Purification and characterisation of the in vitro colony forming cell in monkey hemopoietic tissue

Buoyant density gradient separation of Rhesus monkey bone marrow, spleen and blood leukocytes has demonstrated a reproducible and homogeneous light density distribution profile of cells capable of forming hemopoietic colonies in agar culture (in vitro colony forming cells — CFC). High resolution density gradient separation performed on a light density fraction of bone marrow produced on average a 100-fold enrichment of in vitro CFC with the most enriched fractions containing the majority of the in vitro CFC population present in the original marrow. Fractions were routinely obtained in which up to 23% of cells formed colonies and 33% were capable of proliferating to some degree upon stimulation. Tritiated thymidine suiciding showed the active proliferative status of the in vitro CFC and application of autoradiography and morphological characterisation to highly enriched density fractions has shown that the in vitro CFC in normal marrow is a transitional lymphocyte. Single cell transfer experiments have shown that in vitro CFC's formed colonies containing both granulocytes and macrophages, formally demonstrating the clonal origin of in vitro colonies and the common origin of granulocytes and macrophages.     

GROWTH OF MOUSE AND HUMAN BONE MARROW IN DIFFUSION CHAMBERS IN MICE

Both murine and human bone marrow cells were cultured in plasma clots which were formed inside diffusion chambers implanted into cyclophosphamide- and saline-treated mice. After an initial fall, the number of mouse bone marrow cells and numbers of mouse myeloid stem cells (CFU-C) and agar cluster-forming units rose faster in the cyclophosphamide-treated animals. These hosts also favored formation of myeloid (CFU-D-G) and erythroid (CFU-D-E) colonies and myeloid clusters in the plasma clot. The number and growth rate of mouse CFU-D-G were higher than those of CFU-C from the same marrow population. These observations suggest the existence of humoral factors stimulating granulocyte progenitor cell replication and differentiation. At its best the increment of CFU-D-E number was equivalent to that caused by a single 0·1 unit erythropoietin dose. Culture of normal human marrow cells resulted in colonies in the plasma clot containing only granulocytes and macrophages. Cyclophosphamide-treated host animals were essential for human CFU-D-G development. Plating efficiency for human marrow myeloid colonies was better in the conventional in vitro agar cultures than in diffusion chambers.     

Survival and Repopulation of Irradiated 'Pre-Cfu-C' In Mice

ABSTRACT Supernatants of murine bone-marrow cultures contain a colony-promoting factor (CPF) which increases the number of granulocyte and macrophage colonies in semi-solid agar cultures in the presence of colony-stimulating factor (CSF). Incubation of bone-marrow cells with CPF results in an increase in the number of granulocyte/macrophage progenitor cells (CFU-c) and the CPF-responsive cells may be younger than the CFU-c. We have investigated the radiosensitivity and the pattern of the recovery after irradiation of CPF-responsive cells. We found that the radiosensitivity of CPF-responsive cells was significantly lower than those of CFU-c. burst-forming units-erythroid (BFU-e) and pluripotent stem cells in vivo (CFU-s) and in vitro (CFU-mix). the CPF-responsive cells remained subnormal even at 28 days after irradiation of the mice, a time when the CFU-s and CFU-c had recovered completely. Therefore the CPF-responsive cells may constitute a separate compartment, namely ‘pre-CFU-c’, in the maturation sequence of granulopoiesis, and this maturation of the ‘pre-CFU-c’ to CFU-c seems to be highly stimulated after irradiation to counterbalance the influx from CFU-s.     

Candida albicans is able to use M cells as a portal of entry across the intestinal barrier in vitro

Candida albicans is the most frequent yeast responsible for systemic infections in humans. These infections mainly originate from the gastrointestinal tract where C. albicans can invade the gut epithelial barrier to gain access to the bloodstream. Along the gut, pathogens can use Microfold (M) cells as a portal of entry to cross the epithelial barrier. M cells are specialized cells mainly located in the follicule‐associated epithelium of Peyer patches. In this study, we used scanning electron and fluorescence microscopy, adhesion and invasion assays and fungal mutants to investigate the interactions of C. albicans with M cells obtained in an established in vitro model whereby enterocyte‐like Caco‐2 cells co‐cultured with the Raji B cell line undergo a phenotypic switch to morphologically and functionally resembling M cells. Our data demonstrate that C. albicans co‐localizes with and invades preferentially M cells, providing evidence that the fungus can use M cells as a portal of entry into the intestinal barrier. In addition to active penetration, F‐actin dependent endocytosis contributes to internalization of the fungus into M cells through a mechanism involving hypha‐associated invasins including Ssa1 and Als3.     

