The size of small cell lung carcinoma cells. Ratio to lymphocytes and correlation with specimen size and crush artifact.

The size of small cell lung carcinoma (SCLC) cells has often been ambiguously defined as one and a half to four times that of a lymphocyte. The purpose of this study was to determine the ratio of nuclear diameter (ND) of SCLC cells to that of lymphocytes in the same tissue sections and to assess whether the size of SCLC cells correlates with the size of tumor specimens and crush artifact. The overall mean ND (microns +/- SD) of SCLC cells was 9.2 +/- 2.1, found in 36 oat cell carcinomas (OAT, 1,800 nuclei) and 16 intermediate cell carcinomas (INT, 800 nuclei). The mean ND of OAT and INT cells was 8.1 +/- 1.3 and 11.6 +/- 1.5, respectively. The mean ND of lymphocytes (2,600 nuclei) was 5.2 +/- 0.3. The overall mean of ND ratios (+/- SD) between SCLC cells and lymphocytes was 1.8 +/- 0.4 (median, 1.7), 1.6 +/- 0.2 for OAT and 2.2 +/- 0.3 for INT. The mean size of the 52 SCLC biopsy specimens was 0.6 +/- 0.9 cm. Of all the biopsies, 84.6% (n = 44) showed various degrees of tissue crushing. The ND of SCLC cells was associated with specimen size (P = .004) and the degree of tissue crushing (P = .001). Therefore, our findings further support the hypothesis that OAT should be considered the effect of artifact rather than a true variant of SCLC and that the ND of SCLC cells is approximately two times that of lymphocytes.     

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.     

Effects of lymphocytes from the thymus and lymph nodes on differentiation of hemopoietic spleen colonies in irradiated mice

Hemopoietic colonies were counted macroscopically and microscopically in spleens of hybrid mice seven or eight days after they had been irradiated and given parental bone marrow in donor-host combinations exhibiting poor growth. Colonies counted microscopically were classified as to differentiation pathway. Lymphocytes from the thymus or lymph nodes were injected into some recipients at several different dosages and lymphocyte: bone marrow (L:B) ratios. In confirmation of earlier work it was found that thymocytes increased the number and size of colonies in recipients of marrow. A shift of differentiation toward granulopoiesis was also seen when thymocytes were given, although erythropoietic colonies were still the most frequently seen type except at very high L:B ratios. Lymph node lymphocytes shifted the pattern more markedly toward granulopoiesis, even at low L:B ratios. When lymphocytes from either source were given without marrow, only a few colonies could be found in recipients, and if differentiated they were almost exclusively granulopoietic. Irradiation (900 R) of lymphocyte donors reversed the shift so that a normal pattern of differentiation, like that resulting from marrow alone, was seen; irradiated lymphocytes were nonetheless capable of augmenting the size and total number of hemopoietic colonies.     

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.     

In vitro studies to prove the effect of sera of eosinophilia in colony formation

Serum samples from four patients with reactive eosinophilia and two patients with eosinophilic leukaemia were compared with normal sera with respect to formation of eosinophil colonies after addition of the sera to mononuclear cells from peripheral blood of healthy subjects. Supernatants from ConA stimulated guinea-pig spleen cells and human lymphocytes were tested in a similar way. Grown colonies were placed on glass slides and after staining with luxol fast blue the percentage of eosinophils was counted. The serum samples of the patients with reactive eosinophilia produced the greatest number of eosinophil colonies while supernatants of spleen and lymphocytes produced the greatest number of eosinophilic granulocytes. Our findings suggest the existence of a factor stimulating eosinophil colonies in the tested serum fractions. Beyond that an indication is given for a substance in the supernatants of spleen and lymphocyte suspensions which stimulates more intensively the maturing into eosinophilic granulocytes than the formation of colonies.     

