Colony formation by subpopulations of human T lymphocytes. VI. Further studies on colony phenotype, function, and cloning efficiency

Phytohemagglutinin (PHA)-induced colony formation in semisolid agar medium by human peripheral blood T lymphocytes showed an increasing cloning efficiency with decreasing numbers of cultured cells. Ninety percent of CD4+ cells (inducer/helper phenotype) and 20% of CD8+ cells (cytotoxic/suppressor phenotype) formed colonies when cultured at 10-200 cells/ml culture in the presence of sheep red blood cells (SRBC) and a source of interleukin-2 (IL-2). Probably all T-colony-forming cells, but none of the subsequent colony cells, expressed the Leu-8 antigen. The cloning efficiencies of FACS-sorted cells expressing the natural killer antigenic phenotypes Leu-7+ and CD16+ were found to be less than 1%. The costimulatory effect of red blood cells for colony formation was specific for SRBC and not observed in the presence of red cells obtained from seven other species including man. All T-lymphocyte colonies obtained from unseparated peripheral blood mononuclear cells expressed the CD25 antigen (IL-2 receptor) and colonies were always composed of either CD4+ or CD8+ cells. None of the colony cells expressed the Leu-8 or the CD16 antigens. By their specific morphology in agar culture the majority of colonies composed of CD4+ cells were easily recognized, but but approximately one-third of the CD4+ colonies could not be distinguished from colonies composed of CD8+ cells. On expansion of individual colonies in liquid subculture in the presence of interleukin-2, approximately 15% of the colonies developed natural killer (NK)-like cytotoxic activity, being capable of direct killing of K562 tumor cells. It is concluded that the present method for growing human T colonies exhibits the same cloning efficiency as the most efficient liquid culture systems. Individual T colonies are composed exclusively of T inducer/helper or T cytotoxic/suppressor cells, they are never of mixed phenotype, and they do not contain cells of natural killer phenotype. Regulatory mechanisms influencing colony formation are operating between and within the various subsets of T lymphocytes.     

Self-renewal and commitment to differentiation of human leukemic promyelocytic cells (HL-60)

More than 80% of cells from a human promyelocytic leukemic cell line (HL-60) possess the capacity for self-renewal as evidenced by their ability to form large primary colonies in semisolid medium and the presence within these colonies of cells capable of subsequent colony formation. Colony development is independent of the normal regulator-the myeloid colony stimulating factor. The observed autostimulation suggests the production of specific growth promoters by the cells. Differentiation either to mature granulocytes or macrophages, induced by various agents, was associated with reduced cloning potential. Nevertheless, colonies containing differentiated cells could be developed either by cloning cells in the presence of suboptimal concentrations of inducer or by adding inducers over colonies developed in its absence. Upon differentiation, there was a morphological change from compact to diffused colony morphology due to cell mobility in the semisolid medium. Even at suboptimal concentrations of inducer more than 95% of the colonies became diffused, indicating clonaI homogeneity of the population with respect to differentiation capacity. The loss of self-renewal was found to be one of the early properties which changed following the initiation of differentiation. The loss preceded not only the overt expression of maturation-specific functions but also cellular commitment to terminal differentiation; shorter contact with the inducer was required to cause loss of self-renewal than to induce an irreversible transition to differentiation. This resulted in cells that lost their self-renewal potential without being able to complete their program of differentiation.     

The single cell origin of normal granulocyte colonies in vitro

It has been shown by re-cloning of colonies formed in vitro from rat bone marrow cells, that normal granulocyte colonies can originate from single cells. No mixed macrophage (M) and granulocyte (G) colonies were obtained after re-cloning either M or G colonies. The results indicate, that clones of normal granulocytes and macrophages can be obtained in vitro, and that the mixed primary M and G colonies formed after seeding hematopoietic cells from animals presumably originate from a mixture of M and G cells.     

