(Lymph)angiogenic influences on hematopoietic cells in acute myeloid leukemia

The purpose of this review is to provide an overview of the effect of (lymph)angiogenic cytokines on hematopoietic cells involved in acute myeloid leukemia (AML). Like angiogenesis, lymphangiogenesis occurs in pathophysiological conditions but not in healthy adults. AML is closely associated with the vasculature system, and the interplay between lymphangiogenic cytokines maintains leukemic blast survival in the bone marrow (BM). Once AML is induced, proangiogenic cytokines function as angiogenic or lymphangiogenic factors and affect hematopoietic cells, including BM-derived immune cells. Simultaneously, the representative cytokines, VEGFs and their receptors are expressed on AML blasts in vascular and osteoblast niches in both the BM and the peripheral circulation. After exposure to (lymph)angiogenic cytokines in leukemogenesis and infiltration, immune cell phenotypes and functions are affected. These dynamic behaviors in the BM reflect the clinical features of AML. In this review, we note the importance of lymphangiogenic factors and their receptors in hematopoietic cells in AML. Understanding the functional characterization of (lymph)angiogenic factors in the BM niche in AML will also be helpful in interrupting the engraftment of leukemic stem cells and for enhancing immune cell function by modulating the tumor microenvironment.

CD34-positive cells and their subpopulations characterized by flow cytometry analyses on the bone marrow of healthy allogenic donors / Células CD34-positivas e suas subpopulações caracterizadas por análise de citometria de fluxo em doadores para transplante alogênico de medula óssea

CONTEXT AND OBJECTIVE: Counting and separating hematopoietic stem cells from different sources has importance for research and clinical assays. Our aims here were to characterize and quantify hematopoietic cell populations in marrow donors and to evaluate CD34 expression and relate this to engraftment. DESIGN AND SETTING: Cross-sectional study on hematopoietic stem cell assays, using flow cytometry on donor bone marrow samples, for allogenic transplantation patients at two hospitals in São Paulo. METHODS: Immunophenotyping of marrow cells was performed in accordance with positive findings of CD34FITC, CD117PE, CD38PE, CD7FITC, CD33PE, CD10FITC, CD19PE, CD14FITC, CD13PE, CD11cPE, CD15FITIC, CD22PE, CD61FITC and CD56PE monoclonal antibodies in CD45PerCP+ cells, searching for differentiation and maturation regions. CD34+ sorting cells were analyzed for CD38 and CD117. Rh-123 retention was done before and after sorting. Antigen expression and CD34+ cells were correlated with engraftment. RESULTS: In region R1, 0.1 percent to 2.8 percent of cells were CD34+/CD45+ and 1.1 percent, CD34+/CD45-. The main coexpressions of CD45+ cells were CD38, CD22, CD19 and CD56 in R2 and CD33, CD11c, CD14, CD15 and CD61 in R3 and R4. After sorting, 2.2x10(6) CD34+ cells were equivalent to 4.9 percent of total cells. Coexpression of CD34+/CD38+ and CD34+/CD117+ occurred in 94.9 percent and 82 percent of events, respectively. There was a positive relationship between CD34+ cells and engraftment. More than 80 percent of marrow cells expressed high Rh-123. CD34+ cell sorting showed that cells in regions of more differentiated lineages retained Rh-123 more intensively than in primitive lineage regions. CONCLUSION: We advocate that true stem cells are CD34+/CD45-/CD38-/low-Rh-123 accumulations.

