Last updated: 2023-10-09
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Knit directory: meSuSie_Analysis/
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Note: all the code and analysis reproduced here can be found in Zenodo
In addition to lipid traits of European and African ancestry, we further did analysis in MCHC and SCZ in European and East Asian ancestry.
library(ggpubr)
library(data.table)
library(dplyr)
library(tidyr)
library(ggplot2)
library(patchwork)
library(ggpmisc)
library(VennDiagram)
library(gridExtra)
library(ggbreak)
library(DescTools)
library(coin)
library(susieR)
library(ggrepel)
library(stringr)
load("/net/fantasia/home/borang/Susie_Mult/Revision_Round_1/01_08_Real_Data/summary_res/res.RData")
custom_theme <- function() {
theme(
axis.text.x = element_text(size = 5),
axis.text.y = element_text(size = 5),
axis.title.x = element_text(size = 7, face="bold"),
axis.title.y = element_text(size = 7, face="bold"),
strip.text.x = element_text(size = 5),
strip.text.y = element_text(size = 5),
strip.background = element_blank(),
legend.text = element_text(size=7),
legend.title = element_text(size=7, face="bold"),
plot.title = element_text(size=7, hjust = 0.5),
panel.grid.major = element_blank(),
panel.grid.minor = element_blank(),
panel.border = element_blank(),
axis.line = element_line(color = "black")
)
}
################################################
#
# Set Size/Z-score/eQTL
#
#
###############################################
################################################
#
# Set SiZe Part
#
###############################################
###Median set size by Trait
all_sets_info<-data.frame(res_all%>%group_by(Trait,Region) %>% summarise(across(c("MESuSiE_cs", "SuSiE_cs","Paintor_cs"), ~ sum(.x, na.rm = TRUE))))%>%filter(MESuSiE_cs!=0, SuSiE_cs!=0, Paintor_cs!=0) ###Median Set Size across all locus
all_sets_info_long<-all_sets_info%>%pivot_longer(!(Trait|Region), names_to = "Method", values_to = "Count")
all_sets_info_long$Method<-factor(all_sets_info_long$Method,levels=c("MESuSiE_cs","SuSiE_cs","Paintor_cs"))
levels(all_sets_info_long$Method)<-c("MESuSiE","SuSiE","Paintor")
p_set = ggplot(data =all_sets_info_long,aes(x = Trait, y=Count,fill=Method))+geom_boxplot(aes(x = Trait,fill=Method),outlier.size = 0.1,fatten = 0.5,color = "darkgray")+scale_fill_manual(values=c("MESuSiE"="#023e8a","SuSiE"="#2a9d8f","Paintor"="#f4a261"),guide=FALSE)
p_set =p_set + theme_bw() + xlab("") +ylab("Set Size")+coord_cartesian(ylim=c(0,175))
p_set= p_set+custom_theme()
################################################
#
# Z-score Part
#
###############################################
MESuSiE_cs_Z<-res_all%>%group_by(Trait) %>%filter(MESuSiE_cs==1)%>%summarise(zmax = median(pmax(abs(zscore_EUR),abs(zscore_EAS))))
SuSiE_cs_Z<-res_all%>%group_by(Trait) %>%filter(SuSiE_cs==1)%>%summarise(zmax =median(pmax(abs(zscore_EUR),abs(zscore_EAS))))%>%pull(zmax)
Paintor_cs_Z<-res_all%>%group_by(Trait) %>%filter(Paintor_cs==1)%>%summarise(zmax = median(pmax(abs(zscore_EUR),abs(zscore_EAS))))%>%pull(zmax)
set_size_z_info<-data.frame(cbind(MESuSiE_cs_Z,SuSiE_cs_Z,Paintor_cs_Z))
colnames(set_size_z_info)<-c("Trait",c("MESuSiE","SuSiE","Paintor"))
set_size_z_info_long<-set_size_z_info %>%pivot_longer(!(Trait), names_to = "Method", values_to = "Z")%>%mutate(Method = factor(Method, levels=c("MESuSiE","SuSiE","Paintor")))
