Single platform flow cytometric absolute CD34+ cell counts based on the ISHAGE guidelines. International Society of Hematotherapy and Graft Engineering

In concert with the International Society of Hematotherapy and Graft Engineering (ISHAGE), we previously described a set of guidelines for detection of CD34+ cells based on a four-parameter flow cytometry method (CD45 FITC/CD34 PE staining, side and forward angle light scatter). With this procedure, an absolute CD34+ count is generated by incorporating the leukocyte count from an automated hematology analyser (two-platform method). In the present study, we modified the basic ISHAGE method with the addition of a known number of Flow-Count fluorospheres. To reduce errors inherent to sample washing/centrifugation, we implemented ammonium chloride lyse, no-wash no-fix sample processing. These modifications convert the basic protocol into a single-platform method to determine the absolute CD34 count directly from a flow cytometer and form the basis of the Stem-Kit from Coulter/Immunotech. A total of 72 samples of peripheral blood, apheresis packs, and cord blood were analysed and compared using the ISHAGE protocol with or without the addition of fluorescent microspheres. Comparison of methods showed a high correlation coefficient (r=0.99), with no statistically significant difference or bias between methods (P > 0.05). Linearity of the absolute counting method generated an R2 value of 1.00 over the range of 0-250/microl. Precision of the absolute counting method measured at three concentrations of CD34+-stabilised KG1 a cells (Stem-Trol, COULTER) generated a coefficient of variation (C.V.) ranging from 4% to 9.9%. In a further modification of the single-platform method, the viability dye 7-amino actinomycin D was included and demonstrated that both viable and nonviable CD34+ cells could be identified and quantitated. Together, these modifications combine the accuracy and sensitivity of the original ISHAGE method with the ability to produce an absolute count of viable CD34+ cells. It is the accurate determination of this value that is most clinically relevant in the transplant setting. These modifications may improve the interlaboratory reproducibility of CD34 determinations due to the reduction in sample handling and calculation of results.

Flow cytometric enumeration of CD34+ hematopoietic stem and progenitor cells. European Working Group on Clinical Cell Analysis

The need for a rapid and reliable marker for the engraftment potential of hematopoietic stem and progenitor cell (HPC) transplants has led to the development of flow cytometric assays to quantitate such cells on the basis of their expression of CD34. The variability associated with enumeration of low-frequency cells (i.e., as low as 0.1% or 5 cells/microl) is exceedingly large, but recent developments have improved the accuracy and precision of the assay. Here, we review and compare the major techniques. Based on the current state of the art, we recommend 1) bright fluorochrome conjugates of class II or III monoclonal antibodies (mAbs) that detect all glycoforms of CD34, 2) use of a vital nucleic acid dye to exclude platelets, unlysed red cells, and debris or use of 7-amino actinomycin D to exclude dead cells during data acquisition, 3) counterstaining with CD45 mAb to be included in the definition of HPC, 4) during list mode data analysis, Boolean gating to resolve the CD34+ HPCs from irrelevant cell populations on the basis of the low levels of CD45 expression and low sideward light-scatter signals of HPCs, 5) inclusion of CD34dim and CD34bright populations in the CD34+ cell count, 6) omission of the negative control staining, and 7) for apheresis products, enumeration of at least 100 CD34+ cells to ensure a 10% precision. Unresolved technical questions are 1) the replacement of conventional dual-platform by single-platform assay formats, i.e., derivation of absolute CD34+ cell counts from a single flow cytometric assessment instead of from combined flow cytometer (percent CD34+) and hematology analyzer (absolute leukocyte count) data, 2) the cross-calibration of the available single-platform assays, and 3) the optimal method for sample preparation. An important clinical question to be addressed is the definition of the precise phenotypes and required numbers of HPCs responsible for short- and long-term recovery to optimize HPC transplant strategies.

High level engraftment of NOD/SCID mice by primitive normal and leukemic hematopoietic cells from patients with chronic myeloid leukemia in chronic phase

We have previously shown that intravenously injected peripheral blood (PB) or bone marrow (BM) cells from newly diagnosed chronic myeloid leukemia (CML) patients can engraft the BM of sublethally irradiated severe combined immunodeficient (SCID) mice. We now report engraftment results for chronic phase CML cells in nonobese diabetic (NOD)/SCID recipients which show the superiority of this latter model. Transplantation of NOD/SCID mice with 7 to 10 x 10(7) patient PB or BM cells resulted in the continuing presence of human cells in the BM of the mice for up to 7 months, and primitive human CD34+ cells, including those detectable as colony-forming cells (CFC), as long-term culture-initiating cells, or by their coexpression of Thy-1, were found in a higher proportion of the NOD/SCID recipients analyzed, and at higher levels than were seen previously in SCID recipients. The human CFC and total human cells present in the BM of the NOD/SCID mice transplanted with CML cells also contained higher proportions of leukemic cells than were obtained in the SCID model, and NOD/SCID mice could be repopulated with transplants of enriched CD34+ cells from patients with CML. These results suggest that the NOD/SCID mouse may allow greater engraftment and amplification of both normal and leukemic (Ph+) cells sufficient for the quantitation and characterization of the normal and leukemic stem cells present in patients with CML. In addition, this model should make practical the investigation of mechanisms underlying progression of the disease and the development of more effective in vivo therapies.

