HiCcompare
VignetteHiCcompare
provides functions for the joint
normalization and detection of differential chromatin interactions
between two or multiple Hi-C datasets. HiCcompare
operates
on processed Hi-C data in the form of chromosome-specific chromatin
interaction matrices. It accepts three-column tab-separated text files
storing chromatin interaction matrices in a sparse matrix format (see Creating the hic.table object). Functions to
convert popular Hi-C data formats (.hic
,
.cool
) to sparse format are available (see ?cooler2sparse).
HiCcompare
differs from other packages that attempt to
compare Hi-C data in that it works on processed data in chromatin
interaction matrix format instead of pre-processed sequencing data. In
addition, HiCcompare
provides a non-parametric method for
the joint normalization and removal of biases between two Hi-C datasets
for the purpose of comparative analysis. HiCcompare
also
provides a simple yet robust permutation method for detecting
differences between Hi-C datasets.
The hic_loess
function outputs normalized chromatin
interactions for both matrices ready for the comparative analysis. The
hic_compare
function performs the comparative analysis and
outputs genomic coordinates of pairs of regions detected as
differentially interacting, interaction frequencies, the difference and
the corresponding permutation p-value.
HiCcompare
Install HiCcompare
from Bioconductor.
You will need processed Hi-C data in the form of sparse upper
triangular matrices or BEDPE files in order to use
HiCcompare
. Data is available from several sources and two
examples for downloading and extracting data are listed below. If you
have full Hi-C contact matrices you can convert them to sparse upper
triangular format using the full full2sparse
function as
shown in additional functions
.hic
filesHi-C data is available from several sources and in many formats.
HiCcompare
is built to work with the sparse upper
triangular matrix format popularized by the lab of Erez Lieberman-Aiden
http://aidenlab.org/data.html.
If you already have Hi-C data either in the form of a sparse upper
triangular matrix or a full contact matrix you can skip to the Creating the hic.table object section. If you
obtain data from the Aiden Lab in the .hic
format you will
need to first extract the matrices that you wish to compare.
straw
software from https://github.com/theaidenlab/straw/wiki
and install it.straw
to extract a Hi-C sparse upper triangular
matrix. An example is below:Say we downloaded the GSE63525_K562_combined_30.hic
file
from GEO https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE63525
To extract the raw matrix corresponding to chromosome 22 at 500kb resolution we would use the following command within the terminal
./straw NONE GSE63525_K562_combined_30.hic 22 22 BP 500000 > K562.chr22.500kb.txt
This will extract the matrix from the .hic
file and save
it to the K562.chr22.500kb.txt
text file, in the sparse
upper triangular matrix format. See more examples on on how to use
straw
at https://github.com/theaidenlab/straw/wiki/CPP#running.
Straw requires several inputs for the extraction of data from a
.hic
file.
<NONE/VC/VC_SQRT/KR> <hicFile(s)> <chr1>[:x1:x2] <chr2>[:y1:y2] <BP/FRAG> <binsize>
The first argument is the normalization method. For use in
HiCcompare
you want the raw data so you should selected
NONE
. The second argument is the .hic
file
name. Next is the chromosome numbers of the matrix you want. For an
intrachromosomal contact map both should be the same as in the above
example. If you want a matrix of interchromosomal interactions you can
use different chromosomes i.e. interactions between chromosome 1 and
chromosome 2 (Note that HiCcompare
is only meant to be used
on intrachromosomal interactions at this point in development). The next
argument is whether you want basepair or fragment files. For
HiCcompare
use BP
. The final argument is the
binsize of the matrix (the resolution). To extract a matrix at a
resolution of 1MB enter 10000000
. Typical bin sizes are
1MB, 500KB, 100KB, 50KB, 5KB, 1KB. Note that most matrices with
resolutions higher than 100KB (i.e. matrices with resolutions of 1KB -
50KB) are typically too sparse (due to insufficient sequencing coverage)
for analysis in HiCcompare
.
From here we can just import the matrix into R as you would normally for any tab-delimited file.
K562.chr22 <- read.table('K562.chr22.500kb.txt', header=FALSE)
HiCcompare
, then proceed
to Creating the hic.table
object..cool
filesThe cooler
software, http://cooler.readthedocs.io/en/latest/index.html,
allows access to a large collection of Hi-C data. The cooler index ftp://cooler.csail.mit.edu/coolers
contains Hi-C data for hg19
and mm9
from many
different sources.
.cool
files can be read directly into R using the
cooler2bedpe
function provided by
HiCcompare
.
