Population kinetic study on the origin of guinea pig monocyte heterogeneity

Population kinetic studies were performed on guinea pig peripheral blood monocyte fractions isolated by counter-flow centrifugation elutriation following a single in vivo pulse of tritiated thymidine. Labeled large monocytes (volume 317 micron3; relative distribution 49%; circulating half-life 5.7 hr; and production rate 17,000 cells/ml blood/hr) accumulated in the circulation more rapidly, had a faster turnover time, and were produced in greater numbers than small monocytes (volume 283 micron3; relative distribution 34%; circulating half-life 10.8 hr; and production rate of 6100 cells/ml blood/hr). The kinetic data do not support a maturational sequence of small into large monocytes. Intermediate monocytes (volume 300 micron3; relative distribution 11%; circulating half-life 18.2 hr) and very large monocytes (volume 354 micron3; relative distribution 6%; circulating half-life 36.5 hr) had production rates, respectively, of only 1200 and 320 cells/ml blood/hr. Maxima in the labeling index curve for small and large monocytes suggested a generation time of 24 hr while grain count analysis revealed that these two cell fractions were derived from a precursor population with similar numbers of reductive divisions. Grain count analysis of intermediate and very large monocytes revealed that these cells differed from both small and large monocytes. Our data support the concept that monocyte subsets exist in guinea pig peripheral blood with different kinetics of production and survival.     

OBSERVATIONS ON HUMAN MONOCYTE KINETICS AFTER PULSE LABELING

Monocyte kinetics were studied in seven hematologically normal individuals using in vivo pulse labeling with tritiated thymidine. Although occasional labeled cells appear in the peripheral blood within 4 or 5 hr of the administration of label, a significant outflow from the marrow begins 13–26 hr later. This interval is occupied by the G₂ and M phases of the mitotic cycle since mitotic cells are not observed in the peripheral blood. The duration of the DNA synthesis phase of monocytes is measured at 34 hr ≈ 1.8 hr. Cells do not enter this phase while circulating since exposure of circulating cells to tritiated thymidine does not result in any uptake. If monocytes are not 'end'cells which have completed their mitotic activity before leaving the marrow they must at least be inhibited from further proliferative activity until they are permanently sequestered in other tissues.
The generation time is probably not less than 40 hr and data derived from the mean grain counts of labeled cells suggest that it is often more than 70 hr. The total daily output of monocytes in man is 9.4 × 10⁸ cells per 24 hr ≈ 3.3 × 10⁸.
Cells leave the bloodstream with a half-time of about 71 hr thereby proving themselves to be considerably more durable than neutrophils which have a half-life in the neighborhood of 6 hr.     

Turnover and tissue distribution of 125-I-labeled low density lipoprotein in swine and dogs.

Swine plasma low density lipoprotein (LDL) isolated ultracentrifugally (d 1.019-1.063) was labeled with 125-I, dialyzed, and reisolated by centrifugation at d 1.063. Over 96% of the radioactivity was shown to be associated with the apoprotein. After reinjection into the donor animal, disapperance of 125-I was followed for up to 122 hr. At all time intervals examined, over 95% of the total plasma 125-I was recovered in LDL (D 1.006-1.063), i.e., there was apparently no transfer of radioactivity to high density or very low density lipoproteins. The disappearance curve was biexponential, with half-lives of 0.83 plus or minus 0.06 and 22.5 plus or minus 1.7 hr for the first and second phases, respectively (13 studies). The mean calculated fractional catabolic rate was 0.041 plus or minus 0.003 hr-minus 1. Similar results were obtained in three dogs using autologous LDL of density 1.020-1.050; fractional catabolic rates were 0.031, 0.031, and 0.029 hr-minus 1. Tissue distribution of 125-I was determined in swine killed at various time intervals after [125-I]LDL injection with corrections for radioactivity in trapped plasma. Of the tissues examined, the liver showed by far the highest concentration. Total hepatic radioactivity, expressed as a percentage of total plasma radioactivity, was rather constant and independent of the time of killing from 3 to 122 hr (15.8 plus or minus 1.9%). The total extravascular LDL pool calculated from analysis of the plasma disappearance curves was about 20-30% of the size of the plasma LDL pool. These data are consistent with the conclusion that the liver accounts for a very large fraction of the total extravascular LDL pool. These data are consistent with the conclusion that the liver accounts for a very large fraction of the total extravascular LDL pool and that it is infairly rapid equilibrium with the plasma pool. To what extent the liver is involved in irreversible degradation cannot be inferred from these findings.     

