Development of surface membrane characteristics of "premedullary" macrophages in organ cultures of embryonic rat and hamster lungs

Selective gene expression analysis of the neuroepithelial body microenvironment in postnatal lungs with special interest for potential stem cell characteristics

BACKGROUND

The pulmonary neuroepithelial body (NEB) microenvironment (ME) consists of innervated cell clusters that occur sparsely distributed in the airway epithelium, an organization that has so far hampered reliable selective gene expression analysis. Although the NEB ME has been suggested to be important for airway epithelial repair after ablation, little is known about their potential stem cell characteristics in healthy postnatal lungs. Here we report on a large-scale selective gene expression analysis of the NEB ME.

METHODS

A GAD67-GFP mouse model was used that harbors GFP-fluorescent NEBs, allowing quick selection and pooling by laser microdissection (LMD) without further treatment. A panel of stem cell-related PCR arrays was used to selectively compare mRNA expression in the NEB ME to control airway epithelium (CAE). For genes that showed a higher expression in the NEB ME, a ranking was made based on the relative expression level. Single qPCR and immunohistochemistry were used to validate and quantify the PCR array data.

RESULTS

Careful optimization of all protocols appeared to be essential to finally obtain high-quality RNA from pooled LMD samples of NEB ME. About 30% of the more than 600 analyzed genes showed an at least two-fold higher expression compared to CAE. The gene that showed the highest relative expression in the NEB ME, Delta-like ligand 3 (Dll3), was investigated in more detail. Selective Dll3 gene expression in the NEB ME could be quantified via single qPCR experiments, and Dll3 protein expression could be localized specifically to NEB cell surface membranes.

CONCLUSIONS

This study emphasized the importance of good protocols and RNA quality controls because of the, often neglected, fast RNA degradation in postnatal lung samples. It was shown that sufficient amounts of high-quality RNA for reliable complex gene expression analysis can be obtained from pooled LMD-collected NEB ME samples of postnatal lungs. Dll3 expression, which has also been reported to be important in high-grade pulmonary tumor-initiating cells, was used as a proof-of-concept to confirm that the described methodology represents a promising tool for further unraveling the molecular basis of NEB ME physiology in general, and its postnatal stem cell capacities in particular.

Augmented Proliferation of Human Alveolar Macrophages After Allogeneic Bone Marrow Transplantation

After allogeneic bone marrow transplantation (allo-BMT), recipient alveolar macrophages (AM) are gradually replaced by AM of the donor origin. An influx of mononuclear phagocytes of donor origin to the lung is responsible for the repopulation, but the detailed kinetics remain unclear. We therefore studied 24 BMT recipients who underwent bronchoalveolar lavage (BAL) from 24 to 83 days after BMT. AM cell number, size, morphology, proliferating ability, and genotype of AM were measured. Before day 50, the number and size of AM in BAL fluid were similar to those of normal nonsmokers. However, after day 50, the mean number of AM increased threefold and the mean cell size decreased due to the increase of small AM. These small cells are presumably of donor origin based on DNA fingerprinting analysis and based on fluorescence in situ hybridization for the Y chromosome in a sex-mismatched case. Immunohistochemistry and cell cycle analysis demonstrated that the increase in AM number coincided with a remarkable increase of AM expressing proliferating cell nuclear antigen, suggesting that small AM are proliferating. This is the first report representing that augmented proliferation of donor AM in situ may contribute to the reconstitution of AM population after BMT.

Augmented Proliferation of Human Alveolar Macrophages After Allogeneic Bone Marrow Transplantation

After allogeneic bone marrow transplantation (allo-BMT), recipient alveolar macrophages (AM) are gradually replaced by AM of the donor origin. An influx of mononuclear phagocytes of donor origin to the lung is responsible for the repopulation, but the detailed kinetics remain unclear. We therefore studied 24 BMT recipients who underwent bronchoalveolar lavage (BAL) from 24 to 83 days after BMT. AM cell number, size, morphology, proliferating ability, and genotype of AM were measured. Before day 50, the number and size of AM in BAL fluid were similar to those of normal nonsmokers. However, after day 50, the mean number of AM increased threefold and the mean cell size decreased due to the increase of small AM. These small cells are presumably of donor origin based on DNA fingerprinting analysis and based on fluorescence in situ hybridization for the Y chromosome in a sex-mismatched case. Immunohistochemistry and cell cycle analysis demonstrated that the increase in AM number coincided with a remarkable increase of AM expressing proliferating cell nuclear antigen, suggesting that small AM are proliferating. This is the first report representing that augmented proliferation of donor AM in situ may contribute to the reconstitution of AM population after BMT.

