ALBERT

Description: Key Points Exposure to chemotherapy promotes the exit of specific subpopulations of BMDCs with angio-supportive activity. Notch in BMDCs is required for the exit of these cells from the bone marrow and for chemotherapy-enhanced angiogenesis in tumors.

Description: Apc, a negative regulator of the canonical Wnt signaling pathway, is a bona-fide tumor suppressor whose loss of function results in intestinal polyposis. APC is located in a commonly deleted region on human chromosome 5q, associated with myelodysplastic syndrome (MDS), suggesting that haploinsufficiency of APC contributes to the MDS phenotype. Analysis of the hematopoietic system of mice with the Apcmin allele that results in a premature stop codon and loss of function showed no abnormality in steady state hematopoiesis. Bone marrow derived from Apcmin mice showed enhanced repopulation potential, indicating a cell intrinsic gain of function in the long-term hematopoietic stem cell (HSC) population. However, Apcmin bone marrow was unable to repopulate secondary recipients because of loss of the quiescent HSC population. Apcmin mice developed a MDS/myeloproliferative phenotype. Our data indicate that Wnt activation through haploinsufficiency of Apc causes insidious loss of HSC function that is only evident in serial transplantation strategies. These data provide a cautionary note for HSC-expansion strategies through Wnt pathway activation, provide evidence that cell extrinsic factors can contribute to the development of myeloid disease, and indicate that loss of function of APC may contribute to the phenotype observed in patients with MDS and del(5q).

Description: Two patients with agranulocytosis associated with diphenylhydantoin (DPH) therapy and clinical data suggesting suppression of granulopoiesis were investigated using in vitro culture techniques for committed granulocyte/macrophage precursors. Addition of DPH to cultures containing the patients' sera resulted in significant suppression of colony growth. Extensive studies on the acute serum from one patient revealed the drug-dependent inhibitory activity to be nondialyzable, resistant to chloroform extraction, heat stable, active in the presence of heat-inactivated fetal bovine serum, active against autologous as well as allogeneic cells, and absent from convalescent sera. Drug-dependent bone marrow colony-suppressing activity was removed by absorption on an antiimmunoglobulin-Sepharose column but not by IgG-Sepharose. The serum show non-drug dependent suppression of oxygen consumption by normal polymorphonuclear leukocytes engaged in phagocytosis and also showed evidence of ability to opsonize these cells. When the serum was incubated with mitogen-stimulated lymphocytes, suppression of 3H-thymidine uptake by autologous but not allogeneic cells was noted. Similarly, the serum suppressed short-term 3H-thymidine uptake by autologous but not allogeneic bone marrow. Absorption of the patients' sera with allogeneic polymorphonuclear leukocytes, autologous polymorphonuclear leukocytes, or autologous lymphocytes removed the drug-dependent inhibitory activity, but absorption with allogeneic lymphocytes did not. These data are most consistent with the presence of a noncomplement dependent antibody capable of suppressing granulopoiesis, mediating peripheral destruction of polymorphonuclear leukocytes, and cross-reacting with a lymphocyte antigen of limited population distribution.

Description: Background Neutrophils are the first line of defence against bacterial infection and formation of neutrophil extracellular traps (NETs) is an important protective mechanism. However, NETs can also cause harm by promoting intravascular coagulation and multi-organ failure (MOF) in animal models. Although increasingly considered as important therapeutic targets, there is currently no robust and specific measure of NETs formation to inform clinical care and enable precision medicine in patients on the intensive care unit (ICU). The aim of this study is to establish a novel assay for measuring NETs and assess its clinical significance. Methods A prospective cohort of 341 consecutive adult ICU patients was recruited, following written informed consent. The NETs-forming capacity of ICU admission blood samples was semi-quantified by directly incubating patient plasma with isolated healthy neutrophils ex vivo. The association of NETs-forming capacity with sequential organ failure assessment (SOFA) scores, disseminated intravascular coagulation (DIC) and 28-day mortality were analysed and compared with available NETs assays. Cytokine analysis together with inhibitor studies was performed to determine the driving factors of NETs patients. To determine the pathological relevance of NETs, complementary in vivo studies were performed in mice models of sepsis (caecal ligation and puncture (CLP) or intraperitoneal injection of Escherichia coli), without or with anti-NETs therapy. Results We observed that NETs were directly induced by heterologous healthy neutrophils incubated with plasma taken from ICU patients, but not from healthy donors (unless incubated with 100 nM PMA). Using the novel assay, we could stratify ICU patients into 4 groups, those with absent (22.0%), mild (49.9%), moderate (14.4%) and strong (13.8%) NETs formation, respectively. Strong NETs formation was predominantly found in sepsis (P

Description: Key Points The vicinal disulphide bond and occupancy of its Ca2+-binding site cooperatively determine the stability of the VWF A2 domain. These 2 structural elements control the susceptibility of FL-VWF to proteolysis by ADAMTS13.

