Stem cell: balancing aging and cancer

Stem cells are defined by their self-renewing capacity and the ability to differentiate into one or more cell types. Stem cells can be divided, depending on their origin, into embryonic or adult. Embryonic stem cells derive from early stage embryos and can give rise to cells from all three germ layers. Adult stem cells, first identified in hematopoietic tissue, reside in a variety of adult tissues. Under normal physiologic conditions, adult stem cells are capable of differentiating into the limited cell types that comprise the particular tissue or organ. Adult stem cells are responsible for tissue renewal and exhaustion of their replicative capacity may contribute to tissue aging. Loss of unlimited proliferative capacity in some of the adult stem cells and/or their progenitors may have involved the evolutionary trade-off: senescence prevents cancer but may promote aging. Embryonic stem cells exhibit unlimited self-renewal capacity due to the expression of telomerase. Although they possess some cancer cell characteristics, embryonic stem cells exhibit a remarkable resistance to genomic instability and malignant transformation. Understanding the tumor suppressive mechanisms employed by embryonic stem cells may contribute to the development of novel cancer treatments and safe cell-based therapies for age-related diseases.     

Isoelectric forms of alpha-L-fucosidase in mouse teratocarcinoma-derived cell lines

The alpha-L-fucosidase isoenzyme pattern of mouse teratocarcinoma-derived cell lines was analyzed by isoelectric focusing and compared with the pattern of a mammary carcinoma as an example of a malignant somatic cell line. In addition, these isoenzyme patterns were compared with those of normal fetal and adult mouse tissues from an earlier study. In the normal early fetal and placental tissues as well as in embryonal carcinoma and yolk sac carcinoma cells the alpha-L-fucosidase activity is predominantly associated with basic forms of the enzyme. This embryonic pattern of alpha-L-fucosidase is characterized by one to three isoelectric forms of the enzyme with pI values ranging from 7 to 9.5 accounting for more than two-thirds of the total activity. In contrast, the mammary carcinoma pattern resembles adult somatic tissues and primarily expresses acidic enzymatic forms (which comprise approximately 80% of total activity). The somatic cell malignancies arising in retransplantable teratocarcinomas show varying isoenzyme patterns. Thus, a malignant fibrous histiocytoma expresses predominantly basic forms of the enzyme, whereas a leiomyosarcoma expresses approximately equal amounts of acidic and basic forms of the enzyme resembling in this respect late fetal or immature neonatal tissues. These findings show that the embryonal carcinoma and yolk sac carcinoma cells of the mouse express the embryonic isoenzyme pattern of alpha-L-fucosidase in contrast to malignant cells originating in somatic tissue, like mammary carcinoma, which express the adult pattern. Malignancies arising in somatic tissues of teratocarcinomas may retain the embryonic alpha-L-fucosidase phenotype or show a phenotype corresponding to late fetal or neonatal tissues in normal ontogeny.     

Mammary epithelial cell: influence of extracellular matrix composition and organization during development and tumorigenesis

Stromal-epithelial interactions regulate mammary gland development and are critical for the maintenance of tissue homeostasis. The extracellular matrix, which is a proteinaceous component of the stroma, regulates mammary epithelial growth, survival, migration and differentiation through a repertoire of transmembrane receptors, of which integrins are the best characterized. Integrins modulate cell fate by reciprocally transducing biochemical and biophysical cues between the cell and the extracellular matrix, facilitating processes such as embryonic branching morphogenesis and lactation in the mammary gland. During breast development and cancer progression, the extracellular matrix is dynamically altered such that its composition, turnover, processing and orientation change dramatically. These modifications influence mammary epithelial cell shape, and modulate growth factor and hormonal responses to regulate processes including branching morphogenesis and alveolar differentiation. Malignant transformation of the breast is also associated with significant matrix remodeling and a progressive stiffening of the stroma that can enhance mammary epithelial cell growth, perturb breast tissue organization, and promote cell invasion and survival. In this review, we discuss the role of stromal-epithelial interactions in normal and malignant mammary epithelial cell behavior. We specifically focus on how dynamic modulation of the biochemical and biophysical properties of the extracellular matrix elicit a dialogue with the mammary epithelium through transmembrane integrin receptors to influence tissue morphogenesis, homeostasis and malignant transformation.     

