An in vitro model of epithelial cell growth stimulation in the rodent mammary gland.

Mouse mammary epithelial cell cultures previously described bring about extensive proliferation and a cell population with the appropriate markers for luminal ductal epithelial cells, and also the ability to form normal tissue after implantation into mice. This success may result from a culture environment that resembles certain aspects of the environment in the mammary gland. Mouse mammary epithelial cells, whose proliferation is limited when plated alone, can be stimulated to multiply by contact with lethally irradiated cells of the LA7 rat mammary tumour line. Most of the proliferative stimulus is imparted by direct cell contact between LA7 and mouse mammary cells. Junctions, including adherens junctions, form among all cells in the culture, much as junctions form in the mammary gland. LA7 cells secrete TGFalpha and bFGF, factors found in the mammary gland, and factors to which mouse mammary cells respond in culture. Mouse mammary cells express keratins 8 and 18, markers for luminal cells of the mammary duct. LA7 cells express keratin 14 and vimentin, markers for myoepithelial cells. These facts, taken together, fit a model of cell replacement in an epithelial tissue and also imitate the relationship between luminal ductal cells and myoepithelial cells in the mammary gland. This method of culturing cells is useful, not only for in vitro-in vivo carcinogenesis studies, but also for the study of mechanisms by which growth signals are imparted from one cell to another.

Gap-junctional communication between feeder cells and recipient normal epithelial cells correlates with growth stimulation.

LA7 rat mammary tumor cells stimulate the proliferation, in culture, of three normal epithelial cell types, namely mouse mammary, rat mammary, and mouse thymic cells. Gap-junctional communication between LA7 feeders and mouse mammary cells was demonstrated by microinjection of lucifer yellow, which traveled from LA7 to the surrounding mouse mammary cells. The amount of 3H-uridine exchange between feeder and recipient mouse mammary, rat mammary, and mouse thymus cells correlated with the growth rate induced by the feeders. Cells of the Madin Darby canine kidney (MDCK) line, which do not appreciably stimulate mouse mammary cell growth when used as feeder cells, also exchange little 3H-uridine with them. Expression of connexins Cx43, 32, and 26 was studied in all these cell lines and strains by immunocytochemistry. Mouse mammary cells expressed Cx26, and a few mouse thymic cells expressed Cx32. LA7, mouse mammary, mouse thymic, and rat mammary cells all expressed easily detectable amounts of the gap-junction protein Cx43, in contrast to MDCK cells, which expressed only a hint of the protein. These results suggest that gap junctions composed of Cx43 are those by which the normal epithelial cells communicate with the LA feeders. Thus, the ability of feeder cells to stimulate proliferation in recipients correlates with the expression of Cx43 in both members of the feeder/recipient pair and the capacity to form functional gap junctions between these cells.

Physical connections between feeder cells and recipient normal mammary epithelial cells.

Cells of the LA7 rat mammary tumor line stimulate proliferation of normal mouse mammary epithelial cells in culture when in direct physical contact with them. We examined junctional connections between these LA7 feeders and the recipient mouse mammary epithelial cells in order to study the role these junctions may play in growth signaling. Tight junctions and desmosomes between LA7 feeders and mouse mammary cells were detected by immunocytochemistry. These junctions connected every cell of either type with each of its neighbors. Adherens junctions, although evident between mouse mammary cells, could not be detected between LA7 and mouse mammary cells or between LA7 cells themselves. However, E-cadherin, the transmembrane protein of adherens junctions, was present in LA7 cell lysates. beta-catenin, which normally binds cadherins, was detected at the borders of LA7 cells. Presence of gap junctions between LA7 and mouse mammary cells was determined by traverse of lucifer yellow from an injected LA7 cell to surrounding mouse mammary epithelial cells. The experiments thus indicate that three types of intercellular junctions occur between cells active in direct cell-cell-stimulated proliferation signaling.

Feeder cells impart a growth stimulus to recipient epithelial cells by direct contact.

