Colony formation by mouse peritoneal exudate cells in vitro

Contribution of clonally distinct subpopulations to heterogeneous production of inducible nitric oxide synthase by LPS-stimulated mouse macrophages

Expression of the inducible nitric oxide synthase (iNOS) gene in mouse macrophages can be induced by bacterial lipopolysaccharide (LPS). iNOS (EC 1.14.13.39) catalyzes production of the reactive nitrogen intermediate, nitric oxide (NO), which is very important to macrophage-mediated host defense in species such as the mouse and rat. We have investigated production of iNOS at the level of single cells through immunocytochemical analysis of LPS-stimulated macrophages. Both bone marrow culture-derived macrophages and those of the cell line, RAW 264.7, were examined. Heterogeneous production of iNOS within macrophage populations was explained in part by the existence of clones that were high producers of iNOS and, therefore, NO, while other clones were reproducibly low producers of each. All clonally derived populations continued to demonstrate heterogeneous iNOS production, suggesting that at least one additional mechanism must be responsible for the phenomenon of heterogeneity. In contrast to iNOS, LPS-stimulated macrophages synthesized interferonβ (IFNβ) uniformly throughout the population.

Fcgamma receptor cross-linking stimulates cell proliferation of macrophages via the ERK pathway

Macrophage proliferation can be stimulated by phagocytosis and by cross-linking of Fcgamma receptors (FcgammaR). In this study, we investigated the role of FcgammaR and the signaling cascades that link FcgammaR activation to cell cycle progression. This effect was mediated by the activating FcgammaR, including FcgammaRI and III, via their Fcgamma subunit. Further investigation revealed that the cell cycle machinery was activated by FcgammaR cross-linking through downstream signaling events. Specifically, we identified the extracellular signal-regulated kinase (ERK) signaling pathway as a mediator of signals from FcgammaR activation to cyclin D1 expression, because cyclin D1 expression associated with FcgammaR cross-linking was attenuated by specific inhibitors of the ERK1/2 signaling pathway, PD98059 and U0126 and the spleen tyrosine kinase (Syk) inhibitor, Piceatannol. Our findings establish a link between the ERK activation and cell cycle signaling pathways, thus providing a causal mechanism by which FcgammaR activation produces a mitogenic effect that stimulates macrophage proliferation. Macrophage mitosis following FcgammaR activation could potentially affect the outcome of macrophage interactions with intracellular pathogens. In addition, our results suggest the possibility of new treatment options for certain infectious diseases, chronic inflammatory diseases, and leukemias based on interference with FcgammaR-stimulated macrophage cell proliferation.

The outcome of phagocytic cell division with infectious cargo depends on single phagosome formation

Given that macrophages can proliferate and that certain microbes survive inside phagocytic cells, the question arises as to the post-mitotic distribution of microbial cargo. Using macrophage-like cells we evaluated the post-mitotic distribution of intracellular Cryptococcus yeasts and polystyrene beads by comparing experimental data to a stochastic model. For beads, the post-mitotic distribution was that expected from chance alone. However, for yeast cells the post-mitotic distribution was unequal, implying preferential sorting to one daughter cell. This mechanism for unequal distribution was phagosomal fusion, which effectively reduced the intracellular particle number. Hence, post-mitotic intracellular particle distribution is stochastic, unless microbial and/or host factors promote unequal distribution into daughter cells. In our system unequal cargo distribution appeared to benefit the microbe by promoting host cell exocytosis. Post-mitotic infectious cargo distribution is a new parameter to consider in the study of intracellular pathogens since it could potentially define the outcome of phagocytic-microbial interactions.

