The three dimensional (3D) arrangement of the constituent units of nano-sized molecules determines the functions of natural and artificial molecules. At different length scales, the molecular topology and supramolecular assembles of molecules determine the spatial arrangement of their constituent units. Constructed with a spherical core and multiple conjugated coronal units, 3D conjugated molecules have been developed as useful materials in optoelectronic and biomedical applications. Because of their nanometer molecular size, these molecules are also considered as molecular nanoparticles (MNPs), and used as important building block for giant molecules. However, because of their complex molecular structures, the self-assembly behavior and supramolecular structure of MNPs remain unclear. In this study, the key factors for the supramolecular behaviors of conjugated MNPs were studied. From the microscopic and diffraction results, we concluded that the intramolecular interaction among the peripheral conjugated arms and the molecular symmetry are determinative to the molecular topology and the supramolecular structures of MNPs. When the intramolecular interaction is weak, the MNP adopts a star-like topology with Th symmetry. These star MNPs interact isotropically to give a highly order honeycomb (HC) morphology. On the contrary, when the intramolecular interaction is strong, the MNP adopts a rod-like topology with C3 symmetry. These rod-MNPs prefer to interact intermolecularly in the horizontal direction, and pack into a trigonalcrystal lattice. Annealing the thin film of the MNP turns the HC morphology to the trigonallattice, suggesting that the rod conformation and the trigonal lattice are more energetic favorable. The molecular symmetry and how the MNPs interact intra- and intermolecularly are thus important in shaping the topology and supramolecular structures of conjugated MNPs.