ARID1A serves as a receivable biomarker for the resistance to EGFR-TKIs in non-small cell lung cancer

ARID1A is a key component of the SWI/SNF chromatin remodeling complexes which is important for the maintaining of biological processes of cells. Recent studies had uncovered the potential role of ARID1A alterations or expression loss in the therapeutic sensitivity of cancers, but the studies in this field requires to be further summarized and discussed. Therefore, we proposed a series of mechanisms related to the resistance to EGFR-TKIs induced by ARID1A alterations or expression loss and the potential therapeutic strategies to overcome the resistance based on published studies. It suggested that ARID1A alterations or expression loss might be the regulators in PI3K/Akt, JAK/STAT and NF-κB signaling pathways which are strongly associated with the resistance to EGFR-TKIs in NSCLC patients harboring sensitive EGFR mutations. Besides, ARID1A alterations or expression loss could lead to the resistance to EGFR-TKIs via a variety of processes during the tumorigenesis and development of cancers, including epithelial to mesenchymal transition, angiogenesis and the inhibition of apoptosis. Based on the potential mechanisms related to ARID1A, we summarized that the small molecular inhibitors targeting ARID1A or PI3K/Akt pathway, the anti-angiogenic therapy and immune checkpoint inhibitors could be used for the supplementary treatment for EGFR-TKIs among NSCLC patients harboring the concomitant alterations of sensitive EGFR mutations and ARID1A.

Proteasome Inhibitors and Their Pharmacokinetics, Pharmacodynamics, and Metabolism

The proteasome is responsible for mediating intracellular protein degradation and regulating cellular function with impact on tumor and immune effector cell biology. The proteasome is found predominantly in two forms, the constitutive proteasome and the immunoproteasome. It has been validated as a therapeutic drug target through regulatory approval with 2 distinct chemical classes of small molecular inhibitors (boronic acid derivatives and peptide epoxyketones), including 3 compounds, bortezomib (VELCADE), carfilzomib (KYPROLIS), and ixazomib (NINLARO), for use in the treatment of the plasma cell neoplasm, multiple myeloma. Additionally, a selective inhibitor of immunoproteasome (KZR-616) is being developed for the treatment of autoimmune diseases. Here, we compare and contrast the pharmacokinetics (PK), pharmacodynamics (PD), and metabolism of these 2 classes of compounds in preclinical models and clinical studies. The distinct metabolism of peptide epoxyketones, which is primarily mediated by microsomal epoxide hydrolase, is highlighted and postulated as a favorable property for the development of this class of compound in chronic conditions.

Novel Therapeutics in Radioactive Iodine-Resistant Thyroid Cancer

Iodine-resistant cancers account for the vast majority of thyroid related mortality and, until recently, there were limited therapeutic options. However, over the last decade our understanding of the molecular foundation of thyroid function and carcinogenesis has driven the development of many novel therapeutics. These include FDA approved tyrosine kinase inhibitors and small molecular inhibitors of VEGFR, BRAF, MEK, NTRK and RET, which collectively have significantly changed the prognostic outlook for this patient population. Some therapeutics can re-sensitize de-differentiated cancers to iodine, allowing for radioactive iodine treatment and improved disease control. Remarkably, there is now an FDA approved treatment for BRAF-mutated patients with anaplastic thyroid cancer, previously considered invariably and rapidly fatal. The treatment landscape for iodine-resistant thyroid cancer is changing rapidly with many new targets, therapeutics, clinical trials, and approved treatments. We provide an up-to-date review of novel therapeutic options in the treatment of iodine-resistant thyroid cancer.

Anti-PITPNM3 small molecular compounds reverse breast cancer metastasis by targeting PITPNM3.

