To evaluate the clinical and biological significance of P-glycoprotein (P-gp) expression in adult acute nonlymphocytic leukemia (ANLL), P-gp was detected in 169 patients including 152 previously untreated cases, 7 refractory cases, and 10 cases at remission by using monoclonal antibody UIC2 and flow cytometry. P-gp was expressed in 29% of previously untreated cases, being less than in 71% of the refractory cases. P-gp expression was not found in patients at remission. Morphologically, P-gp expression was high in hybrid acute leukemia (67%) and acute monoblastic leukemia (47%) subtypes. Immunologically, P-gp expression was significantly associated with CD34, CD7, CD14 or CD42b/CD61. Cytogenetically, P-gp expression was highly associated with poor prognosis abnormalities (54%), which was significantly higher than 7% of P-gp expression in good prognosis abnormalities. 23% of P-gp positive previously untreated ANLL (not including M3) achieved complete remission; this was significantly lower than 76% in P-gp negative cases. These suggested that P-gp expression is an index of poor prognosis in adult ANLL and P-gp positive ANLL has unique clinical and biological features.

Imatinib has shown significant clinical and cytogenetic success in the treatment of chronic myeloid leukemia. Although resistance has been observed in a proportion of patients, sudden blastic crisis is a rare event during imatinib therapy. We describe a 24-year-old male patient with Philadelphia chromosome-positive chronic myeloid leukemia in chronic phase who developed sudden blastic crisis in the 24th month of imatinib therapy, with loss of complete cytogenetic response. At this time, the patient had splenomegaly, severe anemia, thrombocytopenia, and leukocytosis. Bone marrow aspirate revealed the presence of massive blastic infiltration with myeloid morphology. Flow cytometric analysis of the bone marrow cells showed positivity for CD45, CD34, CD13, CD33, CD19, CD41, CD61, and glycophorin-A. Trephine biopsy specimens showed 100% cellular marrow with diffuse infiltrate by blasts. A reticulin stain of the bone marrow biopsy section demonstrated severe diffuse fibrosis. Cytogenetic analysis by fluorescence in situ hybridization (FISH) revealed that 92% of the cells were positive for the BCR/ABL fusion signal and had increased copy numbers for chromosomes 8, 13, 19, and 21. The patient's prognosis was unfavorable. In conclusion, chronic myeloid leukemia remains complex and includes unanswered questions. The presented case with a rare event during imatinib therapy highlights the need for the continued monitoring of residual disease and the development of strategies to eliminate residual leukemia cells in patients showing a complete cytogenetic response.

Acute megakaryocytic leukemia (AMKL) is a rare subtype of acute myeloid leukemia (AML), which is challenging to diagnose due to frequent myelofibrosis (MF) and a low percentage of blast cells. In the present study, clinical characteristics and experimental observations in 9 adult patients diagnosed with AMKL, who were recruited by the Sino-U.S. Shanghai Leukemia Co-operative Group, were analyzed in order to summarize the diagnostic experience and provide recommendations on diagnosing AMKL. All the patients were diagnosed according to the 2008 World Health Organization diagnostic criteria. The mean age of the patients with AMKL was 59 years (range, 53-68 years). A total of 8 patients had different degrees of anemia, and 2 patients had <5% marrow blasts present in the bone marrow; however, the percentage of positive cells with cluster of differentiation (CD)41 and CD61 expression was >20%, as demonstrated by flow cytometry. A total of 6 patients were positive for platelet-specific antigens, as indicated by immunocytochemistry. Furthermore, 7 patients presented with moderate or marked MF, as demonstrated by a bone marrow biopsy. Karyotypic analysis indicated that 6 patients had abnormal karyotypes. Only 1 patient exhibited the Janus kinase 2V617F mutation. Treatment efficiency was notably poor, with a median survival time of 6.0 months (range, 1.1-24.0 months). In conclusion, the diagnosis of AMKL requires a combination of the results of bone marrow smears and bone marrow biopsy, immunophenotype or immunohistochemistry. We recommend that routine immunophenotypic analysis should include the CD41 and CD61 markers for diagnosing acute leukemia when bone marrow morphology does not indicate the diagnosis.

