message=FALSE}
## Perform individual P-site mapping procedure
data.psite <- psiteMapping(bam_file_list = bam_path[1:4], 
    gtf_file = bam_path[5], psite.mapping = "auto", cores = 2)
```

P-site mapping outputs a list of values: `coverage`, the coverage across 
each gene; `counts`, the number of P-sites counts per gene; `exons`, the
total transcript coordinates and genomic coordinates for each exon in the 
genome; and `psite.mapping`, the P-site mapping offsets. For the `coverage` 
object, rows correspond to replicates and columns correspond to nucleotide 
positions with respect to 
the total transcript. Similarly, for the `counts` object, rows represent 
genes and columns represent samples. Now, let us examine the offsets 
generated automatically by the function:

```{r}
## P-site mapping offset rule generated
data.psite$psite.mapping
```
The read length of the RPF is listed (`qwidth`), followed by the nucleotide
offset from the 5' end (`psite`). For instance, reads of length 28 have an
offset of 12, meaning that the P-site will be mapped 12 nucleotides from 
the 5' end of the read. 

As mentioned above, the optimal P-site offsets from the 5' end of reads 
is calibrated using a two-step algorithm on start codons genome-wide, 
closely following the procedure of Lauria et al (2018). First, for a 
given read length, the offset is calculated by taking the distance between
the first nucleotide of the start codon and the 5' most nucleotide of 
the read, and then defining the offset as the 5' position with the most 
reads mapped to it. This process is repeated for all read lengths and 
then the temporary global offset is defined to be the offset of the read 
length with the maximum count. Lastly, for each read length, the adjusted
offset is defined to be the one corresponding to the local maximum found
in the profiles of the start codons closest to the temporary global offset. 

In case of insufficient reads mapped to the start codons, we recommend 
users to use the `center` option to take the center of the read as the 
P-site, or to provide their own offset rules by simply using a matrix 
with two columns, labeled `qwidth` and `psite`, passed into the 
`psite.mapping` parameter of the `psiteMapping()` function. We note 
that specifying fixed rules for the P-site offsets might be especially 
useful when comparing across different experiments collected in the same 
organism, to insure consistency in the comparison.

```{r, warning=FALSE, message=FALSE, eval=FALSE}
## Use user specified psite mapping offset rule
offsets <- cbind(qwidth = c(28, 29, 30, 31, 32), 
    psite = c(18, 18, 18, 19, 19))
data.psite2 <- psiteMapping(bam_path[1:4], bam_path[5], 
    psite.mapping = offsets, cores = 2)
```

Lastly, the `psiteMapping()` function uses the parallel computing package
doParallel to speed up the process of mapping P-sites. To utilize this 
feature, specify the number of cores available for the job using the 
`cores` parameter. If `cores` is not specified, this function will 
automatically detect the number of cores on your computer to run jobs
in parallel.

### 2. Data binning
Once reads have been mapped to P-sites in the various experiments, 
the next step is to bin mapped P-sites together to permit statistical 
testing. The smallest bin one could imagine is a single-codon (three 
nucleotides) which would provide the highest resolution of binning, but 
entails some practical problems. For instance, very long genes will have
more codons, therefore after correction for multiple hypothesis testing,
only the most pronounced perturbations would show statistical significance 
at large genes. Alternatively, the largest bin imaginable is to use an 
entire gene as one bin, although positional information across the gene 
will be lost. Therefore, a robust method to choose the right bin size per
gene to permit discovery is needed, which is the essence of the RiboDiPA 
adaptive binning method. 

The adaptive method uses a procedure based on the Freedman-Diaconisis 
rule to pick an optimal number of bins of equal width for each gene, where
different genes will have different bin widths, but the positions and 
number of bins for a gene will be the same across replicates and conditions
to permit testing.    

