The role of coagulome in the tumor immune microenvironment.

The rising incidence and persistent thrombosis in multiple cancers including those that are immunosuppressive highlight the need for understanding the tumor coagulome system and its role beyond hemostatic complications. Immunotherapy has shown significant benefits in solid organ tumors but has been disappointing in the treatment of hypercoagulable cancers, such as glioblastoma and pancreatic ductal adenocarcinomas. Thus, targeting thrombosis to prevent immunosuppression seems a clinically viable approach in cancer treatment. Hypercoagulable tumors often develop fibrin clots within the tumor microenvironment (TME) that dictates the biophysical characteristics of the tumor tissue. The application of systems biology and single-cell approaches highlight the potential role of coagulome or thrombocytosis in shaping the tumor immune microenvironment (TIME). In-depth knowledge of the tumor coagulome would provide unprecedented opportunities to better predict the hemostatic complications, explore how thrombotic stroma modulates tumor immunity, reexamine the significance of clinical biomarkers, and enable steering the stromal versus systemic immune response for boosting the effectiveness of immune checkpoint inhibitors in cancer treatment. We focus on the role of coagulation factors in priming a suppressive TIME and the huge potential of existing anticoagulant drugs in the clinical settings of cancer immunotherapy.

Oncogenic potential of PIK3CD in glioblastoma is exerted through cytoskeletal proteins PAK3 and PLEK2.

The Class IA phosphoinositide-3-kinase catalytic isoforms p110α, p110ß, and p110δ have been implicated to play vital but overlapping roles in various cancers, including glioblastoma (GBM). We have previously shown that PIK3CD, encoding p110δ, is highly expressed in multiple glioma cell lines and involved in glioma cell migration and invasion. Based on the RNA sequencing data from The Cancer Genome Atlas (TCGA) database, we found the level of PIK3CD expression is significantly higher in GBM than WHO grade II and III gliomas and is closely related to poor survival. To further dissect the oncogenic roles of PIK3CD in glioma progression, we employed CRISPR/Cas9 to completely abrogate its expression in the GBM cell line U87-MG and have successfully isolated two knockout clones with different gene modifications. As expected, the knockout clones exhibited significantly lower migration and invasion capabilities when compared with their parental cells. Interestingly, knockout of PIK3CD also dramatically reduced the colony formation ability of the knockout cells. Further study revealed that PIK3CD deficiency could negate tumorigenesis in nude mice. To determine the downstream effect of PIK3CD depletion, we performed RT2 profiler PCR array of selected gene sets and found that knockout of PIK3CD impaired the activity of p-21 activated kinase 3 (PAK3) and pleckstrin 2 (PLEK2), molecules involved in cancer cell migration and proliferation. This explains why the glioma cells without the PIK3CD expression exhibited weaker oncogenic features. Further, RNAseq analysis of parent and knockout clones revealed that this interaction might happen through axonogenesis signaling pathway. Taken together, we demonstrated that PIK3CD could be a potential prognostic factor and therapeutic target for GBM patients.

Proteomic profiling of metabolic proteins as potential biomarkers of radioresponsiveness for colorectal cancer.

Surgery, radiation therapy (RT), and chemotherapy are commonly used treatment modalities for CRC management. The locally advanced CRC is managed with preoperative RT or in combination of chemoradiotherapy whereas palliative RT is recommended for metastatic CRC patients to enhance overall survival and reduce distressing symptoms. There are many biomarkers established based on tumour staging, grading and molecular characteristics of patients (e.g., mutation, DNA methylation, and gene expression profiling). Interestingly, none of these markers are adequately validated for RT scheme. In order to establish the radioresponsive biomarker in CRC, we established a mouse xenograft tumour model and applied radiation to the tumours. We identified 9 metabolic proteins, namely PGK1, PGAM1, ENO1, PKM, TKT, GLUD1, LDHA, GAPDH, and MDH2, which are differentially expressed in tumours with different radioresponsiveness. Furthermore, we validated their expression in tumours from the unirradiated, poorly responded and highly responded tumour groups. In addition, we analysed their expressions in clinical samples from the public database. Extensive literature studies shown that these metabolic proteins are associated with key biochemical pathways including, glycolysis, ammonia detoxification, carcinogenesis, and drug responses. Further studies are needed to translate our findings into clinical use. SIGNIFICANCE: With the increasing incidence of colorectal cancer (CRC) globally, it is crucial to establish strategic treatment protocol by personalizing cancer treatment. Despite the well-established treatment protocols for CRC in the past decades, the mortality remains high. There is a trend of applying personalized treatment to improve patient survival. It has been reported that biomarkers may be used to predict treatment outcomes or to adjust individual treatment protocols. This project aims to identify specific metabolic proteins as biomarkers for CRC radioresponsiveness. Using bioinformatical analysis, we have identified 9 metabolic proteins which could be used as potential biomarkers for radiation therapy in CRC tumours.

Mesenchymal Transformation: The Rosetta Stone of Glioblastoma Pathogenesis and Therapy Resistance.

Despite decades of research, glioblastoma (GBM) remains invariably fatal among all forms of cancers. The high level of inter- and intratumoral heterogeneity along with its biological location, the brain, are major barriers against effective treatment. Molecular and single cell analysis identifies different molecular subtypes with varying prognosis, while multiple subtypes can reside in the same tumor. Cellular plasticity among different subtypes in response to therapies or during recurrence adds another hurdle in the treatment of GBM. This phenotypic shift is induced and sustained by activation of several pathways within the tumor itself, or microenvironmental factors. In this review, the dynamic nature of cellular shifts in GBM and how the tumor (immune) microenvironment shapes this process leading to therapeutic resistance, while highlighting emerging tools and approaches to study this dynamic double-edged sword are discussed.

The potential diagnostic and prognostic role of extracellular vesicles in glioma: current status and future perspectives.

Lack of appropriate diagnostic/prognostic tools for glioblastoma (GB) is considered one of the major setbacks in the early diagnosis and treatment of this deadly brain tumor. The current gold standard for its diagnosis and staging still relies on invasive biopsy followed by histological examination as well as molecular profiling. Nevertheless, noninvasive approaches are being explored and one example is through the investigation of extracellular vesicles (EVs) in the biofluids of GB patients. EVs are known to carry molecular cargoes such as DNA, mRNA, miRNA, proteins and lipids in almost every type of body fluids. Thus, molecular signature of GB may be present in the EVs derived from these patients. This review focuses on the diagnostic/prognostic potential of EVs in GB, through presenting recent studies on (i) molecular components of EVs, (ii) links between EVs and GB tumor microenvironment, and (iii) clinical potential of EV biomarkers, together with the technical shortcomings researchers need to consider for future studies.