Damaging action of photodynamic treatment in combination with hyperthermia on transmembrane transport in murine L929 fibroblasts

Photodynamic treatment of murine L929 fibroblasts with hematoporphyrin derivative caused inhibition of the 2-aminoisobutyric acid transport system. This was reflected by an increase in the apparent Km with a constant Vmax, indicating impairment of the carrier function rather than a decrease of the number of transport sites. Hyperthermic treatment of these cells resulted in a moderate decrease of the activity of the 2-aminoisobutyric acid transport system. Overall protein synthesis was severely inhibited both by photodynamic treatment and by hyperthermia. Hyperthermia subsequent to photodynamic treatment resulted in an additive inhibition of 2-aminoisobutyric acid transport and of protein synthesis. After photodynamic treatment both 2-aminoisobutyric acid transport and protein synthesis were repaired. The repair of 2-aminoisobutyric acid transport depended on protein synthesis, as shown by the virtually complete blockage of repair by anisomycin. After hyperthermia (either alone or subsequent to photodynamic treatment), no recovery of 2-aminoisobutyric acid transport was observed, although protein synthesis was restored to the initial level. Apparently, hyperthermia subsequent to photodynamic treatment blocks the repair of photodynamically induced damage of this transport system. The experimental results further indicate that protein synthesis is not the rate-determining step for the repair of 2-aminoisobutyric acid transport, although it is necessary in this process. Cell survival was decreased both by photodynamic treatment and by hyperthermia. The combined effects of these two treatments were additive. It is discussed that these results indicate that photodynamic inhibition of 2-aminoisobutyric acid transport is not causally related to loss of clonogenicity, contrary to earlier suggestions.     

Deferoxamine photosensitizes cancer cells in vitro

Effect of the iron chelator deferoxamine (DF) on the production of endogenous porphyrins was studied in adenocarcinoma WiDr cells and erythroid K562 cells in vitro. Porphyrin fluorescence was observed in the cells in vitro incubated with DF. The fluorescence spectra recorded in the cells were similar to that of protoporphyrin IX (PpIX). The amount of PpIX generated by DF was around 5% of the ALA effect. Around 90% of the WiDr cells incubated in vitro with DF (0.5 mM, 24 h) and then exposed to light (400-460 nm, 20 min) were photodynamically inactivated. In conclusion, the present study describes a novel approach of using iron chelating agents without 5-aminolevulinic acid (ALA) to photosensitize cancer cells.     

Activating the NaK pump with monensin increases aminoisobutyric acid uptake by mouse fibroblasts

Monensin rapidly tripled the initial rate and extent of α-aminoisobutyric acid accumulation by Swiss 3T3 cells. This ionophore catalyzes the electroneutral exchange of external Na for cellular protons and stimulates the NaK pump by suppling it with more Na. The stimulation of the NaK pump and α-aminoisobutyric acid uptake exhibited a similar dependence on monensin concentration. Ouabain prevented monensin from increasing α-aminoisobutyric acid transport. Aminoisobutryic acid transport was more than doubled at low doses of monensin that activated the NaK pump by elevating cell Na without significantly changing cell K. The rapid activation of α-aminoisobutyric acid transport is probably due to the hyperpolarizing effect of stimulating the electrogenic NaK pump. The stimulation of the NaK pump is quiescent fibroblasts by serum or growth factors may be sufficient to activate the Na-dependent amino acid transport systems.     

Studies on the Formation of Phycocyanin, Porphyrins, and a Blue Phycobilin by Wild-Type and Mutant Strains of Cyanidium caldarium

The synthesis of chlorophyll a and the bile-pigment and protein moieties of phycocyanin were arrested in illuminated cells of Cyanidium caldarium, strain III-D-2, incubated with chloramphenicol, ethionine, p-fluorophenylalanine, and p-chloromercuribenzoate. Pigment synthesis was similarly retarded in illuminated cells provided with nutrient medium lacking nitrogen.

Porphobilinogen, porphyrins, and a blue phycobilin were excreted into the nutrient medium by illuminated and unilluminated cells of wild-type and mutant C. caldarium strains incubated with δ-aminolevulinic acid in darkness. Pigment production from δ-aminolevulinic acid was sensitive to treatment with chloramphenicol and ethionine.

