Flow cytometric evaluation of canine bone marrow differential cell counts

Abstract: Three flow cytometric techniques were evaluated for determination of differential cell counts on canine clinical bone marrow specimens. Techniques included staining bone marrow specimens with 2'7'-dichlo-rofluorescein (DCF) or 3,3'-dihexyloxacarbocyanine iodide (DiOC6) and evaluation of forward-angle light scatter vs. side-angle light scatter plots. Flow cytometric evaluation of bone marrow cells stained with DCF failed to separate bone marrow cells into distinct cell populations. Staining with DiOC6 resulted in separation of bone marrow cells into populations of mature and immature erythroid cells, mature and immature myeloid cells, and lymphocytes. The scatter plot method resulted in identification of mature and immature erythroid cells, immature myeloid cells, metamyelocytes, and bands and segmenters. Lymphocytes could not be differentiated from mature erythroid cells by the scatter plot method. When the results of the DiOC6 method and the scatter plot method were compared with manual bone marrow differential cell counts, the scatter plot method had more similar mean values and higher correlation coefficients. The scatter plot method has the potential of providing rapid semiquantitative assessment of bone marrow differential cell counts in dogs for specimens that contain low numbers of lymphocytes.     

Use of monoclonal antibodies to refine flow cytometric differential cell counting of canine bone marrow cells

OBJECTIVES: To evaluate use of monoclonal antibodies to increase accuracy of flow cytometric differential cell counting of canine bone marrow cells. SAMPLE POPULATION: Bone marrow specimens from 15 dogs. PROCEDURES: Specimens were labeled with monoclonal antibodies that detected CD18, major histocompatability antigen class-II (MHC class-II), CD14, and Thy-1. Location of fluorescent and nonfluorescent cells within gates of a template developed for canine bone marrow differential cell counting was determined, the template was revised, and 10 specimens were analyzed by use of the old and revised templates and by labeling cells with anti-MHC class-II and anti-CD14. RESULTS: Data confirmed the presumptive location of marrow subpopulations in scatter plots, permitted detection of lymphocytes and monocytemacrophages, and was used to revise the analysis template used for differential cell counting. When differential cells counts determined by the original and revised templates were compared with results of manual differential cell counts, the revised template had higher correlation coefficients and more similar mean values. Labeling cells with anti-MHC class-II and anti-CD14 permitted identification of lymphoid and monocyte-macrophages cells in bone marrow specimens. CONCLUSIONS AND CLINICAL RELEVANCE: Use of the revised flow cytometric analysis template combined with anti-CD14 and anti-MHC class-II antibody labeling provides reliable differential cell counts for clinical bone marrow specimens in dogs. These techniques have potential applications to clinical bone marrow examination and preclinical toxicity studies.     

Determination of differential cell counts in feline bone marrow by use of flow cytometry

OBJECTIVE: To evaluate the potential usefulness of 2 flow cytometric methods for determination of differential cell counts in feline bone marrow. SAMPLE POPULATION: 10 bone marrow specimens from client-owned cats. PROCEDURE: Bone marrow specimens were stained with 3,3'-dihexyloxacarbocyanine iodide (DiOC6) and evaluated by use of flow cytometry. Differential counts were also determined by analysis of scatterplots of forward-angle versus side-angle light scatter of unstained specimens, obtained by use of flow cytometry (scatterplot method). Results of both flow cytometric methods were compared with differential cell counts determined by manually counting 1,000 cells on slides of Wright-stained smears. RESULTS: Staining with DiOC6 resulted in identification of mature and immature erythroid and myeloid cells and lymphocytes. Use of the scatterplot method resulted in identification of mature and immature erythroid and myeloid cells and metamyelocytes. However, to identify lymphocytes by use of the scatterplot method, bone marrow specimens were first labeled with an anti-major histocompatability class-II antibody. Comparison of results of the scatterplot method with manual counts yielded higher correlation coefficients and more similar mean values than did comparison of results of the DiOC6 method. Conclusions and Clinical Relevance: The scatterplot method provided more accurate and precise results than the DiOC6 method for determination of bone marrow differential cell counts in cats by use of flow cytometry. When combined with fluorescent labeling of lymphocytes, the scatterplot method has potential to provide rapid semiquantitative assessment of bone marrow differential cell counts in cats.     