The continued requirement for inducer for the development of macrophage and granulocyte colonies

Rat bone marrow cells were seeded as mass cultures or for cloning together with inducer required for colony formation, and at various times after seeding, the cells were re-seeded for cloning either with or without inducer. The results indicate that the development of both macrophage (M) and granulocyte (G) colonies requires a continued supply of the inducer. No M or G colonies were produced when the inducer was replaced by erythropoietin.     

Separation By Velocity Sedimentation of Human Haemopoietic Precursors Forming Colonies in vivo and in vitro Cultures

Cells which give rise to granulocyte-macrophage colonies under the influence of peripheral blood white cells (CFU-c (WBC)) and Mo T cell conditioned medium (CFU-c (Mo)) sedimented at a faster rate than the cells which form mixed erythroid-granulocytic colonies in methylcellulose in vitro (CFU-mix) and granulocytic (CFU-dg) and megakaryocytic (CFU-dm) colonies in diffusion chambers in mice. Despite identical peak sedimentation rate for the two CFU-c populations, sedimentation profiles suggest that they are heterogeneous with respect to size. A proportion of CFU-c (Mo) may be identical with CFU-dg and CFU-mix. Sedimentation profiles for cells which give rise to mixed colonies in vitro (CFU-mix) and to granulocytic colonies in diffusion chambers in cyclophosphamide pretreated mice (CFU-dg (CY)) and in Mo conditioned medium treated mice (CFU-dg (Mo)) were similar. On the average CFU-dm sedimented somewhat slower than CFU-dg. These and other observations suggesting a close relationship between CFU-dg and multipotential haemopoietic precursors are discussed.     

Comparative Investigation of Mesenchymal Stem Cells Isolated from the Bone Marrow and Fetal Liver of Mouse and Rat

We studied the properties of cells forming fibroblast colonies from the bone marrow and fetal liver of mouse and rat. Bone marrow and fetal liver cells formed colonies in vitro including fibroblasts as well as a considerable proportion of macrophages. The colonies formed from bone marrow and hepatic cells of rat differed from the murine ones by a higher proportion of fibroblasts. Most colonies derived from the bone marrow of both mouse and rat included a fraction of cells expressing alkaline phosphatase, and hence, capable of osteogenic differentiation; the colonies derived from the fetal liver included low proportions of such cells. The cell layers derived from the colony-forming fibroblasts of both bone marrow and fetal liver of mouse maintained hematopoiesis in the peritoneal cavity of irradiated mice, which indicated that these progenitor cells can form hematopoietic microenvironment.     

Control of normal differentiation of myeloid leukemic cells. XII. Isolation of normal myeloid colony-forming cells from bone marrow and the sequence of differentiation to mature granulocytes in normal and D+ myeloid leukemic cells

