Effect of Cold Plasma on Glial Cell Morphology Studied by Atomic Force Microscopy

The atomic force microscope (AFM) is broadly used to study the morphology of cells. The morphological characteristics and differences of the cell membrane between normal human astrocytes and glial tumor cells are not well explored. Following treatment with cold atmospheric plasma, evaluation of the selective effect of plasma on cell viability of tumor cells is poorly understood and requires further evaluation. Using AFM we imaged morphology of glial cells before and after cold atmospheric plasma treatment. To look more closely at the effect of plasma on cell membrane, high resolution imaging was used. We report the differences between normal human astrocytes and human glioblastoma cells by considering the membrane surface details. Our data, obtained for the first time on these cells using atomic force microscopy, argue for an architectural feature on the cell membrane, i.e. brush layers, different in normal human astrocytes as compared to glioblastoma cells. The brush layer disappears from the cell membrane surface of normal E6/E7 cells and is maintained in the glioblastoma U87 cells after plasma treatment.     

Contact with basement membrane heparan sulfate enhances the growth of transformed vascular endothelial cells, but suppresses normal cells.

Modulation of vascular endothelial cell growth by basement membrane heparan sulfate was investigated using four lines of normal and transformed cells. The growth of transformed endothelial cells, but not normal cells, on reconstituted basement membrane was severely suppressed when heparan sulfate, one of the components of the membrane, was specifically degraded by an enzyme, heparitinase. Similarly, when cells were grown on surfaces coated with heparan sulfate, as little as 60 pg/cm2 of heparan sulfate caused growth enhancement of transformed cells, but suppression of normal cells. These results together with our previous observations (IMAMURA, T and MITSUI, Y. (1987) Exp. Cell Res., 172: 92-100) argue that transformed cells have reversed a mechanism by which basement membrane heparan sulfate functions as a physiological suppressor for the growth of normal endothelial cells.     

Membrane lipid dynamics and density dependent growth control in normal and transformed avian cells

Membrane fluidity of normal chick embryo fibroblasts and normal Japanese quail fibroblasts and their Rous sarcoma virus and methylcholanthrene transformed counterparts was investigated using the technique of fluorescence depolarisation of 1,6-diphenylhexatriene incorporated in the whole cells and in their isolated plasma membrane vesicles. Normal cells and isolated plasma membranes of normal cells showed significant changes in fluidity as a function of population density while neither Rous sarcoma virus transformed nor methylcholanthrene tumor cells or their isolated plasma membrane showed this effect. Stimulation of growth by addition of calf serum to cultures of quiescent, density-inhibited normal cells was accompanied by rapid changes in the direction of increased membrane lipid fluidity. Neither sparse normal cells, nor sparse or dense transformed cells showed any significant fluidity change in their membrane lipids upon addition of serum. Enzyme and electron microscopic analysis of the ratios of different membrane types in each cell type showed that this ratio was invariant with respect to cell population density but different between transformed and normal cells. Hence, the fluidity changes observed, measured as the mean rotational correlation time of the fluorescene probe in the membrane lipids, truly reflect organisational differences, occurring as a function of population density in cultures of cells which retain density-dependent growth control.     

The effect of extracellular matrix interactions on morphologic transformation in vitro

There is emerging evidence that the structure and function of a cell is dependent in part on the contacts that cells make with the extracellular matrix. We report here the effect of extracellular matrices secreted from both normal and tumor cells have on the structure of normal rat kidney epithelial cells. Normal rat kidney cells plated on the basement membrane secreted by tumor cells adopt a morphology and phenotype which closely resembles a Kirsten-ras transformed normal rat kidney cell. This morphologic transformation was not observed for cells plated on individual extracellular matrix components or on basement membrane secreted by normal placenta cells. This suggests that tumor derived basement membrane has unique characteristics which may cause morphologic transformation of normal rat kidney cells.     