Analysis of the growth kinetics of murine erythroleukaemia cells following commitment to terminal differentiation

Abstract Differentiation of murine erythroleukaemia cells by various inducers involves a step of irreversible commitment, after which the presence of the inducer is not required for completion of the process. Some cells become partially committed and give rise to differentiated as well as undifferentiated progeny. Commitment occurs asynchronously; under suboptimal inducing conditions, such as low concentration of inducer or short duration of exposure, both committed and uncommitted cells co-exist. In the present study the growth of these subpopulations was compared. Murine erythroleukaemia cells were exposed to the inducer hexamethylene-bisacetamide for 24 hr, then the inducer was removed by washing and the rate of proliferation of committed and uncommitted cells was measured. Commitment was scored by cloning the cells in inducer-free semi-solid medium and determining the cellular composition of the colonies with respect to haemoglobin content. The results indicated that following removal of the inducer the rate of proliferation was retarded similarly for both committed and uncommitted cells. Partially committed cells disappeared rapidly due to assymetrical cell division into fully committed and uncommitted cells. Both committed and uncommitted cells resumed logarithmic growth at 53 hr, but while uncommitted cells continued this pace until saturation was achieved, committed cells stopped multiplying earlier as a result of terminal differentiation.     

Analysis of the growth kinetics of murine erythroleukaemia cells following commitment to terminal differentiation

Differentiation of murine erythroleukaemia cells by various inducers involves a step of irreversible commitment, after which the presence of the inducer is not required for completion of the process. Some cells become partially committed and give rise to differentiated as well as undifferentiated progeny. Commitment occurs asynchronously; under suboptimal inducing conditions, such as low concentration of inducer or short duration of exposure, both committed and uncommitted cells co-exist. In the present study the growth of these subpopulations was compared. Murine erythroleukaemia cells were exposed to the inducer hexamethylene-bisacetamide for 24 hr, then the inducer was removed by washing and the rate of proliferation of committed and uncommitted cells was measured. Commitment was scored by cloning the cells in inducer-free semi-solid medium and determining the cellular composition of the colonies with respect to haemoglobin content. The results indicated that following removal of the inducer the rate of proliferation was retarded similarly for both committed and uncommitted cells. Partially committed cells disappeared rapidly due to assymetrical cell division into fully committed and uncommitted cells. Both committed and uncommitted cells resumed logarithmic growth at 53 hr, but while uncommitted cells continued this pace until saturation was achieved, committed cells stopped multiplying earlier as a result of terminal differentiation.     

Hapten-specific murine colony-forming B cells: in vitro response of colonies to fluoresceinated thymus independent antigens

The ability to clone hapten-specific B cells in agar and to subsequently trigger their clonal progeny to antibody synthesis was investigated. Fluorescein (FL) specific B cells were purified on FL-gelatin dishes and cultured in semisolid agar for 6 to 7 days; individual colonies were then picked for restimulation in microculture. FL-specific B cells could be cloned as efficiently as unpurified splenic B cells. The number of colonies formed depended on the presence of sheep erythrocytes (SRBC) or E. coli lipopolysaccharide (LPS) in the cultures. An additive number of colonies were observed with SRBC + LPS compared to that of SRBC or LPS alone. The colonies obtained from SRBC-containing cultures were stimulatable at high frequency by various FL-conjugated antigens to yield anti-FL PFC. However, colonies grown with LPS as the only additive were not stimulatable by any of the antigens tested. On the other hand, addition of M phi or SRBC as additional "mitogens" along with LPS in the agar resulted in progeny colonies that could respond in vitro. Although M phi did not increase the number of colonies, their presence enhanced the size and in some cases the frequency of stimulatable colonies. These data complement earlier observations in suggesting that different B cell subpopulations may grow under different cloning conditions. Moreover, the ability to stimulate the clonal progeny of single B cells to antibody synthesis should permit further definition of triggering and tolerance events at the single-cell level.     