MRL/lpr and MRL+/+ Macrophage DNA Synthesis in the Absence and the Presence of Colony-Stimulating Factor-1 and Granulocyte-Macrophage Colony-Stimulating Factor

Macrophage accumulation and proliferation as well as altered macrophage properties have been observed in autoimmune MRL mice. To determine whether there might be innate differences in the proliferative responses, we examined the DNA synthesis responses of peritoneal macrophages and macrophages derived in vitro from bone marrow precursors (bone marrow-derived macrophages (BMM)). Murine peritoneal exudate macrophages normally require the addition of macrophage CSF (CSF-1) to enter cell cycle in vitro. In contrast, we have found that many thioglycollate-induced adherent peritoneal macrophages, but not resident peritoneal macrophages, from both MRL/lpr and MRL+/+ mice atypically underwent DNA synthesis even in the absence of added CSF-1. They also responded very well to granulocyte-macrophage CSF. These findings may help to explain the appearance of increased macrophage numbers in MRL lesions. In contrast to a previous report, it was found that MRL/lpr and MRL+/+ BMM did not have an enhanced response to CSF-1 and that modulation of CSF-1 receptor expression was not more rapid in MRL BMM. We also found no evidence for abnormal CSF-1 internalization and degradation or for the lpr mutation to have any enhanced effect on BMM survival in the absence of CSF-1. TNF-α lowered the DNA synthesis response to CSF-1 of MRL/lpr BMM rather than enhanced it, as has been reported. Our data suggest that the enhanced accumulation of macrophages in the MRL/lpr kidney cannot be explained by a proposed model of enhanced responsiveness of MRL/lpr BMM to CSF-1, including a contribution by TNF-α.

Macrophage Lineage Cells in Inflammation: Characterization by Colony-Stimulating Factor-1 (CSF-1) Receptor (c-Fms), ER-MP58, and ER-MP20 (Ly-6C) Expression

Macrophage populations resident in tissues and at sites of inflammation are heterogeneous and with local proliferation sometimes evident. Using the convenient murine peritoneal cavity as an inflammation model, the appearance of macrophage lineage cells was followed with time in both thioglycollate- and sodium periodate-induced exudates. The cells were characterized by their proliferative response in vitro in response to colony-stimulating factor-1 (CSF-1) (or macrophage colony-stimulating factor [M-CSF]), particularly by their ability to form colonies in agar, in combination with flow cytometry (surface marker expression and forward and side scatter characteristics). We propose that c-Fms (CSF-1 receptor), unlike other markers, is a uniformly expressed and specific marker suitable for the detection of macrophage-lineage cells in tissues, both in the steady state and after the initiation of an inflammatory reaction. It was shown that the bone marrow myeloid precursor markers, ER-MP58 and ER-MP20 (Ly-6C), but not ER-MP12 (PECAM-1), are expressed by a high proportion of macrophage-lineage cells in the inflamed peritoneum. The macrophage colony-forming cells (M-CFCs) in a 16-hour thioglycollate-induced exudate were phenotyped as c-Fms+ERMP12−20+58+, properties consistent with their being more mature than bone marrow M-CFCs. It is proposed that ER-MP58, as well as ER-MP20, may be a useful marker for distinguishing inflammatory macrophage-lineage cells from the majority of those residing normally in tissues.

© 1998 by The American Society of Hematology.

Macrophage Lineage Cells in Inflammation: Characterization by Colony-Stimulating Factor-1 (CSF-1) Receptor (c-Fms), ER-MP58, and ER-MP20 (Ly-6C) Expression

Macrophage populations resident in tissues and at sites of inflammation are heterogeneous and with local proliferation sometimes evident. Using the convenient murine peritoneal cavity as an inflammation model, the appearance of macrophage lineage cells was followed with time in both thioglycollate- and sodium periodate-induced exudates. The cells were characterized by their proliferative response in vitro in response to colony-stimulating factor-1 (CSF-1) (or macrophage colony-stimulating factor [M-CSF]), particularly by their ability to form colonies in agar, in combination with flow cytometry (surface marker expression and forward and side scatter characteristics). We propose that c-Fms (CSF-1 receptor), unlike other markers, is a uniformly expressed and specific marker suitable for the detection of macrophage-lineage cells in tissues, both in the steady state and after the initiation of an inflammatory reaction. It was shown that the bone marrow myeloid precursor markers, ER-MP58 and ER-MP20 (Ly-6C), but not ER-MP12 (PECAM-1), are expressed by a high proportion of macrophage-lineage cells in the inflamed peritoneum. The macrophage colony-forming cells (M-CFCs) in a 16-hour thioglycollate-induced exudate were phenotyped as c-Fms+ERMP12−20+58+, properties consistent with their being more mature than bone marrow M-CFCs. It is proposed that ER-MP58, as well as ER-MP20, may be a useful marker for distinguishing inflammatory macrophage-lineage cells from the majority of those residing normally in tissues.