Alternatively, data in the .cool
format can be import
into HiCcompare
using the following steps:
cooler
from http://cooler.readthedocs.io/en/latest/index.htmlGSM5981806_HiC_UT242.cool
file from GEO GSE199695.cooler dump --help
for data extraction options. To
extract the contact matrix we use the following commands in the
terminal:cooler dump --join GSM5981806_HiC_UT242.cool > GSM5981806_HiC_UT242.txt
UT242 <- read.table(fileNameIn1, header = FALSE)
. Subset
for speed,
UT242 <- UT242[UT242$V1 == "chr2" & UT242$V4 == "chr2", ]
HiCcompare::cooler2sparse
function.sparse <- cooler2sparse(UT242)
hic.table
object.HiC-Pro is another tool for processing raw Hi-C data into usable
matrix files. HiC-Pro will produce a .matrix
file and a
.bed
file for the data. These .matrix
files
are in sparse upper triangular format similar to the results of Juicer
and the dumped contents of a .hic
file, however instead of
using the genomic start coordinates for the first two columns of the
sparse matrix they use an ID number. The .bed
file contains
the mappings for each of these IDs to their genomic coordinates.
HiCcompare
includes a function to convert the results of
HiC-Pro into a usable format for analysis in HiCcompare
.
When using data from HiC-Pro it is important to use the raw
.matrix
files and NOT the iced .matrix
files.
The iced .matrix
files have already had ICE normalization
applied to them and are not suitable for entry into
HiCcompare
. Here we convert HiC-Pro data for input into
HiCcompare:
# read in files
mat <- read.table("hic_1000000.matrix")
bed <- read.table("hic_1000000_abs.bed")
# convert to BEDPE
dat <- hicpro2bedpe(mat, bed)
# NOTE: hicpro2bedpe returns a list of lists. The first list, dat$cis, contains the intrachromosomal contact matrices
# NOTE: dat$trans contains the interchromosomal contact matrix which is not used in HiCcompare.
See the help using ?hicpro2bedpe
for more details.
Before you start a HiCcompare
analysis, you may want to
detect CNV and exclude these regions along with any other regions known
to exhibit changes or undesirable sequencing characteristics which could
cause false positives. HiCcompare
provides a function to
perform a CNV detection analysis utilizing the QDNAseq
R
package. You will need to have your Hi-C data in .bam
files. This can be accomplished by downloading the raw sequencing
results and aligning them using one of the many Hi-C processing
pipelines. Once you have .bam
files place them in a
specified folder and you can then run get_CNV
. Make sure to
specify the bin size you will be using in kilobase pairs. The bin size
should be the same as the resolution of the Hi-C data that will be used
in the HiCcompare
analysis. The CNV.level
option will allow you to choose which level of CNV you would like to
exclude. The CNV calls are defined as -2 = deletion, -1 = loss, 0 =
normal, 1 = gain, 2 = amplification. In order to exclude amplifications
and deletions set CNV.level = 2
. To exclude any amount of
CNV set CNV.level = 1
.
cnv <- get_CNV(path2bam = 'path/to/bamfiles', out.file = 'path/to/bamfiles/outfile',
bin.size = 1000, genome = 'hg19', CNV.level = 2)
This function will run the CNV detection steps provided in
QDNAseq
and export a .txt
file containing the
copy number calls and a .bed
file containing the regions
detected at or above the chosen CNV level. It will also return a
data.frame containing the regions at or above the chosen CNV level. It
is recommended to exclude regions with scores of -2 or 2, however this
decision is left up to the user.
You may want to exclude the regions with CNV along with blacklisted
regions from any further analysis. HiCcompare
has the
ENCODE blacklists for hg19 and hg38 included (available using
data("hg19_blacklist")
or
data("hg38_blacklist")
). We can now create a data.frame (or
GenomicRanges
object) containing all of the regions we want
to exclude from any further analysis.
data('hg19_blacklist')
# combine cnv excluded regions with blacklist regions
exclude <- cbind(cnv, hg19_blacklist)
Now that we have a data.frame containing the regions to be excluded
we just simply set the exclude.regions
options in the
create.hic.table
function to the exclude
data.frame.
hic.table
objectA sparse matrix format represents a relatively compact and human-readable way to store pair-wise interactions. It is a tab-delimited text format containing three columns: “region1” - a start coordinate (in bp) of the first region, “region2” a start coordinate of the second region, and “IF” - the interaction frequency between them (IFs). Zero IFs are dropped (hence, the sparse format). Since the full matrix of chromatin interactions is symmetric, only the upper triangular portion, including the diagonal, is stored.
If you have two full Hi-C contact matrices you can convert them to
sparse upper triangular matrices using the
HiCcompare::full2sparse
function. Once you have two sparse
matrices you are ready to create a hic.table
object. This
will be illustrated using the included sparse matrices at 500kb
resolution for chromosome 22 from the HMEC and NHEK cell lines.
