metaCcaPlusGp: Function to perform genotype-phenotype association analysis...
In metaCCA: Summary Statistics-Based Multivariate Meta-Analysis of Genome-Wide Association Studies Using Canonical Correlation Analysis
Description
Usage
Arguments
Value
Author(s)
References
Examples
View source: R/metaCcaPlusGp.R
Description
This function performs genotype-phenotype association analysis according
to metaCCA+ algorithm (the variant of metaCCA, where the full covariance matrix
is shrunk beyond the level guaranteeing its positive semidefinite property).
metaCcaPlusGp requires exactly the same inputs as metaCcaGp function,
and it has the same output format.
Usage
1
metaCcaPlusGp( nr_studies, S_XY, std_info, S_YY, N, analysis_type, SNP_id, S_XX )
Arguments
nr_studies
Number of studies to be analysed.
S_XY
Univariate summary statistics of the variables to be analysed.
A list of data frames (one for each study) with row names corresponding
to SNP IDs (e.g., position or rs_id) and the following columns:
- allele_0 - string composed of "A", "C", "G" or "T",
- allele_1 - string composed of "A", "C", "G" or "T",
- then, two columns for each trait (phenotypic variable) to be included in the
analysis; in turn:
1) traitID_b with linear regression coefficients,
2) traitID_se with corresponding standard errors
("traitID" in the column name must be an ID of a trait specified by a user;
do not use underscores "_" in trait IDs outside "_b"/"_se" in order for the
IDs to be processed correctly).
std_info
A vector with numerical values 0/1 (one value for each study)
indicating if the univariate analysis has been performed
on standardised (1) or non-standardised (0) data;
(most likely the data were not standardised - the genotypes were not
standardised before univariate regression coefficients and standard errors
were computed - option 0 should be used).
S_YY
A list of phenotypic correlation matrices (one for each study)
estimated using estimateSyy function.
N
A vector with numbers of individuals in each study.
Arguments below are OPTIONAL and depend on the type of the analysis.
analysis_type
Indicator of the analysis type.
1) Single-SNP–multi-trait analysis of one selected SNP: 1.
2) Multi-SNP–multi-trait analysis: 2.
SNP_id
1) Single-SNP–multi-trait analysis of one selected SNP:
An ID of the SNP of interest.
2) Multi-SNP–multi-trait analysis:
A vector with IDs of SNPs to be analysed jointly.
S_XX
A list of data frames (one for each study) containing correlations
between SNPs. Row names (and, optionally, column names) must correspond
to SNP IDs. This argument needs to be given only in case
of multi-SNP–multi-trait analysis.
Value
result
Data frame with row names corresponding to SNP IDs.
Columns contain:
1) r_1 - leading canonical correlation value,
2) -log10(p-val) - p-value in the -log10 scale,
3) trait_weights - trait-wise canonical weights,
4) snp_weights - SNP-wise canonical weights (only for multi-SNP-<e2><80><93>multi-trait analysis).
Author(s)
Anna Cichonska
References
Cichonska et al. (2016) metaCCA: Summary statistics-based multivariate
meta-analysis of genome-wide association studies using canonical
correlation analysis. Bioinformatics, 32(13):1981-1989.
Examples
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# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Analysis of one study according to metaCCA+ algorithm. #
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Default single-SNP--multi-trait analysis.
# Here, we will test each of 10 SNPs for an association with a set of 10 traits.
result1 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1 ) ),
N = N1 )
# Viewing association results
print( result1, digits = 3 )
# Single-SNP--multi-trait analysis of one selected SNP.
# Here, we will test one of 10 SNPs for an association with a set of 10 traits.
result2 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1) ),
N = N1,
analysis_type = 1,
SNP_id = 'rs80' )
# Viewing association results
print( result2, digits = 3 )
# Multi-SNP--multi-trait analysis.
# Here, we will test a set of 5 SNPs for an association with a set of 10 traits.
result3 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1) ),
N = N1,
analysis_type = 2,
SNP_id = c( 'rs10', 'rs80', 'rs140', 'rs170', 'rs172' ),
S_XX = list( S_XX_study1 ) )
# Viewing association results
print( result3, digits = 3 )
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Meta-analysis of two studies according to metaCCA+ algorithm. #
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Default single-SNP--multi-trait analysis.
# Here, we will test each of 10 SNPs for an association with a set of 10 traits.
meta_result1 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ) )
# Viewing association results
print( meta_result1, digits = 3 )
# Single-SNP--multi-trait analysis of one selected SNP.
# Here, we will test one of 10 SNPs for an association with a set of 10 traits.
meta_result2 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ),
analysis_type = 1,
SNP_id = 'rs80' )
# Viewing association results
print( meta_result2, digits = 3 )
# Multi-SNP--multi-trait analysis.
# Here, we will test a set of 5 SNPs for an association with a set of 10 traits.
meta_result3 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ),
analysis_type = 2,
SNP_id = c( 'rs10', 'rs80', 'rs140', 'rs170', 'rs172' ),
S_XX = list( S_XX_study1, S_XX_study2 ) )
# Viewing association results
print( meta_result3, digits = 3 )
metaCCA documentation built on Nov. 8, 2020, 10:58 p.m.