Immunological properties of partially purified material with monocytosis-producing activity from Listeria monocytogenes.

A fraction rich in a monocytosis-producing activity (MPA) has been obtained by a two-stage chromatographic separation from a saline extract (SE) of Listeria monocytogenes. Like SE, the purified material elicits monocytosis and decreases the halftime of circulating monocytes. The purification of MPA eliminates the following found in SE: the in vitro mitogenic activity, the in vitro adjuvant activity, the immunosuppressive activity, and the granulocytosis-promoting and the lymphopenia-inducing activities.     

Tumor necrosis factor alpha induction in human monocytes

The present study was undertaken to assess the presence of tumor necrosis factor (TNF)-alpha mRNA and protein in circulating human blood monocytes and to study the TNF-alpha gene expression in human monocytes isolated by continuous Percoll gradient fractionation. The technique of RNA isolation directly from the blood samples was used to study TNF-alpha mRNA expression in circulating human blood leukocytes. It was shown that human blood leukocytes of healthy donors contained no presynthesized pool of TNF-alpha mRNA as well as no TNF-alpha protein. It was found that early pretreatment with cycloheximide interferes with TNF-alpha mRNA induction by Staphylococcus aureus.     

Synthesis of tumor necrosis factor-alpha (TNF-alpha) by human monocytes in vitro]

The presence of TNF-alpha mRNA and protein in circulating human blood monocytes isolated by continuous Percoll gradient fractionation was studied. The technique of RNA isolation from the blood samples was used to study TNF-alpha mRNA expression. It was shown that human blood monocytes of healthy donors contained no presynthesized pool of TNF-alpha mRNA as well as no TNF-alpha protein.     

Decreased Fc receptor avidity and degradative function of monocytes from patients with systemic lupus erythematosus

We studied the binding and degradation of stable, soluble heat aggregates of 125I-IgG (A-IgG) by monocytes from 30 patients with systemic lupus erythematosus (SLE) and 30 normals. Relative avidities (KE) for Fc receptor (FcR) binding of A-IgG and maximal binding of A-IgG by monocytes were determined from Scatchard plots of binding data obtained at 4 degrees C. Rates of degradation (Vmax) of A-IgG at 37 degrees C were calculated from Lineweaver-Burke plots of the Michaelis-Menton equation. KE were decreased in SLE monocytes (15.5 X 10(-9) L/M) as compared with normals (20.1 X 10(-9) L/M, p less than 0.005) and Vmax were decreased for SLE (0.89 ng/hr) as compared with normals (1.11 ng/hr, p less than 0.005). The maximal FcR binding by SLE monocytes was not statistically different in SLE patients and normals, but monocytes from SLE patients with active disease showed a lower maximal binding capacity for A-IgG (4.9 ng/10(5) cells) than normals (5.4 ng/10(5) cells, p less than 0.05). KE and Vmax in SLE were also lower for patients with active disease than for normal subjects. KE in patients whose anti-ssDNA binding was greater than 20% were lower than for those with DNA binding of less than 20% (p less than 0.005). These data suggest that patients with active SLE have diminished numbers of available FcR on their circulating monocytes, possibly due to interiorization of FcR during endocytosis of endogenous circulating immune complexes.     