Use of flow cytometry for determination of differential leukocyte counts in bovine blood

A flow cytometric method was developed to perform differential leukocyte counts on bovine blood. Blood specimens from 50 healthy Holstein cows were analyzed by use of a flow cytometer. The method entailed diluting blood with phosphate-buffered, hypotonic saline solution containing acridine orange, and performing a step-wise, 3-parameter analysis on the bases of cell size, cellular granularity, and granulocyte fluorescence. Initially, proportions of monocytes, granulocytes, and lymphocytes were determined by creating appropriate windows on dot plots of cell size (determined by forward light scatter) vs cellular granularity (determined by the logarithm of side light scatter). Eosinophils were resolved by analysis of granulocytes as dot plots of logarithms of green vs red fluorescence ascribed to acridine orange. Proportions of eosinophils and neutrophils were computed from data so generated. Microclumps of platelets spuriously affected counts of some granulocytes, particularly eosinophils. Differential leukocyte counts determined by flow cytometry generally compared favorably with those obtained by use of the conventional microscopic method, using Wright-stained blood films. Mean neutrophil and eosinophil counts determined by the 2 methods did not differ significantly, but lymphocyte counts determined by flow cytometry were significantly higher than those determined by microscopy (P less than 0.01). Correlation coefficients for counts of neutrophils, eosinophils, and lymphocytes determined by the 2 methods ranged from 0.519 to 0.833. Correlation between monocyte counts was low (r = 0.147), although mean monocyte counts determined by the 2 methods did not differ significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

Flow cytometric and immunophenotypic evaluation of acute lymphocytic leukemia in dog bone marrow

Monoclonal antibodies provide powerful tools for detection of lineage-specific markers on hematopoietic cells. We used the combination of cell morphology, cytochemistry, flow cytometric scatter plot analysis, and labeling of cells with 6 monoclonal antibodies to detect and subclassify lymphocytic leukemia in bone marrow from 5 dogs. Antibodies included anti-CD18 (a panleukocyte marker), anti-MHC class II (detects most B and T lymphocytes and monocyte/macrophages), anti-Thy-1 (a pan-T-lymphocyte and monocyte/macrophage marker), anti-CD3 (a pan-T-lymphocyte marker), anti-CD21 (a B-lymphocyte marker), and anti-CD14 (a monocyte/macrophage marker). Of the 5 dogs evaluated, 2 were categorized as acute T-cell prolymphocytic leukemia, 2 as acute non-T, non-B lymphoblastic leukemia, and 1 as acute B-cell lymphoblastic leukemia. Results of this study indicate marked variation in the morphology and immunophenotype of canine lymphocytic leukemia.     

Flow cytometric evaluation of hemophagocytic disorders in canine

Background — Hemophagocytic macrophages in canine bone marrow are observed in malignant histiocytosis as well as benign hemophagocytic histiocytosis. Cytomorphologic evaluation alone may be inadequate to consistently differentiate between benign and malignant forms of hemophagocytic disorders. Objective — The purpose of this study was to evaluate the ability of flow cytometry and immunophenotyping to differentiate between benign and malignant types of hemophagocytic disorders in dogs. Methods — Blood smears and bone marrow differential cell counts were evaluated for 10 dogs with hemophagocytic disorders. Bone marrow samples were labeled with monoclonal antibodies to CD18, MCH class‐II, Thy‐1, CD14, CD3, and CD21. Using flow cytometry, forward‐angle versus side‐angle light scatter plots were analyzed and immunophenotypes were determined. Results — Scatter plots from 3 dogs with a necropsy diagnosis of malignant histiocytosis revealed 2 atypical cell clusters. One cluster contained cells of similar size or larger than immature myeloid cells and metamyelocytes. Cells in the other cluster were highly granular, with granularity similar to or greater than that of metamyelocytes. In bone marrow from dogs with malignant histiocytosis that was labeled with anti‐CD14 antibody, macrophages represented 29–48% of nucleated cells. Seven dogs had a clinical or histopathologic diagnosis of benign hemophagocytic syndrome. Three of the dogs had normal cell distribution in scatter plots. Two dogs had 2 abnormal cell clusters: 1 within the immature myeloid and metamyelocyte gates and the other with granularity similar to or greater than that of metamyelocytes. The remaining 2 dogs had an atypical cell population, mostly within the immature myeloid gate. For dogs with benign hemophagocytic syndromes, 6–17% of cells in the bone marrow were CD14 positive. Conclusions — The cellular distribution in scatter plots and the total number of macrophages in bone marrow may be useful in differentiating malignant histiocytosis from benign hemophagocytic syndromes in dogs.     

