Nanoparticle mediated targeting of toll-like receptors to treat colorectal cancer.

Colorectal cancer (CRC) accounts for approximately 10% of all cancer cases worldwide. Conventional treatment has relied on chemotherapy, radiation therapy and surgery with limited success for patients with metastatic CRC. Toll like receptor (TLR) agonists have garnered attention for their ability to stimulate the innate immune system and consequently stimulate production of proinflammatory cytokines and activate an antitumor T cell response. However, activation of TLRs can also result in tumorigenesis and drug resistance depending on the specific TLR and cell that is targeted. Due to these contradictory effects of TLR stimulation, a key challenge is targeting specific cells, such as the dendritic cells or macrophages, to ensure the most optimal result. Additionally, TLR agonists are small molecules that can be cleared rapidly after local administration and can result in severe systemic side effects. This demonstrates the need to develop appropriate nanoparticle delivery systems for TLR agonists that can specifically target the innate immune system as a tool to treat CRC. In this review, the challenges in designing these nanoparticles will be discussed together with the recent advances of nanoparticle formulations containing TLR agonists.

FUT9-Driven Programming of Colon Cancer Cells towards a Stem Cell-Like State.

Cancer stem cells (CSCs) are located in dedicated niches, where they remain inert to chemotherapeutic drugs and drive metastasis. Although plasticity in the CSC pool is well appreciated, the molecular mechanisms implicated in the regulation of cancer stemness are still elusive. Here, we define a fucosylation-dependent reprogramming of colon cancer cells towards a stem cell-like phenotype and function. De novo transcriptional activation of Fut9 in the murine colon adenocarcinoma cell line, MC38, followed by RNA seq-based regulon analysis, revealed major gene regulatory networks related to stemness. Lewisx, Sox2, ALDH and CD44 expression, tumorsphere formation, resistance to 5-FU treatment and in vivo tumor growth were increased in FUT9-expressing MC38 cells compared to the control cells. Likewise, human CRC cell lines highly expressing FUT9 displayed phenotypic features of CSCs, which were significantly impaired upon FUT9 knock-out. Finally, in primary CRC FUT9+ tumor cells pathways related to cancer stemness were enriched, providing a clinically meaningful annotation of the complicity of FUT9 in stemness regulation and may open new avenues for therapeutic intervention.