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SupplementaryTables.Rmd
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---
title: "Supplementary Dataset"
site: workflowr::wflow_site
date: "2021-March-22"
output:
workflowr::wflow_html:
code_folding: "hide"
editor_options:
chunk_output_type: inline
---
```{r setup, include=FALSE}
knitr::opts_chunk$set(echo = TRUE, message = FALSE, warning = FALSE,
tidy='styler', tidy.opts=list(strict=FALSE,width.cutoff=100), highlight=TRUE)
```
# SI Dataset
## Initiate
```{r}
library(writexl)
suptables<-list()
```
## Table S1: Selection indices
Table S1: Selection indices. For each trait, the standard deviation of BLUPs (blupSD), which were divided by "unscaled" index weights for the StdSI and BiofortSI indices to get StdSI and BiofortSI weights used throughout the study.
```{r}
library(tidyverse); library(magrittr);
indices<-readRDS(file=here::here("data","selection_index_weights_4traits.rds"))
suptables[["TableS01"]]<-indices
indices %>% rmarkdown::paged_table()
```
## Table S2: Summary of cross-validation scheme
Table S2: Summary of cross-validation scheme. For each fold of each Rep, the number of parents in the test-set (Ntestparents) is given along with the number of clones in the corresponding training (Ntraintset) and testing (Ntestset) datasets and the number of crosses to predict (NcrossesToPredict).
```{r}
library(tidyverse); library(magrittr)
parentfolds<-readRDS(file = here::here("data","parentwise_crossVal_folds.rds"))
ped<-readRDS(here::here("data","ped_awc.rds")) %>%
distinct(sireID,damID)
parentfolds %<>%
mutate(CrossesToPredict=map(testparents,~filter(ped,sireID %in% . | damID %in% .)))
```
```{r}
parentfold_summary<-parentfolds %>%
rename(Rep=id,Fold=id2) %>%
mutate(Ntestparents=map_dbl(testparents,length),
Ntrainset=map_dbl(trainset,length),
Ntestset=map_dbl(testset,length),
NcrossesToPredict=map_dbl(CrossesToPredict,nrow)) %>%
select(Rep,Fold,starts_with("N"))
suptables[["TableS02"]]<-parentfold_summary
parentfold_summary %>% rmarkdown::paged_table()
```
## Table S3: Test-parents
Table S3: Test-parents. For each fold of each cross-validation repeat, the set of parents whose crosses are to be predicted is listed.
```{r}
testparents<-parentfolds %>%
rename(Rep=id,Fold=id2) %>%
select(Rep,Fold,testparents) %>%
unnest(testparents)
suptables[["TableS03"]]<-testparents
testparents %>% head %>% rmarkdown::paged_table()
```
## Table S4: Training-Testing partitions of germplasm
Table S4: Training-Testing partitions of germplasm. For each fold of each repeat, the genotype ID (germplasmName) of all clones in the "trainset" and "testset" are given.
```{r}
train_test_germplasmNames<-parentfolds %>%
rename(Rep=id,Fold=id2) %>%
select(Rep,Fold,trainset,testset) %>%
pivot_longer(cols = c(trainset,testset), names_to = "Set", values_to = "germplasmName") %>%
unnest(germplasmName)
suptables[["TableS04"]]<-train_test_germplasmNames
train_test_germplasmNames %>% head %>% rmarkdown::paged_table()
```
## Table S5: Crosses to predict each fold
Table S5: Crosses to predict each fold. For each fold of each repeat, the sireID and damID are given for each cross-to-be-predicted.
```{r}
CrossesToPredict<-parentfolds %>%
rename(Rep=id,Fold=id2) %>%
select(Rep,Fold,CrossesToPredict) %>%
unnest(CrossesToPredict)
suptables[["TableS05"]]<-CrossesToPredict
CrossesToPredict %>% head %>% rmarkdown::paged_table()
```
## Table S6: Predicted and observed cross means
Table S6: Predicted and observed cross means. For each fold of each repeat, each cross distinguished by a unique pair of sireID and damID is given. The genetic model used (Models A, AD, DirDomAD, DirDomBV), whether the prediction is of mean breeding value (predOf=MeanBV) or mean total genetic value (predOf=MeanTGV), the trait (BiofortSI or StdSI), type of observation (ValidationData: GBLUPs or iidBLUPs) and corresponding prediction (predMean) and observations (obsMean) are shown.
