CA 125 production and release by ovarian cancer cells in vitro

The antigenic determinant CA 125 is a high molecular weight glycoprotein which is elevated in more than 80% of patients with epithelial ovarian cancer. Despite its good performance as a human tumor marker, only little is known about its physiological function. According to recent publications, CA 125 production and release appear to be related to cellular growth. In order to investigate this putative relationship more closely, we analyzed the pattern of CA 125 production and release by ovarian cancer cells during exponential cell growth, during cell cycle arrest by colchicine and during inhibition of cellular protein synthesis by cycloheximide. The results were correlated with the cell cycle distribution. According to our results, the main determinant of CA 125 release into the culture supernatant is the total cell count. Although cell cycle arrest in the G2 + M phase by means of colchicine treatment resulted in the death of most cells, which was reflected by an increased release of CA 125, no differences in the intracellular production rate between colchicine treated and untreated cells were seen. In contrast, treatment of cells with cycloheximide not only resulted in decreasing cell numbers but also in a complete inhibition of CA 125 production by surviving cells.     

Endothelial cell-derived high molecular weight von Willebrand factor is converted into the plasma multimer pattern by granulocyte proteases

We have previously found that the von Willebrand factor released by cultured human umbilical vein endothelial cells appeared as a single high molecular weight band in glyoxyl agarose electrophoresis. In the present studies we report that this high molecular weight endothelial cell-derived von Willebrand factor, when incubated with granulocyte lysates, was cleaved into a series of multimers indistinguishable from those seen in normal plasma (or type II von Willebrand disease). This von Willebrand factor-cleaving activity was released from granulocytes by calcium ionophore A23187 but was not detected in cytosolic fractions depleted of granular contents. It was inhibited by the serine protease inhibitor phenylmethylsulfonyl fluoride. This von Willebrand factor-cleaving activity thus provides a possible mechanism for the generation of plasma von Willebrand factor multimers from the high molecular weight form of von Willebrand factor secreted by endothelial cells.     

Repopulating potential of hematopoietic precursor cells

Experiments were performed in 1800 cGy whole-body x-irradiated dogs. Mononuclear cells were collected from bone marrow, peripheral blood, and fetal liver. They were cryopreserved in -196 degrees C liquid nitrogen until used for transplantation. The thawed transfusates were adjusted to contain 1.5-1.6 x 10(5) CFU-GM per kg body weight. The blood granulocyte recovery was rapid after transfusion of blood-derived stem cells as compared to the use of bone-marrow-derived stem cells. In both instances, however, normal values were not reached for several weeks. In contrast, the use of fetal-liver-derived stem cells resulted in a very rapid initial granulocyte increase with a return of values to normal (or even overshoot) within 3 weeks after transplantation. A biomathematical granulocyte renewal simulation system is described that permits calculation of the absolute number of pluripotent stem cells in the transfusate. The data after fetal liver stem cell transplantation can be fitted only if an initial stem cell replication rate of 0.95 is assumed (in contrast to 0.65 using bone marrow or blood-derived stem cells).     

Synergistic effects of purified recombinant human and murine B cell growth factor-1/IL-4 on colony formation in vitro by hematopoietic progenitor cells. Multiple actions

Purified recombinant human B cell growth factor-1/IL-4 was evaluated, alone and in combination, with purified preparations of recombinant human (rhu) CSF or erythropoietin (Epo) for effects on colony formation by human bone marrow CFU-GM progenitor cells (GM) and burst forming unit-E progenitor cells. rhu IL-4 synergized with rhu G-CSF to enhance granulocyte colony formation, but had no effect on CFU-GM colony formation stimulated by rhu GM-CSF, rhu IL-3, or rhu CSF-1. Rhu IL-4 synergized with Epo to enhance BFU-E colony formation equal to that of Epo plus either rhu IL-3, rhu GM-CSF, or rhu G-CSF. Removal of adherent cells and T lymphocytes did not influence the synergistic activities of rhu IL-4. Rmu IL-4, synergized with rhu G-CSF, but not with rmu GM-CSF, rmu IL-3, or natural mu CSF-1, to enhance CFU-GM (mainly granulocyte) colony numbers by a greater than 90% pure preparation of murine CFU-GM. Also, rhu IL-4 at low concentrations enhanced release of CSF and at higher concentrations the release also of suppressor molecules from human monocytes and PHA-stimulated human T lymphocytes. Use of specific CSF antibodies suggested that rhu IL-4 was enhancing the release of G-CSF and CSF-1 from monocytes and the release of GM-CSF and possibly G-CSF from PHA-stimulated T lymphocytes. Use of antibodies for TNF-alpha, IFN-gamma, or TNF-beta as well as measurement of TNF and IFN titers suggested that the suppressor molecule(s) released from monocytes were acting with TNF-alpha and those released from PHA-stimulated T lymphocytes were acting with IFN-gamma. These results implicate B cell growth factor-1/IL-4 as a synergistic activity for hematopoietic progenitors and suggest that the actions can be on both progenitor and accessory cells.     