Development of a novel T-vector supporting efficient green-white screening

T-vectors play an important role in cloning of polymerase chain reaction products. In the present study, a novel pUEG-T vector was developed using enhanced green fluorescent protein (EGFP) as an indicator. To improve EGFP-based green-white screening, the lipoprotein mutant promoter, a strong constitutive promoter, was utilized to control the expression of egfp gene. Two other efficient expression elements, the ColE1 replication origin of pUC18 and the expression cassette of pET-28a, were also integrated into pUEG-T vector. Expression analysis demonstrated the efficient accumulation of active EGFPs in Escherichia coli DH5α cells carrying the T-vector precursor pUEG. In T-A cloning using pUEG-T vector, white colonies containing foreign DNA and green colonies having no insertion could be handily distinguished under normal white light, without any chemical inducer or chromogenic substrate. Furthermore, no false positive was observed in any of the tested white colonies. This proves that pUEG-T is an inexpensive, convenient and efficient T-vector.     

Rapid isolation of monoclonal hybridoma cultures by a 'fusion-cloning' method: the requirement for aminopterin

Hybridomas were generated by fusing the Balb/c SP2/0 myeloma-like cell line with either: (i) splenocytes from Balb/c mice immunized with foot-and-mouth disease virus (FMDV), rinderpest virus (RPV), peste des petits ruminants virus (PPRV), African swine fever virus (ASFV) or pig thymocytes; or (ii) lymph node cells from cattle immunized with FMDV. If the fusion mixtures were plated in cloning medium of methyl cellulose and HAT medium, small hybridoma colonies developed which rarely survived. Fusion mixtures were then plated in liquid HT medium on to 3T3/A31 feeder layers in 75 cm2 flasks, incubated at 37 degrees C for 24 h before adding aminopterin, and incubated for a further 2 to 4 days before cloning in methyl cellulose/HT medium. Without the aminopterin in the cloning medium, colonies of hybridomas, which could be cultured, developed from the majority of fusions. These colonies were isolated in HT medium over feeder layers and given two subcultures in HAT medium as a precaution against any reversion to aminopterin sensitivity during the cloning. No evidence of such reversions were seen, and recloning results suggested that the initial cloning was highly efficient at generating monoclonal cultures.     

Reversible cellular senescence: implications for immortalization of normal human diploid fibroblasts.

IMR-90 normal human diploid fibroblasts, transfected with a steroid inducible mouse mammary tumor virus-driven simian virus 40 T antigen, were carried through crisis to yield an immortal cell line. Growth was dependent on the presence of the inducer (dexamethasone) during both the extended precrisis life span of the cells and after immortalization. After dexamethasone removal, immortal cells divided once or twice and then accumulated in G1. These results are best explained by a two-stage model for cellular senescence. Mortality stage 1 (M1) causes a loss of mitogen responsiveness and arrest near the G1/S interface and can be bypassed or overcome by the cellular DNA synthesis-stimulating activity of T antigen. Mortality stage 2 (M2) is an independent mechanism that is responsible for the failure of cell division during crisis. The inactivation of M2 is a rare event, probably of mutational origin in human cells, independent of or only indirectly related to the expression of T antigen. Under this hypothesis, T-antigen-immortalized cells contain an active but bypassed M1 mechanism and an inactivated M2 mechanism. These cells are dependent on the continued expression of T antigen for the maintenance of immortality for the same reason that precrisis cells are dependent on T antigen for growth: both contain an active M1 mechanism.     

Measurement of in vivo HGPRT-deficient mutant cell frequency using a modified method for cloning human peripheral blood T-lymphocytes

Approximately 80% of human peripheral blood T-lymphocytes could be cloned in the presence of crude interleukin-2, phytohemagglutinin, and X-irradiated autologous lymphocytes and Raji B-cells. This modified cloning method was used to measure the in vivo frequency of HGPRT-deficient mutant T-lymphocytes. Repeated experiments using blood from the same individuals revealed that the frequency of mutant cells was almost constant for each individual even though the cloning efficiency of lymphocytes varied somewhat from experiment to experiment. Approximately 80% of both wild-type unselected and 6-thioguanine-resistant colonies had helper/inducer and about 20% had suppressor/cytotoxic T-lymphocyte markers. No difference was observed in the distribution of lymphocyte subsets in relation to colony type.     