GROWTH AND ORGANIZED DEVELOPMENT OF CULTURED CELLS. VI. THE BEHAVIOR OF INDIVIDUAL CELLS ON NUTRIENT AGAR

Freely suspended cells of a long continuously cultured strain of carrot were dispersed in nutrient agar medium in Petri dishes. After inoculation, cells in randomly chosen fields were photographed at low magnification. The same cells were photographed at intervals over the next 23 days. The fate of 678 units, 24% of which grew visibly, was determined from the photographic record. Cells and units displayed a marked degree of individuality. In some units, there was a progressive increase in cell number; in others, after a few divisions, growth ceased; in still other units, cells enlarged without dividing. Although the evidence of cell division in free cells is conclusive, its incidence and maintenance increased with the size of the initial unit. In general, growth started after an “induction period” of about 5 days, but some cells remained apparently unchanged considerably longer after inoculation, before they started to grow. Although single cells of all sizes were observed to grow by one means or another, it was generally the shorter ones that continued to grow into viable colonies. Elongated cells predominated in the carrot strains used; these grew into colonies first by septation, with little or no over-all increase in size, followed by a stage of cell enlargement. Growth by both cell enlargement and division then ensued. During growth by septation within single cells, some derived cells were seen to burst and die. The most frequent divisions were observed during septation when the average cell generation time was 24 hr. Lacking the controls that normally operate in the intact plant body, there was much variation in the forms assumed during growth, a number of which are illustrated. The importance of epigenetic factors, or external controls, that determine the growth of cells in the plant body is stressed.     

Growth of fibroblasts on linear and planar anchorages of limiting dimensions

BHK and 3T3 cells were grown on small glass fibres and platelets (size range 20–250 μm) in agar gel, over a layer of mouse primary feeder cells. Under these conditions the growth of colonies (4–20 cells) from single control cells, suspended freely in the gel, was less than 1 %, while cells attached to the larger platelets yielded more than 95 % colonies. Fibres (average diameter 0.625 μm) induced somewhat fewer colonies (45–70 %). However, there was a significant induction of single divisions by fibres as short as 30 μm, while on 60 μm fibres more than half the cells had gone through at least one division, compared with 4–12% of freely suspended controls. Longer fibres promoted multiple divisions. Colony formation increased sigmoidally with fibre length from 30 to 250 μm, with a d₅₀ around 115 μm. These figures resembled the observed range of lengths of freely growing BHK and 3T3 fibroblasts in tissue culture dishes. In another experiment, finer fibres (average diameter 0.075 μm) performed almost as well as platelets of equal length but of width 20–30 μm.Thus linear extension provides a stimulus for division of anchorage-dependent fibroblasts. It is suggested that this stimulus may arise from a change in conformation or tension in the cell membrane, rather than from increased surface, cell motility or interaction with substrate surface.The present results are discussed in relation to recent findings on the induction of tumours by solid particles.     

Colony-stimulating factor and the proliferation of X-irradiated myeloid stem cells

Mouse bone marrow cells irradiated in vitro with X-rays (100R or 200R) were cultured for a week in semi-solid agar containing nutrients, horse serum and various amounts of colony-stimulating factor (CSF), and the number of the colonies was counted microscopically. The result showed that the diminution of proliferative activity of myeloid stem cells (CFU-C) induced by X-rays was partly recoverable by increasing the concentration of CSF, and that the irradiated CFU-C required a higher concentration of CSF than did the control CFU-C to produce colonies in the culture. The increased CSF-requirement was not due to the increased liberation of CSF-inactivator or CSF-antagonist in the culture.     

The effect of cytokines on the ploidy of megakaryocytes

The effects of recombinant cytokines on the ploidy of human megakaryocytes derived from megakaryocyte progenitors were studied using serum-free agar cultures. Nonadherent and T cell-depleted marrow cells were cultured for 14 days. Megakaryocyte colonies were identified in situ by the alkaline phosphatase anti-alkaline phosphatase technique, using monoclonal antibody against platelet IIb/IIIa. The ploidy of individual megakaryocytes in colonies was determined by microfluorometry with DAPI (4',6-diamidino-2-phenylindole) staining. Recombinant human interleukin 3 (rhIL-3) and recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) supported megakaryocyte colony formation in a dose-dependent manner. However, both rhIL-3 and rhGM-CSF had no definite ability to increase the ploidy values. Recombinant human erythropoietin (rhEpo) or recombinant human macrophage colony-stimulating factor (rhM-CSF) by itself did not stimulate the growth of megakaryocyte progenitors. rhEpo or rhM-CSF, however, stimulated increases in the number, size and ploidy values of megakaryocyte colonies in the presence of rhIL-3 or rhGM-CSF. Recombinant human interleukin 6 (rhIL-6) showed no capacity to generate or enhance megakaryocyte colony formation when added to the culture alone or in combination with rhIL-3. rhIL-6, however, increased the ploidy values in colonies when added with rhIL-3. These results show that rhEpo, rhM-CSF and rhIL-6 affect endomitosis and that two factors are required for megakaryocyte development.     