## region1 region2 IF
## 1 16000000 16000000 5
## 2 16000000 16500000 2
## 3 16500000 16500000 297
## 4 16000000 17000000 5
## 5 16500000 17000000 92
## 6 17000000 17000000 5690
Now that we have 2 sparse upper triangular matrices we can create the
hic.table
object. create.hic.table
requires
the input of 2 sparse matrices and the chromosome name.
# create the `hic.table` object
chr22.table <- create.hic.table(HMEC.chr22, NHEK.chr22, chr = 'chr22')
head(chr22.table)
## chr1 start1 end1 chr2 start2 end2 IF1 IF2 D M
## <char> <int> <int> <char> <int> <int> <num> <num> <num> <num>
## 1: chr22 16000000 16500000 chr22 16000000 16500000 5 5.203323 0 0.05750528
## 2: chr22 16000000 16500000 chr22 16500000 17000000 2 8.672206 1 2.11639897
## 3: chr22 16500000 17000000 chr22 16500000 17000000 297 480.440193 0 0.69389392
## 4: chr22 16000000 16500000 chr22 17000000 17500000 5 14.742750 2 1.56000562
## 5: chr22 16500000 17000000 chr22 17000000 17500000 92 277.510581 1 1.59283701
## 6: chr22 17000000 17500000 chr22 17000000 17500000 5690 9435.359752 0 0.72964887
By default, all regions for the data entered are used as is. It may
be desirable to exclude certain regions from any further analysis
because they contain CNV or are overlapping blacklisted regions with
known sequencing issues. To exclude the CNV and blacklisted regions we
defined above, create the hic.table
object as follows.
chr22.table <- create.hic.table(HMEC.chr22, NHEK.chr22, chr = 'chr22', exclude.regions = exclude, exclude.overlap = 0.2)
The exclude.overlap
option controls the percentage
overlap required with the regions listed in your data in order to be
exclude. CNV regions should in the same resolution and bins as your data
so they will overlap any of your regions by 100%. Blacklisted regions
tend to be small and may only overlap your regions by a few basepairs.
If you want any amount of overlap to result in exclusion set
exclude.overlap = 0
. To require 100% overlap before
exclusion set exclude.overlap = 1
. By default this option
will exclude regions with 20% or more overlap.
We can also list multiple hic.tables
in order to utilize
parallel computing. First we create another hic.table
as
was done above. Then we combine these two hic.tables
into a
list.
# create list of `hic.table` objects
data("HMEC.chr10")
data("NHEK.chr10")
# create the `hic.table` object
chr10.table <- create.hic.table(HMEC.chr10, NHEK.chr10, chr = 'chr10')
hic.list <- list(chr10.table, chr22.table)
head(hic.list)
## [[1]]
## chr1 start1 end1 chr2 start2 end2 IF1 IF2 D M
## <char> <int> <int> <char> <int> <int> <num> <num> <num> <num>
## 1: chr10 0 500000 chr10 0 500000 11160 1.491828e+04 0 0.4187441
## 2: chr10 0 500000 chr10 500000 1000000 3339 4.766792e+03 1 0.5136024
## 3: chr10 500000 1000000 chr10 500000 1000000 15871 1.998235e+04 0 0.3323333
## 4: chr10 0 500000 chr10 1000000 1500000 1064 6.501731e+02 2 -0.7106025
## 5: chr10 500000 1000000 chr10 1000000 1500000 2963 2.097443e+03 1 -0.4984269
## ---
## 35366: chr10 134000000 134500000 chr10 135000000 135500000 1810 1.273570e+03 2 -0.5071112
## 35367: chr10 134500000 135000000 chr10 135000000 135500000 1971 3.634653e+03 1 0.8828898
## 35368: chr10 135000000 135500000 chr10 135000000 135500000 16716 1.188368e+04 0 -0.4922479
## 35369: chr10 134000000 134500000 chr10 135500000 136000000 1 6.865608e-01 3 -0.5425406
## 35370: chr10 135000000 135500000 chr10 135500000 136000000 4 3.432804e+00 1 -0.2206125
##
## [[2]]
## chr1 start1 end1 chr2 start2 end2 IF1 IF2 D M
## <char> <int> <int> <char> <int> <int> <num> <num> <num> <num>
## 1: chr22 16000000 16500000 chr22 16000000 16500000 5 5.203323 0 0.05750528
## 2: chr22 16000000 16500000 chr22 16500000 17000000 2 8.672206 1 2.11639897
## 3: chr22 16500000 17000000 chr22 16500000 17000000 297 480.440193 0 0.69389392
## 4: chr22 16000000 16500000 chr22 17000000 17500000 5 14.742750 2 1.56000562
## 5: chr22 16500000 17000000 chr22 17000000 17500000 92 277.510581 1 1.59283701
## ---
## 2479: chr22 49000000 49500000 chr22 51000000 51500000 21 54.634896 4 1.37943338
## 2480: chr22 49500000 50000000 chr22 51000000 51500000 35 71.112086 3 1.02273986
## 2481: chr22 50000000 50500000 chr22 51000000 51500000 394 339.083241 2 -0.21655615
## 2482: chr22 50500000 51000000 chr22 51000000 51500000 4066 2741.284207 1 -0.56875831
## 2483: chr22 51000000 51500000 chr22 51000000 51500000 9916 7132.021930 0 -0.47544713
The hic.table
object contains a summary of the
differences between the two matrices. “IF1” and “IF2” correspond to
interaction frequencies in the first and second matrices, “D” is the
unit distance (length of each unit is equivalent to the resolution of
the data, e.g., 500kb), “M” is the log2(IF2) − log2(IF1)
difference.
