In vitro DNA synthesis as indicator of mammary epithelial cell division: [14C]thymidine uptake versus flow cytometry cell cycle analysis

Summary Mammary and adipose explants from eight mid-lactation Holstein cows were co-cultured for 24 h in the presence or absence of liver explants, 1 μg/ml pituitary bovine somatotrophin, or 100 ng/ml insulinlike growth factor-I. Liver explants in the media significantly depressed DNA and protein synthesis by mammary tissue as measured by [¹⁴C]-thymidine and amino acid incorporation. As measured by flow cytometry, the concentration of DNA in the G₀G₁ and G₂M cells and the percentage of cells in the G₀G₁ population of mammary tissue was also significantly depressed by liver tissue. Changes in the percentage of cells in the S and G₂M phases were not significant. Insulinlike growth factor-I in the presence of liver explants depressed protein synthesis, thymidine incorporation, and the concentration of DNA in the G₀G₁ and G₂M cells compared to control but did not affect the percentage of cells in the G₀G₁, S, or G₂M phases. Previously it was assumed that changes in [¹⁴C]thymidine incorporation indicated that changes in cell division were occurring. Flow cytometry revealed that changes in DNA content of mammary cells as a result of liver or hormonal stimulation were not due to changes in cell division. Indications are that differences in cellular DNA content result from changes in the rate of amplification of individual genes responsible for milk protein synthesis.     

The use of flow cytometry and fluorescein-labeled antibodies to measure specific milk proteins in bovine mammary epithelial cells

Summary A flow cytometric technique was developed to measure the relative concentration of whey protein and β-casein in individual fixed and permeabilized bovine mammary epithelial cells. Primary bovine mammary epithelial cells were compared to mammary cells isolated from explants after a 24-h incubation and a bovine mammary epithelial transfected cell line (MAC-T). Cells were incubated with rabbit anti-bovine whey protein (α-lactalbumin + β-lactoglobulin) or β-casein primary antibodies followed by a fluorescein-labeled goat anti-rabbit IgG second antibody. The number and intensity of fluorescing cells were measured using an EPICS Profile Flow Cytometer. Primary and explant cells contained 3.3 and 2.8 times more whey protein than MAC-T cells. Explant epithelial cells contained 2.9 and 5.1 times more β-casein than primary or MAC-T cells. The higher concentrations of specific proteins within the cells was attributed to either greater synthesis or reduced secretion. These data show that flow cytometry is capable of detecting differences in milk protein concentration in different mammary epithelial cell types.     

Steroidal and growth factor regulation of [3H]thymidine incorporation by cultured endosalpingeal cells of the bovine oviduct

Summary Cultured cells from the bovine endosalpinx were used to evaluate effects of estradiol-17β, progesterone, epidermal growth factor, and insulinlike growth factors I and II on [³H]thymidine incorporation. Cells were treated with hormones and growth factors when approximately 50% confluent. After 24 h, DNA synthesis was quantified by pulsing cells with [³H]thymidine for 12 h and determining uptake into DNA. Cells prepared by mechanical dispersal incorporated more [³H]thymidine than cells dispersed with collagenase. However, hormonal responses were the same for both types of cells. As compared to plastic, cells on a Matrigel substratum exhibited lower incorporation of [³H]thymidine and were unresponsive to hormones. Estradiol-17β increased [³H]thymidine incorporation slightly at 10⁻¹⁰ mol/liter and higher. Epidermal growth factor, insulinlike growth factor-I, and insulinlike growth factor-II also stimulated [³H]thymidine incorporation. Effects of insulinlike growth factor-I were greater for cells treated with estradiol-17β. In the absence of estradiol, progesterone inhibited [³H]thymidine incorporation at 1, 10, and 100 ng/ml. When estradiol-17β was present, progesterone stimulated [³H]thymidine incorporation at 1 ng/ml and reduced incorporation at 100 ng/ml. In conclusion, [³H]thymidine incorporation by cultured oviductal endosalpingeal cells can be regulated by ovarian steroids and growth factors. These molecules may represent signals through which the ovary, embryo, and oviduct regulate oviductal growth. Work conducted while on a sabbatical leave supported by the Deutsche Forschungsgemeinschaft.     

