Validation and clinical application of transactivation assays for RUNX1 variant classification

Familial platelet disorder with associated myeloid malignancies (RUNX1-FPD) is caused by heterozygous pathogenic germline variants of RUNX1. In the present study, we evaluate the applicability of transactivation assays to investigate RUNX1 variants in different regions of the protein. We studied 11 variants to independently validate transactivation assays supporting variant classification following the ClinGen Myeloid Malignancies variant curation expert panel guidelines. Variant classification is key for the translation of genetic findings. We showed that new assays need to be developed to assess C-terminal RUNX1 variants. Two variants of uncertain significance (VUS) were reclassified to likely pathogenic. Additionally, our analyses supported the (likely) pathogenic classification of two other variants. We demonstrated functionality of four VUS, but reclassification to (likely) benign was challenging and suggested the need to reevaluate current classification guidelines. Finally, clinical utility of our assays was illustrated in the context of seven families. Our data confirmed RUNX1-FPD suspicion in three families with RUNX1-FPD-specific family history. Whereas for three variants identified in non RUNX1-FPD-typical families, no functional defect was detected. Applying functional assays to support RUNX1 variant classification can be essential for adequate care of index patients and their relatives at risk. It facilitates translation of genetic data into personalized medicine.

Genomic Landscape of RUNX1-Familial Platelet Disorder with Myeloid Malignancies Reveals Rising Clonal Hematopoiesis

Familial platelet disorder with associated myeloid malignancies (FPDMM) is a rare autosomal dominant disease caused by germline RUNX1 mutations. FPDMM patients have defective megakaryocytic development, low platelet counts, prolonged bleeding times, and a life-long risk (20-50%) of developing hematological malignancies. FPDMM is a rare genetic disease in need of comprehensive clinical and genomic studies. In early 2019 we launched a longitudinal natural history study of patients with FPDMM at the NIH Clinical Center and by May 2021 we have enrolled 98 patients and 100 family controls from 55 unrelated families. Genomic data have been generated from 56 patients in 24 families, including whole exome sequencing (WES), RNA-seq, and single-nucleotide polymorphism (SNP) array. We have identified 21 different germline RUNX1 variants among these 24 families, which include lost-of-function mutations throughout the RUNX1 gene, but pathogenic/likely pathogenic missense mutations are mostly clustered in the runt-homology domain (RHD). As an important form of RUNX1 germline mutations, five splice site variants located between exon 4-5 and exon 5-6 were identified in 6 families, which led to the productions of novel transcript forms that are predicted to generate truncated RUNX1 proteins. Large deletions affecting the RUNX1 gene are also common, ranging from 50 Kb to 1.5Mb, which were detected in 8 of the 55 enrolled families. Besides RUNX1, copy number variation (CNV) analysis from both SNP array and WES showed limited CNV events in non-malignant FPDMM patients. In addition, fusion gene analysis did not detect any in-frame fusion gene in these patients, indicating a relatively stable chromosome status in FPDMM patients. Somatic mutation landscape shows that the overall mutation burden in non-malignant FPDMM patients is lower than AML or other cancer types. However, in 13 of the 44 non-malignant patients (30%), somatic mutations were detected in at least one of the reported clonal hematopoiesis of indeterminate potential (CHIP) genes, significantly higher than the general population (4.3%). Moreover, 85% of our patients who carried CHIP mutations are under 65 years of age; in the general population, only 10% of people above 65 years of age and 1% of people under 50 were reported to carry CHIP mutations. Among mutated genes related to clonal hematopoiesis, BCOR is the most frequently mutated gene (5/44) in our FPDMM cohort, which is not a common CHIP gene among the general population. Mutations in known CHIP genes including SF3B1, TET2, and DNMT3A were also found in more than one patient. In addition, sequencing of 5 patients who already developed myeloid malignancies detected somatic mutations in BCOR, TET2, NRAS, KRAS, CTCF, KMT2D, PHF6, and SUZ12. Besides reported CHIP genes or leukemia driver genes, 3 unrelated patients carried somatic mutations in the NFE2 gene, which is essential for regulating erythroid and megakaryocytic maturation and differentiation. Two of the NFE2 mutations are nonsense mutations, and the other is a missense mutation in the important functional domain. NFE2 somatic mutations may play important roles in developing malignancy because 2 of the 3 patients already developed myeloid malignancies. For multiple patients in our cohort, we have sequenced their DNA on multiple timepoints. We have observed patients with expanding clones carrying FKBP8, BCOR or FOXP1 mutations. We have also observed a patient with relatively stable clone(s) with somatic BCOR, DNMT3A, and RUNX1T1, who have been sampled over more than four years. We will follow these somatic mutations through sequencing longitudinally and correlate the findings with clinical observations to see if the dynamic changes of CHIP clones harboring the mutations give rise to MDS or leukemia. In summary, the genomic analysis of our new natural history study demonstrated diverse types of germline RUNX1 mutations and high frequency of somatic mutations related to clonal hematopoiesis in FPDMM patients. These findings indicate that monitoring the dynamic changes of these CHIP mutations prospectively will benefit patients' clinical management and help us understand possible mechanisms for the progression from FPDMM to myeloid malignancies. Disclosures No relevant conflicts of interest to declare.