A hic.table
object can also be created using data in the
7 column BEDPE format. An example of BEDPE data for the HMEC dataset
used above is shown below.
## chr1 start1 end1 chr2 start2 end2 IF1
## <char> <int> <int> <char> <int> <int> <num>
## 1: chr22 16000000 16500000 chr22 16000000 16500000 5
## 2: chr22 16000000 16500000 chr22 16500000 17000000 2
## 3: chr22 16500000 17000000 chr22 16500000 17000000 297
## 4: chr22 16000000 16500000 chr22 17000000 17500000 5
## 5: chr22 16500000 17000000 chr22 17000000 17500000 92
## 6: chr22 17000000 17500000 chr22 17000000 17500000 5690
To create a hic.table
object using BEDPE data is very
similar to using data in the sparse upper triangular format.
## chr1 start1 end1 chr2 start2 end2 IF1 IF2 D M
## <char> <int> <int> <char> <int> <int> <num> <num> <num> <num>
## 1: chr22 16000000 16500000 chr22 16000000 16500000 5 5.203323 0 0.05750528
## 2: chr22 16000000 16500000 chr22 16500000 17000000 2 8.672206 1 2.11639897
## 3: chr22 16500000 17000000 chr22 16500000 17000000 297 480.440193 0 0.69389392
## 4: chr22 16000000 16500000 chr22 17000000 17500000 5 14.742750 2 1.56000562
## 5: chr22 16500000 17000000 chr22 17000000 17500000 92 277.510581 1 1.59283701
## 6: chr22 17000000 17500000 chr22 17000000 17500000 5690 9435.359752 0 0.72964887
If you are using data from HiC-Pro you can create a
hic.table
object as follows.
# first dataset
mat1 <- read.table("hic1_1000000.matrix")
bed1 <- read.table("hic1_1000000_abs.bed")
dat1 <- hicpro2bedpe(mat, bed)
dat1 <- dat1$cis # extract intrachromosomal matrices
# second dataset
mat2 <- read.table("hic2_1000000.matrix")
bed2 <- read.table("hic2_1000000_abs.bed")
dat2 <- hicpro2bedpe(mat, bed)
dat2 <- dat2$cis # extract intrachromosomal matrices
# for chr1
hic.table <- create.hic.table(dat1[[1]], dat2[[1]])
# for all chromosomes
hic.list <- mapply(create.hic.table, dat1, dat2, SIMPLIFY = FALSE)
A hic.table
can also be created using an
InteractionSet
object. Simply enter two
InteractionSets
representing two Hi-C matrices into the
create.hic.table
function and they will be converted to the
proper format. See the InteractionSet
vignette for creating
InteractionSet
objects here
## GInteractions object with 6 interactions and 1 metadata column:
## seqnames1 ranges1 seqnames2 ranges2 | IF
## <Rle> <IRanges> <Rle> <IRanges> | <numeric>
## [1] chr22 16000000-16499999 --- chr22 16000000-16499999 | 5
## [2] chr22 16000000-16499999 --- chr22 16500000-16999999 | 2
## [3] chr22 16500000-16999999 --- chr22 16500000-16999999 | 297
## [4] chr22 16000000-16499999 --- chr22 17000000-17499999 | 5
## [5] chr22 16500000-16999999 --- chr22 17000000-17499999 | 92
## [6] chr22 17000000-17499999 --- chr22 17000000-17499999 | 5690
## -------
## regions: 71 ranges and 0 metadata columns
## seqinfo: 1 sequence from an unspecified genome; no seqlengths
To shorten computational time, or if one is only interested in a
subsection of a Hi-C matrix, one may wish to use a subset of the
hic.table
object. Use the subset.dist
or
subset.index
options, see help for the
create.hic.table
function.
