Triple combination therapy in pulmonary arterial hypertension

Pulmonary arterial hypertension is a severe disease characterized by increasing in pulmonary vascular resistance leading to right ventricular failure and death. Currently available drugs for treatment of PAH act on three different pathways responsible of the pathogenesis of this disease: the endothelin pathway, the nitric oxide pathway and the prostacyclin pathway. The purpose of our study was to reassess our experience on the use of drugs that interact on the pathobiological line of prostacyclin so we retrospectively included all patients, referred to our center from February 1995 to December 2021, who received therapy with i.v. Epoprostenol, s.c. Treprostinil or oral Selexipag. Firstly, we observed that patients treated with Epoprostenol were significantly more compromised at baseline when compared to the two other groups and evaluating the effects of the three different drugs, it emerged that patients treated with Epoprostenol had significantly greater improvements in respect to those treated with Treprostinil and Selexipag. In the second part of our analysis we assessed the effects of these drugs when used as third line strategy in order to limit many confounding factors that could influence demographic, clinical and hemodynamic characteristics of patient populations. The differences emerged in exercise capacity and baseline hemodynamics reflect the fact that in our clinical practice, we add Epoprostenol as third line therapy in more compromised patients, Treprostinil in intermediate situations and Selexipag in less impaired conditions. Comparing the effects of treatments between baseline and first follow-up we noticed smaller benefits with Selexipag when compared with intravenous and subcutaneous strategies but it’s important to weight baseline patient’s differences. Our analysis confirmed clinical and functional benefits for the use of both prostacyclin analogues and prostacyclin receptor agonists in terms of improved functional class, six-minute walking distance and cardiopulmonary hemodynamics

A pragmatic approach to risk assessment in pulmonary arterial hypertension using the 2015 European Society of Cardiology/European Respiratory Society guidelines

open12noTo optimise treatment of patients with pulmonary arterial hypertension (PAH), the 2015 European Society of Cardiology/European Respiratory Society guidelines recommend using risk stratification, with the aim of patients achieving low-risk status. Previous analyses of registries made progress in using risk stratification approaches, however, the focus is often on patients with a low-risk prognosis, whereas most PAH patients are in intermediate-risk or high-risk categories. Using only six parameters with high prognostic relevance, we aimed to demonstrate a pragmatic approach to individual patient risk assessment to discriminate between patients at low risk, intermediate risk and high risk of death.This work was supported by Department of Experimental, Diagnostic and Specialty Medicine-DIMES, University of Bologna, Bologna, Italy and by the National Institute of Biostructures and Biosystems, Rome, Italy.openDardi, Fabio; Manes, Alessandra; Guarino, Daniele; Zuffa, Elisa; De Lorenzis, Alessandro; Magnani, Ilenia; Rotunno, Mariangela; Ballerini, Alberto; Lo Russo, Gerardo Vito; Nardi, Elena; Galiè, Nazzareno; Palazzini, MassimilianoDardi, Fabio; Manes, Alessandra; Guarino, Daniele; Zuffa, Elisa; De Lorenzis, Alessandro; Magnani, Ilenia; Rotunno, Mariangela; Ballerini, Alberto; Lo Russo, Gerardo Vito; Nardi, Elena; Galiè, Nazzareno; Palazzini, Massimilian

The relevance of a low JAK2V617F allele burden in clinical practice: a monocentric study

Since low JAK2V617F allele burden (AB) has been detected also in healthy subjects, its clinical interpretation may be challenging in patients with chronic myeloproliferative neoplasms (MPNs). We tested 1087 subjects for JAK2V617F mutation on suspicion of hematological malignancy. Only 497 (45.7%) patients were positive. Here we present clinical and laboratory parameters of a cohort of 35/497 patients with an AB ≤ 3%.Overall, 22/35 (62.9%) received a WHO-defined diagnosis of MPN and in 14/35 cases (40%) diagnosis was supported by bone marrow (BM) histology (''Histology-based'' diagnosis). In patients that were unable or refused to perform BM evaluation, diagnosis relied on prospective clinical observation (12 cases, 34.3%) and molecular monitoring (6 cases, 17.1%) (''Clinical-based'' or ''Molecular-based'' diagnosis, respectively). In 11/35 (31.4%) patients, a low JAK2V617F AB was not conclusive of MPN. The probability to have a final hematological diagnosis (ET/PV/MF) was higher in patients with thrombocytosis than in patients with polyglobulia (73.7% vs 57.1%, respectively). The detection of AB ≥ 0.8% always corresponded to an overt MPN phenotype. The repetition of JAK2V617F evaluation over time timely detected the spontaneous expansion (11 cases) or reduction (4 cases) of JAK2V617F-positive clones and significantly oriented the diagnostic process.Our study confirms that histology is relevant to discriminate small foci of clonal hematopoiesis with uncertain clinical significance from a full blown disease. Remarkably, our data suggest that a cut-off of AB ≥ 0.8% is very indicative for the presence of a MPN. Monitoring of the AB over time emerged as a convenient and non-invasive method to assess clonal hematopoiesis expansion

