ALBERT

Description: Inherited thrombocytopenias (ITs) are a heterogeneous group of disorders characterized by low platelet count that may result in bleeding tendency. Despite progress being made in defining the genetic causes of ITs, nearly 50% of patients with familial thrombocytopenia are affected with forms of unknown origin. Here, through exome sequencing of 2 siblings with autosomal-recessive thrombocytopenia, we identified biallelic loss-of-function variants in PTPRJ. This gene encodes for a receptor-like PTP, PTPRJ (or CD148), which is expressed abundantly in platelets and megakaryocytes. Consistent with the predicted effects of the variants, both probands have an almost complete loss of PTPRJ at the messenger RNA and protein levels. To investigate the pathogenic role of PTPRJ deficiency in hematopoiesis in vivo, we carried out CRISPR/Cas9-mediated ablation of ptprja (the ortholog of human PTPRJ) in zebrafish, which induced a significantly decreased number of CD41+ thrombocytes in vivo. Moreover, megakaryocytes of our patients showed impaired maturation and profound defects in SDF1-driven migration and formation of proplatelets in vitro. Silencing of PTPRJ in a human megakaryocytic cell line reproduced the functional defects observed in patients’ megakaryocytes. The disorder caused by PTPRJ mutations presented as a nonsyndromic thrombocytopenia characterized by spontaneous bleeding, small-sized platelets, and impaired platelet responses to the GPVI agonists collagen and convulxin. These platelet functional defects could be attributed to reduced activation of Src family kinases. Taken together, our data identify a new form of IT and highlight a hitherto unknown fundamental role for PTPRJ in platelet biogenesis.

Description: Isomorphic mutation of SBDS gene is the cause of Shwachman-Diamond syndrome (SDS). SDS is a rare genetic bone marrow failure and cancer predisposition syndrome. SDS cells have altered ribosome biogenesis and protein synthesis, two high-energy consuming cellular processes. The reported increment in reactive oxygen species production, endoplasmic reticulum stress response and reduced mitochondrial functionality suggest a defect in the energy production in SDS cells. In this study, we analyzed the energetic metabolism in SDS cells and find that the oxygen consumption is impaired when it is induced by pyruvate/malate or succinate. This induces poor ATP production and AMP accumulation with a consequent alteration in the ATP/AMP ratio. Also respiratory chain activity was impaired because of faulty function of the complex IV; this defect is not dependent from impaired protein synthesis despite ribosome biogenesis and transduction defects in SDS. In fact, COX5A and Cox2, two subunits of Complex IV encoded respectively by a nuclear and mitochondrial gene, were expressed at normal levels. Impaired function of complex IV could be due to an increment of cytoplasmic calcium concentration that inhibits complex IV activity. Energetic stress induces changes in cellular metabolism, stimulating or inhibiting a network of molecules involved in regulation of energetic balance, such as AMPK and mTOR. In SDS cells as consequence of energetic stress, AMPK is hyper activated and the glycolytic pathway stimulated. Surprisingly, we found that also the AKT/mTOR pathway is aberrantly hyper activated since both these proteins are hyper-phosphorylated. We can speculate that hyper activation of mTOR is a way through which SDS cells support the energy defect and protein synthesis. All these defects were recovered when the SDS cells were complemented with SDS gene. Finally, leucine is an essential amino acid that induces cell proliferation and protein synthesis, restored OXPHOS and ATP synthesis, reduced the cytoplasmic calcium concentration and the AMPK and AKT/mTOR activity, and improved in vitro erythropoiesis from SDS individuals pointing to leucine as potential tool helpful to sustain deranged energetic metabolism and erythropoiesis in SDS patients. In conclusion, we report for the first time that SDS cells suffer of energetic stress and severe respiratory defect that is related to faulty SBSD protein. These defects are compensated by an enhanced activation of AMPK, glycolysis and mTOR/Akt pathways, which appear to adequately support protein synthesis. A pivotal role in the maintenance of this altered metabolism could be played by altered calcium homeostasis. Noteworthy biochemical defects might be largely corrected by leucine which also favourably affects in vitro erythropoiesis thus pointing to biochemical defects as important determinant for impaired hematopoiesis od SDS. Disclosures Dufour: Pfizer: Consultancy.

Description: Key Points ACTN1 mutations were identified in 10 of 239 families with inherited thrombocytopenia of unknown origin. ACTN1-related thrombocytopenia is characterized by mild thrombocytopenia with platelet macrocytosis and low risk for bleeding.

