This vignette introduces the SNPhood package. In the following, we introduce main features and necessary background. In addition, we generated a workflow vignette that shows an example analysis using real data from the companion package SNPhoodData (see section Workflow ).
SNPhood is under active development, and we highly recommend using the newest available version. In particular, we recommend using the devel branch of Bioconductor / SNPhood to make sure you use the latest features and bugfixes. If you are not sure how to switch to the devel branch, contact us, we are happy to help!
To date, thousands of single nucleotide polymorphisms (SNPs) have been found to be associated with complex traits and diseases. However, the vast majority of these disease-associated SNPs lie in the non-coding part of the genome, and are likely to affect regulatory elements, such as enhancers and promoters, rather than the function of a protein. Thus, to understand the molecular mechanisms underlying genetic traits and diseases, it becomes increasingly important to study the effect of a SNP on nearby molecular traits such as chromatin environment or transcription factor (TF) binding. Towards this aim, we developed SNPhood, a user-friendly Bioconductor [9] R package to investigate, quantify and visualize the local epigenetic neighborhood of a set of SNPs in terms of chromatin marks, TF binding sites using data from NGS experiments. SNPhood comprises a set of easy-to-use functions to extract, normalize and quantify reads for a genomic region, perform data quality checks, normalize read counts using input files, to investigate the binding pattern using unsupervised clustering. In addition, SNPhood can be employed for identifying and visualizing allele-specific binding patterns around SNPs using a robust permutation based FDR procedure. The regions around each SNP can be binned in a user-defined fashion to allow for analyses ranging from very broad regions to highly detailed investigation of specific binding shapes. Importantly, SNPhood supports the integration with genotype information to investigate and visualize genotype-specific binding patterns.
In this section, we want explicitly mention the designated scope of the SNPhood package, its limitations and additional / companion packages that may be used subsequently or beforehand.
First, let’s be clear what SNPhood is NOT:
Instead, SNPhood aims to fill an existing gap for an increasingly common task: Current workflows for analyzing ChIP-Seq data typically involve peak calling, which summarizes the signal of each binding event into two numbers: enrichment and peak size, and usually neglects additional factors like binding shape. However, when a set of regions of interest (ROI) is already at hand - e.g. GWAS SNPs, quantitative trait loci (QTLs), etc. - a comprehensive and unbiased analysis of the molecular neighborhood of these regions, potentially in combination with allele-specific (AS) binding analyses will be more suited to investigate the underlying (epi-)genomic regulatory mechanisms than simply comparing peak sizes. Currently, such analyses are often carried out “by hand” using basic NGS tools and genome-browser like interfaces to visualize molecular phenotype data independently for each ROI. A tool for systematic analysis of the local molecular neighborhood of regions of interest is currently lacking. SNPhood fills this gap to investigate, quantify, and visualize the local epigenetic neighborhood of regions of interest using chromatin or TF binding data from NGS experiments. It provides a set of tools that are largely complimentary to currently existing software for analyzing ChIP-Seq data.
When running the main function analyzeSNPhood, a series of steps and calculations is performed. In summary, the basic mode of action can be summarized in the following schematic:
More specifically, the mode of action and basic workflow is as follows (see also Figure 4):
The following Figure is an extension of Figure 2 and depicts in more detail the workflow of the package when running the function analyzeSNPhood. In addition, some parameters and their mode of action are highlighted in the step they come into play (depicted in orange).
The following input data are required for the SNPhood package, which is also visualized in Figure 6:
The following data frames are all valid as input for SNPhood and its main function analyzeSNPhood:
signal | input |
---|---|
file1.bam | NA |
file2.bam | NA |
file3.bam | NA |
signal | input | individual | genotype |
---|---|---|---|
file1.bam | input1.bam | S1 | file1.vcf:colName1 |
file2.bam | input1.bam | S1 | file1.vcf:colName1 |
file3.bam | input2.bam, input3.bam | S2 | file1.vcf:colName2 |
In summary, the following data can be integrated into SNPhood:
The main function analyzeSNPhood returns an object of the class SNPhood. It contains all information and results necessary for subsequent analyses and visualization. For details on the structure of the object and how to extract information, see the help pages for SNPhood-class (?“SNPhood-class”) or the SNPhood package itself (?SNPhood).
We now explain various additional methodological and technical details in more detail.