Description: Traditionally, the focus of anti-tumor immunity has been on CD8+ CTL responses. It is now realized that CD4+ T cells play a relevant role in protective anti-tumor responses. HLA Class II molecules are expressed on AML blasts, predicting that AML cells may stimulate CD4+ T cells. Based on our studies of inducing AML dendritic cell (AMLDC) differentiation and priming in situ AML-reactive T cells, we developed a novel method of generating multiple autologous AML reactive T cell lines by competitive limiting dilution (LD) AML MNC culture. Most autologous AML reactive T cell lines generated from this culture were CD4+. These CD4+ T cell lines with high IFN-gamma secretion in response to autologous AML cells showed low to moderate specific lysis of autologous AML cells in 4-hour 51Cr release assays. However, co-culture assays demonstrated that these CD4+ AML reactive T cell lines exerted intense cytotoxicity toward autologous AML cells, depleting more than 95% of autologous AML line cells in 2 days, and more than 99% in 7 days, with no or weak toxicity to allogeneic AML cells and cell lines, HL60, NB4, U937 KG1a and ak LCL cell line. Anti-HLA class II, Dr, Dp, Dq mAb (67±16% inhibition) and anti-HLA-Dr mAb (69±11% inhibition) but not anti-HLA class I mAb significantly inhibited IFN-gamma secretion of six CD4+ T cell lines stimulated by autologous AML cells confirmed the HLA class II restriction of reactivity of these CD4+ T cell lines. Flow cytometry analysis showed that these CD4+ T cell lines induced significant Annexin-V expression on autologous AML cells. The induction of Annexin-V+ on AML cells by CD4+ T cell lines correlated significantly with IFN-gamma secretion in response to autologous AML cells (n=11; r=0.84). This result suggested that the most important mechanism of autologous AML cell elimination by CD4+ AML reactive T cells generated from LD-AML-MNC cultures was apoptosis induction related to IFN-gamma secretion.

Description: Disease severity and healthcare utilization varies widely among persons with sickle cell disease (SCD). Hydroxyurea (HU) has been demonstrated to reduce rates of pain and acute chest syndrome, the leading causes of inpatient utilization in patients with Hb SS and S β°-thalassemia in clinical trials. We recently reported that HU was clinically effective in reducing rates of pain and acute chest syndrome in patients who initiate treatment. Use of hydroxyurea in SS/S β°-thalassemia has increased markedly since 2010. Thus we sought to detemine trends of hospital utilization for acute illness during an 8 yr in which HU utilization increased markedly (2010-2017). Data from years 2010-201 were obtained from the SCD database and patient records at Children's Healthcare of Atlanta (CHOA). Utilization data were restricted to acute care admissions. Admissions for elective procedures, non-SCD related discharge diagnoses, rare SCD genotypes, and patients who had undergone bone marrow transplant were excluded. Patients were compared based on number of hospitalizations, age, sex, SCD genotype (SS/S β°-thalassemia vs Hb SC/S β+thalassemia), and discharge diagnosis. A total of 3,116 patients had at least one encounter between 2010 and 2017; 2,947 patients met inclusion criteria. From 2010-2017 the total number of active patients per year increased from 1,546 patients to 1,789 patients (+16%), while the total number acute care admissions increased from 1,295 admissions to 1,609 admissions (+24%). There were no significant differences in the proportion of patients with genotypes SS/S β° thalassemia genotypes (67.0% vs 63.9%, p=0.06). Overall patients with SS/S β° thalassemia had higher admission rates compared to SC/S β+ thalassemia patients (0.94 vs 0.57 admissions per patient per year). During the study period. overall admission rates in SCD (acute illness hospitalizations/patient/yr) increased from a low of 0.74 in 2011 to a high of 0.90 in 2017. The proportion of admissions attributed to SS/S β°-thalassemia patients decreased (79.2% in 2010 vs 72.3% in 2017, p90% of patients over age 8 years), and had greater percentages of admissions for pain and acute chest syndrome then non-SHHU. In conclusion, during a period in which HU utilization in SS/S β°-thalassemia increased significantly, hospital utilization for acute illness in SS/S β° thalassemia decreased as expected. However, during the same period there was an unexpected increase in overall hospital utilization for acute illness in SCD. This increase in hospital utilization was the result of 1) a marked increase in SHHU and 2) an overall increased utilization in SC/S β+ thalassemia. Disclosures Dampier: Pfizer: Research Funding.

