Aberrant expression of CD54 detected by flow cytometry is a characteristic of B-lymphoma cells in bone marrow specimens

Background Flow cytometry (FC) is a popular method to detect bone marrow (BM) involvement in patients with B-cell non-Hodgkin lymphoma (B-NHL). The majority of screen panels of FC still rely on finding monoclonal B-cells, e.g., B-cells with immunoglobin (Ig) light-chain restriction, which has many limitations. Therefore, exploring new markers is warranted. Methods A total of 52 cases of B-NHL with BM involvement were collected. The median age was 60 years. Out of these 52 cases, 34 were male, and 18 were female. A 10-color FC panel was used to detect the expression of CD54 on lymphoma cells. The expression of CD54 was calculated as the mean fluorescence index ratio (MFIR) and was described as the mean ± standard error of the mean (SEM). Results Up to 18/52 (34.62%) of BM specimens abnormally expressed an increased level of CD54, including 1/10 cases of chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL), 9/13 cases of mantle cell lymphoma (MCL), 2/14 cases of follicular lymphoma (FL), 5/9 cases of marginal zone lymphoma (MZL), and 1/3 cases of high-grade B-NHL (HG B-NHL). The expression level of CD54 was significantly increased in MCL cases (53.41 ± 11.04) compared with CLL/SLL cases (11.66 ± 2.79) and FL cases (13.49 ± 2.81). The lowest percentage of CD54-positive B-cells attained 0.13%. In 5/9 cases of MZL and 1/3 cases of HG B-NHL, increased expression of CD54 was the only abnormal immunophenotype detected besides Ig light-chain restriction. No aberrant CD54 expression was identified by FC in lymphoplasmacytic lymphoma (LPL) (0/2) and Burkitt lymphoma (BL) (0/1) cases. Aberrant expression of CD54 was not related to plasma cell differentiation. Conclusion Lymphoma cells, especially in MCL and MZL cases, frequently show increased expression of CD54. Such aberrant expression is not related to plasma cell differentiation. We highly recommend adding CD54 to the FC screening panel to detect BM involvement in patients with B-NHL.

MO057REGIONAL IMPORTANCE OF FIBRINOGEN A Α-CHAIN MUTATION ON RENAL AMYLOIDOSIS

Background and Aims Renal amyloidosis include amyloid A (AA) and light chain (AL) as well as amyloidogenic leukocyte chemotactic factor 2 (ALECT2) and numerous hereditary forms. After identifying amyloidosis by its suggestive pale pink amorphous appearance in optic microscopy (OM) and Congo red positivity, a correct diagnosis of the amyloidogenic precursor protein is determinant to establish prognosis and treatment. Immunohistochemistry (IHC) and immunofluorescence (IF) studies use a limited number of antibodies to detect specific epitopes and may be difficult to interpret. The gold standard has become proteomics but laser microdissection and mass spectroscopy are not routinely available. Other options include electron microscopy with immunogold staining and complementary exams such as scintigraphy with 99mTc-DPD to detect transthyretin-related amyloidosis. Since the cause of amyloidosis vary among regions, analyzing local patterns can help establish a diagnostic procedure. We aimed at describing cases of kidney amyloidosis identified by biopsy during a 4-year interval and discuss possible implication for future diagnosis. Method We analyzed our kidney biopsy database and selected all cases of renal amyloidosis collecting clinical, laboratory and imaging data. Results From January 2016 until December 2019, 194 kidney biopsies were performed at the Hospital of Braga in the Portuguese province of Minho. Among these, 8 (4.1%) revealed amyloidosis. Mean age was 63.8±9.2 years of age, 5 were female, 6 were referred for nephrotic syndrome and 2 for what seemed like acute kidney injury. Mean creatinine at presentation was 3.2±2.3mg/dL. Among them, 2 had AL amyloidosis with light chain restriction by IF, 1 had AA amyloidosis with intense IHC stain and 5 patients had non-AL and non-AA forms of amyloidosis. Of these, 3 had probable fibrinogen A alpha-chain (AFib) amyloidosis, after a heterozygous mutation FGA p.Glu545Val was detected, 1, who did not have IHC performed, was assumed as having AA amyloidosis due to a history of serious recurrent infections and 1 is still under study. Four performed scintigraphy with 99mTc-DPD which was negative. The 2 patients with AL amyloidosis had, by OM, in one case glomerular and tubulointerstitial and on the other, glomerular and vascular involvement and, by IF, both had k light chain restriction. Both had additional cardiac and neurovegetative involvement, were treated with cyclophosphamide-bortezomib-dexamethasone and oral doxycycline with complete hematologic response and stabilization of kidney function. In 1 case, proteinuria only showed a slow decline 2 years after treatment. The 2 patients with AA amyloidosis had glomerular, vascular and tubular deposits. One had bronchiectasis and allergic bronchopulmonary aspergillosis and the other had common variable immunodeficiency with recurrent gastrointestinal and urinary infections with frequent bacteremia. None of them had confirmed extra-renal involvement, although the latter had hepatic fibrosis awaiting biopsy. Both progressed to dialysis soon after diagnosis. The 3 patients with AFib amyloidosis all had glomerular amyloidosis with additional amyloid deposition at tubular, vascular and both respectively. Two had had an increased creatinine and subnephrotic proteinuria for some years whereas 1 had kidney function decline and nephrotic syndrome in the course of few months. All were hypertensive and none had evident extra-renal deposits. Conclusion Identifying the amyloidogenic precursor may be difficult. Algorithms for diagnosis may vary according to local prevalence of specific types and available resources. AFib amyloidosis was very significant in our series. It was also described in 4.5% of hemodialysis patients in the district of Braga making it one of the first causes of amyloidosis in our region. This high prevalence may justify early genetic testing for the specific mutation in non-AL and non-AA forms.

