Twenty-four-color full spectrum flow cytometry panel for minimal residual disease detection in acute myeloid leukemia.

Full spectrum flow cytometry brings a breakthrough for minimal residual disease (MRD) detection in acute myeloid leukemia (AML). We aimed to explore the role of a new panel in MRD detection. We established a 24-color full-spectrum flow cytometry panel. A tube of 24-color antibodies included CD45, CD117, CD34, HLA-DR, CD15, CD64, CD14, CD11c, CD11b, CD13, CD33, CD371, CD7, CD56, CD19, CD4, CD2, CD123, CD200, CD38, CD96, CD71, CD36, and CD9. We discovered that when a tube meets 26 parameters (24 colors), these markers were not only limited to the observation of MRD in AML, but also could be used for fine clustering of bone marrow cells. Mast cells, basophils, myeloid dendritic cells, and plasmacoid dendritic cells were more clearly observed. In addition, immune checkpoint CD96 had the higher expression in CD117+ myeloid naive cells and CD56dimNK cells, while had the lower expression in CD56briNK cells in AML-MRD samples than in normal bone marrow samples. CD200 expression was remarkably enhanced in CD117+ myeloid naive cells, CD4+ T cells, T cells, activated T cells, CD56dimNK cells, and CD56briNK cells in AML-MRD samples. Our results can be used as important basis for auxiliary diagnosis, prognosis judgment, treatment guidance, and immune regulation in AML.

Abnormalities by Multicolor Flow Cytometry for Detection of Minimal Residual Disease in Recipients of Allo-HSCT Originating from Donors: A Cohort Study

Objective: In minimal residual disease (MRD) analysis after allogeneic hematopoietic stem cell transplantation (allo-HSCT), abnormal immunophenotyping is commonly considered as evidence of a secondary recurrence or complications, leading to overtreatment. We aimed to confirm whether such phenotypic abnormality might originate from donors using multicolor flow cytometry (MFC). Materials and Methods: The MRD of bone marrow specimens of 3395 patients who had received allo-HSCT were analyzed using the conventional two-tube, eight-color MFC panel. The frequencies of abnormal immunophenotypes were also evaluated in three groups of patients without malignancies. Results: The frequency of new abnormal polymorphisms was 0.088% (3/3395) among patients who received allo-HSCT. The abnormal cells seen in three patients in complete remission were Fcγ receptor IIIB (FcγRIIIB) gene deletion (CD16- neutrophils), CD2-CD159a-CD159c+ natural killer (NK) cells, and monoclonal B lymphocytosis (MBL), respectively. In addition, abnormal T-cells (CD4+CD8+) were detected in one donor before allo-HSCT. Identical abnormalities were found in the peripheral blood of the corresponding donors of the three patients via MFC. Among the individuals without malignancies, the incidence of FcγRIIIB deletion was 0.2% (11/5256), that of NK cells with the absence of CD2 and single-positive CD159c was 0.05% (1/2000), that of monoclonal CD4/CD8 double-positive T-cells was 0.05% (1/2000), and that of MBL was 1.3% (14/1100). The frequency of NK cells with the absence of CD2 was 1.3% (1/79) and with CD8dim was 14% (11/79) in NK cell lymphoma. The following abnormalities could be identified by the two-tube, eight-color MFC panel: cκ/cλ/CD19/CD5/CD20/ CD38/CD45/CD56 (adding CD10 and CD34 as the ninth and tenth colors) and CD16+CD56/CD5/CD3/CD7/CD4/CD8/CD2/CD45 (adding CD117 as the ninth color). Conclusion: Abnormalities in recipients of allo-HSCT detected by MRD analysis may originate from their donors. Screening of donor specimens with a suitable two-tube, eight- to ten-color MFC panel may be a promising method for minimizing misdiagnoses.

Cytoplasmic CD79a is a promising biomarker for B lymphoblastic leukemia follow up post CD19 CAR-T therapy.

