The Small-Molecule Wnt Inhibitor ICG-001 Efficiently Inhibits Colorectal Cancer Stemness and Metastasis by Suppressing MEIS1 Expression

Recurrence and metastasis remain major obstacles in colorectal cancer (CRC) treatment. Recent studies suggest that a small subpopulation of cells with a self-renewal ability, called cancer stem-like cells (CSCs), promotes recurrence and metastasis in CRC. Unfortunately, no CSC inhibitor has been demonstrated to be more effective than existing chemotherapeutic drugs, resulting in a significant unmet need for effective CRC therapies. In this study, transcriptomic profiling of metastatic tumors from CRC patients revealed significant upregulation in the Wnt pathway and stemness genes. Thus, we examined the therapeutic effect of the small-molecule Wnt inhibitor ICG-001 on cancer stemness and metastasis. The ICG-001 treatment efficiently attenuated self-renewal activity and metastatic potential. Mechanistically, myeloid ecotropic viral insertion site 1 (MEIS1) was identified as a target gene of ICG-001 that is transcriptionally regulated by Wnt signaling. A series of functional analyses revealed that MEIS1 enhanced the CSC behavior and metastatic potential of the CRC cells. Collectively, our findings suggest that ICG-001 efficiently inhibits CRC stemness and metastasis by suppressing MEIS1 expression. These results provide a basis for the further clinical investigation of ICG-001 as a targeted therapy for CSCs, opening a new avenue for the development of novel Wnt inhibitors for the treatment of CRC metastasis.

PCIP-seq: simultaneous sequencing of integrated viral genomes and their insertion sites with long reads

The integration of a viral genome into the host genome has a major impact on the trajectory of the infected cell. Integration location and variation within the associated viral genome can influence both clonal expansion and persistence of infected cells. Methods based on short-read sequencing can identify viral insertion sites, but the sequence of the viral genomes within remains unobserved. We develop PCIP-seq, a method that leverages long reads to identify insertion sites and sequence their associated viral genome. We apply the technique to exogenous retroviruses HTLV-1, BLV, and HIV-1, endogenous retroviruses, and human papillomavirus.

A genetic screen identifies dreammist as a regulator of sleep

Sleep is a nearly universal feature of animal behaviour, yet many of the molecular, genetic, and neuronal substrates that orchestrate sleep/wake transitions lie undiscovered. Employing a viral insertion sleep screen in larval zebrafish, we identified a novel mutant, dreammist (dmist), with altered sleep-wake dynamics. CRISPR/Cas9-mediated disruption of dmist also led to behavioural hyperactivity and reduced sleep at night. The neuronally expressed dmist gene is conserved across vertebrates and encodes a small single-pass transmembrane protein that is structurally similar to the Na+,K+-ATPase regulator, FXYD1/Phospholemman. Disruption of either fxyd1 or atp1a3a, a Na+,K+-ATPase alpha-3 subunit associated with several heritable movement disorders in humans, led to decreased night-time sleep. As intracellular Na+ concentration is disrupted in dmist mutant brains after high neuronal activity similarly to atp1a3a mutants, but is also elevated specifically at night, we propose that sleep-wake stability is modulated by Dmist-dependent changes to Na+ pump function during sleep homeostatic challenge and at specific times of the day-night cycle.

Viral Insertion Safety in Patients with Glioblastoma Who Received a Novel Lentiviral MGMT-P140K Gene Therapy to Protect Bone Marrow from Chemotherapy: No Dominant Clonal Evolution Observed with Chemo-Selection

INTRODUCTION: To protect normal bone marrow from chemotherapy in glioblastoma patients, we have developed a novel strategy by introducing a strong DNA repair protein, mutant (P140K) of human methylguanine methyltransferase (MGMT), into patients’ CD34+ hematopoietic progenitors (HPC) by lentiviral gene transfer leading to selective expansion of drug-resistant P140K-MGMT CD34+ cells and their myeloid and immune cell progeny. METHODS: To achieve long-term stable expression of the P140K-MGMT gene, we used a lentiviral vector which integrates into the host genome. However, viral insertion mutagenesis has raised safety concerns; as the previous γ-retroviral vectors were associated with insertion mutations leading to development of acute lymphoblastic leukemia in 20% of treated patients. Nevertheless, new improved lentiviral vector with safe feature of insertion site far away from gene transcription start site has been developed. Here we evaluated the safety of a lentivirus vector under selection pressure of chemotherapy. HYPOTHESIS: Our lentiviral vector is safer than traditional γ-retroviral vectors as evident by lack of early clonal dominance even with a chemo-selection. RESULTS: Three glioblastoma patients were recruited and underwent resection, after which CD34+ HPC were mobilized with filgrastim, isolated by magnetic bead separation (Miltneyi CliniMACS), and transduced ex vivo with a GMP-grade lentiviral P140K-MGMT vector (Lentigen Corp). Subsequently, patients received radiation/temozolomide for 6 weeks and up to five cycles of monthly O6-benzylguanine/temozolomide (BG/TMZ) treatment. As a result, all three patients demonstrated a 5-15 fold selective expansion of P140K-MGMT positive HPC and their progeny granulocyte and mononuclear cells in peripheral blood and a small number of CFUs from bone marrow indicating a drug-selection mechanism. The viral insertion sites in the cells of these three patients were closely monitored in each chemotherapy cycle and the patients were followed for up to 1 year after the last therapy. We mapped a total of 17,308 viral insertion sites (VIS), for patient 1(6,146), patient 2(2,081) and patient 3(9,081) and the unique viral insertion sites (UVIS) was 382, i.e. 135, 76 and 171 for patient 1, patient 2 and patient 3 respectively. Overall, during the drug-treatment period, there were no persistent UVIS. Moreover, at the conclusion of BG/TMZ treatment, the VIS number sharply diminished. CONCLUSION: Gene transfer of LV MGMTP140K vector into hematopoietic progenitor cells did not lead to clonal dominance during or after drug selection. Dose escalation of BG/TMZ will define hematopoietic tolerance and treatment response. Disclosures Embree: Lentigen Technology Inc: Employment. Dropulic:Lentigen Technology Inc: Employment, Patents & Royalties.