Characterization of porcine peripheral blood leukocytes by light-scattering flow cytometry.

As a basis for other experiments using flow cytometry of porcine peripheral blood leukocytes, cell fractions were isolated by various methods and analyzed by forward angle light scatter and 90 degree light scatter. Cytospin smears of cell samples were also studied by leukocyte differential counts and nonspecific esterase staining. Three main populations of peripheral blood leukocytes [lymphocytes, monocytes, and granulocytes (primarily neutrophils)], were defined in the log 90 degree light scatter by forward angle light scatter histogram. Partial overlap was observed between lymphocyte and monocyte, and between monocyte and granulocyte domains. Correlation between leukocyte differential counts and flow cytometric quantification based on bitmap statistics of appropriate domains was between r = 0.872-0.892 for lymphocyte and granulocyte. Percoll density gradients were used for subfractionation of leukocyte populations, especially for the enrichment of granulocytes. The specific densities were calculated for lymphocytes (1.0585-1.0819 g/cc), monocytes (1.0585-1.0702 g/cc), granulocyte (1.0819-1.0936 g/cc), and erythrocytes (greater than 1.0952 g/cc). We suggest that light scatter characterization is a basis for future studies of porcine blood by flow cytometry.     

Evaluation of monoclonal antibodies for identification of subpopulations of myeloid cells in bone marrow obtained from dogs

OBJECTIVE: To evaluate monoclonal antibodies that may be useful for immunophenotyping myeloid cells in bone marrow of dogs. SAMPLE POPULATION: Bone marrow specimens obtained from 5 dogs. DESIGN: Specimens were labeled with monoclonal antibodies that detected CD18, major histocompatability antigen class-II (MHC class-II), CD14, and Thy-1. Cells labeled with each of the antibodies were isolated by use of a fluorescence-activated cell sorter. Differential cell counts of sorted cells were used to determine cells that were labeled by each of the various antibodies. RESULTS: Myeloid cells labeled with anti-CD18 antibody included granulocytes, lymphocytes, and monocytes-macrophages. Immature and mature granulocytes were labeled. Lymphocytes, monocytes-macrophages, and eosinophils were labeled with anti-Thy-1 antibody. Cells labeled with anti-MHC-class II antibody included approximately 9% of bone marrow cells, which consisted almost exclusively of lymphocytes and monocytes-macrophages. Approximately 4% of bone marrow cells were labeled with anti-CD14 antibody, with > 90% of sorted cells being monocytes-macrophages. CONCLUSIONS AND CLINICAL RELEVANCE: Four monoclonal antibodies for use in detecting subpopulations of canine bone marrow cells were evaluated. These antibodies should be useful in differentiating the origin of leukemic cells in dogs.     

Characterization of bovine haemopoietic progenitor cells using monoclonal antibodies and fluorocytometry

Monoclonal antibodies against bovine leucocyte cell surface differentiation antigens were used in combination with a fluorescence activated cell sorter to enrich bovine haemopoietic progenitor cells present in bone marrow cell populations prior to in vitro culture. After two sequential centrifugations of the bone marrow cell suspension through Ficoll-Paque, the interface fraction was stained with a cocktail of monoclonal antibodies directed against mature monocytes/macrophages, granulocytes and lymphocytes. Using appropriate electronic window settings on a FACStar Plus, cells with a high 90 degrees light scattering property (granular cells), a low forward light scattering property (erythrocytes and reticulocytes) and cells positive for monoclonal antibodies specific for lineage-restricted leucocyte markers were removed and the negative cell fraction collected. These negatively-selected cells were stained with monoclonal antibodies specific for a pan-leucocyte or a MHC class II marker and the positive cell population was collected in a second sort and subsequently submitted to culture. All erythroid and granulocyte/macrophage colony forming cells expressed MHC class II antigens, as well as the pan-leucocyte antigen. These same progenitors did not bind any of a variety of monoclonal antibodies directed against lineage-specific antigens on lymphocytes, granulocytes or monocytes/macrophages, although they did bind monoclonal antibodies recognizing MHC class I antigens. Between 85% and 91% of the isolated cells seeded were capable of forming erythroid or granulocyte/macrophage colonies within 5 to 10 days, thus increasing the plating efficiency of these cell types in bone marrow populations by at least 60 fold.     