Cellular tumorigenicity in nude mice: correlation with cell growth in semi-solid medium

Cultured cells derived from either normal or malignant tissues of several species have been tested by injection into the immune-deficient nude mouse in order to determine the cellular properties which are associated with tumorigenicity in vivo. Results show that one in vitro property consistently correlated with neoplastic growth in nude mice is the ability of the cell to form spherical colonies in a semi-solid growth medium such as methyl cellulose suspension. Cellular tumorigenicity is not determined solely by the malignancy of the tissue of origin, since cells derived from nonmalignant tissues become tumorigenic when they are no longer anchorage dependent for growth. In addition, acquisition of infinite growth potential in heteropioid cell lines is not in itself sufficient to confer tumorigenic capacity on the cells. These results suggest that the degree of cell growth in methyl cellulose is a useful parameter in vitro for predicting tumorigenicity in the animal, and also demonstrate the potential usefulness of the nude mouse for analysis of cellular malignancy irrespective of the tissue or species of origin.     

Transformed growth phenotype of mouse mammary epithelium in primary culture induced by specific fetal mesenchymes.

When mesenchyme from fetal mammary or salivary gland is implanted into adult mouse mammary gland, adjacent epithelium responds with intense hyperplasia. The hyperplastic cells are more vulnerable than are non-stimulated cells to transformation in vivo by a chemical carcinogen or by mammary tumor virus. This system provides a potentially useful model for determining how stroma contributes to mammary tumorigenesis. We have developed co-culture systems and used them to investigate in more detail the nature of the signal produced by the mesenchyme cells. Monolayers of mesenchyme cells were prepared on tissue-culture wells. The mesenchyme cells were trapped on the surface by a thin overlay of agarose. Primary mammary epithelial cells were cultured atop this barrier layer, either as organoids in collagen gels for assessment of anchorage-dependent growth, or as single-cell dispersions in soft agarose for assessment of anchorage-independent growth. Our procedures for assay of anchorage-independent growth allow us for the first time to detect and measure this transformation-defining characteristic in non-immortalized mammary epithelial cells in primary culture. Fetal mammary fat pad precursor tissue and fetal salivary mesenchyme both stimulated anchorage-dependent growth of mammary epithelium, with cell number increasing as much as fifteenfold during a 6-day culture period. These same fetal tissues also stimulated anchorage-independent growth of the mammary epithelial cells, with colony-forming efficiencies of up to 40% in co-cultures with salivary mesenchyme. No colonies formed in the absence of mesenchyme. Cells of colonies contained keratin, which indicates that the colonies grew from epithelial cells and not from a contaminant of another cell type. When co-cultured epithelial cells were subsequently re-cultured in the absence of mesenchyme, they lost their ability to grow independent of anchorage. No colonies grew in co-cultures with fetal cells from heart, kidney, or lung, which is consistent with the lack of stimulation by these tissues in the mammary gland in vivo. A tumor promoter, 12-O-tetradecanoylphorbol acetate (TPA), also caused anchorage-independent growth of the dispersed mammary epithelial cells. Culture medium conditioned by primary or early-passage salivary mesenchyme cells was capable of stimulating growth under both anchorage-dependent and anchorage-independent conditions, confirming that these effects are mediated by a paracrine factor. The results indicate that stimulatory fetal mesenchymes produce soluble molecules that act analogously to transforming growth factors.     

Processing of Human Reduction Mammoplasty and Mastectomy Tissues for Cell Culture

