Cancer is caused by an imbalance between cell cycle progression and apoptosis. Therefore, the majority of anticancer drugs exert their antiproliferative and cytotoxic activity via cell cycle arrest and induction of apoptosis, a controlled form of cell death that is dysregulated in cancer (1). Cytotoxic nucleoside analogues were the first chemotherapeutic agents used for the treatment of cancer (2). To date, the most widely researched cytotoxic nucleoside analogues are predominantly isolated from Cordyceps sinensis and C. militaris.

C. sinensis has been more extensively used and investigated compared with C. militaris, however, both species contain similar bioactive ingredients and exhibit medicinal activity, and are widely used traditional Chinese medicines. A number of bioactive ingredients have been isolated from C. militaris, including adenosine, cordycepin, D-mannitol, and exopolysaccharides. C. militaris has been widely used in traditional Chinese medicine (3), and is claimed to have extensive pharmacological properties, including anti-inflammatory properties, cell cycle disruption, enhancement of immune function, nucleic acid-containing (DNA/RNA) and apoptosis-inducing activities; anti-fatigue, anti-bacterial and anti-diabetic properties; improving lung, liver and kidney functions; and aiding in the treatment of cancer as well as male and female sexual dysfunctions (3). C. militaris is therefore receiving much attention due to these potential health benefits, and it is often used as a substitute for C. sinensis in certain traditional Chinese medicine prescriptions as the two species contain similar bioactive ingredients (4). In view of the growing popularity of C. militaris, cultivation of the C. militaris stroma, a spore of C. militaris, is also conducted. A wide diversity of compounds have been isolated from different strains of Cordyceps as well as artificially cultivated C. militaris (4).

Cordycepin, also known as 3-deoxyadenosine, is a specific polyadenylation inhibitor and is the main functional component in C. militaris (5). Cordycepin is an active small molecule and is implicated in modulating multiple physiological functions, including immune-activation (anti-virus, anti-infection) (6), anti-inflammatory, anti-aging (adjustment of the physical condition, an anticancer effect and enhancement of sexual performance) (7) and anti-tumor effects (8).

Throughout the last 60 years, the antitumor mechanism of Cordycepin has become extensively studied. In 1961, Jagger et al (9) investigated the inhibition of Ehrlich mouse ascites tumor growth by cordycepin and Klenow (10) also investigated the effect of cordycepin on the incorporation of P32-orthophosphate into the nucleic acid of ascites tumor cells in vitro. These studies prompted further research into the association between cordycepin and cancer. In the subsequent decades, numerous studies with regard to cordycepin and cancer were reported. For example, cordycepin was shown to induce antitumor effects or apoptosis in human head and neck squamous cell carcinoma (11), bladder cancer (12), thyroid carcinoma (13), breast cancer (14), multiple myeloma (15), leukemia (5,16,17), lymphoma (18) and mouse leydig tumor cells (19). Additionally, the inhibitory effect of cordycepin was observed in hematogenic metastasis of mouse melanoma (20,21) and lung carcinoma cells (22). Cell cycle arrest was observed to be promoted by cordycepin via the regulation of c-Jun N-terminal kinase (JNK) in human bladder and colon cancer cells (23,24). In hematological malignancies, cordycepin exhibited cytotoxic and apoptogenic effects via the inactivation of polyadenylate polymerase and the resulting inhibition of mRNA polyadenylation (18). In terminal deoxynucleotidyl transferase-positive leukemic cells, these effects are more prominent (18).

It is important to understand how cordycepin inhibits cell proliferation in tumor cells in order to develop it as a new agent for the prevention and treatment of cancer. The A3 adenosine receptor (A₃AR) is a member of the AR family; it is overexpressed in cancer and inflammatory cells, however, low expression is exhibited in normal cells (25). Following cordycepin binding to A₃AR, G protein is activated and subsequently inhibits the formation of cAMP and indirectly decreases phosphorylation of the serine/threonine kinase glycogen synthase kinase (GSK)-3β. The resulting increased phosphorylation of β-catenin causes it to be removed from the cytoplasm by ubiquitination, thereby preventing its nuclear import. A net suppression of cyclin D1 and c-myc is the result of this, which leads to the inhibition of cell growth (Fig. 1) (26). Thus, as cordycepin binds A₃AR, which inactivates the GSK-3β/β-catenin signaling pathway and subsequently suppresses cell division, cordycepin may present a potential therapeutic agent for the inhibition of tumor cell proliferation.

Collectively, the findings that are discussed in the present review provide a novel insight into the effect of cordycepin on cell apoptosis, which supports new concepts for the treatment of cancer. Cell proliferation and apoptosis involve the functional cooperation of many signaling molecules. As summarized in Fig. 1, cordycepin inhibits cell proliferation via binding A₃AR, activating G protein, inhibiting cAMP formation, decreasing GSK-3β/β-catenin activation and suppressing cyclin D1 and c-myc expression.

Cordycepin induces cell apoptosis through three signaling pathways: PKA/TdT signaling pathway, caspase signaling pathway and p38/JNK signaling pathway. The caspase signaling pathway is the most prominent signal pathway by which cell apoptosis is induced by cordycepin. Following cordycepin binding to the DR3 receptor, DR3 activates caspase-8 via FADD. Subsequently, caspase-8 may directly activate caspase-3 or induce mitochondria to release cytochrome c, which also activates caspase-3 with the help of Apaf1 and caspase-9.

These results indicate that a cocktail therapy with cordycepin may greatly reduce the risk of cancer cell metastasis of all types. The significance of cordycepin as a natural medicine is that may be used to treat or prevent cancer progression in the future (41). Further studies are required to determine which of the signaling pathways is most important for the treatment of cancer with cordycepin. In addition, many of the previous studies were focused on the activity of cordycepin at a cellular level. Future in vivo studies investigating the inhibition of tumor progression by cordycepin may provide further insight into the mechanisms behind its activity.