Cells of C. caldarium excreted 7 red-fluorescing porphyrins into the suspending medium during incubation with δ-aminolevulinic acid. Three of these porphyrins were identified as uroporphyrin III, coproporphyrin III, and protoporphyrin on the basis of their spectral properties and by paper chromatogaphy with standards.

The blue phycobilin was characterized spectrally and compared with biliverdin. The algal phycobilin displayed properties of a pigment with a violin-type structure. The phycobilin may be an immediate precursor of phycocyanobilin, the phycocyanin chromophore, or identical to it.

     

Amino acid transport by aggregates of cultured chicken heart cells. Effect of insulin.

Single heart cells dissociated from 14-day-old chicken embryos were reagregated into spheroidal clusters on a gyratory shaker and centrifuged to form cohesive discs of approximately 400 aggregates. These cultured cells accumulated 2-amino[1-14C]isobutyric acid against a gradient. When incubated for 3 hours in a protein-free, buffered, balanced salt solution, concentrative transport decreased to a stable basal level. Incubation in the presence of sodium bovine insulin prevented this fall in transport activity and resulted in increased 2-aminoisobutyric acid uptake to concentrations 40 time sthat in the medium during a subsequent 3-hour transport assay. Intracellular accumulation of 2-aminoisobutyric acid was linear during the initial 15 min of transport in the presence and absence of added insulin. Basal transport of 2-aminoisobutyric acid was temperature-dependent, requied extracellular sodium greater than 125 meg/liter, and demonstrated saturation with an apparent Vmax of 3.4 mmol/liter/10 min and an apparent Km of 2.6 mM. Basal transport activity was not reduced by cycloheximide or puromycin even after 3 hours of exposure...     

Maturation of membrane function: Transport of amino acid by rat erythroid cells

The membrane changes which occur during cellular maturation of erythroid cells have been investigated. The transport of α-aminoisobutyric acid, alanine, and N-methylated-α-aminoisobutyric acid have been studied in the erythroblastic leukemic cell, the reticulocyte, and the erythrocyte of the Long-Evans rat. The dependence of amino acid transport on extracellular sodium concentration was investigated. Erythrocytes were found to transport these amino acids only by Na-independent systems. The steady state distribution ratio was less than 1. Reticulocytes were found to transport α-aminoisobutyric acid and alanine by Na-dependent systems, but only small amounts of N-methylated-α-aminoisobutyric acid. Small amounts of these amino acids were transported by Na-independent systems. The steady state distribution ratio was greater than one for Na-dependent transport. The erythroblastic leukemia cell, a model immature erythroid cell, showed marked Na-dependence (>90%) for α-aminoisobutyric acid and alanine transport, and >80% for the Na-dependent transport of N-methyl-α-aminoisobutyric acid. The steady state distribution ratio for the Na-dependent transport was >4. In the erythroblastic leukemic cell, at least three Na-dependent systems are present: one includes alanine and α-aminoisobutyric acid, but excludes N-methyl-α-aminoisobutyric acid; one is for α-aminoisobutyric acid, alanine and also N-methyl-α-aminoisobutyric acid; and one is for N-methyl-α-aminoisobutyric acid alone. In the reticulocyte, the number of Na-dependent systems are reduced to two: one for α-aminoisobutyric acid and alanine; one for N-methyl-α-aminoisobutyric acid. In the erythrocytes, no Na-dependent transport was found. Therefore, maturation of the blast cell to the mature erythrocyte is characterized by a systematic loss in the specificity and number of transport systems for amino acids.     