Rapid cloning of mammalian cells with honeycomb cloning plates and nonlethal vital stains

A rapid and technically simple method for cloning both adhesive and nonadhesive mammalian cells is described. The procedure employs (a) honeycomb cloning plates and (b) nonlethal vital stains. Instead of placing cloning rings around colonies, cells are initially seeded at clonal density directly into a plate containing an array of cloning rings (the honeycomb plate). Hence, the time involved in placing cloning rings around colonies is eliminated. Second, clone-containing wells of the honeycomb plate are easily identified by staining plates with the nonlethal vital stains, MTT or INT tetrazolium. Vital staining eliminates the time involved in searching for clones. Last, clones are transferred with a cotton-tipped swab thereby eliminating the time involved in trypsinization of cells. In this fashion, one can pick and transfer clones of substrate adherent mammalian cells at a rate of one clone/10 to 15 s. Thus, mammalian cells can be cloned as rapidly as cloning can be carried out in microbial systems.     

Use of differential agar media for detection of cloned DNA fragments in the tetracycline and chloramphenicol resistance genes of pBR322

A method for detecting newly cloned DNA fragments in pBR322-based vectors was devised for use in DNA probe production. Escherichia coli strain DH5 containing plasmids with different resistance patterns to tetracycline (Tc) and chloramphenicol (Cm) were grown on nonpigmented media, blotted, transferred, and incubated for 2 h on MacConkey agar containing Tc or Cm. Resistant colonies changed color to pink as they began fermenting the lactose on the agar, while sensitive colonies remained white but were still viable and could be subcultured. This method can be applied to the detection of other plasmids with insertional inactivation of Tc or Cm resistance marker genes following successful cloning experiments, especially if pUC18 or M13 is not a possible vector. It eliminates 1 day of culture and the labor involved in individually transferring hundreds of colonies.     

Mouse embryonic stem cells efficiently lipofected with nuclear localization peptide result in a high yield of chimeric mice and retain germline transmission potency

Embryonic stem (ES) cells are an important tool in developmental biology, genomics, and transgenic methods, as well as in potential clinical applications such as gene therapy or tissue engineering. Electroporation is the standard transfection method for mouse ES (mES) cells because lipofection is quite inefficient. It is also unclear if mES cells treated with cationic lipids maintain pluripotency. We have developed a simple lipofection method for high efficiency transfection and stable transgene expression by employing the nonclassical nuclear localization signal M9 derived from the heterogeneous nuclear ribonucleoprotein A1. In contrast to using 20 microg DNA for 10 x 10(6) cells via electroporation which resulted in 10-20 positive cells/mm2, M9-assisted lipofection of 2 x 10(5) cells with 2 microg DNA resulted in > 150 positive cells/mm2. Electroporation produced only 0.16% EGFP positive cells with fluorescence intensity (FI) > 1000 by FACS assay, while M9-lipofection produced 36-fold more highly EGFP positive cells (5.75%) with FI > 1000. Using 2.5 x 10(6) ES cells and 6 microg linearized DNA followed by selection with G418, electroporation yielded 17 EGFP expressing colonies, while M9-assisted lipofection yielded 72 EGFP expressing colonies. The mES cells that stably expressed EGFP following M9-assisted lipofection yielded > 66% chimeric mice (8 of 12) and contributed efficiently to the germline. In an example of gene targeting, a knock-in mouse was produced from an ES clone screened from 200 G418-resistant colonies generated via M9-assisted lipofection. To our knowledge, this is the first report of generation of transgenic or knock-in mice obtained from lipofected mES cells and this method may facilitate large scale genomic studies of ES developmental biology or large scale generation of mouse models of human disease.     

