ALBERT

Description: Background : Anagrelide is a widely used therapeutic agent for patients with essential thrombocythemia. While other cytoreductive agents, such as hydroxyurea, influence multi-lineage blood cells, anagrelide exerts less effect on the white and red blood cell lineages. Although the clinical efficacy of anagrelide has been reported, the exact mechanism of action is unclear. Recently, immortalized megakaryocyte progenitor cell lines (imMKCLs) were established from human induced pluripotent stem (iPS) cells by the introduction of doxycycline-inducible lentiviral vectors harboring c-MYC, BMI1, and BCL-XL for the clinical application of artificially generated platelets. In this study, we aimed to elucidate the molecular mechanism of anagrelide on the inhibition of platelet production using imMKCLs as an ideal model for human megakaryogenesis and platelet formation. Materials and Methods : imMKCLs, established at Center for iPS Cell Research and Application, Kyoto University, Japan, were cultured in Iscove's modified Dulbecco's medium with thrombopoietin (TPO), stem cell factor (SCF), and doxycycline. The differentiation of imMKCLs and platelet generation were induced by doxycycline removal. The generation of mature platelets was observed approximately 7 days after the differentiation was initiated. Both undifferentiated and differentiated imMKCLs were treated with several different concentrations of anagrelide. The cell proliferation and number of generated platelets following anagrelide treatment were analyzed by BrdU cell proliferation assay and flow cytometry, respectively. To explore the molecular mechanism of anagrelide treatment in imMKCLs, we performed mRNA sequencing in imMKCLs treated with or without anagrelide followed by gene ontology (GO) analysis and gene set enrichment analysis (GSEA). The expression of genes related to megakaryogenesis and platelet formation was also analyzed utilizing quantitative real-time PCR. Results : Anagrelide exposure caused morphologically suppressive changes in the differentiation of imMKCLs. Anagrelide treatment also suppressed the mRNA expression of the megakaryocytic surface markers CD41 and CD61 in both undifferentiated (P 〈 0.01 and P 〈 0.001, respectively) and differentiated (P 〈 0.01 and P 〈 0.001, respectively) settings. The BrdU incorporation rate in differentiated imMKCLs decreased significantly following anagrelide treatment (P 〈 0.001, anagrelide 0 vs. 1 or 10 µM). The resultant generation of mature platelets (double positive for CD41 and CD42b) was significantly decreased by exposure to anagrelide, as analyzed by flow cytometry (P 〈 0.001). Regarding the molecular mechanism of anagrelide treatment on imMKCLs, GO analysis following RNA sequencing demonstrated that gene sets related to platelet activation and degranulation were significantly downregulated in both undifferentiated and differentiated conditions. Moreover, GSEA revealed that gene sets related to the cell cycle, such as mitosis and DNA replication, were decreased as well as platelet-specific genes. The mRNA expression levels of genes related to megakaryogenesis and platelet-formation, such as FLI1, TAL1, GATA1, and PF4, were significantly downregulated, especially in differentiated imMKCLs, by anagrelide treatment (P 〈 0.001, P = 0.013, P 〈 0.01, and P 〈 0.01, respectively). Conclusions : We successfully reproduced the platelet-lowering effect of anagrelide by using imMKCLs from human iPS cells that could generate functional platelets in culture. Our RNA sequencing results revealed that anagrelide specifically suppressed megakaryogenesis and platelet formation-related genes. Additional studies including an apoptosis assay and cell cycle analysis of imMKCLs following anagrelide exposure are ongoing to elucidate further molecular mechanisms of anagrelide treatment. Disclosures Takayama: Megakaryon co. Ltd.: Research Funding. Eto:Megakaryon co. Ltd.: Research Funding.