Effects of tumour necrosis factor-alpha on BrdU incorporation in cultured human enterocytes

Bromodeoxyuridine incorporation is a useful method for studying the pattern of DNA synthesis in proliferating cells. The distribution pattern of incorporated BrdU in villus enterocytes of duodenal explants was analysed after exposure to TNFalpha in organ culture. TNFalpha caused a consistent, low level uptake of BrdU in the portion of the nucleus close to the nuclear membrane, this pattern was absent from the control cultures. As these epithelial cells are terminally arrested in G(0), the BrdU incorporation was thought not to be due to S phase DNA synthesis, but rather a response to the cytotoxic influence of TNFalpha. Microtitre plate proliferation assays of cell density and DNA synthesis were devised to study the effects of TNFalpha on confluent monolayers of the human foetal jejunal cell line I407 and the mouse fibrosarcoma cell line L929. Both cell lines showed a similar response to TNFalpha. Exposure to TNFalpha alone did not reduce cell numbers but did cause a significant increase in DNA synthesis (p < 0.05). When cycloheximtde was added in tandem with TNFalpha there was a significant reduction in cell number (p < 0.001) and level of DNA synthesis (p < 0.01) indicative of cell death. The DNA of cells exposed to TNFalpha and cycloheximide was fragmented when viewed on an electrophoresis gel. The results show that BrdU incorporation might be a good indicator of damage to the DNA of cells after cytotoxic insult. TNFalpha may be responsible for villus enterocyte damage in enteropathies such as coeliac disease and GVHR of the small bowel.     

Transport and metabolic effects of α-aminoisobutyric acid in saccharomyces cerevisiae

α-Aminoisobutyric acid is actively transported into yeast cells by the general amino acid transport system. The system exhibits a K_m for α-aminoisobutyric acid of 270 μM, a V_max of 24 nmol/min per mg cells (dry weight), and a pH optimum of 4.1–4.3. α-Aminoisobutyric acid is also transported by a minor system(s) with a V_max of 1.7 nmol/min per mg cells. Transport occurs against a concentration gradient with the concentration ratio reaching over 1000:1 (in/out). The α-aminoisobutyric acid is not significantly metabolized or incorporated into protein after an 18 h incubation. α-Aminoisobutyric acid inhibits cell growth when a poor nitrogen source such as proline is provided but not with good nitrogen sources such as NH₄⁺. During nitrogen starvation α-aminoisobutric acid strongly inhibits the synthesis of the nitrogen catabolite repression sensitive enzyme, asparaginase II. Studies with a mutant yeast strain (GDH-CR) suggest that α-aminoisobutyric acid inhibition of asparaginase II synthesis occurs because α-aminoisobutyric acid is an effective inhibitor of protein synthesis in nitrogen starved cells.     

Regulation of amino acid transport in chicken embryo fibroblasts by purified multiplication-stimulating activity (MSA)

Enhanced amino acid transport is observed when quiescent cultures of chicken embryo fibroblasts are stimulated to proliferate by the addition of purified multiplication-stimulating activity (MSA). This increase in amino acid transport is an early event occuring prior to the onset of DNA synthesis in stimulated cells. Results indicate that the changes in transport activity, as measured by α-aminoisobutyric acid (AIB) uptake, are due to stimulation of only the Na⁺-dependent A transport system. There is little or no change in the activities of transport systems ASC, L, or Ly⁺ upon exposure to MSA. A kinetic analysis shows this increased activity is due to a change in Vmax while K_m remains unaltered. Continuous exposure to the stimulus is required to maintain the increased level of transport activity and the presence of inhibitors of RNA and protein synthesis significantly inhibits the response. Results also indicate that a similar specific increase in the A transport system is initiated when RSV tsNY68 infected cells are shifted to the permissive temperature. It appears that the A system of mediation is emerging as a strategic regulatory site for cell function.     

Glucose elevates ornithine decarboxylase expression in Vero cells

The addition of Earle's balanced salt solution (EBSS) of amino acids that are transported by a Na+-dependent cotransport system was not required by Vero cells for ornithine decarboxylase (ODC:EC 4.1.1.17) amplification. Vero cell ODC activity was elevated tenfold above basal levels when confluent cells were incubated for 5 hr in EBSS alone. ODC activity increased as a function of the incubation time in EBSS and was not elevated above basal enzyme levels when cells were incubated in EBSS minus glucose. ODC expression increased as a function of the glucose concentration in EBSS, with 20 mM glucose producing a 90-fold increase in ODC activity. ODC expression is more responsive to glucose in high-density quiescent cultures than in low-density growing cultures. Enhanced ODC expression by glucose depended on Na+ and K+ concentrations. The specific activity of ODC was also elevated above basal levels when mannose or fructose replaced glucose in EBSS. The addition of alanine or asparagine to EBSS enhanced ODC activity above levels obtained with EBSS containing standard (5.5 mM) glucose concentrations. In the absence of glucose, alanine was more effective than asparagine in enhancing ODC expression. These results suggest that the transport of amino acids is not an absolute requirement for Vero cell ODC expression and that ODC expression is linked to changes in cellular energetics and/or ion fluxes.     