Plasmablastic Lymphoma Associated with Adjacent Mature Plasma Cell Population Exhibiting Opposite Light Chain Restriction

Plasmablastic lymphoma (PBL) is an aggressive high-grade B cell lymphoma, considered a variant of diffuse large B cell lymphoma with approximately 75% mortality within 6-7 months. We describe an unusual case of PBL arising as a maxillary mass in an HIV-negative, nontransplanted 78-year-old female. Histologic examination revealed a diffuse infiltrate of anaplastic appearing cells exhibiting plasmablastic morphology with an adjacent contiguous infiltrate of mature appearing plasma cells. The PBL and mature plasma cell components both demonstrated an immunophenotype of CD20(-), CD38(+), and CD138(+). The two populations differed by the PBL featuring a high proliferation rate by Ki-67 (~95%) with coexpression of both c-MYC and EBV, while the mature plasma cell component featured a low proliferation rate by Ki-67 (~5%) without coexpression of c-MYC or EBV. Kappa/lambda staining demonstrated lambda light chain restriction involving the PBL, while the mature plasma cell infiltrate revealed kappa light chain restriction. Our findings describe the rare association of PBL with a synchronous distinct population of mature plasma cells exhibiting opposite light chain restriction.

Daratumumab Interference in Flow Cytometry Producing a False Kappa Light Chain Restriction in Plasma Cells

False kappa light chain restriction on hematogones (normal B-lineage precursors) has been described in patients on the therapeutic anti-CD38 monoclonal antibody daratumumab. In this article, we present a novel case report of pseudo-kappa light chain restriction on lambda-restricted neoplastic plasma cells in a patient with progressive plasma cell myeloma while on daratumumab. Flow cytometric technologists and pathologists need to be aware of this potential diagnostic pitfall.

Concomitant Chronic Lymphocytic Leukemia and Mantle Cell Lymphoma Discovered by Flow Cytometry

Casestudy: Chronic lymphocytic leukemia (CLL) accounts for about 30% of all lymphoid neoplasms and is the most common adult blood cancer in the Western world. Mantle cell lymphoma (MCL) accounts for only about 6% of all B-cell lymphomas in Western countries. MCL and CLL are both CD5 positive B-cell lymphoproliferative disorders. It is necessary to distinguish these two entities as MCL is a more aggressive disease, and requires specific treatment. MCL and CLL can occur in one patient at the same time and is often termed a composite lymphoma. We present an 84-year-old female with a history of endometrial cancer who was found to have splenomegaly and lymphadenopathy. Flow cytometry was performed upon her peripheral blood specimen which demonstrated two distinct populations of abnormal light chain restricted B-cell populations. One population demonstrated kappa light chain restriction and was positive for CD45, CD19, CD20, CD5, CD38, FMC-7, and CD22, representing MCL. The other population showed dim lambda light chain restriction that was also positive for CD45, CD19, dim CD20, CD5, and CD23, representing CLL. FISH studies demonstrated t(11;14), and four common deletions or chromosome aneuploidy associated with CLL. These findings confirmed the dual populations of CLL and MCL. This is an interesting case because it is a very rare combination with only a few cases having been reported with two distinct cell populations in one patient at the same time.