Mouse mammary epithelial cells have been shown to proliferate when cultured in the same vessel with lethally irradiated cells of the LA7 rat mammary tumor line. Presented here are experiments that indicate that the LA7 feeder cells stimulate growth of the normal mouse mammary cells by a mechanism that involves direct contact between the two cell types. It is possible that the LA7 feeder cells stimulate proliferation by secretion of a labile growth factor, by secretion of a soluble growth factor in such low concentrations that dilution by travel over a distance makes it less effective, that the stimulus is transduced directly through membrane receptors on the recipient epithelial cells, or that a growth message is sent through gap junctions between cells. This feeder cell system is proposed as an in vitro model for epithelial wound healing.

Cultured proliferating rat mammary epithelial cells.

Normal epithelial cells from the rat mammary gland proliferated in culture when plated with lethally irradiated cells of the LA7 rat mammary tumor line. Proliferation of the normal rat cells occurred as the LA7 cells slowly died from the radiation. By labeling the cultures with 3H-thymidine it was determined that most of the proliferating rat cells were those adjacent to the LA7 feeder cells. The epithelial cells from the primary culture proliferated after subsequent passages if the cells were plated at each subculture with newly irradiated LA7 cells. If the cells were plated at a ratio of approximately 1:8 rat:LA7 a confluent layer of normal rat cells covered the plastic substrate after 6 to 7 wk. The cells have so far been carried up through Passage 7, which amounted to approximately 19 doublings in cell number, and still proliferate vigorously. The growth medium for this culture system was Dulbecco's modified Eagle's medium:Ham's F12 1:1 supplemented with fetal bovine serum, insulin, and antibiotics. The presence in the cells of keratin, desmosomes, and cell junctions attested to their epithelial origin. The cultures were composed of cells with diploid or near diploid chromosome numbers. Samples of the cultured cells were implanted into the cleared fat pads of nude mice. Most of the implants from Passage 2 formed normal mammary ductal structures, but the incidence of outgrowths decreased significantly with later passages until no outgrowths resulted from the implantation of cells from Passage 5. The one unusual, feeder-independent cell line that arose from a primary culture seemed to be immortal in culture, contained a hyperdiploid chromosome complement, and formed abnormal structures when implanted into cleared fat pads.

Responses of synchronous L5178Y S/S cells to heavy ions and their significance for radiobiological theory.

Synchronous suspensions of the radiosensitive S/S variant of the L5178Y murine leukaemic lymphoblast at different positions in the cell cycle were exposed aerobically to segments of heavy-ion beams (20Ne, 28Si, 40Ar, 56Fe and 93Nb) in the Bragg plateau regions of energy deposition. The incident energies of the ion beams were in the range of 460 +/- 95 MeV u-1, and the calculated values of linear energy transfer (LET infinity) for the primary nuclei in the irradiated samples were 33 +/- 3, 60 +/- 3, 95 +/- 5, 213 +/- 21 and 478 +/- 36 keV microns-1, respectively; 280 kVp X-rays were used as the baseline radiation. Generally, the maxima or inflections in relations between relative biological effectiveness (RBE) and LET infinity were dependent upon the cycle position at which the cells were irradiated. Certain of those relations were influenced by post-irradiation hypothermia. Irradiation in the cell cycle at mid-G1 to mid-G1 + 3 h, henceforth called G1 to G1 + 3 h, resulted in survival curves that were close approximations to simple exponential functions. As the LET infinity was increased, the RBE did not exceed 1.0, and by 478 keV microns-1 it had fallen to 0.39. Although similar behaviour has been reported for inactivation of proteins and certain viruses by ionizing radiations, so far the response of the S/S variant is unique for mammalian cells. The slope of the survival curve for X-photons (D0: 0.27 Gy) is reduced in G1 to G1 + 3 h by post-irradiation incubation at hypothermic temperatures and reaches a minimum (Do: 0.51 Gy) at 25 degrees C. As the LET infinity was increased, however, the extent of hypothermic recovery was reduced progressively and essentially was eliminated at 478 keV microns-1. At the cycle position where the peak of radioresistance to X-photons occurs for S/S cells, G1 + 8 h, increases in LET infinity elicited only small increases in RBE (at 10% survival), until a maximum was reached around 200 keV microns-1. At 478 keV microns-1, what little remained of the variation in response through the cell cycle could be attributed to secondary radiations (delta rays) and smaller nuclei produced by fragmentation of the primary ions.