Enhancement of the synthesis of specific cellular polypeptides in a temperature-sensitive Chinese hamster cell line (K12) defective for entry into S phase

Temperature-sensitive Chinese hamster cells (K12) have been shown to be defective for the initiation of new rounds of DNA replication when incubated at the restrictive temperature (40.5 degrees). By temperature shift experiments with synchronous cultures, we have marked out the step at which the mutation is expressed as the four hours preceding the initiation of DNA synthesis. The block imposed by the mutation has been shown to be irreversible. In order to approach the biochemical characterization of the temperature-sensitive function in K12 cells, we have analyzed the cellular proteins synthesized under permissive (35 degrees) and restrictive temperatures. The synthesis of three polypeptides is markedly enhanced when K12 cells are incubated at 40.5 degrees. One of them (band B) has turned out to be a useful biochemical marker of the expression of K12 mutation since its synthesis is not affected in other ts-mutants or in hybrids in which K12 mutation is complemented. In addition, the alteration in band B synthesis is irreversible and occurs during the same stage of the cell cycle at which the mutated function is expressed.     

Methylation of deoxycytidine incorporated by excision-repair synthesis of DNA

Methylation of deoxycytidine incorporated by DNA excision-repair was studied in human diploid fibroblasts following damage with ultraviolet radiation, N-methyl-N-nitrosourea, or N-acetoxy-2-acetylami-nofluorene. In confluent, nondividing cells, methylation in repair patches induced by all three agents is slow and incomplete. Whereas after DNA replication in logarithmic-phase cultures a steady state level of 3.4% 5-methylcytosine is reached in less than 2 hr after cells are labeled with 6-³H-deoxycytidine, following ultraviolet-stimulated repair synthesis in confluent cells it takes about 3 days to reach a level of ～2.0% 5-methylcytosine in the repair patch. In cells from cultures in logarithmic-phase growth, 5-methylcytosine formation in ultraviolet-induced repair patches occurs faster and to a greater extent, reaching a level of ～2.7% in 10–20 hr. Preexisting hypomethylated repair patches in confluent cells are methylated further when the cells are stimulated to divide; however, the repair patch may still not be fully methylated before cell division occurs. Thus DNA damage and repair may lead to heritable loss of methylation at some sites.     

A reassessment of decreased amino acid accumulation by ehrlich ascites tumor cells in the presence of metabolic inhibitors

This study was undertaken to examine the mechanism by which metabolic inhibition reduces amino acid active transport in ehrlich ascites tumor cells. At 37 degrees C the metabolic inhibitor combination 0.1 mM 2,4-dinitrophenol (DNP) + 10 mM 2- deoxy-D-glucose (DOG) reduced the cell ATP concentration to 0.10- 0.15 mM in less than 5 min. This inhibition was associated with a 20.6 percent +/- 6.4 percent (SD) decrease in the initial influx of α-aminoisobutyric acid (AIB), and a two- to fourfold increase in the unidirectional efflux. These effects could be dissociated from changes in cell Na(+) or K(+) concentrations. Cells incubated to the steady state in 1.0-1.5 mM AIB showed an increased steady-state flux in the presence of DNP + DOG. Steady- state fluxes were consistent with trans-inhibition of AIB influx and trans-stimulation of efflux in control cells, but trans- stimulation of both fluxes in inhibited cells. In spite of the reduction of the cell ATP concentration to less than 0.15 mM and greatly reduced transmembrane concentration gradients of Na(+) and K(+), cells incubated to the steady state in the presence of the inhibitors still established an AIB distribution ration 13.8 +/- 2.6. The results are interpreted to indicate that a component of the reduction of AIB transport produced by metabolic inhibition is attributable to other actions in addition to the reduction of cation concentration gradients. Reduction of cell ATP alone is not responsible for the effects of metabolic inhibition, and both the transmembrane voltage and direct coupling to substrate oxidation via plasma-membrane-bound enzymes must be considered as possible energy sources for amino acid active transport.     