Differential effects of ACTH or 8-Br-cAMP on growth and replication in a functional adrenal tumor cell line

The effects of ACTH and 8-Br-cAMP on growth and replication of a functional mouse adrenal tumor cell line (Y-1) were investigated. ACTH and 8-Br-cAMP both inhibited DNA synthesis and replication when added to randomly growing cell cultures. ACTH addition and serum deprivation each arrested cells in G₁; an additional point of arrest in G₂ occurred with 8-Br-cAMP. Cells whose growth was arrested in G₁ by ACTH had a significantly larger volume and protein and RNA content compared to cells arrested in G₁ by serum deprivation. When ACTH or 8-Br-cAMP was added with serum to cells arrested by serum deprivation, the wave of DNA synthesis and cell division seen with serum was abolished. ACTH and 8-Br-cAMP had no effect on the serum-induced increases in protein and RNA content, rates of leucine incorporation into protein and uridine incorporation into RNA, and RNA polymerase I activity observed in cells during the pre-replicative period. Partial inhibition of the serum-induced increase in uridine transport occurred. ACTH and cAMP do not appear to inhibit replication by generalized negative pleiotypic effects but rather to inhibit the initiation of DNA synthesis more specifically. The ACTH-arrested Y-1 cell resembles an in vivo hypertrophied adrenal cortical cell.     

The depletion of DNA methyltransferase-1 and the epigenetic effects of 5-aza-2’deoxycytidine (decitabine) are differentially regulated by cell cycle progression

5-Aza-2'-deoxycytidine (decitabine) is a drug targeting the epigenetic abnormalities of tumors. The basis for its limited efficacy in solid tumors is unresolved, but may relate to their indolent growth, their p53 genotype or both. We report that the primary molecular mechanism of decitabine—depletion of DNA methyltransferase-1 following its “suicide” inactivation—is not absolutely associated with cell cycle progression in HCT 116 colon cancer cells, but is associated with their p53 genotype. Control experiments affirmed that the secondary molecular effects of decitabine on global and promoter-specific CpG methylation and MAGE-A1 mRNA expression were S-phase dependent, as expected. Secondary changes in CpG methylation occurred only in growing cells ~24–48 h after decitabine treatment; these epigenetic changes coincided with p53 accumulation, an index of DNA damage. Conversely, primary depletion of DNA methyltransferase-1 began immediately after a single exposure to 300 nM decitabine and it progressed to completion within ~8 h, even in confluent cells arrested in G₁ and G₂/M. Our results suggest that DNA repair and remodeling activity in arrested, confluent cells may be sufficient to support the primary molecular action of decitabine, while its secondary, epigenetic effects require cell cycle progression through S-phase.     

Cyclic nucleotides and cell growth

Growth induction in resting fibroblast cultures by serum or growth factors induces a fast, transient cGMP peak which may constitute the intracellular signal for growth. A similar cGMP peak occurs when 3T3 cells arrested at the restriction point or in G₀ by starvation for certain amino acids are induced for growth by readdition of the lacking nutrients. Both 3T3 and SV3T3 cells which are arrested randomly all around the cell cycle do not exhibit major changes in cyclic nucleotides after growth induction. Determination of intracellular cAMP and cGMP levels in normal and transformed fibroblasts under different growth conditions shows that the transition between growing and resting state (G₀ arrest) is accompanied and probably induced by characteristic changes in cAMP to cGMP ratios. cGMP is decreased 2-5-fold in resting as compared to growing cultures, and increased 10-20-fold in activated cultures 20 min after serum induction. No major cGMP change was observed in growing, confluent, or serum-activated cultures of transformed cells. Measurement of guanylcyclase under unphysiological conditions (2 mM Mn⁺⁺) in crude and purified membranes from 3T3 and SV3T3 cultures did not show increased enzyme activity in the transformed cells. Significant differences may only show up when synchronized cells pass through the restriction point in G₁ phase. As a hypothesis it is proposed that transformed cells have an activated guanylcyclase system or a relaxed cGMP-pleiotypic response mechanism at the restriction point of their cell cycle.     