SNPhood creates and returns object of type SNPhood. They are designed to be easy to work with, and all information can be extracted using a small set of functions. See the Workflow vignette and the function documentation for details. If you receive an error message that a particular (potentially older) SNPhood object is not valid, please contact me, and I will help you to change it. This is very likely to be related due to slight changes during the development of SNPhood, and we apaologize for any inconveniance.
All plots are generated with ggplot2 [8] and are either saved directly in the SNPhood object that serves as input for the respective plotting function or returned by the function so that users can modify and replot them as desired. See the help pages of the plotting functions for details. To edit plots, save them in a variable (e.g., plot = plotBinCounts(…)) and either edit them directly by modifying the internal structure of the ggplot list object (e.g., plot$labels$colour = “NEW LEGEND LABEL” to change the legend label) or by adding features in the usual ggplot style, such as plot + geom_lines(…) .
SNPhood requires a number of parameters that are specified in a named list that is needed for the execution of the main function analyzeSNPhood. A default parameter list can be obtained by calling the function getDefaultParameterList.
We explain the supported parameters in more detail in the section Parameters.
SNPhood supports files in BAM format. All BAM files must contain aligned reads and a valid header with, for example, chromosome names and read groups (if applicable). If a corresponding index file with the file ending .bai does not exist for a particular BAM file, it will be created during execution of the main function.
Note that if you already have your BAM files represented in an object of class BamFile or BamFileList from the Rsamtools package, this can easily be integrated into the SNPhood framework. See the help pages of the function collectFiles for details.
As discussed above, SNPhood is not suitable for ChIP-Seq QC. It is important to assess potential biases such as GC, mapping, contamination or other biases beforehand using dedicated tools both within and outside the Bioconductor framework. Example packages from Bioconductor include htSeqTools, ChIPQC, similaRpeak or chipseq (see Bioconductor for a complete list). Alternatively, external software such as FASTQC [11] or Chance [12] may also be used.
Nevertheless, SNPhood offers some rudimentary QC mechanisms that accompany designated QC tools:
The user-provided genomic positions can be extended symmetrically in both 5’ and 3’ direction to analyze their “neighborhood”. The extension size can be set with the parameter regionSize. As an example: for a SNP at position chr1:1000 and parameter regionSize set to 500, the region will be extended 500bp in both directions, yielding the region chr1:[500-1500] of length 500+1+500 = 1001.
To assess the binding pattern within each genomic region in more detail they can be binned in a user-defined fashion. The length of each bin is controled by the parameter binSize (see below). Note that for now each region is treated identically and it is not possible to use different binning schemes within one SNPhood object. Binning always starts at the position with the lowest genomic coordinate (i.e. left of the original position). So setting binSize to 100 for our example region above the bins will be: 500-599, 600-699, …, 1400-1499, 1500-1500. Note that in this particular case, the last bin is only 1 bp short (see next paragraph).
Since the last bin can be of a different size than the othes (depending on the values of the parameter combination regionSize and binSize) the parameter the user can specify how it should be treated by setting the parameter lastBinTreatment (see below for details). In the example given above, to maintain symmetry of the region with respect to the original user-defined position, it might be the most useful option to delete the last bin.
Read counts (and enrichment values, if applicable) are calculated specifically for each bin.
Read extraction for the binned user regions is done using the Rsamtools package. Noteworthy, for increased flexibility and in analogy to read extraction in the Rsamtools package, it is possible to extract only reads with particular BAM flags (e.g. not marked as PCR duplicate, passed quality controls, have a properly aligned mate, etc). Read flags can be set using the parameters starting with readFlag_ accordingly. In addition, the parameters strand, readGroupSpecific, readFlag_reverseComplement, and readFlag_simpleCigar allow additional control over which reads are returned (see the Rsamtools package and below for more details). If the parameter strand is set to sense or antisense and the original user regions have been specified strand-specifically, for example, reads are filtered according to the value of strand. For a graphical depiction, see also Figure 7.
Note that read extraction out of BAM files can be time-consuming, especially if the number of user regions is large or if a high number of reads overlap with the user regions.
For each SNP, the read-group (e.g. most commonly specifying whether a read was mapped to the maternal or paternal genome) specific genotype distribution can be determined (see Figure 8). To determine the genotype distribution, all reads overlapping the SNP positions are extracted from the BAM files and the genotype distribution is determined using the Biostrings package. The genotypes can then be used in various visualizations (see the different plot functions that the package provides) to detect a genotype-dependent pattern.
