---
title: "HIBAG -- an R Package for HLA Genotype Imputation with Attribute Bagging"
author: "Dr. Xiuwen Zheng"
date: "May 3, 2018"
output:
html_document:
theme: default
highlight: tango
toc: yes
pdf_document:
toc: yes
toc_depth: 3
bibliography: HIBAG_Ref.bib
vignette: >
%\VignetteIndexEntry{HIBAG vignette html}
%\VignetteKeywords{HLA, MHC, Imputation, SNP, GWAS}
%\VignetteEngine{knitr::rmarkdown}
---
# Overview
The human leukocyte antigen (HLA) system, located in the major histocompatibility complex (MHC) on chromosome 6p21.3, is highly polymorphic. This region has been shown to be important in human disease, adverse drug reactions and organ transplantation [@Shiina09]. HLA genes play a role in the immune system and autoimmunity as they are central to the presentation of antigens for recognition by T cells. Since they have to provide defense against a great diversity of environmental microbes, HLA genes must be able to present a wide range of peptides. Evolutionary pressure at these loci have given rise to a great deal of functional diversity. For example, the *HLA--B* locus has 1,898 four-digit alleles listed in the April 2012 release of the IMGT-HLA Database [@Robinson13] ([http://www.ebi.ac.uk/imgt/hla/](http://www.ebi.ac.uk/imgt/hla/)).
Classical HLA genotyping methodologies have been predominantly developed for tissue typing purposes, with sequence based typing (SBT) approaches currently considered the gold standard. While there is widespread availability of vendors offering HLA genotyping services, the complexities involved in performing this to the standard required for diagnostic purposes make using a SBT approach time-consuming and cost-prohibitive for most research studies wishing to look in detail at the involvement of classical HLA genes in disease.
Here we introduce a new prediction method for **H**LA **I**mputation using attribute **BAG**ging, HIBAG, that is highly accurate, computationally tractable, and can be used with published parameter estimates, eliminating the need to access large training samples [@Zheng13]. It relies on a training set with known HLA and SNP genotypes, and combines the concepts of attribute bagging with haplotype inference from unphased SNPs and HLA types. Attribute bagging is a technique for improving the accuracy and stability of classifier ensembles using bootstrap aggregating and random variable selection [@Breiman96; @Breiman01; @Bryll03]. In this case, individual classifiers are created which utilize a subset of SNPs to predict HLA types and haplotype frequencies estimated from a training data set of SNPs and HLA types. Each of the classifiers employs a variable selection algorithm with a random component to select a subset of the SNPs. HLA type predictions are determined by maximizing the average posterior probabilities from all classifiers.
# Features
* HIBAG can be used by researchers with published parameter estimates ([http://www.biostat.washington.edu/~bsweir/HIBAG/](http://www.biostat.washington.edu/~bsweir/HIBAG/)) instead of requiring access to large training sample datasets.
* A typical HIBAG parameter file contains only haplotype frequencies at different SNP subsets rather than individual training genotypes.
* SNPs within the xMHC region (chromosome 6) are used for imputation.
* HIBAG employs unphased genotypes of unrelated individuals as a training set.
* HIBAG supports parallel computing with R.
# Examples
```{r echo=FALSE}
options(width=110)
```
```{r}
library(HIBAG)
```
## Pre-fit HIBAG Models for HLA Imputation
```{r fig.width=10, fig.height=5, fig.align='center'}
# load the published parameter estimates from European ancestry
# e.g., filename <- "HumanOmniExpressExome-European-HLA4-hg19.RData"
# here, we use example data in the package
filename <- system.file("extdata", "ModelList.RData", package="HIBAG")
model.list <- get(load(filename))
# HLA imputation at HLA-A
hla.id <- "A"
model <- hlaModelFromObj(model.list[[hla.id]])
summary(model)
# SNPs in the model
head(model$snp.id)
head(model$snp.position)
```
```{r eval=FALSE}
#########################################################################
# Import your PLINK BED file
#
yourgeno <- hlaBED2Geno(bed.fn=".bed", fam.fn=".fam", bim.fn=".bim")
summary(yourgeno)
# best-guess genotypes and all posterior probabilities
pred.guess <- predict(model, yourgeno, type="response+prob")
summary(pred.guess)
pred.guess$value
pred.guess$postprob
```
## Build a HIBAG Model for HLA Genotype Imputation
```{r eval=FALSE}
library(HIBAG)
# load HLA types and SNP genotypes in the package
data(HLA_Type_Table, package="HIBAG")
data(HapMap_CEU_Geno, package="HIBAG")