In vitro culture of cryopreserved bovine mammary cells on collagen gels: synthesis and secretion of casein and lactoferrin

The preparation, cryopreservation, and culture on type I collagen gels of lactating bovine mammary cells with prolonged milk protein synthesis and secretion in vitro is described. Cryopreserved cells prepared as acinar fragments from either lactating or developing mammary glands attached to the collagen substratum within 24-48 hr after plating in serum and hormone supplemented medium. During continued culture in hormone-supplemented (insulin, cortisol, and prolactin) serum-free medium outgrowth of cells from the attached acinar fragments was observed beginning on day 2, with continued outgrowth to near confluence by day 6. Two morphologically distinct cell types were evident; initial outgrowth was by large polygonal cells that were subsequently overlain by spindle-shaped cells. Cells from both lactating and developing mammary glands sustained substantial milk protein secretion for at least 14 days in culture. Alpha S1-casein synthesis and secretion in cultures of lactating mammary cells was dependent on a critical minimum cell population density, below which alpha S1-casein was not secreted. In contrast, lactoferrin (LF) secretion into the medium increased linearly with the increase in cell population density. Cells cryopreserved up to 16 months secreted LF at levels comparable to fresh cultures of the same cells.     

Milk Protein Synthesis, Gene Expression, and Hormonal Responsiveness in Primary Cultures of Mammary Cells from Lactating Sheep

A ruminant mammary cell culture that accurately reproduces mammary function in vitro would be a valuable tool in studies of ruminant lactation, With this in mind, we have examined milk protein synthesis and secretion, milk protein mRNA abundance, and hormonal responsiveness in primary cultures of mammary acini from lecturing sheep. α- and β-casein protein synthesis, β-lactoglobulin synthesis, and α-casein, β-casein, and β-lactoglobulin secretion are maintained at high levels for 8 h in culture, but then decline to approximately 25% of maximal rates between 8 and 24 h in culture, whereas synthesis of other proteins remains unaltered. The relative abundance of α-S₁-casein, β-lactoglobulin, and α-lactalbumin mRNAs similarly decline between 8 and 24 h in culture. Extracellular labeled α-casein is increased fourfold in the presence of fetal calf serum (FCS). In total, FCS alters the abundance of 47 of 68 secreted proteins detected by two-dimensional electrophoresis. However, FCS and lactogenic/galactopoietic hormones had no effect on the rate of decline of mammary function and did not promote any regaining of function when present for up to 9 days in culture. These results suggest that providing its limitations are recognized, this primary cell culture system may be useful in studying some aspects of ruminant mammary function in vitro.     

Cytostatic and Cytotoxic Effects of Pannon (P-30 Protein), A Novel Anticancer Agent

P-30 Protein is a novel protein, of molecular weight approximately 15 kD, obtained from the extract of a vertebrate tissue showing in vivo antitumour activity. Cytostatic and cytotoxic effects of this product in its purified form (P-30 Protein) or in partially purified extracts (Pannon) were studied in vitro on human leukaemic HL-60, human submaxillary carcinoma A-253, human colon adenocarcinoma Colo 320 CM and murine erythroleukaemia (Friend leukaemia) cell lines. of these cells, HL-60, A-253 and Colo 320 CM were sensitive and Friend leukaemia resistant to this agent. the effects were time- and concentration-dependent. During the initial 24–48 h of treatment, a slowdown in cell proliferation was apparent but cell death was not extensive. After 24–48 h, there was a reduction in the proportion of cells in S phase of the cell cycle and the cells became preferentially arrested in G₁ phase. the G₁ cells showed high heterogeneity with respect to RNA content and some cells were characterized by very low RNA content. Progressive cell death occurred in cultures maintained with Pannon for up to 7 d in proportion to its concentration. Reductions of 50 and 90% in clonogenicity of A-253 cells were observed during their growth in the presence of 0.13 and 1.5 μg/ml of this protein, respectively. Exponentially growing cells were more sensitive to Pannon compared with cells from confluent cultures. Colonies of A-253 cells growing in the presence of Pannon were much smaller in size compared with control colonies, indicating that the rate of proliferation of clonogens is reduced by this agent. It appears that P-30 Protein induces cytostatic effects via modulation of cell transition to quiescence or differentiation. the mechanism of its cytotoxic activity is unclear.     