Description: Background: Myeloproliferative neoplasms (MPN) are a diverse group of hematopoietic stem cell disorders. JAK2V617F gain-of-function is the most prevalent mutation, accounting for more than 60% of MPNs. PRMT5 was initially identified as a JAK-binding protein. Its enzymatic function catalyses the symmetric di-methylation of arginine on a variety of substrates, including histones and proteins of the splicing apparatus. It has been proposed that mutant JAK2 can phosphorylate PRMT5, leading to loss of methylation activity and promotion of erythropoiesis (Liu F. et al. Cancer Cell 2011). Based upon this study, it was proposed that enhancing PRMT5 activity may be a useful therapeutic measure (Skoda RC et al. Cancer Cell 2011). Aim: To determine the role of PRMT5 in JAK2V671F mutant hematopoiesis. Hypothesis: Inhibition of PRMT5 will exacerbate JAK2V617F hematopoiesis R esults: Using a conditional null allele, we deleted Prmt5 in embryonic development with the hematopoietic-specific VavCre transgene. This led to embryonic lethality at E9.5 due to absence of erythropoiesis but not other lineages. Similar embryonic lethality was observed using the erythroid specific EpoRCre transgene. Following a 350,000-compound library screen, we developed a potent and selective SAM-dependent inhibitor (CTx034) of PRMT5 similar to that reported by Chan-Penebre E. at al. Nat. Chem. Biol. 2015. Consistent with the genetic evidence that PRMT5 is most important for erythropoiesis, CTx034 was a potent inhibitor of erythropoiesis in cultures derived from healthy human CD34+ cells. This suppression of erythropoiesis was associated with activation of p53. However, progenitor assays of bone marrow cells from patients with MPN showed that JAK2V617F erythropoiesis was more sensitive to CTx034 than normal erythropoiesis. We established JAK2V617F bone marrow chimeric mice to directly compare the in vivo effects of PRMT5 inhibition on mutant and wild-type erythropoiesis within the same animal. Remarkably, these studies showed normalization of spleen size and erythropoiesis, comparable to the current standard of care, Ruxolitinib (Figure 1A-B). Importantly, CTx034 was well tolerated in healthy animals with no suppression of hematopoiesis. One of the major therapeutic challenges for MPN is the eradication of the malignant clone, which is rarely achieved with Ruxolitinib. The addition of MDM2 inhibitors, which activate p53, are currently in trial. Importantly, CTx034 not only suppressed JAK2-mutant erythropoiesis but also activated p53 in JAK2-mutant progenitors, unlike Ruxolitinib (Figure 1C). This result strengthens the therapeutic rationale for PRMT5 inhibitors in MPN. To understand how CTx034 inhibits erythropoiesis, we initially considered direct methylation effects on JAK-STAT signalling and p53. Challenging previous reports, we could find no evidence that JAK alters PRMT5 activity, no evidence that PRMT5 inhibition perturbs JAK-STAT signalling and no evidence that PRMT5 methylates p53. To look more broadly, we performed RNA-seq analysis of CD34+ cells following 72 hours exposure to CTx034. Globally, this demonstrated a potent 'starvation' signal with suppression of protein synthesis despite activation of the upstream mTOR signalling pathway. This suppression of protein synthesis could be linked to three mechanisms. First, CTx034 inhibited methylation of the Sm core complex of the spliceosome, leading to alternate splicing (skipped exons and retained introns) affecting the elongation initiation factor 2 (EIF2) pathway. Second, PRMT5 directly interacts with the translation initiation complex (eIF4A, eIF4B, eIF4E and the poly(A)-binding protein 1, PABP1. Moreover, mass spectrometry identified PABP1 as a new target of PRMT5. Treatment with CTx034 did not alter protein abundance of any of these factors but decreased the RNA binding capacity of PABP1, thereby preventing the correct formation of the initiation of translation complex. Finally, CTx034 perturbed polysome formation with loss of methylation of RPS10. C onclusion: Challenging previous reports, we show that PRMT5 inhibitors are an attractive and novel therapeutic for JAK2V617F MPN by targeting initiation of translation, ribosome biogenesis and activation of p53. Disclosures Sonderegger: CRC Cancer Therapeutics: Research Funding. Cerruti:CRC Cancer Therapeutics: Research Funding. Toulmin:CRC Cancer Therapeutics: Research Funding. Lane:Novartis: Consultancy; Janssen: Consultancy, Research Funding; Celgene: Consultancy. Stupple:CRC Cancer Therapeutics: Employment. Street:MERCK: Membership on an entity's Board of Directors or advisory committees; CRC Cancer Therapeutics: Employment, Patents & Royalties. Jane:CRC Cancer Therapeutics: Patents & Royalties. Altura:MERCK: Employment. Nicholson:MERCK: Employment. Curtis:MERCK: Membership on an entity's Board of Directors or advisory committees; CRC Cancer Therapeutics: Patents & Royalties, Research Funding.