B-cell acute lymphoblastic leukemia in patients with germline RUNX1 mutations

Germline RUNX1 mutations underlie a syndrome, RUNX1-familial platelet disorder (RUNX1-FPD), characterized by bleeding symptoms that result from quantitative and/or qualitative defect in platelets and a significantly increased risk for developing hematologic malignancies. Myeloid neoplasms are the most commonly diagnosed hematologic malignancies, followed by lymphoid malignancies of T-cell origin. Here, we describe the first 2 cases of B-cell acute lymphoblastic leukemia (B-ALL) in patients with confirmed germline RUNX1 mutations. While 1 of the patients had a known diagnosis of RUNX1-FPD with a RUNX1 p.P240Hfs mutation, the other was the index patient of a kindred with a novel RUNX1 variant, RUNX1 c.587C>T (p.T196I), noted on a targeted genetic testing of the B-ALL diagnostic sample. We discuss the clinical course, treatment approaches, and the outcome for the 2 patients. Additionally, we describe transient resolution of the mild thrombocytopenia and bleeding symptoms during therapy, as well as the finding of clonal hematopoiesis with a TET2 mutant clone in 1 of the patients. It is critical to consider testing for germline RUNX1 mutations in patients presenting with B-ALL who have a personal or family history of thrombocytopenia, bleeding symptoms, or RUNX1 variants identified on genetic testing at diagnosis.

The RUNX1 Database (RUNX1db): establishment of an expert curated RUNX1 registry and genomics database as a public resource for familial platelet disorder with myeloid malignancy

Not available.

RUNX1 haploinsufficiency causes a marked deficiency of megakaryocyte-biased hematopoietic progenitor cells

Patients with familial platelet disorder with a predisposition to myeloid malignancy (FPDMM) harbor germline monoallelic mutations in a key hematopoietic transcription factor RUNX1. Previous studies of FPDMM have focused on megakaryocyte (Mk) differentiation, and platelet production and signaling. However, the effects of RUNX1 haploinsufficiency on hematopoietic progenitor cells (HPCs) and subsequent megakaryopoiesis remains incomplete. To address this issue, we studied induced-pluripotent stem cell (iPSC)-derived HPCs (iHPCs) and Mks (iMks) from both patient-derived lines and a wildtype line modified to be RUNX1 haploinsufficient (RUNX1+/-), each compared to their isogenic wildtype control. All RUNX1+/- lines showed decreased iMk yield and depletion of a Mk-biased iHPC subpopulation. To investigate global and local gene expression changes underlying this iHPC shift, single-cell RNA sequencing was performed on sorted FPDMM and control iHPCs. We defined several cell subpopulations in the Mk-biased iHPCs. Analyses of gene sets upregulated in FPDMM iHPCs indicated enrichment for response to stress, regulation of signal transduction and immune signaling-related gene sets. Immunoblotting studies in FPDMM iMks were consistent with these findings, but also identified augmented baseline c-Jun N-terminal kinase (JNK) phosphorylation, known to be activated by transforming growth factor (TGF) β1 and cellular stressors. These findings were confirmed in adult human CD34+-derived stem and progenitor cells (HSPCs) transduced with lentiviral RUNX1 short-hairpin (sh) RNA to mimic RUNX1+/-. In both iHPCs and CD34+-derived HSPCs, targeted inhibitors of JNK and TGFβ1 pathways corrected the megakaryopoietic defect. We propose that such intervention may correct the thrombocytopenia seen in affected FPDMM patients.

Restoring RUNX1 deficiency in RUNX1 familial platelet disorder by inhibiting its degradation

RUNX1 familial platelet disorder (RUNX1-FPD) is an autosomal dominant disorder caused by a monoallelic mutation of RUNX1, initially resulting in approximately half-normal RUNX1 activity. Clinical features include thrombocytopenia, platelet functional defects, and a predisposition to leukemia. RUNX1 is rapidly degraded through the ubiquitin-proteasome pathway. Moreover, it may autoregulate its expression. A predicted kinetic property of autoregulatory circuits is that transient perturbations of steady-state levels result in continued maintenance of expression at adjusted levels, even after inhibitors of degradation or inducers of transcription are withdrawn, suggesting that transient inhibition of RUNX1 degradation may have prolonged effects. We hypothesized that pharmacological inhibition of RUNX1 protein degradation could normalize RUNX1 protein levels, restore the number of platelets and their function, and potentially delay or prevent malignant transformation. In this study, we evaluated cell lines, induced pluripotent stem cells derived from patients with RUNX1-FPD, RUNX1-FPD primary bone marrow cells, and acute myeloid leukemia blood cells from patients with RUNX1 mutations. The results showed that, in some circumstances, transient expression of exogenous RUNX1 or inhibition of steps leading to RUNX1 ubiquitylation and proteasomal degradation restored RUNX1 levels, thereby advancing megakaryocytic differentiation in vitro. Thus, drugs retarding RUNX1 proteolytic degradation may represent a therapeutic avenue for treating bleeding complications and preventing leukemia in RUNX1-FPD.