p_z = ggplot(data = set_size_z_info_long,aes(x = Trait, y=Z,fill=Method))+geom_bar( stat = "identity",position="dodge")+scale_fill_manual(values=c("MESuSiE"="#023e8a","SuSiE"="#2a9d8f","Paintor"="#f4a261"))
p_z = p_z + geom_text(label = round(set_size_z_info_long$Z,2),position = position_dodge(width = 1),vjust=-0.5,size = 5*5/14)
p_z = p_z + theme_bw() + xlab("") +ylab("Median |Z|")+ ylim(0,max(round(set_size_z_info_long$Z,2)+1))
p_z = p_z +custom_theme()
################################################
#
# eQTL enrichment
#
#
###############################################
res_all<-res_all%>%mutate(utr_comb = ifelse((utr_3+utr_5)>0,1,0))
ann_col_name<-c("missense", "synonymous", "utr_comb", "promotor", "CRE","blood_ind_eQTL","brain_ind_eQTL")
# Functions for calculating fold enrichment
calc_fold_enrichment <- function(df, cs_col, ann_col_name) {
df %>%
group_by(Region) %>%
filter(sum(!!sym(cs_col)) != 0) %>%
group_by(Trait, !!sym(cs_col)) %>%
summarise(across(ann_col_name, ~ sum(.x, na.rm = TRUE) / n())) %>%
group_by(Trait) %>%
summarise(across(ann_col_name, ~ .x[!!sym(cs_col) == 1] / .x[!!sym(cs_col) == 0]))
}
MESuSiE_PIP_ann <- calc_fold_enrichment(res_all, "MESuSiE_cs", ann_col_name)
SuSiE_PIP_ann <- calc_fold_enrichment(res_all, "SuSiE_cs", ann_col_name)
Paintor_PIP_ann <- calc_fold_enrichment(res_all, "Paintor_cs", ann_col_name)
# Combine results
Trait_CS_enrichment <- bind_rows(
MESuSiE_PIP_ann %>% mutate(Method = "MESuSiE"),
SuSiE_PIP_ann %>% mutate(Method = "SuSiE"),
Paintor_PIP_ann %>% mutate(Method = "Paintor")
) %>% mutate(Method = factor(Method, levels = c("MESuSiE", "SuSiE", "Paintor")))%>%
dplyr::select(Trait,blood_ind_eQTL,brain_ind_eQTL ,Method )
# Pivot to long format
Trait_CS_enrichment_long <- Trait_CS_enrichment %>%
pivot_longer(cols = -c(Method, Trait), names_to = "Cat", values_to = "Prop") %>%
mutate(Method = factor(Method, levels = c("MESuSiE", "SuSiE", "Paintor")))
Trait_CS_enrichment_long<-Trait_CS_enrichment_long%>%filter((Trait=="MCHC"&Cat=="blood_ind_eQTL")|(Trait=="SC"&Cat=="brain_ind_eQTL"))%>%mutate(Cat ="eQTL")
p_eQTL <- ggplot(Trait_CS_enrichment_long, aes(x = Trait, y = Prop, fill = Method)) +
geom_bar(stat = "identity", position = "dodge") +scale_fill_manual(values = c("MESuSiE" = "#023e8a", "SuSiE" = "#2a9d8f", "Paintor" = "#f4a261")) +
geom_text(,label = round(Trait_CS_enrichment_long$Prop,2),position = position_dodge(width = 1),vjust=-0.5,size = 5*5/14)+
xlab("") + ylab("eQTL Fold Enrichment") + ylim(0,max(round(Trait_CS_enrichment_long$Prop))+1)+
theme_bw() + custom_theme()
p_out<-p_set/p_eQTL+plot_layout(guides = "collect",heights = c(1.5,1))&theme(legend.position = 'bottom')
p_out
##############################################################
#
#
# Real Data Example Plotter
#
#
################################################################
gwas_plot_fun <- function(data_plot, xlab_name, ylab_name, yintercept) {
p_manhattan = ggplot() + geom_point(data = data_plot%>%filter(Lead_SNP==0), aes(x = POS, y = PIP, color = r2), size = 1)
p_manhattan = p_manhattan + geom_point(data = data_plot%>%filter(Lead_SNP==1), aes(x = POS, y = PIP), size = 1.5, color = "red") +
geom_text(data = data_plot%>%filter(Lead_SNP==1), mapping = aes(x = POS, y = PIP, label = SNP), vjust = 1.2, size = 7/14*5, show.legend =FALSE)
p_manhattan = p_manhattan +
scale_color_stepsn(
colors = c("navy", "lightskyblue", "green", "orange", "red"),
breaks = seq(0.2, 0.8, by = 0.2),
limits = c(0, 1),
show.limits = TRUE,
na.value = 'grey50',