```{r}
obsVSpredMeans<-readRDS(here::here("output","obsVSpredMeans.rds"))
write.csv(obsVSpredMeans,file = here::here("manuscript", "SupplementaryTable06.csv"), row.names = F)
# suptables[["TableS06"]]<-obsVSpredMeans
obsVSpredMeans %>% str
```
```{r}
obsVSpredMeans %>% count(Model,predOf,ValidationData) %>% spread(predOf,n) %>% rmarkdown::paged_table()
```
## Table S7: Predicted cross variances
Table S7: Predicted cross variances. All predictions of cross-variance from the cross-validation scheme are detailed. For each fold of each repeat and each unique cross (sireID x damID). Both variances (Trait1==Trait2) and co-variances (Trait1!=Trait2) are given. The genetic model used (Model: A, AD, DirDomAD, DirDomBV), the variance component being predicted (VarComp=VarA or VarD), along with the number of segregating SNPs in the family (Nsegsnps) and the time taken in seconds for computation, per family (totcomputetime) are given. The predictions based on the variance of posterior means (VPM) and the posterior mean variances (PMV) are both shown.
```{r}
library(tidyverse); library(magrittr); library(predCrossVar)
# Tidy predicted Vars for Models A and AD
predictedCrossVars<-list.files(here::here("output/crossPredictions")) %>%
grep("predictedCrossVars_chunk",.,value = T) %>%
map_df(.,~readRDS(here::here("output/crossPredictions",.))) %>%
select(Repeat,Fold,Model,crossVars) %>%
mutate(crossVars=map(crossVars,
function(crossVars){
out<-crossVars$predictedCrossVars$varcovars %>%
mutate(varcomps=map(varcomps,~.$predictedfamvars)) %>%
unnest(varcomps) %>%
unnest(predVars)
return(out)})) %>%
unnest(crossVars)
predictedDirDomCrossVars<-bind_rows(list.files(here::here("output/crossPredictions")) %>%
grep("predictedDirectionalDomCrossVarBVs_chunk",.,value = T) %>%
grep("_15Dec2020.rds",.,value = T) %>%
map_df(.,~readRDS(here::here("output/crossPredictions",.))) %>%
select(Repeat,Fold,crossVars) %>%
mutate(Model="DirDomBV"),
list.files(here::here("output/crossPredictions")) %>%
grep("predictedDirectionalDomCrossVarTGVs_chunk",.,value = T) %>%
grep("_15Dec2020.rds",.,value = T) %>%
map_df(.,~readRDS(here::here("output/crossPredictions",.))) %>%
select(Repeat,Fold,crossVars) %>%
mutate(Model="DirDomAD")) %>%
mutate(crossVars=map(crossVars,
function(crossVars){
out<-crossVars$predictedCrossVars$varcovars %>%
mutate(varcomps=map(varcomps,~.$predictedfamvars)) %>%
unnest(varcomps) %>%
unnest(predVars)
return(out)})) %>%
unnest(crossVars)
# ### Combine all predicted vars into table
predictedCrossVars<-bind_rows(predictedCrossVars,
predictedDirDomCrossVars)
rm(predictedDirDomCrossVars); gc()
saveRDS(predictedCrossVars,file=here::here("output/crossPredictions","TableS7_predictedCrossVars.rds"))
predictedCrossVars<-readRDS(file=here::here("output/crossPredictions","TableS7_predictedCrossVars.rds"))
write.csv(predictedCrossVars,file = here::here("manuscript", "SupplementaryTable07.csv"), row.names = F)
```
```{r}
#suptables[["TableS07"]]<-predictedCrossVars
predictedCrossVars %>% str
```
```{r}
predictedCrossVars %>% count(Model,VarComp) %>% rmarkdown::paged_table()
```
## Table S8: Predicted versus observed cross variances
Table S8: Predicted versus observed cross variances. From the cross-validation analysis. For each fold of each repeat, each cross distinguished by a unique pair of sireID and damID is given. The genetic model used (Model: A, AD, DirDomAD, DirDomBV), whether the prediction is of family variance in breeding value (predOf=VarBV) or variance in total genetic value (predOf=VarTGV), the trait (BiofortSI or StdSI), type of observation (ValidationData: GBLUPs or iidBLUPs) and corresponding prediction (predVar) and observations (obsVar) are shown. The predictions are based on either only the variance of posterior means (VarMethod=VPM) or the posterior mean variances (VarMethod=PMV). The family size (number of genotyped offspring, FamSize) or number of offspring with direct phenotypes (Nobs) are used to weight the correlation (CorrWeight) between observed and predicted family variances.