e15005 Background: Recent studies highlight the fundamental roles of PITPNM3 in breast cancer metastasis. PITPNM3 is identified as the functional receptor of CCL18 and promotes breast cancer cell invasion and metastasis by binding with CCL18. Since anti-CCL18 neutralized antibodies shows medium binding affinity which restricts their clinical application, small molecular inhibitors targeting PITPNM3 are needed to be further investigated. Therefore, we identified several first in class small molecular inhibitors potentially targeting PITPNM3 and can inhibit breast cancer metastasis conducted by PITPNM3 activation. Methods: We performed computer-assisted drug design by constructing PITPNM3 homology model, characterizing potential binding pockets and docking preselected high diversity structured small molecule compounds into the static PITPNM3 model. Top 100 small molecules in silico scores were selected and screened through basic experiments. After screening, the anti-metastasis effects of selected compounds were tested through transwell migration and invasion assay. Immunofluorescence and qPCR were applied to confirm the expression of vimentin and CDH1. Western blot were used to clarify the inhibition effects of selected compounds on PITPNM3 signaling pathways. Results: By using homology remodeling, we successfully constructed the PITPNM3(680-920aa) protein model. The PITPNM3(680-920aa) domain is responsible for interacting with PYK2 and phosphorylating PYK2. The phosphorylation of PYK2 conducted by PITPNM3 signaling pathway will lead to metastasis and epithelial-mesenchymal transition (EMT) of breast cancer cells. We then characterized the potential binding pockets of this static model and a druggable site was founded. More than 50K molecules with high diversity were docked into this druggable site and scored through their docking performance. Finally, top 100 scored small molecules were selected. In addition, through 1 rounds of toxicity screening, 1 round of transwell migration assay screening and 1 round of transwell invasion assay screening, 4 small molecules with higher bioactivity is identified and 1 compound with the highest bioactivity as well as docking performance among 50K small molecules is chose. This compound can inhibit CCL18 treatment as well as tumor associated macrophage co-culture mediated migration and invasion. Besides, it can also inhibit the phophorylation of PYK2 and Src without inhibition the expression of PITPNM3. Conclusions: Our findings identify the first-in-class anti-PITPNM3 small molecule inhibitors. These compounds can inhibit PITPNM3 signaling pathway and reverse breast cancer metastasis.

Can small molecular inhibitors that stop de novo serine synthesis be used in cancer treatment?

To sustain their malignancy, tumour cells acquire several metabolic adaptations such as increased oxygen, glucose, glutamine, and lipids uptake. Other metabolic processes are also enhanced as part of tumour metabolic reprogramming, for example, increased serine metabolism. Serine is a non-essential amino acid that supports several metabolic processes that are crucial for the growth and survival of proliferating cells, including protein, DNA, and glutathione synthesis. Indeed, increased activity of D-3-phosphoglycerate dehydrogenase (PHGDH), the enzyme rate-limiting de novo serine synthesis, has been extensively reported in several tumours. Therefore, selective inhibition of PHGDH may represent a new therapeutic strategy for over-expressing PHGDH tumours, owing to its downstream inhibition of essential biomass production such as one-carbon units and nucleotides. This perspective article will discuss the current status of research into small molecular inhibitors against PHGDH in colorectal cancer, breast cancer, and Ewing’s sarcoma. We will summarise recent studies on the development of PHGDH-inhibitors, highlighting their clinical potential as new therapeutics. It also wants to shed a light on some of the key limitations of the use of PHGDH-inhibitors in cancer treatment which are worth taking into account.

Biological Roles and Therapeutic Applications of IDH2 Mutations in Human Cancer

Isocitrate dehydrogenase (IDH) is a key metabolic enzyme catalyzing the interconversion of isocitrate to α-ketoglutarate (α-KG). Mutations in IDH lead to loss of normal enzymatic activity and gain of neomorphic activity that irreversibly converts α-KG to 2-hydroxyglutarate (2-HG), which can competitively inhibit a-KG-dependent enzymes, subsequently induces cell metabolic reprograming, inhibits cell differentiation, and initiates cell tumorigenesis. Encouragingly, this phenomenon can be reversed by specific small molecule inhibitors of IDH mutation. At present, small molecular inhibitors of IDH1 and IDH2 mutant have been developed, and promising progress has been made in preclinical and clinical development, showing encouraging results in patients with IDH2 mutant cancers. This review will focus on the biological roles of IDH2 mutation in tumorigenesis, and provide a proof-of-principle for the development and application of IDH2 mutant inhibitors for human cancer treatment.

Janus Kinase Inhibitors: A Review of Their Application in the Vitiligo

: The small-molecular inhibitors targeted JAks (JAK inhibitors), could modulate the cytokines-mediated signaling via JAK-STAT pathway, which plays a important role in immune regulation and cell proliferation. The JAK inhibitors are previously designed and synthesized to treat diseases involved with hematologic and immune system. Increasing evidence shows that they are quite effective in atopic dermatitis (AD), alopecia areata (AA), psoriasis, vitiligo, and other autoimmune-induced dermatologic conditions. Currently, many JAK inhibitors possessing anti-vitiligo activity are being investigated in laboratory and clinically. In this view, we would like to summarize so we review the applications of these inhibitors with emphasis on profile of vitiligo, clinical efficacy, dosages, development of new candidates and adverse events through available literatures.