An enriched population of early myeloid cells has been obtained from normal mouse bone marrow by injection of mice with sodium caseinate and the removal of cells with C3 (EAC) rosettes by Ficoll-Hypaque density centrifugation. This enriched population had no EAC or Fc (EA) rosettes and contained 87% early myeloid cells stained for myeloperoxidase and/or AS-D-chloroacetate esterase, 7% cells in later stages (ring forms) of myeloid differentiation and 6% unstained cells, 2% of which were small lymphocytes. After seeding in agar with the macrophage and granulocyte inducer MGI, the enriched population showed a cloning efficiency of 14% when removed from the animal and of 24% after one day in mass culture. Both the enriched and the unfractionated bone marrow cells gave the same proportion of macrophage and granulocyte colonies. The normal early myeloid cells were induced to differentiate by MGI in mass culture in liquid medium to mature granulocytes and macrophages. The sequence of granulocyte differentiation was the formation of EA and EAC rosettes followed by the synthesis and secretion of lysozyme and morphological differentiation to mature cells. D⁺ myeloid leukemic cells with no EA or EAC rosettes had a similar morphology to normal early myeloid cells and showed the same sequence of differentiation. The induction of EA and EAC rosettes occurred at the same time in both the normal and D⁺ leukemic cells, but lysozyme synthesis and the formation of mature granulocytes was induced later in the leukemic than in the normal cells. The results indicate that selection for non-rosette-forming normal early myeloid cells also selected for myeloid colony forming cells, that these normal early myeloid cells can form colonies with differentiation to macrophages and granulocytes, that normal and D⁺ myeloid leukemic cells have a similar sequence of differentiation and that the normal cells had a greater sensitivity for the formation of mature cells by MGI.     

Analysis of pure and mixed murine mast cell colonies

Mast cells have been proposed to originate from diverse sources, including connective tissues, macrophages, T lymphocytes, and hemopoietic cells. Evidence for a hemopoietic origin of mast cells includes the presence of mast cell precursors in spleen colonies and the presence of mast cells in hemopoietic colonies in culture. Here we report a detailed analysis of mouse spleen mixed hemopoietic colonies containing mast cells. All of the colonies in cultures plated at low cell densities were individually removed for analysis by May-Grunwald-Giemsa staining on day 15 of culture. Examination of five dishes which contained a total of 82 colonies showed 16 pure mast cell colonies and 36 mixed mast cell colonies. Sixteen different combinations of cell types were seen and were not distinguishable from each other in situ. The most diverse type of mixed colony contained macrophages (m), neutrophils (n), eosinophils (e), mast cells (Mast), megakaryocytes (M), erythroid cells (E), and blast cells. The clonal origin of mixed mast cell colonies was established by the replating of single cells obtained from blast cell colonies. Individual cells were removed with a micromanipulator, replated, and allowed to grow for 15 days. Cytospin preparations of 10 such colonies showed diverse combinations of cell lineages which were seen in the different types of mixed mast cell colonies described above. Replating studies of mixed mast cell colonies were carried out and a high incidence of replating was seen. Approximately one half of these colonies formed only mast cell colonies upon replating. Further studies showed that pure mast cell colonies could be serially replated four to five times. The replating efficiency of cells in the primary mast cell colonies varied over a wide range (2.5–44%) with an average replating efficiency of 13%. The data also revealed that cells containing metachromatic granules possess significant proliferative capacity. From these studies of pure and mixed mast cell colonies, we concluded (1) that mast cells are in wide variety of types of mixed colonies and that the in situ identification of mixed colonies is unreliable, (2) that mast cells are derived from pluripotent hemopoietic stem cells, and (3) that mast cells with metachromatic granules can have a high proliferating ability.     

The effect of radiation therapy combined with natural killer cells against spontaneous murine fibrosarcoma

The effect of radiation therapy combined with lymphoid cells against spontaneous murine fibrosarcoma (FSa-II) was investigated bothin vivo andin vitro. In thein vivo experiment, syngeneic C3H mice were divided into 3 groups. Animals in the first group were injected with 1 x 10⁵ tumor cells into the right hind leg. Animals in the second and third groups were injected with 1 x 10⁵ tumor cells mixed with 1 x 10⁷ normal lymphoid cells (NLC) or effector lymphoid cells (ELC), respectively. ELC were obtained from spleen and lymph nodes of FSa-II-bearing mice and incubatedin vitro for 40 hr to eliminate suppressor T cell function. NLC were obtained from normal mice and incubated in the same way. Irradiation was given using¹³⁷Cs unit 3 days after cell inoculation. 12 out of 14 mice (85.7%) inoculated with tumor cells mixed with NLC did not show any tumor growth at 60 Gy local irradiation. 12 out of 21 mice (57.1 %) inoculated with tumor cells alone and 6 out of 10 (60%) with tumor cells mixed with ELC rejected tumors at the same radiation dose. This synergistic effect with NLC was not observed when NLC was inoculated after irradiation, indicating that lymphoid cells should be in contact with tumor cells before irradiation. In the⁵¹Cr release assay, lymphoid cells obtained from whole body irradiated (WBI) mice showed 17.8% lysis without irradiation and 28.8% lysis at 5 Gy irradiation. Untreated NLC showed almost no cytotoxic effect at the same radiation dose. This synergistic effect disappeared when WBI lymphoid cells were treated with anti asialo GM1 and complement. These results suggested that NK cells might be important in this synergistic effect with irradiation. To obtain a sufficient level of synergistic effect by in vitro combined treatment of mixed tumor cell - NLC culture and irradiation - incubation for more than 12 hrs and 8 hrs appeared to be necessary before and after irradiation, respectively.     

