Clonal hematopoiesis of indeterminate potential is rare in pediatric patients undergoing autologous stem cell transplantation.

Clonal hematopoiesis of indeterminate potential (CHIP) describes recurrent somatic gene mutations in the blood of healthy individuals, associated with higher risk for hematological malignancies and higher all-cause mortality by cardiovascular disease. CHIP increases with age and is more common in adult patients after chemotherapy or radiation for cancer. Furthermore, in some adult patients undergoing autologous stem cell transplantation (ASCT) or thereafter, CHIP has been identified. In children and adolescents, it remains unclear how cellular stressors such as cytotoxic therapy influence the incidence and expansion of CHIP. We conducted a retrospective study on 33 pediatric patients mostly with solid tumors undergoing ASCT for presence of CHIP. We analyzed CD34+ selected peripheral blood stem cell grafts after several cycles of chemotherapy, prior to cell infusion, by next-generation sequencing including 18 "CHIP-genes". Apart from a somatic variant in TP53 in one patient no other variants indicative of CHIP were identified. As a CHIP-unrelated finding, germline variants in CHEK2 and in ATM were identified in two and four patients, respectively. In conclusion, we could not detect "typical" CHIP variants in our cohort of pediatric cancer patients undergoing ASCT. However, more studies with larger patient numbers are necessary to assess if chemotherapy in the pediatric setting contributes to an increased CHIP incidence and at what time point.

JAK2 Unmutated Polycythaemia-Real-World Data of 10 Years from a Tertiary Reference Hospital.

(1) Background: Polycythaemia is defined by an increase in haemoglobin (Hb) concentration, haematocrit (Hct) or red blood cell (RBC) count above the reference range adjusted to age, sex and living altitude. JAK2 unmutated polycythaemia is frequent but under-investigated in original publications. In this retrospective cohort study, we investigated the clinical and laboratory data, underlying causes, management and outcomes of JAK2 unmutated polycythaemia patients. (2) Methods: The hospital database was searched to identify JAK2 unmutated patients fulfilling WHO 2016 Hb/Hct criteria for PV (Hb >16.5 g/dL in men and >16 g/dL in women, or Hct > 49% in men and >48% in women, or RBC mass > 25% above mean normal predicted value) between 2008 and 2019. Clinical and laboratory data were collected and analysed. (3) Results: From 727,731 screened patients, 294 (0.04%) were included, the median follow-up time was 47 months. Epo and P50 showed no clear pattern in differentiating causes of polycythaemia. In 30%, the cause remained idiopathic, despite extensive work-up. Sleep apnoea was the primary cause, also in patients under 30. Around 20% had received treatment at any time, half of whom had ongoing treatment at the end of follow-up. During follow-up, 17.2% developed a thromboembolic event, of which 8.5% were venous and 8.8% arterial. The mortality was around 3%. (4) Conclusions: Testing for Epo and P50 did not significantly facilitate identification of underlying causes. The frequency of sleep apnoea stresses the need to investigate this condition. Idiopathic forms are common. A diagnostic flowchart based on our data is proposed here. NGS testing should be considered in young patients with persisting polycythaemia, irrespective of Epo and P50 levels.

NGS Evaluation of a Bernese Cohort of Unexplained Erythrocytosis Patients.

(1) Background: Clinical and molecular data on patients with unexplained erythrocyto-sis is sparse. We aimed to analyze the clinical and molecular features of patients with congenital erythrocytosis in our tertiary reference center. (2) Methods: In 34 patients with unexplained erythrocytosis, a 13-gene Next-Generation Sequencing erythrocytosis panel developed at our center was conducted. (3) Results: In 6/34 (18%) patients, eight different heterozygous gene variants were found. These patients were, therefore, diagnosed with congenital erythrocytosis. Two patients had two different gene variants each. All variants were characterized as variants of unknown significance as they had not previously been described in the literature. The rest of the patients (28/34, 82%) had no detected gene variants. (4) Conclusions: Our experience shows that the NGS panel can be helpful in determining the reasons for persistent, unexplained erythrocytosis. In our cohort of patients with erythrocytosis, we identified some, thus far unknown, gene variants which may explain the clinical picture. However, further investigations are needed to determine the relationship between the molecular findings and the phenotype.

Analysis of IL-6 serum levels and CAR T cell-specific digital PCR in the context of cytokine release syndrome.

