Abstract
BackgroundIn eukaryotic genomes, most genes are members of gene families. When comparing genes from two species, therefore, most genes in one species will be homologous to multiple genes in the second. This often makes it difficult to distinguish orthologs (separated through speciation) from paralogs (separated by other types of gene duplication). Combining phylogenetic relationships and genomic position in both genomes helps to distinguish between these scenarios. This kind of comparison can also help to describe how gene families have evolved within a single genome that has undergone polyploidy or other large-scale duplications, as in the case of Arabidopsis thaliana – and probably most plant genomes.ResultsWe describe a suite of programs called OrthoParaMap (OPM) that makes genomic comparisons, identifies syntenic regions, determines whether sets of genes in a gene family are related through speciation or internal chromosomal duplications, maps this information onto phylogenetic trees, and infers internal nodes within the phylogenetic tree that may represent local – as opposed to speciation or segmental – duplication. We describe the application of the software using three examples: the melanoma-associated antigen (MAGE) gene family on the X chromosomes of mouse and human; the 20S proteasome subunit gene family in Arabidopsis, and the major latex protein gene family in Arabidopsis.ConclusionOPM combines comparative genomic positional information and phylogenetic reconstructions to identify which gene duplications are likely to have arisen through internal genomic duplications (such as polyploidy), through speciation, or through local duplications (such as unequal crossing-over). The software is freely available at .
Highlights
IntroductionWhen comparing genes from two species, most genes in one species will be homologous to multiple genes in the second
In eukaryotic genomes, most genes are members of gene families
Overview of Results and Discussion we describe 1) objectives of the OPM suite; 2) application of the method in the melanoma-associated antigen (MAGE) gene family in mouse and human 3) application of the method to the 20S proteasome gene family in Arabidopsis; 4) application of the method to another gene family, the "major latex proteins" in Arabidopsis. 4) discussion of performance
Summary
When comparing genes from two species, most genes in one species will be homologous to multiple genes in the second This often makes it difficult to distinguish orthologs (separated through speciation) from paralogs (separated by other types of gene duplication). Combining phylogenetic relationships and genomic position in both genomes helps to distinguish between these scenarios This kind of comparison can help to describe how gene families have evolved within a single genome that has undergone polyploidy or other large-scale duplications, as in the case of Arabidopsis thaliana – and probably most plant genomes. To extend knowledge about genes in a model species to other related species, it is important to distinguish genes that are directly related to one another through speciation (orthologs) from genes that have duplicated independent of speciation (paralogs) [1]. Characterizing gene families in these terms requires identifying genes as having paralogous or orthologous origins
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