If you are performing your HiCcompare
analysis on the
entire genome you can perform total sum scaling on the data before
performing loess normalization. This requires the use of a list of
hic.table
objects, one for each chromosome. Additionally,
when you create these hic.table
objects you must set
scale = FALSE
. Once you have your list of
hic.table
objects you can then perform total sum
scaling.
It is recommended to use total sum scaling when performing a
HiCcompare
analysis on the entire genome. If you are only
using data for a single chromosome then total sum scaling should be
equivalent to the scale
option in the
create.hic.table
function.
Now that you have created a hic.table
object you can
jointly normalize your two Hi-C matrices. The hic_loess
function has many options and can accept a single hic.table
or a list of hic.tables. If for example you wish to perform joint
normalization for every chromosome on two cell lines while utilizing
parallel computing you can create a list containing the hic.tables for
each chromosome.
To change the degree of the polynomial for the loess joint
normalization you can utilize the degree
option, default is
1 (linear regression). A user-defined span, or the amount of data used
to build the loess model, can also be set with the span
option. However if span = NA
(the default) the automatic
smoothing parameter selection process will run and determine the optimal
span for the data. The type of selection process can be changed using
the loess.criterion
option. Available settings are
gcv
(the default) for generalized cross-validation or
aicc
for Akaike information criterion. The loess automatic
smoothing parameter selection uses a customized version of the
fANCOVA::loess.as
function. For more information on
parameter selection please see the fANCOVA
reference
manual. It is recommended to use the default settings. If you have
already run hic_loess
on a dataset and know the span or
would like to use a specific span then manually setting the span to a
value can significantly reduce computation time especially for high
resolution data.
hic_loess
can utilize the BiocParallel
package to perform parallel computing and lower computation time. The
parallel
option (FALSE by default) will only speed up
computation if a list of hic.tables is entered into the function, i.e.,
it parallelizes processing of several chromosome-specific matrices. This
is useful for performing joint normalization for every chromosome
between two Hi-C datasets. For more information on
BiocParallel
see the reference manual here.
The basis of HiCcompare
rests on the novel concept
termed the MD plot. The MD plot is similar to the MA plot or the
Bland-Altman plot. M is the
log2 difference between the interaction frequencies from the two
datasets. D is the unit
distance between the two interacting regions. Loess is performed on the
data after it is represented in the MD coordinate system. To visualize
the MD plot the Plot
option can be set to TRUE.
If you wish to detect differences between the two Hi-C datasets
immediately following joint normalization you can set the
check.differences
option to TRUE. However, if you only want
to jointly normalize the data for now keep this option set to FALSE. The
difference detection process will be covered in the next section.
# Jointly normalize data for a single chromosome
hic.table <- hic_loess(chr22.table, Plot = TRUE, Plot.smooth = FALSE)
## Span for loess: 0.219052588777294
## GCV for loess: 0.000118686898199309
## AIC for loess: -0.212037314500057
## `geom_smooth()` using method = 'gam' and formula = 'y ~ s(x, bs = "cs")'
## `geom_smooth()` using method = 'gam' and formula = 'y ~ s(x, bs = "cs")'
chr1 | start1 | end1 | chr2 | start2 | end2 | IF1 | IF2 | D | M | adj.IF1 | adj.IF2 | adj.M | mc | A |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
chr22 | 16000000 | 16500000 | chr22 | 16000000 | 16500000 | 5 | 5.203323 | 0 | 0.0575053 | 5.103586 | 5.097713 | -0.0016611 | 0.0591664 | 5.100650 |
chr22 | 16000000 | 16500000 | chr22 | 16500000 | 17000000 | 2 | 8.672206 | 1 | 2.1163990 | 2.079392 | 8.341096 | 2.0040748 | 0.1123242 | 5.210244 |
chr22 | 16500000 | 17000000 | chr22 | 16500000 | 17000000 | 297 | 480.440193 | 0 | 0.6938939 | 303.153008 | 470.688840 | 0.6347275 | 0.0591664 | 386.920924 |
chr22 | 16000000 | 16500000 | chr22 | 17000000 | 17500000 | 5 | 14.742750 | 2 | 1.5600056 | 5.294664 | 13.922271 | 1.3947836 | 0.1652220 | 9.608468 |
chr22 | 16500000 | 17000000 | chr22 | 17000000 | 17500000 | 92 | 277.510581 | 1 | 1.5928370 | 95.652053 | 266.915059 | 1.4805129 | 0.1123242 | 181.283556 |
chr22 | 17000000 | 17500000 | chr22 | 17000000 | 17500000 | 5690 | 9435.359752 | 0 | 0.7296489 | 5807.880851 | 9243.853028 | 0.6704825 | 0.0591664 | 7525.866939 |
# Multiple hic.tables can be processed in parallel by entering a list of hic.tables
hic.list <- hic_loess(hic.list, parallel = TRUE)
The hic_loess
joint normalization function extends the
hic.table
with the adjusted interaction frequencies,
adjusted “M”, the “mc” correction factor, and the average expression
“A”.