A mathematical model for reconstitution of granulopoiesis after high dose chemotherapy with autologous stem cell transplantation

High dose chemotherapy supported with hematopoietic progenitor cells gives a characteristic neutropenic period (blood neutrophils <0.510⁹ c/l) ranging from 10 to 16 days. The question of a correlation between the CFU-GM content of the transplanted CD34+ cells and time to neutrophil recovery by patients having been given high-dose chemotherapy (HD-CT) with stem cell support was addressed by means of a mathematical model of granulopoiesis. The model utilizes a convection-reaction partial differential equation (PDE) with feedback from a cytokine compartment on proliferation, maturation, and mobilization of granulocytes from bone marrow to blood. The observed number of CFU-GM cells in the transplanted CD34+ cell autograft was used as input to the model. Using this approach, the observed gross relationship between CFU-GM content in the reinfused blood product and engraftment time could be reproduced. At the same time, the effects of assumed physiological mechanisms, especially some of the effects of G-CSF on proliferation rate, maturation rate, mobilization, and cell death, could be investigated and discussed relative to observed engraftment. The model makes it possible to explain how cytokines interfere with progenitor cell mobilization from bone marrow to blood, and it points out the implications of a regulating mechanism for the granulocyte maturation rate.     

Human granulocyte colony stimulating factor: effects on human long-term bone marrow cultures

Human granulocyte colony stimulating factor (G-CSF) was previously shown to support the survival and proliferation of early myeloid progenitors (pre-CFU) that are capable of generating more mature CFU-GM progenitor cells. To evaluate the scope of action of G-CSF in the hierarchy of hematopoietic stem cells, we studied the effects of recombinant G-CSF (rhG-CSF) on long-term cultures of normal human bone marrow cells (LTBMC). We found that rhG-CSF predominantly influenced initial cell proliferation and expansion of CFU-GM progenitor cells in LTBMC before establishment of a confluent adherent layer. In rhG-CSF-treated LTBMC, the stromal cell layer was associated with a higher proliferative capacity and progenitor cell content as compared to control cultures. This effect was pronounced early after layer confluence and was gradually lost with culture time. rhG-CSF did not alter the duration of the productive phase of LTBMC, suggesting that it may not be active on the hematopoietic stem cells responsible for LTBMC propagation. Alternatively, stromal cells may exert tight regulatory control over progenitor cells, even in the presence of rhG-CSF.     

Hematopoiesis in the rat: quantitation of hematopoietic progenitors and the response to iron deficiency anemia