© 1998 by The American Society of Hematology.

Activation of mouse peritoneal macrophages in vitro or in vivo by recombinant murine gamma interferon inhibits the growth of Chlamydia trachomatis serovar L1

Peritoneal mouse macrophages activated in vitro with recombinant murine gamma interferon (10 ng/ml) or in vivo (10 micrograms per mouse) showed a significant decrease in the growth and yield of Chlamydia trachomatis. The restriction of the growth of C. trachomatis paralleled the expression of Iad on the macrophages. Mice that received macrophages activated in vitro with recombinant murine gamma interferon showed a significant decrease in the yield of chlamydial infection-forming units from their spleens and peritoneal fluids.

Proliferation of peritoneal mast cells in the skin of W/Wv mice that genetically lack mast cells

Presence of mast cell precursors in the mouse peritoneal cavity was demonstrated, and the precursors were characterized. When a cell suspension, containing mast cell precursor(s), was directly injected into the skin of genetically mast cell-deficient WBB6F1 (WB X C57BL/6)-W/Wv mice, a cluster composed of approximately 2,000 mast cells appeared at the injection site. By determining the proportion of injection sites at which the mast cell cluster appeared, the concentration of mast cell precursors can be calculated by limiting dilution analysis. The concentration in the peritoneal cavity was about five times as great as the concentration in the bone marrow. Although peritoneal mast cell precursors were shown to originate from the bone marrow, physical characterization revealed that the peritoneal precursors differed from the marrow precursors. The peritoneal precursors were less susceptible to irradiation than the marrow precursors; the former were heavier than the latter. When a 95% pure mast cell suspension was prepared from the peritoneal cells by the removal of phagocytes and the density gradient centrifugation, 1 out of 16 cells had the potentiality to make a mast cell cluster in the skin of the W/Wv mice. Moreover, when a single mast cell was identified under the phase contrast microscope and picked up with the micromanipulator, 1 out of 17 mast cells made the cluster. This indicated that some peritoneal mast cells kept extensive proliferative potentiality even after morphological differentiation. In other words, some peritoneal mast cells themselves may function as the committed precursors.

Clonal proliferation of peritoneal exudate cells from New Zealand black mice: age-related changes

Proliferation and differentiation of peritoneal exudate colony-forming cells (PE-CFC) were examined in BALB/c, C57BL/6, and NZB mice; NZB mice provided an experimental animal model for studies of autoimmunity. At 1 and 12 months of age, the number of PE-CFC from NZB mice was significantly less than the number of PE-CFC for other tested strains, whereas the number of clusters formed was reduced only in the older NZB mice. In contrast, 1- to 12-month-old BALB/c and C57BL/6 mice showed no significant age or strain-dependent alterations in PE-CFC. Although the latency period preceding colony growth remained constant for all strains and ages, significant variation in colony size was observed for NZB mice; the largest colonies were noted in the oldest group. We also observed age-associated variations in colony morphology; therefore, age- and strain-dependent differences may exist in the differentiation or functional attributes of PE-CFC subpopulations. The results specifically indicate that NZB mice have age-related alterations in PEC proliferative and differentiation capacities.

