Long-term donor chimerism after MHC (RT1) mismatched bone marrow transplantation in the rat: the role of host alloreactive NK cells.

We have investigated the role of major histocompatibility complex (MHC) (RT1) disparities in the engraftment of bone marrow (BM) cells after whole body irradiation of rats. Mononuclear BM cells from PVG.RT7.2 (RT1c) rats were injected i.v. into sublethally (10Gy) whole body irradiated PVG (RT1c) rats and RT1 congenic and recombinant PVG rats. Repopulation of the BM, spleen, and blood with donor cells was assessed by FACS analysis of cells labelled with the fluorescein isothiocyanate (FITC)-labelled HIS41 monoclonal antibody (MoAb) against the RT7.2 marker. In RT1 matched (PVG.RT7.2 --> PVG) and RT1-mismatched combinations (PVG.RT7.2 --> PVG.1AV1), where radioresistant host natural killer (NK) cells could not recognize the BM inoculum as foreign, a donor chimerism close to 100% was observed after 6-8 weeks. However, in rat strain combinations where host NK cells could recognize an RT1 mismatch, almost no donor cells survived, and the rats were repopulated with leukocytes of host origin. In intra-MHC recombinant rat strains the element determining rejection or acceptance of the allograft mapped to the RT1-B/D-C/E/M region in PVG.R8 and PVG.R23 rats, in accordance with the patterns of NK alloreactivity in these strain combinations. NK cells may therefore be a primary obstacle to successful allogeneic BM engraftment in this model.

Depressed immunity and impaired proliferation of hematopoietic progenitor cells in patients with complete spinal cord injury.

The bone marrow is supplied with both sensory and autonomic neurons, but their roles in regulating hematopoietic and immunocompetent cells are unknown. Leukocyte growth and activity in patients with stable and complete spinal cord injuries were studied. The innervation of the bone marrow below the injury level lacked normal supraspinal activity, that is, a decentralized bone marrow. Lymphocyte functions were markedly decreased in injured patients. Long-term colony formation of all hematopoietic cell lineages, including dendritic cells, by decentralized bone marrow cells was substantially reduced. It was concluded that nonspecific and adaptive lymphocyte-mediated immunity and growth of early hematopoietic progenitor cells are impaired in patients with spinal cord injuries. Possibly, this reflects cellular defects caused by the malfunctioning neuronal regulation of immune and bone marrow function.

Ectopic haematopoiesis in the mouse: roles of stroma and cytokines in granulocytopoiesis in in vivo diffusion chamber cultures.

We have examined a possible role of two different types of irradiated stromal cells, i.e. murine bone marrow (BM) stromal cells and stromal cell line MS-5R, when cocultured with murine blood-borne progenitors or sorted Lin- Sca-1+ bone marrow cells in vivo in peritoneal diffusion chambers (DC). Retrieval and quantification of the cultured cells were performed after 4, 7, and 14 d. Granulocyte and/or macrophage colony-forming cells (G/M-CFC) were enumerated in subcultures from the DC. G/M-CFC production was not enhanced in the stroma-contact cultures, in comparison with the standard stroma-non-contact cultures, but early granulocytopoiesis was stimulated. Perturbation of the humoral environment of DC was investigated in a number of ways, for example with continuous infusion of rhG-CSF from a subcutaneous implanted minipump to DC host mice, with DC host mice carrying a transplantable leukaemia, secreting interleukin 3 (IL-3), and with injections of various cytokines. None of these interventions sustained the expansion of the G/M-CFC population. In conclusion, for ectopic haematopoiesis to take place, several requirements must be met. Relevant stromal cells apparently affect haematopoiesis both via direct cell-cell interactions and via humoral mediators (viz. cytokines) which they secrete.

Maturation rate of mouse neutrophilic granulocytes: acceleration by retardation of proliferation, but no detectable influence from G-CSF or stromal cells.

Our purpose was to examine the possible influence of stromal and humoral mediators on granulocytic maturation rates. Sorted immature murine progenitor (Lin-Sca-1+) cells were cultured in peritoneal diffusion chambers (DCs) with or without a confluent layer of irradiated bone marrow stromal cells on one of the micropore membrane walls. In other experiments, 10 microg/kg/d recombinant G-CSF (rhG-CSF) was administered continuously into DC host mice through s.c. implanted osmotic minipumps. Operationally, maturation rate was assessed as the ratio between the number of polymorphonuclear cells (PMN) and proliferative granulocytes (PG) in short-term cultures, based on the differential cell counts, and supported by flow cytometric measurement of a granulocytic differentiation marker; and by the emergence time of PMN in the DCs, obtained by extrapolation. Also, increased maturation is associated with increased cell density, as reflected by the positioning of the granulocytes during centrifugation in a discontinuous Percoll gradient. This method, as well as the conversion rate of 3H-thymidine labeled PG into the heavier non-PG maturational stages, were also used as indicators of maturation rate. After five, six, and seven days of culture in the peritoneal cavity, DC cells were harvested. Their proliferative status, based on measurement of incorporated bromodeoxyuridine, was determined, and their maturation rates were evaluated. Proliferation of immature granulocytic progenitor cells was apparently inhibited by direct contact with bone marrow stromal cells, and stimulated by G-CSF during the early stage of culturing. However, the subsequent maturation rate, which could be accelerated by increasing culture cellularity, thus decreasing PG proliferation rate, was not detectably influenced by either stromal cells or G-CSF.