```{r}
obsVSpredVars<-readRDS(here::here("output","obsVSpredVars.rds"))
write.csv(obsVSpredVars,file = here::here("manuscript", "SupplementaryTable08.csv"), row.names = F)
#suptables[["TableS08"]]<-obsVSpredVars
obsVSpredVars %>% str
```
```{r}
obsVSpredVars %>% count(Model,predOf,VarMethod,ValidationData) %>% spread(ValidationData,n) %>% rmarkdown::paged_table()
```
## Table S9: Predicted vs observed UC
Table S9: Predicted versus observed UC. For each fold of each repeat, each cross distinguished by a unique pair of sireID and damID is given. The predicted usefulness criterion (predUC) was computed as the predMean + realIntensity*predSD, where predMean is the predicted family mean and predSD is the predicted genetic standard deviation. The genetic model used (Model: A, AD, DirDomAD, DirDomBV), whether the prediction is of family variance in breeding value (predOf=VarBV) or variance in total genetic value (predOf=VarTGV), the trait (BiofortSI or StdSI) and corresponding prediction (predUC) and observations (obsUC) are shown. The family size (number of genotyped offspring, FamSize) is shown along with the realized selection intensity (realIntensity) for each selection stage in the breeding pipeline (Parent, CET, PYT, AYT, UYT) and also a constant intensity value (Stage=ConstIntensity).
```{r}
obsVSpredUC<-readRDS(here::here("output","obsVSpredUC.rds"))
write.csv(obsVSpredUC,file = here::here("manuscript", "SupplementaryTable09.csv"), row.names = F)
#suptables[["TableS09"]]<-obsVSpredUC
obsVSpredUC %>% str
```
```{r}
obsVSpredUC %>% count(Model,predOf,VarMethod,Stage) %>% spread(VarMethod,n) %>% rmarkdown::paged_table()
```
## Table S10: Accuracies predicting the mean
Table S10: Accuracies predicting the mean. For each fold of each repeat, the accuracy predicting family means (Accuracy) is given. The genetic model used (Model: A, AD, DirDomAD, DirDomBV), whether the prediction is of mean breeding value (predOf=MeanBV) or mean total genetic value (predOf=MeanTGV), the trait (BiofortSI or StdSI), type of observation (ValidationData: GBLUPs or iidBLUPs) are shown.
```{r}
accMeans<-readRDS(here::here("output","accuraciesMeans.rds"))
suptables[["TableS10"]]<-accMeans
accMeans %>% str
#accMeans %>% count(Model,predOf,ValidationData,Trait) %>% spread(Trait,n) %>% rmarkdown::paged_table()
```
## Table S11: Accuracies predicting the variances
Table S11: Accuracy of predicting the variances. For each fold of each repeat the estimated accuracy of predicting family variances is given. Accuracy was computed the correlation between predicted and observed variance, either weighted by family size (AccuracyWtCor) or not (AccuracyCor). The genetic model used (Model: A, AD, DirDomAD, DirDomBV), whether the prediction is of family variance in breeding value (predOf=VarBV) or variance in total genetic value (predOf=VarTGV), the trait (BiofortSI or StdSI), type of observation (ValidationData: GBLUPs or iidBLUPs) are shown. The predictions are based on either only the variance of posterior means (VarMethod=VPM) or the posterior mean variances (VarMethod=PMV).
