CD34(+) cell collection efficiency does not correlate with the pre-leukapheresis hematocrit

One hundred and seventy-seven large-volume leukapheresis procedures performed on 91 patients over a 15 month period were reviewed to see if the pre-apheresis hematocrit (Hct) affected the CD34(+) cell collection efficiency (CE) of the Fenwal CS 3000 Plus cell separator. The Hct was 0.174-0.461 (median 0.317), and the peripheral blood CD34(+) cell count 2-2487 per microl (median 21). The total CD34(+) cell quantity collected was 3.0-2677.2 x 10(6) (median 113.0). Based on the number of CD34(+)cells contained in the blood volume processed (23.3-37303.2 x 10(6); median 318.0), the CE was 1.7-87.5% (median 30.3). No correlation was found between the Hct and CE (r(2) = 0.0034; P = 0.44) or the total CD34(+) cell quantity collected (r2 = 0.0040; P = 0.40). CEs for Hct <0.25 (median CE 36%), Hct 0.25-0.299 (median CE 30%) and Hct 0.30 (median CE 30%) were comparable. As expected, highly significant correlations were seen between the CD34(+) cell quantities collected and quantities processed (r2 = 0.59; P < 10(-6)) as well as the peripheral blood CD34(+) cell counts (r2= 0.60; P < 10(-6)). We conclude that the minimum acceptable Hct or hemoglobin level for leukapheresis should be dictated by clinical circumstances because it does not affect stem cell collection.     

Antibodies to CD44 enhance adhesion of normal CD34+ cells and acute myeloblastic but not lymphoblastic leukaemia cells to bone marrow stroma

The role of CD44 in the adhesion of haemopoietic cells to bone marrow stromal layers has not been clearly defined in humans, although its importance in the murine system has been well documented. We have demonstrated that the CD44 antibody, NIH44-1, enhances the adhesion of haemopoietic cells to bone marrow stroma. Normal human CD34⁺ haemopoietic progenitors and blasts from patients with acute myeloblastic, but not lymphoblastic, leukaemia responded to NIH44-1. All CD44 antibodies tested which bound the same epitope as NIH44-1 also augmented haemopoietic cell adhesion to bone marrow adherent layers; however, antibodies which bound to other CD44 epitopes showed mixed responses. Augmented adhesion was independent of cell metabolism, suggesting that antibody binding resulted in direct activation of the CD44 molecule. However, hyaluronic acid was not the ligand for induced adhesion, nor could we show a role for other CD44 ligands including fibronectin, laminin, collagen or chondroitin sulphate proteoglycan. Similarly, none of the 22 CD44 antibodies tested inhibited the stimulatory effect of the NIH44-1. Expression of CD44 was not sufficient to determine NIH44-1 responsiveness since cell lines and leukaemic cells which failed to respond to NIH44-1 expressed high levels of CD44. Neither CD44 isoforms nor glycosylation patterns could be identified as predictive of response. CD44 antibodies enhanced binding of normal and leukaemic haemopoietic progenitors to bone marrow fibroblasts via an unidentified stromal ligand.     

Expression of adhesion molecules on CD34+ cells: CD34+ L-selectin+ cells predict a rapid platelet recovery after peripheral blood stem cell transplantation

