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Overview

Here we describe an end-to-end RSS-NET analysis of inflammatory bowel disease (IBD) GWAS summary statistics (Liu et al, 2015) and a gene regulatory network inferred for natural killer (NK) cells. This example illustrates the actual data analyses performed in Zhu et al (2020).

To reproduce results of this example, please use scripts in the directory script_dir, and follow the step-by-step guide below. Before running any script in script_dir, please install RSS-NET.

Since a real genome-wide analysis is conducted here, this example is more complicated than the previous simulation example. It is advisable to go through the previous simulation example before diving into this real data example.

Note that the working directory here is assumed to be wdtba. Please modify scripts accordingly if a different directory is used.

Step-by-step illustration

Download input data files

1. ${gwas}_sumstat.mat: processed GWAS summary statistics and LD matrix estimates

This file is large (43G) because it has a LD matrix of 1.1 million common SNPs. Please contact me (xiangzhu[at]stanford.edu) if you have trouble accessing this file.

Let’s look at the contents of ibd2015_sumstat.mat.

GWAS summary statistics and LD estimates are stored as cell arrays. RSS-NET only uses the following variables:

  • betahat{j,1}, single-SNP effect size estimates of all SNPs on chromosome j;
  • se{j,1}, standard errors of betahat{j, 1};
  • chr{j,1} and pos{j, 1}, physical positions of these SNPs (GRCh37 build);
  • SiRiS{j,1}, a sparse matrix, defined as repmat((1./se),1,p) .* R .* repmat((1./se)',p,1), where R is the estimated LD matrix of these p SNPs.

2. ${gwas}_snp2gene.mat: physical distance between SNPs and genes

This file contains the physical distance between each GWAS SNP and each protein-coding gene, within 1 Mb. This file corresponds to \({\bf G}_j\) in the RSS-NET model.

In this example, there are 18334 SNPs and 1081481 genes.

The SNP-to-gene distance information is captured by a three-column matrix [colid rowid val]. For example, the distance between gene 1 and SNP 6 is 978947 bps.

3. ${net}_gene2gene.mat: gene regulatory network

This file contains information of gene-to-gene connections in a given regulatory network.

For implementation convenience, this file contains the trivial case where each gene is mapped to itself with val=1.

For a given network, transcription factors (TFs) are stored in rowid and target genes (TGs) are stored in colid. In this example there are 3105 TGs and 376 TFs. Among these TFs and TGs, there are 92399 edges. The edge weights range from 0.61 to 1. These TF-to-TG connections and edge weights correspond to \(\{{\bf T}_g,v_{gt}\}\) in the RSS-NET model.

Run RSS-NET analysis

3. Submit job arrays

For a given GWAS and a given regulatory network, all RSS-NET analysis tasks are almost identical and they only differs in hyper-parameter values. To exploit this, we run one RSS-NET analysis as a job array with multiple tasks that run in parallel.

To this end, we write a simple sbatch script ibd2015_nkcell.sbatch, and submit it to a cluster with Slurm available.

After the submission, multiple jobs should run in different nodes simultaneously.

For each task of this job array, we request 1 node with 8 CPUs and 32 Gb total memory and set the maximum job wall-clock time as 12.5 hours. The actual memory utilized per task is 26.58 GB (efficiency: 85.06% of 31.25 GB). The actual running time per task ranges from xx to xx, with median being xx.

Each task of the job array outputs results in a Version 7 MAT-file. Each MAT-file contains variational estimates for a given set of hyper-parameter values. For example, the following MAT-file ibd2015_Primary_Natural_Killer_cells_from_peripheral_blood_NK_out_66.mat stores RSS-NET results based on the 66-th row of hyper-parameter data frame.

Here [alpha mu s] correspond to the optimal variational parameters \(\{\alpha_j^\star,\mu_j^\star,(\tau_j^\star)^2\}\) for the given hyper-parameters, logw corresponds to the variational lower bound \(F^\star\) and [theta0 theta sigb sige] corresponds to \(\{\theta_0,\theta,\sigma_0,\sigma\}\). Please see Supplementary Notes of Zhu et al (2020) for definitions.

Summarize RSS-NET results

1. ${gwas}_${net}_${cis}_results_model.mat: network-level enrichments

Let \(M_0:\theta=0~\text{and}~\sigma^2=0\) denote the baseline model in RSS-NET. Here log10_bf* are log 10 BFs comparing the flollowing 4 enrichment models against \(M_0\).

  • log10_bf: \(M_1:\theta>0~\text{or}~\sigma^2>0\);
  • log10_bf_ns: \(M_{11}:\theta>0~\text{and}~\sigma^2=0\);
  • log10_bf_nt: \(M_{12}:\theta=0~\text{and}~\sigma^2>0\);
  • log10_bf_ts: \(M_{13}:\theta>0~\text{and}~\sigma^2>0\).

Because \(M_1\) is more flexible than other models, we mainly use log10_bf as recommended by Zhu et al (2020).

More examples

The RSS-NET analyses of 18 complex traits and 38 gene regulatory networks reported in Zhu et al (2020) are essentially 684 modified rerun of the example above (with different input GWAS and/or network data). Our full analysis results are publicly available at https://xiangzhu.github.io/rss-peca.

Appendix


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