For the cell type diagnosis of leukemia in adult patients, particularly when the sampling of bone marrow is difficult, the study of peripheral blood leukocytes (PBLs) by immuno-electron microscopy provides significant information, as illustrated here in two cases of hairy cell leukemia and seven cases tentatively identified as megakaryoblastic leukemia (M7). Indirect immunogold labeling with the B-ly7 monoclonal antibody (CD103) proved valuable in confirming the diagnosis of hairy cell leukemia. Immunogold labeling for the GpIIIa platelet glycoprotein (CD61) was used in cases where the light microscopy of blood films revealed possible megakaryoblastic leukemia. Under the electron microscope, however, the CD61 positive cells showed, in almost all cases, a wide spectrum of megakaryopoietic differentiation which made the diagnosis of M7 questionable. Most of the CD61 positive cells featured cytoplasmic differentiation markers such as alpha granules and demarcation membranes, further confirming the presence of circulating megakaryocythemia, a phenomenon described many years ago in various myeloproliferative disorders. It is suggested, therefore, that many of these cases should not be identified as true megakaryoblastic leukemias.

OBJECTIVE

To describe the frequency and compare the clinical characteristics, treatment response, survival and hematologic, immunophenotypic, cytogenetic, and histologic findings in adult patients with acute megakaryoblastic leukemia (AMegL) and megakaryocytic blast crisis of chronic myeloid leukemia (MegBC-CML).

METHODS

The records of patients with AMegL and MegBC-CML attended in our institution between July 1993 and December 2000 were revised. Megakaryocytic lineage was established by the presence of one or more megakaryocyte/platelet associated antigens (CD41, CD42b, and CD61) in>> 20% blast cells.

RESULTS

In 90 months, 277 patients with acute leukemia were admitted and 25 with chronic myeloid leukemia (CML) in blast crisis (BC) were identified. Twelve of 125 patients (9.6%) with acute myeloid leukemia were AMegL and 32% of cases with CML-BC were MegBC-CML. Leukemic cells of patients with AMegL expressed more frequently CD15 antigen than blast cells of those with MegBC-CML (83% and 37.5%; p < 0.05). In contrast, blast cells expressing myeloperoxidase were present in 50% and 10% of cases with MegBC-CML and AMegL, respectively (p < 0.05). Only one patient in each group obtained remission. Although median survival in patients with AMegL was lower (70 days) than in those with MegBC-CML (175 days) the difference did not reach statistical significance.

CONCLUSIONS

AMegL and MegBC-CML differ in some clinical and laboratory characteristics and are diseases with poor treatment response and short survival.

A 16-month-old female spayed Labrador Retriever was referred to the University of Edinburgh for exercise intolerance, inappetence, and severe anemia. A CBC showed severe nonregenerative anemia and moderate numbers of atypical cells with morphologic features most consistent with megakaryoblastic origin. Similar cells were identified in a bone marrow aspirate and accounted for 23% of all nucleated cells. Atypical promegakaryocytes and megakaryocytes were also noted. Myelodysplastic syndrome affecting the megakaryocytic lineage was suspected. Cytologic examination of a fine-needle aspirate of the spleen revealed rare megakaryoblasts similar to those in blood and bone marrow. At necropsy, the bone marrow consisted of atypical megakaryoblasts and megakaryocytes that were also infiltrating spleen, liver, lymph nodes, renal perihilar tissue, and visceral adipose tissue, consistent with acute megakaryoblastic leukemia. Immunohistochemical analysis of splenic sections confirmed megakaryoblastic origin (immunoreactive for CD61 and von Willebrand factor). Some leukemic cells were also immunoreactive for myeloperoxidase (MPO). This aberrant immunophenotype suggested both megakaryocytic and granulocytic/monocytic differentiation of the leukemic cells. To our knowledge, this is the first report of MPO-positive acute megakaryoblastic leukemia in a dog.

OBJECTIVE

To characterize the immunophenotype of blast crisis (BC) in Mexican patients with chronic myeloid leukemia (CML).

METHODS

Mononuclear cells of 17 patients with CML in BC were immunophenotyped employing a panel of 18 monoclonal antibodies: CD5, CD10, CD14, CD22, and anti-HLA-DR used in all patients; CD2, CD15, CD19, CD34, and CD41 in 13 to 16 patients; and CD3, CD7, CD13, CD20, CD21, CD33, CD42b, and CD61 in less than 10 patients.

RESULTS

Myeloid was the most frequent type (9/17 cases) followed by lymphoid (6/17) and hybrid or mixed lineage (2/17). Four of the myeloid BC expressed megakaryocyte/platelet associated antigens; 5 of 6 cases with lymphoid BC showed an early precursor B cell immunophenotype (HLA-DR+, CD10+), and the other was an uncommon case of lymphoid B/T transformation (CD19+, CD5+). The CD34 antigen was present in 6 out of 15 cases: 4 patients with lymphoid BC, 1 with myeloid transformation, and 1 with megakaryoblastic BC.

CONCLUSIONS

Our findings are comparable to those found in the literature comprising 192 patients. The present study confirms the lineage heterogeneity of CML BC and suggests that extensive immunophenotyping may allow insight for a more precise recognition of normal and leukemic ontogenesis.

