Mouse adenoviruses (MAdV), like human adenoviruses (HAdVs), have specific tissue tropisms. MAdV-1 infects macrophages and vascular endothelial cells, which can result in encephalitis, while MAdV-2 infects epithelial cells of the intestine but does not cause overt disease. The viral protein that determines MAdV tropism is unknown; however, for many viral families it is the viral attachment protein that is critical. For MAdVs, fiber is the viral attachment protein, and the receptors used by MAdV-1 and MAdV-2, although unknown, are distinct. To test whether MAdV receptor usage dictates tissue tropism, I constructed a MAdV-2 chimeric virus, replacing its fiber protein with that of MAdV-1 using a gene-editing recombination system. The chimera was used to infect a 3D culture model of the intestinal epithelium called “enteroids.” As expected, MAdV-1 does not replicate in enteroids and MAdV-2 does, consistent with their in vivo tropisms. Remarkably, the chimera replicated efficiently, indicating that the fiber protein is not the sole determinant of MAdV-2 intestinal tropism. Although fiber is not the main contributor to tropism, its interactions with host factors are still likely important for productive infection. A recent study identified N-acetylglucosamine (GlcNAc) as a specific ligand for MAdV-2 fiber. We have shown that GlcNAc is not the primary receptor for MAdV-2; however, binding to GlcNAc may aid in adhesion of MAdV-2 and penetration through the mouse intestinal mucus layer. To test this hypothesis, I mutated the GlcNAc interacting residues in MAdV-2 fiber to prevent GlcNAc binding. I am currently comparing the infectivity of this mutant virus to wild type MAdV-2 in both epithelial tumor cells and enteroids. Unlike tumor cell cultures, enteroids contain mucus-secreting goblet cells which will recreate the in vivo context more accurately. Together, these studies of MAdV may help us to understand why different HAdVs infect specific tissues.