Factors influencing fetal macrophage development: III. Immunocytochemical localization of cytokines and time-resolved expression of differentiation markers in organ-cultured rat lungs

BACKGROUND

Exogenous TNF alpha, IL-1 beta, M-CSF, and GM-CSF all stimulate growth of macrophages arising in explanted fetal rat lungs. The present study examines the intrinsic availability of these factors in intact and organ-cultured lungs and utilizes expression of cytokines and marker proteins to explore the differentiation pathway followed by phagocytes in vitro.

METHODS

Factors and markers were localized immunocytochemically in paraffin sections of 14- and 15-day fetal rat lungs and lungs organ-cultured up to 7 days on serum-containing medium solidified with agar. Western analyses for the cytokines were performed on lysates of whole 15-day lungs, and in situ hybridization of M-CSF receptor mRNA was carried out in sections of 14 + 2 day cultured lung.

RESULTS

IL-1 beta, M-CSF, and GM-CSF were demonstrated in the stroma of intact and cultured lungs by immunostaining, results confirmed by Western blotting. TNF alpha appeared to be absent. A few precursors (angular cells) expressed the macrophage lineage marker RM-1 as early as day 14, and immunostaining became stronger and more widespread as the population matured and expanded in cultures. The OX-6 antibody to Ia antigen first reacted with macrophages in 14 + 1 day explants, and within a week 50% of cells were positive. M-CSF and mRNA for its receptor were present at 14 + 2 days, as was PDGF, which had been demonstrated in the stroma and epithelium prior to explantation. Definite reactivity for IL-1 beta and GM-CSF followed at 14 + 4 and 14 + 5 days.

CONCLUSIONS

M-CSF, GM-CSF, and IL-1 beta, but not TNF alpha, are available to replicating angular cells before and during their conversion to phagocytes. Fetal lungs thus qualify as a hematopoietic tissue supportive of macrophages. The path of differentiation pursued in organ cultures involves early expression of structural elements (RM-1, Ia antigen) followed by synthesis of cytokines of the TNF alpha cascade. Immunostaining for both RM-1 and OX-6 suggests that fetal lung macrophages share a common heritage with antigen-presenting pulmonary dendritic cells.

Development and heterogeneity of macrophages and their related cells through their differentiation pathways

Macrophages are a heterogeneous population differing in their site of location, morphology and function. They develop from hematopoietic stem cells originating in both fetal and bone marrow hematopoiesis. In yolk sac and early hepatic hematopoiesis, primitive/fetal macrophages develop from hematopoietic stem cells, bypassing the stage of monocytic cells (monoblasts, promonocytes and monocytes), possess proliferative capacity and differentiate into resident macrophages in tissues in late ontogeny. Monocytic cells develop in hepatic hematopoiesis after the development of primitive/fetal macrophages, then move into the bone marrow in late ontogeny, forming a monocyte-derived macrophage population in tissues. Like monocytes, the monocyte-derived macrophages have no proliferative potential and are short-lived, whereas the resident macrophages are long-lived in tissue, possess proliferative capacity and can be sustained by self-renewal. In adult life, the bone marrow releases macrophage precursors (immature myeloid cells) and monocytes into peripheral blood, but normally not monoblasts or promonocyts. The myeloid precursor cells migrate into tissues and differentiate into resident macrophages or related cells in situ due to macrophage differentiation or growth factors, such as M-CSF and GM-CSF, produced in situ and/or supplied humorally. Monocytes, however, migrate into tissues in response to inflammatory stimuli and differentiate into exudate macrophages. The distinct differentiation pathways of monocyte/macrophages, resident macrophages, other macrophage subpopulations, and macrophage-related cells are reviewed together with the heterogeneity of macrophage precursor cells.

Exogenous cytokines enhance survival of macrophages from organ cultured embryonic rat tissues

BACKGROUND

Macrophage precursors are present in embryonic rats shortly after the onset of hematopoiesis. During organogenesis they soon establish residency in many parts of the body and become convertible into phagocytes, at first gaining morphological characteristics of macrophages and later a range of surface antigens used to characterize subpopulations in adults. Nonetheless, it is uncertain whether representatives of this fetal lineage continue to exist past birth. We investigated the question indirectly by seeing if such cells can be made to survive in vitro to an age equivalent to adulthood and by examining underlying conditions that favor this outcome.

