Mast cell growth factor (C-Kit Ligand) in combination with granulocyte-macrophage colony-stimulating factor and interleukin-3:in vivo hemopoietic effects in irradiated mice compared toin vitro effects

In the presence of hemopoietic cytokines such as granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-3 (IL-3), mast cell growth factor (MGF; also known as steel factor, stem cell factor, and c-kit ligand) has proven to be a potent hemopoietic regulatorin vitro. In these studies, we examined thein vivo effects of MGF in combination with GM-CSF or GM-CSF plus IL-3. Effects were based on the ability of these cytokines to stimulate recovery from radiation-induced hemopoietic aplasia. Female B6D2F1 mice were exposed to a sublethal 7.75-Gy dose of⁶⁰Co radiation followed by subcutaneous administration of either saline, recombinant murine (rm) MGF (100g/kg/day), rmGM-CSF (100g/kg/day), rmIL-3 (100g/kg/day), or combinations of these cytokines on days 1–17 postirradiation. Recoveries of bone marrow and splenic spleen colony-forming units (CFU-s), granulocyte macrophage colony-forming cells (GM-CFC), and peripheral white blood cells (WBC), red blood cells (RBC) and platelets (PLT) were determined on days 14 and 17 during the postirradiation recovery period. MGF administered in combination with GM-CSF or in combination with GM-CSF plus IL-3 either produced no greater response than GM-CSF alone or down-regulated the GM-CSF-induced recovery. These results sharply contrasted results ofin vitro studies evaluating the effects of these cytokines on induction of GM-CFC colony formation from bone marrow cells obtained from normal or irradiated B6D2F1 mice, in which MGF synergized with GM-CSF or GM-CSF plus IL-3 to increase both GM-CFC colony numbers and colony size. These studies demonstrate a dichotomy between MGF-induced effectsin vivo andin vitro and emphasize that caution should be taken in attempting to predict cytokine interactionsin vivo in hemopoietically injured animals based onin vitro cytokine effects.Abbreviations GM-CSF Granulocyte-Macrophage Colonly-Stimulating Factor - IL-3 Interleukin-3 - MGF Mast Cell Growth Factor - SCF Stem Cell Factor - rm Recombinant Murine - CFU-s Colony Forming Unit-Spleen - GM-CFC Granulocyte Macrophage Colony-Forming Cell - WBC White Blood Cells - RBC Red Blood Cells - PLT Platelets - SLF Steel Factor - G-CSF Granulocyte Colonly-Stimulating Factor - IL-1 Interleukin-1 - IL-6 Interleukin-6 - Epo Erythropoietin - CFC Colony-Forming Cell - Sl Steel - BFU-e Erythroid Burst Forming Units - s.c Subcutaneous - PEG Polyethyleneglycol - PIXY321 GM-CSF/IL-3 Fusion Protein     

Cytometry and Time-Dependent Variations in Peripheral Blood and Bone Marrow Cells: A Literature Review and Relevance to the Chronotherapy of Cancer

By flow cytometry of individual cells, multiple cell properties can be analyzed. Such parameters may be important in relation to cytotoxic treatment of cancer. For example, DNA measurements will answer questions regarding cell kinetics. Myelosuppression is the major dose-limiting toxicity during cancer treatment. Therefore, the study of cell cycle parameters in bone marrow cells is highly relevant. However, inattention to the existence and potential importance of biological rhythms may introduce artifacts and misleading results. The literature of rhythms in hematology is reviewed. Time-dependent variations in hematological variables have been extensively studied and rhythms have been described for all kinds of blood cells. Also the numbers of hemopoietic stem cells in the bone marrow undergo circadian variations. Our group has shown how such variations change with aging in mice. The relevance of time sequence studies in aging research of hemopoiesis was clearly demonstrated. In animal studies using cytometry, our group has demonstrated extensive circadian variations in cell cycle distribution of bone marrow cells, especially the DNA synthesis (S-phase). In humans a few and rather small time sequence studies of the bone marrow have been performed, so far. In this overview the clinical implications of circadian rhythms of S-phase variations measured by flow cytometry of human bone marrow cells are discussed. Male volunteers were examined every 4 h around-the-clock. The data indicated a lower proliferative activity during night, suggesting the possibility of reducing the bone marrow toxicity to cancer treatment when taking these time-dependent variations into consideration.     

