Anti Thymocyte Globulin-Based Treatment for Acquired Bone Marrow Failure in Adults

Idiopathic acquired aplastic anemia can be successfully treated with Anti Thymocyte Globulin (ATG)-based immune suppressive therapy and is therefore considered a T cell-mediated auto immune disease. Based on this finding, several other forms of idiopathic acquired bone marrow failure are treated with ATG as well. For this review, we extensively searched the present literature for evidence that ATG can lead to enduring remissions in different forms of acquired multi- or single-lineage bone marrow failure. We conclude that ATG-based therapy can lead to an enduring hematopoietic response and increased overall survival (OS) in patients with acquired aplastic aplasia. In patients with hypocellular myelodysplastic syndrome, ATG can lead to a hematological improvement without changing the OS. ATG seems less effective in acquired single-lineage failure diseases like Pure Red Cell Aplasia, Amegakaryocytic Thrombocytopenia and Pure White Cell Aplasia, suggesting a different pathogenesis in these bone marrow failure states compared to aplastic anemia. T cell depletion is hypothesized to play an important role in the beneficial effect of ATG but, as ATG is a mixture of polyclonal antibodies binding to different antigens, other anti-inflammatory or immunomodulatory effects could play a role as well.

p53-dependent induction of P2X7 on hematopoietic stem and progenitor cells regulates hematopoietic response to genotoxic stress

Stem and progenitor cells are the main mediators of tissue renewal and repair, both under homeostatic conditions and in response to physiological stress and injury. Hematopoietic system is responsible for the regeneration of blood and immune cells and is maintained by bone marrow-resident hematopoietic stem and progenitor cells (HSPCs). Hematopoietic system is particularly susceptible to injury in response to genotoxic stress, resulting in the risk of bone marrow failure and secondary malignancies in cancer patients undergoing radiotherapy. Here we analyze the in vivo transcriptional response of HSPCs to genotoxic stress in a mouse whole-body irradiation model and, together with p53 ChIP-Seq and studies in p53-knockout (p53KO) mice, characterize the p53-dependent and p53-independent branches of this transcriptional response. Our work demonstrates the p53-independent induction of inflammatory transcriptional signatures in HSPCs in response to genotoxic stress and identifies multiple novel p53-target genes induced in HSPCs in response to whole-body irradiation. In particular, we establish the direct p53-mediated induction of P2X7 expression on HSCs and HSPCs in response to genotoxic stress. We further demonstrate the role of P2X7 in hematopoietic response to acute genotoxic stress, with P2X7 deficiency significantly extending mouse survival in irradiation-induced hematopoietic failure. We also demonstrate the role of P2X7 in the context of long-term HSC regenerative fitness following sublethal irradiation. Overall our studies provide important insights into the mechanisms of HSC response to genotoxic stress and further suggest P2X7 as a target for pharmacological modulation of HSC fitness and hematopoietic response to genotoxic injury.

Differential Redox State and Iron Regulation in Chronic Obstructive Pulmonary Disease, Acute Respiratory Distress Syndrome and Coronavirus Disease 2019

In patients affected by Acute Respiratory Distress Syndrome (ARDS), Chronic Obstructive Pulmonary Disease (COPD) and Coronavirus Disease 2019 (COVID-19), unclear mechanisms negatively interfere with the hematopoietic response to hypoxia. Although stimulated by physiological hypoxia, pulmonary hypoxic patients usually develop anemia, which may ultimately complicate the outcome. To characterize this non-adaptive response, we dissected the interplay among the redox state, iron regulation, and inflammation in patients challenged by either acute (ARDS and COVID-19) or chronic (COPD) hypoxia. To this purpose, we evaluated a panel of redox state biomarkers that may integrate the routine iron metabolism assays to monitor the patients’ inflammatory and oxidative state. We measured redox and hematopoietic regulators in 20 ARDS patients, 20 ambulatory COPD patients, 9 COVID-19 ARDS-like patients, and 10 age-matched non-hypoxic healthy volunteers (controls). All the examined pathological conditions induced hypoxia, with ARDS and COVID-19 depressing the hematopoietic response without remarkable effects on erythropoietin. Free iron was higher than the controls in all patients, with higher levels of hepcidin and soluble transferrin receptor in ARDS and COVID-19. All markers of the redox state and antioxidant barrier were overexpressed in ARDS and COVID-19. However, glutathionyl hemoglobin, a candidate marker for the redox imbalance, was especially low in ARDS, despite depressed levels of glutathione being present in all patients. Although iron regulation was dysfunctional in all groups, the depressed antioxidant barrier in ARDS, and to a lesser extent in COVID-19, might induce greater inflammatory responses with consequent anemia.