Macrophage growth inhibitors derived from the murine peritoneal cavity

The murine peritoneal cavity contains factors that inhibit the in vitro growth and colony formation of macrophages. The inhibition of macrophage growth is not due to cell death. In the presence of inhibitors, the growth of colony-forming macrophages is suppressed, and small clusters are formed as a result of limited proliferation. The more mature mononuclear phagocytes (blood monocytes and peritoneal exudate macrophages) are more sensitive to the overall inhibitory effect of the peritoneal inhibitors than the less mature bone marrow mononuclear phagocytes. Furthermore, using dialysis and Amicon ultrafiltration, at least two inhibitors with differential inhibitory effects can be demonstrated. The colony formation of bone marrow mononuclear phagocytes is suppressed mainly by a protease-resistant, small molecular weight (less than 1,000) dialyzable inhibitor. In contrast, peritoneal exudate macrophages are sensitive to both the small molecular weight inhibitor and a protease-sensitive, large molecular weight (greater than 12,000), nondialyzable inhibitor. The data suggest a possible existence of a dual inhibitor control on the proliferation of mononuclear phagocytes in vivo. In addition, the in vitro cultured peritoneal exudate cells are capable of producing inhibitors that mimic the activity of the in vivo inhibitors.

Role of laboratory chemosensitivity testing in the selection of cancer chemotherapy for individual patients

Recently several assays have been developed which allow the growth of colonies from cell suspensions prepared from human tumour biopsy specimens. It has been suggested that such assays will provide a reliable means of measuring the chemosensitivity of human tumours for predicting the response to treatment in patients. We have briefly reviewed the previous, largely unsuccessful, attempts at chemosensitivity testing and the potential place of the new assays. The measurement of the survival of clonogenic tumour cells after cytotoxic treatment probably reflects to some extent the survival of cells which in vivo are capable of proliferating to repopulate and regrow the tumour. This endpoint therefore has advantages over alternatives that do not directly measure reproductive cell death, and the assays also have the advantage of suppressing the growth of many non-malignant cells found in tumours. However, technical problems such as the preparation of cell suspensions and the artificial nature of the drug exposure phase of the assays have not been completely overcome and the plating efficiencies remain low in most systems. Work with model systems such as human tumour xenografts tends to support the usefulness of the assays but also highlights some difficulties. Clinical studies of chemosensitivity testing are in progress and initial results are encouraging but inconclusive.

Cell growth and antimicrobial activity of mouse peritoneal macrophages in response to glucocorticoids, choleragen and lipopolysaccharide

Normal, thioglycollate-stimulated and BCG-activated mouse peritoneal macrophages were cultivated in vitro with the conditioned medium of mouse L-929 cells. The thioglycollate- and BCG-macrophages rapidly proliferated, whereas normal macrophages grew more slowly. A clear morphological difference between the three types of macrophages in the culture was observed. Glucocorticoids inhibited the growth of the macrophages at pharmacological concentrations. Other steroids, progesterone, diethylstilbestrol and testosterone in that order, had a far lower growth-inhibiting effect. Macrophages cultured with 10(-6) M dexamethasone had a reduced antimicrobial effect on Candida parapsilosis compared with that of the untreated cells. Choleragen had the same effect on the macrophages as glucocorticoids. The toxin inhibited growth at a concentration as low as 10 pg/ml and cells treated with 1 ng of choleragen per ml had decreased antifungal activity. Similarly, Escherichia coli lipopolysaccharide at 10 ng/ml inhibited the growth of thioglycollate-macrophages. However, macrophages incubated with the lipopolysaccharide had enhanced anticandida activity. Thus, the immunosuppressors glucocorticoid and choleragen inhibited both the increase in the number of macrophages and the microbicidal activity of the phagocytes. Lipopolysaccharide, an immunostimulant, stimulated macrophage activity, but was toxic for cell growth.