To determine the quantitative effects of iron deficiency on erythropoiesis and to assess the response of erythroid progenitors to sustained anemia, we developed quantitative assays for various hematopoietic progenitors in the adult, Sprague-Dawley rat including erythroid colony- and burst-forming cells (CFU-E and BFU-E), granulocyte/macrophage colony-forming cells (CFU-GM), and megakaryocytic colony-forming cells (CFU-Meg). CFU-E were cultured in methylcellulose and grew best in the presence of fetal calf serum. CFU-GM, BFU-E, and CFU-Meg grew better in normal rat plasma and required the presence of pokeweed mitogen-stimulated rat spleen cell conditioned medium. The numbers of progenitors and nucleated erythroblasts in total marrow were estimated by the ratios of radioactivity in the humerus to the total skeleton as determined by radioiron dilution. The numbers of progenitors and erythroblasts in the spleen were measured by simple dilution. Sustained anemia was brought about through chronic iron deficiency. The response to iron deficiency anemia (IDA) was monitored by the numbers of the various progenitors and their cell cycle characteristics as measured by the tritiated thymidine suicide technique. With IDA, the number of CFU-F in the body (marrow plus spleen) was increased to 3.5 times control, whereas the numbers of BFU-E and CFU-GM were unchanged. There was no difference in the percentage of CFU-E, BFU-E, and CFU-GM in DNA synthesis (68%, 19.4%, and 18.8%, respectively). With iron therapy of IDA, CFU-E numbers in marrow began to decrease by day 1 and fell in a manner reciprocal to changes in the hematocrit. Marrow and spleen erythroblasts, 1.7 times control in IDA, increased further to 3.9 times control by the fourth day after iron administration. There was no change in BFU-E or CFU-GM numbers in response to iron repletion, although the fraction of progenitors increased in the spleen. Thus, IDA does not limit the increase in CFU-E seen with anemia, but does restrict erythroid maturation. Furthermore, the increase in CFU-E and the state of chronic anemia occur without detectable changes in the number of cell cycle state of the more primitive BFU-E.     

Retention of the mitochondrial probe rhodamine 123 in normal lymphocytes and leukemic cells in relation to the cell cycle

The cationic fluorochrome rhodamine 123 (R123) is specifically taken up by mitochondria of live cells where it is retained due to the mitochondrial transmembrane potential. After pulse exposure of human normal quiescent or proliferating lymphocytes, human lymphocytic leukemic MOLT cells, and mice leukemic L1210 cells to 10 micrograms/ml of R123, the dye release was studied using flow cytometry. Two distinct phases of R123 release, each following first-order kinetics, were apparent; the half-time of retention for the rapidly and slowly released fractions of R123 was 0.8-1.1 and 2.8-4.2 h, respectively. Simultaneous supravital cell staining with R123 and Hoechst 33342 made it possible to correlate retention of R123 with cell position in the cell cycle. No significant differences were observed in the rate of R123 release from cells in G1 vs S or vs G2 + M phases of the cycle. The data rule out a possibility that the release of R123 is due to periodic depolarization of the mitochondria in the cell as may be postulated by cell cycle models that assume a transient passage of cells through resting phase following division. The observed similar rates of R123 release regardless of cell type or cell cycle phase suggest that the factors affecting the exchange are similar in normal lymphocytes vs leukemic cells and unrelated to cell proliferation rate or phase of the cell cycle. Two distinct rates of R123 release indicate the presence of two kinds of binding sites differing in affinity to the dye.     

Control of macromolecular synthesis in proliferating and resting Syrian hamster cells in monolayer culture. 3. Electrophoretic patters of newly synthesized proteins in synchronized proliferating cells and resting cells

Electrophoretic patterns of newly synthesized proteins have been compared for hamster embryo fibroblasts in asynchronous cultures, mitotically synchronized cultures, and stationary phase cultures. Only proteins with molecular weight between 30,000 and 150,000, comprising 60–70% of the total cell proteins and excluding histones and collagen were included in the comparison. Although no significant differences could be detected between such patterns for cells at different stages of the cell cycle, significant differences were detected between patterns for cells in stationary phase and for proliferating asynchronous or synchronous cells in any stage of the cell cycle. These differences amounted to at least 5% of the newly synthesized cellular proteins. Much larger differences were detected between patterns from a nuclear fraction of proliferating and resting cells. These results indicate that normal cells in stationary phase are arrested in a state distinct from any phase of the normal cell cycle and may provide a biochemical marker for resting cells.     

