est.map: Estimate genetic maps
In kbroman/qtl: Tools for Analyzing QTL Experiments
est.map R Documentation
Estimate genetic maps
Description
Uses the Lander-Green algorithm (i.e., the hidden Markov model
technology) to re-estimate the genetic map for an experimental cross.
Usage
est.map(cross, chr, error.prob=0.0001,
map.function=c("haldane","kosambi","c-f","morgan"),
m=0, p=0, maxit=10000, tol=1e-6, sex.sp=TRUE,
verbose=FALSE, omit.noninformative=TRUE, offset, n.cluster=1)
Arguments
cross
An object of class cross. See
read.cross for details.
chr
Optional vector indicating the chromosomes to consider.
This should be a vector of character
strings referring to chromosomes by name; numeric values are
converted to strings. Refer to chromosomes with a preceding -
to have all chromosomes but those considered. A logical (TRUE/FALSE)
vector may also be used.
error.prob
Assumed genotyping error rate used in the calculation
of the penetrance Pr(observed genotype | true genotype).
map.function
Indicates whether to use the Haldane, Kosambi,
Carter-Falconer, or Morgan map function when converting genetic
distances into recombination fractions. (Ignored if m > 0.)
m
Interference parameter for the chi-square model for
interference; a non-negative integer, with m=0 corresponding to no
interference. This may be used only for a backcross or intercross.
p
Proportion of chiasmata from the NI mechanism, in the Stahl
model; p=0 gives a pure chi-square model. This may be used only for
a backcross or intercross.
maxit
Maximum number of EM iterations to perform.
tol
Tolerance for determining convergence.
sex.sp
Indicates whether to estimate sex-specific maps; this is
used only for the 4-way cross.
verbose
If TRUE, print tracing information.
omit.noninformative
If TRUE, on each chromosome, omit individuals
with fewer than two typed markers, since they are not informative for
linkage.
offset
Defines the starting position
for each chromosome. If missing, we use the starting positions that
are currently present in the input cross object. This should be a
single value (to be used for all chromosomes) or a vector with length
equal to the number of chromosomes, defining individual starting
positions for each chromosome. For a sex-specific map (as in a 4-way
cross), we use the same offset for both the male and female maps.
n.cluster
If the package snow is available
calculations for multiple chromosomes are run in parallel using this
number of nodes.
Details
By default, the map is estimated assuming no crossover interference,
but a map function is used to derive the genetic distances (though, by
default, the Haldane map function is used).
For a backcross or intercross, inter-marker distances may be estimated
using the Stahl model for crossover interference, of which the
chi-square model is a special case.
In the chi-square model, points are tossed down onto the four-strand
bundle according to a Poisson process, and every (m+1)st point is a
chiasma. With the assumption of no chromatid interference, crossover
locations on a random meiotic product are obtained by thinning the
chiasma process. The parameter m (a non-negative integer)
governs the strength of crossover interference, with m=0
corresponding to no interference.
In the Stahl model, chiasmata on the four-strand bundle are a
superposition of chiasmata from two mechanisms, one following a
chi-square model and one exhibiting no interference. An additional
parameter, p, gives the proportion of chiasmata from the no
interference mechanism.
Value
A map object; a list whose components (corresponding to
chromosomes) are either vectors of marker positions (in cM) or
matrices with two rows of sex-specific marker positions.
The maximized log likelihood for each chromosome is saved as an
attribute named loglik. In the case that estimation was under
an interference model (with m > 0), allowed only for a backcross, m
and p are also included as attributes.
Author(s)
Karl W Broman, broman@wisc.edu
References
Armstrong, N. J., McPeek, M. J. and Speed, T. P. (2006) Incorporating
interference into linkage analysis for experimental crosses.
Biostatistics 7, 374–386.
Lander, E. S. and Green, P. (1987) Construction of multilocus genetic linkage
maps in humans. Proc. Natl. Acad. Sci. USA 84, 2363–2367.
Lange, K. (1999) Numerical analysis for statisticians.
Springer-Verlag. Sec 23.3.
Rabiner, L. R. (1989) A tutorial on hidden Markov models and selected
applications in speech recognition. Proceedings of the IEEE
77, 257–286.
Zhao, H., Speed, T. P. and McPeek, M. S. (1995) Statistical analysis of
crossover interference using the chi-square model. Genetics
139, 1045–1056.