Raw read counts among datasets can be misleading and are difficult to compare. To make reads comparable across individuals, SNPhood currently provides two different normalization procedures:
The following figure gives an overview of the two different normalization procedures and how they function:
Proper normalization between the ChIP and control samples particularly important when comparing across regions in the genome as the DNA accessibility differs between open and closed chromatin, which will be reflected in the number of “noise” reads obtained from those regions. If negative control files (such as input, IgG) are available, they can be integrated into the SNPhood package to normalize read counts and calculate enrichment for each user region.
Normalizing read counts by input is possible when the following criteria are met:
Note that if this normalization is performed, this overrides the value of the parameter normAmongEachOther to FALSE because this is already integrated within the input normalization procedure.
Specifically, input normalization works as follows. First, read counts between input and signal are normalized to account for differences in library size (see below for details). Thus, the resulting enrichment is based on the normalized and not the raw read counts (i.e., after applying a correction by size factors using the DeSeq2 [3] package, see next section) for both input and signal. Second, for each bin of each SNP region, the maximum of the following three numbers is taken as basis for calculating the enrichment:
The global average is calculated as follows: First, the total number of reads across the full genome is determined. Because of repetitive features on the chromosomes, the actual mappable genome size, however, is smaller than the full genome size (between ~65% and ~80%, dependent on the actual read length). This so-called mappable or effective genome size is important to correctly calculate the genome wide average per base and subsequently per bin. The effective genome size is specified by the parameter effectiveGenomeSizePercentage. SNPhood tries to automatically determine a good proxy for it from the data so the user does not have to worry about setting it correctly. However, there are cases when setting reasonable values for this parameter is mandatory (see parameter description at the end for more details). To do so, we estimate the read length in the BAM file by taking the maximal read length of the first 1000 reads and estimate a reasonable number for the effective genome size given the genome assembly and the read length according to the data for the proportions of unique start sites for nucleotide-space short tag alignments in Koehler et al. (2011), Table 1 [10]. Because these values have been obtained only for a particular genome assembly version for each species (e.g., hg19), we use the same values for other assembly versions of the same species (e.g., hg38). If this approximation is not accurate enough for the user, the parameter can be set manually, as mentioned before. Furthermore, the read length from the table will be taken that is closest to the observed one. For example, for a read length of 80 for hg19, the value for read length 75 (79.3%) will be taken.
Species | 25 (1) (%) | 30 (1) (%) | 35 (1) (%) | 50 (2) (%) | 60 (3) (%) | 75 (4) (%) | 90 (5) (%) |
---|---|---|---|---|---|---|---|
Homo sapiens | 66.0 | 70.9 | 74.1 | 76.9 | 77.5 | 79.3 | 80.8 |
Mus musculus | 69.9 | 74.4 | 77.1 | 79.1 | 79.4 | 80.7 | 81.7 |
Caenorhabditis elegans | 85.3 | 87.7 | 89.0 | 89.8 | 89.9 | 90.6 | 91.1 |
Drosophila melanogaster | 67.5 | 68.4 | 69.0 | 69.2 | 69.2 | 69.5 | 69.8 |
The global average is then calculated by calculating the average number of reads that overlap with a bin, as follows:
nReadsTotal / (genomeSizeTotal x effectiveGenomeSizeProp) x (binSize + readLength - 1)
The variables are defined as follows:
The maximum of these three values (after normalization) is then compared to the normalized number of reads per bin in the signal file and an enrichment is calculated. This is similar to the normalization implement in the MACS2 peak caller [7]; it avoids inflating small read counts from input and corrects local biases caused by DNA accessibility.
The following illustration summarizes how input normalization is performed for each bin and user region:
If no negative control is available we recommend a normalization by library size so that different samples can be compared among each other. This normalization can be performed among all processed files by setting the parameter normAmongEachOther to TRUE. Note that if only one dataset is present in the analysis, there is no need for this type of normalization.
Converting raw read counts to normalized read counts is possible when the following criteria are met:
After this normalization, read counts are numeric values that reflect the normalized read counts among all processed files.
The normalization is done using the DeSeq2 package by creating a virtual sample and determining size factors for each library that reflect the normalization factor, based on the total number of read counts per user region (i.e., before binning). For more details, see the DeSeq2 package and Love et al. (2014) [3].