METHODS FOR COMPUTING LYMPHOCYTE KINETICS IN MAN BY ANALYSIS OF CHROMOSOMAL ABERRATIONS SUSTAINED DURING EXTRACORPOREAL IRRADIATION OF THE BLOOD

Data on lymphocyte kinetics may be derived in patients undergoing treatment by extracorporeal irradiation of the blood by studying chromosome aberrations induced in their lymphocytes; the aberrations are observed when the lymphocytes are stimulated by phytohaemagglutinin to divide in culture. Two methods of analysis are described, one depends on the total number of dicentrics scored, the other employs the dilution principle, regarding each lymphocyte bearing one or more aberrations as specifically labelled. Two parameters may be calculated: the mean residence time of lymphocytes in the blood and the size of the extravascular pool of lymphocytes in the body. In a patient with Hodgkin's disease, the mean residence time was found to be 4.7–7.5 min and the extravascular pool 800–1070 g.     

Involvement of CD147 in overexpression of MMP-2 and MMP-9 and enhancement of invasive potential of PMA-differentiated THP-1

Background  

During infection and inflammation, circulating blood monocytes migrate from the intravascular compartments to the extravascular compartments, where they mature into tissue macrophages. The maturation process prepares the cells to actively participate in the inflammatory and immune responses, and many factors have been reported to be involved in the process. We found in our study that CD147 played a very important role in this process.     

TNF skews monocyte differentiation from macrophages to dendritic cells

Monocytes represent a large pool of circulating precursors of APCs, both macrophages and dendritic cells (DCs). It is thus important to identify the mechanisms by which microenvironment regulates monocyte differentiation. We have previously shown that, upon contact with resting stromal cells such as fibroblasts, monocytes differentiate into macrophages in an IL-6/M-CSF-dependent fashion. Yet, in the inflamed tissue, monocytes need to yield DCs for the adaptive immunity to be induced. Inasmuch as TNF and IL-1 are present at the site of inflammation, we tested their capacity to modulate monocyte differentiation into either macrophages or DCs. TNF, but not IL-1, induce monocytes to become DCs despite the presence of fibroblasts. TNF-induced DCs contain Langerin-positive cells and are able to induce allogenic T cell proliferation. Then, TNF was found to decrease the expression and internalization of the M-CSF receptor, thus overriding the IL-6/M-CSF pathway. Thus, TNF facilitates the induction of adaptive immunity by promoting DC differentiation not only from CD34+ progenitors but also from CD14+ blood precursors.     

Monocyte kinetics in rabbits

Previous studies of monocytes isolated from peripheral blood have suggested that the lung sequesters these cells and has an important role in monocyte kinetics. However, the lung also provides the first capillary bed encountered by these cells after intravenous injection. A major criticism of the previous reports is that the behavior of monocytes in the lung may be altered as a result of the isolation procedure. The present study addresses this question by comparing the distribution of isolated monocytes (87% pure) in various organs 10 min after they were injected into either the central venous or the arterial circulation. The data show that the extraction of monocytes on the first passage through the lung after intravenous injection was 86.5 +/- 1.5%. After the monocytes had circulated for 10 min, the lungs contained 35.5 +/- 2.5% of the cells after intravenous injection and 29.7 +/- 2.2% after intra-arterial injection (P greater than 0.05). The lung-to-blood recovery ratio after either intravenous or intra-arterial injection showed that the lung contained a marginating pool of monocytes that was five to seven times the size of the circulating pool. The retention of monocytes in a region of the lung was proportional to the regional erythrocyte transit time. The half-life of the radiolabeled monocytes in the circulation was approximately 25 h. We conclude that the lung contains a marginating pool of monocytes and speculate that they concentrate there in preparation for migration into the interstitium and air space of the lung.     

Tumor necrosis factor α induction in human monocytes

The present study was undertaken to assess the presence of tumor necrosis factor (TNF)-α mRNA and protein in circulating human blood monocytes and to study the TNF-α gene expression in human monocytes isolated by continuous Percoll gradient fractionation. The technique of RNA isolation directly from the blood samples was used to study TNF-α mRNA expression in circulating human blood leukocytes. It was shown that human blood leukocytes of healthy donors contained no presynthesized pool of TNF-α mRNA as well as no TNF-α protein. It was found that early pretreatment with cycloheximide interfers with TNF-α mRNA induction by Staphylococcus aureus.     