Digital image analysis of hematopoietic colonies in vitro.

A system for automatic analysis of in vitro hematopoietic colonies is described and evaluated. With the standard resolution provided by video cameras, the improvement in visualization obtained using features other than size and darkness when classifying potential colonies appears to be limited. We confirmed this by comparing results obtained with the test system with those obtained with a commercial one. However, for some applications it may be useful to supplement the system with specific methods, e.g., to separate merged colonies. Digital image analyses provide new possibilities, for instance of measuring the total cellularity of the dish or analyzing colonies according to the size and cell density of each colony. Examples provided are time course studies of colony development, cellularity feedback effects on colony sizes, and bell-shaped dose-response curves for the growth stimulation obtained by certain conditioned media on a subpopulation of progenitor cells that gives rise to large colonies.

Role of classical (RT1.A) and nonclassical (RT1.C) MHC class I regions in natural killer cell-mediated bone marrow allograft rejection in rats.

BACKGROUND: We have studied the role of the different MHC (RT1) subregions in acute natural killer (NK) cell-mediated bone marrow allograft rejection in lethally irradiated, bone marrow cell (BMC) reconstituted rats. METHODS: We employed a series of MHC congenic and intra-MHC recombinant rat strains so that effects of mismatches in defined RT1 subregions could be studied systematically. BMC allograft survival was measured as 125IUdR uptake in the spleen between day 5 and day 7 after irradiation and BMC reconstitution. RESULTS: We found that in certain RT1 haplotype combinations, nonclassical RT1.C disparities by themselves could determine graft rejection (i.e., in the u/av1 recombinant haplotypes), whereas in another combination (between the av1 and c haplotypes) a mismatch for an isolated classical RT1.A region was decisive for engraftment. Thus, PVG.R1 BMC failed to proliferate in PVG rats, differing in the RT1.A region only, whereas in PVG.1U rats rejection could be determined by isolated differences in the RT1.C region (LEW.1WR1). Also, RT1 homozygous rats (RT1.U) rejected semi-allogeneic F1 hybrid BMC. The acute rejection of BMC was mediated by NK cells, as athymic nude rats, lacking alloreactive T cells but with normal alloreactive NK cells, showed the same patterns of rejection as did normal rats. Nude rats also rejected allogeneic lymphocytes, a previously documented NK-mediated phenomenon, with identical requirements of MHC disparity. CONCLUSIONS: This investigation shows that rat effector NK cells are radioresistant, independent of the thymus, and capable of recognizing and rejecting MHC mismatched transplanted BMC on the basis of mismatches in both classical and nonclassical class I regions in vivo. The studies underline the importance also of NK cells in determining BMC allograft survival.

No neuronal regulation of murine bone marrow function.

Bone marrow is innervated by efferent (sympathetic) and afferent nerves, but it is not clear whether these nerves affect cell formation or release in any significant way. To elucidate this problem, we studied mice neonatally sympathectomized with 6-hydroxydopamine and adult mice in which one hind limb was surgically denervated. Progenitor and transit cell numbers and proliferative activity were estimated in bone marrow, blood, and spleen. In addition, we performed unilateral electrical stimulation of nerve fibers to tibial marrow and applied a cell mobilizing stimulus (bleeding, granulocyte colony-stimulating factor injection, or intraperitoneal injection of a chemotactic substance) to investigate cell egress from the marrow. Blood flow to hindleg bone marrow was assessed with the radioactive microsphere technique. Except for a smaller bone marrow cell population and lower body weight in neonatally sympathectomized mice, we found no clear indications that bone marrow innervation influenced cell production. Also, the innervation did not detectably affect cell release from the marrow. Electrical stimulation of hind limb nerves did not change the blood flow to the marrow, whereas it markedly decreased blood flow to the overlying muscle. We therefore conclude that no obvious function can be ascribed to tibial marrow innervation in the mouse.

Leucopoiesis versus concentration of cytokines in diffusion chamber cultures of mouse bone marrow cells: clues to the physiological roles of growth factors.