```{r, warning=FALSE, message=FALSE,eval=FALSE}
## Merge the P-site data into bins with a fixed or an adaptive width
data.binned <- dataBinning(data = data.psite$coverage, bin.width = 0, 
    zero.omit = FALSE, bin.from.5UTR = TRUE, cores = 2)
```

The function `dataBinning()` returns a list of binned P-site footprint 
matrices. In each matrix, rows correspond to replicates, and columns 
correspond to bins. If the parameter `bin.width` is not specified or set 
to zero, this indicates that the function will run in the adaptive binning 
mode (as opposed to fixed-width mode, see below). In general, we recommend 
to use adaptive binning, due to the fact that most Ribo-seq experiments 
are sparse and have few numbers of reads, on a per codon basis. 

If the `zero.omit` argument is set to `TRUE`, bins with all zeros across 
all replicates are removed from the differential pattern analysis. When 
the length of total transcript is not an integer multiple of the bin width,
binning will start from the 5' end if `bin.from.5UTR` argument is `TRUE`,
or from the 3' end otherwise. In general, bin width is equal for every bin
across the total transcript, except for the last two bins, which are 
adjusted to prevent the last bin from being very small in the case where 
the bin width does not divide the total transcript length evenly.

```{r, warning=FALSE, message=FALSE,eval=FALSE}
## Merge the P-site data on each codon
data.codon <- dataBinning(data = data.psite$coverage, bin.width = 1, 
    zero.omit = FALSE, bin.from.5UTR = TRUE, cores = 2)
```

In cases where coverage permits, users can also specify a fixed width of bin, 
all the way down to 1, which represents single-codon resolution. This can be 
useful for examining details at regions that are very likely to have changes 
in translational regulation, namely near the start and stop codons. For 
instance, we examined 50 codons upstream and downstream of the stop and start
codons respectively to identify a patterns of stacked ribosomes near the stop 
codon in the case of New1 deletion (see Li et al, 2020).

```{r, warning=FALSE, message=FALSE,eval=FALSE}
## Merge the P-site data on each exon and perform differential pattern analysis
result.exon <- diffPatternTestExon(psitemap = data.psite, 
    classlabel = classlabel, method = c('gtxr', 'qvalue'))
```

In cases where users would prefer to use exons as the bins for statistical 
testing, we have provided a function called `diffPatternTestExon()`. This 
function rolls data binning and differential pattern testing into one function
and outputs the same structure qw `diffPatternTest()` function. For organisms 
like yeast where alternative splicing is minimal, this option may not be very 
useful, but for higher organisms with many exons and much more alternative 
splicing, it may provide useful insight.

### 3. Differential pattern analysis
Once appropriate bins have been generated, the RiboDiPA package performs 
differential pattern testing on P-site counts bin by bin for each gene. 
Briefly, counts are modeled by a negative binomial distribution to call 
bins with statistically significant differences across conditions, and 
then the smallest p-value for a given gene is adjusted to control for 
multiple hypothesis testing across all genes. 