The influence of fibroblast-like cells derived from canine fetal hematopoietic tissues on the regulation of lymphohematopoiesis

Media conditioned by fibroblast-like cells derived from organs active in fetal lymphohematopoiesis were studied for their effects on adult granulocyte/macrophage colony-forming units (CFU-GM). Fibroblasts from fetal liver produced a factor stimulatory for CFU-GM, whereas fibroblasts from fetal marrow produced a factor inhibitory for CFU-GM which was not completely relieved by adding indomethacin to the assay. Our studies indicated that neither fetal marrow nor fetal liver produced factors affecting lymphocyte colony-forming units (CFU-L). Cell-cell interactions between fibroblast-like cells derived from fetal liver or marrow and normal adult CFU-GM were also studied. We observed that fibroblasts derived from both fetal and adult marrow inhibited colony formation, whereas inhibition in the presence of fetal liver fibroblasts was minimal. Loss of inhibitory activity by a liver fibroblast cell line over repeated passages was seen. Differential analysis of colonies formed above an adherent layer of fetal marrow fibroblasts suggested that these fibroblasts suppress myeloid/macrophage differentiation to a far greater degree than did adult marrow fibroblasts. A role in the regulation of fetal lymphohematopoiesis may be played by stromal fibroblasts.     

Purification of a trypsin inhibitor secreted by embryogenic carrot cells

A protease inhibitor with a molecular weight of about 12,800 was purified to electrophoretic homogeneity from Daucus carota cells. The protease inhibitor was heat stable and inhibited trypsin but had no activity toward chymotrypsin or subtilisin. Nonembryogenic as well as embryogenic strains contained the inhibitor in similar amounts, but in the embryogenic strains the trypsin inhibitor was released from the cells and as a result accumulated in high concentrations in the culture medium, whereas no release of the trypsin inhibitor was found during cultivation of the nonembryogenic strains. Very low amounts of acid phosphatase or α-mannosidase activity were found in the culture filtrate of both embryogenic and nonembryogenic strains, which suggest that the release of the inhibitor from embryogenic strains was not due to cell lysis.     

REGULATION OF BONE MARROW CELL GROWTH IN DIFFUSION CHAMBERS: THE EFFECT OF GRANULOCYTE EXTRACTS

Hypotonic lysis of mature human blood granulocytes yielded an extract which reduced granulopoiesis and enhanced macrophage formation of mouse bone marrow cells cultured for 7 days in diffusion chambers (DC). The low molecular weight fraction (MW < 15,000–25,000 Daltons) obtained by Amicon filtration of the extract, reduced granulopoiesis without affecting macrophage formation. The high molecular weight fraction (MW > 15,000–25,000 Daltons) reduced the number of granulocytes and increased the number macrophages. Erythrocyte extract increased the macrophage formation in DC but did not alter the number of granulocytes. The spleen colony assay showed that the granulocyte extract increased the number of CFU-S in DC. It is suggested that the granulocyte extract contain an inhibitor of stem cell differentiation to myeloid cells thereby reducing the number of proliferative granulocytes in DC 7 days later. The inhibitor of differentiation may lead to an increased self renewal of the stem cell in the DC system.     

Cell Cycle Synchronization at the G2/M Phase Border by Reversible Inhibition of CDK1

Chemical agents for cell cycle synchronization have greatly facilitated the study of biochemical events driving cell cycle progression. G1, S and M phase inhibitors have been developed and used widely in cell cycle research. However, currently there are no effective G2 phase inhibitors and synchronization of cultured cells in G2 phase has been challenging. Recently, a selective CDK1 inhibitor, RO-3306, has been identified that reversibly arrests proliferating human cells at the G2/M phase border and provides a novel means for cell cycle synchronization. A single-step protocol using RO-3306 permits the synchronization of >95% of cycling cancer cells in G2 phase. RO-3306 arrested cells enter mitosis rapidly after release from the G2 block thus allowing for isolation of mitotic cells without microtubule poisons. RO-3306 represents a new molecular tool for studying CDK1 function in human cells.     