Physiological mechanisms that regulate formation of neutrophil granulocytes, macrophages and their precursor cells were studied with the diffusion chamber (DC) technique. DC inoculated with mouse bone marrow cells were implanted intraperitoneally into host mice. When these in vivo cultures had been established and their marrow populations were expanding (2-day cultures), the DC were transferred to different environments: new, normal mice, lethally irradiated mice, or incubation flasks with optimal concentrations of growth factors. Culture development during the following final culture period was correlated to the concentration of some select candidate growth regulators in DC. After 3 d the cellularity of DC in irradiated hosts had increased significantly more than in the normal hosts. A difference was detectable already after 1-2 d when preculturing was omitted. The increased growth appeared to take place at several stages of cell maturation and not only at the progenitor cell level. Colony stimulating factor(s) for granulocyte and macrophage progenitors, as well as cytokines stimulating the bone marrow-derived cell line, 14 M.1, were present in DC fluid (DCF) at higher concentrations in irradiated than in normal mice throughout the final culture period. On the other hand, DCF concentrations of tumour necrosis-like factor (that may either induce CSF secretion or directly inhibit myelopoiesis), were not significantly different in irradiated compared with normal DC hosts. The cytokines detected in the DC may at least in part stem from inflammatory cells accumulating around the chambers. This animal model should be useful in further investigation of the highly complex regulatory network governing formation of white blood cells in the intact organism.

A new method for rapid technetium-99m labelling of leucocytes: functional cell studies in vitro.

The aim of this study was to assess the cytotoxicity of a new leucocyte-labelling method, which may be used clinically to localize inflammatory and immune reactions. Human blood leucocytes, their mononuclear sub-population, and mouse mononuclear bone marrow cells were labelled with 99mTc for 30-45 min, washed once, and then evaluated in various functional assays. The new procedure includes [99mTc]-labelling with a bisalt method, in the presence of dihydroxybenzoic acid as an intermediate antioxidant-complexing stabilizer, and a carboxylic acid salt of stannous ions as a reducing agent. To challenge the method, cells were labelled about two orders of magnitude more heavily in these initial methodological studies than in on-going clinical trials. Labelled leucocytes ingested latex beads as readily as the controls, but migrated chemotactically and randomly somewhat slower than the control cells. The lymphocytes were triggered by PHA and Con A in a normal way. However, lymphocytes and haemopoietic progenitor cells exposed to radiation for several days, were killed by the isotope doses used, of which about 2% (i.e. 20 MBq) were bound per million cells. All deleterious effects were apparently due to irradiation, and the labelling procedure itself did not damage the cells.

Thymic hormones and syngeneic T-lymphocytes are not required for leukopoiesis in an in vivo culture system for mouse bone marrow cells.

In order to explore the regulatory influence of thymic hormones and T cells on leukopoiesis , bone marrow cells from normal and athymic nude mice were cultured in peritoneal diffusion chambers (DC) that were implanted intraperitoneally into either normal or nude mice. T-cell-deficient nu/nu-C3H marrow cells formed slightly above normal numbers and nu/nu-BALB/c formed slightly below normal numbers of progenitor cells for granulocytes and/or macrophages in four-day DC cultures. Seven-day leukopoiesis in DC, as estimated by 3H-thymidine incorporation and differential cell counts, was not detectably affected by T-cell absence from nu/nu-BALB/c marrow. Leukopoiesis , including formation of progenitor cells, was not significantly different in normal and T-cell-deficient DC hosts. Normal thymocytes added to the T-cell-deficient bone marrow inocula decreased the generation of progenitor cells. These results indicate that (a) expansion of a proliferating granulocyte-macrophage progenitor cell population takes place in in vivo DC cultures without the presence of thymic hormones and T-lymphocytes, and that (b) T-lymphocytes may either stimulate or inhibit progenitor cell growth, and the balance between stimulation and inhibition apparently varies between mouse strains.

Methodological studies on growth of mouse granulocyte/macrophage colonies in methylcellulose-containing media.

We studied the influence of various physicochemical parameters on colony development and total cell numbers in 7-day methylcellulose cultures of mouse bone marrow cells. Colony growth was markedly retarded by an increase of PO2 from approximately 6.7 kPa towards that in ambient air and by a decrease of incubator temperature from 37 degrees C to 33 degrees C. Medium osmolality above approximately 340 mosm/kg inhibited formation of granulocytes (in cultures containing growth factors from pokeweed mitogen-stimulated spleen cells), but not macrophages (L cell-produced growth factors). At most, colony growth was affected slightly by moderate changes in pH (7.17-7.47) or concentration of methylcellulose (0.77-1.02%), or by the presence of 2-mercaptoethanol (50 mumol/1), Hepes buffer (25 mmol/1), or erythropoietin (0.1-1 units/ml). The culture trays could be stored for one day at 4 degrees C in the incubation boxes before colonies or cells were counted.

Flow cytometry of mouse bone marrow cells cultured in vivo or in vitro.

We have developed new methods for counting cyto-(fluoro)-metrically cells retrieved from diffusion chamber and methylcellulose cultures of mouse bone marrow. Total cell counting and DNA distribution measurements were based on detection of the fluorescence from propidium iodide stained nuclei. Staining of cell nuclei with propidium iodide further allowed the separate enumeration of avid phagocytes that had endocytosed fluorescent latex beads. Finally, we quantified peroxidase positive cells by using o-Dianisidine as a substrate for the enzyme, the formation of brown reaction product being enhanced by the presence of lidocaine and dichlorophenol. We found the new techniques precise, reliable and suitable for analysis of cell growth and maturation in culture.