Serine–threonine protein kinase B-RAF (BRAF)-mutated metastatic melanoma (MM) is a highly aggressive type of skin cancer. Treatment of MM patients using BRAF/MEK inhibitors (BRAFi/MEKi) eventually leads to drug resistance, limiting any clinical benefit. Herein, we demonstrated that the nicotinamide adenine dinucleotide (NAD)-biosynthetic enzyme nicotinamide phosphoribosyltransferase (NAMPT) is a driving factor in BRAFi resistance development. Using stable and inducible NAMPT over-expression systems, we showed that forced NAMPT expression in MM BRAF-mutated cell lines led to increased energy production, MAPK activation, colony-formation capacity, and enhance tumorigenicity in vivo. Moreover, NAMPT over-expressing cells switched toward an invasive/mesenchymal phenotype, up-regulating expression of ZEB1 and TWIST, two transcription factors driving the epithelial to mesenchymal transition (EMT) process. Consistently, within the NAMPT-overexpressing cell line variants, we observed an increased percentage of a rare, drug-effluxing stem cell-like side population (SP) of cells, paralleled by up-regulation of ABCC1/MRP1 expression and CD133-positive cells. The direct correlation between NAMPT expression and gene set enrichments involving metastasis, invasiveness and mesenchymal/stemness properties were verified also in melanoma patients by analyzing The Cancer Genome Atlas (TCGA) datasets. On the other hand, CRISPR/Cas9 full knock-out NAMPT BRAFi-resistant MM cells are not viable, while inducible partial silencing drastically reduces tumor growth and aggressiveness. Overall, this work revealed that NAMPT over-expression is both necessary and sufficient to recapitulate the BRAFi-resistant phenotype plasticity.
The term NADome refers to the intricate network of intracellular and extracellular enzymes that regulate the synthesis or degradation of nicotinamide adenine dinucleotide (NAD) and to the receptors that engage it. Traditionally, NAD was linked to intracellular energy production through shuffling electrons between oxidized and reduced forms. However, recent data indicate that NAD, along with its biosynthetic and degrading enzymes, has a life outside of cells, possibly linked to immuno-modulating non-enzymatic activities. Extracellular NAD can engage puriginergic receptors triggering an inflammatory response, similar - to a certain extent – to what described for adenosine triphosphate (ATP). Likewise, NAD biosynthetic and degrading enzymes have been amply reported in the extracellular space, where they possess both enzymatic and non-enzymatic functions. Modulation of these enzymes has been described in several acute and chronic conditions, including obesity, cancer, inflammatory bowel diseases and sepsis. In this review, the role of the extracellular NADome will be discussed, focusing on its proposed role in immunomodulation, together with the different strategies for its targeting and their potential therapeutic impact.
Background Nicotinamide phosphoribosyltransferase (NAMPT), the rate-limiting enzyme in nicotinamide adenine dinucleotide (NAD) biosynthesis, is up-regulated in several cancers, including metastatic melanoma (MM). The BRAF oncogene is mutated in different cancer types, among which MM and thyroid carcinoma (THCA) are prominent. Drugs targeting mutant BRAF are effective, especially in MM patients, even though resistance rapidly develops. Previous data have linked NAMPT over-expression to the acquisition of BRAF resistance, paving the way for therapeutic strategies targeting the two pathways. Methods Exploiting the TCGA database and a collection of MM and THCA tissue microarrays we studied the association between BRAF mutations and NAMPT expression. BRAF wild-type (wt) cell lines were genetically engineered to over-express the BRAF V600E construct to demonstrate a direct relationship between over-activation of the BRAF pathway and NAMPT expression. Responses of different cell line models to NAMPT (i)nhibitors were studied using dose–response proliferation assays. Analysis of NAMPT copy number variation was performed in the TCGA dataset. Lastly, growth and colony forming assays were used to study the tumorigenic functions of NAMPT itself. Results The first finding of this work is that tumor samples carrying BRAF-mutations over-express NAMPT, as demonstrated by analyzing the TCGA dataset, and MM and THC tissue microarrays. Importantly, BRAF wt MM and THCA cell lines modified to over-express the BRAF V600E construct up-regulated NAMPT, confirming a transcriptional regulation of NAMPT following BRAF oncogenic signaling activation. Treatment of BRAF-mutated cell lines with two different NAMPTi was followed by significant reduction of tumor growth, indicating NAMPT addiction in these cells. Lastly, we found that several tumors over-expressing the enzyme, display NAMPT gene amplification. Over-expression of NAMPT in BRAF wt MM cell line and in fibroblasts resulted in increased growth capacity, arguing in favor of oncogenic properties of NAMPT. Conclusions Overall, the association between BRAF mutations and NAMPT expression identifies a subset of tumors more sensitive to NAMPT inhibition opening the way for novel combination therapies including NAMPTi with BRAFi/MEKi, to postpone and/or overcome drug resistance. Lastly, the over-expression of NAMPT in several tumors could be a key and broad event in tumorigenesis, substantiated by the finding of NAMPT gene amplification.