Effect of staurosporine on MOLT-4 cell progression through G2 and on cytokinesis

Staurosporine (SSP) is an inhibitor of a variety of protein kinases with an especially high affinity towards protein kinase C. Whereas SSP has been shown to halt the cell cycle progression of various normal, nontransformed cell types in G₁, most virus transformed or tumor cells are unaffected in G₁ but arrest in G₂ phase. SSP has also been observed to increase the appearance of cells with higher DNA content, suggestive of endoreduplication, in cultures of tumor cells. Using multivariate flow cytometry (DNA content vs. expression of cyclin B, nucleolar p120 protein, or protein reactive with Ki-67 antibody) which makes it possible to discriminate cells with identical DNA content but at different phases of the cycle, we have studied the cell cycle progression of human lymphocytic leukemic MOLT-4 cells in the presence of 0.1 μM SSP.MOLT-4 cells did not arrest in G₁ or G₂ phase in the presence of the inhibitor. Rather, they failed to undergo cytokinesis, entering G₁ phase at higher DNA ploidy (tetraploidy; G_1T), and then progressed through S_T (rereplication) into G_2T and M_T. The rates of entrance to G₂ and G_2T were essentially identical, indicating that the rates of cell progression through S and S_T as well as through G₂ and G_2T, respectively, were similar. Cells entrance to mitosis and mitotic chromatin condensation were also similar at the diploid and tetraploid DNA content level and were unaffected by 0.1 μM SSP. No evidence of growth imbalance (altered protein or RNA to DNA ratio) was observed in the case of tetraploid cells. The data show that, in the case of MOLT-4 cells, all events associated with the chromosome or DNA cycle were unaffected by SSP; the only target of the inhibitor appears to be kinase(s) controlling cytokinesis. © 1994 Wiley-Liss, Inc.     

The production and localization of laminin in cultured vascular and corneal endothelial cells

The production and localization of laminin, as a function of cell density (sparse versus confluent cultures) and growth stage (actively growing versus resting cultures), has been compared on the cell surfaces of cultured vascular and corneal endothelial cells. Comparison of the abilities of the two types of cells to secrete laminin and fibronectin into their incubation medium reveals that vascular endothelial cells can secrete 20-fold as much laminin as can corneal endothelial cells. In contrast, both cell types produce comparable amounts of fibronectin. Furthermore, if one compares the secretion of laminin and fibronectin as a function of cell growth, it appears that the laminin released into the medium by either vascular or corneal endothelial cells, is a function of cell density and cell growth, since this release is most pronounced when the cells are sparse and actively growing, and decreases by 10- and 30-fold, respectively, when either vascular or corneal endothelial cell cultures become confluent. With regard to fibronectin secretion, no such variation can be seen with vascular endothelial cell cultures, regardless of whether they are sparse and actively growing or confluent and resting. Corneal endothelial cell cultures, demonstrated a twofold increase in fibronectin production when they were confluent and resting as compared to when they were sparse and actively growing. When the distribution of laminin versus fibronectin within the apical and basal cell surfaces of cultured corneal and vascular endothelial cells is compared, one can observe that unlike fibronectin, which in sparse and subconfluent cultures can be seen to be associated with both the apical cell surface. In confluent cultures, laminin can be found associated primarily with the extracellular matrix beneath the cell monolayer, where it codistributes with type IV collagen.     

Manipulation of medium conditions and differentiation in the rat myogenic cell line L6

Myoblasts of the L6 rat cell line were grown in Ham's F12 nutrient medium containing 10% fetal calf serum (F12 + FCS). Although the cells were confluent by 6 days in culture, fusion was not observed even if cultures were maintained for 10–14 days. At least 80% of the cells in such confluent unfused cultures were in the G₁ phase of the cell cycle and less than 5% of the cells in confluent cultures synthesized DNA during a 4-day period. The synthesis of muscle-specific proteins (α-actin, β-tropomyosin, and myosin light chains LC1_emb and LC2_F) was negligible when compared to fused cultures of L6 cells grown for a similar time in Dulbecco's medium with 10% FCS (DME + FCS). When the unfused cultures were shifted from F12 + FCS to DME + FCS, DNA synthesis could be demonstrated in more than 95% of the cells and fusion occurred, indicating that neither proliferative nor myogenic capacity had been irreversibly lost. Raising the levels of calcium, varying the serum concentration from 0 to 20%, or the addition of medium components (present in DME but reduced or absent in F12) all failed to induce fusion in the L6 cells grown in F12. However, L6 cells will fuse in mixtures of F12 + FCS and DME + FCS. Fusion will also occur if L6 cells are grown at clonal density in F12 + FCS supplemented with calcium. While it has not been possible to determine why F12 + FCS is nonpermissive for L6 cells in confluent mass cultures, the results demonstrate that prolonged residence in the G₁ phase of the cell cycle is not a sufficient condition for L6 myoblast differentiation to occur.     