METHODS

Fourteen-day embryonic lungs, hearts, and limb buds were organ cultured on a firm serum-containing medium. Fetal macrophages developed within all explants and then migrated out to form a corona of cells surrounding each explant. The lung cultures were selected for subsequent work which mainly used coronal area as the measure of macrophage population size in experimental and control groups. Baseline growth and survival of macrophages were established for cultures grown on standard medium, then effects of the following were examined: indomethacin (10(-6) M) as it influences initial production of macrophages from precursors and later survival of differentiated cells; and macrophage colony-stimulating factor (M-CSF), used alone at moderate dosage (50-100 U), and combined with granulocyte-macrophage CSF (both 200 U), for its importance to long-term survival of the population. Mitogenic influence of M-CSF on differentiated macrophages was demonstrated by uptake of 5-bromo-2'-deoxyuridine.

RESULTS

Indomethacin inhibited the formation of macrophages from precursors but enhanced the survival of differentiated cells. M-CSF increased BrdU uptake of differentiated macrophages and permitted coronal growth to continue long past the approximately 30 day limit of controls. Beyond this interval, M-CSF was essential for macrophage survival, since coronas quickly shrank after the cytokine was withdrawn. Administration of the M-CSF/GM-CSF mixture to the 2 oldest M-CSF-exposed cultures between 98 and 127 days in vitro resulted in an increase in the number of coronal macrophages (P < 0.001); withdrawal between 129 and 140 days led to a decrease (P < 0.005). Ultimately a few cells were still surviving at 183 days.

CONCLUSIONS

Intrinsic factors promote early formation of macrophages within the explants, but the availability of factors is lessened by the anti-inflammatory action of indomethacin. Its later promotion of macrophage survival may be based on suppression of autogenous prostaglandin (PGE2) synthesis. M-CSF greatly promotes macrophage survival; in context this is sufficient to show that the fetal macrophage line has a clear potential to survive well into adulthood.

Development, differentiation, and proliferation of macrophages in the rat yolk sac

Immunohistochemical and immunoelectron microscopic investigation using anti-rat macrophage monoclonal antibody (mAb) RM-1 demonstrated the first emergence of immature macrophages within blood islands of fetal rat yolk sacs at fetal day 9. At fetal day 10, they matured into fetal macrophages, showed intense immunoreactivity to RM-1, developed lysosomal granules, endocytic vesicles or vacuoles, and extended fine cytoplasmic processes. By the rosetting assay with IgG-coated sheep erythrocyte antibody (IgG-EA), both the immature and mature fetal macrophages showed rosette formation and phagocytosis of IgG-EA, but they were negative for peroxidase (PO) reaction. At fetal day 11, fetal macrophages were observed in the mesenchymal layer of the yolk sacs. In the yolk sacs, no promonocytes or monocytes were observed, although there was a very minor population (less than 1%) of immature myeloid cells containing a few small PO-positive cytoplasmic granules from fetal day 11 on. After combination of the vitelline vessels to the embryonic cardiovascular system, fetal macrophages appeared in embryonic rat tissues. By [3H]thymidine autoradiography, yolk sac macrophages were demonstrated to possess a marked proliferative potential. These results suggest that fetal macrophages in the yolk sac differentiate from haematopoietic stem cells without passing through the promonocyte or monocyte stage, proliferate actively, and colonize the embryonic rat tissues.

Macrophage development: IV. Effects of blood factors on macrophages from prenatal rat lung cultures

Effects of colony-stimulating factors M-CSF, GM-CSF, G-CSF, and IL-3 were assessed on cells of macrophage lineage present in organ cultured 14-day prenatal rat lungs. Treatment groups were compared between one another and against control lungs grown on standard medium containing 40% fetal bovine serum without added factors, where a monoculture of macrophages rapidly develops from precursors present at explantation, leading to appearance of a large mature population on the pleural surface outside the lungs. Studies were carried out in living cultures and by light and electron microscopy using peroxidase-coupled isolectin B4 of Griffonia simplicifolia to identify macrophages and their precursors. In the first experiment, 14-day prenatal lung explants (14 + 0 days) containing macrophage precursors but not matured cells were exposed to individual CSFs for 7 days in an attempt to determine whether precursors are committed irrevocably to the macrophage line or can be altered by exposure to factors promoting significant granulocyte development. In succeeding experiments, 4- and 7-day-old cultures (14 + 4, 14 + 7 days) containing matured macrophages were targeted to see whether macrophage survival can be extended beyond expectations in controls and whether mitotic activity is stimulated. Recombinant CSFs were used at dosage levels known to promote colony formation in vitro (200-1,000 CFU/ml). Cultures exposed from prenatal day 14 to M-, GM-, G-CSF, or IL-3 yielded a monoculture of macrophages without exception. Populations developed in the presence of M- or GM-CSF were much larger than in controls or cultures grown with the other blood factors. GM-CSF-exposed cultures produced by far the largest macrophages, among them many multinucleate giant cells. Macrophages developed in the presence of G-CSF were also significantly larger than controls. Growth of the mature macrophage population was greatly stimulated by exposure to M-CSF or GM-CSF but not by IL-3 or G-CSF. Mitotic figures were noted in the coronas of emerged cells surrounding stimulated cultures, compared to none in the controls. Ultrastructurally, macrophages stimulated by M-CSF retained a mature appearance like macrophages in control, IL-3, and G-CSF treatment groups, whereas many in the GM-CSF group became less differentiated. As to long-term survival, a single 14-day explant was grown for 8 days on standard medium (the equivalent date for birth), then placed in a soft agar medium containing M-CSF.(ABSTRACT TRUNCATED AT 400 WORDS)