The effects of Arctigenin-Valine ester on chemotherapy-induced myelosuppression in mice

ObjectiveTo explore whether Arctigenin-Valine ester (ARG-V) can treat myelosuppression caused by chemotherapy.MethodsThe number of peripheral blood cells of the mice was measured by an automatic blood analyzer, and the hematopoietic progenitor colonies CFU-GM, CFU-E, BFU-E, and CFU-Meg were cultured in vitro. Hematopoietic progenitor colonies and BMNCs were counted under an inverted microscope. The expressions of cytokines GM-CSF, EPO and TPO were detected by ELISA. The cell cycle was measured by flow cytometry. The expressions of related proteins MEK and p-ERK were quantitated by western blots, and the thymus index and spleen index were quantitated.ResultsAfter taking ARG-V, the peripheral blood cells of the mice gradually returned to normal, the number of nucleated cells in the bone marrow increased, the thymus index increased, the spleen index decreased, the number of hematopoietic progenitor cells increased, and the hematopoietic cytokines decreased. And ARG-V promoted the transformation of myelosuppression cells from G0/G1 to S and from S to G2/M. ARG-V could up-regulate the expression of MEK and p-ERK, and low dose ARG-V is not as effective in all aspects as high dose ARG-V.ConclusionARG-V can effectively alleviate the myelosuppression that caused by intraperitoneal injection of CTX in 100mg/kg, and ARG-V can promote the proliferation and differentiation of hematopoietic progenitor cells and improve immunity, and the effect of high-dose Arctigenin-Valine ester is more significant to some extent.     

A clonal approach to the problem of neural crest determination.

A fundamental question regarding neural crest development is the possible pluripotential nature of this embryonic tissue. As a first step in examining this problem, clonal techniques are used to produce homogeneous populations of crest cells. Primary cultures of these cells are obtained by explanting neural tubes from Japanese quail in vitro and allowing crest cells to migrate away. The explant is removed, the outgrowth is isolated, dissociated with trypsin, and the cells plated at clonal density. Colonies derived in this manner fall into the following categories: all cells of the colony pigmented; none of the cells pigmented; and some of the cells pigmented, the remainder unpigmented. Pigmented colonies generally arise from small, round cells whereas the non-pigmented colonies usually originate from large, flattened polymorphous cells. Differentiation of melanocytes does not preclude their continued proliferation. The pigment phenotype, in addition, is stable through at least 25 generations. That the mixed colonies, in fact, are clonally derived is shown by physically isolating single cells. The identity of the non-pigment cells was not established in the present work. A possible neural fate is suggested, however, since nerve-like cells develop after the petri plates become overgrown. Neural clones did not form even though nerve growth factor activity is present as a normal constituent of the culture medium and was added as a supplement in some instances. These techniques permit the preparation of large, homogeneous populations of neural crest cells and afford an opportunity to examine aspects of crest determination heretofore impossible to study.     