As indicated in Figure 9, normalization may happen at different steps. Because SNPhood supports multiple datasets to be pooled together to one dataset for both signal and input, multiple normalization steps may be required.
The function testForAllelicBiases performs a statistical test to test for allelic biases given the read counts of two read groups (e.g., maternal vs. paternal). The prerequisite for this type of analysis is that the reads have been reliably mapped to the paternal and maternal genome (e.g. as described in Kasowski et al. [4]).
To determine whether a given region shows an allelic bias, we perform a binomial test for each bin and use the lowest p-value for each region as a test statistic, which we compare to an empirical p-value distribution (described below). This ensures to select the bin with the most power (which often has the highest number of reads) to detect allelic bias. We emphasize that the obtained p-values should not be used as anything else than a test statistic.
To assess the significance of each region we implemented a permutation-based procedure to control the false discovery rate (FDR). In summary, we use the p-values from the binomial tests as a test statistic to calculate the FDR with a random background model. More specifically, for each bin, we generate an empirical p-value distribution by randomly but equally assigning each overlapping read to one of the two read groups, perform a binomial test and select the most significant p-value for each region. For a given p-value threshold the FDR is then calculated as the fraction of significant regions identified from the random by the total number of significant regions. Finally, we note that the FDR calculation is based on the full set of user regions. paste. This approach is conceptually similar to what was done in Alexandrov et al. 2013 [16], section “Statistical analysis of relationships between age and mutations”. Thus, because that overdispersion affects both our real and shuffled data, it is likely that our procedure is rather too pessimistic than too optimistic in discovering allelic bias.
As an output, the raw p-values (to be used as “scores”) from the binomial tests, estimates for the allelic fraction and corresponding confidence intervals are reported for each bin across all user regions. In addition, the corresponding FDR values for a user-defined set of p-values is also given that may then be used to select the regions based on a given FDR threshold.
SNPhood has originally been designed to analyze read profiles in a bin-wise fashion. Therefore, currently, the FDR calculation can only be performed if the number of bins per region is at least 5. For analyses with less than 5 bins, the raw p-values have to be corrected manually, for example with standard multiple testing corrections. Note, however, that potential overdispersion in the count data is not accounted for in such a case. We are currently thinking about a procedure that is more independent on the number of bins.
We currently support two ways of integrating genotypes with user regions (e.g., SNPs):
For each dataset/individual in a SNPhood object, a file in VCF format may be used to associate genotypes for each SNP region. For more details on the VCF format, see here.
Parsing VCF files is done using the VariantAnnotation package, which supports both uncompressed and compressed (gzipped, file ending .gz) VCF files that comply with the VCF standard (e.g. as used by the 1000 Genomes Project [5]).
Matching is done by position rather than ID of the SNPs, and SNP positions from the SNPhood object not defined in the corresponding VCF file will have a genotype of NA. Non-matching rows from the VCF file are discarded and not imported. The column names (i.e., the IDs of the individuals to extract the genotypes from) must also be provided.
SNPhood provides some clustering functionalities to cluster SNPs based on their local neighborhood. Clustering can be done on both counts or enrichment, dependent on the type of data stored in the SNPhood object. Data from any of the defined read groups and datasets can be used for this purpose.
The underlying clustering is done using partitioning around medoids (PAM), which is implemented in the cluster package. PAM clustering is more robust than k-means clustering as the algorithm minimizes the sum of dissimilarities instead of a sum of squared Euclidean distances.
To compare and cluster different datasets, and in particular, to compare the shape of binding across the different SNPs within one or several data sets, we implemented a standardization procedure across the bins for each SNP (i.e. subtracting the mean dividing by standard deviation for each SNP). This allows the investigation of the binding shape irrespective of the overall signal intensity.
Several plotting functions are available to investigate the clusters, see the help pages for details.
An additional feature that might be useful when performing clustering on several individuals is to group individuals for each SNP according to their genotype, which we divide into strong and weak genotypes. They are determined based on the signal obtained for the different genotypes (see help pages of the function calculateWeakAndStrongGenotype). One can then perform the clustering only on the signal averaged across all high-genotype individuals at each SNP to increase the signal to noise ratio (analogous to the analysis in Figure 6 in Grubert et al. [6]).
In this section, we will give an overview over CPU and memory requirements when running or planning a SNPhood analysis.
