Regulation of mouse mammary tumor viral RNA synthesis in embryonal carcinoma cells and in teratocarcinoma derived myoblasts.

The expression of the mouse mammary tumor virus (MMTV) was studied in undifferentiated embryonal carcinoma cells (ECC), in partially differentiated myoblastic cells derived from ECC cells, and in fully differentiated myotubes. Whereas no appreciable amount of MMTV RNA could be detected in embryonal carcinoma cells, hybridation with radioactive viral cDNA revealed relatively large quantities of tumor virus RNA in the teratocarcinoma derived myoblasts. The MMTV RNA level was strongly reduced after differentiation of myoblasts into myotubes. The glucocorticoid hormone dexamethasone which stimulates the MMTV RNA synthesis in differentiated mammary cells did not affect this synthesis in myoblastic cells. By contrast, the apparently repressed synthesis of MMTV RNA in myotubes was almost completely overcomed with dexamethasone.     

Damage and repair in mammalian cells after exposure to non-ionizing radiations : I. Ultraviolet and visible light irradiation of cells of the rat kangaroo (Potorous tridactylus) and determination of photorepairable damage in vitro

Cornea cells of the rat kangaroo or “potoroo” (Potorous tridactylus) were exposed to far-UV (254 or 302 nm) radiation, with or without subsequent illumination by near-UV or visible light. The DNA of these cells was extracted and tested for the presence of photoproducts binding yeast photoreactivating enzyme (PRE). The criterion for the latter was competitive inhibition of an in vitro photorepair system, consisting of UV-irradiated transforming DNA of Haemophilus influenzae and an extract containing yeast PRE. The effects on repair kinetics of the transforming DNA indicate that in UV-irradiated potoroo cornea cells up to approximately 90% of photorepairable DNA damage can be photorepaired within 15 min. However, the extent of cellular photorepair, assessed by the reduction in competitive inhibition of the in vitro repair system depends appreciably on experimental parameters during photoreactivating treatment. Control experiments with non-UV-irradiated cells indicated that, depending on specific conditions, the photoreactivating treatment itself produces a varying amount of DNA damage, which reacts with the PRE in vitro. To avoid most of this kind of damage, cells are nitrogen-gassed and kept at 5°C during illumination, and the photoreactivating light must not contain wavelengths shorter than 380–400 nm. Our results show that wavelengths >470 nm are still very effective, whereas wavelengths >555 nm are ineffective in photorepairing potoroo DNA. For unknown reasons, one particular strain of potoroo cornea cells lost its potential for photorepair. Treatment of unirradiated potoroo cells, or their extracted DNA, with hydrogen peroxide also results in competitive inhibition of photorepair in vitro, resembling that observed after near-UV illumination. Because of the occurrence of synergistic effects it is not clear whether the damage only interacts with PRE or can actually be photorepaired under appropriate conditions.

The results presented in this paper suggest that the expression of photorepair in mammalian cells, unlike that in prokaryotes, greatly depends on a number of experimental parameters, including the spectral composition of photoreactivating light. Apparently superposition of damage by the photoreactivating treatment itself is the critical factor. This may explain experimental discrepancies existing in different laboratories studying photorepair in UV-irradiated cells of placental mammals.     

Plasma membrane and lysosomal localization of CB1 cannabinoid receptor are dependent on lipid rafts and regulated by anandamide in human breast cancer cells

In this report we show, by confocal analysis of indirect immunofluorescence, that the type-1 cannabinoid receptor (CB1R), which belongs to the family of G-protein-coupled receptors, is expressed on the plasma membrane in human breast cancer MDA-MB-231 cells. However, a substantial proportion of the receptor is present in lysosomes. We found that CB1R is associated with cholesterol- and sphyngolipid-enriched membrane domains (rafts). Cholesterol depletion by methyl-beta-cyclodextrin (MCD) treatment strongly reduces the flotation of the protein on the raft-fractions (DRM) of sucrose density gradients suggesting that CB1 raft-association is cholesterol dependent. Interestingly binding of the agonist, anandamide (AEA) also impairs DRM-association of the receptor suggesting that the membrane distribution of the receptor is dependent on rafts and is possibly regulated by the agonist binding. Indeed MCD completely blocked the clustering of CB1R at the plasma membrane. On the contrary the lysosomal localization of CB1R was impaired by this treatment only after AEA binding.     

Developmental studies on the Sigma and Delta-1 glutathione transferases of Lucilia cuprina

The glutathione transferases (GSTs) are a large group of enzymes having both detoxication roles and specialist metabolic functions. The present work represents an initial approach to identifying some of these roles by examining the variation of specific members of the family under differing conditions. The GSTs from Lucilia cuprina have been partially purified, members of two families being isolated, by the use of glutathione immobilised on epichlorhydrin-activated Sepharose 6B. The GSTs were separated by 2D SDS-PAGE and characterised by MALDI-TOF analysis of tryptic peptides. The mass fragments were then matched against the corresponding Drosophila melanogaster and Musca domestica sequences. GSTs were identified as coming from only the Sigma and Delta classes. The multiple Delta zones appear all to be derived from the Lucilia GSTD1 isoform. The distribution of these GST proteins has been studied during different developmental stages of the insect. Delta isoforms were present in all developmental stages of L. cuprina. The Sigma GST was not detectable in the egg, was just detectable in the larval and pupal stages and was the major GST isolated in the adult. Sigma and Delta isoforms were both found in all body segments of the insect. Both isoforms appear to undergo extensive post-translational modification. Activities of the two types of protein with model substrates have been determined.