Macrophages as a source of tumoricidal activity (tumor-necrotizing factor)

Macrophage-enriched peritoneal exudate cells from mice infected with Mycobacterium bovis BCG, macrophage-like tumor cells (PU 5-1.8), and peritoneal macrophages propagated in vitro with macrophage growth factor released tumoricidal activity into the culture medium within 2 to 3 h after stimulation with nanogram quantities of bacterial lipopolysaccharide. The cytotoxic activities from each of the macrophage culture supernatants eluted from diethylaminoethyl-Sephacel columns at a sodium chloride concentration of 200 mM exhibited a molecular weight of 50,000 to 60,000 as estimated by gel filtration, were stable at 56 degrees C for 30 min, and were active at a pH range of 6 to 10. A rabbit antiserum directed against serum-derived cytotoxic activity (tumor-necrotizing factor) from BCG-infected and lipopolysaccharide-challenged mice inhibited all of the cytotoxic activities generated in vitro. This suggests that the macrophage-derived cytotoxins are identical with serum-derived cytotoxic factor, which further implies that the macrophage is the cellular source of tumor-necrotizing factor.

Formation of mononuclear phagocyte (macrophage) colonies by mouse spleen cells in liquid culture. I. Kinetics of appearance of colonies and characterization of macrophage colony-forming cells

When spleen cells of the adult mouse were tested for the formation of mononuclear phagocyte (macrophage) colonies by the liquid culture technique with an incubation period of 7--8 days, about 100 macrophage colonies were produced from 1 X 10(6) cells. The number of macrophage colonies appearing after 2 days of incubation was small, but thereafter increased progressively up to at least 8 days. In the later stages of incubation (after day 6) large colonies consisting of more than 100 cells appeared. Macrophage colonies in the early stages consisted almost solely of macrophages. On day 6 significant numbers of small round mononuclear cells with no detectable phagocytic activity were seen in the center of large colonies, and by day 8 marked crowding of these cells had occurred. The peripheral region of the large colonies consisted mainly of macrophages and the intermediate region of middle-sized round or slightly stretched cells with weak phagocytic activity. Approximately two-thirds of the colony-forming cells still remained after glass-adherent cells were removed from the spleen cells by passing over a glass-bead column. In cultures of glass-nonadherent cells macrophage colonies were not generated in the early stage. The number of colony-forming cells did not change significantly even after actively phagocytic cells were rigorously removed from the spleen cells. In addition, no macrophage colonies were generated in cultures of spleen cells treated with mitomycin C.

Transformation of mouse peritoneal macrophages and bone marrow cells by simian virus 40

A fraction of cultured mouse peritoneal macrophages and bone marrow cells acquired the ability to divide after infection by simian virus 40 (SV40). Two types of transformed lines were obtained. Most transformants isolated 400-60 days after infection did not display macrophage specific properties such as ingestion of opsonized red blood cells, possession of Fc receptors and complement receptors, and acid phosphatase activity throughout the whole culture phase. Cells of the transformed lines isolated by trypsin selection 2--6 months after infection displayed these properties when the cell density became high and cell growth was arrested. In the cells of the latter type of transformed lines, SV40 T-antigen was intensely demonstrated by immunofluorescence in the growing phase, but weakly or not at all in the stationary phase. It is suggested that the reversion to the phenotype of the progenitor (expression of macrophage specific functions) depends on the physiological state of the culture; however, it is uncertain whether the development of the macrophage functions is directly related to the SV40 T-antigen.

Complement proteins and macrophages. 1. Quantitative estimation of factor B produced by mouse peritoneal macrophages

Cobra venom factor was used for the detection of factor B synthesized by mouse peritoneal macrophages. This method was shown to be specific for factor B assay by neutralization by antimouse factor B antibody. The amount of factor B in the culture supernatant, assessed by this method, was found to be dependent on the medium used for cultivation of macrophages. The addition of 25% L cell-conditioned medium to minimal essential medium (LCM-MEM) enhanced the production of factor B and also of lysozyme. Kinetic analysis in LCM-MEM showed that factor B produced by 6 x 10(4) cells/cm2 increased up to 72 hr and reached a plateau at 96 hr. The amounts of factor B and lysozyme produced in LCM-MEM depended upon the number of macrophages. Production of factor B was completely inhibited by 1 microgram of cycloheximide per ml and was restored by its removal.

