Ultrastructural alterations in ciliary cells exposed to ionizing radiation

Summary Early effects of ionizing radiation were investigated in an experimental in vitro system using the ciliary cells of the tracheal mucous membrane of the rabbit, irradiated at 30° C and at more than 90% humidity. The changes in physiological activities of the ciliary cells caused by irradiation were continuously registered during the irradiation. The specimens were examined immediately after irradiation electron microscopically. The morphological changes in irradiated material after 10–70 Gy are compared with normal material. After 40–70 Gy, scanning electron microscopy revealed the formation of vesicles on cilia, and club-like protrusions and adhesion of their tips. After 30–70 Gy, a swelling of mitochondrial membranes and cristae was apparent transmission electron microscopically. The membrane alterations caused by irradiation are assumed to disturb the permeability and flow of ATP from the mitochondria, which in turn leads to the recorded changes in the activity of the ciliated cells.This investigation was supported by grants from Konung Gustaf V:s Jubileumsfond, John and Augusta Perssons Stiftelse, B. Kamprads Fond, the Faculty of Medicine, University of Lund, Sweden and the Swedish Medical Research Council (No. B77-17X-03897-05)The authors are greatly indebted to Miss Inger Norling, Miss Marianne Palmegren and Miss Birgitta Sandström for their excellent technical assistance     

Replication and amplification of recombinant plasmid molecules as extra chromosomal elements in transformed mammalian cells

Mouse thymidine kinase negative (TK^?) L cells, F4-12B2TK^? Friend erythroleukemic cells and hamster BHKTK^? cells were transformed in the absence of carrier DNA with closed circular molecules of herpes simplex virus 1 TK DNA cloned in plasmid pAT153 (pTK-1). The physical status of donor DNA in the transformed cells was studied by Southern blot hybridization and spot hybridization techniques. Up to 65 copies of pTK-1 DNA molecules/cell were present in transformed cells grown under selective conditions. Whereas a steady increase in the number of pTK-1 copies/cell was found during the first few weeks of growth in selective medium, 2–8 months later copy numbers varied within the same cell line and their numbers rarely exceeded fifty copies/cell. Donor DNA sequences were found both in the Hirt precipitate and in the supernatant showing that some of the pTK-1 molecules existed in circular form. Many of the cell lines gave a Southern blot hybridization pattern indicative of pTK-1 sequences integrated into high molecular weight DNA as well as present in a circular configuration.     

Asymmetric somatic cell hybridization in plants

As part of an investigation into whether it would be possible to use UV radiation as a suitable pretreatment of the donor cells in asymmetric hybridization experiments, the effects of this treatment on sugarbeet (Beta vulgaris L.) protoplast DNA have been determined and compared with those of gamma radiation. Both nuclear and mitochondrial DNAs have been examined. The dose ranges chosen had previously been determined to be potentially applicable for fusion experiments. Pulsed field gel electrophoresis and standard agarose gel electrophoresis have been used in combination with laser scanning densitometry to gain an insight into the precise nature and degree of DNA damage resulting from irradiation. It was observed that UV radiation introduced substantial modifications to sugarbeet DNA. Double-strand breaks were detected, the number of which was found to be directly proportional to the dose applied. Such breaks indicate that UV radiation results in substantial chromosome/chromatid fragmentation in these cells. Chemical modifications to the DNA structure could be revealed by a significant reduction in DNA hybridization to specific mitochondrial and nuclear DNA probes. Following gamma irradiation at equivalent biological doses (i.e. those just sufficient to prevent colony formation) much less damage was detected. Fewer DNA fragments were produced indicating the presence of fewer double-strand breaks in the DNA structure. In comparison to UV treatments, DNA hybridization to specific probes following gamma radiation was inhibited less. For both treatments, mitochondrial DNA appeared more sensitive to damage than nuclear DNA. The possibility that DNA repair processes might account for these differences has also been investigated. Results indicate either that repair processes are not involved in the effects observed or that DNA repair occurs so fast that it was not possible to demonstrate such involvement with the experimental system used. The general relevance of such processes to asymmetric cell hybridization is discussed.     

Roles of iron in neoplasia

Research and clinical observations during the past six decades have shown that: 1. Iron promotes cancer cell growth; 2. Hosts attempt to withhold or withdraw iron from cancer cells; and 3. Iron is a factor in prevention and in therapy of neoplastic disease. Although normal and neoplastic cells have similar qualitative requirements for iron, the neoplastic cells have more flexibility in acquisition of the metal. Excessive iron levels in animals and humans are associated with enhanced neoplastic cell growth. In invaded hosts, cytokine-activated macrophages increase intracellular ferritin retention of the metal, scavenge iron in areas of tumor growth, and secrete reactive nitrogen intermediates to effect efflux of nonheme iron from tumor cells. Procedures associated with lowering host intake of excess iron can assist in prevention and in management of neoplastic disease. Chemical methods for prevention of iron assimilation by neoplastic cells are being developed in experimental and clinical protocols. The antineoplastic activity of a considerable variety of chemicals, as well as of radiation, is modulated by iron. The present article focuses on recent findings and suggests directions for further cancer-iron research.     

