Lasing　properties　of　the　two-dimensional　(2D)　distributed　feedback　(DFB)　lasers　can　be　engineered　by　replacing　either　the　gain　medium　or　periodic　structures　necessary　for　the　feedback　mechanism.　Quasicrystals　are　the　intermediate　class　between　the　periodic　and　random　structures.　They　have　high　rotational　symmetry　and　more　favorable　for　the　generation　of　photonic　bandgap　as　compared　to　periodic　structures.　In　our　experiment,　we　designed　a　pentagonal　prism　for　the　holographic　lithography　to　construct　a　long-range　10-fold　rotational　symmetry,　which　exhibits　2D　quasiperiodic　structures.　A　solution-processable　colloidal　quantum　dots　(CQDs)　was　spin-coated　on　the　resultant　2D　quasicrystals.　An　analytical　model　based　on　the　cavity　mode　coupling　effect　was　developed　to　predict　the　output　performance　of　the　2D　DFB　CQDs　photonic　quasicrystals　laser.　The　respective　optically　pumped　2D　photonic　quasicrystal　samples　exhibit　multi-wavelength　lasing　emission　in　different　directions　due　to　long-range　rotational　symmetry.　The　five　DFB　lasing　spots　are　symmetrically　distributed　in　the　2D　space,　the　center　of　the　lasing　spots　is　similar　to　a　star　shape.　The　derived　analytical　model　predictions　are　in　line　with　the　experimental　results.