Efficient adenovirus-mediated gene expression in malignant human plasma cells: relative lymphoid cell resistance

Although adenoviruses offer several potential advantages as gene transfer vectors, some hematopoietic cells, particularly lymphoid cells, are considered relatively resistant to adenovirus-mediated gene transfer. To examine the role of adenovirus-mediated gene transfer in the lymphoid malignancy multiple myeloma (MM), we used E1- and E3-deleted adenoviral vectors to infect myeloma and lymphoma cell lines and subsequently primary bone marrow plasma cells and lymphocytes from patients with MM. Adenoviral vectors expressing LacZ or luciferase (AdCA18) reporter genes were used initially. Subsequently, we studied adenoviral vectors expressing genes of potential value in therapeutic immunomodulation, i.e., CD80 (AdB7-1) and interleukin-2 (AdIL-2). A human plasma cell line (OCI-My5) infected with LacZ or AdB7-1 vectors expressed the corresponding gene product in 95% and 85% of exposed cells, respectively. Time course experiments indicated that maximum expression of adenoviral transgenes in plasma cells was reached 3 days after infection. IL-2 was detected in the supernatant of AdIL-2-infected plasma cells, was functional, and could be detected for at least 30 days after infection. In contrast, three lymphoma cell lines (OCI-Ly2, OCI-Ly13.2, and OCI-Ly17) were significantly less sensitive to adenovirus infection, with relatively low efficiencies of gene transfer even using high adenoviral titers: Surface CD80 expression (13-25% of infected cells) and positive LacZ staining (0-5% of infected cells). Indeed, expression of luciferase was 96-168 times higher in AdCA18-infected OCI-My5 cells than in the OCI-Ly2 lymphoma cell line. Similar patterns were observed in primary plasma cells and lymphocytes from 19 MM patient bone marrow samples. After infection with AdB7-1, increased levels of CD80 expression on CD38 bright bone marrow plasma cells were observed in 84% of patients, with a 33% average increase in the number of plasma cells expressing CD80. In contrast, although increased CD80 expression was also detected on AdB7-1-infected CD19+ B lymphocytes from 63% of the MM patients, an average of only 14% of the infected lymphocytes demonstrated increased expression of CD80. Circulating T lymphocytes could not be transduced with AdB7-1. The relative resistance of B and T lymphocytes to adenovirus-mediated gene transfer warrants further investigation. Adenoviral vectors can efficiently infect malignant plasma cells and may be useful vehicles for therapeutic gene transfer.

Quality assurance of stem cell enumeration by flow cytometry. Canadian QASE Study Group

The enumeration of CD34+ cells by flow cytometry is commonly employed to assess progenitor/stem cell numbers in peripheral blood, cord blood, and apheresis products used for peripheral blood stem cell transplantation (PBSCT). Until recently, the enumeration of CD34+ cells has evolved in the absence of any procedural guidelines or quality assurance programs. We established a voluntary quality assurance for stem cell enumeration (QASE) program for Canadian laboratories involved in PBSCT. The goals of this study were 1) to survey current flow cytometric procedures for CD34 enumeration; 2) to evaluate inter-institutional reproducibility of currently employed assays; and 3) to evaluate the impact of adoption of a common method on inter-laboratory variability. Fourteen to nineteen laboratories participated in this program by enumerating CD34+ cells in shared cord blood samples. The survey showed a wide variation in flow cytometric methodology which in part contributed to the wide range in results obtained between different centres. Major differences in methodology included the number of events counted, use of isotype control and gating strategy. Participation in this program and adoption of a common methodology increased level of agreement for any given result although this trend did not reach statistical significance (P = 0.13). The results of this survey emphasize the need for a quality assurance program for stem cell enumeration by flow cytometry.