INTRODUCTION: Chimeric antigen receptor T-cell (CAR-T) therapies are increasingly used to treat relapsed B-cell lymphomas and acute lymphoblastic leukemia. Considering the frequency of cytokine release syndrome and CAR-T-related encephalopathy syndrome (CRS/CRES) after CAR-T administration, strategies enabling timely prediction of impending CRS/CRES are a clinical need. METHODS: We evaluated the dynamics of serum interleukin (IL)-6 levels and CAR-T transgene copy numbers by digital droplet polymerase chain reaction in the peripheral blood of 11 consecutive patients with aggressive B-cell malignancies. RESULTS: Four of 11 patients developed CRS, and 3 patients had CRES (33%), 2 of them had previous CRS. IL-6 levels increased on the day of clinical manifestation of CRS. All CRS patients had increased IL-6 peak levels (median IL-6 peak 606 pg/mL in CRS patients vs. 22 pg/mL in non-CRS patients, p = 0.0061). Different patterns emerged from the dynamics of CAR-T/µg genomic DNA: "rapid increase and rapid decrease with complete disappearance," "rapid increase and slow decrease with higher persistence," "rapid increase and rapid decrease with lower persistence," and "slow increase and rapid decrease with almost disappearance." Patients with the pattern "rapid increase and slow decrease with higher persistence" of CAR-T/µg genomic DNA concentration seemed to be at higher risk of developing CRS/CRES. CONCLUSION: Thus, the dynamics of CAR-T transgene copy numbers merits further evaluation for a possible association with manifestation of CRS. Increased IL-6 serum levels at CRS manifestation may contribute to the interpretation of symptoms.

Current concepts and future directions for hemato-oncologic diagnostics.

At present, hemato-oncologic diagnostics is facing dynamic changes. This applies to the exploration and introduction of novel technologies such as next-generation sequencing or digital droplet PCR for myeloid and lymphatic malignancies in laboratory routine, or liquid biopsy for patients with lymphoid malignancies. Targeted therapies such as FLT3 or IDH1/IDH2 inhibitors for acute myeloid leukemia are entering clinical practice. Thus, the demand for hematologic precision diagnostics both at initial diagnosis and during the course of the disease are equally increasing, and a short turn-around time becomes crucial. NGS expands the armamentarium for minimal residual disease diagnostics, but novel questions arise relating to sensitivity, the appropriate time points of this analysis, or the thresholds triggering therapeutic interventions. In this review article, we summarize some of the most relevant current changes and subsequent challenges for diagnostics in various myeloid and lymphatic malignancies. Future directions of hemato-oncologic diagnostics in the next 5-10 years are highlighted.

Clinical potential of introducing next-generation sequencing in patients at relapse of acute myeloid leukemia.

Relapse of acute myeloid leukemia (AML) remains a major determinant of outcome. A number of molecularly directed treatment options have recently emerged making comprehensive diagnostics an important pillar of clinical decision making at relapse. Acknowledging the high degree of individual genetic variability at AML relapse, next-generation sequencing (NGS) has opened the opportunity for assessing the unique clonal hierarchy of individual AML patients. Knowledge on the genetic makeup of AML is reflected in patient customized treatment strategies thereby providing improved outcomes. For example, the emergence of druggable mutations at relapse enable the use of novel targeted therapies, including FLT3 inhibitors or the recently approved IDH1/2 inhibitors ivosidenib and enasidenib, respectively. Consequently, some patients may undergo novel bridging approaches for reinduction before allogeneic stem cell transplantation, or the identification of an adverse prognostic marker may initiate early donor search. In this review, we summarize the current knowledge of NGS in identifying clonal stability, clonal evolution, and clonal devolution in the context of AML relapse. In light of recent improvements in AML treatment options, NGS-based molecular diagnostics emerges as the basis for molecularly directed treatment decisions in patients at relapse.

Detection of rare reciprocal RUNX1 rearrangements by next-generation sequencing in acute myeloid leukemia.

Reciprocal RUNX1 fusions are traditionally found in up to 10% of acute myeloid leukemia (AML) patients, usually associated with a translocation (8;21)(q22;q22) corresponding to the RUNX1-RUNX1T1 fusion gene. So far, alternative RUNX1 rearrangements have been reported only rarely in AML, and the few reports so far have focused on results based on cytogenetics, fluorescence in situ hybridization, and polymerase chain reaction. Acknowledging the inherent limitations of these diagnostic techniques, the true incidence of rare RUNX1 rearrangements may be underestimated. In this report, we present two cases of adult AML, in which we detected rare RUNX1 rearrangements not by conventional cytogenetics but rather by next-generation panel sequencing. These include t(16;21)(q24;q22)/RUNX1-CBFA2T3 and t(7;21)(p22;q22)/RUNX1-USP42, respectively. In both patients the AML was therapy-related and associated with additional structural and numerical alterations thereby conferring bad prognosis. This is in line with previous reports on rare RUNX1 fusions in AML and emphasizes the clinical importance of their detection. In summary, our report not only confirms the clinical utility of NGS for diagnostics of rare reciprocal rearrangements in AML in a real-life scenario but also sheds light on the variety and complexity within AML. It further emphasizes the need for collection of additional cases for deepening insights on their clinical meaning as well as their frequency.