Necrotic tumor cells oppositely affect nitric oxide production in tumor cell lines and macrophages

Nitric oxide (NO) is a highly reactive free radical with profound tumoricidal activity, produced by both macrophages and tumor cells. While it has been postulated that necrotic tumor cells can augment macrophage anti-tumor action, we investigated the effect of tumor cell necrosis on NO synthesis and viability of L929 fibrosarcoma and C6 astrocytoma cell lines. The presence of necrotic tumor cells dose-dependently reduced NO production in IFN-gamma stimulated L929 cells, and rescued them from NO-dependent autotoxicity. This effect was mediated through soluble products, since it was completely preserved after blocking the contact between the necrotic and live cells. On the other hand, apoptotic tumor cells were unable to suppress IFN-gamma-triggered NO release and subsequent decrease of cell respiration in L929 cultures. Similar results were obtained with C6 astrocytoma cell line. This down-regulation of NO synthesis in response to necrotic cell products was not specific for tumor cell lines, since necrotic tumor cells markedly suppressed NO production in cytokine-stimulated primary fibroblasts and astrocytes. In contrast, both murine and rat peritoneal macrophages readily increased their basal or IFN-gamma-induced NO production when incubated with necrotic tumor cells. Taken together, these results suggest that tumor cell necrosis might promote or restrict tumor growth through suppression or enhancement of NO synthesis in tumor cells and macrophages, respectively, with net effect presumably depending on the extent of macrophage infiltration.     

Relationship between cell proliferation, chromatin template activity and accumulation of nuclear proteins

Trypsinization of confluent monolayers of WI-38 cells causes an extensive loss of nuclear proteins. The loss of nuclear proteins is restored only several hours after the cells have been replated at a lower density in 10% serum. When trypsinized fibroblasts are replated at a lower density in 10% serum, there is also a sustained progressive leading to DNA synthesis and cell division. If 0.3% serum is used instead of 10%, there is a modest increase in nuclear template activity, but not accumulation of nuclear proteins and no DNA synthesis or cell division.     

Density dependent inhibition of both growth and T-antigen expression in revertants isolated from simian virus 40-transformed mouse SVT2 cells.

Phenotypic revertants were isolated from simian virus 40-transformed cells in order to examine the relationship between simian virus 40 T-antigen expression and G1 arrest of growth. Revertant clones with increased adherence were selected from cultures of SVT2, a simian virus 40-transformed BALB/c mouse cell line, and screened to find arrestable revertant clones which inhibited DNA synthesis when crowded. The clones selected from untreated SVT2 were unstable and showed little or no inhibition of DNA synthesis when crowded. Stable revertants were found after treatment of SVT2 with Colcemid to increase ploidy. The stable revertants all lost most transformed growth properties tested, including tumorigenicity, but only a few showed the same degree of inhibition of DNA synthesis at high cell density as BALB/3T3. All revertant clones expressed T antigen at low cell density. Three revertants showed coordinate inhibition of DNA synthesis and apparent loss of T antigen at high cell density. We suggest that changes in gene dosage rather than mutations caused the altered properties of the new revertants and that continued DNA synthesis in confluent cultures may be the transformed phenotype that requires the least simian virus 40 T antigen.     

The characteristics of enhanced DNA synthesis in L cells treated with interferon and arginine-deprived

DNA synthesis as measured by incorporation of radioactive thymidine or deoxyadenosine is enhanced up to ten-fold in interferon-treated L929 cells as compared to cells not treated with interferon when both were incubated in arginine-deficient medium. Rates and amounts of RNA and protein synthesis were only modestly increased by comparison. The effect was marked after 2 days of arginine starvation and at an interferon dose of 20 PRD₅₀. The labelled product was DNasesensitive and its synthesis was inhibited by cytosine arabinoside and hydroxyurea, but not by puromycin or actinomycin. Autoradiographic studies indicated that label incorporation was entirely intranuclear in interferon-treated cells and substantially greater than non-treated cells.     