In vitro maintenance and retroviral transduction of human myeloma cells in long-term marrow cultures

One objective of clinical gene marking trials in multiple myeloma (MM) is to determine the extent to which relapse after stem cell transplant is attributable to contamination of the autograft with myeloma cells. A requirement in these studies is ex vivo genetic marking of malignant cells present in autografts which are derived from patients exposed to significant prior chemotherapy. We evaluated gene marking of cloonogenic myeloma cells in marrow aspirates from 14 patients with MM. To effect gene transfer we utilized a long-term marrow culture (LTMC) system previously shown to facilitate gene transfer into a spectrum of hematopoietic progenitor and stem cells. Transduction of cells in LTMC was performed by multiple supernatant exposure. At LTMC initiation and after 21 days of culture malignant cells were assessed by morphology, flow cytometry, and polymerase chain reaction (PCR). The mean number of day 21 LTMC adherent layer-derived granulocyte/macrophage progenitors as a percentage of the original inoculum was within the normal range for this technique. The efficiency of transduction of normal hematopoietic progenitors as determined by the number of colonies positive for proviral DNA by PCR, G418 resistance, and X-gal staining was also within the expected range; 65%, 44% and 23%, respectively. Thus, there was no evidence that prior chemotherapy exposure or malignant cell contamination compromised cell survival or gene transfer efficiency in LTMC. All patients retained plasma cells in LTMCs for the duration of the 21-day culture period. Molecular analysis confirmed the persistence of clonal IgVH gene rearrangements in day 21 LTMC-derived DNA from 6 of 12 informative patients (50%). PCR using allele-specific primers when available confirmed the specificity of IgVH rearrangements for the myeloma clone. In 2 of the 14 patients, expansion of clonogenic cells was demonstrated in LTMC. In both cases there was strong evidence for transfer of reporter genes (neo and LacZ) into the myeloma clone: morphologically abnormal G418-resistant colonies demonstrated intense staining for beta-galactosidase, and cytospin preparations showed 100% plasma cells with monoclonal heavy and light chain restriction. In one patient, individual colonies positive for beta-galactosidase bore a cytogenetic abnormality characteristic of the patient's myeloma clone. PCR of DNA from pooled plasma cell colonies using tumor-specific CDR3 primers was positive. Our results demonstrate the maintenance of myeloma cells in vitro for up to 21 days in LTMC. They further illustrate that these cells can be genetically marked using transduction protocols currently being tested in clinical trials of hematopoietic cell gene transfer.

Increased levels of CD34+ hemopoietic progenitor cells in atopic subjects

We investigated the contribution of hemopoietic progenitors to the accumulation of inflammatory cells in allergic airways disease. Using a multiparameter flow-cytometric method, the detection of peripheral blood (PB) and bone marrow (BM) cells expressing CD34, a progenitor cell marker, was explored. True CD34+ blast cells were detected as a discrete cluster exhibiting low intensity CD45 expression, low granularity, and low to intermediate cell size. A significantly greater number of CD34+ cells was detected in the PB of atopic individuals (1,438 +/- 347/10(6) nonadherent mononuclear cells [NAMNC], n = 19) compared with nonatopics (236 +/- 77/10(6) NAMNC, n = 13; P = 0.006). Similarly, in BM samples, a significantly greater number of CD34+ cells was detected in atopic (17,537 +/- 4,986/10(6) NAMNC, n = 7) compared with nonatopic subjects (6,422 +/- 1,853/10(6) NAMNC, n = 13, P = 0.02). Greater numbers of total colony-forming units (CFU) (granulocyte/macrophage [GM] and Eo/Baso) were present in cultures of PB NAMNC from atopics (24 +/- 5 CFU/10(6) NAMNC) cultured with recombinant human interleukin 5 (rhIL-5) (1 ng/ml) compared with nonatopics (5 +/- 2 CFU/10(6) NAMNC; P = 0.003). Analyses of colony subtypes showed significantly greater numbers of IL-5-responsive Eo/Baso-CFU in cultures from atopics (15 +/- 2 CFU/10(6) NAMNC) compared with nonatopics (5 +/- 2 CFU/10(6) NAMNC; P = 0.011). In contrast, no significant differences in colony counts were found between the two subject groups in cultures with rhIL-3 (1 ng/ml) or rhGM-CSF (10 ng/ml). A positive correlation was observed between PB CD34+ cell numbers and total CFU in cultures with rhIL-5 (r = 0.43, n = 32, P = 0.01) and rhGM-CSF (r = 0.45, n = 32, P = 0.009). Purging BM NAMNC with an anti-CD34 monoclonal antibody completely abrogated in vitro colony growth, supporting the view that a subset of CD34+ cells represents the relevant population of progenitors growing in culture. These data indicate that flow cytometric estimation of CD34+ cells is predictive of the colony-forming capacity of the sample and may be a useful alternative tool to clonogenic assays for enumerating progenitors. In addition, raised levels of CD34+ cells and IL-5-responsive Eo/Baso-CFU in atopics, including patients with atopic asthma, indicate a role for progenitors in allergic airways disease.