the MD plot is used to represent the differences M between two normalized datasets at a distance D. Normalized M values are centered around 0 and the distribution at each distance remains fairly consistent. The M values are approximately normally distributed. M values are converted to Z-scores using the standard approach:
$$ Z_i = \frac{M_i - \bar{M}}{\sigma_M} $$ where M̄ is the mean value of all M’s on the chromosome and σM is the standard deviation of all M values on the chromosome and i is the ith interacting pair on the chromosome.
During Z-score conversion the average expression of each interacting pair is considered. Due to the nature of M, a difference represented by an interacting pair with IFs 1 and 10 is equivalent to an interacting pair of IFs 10 and 100 with both differences having an M value of 3.32. However the average expression of these two differences is 5.5 and 55, respectively. Differences with higher average expression are more trustworthy than those with low average expression due to the fact that a relatively small difference on the raw scale can lead to a large log2 fold change. Additionally since the IFs represent Hi-C sequencing reads, lower average numbers of reads are also less trustworthy. Thus we filter out differences with low average expression before calculating Z-scores when average expression (A) is less than a user set quantile (typically 5-20%) or a user set specific value of A. The Z-scores can then be converted to p-values using the standard normal distribution.
To determine how to filter your data you can use the
filter_params()
function. This will produce a plot of the
Matthews Correlation Coefficient (MCC) vs. the A minimum value filtered
out. This plot should help you determine a reasonable value to set your
filtering parameter in hic_compare
. You may need to adjust
the numChanges
option and the FC
option
depending on the resolution of the data and how noisy it is.
Here we check the filtering:
Difference detection can be performed using the
hic_compare()
function. Before difference detection you
will need to decide how you would like to filter out interactions with
low average expression. You can filter based on a specific value of A.
Once you have a normalized hic.table
or list of
hic.tables
detect differences with an A filter as
follows:
## Filtering out interactions with A < 15
If you leave the A.min = NA
then the 10th percentile of
A will be calculated and used for filtering by default. The resulting
table will display the results as shown below:
chr1 | start1 | end1 | chr2 | start2 | end2 | IF1 | IF2 | D | M | adj.IF1 | adj.IF2 | adj.M | mc | A | Z | p.value | p.adj |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
chr22 | 16000000 | 16500000 | chr22 | 16000000 | 16500000 | 5 | 5.203323 | 0 | 0.0575053 | 5.103586 | 5.097713 | -0.0016611 | 0.0591664 | 5.10065 | NA | 1.0000000 | 1.0000000 |
chr22 | 16500000 | 17000000 | chr22 | 16500000 | 17000000 | 297 | 480.440193 | 0 | 0.6938939 | 303.153008 | 470.688840 | 0.6347275 | 0.0591664 | 386.92092 | 1.2636692 | 0.2063488 | 0.8469872 |
chr22 | 17000000 | 17500000 | chr22 | 17000000 | 17500000 | 5690 | 9435.359752 | 0 | 0.7296489 | 5807.880851 | 9243.853028 | 0.6704825 | 0.0591664 | 7525.86694 | 1.3334594 | 0.1823811 | 0.8469872 |
chr22 | 17500000 | 18000000 | chr22 | 17500000 | 18000000 | 17641 | 23887.590475 | 0 | 0.4373290 | 18006.472072 | 23402.751072 | 0.3781626 | 0.0591664 | 20704.61157 | 0.7628794 | 0.4455353 | 0.8469872 |
chr22 | 18000000 | 18500000 | chr22 | 18000000 | 18500000 | 27241 | 22369.087265 | 0 | -0.2842733 | 27805.357163 | 21915.068475 | -0.3434397 | 0.0591664 | 24860.21282 | -0.6456180 | 0.5185268 | 0.8469872 |
chr22 | 18500000 | 19000000 | chr22 | 18500000 | 19000000 | 10592 | 8412.039485 | 0 | -0.3324475 | 10811.436550 | 8241.302792 | -0.3916139 | 0.0591664 | 9526.36967 | -0.7396494 | 0.4595127 | 0.8469872 |
Where Z
is the Z-score calculated for the interaction
(Z-scores with NA values result from filtering based on A),
p.value
is the un-adjusted p-value based on the standard
normal distribution, and p.adj
is the p-value after the
multiple testing correction specified was applied.