CONTEXTO E OBJETIVO: A contagem e separação de células-tronco hematopoéticas de diferentes fontes tem importância para ensaios clínicos e pesquisa basica. Nosso objetivo foi caracterizar e quantificar as populacões de células hematopoéticas, bem como avaliar a expressão do antígeno CD34 em populações mais primitivas e correlacioná-las com a enxertia nos doadores de medula óssea para transplante alogênico. TIPO DE ESTUDO E LOCAL: Estudo transversal no qual a diferenciação e a seleção de células-tronco hematopoéticas foram realizadas em amostras de medula óssea de doadores de pacientes submetidos a transplante alogênico nos Hospitais São Paulo e Santa Marcelina, São Paulo, Brasil. MÉTODOS: Imunofenotipagem de células mononucleares de medula óssea foi feita na população de células CD45PerCP+ com os seguintes anticorpos: CD34FITC, CD117PE, CD38PE, CD7FITC, CD33PE, CD10FITC, CD19PE, CD14FITC, CD13PE, CD11cPE, CD15FITC, CD22PE, CD61FITC e CD56PE. Após a definição de regiões de células positivas ao CD34, estas células foram selecionadas e analisadas para a co-expressão do CD38 e CD117. Células mononucleares totais de medula óssea e aquelas obtidas após a seleção foram testadas para a retenção de Rh-123. O teste de Friedman e o coeficiente de Sperman foram utilizados para comparar as expressões e correlacionar a contagem de células CD34+ com a enxertia. RESULTADOS: Na região R1, 0,1 por cento a 2,8 por cento das células foram CD34+/CD45+, porém apenas 1,1 por cento das células foram CD34+/CD45-. As principais co-expressões de células CD45+ foram CD38, CD22, CD19 e CD56 na região R2 e CD33, CD11c, CD14, CD15 e CD61 nas regiões R3 e R4. Após a seleção, a mediana de 2,2x106 células CD34+ foi equivalente a 4,9 por cento do total mediano de células da medula óssea. Co-expressões de células CD34+/CD38+ e CD34+/CD117+ ocorreram em 94,95 e 82 por cento, respectivamente. Houve relação positiva entre o número de células CD34+ infundidas e o dia da enxertia. ...

Variant FCGR3 genes: transcription and possible origins.

The Fc receptors for human immunoglobulin G (FcgammaR) IIIb are encoded by genes clustered on the long arm of chromosome 1 (band q21 --> 24) and exhibit allelic polymorphisms. Several rare FCGR3B sequences were identified in both white and black donors. However, the origins of these genomic variants are unknown and their transcription has not yet been investigated. Blood from a donor with known FCGR3 variants was used to extract DNA from peripheral blood CD34+ cells, CD19+ B-cells, neutrophils and buccal cells, after which FCGR3 gene sequencing was performed. Additionally, RNA samples from 5 Caucasian individuals containing known variant FCGR3 genes were reverse-transcribed to cDNA and the FCGR3 genes were sequenced. Our results showed that the frequencies of variant clones were higher in B-cell preparations than in CD34+ hematopoietic progenitor cells from peripheral blood and neutrophils. Very high variant frequencies were found in buccal cell-derived clones. Variant cDNA sequences were identified in three of five individuals with known FCGR3 variants. We conclude that FCGR3 gene variants are differentially transcribed between cell types and tissues, increasing the likelihood of the presence of variant FcgammaRIII receptors on the cell surface. The significance of the high number of variant clones in buccal cells, however, is unclear.

Artículos de revisión: cultivos de expansión ex vivo de células madre a partir de sangre de cordón umbilical / Reviews: hematopoietic stem cell, ex vivo expansion from umbilical cordon blood

