Antrodia cinnamomea (AC) is a high value medicinal mushroom with various bioactivities such as anticancer, antioxidative, hypoglycemia, hepatoprotection, anti-hepatitis B virus, immunomodulation and anti-inflammation. In nature, besides the commonly known red AC phenotypes, there are also yellow and white AC phenotypes that are not well studied. The aims of this study were to authenticate the phylogenetic identity of different AC phenotypes, and analyze their triterpenoid contents and compositions, followed by investigating the triterpenoids and polysaccharides contents and immunomodulatory activities of different brown rice cultured AC phenotypes. Eight different wildly collected AC phenotypes were subjected to phylogenetic analysis to confirm their authenticity. Based on ITS sequence results, the eight different AC phenotypes were confirmed to be species AC, and their DNA sequence have been registered in NCBI GenBank with the following accession numbers: MN947413, MN947415, MN947416, MN947417, MN947418, MN947419, MK764936 and MK764937. Among the different AC phenotypes, results showed that red AC had the highest triterpenoid contents, followed by yellow AC and white AC. HPLC profiles indicated that different AC phenotypes had similar triterpenoid compounds, including antcin A, antcin B, antcin C, antcin K, antcin G, antcin H, dehydrosulfurenic acid, 15-acetyldehydrosulfurenic acid and dehydroeburicoic acid. For different AC phenotypes cultured on brown rice, results showed that red AC and white AC had similar triterpenoid contents, but their triterpenoid profiles were slightly different. Only antcin C was found in red AC. The polysaccharides of both red AC and white AC cultured on brown rice possessed similar monosaccharide compositions; however, the glucose, mannose, fucose, and arabinose contents between them are different. In addition, the molecular weight of red AC polysaccharides was much lower than white AC. The polysaccharides from red AC and white AC significantly inhibited the TNF-α and IL-6 production in LPS-induced RAW264.7 macrophage cells; however, only white AC polysaccharides was found to significantly inhibit NO production. In conclusion, the results indicate that among different AC phenotypes, red AC had the highest triterpenoid contents, and the differences in the physicochemical properties of white AC polysaccharides may lead to its better anti-inflammatory potency than red AC.