name = expression(R^2)
)
p_manhattan = p_manhattan +
geom_hline(
yintercept = yintercept,
linetype = "dashed",
color = "grey50",
size = 0.5
)
p_manhattan = p_manhattan +
geom_vline(
xintercept = data_plot%>%filter(lead_SNP==1)%>%pull(POS),
linetype = "dashed",
color = "grey50",
size = 0.5
)
p_manhattan = p_manhattan + xlim(min(data_plot$POS),max(data_plot$POS))
p_manhattan = p_manhattan + expand_limits(x = round(max(data_plot$POS)/(1024^2))*(1024^2))
if(max(data_plot$POS>(1024^2))){
p_manhattan = p_manhattan + scale_x_continuous(labels = function(x) paste0( round(x / (1024^2),2), " MB"))
}
if(max(data_plot$POS<(1024^2))){
p_manhattan = p_manhattan + scale_x_continuous(labels = function(x) paste0(round(x / 1e3,2), " KB"))
}
p_manhattan = p_manhattan + xlab(xlab_name) +ylab(ylab_name)
p_manhattan = p_manhattan + guides(fill = guide_legend(title = as.expression(bquote(R^2))))
p_manhattan = p_manhattan + theme_bw()+custom_theme()
return(p_manhattan)
}
###Function used for PIP plot
finemap_plot_fun<-function(data_plot,xlab_name,ylab_name,yintercept){
p_manhattan = ggplot() + geom_point(data = data_plot, aes(x = POS, y = PIP, color = r2,shape = cat))+scale_shape_manual(name="Category",drop=FALSE,values=c(20,24,25,23,22))
p_manhattan = p_manhattan + geom_text(data =data_plot%>%filter(Lead_SNP==1), mapping=aes(x=POS, y=PIP, label=SNP),vjust=1.2, size= 7/14*5,show.legend = FALSE)
p_manhattan = p_manhattan + theme_bw()+scale_color_stepsn(
colors = c("navy", "lightskyblue", "green", "orange", "red"),
breaks = seq(0.2, 0.8, by = 0.2),
limits = c(0, 1),
show.limits = TRUE,
na.value = 'grey50',
name = expression(R^2)
)
p_manhattan = p_manhattan + geom_hline(
yintercept =yintercept,
linetype = "dashed",
color = "grey50",
size = 0.5
) + geom_vline(
xintercept = data_plot%>%filter(lead_SNP==1)%>%pull(POS),
linetype = "dashed",
color = "grey50",
size = 0.5
)
p_manhattan = p_manhattan + xlim(min(data_plot$POS),max(data_plot$POS))
p_manhattan = p_manhattan + expand_limits(x = round(max(data_plot$POS)/(1024^2))*(1024^2))
if(max(data_plot$POS>(1024^2))){
p_manhattan = p_manhattan + scale_x_continuous(labels = function(x) paste0(round(x / (1024^2),2), " MB"))
}
if(max(data_plot$POS<(1024^2))){
p_manhattan = p_manhattan + scale_x_continuous(labels = function(x) paste0(round(x / 1e3,2), " KB"))
}
p_manhattan= p_manhattan+xlab(xlab_name)+ylab(ylab_name)
p_manhattan= p_manhattan+guides(fill=guide_legend(title=as.expression(bquote(R^2))))
p_manhattan = p_manhattan + theme_bw()+custom_theme()
return(p_manhattan)
}
# Function used for gene plot
gene_range_plot_fun<-function(gene_list_data,plot.range){
p<-ggplot(data = gene_list_data) +
geom_linerange(aes(x = Gene, ymin = Start, ymax = End))+ylim(plot.range)+ expand_limits(y = round(max(plot.range[2])/(1024^2))*(1024^2))+scale_y_continuous(labels = function(y) paste0(round(y / (1024^2),2), " MB"))+coord_flip()+
geom_text(aes(x = Gene, y = Start, label = Gene), hjust = "right", size = 5/14*5) + ylab(paste0("chr",unique(gsub("chr","",gene_list_data$Chrom))))+ xlab("Gene") +
theme_bw() + theme(
axis.text.x = element_text(size = 5),
axis.text.y = element_blank(),
axis.ticks.y = element_blank(),
axis.title.x = element_text(size = 7, face="bold"),
axis.title.y = element_text(size = 7, face="bold"),
strip.text.x = element_text(size = 5),
strip.text.y = element_text(size = 5),
strip.background = element_blank(),
legend.text = element_text(size=7),
legend.title = element_text(size=7, face="bold"),