```{r, warning=FALSE, message=FALSE,eval=FALSE}
## Perform differential pattern analysis
result.pst <- diffPatternTest(data = data.binned, 
    classlabel = classlabel, method=c('gtxr', 'qvalue'))
```

The `diffPatternTest()` function takes the output from data binning as input,
and also requires a class label object, describing the comparison to be made.
The class label object is simply a data frame with two columns, `condition`
and `comparison`, where `condition` labels the conditions tested, and 
`comparison` labels the experimental conditions numerically, where "1" 
indicates the control condition, "2" indicates the treatment condition, 
and "0" indicates replicates that should not be compared, if present.

The output of this function is a list that contains a data 
frame object `gene` as well as other objects that store intermediate 
calculations. `gene` contains gene-level $T$-value, $p$-value, and $q$-value 
(if $q$-value is specified as the metric for multiple comparison error 
correction) of all genes. The `bin` object contains bin-level test $p$-value 
and corresponding adjusted $p$-value for each bin of each gene.

$T$-value, bin-level $p$-value, and bin-level adjusted $p$-value and 
gene-level adjusted $p$-value and $q$-value (in this case measured by 
the qvalue) of all  genes. The gene-level $p$-value and $q$-value are 
the main result of the testing, and therefore the main output of the package. 


Additionally, the $T$-value is a supplementary statistic that quantifies
the magnitude of difference between conditions, with larger numbers 
indicating a greater difference. The $T$-value is defined to be 1-cosine of 
the angle between the first right singular vectors of the footprint matrices
of the two conditions under comparison. It ranges from 0-1, with larger values 
representing larger differences between conditions, and practically speaking,
can be used to identify genes with larger magnitude of pattern difference 
beyond statistical significance. This might be helpful to investigators to
prioritize certain genes for investigation among many that may pass the 
significance test for differential pattern.


Optionally, users may specify which method to use for correction of type I 
error for multiple hypothesis testing. The $q$-value method from `qvalue` 
package is the default method of FDR control at the gene-level, and the hybrid
Hochberg-Hommel method `gtxr` from `elitism` pacakge is the default method
of multiplicity correction at bin-level. Other options defined by the package
`elitism` is invoked by the option to the parameter method.


### 4. Plotting and genome visualization
RiboDiPA implemented two plot functions for visualizing the footprint data 
and test results including :1) individual gene 
plotting in the landscape of total transcript; and 2) track plotting through 
genome browser using R package `igvR`.  

##### Individual gene plotting
The individual gene plotting is implemented with the package `ggplot2`. 
Two plotting functions, `plotTrack()` and `plotTest()`, are provided, 
with the former for mapped P-site plotting and the latter 
for binned data that are generated from the mapped P-sites.  

The `plotTrack()` function visualizes reads mapped to P-site positions on a 
per gene basis. The input argument `data` is the output object of 
`psiteMapping()` or the `psiteMapping()` output object from the wrapper 
`RiboDiPA()` function (i.e., `result.wrp$data.psite` from the example codes 
above). The counts of RPFs mapped to P-sites is shown on the y-axis, while 
the total transcript in nucleotides is shown on the x-axis.

```{r fig2, fig.height=6, fig.width=6, fig.align="center", results='hide'}
## Plot ribosome per nucleotide tracks of specified genes.
plotTrack(data = data.psite, genes.list = c("YDR050C", "YDR064W"),
    replicates = NULL, exons = FALSE)
```

`plotTrack()` always shows the total transcript with the 5' end on the left 
and the 3' end on the right with the corresponding genomic coordinates of the 
start codon and stop codon labelled. User can specify one or more genes to be 
plotted at a time. If the exons argument is set to `TRUE`, RPFs per exon of 
the  specified genes are also ouput.

```{r fig3, fig.height = 9, fig.width = 10, fig.align = "center",results='hide'}
## Plot binned ribosome tracks of siginificant genes: YDR086C and YDR210W.
## you can specify the thrshold to redefine the significant level
plotTest(result = result.pst, genes.list = NULL, threshold = 0.05) 
```

The `plotTest()` plots the binned RPF footprint used in the differential 
pattern testing. The input argument `result` for `plotTest()` is the entire 
output object of  `diffPatternTest()` or `diffPatternTestExon()` or
`RiboDiPA()` function. For replicates marked as "1" in `classlabel` (see
`diffPatternTest()` function), the tracks are colored blue and replicates 
marked as "2"  are colored red. Differential bins are colored black, with 
bin-level adjusted $p$-value annotated underneath the the track of the last
replicate. If `genes.list` is not specified, all genes with significant 
differential pattern will be output. 

Lastly, the threshold parameter allows users to specify a threshold of 
signifance level for seleciton of significant genes. A threshold value 
of 0.05 will only plot genes with $q$-value less than or equal to 0.05.



##### Track plotting via genome browser ####
Three functions, `bpTrack()`, `binTrack()`, and `exonTrack()`, 
are provided to support the track plotting through genome browser by utilizing
`igvR`. The uses can examine the ribosome footprint in the genomic 
landscape and the differential pattern test results. All three functions output
`GRanges` objects as input of `igvR` for track visualization, respectively, 
RPF in base pair, binned RPF from `diffPatternTest()` with differential 
pattern test results, and RPF by exons with test results.

To visualize these tracks in genome browser, users should install `igvR` 
through Bioconductor. Some simple illustration examples are given below.