Degradation process of Mycobacterium leprae cells in infected tissue examined by the freeze-substitution method in electron microscopy

Mycobacterium leprae cells (strain Thai-53) harvested from infected mouse foot pads were examined by electron microscopy using the freeze-substitution technique. The population of M. leprae cells from the infected tissue consisted of a large number of degraded cells and a few normal cells. These thin sectioned cell profiles could be categorized into four groups depending on the alteration of the membrane structures, and the degradation process is considered to occur in stages, namely from stages 1 to 3. These are the normal cells with an asymmetrical membrane, a seemingly normal cell but with a symmetrical membrane (stage 1), a cell possessing contracted and highly concentrated cytoplasm with a membrane (stage 2), and a cell that has lost its membrane (stage 3). The peptidoglycan layer was found to remain intact in these cell groups.     

Foreword: Protein secretion and the Golgi apparatus

Resonance and nonresonance Raman spectra have been obtained from neoplastically transformed and normal avian lymphocytes. The acyl chains of membrane phospholipids of neoplastic cells are more highly unsaturated than those of normal cells. The observation of prominent carotenoid bands in both cell populations indicates the availability of a sensitive, intrinsic probe of membrane potential and local membrane environment.     

Ganglioside sialidase distribution in mucolipidosis type IV cultured fibroblasts

The subcellular distribution of ganglioside sialidase in Mucolipidosis IV (ML IV) cells was characterized by a series of Percoll gradients. Similar to normal cells, the enzyme cosedimented with plasma membrane markers, although this activity was reduced and exhibited decreased solubility in ML IV cells. Only trace amounts of ganglioside sialidase (less than 5%) was found in the lysosomes of normal cells. This activity was apparently reduced in ML IV cells but its minute activity in controls excluded further characterization of these differences. Plasma membranes on 6.7 and 5.6% Percoll gradients were biomodally distributed. Ganglioside sialidase in normal cells was found to be in both the heavier and the lighter membrane fractions, whereas the enzyme in ML IV cells was associated mainly with the denser membrane fraction. These data indicate that the enzyme in ML IV cells is characteristically different from normal in that it exhibits reduced activity and solubility and a different plasma membrane distribution.     

Phosphorylation of membrane proteins from Plasmodium berghei-infected red cells.

Membrane from Plasmodium berghei-infected mouse red cells has a different pattern of phosphorylation by (γ-³²P)ATP from normal membrane. A phosphorylated membrane protein of apparent molecular weight 42,000, absent in membrane from normal cells, can be detected in membrane from infected cells. The new phosphorylated protein can be extracted by 0.1 mM EDTA but not by triton X-100, indicating that it may be red cell actin.     

Different cyclic changes in the surface membrane of normal and malignant transformed cells

Transformed fibroblasts in interphase and normal fibroblasts in mitosis were agglutinated by Con A and the lectin from wheat germ, whereas normal fibroblasts in interphase and transformed fibroblasts in mitosis were not agglutinated by these lectins. The percentage of fluorescent cells at non-saturation concentrations of fluorescent ConA was also higher with transformed interphase and normal mitotic cells, than with normal interphase and transformed mitotic cells. Under the same conditions, a similar number of radioactively labeled ConA molecules were bound to normal and transformed cells in interphase and mitosis. Our results indicate different cyclic changes in the surface membrane of normal and transformed fibroblasts, so that regarding interaction with these lectins, normal mitotic cells resemble transformed interphase cells and transformed mitotic resemble normal interphase cells. The data suggest that there is a reversed cyclic change in the mobility of specific surface membrane sites in normal and transformed cells.     

Reduced transglutaminase-catalyzed cross-linking of exogenous amines to membrane proteins in sickle erythrocytes

In order to determine the capacity of sickle cells to undergo transglutaminase-catalyzed cross-linking of membrane proteins, human normal and sickle erythrocytes were incubated with [ring-2-14C]histamine in the presence of Ca2+ and ionophore A23187. The [14C]histamine incorporation into membrane components was observed in freshly prepared erythrocytes. Incorporation of radioactivity into spectrin and Band 3 membrane components was significantly (P less than 0.001) less in sickle erythrocytes than in normal cells. Transglutaminase deficiency was excluded by the finding of increased activity of this enzyme in sickle cells from patients with reticulocytosis. The incorporation of [3H]spermine into red cell membranes was also less in sickle erythrocytes than in normal cells under the same conditions of incubation used for [ring-2-14C]histamine. Sickle erythrocytes were more permeable to these amines than normal cells. It is proposed that the gamma-glutamyl sites of membrane proteins in sickle erythrocytes are less accessible for transglutaminase-catalyzed cross-linking to histamine and polyamines in vitro, perhaps due to prior in vivo activation of this enzyme by the increased calcium in sickle cells and/or shielding secondary to altered membrane organization.     

