Increased activity of FIM in serum of mice during a Mycobacterium bovis (BCG) infection.

In mice given an intravenous injection of Mycobacterium bovis (BCG), the bacilli proliferated in the spleen, liver and lungs but the peritoneal cavity remained sterile. The numbers of blood monocytes and alveolar macrophages were increased during the first 2 weeks of the infection, whereas the number of peritoneal macrophages remained constant. To study whether factor-increasing monocytopoiesis (FIM) plays a role in the regulation of the monocytosis during the BCG infection, the activity of this factor in the serum of mice at various intervals during the infection was determined. Previous studies have shown that FIM stimulates monocyte production by its effect on the mitotic activity of monoblasts and promonocytes in the bone marrow. The FIM activity of the serum reached a maximum on Day 4 and remained elevated during the first 21 days of the BCG infection. Since FIM is synthesized and secreted by macrophages that have phagocytosed opsonized particles, it is highly probable that FIM occurring in serum originates from macrophages that have ingested BCG. The results of the present study led to the conclusion that FIM plays a role in the monocytosis developing during infection with BCG.

Effect of lung surfactant on the release of factor increasing monocytopoiesis by macrophages.

Upon ingestion of particulate and soluble material, at the site of an inflammation macrophages release the factor increasing monocytopoiesis (FIM), which accelerates the rate of division of the monoblasts and promonocytes in the bone marrow. It is not known, however, whether FIM is released by macrophages present at noninflamed sites. Since FIM is secreted only during phagocytosis and alveolar macrophages ingest surfactant in vivo, the present study was performed to find out whether surfactant induces the release of FIM by alveolar macrophages. Resident alveolar macrophages were found to contain FIM and secrete this factor in vitro in the absence of an introduced phagocytable particle. Resident peritoneal macrophages also contained FIM and released this factor after exposure to surfactant. These findings suggest that in the absence of an inflammatory stimulus in vivo, alveolar macrophages that have ingested surfactant release FIM to maintain the normal production of monocytes in the bone marrow.

Regulation of granulocyte responses in the blood and peritoneal cavity of CBA and B10 mice during an acute inflammation.

The regulatory mechanisms that determine the course of an inflammation induced by an intraperitoneal injection of kaolin were investigated in Listeria-susceptible CBA and Listeria-resistant B10 mice. The magnitude of the granulocyte inflammatory response in the peritoneal cavity was high in B10 mice (area under the curve; AUC0-48 h: 210.9 x 10(6) granulocytes/mouse x h) and lower in CBA mice AUC0-48 h: 136.8 x 10(6) granulocytes/mouse x h), whereas the reverse was seen for the granulocyte response in the peripheral blood (AUC0-48 h: 30.5 and 80.7 x 10(6) granulocytes/mouse x h, respectively). With respect to the presence of humoral factors that affect the number of granulocytes in the circulation, sera of both mouse strains sampled 24 h after the kaolin injection had granulocytosis-inducing effect in CBA recipient mice and did not induce a response in the B10 recipient mice. This divergent sensitivity to serum factors inducing granulocytosis is consistent with the difference in the blood granulocyte response of B10 and CBA mice but does not explain the divergent inflammatory responses in the peritoneal cavity. Computer simulation showed that at least two factors must be taken into consideration to explain the differences in the inflammatory response, i.e., a factor regulating the release of granulocytes from the bone marrow and a factor governing the rate of granulocyte efflux from the site of inflammation.

Macrophages as origin of factor increasing monocytopoiesis.