El éxito en el enfrentamiento a las hemopatías malignas depende de la erradicación de los clones tumorales por medio de la quimioterapia y la radioterapia. Sin embargo, en determinados pacientes la capacidad de curación se muestra limitada, y se requiere la sustitución de la función medular dañada por una nueva hematopoyesis sana, a través del trasplante de médula ósea (TMO). Este tipo de terapia celular puede contar ahora con donantes alternativos obtenidos a partir de la sangre de cordón umbilical (SCU) almacenada en bancos creados en varios países. Se ha comprobado la necesidad de promover un implante más rápido que disminuya la morbimortalidad relacionada con el procedimiento y permita la generalización de su uso, y se han propuesto estrategias basadas en la expansión de las células progenitoras hematopoyéticos (CPH) ex vivo, en cultivos a partir de SCU, lo que permite su uso en trasplantes con bajo contenido celular, y para diferenciar células pertenecientes a diferentes linajes hematopoyéticos, e incluso tejidos, con diferentes objetivos: trasplante hematopoyético, soporte de la recuperación a corto plazo, inmunoterapia, terapia génica, y diferenciación a tejidos mesenquimales. En esta revisión se explica cómo, de un producto habitualmente desechado, la SCU se ha convertido en una fuente de gran interés científico por la facilidad de su colecta, la fuente "ilimitada" de donantes, la calidad biológica de sus células madre cercanas a la época embrionaria y fetal del desarrollo, y la posibilidad de un uso amplio en diferentes estrategias de expansión ex vivo para terapia celular.

Proportions of Cells Expressing CD38-/CD34+, CD38+/CD34+, CD19+/CD34+, or CD13,33+/CD34+ in the Regenerating Bone Marrows During Complete Remission of Acute Leukemia or After Bone Marrow Transplantation / 대한진단검사의학회지

BACKGROUND: The hemopoietic stem cells increase in number during the regeneration after chemotherapy or bone marrow transplantation (BMT). Although the proportion of hemopoietic stem cells and their differentiation have been studied by immunophenotyping using the flow cytometry, no substantial research efforts have been directed toward the regenerating marrow. We attempted to discover the proportions of undifferentiated stem cells, committed stem cells, B cell precursors, and myeloid precursors in the regenerating bone marrows during complete remission (CR) and after engraftment of BMT. METHODS: Bone marrow samples from 82 patients with acute leukemia in CR and from 25 patients after BMT engraftment, along with 22 control samples, were used to find the numbers of CD38-/CD34+, CD38+/CD34+, CD19+/CD34+, and CD13,33+/CD34+ cells in the large lymphocyte gate by flow cytometry. We cross-analyzed our results in terms of groups: CR, BMT, and initial diagnosis groups. We performed significance tests on age, relapse, chromosomal abnormalities, clinical outcomes, and initial immunophenotypes of the leukemic cells. RESULTS: The proportions of CD38-/CD34+, CD38+/CD34+, CD19+/CD34+, and CD13,33+/CD34+ cells are more highly distributed in acute B-lymphoblastic leukemia than the normal group and also in the CR than the BMT group. CD19+/CD34+ cells were increased in the relapse group and CD38+/ CD34+, CD19+/CD34+, and CD13,33+/CD34+ cells were increased in the group with chromosomal abnormality. The results were irrelevant to the initial immunophenotype of the leukemic blasts. CONCLUSIONS: The increases of the markers spanned too widely to apply one specific cutoff value to analyze them. They seemed to be the results of normal regeneration, irrelevant to relapse or initial immunophenotype of leukemic blasts.

Aspectos inmunológicos del trasplante de células progenitoras hematopoyéticas / Immunological aspects of the transplant of haematopoietic progenitor cells

Los pacientes sometidos a trasplante de células hematopoyéticas experimentan un período prolongado de disfunción inmunológica que puede persistir por un año o más, con una afectación tanto de la inmunidad celular como humoral. Esto hace que tengan un riesgo elevado de infecciones en el período postrasplante. Después del acondicionamiento, hay una pérdida de la memoria de inmunidad acumulada durante toda la vida a la exposición a agentes infecciosos, ambientales y vacunaciones. El tratamiento de las infecciones se hace difícil, dado la pobre respuesta inmunitaria presente. Una de las herramientas para limitar el riesgo de infección es el uso de vacunas, aunque su efectividad se ve limitada por la inmunidad disfuncional que caracteriza a este período

Immunophenotype of hematopoietic stem cells from placental/umbilical cord blood after culture