Effects of endotoxin on proliferation of human hematopoietic cell precursors

In examining the effects of corticosteroids on hematopoiesis in vitro, we observed that results were highly dependent on the lot of commercial fetal calf serum (FCS) utilized. We hypothesized that this variability correlated with the picogram (pg) level of endotoxin contaminating the FCS. Randomly obtained commercial lots of FCS contained 0.39 to 187 pg/ml of lipopolysaccharide (LPS). Standard FCS concentrations in hematopoietic precursor proliferation assays (granulocyte-marcrophage colony forming units [CFU-GM]) resulted in final LPS levels as high as 40 pg/ml. LPS (2–5 pg/ml) added to essentially endotoxin-free cultures, induced human mononuclear cell release of interleukin (IL)-1, IL-6 and granulocyte colony stimulating factor (G-CSF). Lots of FCS induced the release of IL-1, IL-6, and G-CSF from human mononuclear cells and the release of these factors correlated with the level of contaminating LPS. Human bone marrow CFU-GM proliferation, in response to granulocyte-macrophage colony stimulating factor (GM-CSF), positively correlated with the level of LPS contaminating the FCS and the FCS-induced release of IL-6 from mononuclear cells. CFU-GM proliferation of human bone marrow cluster of differentiation (CD) 34+CD14-cells were not affected by the presence of endotoxin. These data suggest that LPS at 2–5 pg/ml may induce bone marrow accessory cell release of hematopoietic growth factors, thus altering proliferative response of hematopoietic precursors and confounding the study of exogenously added cytokines to culture systems. This revised version was published online in July 2006 with corrections to the Cover Date.     

Cell Cycle-Dependent Modulation of Biosynthesis and Stimulus-Evoked Release of Catecholamines in PC12 Pheochromocytoma Cells

Catecholamine biosynthesis and its stimulus-evoked release in PC12 pheochromocytoma cells were studied as a function of cell cycle by means of HPLC with electrochemical detection. We found that 3,4-dihydroxyphenylethylamine (dopamine) levels in PC12 cells remained constant throughout the period of cell cycle. In contrast, the noradrenaline content was dependent on the cell cycle: it increased during the S + G2 phase followed by a decrease in the M phase. These results were confirmed further by measuring the activities catalyzing the catecholamine biosynthesis. Thus, activities of tyrosine 3-monooxygenase and 3,4-dihydroxyphenylalanine decarboxylase were independent of the cell cycle, whereas both soluble and membrane-bound dopamine beta-monooxygenase activities were modulated during the cell cycle. On the other hand, release of the catecholamines stimulated with 50 mM KCl increased in the G1 phase, reached a maximum in the late G1, and then gradually decreased in later periods. We also found that carbamylcholine-induced release of the catecholamines occurred maximally in the early S + G2 phase followed by a decrease during the M phase. Cell cycle dependence of the catecholamine release was in good agreement with that of 45Ca2+ uptake. Thus, this study provides evidence that the catecholamine biosynthesis and its release in PC12 cells are modulated during the period of cell cycle.     

Purification and characterization of a DNA synthesis inhibitor protein from mouse embryo fibroblasts

A DNA synthesis inhibitor protein was purified from the conditioned medium of cycloheximide treated mouse embryo fibroblasts. This protein has a molecular weight of 45,000 as determined by gel filtration and Polyacrylamide gel electrophoresis. The levels of the [³⁵S] methionine la belled 45 kDa protein in the medium and matrix were monitored across two cell cycles in synchronized cultures. The 45 kDa protein was present in higher levels in the medium of non-S-phase cells depicting a peak between the two S-phases. The DNA synthesis inhibitor protein was immunologically related to a chicken DNA-binding protein which showed similar cell cycle specific variations at the intracellular level. The purified 45 kDa protein inhibited DNA synthesis in murine and human cells. In mouse embryo fibroblasts, the DNA synthesis was inhibited to an extent of 86% by 0.25 μg/ml of the inhibitor, while higher amounts of the inhibitor were required to arrest DNA synthesis in human skin fibroblasts: in these cells, 4 μg/ml of the inhibitor inhibited DNA synthesis to an extent of 50%. The high levels of the 45 kDa protein in the medium of non-S phase cells and its DNA synthesis inhibitory potential suggest that this protein may be involved in the regulation of DNA synthesis during the cell cycle.     

