The entry of rotaviruses into epithelial cells seems to be a multistep process. Infection competition experiments have suggested that at least three different interactions between the virus and cell surface molecules take place during the early events of infection, and glycolipids as well as glycoproteins have been suggested to be primary attachment receptors for rotaviruses. The infectivity of some rotavirus strains depends on the presence of sialic acid on the cell surface, however, it has been shown that this interaction is not essential, and it has been suggested that there exists a neuraminidase‐resistant cell surface molecule with which most rotaviruses interact. The comparative characterization of the sialic acid‐dependent rotavirus strain RRV (G3P5[3]), its neuraminidase‐resistant variant nar3, and the human rotavirus strain Wa (G1P1A[8]) has allowed us to show that α2β1 integrin is used by nar3 as its primary cell attachment site, and by RRV in a second interaction, subsequent to its initial contact with a sialic acid‐containing cell receptor. We have also shown that integrin αVβ3 is used by all three rotavirus strains as a co‐receptor, subsequent to their initial attachment to the cell. We propose that the functional rotavirus receptor is a complex of several cell molecules most likely immersed in glycosphingolipid‐enriched plasma membrane microdomains.