Identification and enumeration of human hematopoietic stem cells remain problematic, since in vitro and in vivo stem cell assays have different outcomes. We determined if the altered expression of adhesion molecules during stem cell expansion could be a reason for the discrepancy. CD34+CD38- and CD34+CD38+ cells from umbilical cord blood were analyzed before and after culture with thrombopoietin (TPO), FLT-3 ligand (FL) and kit ligand (KL; or stem cell factor) in different combinations: TPO + FL + KL, TPO + FL and TPO, at concentrations of 50 ng/mL each. Cells were immunophenotyped by four-color fluorescence using antibodies against CD11c, CD31, CD49e, CD61, CD62L, CD117, and HLA-DR. Low-density cord blood contained 1.4 ± 0.9 percent CD34+ cells, 2.6 ± 2.1 percent of which were CD38-negative. CD34+ cells were isolated using immuno-magnetic beads and cultured for up to 7 days. The TPO + FL + KL combination presented the best condition for maintenance of stem cells. The total cell number increased 4.3 ± 1.8-fold, but the number of viable CD34+ cells decreased by 46 ± 25 percent. On the other hand, the fraction of CD34+CD38- cells became 52.0 ± 29 percent of all CD34+ cells. The absolute number of CD34+CD38- cells was expanded on average 15 ± 12-fold when CD34+ cells were cultured with TPO + FL + KL for 7 days. The expression of CD62L, HLA-DR and CD117 was modulated after culture, particularly with TPO + FL + KL, explaining differences between the adhesion and engraftment of primary and cultured candidate stem cells. We conclude that culture of CD34+ cells with TPO + FL + KL results in a significant increase in the number of candidate stem cells with the CD34+CD38- phenotype.

Purification of human hemopoietic stem cells for transplantation in Thailand.

Stem cell transplantation (SCT) has become the therapy of choice for many hematologic and immunologic disorders. At present, only 25% of patients have suitable HLA-identical donors. In an attempt to increase the donor pool for SCT in Thailand and Southeast Asia, we developed a program whereby parents and mismatched siblings can be used as donors. In this preliminary study, after granulocyte-colony-stimulating factor (G-CSF) was given to adult donors, peripheral blood stem cells (PBSC) were collected and CD34+ cells purified using a CliniMACS immunomagnetic device (Miltenyi Biotec, Germany). In seven experiments, purified CD34+ cells could be obtained from G-CSF-stimulated PBSC in large numbers (1.71 +/- 0.19 x 10(8)), with high purity (93 +/- 2.4%) and excellent recovery (64.28% - 85.62%). Immune reactive T and NK cells were adequately depleted to less than 0.2%. The purification procedure can be completed within 3 hours. In conclusion, a clinical stem cell purification program using this novel device is now established in Thailand and for the first time in Southeast Asia. This should allow further development of advanced SCT therapy including haploidentical and mismatched CD34+ SCT for patients' lacking HLA-identical donors in this region.

The possible cost effectiveness of peripheral blood stem cell mobilization with clophosphamide and the late addition of G-CSF

The purpose of this study was to develop a cost-effective protocol for the mobilization of peripheral blood stem cells (PBSC) in patients with malignancy. Thirty consecutive patients were randomized to mobilize PBSC with the late addition of a standard 250 microg dose of G-CSF (Neutrogen) from day 8 or early addition of the same dose of G-CSF from day 2, following cyclophosphamide (CY) 4 g/m2. The median yield of CD34+ cells from evaluated patients was 7.87 x 10(6)/kg (range, 2.06-27.25), collected in a median of four apheresis (range, 2-9). Target CD34 + cell doses > or = 2.0 x 10(6)/kg were achieved in all patients able to be evaluated. There were no statistically significant differences in CD34+ cell yields or toxicities. Overall engraftment occurred with median days to neutrophils > or = 0.5 x 10(9)/L or platelets > 20 x 10(9)/L of 11 and 17 days, respectively. However, the duration of G-CSF administration was markedly shorter in the late use of G-CSF group than in the early use of G-CSF group, with a median of 9 days compared with 15 days (p>0.001). PBSC harvesting after priming with CY plus delayed use of G-CSF made it a safe and cost-effective procedure.