Adhesion molecules play a role in the migration of hematopoietic progenitor cells and regulation of hematopoiesis. To study whether the mobilization process is associated with changes in expression of adhesion molecules, the expression of CD31, CD44, L-selectin, sialyl Lewisx, beta 1 integrins very late antigen 4 (VLA-4) and VLA-5, and beta 2 integrins lymphocyte function-associated 1 and Mac-1 was measured on either bone marrow (BM) CD34+ cells or on peripheral blood CD34+ cells mobilized with a combination of granulocyte colony- stimulating factor (G-CSF) and chemotherapy. beta 1 integrin VLA-4 was expressed at a significantly lower concentration on peripheral blood progenitor cells than on BM CD34+ cells, procured either during steady- state hematopoiesis or at the time of leukocytapheresis. No differences in the level of expression were found for the other adhesion molecules. To obtain insight in which adhesion molecules may participate in the homing of peripheral blood stem cells (PBSCs), the number of CD34+ cells expressing these adhesion molecules present in leukocytapheresis material was quantified and correlated with hematopoietic recovery after intensive chemotherapy in 27 patients. The number of CD34+ cells in the subset defined by L-selectin expression correlated significantly better with time to platelet recovery after PBSC transplantation (r = - .86) than did the total number of CD34+ cells (r = -.55). Statistical analysis of the relationship between the number of CD34+L-selectin+ cells and platelet recovery resulted in a threshold value for rapid platelet recovery of 2.1 x 10(6) CD34+ L-selectin+ cells/kg. A rapid platelet recovery (< or = 14 days) was observed in 13 of 15 patients who received > or = 2.1 x 10(6) CD34+ L-selectin+ cells/kg (median, 11 days; range, 7 to 16 days), whereas 10 of 12 patients who received less double positive cells had a relative slow platelet recovery (median, 20 days; range, 13 to 37 days). The L-selectin+ subpopulation of CD34+ cells also correlated better with time to neutrophil recovery (r = - .70) than did the total number of reinfused CD34+ cells (r = -.51). However, this latter difference failed to reach statistical significance. This study suggests that L-selectin is involved in the homing of CD34+ cells after PBSC transplantation.     

不同来源的CD34^＋细胞归巢相关分子的表达

目的 研究不同来源CD34^＋细胞归巢相关分子（HRM）的表达情况。方法采用免疫磁珠法（MACS）分选不同来源的CD34^＋细胞，免疫荧光标记流式细胞仪测定HRM的表达。结果骨髓（BM）、动员后的外周血（mPB）及脐血（UCB）来源的CD34^＋细胞均高表达细胞黏附分子CD49d、CD49e、CD54、CD11a、CD62L、CD44、CD31。UCB来源的CD34^＋细胞表面表达的细胞黏附分子中，CD49e表达显著低于BM和mPB来源的CD34^＋细胞（P〈0．05），CD54表达显著低于mPB来源者（P〈0．05），CXCR4表达显著低于BM来源者（P〈0．05）。结论UCB来源的造血干／祖细胞归巢能力低可能是UCB移植造血重建延迟的原因之一。     

粒细胞集落刺激因子动员对CD34^＋细胞黏附分子表达的影响

目的探讨粒细胞集落刺激因子（G—CSF）动员对CD34^＋细胞黏附分子表达的影响。方法应用流式细胞仪检测健康供者稳态及G—CSF动员过程中骨髓、外周血CD34^＋细胞的黏附分子表达变化，并应用结晶紫染色测定CD34^＋细胞的黏附功能。结果G-CSF动员后CD34^＋CD49d^＋细胞比例无显著下降，外周血CD34^＋CD621．^＋、CD34^＋CD54^＋和CD34^＋CDlla^＋细胞比例增高。动员后CD34^＋细胞表面CD49d的平均荧光强度显著减弱，但CD49e、CD62L、CDlla、CD54的平均荧光强度虽呈减弱趋势，却无统计学差异。动员后CD34^＋细胞黏附纤连蛋白能力下降。结论G—CSF通过降低造血干细胞与骨髓基质的黏附而产生动员效应。     

CD34 expression is regulated reciprocally with adhesion molecules in vascular endothelial cells in vitro

Freshly cultured vascular endothelial cells express the CD34 antigen in a diffuse cell surface pattern with some concentration on microvilli. Expression is downregulated with proliferation in continuous culture and undetectable after nine population doublings but can be maintained by restraining cell proliferation and promoting cell contact. Expression of CD34 at the antigen and mRNA levels on early passage cells is rapidly downregulated by interleukin-1 beta (IL-1 beta), interferon-gamma (INF-gamma), and tumor necrosis factor-alpha (TNF- alpha) under conditions in which these ligands upregulate the adhesion molecules: endothelial leukocyte adhesion molecule 1 (ELAM-1) and intracellular adhesion molecule 1 (ICAM-1). This reciprocal pattern of expression and the topographic distribution of CD34 molecules on the lumenal interdigitated microprocesses of adjacent endothelial cells in vivo suggest that CD34 might have a negative modulating role on adhesion functions of endothelia.     