Identification of CD34+ subsets after glycoprotease selection: engraftment of CD34+Thy-1+Lin- stem cells in fetal sheep

Epitopes on the CD34 molecule detected by some CD34 antibodies can be cleaved by a unique glycoprotease from Pasteurella haemolytica, which cleaves only glycoproteins rich in O-linked glycans. A method to isolate CD34+ cells from adult bone marrow was developed subsequently, in which CD34+ cells were isolated in high purity and yield following immunomagnetic bead selection and detachment with the glycoprotease. Using a variety of other cell-surface markers shown here to be insensitive to glycoprotease, committed progenitors of T lymphoid, B lymphoid, monomyeloid, megakaryoblastic, or erythroid lineages could be identified. Significantly, candidate hematopoietic stem cells (HSC) that are contained within a CD34+Lin- (CD2-, CD14-, CD15-, CD16-, CD19-) (or CD34+CD38-) subset expressing the Thy-1 antigen (CDw90), c-kit receptor (CD117), and CDw109 but lacking expression of CD71 and HLA-DR antigens also were detected. Functionally distinct subsets of glycoprotease-selected CD34+ cells were identified and subfractionated using flow cytometry and fluorescence-activated cell sorting (FACS). These subsets included candidate HSCs expressing the CD34+Thy-1+Lin- phenotype, which were sorted from a CD34+ fraction of a mobilized peripheral blood (MPB) sample. In a fetal sheep model, when CD34+Thy-1+Lin- cells were injected intraperitoneally, they were capable of homing to the marrow, where they generated long-term multilineage hematopoiesis and maintained human CD34+ cells, indicating that candidate HSC subsets of CD34+ cells selected with this highly specific enzyme were capable of engraftment in vivo. The ability to identify and purify virtually any phenotypically defined subset of glycoprotease-selected CD34+ stem/progenitor cells should facilitate the study of hematopoiesis in vitro and in animal models in vivo as well as the development of novel genetic techniques for the correction of specific blood cell disorders in humans.

The ISHAGE guidelines for CD34+ cell determination by flow cytometry. International Society of Hematotherapy and Graft Engineering

The increased use of Peripheral Blood Stem Cells (PBSC) to reconstitute hematopoiesis in autotransplant and, more recently, allotransplant settings has not been associated with a consensus means to quality control the PBSC product. Since the small population of cells that bear the CD34 antigen are thought to be responsible for multilineage engraftment, graft assessment by flow cytometric quantitation of CD34+ cells should provide a rapid, reliable, and reproducible assay. Unfortunately, although a number of flow cytometric assays for CD34 enumeration have been described, the lack of a standardized method has led to the generation of widely divergent data. Furthermore, none of these assays has been validated as to interlaboratory reproducibility and suitability for widespread clinical application. In early 1995, the International Society of Hematotherapy and Graft Engineering (ISHAGE) established a Stem Cell Enumeration Committee, the mandate of which was to validate a simple, rapid, and sensitive flow cytometric method to quantitate CD34+ cells in peripheral blood and apheresis products. We also sought to establish its utility on a variety of flow cytometers in clinical laboratories and its reproducibility between transplant centers. Here, we describe the four-parameter flow methodology adopted by ISHAGE for validation in a multicenter study in North America.

Peripheral blood progenitor cell collections in multiple myeloma: predictors and management of inadequate collections

Thirty-seven patients with previously treated multiple myeloma (MM) underwent peripheral blood progenitor cell (PBPC) collection following high-dose cyclophosphamide and GM-CSF or sequential IL-3 and GM-CSF. Patients with an inadequate collection were considered for a second or third collection. 25 patients underwent subsequent autotransplant. The only variable predictive of CFU-GM yield was the extent of prior melphalan therapy. All repeat collections were unsuccessful and patients infused with an autograft obtained from multiple sets of collections had a high incidence of delayed engraftment. We conclude that melphalan should be avoided or PBPC collection performed early in the disease course in patients who are potential transplant candidates.