Description: Immune thrombocytopenic purpura (ITP) is one of the most common hemorrhagic disorders in childhood, often caused by an acute self-limiting event. However, 30% of these children develop chronic ITP. Identification of the underlying causes in ITP is an important challenge. Inherited thrombocytopenia (IT) is a rare, underdiagnosed disease, included among the chronic platelet disorders. Next-Generation-Sequencing (NGS) could be an efficient way of discovering potential IT-associated mutations in children with chronic ITP. The purpose of this retrospective study was to investigate children with chronic ITP using a targeted NGS, in order to identify IT-associated mutations. Between June 2017 and April 2020, mutational screening by a targeted NGS was performed on 19 children, either with a familial history of IT [4 unrelated patients (pts)], or with chronic ITP (15 pts), after all other causes of thrombocytopenia were excluded. Nineteen relatives were also investigated. This study was carried out in collaboration with the Laboratory of Genetics, IRCCS Burlo Garofolo in Trieste, that developed a targeted NGS method for the simultaneous analysis of 28 IT genes. The cost of the NGS tests were supported by the public healthcare service. We retrospectively divided our cohort of 19 pts, into three subgroups: Group I included 4 unrelated pts with familial IT; Group II consisted of 6 pts with chronic ITP and a clinical history and/or laboratory features associated with familial IT; and, Group III included 9 pts with chronic ITP refractory to several treatments (Table 1). The median age at the initial diagnosis of thrombocytopenia was lower in Group I than in Groups II and III (19/12 years vs 1310/12 years and 9 years, respectively, p=0.33). The median time between the diagnosis of thrombocytopenia, and the time of the study, was shorter in Group I compared to Groups II and III (11.7 months vs 45.3 and 51.7 months, respectively, p=0.16). Median platelet count at the disease onset was lower in Group III than in Groups I and II (21 x 109/L vs 99 x 109/L and 38 x 109/L, respectively, p=0.28). The median MPV values were 12.5 fL, 9.85 fL and 8.8 fL in Groups II, III, and I respectively. Bleeding symptoms requiring treatment were present at diagnosis in 1/6 (16%) and in 5/9 (55%) children of Groups II and III, respectively. Genetic variants, usually detected in IT, were found in heterozygosity in all children in Groups I and II, and in 7/9 (78%) in Group III. Two out of 4, 2/6 and 2/9 children in Groups I, II, and III, respectively, presented ≥2 variants. Among the 4 children of Group I, ANKDR26 variant was found in 2 pts, together with GP1BA and NBEAL2 (pt#1) and TUBB1 (pt#2). ANKDR26 variant was also recorded as a single mutation in their relatives. Two different variants involving GP1BA (c.98T〉A and c.515CT mutation with mild macrothrombocytopenia had relatives with a previous diagnosis of monoallelic Bernard-Souliers syndrome. As shown in table 1, ABCG8, ACTN1, ETV6, GP1BA, MYH9, SLFN14, or WAS variants, found in combination in 2 pts (pt#5, pt#8), were also detected in the children in Group II, as well as, at least one of the relatives (for a total of 7 cases). ABCG5, ABCG8, ETV6, FLNA, GP1BA, NBEAL2, or SLFN14 were found as variants in patients of Group III. The peripheral blood smear evaluation confirmed the diagnosis of grey platelet syndrome with two NBEAL2 mutations in pt #16. SLFN14, as a single variant, was associated with macrothrombocytopenia in one pt (#10). Three pts (#5, #6, #17), with variants of ABCG8 had hypercholesterolemia. In the cohort of pts with chronic ITP, 4 (#12, #13, #14, #15) had relatives with thrombocytopenia, and 2 (#11, #13) had a familial history of hematological malignancies. Segregation analysis in families, and functional studies to evaluate the pathogenic role of the variants reported, are still in progress. The clinical significance of IT-associated mutations in chronic ITP is uncertain, and yet to be clarified. However, our experience has shown that an in-depth clinical history, and accurate peripheral blood smear examinations, are important to better characterize chronic ITP in children. A targeted NGS method for the simultaneous analysis of different IT genes, has demonstrated to be an effective approach to explore in-depth the IT-associated mutations in children with chronic ITP, refractory to treatment. Table 1. Disclosures Giona: Novartis: Research Funding; Takeda: Speakers Bureau; Sanofi Genzyme: Research Funding, Speakers Bureau.