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.     

Acetylcholinesterase in normal and malignant human cells

Acetylcholinesterase (AChE) activity was determined in normal and malignant human cell lines by histochemical methods. In normal human fibroblasts, no AChE activity could be demonstrated by any histochemical technique or substrate. Enzymic activity was observed in HT-1080 human fibrosarcoma cells, RD 2 human rhabdomyosarcoma cells, and SW 311 human colon carcinoma cells. Activity was localized around the nuclear envelope, in the cytoplasm and associated with the cortical region of most cells. The specificity of the reaction was shown through the use of specific cholinesterase inhibitors.     

Three-dimensional culture models of normal and malignant breast epithelial cells

Extracellular matrix is a key regulator of normal homeostasis and tissue phenotype. Important signals are lost when cells are cultured ex vivo on two-dimensional plastic substrata. Many of these crucial microenvironmental cues may be restored using three-dimensional (3D) cultures of laminin-rich extracellular matrix (lrECM). These 3D culture assays allow phenotypic discrimination between nonmalignant and malignant mammary cells, as the former grown in a 3D context form polarized, growth-arrested acinus-like colonies whereas the latter form disorganized, proliferative and nonpolar colonies. Signaling pathways that function in parallel in cells cultured on plastic become reciprocally integrated when the cells are exposed to basement membrane-like gels. Appropriate 3D culture thus provides a more physiologically relevant approach to the analysis of gene function and cell phenotype ex vivo. We describe here a robust and generalized method for the culturing of various human breast cell lines in three dimensions and describe the preparation of cellular extracts from these cultures for molecular analyses. The procedure below describes the 3D 'embedded' assay, in which cells are cultured embedded in an lrECM gel (Fig. 1). By lrECM, we refer to the solubilized extract derived from the Engelbreth-Holm-Swarm mouse sarcoma cells. For a discussion of user options regarding 3D matrices, see Box 1. Alternatively, the 3D 'on-top' assay, in which cells are cultured on top of a thin lrECM gel overlaid with a dilute solution of lrECM, may be used as described in Box 2 (Fig. 1 and Fig. 2).     

Long-term culture of normal human colonic epithelial cells in vitro.

Studies of normal cellular function as well as the understanding of cellular mechanisms of carcinogenesis and other diseases of the large intestine have been limited, particularly due to the lack of long-term culture of normal human large intestinal epithelial cells (NHLIEC). Using the epithelia from surgically resected human colon, we have dissociated a sufficient number of viable NHLIEC and maintained them in in vitro culture for up to 5 months. Normal-appearing human large intestinal mucosal fragments (1 mm2) were treated with 0.01 mg/ml trypsin, 0.2 mg/ml collagenase + 0.1 mM EGTA or 0.1 mg/ml trypsin + 0.1 mM EGTA in a Stomacher laboratory blender to isolate the cells. Compared with other methods, the use of the Stomacher blender combined with low concentrations of proteolytic enzymes yielded greater numbers of cells per gram of tissue, with up to 84% viable cells. Primary and serially passaged NHLIEC were cultured in CMRL-1066, MEM with 5% serum, and serum-free KGM. These media were all supplemented with insulin, hydrocortisone, epithelial growth factor, and bovine pituitary extract. CMRL-1066 was found to be the best medium for NHLIEC. Contaminating fibroblasts were selectively removed by briefly allowing the cells to adhere to the culture vessel and adding 25 U/ml collagenase to the culture media at the first subculture treatment. The epithelial nature and secretory function of the established cells were confirmed by morphological criteria (light microscopy, phase contrast microscopy and electron microscopy), immunoreactivity to cytokeratin, and positive mucin cytochemistry. We propose that using this methodology for the culture and maintenance of NHLIEC for an extended period of time would serve as a valuable model for a variety of investigations.     

A comparative study of glycosaminoglycans in cultures of human, normal and malignant glial cells.