Morphometric comparisons of rat alveolar macrophages, pulmonary interstitial macrophages, and blood monocytes

Pulmonary interstitial macrophages (IM) account for a substantial fraction of the total pulmonary macrophage (PM) population in the mammalian lung, with the remaining balance of extravascular mononuclear phagocytes being mainly alveolar macrophages (AM). Unlike the AM that can be harvested readily by bronchoalveolar lavage, the lung's IM subpopulation of PM has been characterized less well, primarily because of its relative inaccessibility. Recently we developed a method to isolate viable IM from rat lungs using an Fc gamma receptor affinity technique in conjunction with multiparameter flow cytometry. Using this approach, we undertook the present investigation to characterize quantitatively the structural features of the IM and to compare the morphologic attributes of this subpopulation of PM to those of flow cytometrically sorted AM and blood monocytes (BM). Measured or calculated parameters for each population included mean cellular equivalent circular diameter, cell area and volume, and nuclear, mitochondrial, cytoplasmic, and lysosomal volume densities in each cell type. Lysosomal volume densities were subcategorized further into primary lysosomes, small secondary lysosomes, large secondary lysosomes, lipid droplets, and vacuoles. Additionally, the shape, form, and surface irregularity of the cells and various subcellular components were determined. Comparisons of the size and other structural features of the AM, IM, and BM have indicated that (1) the morphologic phenotypes of these three populations of mononuclear phagocytes distinctly differ from one another, (2) the IM and BM are morphologically and morphometrically more akin to one another than they are to AM, and (3) the IM are more similar to the AM than are the BM. These findings suggest that the IM may represent a transitional stage of maturation between BM and AM. Our findings, however, do not rule out the possibility that at least some of the lung's IM are a discrete, BM-independent population of macrophages.

Macrophage development: I. Rationale for using Griffonia simplicifolia isolectin B4 as a marker for the line

The isolectin B4 of Griffonia simplicifolia (GSA I-B4) binds to cell membrane glycoconjugates bearing terminal alpha-D-galactose, which macrophages possess. We have investigated the merits of its use as a marker for cells of this lineage when examining the early origin of macrophage populations in rat embryos, the stages and time scale of transformation from precursor forms to active, matured cells, and the response of precursors and macrophages to colony-stimulating blood factors, the last two studies conducted in organ cultures of prenatal lungs. In the present instance, GSA I-B4 was used either coupled with fluorescein (FITC) for light microscopy of living and fixed cells, or with peroxidase for light or electron microscopy. Control incubations of lung culture-derived macrophages proved that staining resulted from specific binding to galactosyl units on the cell membrane, since it was competitively inhibited by alpha-D-galactose. The lectin binds to few cells in 14-day prenatal lung explants but to a great many macrophages that subsequently develop in the cultures, indicating that it can be relied on for quantitative studies on population growth; however, it is important to provide reagents with good access to the cells. Apart from macrophages and their precursors, virtually no cells in prenatal lung cultures bind this lectin. Granulocytes of adult blood are GSA positive, but they are not yet present in 14-day prenatal explants and do not develop subsequent to culturing; hence they are not a source of confusion for experimental studies using this system. Precursors of granulocytes begin to appear in rat embryos around day 13 and have GSA-positive cell membranes, but like definitive granulocytes they also have conspicuous peroxidase-positive lysosomal granules which serve to distinguish them from early macrophages, particularly when cells are studied at an ultrastructural level. With these objections cleared away, GSA I-B4 emerges as a valuable means to mark cells of the macrophage line, mature or immature.

