The clinicopathologic significance of NPM1 mutation and ability to detect mutated NPM1 by immunohistochemistry in non-AML myeloid neoplasms.

NPM1 mutated non-AML myeloid neoplasms (MN; <20% blasts) are characterized by an aggressive clinical course in a few studies. In this retrospective study, we evaluate the clinicopathologic and immunohistochemical features of non-AML MN patients with NPM1 mutations. We assessed NPM1 mutation by targeted next generation sequencing (NGS). Cytoplasmic NPM1 expression was assessed by immunohistochemistry (IHC) on formalin-fixed, formic acid-decalcified bone marrow biopsy specimens. We evaluated 34 non-AML MN patients with NPM1 mutations comprising MDS (22), MPN (3) and MDS/MPN (9). They commonly presented with anemia (88%), thrombocytopenia (58%) and leukopenia (50%). Bone marrow dysplasia was common (79%). The karyotype was often normal (64%). NGS for MN-associated mutations performed in a subset of the patients showed a median of 3 mutations. NPM1 mutations were more often missense (c.859C > T p. L287F; 65%) than frameshift insertion/duplication (35%) with median variant allele frequency (VAF; 9.7%, range 5.1%-49.8%). Mutated NPM1 by IHC showed cytoplasmic positivity in 48% and positivity was associated with higher VAF. The median overall survival (OS) in this cohort was 70 months. Nine patients (26%) progressed to AML. OS in patients who progressed to AML was significantly shorter than the one of patients without progression to AML (OS 20 vs. 128 months, respectively, log rank p = 0.05). NPM1 mutated non-AML MN patients commonly had cytopenias, dysplasia, normal karyotype, mutations in multiple genes, and an unfavorable clinical outcome, including progression to AML. Our data demonstrated that IHC for NPM1 can be a useful supplementary tool to predict NPM1 mutation in some non-AML MN; however, genetic testing cannot be replaced by IHC assessment.

Immune Escape Mechanisms in Intravascular Large B-Cell Lymphoma: A Molecular Cytogenetic and Immunohistochemical Study.

OBJECTIVES: Intravascular large B-cell lymphomas (IVLBCLs) are rare extranodal LBCLs in which relapse is relatively frequent. We sought to further characterize potential immune escape mechanisms in IVLBCLs that newer therapies can exploit. METHODS: A series of 33 IVLBCLs were evaluated for programmed cell death ligand 1 (PD-L1) and PD-L2 expression by immunohistochemistry (IHC), chromosomal alterations (CAs) in the PDL1/PDL2 locus by fluorescence in situ hybridization, and loss of major histocompatibility complex (MHC) class I and II expression by IHC. RESULTS: Cases were subclassified as classical (n = 22) or hemophagocytic syndrome (HPS)-associated (n = 11) variants. A total of 12 cases (39%; n = 12/31) expressed PD-L1 and/or PD-L2. CAs were seen in 7 cases (7/29 [24%]) and included gains, amplifications, and rearrangements. CAs in classical variant cases (24%; n = 5/21) included gains (n =1), gains with concurrent rearrangements (n = 2), and amplifications (n = 2). The 2 HPS-associated variant cases with CAs (25%; n = 2/8) both showed amplification, including 1 case with a concurrent rearrangement. A majority of cases with CAs (71%; n = 5/7) were PD-L1/PD-L2 IHC positive. Among PD-L1/PD-L2 IHC-positive cases, 45% harbored a CA. Loss of MHC class I and/or class II was seen in 27% (n = 9/33) of cases. CONCLUSIONS: Altogether, our data show that 65% (n = 20/31) of IVLBCLs may exploit immune evasion strategies through PD-L1/PD-L2 expression or downregulation of MHC proteins.

Decreased BIM expression in BCL2-negative follicular lymphoma: a potential mechanism for resistance to apoptosis.

Follicular lymphoma (FL) is characterized by t(14; 18)(q32; q21), leading to overexpression of the antiapoptotic molecule BCL2; however, a subset of FLs lack BCL2 rearrangement and BCL2 expression as analyzed by immunohistochemistry (IHC). In this study, we evaluated expression of antiapoptotic (MCL1 and BCL-XL) and proapoptotic proteins (BIM) by IHC in both BCL2(-) and BCL2(+) FLs. FLs diagnosed between 2009 and 2019 were reviewed to identify BCL2(-) cases by IHC (assessed by clone 124). Immunohistochemical analyses for BCL2 (EP36), MCL1, BIM, BCL-XL, and Ki-67 were performed on tissue microarrays or whole slides. BCL2 (EP36) was interpreted as positive (≥10%) or negative (<10%). Ki-67 was interpreted on tumor cells in 10% increments. The remaining immunohistochemical analysis results were scored on tumor cells in 10% increments, and intensity was interpreted as weak, moderate, or strong to derive an H-score. Twenty-four BCL2(-) FLs were initially identified, but on further testing with BCL2(EP36) immunohistochemical staining, 5 of 24 were reclassified as BCL2(+), leaving 19 BCL2(-) FLs. Thirty-three BCL2(+) FLs were selected with sufficient tissue for additional immunohistochemical analyses. There was no significant difference in expression of antiapoptotic BCL-XL or MCL1 between BCL2(-) and BCL2(+) FLs (p = 0.75 and 0.28, respectively). However, proapoptotic BIM expression was significantly lower in BCL2(-) FLs than in BCL2(+) FLs (p = 0.002). In our study, 21% of putative BCL2(-) FLs were BCL2(+) when tested with alternative clones, supporting the practice of having more than one BCL2 clone in immunohistochemical laboratories. Decreased BIM expression in BCL2(-) FLs could have an overall antiapoptotic effect and represent an alternate mechanism for cell survival in BCL2(-) FLs.

Severe megaloblastic anemia: Vitamin deficiency and other causes.

Megaloblastic anemia causes macrocytic anemia from ineffective red blood cell production and intramedullary hemolysis. The most common causes are folate (vitamin B9) deficiency and cobalamin (vitamin B12) deficiency. Megaloblastic anemia can be diagnosed based on characteristic morphologic and laboratory findings. However, other benign and neoplastic diseases need to be considered, particularly in severe cases. Therapy involves treating the underlying cause-eg, with vitamin supplementation in cases of deficiency, or with discontinuation of a suspected medication.