Histological and histochemical studies on the distribution of a few enzymes in the neoplastic liver of Uroloncha malabarica (Linnaeus)

The present work describes histological and histochemical observations made on the neoplastic liver of Indian silver bills, Uroloncha malabarica. The histology of neoplastic tissue as well as liver has been discussed. Further, a few enzymes like alkaline phosphatase, acid phosphatase, 5-nucleotides and non-specific esterase have been localized in the diseased liver. The occurrence of lymphocytoma caused a marked change in the localization of the enzymes. Sometimes total inhibition of the enzyme was encountered. Damaged sinusoid cells and bile canaliculi of the neoplasm as well as liver lobules show no reaction for alkaline phosphatase. However, its counterpart, acid phosphatase, exhibits intense activity in both neoplastic tissue and liver cells. Aggregates of neoplastic tissue give moderate 5-nucleotidase reaction while it gives poor activity in hepatic tissue of the diseased liver. Parenchymatous cells are able to give some activity for the non-specific esterase while it is very dull in the neoplastic tissue.     

Neoplastic conversion of preneoplastic Syrian hamster cells: rate estimation by fluctuation analysis.

Analysis of the role of gene mutations in the multistep process of neoplastic transformation requires that the discrete steps in carcinogenesis first be dissected. Toward this end, we have isolated and characterized preneoplastic Syrian hamster cells which exhibit in vitro a trait highly correlated with neoplastic conversion in vivo. Previous findings (J. C. Barrett, Cancer Res. 40:91-94, 1980) indicate that spontaneous neoplastic transformation of Syrian hamster cells occurs in at least two steps. An intermediate stage, characterized by an aneuploid established cell line which has a propensity to become neoplastic spontaneously upon further growth in vitro, has been described. These preneoplastic cells differ from diploid early-passage Syrian hamster cells in becoming capable of anchorage-independent growth in semisolid agar, as well as becoming neoplastic in vivo when attached to a solid substrate. Evidence presented here demonstrates that anchorage-independent conversion in vitro is a reliable marker for neoplastic conversion in this cell system. Fluctuation analyses, patterned after those described by Luria and Delbruck for microbial genetics, demonstrate that anchorage-independent variants are generated randomly from clonally derived preneoplastic cells at the rate of 10(-8) to 10(-7) variants per cell per generation. These results establish a multistep stochastic process for transformation in vitro and indicate that conversion to anchorage independence may be necessary for Syrian hamster cells to become tumorigenic. The possible role of gene mutation in this step during neoplastic progression is discussed.     

Epithelial-myoepithelial carcinoma of the parotid. A case of ductal-predominant presentation with cytologic, histologic and ultrastructural correlations

BACKGROUND: The cytologic features of the usual type of epithelial-myoepithelial carcinoma (EMC) of the parotid, with myoepithelial cell predominance, is well described in the cytology literature. In contrast, the cytologic features of ductal-predominant-type EMC has not yet been reported. CASE: An 82-year-old male presented with a 2.7-cm parotid mass of two years' duration. Fine needle aspiration smears stained with Diff-Quik showed cohesive tissue fragments outlined by metachromatic fibrils scattered in abundant, smooth, bluish background material. Ultrafast Papanicolaou stain revealed sharply outlined, large ductal cells with smooth, round to oval nuclei, prominent nucleoli and abundant vacuolated cytoplasm; the cells were arranged tridimensionally in occasional follicles that contained thick secretions. Neoplastic myoepithelial cells were occasionally seen at the periphery of tissue fragments, most commonly hidden underneath the neoplastic ductal epithelium at a slightly different focal plane; the cells had small, oval, dark nuclei and inconspicuous cell borders. The nuclear area and cell size of the neoplastic ductal cells was two and three times, respectively, that of neoplastic myoepithelial cells. CONCLUSION: EMC, depending on the ratio of ductal to myoepithelial cell components, has different cytologic presentations. This case illustrates the ductal-predominant presentation of EMC.     