Cytologic evaluation of primary and secondary myelodysplastic syndromes in the dog

Myelodysplastic syndromes are a heterogeneous group of acquired primary and secondary alterations of hematopoietic stem cells that result in cytopenias in blood and cytologic features of dysplasia in blood and/or bone marrow. To better understand the cytologic features that would permit differentiation of primary and secondary forms of myelodysplasia, we reviewed 267 consecutive bone marrow reports from dogs. These reports indicated that 34 dogs (12.7%) had dysgranulopoiesis, dyserythropoiesis, and/or dysthrombopoiesis in >10% of granulopoietic cells, erythroid cells, and/or megakaryocytes, respectively. Thirteen dogs had primary myelodysplastic syndromes, and 21 had secondary myelodysplastic syndromes. Of the 13 dogs with primary myelodysplasia, 4 were subclassified as myelodysplastic syndrome with refractory anemia (MDS-RA), and 9 were subclassified as myelodysplastic syndrome with excess blasts (MDS-EB). Secondary conditions associated with dysplasia in the bone marrow included malignant lymphoma (n = 5), myelofibrosis (n = 3), immune-mediated thrombocytopenia (n = 4), immune-mediated hemolytic anemia (n = 5), multiple myeloma with melphalan administration (n = 1), pyometra with estrogen administration (n = 1), polycythemia vera (n = 1), and thrombopathia (n = 1). MDS-RA was characterized by <5% myeloblasts in bone marrow, normal granulocyte maturation ratio, increased erythroid maturation ratio, and dysplastic changes in >15% of erythroid cells. MSD-EB was characterized by >/=5% myeloblasts in bone marrow, high granulocyte maturation and erythroid maturation ratios, >/=32% dysplastic granulocytes, and the presence of small atypical immature myeloid cells. Secondary myelodysplastic syndromes were characterized by <5% myeloblasts in bone marrow, variable granulocyte maturation and erythroid maturation ratios, and variable dysplastic features. These results indicate that morphology alone cannot be used to distinguish primary and secondary myelodysplastic syndromes in dogs.     

Expression of CD3 and CD11b antigens on blood and mammary gland leukocytes and bacterial survival in milk of cows with experimentally induced Staphylococcus aureus mastitis.

OBJECTIVES: To differentiate early (1 to 8 days) from late (9 to 14 days) inflammatory phases and assess relationships between leukocyte phenotype and bacterial recovery in cows with Staphylococcus aureus-induced mastitis. ANIMALS: 10 first-lactation Holstein cows. PROCEDURE: Blood and milk samples were collected from 4 or 6 cows before and after intramammary infusion of sterile broth or S. aureus, respectively. Flow cytometric expression of CD3 and CD11b antigens on blood and milk leukocytes, leukocyte differential counts, bacterial counts in milk, and somatic cell counts were determined longitudinally. RESULTS: Density of CD3 molecules decreased on blood lymphocytes and increased on milk lymphocytes after infusion of bacteria. Density of CD11b molecules on lymphocytes and phagocytes and percentage of CD11b+ lymphocytes in milk increased significantly after infusion; maximum values were achieved during the early inflammatory phase. Density of CD3 and CD11b molecules on milk lymphocytes and macrophages, respectively, 1 day after inoculation were negatively correlated with bacterial recovery on day 1 and days 9 to 14, respectively. Density of CD11b molecules on milk macrophages and the ratios of phagocyte to lymphocyte percentages and polymorphonuclear cell to macrophage percentages in milk differentiated the early from the late inflammatory phase. CONCLUSIONS AND CLINICAL RELEVANCE: Activation of bovine mammary gland macrophages and T cells in response to intramammary infusion of S. aureus was associated with an inability to culture this bacterium from milk. Identification of specific inflammatory phases of S. aureus-induced mastitis in cows may allow for the design of more efficacious treatment and control programs.     