Fetal bone marrow CD34+CD41+ cells are enriched for multipotent hematopoietic progenitors, but not for pluripotent stem cells

We have investigated the expression of CD41a (gpIIbIIIa) on a subpopulation of human fetal bone marrow (FBM) CD34+ progenitor cells. Human FBM CD34+Lin- cells were subfractionated into CD41a+ and CD41a- subpopulations by flow cytometry. All the megakaryocyte colony-forming cells (CFU-MK) and almost all the burst-forming units-megakaryocyte (BFU-MK) were found within the CD41a+ subpopulation. In addition, a 14-fold greater number of granulocyte-macrophage colony-forming units (CFU-GM) and a five-fold greater number of mixed lineage progenitor cells (CFU-mix) were observed within the CD34+Lin-CD41a+ subpopulation compared to the CD34+Lin-CD41a- subpopulation. The high proliferative potential of CD34+Lin-CD41a+ cells was demonstrated by their capacity to expand in in vitro culture containing human plasma and recombinant Mpl ligand (thrombopoietin [Tpo]) with production of over 80% CD41b+ (gpIIb+) MKs. However, in long-term bone marrow cultures, the CD34+Lin-CD41a- population contained a significantly higher frequency of cobblestone area-forming cells (CAFC) than the CD34+Lin-CD41a+ population, indicating the presence of a primitive hematopoietic stem cell (HSC) population within the CD34+Lin-CD41a- subset. These data suggest that fetal CD34+Lin-CD41a+ cells are enriched for MK progenitor cells (CFU-MK and BFU-MK), myeloid progenitors, and CFU-mix but do not contain the more primitive CAFC.

Optimizing the CD34+ and CD34+Thy-1+ stem cell content of peripheral blood collections

We have previously described a sensitive and specific CD34 enumeration assay and report here a prospective analysis of 25 myeloma patients undergoing PBSC mobilization using this assay to determine the optimal days for collection of CD34+ and CD34+Thy-1+ cells after chemotherapy and growth factor mobilization. Correlations between frequency of peripheral blood CD34+ cells, circulating white blood cell (WBC) count, apheresis CD34+ cell count, nucleated cell count (NCC), and numbers of apheresis colony-forming units granulocyte/macrophage (CFU-GM) were determined. To assess levels of the more primitive subsets of CD34+ cells in the PBSC collections, coexpression of the Thy-1 antigen (CDw90) on CD34+ cells was also assessed. Marked heterogeneity was noted between patients with apheresis samples containing a median NCC of 4.2 x 10(8)/kg (range 1.3-8.1), median CFU-GM 17 x 10(4)/kg (range 0.15-32 x 10(4)/kg), and median CD34+ cell count of 1.39 x 10(6)/kg (range 0.02-6.6). The frequency of CD34+ cells in PBSC collections coexpressing Thy-1 was also heterogenous (6.2-50% of CD34+ cells), median 21.6%, mean 24.7 +/- 2%. The apheresis CD34+ cell count correlated with the peripheral blood CD34+ cell percentage (r = 0.71, p < 0.0001) but only weakly with the peripheral WBC. Apheresis CD34+Thy-1+ cell numbers correlated strongly with the circulating CD34+ cell numbers (r = 0.80), but no correlation was noted between these candidate stem cells and the peripheral WBC. In contrast, apheresis CFU-GM levels correlated most strongly with the peripheral WBC count (r = 0.61, p < 0.0001). The apheresis CD34+ cell count correlated with apheresis CFU-GM (r = 0.75, p < 0.0001) but not with the apheresis NCC. Apheresis CD34+Thy-1+ counts significantly correlated only with the apheresis CD34+ cell count and not with the apheresis CFU-GM or NCC. A higher percentage of circulating and apheresis CD34+ cells expressing Thy-1 were found on day 1 of collection, and the percentage of CD34+ cells expressing Thy-1 decreased on each subsequent day of measurement: median of 22% day 1 vs. 16.6% day 4, p = 0.04. This study therefore confirms that accurate quantitation of circulating CD34+ cells best predicts the optimal day for apheresis collection of CD34+ and CD34+Thy-1+ cells and is superior to the WBC count in this regard. Furthermore, the candidate stem cell (CD34+Thy-1+) subset is most prevalent during the earliest phases of CD34+ cell mobilization.

Microbial biotransformation of the angiotensin II antagonist GR117289 by Streptomyces rimosus to identify a mammalian metabolite

Screening a range of microorganisms incubated with the angiotensin II antagonist GR117289 resulted in the use of Streptomyces rimosus to generate five related biotransformation products. These comprised three compounds hydroxylated on the aliphatic side chain, one further oxidized to a ketone, and one hydroxylated on the phenyl ring. These microbial metabolites were used as standards to identify a human metabolite detected in plasma and urine, but present in insufficient quantities for full structural characterisation. This further demonstrates how the use of microbial biotransformation systems at an early stage of drug metabolism studies can act as a valuable tool in facilitating identification of minor human metabolites.