The glycosaminoglycans (GAG) of human cultured normal glial and malignant glioma cell lines were studied using 35S-sulphate or 3H-glucosamine as markers. 35S-labelled GAG were assayed by precipitation with cetylpyridinium chloride; 3H-labelled sulphated GAG and 3H-labelled hyaluronic acid were quantitated after separation on a DEAE-cellulos column. The net production of GAG and the distribution, composition and turnover of GAG were similar in all of the normal cell lines tested, but showed a great variability in the malignant cell lines. Most of the glioma cell lines produced more hyaluronic acid and less sulphated GAG than the normal cell lines, but exceptions were noted. The GAG of the trypsin susceptible (pericellular pool of normal glial cells consisted mainly of heparan sulphate with only minor amounts of other GAG. The analogous material of most glioma cells showed hyaluronic acid as the major GAG. Material liberated by trypsin from EDTA-detached cells (membrane fraction) was enriched in heparan sulphate as compared to the entire pericellular pool. Substrate attached material (SAM) left with the plastic dish after EDTA treatment of normal cultures was rich in heparan sulphate, whereas SAM of glioma cells lacked heparan sulphate or showed greatly reduced amounts of this component. Release of newly synthesized GAG to the extracellular medium was a rapid process in the normal cells but was more or less delayed in the glioma cells. The extracellular medium of the malignant glioma cultures was consistently poor in dermatan sulphate, as compared to that of normal cultures.     

Proliferation control in cloned normal and malignant human cells

A method for cloning of a variety of normal and malignant human cells in culture is described. Palladium is precipitated on agarose through masks prefabricated by a photolithographic technique. Practically any pattern can be produced where cells exclusively settle and multiply as ‘miniclones’ on the metal ‘islands’. This communication establishes

1. 1. that ‘miniclones’ settle and multiply with the same efficiency as cells of a mass population, thus constituting an unbiased cell sample

2. 2. that certain malignant lines cannot be studied with the unmodified technique suitable for normal glia-like cells because of excessive translocation between islands

3. 3. that this can be circumvented by the interposition of a thin agar overlay between the cells and the fluid medium. Proliferation of normal glia-like cells was inhibited on palladium islands in a cell density-dependent way. On sufficiently small islands even single cells could be prevented from dividing. Circles of about 3 000 μm² prevented multiplication of about 50% of single cells otherwise capable of division, suggesting that cell-to-cell contacts may not be necessary for proliferation inhibition of normal cells.

     

Radiosensitivity of normal human epidermal cells in culture

Using an in vitro culture system we have derived radiation survival curves for the clonogenic cells of normal human epidermis. The culture system used allows the epidermal cells to stratify and form a multi-layered sheet of keratinizing cells. The cultures appear to be a very good model for epidermis in vivo. The survival curves show a population which is apparently more sensitive than murine epidermis in vivo. It remains unclear whether this is an intrinsic difference between the species or is a consequence of the in vitro cultivation of the human cells.     

Growth of normal human mammary cells in culture

Summary Reduction mammoplasty tissue was used to obtain short-term cultures of human epithelial cell populations. Digestion of tissue with collagenase and hyaluronidase resulted in cell clusters (organoids) resembling ductal and alveolar structures; these could be separated by filtration from the stromal components. Epithelial outgrowth from these organoids was greatly enhanced by the addition of conditioned medium from other human epithelial and myoepithelial cell lines. Additionally, the mammary epithelial growth was stimulated by insulin, hydrocortisone, epidermal growth factor, and steroid hormones. With this enriched nutritional environment, active cell division could be maintained for 1 to 3 months and cells could be serially subcultured 1 to 4 times. This research was supported by Grant PDT-72 from the American Cancer Society and Grant CP-70510 from the National Institutes of Health.     

Absence of fibronectin and presence of plasminogen activator in both normal and malignant human mammary epithelial cells in culture

Primary monolayer cultures of normal and malignant human mammary epithelial cells were tested for fibronectin by indirect immunofluorescence using antisera specific for fibronectin. This protein was not detectable on either the normal or malignant epithelial cells. Similar results were obtained for normal and malignant mouse mammary epithelial cell cultures. Control normal and transformed fibroblasts exhibited the expected result: the normal cells were positive and the transformed cells were negative. With the use of supernatant fluids from the same cultures or an agar-overlay assay on viable cells, high levels of plasminogen-dependent fibrinolytic activity were detectable in both the normal and malignant mammary cells. Thus, two characteristics that distinguish normal from transformed fibroblasts do not serve as markers of malignancy in mammary epithelial/carcinoma systems.     