Earlier investigations had indicated that the factor increasing monocytopoiesis (FIM), present in the serum of mice and rabbits during the onset of an inflammatory response, is released by cells of the inflammatory exudate. The present study was performed to determine which cells produce and secrete this factor and to establish the kinetics of its production and secretion. FIM was assayed in vivo by intravenous injection of samples into untreated mice and monitoring the course of the number of blood monocytes in the recipients. FIM was assayed in vitro by adding samples to cultures of the macrophage cell line PU5 and determining the rate of proliferation of the cells. The results show that only macrophages contain and synthesize FIM. This factor is secreted upon exposure to a phagocytic stimulus, and after the release of preformed FIM, macrophages secrete newly synthesized FIM. Granulocytes and lymphocytes neither contain nor secrete FIM. The characteristics of FIM derived from macrophages are in all aspects similar to those of FIM in serum. Macrophage-derived FIM is a protein with a molecular weight between 10 and 25 X 10(3), its activity is cell-lineage specific and dose dependent, and it stimulates monocyte production in the bone marrow. Macrophage-derived FIM is not identical to either CSF-1 or IL-1, and has no chemotactic activity. Taken together, the present results show that FIM occurring in serum during an inflammatory response originates from macrophages at the site of the inflammation. In this way the macrophages themselves regulate the supply of circulating blood monocytes that can migrate to the site of injury when needed.

Cell kinetic analysis of a murine macrophage cell line.

For the present study, which was performed to find a reliable method suitable for determination of the cell kinetic parameters of a continuous cell line, use was made of the macrophage cell line J774.1. The doubling time of the cell population was approximately 27 h. The continuous labeling curve showed that all the cells divide and almost no quiescent cells occur. The cell-cycle time as determined from the curve of the labeled cells in mitosis, the course of the stathmokinetic index, and time-lapse videorecordings, was about 19 h. The discrepancy between the population doubling time and the cell-cycle time must be due to death and disintegration of cells during culture in vitro. The results indicate that the doubling time of a cell population is not a reliable parameter to determine the kinetics of a population of continuously proliferating cells and that determination of the course of the stathmokinetic index offers a rapid and simple method to establish the cell-cycle time reliably.

Morphological, cytochemical, functional, and proliferative characteristics of four murine macrophage-like cell lines.

The aim of the present study was to obtain objective data on the morphology and quantitative information about other characteristics of murine macrophage-like cell lines J774.1, PU5-1.8, WEHI-3, and P388-D1, and to compare the findings with those in resident and exudate macrophages collected directly from mice. Fetal fibroblasts were included to serve as controls. Evaluation of the morphological data showed that the cell lines J774.1 and WEHI-3 are almost identical in most respects, that the cells of P388-D1 differ widely from both of the former lines, and that the morphometric parameters of cell line PU5-1.8 occupy an intermediate position. The cells of the P388-D1 line show the most similarity to resident and exudate macrophages, and cell lines J774.1 and WEHI-3 the least. Fetal fibroblasts had divergent values for all morphometric parameters. Good correspondence was found when the quantitative data obtained by morphometric analysis of the cells in question were compared with the morphological pictures. No gross differences as to cytochemical characteristics were found between the cells of the four cell lines, except for 5'-nucleotidase activity. The occurrence of IgG receptors and the ingestion of EIgG were also similar, but the percentage of cells with C3b receptors was much lower in two of the cell lines (WEHI-3 and P388-D1) and the level of EIgMC ingestion was very much higher in one (J774.1) compared with both the other cell lines and the resident and exudate macrophages. The ingestion of opsonized bacteria and latex varied widely within and between the cell lines. Quantitative data on the binding of monoclonal antibodies by the cells of the macrophage cell lines and the resident and exudate macrophages showed a wide variation. The doubling time of the cell lines is on average 1 day; distinct differences were found between these lines with respect to the lag-time of proliferation after replating. Cluster analysis and statistical analysis of morphological and other characteristics gave insight into the degree of resemblance between the cells of the four cell lines on the one hand and the resident and exudate macrophages on the other.

Method to select mice in the steady state for biological studies.

