EpCAM and Trop2 are homologous transmembrane proteins that are involved in cell-proliferation as well as differentiation and contribute to adhesion, though their role in cellular processes is not yet fully known. In medicine, they are often used as biomarkers and targets of carcinoma treatments, as they are often overexpressed in this type of cancer. Homodimeric paralogues are remarkably similar in their amino-acid sequences and fold and can be expressed on the surface of the same epithelial cells. There have been quite a number of paralogous homodimeric proteins that can form heterodimeric complexes reported to date. Molecular dynamics simulations of the predicted structure of the heterodimer have pointed at the possibility of such a complex existing and interactions between subunits are predicted to be strong. Our aim was to experimentally evaluate those findings and prepare the heterodimer in vitro. For that purpose, we prepared a recombinant pFastBac Dual expression vector containing the extracellular parts of a non-glycosylated mutant of EpCAM with a hexahistidine tag and partly non-glycosylated mutant of Trop2 with a StrepII tag. Recombinant proteins were produced in the insect cell line Sf9. Following expression, a two-step isolation of the potential heterodimer was performed: first with nickel and then with Strep-Tactin affinity chromatography. After the second isolation step, we expected the potential heterodimer to be in the bound fraction, yet none was detected. We proposed that binding to the Strep-Tactin resin could be obstructed due to steric hindrances and StrepII tag inaccessibility. That was however not the case as no Trop2 was detected in the unbound fraction after SDS-PAGE analysis. After detection of T2EX-StrepII with Strep-Tactin-HRP in the medium and homogenisate of insect cells after expression, we estimated that the expression level of T2EX-StrepII is approximately 120 times lower than that of ngEpEX-His. In the case of heterodimer existing, there would probably not be enough of it formed to be detected using our approach.