```{r}
accVars<-readRDS(here::here("output","accuraciesVars.rds"))
suptables[["TableS11"]]<-accVars
accVars %>% str
```
```{r, cols.print=16}
accVars %>% #mutate(Trait1_Trait2=paste0(Trait1,"_",Trait2)) %>%
count(Model,predOf,VarMethod,ValidationData) %>% rmarkdown::paged_table()
```
## Table S12: Accuracies predicting the usefulness criteria
Table S12: Accuracy predicting the usefulness criteria. For each fold of each repeat the estimated accuracy of predicting family usefulness criteria is given. Accuracy was computed as the correlation between predicted UC and observed UC (mean of selected offspring), either weighted by family size (AccuracyWtCor) or not (AccuracyCor). The genetic model used (Model: A, AD, DirDomAD, DirDomBV), whether the prediction is of UC in breeding value (predOf=VarBV) or UC in total genetic value (predOf=VarTGV), the trait (BiofortSI or StdSI), type of observation (ValidationData: GBLUPs or iidBLUPs) are shown. The predictions of cross variance used to compute the UC are based on either only the variance of posterior means (VarMethod=VPM) or the posterior mean variances (VarMethod=PMV).
```{r}
accUC<-readRDS(here::here("output","accuraciesUC.rds"))
suptables[["TableS12"]]<-accUC
accUC %>% str
```
```{r, cols.print=16}
accUC %>%
count(Model,predOf,VarMethod,Stage,Trait) %>% spread(Trait,n) %>% rmarkdown::paged_table()
```
## Table S13: Realized within-cross selection metrics
Table S13: Realized within-cross selection metrics. Table summarizing measurements made of selection within each cross (unique sireID-damID). Summaries included: family size (FamSize), number (NmembersUsedAsParent) and proportion of members used as parents (propUsedAsParent), mean GEBV and GETGV of top 1% of each family (meanTop1pctGEBV, meanTop1pctGETGV), for each selection index Trait (Trait: BiofortSI, StdSI), proportion of each family that has been phenotyped (propPhenotyped, NmembersPhenotyped) and past each stage of the breeding pipeline (propPast and NmembersPast CET, PYT, AYT) and finally the corresponding realized intensity of selection for each stage (e.g. realIntensityAYT).
```{r, cols.print=28}
realizedcrossmetrics<-readRDS(file=here::here("output/crossRealizations","realizedCrossMetrics.rds"))
realizedcrossmetrics %<>%
select(-Repeat,-Fold,-Model,-contains("realizedUC")) %>%
ungroup() %>%
distinct %>%
arrange(desc(FamSize))
suptables[["TableS13"]]<-realizedcrossmetrics
realizedcrossmetrics %>% str
```
## Table S14: Proportion homozygous per clone
Table S14: Genome-wide proportion of SNPs that are homozygous, for each clone (GID=germplasmName).
```{r, eval=F}
library(tidyverse); library(magrittr); library(rsample); library(predCrossVar)
ped<-readRDS(here::here("data","ped_awc.rds"))
snps<-readRDS(here::here("data","dosages_awc.rds"))
snps %<>%
.[rownames(snps) %in% ped$FullSampleName,] %>%
remove_invariant(.); dim(snps) # [1] 3199 33370
f<-getPropHom(snps)
propHom<-tibble(GID=names(f), PropSNP_homozygous=as.numeric(f))
saveRDS(propHom,file=here::here("output","propHomozygous.rds"))
```
```{r}
propHom<-readRDS(file=here::here("output","propHomozygous.rds"))
suptables[["TableS14"]]<-propHom
head(propHom) %>% rmarkdown::paged_table()
```
## Table S15: Variance estimates for genetic groups
Table S15: Variance-covariance estimates for each genetic group. Summary of the population-level genetic variance estimates in each genetic group (GG=C0, TMS13=C1, TMS14=C2, TMS15=C3), for each genetic model (Model: A, AD, DirDomA, DirDomAD), each variance (Trait1==Trait2) and covariance (Trait1!=Trait2). The estimates are computed both based on the variance of posterior means (VarMethod=VPM) and the posterior mean variances (VarMethod=PMV). The "Method" refers to whether linkage disequilibrium is accounted for (M2) or not (M1).