Increased susceptibility to SV40 transformation with development and in vitro aging

The incidence of most cancers increases with aging. To examine whether this increased risk might be related to a higher susceptibility of older cells to neoplastic transformation, we transfected rat fibroblasts aged in vivo and in vitro with origin-defective SV40 DNA and measured the number of transformed foci. Substantial increases in the number of transformed foci were observed in cells from adult rats when compared with those of cells from embryos or weanlings. Much higher numbers of foci were also obtained at late passage, when 68% or more of the in vitro lifespan had been completed, while no foci were produced from cells at early or middle passage. To control for changes with aging in uptake, integration, or expression of exogenous DNA, parallel cultures were transfected with a G418 resistance gene. The number of G418-resistant colonies did not increase with aging and, in fact, decreased in late passage embryonic cell cultures. Therefore, increased susceptibility to SV40 transformation appears to be a feature of development and in vitro aging in rat Cells.     

Two-step growth curve from undisturbed cultures of Tetrahymena pyriformis

Single cells from developing two day granulocytic bone marrow colonies were transfered in agar cultures. After three to five days, 48 of 239 transfered single cells had transformed to single macrophages or proliferated to form aggregates of pure macrophages or mixed macrophage-granulocyte aggregates. Some granulocytes in colonies developing in vitro from bone marrow cells appear to have the capacity to transform to macrophages.     

Scanning Electron Microscopy of the Influence of Fixation Vehicle Osmolality on Cell Morphology of Spiroplasma, Acholeplasma, and Mycoplasma spp. grown on Agar

Young Spiroplasma citri, corn stunt spiroplasma, and honey bee spiroplasma colonies fixed in 5% glutaraldehyde in M 199 cell culture medium with 0.25 M sucrose showed elongated mycelium-like cells which were sometimes branched or helical. In older colonies beaded chains and rounded bodies were formed. Fixation in 6 % glutaraldehyde in distilled water resulted in amorphous masses in which rounded bodies were present. The spiroplasma cells did not remain osmotically active after glutaraldehyde fixation. Acholeplasma laidlawii and Mycoplasma hyorhinis colonies fixed in glutaraldehyde with or without M 199 medium with 0.25 M sucrose showed little difference in cell morphology.     

Proliferative effects of purified granulocyte colony-stimulating factor (G-CSF) on normal mouse hemopoietic cells

When granulocyte colony-stimulating factor (G-CSF), purified to homogeneity from mouse lung-conditioned medium, was added to agar cultures of mouse bone marrcw cells, it stimulated the formation of small numbers of granulocytic colonies. At high concentrations of G-CSF, a small proportion of macrophage and granulocyte-macrophage colonies also developed. G-CSF stimulated colony formation by highly enriched progenitor cell populations obtained by fractionation of mouse fetal liver cells using a fluorescence-activated cell sorter, indicating that G-CSF probably acts directly on target progenitor cells. Granulocytic colonies stimulated by G-CSF were small and uniform in size, and at 7 days of culture were composed of highly differentiated cells. Studies using clonal transfer and the delayed addition of other regulators showed that G-CSF could directly stimulate the initial proliferation of a large proportion of the granulocvte-macrophage progenitors in adult marrow and also the survival and/or proliferation of some multipotential, erythroid, and eosinophil progenitors in fetal liver. However, G-CSF was unable to sustain continued proliferation of these cells to result in colony formation. When G-CSF was mixed with purified granulocyte-macrophage colony-stimulating factor (GM-CSF) or macrophage colony-stimulating factor (M-CSF), the combination stimulated the formation by adult marrow cells of more granulocyte-macrophage colonies than either stimulus alone and an overall size increase in all colonies. G-CSF behaves as a predominantly granulopoietic stimulating factor but has some capacity to stimulate the initial proliferation of the same wide range of progenitor cells as that stimulated by GM-CSF.     

COLONY-FORMING ABILITY OF BONE MARROW CELLS OF W ANAEMIC MICE ON MACROPHAGE LAYER FORMED IN PERITONEAL CAVITY OF MICE

The colony-forming ability of haematopoietic cells of W anaemic mice was examined on the macrophage layer formed in the peritoneal cavity of mice. Bone marrow cells of W anaemic mice formed a considerable number of colonies on the macrophage layer, notwithstanding they did not form any colonies in the spleen of the same recipients. As the colony-forming ability of the bone marrow cells was not reduced by the incubation with ³H-thymidine, most of the cells which formed colonies on the macrophage layer seemed to stay in G₀ state. The interrelationship between the spleen colony-forming cells, the macrophage-layer colony-forming cells, and in vitro colony-forming cells was discussed.     

