Comparison of Multiple Clinical Testing Modalities for Assessment of NPM1-Mutant AML.

BACKGROUND: NPM1 mutation status can influence prognosis and management in AML. Accordingly, clinical testing (i.e., RT-PCR, NGS and IHC) for mutant NPM1 is increasing in order to detect residual disease in AML, alongside flow cytometry (FC). However, the relationship of the results from RT-PCR to traditional NGS, IHC and FC is not widely known among many practitioners. Herein, we aim to: i) describe the performance of RT-PCR compared to traditional NGS and IHC for the detection of mutant NPM1 in clinical practice, and also compare it to FC, and ii) provide our observations regarding the advantages and disadvantages of each approach in order to inform future clinical testing algorithms. METHODS: Peripheral blood and bone marrow samples collected for clinical testing at variable time points during patient management were tested by quantitative, real-time, RT-PCR and results were compared to findings from a Myeloid NGS panel, mutant NPM1 IHC and FC. RESULTS: RT-PCR showed superior sensitivity compared to NGS, IHC and FC with the main challenge of NGS, IHC and FC being the ability to identify a low disease burden (<0.5% NCN by RT-PCR). Nevertheless, the positive predictive value of NGS, IHC and FC were each ≥ 80% indicating that positive results by those assays are typically associated with RT-PCR positivity. IHC, unlike bulk methods (RT-PCR, NGS and FC), is able provide information regarding cellular/architectural context of disease in biopsies. FC did not identify any NPM1-mutated residual disease not already detected by RT-PCR, NGS or IHC. CONCLUSION: Overall, our findings demonstrate that RT-PCR shows superior sensitivity compared to a traditional Myeloid NGS, suggesting the need for "deep-sequencing" NGS panels for NGS-based monitoring of residual disease in NPM1-mutant AML. IHC provides complementary cytomorphologic information to RT-PCR. Lastly, FC may not be necessary in the setting of post-therapy follow up for NPM1-mutated AML. Together, these findings can help inform future clinical testing algorithms.

Clinical Laboratory Validation and Implementation of Quantitative, Real-Time PCR-based Detection of NPM1 Type A Mutation.

BACKGROUND: NPM1 mutations have prognostic significance in acute myeloid leukemia (AML) and monitoring mutant NPM1 levels during and after therapy has been described to predict relapse and survival. Despite the published significance of this molecular biomarker, routine monitoring for mutant NPM1 levels has not been widely adopted in academic clinical laboratories. Therefore, our objective was to validate a quantitative, reverse transcription-PCR assay for the detection of NPM1 Type A mutant transcripts for use in the clinical laboratory. METHODS: A quantitative, real-time, reverse-transcription PCR-based method for the detection of NPM1 Type A mutant transcripts was validated for use in routine clinical practice. Results from this assay were compared to results from orthogonal methods, including next generation sequencing and digital droplet PCR. RESULTS: This real-time, reverse-transcription PCR-based method is sensitive (limit of detection: 0.0150% NCN and reproducible (≤ 0.5 log10-fold variation). We summarize the rigorous validation results and share observations that will help other clinical laboratories that may wish to implement this testing. We show the superior sensitivity of this assay compared to other assays (e.g., 45 gene Myeloid Next Generation Sequencing panel) and present a representative case which highlights the assay's utility in the pathologic assessment of cases with borderline morphologic or flow cytometric findings. CONCLUSIONS: As molecular testing for residual disease in AML continues to expand, this sensitive and reproducible method will be an appropriate testing option for the detection of NPM1 Type A mutant transcripts in clinical practice.

Bone marrow morphology predicts additional chromosomal abnormalities in patients with myelodysplastic syndrome with del(5q).

The current World Health Organization classification considers myelodysplastic syndrome with isolated del(5q) a distinct entity owing to its characteristic clinical and pathologic features. Recently, several studies have examined survival, leukemic transformation, and various prognostic factors in these patients. However, there is a lack of detailed comparative pathologic analysis of myelodysplastic syndrome cases in which del(5q) is present in association with additional cytogenetic abnormalities. We studied 26 cases of myelodysplastic syndrome at initial diagnosis with 5q- alone, 5q- plus 1 additional abnormality, and 5q- as part of a complex karyotype. Four of 17 patients had evidence of JAK2 V617F mutation. In contrast to cases of myelodysplastic syndrome with isolated 5q-, patients with additional abnormalities had normal mean corpuscular volume and decreased platelet counts (P < .001). Based on bone marrow examination, they were significantly more likely to have increased cellularity, trilineage dysplasia, lower proportion of small hypolobated megakaryocytes, higher number of blasts, and fibrosis. The presence of these morphologic features can be used to distinguish these more aggressive cases from those with myelodysplastic syndrome with isolated 5q- and a more benign clinical course.

Selective cortical interneuron and GABA deficits in cyclin D2-null mice.

In contrast to cyclin D1 nulls (cD1-/-), mice without cyclin D2 (cD2-/-) lack cerebellar stellate interneurons; the reason for this is unknown. In the present study in cortex, we found a disproportionate loss of parvalbumin (PV) interneurons in cD2-/- mice. This selective reduction in PV subtypes was associated with reduced frequency of GABA-mediated inhibitory postsynaptic currents in pyramidal neurons, as measured by voltage-clamp recordings, and increased cortical sharp activity in the EEGs of awake-behaving cD2-/- mice. Cell cycle regulation was examined in the medial ganglionic eminence (MGE), the major source of PV interneurons in mouse brain, and differences between cD2-/- and cD1-/- suggested that cD2 promotes subventricular zone (SVZ) divisions, exerting a stronger inhibitory influence on the p27 Cdk-inhibitor (Cdkn1b) to delay cell cycle exit of progenitors. We propose that cD2 promotes transit-amplifying divisions in the SVZ and that these ensure proper output of at least a subset of PV interneurons.