```{r}
varcomps_geneticgroups<-readRDS(here::here("output","pmv_varcomps_geneticgroups_tidy_includingSIvars.rds"))
varcomps_geneticgroups %<>%
spread(VarComp,Var) %>%
mutate_if(is.numeric,~round(.,6)) %>%
mutate(propDom=ifelse(!is.na(VarD),round(VarD/(VarA+VarD),2),0)) %>%
select(-outName) %>%
arrange(VarMethod,desc(Method))
suptables[["TableS15"]]<-varcomps_geneticgroups
varcomps_geneticgroups %>% rmarkdown::paged_table()
```
```{r}
varcomps_geneticgroups %>% count(Method,VarMethod) %>% rmarkdown::paged_table()
```
```{r}
varcomps_geneticgroups %>% count(Group,Model) %>% spread(Model,n) %>% rmarkdown::paged_table()
```
## Table S16: Directional dominance effects estimates
Table S16: Directional dominance effects estimates. Based on the directional dominance model, the genome-wide posterior mean (InbreedingEffect) and posterior standard deviation (InbreedingEffectSD) inbreeding effect is given. Estimates are provided for each trait, genetic group (Group), and each repeat-fold of the cross-validation study.
```{r}
ddEffects<-readRDS(file=here::here("output","ddEffects.rds"))
ddEffects %<>%
mutate(Group=ifelse(is.na(Group),"ParentwiseCV",Group))
suptables[["TableS16"]]<-ddEffects
ddEffects %>% rmarkdown::paged_table()
```
```{r}
ddEffects %>% count(Group,Dataset,Trait) %>% spread(Trait,n) %>% arrange(Dataset)
```
## Table S17: Predictions of untested crosses
Table S17: Predictions of untested crosses. Compiled predictions of 47,083 possible crosses (sireID x damID) of 306 parents. Predictions were made with two additive-dominance genetic models: either with (Model=DirDomAD) or without (Model=ClassicAD) a directional dominance term. The predictions included are the cross mean (predMeanBV,predMeanGV), standard deviation (predSdBV,predSdGV) and usefulness (predUCparent,predUCvariety) in terms of breeding (BV) and total genetic (GV) value. Additional information provided for each cross include: whether the cross is a self (IsSelf=T/F), has previously been made (CrossPrevMade=Yes/No), the number of segregating SNPs expected in the family (Nsegsnps) and the parental GEBV (sireGEBV, damGEBV).
```{r}
library(tidyverse); library(magrittr);
predUntestedCrossMeans<-readRDS(here::here("output/crossPredictions","predictedUntestedCrossMeans_SelIndices.rds"))
#predUntestedCrossMeans %>% count(Model)
predUntestedCrossVars<-readRDS(here::here("output/crossPredictions","predictedUntestedCrossVars_SelIndices.rds"))
#predUntestedCrossVars %>% count(Model,predOf)
predUntestedCrosses<-predUntestedCrossMeans %>%
left_join(predUntestedCrossVars %>%
rename(Trait=Trait1) %>% select(-Trait2) %>%
mutate(Model=ifelse(Model %in% c("A","AD"),"ClassicAD","DirDom")) %>%
spread(predOf,predVar))
#
predUntestedCrosses %<>%
mutate(VarTGV=VarA+VarD,
predSdBV=sqrt(VarBV),
predSdTGV=sqrt(VarTGV)) %>%
select(-VarBV,-VarTGV,-VarA,-VarD) %>%
# Mean prop. selected is 2% for "parents" and 5% for "varieties" (AYT stage).
# Since in general, we want to use fewer crosses with more progeny, let's use 1% (std. sel. intensity = 2.67) for predicting UC.