Monocyte recruitment during infection and inflammation

Monocytes originate from progenitors in the bone marrow and traffic via the bloodstream to peripheral tissues. During both homeostasis and inflammation, circulating monocytes leave the bloodstream and migrate into tissues where, following conditioning by local growth factors, pro-inflammatory cytokines and microbial products, they differentiate into macrophage or dendritic cell populations. Recruitment of monocytes is essential for effective control and clearance of viral, bacterial, fungal and protozoal infections, but recruited monocytes also contribute to the pathogenesis of inflammatory and degenerative diseases. The mechanisms that control monocyte trafficking under homeostatic, infectious and inflammatory conditions are being unravelled and are the focus of this Review.     

Time dependence of transmembrane potential changes and intracellular calcium flux in stimulated human monocytes

An important characteristic of the functional differentiation of the blood monocyte is the development of its capacity to recognize and respond to stimuli. This ability is mediated to a large extent by specific receptor glycoproteins located on the cell surface. Stimulation of mononuclear phagocytes via these receptors results in a rapid rise in intracellular Ca++ concentration, accompanied or followed by a change in membrane potential, generation of oxidative products, degranulation, and effector functions such as phagocytosis, aggregation, or locomotion. While the development of these characteristics is difficult to characterize in vivo, several investigators have demonstrated in vitro changes in these cells that correlate with the development of effector function. To examine the mechanisms of specific membrane-stimulus interactions of monocytes as they differentiate into macrophage-like cells, we studied the responses of human monocytes and of monocytes incubated in serum-containing medium for up to 96 hr to the chemotactic peptide formyl-methionyl-leucyl-phenylalanine (fMLP). Freshly isolated monocytes exhibited little change in transmembrane potential following stimulation with an optimal concentration of peptide and underwent a significant increase only after 48 hr in culture. While constant resting intracellular Ca++ concentrations were maintained during the culture period, intracellular Ca++ levels following fMLP stimulation increased with with incubation in serum, for up to 96 hr. In contrast, fMLP-induced respiratory burst activity increased from 0 to 24 hr in culture; it remained elevated at 48 hr but declined again by 96 hr. Incubation of the cells for 24 hr increased their random (unstimulated) motility in modified Boyden chambers but did not alter the cells' directed (chemotactic) response to fMLP in comparison to the response of freshly isolated monocytes. Peptide binding to the cells did not increase during the incubation period, indicating that an increase in receptor number or in affinity for fMLP was not responsible for the enhanced responsiveness to fMLP as incubation time increased. These studies indicate that incubation of monocytes in serum-containing medium leads to a complex, altered series of responses to fMLP that correlate with the differentiation of the original monocytes in vitro and may relate to the in vivo differentiation of monocytes to macrophages.     

Population kinetic study of guinea pig monocytes and their subsets during acute inflammation

Guinea pig peripheral blood monocytes exist in four subsets which differ in cytochemistry, function, rates of production, and circulatory time during steady state. These subsets are designated small, intermediate, large, and very large vacuolated monocytes. To address the question as to whether all subsets participate equally in the acute inflammatory response, population kinetics were performed on monocyte subsets isolated by counterflow centrifugation elutriation following a single intravenous pulse of tritiated thymidine given concurrently with an intraperitoneal injection of phytohemagglutinin as phylogistic agent. Inflammation reduced the cell cycle times of the precursors for all monocyte subsets, increasing their production. However, inflammation increased the number of precursors only for large monocytes. In addition, a reserve of exclusively large monocytes existed which appeared in the circulation within 3 hr of inflammation induction. The subsequent loss of large monocytes from the circulation exceeded their production in contrast to all other monocyte fractions. Over 92% of all monocytes entering the acute inflammatory site were large monocytes despite the fact that they constituted only 58% of monocytes under steady state conditions. Small, intermediate, and very large vacuolated monocytes were only minor participants in the acute inflammatory response. These results indicate heterogeneity in the monocyte subset response to acute inflammation.     