Description: [Introduction] AL amyloidosis is caused by the deposition of abnormally folded clonal immunoglobulin (IG) light chains (LCs, λ:κ = 3:1) made by malignant plasma cells in the bone marrow (BM), which leads to multi-organ dysfunction, often involving the heart, kidney, liver, skin, and nerves. However, little is known about what regulates organ tropism of amyloid deposition in this disease. In addition, no study has analyzed the repertoire of IG germlines of plasma cells in the BM in AL amyloidosis using next generation sequencing (NGS). In this study, we aimed to identify the clonal composition of IG λ light-chain variable region (IGLV) genes in BM cells in patients with AL amyloidosis using NGS. [Material and method] BM cells were obtained at diagnosis from 38 patients with AL amyloidosis and those with other plasma cell disorders: multiple myeloma (MM, n = 7), and monoclonal gammopathy of undetermined significance (MGUS, n = 11) with λ-type monoclonal paraprotein. Seven normal control (NC) patients had either immune thrombocytopenia or malignant lymphoma without BM invasion. Genomic DNA was extracted from the BM mononuclear cells preserved in LABO Banker1 or BM clots in O.C.T compound using QIAamp DNA Blood Mini kit. The IGLV1 and IGLV2 genes were amplified by polymerase chain reaction using a 5′ primer for the IGLV1/2 framework 3 (FR3) region and 3′ consensus primers for the IGLJ1/2/3 joining regions. Multiple samples were pooled, and paired-end 2 × 250 base pair sequencing reactions were performed using an Illumina MiSeq sequencer and then analyzed by an open-source program called Vidjil. All subjects provided written informed consent to participate in the study, in accordance with the Declaration of Helsinki. This study was approved by the ethics committee of the Chiba University Graduate School of Medicine and Japanese Red Cross Medical Center. [Results] Clinical and laboratory features of 38 patients with AL amyloidosis were as follows: primary AL amyloidosis (n = 31); 15 and 20 patients had cardiac and renal dysfunctions, respectively, and secondary AL amyloidosis with MM (n = 7); 4 and 1 patient had cardiac and renal dysfunctions, respectively. In patients with AL amyloidosis, the median plasma cell count in BM aspirate smears was 3.3% (0.1%-50.4%), and the median difference in involved and uninvolved light chains (dFLC) was 104.5 mg/L (28.5mg/L -2673.3mg/L). Representative results of the Vidjil analysis in NC, MGUS, AL amyloidosis, and MM are shown in Figure 1. The most abundant IGLV gene accounted for not 〉1% of the reads, and there was no dominant germline in NC samples. Therefore, we defined the dominant clone as 〉1% of IG germlines in plasma cells. According to this definition, clonal IG germlines were found in 27 of 31 patients with primary AL amyloidosis (87%), 5 of 7 with secondary AL amyloidosis (71%), 7 of 7 with MM (100%), and 8 of 11 with MGUS (73%). However, the size of clones in AL amyloidosis (median 3.1%, 0.38%-14.3%) was significantly smaller than that in MM (median 17.8%, 2.2%-17.9%) (P

Description: Introduction: A novel tubulin binding agent PTC596, which is currently in clinical trials for solid tumors, was originally identified by its ability to kill cancer stem cells and to reduce BMI1 activity. PTC596 treatment results in hyperphosphorylation of the BMI1 protein and loss of BMI1 function as demonstrated by a reduction in H2A ubiquitination levels in a range of solid tumor lines. Subsequent studies have shown that the down-regulation of BMI1 protein is due to a G2/M arrest. In this study, we aimed to investigate the in-vitro and in-vivo anti-tumor activities of PTC596 and the combination with bortezomib in multiple myeloma (MM). Methods: For in-vitro evaluation, MTS and BrdU ELISA assays were performed using human MM cell lines. Approved by the Institutional Review Committee at Chiba University, primary myeloma cells and bone marrow stromal cells (BMSCs) were collected from the bone marrow of MM patients with informed consent. For in-vivo evaluation, the MM.1S subcutaneous xenograft model in NOG mice was used. To understand the mechanisms of action and target genes of the treatments, flow cytometry (FCM), western blotting, RNA-seq, and ChIP-seq were performed. Results: PTC596 induced significant cytotoxicity in all MM cell lines tested, including bortezomib-resistant OPM-2/BTZ and KMS-11/BTZ cells (CC50: 24-98 nM). PTC596 also suppressed cell proliferation when these cell lines were co-cultured with BMSCs. As expected, PTC596 reduced the levels of BMI1 protein and uH2A in a dose-dependent manner. Of note, PTC596 induced cell cycle arrest as detected by a BrdU FCM assay in MM cells and apoptosis as detected by annexin-V FCM in MM cell lines and primary myeloma cells. Moreover, oral administration of PTC596 twice a week for three weeks significantly inhibited the growth of MM.1S tumors implanted in immunodeficient mice and improved the survival of mice as compared with mice treated with vehicle only (p=0.0021). Of interest, bortezomib appeared to transcriptionally repress the expression of BMI1 and reduce the levels of uH2A. We then tested the efficacy of the combination of PTC596 with bortezomib in MM cells and found additive or synergistic effects when MM cell lines were co-cultured with BMSCs. Reductions in the levels of BMI1 protein and uH2A by PTC596 or bortezomib alone were significantly enhanced in the combination treatment. Furthermore, apoptosis induced by bortezomib was significantly enhanced by the combination with PTC596 as evidenced by increased annexin-positive cells detected in flow cytometric analysis and increased cleavage of caspases with reduction in MCL1 protein in western blotting. RNA-seq of MM.1S cells treated with PTC596 alone or in combination with bortezomib demonstrated repression of gene sets related to the cell cycle in either setting and enrichment of gene sets related to apoptosis in the combination. Ongoing analysis of our ChIP-seq data will reveal the direct targets of BMI1 in MM cells. Remarkably, oral administration of PTC596 combined with subcutaneous injection of bortezomib twice a week for five weeks significantly reduced MM.1S tumor growth in comparison to the control or either single treatment (p