L'intensité lumineuse,son influence sur la teneur en phosphore des carapaces d'Ostracodes

Actual and fossil shells of ostracodes have beenanalyzed with an electronic microprobe: all of them contain phosphorus. X—pictures teach us that the repartition of this chemical element is homogeneous in all the points of the shell. There is no relationship between phosphorus contents in the shells of ostracodes and salinity. In return, there is a relationship between phosphorus contents and temperature and, chiefly, organic phosphorus contents in the environment. However, it is interesting to observe that the analyzed shells of fresh-water ostracodes contain less phosphorus that the generality of the shells of marine ostracodes. The contents of organic phosphorus, in the biotope, depends on the growth of phytoplancton in the upper layers of water which needs a minimum light intensity.     

A proteomic and phosphoproteomic landscape of KRAS mutant cancers identifies combination therapies

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NK cells: An attractive candidate for cancer therapy

Natural killer (NK) cells have significant capability in tumor immune-surveillance. The ability of lyse transformed cells immediately in an antigen-independent manner make them an attractive candidate for cancer cell therapy. Despite employment of NK cells in cancer immunotherapy, clinical trials are faced with serious limitations such as trouble with the penetration of NK cells in tumor sites, limited in vivo persistence, and tumor microenvironment interference. Taken together, the NK-cell cancer therapy is still infant scenario that has a long way to be translated in clinic. Current article first reviews characteristic features of NK lymphocytes. Then, it discusses about important disruptive barriers and motivator in the developmental stages of NK cells like as tumor microenvironment. Finally, some revolutionary approaches are highlighted utilizing of NK cells in cancer therapy.     

Development of a human three-dimensional organotypic skin-melanoma spheroid model for in vitro drug testing

Despite remarkable efforts, metastatic melanoma (MM) still presents with significant mortality. Recently, mono-chemotherapies are increasingly replenished by more cancer-specific combination therapies involving death ligands and drugs interfering with cell signaling. Still, MM remains a fatal disease because tumors rapidly develop resistance to novel therapies thereby regaining tumorigenic capacity. Although genetically engineered mouse models for MM have been developed, at present no model is available that reliably mimics the human disease and is suitable for studying mechanisms of therapeutic obstacles including cell death resistance. To improve the increasing requests on new therapeutic alternatives, reliable human screening models are demanded that translate the findings from basic cellular research into clinical applications. By developing an organotypic full skin equivalent, harboring melanoma tumor spheroids of defined sizes we have invented a cell-based model that recapitulates both the 3D organization and multicellular complexity of an organ/tumor in vivo but at the same time accommodates systematic experimental intervention. By extending our previous findings on melanoma cell sensitization toward TRAIL (tumor necrosis factor-related apoptosis-inducing ligand) by co-application of sublethal doses of ultraviolet-B radiation (UVB) or cisplatin, we show significant differences in the therapeutical outcome to exist between regular two-dimensional (2D) and complex in vivo-like 3D models. Of note, while both treatment combinations killed the same cancer cell lines in 2D culture, skin equivalent-embedded melanoma spheroids are potently killed by TRAIL+cisplatin treatment but remain almost unaffected by the TRAIL+UVB combination. Consequently, we have established an organotypic human skin-melanoma model that will facilitate efforts to improve therapeutic outcomes for malignant melanoma by providing a platform for the investigation of cytotoxic treatments and tailored therapies in a more physiological setting.     

Cell sheet technology: a promising strategy in regenerative medicine

Regenerative medicine is a burgeoning field that is important to combat challenging diseases and functional impairments. Compared with traditional cell therapies with evident shortcomings (e.g., cell suspension injection or tissue engineering with scaffolds), scaffold-free cell sheet technology enables transplanted cells to be grafted and fully maintain their viability on target sites. Clinical and experimental studies have advanced the application of cell sheet technology to numerous tissues and organs (e.g., liver, cornea and bone). However, previous reviews have failed to discuss vital aspects of this rapidly developing technology, and many new challenges are gradually emerging. This review aims to provide a comprehensive introduction to cell sheet technology from cell selection to the ultimate applications of cell sheets, and challenges and future visions are also described.