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title: "Get started"
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Codon usage bias is a phenomenon whereby different organisms exhibit distinct preferences for synonymous codons, which are multiple codons that encode the same amino acid. This variation in codon usage patterns is observed across all levels of life, from bacteria to eukaryotes. Codon usage bias is influenced by a variety of factors, including gene expression, GC content, and horizontal gene transfer. Understanding the causes and consequences of codon usage bias is important for a variety of fields, including molecular biology, evolutionary biology, and biotechnology.
`cubar` can be a helpful tool for researchers who are interested in studying codon usage bias. It provides a variety of functions that can be used to calculate and visualize codon usage bias metrics.
Here, we demonstrate the basic functionalities of `cubar` by analyzing the coding sequences (CDSs) of brewer's yeast as an example.
```{r, include = FALSE}
knitr::opts_chunk$set(
collapse = TRUE,
comment = "#>"
)
```
```{r setup}
suppressPackageStartupMessages(library(Biostrings))
suppressPackageStartupMessages(library(data.table))
library(cubar)
library(ggplot2)
```
### Sequences and the Genetic Code
First, quality control was performed on the provided Yeast CDS sequences to ensure that each sequence had the correct start codon, stop codon, and no internal stop codons. Additionally, the length of each sequence was verified to be a multiple of three. These QC procedures can be adjusted based on the input sequences. For example, if your sequences do not contain 3' stop codons, you can skip this check by setting `check_stop = FALSE`.
```{r}
# example data
yeast_cds
# qc
yeast_cds_qc <- check_cds(yeast_cds)
yeast_cds_qc
```
CDSs sequences can be convert to codon sequences by `seq_to_codons` or translated to corresponding amino acid sequences with `translate` from `Biostrings`.
```{r}
# convert a CDS to codon sequence
seq_to_codons(yeast_cds_qc[['YDR320W-B']])
# convert a CDS to amino acid sequence
Biostrings::translate(yeast_cds_qc[['YDR320W-B']])
```
Many codon usage metrics depend on codon frequencies, which can be calculated easily by the function `count_codons`.
```{r}
# get codon frequency
yeast_cf <- count_codons(yeast_cds_qc)
```
In the resulting matrix, each row represents a gene, and each column represents a codon. The values in the matrix represent the frequency of each codon in the corresponding gene.
```{r}
yeast_cf[1:3, 1:3]
```
To interact with the genetic code, `cubar` provided a helpful function to convert genetic code in `Biostrings` to a handy table and an option to visualize possible codon-anticodon pairing.
```{r}
# get codon table for the standard genetic code
ctab <- get_codon_table(gcid = '1')
# plot possible codon and anticodon pairings
plot_ca_pairing(ctab)
```
Alternatively, user can create a custom genetic code table by providing a mapping between amino acids and codons.
```{r}
# example of a custom mapping
head(aa2codon)
# create a custom codon table
custom_ctab <- create_codon_table(aa2codon)
head(custom_ctab)
```
### Codon usage indices
Most indices can be calculate with `get_*` series functions and the return value is usually a vector with value names identical to the names of sequences. Here we demonstrate how to calculate various indices with the above yeast CDS data.
#### Effective Number of Codons (ENC)
```{r}
# get enc
enc <- get_enc(yeast_cf)
head(enc)
plot_dist <- function(x, xlab = 'values'){
x <- stack(x)
ggplot(x, aes(x = values)) +
geom_histogram(bins = 40, fill = '#88CCEE') +
labs(x = xlab, y = 'Number of genes') +
theme_classic(base_size = 12) +
theme(axis.text = element_text(color = 'black'))
}
plot_dist(enc, 'ENC')
```
#### Fraction of optimal codons (Fop)
```{r}
# get fop
fop <- get_fop(yeast_cf)
plot_dist(fop, 'Fop')
```
`cubar` provides a method to determine the optimal (or "preferred") codon for each codon subfamily based on regression of codon usage against scores for genes. Preferred codons are more likely to be used in genes with high scores. Consequently, preferred codons will have positive coefficients in the regression analysis. Users can provide a vector of their own gene scores, for example, `log1p`-transformed gene expression levels (RPKM or TPM). It worthy noting that the order of gene scores should match the order of genes in the codon frequency matrix. Otherwise, the results will be meaningless. If gene scores were not provided, `cubar` will use the opposite of ENC by default (so that genes with stronger codon usage bias have larger scores).
To view the optimal codons, you can manually run the `est_optimal_codons` function.
```{r}
optimal_codons <- est_optimal_codons(yeast_cf, codon_table = ctab)
head(optimal_codons[optimal == TRUE])
```
#### Codon Adaptation Index (CAI)
```{r}
# estimate RSCU of highly expressed genes
yeast_exp <- as.data.table(yeast_exp)
yeast_exp <- yeast_exp[gene_id %in% rownames(yeast_cf), ]
yeast_heg <- head(yeast_exp[order(-fpkm), ], n = 500)
rscu_heg <- est_rscu(yeast_cf[yeast_heg$gene_id, ], codon_table = ctab)