Experimental examination of normal human mammary epithelial cell (HMEC) behavior, and how normal cells acquire abnormal properties, can be facilitated by in vitro culture systems that more accurately model in vivo biology. The use of human derived material for studying cellular differentiation, aging, senescence, and immortalization is particularly advantageous given the many significant molecular differences in these properties between human and commonly utilized rodent cells^1-2. Mammary cells present a convenient model system because large quantities of normal and abnormal tissues are available due to the frequency of reduction mammoplasty and mastectomy surgeries.The mammary gland consists of a complex admixture of many distinct cell types, e.g., epithelial, adipose, mesenchymal, endothelial. The epithelial cells are responsible for the differentiated mammary function of lactation, and are also the origin of the vast majority of human breast cancers. We have developed methods to process mammary gland surgical discard tissues into pure epithelial components as well as mesenchymal cells³. The processed material can be stored frozen indefinitely, or initiated into primary culture. Surgical discard material is transported to the laboratory and manually dissected to enrich for epithelial containing tissue. Subsequent digestion of the dissected tissue using collagenase and hyaluronidase strips stromal material from the epithelia at the basement membrane. The resulting small pieces of the epithelial tree (organoids) can be separated from the digested stroma by sequential filtration on membranes of fixed pore size. Depending upon pore size, fractions can be obtained consisting of larger ductal/alveolar pieces, smaller alveolar clusters, or stromal cells. We have observed superior growth when cultures are initiated as organoids rather than as dissociated single cells. Placement of organoids in culture using low-stress inducing media supports long-term growth of normal HMEC with markers of multiple lineage types (myoepithelial, luminal, progenitor)^4-5. Sufficient numbers of cells can be obtained from one individual''s tissue to allow extensive experimental examination using standardized cell batches, as well as interrogation using high throughput modalities.Cultured HMEC have been employed in a wide variety of studies examining the normal processes governing growth, differentiation, aging, and senescence, and how these normal processes are altered during immortal and malignant transformation^4-15,16. The effects of growth in the presence of extracellular matrix material, other cell types, and/or 3D culture can be compared with growth on plastic^5,15. Cultured HMEC, starting with normal cells, provide an experimentally tractable system to examine factors that may propel or prevent human aging and carcinogenesis.     

Cytokeratin profile of immunomagnetically separated epithelial subsets of the human mammary gland

Summary We have used enzymatic and immunomagnetic techniques for the physical separation of the basal and luminal epithelium of the human mammary gland. Immediately after tissue dissociation and cell sorting, we have examined the steady-state CK composition of these cells individually by direct two-dimensional gel electrophoresis of intermediate filament extracts. Our results demonstrate that cytokeratins typical of simple and stratified epithelial cells are simultaneously expressed by both mammary epithelial subclasses in vivo. Moreover, the entire spectrum of cytokeratins seen in vivo is also maintained in short-term cultures of human mammary epithelium. A comparison of the data obtained by direct cytokeratin analysis with published indirect immunolocalization studies is presented. The ability to isolate purified epithelial subsets from normal human breast tissue by a simple immunomagnetic procedure demonstrated here can facilitate the development of relevant model systems for studying the regulatory components in growth, differentiation and malignant transformation of the human breast.     

Differential transformation of mammary epithelial cells by Wnt genes.

The mouse Wnt family includes at least 10 genes that encode structurally related secreted glycoproteins. Wnt-1 and Wnt-3 were originally identified as oncogenes activated by the insertion of mouse mammary tumor virus in virus-induced mammary adenocarcinomas, although they are not expressed in the normal mammary gland. However, five other Wnt genes are differentially expressed during development of adult mammary tissue, suggesting that they may play distinct roles in various phases of mammary gland growth and development. Induction of transformation by Wnt-1 and Wnt-3 may be due to interference with these normal regulatory events; however, there is no direct evidence for this hypothesis. We have tested Wnt family members for the ability to induce transformation of cultured mammary cells. The results demonstrate that the Wnt gene family can be divided into three groups depending on their ability to induce morphological transformation and altered growth characteristics of the C57MG mammary epithelial cell line. Wnt-1, Wnt-3A, and Wnt-7A were highly transforming and induced colonies which formed and shed balls of cells. Wnt-2, Wnt-5B, and Wnt-7B also induced transformation but with a lower frequency and an apparent decrease in saturation density. In contrast, Wnt-6 and two other family members which are normally expressed in C57MG cells, Wnt-4 and Wnt-5A, failed to induce transformation. These data demonstrate that the Wnt genes have distinct effects on cell growth and should not be regarded as functionally equivalent.     

Developmental Changes in the in Vitro Activated Regenerative Activity of Primitive Mammary Epithelial Cells

Many normal adult tissues contain rare stem cells with extensive self-maintaining regenerative potential. During development, the stem cells of the hematopoietic and neural systems undergo intrinsically specified changes in their self-renewal potential. In the mouse, mammary stem cells with transplantable regenerative activity are first detectable a few days before birth. They share some phenotypic properties with their adult counterparts but are enriched in a subpopulation that displays a distinct gene expression profile. Here we show that fetal mammary epithelial cells have a greater direct and inducible growth potential than their adult counterparts. The latter feature is revealed in a novel culture system that enables large numbers of in vitro clonogenic progenitors as well as mammary stem cells with serially transplantable activity to be produced within 7 days from single fetal or adult input cells. We further show that these responses are highly dependent on novel factors produced by fibroblasts. These findings provide new avenues for elucidating mechanisms that regulate normal mammary epithelial stem cell properties at the single-cell level, how these change during development, and how their perturbation may contribute to transformation.     