Decrease in mitogen responsiveness of mononuclear cells from peripheral blood after epinephrine administration in humans

A single subcutaneous injection of 0.2 mg epinephrine into healthy human subjects caused a transient lymphocytosis in peripheral blood. Mononuclear cells (MNC), isolated at various times after epinephrine administration, were cultured in the presence of mitogens. The blastogenic responses to pokeweed mitogen (PWM) and phytohemagglutinin (PHA) were significantly reduced for up to 60 min post-epinephrine (p less than 0.05); the response to concanavalin A (Con A) was reduced in the 15-min samples only. All responses returned to pre-injection levels by 120 min post-injection. Removal of adherent monocytes from MNC isolates before culture did not restore normal mitogen responsiveness. When MNC were cultured in the absence of mitogens, there was no difference in survival between pre- and post-epinephrine samples. Incubation of untreated MNC for 2 hr or 18 hr in vitro with various concentrations of epinephrine (10(-5) to 10(-1) mg/ml) had no effect upon the subsequent blastogenic response to mitogens. Other workers have reported that epinephrine administration causes alterations in the composition of the circulating lymphocyte pool. Taken together, these data suggest that the reduction in mitogen responsiveness after epinephrine is the result of changes in the distribution of lymphocyte subclasses in peripheral blood.     

Enhancement of human neutrophil functions by a monoclonal antibody directed against a 19-kDa antigen.

A mouse IgG mAb termed P1C3 was raised against A23187-treated human peripheral blood neutrophils and has been shown to recognize an Ag with an apparent molecular mass of 19 kDa, herein named p19. This p19 Ag was weakly expressed at the cell surface of resting human peripheral blood neutrophils and monocytes, but its cell surface expression was dramatically increased upon activation of these cell types with different secretagogues, including FMLP, PMA, and the calcium ionophores A23187 and ionomycin. A large latent pool of p19 molecules became accessible by immunofluorescence flow cytometry after cell permeabilization of resting neutrophils. A practically total translocation of the intracellular pool of this p19 molecule to the plasma membrane was achieved under appropriate cell stimulation, which induced an almost total degranulation of neutrophil secretory granules. The p19 Ag was absent from platelets, PBL, as well as from the human promyelocytic cell line HL-60, the human promonocytic cell line U937, and the human lymphoid cell lines Daudi and Jurkat. The p19 Ag was also expressed by circulating and/or interstitial neutrophils and monocytes in distinct tissues examined. The mAb P1C3 was found to enhance several neutrophil responses, such as chemotaxis, cell adhesion, phagocytosis, and respiratory burst. These data indicate that the mAb P1C3 recognizes an intracellular Ag in human resting mature neutrophils and monocytes, which upon cell activation is translocated to the cell surface and is able to affect cell functionality.     

DYNAMICS OF LEUKOCYTE MIGRATION INTO THE MOUSE ASCITES TUMOR

There is a marked increase in the number of peritoneal leukocytes (lymphocytes, monocytes and granulocytes) during the growth of Ehrlich ascites tumor in mice. No local proliferation (as indicated by a labeling at 1 hr following a single ³H-TdR injection) was observed in the normal peritoneal leukocytes or those in the ascites tumor, except for a very minor labeling of some tumor macrophages. Kinetics of peritoneal leukocytes was studied with a series of twelve injections of ³H-thymidine (20 μCi every 8 hr) in normal mice as well as mice injected with 10⁶ tumor cells i.p. 2 hr after the last ³H-TdR injection. Animals were sacrificed at intervals up to 6 days. Granulocyte labeling in the blood as well as peritoneal space was near 100% in both groups of animals at all the intervals. Temporal changes in the labeling of lymphocytes (from 10% at 0 day to 22% at day 6), and monocytes (from 20% at 0 day to 57% at day 6) were identical in the blood and peritoneal space of normal animals, indicating a free exchange of cells between these compartments. Higher labeling indices than those in the controls were attained in the blood of tumor-bearing hosts (viz 40% for lymphocytes and 80% for monocytes at 6 days) suggesting an increased turnover of these cells in the circulation. In addition, peritoneal mononuclear cells of tumor-bearing mice showed even a higher labeling than those in the blood (viz 65% for lymphocytes and 92% for monocytes at 6 days) indicating a selective migration and/or retention of newly formed cells within the tumor, in contrast to a random migration into the normal peritoneal cavity. Furthermore, an identical labeling of macrophages to that of monocytes within the tumor indicated a short monocyte-macrophage transition. The preferential accumulation of young mononuclear cells into the tumor may be of functional importance.     