Interaction of serum and cell spreading affects the growth of neoplastic and non-neoplastic fibroblasts

Both growth factor availability and cell-to-cell contact have been mechanisms used to explain cell growth regulation at high cell density. Recently Folkman and colleagues have shown that changes in cell shape, rather than cell-to-cell contact, can regulate the growth of fibroblasts. However, in those studies the relation between serum and shape regulation of growth was not studied, nor were neoplastic and non-neoplastic cells compared. In this report we have studied these aspects by varying cell spreading and serum concentration independently for 2 non-neoplastic and 3 neoplastic cell lines. Cell spreading (projected cell area) was controlled by decreasing the adhesiveness of tissue culture plastic plates with poly (hydroxyethyl methacrylate) [poly (HEMA)]. Cell growth was measured as the increase in cell number/day. We have found that more spreading increased net growth of both neoplastic and non-neoplastic cells, while less spreading (toward rounded configuration) depressed growth. There were also quantitative differences between neoplastic and non-neoplastic cells. Neoplastic cells continued to grow under conditions of cell rounding, which completely prevented the growth of their non-neoplastic counterparts. Some neoplastic cells also tended to show little or no increase in net cell number for serum concentrations above 10% as cells became more spread; in contrast, all non-neoplastic cells grew more with increasing concentrations of serum as they became well spread. Thus, in normal cells, it appears that the sensitivity of cells to humoral factors is governed by cell spreading. This interaction between serum and cell shape is less prominent in some neoplastic cells.     

Transforming growth factors and the regulation of cell proliferation

The number of different growth regulatory molecules which have been isolated and characterized is continuing to increase. As more information is obtained, it has become apparent that the cooperative actions of many factors with distinct activities is necessary for appropriate proliferative responses. An interplay of both growth stimulatory and growth inhibitory factors is essential for normal growth. Of crucial importance, therefore, is the appropriate regulation of growth factors. Unregulated expression, synthesis, posttranslational processing or activation of either positive or negative growth signals may contribute to neoplastic transformation (Fig. 3). Altered responses to normally positive or negative signals by transformed cells have been demonstrated by several investigators [64, 79, 84]. While altered growth factor responses in transformed cells are well documented, the mechanisms responsible for the loss of growth control are poorly understood and are likely to be both complex and numerous. Continued efforts to dissect and comprehend fully growth factor action on normal cells will be necessary before an understanding of neoplastic transformation can be achieved.     

Further studies on the radiation-induced expression of a tumor-specific antigen in human cell hybrids

The neoplastic transformation of human cell hybrids (HeLa x skin fibroblasts) is accompanied by the expression of a cell surface protein for which monoclonal antibodies have been raised. The gamma-radiation-induced neoplastic transformation of these cells has been studied where the expression of this cell surface protein, as detected by immunoperoxidase staining, has been used as an end point. The yield of foci of positively staining cells has been shown to increase with increasing time postirradiation at which the assay is done and decrease with increasing density of viable cells plated postirradiation. The time of plating postirradiation is also an important parameter with transformation frequencies increasing over the first 6 h of postirradiation holding at confluence, followed by a gradual decrease.     

Cutting edge: systemic inhibition of angiogenesis underlies resistance to tumors during acute toxoplasmosis

The ability of various infections to suppress neoplastic growth has been well documented. This phenomenon has been traditionally attributed to infection-induced concomitant, cell-mediated antitumor immunity. We found that infection with Toxoplasma gondii effectively blocked neoplastic growth of a nonimmunogenic B16.F10 melanoma. Moreover, this effect was independent of cytotoxic T or NK cells, production of NO by macrophages, or the function of the cytokines IL-12 and TNF-alpha. These findings suggested that antitumor cytotoxicity was not the primary mechanism of resistance. However, infection was accompanied by strong, systemic suppression of angiogenesis, both in a model system and inside the nascent tumor. This suppression resulted in severe hypoxia and avascular necrosis that are incompatible with progressive neoplastic growth. Our results identify the suppression of tumor neovascularization as a novel mechanism critical for infection-induced resistance to tumors.     

The structure and development of a genetic tumour of the pea

Summary The development of the neoplasm of the pea pod has been examined by electron microscopy. The subsidiary cells of the stomata are the site of neoplastic development, and the earliest signs of tumour growth are the accumulation of lipid material in these cells and a decrease in the degree of their vacuolation. Mitosis in these cells gives rise to a population of neoplastic cells similar in structure to normal parenchyma. The only structural abnormality which persists in mature neoplastic tissue is the degeneration of the plastids. The chloroplasts of the original subsidiary cells undergo a continuous series of degenerative changes involving loss of photosynthetic function. The mode of development of the neoplasm and the ultrastructural changes associated with it are discussed in relation to other plant tumours.     