Complex chromosomal rearrangements leading to MECOM overexpression are recurrent in myeloid malignancies with various 3q abnormalities

Chromosomal rearrangements involving 3q26 are recurrent findings in myeloid malignancies leading to MECOM overexpression, which has been associated with a very poor prognosis. Other 3q abnormalities have been reported and cryptic MECOM rearrangements have been identified in some cases. By fluorescence in situ hybridization (FISH) analysis, we investigated 97 acute myeloid leukemia/myelodysplastic syndrome patients with various 3q abnormalities to determine the role and the frequency of the involvement of MECOM. We identified MECOM rearrangements in 51 patients, most of them showed 3q26 involvement by chromosome banding analysis (CBA): inv(3)/t(3;3) (n\u2009=\u200926) and other balanced 3q26 translocations (t(3q26)) (n\u2009=\u200915); the remaining cases (n\u2009=\u200910) showed various 3q abnormalities: five with balanced translocations involving 3q21 or 3q25; two with homogenously staining region (hsr) on 3q; and three with other various 3q abnormalities. Complex rearrangements with multiple breakpoints on 3q, masking 3q26 involvement, were identified in cases with 3q21/3q25 translocations. Furthermore, multiple breaks were observed in two cases with t(3q26), suggesting that complex rearrangement may also occur in apparently simple t(3q26). Intrachromosomal gene amplification was another mechanism leading to MECOM overexpression in two cases with hsr on 3q. In the last three cases, FISH analysis revealed 3q26 involvement that was missed by CBA because of metaphases' suboptimal quality. All cases with MECOM rearrangements showed overexpression by real-time quantitative PCR. Finally, MECOM rearrangements can occur in patients with 3q abnormalities even in the absence of specific 3q26 involvement, underlining that their frequency is underestimated. As MECOM rearrangement has been associated with very poor prognosis, its screening should be performed in patients with any 3q abnormalities. \ua9 2016 Wiley Periodicals, Inc

Revealing very small FLT3 ITD mutated clones by ultra-deep sequencing analysis has important clinical implications in AML patients

FLT3 internal tandem duplication (ITD), one of the most frequent mutations in Acute Myeloid Leukemia (AML), is reported to be an unstable marker, as it can evolve from FLT3 ITD- to ITD+ during the disease course. A single-gene sensitive mutational screening approach may be helpful for better clarifying the exact timing of mutation occurrence, especially when FLT3 ITD appears to occur late, at disease progression. We developed an amplicon-based ultra-deep-sequencing (UDS) approach for FLT3 mutational screening. We exploited this highly sensitive technology for the retrospective screening of diagnosis, relapse and follow-up samples of 5 out of 256 cytogenetically normal (CN-) AML who were FLT3 wild-type at presentation, but tested ITD+ at relapse or disease progression. Our study revealed that all patients carried a small ITD+ clone at diagnosis, which was undetectable by routine analysis (0,2-2% abundance). The dynamics of ITD+ clones from diagnosis to disease progression, assessed by UDS, reflected clonal evolution under treatment pressure. UDS appears as a valuable tool for FLT3 mutational screening and for the assessment of minimal residual disease (MRD) during follow-up, by detecting small ITD+ clones that may survive chemotherapy, evolve over time and definitely worsen the prognosis of CN-AML patients

A cell cycle-related genomic and transcriptomic signature distinguish aneuploid and euploid acute myeloid leukemia