First let’s focus on CPU time. The following parameters have the largest influence on CPU time:
Now let’s take a closer look at memory. Due to the complexity of the data and the various parameters and their dependencies, it is not possible to establish a “formula” of how much memory is needed. However, the following parameters have the largest influence on the memory footprint:
This all sounds terribly complicated, but here are a few rules of thumb:
nCores
Description: The number of cores that should be used for computationally demanding and parallelizable tasks: the more cores the smaller the total running time. However, note that the decrease in running time is not necessarily linear because not all computationally intensive tasks can be executed in parallel.
Valid values: any positive integer larger than 0 and smaller than the number of available cores
Default value: 1
keepAllReadCounts
Description: If TRUE all count matrices from datasets with the same individual ID will be stored within the SNPhood object after pooling datasets. This parameter is only relevant if the parameter poolDatasets is set to TRUE and will be ignored otherwise. Setting it to FALSE (the default) can save a considerable amount of space (decreased memory consumption) but makes it impossible to analyze and visualize read counts for the original datasets. This will only be possible for the pooled datasets, as given by their individual ID.
Valid values: TRUE or FALSE
Default value: FALSE
normByInput
Description: If TRUE input normalization will be performed. This is highly recommended but requires that appropriate input files are available (e.g., a BAM file with input DNA reads).
Valid values: TRUE or FALSE
Default value: TRUE
normAmongEachOther
Description: Only applicable when when analyzing multiple datasets. If TRUE all datasets will be normalized among each other, i.e. the read counts of all processed files will be normalized using the size factor normalization in the DeSeq2 package.
Valid values: TRUE or FALSE
Default value: TRUE
poolDatasets
Description: To maximize the power to detect allelic biases at particular sites, for example, multiple datasets can be pooled (i.e., combined) to a “meta” dataset. If set to TRUE, all datasets with the same individual ID are pooled and therefore are merged to one dataset (that is, their read counts are summed up). Biological replicates, for example, are typically pooled to increase the power to detect allelic biases.
Valid values: TRUE or FALSE
Default value: TRUE
strand
Description: Should reads be counted regardless of the strand from the original SNP position (“BOTH”), only if they are in sense direction to the region of interest (“SENSE”) or only antisense (“ANTISENSE”)? To retrieve reads regardless of the strand, use the option “both”. If the strand in the user regions file is not provided, or if it is “*" or “.”, reads will be retrieved regardless of the strand.
Valid values: SENSE or ANTISENSE or BOTH
Default value: BOTH
readGroupSpecific
Description: In BAM files, @RG tags can be defined, which allows grouping a set of reads from different experiments, alleles, origins, etc. Each read is associated with one specific read group. The parameter readGroupSpecific determines if read counts will be analyzed individually for each read group as specified in the BAM file. If set to TRUE, any input normalization will be turned off, and only read counts are returned but no enrichment due to the lack of input normalization. If set to FALSE, the defined read groups will be ignored and counts and enrichment are calculated regardless of the read group. This is particularly useful if read groups provide information about whether a read was mapped to the ‘maternal’ or ‘paternal’ genome, and required for allele-specific analyses.
Valid values: TRUE or FALSE
Default value: FALSE
readFlag_isPaired
Description: A logical(1) indicating whether unpaired (FALSE), paired (TRUE), or any (NA) read should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: TRUE
readFlag_isProperPair
Description: A logical(1) indicating whether improperly paired (FALSE), properly paired (TRUE), or any (NA) read should be returned. A properly paired read is defined by the alignment algorithm and might, e.g., represent reads aligning to identical reference sequences and with a specified distance. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: TRUE
readFlag_isUnmappedQuery
Description: A logical(1) indicating whether unmapped (TRUE), mapped (FALSE), or any (NA) read should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: FALSE
readFlag_hasUnmappedMate
Description: A logical(1) indicating whether reads with mapped (FALSE), unmapped (TRUE), or any (NA) mate should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: FALSE
readFlag_isMinusStrand
Description: A logical(1) indicating whether reads aligned to the plus (FALSE), minus (TRUE), or any (NA) strand should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: NA
readFlag_isMateMinusStrand
Description: A logical(1) indicating whether mate reads aligned to the plus (FALSE), minus (TRUE), or any (NA) strand should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: NA
readFlag_isFirstMateRead
Description: A logical(1) indicating whether the first mate read should be returned (TRUE) or not (FALSE), or whether mate read number should be ignored (NA). See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: NA
readFlag_isSecondMateRead
Description: A logical(1) indicating whether the second mate read should be returned (TRUE) or not (FALSE), or whether mate read number should be ignored (NA). See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: NA
readFlag_isNotPrimaryRead
Description: A logical(1) indicating whether alignments that are primary (FALSE), are not primary (TRUE) or whose primary status does not matter (NA) should be returned. A non-primary alignment (“secondary alignment” in the SAM specification) might result when a read aligns to multiple locations. One alignment is designated as primary and has this flag set to FALSE; the remainder, for which this flag is TRUE, are designated by the aligner as secondary. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: FALSE
readFlag_isNotPassingQualityControls
Description: A logical(1) indicating whether reads passing quality controls (FALSE), reads not passing quality controls (TRUE), or any (NA) read should be returned. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: FALSE
readFlag_isDuplicate
Description: logical(1) indicating that un-duplicated (FALSE), duplicated (TRUE), or any (NA) reads should be returned. ‘Duplicated’ reads may represent PCR or optical duplicates. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE or NA
Default value: FALSE
readFlag_minMapQ
Description: A non-negative integer(1) specifying the minimum mapping quality to include. BAM records with mapping qualities less than this value are discarded.. See the Rsamtools package in R for more information.