Epstein-Barr virus (EBV) and human hematopoietic cell lines: a review.

Two facts need to be pointed out to help explain why the history of Epstein-Barr virus (EBV) research has been inseparable from that of the studies with human hematopoietic cell lines of neoplastic and non-neoplastic origin. One is that Burkitt lymphoma (BL) cell lines, EBV-positive or-negative, can be established in culture quite easily. Thus, the BL cell lines which Epstein established were indeed some of the first hematopoietic as well as virus-carrying cell lines of human neoplastic origin. The other is that EBV-positive B-cell lymphoblastoid cell lines (B-LCL) of normal origin can be grown from samples of sero-positive individuals. B-LCL were often mistakenly regarded as being of neoplastic origin, but are almost always of normal cell origin. Very rarely, however, B-LCL with the same clonal markers as those of neoplastic cells have also been obtained. While the development of B-LCL has been referred to as the in vitro viral immortalization of human B cells and as a phenomenon representing the potential oncogenicity of EBV, the phenotypic and genotypic differences between B-LCL and EBV-carrying BL cells are obvious, indicating that the development of B-LCL per se does not prove the oncogenic activity of EBV. Two EBV-derived antigens, EBNA2 and latent-infection membrane protein (LMP), which are strongly expressed by B-LCL but not by BL cells, have recently been detected in EBV-positive proliferative B cells in patients with organ transplants, suggesting that the proliferating of B-LCL-like cells may take place as an initial step of the multi-step in vivo oncogenesis of EBV.(ABSTRACT TRUNCATED AT 250 WORDS)     

In search of mammary gland stem cells

Summary The evidence for mammary epithelial stem cells and their phenotypic characteristics in normal and neoplastic development is reviewed. The presence of stem cells in all parts of the mammary parenchyma at all stages of differentiation has been demonstrated by transplantation experiments. The phenotypic characterization of stem cells has been defined by a battery of monospecific antibodies. These studies suggest that a mammary epithelium stem cell compartment exists in the basal layer of the gland as well as in the end bud. Whether these same stem cells are expressed in mammary preneoplasias and neoplasias has not been answered conclusively. Phenotypic markers specific for stem cells and stably expressed in transformed cell populations are needed to follow the fate of stem cells.Dedicated to Professor Stuart Patton on the occassion of his 70th birthday.     

Constitutive Production of Macrophage Colony-Stimulating Factor and Interleukin-6 by Human Ovarian Surface Epithelial Cells

Normal and neoplastic epithelial cells produce growth factors that can affect cells from different lineages. Epithelial ovarian cancers produce M-CSF and IL-6. In the present study, production of these cytokines has been measured in the apparently normal epithelial cells from which epithelial ovarian neoplasms are thought to arise. Epithelial cells from the surface of premenopausal human ovaries were established in short-term cultures. The cells bound anti-cytokeratin antibodies and exhibited characteristic epithelial morphology by light and transmission electron microscopy. M-CSF and IL-6 were detected in supernatants from cultures of these cells, using assays specific for each factor. Cytokine levels were comparable to those in supernatants from ovarian and breast cancer cell lines. M-CSF expression could also be demonstrated by immunohistochemical analysis with specific rabbit heteroantiserum. Thus, M-CSF and IL-6 are produced constitutively by normal as well as by neoplastic ovarian epithelium.     

The tumor microenvironment: a critical determinant of neoplastic evolution

Evolution of neoplastic cells has generally been regarded as a cumulative intrinsic process resulting in altered cell characteristics enabling enhanced growth properties, evasion of apoptotic signals, unlimited replicative potential and gain of properties enabling the ability to thrive in ectopic tissues and in some cases, ability to metastasize. Recently however, the role of the neoplastic microenvironment has become appreciated largely due to the realization that tumors are not merely masses of neoplastic cells, but instead, are complex tissues composed of both a non-cellular (matrix proteins) and a cellular 'diploid' component (tumor-associated fibroblasts, capillary-associated cells and inflammatory cells), in addition to the ever-evolving neoplastic cells. With these realizations, it has become evident that early and persistent inflammatory responses observed in or around many solid tumors, play important roles in establishing an environment suitable for neoplastic progression by providing diverse factors that alter tissue homeostasis. Using cutaneous melanoma and squamous cell carcinoma as tumor models, we review the current literature focussing on inflammatory and tumor-associated fibroblast responses as critical mediators of neoplastic progression for these malignancies.     