Interaction of tumor and normal blood cells with ethylene oxide and propylene oxide block copolymers

Ethylene oxide and propylene oxide block copolymers (pluronics) are widely known as agents that promote drug penetration across biological barriers. We have studied the interaction of normal and malignant blood cells with pluronics L61 and P85 that have different hydrophobicity. SP2/0 myeloma cells accumulated pluronics while normal cells adsorb most of the polymer on the surface. Interaction of pluronics with cells resulted in drastic changes of membrane microviscosity. Tumor cell membrane microviscosity decreased after pluronics adsorption, in contrast to normal cells, whose membrane microviscosity was enhanced. We suppose that sensitivity of tumor cell membrane microviscosity to the pluronics action correlates with its permeability for molecular substances.     

亚硒酸钠对肿瘤细胞膜流动性及致癌性的影响

 本文为探讨硒抗肿瘤的机理而开展了硒对小鼠腹水型肝癌(Hep.A)细胞膜流动性影响的研究。结果表明;1.腹水型肝癌细胞膜流动性明显高于正常肝细胞的膜流动性。2.硒能显著降低腹水型肝癌细胞膜的流动性,而对正常肝细胞的膜流动性没有明显影响。3.通过降低腹水型肝癌细胞膜的流动性,可降低肿瘤细胞的致癌力。     

F20C,a new fluorescent membrane probe,moves more slowly in malignant and mitogen-transformed cell membranes than in normal cell membranes

New fluorescent probes of membrane mobility can be introduced into cell membranes at single points with particles of a membrane mobility agent, A₂C. The initial entry of fluorescence from the particle into the cell membrane and the subsequent lateral spread of fluorescence have been observed for cells in suspension. A dramatic difference between the behavior of normal lymphocytes and that of mitogen-transformed and mastocytoma cells is found. Both the initial entry and the spreading of fluorescence are much slower in the transformed and tumor cells than in the normal cells at 18°C. Entry and spread of fluorescence in normal cells become slow enough to be observed only at 12°C or below.     

Type C Niemann-Pick disease. Lysosomal accumulation and defective intracellular mobilization of low density lipoprotein cholesterol

The intracellular accumulation of unesterified cholesterol was examined during 24 h of low density lipoprotein (LDL) uptake in normal and Niemann-Pick C fibroblasts by fluorescence microscopy with filipin staining and immunocytochemistry. Perinuclear fluorescence derived from filipin-sterol complexes was observed in both normal and mutant cells by 2 h. This perinuclear cholesterol staining reached its peak in normal cells at 6 h. Subsequent development of fluorescence during the remaining 18 h of LDL incubation was primarily limited to the plasma membrane region of normal cells. In contrast, mutant cells developed a much more intense perinuclear fluorescence throughout the entire 24 h of LDL uptake with little enhancement of cholesterol fluorescence staining in the plasma membranes. Direct mass measurements confirmed that internalized LDL cholesterol more readily replenishes the plasma membrane cholesterol of normal than of mutant fibroblasts. Perinuclear filipin-cholesterol fluorescence of both normal and mutant cells was colocalized with lysosomes by indirect immunocytochemical staining of lysosomal membrane protein. Abnormal sequestration of LDL cholesterol in mutant cells within a metabolically latent pool is supported by the finding that in vitro esterification of cellular cholesterol could be stimulated in mutant but not in normal cell homogenates by extensive disruption of the intracellular membranous structures of cells previously cultured with LDL. Deficient translocation of exogenously derived cholesterol from lysosomes to other intracellular membrane sites may be responsible for the delayed homeostatic responses associated with LDL uptake by mutant Niemann-Pick Type C fibroblasts.     

