asymLD package for R computes asymmetric LD measures (ALD) for multi-allelic genetic data. These measures are identical to the correlation measure (r) for bi-allelic data. We first described the ALD measure in the following article:
Thomson, Glenys, and Richard M. Single. "Conditional Asymmetric Linkage Disequilibrium (ALD): Extending the Biallelic r2 Measure." Genetics 198.1 (2014): 321-331.link
Abstract For multiallelic loci, standard measures of linkage disequilibrium provide an incomplete description of the correlation of variation at two loci, especially when there are different numbers of alleles at the two loci. We have developed a complementary pair of conditional asymmetric linkage disequilibrium (ALD) measures. Since these measures do not assume symmetry, they more accurately describe the correlation between two loci and can identify heterogeneity in genetic variation not captured by other symmetric measures. For biallelic loci the ALD are symmetric and equivalent to the correlation coefficient r. The ALD measures are particularly relevant for disease-association studies to identify cases in which an analysis can be stratified by one of more loci. A stratified analysis can aid in detecting primary disease-predisposing genes and additional disease genes in a genetic region. The ALD measures are also informative for detecting selection acting independently on loci in high linkage disequilibrium or on specific amino acids within genes. For SNP data, the ALD statistics provide a measure of linkage disequilibrium on the same scale for comparisons among SNPs, among SNPs and more polymorphic loci, among haplotype blocks of SNPs, and for fine mapping of disease genes. The ALD measures, combined with haplotype-specific homozygosity, will be increasingly useful as next-generation sequencing methods identify additional allelic variation throughout the genome.
To compute ALD in a data set, you can use the function compute.ALD within the asymLD package, as follows:
ald.results <- compute.ALD(dat, tolerance = 0.005)
Parameter dat is a data.frame with 5 required variables:
Parameter tolerance is a threshold for the sum of the haplotype frequencies. If the sum of the haplotype frequencies is greater than 1+tolerance or less than 1-tolerance an error is returned.
The function returns a dataframe (in the above example ald.results) with the following components:
This is an example of ALD measure using haplotype frequencies from Wilson (2010)
library(asymLD)
data(hla.freqs)
hla.a_b <- hla.freqs[hla.freqs$locus1=="A" & hla.freqs$locus2=="B",]
head(hla.a_b)
## haplo.freq locus1 locus2 allele1 allele2
## 170 0.06189 A B 0101 0801
## 171 0.04563 A B 0201 4402
## 172 0.04318 A B 0301 0702
## 173 0.03103 A B 0201 4001
## 174 0.02761 A B 0301 3501
## 175 0.01929 A B 0205 1503
compute.ALD(hla.a_b)
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 A B 0.1021811 0.340332 0.04876543 0.1903394 0.5150291 0.3857872
hla.c_b <- hla.freqs[hla.freqs$locus1=="C" & hla.freqs$locus2=="B",]
compute.ALD(hla.c_b)
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 C B 0.08637241 0.7350216 0.05040254 0.4520268 0.8425979 0.6503396
Note that there is substantially less variablity (higher ALD) for HLA*C conditional on HLA*B than for HLA*B conditional on HLA*C, indicating that the overall variation for C is relatively low given specific B alleles.
This is an example using SNP data where results are symmetric and equal to the ordinary correlation measure (r).
data(snp.freqs)
snps <- c("rs1548306", "rs6923504", "rs4434496", "rs7766854")
compute.ALD(snp.freqs[snp.freqs$locus1==snps[2] & snp.freqs$locus2==snps[3],])
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs6923504 rs4434496 0.5385803 0.5971276 0.700556 0.738551 0.3562095 0.3562095
snp.freqs$locus <- paste(snp.freqs$locus1, snp.freqs$locus2, sep="-")
by(snp.freqs,list(snp.freqs$locus),compute.ALD)
## : rs1548306-rs4434496
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs1548306 rs4434496 0.5593208 0.5869306 0.7005549 0.719316 0.2503054 0.2503054
## --------------------------------------------------------
## : rs1548306-rs6923504
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs1548306 rs6923504 0.5593208 0.6528273 0.5385803 0.6364877 0.4606378 0.4606378
## --------------------------------------------------------
## : rs1548306-rs7766854
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs1548306 rs7766854 0.5593208 0.5869306 0.7005549 0.719316 0.2503054 0.2503054
## --------------------------------------------------------
## : rs4434496-rs7766854
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs4434496 rs7766854 0.700556 1 0.700556 1 1 1
## --------------------------------------------------------
## : rs6923504-rs4434496
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs6923504 rs4434496 0.5385803 0.5971276 0.700556 0.738551 0.3562095 0.3562095
## --------------------------------------------------------
## : rs6923504-rs7766854
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs6923504 rs7766854 0.5385803 0.5971276 0.700556 0.738551 0.3562095 0.3562095
Note that in all of the above examples ALD.1.2 is equal to ALD.2.1 due to symmetry in the SNP data.
In the following example we show that the ALD measures are equal to the r correlation due to symmetry for bi-allelic SNPs.
p.AB <- snp.freqs$haplo.freq[1]
p.Ab <- snp.freqs$haplo.freq[2]
p.aB <- snp.freqs$haplo.freq[3]
p.ab <- snp.freqs$haplo.freq[4]
p.A <- p.AB + p.Ab
p.B <- p.AB + p.aB
r.squared <- (p.AB - p.A*p.B)^2 / (p.A*(1-p.A)*p.B*(1-p.B))
sqrt(r.squared) #the r correlation measure
## [1] 0.4606378
compute.ALD(snp.freqs[snp.freqs$locus1==snps[1] & snp.freqs$locus2==snps[2],])
## locus1 locus2 F.1 F.1.2 F.2 F.2.1 ALD.1.2 ALD.2.1
## 1 rs1548306 rs6923504 0.5593208 0.6528273 0.5385803 0.6364877 0.4606378 0.4606378