Richter syndrome (RS) is the histological transformation of chronic lymphocytic leukemia (CLL) into an aggressive lymphoma, typically diffuse large B-cell lymphoma (DLBCL), with most cases clonally related to the preceding CLL. [1][2][3] In the past 10 years, a revolution has occurred in therapeutic options for patients with CLL. 4 However, little has changed for patients with RS, with only a few phase 1 and 2 clinical trials ongoing, mostly based on different drug combinations. 5 Novel therapeutic perspectives for RS may come from immune-based therapies 6,7 or, alternatively, from the use of antibody-drug conjugates (ADCs) targeting antigens predominantly or exclusively expressed by neoplastic cells. 8 Footnotes
The leukocyte surface antigen CD37 (TSPAN26), a member of the tetraspanin superfamily, is widely expressed on most malignant B cells, making it an actionable target for treatment of patients with chronic lymphocytic leukemia (CLL) and other B-cell non-Hodgkin lymphoma (NHL) indications. Accordingly, αCD37 antibodies have shown promising results in phase 1/2 clinical trials for CLL and NHL. Richter's syndrome (RS) is the transformation of CLL into an aggressive and rapidly fatal lymphoma, typically a diffuse large B cell lymphoma (DLBCL). RS is a challenging disease since very few effective treatment options exist for these patients and the available regimens, mainly based on R-CHOP scheme, show limited efficacy. We recently established patient-derived xenograft (PDX) models from RS patients and have shown that they can be used to test the efficacy of novel drugs and drug combinations 1,2. All available RS-PDX models were characterized by high-levels of CD37 expression, when assessed by RNA sequencing, reverse-transcriptase-polymerase chain reaction (RT-PCR), flow cytometry (FACS), western blot (WB) and immunohistochemistry (IHC). More precisely, two models (RS1316 and IP867/17) showed slightly higher CD37 levels compared to the others (RS9737 and RS1050). These models were used to test three different αCD37-ATACs®, ADCs which comprise amanitin-derivatives as payload. Amanitin (the main poison in the green deathcap mushroom) belongs to the well-known amatoxin family. Amanitin is taken up by OATP1B3 transporter, solely expressed on hepatocytes. Upon mushroom intoxication, it can lead to severe liver toxicity by inhibiting the RNA polymerase II. Upon conjugation to target-specific antibodies, the maximal tolerated dose is significantly increased by reducing the non-specific liver uptake. By binding to its antigen, ATACs deliver amanitin only into target-positive cancer cells while target negative cells show no off-target toxicity. Consistent with CD37 expression on the cell surface, ex-vivo treatment of freshly purified cells from RS-PDX tumor masses to αCD37-ATACs® resulted in increased apoptosis after 72 hours of treatment, with only minor differences among the 3 ATACs® and the models used. Since alpha-amanitin is a deadly toxin known to target human RNA polymerase II and, at high doses, also RNA polymerase III, we checked messenger RNA levels in basal conditions and after CD37-ATAC® treatment by looking at different housekeeping genes, and confirmed a reduction in global mRNA levels. αCD37-ATAC® efficacy was then assessed in vivo in systemic RS-PDX models where RS cells are intra-venously (i.v.) injected in the tail vein and cells distribute to different tissues (blood, spleen and bone marrow), resembling the human disease. Cells from RS1316, RS1050 and RS9737 models were injected into the tail vein and left to engraft 14 days, before mice were randomly assigned to vehicle or ATAC® groups. A single i.v. treatment for each αCD37-ATAC® was administered, testing two different doses for each compound, and mice were then monitored for survival. Overall, the single administration of all three ATACs® caused highly significant disease regression. In the RS1316 model, independently of the dose or tested ATAC®s, all treated mice, except one, were alive and disease-free until the end of the experiment, 140 days post cells injection, while survival of vehicle-treated mice was 65 days. FACS analysis to trace neoplastic cells in parenchymatous organs and bone marrow confirmed the absence of neoplastic cells. In the other 2 models, RS9737 and RS1050, even though ATAC® treatment did not result in complete disease eradication, a single administration of αCD37-ATAC® resulted in a dramatically increased survival (approximately 35-60 days, depending on the model and ATAC® used). Finally, CD37 expression was confirmed by RNA sequencing on a cohort of 15 primary RS samples, even though with variable levels. Compared to CLL cells, RS samples showed CD37 expression levels comparable to those reported for DLBCL cells. Overall, these data indicate CD37 as a potential target to treat RS patients with selective targeting αCD37-ATACs®. ATACs® is a registered trade mark of Heidelberg Pharma Research GmbH, Germany References Vaisitti T et al. Blood. 2021;137(24):3365-3377. Iannello A, et al. Blood. 2021;137(24):3378-3389. Disclosures Orlik: Heidelberg Pharma: Current Employment. Kulke: Heidelberg Pharma: Current Employment. Pahl: Heidelberg Pharma: Current Employment. Deaglio: Heidelberg Pharma: Research Funding; Astra Zeneca: Research Funding.
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