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Description Usage Arguments Value Author(s) References Examples
View source: R/metaCcaPlusGp.R
Description
This function performs genotype-phenotype association analysis according to metaCCA+ algorithm (the variant of metaCCA, where the full covariance matrix is shrunk beyond the level guaranteeing its positive semidefinite property).
metaCcaPlusGp requires exactly the same inputs as metaCcaGp function,
and it has the same output format.
Usage
1 | metaCcaPlusGp( nr_studies, S_XY, std_info, S_YY, N, analysis_type, SNP_id, S_XX )
|
Arguments
nr_studies |
Number of studies to be analysed. |
S_XY |
Univariate summary statistics of the variables to be analysed. A list of data frames (one for each study) with row names corresponding to SNP IDs (e.g., position or rs_id) and the following columns: - - - then, two columns for each trait (phenotypic variable) to be included in the analysis; in turn: 1) 2) ("traitID" in the column name must be an ID of a trait specified by a user; do not use underscores "_" in trait IDs outside "_b"/"_se" in order for the IDs to be processed correctly). |
std_info |
A vector with numerical values (most likely the data were not standardised - the genotypes were not
standardised before univariate regression coefficients and standard errors
were computed - option |
S_YY |
A list of phenotypic correlation matrices (one for each study)
estimated using |
N |
A vector with numbers of individuals in each study. |
Arguments below are OPTIONAL and depend on the type of the analysis.
analysis_type |
Indicator of the analysis type. 1) Single-SNP–multi-trait analysis of one selected SNP: 2) Multi-SNP–multi-trait analysis: |
SNP_id |
1) Single-SNP–multi-trait analysis of one selected SNP: An ID of the SNP of interest. 2) Multi-SNP–multi-trait analysis: A vector with IDs of SNPs to be analysed jointly. |
S_XX |
A list of data frames (one for each study) containing correlations between SNPs. Row names (and, optionally, column names) must correspond to SNP IDs. This argument needs to be given only in case of multi-SNP–multi-trait analysis. |
Value
result |
Data frame with row names corresponding to SNP IDs. Columns contain: 1) 2) 3) 4) |
Author(s)
Anna Cichonska
References
Cichonska et al. (2016) metaCCA: Summary statistics-based multivariate meta-analysis of genome-wide association studies using canonical correlation analysis. Bioinformatics, 32(13):1981-1989.
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 | # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Analysis of one study according to metaCCA+ algorithm. #
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Default single-SNP--multi-trait analysis.
# Here, we will test each of 10 SNPs for an association with a set of 10 traits.
result1 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1 ) ),
N = N1 )
# Viewing association results
print( result1, digits = 3 )
# Single-SNP--multi-trait analysis of one selected SNP.
# Here, we will test one of 10 SNPs for an association with a set of 10 traits.
result2 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1) ),
N = N1,
analysis_type = 1,
SNP_id = 'rs80' )
# Viewing association results
print( result2, digits = 3 )
# Multi-SNP--multi-trait analysis.
# Here, we will test a set of 5 SNPs for an association with a set of 10 traits.
result3 = metaCcaPlusGp( nr_studies = 1,
S_XY = list( S_XY_study1 ),
std_info = 0,
S_YY = list( estimateSyy(S_XY_full_study1) ),
N = N1,
analysis_type = 2,
SNP_id = c( 'rs10', 'rs80', 'rs140', 'rs170', 'rs172' ),
S_XX = list( S_XX_study1 ) )
# Viewing association results
print( result3, digits = 3 )
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Meta-analysis of two studies according to metaCCA+ algorithm. #
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# Default single-SNP--multi-trait analysis.
# Here, we will test each of 10 SNPs for an association with a set of 10 traits.
meta_result1 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ) )
# Viewing association results
print( meta_result1, digits = 3 )
# Single-SNP--multi-trait analysis of one selected SNP.
# Here, we will test one of 10 SNPs for an association with a set of 10 traits.
meta_result2 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ),
analysis_type = 1,
SNP_id = 'rs80' )
# Viewing association results
print( meta_result2, digits = 3 )
# Multi-SNP--multi-trait analysis.
# Here, we will test a set of 5 SNPs for an association with a set of 10 traits.
meta_result3 = metaCcaPlusGp( nr_studies = 2,
S_XY = list( S_XY_study1, S_XY_study2 ),
std_info = c( 0, 0 ),
S_YY = list( estimateSyy(S_XY_full_study1),
estimateSyy(S_XY_full_study2) ),
N = c( N1, N2 ),
analysis_type = 2,
SNP_id = c( 'rs10', 'rs80', 'rs140', 'rs170', 'rs172' ),
S_XX = list( S_XX_study1, S_XX_study2 ) )
# Viewing association results
print( meta_result3, digits = 3 )
|
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