INHIBITION OF CELL GROWTH IN THE G1 PHASE BY ADENOSINE 3'',5''-CYCLIC MONOPHOSPHATE

Incorporation of tritiated thymidine into acid-precipitable material was used to measure the rate of DNA synthesis in secondary cultures of human diploid fibroblasts. Confluent cultures of human diploid fibroblasts, which are synchronized in the G₁ phase due to contact inhibition, were released from growth inhibition either by the addition of fresh medium to the cultures or by trypsinization and replating at nonconfluent densities. Either treatment resulted in a synchronous wave of DNA synthesis beginning 10–15 h after treatment and peaking at 20–25 h. In confluent cultures stimulated by fresh medium, either the addition of 0.25 mM N⁶, O²-dibutyryl-adenosine 3',5'-cyclic monophosphate (db-cAMP) to the medium in the interval 4–8 h after stimulation or the replacement of the fresh medium in that same 4 h interval with the depleted medium present on the cells for the 2 day period before stimulation delayed the synchronous onset of DNA synthesis in the cultures by about 4 h. In nonconfluent cultures freshly seeded from trypsinized confluent cultures, this same depleted medium obtained after a 2 day incubation of fresh medium on confluent cultures is shown to support the progress of the cells into S phase; however, the addition of 0.25 mM db-cAMP to the medium 3½ h after replating still partially prevented the initiation of DNA synthesis in the cultures. The results are discussed in terms of the role of serum and cAMP in the control of cell growth in fibroblast cultures.     

The depletion of DNA methyltransferase-1 and the epigenetic effects of 5-aza-2′deoxycytidine (decitabine) are differentially regulated by cell cycle progression

5-Aza-2′-deoxycytidine (decitabine) is a drug targeting the epigenetic abnormalities of tumors. The basis for its limited efficacy in solid tumors is unresolved, but may relate to their indolent growth, their p53 genotype or both. We report that the primary molecular mechanism of decitabine—depletion of DNA methyltransferase-1 following its “suicide” inactivation—is not absolutely associated with cell cycle progression in HCT 116 colon cancer cells, but is associated with their p53 genotype. Control experiments affirmed that the secondary molecular effects of decitabine on global and promoter-specific CpG methylation and MAGE-A1 mRNA expression were S-phase dependent, as expected. Secondary changes in CpG methylation occurred only in growing cells ∼24–48 h after decitabine treatment; these epigenetic changes coincided with p53 accumulation, an index of DNA damage. Conversely, primary depletion of DNA methyltransferase-1 began immediately after a single exposure to 300 nM decitabine and it progressed to completion within ∼8 h, even in confluent cells arrested in G₁ and G₂/M. Our results suggest that DNA repair and remodeling activity in arrested, confluent cells may be sufficient to support the primary molecular action of decitabine, while its secondary, epigenetic effects require cell cycle progression through S-phase.Key words: 5-aza-2′-deoxycytidine, decitabine, DNA methyltransferase-1, suicide inactivation, p53, S-phase, cell cycle     

Synthesis of glycoprotein, glycolipid, protein, and lipid in synchronized L5178Y cells

Synthesis of four macromolecular classes found in membranes—glycoprotein, glycolipid, protein, and lipid—was measured as a function of time of the cell cycle in synchronized L5178Y cells. Incorporation of leucine, choline, fucose, glucosamine, or thymidine into the cells, protein, nucleic acid, or lipid was measured by pulse-labeling for ½ hr at ½ hr intervals after release from the mitotic block. The amount of protein, lipid, glycoprotein, or glycolipid released or secreted into the medium by the L5178Y cells was also measured as a function of time of the cell cycle. Cellular protein was found to be synthesized throughout the cell cycle, with the highest synthesis occurring in the S period; synthesis was depressed in the M period. Cellular glycoprotein was synthesized at approximately the same times as protein, except that the rates of glycoprotein synthesis in the S period relative to other periods were much greater than for protein. Secreted protein was synthesized throughout the cell cycle without any general pattern, except that secretion was elevated in the late S and G₂ periods. Secreted glycoprotein was similar to secreted protein. Cellular lipid and cellular glycolipid were synthesized almost exclusively in the G₂ and M periods; there was no synthesis in the G₁ and S periods. Release or secretion of glycolipid and lipid also occurred in the G₂ and M periods.     