Comparison of CD34+ subsets and clonogenicity in human bone marrow, granulocyte colony-stimulating factor-mobilized peripheral blood, and cord blood

To compare the clonogenicity and distribution of CD34+ subsets in bone marrow (BM), granulocyte colony-stimulating factor (G-CSF) mobilized peripheral blood (PB) and cord blood (CB), we analyzed in vitro colony formation and CD34+ cells co-expressing differentiation molecules (CD38, HLA-DR), myeloid associated molecules (CD13, CD33), a T-cell associated molecule (CD3), and a B-cell associated molecule (CD19) from mononuclear cells (MNCs) in the three compartments. The proportions of CD34+CD38- cells (BM: 4.4+/-2.8%, PB: 5.3+/-2.1%, CB: 5.9+/-3.9%) and CD34+HLA-DR cells (BM: 4.7+/-3.4%, PB: 5.5+/-2.3%, CB: 6.1+/-3.7%) did not differ significantly among the compartments. In contrast, a significantly higher proportion of CD34 cells of PB and CB co-expressed CD13 (75.0+/-11.4%, 77.7+/-17.3%) and CD33 (67.1 +/-5.7%, 56.8+/-10.3%) compared with those of BM (43.0+/-6.3%, 27.6+/-5.1%) and a significantly higher number of granulocyte-macrophage colony-forming units (CFU-GM) and erythroid burst-forming units (BFU-E) were detected in MNCs derived from PB and CB compared with those from BM (p<0.01). The proportion of CD34+CD19+ cells was higher in BM (34.9+/-11.9%) than those in PB (5.6+/-3.0%) and CB (4.7=2.1%) (p<0.05). The proportion of CD34+CD3+ was comparable in all three compartments. In conclusion, our findings show that MNCs of mobilized PB and CB display similar phenotypic profiles of CD34+ subsets and clonogenicity, different from those of BM.

Umbilical cord blood as a source of CD34 positive haematopoietic stem cells.

In this paper we have used a monoclonal antibody to CD34 an antigen expressed solely on stem cells, and stem cell colony assays to show that umbilical cord blood has nearly the same number of functional stem cells as compared to normal bone-marrow. The number of CD34+ve cells in cord blood being 2 to 2.7 per cent, whereas bone-marrow had 3 to 3.5 per cent. The multi-potent colony forming cells (CFU-GEMM) were 60 +/- 18 in cord blood per 2 x 10(5) mononuclear cells (MNCs), whereas normal bone-marrow had 70 +/- 10 per 2 x 10(5) MNCs. Enrichment of these stem cells on Percoll gradients was successful for normal bone-marrow but not for cord blood.

Studies on the pathogenesis of aplastic anemia in Thailand: evidence of immune-mediated mechanism.

The pathogenesis of aplastic anemia in Thailand was studied by using in vitro progenitor cells culture. In 37 patients who had active disease, the numbers of colonies derived from erythroid and granulocyte-macrophage progenitor cells (BFU-E and CFU-GM) were markedly decreased both in the blood and bone marrow as compared to normal controls. Co-culture of patients' cells with normal blood cells was performed in order to verify an immunologically mediated mechanism. In 8 of 26 patients, there were very low numbers of colonies both BFU-E and CFU-GM in the blood and bone marrow with significant suppression of colony formation in co-culture. Suppressor cells may have caused the aplasia in these patients. The rest had low colony formation and no suppression in co-culture. These patients may have absent or defective stem cells. None had normal colony formation. Therefore, aplastic anemia in Thailand may result mostly from defects involving the stem cells. Only some patients had cell mediated suppression of hematopoiesis as detected by co-culture.