A patient is described with chronic myelogenous leukemia in blastic crisis, in whom numerous circulating platelet fragments and megakaryocytic nuclei were present, with 50% blasts and 50% micromegakaryocytes in the marrow. The blasts expressed myeloid-associated antigens CD34, CD33, and CD13, whereas the micromegakaryocytes were positive for CD41, CD42b, and CD61. These findings suggested a myeloblastic transformation with a possible megakaryoblastic component. Cytogenetic analysis showed rearrangement of 3q26 in the form of t(2;3) (p13;q26), in addition to t(9;22) (q34;q11). Dual-color flow cytometric analysis of DNA content of CD42b-positive cells showed that the micromegakaryocytes were predominantly 2N, indicating a maturation block before nuclear endoreplication and polyploidization. These findings confirmed a combined myeloblastic and megakaryoblastic transformation. It is concluded that dual-color flow cytometric DNA analysis is a useful method for the investigation of abnormal megakaryocytopoiesis in hematologic malignancies.

One hundred-twenty-five adult patients with de novo acute myeloid leukemia (AML) were treated according to a standard 7 + 3 induction regimen. Karyotype and immunological phenotype of blasts examined prior to treatment were correlated with each other, with response to treatment and duration of survival. The following monoclonal antibodies (mAbs) were used for immunological phenotyping: VIM-D5 (CD15), MY7 (CD13), MY9 (CD33), VIM-2 (CDw65), VIM-13 (CD14), 63D3 (CD14), VID-1 (anti HLA-DR), WT1 (CD7), CLB-Ery3 (antiblood group H antigen), C17-27 (CD61), and an antiserum against TdT. Despite a considerable overlap between the individual groups, patients with specific aberrations as defined by the MIC classification (n = 39) showed distinct, characteristic, myeloid or myelomonocytic immunophenotypes. In M2/t(8;21) there was a significant association with negativity to CD13, in M3/t(15;17) with negativity to CD15 and HLA-DR, whereas in M4/inv(16) expression of blood group H antigen was unexpectedly found. The response to therapy, as well as rate of complete remission as duration of survival, was better in patients with M2/t(8;21), M3/t(15;17), and M4Eo/inv(16) as compared to all other patients and significantly worse in patients with M5a/t/del(11)(q23). In 35 patients with normal karyotype and 16 patients with cytogenetic anomalies not presently associated with FAB subtypes the expected correlations of rather immature myeloid immunologic phenotypes with M1 and M2 morphology and CD14 expression in monoblastic leukemias was found. Remission rate and survival were significantly worse in 19 patients with complex nonrandom aberrations, where blast cell expression of blood group H antigen and of TdT were significantly increased.

BACKGROUND

The processes of leukemogenesis and differentiation of the megakaryo-erythroid lineage remain poorly understood. Leukemic cell lines derived from megakaryocytic leukemia are valuable reagents for studies on these events.

METHODS

A new cell line, JAS-R, was established from a 64-year-old patient with acute megakaryocytic leukemia (AML M7). Its characteristics were studied by morphological, immunophenotypic and molecular biological analysis.

RESULTS

Immunophenotyping showed that the JAS-R cells were positive for CD33, CD41 and CD61, as well as moderately to weakly positive for CD4, CD7, CD13 and glycophorin A. Chromosomal analysis revealed a composite karyotype, but no major translocation abnormalities were observed. Electron microscopy disclosed that the JAS-R cells had numerous surface blebs and some cells also had alpha-granules and demarcation membranes. The mRNAs of 4 major proteins (platelet factor 4, beta-thromboglobulin, selectin-P and thrombospondin 1) found in alpha-granules were all expressed by the JAS-R cells. In particular, expression of platelet factor 4 was high. To further characterize JAS-R cells, comparison with 4 other megakaryo-etythroid cell lines (CMK, MEG-01, K562 and KU812) was done by gene expression profiling using an oligo-DNA microarray. The results showed that JAS-R was a distinctive cell line. It was noteworthy that the JAS-R cells secreted erythropoietin and expressed erythropoietin receptor. A neutralizing antibody for erythropoietin partly inhibited the proliferation of the cells.

CONCLUSIONS

JAS-R may be a useful cell line for investigating the differentiation and leukemogenesis of megakaryo-erythroid cells and for studying the influence of erythropoietin on these cells.