Minimal residual disease (MRD) detection is an important prognostic parameter in patients with refractory or relapsed B-cell acute lymphoblastic leukemia (R/R B-ALL). CD79a has been reported to exhibit a high degree of linage-specificity for B-cell differentiation, with a specificity of 88% and a sensitivity of 100%. In this study, we investigated the efficiency and prognostic role of cytoplasmic CD79a (cCD79a) antibody-gated multicolor flow cytometry (MFC) in MRD detection in patients with B-ALL who received CD19-targeted chimeric antigen receptor (CAR) T-cell therapy bridging to allogeneic hematopoietic stem cell transplantation (allo-HSCT). The retrospective analysis was carried on to 59 patients who accepted allo-HSCT after CD19-CAR-T infusion from June 2016 to May 2017. The MFC MRD statuses before and after allo-HSCT were both strongly correlated with the transplantation prognosis, the MFC panel with cCD79a gating can effectively monitor MRD after CD19 CAR T-cell therapy and predict the prognosis after allo-HSCT. Trial registration: ClinicalTrials#: ChiCTR-IIh-16008711.gov: NCT03173417. Registered 30 May 2017 - retrospectively registered, https://www.clinicaltrials.gov/.

Analysis of the Expression of the TRBC1 in T lymphocyte tumors.

T cell therapy represents a new class of immunotherapies garnering considerable attention. T cell receptor beta chain constant region 1 (TRBC1) is partially expressed in subsets of normal T cells. However, the immunotherapy of T lymphocyte tumors is rarely validated in clinical trials. Here, we aim to explore whether TRBC1 is a promising target for the immunotherapy of T lymphocyte tumors. This study examined TRBC1 expression in 25 healthy bone marrow samples, 39 patients with T-lineage acute lymphocytic leukemia (T-ALL), 4 patients with mature T cell neoplasms, and 5 patients suspected with mature T cell neoplasms with evidence of T cell neoplasia. Moreover, the expression of TRBC1 was evaluated by flow cytometry and through PCR detection of TCR gene rearrangements. The expression of monophasic TRBC1 was identified in all 25 normal bone marrows (23.83% ± 2.74% positive rate). The expression of TRBC1 was positive in 5 patients (12.8%) among the 39 T-ALL patients. TRBC1 was partially expressed in 1 patient (25%) with T cell non-Hodgkin's lymphoma (T-NHL) and in 1 patient (20%) suspected to have T-NHL. Healthy donors showed a pattern of partial expression and patients with T-lymphocyte tumors showed a polytypic TRBC1 expression pattern. Thus, TRBC1 may be a diagnostic and therapeutic marker for T lymphocyte tumors.

[Preparation of monoclonal antibody against human CD33 by immunizing mice with recombinant vector].

Objective To prepare a monoclonal antibody (mAb) against human CD33 by immunizing mice with recombinant vector and analyze its characteristics and clinical application. Methods The eukaryotic expression vector pcDNA3.1(+)/CD33 was constructed and used to immunize mice. The mouse monoclonal antibody against human CD33 was then harvested using the hybridoma technique. Its properties were evaluated and the clinical performance was validated. Results One hybridoma cell line capable of secreting mouse anti-human CD33 monoclonal antibody was successfully obtained, which was named HI33a for clone identification with a subclass of IgG2a, κ. Flow Cytometry analysis revealed that the antibody could stain myeloid cell lines but not lymphoid cell lines, and it could inhibit the binding of similar imported antibodies with HL-60 cells competitively. Western blotting verified that it could bind a Mr 67 000 membrane protein extracted from HL-60 cells, which was a strong indication of the characteristics of CD33 protein molecule. Labeled with PE fluorescein, CD33-PE was tested as an antibody reagent in comparison with other similar imported products. Its overall performance including the accuracy, linearity, and precision all met the industrial standard. Further clinical evaluation of 558 bone marrow samples showed that the results were highly consistent with those by the imported reagents used as controls. Conclusion A hybridoma cell line stably secreting anti-human CD33 mAb was prepared.