Cancer is the leading causes of mortality and morbidity worldwide with approximately 8.2 million cancer related deaths in 2012 and is expected that annual new cases will rise 57% within the next two decades as reported by World Health Worldwide. According to the statistics from Taiwan’s Ministry of Health and Welfare, cancer has taken the first position in causes of death in Taiwan in the past three decades. Searching for the optimal combination therapeutic approaches to decrease drugs toxicities and resistance, developing novel small molecular agents to improve current treatments and identifying the important prognostic factors to design the targeted therapies are our ultimate goals of eliminating cancers. In this thesis, we investigated (1) the effect of vincristine-vorinostat combination on human acute lymphoblastic leukemia (ALL), (2) the mechanism underlying anticancer activity of MPT0B392 on human acute leukemia and (3) the clinical importance of eIF4E binding protein 1 (4E-BP1) on human colorectal cancer (CRC). Vincristine, a traditional microtubule-depolymerizing agent, is one of combination chemotherapy drugs used in treatment of ALL; vorinostat, also called SAHA, was the first approved pan-HDAC inhibitor for T cell lymphoma. In the first study, we investigated the vincristine and vorinostat combined effect and the underlying antileukemic mechanism. Our data showed that combination of vincristine and vorinostat induced cells arrest synergistically in the G2M phase, following by obviously accumulation in the subG1 phase. Low concentration of vincristine caused microtubule dynamic changes, and this phenomenon was enhanced by co-incubated with vorinostat, which inhibited HDAC6, causing tubulin acetylation, also leading to microtubule instabilities. This result was consistent with vincristine in combination with HDAC6 inhibitors, tubastatin A and Acy1215. In vivo xenografting experiments corroborated the in vitro activity and tolerability of the combination. Based on these findings, the combination of microtubule depolymerizing agents and HDAC inhibitors can provide the basis of clinical treatment for ALL. In the second study, we elucidated the underlying mechanisms of a novel quinoline derivative, MTP0B392 (B392), which was specially designed for oral administration. B392 induced acute leukemic cells arrest in the G2M phase and ultimately led to apoptosis, which was corroborated by the observation of cleavaged-caspase 3 by immunohistochemistry staining in B392-treated groups of xenograft experiments. B392 also suppressed microtubule polymerization with less susceptibility to P-gp activity, activated mitotic spindle checkpoint as well as caused activation of c-Jun-N-terminal-kinase (JNK), which further contributing to mitochondrial membrane potential loss, caspases and PARP cleavages. Furthermore, B392 had an ability to enhance the cyototoxicity of sirolimus (mTOR inhibitor) in the sirolimus-resistant cells. Our results suggest that B392 is a potential antileukemic drug that could be applied in mono- and combination therapy. 4E-BP1 (eIF4E binding protein 1) is a key regulator in cap-dependent and independent translation, thereby controlling protein synthesis. In the third study, we identified 4E-BP1 as an important prognostic factor in CRC. We found that the protein expression level of 4E-BP1 was more abundant in colorectal cancer cell lines and patients’ tissues when compared to normal colon cell line and tissues. By the analysis of clinical patients’ pathological parameters, 4E-BP1 expression has statically correlation with disease progression. Under hypoxia, 4E-BP1 is thought to be a crucial factor for cap-independent translation. Additionally, YMX-110, a cryptopleurine derivative, led to tumor suppression by deletion of 4E-BP1. Thus, the inhibition of protein synthesis by YXM110 in hypoxic condition was further evaluated. Our data show that YXM110 decreased hypoxia-inducible factor 1