Cultures of Chlamydia trachomatis in mouse peritoneal macrophages: factors affecting organism growth

Growth of Chlamydia trachomatis B/TW-5/OT and L(2)/434/Bu strains in cultures of thioglycolate-activated mouse peritoneal macrophages was studied. Both strains grew to a limited extent in the macrophages, but lymphogranuloma venereum (LGV) grew better than trachoma. Growth was enhanced by centrifugation of the inoculum onto the macrophage cell layer and inhibited by pretreatment of macrophages for 2 h with 100 mug of concanavalin A per ml. No significant effect was observed by pretreatment of macrophages with diethylaminoethyl-dextran (30 mug/ml, 30 min), cytochalasin B (20 mug/ml, 1 h), and cyclophosphamide (200 mug/ml, overnight) or by treatment with hydrocortisone (1 and 10 mug/ml, overnight before inoculation and during a 2-day incubation after inoculation). Resistance to intracellular growth of the two organisms was not increased in macrophages obtained from mice immunized with the organisms compared with macrophages from nonimmunized mice unless they were pretreated in vitro with penicillin (100 U/ml, overnight). The yields of LGV organisms from the penicillin-pretreated macrophages of LGV-immunized mice were 100-fold less than from the pretreated macrophages of nonimmunized control mice. At the same time, the yields of LGV organisms from penicillin-pretreated macrophages of mice immunized with trachoma, gonococcus, and HeLa cells were not different from those obtained in pretreated macrophages of nonimmunized control mice.

Peritoneal exudate cells. IV. Characterization of colony forming cells

The adherence, phagocytic activity and buoyant density of mouse peritoneal exudate colony forming units (CFU-PE) were investigated. There was a significant enrichment in the proportion of CFU-PE in the adherent cells population, defined as cells adhering to a plastic surface within 30 minutes of incubation. The phagocytic activity of CFU-PE was studied by incubating exudate cells with iron particles for 45 minutes. The cells were then separated into phagocytic and non-phagocytic cell fractions by passing the incubation mixture through a magnetic field. A significant enrichment of CFU-PE was seen in the phagocytic cell fraction. When exudate cells were fractionated in a Ficoll discontinuous density gradient, more than 88% of CFU-PE were recovered at the 16/18% and 18/20% interfaces. It is concluded that CFU-PE are adherent cells, have strong phagocytic activity and have a buouant density between 1.0562 and 1.0703. When bone marrow cells were studied by these techniques, the committed stem cells for both granulocytes and marcophages (CFU-C) were enriched in both non-adherent cell and non-phagocytic cells populations. In the Ficoll density gradient, CFU-C banded at a heavier density region than CFU-PE.

Factors regulating macrophage production and growth: identity of colony-stimulating factor and macrophage growth factor

The activities of a colony-stimulating factor (CSF), which stimulates granulocyte-macrophage colony formation by mouse hemopoietic cells, and macrophage growth factor (MGF), which stimulates proliferation of activated peritoneal macrophages, have been demonstrated by various criteria to reside in the same molecular species. These criteria include occurrence in various sources and copurification of the activities in mouse L-cell-conditioned medium as well as the biological, physicochemical, and antigenic properties of the activities of L-cell-conditioned medium. CSF and MGF activities of L-cell-conditioned medium are ascribable to a glycoprotein of mol wt approximately 60,000 which migrates electrophoretically with alpha-globulin. Human urinary CSF, which also possesses MGF activity, has similar properties and can be neutralized by antiserum to highly purified L-cell medium CSF. A procedure is described for the partial purification of material from L-cell medium that has activity at 1 ng/ml in both MGF and CSF assays.