plot.title = element_text(size=7, hjust = 0.5),
panel.grid.major = element_blank(),
panel.grid.minor = element_blank(),
panel.border = element_blank(),
axis.line.x = element_line(color = "black"),
axis.line.y = element_line(color = "black")
)
return(p)
}
#####################################################################################################################
#
#
#
# Example showcase
#
#
#
#####################################################################################################################
Gene_List<-fread("/net/fantasia/home/borang/Susie_Mult/simulation/simu_0120/data/Gencode_GRCh37_Genes_UniqueList2021.txt",header=T)
###################################################################
#
#
# SCZ example (rs4702 of FURIN)
#
#
##################################################################
region = 120
trait_name = "SC"
res_z_dir<-paste0("/net/fantasia/home/borang/Susie_Mult/Revision_Round_1/01_08_Real_Data/",trait_name,"/",trait_name,"/")
out_dir<-paste0(res_z_dir,"data/")
out_res_dir<-paste0(res_z_dir,"res/")
##Data Reprocess
EUR_COV<-as.matrix(fread(paste0(out_dir,"Region_",region,".LD1")))
EAS_COV<-as.matrix(fread(paste0(out_dir,"Region_",region,".LD2")))
candidate_region<-res_all%>%filter(Region==region)
# rs4702 is the 3'utr of FURIN gene, highlighted in the paper
lead_SNP = "rs4702"
lead_SNP_index<-which(candidate_region$SNP==lead_SNP)
candidate_region<-candidate_region%>%mutate(r2_EUR = unname(unlist((EUR_COV[,lead_SNP_index])^2)) ,r2_EAS = unname(unlist((EAS_COV[,lead_SNP_index])^2)),POS = as.numeric(POS))
####Category Setting
candidate_region<-candidate_region%>%mutate(SuSiE_cat = case_when(susie_EUR>0.5&susie_EAS>0.5 ~ 3,
susie_EUR>0.5&susie_EAS<0.5 ~ 1,
susie_EUR<0.5&susie_EAS>0.5 ~ 2,
TRUE ~ 0),
Paintor_cat = case_when(Paintor_PIP>0.5~4,
TRUE~0),
MESuSiE_cat = case_when(MESuSiE_PIP_WB>0.5~1,
MESuSiE_PIP_BB>0.5~2,
MESuSiE_PIP_Shared>0.5~3,
TRUE~0))
###GWAS PLOT
EUR_GWAS_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = -log10(2*pnorm(-abs(zscore_EUR))),Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS))%>%select(SNP,POS, r2,PIP,Lead_SNP)
EAS_GWAS_plot_data<-candidate_region%>%mutate(r2 = r2_EAS,PIP = -log10(2*pnorm(-abs(zscore_EAS))),Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS))%>%select(SNP,POS, r2,PIP,Lead_SNP)
p_EUR<-gwas_plot_fun (EUR_GWAS_plot_data, "PGC-EUR", "-log10(P-value)", -log10(5e-8))
p_EAS<-gwas_plot_fun (EAS_GWAS_plot_data, "PGC-EAS", "-log10(P-value)", -log10(5e-8))
###Finemap Plot
EUR_SuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = susie_EUR,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(SuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
EAS_SuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EAS,PIP = susie_EAS,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(SuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
MESuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = MESuSiE_PIP_Either,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(MESuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
Paintor_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = Paintor_PIP,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(Paintor_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
p_EUR_SuSiE<-finemap_plot_fun(EUR_SuSiE_plot_data, "SuSiE PGC EUR", "PIP", 0.5)
p_EAS_SuSiE<-finemap_plot_fun(EAS_SuSiE_plot_data, "SuSiE PGC EAS", "PIP", 0.5)