Sensitive detection and enumeration of CD34+ cells in peripheral and cord blood by flow cytometry

Peripheral blood stem cell autografts are increasingly used to reconstitute hematopoiesis after intensive, potentially marrow-ablative therapy. Assessment of autograft adequacy by enumeration of hematopoietic progenitors in colony-forming assays is handicapped by lack of reproducibility and prolonged assay time. Alternative approaches of graft assessment by flow-cytometric enumeration of stem/progenitor cells bearing the CD34 antigen can be hampered by low specificity and sensitivity. Here, we report a rapid and reliable multiparameter flow-cytometric approach to accurately enumerate CD34+ cells in peripheral blood (PB) mononuclear cells (MNCs). Total nucleated white blood cells (WBCs) are quantified by staining with fluorescein isothiocyanate (FITC)-conjugated CD45 antibody. Simultaneous staining by phycoerythrin (PE)-conjugated CD34 antibody defines an approximate number for the CD34+ progenitor/stem cell subfraction. When starting CD34+ cell numbers are low (0.01-0.5%), other nonspecifically stained leukocytes make accurate enumeration impossible. However, when the CD34+ fraction is analyzed for CD45 expression vs. side scatter (granularity), true CD34+ blast cells form a discrete cluster exhibiting low-density CD45 expression and low side-scatter characteristics. Cells within this "blast region" can be readily distinguished from lymphocytes, monocytes, granulocytes, and other events that can contaminate the CD34+ population. Here, we used this sensitive procedure to enumerate CD34+ cells in steady-state PB samples (0.03-0.09%), normal bone marrow (BM) aspirates, and umbilical cord blood collections (0.33-1.98%). This approach thus provides a means to analyze CD34+ cells in specimens from patients who have been extensively treated with chemotherapy and those undergoing PB stem cell mobilization with cytokines. Additionally, it is useful for assessment of CD34+ cells in a variety of clinical samples exhibiting perturbations of the hematopoietic progenitor/stem cell compartments.

Tools to cleave glycoproteins

There are a variety of enzymes available that are able to cleave glycoproteins, including enzymes that are specific for carbohydrate-carbohydrate linkages, carbohydrate-protein bonds and the peptide backbone. Such enzymes are useful for determining the sites of glycosylation within proteins, and for releasing glycan structures for subsequent carbohydrate analysis. One protease has been identified as being specific for O-sialoglycoproteins and can be used to identify such molecules and their epitope regions. The lack of cytotoxicity and the narrow specificity of this enzyme provides an improved method for the immunomagnetic selection of human bone-marrow stem-cells.

CD34 antigen: molecular features and potential clinical applications

Despite the wide variety of functions exhibited by mature peripheral blood cells, all are derived from a small pool (1-3%) of primitive precursor cells in the bone marrow (BM) that bear a unique surface glycoprotein, CD34. Isolated CD34+ cells are capable of reconstituting all hematopoietic lineages, both in experimental animals and in humans following intensive therapy. CD34+ cells capable of reconstituting hematopoiesis are also found at low frequency in peripheral blood (PB), a frequency which can be dramatically increased by combinations of chemotherapy and recombinant cytokines. In some cases, PB "stem cells" (PBSC) can be used to augment or even replace conventional BM autografts. The availability of CD34 antibodies has greatly aided the development of techniques for the enrichment of primitive progenitor cells, thus allowing studies of the hematopoietic potential of stem cells in vitro. Additionally, the use of CD34 antibodies for the "positive selection" of hematopoietic stem/progenitor cells from tumor-contaminated marrow may possibly represent an alternative "purging" strategy prior to transplantation. The availability of pure populations of the most primitive hematopoietic progenitor cells will also facilitate study of genetic manipulation as a practical therapeutic modality.

Role of aberrant sialylation of chronic myeloid leukemia granulocytes on binding and signal transduction by chemotactic peptides and colony stimulating factors