Neonates with Down's syndrome may develop a transient myeloproliferative disorder (TMPD) which on presentation is indistinguishable from acute leukemia, with the difference manifest only on follow-up. The clinical course is one of spontaneous remission in TMPD and relentless progression in leukemia. We describe a Down's neonate presenting with hyperleucocytosis and circulating blasts which were positive for CD34, myeloid (CD33), megakaryocytic (CD41, CD42b, CD61), and T-lineage (CD3, CD7), but not B-lineage, associated antigens. Clonal rearrangement of the T-cell receptor beta (TCR beta) gene was found, with the immunoglobulin heavy chain gene in germline configuration, showing the disease to be a clonal proliferation of a multipotential stem cell involving the myeloid and T lineages. Dual-colour flow cytometric DNA ploidy analysis of CD41 positive blasts showed initially a predominant 2N population, but polyploidization to 6N and 8N cells was found on follow-up, concomitant with a progressive decrease in circulating blasts, suggesting maturation of the abnormal clone and a provisional diagnosis of TMPD. This was shown by the eventual resumption of normal haemopoiesis with the disappearance of blasts and the clonally rearranged TCR beta gene.

The immunophenotype (a), ultrastructural features (b) and cell kinetics (c) of circulating megakaryoblasts have been studied in two cases of pure megakaryoblastic and one case of mixed (myeloblastic, megakaryoblastic) cell proliferation in chronic myeloid leukaemia (CML). (a) The blast cells showed early megakaryocyte differentiation antigen (HLA-DR), platelet specific GpIIIa (CD61) and GpIIb-IIIa (CD41) antigens in different percentages. (b) The megakaryoblasts were recognized by the presence of platelet GpIIIa (CD61) demonstrated by an immunoelectron microscopic method. The labelled cells were "lymphocyte-like" megakaryoblasts and cells with features of cytoplasmic maturation (demarcation membranes, alpha granules and vacuoles). (c) Cellular DNA content of the megakaryoblasts was measured by propidium iodide (PI) staining of cells expressing platelet GpIIIa (CD61). Flow cytometric (FC) DNA analysis revealed no aneuploidy and high ploidy (greater than 4N) cell population. In the two cases of pure megakaryoblastic proliferation a high percentage of the megakaryoblasts were in the S-phase, while the non-megakaryoblastic cell fraction showed no elevated S-phase compartment. It is concluded that in CML the circulating megakaryoblasts (1) have a nuclear maturation arrest and accumulation at the level of tetraploid DNA content, (2) surface antigen expression and cytoplasmic organelles show a tendency to mature and (3) in pure megakaryoblastic proliferation the myeloid cells are not in the cell compartment showing high proliferation.

In our report, myelofibrosis in children is discussed and two cases of acutely developing myelofibrosis in association with acute megakaryoblastic leukaemia (M7) are presented. In the first case (girl, 34 months), it was acute myelofibrosis of hypocellular marrow. Diagnosis of M7 was confirmed by positive reaction of blasts from peripheral blood with CD42 and CD61 monoclonal antibodies. In the other child (girl, 5 years old), Ph1(+) chronic myeloid leukaemia diagnosed 22 months earlier transformed to M7. Similar to the first case, no marrow aspirate could be obtained and the diagnosis of M7 was made by the bone marrow histology that showed the presence of grossly fibrosed, hypercellular marrow with a large number of dysplastic, maturing megakaryocytes. Neither of the children had Down's syndrome. Although according to FAB classification both cases represent the same haematological entity, their clinical and histopathological presentations are very different.

We present 15 patients with megakaryocytic (Mk) blast crisis (BC) of a Philadelphia (Ph) chromosome positive CML confirmed by immunophenotype analysis between 1989-2000. The primary aim of this study is to define clinical, immunological, cytogenetic and laboratory characteristics of Mk BC in Ph positive CML. We have done retrospective analysis regarding basic clinical findings, immunologic phenotype, cytogenetic studies and platelet functions. All patients had significant expression of CD61 (14/14) and CD34 (13/13) antigens, and a high frequency of expression of CD13 (9/12), CD33 (10/12) and CD11b (9/11). The BC in 6/15 patients was presented with thrombocytosis, 7/15 had a normal platelet count and two patients had thrombocytopenia. A grade IV myelofibrosis was present in 8/10 patients. Six patients evolved additional karyotypic abnormalities. Two patients had extramedullary BC. The serum activity of LDH (med. 1095.6) was elevated in all patients. A platelet dysfunction was documented in 4/5 patient tested. There are no clinical and hematological characteristics specific for Mk BC of CML. Normal or elevated platelet count (med. 427.4 x 109/L) in BC of CML with prominent expression of CD34 and CD61 antigens, and significant myelofibrosis (grade IV) are the most consistent clinical findings.

Purpose: The CD36 scavenger receptor is a mediator of both atherogenesis and thrombosis. We aimed to investigate the prognostic value of CD36+ microparticles (MPs) released from platelets for cardiovascular event presentation in coronary artery disease (CAD) patients and the effects of different antiplatelet drugs on MPs.

