The evolutionary significance of vitamin D, skin pigment, and ultraviolet light.

Vitamin D is essential for normal growth, calcuim absorption, and skeletal development. Vitamin D deficiency can cause death, immobilization, or pelvic deformities which prevent normal childbirth. In the past these problems were extremely common in North America and Europe, and were only elminated by adding vitamin D to food. Prior to that, variations in available vitamin D affected health, survival and reproductive efficiency sufficiently to have evolutionary significance. Vitamin D is naturally present in few foods; most comes from the photo-conversion of 7-dehydrocholesterol in skin. The limiting factor in this conversion is the availability of ultraviolet light less than310 nm. Seasonal and geographic variations in natural ultraviolet radiation cause parallel variations in blood vitamin D levels, intestinal calcuim absorption, and clinical vitamin D deficiency. These physiological variations can be abolished by exposure to comparable artificial ultraviolet radiation, or by dietary vitamin D supplements. Ultraviolet radiation less than310 nm is absorbed by skin pigment, but is also increases skin pigmentation. This has led to the hypothesis that skin pigment regulates skin vitamin D production. Little direct evidence exists to test this reasonable hypothesis, but necessary and sufficient conditions for establishing it can be outlined. Until this hypothesis is experimentally tested, it is impossible to evaluate the corollary hypothesis: that racial variations in the efficiency of cutaneous vitamin D production restricted the evolution of dark-skinned peoples to tropical latitudes and thereby caused the geographic distribution of the races.     

The effects of actinomycin D and cordycepin on neurite formation and acetylcholinesterase activity in mouse neuroblastoma cells

Actinomycin D (actD) (0.003–0.10 μg/ml) and cordycepin (3–30 μg/ml) were used to examine the requirement of de novo RNA synthesis in the pH 6.6-induced expression of neurites and acetylcholinesterase activity in C-1300 mouse neuroblastoma cells. ActD at 0.03 and 0.10 μg/ml caused a pronounced stimulation in neurite formation following 20 h of treatment, although by 30 h exposure to actD (0.01–0.10 μg/ml), neurite formation had rapidly declined. Cordycepin (3–30 μg/ml) also inhibited neurite formation in a concentration- and time-dependent manner, although it did not produce an initial stimulation in neurite formation. The pH 6.6-induced increase in acetylcholinesterase activity was inhibited by both actD and cordycepin in a concentration- and time-dependent manner. Cell viabilities in the presence of actD and cordycepin were 90% or greater throughout the course of these studies.The effects of actD on [³H]uridine and [³H]leucine transport into cells and on incorporation into acid-insoluble material showed that actD inhibited RNA synthesis to a greater extent than it inhibited protein synthesis. Cordycepin caused only minor effects on [³H]uridine and [³H]leucine transport into cells and incorporation into acid-insoluble material; these effects were variable and neither concentration- nor time-dependent. The results of this study show that actD can inhibit the pH 6.6-induced expression of neurites and acetylcholinesterase activity in mouse neuroblastoma cells at concentrations which were relatively non-toxic and which caused a greater inhibition of RNA synthesis than of protein synthesis. This suggests that de novo RNA synthesis is required for the expression and maintenance of neurites and acetylcholinesterase activity in mouse neuroblastoma cells. Experiments with cordycepin were consistent with this conclusion.     

Correlation between resistance to actinomycin D, karyology, agglutination by concanavalin A and tumorigenicity in Chinese hamster hybrid cells.

Subclones isolated from a Chinese hamster hybrid line, derived from fusion of an actinomycin D-resistant and an actinomycin D-sensitive strain, were studied with respect to their resistance to actinomycin D, karyology, transplantability and agglutination by concanavalin A. Statistical analysis of the results allowed the establishment of a classification of the strains based on increasing resistance to actinomycin D. There appeared to be an inverse correlation between actinomycin D-resistance and tumorigenicity and a positive correlation between this resistance and the presence of a marker chromosome.     

Isolation of uvh1, an Arabidopsis mutant hypersensitive to ultraviolet light and ionizing radiation.

A genetic screen for mutants of Arabidopsis that are hypersensitive to UV light was developed and used to isolate a new mutant designated uvh1. UV hypersensitivity in uvh1 was due to a single recessive trait that is probably located on chromosome 3. Although isolated as hypersensitive to an acute exposure to UV-C light, uvh1 was also hypersensitive to UV-B wavelengths, which are present in sunlight that reaches the earth's surface. UV-B damage to both wild-type and uvh1 plants could be significantly reduced by subsequent exposure of UV-irradiated plants to photoreactivating light, showing that photoreactivation of UV-B damage is important for plant viability and that uvh1 plants are not defective in photoreactivation. A new assay for DNA damage, the Dral assay, was developed and used to show that exposure of wild-type and uvh1 plants to a given dose of UV light induces the same amount of damage in chloroplast and nuclear DNA. Thus, uvh1 is not defective in a UV protective mechanism. uvh1 plants were also found to be hypersensitive to ionizing radiation. These results suggest that uvh1 is defective in a repair or tolerance mechanism that normally provides plants with resistance to several types of DNA damage.     