Valid values: any non-negative integer. Nothing is filtered with the default value of 0.
Default value: 0
readFlag_reverseComplement
Description: A logical(1) vectors. BAM files store reads mapping to the minus strand as though they are on the plus strand. Rsamtools obeys this convention by default (reverseComplement=FALSE), but when this value is set to TRUE returns the sequence and quality scores of reads mapped to the minus strand in the reverse complement (sequence) and reverse (quality) of the read as stored in the BAM file. This might be useful if wishing to recover read and quality scores as represented in fastq files, but is NOT appropriate for variant calling or other alignment-based operations. See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE
Default value: FALSE
readFlag_simpleCigar
Description: A logical(1) vector which, when TRUE, returns only those reads for which the cigar (run-length encoded representation of the alignment) is missing or contains only matches / mismatches (‘M’). See the Rsamtools package in R for more information.
Valid values: TRUE or FALSE
Default value: FALSE
path_userRegions
Description: Path to a BED file with a set of user regions for which read counts or enrichment values should be obtained. Supported are regular BED files with with TAB as column separator and 6 columns: chromosome (format: integers only or of type chr*), start (format: integers), end (format: integers), annotation (format: character), score (format: integer, will be ignored), and strand (format: one of [+-*.]). Note that the order of the columns is very important.
For user convenience, the following additional BED-like formats with fewer columns are supported and automatically recognized according to their total number of columns: 5 columns BED file (chromosome, start, end, annotation, strand), 4 columns BED file (chromosome, start, end, annotation), 3 columns BED file (chromosome, SNP position, annotation) and 2 columns BED file (chromosome, SNP position). See also the section input above for a visual summary of supported formats.
Valid values: a valid path to the file
Default value: none
assemblyVersion
Description: Genome assembly version. See valid values for a list of currently supported genome assemblies.
Valid values: hg18, hg19, hg38, mm9, mm10, dm3, sacCer3, and sacCer2 are supported. Click here to contact us if you need additional genomes.
Default value: hg19
effectiveGenomeSizePercentage
Description: The proportion of the genome that resembles the effective or mappable genome size, given the specific genome assembly version and the read length. If set to -1, SNPhood tries to automatically determine a reasonable value given the data from Koehler et al. (2011), Table 1 [10]. Currently, this automatic determination is only possible for the following genome assemblies: hg38, hg19, hg18, mm10, mm9, and dm3. For other genome assemblies or user-defined and potentially more precise values, the parameter has to or can be set manually. For more details, see here.
Valid values: -1 or a value between 0 and 1.
Default value: -1
headerLine
Description: Does the user regions file contain a header line? If set to TRUE, the first line will be skipped.
Valid values: TRUE or FALSE
Default value: TRUE
linesToParse
Description: For test purposes, use only the first X lines instead of the full file. Set to -1 to read in the full file.
Valid values: any positive integer value or -1
Default value: -1
regionSize
Description: This parameter determines the size of the user regions (in bp). The user-provided positions will be extended by this value on both sides, so that the entire region will be of size:2* regionSize + 1 because the original user position is also included. For more details, see Extending user regions and binning.