犬瘟热病毒自然感染犬淋巴组织中T、B细胞变化的研究

为了调查患犬瘟热病犬淋巴组织中T、B细胞变化的特点及淋巴细胞减少的发病机制,试验通过免疫组织化学的方法观察了T细胞(用CD3和CD45RO检测T细胞)、B细胞(用IgG、IgM抗血清检测B细胞)和犬瘟热病毒(抗犬瘟热病毒抗体)在病犬淋巴组织中的分布。结果表明:在淋巴组织中的淋巴细胞、淋巴小结中树突状细胞和巨噬细胞中均检出了抗病毒阳性反应细胞。在骨髓组织的前髓细胞中也发现抗病毒阳性反应细胞和嗜酸性胞浆内及核内包涵体的存在。与对照组相比,CD3和CD45RO阳性细胞主要存在于T细胞的分布域;但CD3和CD45RO阳性T细胞的数量较少。位于淋巴组织中的巨噬细胞有的被CD45RO染成阳性。在B细胞分布的区域中,IgG、IgM阳性细胞的数量明显减少;一些位于淋巴组织的浆细胞也被IgG或IgM染成阳性。在淋巴组织中淋巴细胞减少的顺序为:IgG阳性细胞减少最明显,其次为IgM和CD45RO阳性细胞,再次为CD3阳性细胞。依据试验结果,作者认为病犬淋巴组织中淋巴细胞减少主要是由B细胞缺乏所引起的;淋巴细胞的增殖能力减弱是引起淋巴组织中淋巴细胞减少的重要原因。     

Flow cytometric patterns in blood from dogs with non-neoplastic and neoplastic hematologic diseases using double labeling for CD18 and CD45

BACKGROUND: In dogs, flow cytometry is used in the phenotyping of immunologic cells and in the diagnosis of hemic neoplasia. However, the paucity of specific antibodies for myeloid cells and B lymphocytes and of labeled antibodies for multicolor techniques limits the ability to detect all leukocyte subpopulations. This is especially true for neoplastic and precursor cells. CD18 and CD45 are expressed on all leukocytes and are involved in cell activation, and together could be useful in helping determine cell lineage. OBJECTIVES: The purpose of this study was to double label canine blood for CD18 and CD45 and to use the differential expression of antigens to identify leukocyte populations in dogs with non-neoplastic and neoplastic hematologic diseases. METHODS: A template was developed using blood samples from 10 clinically healthy dogs and a back-gating technique. Differential leukocyte counts obtained with the template were compared with those obtained by manual and automated methods on blood samples from 17 additional healthy dogs. Blood samples obtained from 9 dogs with non-neoplastic (reactive) hematologic diseases and 27 dogs with hemic neoplasia were double stained for CD18 and CD45 using mouse anticanine CD18 monoclonal antibody (mAb) plus phycoerythrin-conjugated rat anticanine CD45 mAb and fluorescein isothiocyanate-conjugated rabbit antimouse IgG. Hemic neoplasms were diagnosed by cell morphology, and immunophenotypic and cytochemical markers. RESULTS: With the double label, neutrophils, eosinophils, monocytes, and T- and B-lymphocytes were identified. In reactive disorders, a population of activated neutrophils with high CD45 and CD18 expression was detected. In hemic neoplasia, cell lineage was easily determined, even in acute leukemia. CONCLUSIONS: Double labeling for CD18/CD45 may be useful as a screening method to evaluate hematologic diseases and help determine cell lineage, and to aid in the selection of a panel of antibodies that would be useful for further analysis.     

No apoptotic cell death of erythroid cells of erythroblastic islands in bone marrow of healthy rats

A possibility of apoptotic cell death in erythropoietic regulation was examined by means of detailed light microscopical histoplanimetry, electron microscopy, the in situ nick-end labeling method, and an immunohistological method in the rat bone marrow. Serum erythropoietin concentrations were shown at normal levels. The erythroid series on a mature process presented several morphological features of apoptosis, i.e. the shrinkage of both nuclei and cytoplasm and the chromatin condensation. In the light microscopical histoplanimetry, however, morphological signs of final apoptotic cell death were never found in any erythroid cell within the erythroblastic islands. This finding was also supported by detailed ultrastructural observation: No erythroid cell bodies were trapped and degraded by the central macrophages of the erythroblastic islands, while the denucleated nuclei with small amount of cytoplasm of late erythroblasts were often trapped and degraded in the macrophages. Nuclear DNA fragmentation was not detected in any erythroblasts, but was detected in the lysosomes of the central macrophages. These findings suggest that erythropoiesis is regulated by other regulatory mechanisms than apoptotic cell death. An additional ultrastructural finding shows that the reticulocytes anchored to the central macrophages are transported into the peripheral blood circulation.     