# a list of HLA genotypes
# e.g., train.HLA <- hlaAllele(sample.id, H1=c("01:02", "05:01", ...),
# H2=c("02:01", "03:01", ...), locus="A")
# the HLA type of the first individual is 01:02/02:01,
# the second is 05:01/03:01, ...
hla.id <- "A"
train.HLA <- hlaAllele(HLA_Type_Table$sample.id,
H1 = HLA_Type_Table[, paste(hla.id, ".1", sep="")],
H2 = HLA_Type_Table[, paste(hla.id, ".2", sep="")],
locus=hla.id, assembly="hg19")
# selected SNPs:
# the flanking region of 500kb on each side,
# or an appropriate flanking size without sacrificing predictive accuracy
region <- 500 # kb
snpid <- hlaFlankingSNP(HapMap_CEU_Geno$snp.id,
HapMap_CEU_Geno$snp.position, hla.id, region*1000, assembly="hg19")
length(snpid)
# training genotypes
# import your PLINK BED file,
# e.g., train.geno <- hlaBED2Geno(bed.fn=".bed", fam.fn=".fam", bim.fn=".bim")
# or,
train.geno <- hlaGenoSubset(HapMap_CEU_Geno,
snp.sel = match(snpid, HapMap_CEU_Geno$snp.id))
summary(train.geno)
# train a HIBAG model
set.seed(100)
model <- hlaAttrBagging(train.HLA, train.geno, nclassifier=100)
```
```{r echo=FALSE}
mobj <- get(load(system.file("extdata", "ModelList.RData", package="HIBAG")))
model <- hlaModelFromObj(mobj$A)
```
```{r}
summary(model)
```
## Build and Predict in Parallel
```{r eval=FALSE}
library(HIBAG)
library(parallel)
# load HLA types and SNP genotypes in the package
data(HLA_Type_Table, package="HIBAG")
data(HapMap_CEU_Geno, package="HIBAG")
# a list of HLA genotypes
# e.g., train.HLA <- hlaAllele(sample.id, H1=c("01:02", "05:01", ...),
# H2=c("02:01", "03:01", ...), locus="A")
# the HLA type of the first individual is 01:02/02:01,
# the second is 05:01/03:01, ...
hla.id <- "A"
train.HLA <- hlaAllele(HLA_Type_Table$sample.id,
H1 = HLA_Type_Table[, paste(hla.id, ".1", sep="")],
H2 = HLA_Type_Table[, paste(hla.id, ".2", sep="")],
locus=hla.id, assembly="hg19")
# selected SNPs:
# the flanking region of 500kb on each side,
# or an appropriate flanking size without sacrificing predictive accuracy
region <- 500 # kb
snpid <- hlaFlankingSNP(HapMap_CEU_Geno$snp.id,
HapMap_CEU_Geno$snp.position, hla.id, region*1000, assembly="hg19")
length(snpid)
# training genotypes
# import your PLINK BED file,
# e.g., train.geno <- hlaBED2Geno(bed.fn=".bed", fam.fn=".fam", bim.fn=".bim")
# or,
train.geno <- hlaGenoSubset(HapMap_CEU_Geno,
snp.sel = match(snpid, HapMap_CEU_Geno$snp.id))
summary(train.geno)
# Create an environment with an appropriate cluster size,
# e.g., 2 -- # of (CPU) cores
cl <- makeCluster(2)
# Building ...
set.seed(1000)
hlaParallelAttrBagging(cl, train.HLA, train.geno, nclassifier=100,
auto.save="AutoSaveModel.RData", stop.cluster=TRUE)
model.obj <- get(load("AutoSaveModel.RData"))
model <- hlaModelFromObj(model.obj)
summary(model)
```
```R
# best-guess genotypes and all posterior probabilities
pred.guess <- predict(model, yourgeno, type="response+prob", cl=cl)
```
## Evaluate Overall Accuracy, Sensitivity, Specificity, etc
The function `hlaReport()` can be used to automatically generate a tex or HTML report when a validation dataset is available.