p_MESuSiE<-finemap_plot_fun(MESuSiE_plot_data, "MESuSiE", "PIP", 0.5)
p_Paintor<-finemap_plot_fun(Paintor_plot_data, "Paintor", "PIP", 0.5)
# Gene Plot
plot.range <- c(min(candidate_region$POS), max(candidate_region$POS))
Gene_List_sub_coding<-Gene_List%>%filter(Chrom==paste0("chr",unique(candidate_region$CHR)))%>%filter(Start<max(candidate_region$POS),End>min(candidate_region$POS))%>%filter(Coding=="proteincoding")%>%filter(!is.na(cdsLength))
p2<-gene_range_plot_fun(Gene_List_sub_coding,plot.range)
##Combine Plot together
combined_plot<-(p_EUR/p_EUR_SuSiE/p_MESuSiE/p2+plot_layout(heights = c(1,1,1,1.5))|p_EAS/p_EAS_SuSiE/p_Paintor/p2+plot_layout(heights = c(1,1,1,1.5)))+plot_layout(guides = 'collect')&theme(legend.position = "bottom")
combined_plot
##############################################################
#
#
# MCHC example rs360153 SWAP70
#
################################################################
region = 18
trait_name = "MCHC"
res_z_dir<-paste0("/net/fantasia/home/borang/Susie_Mult/Revision_Round_1/01_08_Real_Data/",trait_name,"/",trait_name,"/")
out_dir<-paste0(res_z_dir,"data/")
out_res_dir<-paste0(res_z_dir,"res/")
##Data Reprocess
EUR_COV<-as.matrix(fread(paste0(out_dir,"Region_",region,".LD1")))
EAS_COV<-as.matrix(fread(paste0(out_dir,"Region_",region,".LD2")))
candidate_region<-res_all%>%filter(Region==region)
lead_SNP = "rs360153"
lead_SNP_index<-which(candidate_region$SNP==lead_SNP)
candidate_region<-candidate_region%>%mutate(r2_EUR = unname(unlist((EUR_COV[,lead_SNP_index])^2)) ,r2_EAS = unname(unlist((EAS_COV[,lead_SNP_index])^2)),POS = as.numeric(POS))
####Category Setting
candidate_region<-candidate_region%>%mutate(SuSiE_cat = case_when(susie_EUR>0.5&susie_EAS>0.5 ~ 3,
susie_EUR>0.5&susie_EAS<0.5 ~ 1,
susie_EUR<0.5&susie_EAS>0.5 ~ 2,
TRUE ~ 0),
Paintor_cat = case_when(Paintor_PIP>0.5~4,
TRUE~0),
MESuSiE_cat = case_when(MESuSiE_PIP_WB>0.5~1,
MESuSiE_PIP_BB>0.5~2,
MESuSiE_PIP_Shared>0.5~3,
TRUE~0))
###GWAS PLOT
EUR_GWAS_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = -log10(2*pnorm(-abs(zscore_EUR))),Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS))%>%select(SNP,POS, r2,PIP,Lead_SNP)
EAS_GWAS_plot_data<-candidate_region%>%mutate(r2 = r2_EAS,PIP = -log10(2*pnorm(-abs(zscore_EAS))),Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS))%>%select(SNP,POS, r2,PIP,Lead_SNP)
p_EUR<-gwas_plot_fun (EUR_GWAS_plot_data, "UKBB", "-log10(P-value)", -log10(5e-8))
p_EAS<-gwas_plot_fun (EAS_GWAS_plot_data, "BBJ", "-log10(P-value)", -log10(5e-8))
###Finemap Plot
EUR_SuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = susie_EUR,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(SuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
EAS_SuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EAS,PIP = susie_EAS,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(SuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
MESuSiE_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = MESuSiE_PIP_Either,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(MESuSiE_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
Paintor_plot_data<-candidate_region%>%mutate(r2 = r2_EUR,PIP = Paintor_PIP,Lead_SNP = ifelse(SNP==lead_SNP,1,0),POS= as.numeric(POS),cat = factor(Paintor_cat,levels = c("0", "1", "2", "3", "4"), labels = c("Non", "EUR", "EAS", "Shared", "Paintor")))%>%select(SNP,POS, r2,PIP,Lead_SNP,cat)
p_EUR_SuSiE<-finemap_plot_fun(EUR_SuSiE_plot_data, "SuSiE UKBB", "PIP", 0.5)