Identification of acute myeloid leukemia in dogs using flow cytometry with myeloperoxidase, MAC387, and a canine neutrophil-specific antibody

BACKGROUND: Flow cytometry may be used to determine immunophenotype or lineage of leukemic cells, but few antibodies are available that are specific for cells of monocytic and granulocytic lineage. OBJECTIVE: The purpose of this study was to evaluate the flow cytometric staining patterns of 3 commercial monoclonal antibodies for monocytes and granulocytes in clinically healthy dogs and in dogs with acute myeloid leukemia (AML). METHODS: Mouse antihuman macrophage antibody (MAC387), mouse anti-human myeloperoxidase (MPO), and a canine neutrophil-specific antibody (NSA) were evaluated using flow cytometry on blood from 6 clinically healthy control dogs, and on blood (n = 7) and/or bone marrow (n = 2) from 8 dogs with AML. A diagnosis of acute leukemia was confirmed by >30% blasts in bone marrow or >30% blasts in peripheral blood, together with bi- or pancytopenia, circulating CD34-positive blast cells, and clinical signs of disease. Leukemic samples also were evaluated using a wide panel of monoclonal antibodies. RESULTS: MAC387 stained neutrophils and monocytes from control dogs, although the staining profiles for the 2 cell types differed. MPO and NSA resulted in strong positive staining of neutrophils; MPO also stained monocytes weakly. Lymphocytes did not stain with any of the antibodies. One case was classified as AML of granulocytic lineage (AML-M1), 6 cases were classified as acute monocytic leukemia (AML-M5), and 1 case was classified as acute myelomonocytic leukemia (AML-M4). Neoplastic myeloblasts in the dog with granulocytic AML were positive for MPO, NSA, MAC387, and CD4. All monoblasts from the dogs with AML-M5 were positive for CD14, 5 of 6 were positive for MAC387, and 2 were positive for MPO. NSA staining was negative in the 2 dogs with AML-M5 in which it was evaluated. In the dog with AML-M4 variable percentages of blast cells were positive for CD14, MPO, MAC387, CD4, and NSA. CONCLUSIONS: Antigens identified by antibodies to MAC387, MPO, and NSA were expressed not just by normal mature neutrophils and monocytes, but also by neoplastic myeloblasts and monoblasts. These 3 antibodies may be useful as part of a wider panel for immunophenotyping AML in dogs.     

A light and electron microscopic study of changes in blood and bone marrow in acute hemorrhagic Trypanosoma vivax infection in calves.

Eleven 6-month-old calves were tsetse fly challenged with a stock of Trypanosoma vivax (IL 2337) that causes hemorrhagic infection. The calves were randomly euthanatized every 4 to 6 days; two other calves served as controls. Peripheral blood changes included anemia, thrombocytopenia, and an initial leukopenia. Later in the course of infection, leukocytosis associated with lymphocytosis and neutropenia developed. Moderate reticulocytosis (highest mean count 3.6 +/- 3.7%, maximum count 9.4%) accompanied the first wave of parasitemia, but poor response (highest mean 0.4 +/- 0.0%) occurred during the second wave, despite the persistence of severe anemia. Light microscopic examination of bone marrow samples showed a drop in the myeloid: erythroid ratio with a decrease in granulocytes, particularly metamyelocytes, bands, and segmenters. Increase in lymphocyte counts corresponded with the appearance of lymphoid nodules within the marrow. Megakaryocytic volume increased significantly in infected animals, and some megakaryocytes showed emperipolesis of red cells, neutrophils, and lymphocytes. Transmission electron microscopic examination of the bone marrow revealed that trypanosomes had crossed the sinusoidal endothelium into the hematopoietic compartment as early as the second day of parasitemia. Macrophages proliferated in the bone marrow; and from the second day of parasitemia until the end of the experimental infection, on day 46, the macrophages had phagocytosed normoblasts, eosinophil and neutrophil myelocytes, metamyelocytes, bands, and segmenters, as well as reticulocytes, erythrocytes, and thrombocytes. Therefore, dyserythropoiesis and dysgranulocytopoiesis were responsible, in part, for the observed anemia and granulocytopenia, respectively.     

An immunodeficiency in Fell ponies: a preliminary study into cellular responses.