Expression and function of adhesion molecules on human hematopoietic stem cells: CD34+ LFA-1- cells are more primitive than CD34+ LFA-1+ cells.

Advances in fluorescence-activated cell sorter technology have brought about multicolor analysis of cell phenotypes. To clarify the phenotypes of human hematopoietic stem cells (HSCs), we initially prepared novel antibodies against CD34 and labeled one of them (4A1) with allophycocyanin (APC). With this, we analyzed the phenotypes of CD34+ HSCs and showed that primitive HSCs or CD34+CD33- cells expressed adhesion molecules such as CD43, CD44, CD11a, CD11c, CD18, and leukocyte adhesion molecule (LAM-1). The more primitive hematopoietic cells or CD34+CD38- cells also expressed CD11a and CD18 with an incidence of 20% to 30%. To clarify the role of adhesion molecules in HSCs, we examined the colony forming capacity after long-term culture with allogeneic irradiated stromal layers. Among CD34+CD33- cells, CD18+ cells gave rise to colony-forming cells (CFCs) on stromal layers, but reached a maximum at week 2, after which the number of generated CFCs decreased. On the other hand, CD18- cells generated less CFCs than CD18+ cells at 2 to 3 weeks, but increased after 4 weeks of culture. When CD18 or CD11a antibody was added to a coculture system of CD34+CD33- cells with stromal layers, the number of generated CFCs decreased significantly compared with the no antibody control. Leukocyte function-associated antigen-1 (LFA-1) (CD11a/CD18) was expressed on some populations of hematopoietic cells and contributed to the proliferation by interacting with stromal cells. However, more primitive cells capable of reconstituting hematopoiesis did not express LFA-1. These data provide a rationale for the administration of anti-LFA-1 antibody after bone marrow transplantation for reducing the graft failure.     

Expression of adhesion molecules on acute leukemic blast cells and sensitivity to normal LAK activity

Summary Antigenic expression of CD54 and CD58 adhesion molecules was investigated on leukemic blast samples from ten patients with acute lymphoblastic (ALL) and 14 with acute myeloblastic (AML) leukemia. The mean intensity of fluorescence (MIF) was calculated and correlated with sensitivity of blast cells to the lytic activity of allogeneic lymphokine-activated killer (LAK) cells. CD54 antigen was expressed in all AML cases with an MIF of 11.2 while in ALL, though present in the majority of cases, it was absent in one case and expressed in less than 30% of blasts in two others, with an overall MIF of 3.0. CD58 expression was similar in both groups of patients, with an MIF of 7.6 in ALL and 7.0 in AML. In addition, in six of the ten ALL cases and in two of the 14 AML cases, leukemic blasts proved to be resistant to the cytotoxic activity of normal allogeneic LAK effectors. In these LAK-resistant patients, the CD54 antigenic expression was lower (p=0.03) than in LAK-sensitive patients with an MIF of 1.7 vs 4.9 in ALL and 1.35 vs 12.9 in AML cases. Finally, blocking of CD54 and/or CD58 receptors on leukemic blasts resulted in a slight reduction of⁵¹Cr release. Findings suggest that CD54 is differently expressed on myeloid and lymphoid blasts and that there is a correlation between CD54 MIF and susceptibility of blasts to the LAK activity.     

Different expression of adhesion molecules on myeloid and B-lymphoid CD34+ progenitors in normal bone marrow

Abstract: The expression of adhesion molecules was studied on B lymphoid and myeloid CD34⁺ precursors in normal bone marrow. Bone marrow aspirates were labelled in a double fluorescence procedure with the CD34 monoclonal antibody 43A1 and with antibodies directed against maturation and differentiation antigens and adhesion molecules. Three clusters of CD34⁺ cells could be distinguished by their light scatter characteristics in flow cytometry. The population with the lowest forward scatter contained B-lymphoid precursors while the two others showed phenotypic characteristics of, respectively, early and late myeloid precursors. Nearly all CD34⁺ cells in the 3 subpopulations expressed VLA-4, VLA-5, LFA-3 and H-CAM. B-lymphoid progenitors showed a higher density of VLA-4 and VLA-5 than the myeloid progenitors. Myeloid precursors, and particularly the late subset, expressed more HCAM than the B-lymphoid progenitors. The majority of the CD34⁺ cells also expressed LFA-1 and L-selectin. Higher numbers of positive cells were found in the myeloid subset. The early myeloid subset showed the highest positivity for L-selectin. We conclude that B lymphoid and early and late myeloid CD34⁺ precursors in normal bone marrow show a different profile of adhesion molecules. These profiles could reflect a higher tendency of the myeloid CD34⁺ precursors to circulate.     