Methods: A total of 101 aspirin-treated CAD patients, who were planned to undergo coronary angiography (CAG), were randomized to either a standard clopidogrel regimen or ticagrelor treatment. Total Annexin V-(AV)+ MPs, CD61+/AV+ MPs, and CD36+/CD61+/AV+ MPs were quantified by flow cytometry at baseline, before and immediately after the operation. The ADP-induced platelet inhibition rate was measured by thromboelastogram (TEG) examination 1 h before the operation.

Results: The baseline levels of CD36+/CD61+/AV+ MPs were significantly increased in percutaneous coronary intervention (PCI) patients (n = 52) compared to no-PCI patients (n = 49) (p < 0.05). A ROC-curve clustered model for CD36+/CD61+/AV+ MPs at baseline predicted an increased risk of PCI [p = 0.009, AUC = 0.761 (95%CI: 0.601 to 0.922)]. Moreover, TEG examination showed that the preoperative proportion of CD36+/CD61+/AV+ MPs was significantly negatively correlated with R time and K time (r = - 0.236, p = 00.026; r = - 0.288, p = 0.006), and positively correlated with MA_ADP (r = 0.226, p = 0.045). Subgroup analysis of PCI group showed that the platelet inhibition rate of ticagrelor was significantly higher (66.05% ± 28.76% vs.31.01% ± 27.33%, p < 0.001), and the number of AV+ MPs, CD61+/AV+ MPs, and CD36+/CD61+/AV+ MPs before the operation was significantly lower than clopidogrel (p < 0.05, all).

Conclusion: The high levels of CD36+ MPs derived from activated platelets are related to an increased risk of PCI in CAD patients. Ticagrelor significantly reduced the number of CD61+/AV+ MPs and CD36+/CD61+/AV+ MPs. This trial registration number is ChiCTR1800014908 and the date of registration is 2018.05.01.

Keywords: CD36; Microparticles; Platelet; Thromboelastogram; Ticagrelor.

BACKGROUND

Achieving hemostasis in anticoagulated patients is an increasingly important clinical issue. Poly-N-acetylglucosamine (pGlcNAc) nanofibers activate platelets by β3 subunit (CD61) and the von Willebrand receptor GP1b (CD42b) integrin signaling for generation of a prothrombotic surface membrane. Recombinant coagulation factor VIIa (rFVIIa) functions in hemophilia A and B by catalyzing formation of the Xa/Va complex on the surface of activated platelets. These observations suggest that pGlcNAc nanofibers may amplify the activity of rFVIIa in hemophilic blood.

METHODS

The activity of rFVIIa on platelets was tested by performing thromboelastographic analysis with blood from hemophilia B dogs in the presence of pGlcNAc nanofibers and increasing concentrations of rFVIIa. Mechanisms for hemostatic system activation were investigated with inhibitors of tissue factor, factor XIIa, and platelet function.

RESULTS

Recombinant FVIIa was observed to partially restore the ability of the hemophiliac blood to form fibrin clots in a dose-dependent manner with thromboelastographic analysis. The addition of pGlcNAc nanofibers amplified the rFVIIa effect. The activity of rFVIIa and the amplification effect of pGlcNAc were dependent on platelet integrin function but independent of FXIIa and tissue factor activities.

CONCLUSIONS

The pGlcNAc nanofibers amplify rFVIIa activity in hemophilia B canine blood by activating platelets through integrin-dependent mechanisms.

Anagrelide is a treatment option for patients with essential thrombocythemia. Although the clinical efficacy of anagrelide has been established, there is limited knowledge of the molecular mechanism underlying its effect. Here, we evaluated the effect of anagrelide on primary megakaryocytic progenitors from cord blood-derived CD34-positive cells. Anagrelide treatment reduced the expression of megakaryocytic markers (CD41 and CD61). Microarray analysis was performed to characterize gene profiles altered by exposure to anagrelide. The analysis demonstrated upregulation and downregulation (>2-fold) of eight and 34 genes, respectively, in anagrelide-treated megakaryocyte progenitors. This included genes encoding prototypical megakaryocytic proteins, such as PPBP, PF4, and GP6. Gene ontology analysis of genes suppressed by anagrelide treatment revealed significant enrichment of genes involved in platelet activation and degranulation. Expression levels of transcription factors involved in megakaryocyte commitment/differentiation were further evaluated by quantitative RT-PCR, demonstrating significant downregulation of FLI1 and TAL1 in anagrelide-treated megakaryocyte progenitors. Knockdown of TAL1 in primary megakaryocyte progenitors confirmed significant downregulation of FLI1 and megakaryocytic genes. Anagrelide had no significant effect on the surface expression of erythroid markers or on the expression of transcription factors involved in erythroid commitment/differentiation. In conclusion, anagrelide suppresses megakaryocytic differentiation, partly through decreasing the expression of megakaryocytic transcription factors.