Inference for an age-dependent,multitype branching-process model of mast cells

We consider an age-dependent, multitype model for the growth of mast cells in culture. After a colony of cells is established by an initiator type, the two possible types of cells are resting and proliferative. Using novel inferential procedures, we estimate the generation-time distribution and the offspring distribution of proliferative cells, and the waiting-time distribution of resting cells.List of Notations B _i cumulative distribution function for the time until branching of a cell of type i - b _i probability density function for the time until branching of a cell of type i - b _i b _i (1–D _i ) - D _i cumulative distribution function for the time until death of a cell of type i - d _i probability density function for the time until death of a cell of type i - probability density function of a gamma distribution - G _i cumulative distribution function for the lifetime of a cell of type i - G _1*2 Convolution of G ₁ and G ₂ - ¯G _i 1–G _i - g _i probability density function for the lifetime of a cell of type i - L _i likelihood of a history of type i - m average number of proliferative daughters produced by dividing cells - M _ij (t) the expected number of type-j cells in a colony at time t if that colony began at time 0 with one type-i cell - M _i+ (t) M _i0 (t) + M _i 1(t) + M _i 2(t) - p _rs probability that a dividing cell produces r proliferative and s resting daughters - t _i times defining colony histories. See IV.2.1 - T ₀ time to division of an initiator cell - T ₁, T ₂ times from birth to division of the two daughters of an initiator cell - T ₍₁₎, T ₍₂₎ order statistics of T ₁ and T ₂ - minimum value of a gamma distribution - scale parameter of a gamma distribution or of an exponential distribution - probability per unit time of death for proliferative and resting cells - _rs expected value of p _rs when there is heterogeneity - shape parameter of a gamma distribution     

Hemopoietic sites and development of eosinophil granulocytes in the loach,Misgurnus anguillicaudatus

Summary Unique eosinophils, each of which contained only one eosinophilic granule, have been found in the peripheral blood of the loach (itMisgurnus anguillicaudatus). Several loach organs have been studied by light and electron microscopy to determine the hemopoietic site of this cell type. Eosinophils are produced mainly in the spleen and to a small extent in the kidney, but not in other organs.Presumed myeloblasts are identified as large lymphoid cells containing a number of small-dense granules (diameter, 0.12–0.16 m) in the cytoplasm. These granules have been observed throughout eosinophilopoiesis but they are most abundant in the promyelocyte stage. The largest cells have been identified as myelocytes which contain a number of large granules (diameter, 0.7–1.4 m) with electron-dense crystalline cores. These large granules are present from the myelocyte to metamyelocyte stage. Metamyelocytes differ from myelocytes in having more large granules. Mature eosinophils are morphologically similar to metamyelocytes but are characterized by the presence of only one very large electron-dense granule (diameter, 2.5–2.8 m) with a crystalline core.The nature of these granules has been studied by enzyme digestion using pepsin and trypsin. The results indicate that the crystalline cores are almost pure protein.     

Retention of hemopoiesis in tail vertebrae of newborn rats

Summary In newborn rats, the marrow cavity of tail vertebrae is hemopoietic and contains no adipose tissue. The latter develops soon after birth to replace the hemopoietic tissue within the nonexpansile volume of the marrow cavity. By transposing the tail into the warmer environment of the abdomen, hemopoiesis was retained, and the development of adipose tissue was prevented in the transposed segment, when the operation was done in preweanling but not in adult animals. Systemic stimuli of erythropoiesis (phlebotomy, induced hemolysis) acted synergistically with the temperature increment to retain hemopoiesis. The findings support the concept that adipose cells in the yellow marrow are relatively stable and once developed, they are not readily mobilized. The findings may also explain the discrepancies in the results obtained by rat tail transposition.Supported by ERDA Contract EP-78-S-03-0899, NASA Grant NSG 9061 and RCDA AM16125 awarded to Mehdi Tavassoli     

Avian HSC emergence, migration, and commitment toward the T cell lineage

To date three sites of emergence of hemopoietin cells have been identified during early avian development: the yolk sac, the intraaortic clusters and recently the allantois. However, the contributions of the hematopoietic stem cell (HSC) populations generated by these different sites to definitive hematopoiesis and their migration routes are not fully unraveled. Experimental embryology as well as the establishment of the genetic cascades involved in HSC emergence help now to draw a better scheme of these processes.