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Genetic Analysis of Genome-wide Variation in Human Gene Expression Morley M. et al. Nature 2004,430: 743-747 . . Yen-Yi Ho. Outline. Introduction Data Method: Linkage analysis Results Discussion Comments. Introduction.
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Genetic Analysis of Genome-wide Variation in Human Gene ExpressionMorley M. et al. Nature 2004,430: 743-747. Yen-Yi Ho
Outline • Introduction • Data • Method: Linkage analysis • Results • Discussion • Comments
Goal : Identify loci associated with variation in expression levels Nucleus regulators Genomic DNA mRNA mRNA Target
Trans-regulator Cis-regulator Cis and Trans regulation Target gene expression phenotype
Data Centre d'Etude du Polymorphisme Humain (CEPH) families are Utah residents with ancestry from northern and western Europe. • 14 families with genotype and expression data available for all parents and a mean of eight offspring (range 7-9)
2,756 autosomal SNP genetic loci (100kb within cluster, 3 Mb between cluster). • Gene expression phenotypes ~8,500 gene expression phenotypes in immortalized B cells using Affymetrix Genome Focus Array. Expression intensity was scaled to 500 and transformed by log2.
3,554 most variable expression phenotypes are selected (between > within variation). • Using CEPH unrelated individuals (94 grandparents), two array replicates per individual was performed. The within individual variation was indicated by the mean of variance of array replicates.
A1 A2 A3 A4 A1 A2 A3 A4 A1 A2 A3A4 A1 A3 A1 A4 A1 A3 A2 A4 A1 A3 A1 A3 IBD=2 Method: Linkage analysis IBD=1 IBD=0 IBD: identical-by-descent
15 10 5 For a particular target gene expression t-statistics SNP1 2 3 4 5 Genetic Locus
Results Criteria 1 : t > 5 (P-value < 4.3 , LOD > 5.3) : 142 expression phenotypes have at least one significant regulator. Criteria 2 : t > 4 (P-value < 3.7 , LOD > 3.4): 984 expression phenotypes have at least one significant regulator.
Cis and trans- regulation Under criteria 1, • 27/142 (19%) expression phenotype have only a single cis-regulator. • 110/142 (77.5%) expression phenotype have only a single trans-regulator. • 2 /142 have a cis and a trans-acting regulator • 3 /142 gene expression have two trans-acting regulator Under criteria 2, 164 / 984 (16%) has multiple regulators
5 Mb window (total 491 windows) T-statistic 1 2 3 . . . 3554 Gene expression “Target” Criteria 2 t > 3.4 SNP 1 2 3 …..2756 SNP 1 2 3 …..2756 Genetic Locus “regulator”
Master regulator 31 25 14q32 20q13 Divide the autosomal genome into 491 windows of 5 Mb, and count the number of regulators in the regions under criteria 2 (total 984 phenotypes with significant linkages).
Co-regulation • Use the gene expression levels of 94 CEPH grandparents • Hierarchical clustering was performed and group genes by the correlation of the 31 target gene expression levels • Permutation test was used to determine the significant level of pair-wise correlation.
Population-based association analysis for cis-regulators (SNP regulator)
Discussion • The study applied genome-wide mapping method to identify the chromosomal regions regulate to the gene expression phenotypes. • This type of study has the potential to uncover complicated transcriptional control. • Cis-, trans-acting and master regulators were discovered. • The linkage results are reliable as verified by association study and qRT-PCR.
Comments • In this study, gene expression measured in immortalized B cells may be very different from the expression of human B cells in the blood. • Co-regulated genes and the pathways that connect genes are identified. • We would be even more interested in utilizing the data to improve our understanding of human disease. Genotype Gene expression Phenotype
Candidate regions have cis-effects. • Different phenotype / expression signatures associated with different “regulators”.
Statistical design and analysis issues Design: • Choice of relative type or pedigree in humans. • Choice of tissue and timing of mRNA sampling. Analysis: • Multiple testing: linkage location, transcripts. • Regulatory hotspots: methods to find master regulatory loci. • Regulatory networks: searching for small sets of Co-regulated transcripts.
Reference • Genetic analysis of genome-wide variation in human gene expression. Moley M., Molony C.M, Teresa M. Weber T.M. et al. Nature 430:743-747 (2004). • Genetics of gene expression surveyed in maize, mouse, and man. Schadt E.E., Monks S.A., Drake T.A. et al. Nature 422: 297-302 (2003). • Mapping expression in randomized rodent genomes. Broman K.W. Nature Genetics 37: 209-210 (2005). • Natural variation in human gene expression assessed in lymphoblastoid cells. Cheung V.G., Conlin L.K., Weber T.M. et al. Nature Genetics 33: 422-425 (2003). • Mapping determinants of human gene expression by regional and genome-wide association. Cheung V.G., Spielman R.S., Ewens K.G. et al. Nature 437: 1365-1369 (2005).