Chronic myelogenous leukemia (CML) granulocytes exhibit a number of characteristics attributable to immature granulocytes, including marked increases in cell surface sialylation of glycoproteins which may be due, at least in part, to an increased activity of cytidine 5'-monophosphate-N-acetylneuraminic acid:Ga1 beta 1-3Ga1NAc alpha(2-3)-sialyltransferase (EC 2.4.99.4), and perhaps to altered activity of other glycosyltransferases and sialidases. This aberrant sialylation of CML granulocytes contributes to the decreased binding of the synthetic chemotactic peptide, formyl Met Leu Phe (fMLP), to the surface of CML granulocytes which leads to a rapid, transient increase in cytosolic free calcium ([Ca2+]i), an integral step in the biochemical cascade leading to cell activation. To determine if the decrease in binding of fMLP to CML granulocytes translates into a functional deficit, we measured fMLP-induced increases in [Ca2+]i. Compared to normal granulocytes, fMLP-induced increases in [Ca2+]i were markedly decreased in CML granulocytes. After sialidase treatment, a significant augmentation in fMLP-induced increases in [Ca2+]i was noted in CML granulocytes, indicating that the decreased signalling may be a consequence of aberrant sialylation. To determine if the effects of aberrant sialylation also alters the binding of endogenous polypeptide mediators, we determined the effect of desialylation of CML and normal granulocytes on binding of the colony stimulating factor for granulocytes and monocytes (GM-CSF), which plays a role in differentiation and proliferation of myeloid-lineage cells. As with fMLP binding, we also showed that the binding of GM-CSF to CML granulocytes, but not normal granulocytes, was markedly increased after sialidase treatment. Similarly, binding of GM-CSF to undifferentiated HL-60 cells was markedly increased after sialidase treatment. Therefore, we have demonstrated that aberrant sialylation of CML granulocytes not only alters the binding of fMLP and GM-CSF to their receptor(s), but may also alter signal transduction. Thus, aberrant glycosylation of CML granulocytes may reduce the binding of hematopoietic growth factors, which in turn may be responsible for the immature phenotype of CML granulocytes.

Characterization of canine platelet P-selectin (CD 62) and its utility in flow cytometry platelet studies

1. P-selectin (PADGEM, GMP140, or CD62) a member of lectin-like adhesive proteins is expressed on the surface of activated degranulated canine platelets and is the calcium-dependent receptor for leukocyte adhesion. 2. The electrophoretic mobility of P-selectin, by Western blot analysis and immunoprecipitation from radiolabeled membranes of canine and human platelets, was similar or identical and immunocytochemical studies localized P-selectin in internal vesicles similar to the alpha granule localization in human platelets. 3. Two antibodies to human P-selectin KC4.1 and AC1.2 crossreacted with canine platelets whose surface binding, in response to agonists thrombin, calcium ionophore (A23187), phorbol esters and ADP, was similar. 4. Anti-P-selectin antibodies in conjunction with crossreacting anti-GPIIb/IIIa antibodies (A2A9, 7E3, RUU-PL7F12) enables the analysis of activated platelets, platelet-derived microparticles and platelet-leukocyte interactions in canine models by flow cytometry.

Activated protein kinase C directly phosphorylates the CD34 antigen in acute lymphoblastic leukemia cells

The precursors of all blood cell lineages are contained within the 1-3% of bone marrow cells which express the CD34 antigen, and this population can reconstitute the hematopoietic system of lethally irradiated animals and humans. A potential regulatory role for the CD34 antigen in progenitor cell function and differentiation was indicated by our recent findings that the CD34 antigen can be phosphorylated in vivo to high stoichiometry in primitive CD34+ cell-lines by activated protein kinase C. To exclude the possibility that these effects were restricted to cell-lines, we have performed similar experiments on fresh cells from a patient with drug-resistant acute lymphoblastic leukemia. Similar to our previous findings, we found the CD34 antigen to be hyperphosphorylated in lymphoblasts labeled in the presence of active phorbols. The same peptides which were hyperphosphorylated in phorbol-stimulated cell-lines were also phosphorylated in phorbol-stimulated lymphoblasts. These data indicate that CD34 is a substrate molecule for PKC in fresh CD34+ lymphoblasts and underline the role of modulators of PKC activity in the biology of primitive leucocytes.

Retention of progenitor cell function in CD34+ cells purified using a novel O-sialoglycoprotease

We previously showed that the sialoglycoprotein, CD34, which is expressed on primitive human hematopoietic progenitor cells, is cleaved by a unique glycoprotease from Pasteurella haemolytica (P.h. glycoprotease). This proteolytic enzyme specifically cleaves glycoproteins rich in O-sialoglycans. Glycoproteins containing only N-linked glycans are not cleaved. Cleavage of the CD34 antigen results in the loss of epitopes detected by five of seven CD34-designated antibodies. In this study, we investigated the role of the P.h. glycoprotease in isolating CD34+ cells from unfractionated normal human bone marrow mononuclear cells (MNCs), and determined the effect of the glycoprotease on the proliferative capacity of the progenitor-enriched fraction. CD34+ cells were isolated from MNCs using immunomagnetic beads attached via a CD34 antibody whose epitope is susceptible to removal by the cleavage with the glycoprotease. Subsequent cleavage with P.h. glycoprotease for 30 min at 37 degrees C released the CD34+ cells from the beads with a recovery of up to 78%. Using a CD34 antibody whose epitope was not removed by the glycoprotease, up to 95% of the recovered cells expressed CD34. Compared to unseparated MNCs, the CD34+ cells showed the following enrichment of committed hematopoietic progenitors, as assayed in semi-solid media: CFU-GM, 45-fold; CFU-M, 13-fold; BFU-E, 26-fold and CFU-GEMM, 81-fold. Hematopoiesis was also studied in two-stage long-term bone marrow cultures in which the CD34+ cells were co-cultured over irradiated, allogeneic adherent layers. Output of CFU-GM over a seven week period from these cultures was similar to that from control cultures with autologous adherent-cell-depleted marrow MNCs. These data suggest that the loss of O-sialo-glycosylated peptide moieties from P.h. glycoprotease-released CD34+ cells neither affects the functional capacity of committed progenitors, nor impairs the proliferation of long-term culture-generating cells. The P.h. glycoprotease can be used to facilitate the isolation and recovery of functionally competent CD34+ cells at high yield and purity, without prior removal of other adherent cells. The ability to rapidly purify CD34+ cells using this non-cytotoxic enzyme has important implications for bone marrow transplantation as well as for gene transfer studies in vitro.