Exosomes and immune surveillance of neoplastic lesions: a review

The immune system has been reported to suppress the development and progression of neoplastic lesions; however, the exact mechanisms by which neoplastic lesions and the immune system interact are not well understood. Within the last decade, tiny membrane bound particles, approximately 30-100 nm in diameter, have been observed in the blood and other body fluids. These particles, currently called exosomes, are released from many types of tissues including tumors, and they contain and carry many proteins, and mRNAs and microRNA species. We review here how tumors suppress the immune system, especially by the formation of exosomes. Exosomes released from tumors are carried in part by the vascular system to distant cells, which phagocytose them. Depending on the proteins, mRNAs or microRNAs in the exosomes and the cell type, phagocytosis of exosomes may provide a modulating signal to the cell. In the case of exosomes from tumors, uptake of the exosomes by cells of the immune system has been reported to have three main effects: 1) suppression of the number and activity of natural killer cells, 2) suppression of the activity of T cells and 3) suppression of the number and maturation of mature dendritic cells.     

New insights into the role of extracellular matrix during tumor onset and progression

Recently, a view of the tumor as a functional tissue interconnected with the microenvironment has recently been described. For many years, the stroma has been studied in the context of the malignant lesion, and only rarely has its role been considered before carcinogenic lesions appear. Recent studies have provided evidence that stromal cells and their products can cause the transformation of adjacent cells through transient signaling that leads to the disruption of homeostatic regulation, including control of tissue architecture, adhesion, cell death, and proliferation. It is now well established that tumor progression requires a continually evolving network of interactions between neoplastic cells and extracellular matrix. A relevant step of this process is the remodeling of microenvironment which surrounds tumors leading to the release of ECM-associated growth factors which can then stimulate tumor and/or endothelial cells. Finally, tumor cells reorganizing the extracellular matrix to facilitate communications and escape the homeostatic control exerted by the microenvironment modify response to cytotoxic treatments.     

Stearoyl-CoA desaturase is involved in the control of proliferation, anchorage-independent growth, and survival in human transformed cells

Saturated and monounsaturated fatty acids are the most abundant fatty acid species in mammalian organisms, and their distribution is regulated by stearoyl-CoA desaturase, the enzyme that converts saturated into monounsaturated fatty acids. A positive correlation between high monounsaturated fatty acid levels and neoplastic transformation has been reported, but little is still known about the regulation of stearoyl-CoA desaturase in cell proliferation and apoptosis, as well as in cancer development. Here we report that simian virus 40-transformed human lung fibroblasts bearing a knockdown of human stearoyl-CoA desaturase by stable antisense cDNA transfection (hSCDas cells) showed a considerable reduction in monounsaturated fatty acids, cholesterol, and phospholipid synthesis, compared with empty vector transfected-simian virus 40 cell line (control cells). hSCDas cells also exhibited high cellular levels of saturated free fatty acids and triacylglycerol. Interestingly, stearoyl-CoA desaturase-depleted cells exhibited a dramatic decrease in proliferation rate and abolition of anchorage-independent growth. Prolonged exposure to exogenous oleic acid did not reverse either the slower proliferation or loss of anchorage-independent growth of hSCDas cells, suggesting that endogenous synthesis of monounsaturated fatty acids is essential for rapid cell replication and invasiveness, two hallmarks of neoplastic transformation. Moreover, apoptosis was increased in hSCDas cells in a ceramide-independent manner. Finally, stearoyl-CoA desaturase-deficient cells were more sensitive to palmitic acid-induced apoptosis compared with control cells. Our data suggest that, by globally regulating lipid metabolism, stearoyl-CoA desaturase activity modulates cell proliferation and survival and emphasize the important role of endogenously synthesized monounsaturated fatty acids in sustaining the neoplastic phenotype of transformed cells.     