head(rscu_heg) # RSCU values are shown in the column `rscu`
# calculate CAI of all genes
# note: CAI values are usually calculated based RSCU of highly expressed genes.
cai <- get_cai(yeast_cf, rscu = rscu_heg)
plot_dist(cai, xlab = 'CAI')
```
#### tRNA Adaptation Index (tAI)
```{r}
# get tRNA gene copy number from GtRNADB
trna_gcn <- table(data.table::tstrsplit(sub(' .*', '', names(yeast_trna)), '-')[[3]])
trna_gcn <- trna_gcn[names(trna_gcn) != 'NNN'] # copy of each anticodon
# calculate tRNA weight for each codon
trna_w <- est_trna_weight(trna_level = trna_gcn, codon_table = ctab)
# get tAI
tai <- get_tai(yeast_cf, trna_w = trna_w)
plot_dist(tai, 'tAI')
```
Note that cubar has an internal copy of yeast_trna. You can also download mature tRNA sequences from the GtRNADB website (if you are lucky to have good internet connection) and read them into R using the following code:
```{r}
# path_gtrnadb <- 'http://gtrnadb.ucsc.edu/genomes/eukaryota/Scere3/sacCer3-mature-tRNAs.fa'
# yeast_trna <- Biostrings::readRNAStringSet(path_gtrnadb)
```
#### Correlation between indices
```{r}
pairs(cbind(CAI = cai, ENC = enc, Fop = fop, TAI = tai),
cex = 0.5, col = alpha('black', 0.2))
```
### Utilities
#### Test of differential usage
`cubar` provides a function to test for differential codon usage between two sets of sequences. The function `codon_diff` calculates the odds ratio and p-value for each codon, comparing the usage in the two sets of sequences. The function returns a data table with the results of the global, family, and subfamily tests.
Here, we compare the codon usage of lowly expressed genes with highly expressed genes in yeast.
```{r}
# get lowly expressed genes
yeast_leg <- head(yeast_exp[order(fpkm), ], n = 500)
yeast_leg <- yeast_leg[gene_id %in% rownames(yeast_cf), ]
# differetial usage test
du_test <- codon_diff(yeast_cds_qc[yeast_heg$gene_id], yeast_cds_qc[yeast_leg$gene_id])
du_test <- du_test[amino_acid != '*', ]
```
The results of the differential usage test can be visualized using a bar plot of the odds ratios for each codon. Codons with odds ratios greater than 1 are used more frequently in the highly expressed genes, while codons with odds ratios less than 1 are used more frequently in the lowly expressed genes.
```{r}
du_test$codon <- factor(du_test$codon, levels = du_test[order(-global_or), codon])
ggplot(du_test, aes(x = codon, y = log2(global_or))) +
geom_col() +
labs(x = NULL, y = 'log2(OR)') +
theme_classic(base_size = 12) +
theme(axis.text = element_text(color = 'black'),
axis.text.x = element_text(angle = 90, vjust = 0.5, hjust = 1))
```
`cubar` also tests for differences in codon usage at the family and subfamily levels.
```{r}
du_test2 <- du_test[!amino_acid %in% c('Met', 'Trp'), ]
du_test2$codon <- factor(du_test2$codon, levels = du_test2[order(-fam_or), codon])
ggplot(du_test2, aes(x = codon, y = log2(fam_or))) +
geom_col() +
labs(x = NULL, y = 'log2(OR)') +
facet_grid(cols = vars(amino_acid), space = 'free', scales = 'free', drop = TRUE) +
theme_light() +
theme(axis.text.x = element_text(angle = 90, vjust = 0.5, hjust = 1))
```
#### Codon usage optimization
`cubar` provides a function to optimize codon usage for heterologous expression. Here is an example of optimizing the codon usage of the yeast gene YFR025C (HIS2) based on the optimal codons calculated earlier.
```{r}
# optimize codon usage to the optimal codon of each amino acid
opc_aa <- est_optimal_codons(yeast_cf, codon_table = ctab, level = 'amino_acid')
seq_optimized <- codon_optimize(yeast_cds_qc[['YFR025C']], optimal_codons, level = 'amino_acid')
# CAI before and after optimization
plot_dist(cai, 'CAI') +
geom_vline(xintercept = cai['YFR025C'], linetype = 'dashed', color = 'red') + # before
geom_vline(xintercept = get_cai(count_codons(seq_optimized), rscu_heg),
linetype = 'dashed', color = 'black') # after
```
#### Sliding-window analysis
`cubar` provides a function to perform a sliding-window analysis of codon usage bias. This analysis can be useful for identifying regions of a gene that exhibit distinct codon usage patterns. Here, we demonstrate how to perform a sliding-window analysis on YLR106C, one of the longest yeast genes.
```{r}
swa <- slide_apply(yeast_cds_qc[['YHR099W']], .f = get_cai,
step = 30, before = 20, after = 20, rscu = rscu_heg)
# plot the results
slide_plot(swa, 'CAI')
```
### FAQ
What do families and subfamilies mean in `cubar`?
> A codon family is the set of codons encoding the same amino acid. For a large codon family that has more than four synonymous codons, `cubar` will break it into two subfamilies depending on the first two nucleotides of codons. For example, leucine is encoded by six codons in the standard genetic code. `cubar` will break the six codons into two subfamilies: `Leu_UU` for `UUA` and `UUG`; `Leu_CU` for `CUU`, `CUC`, `CUA`, and `CUG`. Unless otherwise stated, codon weights for most indices are calculated at the subfamily level. However, there are options to estimate optimal codons and perform codon optimization at the family level to suit different user needs.