Collection of small amounts of blood from the orbital sinus was found to be a satisfactory method for repeated sampling in mice, which means that these animals can be selected for further study on the basis of the leukocyte count. In biomedical research it is often necessary to have detailed information about the effect of injected material on the numerical course of circulating leukocytes. However, the present study has shown that 2 stress-producing procedures on 1 day disturb the steady state, and that this disturbance is expressed in changes in the number of leukocytes. Such stress could be avoided by alteration of the experimental design to include only 1 stressful situation each day. When blood was sampled in the orbital sinus on 1 day to determine the animals' condition and on the next day only the tail was punctured as sham injection, the number of blood leukocytes remained constant throughout the observation period. Comparative studies on the numbers of monocytes, lymphocytes, and granulocytes in blood from the tail, heart, and orbital sinus showed a systematic difference in the mean numbers of certain types of leukocytes. Statistically significant differences were found between the mean numbers of monocytes, lymphocytes, and granulocytes in orbital blood from normal mice of 5 specific pathogen-free strains, i.e., Cpb:SE (Swiss), CBA/Cpb, BALB/cCpb, C3H/Rij, and DBA/2Rij.

Differences in the response of inbred mouse strains to the factor increasing monocytopoiesis.

Previous studies have shown that monocyte production during an inflammatory response is controlled by the factor increasing monocytopoiesis (FIM), secreted by macrophages at the site of inflammation. The inflammatory reaction to latex particles and a saline-soluble extract of Listeria monocytogenes (SEL), expressed as the number of monocytes in the circulation and of macrophages at the site of inflammation, was about twice as strong in C57BL/10 mice compared with CBA mice. This raised the question as to the mechanism underlying these differences. One possibility might be that these mouse strains differ with respect to the production of FIM, but this cannot be the case because the maximum levels of FIM activity in the serum of both C57BL/10 and CBA mice given latex or SEL intraperitoneally were almost the same; however, the courses of FIM activity in the two strains after intraperitoneal latex were not exactly synchronous. Another possibility is that the sensitivity of monocyte precursor cells for FIM differs. Evidence for the latter was provided by the finding that the intravenous injection of sera with FIM activity obtained from C57BL/10 and from CBA mice into the C57BL/10 mice evoked monocytosis, whereas CBA mice did not respond to these sera. Earlier studies showed that an increase of monocytes after the injection of serum containing FIM reflects increased monocyte production. Taken together, the results of the present study demonstrate that one of the mechanisms underlying the genetic control of the inflammatory response is, rather than enhanced FIM synthesis, the ability of monocyte precursors in the bone marrow to respond to FIM by increased monocyte production.

Presence of the factor increasing monocytopoiesis (FIM) in rabbit peripheral blood during an acute inflammation.

An intraperitoneal injection of latex in rabbits was found to give rise to an increase in the number of macrophages at the site of inflammation and a concomitant monocytosis in the peripheral blood. The results showed that during the initial phase of the inflammatory reaction a humoral factor is present in the circulation of these animals that stimulates the monocyte production in the bone marrow in a concentration-dependent way. This factor has been called the factor increasing monocytopoiesis (FIM), in analogy with the name given to the factor previously found in mice. Rabbit FIM is cell-line specific since it has no effect on granulocyte or lymphocyte production, has an estimated molecular weight of between 10,000 and 25,000 daltons, was found to be sensitive to treatment with proteases, to be unaffected by glycosidases, and to be readily inactivated in vitro at 37 degrees C. Neither rabbit nor mouse FIM is species specific, since rabbit FIM evoked moderate monocytosis in mice and vice versa.

Culture of mononuclear phagocytes on a teflon surface to prevent adherence.

A method is described for the culture of mononuclear phagocytes in suspension by incubation on a Teflon film to which the cells do not adhere. The characteristics of peritoneal macrophages, bone marrow mononuclear phagocytes, macrophage cell lines, and fibroblasts cultured in this way are similar to those observed after culture on glass or plastic surfaces. Culture of mononuclear phagocytes in Teflon film dishes has three important advantages: the cells can be easily harvested without damage, recovery is almost complete, and the cells are not functionally impaired. Thus, this method makes it possible to use cultured mononuclear phagocytes for many studied that could previously only be done in freshly collected cells.