# predCrossVar::intensity(0.01) %>% round(.,2) # [1] 2.67
mutate(predUCparent=predMeanBV+(2.67*predSdBV),
predUCvariety=predMeanGV+(2.67*predSdTGV))
ped<-readRDS(here::here("data","ped_awc.rds"))
predUntestedCrosses %<>%
left_join(ped %>% distinct(sireID,damID) %>% mutate(CrossPrevMade="Yes")) %>%
mutate(CrossPrevMade=ifelse(is.na(CrossPrevMade),"No",CrossPrevMade),
IsSelf=ifelse(sireID==damID,TRUE,FALSE))
rm(ped)
```
```{r}
predUntestedCrosses %>% str
```
```{r}
write.csv(predUntestedCrosses,file = here::here("manuscript", "SupplementaryTable17.csv"), row.names = F)
#suptables[["TableS17"]]<-predUntestedCrosses
```
## Table S18: Long-form table of predictions about untested crosses
Table S18: Long-form table of predictions about untested crosses. Compiled predictions of 47,083 possible crosses (sireID x damID) of 306 parents. Predictions were made with two additive-dominance genetic models: either with (Model=DirDomAD) or without (Model=ClassicAD) a directional dominance term. The predictions (Pred) included are of the cross mean (PredOf=Mean), standard deviation (PredOf=Sd) and usefulness (PredOf=UC) in terms of breeding (Component=BV) and total genetic (Component=GV) value. Additional information provided for each cross include: whether the cross is a self (IsSelf=T/F) and has previously been made (CrossPrevMade=Yes/No).
```{r}
predBVs<-predUntestedCrosses %>%
select(sireID,damID,IsSelf,CrossPrevMade,Model,Trait,predMeanBV,predSdBV,predUCparent) %>%
rename(predMean=predMeanBV,
predSd=predSdBV,
predUC=predUCparent) %>%
pivot_longer(cols = c(predMean,predSd,predUC), names_to = "PredOf", values_to = "Pred",names_prefix = "pred")
predTGVs<-predUntestedCrosses %>%
select(sireID,damID,IsSelf,CrossPrevMade,Model,Trait,predMeanGV,predSdTGV,predUCvariety) %>%
rename(predMean=predMeanGV,
predSd=predSdTGV,
predUC=predUCvariety) %>%
pivot_longer(cols = c(predMean,predSd,predUC), names_to = "PredOf", values_to = "Pred",names_prefix = "pred")
predUntestedCrosses_long<-bind_rows(predBVs %>% mutate(Component="BV"),
predTGVs %>% mutate(Component="TGV"))
# predUntestedCrosses_long %<>%
# left_join(predUntestedCrosses_long %>%
# group_by(Trait,Model,PredOf,Component) %>%
# summarise(top1pct = quantile(Pred, 0.99)) %>%
# ungroup()) %>%
# mutate(Selected=ifelse(Pred>=top1pct,"Selected","NotSelected")) %>%
# mutate_all(~`attributes<-`(.,NULL))
```
```{r}
predUntestedCrosses_long %>% str
```
```{r}
predUntestedCrosses_long %>%
count(Trait,Model,PredOf,Component) %>% spread(Trait,n) %>% rmarkdown::paged_table()
```
```{r}
write.csv(predUntestedCrosses_long,file = here::here("manuscript", "SupplementaryTable18.csv"), row.names = F)
#suptables[["TableS18"]]<-predUntestedCrosses_long
```
```{r}
rm(list=grep("suptables",ls(),invert = T, value = T)); gc()
```
## Table S19: Top 50 crosses selected by each criterion
Table S19: Top 50 crosses (sireID x damID) selected by each of 16 predictions of 47,083 crosses. Predictions for each trait were made with two additive-dominance genetic models: either with (Model=DirDomAD) or without (Model=ClassicAD) a directional dominance term. The predictions (Pred) selected on are of the cross mean (PredOf=Mean), standard deviation (PredOf=Sd) and usefulness (PredOf=UC) in terms of breeding (Component=BV) and total genetic (Component=GV) value. Additional information provided for each cross include: whether the cross is a self (IsSelf=T/F) and has previously been made (CrossPrevMade=Yes/No).
```{r}
library(tidyverse); library(magrittr); library(ggforce)
predUntestedCrosses<-read.csv(here::here("manuscript","SupplementaryTable18.csv"),stringsAsFactors = F)
top50crosses<-predUntestedCrosses %>%
filter(PredOf!="Sd") %>%
group_by(Trait,Model,PredOf,Component) %>%
slice_max(order_by = Pred,n=50) %>% ungroup()
suptables[["TableS19"]]<-top50crosses
```
```{r}
top50crosses %>% str
```
# Write SupplementaryTables.xlsx
```{r}
writexl::write_xlsx(suptables,path = here::here("manuscript","SupplementaryTables.xlsx"),format_headers =FALSE)
```