Nucleocytoplasmic large DNA viruses (NCLDVs) have genome sizes that range from around 100 kilobases (kb) to up to 2.5 megabases, and virion sizes that can reach up to 1.5 μm. Their large size in both of these contexts is atypical and defies the traditional view that viruses are streamlined, "filterable infectious agents". NCLDVs include many diverse groups, including Poxviruses, Asfarviruses, Iridoviruses, Mimiviruses, and Marseilleviruses. Poxviruses are perhaps the most well-studied; these viruses have 135-360 kbp genomes with about half of the genes encoding essential replication genes and the other half encoding genes related to host-virus interactions. Many of the genes involved in host-virus interactions are involved in immunomodulatory processes and have homology to proteins encoded by the host. These viral genes, often referred to as "mimics", are therefore believed to be the result of host-to-virus gene transfer. In this study I sought to examine if common poxvirus immunomodulatory genes were found in other NCLDV lineages, and if so, to analyze the evolutionary history of these genes. I identified 5 protein families of immunomodulatory genes that were found in both poxviruses and other NCLDV lineages, and I used phylogenetic tools to compare viral immunomodulatory genes of NCLDVs to their eukaryotic orthologs to evaluate the number of times different NCLDV lineages have acquired these genes. Our phylogenetic analyses showed that several viral immunomodulatory genes were acquired multiple times by different NCLDV lineages, while others appear to have been transferred between viral groups. Interestingly, some NCLDV genes clustered together with homologs from the unrelated Herpesviridae family, suggesting that inter-viral gene exchange can traverse vast evolutionary distances. The vast diversity of hosts infected by different NCLDV lineages suggests that these immunomodulatory genes play key roles that are useful to viruses in a variety of contexts. This research provides insight into how giant viruses acquire host genes, which contribute to their large genome size, and how those genes evolved to subvert antiviral defenses.