Blood pharming is a recently designed concept to enable in vitro production of blood cells that are safe, effective and readily available. This approach represents an alternative to blood donation and may contribute to overcome the shortage of blood products. However, the high variability of the human leukocyte antigen (HLA) loci remains a major hurdle to the application of off-the-shelf blood products. Refractoriness to platelet (PLT) transfusion caused by alloimmunization against HLA class I antigens constitutes a relevant clinical problem. Thus, it would be desirable to generate PLT units devoid of HLA antigens. To reduce the immunogenicity of cell-based therapeutics, we have permanently reduced HLA class I expression using an RNA interference strategy. Furthermore, we demonstrated that the generation of HLA class I-silenced (HLA-universal) PLTs from CD34+ progenitor cells using an shRNA targeting β2-microglobulin transcripts is feasible. CD34+ progenitor cells derived from G-CSF mobilised donors were transduced with a lentiviral vector encoding for the β2-microglobulin-specific shRNA and differentiated into PLTs using a liquid culture system. The functionality of HLA-silenced PLTs and their ability to escape HLA antibody-mediated cytotoxicity were evaluated in vitro and in vivo. Platelet activation in response to ADP and thrombin were assessed in vitro. The immune-evasion capability of HLA-universal megakaryocytes (MKs) and PLTs was tested in lymphocytotoxicity assays using anti-HLA antibodies. To assess the functionality of HLA-universal PLTs in vivo, HLA-silenced MKs were infused into NOD/SCID/IL-2Rγc(-/-) mice with or without anti-HLA antibodies. PLT generation was evaluated by flow cytometry using anti-CD42a and CD61 antibodies. HLA-universal PLTs demonstrated to be functionally similar to blood-derived PLTs. Lymphocytotoxicity assays showed that HLA-silencing efficiently protects MKs against HLA antibody-mediated complement-dependent cytotoxicity. 80-90% of HLA-expressing MKs, but only 3% of HLA-silenced MKs were lysed. In vivo, both HLA-expressing and HLA-silenced MKs showed human PLT production (up to 0.5% within the PLT population) when anti-HLA antibodies were absent. However, in presence of anti-HLA antibodies HLA-expressing MKs were rapidly cleared from the circulation of mice, while HLA-silenced MKs escaped HLA antibody-mediated cytotoxicity and human PLT production was detectable up to 11 days. Our studies show that HLA-silenced PLTs are functional and efficiently protected against HLA antibody-mediated cytotoxicity. In this chapter, we provide a review of our most recent findings in the use of CD34+ progenitor cells for the production of HLA-universal PLTs and their potential clinical applications. Provision of HLA-universal PLT units may become an important component in the management of patients with PLT transfusion refractoriness.

Granulocyte colony-stimulating factor (G-CSF)/Chemotherapy mobilized peripheral blood progenitors are an effective source of stem cells which affords rapid and complete hematopoietic engraftment after myeloablative chemotherapy regimens. The dose of G-CSF most commonly used for mobilization is 5 micrograms/kg. We measured G-CSF levels in patients with chemosensitive malignancies undergoing peripheral stem cell harvest to determine whether there was a relationship between serum G-CSF levels and the yield of CD34+ hematopoietic progenitors. Peripheral blood stem cells (PBSCs) were mobilized by chemotherapy followed by G-CSF (5 micrograms/kg) started 24 hours after completion of chemotherapy. PBSCs were collected by daily leukapheresis during G-CSF stimulation once the WBC had recovered to 1.0 x 10(9)/L, with 10 liters of blood processed using a Fenwall CS 3000. G-CSF levels were monitored daily before and after leukapheresis. CD34+ cells from daily leukapheresis collections were determined in 11 patients. Immunophenotyping analyses of CD34+ and non-CD34+ cells for surface antigens CD38+, HLA-DR, CD71+, CD61+ and CD42a+ were performed on these daily leukapheresis. The mean (SD) number of days to neutrophil recovery (NR:>> or = 0.5 x 10(9)/L) after stem cell reinfusion was 9.2 (1.92). The corresponding values for platelet recovery (PR:>> or = 20 x 10(9) L) were 8.1 (2.39) days. Using multiple regression analyses, the best predictors for NR were: last G-CSF (R2 = 0.21); last G-CSF and CD34+ (R2 = 0.67); last G-CSF, CD34+ and number of chemotherapy cycles (R2 = 0.72).(ABSTRACT TRUNCATED AT 250 WORDS)