Description: Introduction: Recent studies based on next-generation sequencing revealed the genetic landscape of diffuse large B cell lymphoma (DLBCL). A new genetic classification system was proposed, including four groups; the BCL2 and SGK1 groups that were both associated with germinal center B-cell like (GCB) DLBCL, an MYD88 group that was associated with non-GCB DLBCL, and a NOTCH2 group that was not associated with a specific cell-of-origin (COO). Unfortunately, this classification method is somewhat complex and thus not fully accepted in clinical practice. Furthermore, part of all cases remained unclassified; as such, it is clear that the diversity of the genetic landscape of DLBCL is not yet fully understood. In this study, we performed a retrospective analysis of genetic abnormalities and their correlations with clinical characteristics in a Japanese cohort of patients diagnosed with DLBCL. Materials and Methods: We collected clinical data from 224 of a total of 234 patients who were diagnosed with DLBCL between 2013 and 2018 at Chiba University Hospital. We also collected formalin-fixed paraffin-embedded (FFPE) specimens obtained from 204 patients via standard diagnostic procedures. The COO for each sample was assessed using the Hans algorithm with immunohistochemical staining; rearrangements of BCL2, BCL6, and MYC were evaluated by fluorescence in situ hybridization. Targeted DNA sequencing was performed using a 144-gene custom panel. Results: Of the 224 DLBCL patients evaluated in our study, the median age at diagnosis was 69 years (range, 18 - 92 years). The median follow-up time was 34 months; three-year progression-free survival (PFS) was 63.2%, and three-year overall survival was 78.0%. COO was determined in 218 cases; 93 of these cases (41.5%) were classified as GCB type and 125 cases (55.8%) as non-GCB type. We successfully performed targeted DNA sequencing in 167 of the 204 FFPE samples. Compared to previous reports, our cohort included relatively higher frequencies of mutations in PIM1 (44.3%), KMT2D (40.7%), MYD88L265P (37.7%), and CD79B (24.5%); by contrast, we detected comparatively lower mutation frequencies in B2M (6.6%), ETV6 (5.4%), CDKN2A (4.7%), and TNFAIP3 (4.1%). Multivariate adjustment of genes extracted by univariate analysis and factors identified by International Prognostic Index score revealed that genetic mutations of MYD88L265P (Hazard ratio [HR] = 2.045), IL16 (HR = 4.848), and BCOR (HR = 6.295) were significant prognostic factors. Mutations in IL16 and BCOR are novel factors that will be used to predict poor prognosis. In the 167 sequenced cases, 110 were classified into the aforementioned four subtypes based on mutations detected in 23 genes together with rearrangements of BCL2 and BCL6; specifically, 47 cases were classified as members of the MYD88 group, 28 in the BCL2 group, 19 in the NOTCH2 group, and 16 in the SGK1 group. We identified a trend toward differential PFSs among the four groups (p = 0.18); three-year PFS was 51.2% among patients with MYD88 group, 59.6% in the BCL2 group, 63.2% in the NOTCH2 group, and 75.0% for the SGK1 group. When compared outcomes of patients in the BCL6 group, patients in the MYD88 group had significantly inferior PFS (p = 0.043) among the non-GCB DLBCL patients; those in the BCL2 group revealed a trend toward inferior PFS compared with those in the SGK1 group (p = 0.34) among the GCB DLBCL patients. We next focused on 28 cases of CD5-positive DLBCL; this is a distinct DLBCL subtype with poor prognosis that is identified more frequently among Asians. We observed significantly higher frequencies of frameshift or nonsense mutations in CD58 and missense mutations in MYD88L265P. Furthermore, evaluation of gene expression data for CD5-positive DLBCL reported in a published database (Miyazaki K et al. Int J Hematol. 2015) revealed diminished expression of CD58 (p = 0.01) and augmented expression of MYD88L265P (p 〈 0.001). These results suggest that there may be a specific correlation between genetic mutations and gene expression. Intriguingly, these specific genes are key regulators of the immune response, suggesting that inflammation contribute to the unfavorable outcome of CD5-positive DLBCL. Conclusion: Our study provides support for the genetic classification of DLBCL using targeted DNA sequencing to evaluate outcomes in our Japanese cohort. We also identified mutations in novel candidate genes that may be used to predict clinical outcomes. Disclosures Nakaseko: Novartis Pharma KK: Speakers Bureau; Pfizer Japan Inc.: Speakers Bureau. Kaneda:SRL Inc.: Research Funding; SCRUM Inc.: Research Funding; Tsubakimoto Chain Co.: Research Funding; Takeda Foundation: Research Funding; Princess Takamatsu Cancer Research Fund.: Research Funding; Wedge Co Ltd: Research Funding.