Genetical genomics: combining genetics with gene expression analysis

doi:10.1093/hmg/ddi267

Human Molecular Genetics 2005 14(Review Issue 2):R163-R169; doi:10.1093/hmg/ddi267

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Genetical genomics: combining genetics with gene expression analysis

Jun Li¹ and Margit Burmeister²^,3^,*

¹Stanford Human Genome Center, Stanford University, Palo Alto, CA, USA, ²Department of Psychiatry and ³Department of Human Genetics, Molecular and Behavioral Neuroscience Institute, University of Michigan, Ann Arbor, MI 48109-0720, USA

^* To whom correspondence should be addressed. Tel: +1 7346472186; Fax: +1 7346474130; Email: margit{at}umich.edu

Received June 27, 2005; Accepted July 14, 2005

The biological mechanisms that link genetic variation and itsphenotypic outcome stand as a central puzzle in biology. Geneticistshave usually approached this problem by trying to identify geneticvariants that underlie the trait in question. Ten years ago,microarray technology opened a second front by making it possibleto compare expression levels for most active genes under a varietyof genetic and environmental conditions. A typical study revealsup- or down-regulation of genes or pathways associated witha phenotype (case/control) or condition (treated/untreated).In the past few years, a number of groups have started to combinegene expression studies with genetic linkage analysis, leadingto a new synergy between these approaches. In this strategy,expression levels are treated as quantitative phenotypes andgenetic variants that influence gene expression are sought.Several studies have shown that mRNA levels for many genes areheritable, thus amenable to genetic analysis. Quantitative traitloci mapping efforts have led to the initial characterizationof genetic regulation in ‘cis’ probably becauseof variants in the gene's own regulatory regions, as well asin ‘trans’, i.e. by loci elsewhere in the genome.The existence of some ‘master regulators’ that eachaffects expression levels of hundreds of genes is an importantfinding that will surely enrich our understanding of regulatorynetworks. Although this novel field is still developing, understandingthe genetic basis of molecular phenotypes such as gene expressionis expected to shed light on the intermediate processes thatconnect genotype to cellular and organismal traits and representsa critical step towards true systems biology.

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