Reproducibility and usability of chronic virus infection model using agent-based simulation; comparing with a mathematical model

We created agent-based models that visually simulate conditions of chronic viral infections using two software. The results from two models were consistent, when they have same parameters during the actual simulation. The simulation results comprise a transient phase and an equilibrium phase, and unlike the mathematical model, virus count transit smoothly to the equilibrium phase without overshooting which correlates with actual biology in vivo of certain viruses. We investigated the effects caused by varying all the parameters included in concept; increasing virus lifespan, uninfected cell lifespan, uninfected cell regeneration rate, virus production count from infected cells, and infection rate had positive effects to the virus count during the equilibrium period, whereas increasing the latent period, the lifespan-shortening ratio for infected cells, and the cell cycle speed had negative effects. Virus count at the start did not influence the equilibrium conditions, but it influenced the infection development rate. The space size had no intrinsic effect on the equilibrium period, but virus count maximized when the virus moving speed was twice the space size. These agent-based simulation models reproducibly provide a visual representation of the disease, and enable a simulation that encompasses parameters those are difficult to account for in a mathematical model.     

Nucleotide and prostaglandin cycling in canine cyclic hematopoiesis

Bone marrow cells were collected from normal dogs, normal dogs made neutropenic with cyclophosphamide, and 11 dogs affected with cyclic hematopoiesis (CH) on 3 consecutive days of separate 12- to 14-day cycles. The mononuclear marrow cells from both groups of control dogs and from the CH dogs on each of 12-cycle days were cultured for 2.5 hr in serum-free media. The amounts of prostaglandins (PGF2 alpha and PGE) and cyclic GMP (cGMP) measured in the media were found to vary with the cycle in the CH dog. PGF2 alpha was highest as the dogs recovered from the neutropenia and lowest 4 days before the onset of the next neutropenic episode. Cyclic GMP was lowest 4-5 days before the onset of neutropenia, then dramatically increased as the neutropenic period approached. Cyclic GMP was highest when PGF2 alpha was lowest. Normal dogs, made neutropenic with a single dose of cyclophosphamide, had elevations of PGF2 alpha but not PGE or cGMP during the recovery period of active granulopoiesis.     

Production of proliferation inhibitors by mature granulocytes

The aim of the experiments was to find ways of increasing the yield of small molecular weight inhibitors of cell proliferation released by granulocytes. Almost pure populations of granulocytes from pig or human blood, or from sterile inflammatory exudates in rats were treated in various ways and then spun down. Molecules below approximately 10 000 dalton (Diaflo ultrafiltration or Sephadex G 25 filtration) in the supernatants were tested for inhibitory activity by measuring 3H-thymidine incorporation in 5 to 6-h coverslip cultures of rat bone marrow cells. The different granulocyte treatments were: Freeze-thawing, sonication, incubation (at +4 degrees -37 degrees C) in hypotonic media (0-200 mosm/kg), storage in vitro overnight (at +4 degrees C) before incubation, incubation at 37 degrees C in complete and buffered tissue culture medium (Fischer's with 10 mmol/1 HEPES), incubation in saline only (2-h periods, approximately 70 X 10(6) cells/ml), or with lidocaine added, with Ca++ and the Ca++ ionophore A-23187, with K+ and the K+ ionophore Valinomycin, with a high K+ concentration (50 mmol/1), with arachidonic acid, with a cAMP analogue, or with a protease inhibitor added during or at the end of the incubation. On a per cell basis rat peritonitis granulocytes released more inhibitor than pig blood granulocytes, whereas human blood granulocytes were not detectably inhibitory at all. Arachidonic acid was the most promising agent tested to increase inhibitor release above that occurring spontaneously from granulocytes incubated in saline.     

Identification of leukemia cell-derived inhibitory activity (LIA) in conditioned media from human myeloid leukemic cell line ML-2

Conditioned media from the human myeloid leukemic cell line ML-2 contain a factor that inhibits the entry of normal CFU-GM into S phase of mitotic cycle as measured by the 3H-TdR suicide technique. This factor was detected in conditioned media prepared by incubating 5 X 10(6) ML-2 cells/ml or 1 X 10(6) ML-2 cells/ml in serum-free RPMI for 5 or 24 hours respectively, and was isolated by ultrafiltration through an XM 300 Diaflo membrane followed by chromatography on Sepharose 6 B. Ferritin, prepared from human placenta, had the same inhibitory effect on CFU-GM. Antibodies against human placental ferritin completely inactivated the inhibitory effect of both human placental ferritin and the factor released from ML-2 cells. The inhibitory activity produced by the cell-line ML-2 was considered as LIA (leukemia cell-derived inhibitory activity) earlier found in HL-60 cell line and AML and CML cells.