HYDROXYUREA EFFECTS IN THE C3H MOUSE II. MAMMARY TUMOR CELL KINETICS

The cellular kinetics of C3H mouse mammary tumors were studied following a single dose (3 mg/g body weight) of hydroxyurea (HU). This dose was large enough to cause a significant perturbation in the growth curves of these tumours. This was accomplished by labeling the cells with tritiated 5-iodo-2'-deoxyuridine and performing detailed autoradiographic analysis. This dose of HU caused a temporary inhibition in growth and completely inhibited DNA synthesis for 4–5 hr. The HU-killed cells (pyknotic and karyorrhectic) reach a maximum around 10–12 hr and are apparently all removed in about 1 day. Tumors from a fast-growing line (S102F) showed some evidence for cell synchrony upon recovery from HU inhibition but desynchronization occurred within one cell cycle. The cell generation time was not decreased during the acute recovery phase, but the growth fraction shifted from 0·6 to 1·0, and the data suggested that the normal flow of cells from the proliferating pool to the degenerate pool was temporarily interrupted. The cellular kinetic parameters have probably returned to normal by 48 hr after the HU injection.     

Interferon-gamma-activated human monocytes inhibit the intracellular multiplication of Legionella pneumophila

We have examined the interaction between interferon-gamma (IFN-gamma)-activated human monocytes and Legionella pneumophila, the agent of Legionnaires' disease. Human monocytes activated with human recombinant IFN-gamma inhibit the intracellular multiplication of L. pneumophila. The degree of inhibition is proportional to the concentration of IFN-gamma, and maximal inhibition consistently occurs with greater than or equal to 2 micrograms/ml. Monoclonal anti-IFN-gamma antibody completely neutralizes the capacity of IFN-gamma to activate monocytes. Monocytes infected 24 hr after explantation maximally inhibit L. pneumophila multiplication if treated with IFN-gamma before infection or up to 2 hr after infection; treatment 6 hr or more after infection results in submaximal inhibition. Monocytes infected 48 hr after explantation inhibit L. pneumophila multiplication maximally if treated with IFN-gamma up to 12 hr before infection, but submaximally if treated at the time of infection. Once activated, monocytes inhibit L. pneumophila multiplication in the absence of IFN-gamma in the culture. Strikingly, monocytes maximally inhibit L. pneumophila multiplication after treatment with IFN-gamma for as briefly as 1 hr before infection. In the absence of anti-L. pneumophila antibody, neither IFN-gamma-activated monocytes nor nonactivated monocytes kill L. pneumophila. In the presence of specific antibody and complement, IFN-gamma-activated monocytes kill a proportion (0.5 log) of an inoculum but not more than nonactivated monocytes. L. pneumophila forms a specialized phagosome in IFN-gamma-activated monocytes that does not differ ultrastructurally from the L. pneumophila phagosome in nonactivated monocytes. These results demonstrate that IFN-gamma can activate human monocytes to exert a potent antimicrobial effect against a highly virulent intracellular bacterial pathogen. These findings extend previous observations on interactions between activated mononuclear phagocytes and L. pneumophila, and additionally support the hypothesis that cell-mediated immunity plays a major role in host defense against L. pneumophila.