Different expression of adhesion molecules on CD34+ cells in AML and B-lineage ALL and their normal bone marrow counterparts.

The expression of adhesion molecules on CD34+ cells in acute myeloid leukemia (AML) and B-lineage acute lymphoblastic leukemia (B-lineage ALL) was compared with that on the myeloid and B-lymphoid CD34+ cells in normal bone marrow. Bone marrow aspirates of 10 patients with AML, 8 patients with B-lineage ALL and of 6 healthy volunteers were examined. The phenotype of the CD34+ cells was determined with a double immunofluorescence method and flow cytometry. CD34+ cells in AML and B-lineage ALL showed a lower expression of VLA-2 and VLA-3 and a higher expression of ICAM-1 and LFA-3 than their normal bone marrow counterparts. AML CD34+ cells had less L-selectin but more VLA-5 on their surface membrane than normal myeloid CD34+ cells. B-lineage ALL CD34+ cells showed an overexpression of LFA-3. In individual patients deficiencies or over-expression of the beta1 integrin chain, VLA-4, PECAM-1 or HCAM also occurred. An abnormal adhesive capacity of the leukemic cells may influence their proliferation, their localisation and apoptosis. An aberrant expression of adhesion molecules may be used for the detection of minimal residual leukemia in these patients.     

Adhesion molecules on CD 34+ hematopoietic cells in normal human bone marrow and leukemia

Summary Expression of selected adhesion molecules of the integrin and immunoglobulin family was investigated on CD 34+ leukemic cells in 19 AML and 11 ALL cases to evaluate phenotypic differences in adhesive properties of malignant hematopoietic precursor cells in comparison to normal bone marrow CD 34+ cells. Of the 2-integrin family, CD 11a was expressed on > 50% of CD 34+ cells in normal bone marrow and almost all leukemias, whereas CD 11 b and CD 11 c were not expressed on CD 34+ cells in normal bone marrow, but were found on CD 34+ blasts in some leukemias of a heterogeneous immunophenotype. Of the 1-family, CDw 49d (VLA-4) was strongly expressed on normal CD 34+ bone marrow cells and on the blasts of all 30 CD 34+ leukemic samples, whereas CDw 49 b (VLA-2) was absent on CD 34+ cells in normal bone marrow, but detected on CD 34+ cells in a few leukemias which did not constitute a clinical or phenotypic entity according to the FAB classification or immunocytological analysis. The lymphocyte-homing-associated adhesion molecule CD 44 (HCAM) and CD 58 (LFA-3) were expressed on CD 34+ cells in all investigated cases of normal and leukemic bone marrow. ICAM-1 (CD 54), the inducible receptor ligand for CD 11 a/CD 18, although present on CD 34+ cells in normal bone marrow, was lacking on blast cells of some ALL and AML cases. So far, the variable expression of 2-integrins as well as of VLA-2 and of ICAM-1 could indicate distinct differences in cell-cell or cell-matrix adhesion of leukemic cells in ALL and AML patients.     

Circulating CD34+ cells in cord blood and mobilized blood have a different profile of adhesion molecules than bone marrow CD34+ cells

Abstract: The expression of adhesion molecules was studied on CD34+ hematopoietic precursors in cord blood, bone marrow and mobilized blood. The samples were labeled in a double immunofluorescence procedure with a CD34 monoclonal antibody and with antibodies against maturation and differentiation antigens and adhesion molecules. Myeloid precursors formed the majority of the CD34+ cells in all samples. In bone marrow a separate cluster of B-cell precursors with low forward scatter was present. Nearly all CD34+ cells in normal bone marrow expressed VLA-4 and VLA-5, PECAM-1, LFA-3 and HCAM. The majority of the CD34+ cells also had LFA –1 and L-selectin on the surface membrane. A small subset was VLA-2, VLA-3, ICAM-1 or Mac-1 positive. CD34+ cells expressing the vitronectin receptor or the CD11c antigen were rare. Cord blood and mobilized blood CD34+ cells had a lower expression of VLA-2, VLA-3 and VLA-5 and a higher expression of LFA-1, ICAM-1 and L-selectin than bone marrow CD34+ cells. Except for LFA-1, this was not due to the presence of more myeloid precursors in these samples. Low β₁ integrin expression may lead to less adhesion to the extracellular matrix. High expression of L-selectin may facilitate interaction with endothelial cells. Therefore, this phenotype may favour mobilization.     