p_EAS_SuSiE<-finemap_plot_fun(EAS_SuSiE_plot_data, "SuSiE BBJ", "PIP", 0.5)
p_MESuSiE<-finemap_plot_fun(MESuSiE_plot_data, "MESuSiE", "PIP", 0.5)
p_Paintor<-finemap_plot_fun(Paintor_plot_data, "Paintor", "PIP", 0.5)
# Gene Plot
plot.range <- c(min(candidate_region$POS), max(candidate_region$POS))
Gene_List_sub_coding<-Gene_List%>%filter(Chrom==paste0("chr",unique(candidate_region$CHR)))%>%filter(Start<max(candidate_region$POS),End>min(candidate_region$POS))%>%filter(Coding=="proteincoding")%>%filter(!is.na(cdsLength))
p2<-gene_range_plot_fun(Gene_List_sub_coding,plot.range)
##Combine Plot together
combined_plot<-(p_EUR/p_EUR_SuSiE/p_MESuSiE/p2+plot_layout(heights = c(1,1,1,1.5))|p_EAS/p_EAS_SuSiE/p_Paintor/p2+plot_layout(heights = c(1,1,1,1.5)))+plot_layout(guides = 'collect')&theme(legend.position = "bottom")
combined_plot
sessionInfo()
R version 4.3.1 (2023-06-16)
Platform: x86_64-pc-linux-gnu (64-bit)
Running under: Ubuntu 20.04.6 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/liblapack.so.3; LAPACK version 3.9.0
locale:
[1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
[3] LC_TIME=en_US.UTF-8 LC_COLLATE=en_US.UTF-8
[5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
[7] LC_PAPER=en_US.UTF-8 LC_NAME=C
[9] LC_ADDRESS=C LC_TELEPHONE=C
[11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
time zone: America/New_York
tzcode source: system (glibc)
attached base packages:
[1] grid stats graphics grDevices utils datasets methods
[8] base
other attached packages:
[1] stringr_1.5.0 ggrepel_0.9.1 susieR_0.11.84
[4] coin_1.4-2 survival_3.3-1 DescTools_0.99.45
[7] ggbreak_0.1.1 gridExtra_2.3 VennDiagram_1.7.3
[10] futile.logger_1.4.3 ggpmisc_0.4.7 ggpp_0.4.4
[13] patchwork_1.1.1 tidyr_1.3.0 dplyr_1.1.2
[16] data.table_1.14.8 ggpubr_0.6.0 ggplot2_3.4.2
[19] workflowr_1.7.0
loaded via a namespace (and not attached):
[1] formatR_1.14 gld_2.6.5 sandwich_3.0-2
[4] readxl_1.4.2 rlang_1.1.1 magrittr_2.0.3
[7] git2r_0.32.0 multcomp_1.4-25 matrixStats_1.0.0
[10] e1071_1.7-13 compiler_4.3.1 getPass_0.2-2
[13] callr_3.7.3 vctrs_0.6.2 quantreg_5.95
[16] crayon_1.5.2 pkgconfig_2.0.3 fastmap_1.1.1
[19] backports_1.4.1 labeling_0.4.2 utf8_1.2.3
[22] promises_1.2.0.1 rmarkdown_2.22 ps_1.7.2
[25] MatrixModels_0.5-1 purrr_1.0.1 xfun_0.39
[28] modeltools_0.2-23 cachem_1.0.8 aplot_0.1.10
[31] jsonlite_1.8.3 highr_0.10 later_1.3.1
[34] reshape_0.8.9 irlba_2.3.5.1 broom_1.0.5
[37] parallel_4.3.1 R6_2.5.1 bslib_0.5.0
[40] stringi_1.7.12 car_3.1-2 boot_1.3-28.1
[43] jquerylib_0.1.4 cellranger_1.1.0 Rcpp_1.0.11
[46] knitr_1.39 zoo_1.8-12 httpuv_1.6.11
[49] Matrix_1.5-4.1 splines_4.3.1 tidyselect_1.2.0
[52] rstudioapi_0.14 abind_1.4-5 yaml_2.3.7
[55] codetools_0.2-19 processx_3.8.0 plyr_1.8.8
[58] lattice_0.20-45 tibble_3.2.1 withr_2.5.1
[61] evaluate_0.18 gridGraphics_0.5-1 lambda.r_1.2.4
[64] proxy_0.4-27 pillar_1.9.0 carData_3.0-5
[67] whisker_0.4.1 stats4_4.3.1 ggfun_0.0.9
[70] generics_0.1.3 rprojroot_2.0.3 munsell_0.5.0
[73] scales_1.2.1 rootSolve_1.8.2.3 class_7.3-20
[76] glue_1.6.2 lmom_2.8 tools_4.3.1
[79] SparseM_1.81 ggsignif_0.6.4 Exact_3.1
[82] fs_1.6.2 mvtnorm_1.1-3 libcoin_1.0-9
[85] colorspace_2.1-0 cli_3.6.1 futile.options_1.0.1
[88] fansi_1.0.5 expm_0.999-7 mixsqp_0.3-48
[91] gtable_0.3.1 rstatix_0.7.2 yulab.utils_0.0.4
[94] sass_0.4.6 digest_0.6.30 TH.data_1.1-2
[97] ggplotify_0.1.0 farver_2.1.1 htmltools_0.5.5
[100] lifecycle_1.0.3 httr_1.4.6 MASS_7.3-57