Abstract MP153: TET2 Regulates Type I Interferon Signaling in the Hematopoietic Response to Myocardial Infarction

Myocardial infarction (MI) elicits a rapid and vigorous reaction from the bone marrow hematopoietic compartment, inducing a massive efflux of myeloid first responders into the bloodstream. These cells traffic to the infarct, where they mediate cardiac remodeling and repair through inflammatory signaling and recruitment of additional immune cells to the injured myocardium. A hyperinflammatory myeloid compartment, as is produced by mutations in epigenetic regulator TET2 associated with clonal hematopoiesis, can thus drive adverse cardiac remodeling after MI and accelerate progression to heart failure. Whether loss of TET2 alters the transcriptional landscape of MI-induced myelopoiesis remains to be investigated in an unbiased fashion. Here, we performed single-cell RNA sequencing of >16,000 bone marrow myeloid cells isolated from wild-type and Tet2 -/- mice after MI to characterize the emergency hematopoietic response in the presence and absence of TET2. Our data capture distinct transitional states of myeloid lineage commitment and maturation, originating from myeloid progenitors and progressing along divergent granulocytic and monocytic differentiation trajectories. Additionally, we delineate a subpopulation of interferon (IFN)-activated myeloid progenitors, monocytes, and neutrophils characterized by the concerted upregulation of various Type I IFN-stimulated genes, and find the fraction of IFN-activated cells, as well as the degree of activation, to be markedly higher in Tet2 -/- mice. We have previously described activation of this pathway after MI in mice, and demonstrated cardioprotective effects of its genetic or pharmacological inhibition. Our findings reveal heightened activation of the antiviral Type I interferon response among bone marrow myeloid cells of Tet2 -/- mice during MI-induced emergency hematopoiesis. This highlights IFN signaling as a potential candidate driver of cardiovascular pathologies (including atherosclerosis, myocardial infarction, and heart failure) associated with TET2-mediated clonal hematopoiesis. Further studies are necessary to investigate whether Tet2 -/- mice exhibit enhanced response to blockade of Type I IFN signaling after MI, and to determine whether myeloid cells of TET2 -mutant humans are similarly activated.

Ferric Carboxymaltose in the treatment of chemotherapy-induced anaemia: an effective, safe and cost- sparing alternative to blood transfusion

Anaemia is highly prevalent in cancer patients, adversely affects quality of life and impacts survival. The pathogenesis is multifactorial, with iron deficiency being a major and potentially treatable contributor. This study aimed to assess the effectiveness and economic impact of ferric carboxymaltose in chemotherapy-induced anaemia. This prospective cohort study between 2015–2016 of chemotherapy-treated patients for solid tumours, grade ≥2 anaemia and iron deficiency evaluated hematopoietic response four weeks after ferric carboxymaltose treatment. Transfusion rate of all cancer patients treated at our ambulatory unit during the two-year study period (2015–2016) was compared to a retrospective cohort (2013–2014) who received blood transfusion only. Between 2015–2016, 99 patients were included and treated with ferric carboxymaltose, the majority of whom (n = 81) had relative iron deficiency. Mean haemoglobin concentrations improved from 9.2 [6.7–10.8] g/dL to 10.6 [7.8–14.2] g/dL four weeks after treatment. A 26% reduction in the transfusion rate was observed from control retrospective to the prospective study group including ferric carboxymaltose treated patients [relative risk 0.74 (95% CI:0.66–0.83)]. The cost analysis showed a benefit for the use of ferric carboxymaltose in chemotherapy-induced anaemia. This study shows that ferric carboxymaltose is an effective, cost-saving support treatment, reducing the need for allogeneic transfusions saving blood units which are a limited resource.

A mouse model of recurrent myocardial infarction reports diminished emergency hematopoiesis and cardiac inflammation

Recurrent MI is common in patients with coronary artery disease and associates with high mortality. Here we developed a surgical mouse model in which two subsequent MIs affect different left ventricular regions in the same mouse. Recurrent MI was induced by ligating the left circumflex followed by the left anterior descending branch of the coronary artery. We characterized the resulting ischemia by whole-heart fluorescent coronary angiography after optical organ clearing and by cardiac MRI. We report that a first MI induces bone marrow “memory” via a circulating signal, thereby affecting hematopoietic factor expression in bone marrow macrophages. This altered the organism’s reaction to subsequent events. Inspite at least similar extent of injury reported by blood troponin, recurrent MI caused reduced emergency hematopoiesis and less leukocytosis than a first MI. Consequently, fewer leukocytes migrated to the ischemic myocardium. The hematopoietic response to lipopolysaccharide was also mitigated after a previous MI. Our data suggest that hematopoietic and innate immune responses are shaped by a preceding MI.