Studies of gene transfer and reversion to mitomycin C resistance in Fanconi anemia cells

As a first step to the cloning of the Fanconi anemia (FA) gene, we have attempted to correct the sensitivity of FA cells to DNA crosslinking agents by the introduction of wild-type DNA. The protocol involved the introduction of both genomic and pRSVneo DNA, selection for G418-resistant colonies and the subsequent selection of mitomycin C-resistant cells from the latter. Preliminary experiments indicated that untransformed FA cells were not suitable recipients for the introduction of foreign DNA, so all experiments were performed with an SV40-transformed FA cell line. Approximately 40,000 G418-resistant colonies were obtained in 5 separate experiments at an overall frequency of about 5 X 10(-4). These were then selected in mitomycin C and 15 colonies were recovered. Colonies were obtained with wild-type DNA (both human and rodent) and with FA DNA at about the same frequency of 2 X 10(-7). Colonies were isolated and shown to have a stable, partial (from 25 to 90% of wild-type) resistance to mitomycin C. One colony was also shown to be partially resistant to two other DNA crosslinking agents, diepoxybutane and nitrogen mustard. This clone also had an intermediate level of spontaneous and MMC-induced chromosome aberrations. pRSVneo, but not rodent, DNA could be demonstrated in the high molecular weight fraction of several colonies. Thus, it is likely that these colonies represent partial revertants rather than transfectants. These mitomycin C-resistant FA cells should be useful for the biochemical analysis of the FA mutation.     

Construction and characterization of new coliphage M13 cloning vectors

New single-stranded DNA cloning vectors have been constructed by the insertion of additional DNA fragments into a HaeII restriction site in the bacteriophage M13 duplex replicative form (RF). These inserts into the M13 genome bring a single restriction sites useful for cloning, including PstI, XorII, EcoRI, SstI, XhoI, KpnI, and PvuII. Drug-resistance genes cloned into M13 include the beta-lactamase (bla) gene and the chloramphenicol acetyl transferase (cat) gene. These vectors provide a convenient means of easily obtaining the separated strands of a cloned duplex DNA fragment by cloning the fragment in each of the two possible orientations. Standard cloning techniques commonly applied to double-stranded DNAs can be utilized to insert foreign DNAs into the duplex RF DNAs of these vectors. Cells transformed by chimeric DNAs extrude filamentous phage particles carrying a circular single-stranded copy of the chimeric viral strand. Because M13-infected cells continue to grow and divide, cells can be transformed to yield either plaques or drug-resistant colonies. Specific inserts are readily detected by plaque hybridization techniques using an appropriate probe. Chimeric viral single strands from virus particles in the supernatant of small volumes of infected cultures can be rapidly and sensitively analyzed by agarose gel electrophoresis to determine the size of an insert.     

Hybridoma cell lines secreting monoclonal antibodies against foot-and-mouth disease virus (FMDV). II. Cloning conditions

Three methods of cloning hybridoma cells--picking colonies from the masterplate, limit dilution cloning, and cloning in semi-solid medium over macrophage (m phi) feeder layers--were compared. Cloning in semi-solid medium was found to be the most efficient and reliable, especially with our relatively slow growing anti-foot-and-mouth disease virus (FMDV) antibody secreting hybridoma cells. The optimum culture dish for this cloning was the 6-well (6W) dish (well diameter 1.5 cm), while the optimum cloning procedure was 10 to 10(2) hybridoma cells in 1% (w/v) methylcellulose in Dulbecco's minimal essential medium (DMEM) supplemented with 50% (v/v) conditioned medium, 10% (v/v) foetal or donor calf serum and 2 mM glutamine, over a 24-48 h old culture of syngeneic m phi in each well of the 6W plate. This could, however, produce problems in that colony formation was sometimes 'loose', and confident picking of individual colonies was impaired. Such a problem could be avoided by using a solid agar interface of 1% (w/v) agar Noble in DMEM or RPMI 1640 medium between the feeder cells and the hybridoma cells in semi-solid medium.     