Embryonic Stem Cells Are Redirected to Non-Tumorigenic Epithelial Cell Fate by Interaction with the Mammary Microenvironment

Experiments were conducted to redirect mouse Embryonic Stem (ES) cells from a tumorigenic phenotype to a normal mammary epithelial phenotype in vivo. Mixing LacZ-labeled ES cells with normal mouse mammary epithelial cells at ratios of 1∶5 and 1∶50 in phosphate buffered saline and immediately inoculating them into epithelium-divested mammary fat pads of immune-compromised mice accomplished this. Our results indicate that tumorigenesis occurs only when normal mammary ductal growth is not achieved in the inoculated fat pads. When normal mammary gland growth occurs, we find ES cells (LacZ+) progeny interspersed with normal mammary cell progeny in the mammary epithelial structures. We demonstrate that these progeny, marked by LacZ expression, differentiate into multiple epithelial subtypes including steroid receptor positive luminal cells and myoepithelial cells indicating that the ES cells are capable of epithelial multipotency in this context but do not form teratomas. In addition, in secondary transplants, ES cell progeny proliferate, contribute apparently normal mammary progeny, maintain their multipotency and do not produce teratomas.     

Glycosaminoglycan accumulation by normal and malignant human mammary epithelial cells in primary culture

The effects of glycosaminoglycans (GAGs) on cell growth and differentiation appear to vary with cell type and stage of development. This study describes the types and distribution of GAGs accumulated by normal and malignant human mammary epithelial cells in primary culture during their exponential and stationary phases of growth. Cultures incubated with [3H]glucosamine or [35S]sulfate were separated into medium, extracellular matrix (ECM), and cell fractions. Labelled GAGs were identified by chemical and enzymatic degradations and cellulose acetate electrophoresis. Cultures of normal cells in the exponential phase of growth released the most labelled GAGs into the medium fraction, the majority of which was hyaluronic acid (HA). The increase in labelled GAG accumulation, the increase in sulfated GAGs localized in the ECM fraction correlated with the reduced proliferative activity and increased cell density of cells in stationary cultures. In contrast, cultures of mammary tumour cells had the same labelled GAG profile, regardless of their growth status. Although there was variation among tumours, in general, the majority of the labelled GAGs were secreted into the medium fraction and the predominant GAG was HA. The results are comparable with those obtained from studies on mammary tissue in vivo. Primary cultures of human mammary epithelial cells should be useful for determining how modulations of GAGs affect growth and differentiation of these cells.     

Proteomic evaluation of sheep serum proteins

Background

Mammary tumours frequently develop in female domestic cats being highly malignant in a large percentage of cases. Chemokines regulate many physiological and pathological processes including organogenesis, chemotaxis of inflammatory cells, as well as tumour progression and metastasization. In particular, the chemokine/receptor pair SDF-1/CXCR4 has been involved in the regulation of metastatic potential of neoplastic cells, including breast cancer. The aim of this study was the immunohistochemical defininition of the expression profile of CXCR4 in primary and metastatic feline mammary carcinomas and the evaluation of the role of SDF-1 in feline mammary tumour cell proliferation.

Results

A total of 45 mammary surgical samples, including 33 primary tumours (31 carcinomas and 2 adenomas), 6 metastases, and 4 normal mammary tissues were anlyzed. Tumor samples were collected from a total number of 26 animals, as in some cases concurrent occurrence of neoplasm in more than one mammary gland was observed. Tissues were processed for standard histological examination, and all lesions were classified according to the World Health Organization criteria. CXCR4 expression in neoplastic cells was evaluated by immunohistochemistry. The level of CXCR4 immunoreactivity was semi-quantitatively estimated as CXCR4 score evaluating both the number of positive cells and the intensity of staining. Six primary, fibroblast-free primary cultures were obtained from fresh feline mammary carcinomas and characterized by immunofluorescence for CXCR4 and malignant mammary cell marker expression. SDF-1-dependent in vitro proliferative effects were also assayed. CXCR4 expression was observed in 29 out of 31 malignant tissues with a higher CXCR4 score observed in 4 out of 6 metastatic lesions than in the respective primary tumours. In 2 benign lesions analyzed, only the single basaloid adenoma showed a mild positive immunostaining against CXCR4. Normal tissue did not show CXCR4 immunoreactivity. CXCR4 score was statistically significantly associated with the histological features of the samples, showing an increase accordingly with the degree of neoplastic transformation (from normal tissue to metastatic lesions). Finally, in the primary cultures obtained from 6 primary feline mammary carcinomas CXCR4 expression was detected in all cells and its activation by SDF-1 in vitro treatment caused a significant increase in the proliferation rate in 5 out of 6 tumours.