Macrophage development: III. Transformation of pulmonary macrophages from precursors in fetal lungs and their later maturation in organ culture

The fate of macrophage precursors residing in 14-day prenatal rat lungs was followed in organ cultures to obtain a detailed, ultrastructurally resolved picture of the sequence and timing of events accompanying their transformation into typical pulmonary macrophages. Cultures were examined at close intervals during the first day (1, 2, 3, 4, 6, 9, 12, 15, 18, and 24 hr) and at wider intervals thereafter (2, 4, 5, 7, 9, and 13 days) to yield a developmental series of cells identified as in the macrophage line based on binding of peroxidase-coupled isolectin B4 of Griffonia simplicifolia (GSA I-B4) to cell membranes and on negligible content of peroxidase-positive granules in the cytoplasm. Organ culturing stimulated virtually all precursors to develop into macrophages. GSA-positive cells in explants occurred outside vessels in pulmonary connective tissue, and at the outset none were typical macrophages: 71% were angular cells, resembling unlabeled mesenchymal cells around them, 16% were undifferentiated leukocytes, and the remainder were irregularly shaped cells with few vacuoles intermediate between the preceding and the macrophages. During the first 12 hr in culture the proportion of angular cells and leukocytes fell to zero, and that of intermediate cells first rose, then receded. In the same interval the proportion of macrophages rose to 87.5%, and by 24 hr all GSA-positive cells were typical macrophages generally engorged with phagocytosed material; about 8 hr appear necessary for converting half the population. Notable ultrastructural changes during this period of transformation involved the centrioles and cytoskeleton, reflecting enhanced cell mobility and phagocytosis. A period of maturation followed, marked by disappearance of cellular debris from phagosomes and an increased prevalence of cells with elaborate lamellipodia. This accords with earlier work showing that macrophage Fc receptor density increases sharply during the first 24 hr, but elevated levels of histochemically demonstrable acid phosphatase appear only later. Mitotic activity was conspicuous in GSA-positive cells throughout both periods. 3H-thymidine labeling indices for precursors and macrophages, determined at six intervals between 1 hr and 24 hr, remained steady at approximately 34%, whereas indices of other categories of lung cells (GSA-negative stromal cells, pleural cells, and airway epithelium) began at this level but rapidly declined, indicating that the GSA-positive cells constitute a single population distinct from others in the lungs. Macrophages found outside the lung cultures after 4-5 days qualify as a mature population, but having migrated away from direct contact with the lung stroma, they survive only a week or two and no longer divide.

Macrophage development: II. Early ontogeny of macrophage populations in brain, liver, and lungs of rat embryos as revealed by a lectin marker

Earliest origins of macrophage populations in the central nervous system, the liver, and the lungs were studied in rat embryos aged between 10.5-11 days and 14 days of gestation, based on light and electron microscopic identification of macrophages using peroxidase-coupled isolectin B4 of Griffonia simplicifolia (GSA I-B4), which recognizes alpha-D-galactose groups on the cell membrane. During embryonic life macrophages and their precursors are GSA I-B4-positive and generally bereft of peroxidase-positive granules. At 10.5 days the yolk sac and embryonic circulations have just become joined, the brain has five vesicles but nerve cells are little differentiated, the liver exists as a diverticulum of the gut with fingerlike extensions of hepatocytes, and the lungs as a laryngotracheal groove. Macrophages and/or their precursors occurred in small numbers in embryonic mesenchyme and blood vessels but showed no special affinity for either liver or lung rudiments. The developing brain was the first organ to be colonized, beginning on prenatal day 12. The liver followed between days 12 and 13 and was succeeded by the lungs, beginning between days 13 and 14. Dividing macrophages were present in these organs at the outset of colonization and throughout the duration of the embryo series, indicating that from the beginning, replication of resident cells contributes to growth of the local population. Granulocyte precursors were first apparent in the liver around day 13; they are also GSA-positive but are distinguished from macrophages by their content of peroxidase-positive granules. Organ cultures of 13-day liver and lungs, and 14-day brain tissue, indicate that whereas isolated liver fragments support the formation of both granulocytes and macrophages, only the latter develop in brain or lung cultures. A resident population of macrophages evidently is set up very early in these organs, well before white cells colonize the spleen, bone marrow, and other future blood forming regions. The events outlined are seen as stages in an embryo-wide process that leads to establishment of macrophage populations in various organs.