Impact of orphaning on field colonies of Southeast Asian Macrotermes gilvus (Hagen) and M. carbonarius (Hagen) (Termitidae, Macrotermitinae)

Field colonies of Macrotermes gilvus (Hagen) and M. carbonarius (Hagen) were experimentally orphaned to examine their potential for producing replacement reproductives. Orphaned colonies were investigated only once for caste composition at selected time intervals at 3, 6, 9 or 12 months after orphaning. Of the 38 orphaned colonies of M. gilvus, 15 colonies (39.5%) re-established. In M. carbonarius, three colonies out of 20 (15%) re-established. Re-established colonies were headed by adultoids which were morphologically indistinguishable from primary reproductives. In naturally orphaned colonies of M. gilvus, we often found multiple adultoids with normal pigmentation but torn wings, i.e. the colonies retained alates as replacement reproductives. The number of reproductives probably declines over time. It may take alates of M. gilvus 6 months to develop into functional adultoids, and up to 12 months for alates of M. carbonarius. Our results also demonstrate that the presence of sexual castes (nymphs or alates) at the time of orphaning does not necessarily guarantee the success of colonies in re-establishing themselves as breeding colonies. We also found a high prevalence of occupation of the mounds by other termite species, after the death of M. gilvus (18.4%) or M. carbonarius (30.0%) colonies, probably using them as foraging sites.     

Characteristics of in vitro colony formation by cells from haemopoietic tissues

Summary The characteristics of stimulation of colony formationin vitro from cells of mouse haemopoietic tissues has been briefly reviewed. Mouse kidney or embryo feeder cells, media conditioned by the cells from these tissues, normal or leukemic mouse sera, sera from leukemic or infectious mononucleosis patients, human urine and mouse embryo extracts are all sources of colony stimulating activity and their properties have been described. All sources of colony-stimulating activity produce clones of cells of the granulocyte series. In tritiated thymidine treated mice injection of preparations rich in colony-stimulating activity has been shown to produce a neutrophil leucocytosis and accelerate the rate of accumulation of labelled neutrophils in the blood. It is suggested that thein vitro assay can detect factors capable of stimulating granulocyte development.     

TWO DISTINCT COLONIAL MORPHOTYPES OF AMPHORA COFFEAEFORMIS (BACILLARIOPHYCEAE) CULTURED ON SOLID MEDIA1

When cultured on different types of solid media, the marine-fouling diatom Amphora coffeaeformis (Ag.) Kütz. consistently formed two distinct colonial morphotypes named tight and fuzzy. Tight colonies were comprised mainly of small, morphologically distorted, nonmotile cells, whereas morphologically normal and highly motile cells formed the fuzzy colonies. Cells from tight colonies were less adherent to glass, grew more slowly in liquid media, and had a slightly decreased viability on plates with copper than cells from fuzzy colonies. Whereas the protein profiles of the two types of cells were nearly identical in polyacrylamide gels stained with Coomassie blue, cells from tight colonies produced a significantly lower amount of a protease-resistant, low M_r polysaccharide or glycoconjugate as detected in silver-stained gels. The frequency of appearance of the fuzzy and tight morphotypes was not influenced by the mode of nutrition or the type of substratum to which the algal cells adhered. However, certain formulations of solid medium and the presence of growth-inhibitory concentrations of copper in agar plates favored the formation of tight colonies. Due to their frequencies and patterns of appearance, it was clear that the two naturally formed morphotypes were not the consequence of spontaneous mutations, genetic rearrangement, or selection of stable natural variants, and we have hypothesized that they were linked to a normal physiological behavior. The tight colonial morphotype was used as a valuable marker to screen for true motility/adhesion mutants within an ultraviolet-mutagenized population of A. coffeaeformis. Seven mutants were isolated that were non-motile on agar plates, poorly adherent to glass, and distinguished from naturally formed cells from tight colonies by their inability to form fuzzy colonies upon subculture on solid media.