Campylobacter fetus adheres to and enters INT 407 cells

Campylobacter fetus is a Gram-negative bacterial pathogen of humans and ungulates and is normally transmitted via ingestion of contaminated food or water with infection resulting in mild to severe enteritis. However, despite clinical evidence that C. fetus infection often involves transient bacteremic states from which systemic infection may develop and the frequent isolation of C. fetus from extra-intestinal sites, this organism displays very poor invasiveness in in vitro models of infection. In this study, immunofluorescence microscopy and gentamicin protection assays were used to investigate the ability of six clinical isolates and one reference strain of C. fetus to adhere to and invade the human intestinal epithelial cell line, INT 407. During an initial 4-h infection period, all C. fetus strains were detected intracellularly using both techniques, though adherence and internalization levels were very low when determined from gentamicin protection assays. Microscopy results indicated that during a 4-h infection period, four of the five clinical strains tested were adherent to 41.3-87.3% of INT 407 cells observed and that 25.2-34.6% of INT 407 cells contained intracellular C. fetus. The C. fetus reference strain displayed the lowest levels of adherence and internalization. A modified infection assay revealed that C. fetus adherence did not necessarily culminate in internalization. Despite the large percentage of INT 407 cells with adherent bacteria, the percentage of INT 407 cells with intracellular bacteria remained unchanged when incubation was extended from 4 h to 20 h. However, microscopy of INT 407 cells 24 h postinfection (p.i.) revealed that infected host cells contained clusters of densely packed C. fetus cells. Gentamicin protection assays revealed that intracellular C. fetus cells were not only viable 24 h p.i. but also that C. fetus had increased in number approximately three- to fourfold between 4 and 24 h p.i., indicative of intracellular replication. Investigation of the role of the host cell cytoskeleton revealed that pretreatment of host cells with cytochalasin D, colchicine, vinblastine, taxol, or dimethyl sulfoxide (DMSO) did not impact upon C. fetus adherence or internalization of INT 407 cells. Microscopy indicated neither rearrangement nor colocalization of either microtubules or microfilaments in INT 407 cells in response to C. fetus adherence or internalization. Together, these data indicate that clinical isolates of C. fetus are capable of adhering, entering, and surviving within the nonphagocytic epithelial cell line, INT 407.     

The effect of hyperbaric oxygenation on thein vitro growth ofEscherichia coli in environments with and without blood cells

The aim of this study was to investigate whether thein vitro presence of blood cells influences the anti-microbial activity of hyperbaric oxygen (HBO) againstEscherichia coli. FiftyE. coli isolates from clinical samples were used in the study. A small number of colonies belonging to each isolate from the nutrient media were transferred into two K₃EDTA tubes (the blood group) and two Mueller-Hinton broth tubes (the broth group). Then, both groups were divided into subgroups according to whether HBO was administered (HBO subgroup) or not (non-HBO subgroup). HBO treatment was applied for one hour at 2.5 absolute atmospheres. The tubes in the non-HBO subgroup were left at room temperature during this period. Subsequently, all the tubes were cultured on Mueller-Hinton and Eosin Methylene Blue agar using the quantitative counting technique. After 18 to 24 h incubation at 37 °C, the colonies formed in the plates were counted. In the blood group, compared with non-HBO subgroup samples, the number of colonies decreased in 56% of samples, increased in 32% of samples and did not change in 12% of samples in the HBO subgroup. Whereas, in the broth group the number of colonies decreased in only 32% of samples increased in 38% of samples and did not change in 30% of samples in the HBO subgroup compared with the non-HBO subgroup. The difference between the blood and the broth groups revealed a statistical significance using Pearson’s Chi-square test (P=0.025). We concluded that the antibacterial effect of HBO onE. coli increases in the cellular environment belonging to the host organism.     