Insulin binding, internalization, and degradation by a cultured kidney cell line.

Proximal tubules are a key site of insulin metabolism, which is in part a receptor-mediated process. To explore the interaction between insulin and the kidney and to evaluate the role of receptors in insulin uptake and processing, a study was carried out with a cultured proximal-like opossum kidney (OK) cell line. 125I-insulin associated with confluent monolayers in a specific manner, and this interaction was competitively inhibited by insulin; unrelated peptides were relatively ineffective. Insulin degradation exhibited time and temperature dependency and up to a concentration of 5 X 10(-8) M was not saturable. Degradation exhibited partial hormone specificity. Separation of plasma membrane bound from internalized insulin was achieved by lowering extracellular pH. At 4 degrees C, 94% of cell-associated radioactivity was membrane bound, whereas at 37 degrees C, in the steady state, 33% was membrane bound and 67% was internalized. There was a significant correlation between membrane-bound insulin and the rate of degradation. These findings reveal that the binding and processing of insulin by the kidney cell line are compatible with the description of the uptake of filtered insulin by the proximal tubule in the intact kidney. Accordingly we conclude that this cell line provides a good model for studying renal epithelial uptake and metabolism of insulin.

Cultured mouse mammary epithelial cells: normal phenotype after implantation.

Mammary epithelial cells from normal virgin BALB/c mice were cultivated in vitro by the feeder cell technique developed and reported previously. These cells were cultured up to the 10th passage, equivalent to 60 cell divisions in culture. They were then tested for normality by several criteria, namely, the ability to regrow into normal mammary glands after implantation into cleared mammary fat pads of both syngeneic and nude mice, chromosome numbers, and response to mammogenic hormones. The cultured cells did form normal mammary ducts after implantation. The fraction of fat pads with ductal outgrowths as well as the size of the outgrowths was proportional to the number of cells implanted. When 10(6) cells were implanted into BALB/c mice, 83% of the fat pads contained outgrowths, filling, on the average, approximately 87% of the fat pad. More ductal outgrowths occurred from implanted cells taken from lower tissue culture passages than from high ones, and the number of outgrowths was greater in BALB/c mice than in nude mice. A small fraction of the cells in culture reacted with antibodies to casein, but there was no evidence of alpha-lactalbumin in the cells. However, ductal outgrowths from implanted cells responded to hormone stimulation of an estrogen deoxycorticosteroid pellet by forming well-developed lobulo-alveolar structures characteristic of pregnancy. Of the cells that were studied in passages 3 and 7, 85% were diploid. An abnormally growing culture in passage 10 was composed of cells in the tetraploid range. These tetraploid cells formed normal mammary ducts when implanted into animals.

Long-term proliferation of mouse thymic epithelial cells in culture.

Epithelial cells from the normal mouse thymus were successfully cultivated on tissue culture plastic when plated with lethally irradiated support cells of the LA7 rat mammary tumor line. As the irradiated LA7 cells slowly decreased in number the thymus cells proliferated concomitantly to form a confluent monolayer. The cells now in culture have been subcultured 8 times, have doubled in number at least 30 times, and are still proliferating vigorously. The culture technique also supported clonal growth from a single cell, and nine clones have been isolated. The colony-forming efficiency of thymic cells plated at low concentrations was about 8%. These cultures were never overgrown by fibroblasts. The thymus cells were characterized as epithelial by the presence of cytoplasmic keratin and numerous desmosomes and tonofilaments. They were shown to be mouse cells by immunocytochemistry with species specific antibodies, by isoenzyme analysis, and by karyology. The cells stained when reacted with antibodies to tubulin, vimentin, and actin, but not with antibodies to Thy-1.2, Lyt-1, Lyt-2, Ia, or H-2 proteins. More than 85% of the cells had a normal mouse diploid chromosome number of 40. This culture technique opens the way for future studies of T-cell education with homogeneous thymic epithelial cell populations both in vitro and after reimplantation into genetically defined strains of mice.

To grow mouse mammary epithelial cells in culture.