Differentiation of cultured human keratinocytes: Effect of culture conditions on lipid composition of normal vs. malignant cells

Summary Differentiation in keratinocytes can be experimentally modulated by changing the culture conditions. When cultured under conventional, submerged conditions, the extent of cellular differentiation is reduced in the presence of low calcium medium and is enhanced in medium containing physiologic calcium concentrations. Moreover cultures grown at the air-medium interface or on a dermal substrate, or both, differentiate even further. Herein we report the effect of culture conditions on lipid composition in normal human keratinocytes and three squamous carcinoma cell (SCC) lines that vary in their capacity to differentiate as assessed by cornified envelope formation. Under submerged conditions, the total phospholipid content was lower, triglyceride content higher, and phospholipid: neutral lipid ratio lower in direct correlation to the degree of differentiation in these cultures. When grown at the air-medium interface on the-epidermized dermis, evidence of further morphologic differentiation was found only for well-differentiated SCC cells and normal keratinocytes. Similarly, the phospholipid content remained high in poorly differentiated SCC cells and it, decreased modestly in well-differentiated SCC cells and markedly in normal keratinocytes. In all cell lines the triglyceride content was increased and cholesterol content decreased when compared to parallel submerged cultures, but these differences were most pronounced in well-differentiated cell lines. Acylceramides and acylglucosylceramides were found only in normal keratinocytes and only under the most differentiation-enhancing conditions. These studies demonstrate differentiation-related changes in the lipid content of both normal and neoplastic keratinocytes. This work was supported in part by NATO Scientific Award (RG 8510056).     

Expression of PDE11A in normal and malignant human tissues.

Cyclic nucleotide phosphodiesterase 11A (PDE11A) is the newest member in the PDE family. Although the tissue distribution of PDE11A mRNA has been shown, its protein expression pattern has not been well studied. The goal of this report is to investigate the distribution of PDE11A proteins in a wide range of normal and malignant human tissues. We utilized a polyclonal antibody that recognized all four PDE11A isoforms. Its specificity was demonstrated by Western blot analysis on a recombinant human PDE11A protein and native PDE11A proteins in various human tissues. Immunohistochemistry showed that PDE11A is widely expressed. Various degrees of immunoreactivity were observed in the epithelial cells, endothelial cells, and smooth muscle cells of all tissues examined. The highest expression was in the epithelial, endothelial, and smooth muscle cells of the prostate, Leydig, and spermatogenic cells of the testis, the tubule epithelial cells in the kidney, the epithelial and endothelial cells in the adrenal, the epithelial cells and macrophages in the colon, and the epidermis in the skin. Furthermore, PDE11A expression was also detected in several human carcinomas. Our results suggest that PDE11A might be involved in multiple physiological processes in various organs via its ability to modulate intracellular cAMP and cGMP levels.     

The surface morphology of normal and malignant rat liver epithelial cells in culture

Summary A direct comparison has been made between normal parenchymal cells cultured from rat liver and malignant cells from both a rat liver tumor and a spontaneously transformed line derived from the parent rat culture. In all nondividing cells there was a 3- to 5-fold increase in the population of surface microvilli on the malignant cells compared to the normal cells. Notable variations in overall morphology were also observed when cells were incubated in arginine-deficient medium. During the course of this work T. D. Allen and P. T. Iype were supported by grants from the Medical Research Council and Cancer Research Campaign, and M. J. Murphy, Jr. was supported by a Special Fellowship of the Leukemia Society of America, Inc. and the Jean Shaland Fund.     

Comparative analysis of the synchronization methods of normal and transformed human cells

Reactions of genetically identical cells to various exogenous and endogenous stimuli can vary significantly. One of the main factors of this non-genetic cellular heterogeneity is the cell cycle. The most convenient way to study the subcellular processes depending on the cell cycle stage is the synchronization of the cells. Toxic inhibitors of DNA replication and/or mitotic spindle assembly are typically used to synchronize cells. It is important to accurately select the synchronization method for a particular experiment. In this study, we performed a comparative analysis of the synchronization methods of normal and transformed human cells, paying special attention to the accuracy of synchronization and toxicity of the methods used.     