Amplification of the human putative oncogene INT1 in primary retinoblastoma tumors

We report the amplification of the putative oncogene INT1 in two of four retinoblastomas. In one case, the INT1 signal was amplified 10 to 15-fold, in the other 100-fold. In both cases there were signs of increased tumor aggressiveness with invasion of the choroid and development of metastases. The two cases without INT1 amplification had neither metastases nor locally invasive growth. Our findings indicate that INT1 amplification may be a feature of increased malignant potential in retinoblastomas.     

Transformation of normal diploid cells by isolated metaphase chromosomes of virus-transformed or spontaneous tumor cells.

Normal diploid human cells with a limited life-span in culture, as well as primary or secondary cell cultures of mouse or rat embryos, can be transformed in vitro (i.e. grow in soft-agar or low-serum medium) after a single exposure to metaphase chromosomes from SV40-transformed human or rat cells, Ad5-transformed human cells and several spontaneous human or mouse tumor cells. Chromosomes from normal diploid cells do not show any such transforming activity. As judged from the number of colonies formed in selective medium, the efficiency of transformation is, with some exceptions, of the order of 10(-5)--10(-6) and is generally higher for homologous than for heterologous transfers. A fraction of the colonies demonstrate abortive transformation. Nevertheless, using chromosomes from all but one donor cell population, at least one transferent cell line expressing a stable transformed phenotype has been established. Our results demonstrate that transformation of normal diploid cells by a presumptive chromosome-mediated gene transfer can be obtained with a variety of donor and recipient cells.     

Interferon treatment of Ehrlich ascites tumor cells: effects on exogenous mRNA translation and tRNA inactivation in the cell extract.

We reported earlier that in cell extracts that were prepared from interferon-treated Ehrlich ascites tumor cells and preincubated and passed through Sephadex G-25 (S60INT), the translation of exogenous mRNA (viral and host) was impaired and the impairment could be overcome to a large extent by adding a crude tRNA preparation from Ehrlich ascites tumor cells but not from Escherichia coli. We find now that the rate of inactivation of some tRNA's (especially those specific for leucine, lysine, and serine) but not those of many others is faster in S30INT than in corresponding extracts from control cells. This increased rate of tRNA inactivation may perhaps account for the need for added RNA to overcome at least partially the impairment of translation in S30INT. The relationship of the increased rate of tRNA inactivation to the antiviral effect of interferon is unclear. So far no significant difference has been detected in the amount of tRNA needed to overcome the impairment of encephalomyocarditis virus RNA translation in S30INT between tRNA from interferon-treated cells and tRNA from control cells. Futhermore, no difference was found in the rate of inactivation in S30INT between leucine-specific tRNA's from interferon-treated and from control cells. tRNA's specific for leucine and lysine were not inactivated (unless very slowly) during incubation under out conditions in an extract from interferon-treated (or from control) cells unless the extract had been passed through Sephadex G-25 or dialyzed. The translation fo exogenous mRNA was, however, impaired in an extract from interferon-treated cells that had not been passed through Sephadex G-25. This impairment was apparently not overcome by added tRNA.     

Human T lymphocyte colonies in agar: a comparison with other T cell assays in healthy subjects and cancer patients.

Colonies of human lymphocytes with T cell characteristics will grow in agar from repeated mitotic divisions with phytohaemagglutinin (PHA) stimulation. The colonies comprise spheres of tightly-packed cells with up to 500-1,000 blast-like cells in each colony. 65% of cells from pooled colonies bound AET-treated sheep red cells. 1,100-2,500 colonies/10(6) peripheral blood lymphocytes developed when cell donors were healthy but lower numbers (350-1,000 colonies/10(6) lymphocytes) were detected in blood from cancer patients. Comparison with other non-specific assays of cell-mediated immunity showed that while 66% of cancer patients were anergic (to five recall antigens) and 78% exhibited depressed mitotic activity in standard cultures with low dose PHA, 100% of these patients revealed T cell colony formation below normal. It is suggested that further studies of T lymphocyte colony-forming cells in healthy people and in a number of disease states may significantly advance our understanding of mechanisms of cell-mediated immunity.     

Unequal cell division, growth regulation and colony size of mammalian cells: a mathematical model and analysis of experimental data.