Stability and comparative transport capacity of cells, mureinoplasts, and true protoplasts of a gram-negative bacterium

The outer layers of the cell envelope of a pseudomonad of marine origin were removed by washing the cells in 0.5 m NaCl followed by suspension in 0.5 m sucrose. The term mureinoplast has been suggested for the rod-shaped forms which resulted from this treatment. As previously established, these forms lacked the outer cell wall layers but still retained a rigid peptidoglycan structure. Mureinoplasts remained stable if suspended in a balanced salt solution containing 0.3 m NaCl, 0.05 m MgSO(4), and 0.01 m KCl but, unlike whole cells, lost ultraviolet (UV)-absorbing material if suspended in 0.5 m NaCl or 0.05 m MgCl(2). Sucrose added to the balanced salt solution also enhanced the loss of UV-absorbing material. Addition of lysozyme to suspensions of mureinoplasts in the balanced salt solution produced spherical forms which, by electron microscopy and the analysis of residual cell wall material, appeared to be true protoplasts. Only undamaged mureinoplasts, as judged by their capacity to fully retain alpha-aminoisobutyric acid, were capable of being converted to protoplasts. Protoplasts and undamaged mureinoplasts retained 100% transport capacity when compared to an equal number of whole cells. The Na(+) requirement for transport of alpha-aminoisobutyric acid and the sparing action of Li(+) on this Na(+) requirement were the same for both protoplasts and whole cells. These observations indicate that, in this gram-negative bacterium, the cell wall does not participate in the transport process though it does stabilize the cytoplasmic membrane against changes in porosity produced by unbalanced salt solutions. The results also indicate that the requirements for Na(+) for transport and for the retention of intracellular solutes are manifested at the level of the cytoplasmic membrane.     

Further characterization of a cell-free system for measuring replicative and repair DNA synthesis with cultured human fibroblasts and evidence for the involvement of DNA polymerase alpha in DNA repair.

DNA repair synthesis can be specifically measured in osmotically opened, confluent cultured human fibroblasts after exposure to DNA damaging agents such that both induction and mediation of DNA repair synthesis can take place in this cell-free system. Alternatively, by utilizing osmotically shocked, log phase cells and altering the DNA precursors, pH and ionic strength, replicative DNA synthesis can be specifically monitored. Autoradiographic studies show that virtually all of the nuclei from the lysates of the confluent, UV-iradiated cells are lightly labeled in the fashion characteristic of DNA repair. By contrast, only a fraction of nuclei is labeled in a population of unperturbed, opened log phase cells and the labeling is heavy and characteristic of replicative synthesis. Furthermore, equilibrium density gradient sedimentation shows that DNA synthesis in lysates of log-phase cells is semiconservative, whereas that with UV-irradiated cells is repair synthesis. This open cell system has been used to study the enzymology of DNA repair. Thus, dideoxythymidine triphosphate, a specific inhibitor of DNA polymerases beta and gamma, does not inhibit either replicative or repair synthesis. By contrast, aphidicolin, a specific inhibitor of DNA polymerase alpha, inhibits DNA repair and replicative synthesis in both intact and permeabilized cells. Finally, phage T4 UV-exonuclease stimulates repair synthesis, but only when phage T4 UV-endonuclease is also added to the UV-irradiated nuclei.     

Incorporation and Degradation of C and H-labeled Thymidine by Sugarcane Cells in Suspension Culture

Sugarcane cells growing in suspension culture degrade exogenous thymidine, releasing thymine. Thymine is not utilized for DNA synthesis. Thymine is rapidly catabolized to β-aminoisobutyric acid which is found within the cell. Thymidine in the medium is used for DNA synthesis. The label of [2-¹⁴C]thymidine is lost as ¹⁴CO₂, but the label of [³H]methylthymidine is found in the cell as [³H]β-aminoisobutyric acid, some of which is used for the synthesis of other cell components. The degradation of thymidine can be partially inhibited by addition of certain substituted pyrimidines.