Valid values: any positive integer value
Default value: 500
binSize
Description: Size (in bp) of each bin. The full user region is binned equally according to the value of binSize. For more details, see the section Extending user regions and binning. Valid values: any positive integer value between 1 and regionSize (see above)
Default value: 10
lastBinTreatment
Description: The last bin in each region may be shorter than the other bins due to the specific settings of the parameters regionSize and binSize. Should the last bin be left untouched (“KEEPUNCHANGED”), deleted (“DELETE”), or extended to the bin size of the other bins (“EXTEND”)?
Valid values: KEEPUNCHANGED, DELETE or EXTEND
Default value: KEEPUNCHANGED
zeroBasedCoordinates
Description: By default, bases in BED files are zero-based. If not, set this parameter to FALSE, and positions will be converted to a zero-based format (i.e., positions will be decreased by one).
Valid values: TRUE or FALSE
Default value: TRUE
startOpen and endOpen
Description: The convention for BED files is a half-open format (startOpen = FALSE and endOpen = TRUE). That is, the last base is not included in the feature while the first one is (example: 100-101 for a SNP located at position 100). However, fully closed intervals are common as well (example: 100-100). Internally, all positions are converted to a fully closed interval but for user convenience, this does not need to be done manually.
Valid values: TRUE or FALSE
Default value: FALSE
We value all the feedback that we receive and will try to reply in a timely manner.
Please report any bug that you encounter as well as any feature request that you may have to SNPhood@gmail.com.
[1] R Core Team (2014). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL http://www.R-project.org/
[2] Morgan M, Pagès H, Obenchain V and Hayden N. Rsamtools: Binary alignment (BAM), FASTA, variant call (BCF), and tabix file import. R package version 1.18.2, http://bioconductor.org/packages/release/bioc/html/Rsamtools.html.
[3] Love, M. I., Huber, W., & Anders, S. (2014). Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol, 15(12), 550.
[4] Kasowski, M., Kyriazopoulou-Panagiotopoulou, S., Grubert, F., Zaugg, J. B., Kundaje, A., Liu, Y., … & Snyder, M. (2013). Extensive variation in chromatin states across humans. Science, 342(6159), 750-752.
[5] 1000 Genomes Project Consortium. (2010). A map of human genome variation from population-scale sequencing. Nature, 467(7319), 1061-1073.
[6] Grubert, F., Zaugg, J. B., Kasowski, M., Ursu, O., Spacek, D. V., Martin, A. R., … & Snyder, M. (2015). Genetic Control of Chromatin States in Humans Involves Local and Distal Chromosomal Interactions. Cell, 162(5), 1051-1065.
[7] Zhang, Y., Liu, T., Meyer, C. A., Eeckhoute, J., Johnson, D. S., Bernstein, B. E., … & Liu, X. S. (2008). Model-based analysis of ChIP-Seq (MACS). Genome biology, 9(9), R137.
[8] Wickham, H. (2009). ggplot2: elegant graphics for data analysis. Springer Science & Business Media.
[9] Huber, W., Carey, V. J., Gentleman, R., Anders, S., Carlson, M., Carvalho, B. S., … & Morgan, M. (2015). Orchestrating high-throughput genomic analysis with Bioconductor. Nature methods, 12(2), 115-121.
[10] Koehler, R., Issac, H., Cloonan, N., & Grimmond, S. M. (2011). The uniqueome: a mappability resource for short-tag sequencing. Bioinformatics, 27(2), 272-274.
[11] Andrews, S. (2010). FastQC: A quality control tool for high throughput sequence data. Reference Source.
[12] Diaz, A., Nellore, A., & Song, J. S. (2012). CHANCE: comprehensive software for quality control and validation of ChIP-seq data. Genome Biol, 13(10), R98.
[13] van de Geijn, B., McVicker, G., Gilad, Y., & Pritchard, J. (2014). WASP: allele-specific software for robust discovery of molecular quantitative trait loci. bioRxiv, 011221.
[14] Shabalin, A. A. (2012). Matrix eQTL: ultra fast eQTL analysis via large matrix operations. Bioinformatics, 28(10), 1353-1358.
[15] Alexandrov, L. B., Nik-Zainal, S., Wedge, D. C., Aparicio, S. A., Behjati, S., Biankin, A. V., … & Boyault, S. (2013). Signatures of mutational processes in human cancer. Nature, 500(7463), 415-421.