Construction of a tightly regulated plasmid vector for Streptococcus pneumoniae: controlled expression of the green fluorescent protein

We have constructed a regulated plasmid vector for Streptococcus pneumoniae, based on the streptococcal broad-host-range replicon pLS1. As a reporter gene, we subcloned the gfp gene from Aequorea victoria, encoding the green fluorescent protein. This gene was placed under the control of the inducible P(M) promoter of the S. pneumoniae malMP operon which, in turn, is regulated by the product of the pneumococcal malR gene. Binding of MalR protein to the P(M) promoter is inactivated by growing the cells in maltose-containing media. Highly regulated gene expression was achieved by cloning in the same plasmid the P(M)-gfp cassette and the malR gene, thus providing the MalR regulator in cis. Pneumococcal cells harboring this vector gave a linear response of GFP synthesis in a maltose-dependent mode without detectable background levels in the absence of the inducer.     

Blastocystis hominis: A simplified, high-efficiency method for clonal growth on solid agar

Colony growth of protozoan parasites in agar can be useful for axenization, cloning, and viability studies. This is usually achieved with the pour plate method, for which the parasite colonies are situated within the agar. This technique has been described for Giardia intestinalis, Trichomonas vaginalis, and Entamoeba and Blastocystis species. Extracting such colonies can be laborious. It would be especially useful if parasites could be grown on agar as colonies. These colonies, being exposed on the agar surface, could be conveniently isolated for further investigation. In this study, we report the successful culture of B. hominis cells as colonies on solid agar. Colonies were enumerated and the efficiency of plating was determined. It was observed that B. hominis could be easily cultured on agar as clones. The colonies were dome-shaped and mucoid and could grow to 3 mm in diameter. Flow cytometric analyses revealed that parasite colonies remained viable for up to 2 weeks. Viable colonies were conveniently expanded in liquid or solid media. Scanning electron microscopy revealed that each colony consists of two regions; a dome-shaped, central core region and a flattened, peripheral region. Older colonies possessed numerous strand-like surface coat projections. This study provides the first report of clonal growth of B. hominis on agar and a simple, effective method for cloning and expansion of B. hominis cells.     

Rapid cloning of mammalian cells with honeycomb cloning plates and nonlethal vital stains

Summary A rapid and technically simple method for cloning both adhesive and nonadhesive mammalian cells is described. The procedure employs (a) honeycomb cloning plates and (b) nonlethal vital stains. Instead of placing cloning rings around colonies, cells are initially seeded at clonal density directly into a plate containing an array of cloning rings (the honeycomb plate). Hence, the time involved in placing cloning rings around colonies is eliminated. Second, clone-containing wells of the honeycomb plate are easily identified by staining plates with the nonlethal vital stains, MTT or INT tetrazolium. Vital staining eliminates the time involved in searching for clones. Last, clones are transferred with a cotton-tipped swab thereby eliminating the time involved in trypsinization of cells. In this fashion, one can pick and transfer clones ofsubstrate adherent mammalian cells at a rate of one clone/ 10 to 15 s. Thus, mammalian cells can be cloned as rapidly as cloning can be carried out in microbial systems. This study was supported, in part, by Grant CA 33074 from the National Cancer Institute, Bethesda, MD, Grant PCM-8218137 from the National Science Foundation, Washington, D.C., and a grant from the National March of Dimes.     

The growth and morphological characteristics of undifferentiated and differentiated cells of the F9 mouse teratocarcinoma line

Differentiation of the F9 cell line was induced by treating the cells with retinoic acid (10(-6) M) and dibutyryl cycloadenosinemonophosphate (10(-4) M). The population doubling time and the portion of cells in G1-phase increase and saturation density falls as the result of this treatment. Differentiated F9 cells demonstrate a decreased capacity of forming colonies in the soft agar, lose their capacity of proliferating at the clonal density, and acquire the limited life-span in culture after reseeding at a high density. Some cells in the differentiated population retain their capacity of forming colonies in the soft agar and (or) of binding antibodies against the stem cell marker SSEA-1. Cells with the stem cell morphology were found in the course of passaging of differentiated cells after reseeding at a high density. These cells were able to differentiate after the standard procedure of the induction of differentiation with retinoic acid and dibutyryl cAMP. Causes of the rising and supporting of heterogeneity of the differentiated F9 cells are discussed.