Studies on the outer surface of normal and RSV-transformed BHK fibroblast plasma membrane

The probe trinitrobenzene sulphonate (TNBS) was used to selectively label the cell surface of normal and Rous sarcoma virus-transformed BHK fibroblasts. A five-fold increase in the number of TNBS-binding groups exposed on the outer membrane surface after neoplastic transformation was measured. The extra trinitrophenyl (TNP) groups bound by transformed cells were mostly removable by mild trypsinization and no differences were found between the amount of TNP bound by phospholipids in both normal and transformed cells. SDS-acrylamide patterns of TNP-labelled membrane proteins purified from normal and transformed cells showed only minor differences. This led to the conclusion that the increased exposure of TNBS-binding groups was due mainly to different binding properties of membrane proteins towards the probe rather than the appearance of new surface components in transformed cells.     

Plasma membrane lipid order of leukemic and normal immature avian erythroid cells

Mammalian erythroblasts and their leukemic counterparts contain characteristic disordered regions of plasma membrane identified as putative membrane protein collection sites. In order to determine whether erythroid cells which do not enucleate contain homologous membrane domains, immature avian erythroid precursor cells and avian erythroleukemic cells were examined using merocyanine 540 (MC540), a fluorescent dye whose binding is sensitive to the packing of membrane lipids. Results were found to contrast with previous studies of the murine equivalents of these cells. In birds, normal erythroid precursors, including basophilic erythroblasts from the bone marrow and spleen of anemic animals, contained no detectable (less than 0.1%) cells which were stained by the dye. But cells from chicks infected with avian erythroblastosis virus (AEV) did stain. Considering the pattern of staining observed on AEV-erythroblasts relative to other leukemic and normal phenotypes, however, we conclude that neither normal nor leukemic avian erythroid cells contain a functional equivalent to the membrane protein collection sites found on their mammalian counterparts.     

Differences in membrane lipid composition and fluidity of transplanted GRSL lymphoma cells, depending on their site of growth in the mouse

GRSL lymphoma cells were isolated from various growth sites in the host. The relative membrane lipid fluidities of these cells and of normal lymphoid cells were estimated by fluorescence polarization, using the probe diphenylhexatriene and by measuring the (free) cholesterol/phospholipid molar ratio in whole cells. The results indicate that the membrane fluidity (reciprocal of the lipid structural order) of the lymphoma cells increases in the order of their location: peripheral blood less than spleen less than mesenterial lymph node less than ascites fluid. The membrane fluidities of normal lymphocytes from thymus, mesenterial lymph node and spleen were about the same, but higher than of peripheral blood lymphocytes, and between those of the lymphoma cells from lymph node and spleen. These results are confirmed by more extensive analysis on purified plasma membranes from the splenic and ascitic GRSL lymphoma cells and from normal splenocytes and thymocytes. The significantly higher lipid order parameter found in the GRSL plasma membrane isolated from the spleen as compared to those from the ascites cells could be fully explained by the differences measured in the major chemical determinants of the fluidity, i.e., the cholesterol/phospholipid ratio, the sphingomyelin content and the degree of saturation of the fatty acyl groups of the phospholipids. It was also found that the cholesterol/phospholipid ratio in erythrocyte membranes isolated from the peripheral blood of the tumor bearers was higher than in those from normal control mice. The observed differences in membrane fluidity between distinct subsets of tumor cells may be relevant to the sensitivity of these cells to immune attack or to drugs.     