Iron and neoplasia

Normal and neoplastic cells (like nonpathogenic and pathogenic microorganisms) apparently have similar needs and tolerances for iron, but neoplastic cells (like pathogenic microorganisms) may exhibit altered mechanisms of iron acquisition that permit continued growth in host iron-restricted tissues. Excess iron tends to interfere with host defense against malignant cells (as well as against microbial invaders); severe iron deficiency may likewise be detrimental. Elevated temperature is more toxic towards neoplastic than to normal host cells; it is not yet known whether the site of action of heat might be associated with iron acquisition (as has been demonstrated for gram negative bacteria). Persons or animals with iron overload tend to be at greater risk than normal hosts in the development of neoplasms. Construction of animal models of iron overload, although difficult, is strongly indicated at this time. Based on such models, decisions then can be made about the extent to which (a) nutritional immunity against neoplastic cells is practiced by vertebrate hosts and (b) clinical procedures could be employed to strengthen such immunity as an adjunct to radiotherapy, chemotherapy, and surgery.     

Localization of neuron-specific (gamma gamma) enolase in proliferating (supportive and neoplastic) Schwann cells. An immunohisto- and electron-immunocyto-chemical study of ganglioneuroblastoma and schwannomas

Neuron-specific (gamma gamma) enolase, a glycolytic enzyme used as a relatively specific marker for normal neurons and neuroendocrine cells, has recently been found in a variety of neoplastic cells and in reactive astrocytes. Its localization was investigated by immunohisto- and electron-immunocyto-chemistry, in the proliferating supportive Schwann cells of a peripheral ganglioneuroblastoma and in the neoplastic Schwann cells of four acoustic tumours. By light microscopy, the neoplastic Schwann cells showed moderate uneven diffuse immunopositivity for enolase. By electron-immunocytochemistry, both types of Schwann cells demonstrated immunopositivity discretely limited to their cell surface membranes. The neoplastic ganglion cells and axons of the ganglioneuroblastoma and the normal neurons and axons included in the schwannomas were, as expected, intensely immunopositive. The visualization of gamma gamma enolase on the cell surface membranes of both neoplastic and non-neoplastic proliferating Schwann cells suggests that increased glycolytic activity may occur on the surface of these proliferating cells irrespective of the nature of the proliferation.     

Outlook for the genetic engineering approach in radiobiology

Present evidence on the use of genetic engineering methods in studying the molecular mechanism of radiation damage and repair of DNA, as well as radiation mutagenesis and carcinogenesis has been summarized. The new approach to radiobiological research has proved to be extremely fruitful. Some previously unknown types of structural disorders in DNA molecule have been discovered, some repair genes isolated and their primary structure established, some aspects of radiation mutagenesis elucidated, and research into deciphering the molecular bases of neoplastic transformations of exposed cells are being successfully investigated. The authors discuss the perspectives of using genetic engineering methods in radiobiology.     

Two types of transglutaminase in the PC12 pheochromocytoma cell line. Stimulation by sodium butyrate

Transglutaminases are a class of enzymes capable of covalently cross-linking both intracellular and extracellular proteins. The activity of tissue transglutaminase is known to decrease precipitously following neoplastic transformation, and it has been hypothesized that transglutaminase may be involved in growth regulation. We have found that the differentiation promoter sodium butyrate is able to cause a marked increase in transglutaminase activity in PC12 pheochromocytoma cells in a time- and dose-dependent manner. This increased transglutaminase activity is associated with growth arrest, as well as with striking morphological changes including increased cell adhesion. The transglutaminase induced by sodium butyrate appears to be tissue transglutaminase, based on its cytosolic localization, thermal lability at basic pH, and elution profile on anion-exchange chromatography. Untreated PC12 cells contain only small amounts of transglutaminase which resembles epidermal transglutaminase, an enzyme previously described only in skin. In contrast to sodium butyrate, nerve growth factor did not stimulate tissue transglutaminase in PC12 cells, although it, too, caused growth arrest. It is hypothesized that transglutaminase may be involved in certain morphological changes accompanying cellular differentiation and neoplastic transformation, rather than in growth regulation per se.