Expression of adhesion molecules LFA-3 and N-CAM on normal and malignant human plasma cells

Normal and malignant plasma cells were investigated for the expression of seven cellular adhesion molecules by immunofluorescence microscopy. The antigens investigated were CD2 and its ligand, LFA-3 (CD58). LFA-1 alpha (CD11a) and LFA-1 beta (CD18) and their ligand ICAM-1 (CD54), H-CAM (lymphocyte homing receptor; CD44) and N-CAM (CD56). Marrow from 18 patients with myeloma, two with plasma cell leukaemia (PCL), four with monoclonal gammopathy of uncertain significance (MGUS) and 10 normal allogeneic bone marrow donors was studied. All plasma cells from normals and multiple myeloma patients were negative for CD2, CD11a and CD18. All normal and myeloma marrow plasma cells were positive for ICAM-1. 16/18 myeloma cases tested, and all other samples (normal, MGUS and PCL), contained plasma cells positive for H-CAM. Only one normal, but 12/16 myelomas tested were positive for N-CAM (P less than 0.02). One of four MGUS cases was moderately positive and one other weakly positive for N-CAM. Both PCLs were N-CAM negative. 12/18 myelomas were positive for LFA-3, but only two normals (P less than 0.05). All MGUS cases were negative for LFA-3, as was one PCL, the other being weakly positive. Three cases were negative for both adhesion molecules, three cases expressed only N-CAM or LFA-3 and 10 cases expressed both. LFA-3 and N-CAM are expressed significantly in myeloma rather than normal plasma cells. Cases of MGUS may express N-CAM but not, in this small series, LFA-3. Plasma cells in the peripheral blood (PCL) and plasma cell lines express little or no LFA-3 or N-CAM.     

CD34 expression on murine marrow-derived mesenchymal stromal cells: impact on neovascularization

OBJECTIVE: CD34 is a sialomucin often expressed by cells with hemangiopoietic potential and widely serves as a surrogate marker of stem cell potential. Mesenchymal stromal cells (MSCs) also express CD34, although the functional significance of its expression remains undefined. In this study, we determined whether CD34(pos) MSCs are functionally distinct from CD34(null) MSCs. MATERIALS AND METHODS: MSCs derived from C57Bl/6 mice were transduced to express the green fluorescent protein (GFP) from which pure CD34(pos) MSC and CD34(null) MSC clones were selected. In vitro, clones were examined by microarray analysis, while in vivo subcutaneous implantation of matrix-embedded MSCs was used to assess cell survival, differentiation, and neovascularization. RESULTS: The flow cytometric phenotype of CD34(pos) and CD34(null) MSCs were similar, as was gene expression of vascular endothelial growth factors (VEGFs) A and B. However, CD34(pos) MSCs upregulated a number of supplementary angiogenesis-associated genes and showed a greater expression of gene associated with vascular differentiation. At 15 days postimplantation, cell survival between CD34(pos) and CD34(null) MSCs was similar, however, CD34(pos) MSCs evoked a significantly greater host-derived response (4.2 +/- 0.7 vs 1.9 +/- 0.5 x 10(6) cells; p < 0.05). GFP-expressing CD34(pos) MSC implants acquired significantly more CD31 expression compared to CD34(null) MSC cells (10.7% +/- 8.4% vs 3.1% +/- 0.6%; p < 0.05), as well as a significantly greater host-derived endothelial cell influx (CD31(+)/CD45(-)). CONCLUSION: CD34 expression by MSCs correlates with enhanced vasculogenic and angiogenic potential in vivo.