Platelet microvesicles (pMVs) are submicron-sized heterogeneous vesicles released upon activation and contain several membrane receptors and proteins (CD41, CD61, CD62, CXCR4, PAR-1, etc.). We have revealed their ability to adhere to the triblock copolymer pluronic-F127 (PF127) and form a platelet microvesicular nanocloud which has the potential to enhance the transvascular migration of hematopoietic stem cells across the sinusoidal endothelium to the bone marrow. Besides, the pMVs nanoclouds bestow survival benefits when present on the cells used for infusion, particularly with PF127-stabilized with chitosan-alginate (PF127-CA HSCs). The vesicles were found to be firmly associated with PF127 in the nanocloud, which was detected by confocal laser scanning microscopy. The abrogation of CXCR4/SDF-1 axis regulating the transmigration of the cells by antagonist AMD3100 revealed that the enriched CXCR4 receptors on pMVs robustize the transmigration of the infused cells. The homing of the cells led to effective engraftment and faster regeneration of the critical blood lineages, which elicited 100% survival of the mice receiving lethal doses of radiation. The Human Long-Term Culture Initiating Cells (LTC-ICs), Severe Combined Immunodeficient (SCID) - Repopulating Cells (SRCs) and Colony Forming Cells (CFCs) responsible for the regeneration, but present in extremely low numbers in the infused cell dose, have enabled the cells to reach the bone marrow in high numbers. This potential of the PF127 to sequester the pMVs and its application to achieve over 10-fold delivery of HSCs across the trans-endothelial checkpoint has so far not been reported. Thus, this mechanistic innovation is a potential post-exposure life-saving regimen capable of circumventing the irreparable damage to the bone marrow caused by lethal doses of radiation.

The current study analyzed the clinical and genetic characteristics of a family with familial myeloproliferative neoplasms (MPNs). Whole-exome sequencing was conducted, and a germline heterozygous mutation in lysine methyltransferase 2A (KMT2A, also known as MLL1), G3131S (c.9391G > A, p.Gly3131Ser, rs150804738), was identified. Somatic DNA and germline DNA were collected from 8 family members, 120 healthy donors (somatic DNA), and 30 healthy donors (germline DNA). Using Sanger sequencing, the KMT2A G3131S mutation was analyzed. Four individuals, the proband (II-1), his sister (patient II-2), and family members II-3 and III-1 (somatic DNA and germline DNA), tested positive for the KMT2A G3131S mutation. We did not observe the KMT2A G3131S mutation in healthy donors (somatic DNA and germline DNA), indicating that this is not a SNP. Bioinformatics analysis of KMT2A G3131S suggested that protein structure changes could be caused by this mutation. To further elucidate the function of KMT2A G3131S, the CRISPR-Cas9 technique was applied to generate a KMT2A G3131S heterozygous K562 cell line. The colony formation potency, apoptosis, and cell cycle of KMT2A G3131S mutant K562 cells were analyzed. The results demonstrated that KMT2A G3131S mutant K562 cells showed increased proliferation and colony formation ability. Immunophenotyping was performed using flow cytometry to analyze the surface marker expression of gene-edited KMT2A G3131S mutant K562 cells. A significant increase in CD11b and mild increases in CD61 and CD235a were observed in KMT2A G3131S mutant K562 cells, suggesting that the KMT2A G3131S mutant could cause an increase in myeloproliferation. May-Giemsa staining showed that the morphological changes in KMT2A G3131S mutant K562 cells were consistent with the flow cytometry analysis. To verify which downstream genes were affected by the KMT2A G3131S mutant, we performed real-time PCR to evaluate the expression of previously reported KMT2A-related genes and found that C-MYB expression was significantly decreased. Western blotting was applied to investigate the expression of Kmt2a and C-myb proteins, and the results showed that in KMT2A G3131S mutant K562 cells, the expression of C-myb was decreased. Our findings suggested that KMT2A G3131S could affect the myeloproliferation of K562 cells and decrease C-myb expression. In conclusion, KMT2A G3131S could be considered a novel genetic susceptibility gene in familial MPN.

Keywords: Familial myeloproliferative neoplasms; Genetic susceptibility; Germline mutation; KMT2A.

Background: Measurable residual disease (MRD) is a strong independent poor prognostic factor for acute leukemia. Multiparameter flow cytometry (FCM) is a commonly used MRD detection method. However, FCM MRD detection is not well standardized, and the interpretation is subjective. There are normal/reactive minor cell populations in bone marrow (BM) and peripheral blood (PB), which could be confused with MRD.