```{r}
library(HIBAG)
# load HLA types and SNP genotypes in the package
data(HLA_Type_Table, package="HIBAG")
data(HapMap_CEU_Geno, package="HIBAG")
# make a list of HLA types
hla.id <- "A"
hla <- hlaAllele(HLA_Type_Table$sample.id,
H1 = HLA_Type_Table[, paste(hla.id, ".1", sep="")],
H2 = HLA_Type_Table[, paste(hla.id, ".2", sep="")],
locus=hla.id, assembly="hg19")
# divide HLA types randomly
set.seed(100)
hlatab <- hlaSplitAllele(hla, train.prop=0.5)
names(hlatab)
summary(hlatab$training)
summary(hlatab$validation)
# SNP predictors within the flanking region on each side
region <- 500 # kb
snpid <- hlaFlankingSNP(HapMap_CEU_Geno$snp.id,
HapMap_CEU_Geno$snp.position, hla.id, region*1000, assembly="hg19")
length(snpid)
# training and validation genotypes
train.geno <- hlaGenoSubset(HapMap_CEU_Geno,
snp.sel = match(snpid, HapMap_CEU_Geno$snp.id),
samp.sel = match(hlatab$training$value$sample.id,
HapMap_CEU_Geno$sample.id))
summary(train.geno)
test.geno <- hlaGenoSubset(HapMap_CEU_Geno, samp.sel=match(
hlatab$validation$value$sample.id, HapMap_CEU_Geno$sample.id))
```
```{r eval=FALSE}
# train a HIBAG model
set.seed(100)
model <- hlaAttrBagging(hlatab$training, train.geno, nclassifier=100)
```
```{r echo=FALSE}
mobj <- get(load(system.file("extdata", "OutOfBag.RData", package="HIBAG")))
model <- hlaModelFromObj(mobj)
```
```{r}
summary(model)
# validation
pred <- predict(model, test.geno)
summary(pred)
# compare
comp <- hlaCompareAllele(hlatab$validation, pred, allele.limit=model,
call.threshold=0)
comp$overall
```
### Evaluation in Figures
The distance matrix is calculated based on the haplotype similarity carrying HLA alleles:
```{r fig.align="center", fig.height=4, fig.width=5}
# hierarchical cluster analysis
d <- hlaDistance(model)
p <- hclust(as.dist(d))
plot(p, xlab="HLA alleles")
```
```{r fig.align="center", fig.height=3.3, fig.width=5}
# violin plot
hlaReportPlot(pred, model=model, fig="matching")
```
Matching proportion is a measure or proportion describing how the SNP profile matches the SNP haplotypes observed in the training set, i.e., the likelihood of SNP profile in a random-mating population consisting of training haplotypes. It is not directly related to confidence score, but a very low value of matching indicates that it is underrepresented in the training set.
```{r fig.align="center", fig.height=3.3, fig.width=5}
hlaReportPlot(pred, hlatab$validation, fig="call.rate")
hlaReportPlot(pred, hlatab$validation, fig="call.threshold")
```
### Report in Text
Output to plain text format:
```{r}
# report overall accuracy, per-allele sensitivity, specificity, etc
hlaReport(comp, type="txt")
```
### Report in Markdown
Output to a markdown file:
```{r results='asis'}
# report overall accuracy, per-allele sensitivity, specificity, etc
hlaReport(comp, type="markdown")
```
### Report in LaTeX
Output to a tex file, and please add `\usepackage{longtable}` to your tex file:
```{r}
# report overall accuracy, per-allele sensitivity, specificity, etc
hlaReport(comp, type="tex", header=FALSE)
```
## Release HIBAG Models without Confidential Information
```{r eval=FALSE}
library(HIBAG)
# make a list of HLA types
hla.id <- "DQA1"
hla <- hlaAllele(HLA_Type_Table$sample.id,
H1 = HLA_Type_Table[, paste(hla.id, ".1", sep="")],
H2 = HLA_Type_Table[, paste(hla.id, ".2", sep="")],
locus = hla.id, assembly = "hg19")
# training genotypes
region <- 500 # kb
snpid <- hlaFlankingSNP(HapMap_CEU_Geno$snp.id, HapMap_CEU_Geno$snp.position,
hla.id, region*1000, assembly="hg19")
train.geno <- hlaGenoSubset(HapMap_CEU_Geno,
snp.sel = match(snpid, HapMap_CEU_Geno$snp.id),
samp.sel = match(hla$value$sample.id, HapMap_CEU_Geno$sample.id))
set.seed(1000)
model <- hlaAttrBagging(hla, train.geno, nclassifier=100)
summary(model)
# remove unused SNPs and sample IDs from the model
mobj <- hlaPublish(model,
platform = "Illumina 1M Duo",
information = "Training set -- HapMap Phase II",
warning = NULL,
rm.unused.snp=TRUE, anonymize=TRUE)
save(mobj, file="Your_HIBAG_Model.RData")
```
## Release a Collection of HIBAG Models
```{r eval=FALSE}
# assume the HIBAG models are stored in R objects: mobj.A, mobj.B, ...
ModelList <- list()
ModelList[["A"]] <- mobj.A
ModelList[["B"]] <- mobj.B
...