Composition and distribution of glycosaminoglycans in cultures of human normal and malignant glial cells.

The glycosaminoglycans of human cultured normal glial and malignant glioma cells were studied. [35S]Sulphate or [3H]glucosamine added to the culture medium was incorporated into glycosaminoglycans; labelled glycosaminoglycans were isolated by DEAE-cellulose chromatography or gel chromatography. A simple procedure was developed for measurement of individual sulphated glycosaminoglycans in cell-culture fluids. In normal cultures the glycosaminoglycans of the pericellular pool (trypsin-susceptible material), the membrane fraction (trypsin-susceptible material of EDTA-detached cells) and the substrate-attached material consisted mainly of heparan sulphate. The intra- and extra-cellular pools showed a predominance of dermatan sulphate. The net production of hyaluronic acid was low. The accumulation of 35S-labelled glycosaminoglycans in the extracellular pool was essentially linear with time up to 72h. The malignant glioma cells differed in most aspects tested. The total production of glycosaminoglycans was much greater owing to a high production of hyaluronic acid and hyaluronic acid was the major cell-surface-associated glycosaminoglycan in these cultures. Among the sulphated glycosaminoglycans chondroitin sulphate, rather than heparan sulphate, was the predominant species of the pericellular pool. This was also true for the membrane fraction and substrate-attached material. Furthermore, the accumulation of extracellular 35S-labelled glycosaminoglycans was initially delayed for several hours and did not become linear with time until after 24 h of incubation. The glioma cells produced little dermatan sulphate and the dermatan sulphate chains differed from those of normal cultures with respect to the distribution of iduronic acid residues. The observed differences between normal glial and malignant glioma cells were not dependent on cell density; rather they were due to the malignant transformation itself.     

Differences in cholesterol transport by normal and malignant human kidney cells

Cholesterol uptake and release was measured in normal and malignant human kidney cells in culture. The time course and level of cholesterol uptake was the same in both normal and malignant cells and there was no accumulation of cholesterol. However, the time course of cholesterol release was strikingly different in normal $\text{versus}$ malignant cells. Release of cholesterol by normal cells plateaued early; whereas release by malignant cells continued at a linear rate. The results suggest that malignant cells lack either a competent mechanism for regulation of cholesterol synthesis or lack a mechanism for regulation of cholesterol efflux, thus leading to deregulation of cholesterol synthesis.     

Predominant nuclear localization of mammalian target of rapamycin in normal and malignant cells in culture

Mammalian target of rapamycin (mTOR) controls initiation of translation through regulation of ribosomal p70S6 kinase (S6K1) and eukaryotic translation initiation factor-4E (eIF4E) binding protein (4E-BP). mTOR is considered to be located predominantly in cytosolic or membrane fractions and may shuttle between the cytoplasm and nucleus. In most previous studies a single cell line, E1A-immortalized human embryonic kidney cells (HEK293), has been used. Here we show that in human malignant cell lines, human fibroblasts, and murine myoblasts mTOR is predominantly nuclear. In contrast, mTOR is largely excluded from the nucleus in HEK293 cells. Hybrids between HEK293 and Rh30 rhabdomyosarcoma cells generated cells co-expressing markers unique to HEK293 (E1A) and Rh30 (MyoD). mTOR distribution was mainly nuclear with detectable levels in the cytoplasm. mTOR isolated from Rh30 nuclei phosphorylated recombinant GST-4E-BP1 (Thr-46) in vitro and thus has kinase activity. We next investigated the cellular distribution of mTOR substrates 4E-BP, S6K1, and eIF4E. 4E-BP was exclusively detected in cytoplasmic fractions in all cell lines. S6K1 was localized in the cytoplasm in colon carcinoma, HEK293 cells, and IMR90 fibroblasts. S6K1 was readily detected in all cellular fractions derived from rhabdomyosarcoma cells. eIF4E was detected in all fractions derived from rhabdomyosarcoma cells but was not detectable in nuclear fractions from colon carcinoma HEK293 or IMR90 cells.