For a succinct version of this example where you can copy/paste all code in one go, see the main vignette
In this example genotypes are simulated from a fictional pedigree, which together with the associated life history data is provided with the package. This pedigree consists of 5 discrete generations with interconnected half-sib clusters (Pedigree II in the paper1).
# Install the package. This is only the required the first time, or if you wish to update
# install.packages("sequoia")
# Load the package. This is required at the start of every new R session.
library(sequoia)
# Load the example pedigree and life history data
data(Ped_HSg5, LH_HSg5)
# Take a look at the data structure
tail(Ped_HSg5)
head(LH_HSg5)
# or, in Rstudio, view the full dataframe:
View(Ped_HSg5)
Simulate some genotype data to use for this try-out.
Function SimGeno()
can simulate data with a specific
genotyping error rate, call rate and proportion of non-genotyped
parents, see its helpfile (?SimGeno
) for details. Here we
use the defaults; 40% of parents are presumed non-genotyped (their
genotypes are removed from the dataset before SimGeno()
returns its result).
Alternatively, use the simulated genotype data included in the package to get identical results:
Run sequoia with the genotype data, lifehistory data, and otherwise default values. It is often advisable to first only run parentage assignment, and check if the results are sensible and/or if any parameters need adjusting. Full pedigree reconstruction, including sibship clustering etc., is much more time consuming.
To only run a data check, duplicate check (always performed first)
and parentage assignment, specify Module = 'par'
:
## ℹ Checking input data ...
## ! There are 2 SNPs scored for <50% of individuals
## ℹ There are 920 individuals and 200 SNPs.
##
## ── Among genotyped individuals: ___
## ℹ There are 467 females, 453 males, 0 of unknown sex, and 0 hermaphrodites.
## ℹ Exact birth years are from 2000 to 2005
## ___
## ℹ Calling `MakeAgePrior()` ...
## ℹ Ageprior: Flat 0/1, overlapping generations, MaxAgeParent = 6,6
##
## ~~~ Duplicate check ~~~
## ✔ No potential duplicates found
##
## ~~~ Parentage assignment ~~~
## Time | R | Step | progress | dams | sires | Total LL
## -------- | -- | ---------- | ---------- | ----- | ----- | ----------
## 06:55:53 | 0 | initial | | 0 | 0 | -70880.7
## 06:55:53 | 0 | parents | | 514 | 524 | -57593.7
## 06:55:58 | 99 | est byears | |
## 06:55:58 | 99 | calc LLR | |
## ✔ assigned 514 dams and 524 sires to 920 individuals
You will see several plots appearing:
SnpStats()
, which is called by CheckGeno()
to make sure there are no monomorphic SNPs or SNPs with extremely high
missingness in the datasetSummarySeq()
):
nearly 60% of individuals have a genotyped parent assigned, in line with
the 40% non-genotyped parents we simulated.In addition, you will see several messages, including about the initial and post-parentage total LL (log10-likelihood). This is the probability of observing the genotype data, given the (current) pedigree; initially it is assumed that all individuals are unrelated. This number is negative, and gets closer to zero when the pedigree explains the data better.
The result is a list, with the following elements:
## [1] "Specs" "ErrM" "args.AP" "Snps-LowCallRate"
## [5] "DupLifeHistID" "NoLH" "AgePriors" "LifeHist"
## [9] "PedigreePar" "TotLikPar" "AgePriorExtra" "LifeHistPar"
which are explained in detail in the helpfile (?sequoia
)
and the main vignette.
you find the assigned parents in list element
PedigreePar
:
## id dam sire LLRdam LLRsire LLRpair OHdam OHsire MEpair
## 915 b05187 a04045 <NA> 7.16 NA NA 0 NA NA
## 916 a05188 a04045 <NA> 7.37 NA NA 0 NA NA
## 917 a05189 <NA> b04177 NA 3.32 NA NA 0 NA
## 918 b05190 <NA> b04177 NA 3.53 NA NA 0 NA
## 919 b05191 <NA> b04177 NA 3.50 NA NA 0 NA
## 920 b05192 <NA> b04177 NA 4.34 NA NA 0 NA
we can compare these to the true parents, in the original pedigree from which we simulated the genotype data:
## parent
## class dam sire
## Total 537 544
## Match 513 523
## Mismatch 1 1
## P1only 23 20
## P2only 0 0
Here ‘GG’ stands for Genotyped offspring, Genotyped parent.
Then, we can run full pedigree reconstruction. By default, this re-runs the parentage assignment.
If you don’t want to re-run parentage assignment (e.g. because it took quite a bit of time), or if you have specified several non-default parameter values you want to use again, , you can provide the old output as input.
Re-used will be:
$Specs
)$ErrM
)$LifeHist
)$AgePriors
)The last is generated by MakeAgePrior()
, which has
detected that all parent-offspring pairs have an age difference of 1, and all siblings an age difference of
0, i.e. that generations do not
overlap. This information will be used during the full pedigree
reconstruction.
## M P FS MS PS
## 0 0 0 1 1 1
## 1 1 1 0 0 0
## 2 0 0 0 0 0
So run sequoia()
with the old output as input,
Full pedigree reconstruction will take at least a few minutes to run on this fairly simple dataset with one thousand individuals. It may take a few hours on larger or more complex datasets, and/or if there is much ambiguity about relationships due to a low number of SNPs, genotyping errors, and missing data.
The output from this example pedigree is included with the package:
You will get several messages:
CheckGeno()
to inform you that the genotype data
is OKSeqList
(the output from
the old sequoia()
run) are being re-usedAgain you will see some plots:
$AgePriorExtra
). These are derived from the ageprior for
parents and siblings, which hasn’t changed since just after parentage
assignmentFor additional plots and a few tables to inspect the pedigree, you
can use SummarySeq()
:
## [1] "PedSummary" "ParentCount" "GPCount" "SibSize"
And again we can also compare the results to the true parents:
## , , parent = dam
##
## class
## cat Total Match Mismatch P1only P2only
## GG 537 537 0 0 0
## GD 357 357 0 0 0
## GT 894 894 0 0 0
## DG 39 39 0 0 0
## DD 27 27 0 0 0
## DT 66 66 0 0 0
## TT 960 960 0 0 0
##
## , , parent = sire
##
## class
## cat Total Match Mismatch P1only P2only
## GG 543 543 0 0 0
## GD 351 351 0 0 0
## GT 894 894 0 0 0
## DG 33 33 0 0 0
## DD 33 33 0 0 0
## DT 66 66 0 0 0
## TT 960 960 0 0 0
See ?PedCompare
for a more interesting example with some
mismatches.
If you wish to count e.g. the number of full sibling pairs that are
assigned as full siblings, paternal half siblings, maternal
halfsiblings, or unrelated, or similar comparisons, use
ComparePairs()
.
Lastly, you often wish to save the results to file. You can do this
as an Rdata
file, which can contain any number of R
objects. You can later retrieve these in R using load
, so
that you can later resume where you left of. The disadvantage is that
you cannot open the Rdata
files outside of R (as far as I
am aware). Therefore, sequoia
also includes a function to
write all output to a set of plain text files in a specified folder.
Huisman, Jisca. “Pedigree reconstruction from SNP data: parentage assignment, sibship clustering and beyond.” Molecular ecology resources 17.5 (2017): 1009-1024.↩︎