This work describes mathematically the dynamics of expansion of cell populations from the initial division of single cells to colonies of several hundred cells. This stage of population growth is strongly influenced by stochastic (random) elements including, among others, cell death and quiescence. This results in a wide distribution of colony sizes. Experimental observations of the NIH3T3 cell line as well as for the NIH3T3 cell line transformed with the ras oncogene were obtained for this study. They include the number of cells in 4-day-old colonies initiated from single cells and measurements of sizes of sister cells after division, recorded in the 4-day-old colonies. The sister cell sizes were recorded in a way which enabled investigation of their interdependence. We developed a mathematical model which includes cell growth and unequal cell division, with three possible outcomes of each cell division: continued cell growth and division, quiescence, and cell death. The model is successful in reproducing experimental observations. It provides good fits to colony size distributions for both NIH3T3 mouse fibroblast cells and the same cells transformed with the rasEJ human cancer gene. The difference in colony size distributions could be fitted by assuming similar cell lifetimes (12-13 hr) and similar probabilities of cell death (q = 0.15), but using different probabilities of quiescence, r = 0 for the ras oncogene transformed cells and r = 0.1 for the non-transformed cells. The model also reproduces the evolution of distributions of sizes of cells in colonies, from a single founder cell of any specified size to the stable limit distribution after eight to ten cell divisions. Application of the model explains in what way both random events and deterministic control mechanisms strongly influence cell proliferation at early stages in the expansion of colonies.     

Is group living an antipredator defense in a facultatively communal webspinner (Embiidina: Clothodidae)?

I tested whether predator attack rate is a function of expanse of silk for colonies ofAntipaluria urichi, a facultatively communal webspinner. The avoidance effect hypothesis predicts that the probability of a predator detecting a group does not increase proportionately with an increase in expanse of silk, and therefore, larger groups are relatively less likely to be attacked. I counted the number of holes inflicted on silk over 3 weeks, an indirect measure of predation, for 47 colonies. Supporting the avoidance effect, holes per perimeter of silk accumulated at a rate lower than would be predicted by size alone. Further analysis using predation risk, computed as holes per individual per silk perimeter, revealed that risk was extremely variable for colonies with little silk (<200 cm) but, on average, did not vary as silk expanse increased. Overall, predators of webspinner colonies appear to be influenced by the avoidance effect, but whether the occupants of the silk are safer is unresolved.     

The mutation rate of the human mtDNA deletion mtDNA4977.

The human mitochondrial mutation mtDNA4977 is a 4,977-bp deletion that originates between two 13-bp direct repeats. We grew 220 colonies of cells, each from a single human cell. For each colony, we counted the number of cells and amplified the DNA by PCR to test for the presence of a deletion. To estimate the mutation fate, we used a model that describes the relationship between the mutation rate and the probability that a colony of a given size will contain no mutants, taking into account such factors as possible mitochondrial turnover and mistyping due to PCR error. We estimate that the mutation rate for mtDNA4977 in cultured human cells is 5.95 x 10(-8) per mitochondrial genome replication. This method can be applied to specific chromosomal, as well as mitochondrial, mutations.     

The evolution of two mutations during clonal expansion

Knudson's two-hit hypothesis proposes that two genetic changes in the RB1 gene are the rate-limiting steps of retinoblastoma. In the inherited form of this childhood eye cancer, only one mutation emerges during somatic cell divisions while in sporadic cases, both alleles of RB1 are inactivated in the growing retina. Sporadic retinoblastoma serves as an example of a situation in which two mutations are accumulated during clonal expansion of a cell population. Other examples include evolution of resistance against anticancer combination therapy and inactivation of both alleles of a metastasis-suppressor gene during tumor growth. In this article, we consider an exponentially growing population of cells that must evolve two mutations to (i) evade treatment, (ii) make a step toward (invasive) cancer, or (iii) display a disease phenotype. We calculate the probability that the population has evolved both mutations before it reaches a certain size. This probability depends on the rates at which the two mutations arise; the growth and death rates of cells carrying none, one, or both mutations; and the size the cell population reaches. Further, we develop a formula for the expected number of cells carrying both mutations when the final population size is reached. Our theory establishes an understanding of the dynamics of two mutations during clonal expansion.