Differential sensitivity of CD34 epitopes to cleavage by Pasteurella haemolytica glycoprotease: implications for purification of CD34-positive progenitor cells

Our previous studies have shown that a unique glycoprotease from Pasteurella haemolytica specifically cleaves only proteins containing sialylated O-linked glycans. The hematopoietic progenitor cell antigen, CD34, which is heavily glycosylated with both N- and O-linked glycans, is readily cleaved by this protease. In this study, we demonstrate that the epitopes detected by five of the seven CD34 monoclonal antibodies are removed by the glycoprotease. The differential sensitivity of the CD34 epitopes to cleavage with either neuraminidase and/or glycoprotease establishes three classes of epitopes: 1) (class I) those identified by MY10, B1.3C5, 12.8, and ICH3 that are differentially affected by neuraminidase and removed by the glycoprotease; 2) (class II) the epitope detected by QBEND 10 that is removed only by the glycoprotease; and 3) (class III) those identified by TUK3 and 115.2 that are not removed by either enzyme. Cleavage of the 110-kd CD34 structure by the glycoprotease generates a major cell-bound fragment of about 75 kd, identified by the class III antibodies. We have also used the enzyme to improve the rapid recovery of CD34+ cells selected by immunomagnetic affinity techniques. In a preclinical model, we separated CD34+ KG1 cells with high yield (90%-95%) and high purity (94%-98%) from sham mixtures containing 50% CD34- cells. We also separated CD34+ blast cells from a patient in megakaryoblastic crisis of chronic myelogenous leukemia. In this case, the purity and yield were 93% and 94%, respectively. Enzyme treatment had no detrimental effect on cell viability, and the treated cells showed a normal quantitative expression and distribution of CD34 antigen as assessed with class III antibodies. We conclude that the P. haemolytica glycoprotease has potential to improve the isolation, from human bone marrow, of primitive hematopoietic cells that carry the CD34 antigen.

Cleavage of the cell-surface O-sialoglycoproteins CD34, CD43, CD44, and CD45 by a novel glycoprotease from Pasteurella haemolytica

The study of structural/functional characteristics of the cell-surface glycoproteins of leukocytes has led to a better understanding of the differentiation and maturation of hematopoietic cells. We have assessed the ability of a unique metalloprotease that is secreted by the bovine fibrinous pneumonia pathogen Pasteurella haemolytica, to cleave cell-surface glycoproteins expressed on human leukocytes. Biochemical analysis shows that the O-glycosylated cell surface Ag CD34, CD43 (leukosialin), CD44 (hyaluronic acid receptor), and CD45 (leukocyte common Ag), are all cleaved by this protease. Although these enzyme-sensitive structures contain N-linked glycans, they are all extensively glycosylated with O-linked carbohydrates, which are especially abundant on CD34 and CD43. In contrast, the glycoproteins CD18/11a,b,c (leukocyte integrins), CD71 (transferrin receptor), HLA class I, and 8A3 Ag, which contain N-linked glycans but no O-sialo-glycans, were resistant to the action of the enzyme. Inasmuch as previous studies using glycophorin A had indicated that the substrate specificity of this enzyme may be uniquely restricted to the cleavage of O-sialoglycoproteins, we have designated this activity, P. haemolytica glycoprotease. Immunofluorescence analysis with a variety of antibodies to different epitopes of the P. haemolytica glycoprotease-sensitive structures indicate that this enzyme may have widespread applications in epitope-mapping studies, and represents a novel tool with which to study structure/function relationships for O-sialoglycosylated cell-surface proteins. However, most significantly these results suggest that the P. haemolytica glycoprotease may be of use in the affinity purification and recovery of clinically important leukocyte subsets, such as primitive hematopoietic progenitors that express CD34.