Conclusions

These results indicate that malignant feline mammary tumours commonly express CXCR4, with a higher level in malignant tumours, and, in most of the cases analysed, metastatic cells display stronger immunoreactivity for CXCR4 than the corresponding primary tumours. Moreover, CXCR4 activation in primary cultures of feline mammary carcinomas causes increase in the proliferative rate. Thus, SDF-1/CXCR4 system seems to play a tumorigenic in feline mammary gland malignancy and in vitro cultures from these tumour samples may represent an experimental model to investigate the biological and pharmacological role of this chemokinergic axis.     

Dormant Wnt-initiated mammary cancer can participate in reconstituting functional mammary glands

The minimal residual disease foci that beget breast cancer relapse after a period of disease dormancy remain uncharacterized despite their enormous clinical importance. To model dormant breast cancer in vivo, we employed a transgenic mouse model in which Wnt1-initiated mammary cancer is doxycycline dependent. After regression of Wnt-dependent cancers, subclinical disease lesions were propagated in vivo using classical tissue recombination techniques. Surprisingly, outgrowths derived from dormant malignant tissue reconstituted morphologically normal ductal trees in wild-type mammary fat pads. Whereas hyperplasia-derived outgrowths remained benign, outgrowths derived from dormant malignancy underwent a morphological transition suggesting single-step transformation following reactivation of Wnt signaling and rapidly yielded invasive mammary tumors. Remarkably, outgrowths derived from dormant malignancy could be serially propagated in vivo and retained the potential to undergo lobuloalveolar differentiation in response to hormones of pregnancy. Matching somatic H-Ras mutations shared by antecedent tumors and descendant mammary ductal outgrowths confirmed their clonal relatedness. Thus, propagation of epithelium that possesses a latent malignant growth program reveals impressive regenerative and developmental potential, supporting the notion that dormant mammary cancers harbor transformed mammary progenitor cells. Our results define an experimental paradigm for elucidating biological properties of dormant malignancy.     

Aerobic lactate production by mammary tissue.

Glucose uptake and L-lactate production were measured in cell, slice and intact tissue preparations of mammary glands from late-pregnant and lactating rats. The tissues showed extensive conversion of glucose into lactate in vitro, but not in vivo. Therefore aerobic lactate formation is not a normal feature of mammary tissue, but occurs in vitro as the result of some metabolic derangement.     

Effect of hormones on growth rates of malignant and nonmalignant human mammary epithelia in cell culture

Summary The individual effects of seven hormones on the in vitro growth rate of different classifications of human mammary epithelium were compared. Hormones used were: 17β-estradiol, estriol, progesterone, hydrocortisone, testosterone, prolactin, and growth hormone. Cell cultures included three established breast cell lines and primary monolayer cultures established form breast fluids and excised mammary tissue from 40 women and 4 men. Specimens comprised three classifications: normal, nonmalignant atypical, and malignant. Growth was quantitated in situ and expressed as population doubling time. Principal findings were: (a) estrogens, prolactin, and growth hormone stimulated growth of normal cells more frequently than growth of malignant cells, whereas testosterone and hydrocortisone stimulated growth of malignant cells more frequently than growth of normal cells; (b) cells cultured from nonmalignant atypias generally showed hormone response profiles intermediate between those of normal and malignant cells; (c) progesterone stimulated the growth of cells from malignant specimens but not the growth of cells from normal and nonmalignant atypical samples. This research was supported by NIAID Research Training Grant 5-TO1-A1-00332-06.     

Haymaker gene expression in malignant and normal gynecologic tissues.