See Also
map2table, plotMap, replace.map,
est.rf, fitstahl
Examples
data(fake.f2)
newmap <- est.map(fake.f2)
logliks <- sapply(newmap, attr, "loglik")
plotMap(fake.f2, newmap)
fake.f2 <- replace.map(fake.f2, newmap)
kbroman/qtl documentation built on Jan. 13, 2024, 10:14 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
| est.map | R Documentation |
Estimate genetic maps
Description
Uses the Lander-Green algorithm (i.e., the hidden Markov model technology) to re-estimate the genetic map for an experimental cross.
Usage
est.map(cross, chr, error.prob=0.0001,
map.function=c("haldane","kosambi","c-f","morgan"),
m=0, p=0, maxit=10000, tol=1e-6, sex.sp=TRUE,
verbose=FALSE, omit.noninformative=TRUE, offset, n.cluster=1)
Arguments
cross |
An object of class |
chr |
Optional vector indicating the chromosomes to consider.
This should be a vector of character
strings referring to chromosomes by name; numeric values are
converted to strings. Refer to chromosomes with a preceding |
error.prob |
Assumed genotyping error rate used in the calculation of the penetrance Pr(observed genotype | true genotype). |
map.function |
Indicates whether to use the Haldane, Kosambi, Carter-Falconer, or Morgan map function when converting genetic distances into recombination fractions. (Ignored if m > 0.) |
m |
Interference parameter for the chi-square model for interference; a non-negative integer, with m=0 corresponding to no interference. This may be used only for a backcross or intercross. |
p |
Proportion of chiasmata from the NI mechanism, in the Stahl model; p=0 gives a pure chi-square model. This may be used only for a backcross or intercross. |
maxit |
Maximum number of EM iterations to perform. |
tol |
Tolerance for determining convergence. |
sex.sp |
Indicates whether to estimate sex-specific maps; this is used only for the 4-way cross. |
verbose |
If TRUE, print tracing information. |
omit.noninformative |
If TRUE, on each chromosome, omit individuals with fewer than two typed markers, since they are not informative for linkage. |
offset |
Defines the starting position for each chromosome. If missing, we use the starting positions that are currently present in the input cross object. This should be a single value (to be used for all chromosomes) or a vector with length equal to the number of chromosomes, defining individual starting positions for each chromosome. For a sex-specific map (as in a 4-way cross), we use the same offset for both the male and female maps. |
n.cluster |
If the package |
Details
By default, the map is estimated assuming no crossover interference, but a map function is used to derive the genetic distances (though, by default, the Haldane map function is used).
For a backcross or intercross, inter-marker distances may be estimated using the Stahl model for crossover interference, of which the chi-square model is a special case.
In the chi-square model, points are tossed down onto the four-strand
bundle according to a Poisson process, and every (m+1)st point is a
chiasma. With the assumption of no chromatid interference, crossover
locations on a random meiotic product are obtained by thinning the
chiasma process. The parameter m (a non-negative integer)
governs the strength of crossover interference, with m=0
corresponding to no interference.
In the Stahl model, chiasmata on the four-strand bundle are a
superposition of chiasmata from two mechanisms, one following a
chi-square model and one exhibiting no interference. An additional
parameter, p, gives the proportion of chiasmata from the no
interference mechanism.
Value
A map object; a list whose components (corresponding to
chromosomes) are either vectors of marker positions (in cM) or
matrices with two rows of sex-specific marker positions.
The maximized log likelihood for each chromosome is saved as an
attribute named loglik. In the case that estimation was under
an interference model (with m > 0), allowed only for a backcross, m
and p are also included as attributes.
Author(s)
Karl W Broman, broman@wisc.edu
References
Armstrong, N. J., McPeek, M. J. and Speed, T. P. (2006) Incorporating interference into linkage analysis for experimental crosses. Biostatistics 7, 374–386.
Lander, E. S. and Green, P. (1987) Construction of multilocus genetic linkage maps in humans. Proc. Natl. Acad. Sci. USA 84, 2363–2367.
Lange, K. (1999) Numerical analysis for statisticians. Springer-Verlag. Sec 23.3.
Rabiner, L. R. (1989) A tutorial on hidden Markov models and selected applications in speech recognition. Proceedings of the IEEE 77, 257–286.
Zhao, H., Speed, T. P. and McPeek, M. S. (1995) Statistical analysis of crossover interference using the chi-square model. Genetics 139, 1045–1056.
See Also
map2table, plotMap, replace.map,
est.rf, fitstahl
Examples
data(fake.f2)
newmap <- est.map(fake.f2)
logliks <- sapply(newmap, attr, "loglik")
plotMap(fake.f2, newmap)
fake.f2 <- replace.map(fake.f2, newmap)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.