HiCcompare
results to
InteractionSet
objectsIf after running hic_loess
or hic_compare
on your data you wish to perform additional analyses which require the
GRanges
object class you can convert the results using the
make_InteractionSet
function. This function will produce an
InteractionSet
object with the genomic ranges contained in
the hic.table
along with several metadata files containing
the additional information produced by hic_loess
or
hic_compare
.
HiCcompare
includes functions for simulating Hi-C data.
The hic_simulate
function allows you to simulate two Hi-C
matrices with added bias and true differences at a specified fold
change. As an example we will simulate two matrices with 250 true
differences added at a fold change of 4.
number_of_unitdistances <- 100 # The dimensions of the square matrix to be simualted
number_of_changes <- 250 # How many cells in the matrix will have changes
i.range <- sample(1:number_of_unitdistances, number_of_changes, replace = TRUE) # Indexes of cells to have controlled changes
j.range <- sample(1:number_of_unitdistances, number_of_changes, replace = TRUE) # Indexes of cells to have controlled changes
sim_results <- hic_simulate(nrow = number_of_unitdistances, medianIF = 50000, sdIF = 14000, powerlaw.alpha = 1.8, fold.change = 4, i.range = i.range, j.range = j.range, Plot = TRUE, alpha = 0.1)
## Span for loess: 0.169321207670322
## GCV for loess: 0.000114342073241783
## AIC for loess: 0.390466662859675
## Filtering out interactions with A < 100
## True Positives: 205 Total added differences: 209 True Negatives: 4456
## TPR: 0.980861244019139
## SPC: 0.986932447397564
The results of the simulation are saved in a list.
## [1] "TPR" "SPC" "pvals" "hic.table" "true.diff" "truth" "sim.table"
TPR is the true positive rate, SPC is the specificity, pvals is a
vector of the p-values for every cell in the matrices, hic.table is the
resulting hic.table object after hic_loess
and
hic_compare
have been applied to the simulated data,
true.diff is a table for the cells that had the specified fold change
applied to them, truth is a vector of 0’s and 1’s indicating if a cell
had a true difference applied - this is useful for input into ROC
packages, sim.table is the simulated data in a hic.table object before
being scaled, normalized, and analyzed for differences.
The sim_matrix
function will produce two simulated Hi-C
matrices without performing any analysis.
HiCcompare
contains some additional functions that may
be useful.
If you do not choose to show the MD plots when you initially run
hic_loess
or hic_compare
you can use the
MD.plot1
or MD.plot2
functions.
MD.plot1
will create a side by side MD plot showing before
and after loess normalization. Enter your original M and D vectors along
with the M correction factor, mc
, calculated by
hic_loess
. The smooth
option controls if the
plot is plotted using smoothScatter
or as a
ggplot2
scatter plot.
MD.plot2
will create a standard MD plot with optional
coloring based on p-value. Just enter an M and D vector and a p-value
vector if desired.
# p-value coloring
MD.plot2(M = hic.table$adj.M, D = hic.table$D, hic.table$p.value, smooth = FALSE)
There are two matrix transformation functions included.
sparse2full
will transform a sparse upper triangular matrix
to a full Hi-C matrix. full2sparse
will transform a full
Hi-C matrix to sparse upper triangular format.
## Matrix dimensions: 71x71
## 1.6e+07 16500000 1.7e+07 17500000 1.8e+07
## 1.6e+07 6 10 17 13 1
## 16500000 10 554 320 118 23
## 1.7e+07 17 320 10880 2922 576
## 17500000 13 118 2922 27545 3693
## 1.8e+07 1 23 576 3693 25794
## region1 region2 IF
## <num> <num> <num>
## 1: 16000000 16000000 6
## 2: 16000000 16500000 10
## 3: 16500000 16500000 554
## 4: 16000000 17000000 17
## 5: 16500000 17000000 320
## 6: 17000000 17000000 10880
KRnorm
will perform Knight-Ruiz normalization on a Hi-C
matrix. Just enter the full Hi-C matrix to be normalized.
SCN
will perform Sequential Component Normalization on a
Hi-C matrix. Just enter the full Hi-C matrix to be normalized.
MA_norm
will perform MA normalization on a
hic.table
object.