# save to an R data file
save(ModelList, file="HIBAG_Model_List.RData")
```
## Association Tests
In the association tests of HLA allele, four models (dominant, additive, recessive and genotype) are allowed, and linear/logistic regressions can be conducted according to the dependent variable.
| Model | Description (given a specific HLA allele h) |
|:----------|:--------------------------------------------|
| dominant | [-/-] vs. [-/h,h/h] (0 vs. 1 in design matrix) |
| additive | [-] vs. [h] in Chi-squared and Fisher's exact test, the allele dosage in regressions (0: -/-, 1: -/h, 2: h/h in design matrix) |
| recessive | [-/-,-/h] vs. [h/h] (0 vs. 1 in design matrix) |
| genotype | three categories: [-/-], [-/h], [h/h] |
```{r echo=FALSE}
fn <- system.file("doc", "case_control.txt", package="HIBAG")
```
```R
# prepare data
fn <- "case_control.txt"
# or fn <- system.file("doc", "case_control.txt", package="HIBAG")
```
The example text file: [case_control.txt](case_control.txt).
```{r}
dat <- read.table(fn, header=TRUE, stringsAsFactors=FALSE)
head(dat)
# make an object for hlaAssocTest
hla <- hlaAllele(dat$sample.id, H1=dat$A, H2=dat$A.1, locus="A", assembly="hg19", prob=dat$prob)
summary(hla)
```
Or the best-guess HLA genotypes from `predict()` or `hlaPredict()`:
```R
hla <- predict(model, yourgeno)
```
### Allelic Association
`h` in the formula is denoted for HLA genotypes. Pearson's Chi-squared and Fisher's exact test will be performed if the dependent variable is categorial, while two-sample t test or ANOVA F test will be used for continuous dependent variables.
```{r}
hlaAssocTest(hla, disease ~ h, data=dat) # 95% confidence interval (h.2.5%, h.97.5%)
# show details
print(hlaAssocTest(hla, disease ~ h, data=dat, verbose=FALSE))
hlaAssocTest(hla, disease ~ h, data=dat, prob.threshold=0.5) # regression with a threshold
hlaAssocTest(hla, disease ~ h, data=dat, showOR=TRUE) # report odd ratio instead of log odd ratio
hlaAssocTest(hla, disease ~ h + pc1, data=dat) # confounding variable pc1
hlaAssocTest(hla, disease ~ h, data=dat, model="additive") # use an additive model
hlaAssocTest(hla, trait ~ h, data=dat) # continuous outcome
```
### Amino Acid Association
We convert [P-coded](http://hla.alleles.org/alleles/p_groups.html) alleles to amino acid sequences. `hlaConvSequence(..., code="P.code.merge")` returns the protein sequence in the 'antigen binding domains' (exons 2 and 3 for HLA Class I genes, exon 2 for HLA Class II genes).
```{r}
aa <- hlaConvSequence(hla, code="P.code.merge")
```
1. the sequence is displayed as a hyphen (-) where it is identical to the reference.
2. an insertion or deletion is represented by a period (.).
3. an unknown or ambiguous position in the alignment is represented by an asterisk (*).
4. a capital X is used for the 'stop' codons in protein alignments.
```{r}
head(c(aa$value$allele1, aa$value$allele2))
# show cross tabulation at each amino acid position
summary(aa)
# association tests
hlaAssocTest(aa, disease ~ h, data=dat, model="dominant") # try dominant models
hlaAssocTest(aa, disease ~ h, data=dat, model="dominant", prob.threshold=0.5) # try dominant models
hlaAssocTest(aa, disease ~ h, data=dat, model="recessive") # try recessive models
```
# Resources
* Allele Frequency Net Database (AFND): [http://www.allelefrequencies.net](http://www.allelefrequencies.net).
* IMGT/HLA Database: [http://www.ebi.ac.uk/imgt/hla](http://www.ebi.ac.uk/imgt/hla).
* HLA Nomenclature: [G Codes](http://hla.alleles.org/alleles/g_groups.html) and [P Codes](http://hla.alleles.org/alleles/p_groups.html) for reporting of ambiguous allele typings.
# Session Info
```{r}
sessionInfo()
```