Subnuclear redistribution of DNA species in confluent and growing mammalian cells

About 20 to 25 percent of the nuclear DNA from cultured cells of the African green monkey, Cercopithecus aethiops, consists of a homogeneous, highly repetitive fraction designated C. aethiops component DNA. Use of in situ hybridization techniques reveals component at the centromeres of chromosomes from both diploid and heteroploid African green monkey kidney (AGMK) tissue culture cells. — Component DNA comprises 47 percent of the nucleolar DNA in actively growing primary AGMK cells, but only 31 percent of the nucleolar DNA in confluent cells which show density-dependent growth inhibition. Further, there is a pronounced shift of both main band and component DNA from euchromatin to heterochromatin when growing cells attain confluency. Thus, the relative subnuclear distributions of component and main band DNA's are different in growing and confluent cells. — In situ hybridization techniques indicate that component sequences aggregate in clumps in nuclei of growing cells and show a diffuse distribution in nuclei of confluent cells. This suggests that centromeric regions of the various chromosomes or groups of chromosomes aggregate and disaggregate reversibly as the culture changes from density-dependent growth inhibition to active cell division. — Hypotonic citrate treatment of primary AGMK cells causes nucleoli of confluent cells to disperse: this dispersion following citrate treatment was not seen in growing AGMK cells or in confluent or growing heteroploid cells. Similarly, this nucleolar dispersion was seen in confluent diploid mouse and human cells but not in growing diploid cells or in confluent or growing heteroploid cells.     

Membrane interactions and lipid binding of casein oligomers and early aggregates

Caseins constitute the main protein components in mammalian milk and have critical functions in calcium transport and prevention of protein aggregation. Fibrillation and aggregation of κ-casein, a phenomenon which has only recently been detected, might be associated with malfunctions of milk secretion and amyloidosis phenomena in the mammary glands. This study employs a newly-designed chromatic biomimetic vesicle assay to investigate the occurrence and the parameters affecting membrane interactions of casein aggregates and the contribution of individual casein members to membrane binding. We show that physiological casein colloids exhibit membrane activity, as well as early globular aggregates of κ-casein, a prominent casein isoform. Furthermore, inhibition of κ-casein fibrillation through complexation with α_S-casein and β-casein, respectively, was found to go hand in hand with induction of enhanced membrane binding; these data are important in the context of casein biology since in secreted milk κ-casein is found only in assemblies containing also α_S-casein and β-casein. The chromatic experiments, complemented by transmission electron microscopy analysis and fluorescence quenching assays, also revealed significantly higher affinity early spherical aggregates of k-casein to anionic phosphatidylglycerol-lipids, as compared to zwitterionic phospholipids. Overall, this study suggests that lipid interactions play important roles in maintaining the essential physiological functions of caseins in mammalian milk.     

In vitro and in vivo growth and casein gene expression of mouse mammary tumor epithelial cells in response to hormones

Cells from autochthonous mouse mammary carcinomas which display estrogen-independent growth _vivo were studied for their hormonal responses in primary culture. A culture system employing insulin-supplemented, serum-free medium and basement membrane Matrigel as a substratum was used to cultivate tumor cells. The cells did not exhibit in vitro estrogenor prolactin-dependent growth. Primary tumors still displayed a constitutional expression of α-, β-, and γ-casein mRNAs. These messages were dramatically reduced during the culture period. However, seven to eightfold increases in α- and β-casein mRNAs were inducible in the 5-day cultures by treatment with prolactin and hydrocortisone. If the hormones were present through a 2-week culture period, the levels of α-, β-, and γ-casein mRNAs in the cells were maintained and displayed in a time-dependent increase with a peak at 10–14 days. The accumulation of β-casein mRNA in vitro did not require DNA synthesis. Administration of prolactin directly into the growing tumors in vivo could also enhance β-casein mRNA levels in the tumor cells. Morphological studies of the cells cultured in the presence of prolactin and hydrocortisone did not reveal visible changes compared with those without hormonal treatment. Transplantation of tumor cells cultured in the presence or absence of hormones resulted in the development of tumors in mice at approximately the same time. The current studies suggest that the autochthonous mammary tumor cells, independent of estrogen for cell growth, were still inducible for casein gene expression in vitro and in vivo by appropriate hormones. The induction and maintenance of casein messages by a single hormonal treatment did not appear to correlate with morphology and DNA synthesis of cells in vitro or with tumor-producing capacities in vivo.