Methods: The FCM data of 231 BM and 44 PB pediatric samples performed in a recent 15-month period were retrospectively reviewed. These samples were from 56 B-lymphoblastic leukemia (B-ALL) patients, 11 T-lymphoblastic leukemia (T-ALL) patients, 28 acute myeloid leukemia (AML)/myelodysplastic syndrome (MDS) patients, 44 cytopenia/leukocytosis patients, and five patients with mycosis fungoides.

Results: There were over 10 normal or reactive minor cell populations identified with certain phenotypes mimicking MRD of acute leukemia. These mimickers included CD19+ NK cells, CD22+ basophils, CD22+ dendritic cells (DCs), and plasma cells for B-ALL MRD; CD4/8 double-negative T cells, CD4/8 double-positive T cells, cytoplasmic CD3+ NK cells, CD2- T cells, CD7- T cells, CD5- gamma delta T cells, CD56+ NKT cells for T-ALL MRD; CD33+ NK cells, CD117+ NK cells, basophils, plasmacytoid DCs, non-classical monocytes, CD56+ and/or CD61+ monocytes for AML MRD.

Conclusions: These data confirm the presence of a variety of normal/reactive minor cell populations that could mimic MRD of acute leukemia by FCM. Recognizing these MRD mimickers is important for correct FCM MRD interpretation.

Keywords: MRD mimickers; acute leukemia; flow cytometry; minimal residual disease.

The current SARS-CoV-2 pandemic is accompanied by high morbidity and mortality rates, and there is a compelling need for effective vaccines and therapeutic agents to lessen the severity of COVID-19 disease. Appropriate animal models are essential for testing of vaccines and therapeutics and for mechanistic studies of infection and the host response. The Spike (S) protein of SARS-COV-2 has a high affinity for the human ACE2 receptor, which is expressed on multiple cell types including alveolar epithelial and vascular endothelial cells. Wild-type mice are not susceptible to developing coronavirus-mediated diseases. Accordingly, several human (h)ACE2 transgenic mouse models have been developed for coronavirus research. However, these mice have failed to closely mimic important aspects of the human immunopathological responses to SARS-CoV-2. We report herein that DRAGA (HLA-A2.HLA-DR4.Rag1KO.IL-2Rγc KO.NOD) mice infused with human hematopoietic stem cells from cord blood reconstitute a fully functional human immune system, as well as engraft human epithelial and endothelial cells, sustain SARS-CoV-2 infection, and develop severe COVID-19-like symptoms. In pilot experiments, infected mice developed parenchymal and epithelial lung infiltrations with granzyme B ⁺ and perforin ⁺ CD8 ⁺ T cells and alveolar CD61 ⁺ microthrombi, mimicking human immunopathological responses to SARS-CoV-2. We propose the DRAGA mouse as a novel pre-clinical tool for studying COVID-19 immunopathology and human immune responses to SARS-CoV-2, including events leading to the cytokine storm and coagulopathies, as well as for testing of candidate vaccines and therapeutics.

BACKGROUND

Recently, umbilical cord blood (UCB) has been recognized as a suitable potential source of hematopoietic stem/progenitor cells (HSPCs) for transplantation. Lengthy thrombocytopenia after UCB transplantation is a major problem because of insufficient megakaryocyte (Mk) progenitors, which results in delayed platelet recovery. Frequent allogenic platelet transfusion leads to resistance to platelet units and higher risk of transmission of pathogenic agent.

OBJECTIVE

Ex vivo expansion of HSPCs and their differentiation to Mk progenitors on aminated PES nanofiber could lead to faster platelet recovery after UCB transplantation.

METHODS

CD34 cells were positively enriched using the MidiMACS system. CD34(+) cells were seeded onto conventional culture and aminated PES scaffold. The proliferation of CD34(+) cells, and also their differentiation into Mk progenitors, were evaluated. We used the flow cytometric method for analyzing CD41 and CD61 markers and real-time PCR for the expression level of transcription factors, as NF-E2 and GATA-1.

RESULTS

This study indicated increased CD34(+) cell population in aminated PES compared to the conventional system. After differentiation, the amount of CD41/CD61-expressing cells and the quantity of NF-E2 expression level increased in the aminated PES versus the 2-D system. The quantity of GATA-1 expression level was reduced on CD41/CD61(+) cells compared to CD34(+) cells, with no difference between the aminated PES and the conventional system.

CONCLUSIONS

Aminated PES nanofiber could have more effect on the proliferation of CD34(+) cells and Mk differentiation than the conventional culture.

CONCLUSIONS

Injection of the expanded cells and differentiated Mk progenitors, along with the transplantation of UCB stem cells might accelerate recovery of platelets and decrease the period of thrombocytopenia after transplantation.