```{r, warning=FALSE, message=FALSE, eval=FALSE}
##base-bair RPF track
library(igvR)
thred <- 0.05
igv <- igvR()
setBrowserWindowTitle(igv, "ribosome footprint track example")
setGenome(igv, "saccer3")

data(data.psite)
names.rep <- c("mutant1", "mutant2", "wildtype1", "wildtype2")
tracks.bp <- bpTrack(data = data.psite, names.rep = names.rep, 
    genes.list = c("YDR050C", "YDR062W", "YDR064W"))

for(track.name in names.rep){
    track.rep <- tracks.bp[[track.name]]
    track <- GRangesQuantitativeTrack(trackName = paste(track.name, "bp"),
        track.rep[,1], color = "green")
    displayTrack(igv, track)
}}

```{r, warning=FALSE, message=FALSE, eval=FALSE}
## bin track and test results
data(result.pst)
data(data.psite)
tracks.bin <- binTrack(data = result.pst, exon.anno = data.psite$exons)

for(track.name in names(tracks.bin)){
    track.rep <- tracks.bin[[track.name]]
    resize(track.rep, width(track.rep) + 1)
    track <- GRangesQuantitativeTrack(trackName = paste(track.name, "binned"),
        track.rep[,1], color = "black")
    displayTrack(igv, track)
}

track.rep2 <- tracks.bin[[1]]
sig.bin <- (values(track.rep2)[,5] <= thred)
log10.padj <- - log10(values(track.rep2)[,5])
mcols(track.rep2) <- data.frame(log10padj = log10.padj)
track.rep2 <- track.rep2[which(sig.bin),]
track <- GRangesQuantitativeTrack(trackName = "- log 10 of padj",
    track.rep2, color = "red", trackHeight = 40)
displayTrack(igv, track)
```

The first input argument of `bpTrack()`, `data`, is the output object of 
`psiteMapping()` or `RiboDiPA()` function. If the replicate names 
`names.rep` is not specified, column names of `data$counts` will be used
as track label on `igvR` visualization. Also, if a list of genes for 
visualization is not provided, then all genes listed in `data$coverage`
will be plotted.

The function `binTrack()` uses the output object of `diffPatterbTest()` 
or `RiboDiPA()` function for the argument `data`, and the value `exons` of
`psiteMapping()` function output for the argument `exon.anno`. Besides of 
ribosome binned tracks, differential pattern test results is also reported
in the value of `binTrack()`. In Figure 2, a both base-pair 
RPF track and binned track are shown through `igvR`. The green bars are 
the ribosome tracks per bp, the black bars are the binned tracks, while red
bars are plotted at significant bins (i.e., adjusted bin-level p-value 
$\leq 0.05$), with 
$-\log_{10}$ of adjusted p-value also plotted. 

<center>

![Figure 2: igvR genome browser tracks](igvR.png){width=90%} 
</center>


```{r, warning=FALSE, message=FALSE, eval=FALSE}
## bin track and test results
igv2 <- igvR()
setBrowserWindowTitle(igv2, "ribosome footprint per exon example")
setGenome(igv2, "saccer3")
data(result.exon)
tracks.exon <- exonTrack(data = result.exon, gene = "tY(GUA)D")
for(track.name in names(tracks.exon)){
    track.rep <- tracks.exon[[track.name]]
    for(tx.name in names(track.rep)){
        track.tx <- tracks.exon[[track.name]][[tx.name]]
        track <- GRangesQuantitativeTrack(trackName = 
            paste(track.name, tx.name), track.tx[,1], color = track.name)
        displayTrack(igv2, track)
    }
}
```

For higher organisms, where exons are used as the bins for statistical 
testing through the function `diffPatternTestExon()`, `exonTrack()` is the 
proper function to output tracks for visualization purpose. It outputs a list
of lists. Each element is a list of `GRanges` objects representing replicates,
and each second level list element is exon-level P-site footprint counts in a
transcript.

The argument `data` uses the output object of `diffPatternTestExon()`. 
The second argument `gene` requires a single gene name to be plotted, since 
different genes may have different number of transcripts.


### Conclusion
This concludes our vignette. For additional information, please consult 
the reference manual for each individual function, as well as the associated
paper for this package for methodological details (Li et al, 2020).


## Session info

```{r sessionInfo}
sessionInfo()
```