Challenges in the introduction of next-generation sequencing (NGS) for diagnostics of myeloid malignancies into clinical routine use.

Given the vast phenotypic and genetic heterogeneity of acute and chronic myeloid malignancies, hematologists have eagerly awaited the introduction of next-generation sequencing (NGS) into the routine diagnostic armamentarium to enable a more differentiated disease classification, risk stratification, and improved therapeutic decisions. At present, an increasing number of hematologic laboratories are in the process of integrating NGS procedures into the diagnostic algorithms of patients with acute myeloid leukemia (AML), myelodysplastic syndromes (MDS), and myeloproliferative neoplasms (MPNs). Inevitably accompanying such developments, physicians and molecular biologists are facing unexpected challenges regarding the interpretation and implementation of molecular genetic results derived from NGS in myeloid malignancies. This article summarizes typical challenges that may arise in the context of NGS-based analyses at diagnosis and during follow-up of myeloid malignancies.

Genetic alterations crossing the borders of distinct hematopoetic lineages and solid tumors: Diagnostic challenges in the era of high-throughput sequencing in hemato-oncology.

Owing to the introduction of next-generation sequencing (NGS) new challenges for diagnostic algorithms and the interpretation of the results for therapeutic decision making in hemato-oncology have arisen. Recurrent somatic mutations crossing the borders between different hematological entities and solid neoplasms have been detected. In analogy to mutant TP53, the same mutation type may occur in myeloid, B- or T-lymphatic malignancies or solid neoplasms. At the same time, a certain mutation can show different prognostic outcomes in different entities and co-existence of certain mutations may change the prognostic relevance. These insights may spark the investigation of targeted therapies with the same substances across different disease entities. This review article summarizes mutations that can emerge in different hematologic and solid malignancies and summarizes other obstacles in the era of modern molecular diagnostics, such as the phenomenon of "clonal hematopoiesis of indeterminate potential" being difficult to interpret in the individual patient.

Eukaryotic initiation factor 4G suppresses nonsense-mediated mRNA decay by two genetically separable mechanisms.

Nonsense-mediated mRNA decay (NMD), which is best known for degrading mRNAs with premature termination codons (PTCs), is thought to be triggered by aberrant translation termination at stop codons located in an environment of the mRNP that is devoid of signals necessary for proper termination. In mammals, the cytoplasmic poly(A)-binding protein 1 (PABPC1) has been reported to promote correct termination and therewith antagonize NMD by interacting with the eukaryotic release factors 1 (eRF1) and 3 (eRF3). Using tethering assays in which proteins of interest are recruited as MS2 fusions to a NMD reporter transcript, we show that the three N-terminal RNA recognition motifs (RRMs) of PABPC1 are sufficient to antagonize NMD, while the eRF3-interacting C-terminal domain is dispensable. The RRM1-3 portion of PABPC1 interacts with eukaryotic initiation factor 4G (eIF4G) and tethering of eIF4G to the NMD reporter also suppresses NMD. We identified the interactions of the eIF4G N-terminus with PABPC1 and the eIF4G core domain with eIF3 as two genetically separable features that independently enable tethered eIF4G to inhibit NMD. Collectively, our results reveal a function of PABPC1, eIF4G and eIF3 in translation termination and NMD suppression, and they provide additional evidence for a tight coupling between translation termination and initiation.

Analysis of nonsense-mediated mRNA decay in mammalian cells.

The nonsense-mediated mRNA decay (NMD) pathway acts to selectively identify and degrade mRNAs that contain a premature translation termination codon (PTC), and hence reduce the accumulation of potentially toxic truncated proteins. NMD is one of the best studied mRNA quality-control mechanisms in eukaryotes, and it has become clear during recent years that many physiological mRNAs are also NMD substrates, signifying a role for NMD beyond mRNA quality control as a translation-dependent post-transcriptional regulator of gene expression. Despite a great deal of scientific research for over twenty years, the process of NMD is far from being fully understood with regard to its physiological relevance to the cell, the molecular mechanisms that underpin this pathway, all of the factors that are involved, and the exact cellular locations of NMD. This unit details some of the fundamental RNA based approaches taken to examine aspects of NMD, such as creating PTC+ reporter genes, knocking down key NMD factors via RNAi, elucidating the important functions of NMD factors by complementation assays or Tethered Function Assays, and measuring RNA levels by reverse-transcription quantitative PCR.