Below is an example script for using HiCcompare
on a
computing cluster. The data was concatenated into a single sparse matrix
for each group, containing information for all the chromosomes.
library(HiCcompare)
library(BiocParallel)
args = commandArgs(trailingOnly=TRUE)
dat1 <- read.table(args[1], header=FALSE, col.names=c("chr1", "start1", "end1", "chr2", "start2", "end2", "IF"))
dat2 <- read.table(args[2], header=FALSE, col.names=c("chr1", "start1", "end1", "chr2", "start2", "end2", "IF"))
dat1 <- dat1[dat1$chr1==dat1$chr2, ]
dat2 <- dat2[dat2$chr1==dat2$chr2, ]
dat1 <- split(dat1, dat1$chr1)
dat2 <- split(dat2, dat2$chr1)
hic.list <- mapply(create.hic.table, dat1, dat2, SIMPLIFY = FALSE, scale=FALSE)
hic.list <- total_sum(hic.list)
register(MulticoreParam(workers = 10), default = TRUE)
hic.list <- hic_loess(hic.list, Plot=TRUE, parallel=TRUE)
hic.list <- hic_compare(hic.list, A.min = NA, adjust.dist = TRUE, p.method = 'fdr', Plot = TRUE, parallel=TRUE)
hic.list <- do.call(rbind, hic.list)
hic.list <- hic.list[hic.list$p.adj<0.05,]
write.table(hic.list, args[3])
The above can be saved as an R script and then submitted to a cluster using the following submission script.
#!/bin/sh
# Sun Grid Engine options (lines prefixed with #$)
#$ -cwd
#$ -N HiCCompare
#$ -l h_rt=06:00:00
#$ -l h_vmem=32G
#$ -pe sharedmem 11
#$ -V
Rscript 01_HiCcompare.R $1 $2 $3
Credit to Ilya Flyamer (@Phlya on
GitHub) for this example of using HiCcompare
on a
cluster.
## R version 4.4.1 (2024-06-14)
## Platform: x86_64-pc-linux-gnu
## Running under: Ubuntu 24.04.1 LTS
##
## Matrix products: default
## BLAS: /usr/lib/x86_64-linux-gnu/openblas-pthread/libblas.so.3
## LAPACK: /usr/lib/x86_64-linux-gnu/openblas-pthread/libopenblasp-r0.3.26.so; LAPACK version 3.12.0
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C LC_TIME=en_US.UTF-8 LC_COLLATE=C LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8 LC_PAPER=en_US.UTF-8 LC_NAME=C LC_ADDRESS=C LC_TELEPHONE=C LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## time zone: Etc/UTC
## tzcode source: system (glibc)
##
## attached base packages:
## [1] stats graphics grDevices utils datasets methods base
##
## other attached packages:
## [1] HiCcompare_1.29.0 dplyr_1.1.4 rmarkdown_2.28
##
## loaded via a namespace (and not attached):
## [1] SummarizedExperiment_1.35.5 gtable_0.3.6 xfun_0.48 bslib_0.8.0 ggplot2_3.5.1 rhdf5_2.49.0 Biobase_2.67.0 lattice_0.22-6 rhdf5filters_1.17.0 vctrs_0.6.5 tools_4.4.1 generics_0.1.3 stats4_4.4.1 parallel_4.4.1
## [15] tibble_3.2.1 fansi_1.0.6 highr_0.11 pkgconfig_2.0.3 pheatmap_1.0.12 Matrix_1.7-1 KernSmooth_2.23-24 data.table_1.16.2 RColorBrewer_1.1-3 S4Vectors_0.43.2 lifecycle_1.0.4 GenomeInfoDbData_1.2.13 farver_2.1.2 compiler_4.4.1
## [29] munsell_0.5.1 codetools_0.2-20 InteractionSet_1.33.0 GenomeInfoDb_1.41.2 htmltools_0.5.8.1 sys_3.4.3 buildtools_1.0.0 sass_0.4.9 yaml_2.3.10 pillar_1.9.0 crayon_1.5.3 jquerylib_0.1.4 BiocParallel_1.41.0 cachem_1.1.0
## [43] DelayedArray_0.31.14 abind_1.4-8 nlme_3.1-166 gtools_3.9.5 tidyselect_1.2.1 digest_0.6.37 labeling_0.4.3 maketools_1.3.1 splines_4.4.1 fastmap_1.2.0 grid_4.4.1 colorspace_2.1-1 cli_3.6.3 SparseArray_1.5.45
## [57] magrittr_2.0.3 S4Arrays_1.5.11 utf8_1.2.4 withr_3.0.2 UCSC.utils_1.1.0 scales_1.3.0 XVector_0.45.0 httr_1.4.7 matrixStats_1.4.1 gridExtra_2.3 evaluate_1.0.1 knitr_1.48 GenomicRanges_1.57.2 IRanges_2.39.2
## [71] mgcv_1.9-1 rlang_1.1.4 Rcpp_1.0.13 glue_1.8.0 BiocGenerics_0.53.0 jsonlite_1.8.9 Rhdf5lib_1.27.0 R6_2.5.1 MatrixGenerics_1.17.1 zlibbioc_1.51.2
HiCcompare
hic.table
objectHiCcompare
results to InteractionSet
objects