Binding of epidermal growth factor to its receptor is affected by membrane phospholipid environment

Cells of epithelial origin generally require ethanolamine to grow in culture; when these cells are grown without ethanolamine, the phosphatidylethanolamine content of their membrane phospholipid becomes 1/2 to 1/3 of the normal amount, and growth stops. We have hypothesized that growth ceases because the phospholipid environment becomes unsuitable for membrane-associated function. Using ethanolamine-requiring rat mammary cells, we have investigated the possible effect of phosphatidylethanolamine deficiency on the binding characteristics of epidermal growth factor. Apparent dissociation constant for the high-affinity sites in cells having normal membrane phospholipid was 1.7 X 10(-10) M, whereas that of phosphatidylethanolamine-deficient cells was 2.7 X 10(-10) M: the difference was small, but significant. Pretreatment with phorbol ester caused the loss of high-affinity sites in cells having normal membrane, whereas binding characteristics of epidermal growth factor became refractory to the pretreatment in phosphatidylethanolamine-deficient cells. In addition, the rate of internalization of bound epidermal growth factor in phosphatidylethanolamine-deficient cells was about 1/4 of normal cells. Further, whether cells had normal or phosphatidylethanolamine-deficient membranes seemed to affect the phosphorylation patterns of membrane proteins in response to epidermal growth factor or phorbol ester. These results suggest that membrane phospholipid environment affects the activity of the epidermal growth factor receptor.     

Relevance of drug uptake,cellular distribution and cell membrane fluidity to the enhanced sensitivity of Down's syndrome fibroblasts to anticancer antibiotic-mitoxantrone

Sensitivity of human fibroblasts derived from Down's syndrome (DS) individuals (S-240, T-158, T-74, T-164) and normal donors (S-126, WA-1) to anticancer antibiotic-mitoxantrone (1,4-dihydroxy-5,8-bis((2-((2-hydroxy-ethyl)amino)ethyl)amino)-9,10-anthracenedione dihydrochloride; MIT) and its relationship to the transport rate, cellular distribution and interaction with cell membrane were studied. The survival assay showed that MIT was more toxic to trisomic fibroblast lines than to normal cells. Studies of transport kinetics indicated that the amount of drug taken up and extruded by DS cells was diminished, compared to control cells. In contrast, the cellular level of MIT associated with DNA was greater in trisomic than in normal cells. The fluorescence anisotropy measurements of TMA-DPH and 12-AS demonstrated that the fluidity of the polar region of the outer lipid monolayer of DS cell membrane was decreased in comparison with normal cells. MIT treatment decreased fluidity of the inner hydrophobic region of plasma membrane, but only slightly influenced the fluidity of the outer surface of the cell membrane. Finally, we concluded that lowered membrane fluidity, diminished amount of MIT extruded by cells and the enhanced level of the drug associated with DNA could be responsible for the enhanced sensitivity of DS fibroblasts to the MIT treatment.     

RFP134对UMR106细胞膜脂流动性的影响(英文)

癌细胞具有与正常细胞不同的膜脂流动性,导致细胞对生长因子和癌基因产物反应敏感;引起细胞增殖失控。本实验室从植物中发现一种二萜类活性物质──RFP134,在细胞周期和信号传递等多方面表现出有抑制癌细胞增殖,促进细胞分化的作用。本文以大鼠成骨肉瘤细胞（UMR106）和正常大鼠成骨细胞为模型,研究其对癌细胞膜脂流动性的影响。细胞系UMR106由美国麻省总医院内分泌室赠送。成骨细胞由本实验室分离培养。以不同浓度（20、40、60、80、100μM／L）的RFP134,在同一时间处理细胞,或以最适浓度（50μM／L）在不同时间作用于细胞。DPH为荧光标记物,测得的荧光偏振值和微粘度值为膜膜流动性指标。结果显示,无论在恒定的时间、以不同浓度的RFP134作用于UMR106细胞（Fig.1B）,或以恒定的浓度、在不同时间处理UMR106细胞（Fig．1D）,结果均表现为显著降低膜脂流动性。前者,RFP134作用于细胞时,细胞荧光偏振值与微粘度值逐步升高,其变化呈量效关系;而后者,呈时效关系。但在最适浓度与最佳作用时间,荧光偏振值和微粘度值达饱和状态。在同样条件下,RFP134对正常成骨细胞的膜脂流动性影响极小。即：荧光偏振值和微粘度值均在正常范围内保持恒定（Fig．1A;Fig．1C）。RFP134降低癌细胞的膜脂流动性