A putative immunodeficiency, causing mortality in UK Fell pony foals (Fell pony syndrome), was studied in affected foals and compared with healthy, age-matched foals. Differential cell counts of peripheral blood indicated that the syndrome foals were lymphopenic (P<0.05). Flow cytometric analysis of circulating leucocytes showed a reduced MHC II expression (P<0.01) on lymphocytes but not on polymorphonuclear cells in affected foals. There were no changes in the percentages of CD4+ or CD8+ T cells. There was an increased (P<0.05) expression of CD11a/18 by the lymphocytes of the syndrome foals, compared to the control foals, which is probably a response to systemic bacterial infections. The syndrome foals' lymphocytes responded to mitogens (PHA, ConA, PWM) at normal levels. The data do not conform to any known immunodeficiencies identified in any other species. Further analyses will be required, particularly on bone marrow function.     

Longitudinal evaluation of bovine mammary gland health status by somatic cell counting, flow cytometry, and cytology.

Bovine mastitis phases induced by Staphylococcus aureus were assessed in 6 lactating cows before challenge and at 1, 4-8, and 9-14 days postinoculation (dpi). Milk lymphocytes, macrophages, and polymorphonuclear cells (PMN) were counted by conventional (manual) cytology, identified by CD3+ and CD11b+ immunofluorescence and counted by flow cytometry (based on leukocyte forward and side light scatter values). Somatic cell counts (SCC) and recovery of bacteria were recorded at the same times. Preinoculation samples showed a lymphocyte-dominated composition. At 1 dpi, the percentage of PMN increased and that of lymphocytes decreased. At 4-8 dpi, PMN were predominant, but the percentage of mononuclear cells increased above that at 1 dpi and further increased by 9-14 dpi (when lymphocytes approached prechallenge values). Based on leukocyte percentages, 3 indices were created from the data: 1) the PMN/lymphocyte percentage ratio (PMN/L), 2) the PMN/macrophage percentage ratio (PMN/M), and 3) the phagocyte (PMN and macrophage)/lymphocyte percentage ratio (Phago/L). Significant correlations were found between cytologic and flow cytometric data in all of these indicators (all with P < or = 0.01). These indices identified nonmastitic, early inflammatory (1-8 dpi), and late inflammatory (9-14 dpi) animals. In contrast, SCC and bacteriology did not. Although sensitivity of the SCC was similar to that of Phago/L, the specificity of SCC was almost half that of the Phago/L index. Based on flow cytometry indicators, an algorithm for presumptive diagnosis of bovine mastitis was developed. Flow cytometry provides results as valid as those obtained by conventional (manual) cytology, shows greater ability to identify mastitic cases than does SCC, and may identify 3 mammary gland health-related conditions.     

Characterization of CD34+ cells from canine umbilical cord blood, bone marrow leukocytes, and peripheral blood by flow cytometric analysis

Characterization of CD34+ cells in canine bone marrow, umbilical cord blood, and peripheral blood was performed by flow cytometric analysis. The ratio of CD34+CD45hi cells, which are absent in human blood, was high in the CD34+ cell fraction, but 98% of these was suggested B-cells. The remaining CD34+CD45lo cells may comprise canine hematopoietic progenitor cells, and these cells accounted for 0.23 +/- 0.07% of the fraction in cord blood, 0.30 +/- 0.07% in bone marrow, and 0.02 +/- 0.01% in peripheral blood.     

Phenotypic analysis of ovine bone marrow cells using monoclonal antibodies and lectins

Three major subpopulations of ovine bone marrow cells were identified by flow cytometry on the basis of differences in forward (FSC) versus right angle (SSC) light scattering properties and binding of monoclonal antibodies. Region 1 (low FSC, low SSC) contained erythroid series cells and some small lymphocytes. Region 2 (high FSC, low SSC) contained monocytes, myeloid blast cells, medium-large lymphocytes and virtually all of the progenitor/stem cells capable of forming colonies in soft agar cultures. Region 3 (high SSC) contained granulocytes at various stages of development, predominantly (greater than 90%) neutrophils and eosinophils. Using this technique it was possible to identify several cell-surface antigens on bone marrow cells of different lineages using specific monoclonal antibodies and lectins. Amongst the haemopoietic stem/progenitor cell population, immature colony-forming cells were leucocyte common antigen (LCA) negative while more mature colony-forming cells expressed LCA. A proportion of progenitor cells were MHC class I positive. This analysis is an important first step in characterising ovine haemopoietic cells for future studies on: the development of inflammatory cells, the migration of stem/progenitor cells in vivo and the tropism of pathogens.