The model species of social amoebae, Dictyostelium discoideum, has a compact genome consisting of about two thirds protein-coding regions, with intergenic regions that are rarely larger than 1,000 bp. We hypothesize that the haploid state of D. discoideum cells provides defense against the amplification of mobile elements whose transposition activities would otherwise lead to the accumulation of heterozygous, potentially lethal mutations in diploid populations. We further speculate that complex transposon clusters found on D. discoideum chromosomes do not a priori result from integration preferences of these transposons, but that the clusters instead result from negative selection against cells harboring insertional mutations in genes. D. discoideum cells contain a fraction of retrotransposons that are found in the close vicinity of tRNA genes. Growing evidence suggests that these retrotransposons use active recognition mechanisms to determine suitable integration sites. However, the question remains whether these retrotransposons also cause insertional mutagenesis of genes, resulting in their enrichment at tRNA genes, which are relatively safe sites in euchromatic regions. Recently developed in vivo retrotransposition assays will allow a detailed, genome-wide analysis of de novo integration events in the D. discoideum genome.