Chromosome gain or loss, which is the hallmark of aneuploidy, occurs in about 10% of adult Acute Myeloid Leukemia (AML) cases (Farag et al. IJO 2002, Breems et al. JCO 2008), despite inducing a dramatic reduction of cellular fitness in non-malignant cells (Torres et al. Science 2007). The study aimed to identify AML-specific molecular mechanisms having a causative and/or tolerogenic role towards aneuploidy. We performed 100 bp paired-end whole exome sequencing (WES, Illumina Hiseq2000) of 38 aneuploid (A) and 34 euploid (E) AML cases, identified according to cytogenetic analysis and SNP array (CytoScan HD, Affymetrix). Variants were called with GATK, MuTect and VarScan. We also compared the transcriptomic profile of leukemic bone marrow cells from 21 A-AML and 28 E-AML cases (HTA 2.0, Affymetrix). A-AML showed a significantly higher mutation load compared with E-AML (median number of variants: 25 and 15, respectively, p<.001) and a specific pattern of genomic lesions. Indeed, mutations in myeloid transcription factors and chromatin modifiers preferentially occurred in E-AML (p = .04 and p<.01, respectively), while A-AML was enriched for alterations in cell cycle-related genes (p<.01), with 70% of cases carrying at least one of those mutations (vs. 35% of E-AML, p<.01). The mutated genes played different functions across cell cycle phases, including DNA replication, centrosome dynamics, chromatid cohesion, chromosome segregation and spindle-assembly checkpoint. Moreover, 29% of A-AML displayed mutations of TP53 or a TP53-related gene (DDIAS, USP10), compared with 5.9% of E-AML cases (p = .01), with enrichment for a transcriptional signature of p53 downregulation in the aneuploid cohort (p<.05). Among the differentially expressed genes, we identified a cell cycle-related signature characterized by increased CDC20 and UBE2C and reduced RAD50, ATR and CCNA1 in A-AML (p<.001), confirmed at protein level, which was able to separate A-AML and E-AML. A-AML also showed upregulation of a KRAS transcriptional signature, irrespective of KRAS mutational status (p<.05). Our data show a link between aneuploidy and genomic instability in AML and highlight novel molecular mechanisms for the acquisition and/or maintenance of the aneuploid phenotype. Deregulation of the cell cycle machinery and DNA damage/repair checkpoints, either through mutations, copy number and transcriptomic alterations, cooperate with leukemogenic pathways, as KRAS signaling, to develop A-AML and overcome the unfitness barrier. This evidence suggests that a number of A-AML patients may benefit from pharmacological reactivation of TP53 and inhibition of KRAS pathway

Abstract 90: A cell cycle-related genomic and transcriptomic signature distinguish aneuploid and euploid acute myeloid leukemia

Chromosome gain or loss, which is the hallmark of aneuploidy, occurs in about 10% of adult Acute Myeloid Leukemia (AML) cases (Farag et al. IJO 2002, Breems et al. JCO 2008), despite inducing a dramatic reduction of cellular fitness in non-malignant cells (Torres et al. Science 2007). The study aimed to identify AML-specific molecular mechanisms having a causative and/or tolerogenic role towards aneuploidy. We performed 100 bp paired-end whole exome sequencing (WES, Illumina Hiseq2000) of 38 aneuploid (A) and 34 euploid (E) AML cases, identified according to cytogenetic analysis and SNP array (CytoScan HD, Affymetrix). Variants were called with GATK, MuTect and VarScan. We also compared the transcriptomic profile of leukemic bone marrow cells from 21 A-AML and 28 E-AML cases (HTA 2.0, Affymetrix). A-AML showed a significantly higher mutation load compared with E-AML (median number of variants: 25 and 15, respectively, p<.001) and a specific pattern of genomic lesions. Indeed, mutations in myeloid transcription factors and chromatin modifiers preferentially occurred in E-AML (p = .04 and p<.01, respectively), while A-AML was enriched for alterations in cell cycle-related genes (p<.01), with 70% of cases carrying at least one of those mutations (vs. 35% of E-AML, p<.01). The mutated genes played different functions across cell cycle phases, including DNA replication, centrosome dynamics, chromatid cohesion, chromosome segregation and spindle-assembly checkpoint. Moreover, 29% of A-AML displayed mutations of TP53 or a TP53-related gene (DDIAS, USP10), compared with 5.9% of E-AML cases (p = .01), with enrichment for a transcriptional signature of p53 downregulation in the aneuploid cohort (p<.05). Among the differentially expressed genes, we identified a cell cycle-related signature characterized by increased CDC20 and UBE2C and reduced RAD50, ATR and CCNA1 in A-AML (p<.001), confirmed at protein level, which was able to separate A-AML and E-AML. A-AML also showed upregulation of a KRAS transcriptional signature, irrespective of KRAS mutational status (p<.05). Our data show a link between aneuploidy and genomic instability in AML and highlight novel molecular mechanisms for the acquisition and/or maintenance of the aneuploid phenotype. Deregulation of the cell cycle machinery and DNA damage/repair checkpoints, either through mutations, copy number and transcriptomic alterations, cooperate with leukemogenic pathways, as KRAS signaling, to develop A-AML and overcome the unfitness barrier. This evidence suggests that a number of A-AML patients may benefit from pharmacological reactivation of TP53 and inhibition of KRAS pathway