Antrodia cinnamomea, a unique native basidiomycetes, inhabitats on the inner trunk of Taiwanese endemic tree species, Cinnamomum kanehirae. The crude extracts from A. cinnamomea have been shown medicinal potential, including anti-cancer, anti-inflammation, and anti-oxidation, etc. Triterpenoids, the major secondary metabolites of A. cinnamomea, are supposed to be correlated with these biological activities. However, clinic trials are always being impeded due to lacking adequate quantity of putative active gradients. To circumvent the obstacles, metabolic engineering of the genes of A. cinnamomea to biosynthesize the potent medicinal triterpenoids may be an alternative choice. We found two of the putative genes squalene monooxygenase (SM) and lanosterol synthase (LS) in triterpenoid biosynthesis pathway from constructed and annotated A. cinnamomea transcriptome database. Using approaches with RACE (rapid amplification of cDNA ends) and A. cinnamomea fosmid library, full-length cDNA of AcSM and AcLS have been worked out, and open reading frames (ORF) were defined. Additionally, these two genes were characterized by analysis of the high conserved domains, active sites, and phylogenetical relatedness, and also their functions were verified by complementation test in yeast knockout (YKO) strains. The recombinant fusion proteins of GST-AcSM and GST-AcLS were successfully expressed in Escherichia coli Rosetta, and have been purified to homogeneity. However, the enzymatic activities of AcSM and AcLS heterologously expressed in E. coli could not be confirmed. It is suspected that the recombinant AcSM and AcLS are non-functional due to the inappropriate folding. In the future, metabolic engineering of the AcSM and AcLS in combination with cytochrome P450 and heterologously expressing in a pertinent host to generate bioactive triterpenoids may be possible.