Normal mouse mammary epithelial cells from Balb/c mice were successfully cultivated on tissue culture plastic with lethally irradiated LA7 feeder cells. The feeder cells also promoted colony formation from single mouse mammary cells, and the fraction of cells that formed colonies was proportional to the density of feeder cells. The mouse mammary cells could be passaged at least 8-12 times as long as new feeder cells were added at each passage. The cells now in culture have doubled in number at least 30 times, but the in vitro lifespan is not yet known. The cultures of mouse cells maintained by this technique never became overgrown with fibroblasts and numerous domes formed in the cultures.

CO2/bicarbonate stimulates growth independently of PH in mouse mammary epithelial cells.

Mouse mammary cells of the NMuMG line proliferated faster and formed colonies more efficiently when the air above the cells contained 5% CO2. An increase in colony forming efficiency also occurred if the bicarbonate concentration in the medium was higher (44 versus 13 mM). These growth increases induced by the CO2 or bicarbonate occurred even when the control cultures were maintained at the same pH, and they occurred at every pH tested. Both the growth rate and colony forming efficiency of the NMuMG cells were highest at pH 7.0 to 7.3.

Mouse mammary cells in D-valine medium.

Cells of a mouse mammary epithelial cell line as well as fibroblasts from a mouse mammary explant were severely inhibited from proliferating in a medium in which D-valine was substituted for L-valine. After the first few days in D-valine medium, the number of epithelial cells did not increase despite the fact that a few percent continued to synthesize DNA. The cells did recognize the presence of the D-valine in the medium because cells in D-valine increased in volume and their numbers remained stationary, whereas cells without valine shrank and the cell numbers decreased with time.

An investigation of the effect of radioactive labeling of DNA on excision repair in UV-irradiated human fibroblasts.

Previous studies on the kinetics of thymine dimer excision and unscheduled DNA synthesis in UV-irradiated human fibroblasts showed a significant discrepancy in these two parameters (Ehmann et al., 1978. Biophys. J. 22: 249). In the present study we have investigated the effect of the level of the radioactive isotope used for labeling cells on the kinetics of a parameter that directly measures thymine dimer excision. We find no significant differences in the kinetics of this parameter in cells lightly or heavily labeled with radioactive thymidine.

Defective recovery of semi-conservative DNA synthesis in xeroderma pigmentosum cells following split-dose ultraviolet irradiation.

In normal human fibroblasts we observe an enhancement of the recovery of the rate of semi-conservative DNA synthesis after split-dose UV-irradiation relative to a single total UV dose. The enhanced recovery is totally absent in both a xeroderma pigmentosum variant line and two xeroderma pigmentosum lines belonging to complementation groups A and C.

The kinetics of thymine dimer excision in ultraviolet-irradiated human cells.

We have investigated the kinetics of the loss of thymine dimers from the acid-insoluble fraction of several ultraviolet (UV)-irradiated cultured human cell lines. Our results show that UV fluences between 10 and 40 J/m2 produce an average of 21-85 x 10(5) thymine dimers per cell and an eventual maximal loss per cell of 12-20 x 10(5) thymine dimers. The time for half-maximal loss of dimers ranged from 12-22 h after UV irradiation. In contrast, the time for half-maximal repair synthesis of DNA measured by autoradiography was 4.5 h. This figure agrees well with reported half-maximal repair synthesis times, which range from 0.5 to 3.6 h based on our analysis. The discrepancy in the kinetics of the loss of thymine dimers from DNA and repair synthesis is discussed in terms of possible molecular mechanisms of thymine dimer excision in vivo and in terms of possible experimental artifacts.

Caffeine, cyclic AMP and postreplication repair of mammalian cell DNA.

The methylxanthines, caffeine and theophylline, inhibit postreplication repair of DNA in mammalian cells. Because they also inhibit cyclic AMP phosphodiesterase, it was thought that there might be some connection between concentrations of cyclic AMP and postreplication repair. We tested this possibility by performing DNA sedimentation experiments with a cyclic AMP-resistant mouse lymphoma cell mutant and its wild-type counterpart. The results show that there is no connection between cellular cyclic AMP concentrations and the rate of postreplication repair. Therefore, it is more likely that caffeine and theophylline inhibit postreplication repair by some other means, such as by binding to DNA.