Clonal growth of hamster free alveolar cells in soft agar

Free alveolar cells obtained from healthy unstimulated hamsters were tested for their ability to form colonies in soft agar. Every bronchial washing so far tested contained colon-forming cells. The average plating efficiency was 8.1% (2.4-18.3%). Alveolar colony-forming cells were characterized by having a long initial lag period (4-8 days) and only mononuclear phagocytes were found in the colony. Medium conditioned by baby hamster kidney cells or other cells was required for the initiation and maintenance of their growth. Alveolar cells from normal mice and rats also formed colonies under appropriate culture conditions.

Formation of plaques by adherent spleen cells from nonimmunized mice, incubated in vitro with the nonadherent fraction of immune allogeneic cells

Twenty-four-hour incubation of adherent spleen cells from normal C57BL mice with purified nonadherent spleen cells from CBA mice, in the peak of their primary response against sheep red blood cells, resulted in the appearance of plaque-forming cells in the adherent cell population. The immunological nature of these plaques was demonstrated by their complement dependency and the inhibitory effect of specific anti-mouse IgM serum. Direct, but not indirect plaque formation was found to be associated with the adherent cell population for which direct cell to cell contact is necessary. Experiments with cytotoxic specific anti-strain sera revealed that in this system, the adherent plaque-forming cells are the nonimmune adherent C57BL cells.

Proliferation and colony-forming ability of peritoneal exudate cells in liquid culture

Peritoneal exudate cells, obtained from mice injected with thioglycollate medium and cultured in medium containing L-cell-conditioned medium, will proliferate in an exponential fashion for 18 days with a doubling time of 68 h. After a 2 h pulse of tritiated thymidine, labeled adherent cells increased to a maximum of 22-34% during the 1st and 2nd wk of culture. Increasing the cell concentration from 2 times 10-3 to 2 times 10-5 cells/culture reduced exponential growth to 10 days and the doubling time was increased to 81.6 h. Under these culture conditions, peritoneal exudate cells were shown to form colonies on the surface of culture dishes when plated at low density. The cells within the colony were shown to be macrophages using yeast and antibody-coated sheep erythrocytes as a test for phagocytic function. The plating efficiolonies arose from a single precursor cell. The adherent cell population contains the colony-forming precursors. These precursors can be stimulated to form colonies for at least 2 wk by the addition of conditioned medium to cultures at various times after plating. While very few colony-forming cells could be demonstrated in the unstimulated peritoneal lavage, their numbers begin to increase in the exudate 4 h after injection of thioglycollate medium and reach a maximum by day 3 and then decrease. Isolated colonies may be useful in studying the function of macrophages.

Isolation of a Sindbis virus variant by passage on mouse plasmacytoma cells

A variant of Sindbis virus has been isolated by growing a stock of virus, previously passaged on chicken embryo cells, in mouse plasmacytoma (MOPC 315) cells in suspension culture. An indirect immunofluorescence test and infective center assay showed that only a small fraction of cells could be infected by the stock wild-type virus, but that the population of virus accumulating after a few passages on the mouse cells had host-range properties distinct from the stock virus. The mouse-passaged virus retained its virulence for the original host and back-passaging of this virus on chicken cells did not change its newly acquired properties. Thus, this variant appears to be a genetically distinct form of Sindbis that adsorbs to and grows much better than the stock virus on several types of mouse cells including cultures of mouse macrophages.

The origin of chicken hematopoietic colonies as assayed in semisolid agar

This investigation was undertaken to determine whether primitive stem cells and/or fully differentiated macrophages were the source of in vitro colonies derived from hematopoietic tissues. The chicken colony-forming cell (CFC) present in uncultured yolk sac was a nonadherent, presumably undifferentiated cell. The efficiency of colony formation in this case was approximately 0.08%. In contrast to uncultured yolk sac, the CFC present in one-week old yolk sac cultures was evidently a macrophage. Yolk sac cultures, which consisted of greater than 99% macrophages, produced colonies with an efficiency of 1-5% while cultures derived from peritoneal macrophages produced colonies with an efficiency of 10%. Silica selectively destroyed macrophages and reduced the colony forming efficiency of cells derived from yolk sac cultures.