We previously reported that cell lines established from human carcinomas and leukemias/lymphomas expressed high levels of an intracellular membrane-bound protein, Haymaker, whereas cell lines derived from non-malignant connective tissue cells and lymphoid cells expressed low levels of this gene product. To determine whether these findings reflect neoplastic transformation or, alternatively, tissue specificity, we examined by immunohistochemical and molecular methods the expression of Haymaker in gynecologic organs with and without tumor. A highly specific, affinity-purified rabbit polyclonal antibody against a 25-mer Haymaker peptide was used for immunohistochemical staining and morphometric analysis of 85 tissue specimens. Immunohistochemical studies demonstrate, for the first time, that Haymaker protein is highly expressed in epithelial cells of the endometrium of the normal uterus and to a somewhat lesser extent in the mucosa of the normal vagina and cervix, but is poorly expressed or absent in cells of the connective tissue and smooth muscle strata of these organs (p < 0.005). Significant differences in Haymaker expression, as assessed by immunohistochemistry, between malignant and normal gynecologic tissues were not observed (p = 0.27). The expression of Haymaker protein does not appear, therefore, to be a marker of malignant transformation of the epithelium of gynecologic organs but rather distinguishes both normal and malignant epithelial cells from normal connective tissue and smooth muscle cells.     

Reconstruction of human mammary tissues in a mouse model

Establishing a model system that more accurately recapitulates both normal and neoplastic breast epithelial development in rodents is central to studying human breast carcinogenesis. However, the inability of human breast epithelial cells to colonize mouse mammary fat pads is problematic. Considering that the human breast is a more fibrous tissue than is the adipose-rich stroma of the murine mammary gland, our group sought to bypass the effects of the rodent microenvironment through incorporation of human stromal fibroblasts. We have been successful in reproducibly recreating functionally normal breast tissues from reduction mammoplasty tissues, in what we term the human-in-mouse (HIM) model. Here we describe our relatively simple and inexpensive techniques for generating this orthotopic xenograft model. Whether the model is to be applied for understanding normal human breast development or tumorigenesis, investigators with minimal animal surgery skills, basic cell culture techniques and access to human breast tissue will be able to generate humanized mouse glands within 3 months. Clearing the mouse of its endogenous epithelium with subsequent stromal humanization takes 1 month. The subsequent implantation of co-mixed human epithelial cells and stromal cells occurs 2 weeks after humanization, so investigators should expect to observe the desired outgrowths 2 months afterward. As a whole, this model system has the potential to improve the understanding of crosstalk between tissue stroma and the epithelium as well as factors involved in breast stem cell biology tumor initiation and progression.     

Targeting of tumor cells by low density lipoproteins: principle and use of ellipticin derivatives]

Cells acquire cholesterol via de novo synthesis and high affinity receptor-mediated uptake of low-density lipoprotein (LDL). Some tumor tissues display increased receptor-mediated uptake of LDL as compared with the corresponding normal tissues. This increased LDL receptor activity is unexplained: a high cholesterol demand for cell growth or a mechanism directly linked to cell transformation. LDL has therefore been proposed as a potential carrier for chemotherapeutic agents. Various methods have been used to incorporate antineoplastic lipophilic drugs into LDL. The resultant drug-LDL complexes have been shown to be cytotoxic towards tumor cells in vitro, via the LDL receptor dependent pathway. However little is now on the in vivo fate of this complex. We described the incorporation of lipophilic derivatives of ellipticine into LDL by a fusion or facilitated transfer technique between drug containing microemulsions and LDL. The drug-LDL complex expressed similar metabolic activity, in vitro and in vivo, than native LDL. Initial experiments with melanoma B16 tumor-bearing mice suggest that LDL may be a potential drug carrier in the treatment of malignant diseases. The knowledge of the molecular mechanism of the expression of the LDL receptor in tumor cells and the ability to downregulate the LDL receptor in the normal tissues, will define the application field of this targeting approach.     

Electrophysiological study of coupling between cultured cells of the mouse mammary gland in five distinct physiological states.

Electrical coupling has been observed between cultured cells of the mouse mammary gland in five distinct physiological or pathological states. We have employed young primary cultures of cells dissociated from the following tissues: normal glands from young virgin or midpregnant females, hyperplastic alveolar nodules (believed to be precancerous) transplanted in gland-free mammary fat pads, and spontaneous mammary adenocarcinomas and their pulmonary metastases. All successfully impaled pairs of cells (a total of 97 pairs) were found to be ionically coupled. Furthermore, in normal and tumor cell cultures, electrical coupling was observed between dome-dome and dome-nondome cell pairs. This study correlates with electronmicroscopic studies of fresh normal, hyperplastic, and tumor samples, which show the presence of gap junctions in all three.