Pharmacokinetics and Exposure-Response of Luspatercept in Patients with Anemia Due to Low- or Intermediate-1-Risk Myelodysplastic Syndromes (MDS): Preliminary Results from Phase 2 Studies

Background: Luspatercept is a modified ActRIIB-IgG Fc fusion protein that corrects ineffective erythropoiesis. In phase 2 studies, luspatercept treatment led to long-term increases in hemoglobin (Hb) levels and reduction in transfusion burden in patients (pts) with IPSS Low- or Intermediate-1-risk MDS. Aims: To characterize the pharmacokinetics (PK) of luspatercept and explore the exposure-response relationship for efficacy and safety in pts with MDS, thereby informing selection of the starting dose for phase 3 studies of luspatercept in MDS. Methods : PK, safety, and efficacy data were collected from two phase 2 studies (base and extension). In the base study, luspatercept was administered once every 3 weeks by subcutaneous injection to sequential cohorts for up to 5 doses. The base study included a dose-finding phase (at fixed doses from 0.125 to 1.75 mg/kg), and an expansion cohort (at a starting dose of 1.0 mg/kg followed by individual dose titration up to 1.75 mg/kg). Pts completing the base study were eligible to enroll in an extension study, where they continued to receive luspatercept every 3 weeks for up to 24 months. Pts who had treatment interruption for ≥ 3 months before enrolling in the extension study received a starting dose of 1.0 mg/kg (followed by dose titration) and were treated as "new" pts in the exposure-response analysis. The main exposure endpoint was area under the luspatercept serum concentration−time curve (AUC). Clinical endpoints included Hb increase, transfusion reduction, and drug-related adverse events (AEs) in weeks 1-15. Responders were defined as pts achieving erythroid hematologic improvement (HI-E) per IWG criteria, i.e. Hb increase ≥ 1.5 g/dL for 8 weeks in low transfusion burden (LTB) pts, and transfusion reduction ≥ 4 RBC units/8 weeks in high transfusion burden (HTB) pts. Results : As of July 20, 2016, preliminary data were available for 66 pts: 22 LTB pts (baseline Hb 6.4-10.1 g/dL) and 44 HTB pts (baseline transfusion burden 4-18 units/8 weeks). Median age was 72 years (range 27-90); 41% were female. A total of 39 pts were eligible for individual dose titration; of these, ~49% had ≥ 1 dose escalation (to 1.33 mg/kg) and ~15% had 2 dose escalations (to 1.75 mg/kg) in the first 3 months. Luspatercept PK was adequately described by a 1-compartment PK model with linear absorption and elimination. Half-life of luspatercept in serum was ~10-14 days across doses. Body weight positively correlated with luspatercept clearance and its volume of distribution. Baseline transfusion burden (LTB vs HTB) and erythropoietin (EPO) level (10-4,752 U/L) had no significant effect on luspatercept PK. In LTB pts who were transfusion-free on treatment, higher luspatercept AUC correlated with greater Hb increase (P < 0.01). In HTB pts, AUC correlated with reduced transfusion units in pts with baseline EPO ≤ 500 U/L (P< 0.01) but not in pts with baseline EPO > 500 U/L. Median AUC was 148 d·µg/mL in LTB responders and 185 d·µg/mL in HTB responders. Luspatercept AUC also correlated with frequency of IWG HI-E responders for LTB pts, HTB pts (baseline EPO ≤ 500 U/L), and the 2 groups combined. In pts requiring transfusion (≥ 2 units/8 weeks) with baseline EPO ≤ 500 U/L, baseline transfusion burden was a significant predictor of achieving transfusion independence (TI) ≥ 8 weeks, and higher luspatercept AUC was associated with greater TI rate after accounting for baseline transfusion burden. Thus, individualized dosing based on baseline transfusion burden may increase the likelihood of achieving TI in HTB pts. Population PK simulation predicted that the starting dose resulting in 90% of LTB pts and 50% of HTB pts achieving efficacious AUC for HI-E would be 1 mg/kg and 1.1 mg/kg, respectively; higher doses would result in a higher proportion of pts achieving efficacious AUC. There was no significant relationship between severity and frequency of drug-related AEs and luspatercept serum exposure. Conclusions: Higher luspatercept serum exposure correlated with greater erythroid hematopoietic response for both LTB and HTB pts. Exposure-response modeling and PK simulation support a phase 3 starting dose of 1.0 mg/kg and intra-patient dose escalation up to 1.75 mg/kg according to erythroid hematopoietic response. A phase 3 study of luspatercept in regularly transfused ring sideroblast positive patients with lower-risk MDS according to IPSS-R criteria is ongoing (MEDALIST study; ClinicalTrials.gov NCT02631070). Disclosures Chen: Celgene Corporation: Employment, Equity Ownership. Laadem:Celgene Corporation: Employment, Equity Ownership. Wilson:Acceleron Pharma: Employment, Equity Ownership. Zhang:Acceleron Pharma: Employment. Sherman:Acceleron Pharma: Employment, Equity Ownership, Patents & Royalties. Ritland:Celgene Corporation: Employment, Equity Ownership. Attie:Acceleron Pharma: Employment, Equity Ownership.