Inhibition of microtubule assembly by actinomycin D, an anti-tumour drug

Effect of actinomycin D, an antibiotic, was investigated on the biological function of tubulin from bovine brain. The microtubule assembly was inhibited nearly completely when an equal molar ratio of actinomycin D and tubulin was used. The depolymerisation of the same, however, was not altered under the same conditions. The competence of tubulin to bind colchicine and GTP was also not affected. Chromatographic and the spectrophotometric studies showed that 0.94 mol of actinomycin D binds per mole of tubulin.     

Photosynthetic metabolism of an antarctic diatom and its physiological responses to fluctuations in light

Summary The short-term incorporation of NaH¹⁴CO₃ (10 to 60 s) into photosynthetic products has been studied in the antarctic diatom Nitzschia turgiduloides. It appears that there are two pathways of inorganic carbon assimilation: the C₃ pathway (Calvin cycle) principally, on which are superimposed -carboxylation reactions. Photorespiration, which contributes to decrease the net photosynthesis rate, has also been reported. With regard to these results the antarctic diatom was not different from the temperate one. However, the antarctic diatom presents some distinctive features. -carboxylation reactions which are probably favoured in Antarctic waters because of the high nitrate or ammonium concentrations, and also because they are more economical in terms of energy, are enhanced at the expense of the Calvin cycle reactions. On the other hand, the photorespiration rate is lower than that observed in temperate species, leading to an enhancement of net photosynthesis rate; this seems to occur principally by the more advantageous tartronic semialdehyde pathway. These two features are more pronounced for cells grown under light: dark cycles, particularly a 2:2 hour regime, as compared to continuous light. By contrast to the temperate species Skeletonema costatum, changes in the light regime modifies not only the relative amount of inorganic carbon assimilated by the C₃ or the -carboxylation pathways, but also the total amount of CO₂ incorporated per g Chl a. The productivity is highest in 2:2 regime, which simulates conditions of vertical mixing encountered in Antarctic Ocean more than does a 12:12 regime. This finding corroborates the view that the antarctic diatom is well adapted to its environment, although its production is not optimal compared to that of the temperate species grown under the same conditions of irradiance and temperature. Whether this is a genetic adaptation needs to be examined.     

Selective binding of actinomycin D and distamycin A to DNA.

The exact sites at which a number of drugs inhibit the nick translation of DNA by E.coli DNA polymerase-I have been pinpointed. In order to do this, a method has been developed for sequencing double-stranded plasmid DNA from the site of a specifically induced nick. The initial experiments have concentrated on analysis of drug inhibition of nick translation in a 200 nucleotide region near the Eco Rl origin of pBR313. Many drugs were found to inhibit nick translation in a highly sequence specific manner. For actinomycin D, significant inhibition occurred at just four sites in the nucleotide sequence under test and only one sequence (pGpCpGpCpGpGp) gave really strong inhibition. Distamycin A gave a different pattern of inhibition with particularly strong stops in just two of the many A-T rich regions in the DNA. Experiments with caffeine suggest that factors in addition to primary sequence are important in determining where major inhibition occurs.     

A new approach to the design of hybrid hybridomas based on the use of an actinomycin D-resistant line of murine myeloma]

The hybrid hybridomas (tetradomas) were produced from the fusion of the double mutant actinomycin Dr (ADr)/HATs hybridoma to horseradish peroxidase (HRP) and wild type hybridoma to alpha-endorphin (EP). The double mutant phenotype was constructed using the new strategy, based on the fusion of immune mouse splenocytes with mouse myeloma (X63.Ag8, 653) cell variants, made resistant to 30 ng/ml of AD by stepwise selection. This allowed the direct introduction of the dominant selective marker (ADr) into the hybrid cells. Tetradomas secreted the bispecific monoclonal antibodies (bi Mabs), simultaneously binding to EP and HRP in double antigen ELISA, the ELISA plates covered with EP-bovine serum albumin conjugate. Using rat pituitary the bi Mabs were shown to be effective for immunostaining of EP-producing cells. EP-producing cells.     

Identification ofStreptomyces sp. Tc022, an endophyte inAlpinia galanga, and the isolation of actinomycin D

Some endophytic actinomycetes (120) were isolated from the roots ofAlpinia galanga. Identification of these endophytes was based on their morphology and amino acid composition of the whole-cell extract. Most isolates were classified aStreptomyces sp. (82), with the remainder belonging toNocardia sp. (11),Microbispora sp. (3) andMicromonospora sp. (2). Eight isolates were unclassified and 14 were lost during subculture. The strain identified as endophyticStreptomyces sp. Tc022 strongly inhibitedColletotrichum musae andCandida albicans. This endophyte was cultured, the agar was extracted with organic solvent and the extract was purified on a column of silica gel to give a major component, which was identified to be actinomycin D on the basis of spectroscopic dat Actinomycin D showed antifungal activity againstColletotrichum musae andCandida albicans with the MIC of 10 and 20 mg ml^?1, respectively.     

Ultraviolet resonance Raman study of DNA and of its interaction with actinomycin D.

The DNA-Actinomycin D interaction has been studied by resonance Raman effect using DNA as chromophore. First, the resonance Raman spectra of DNA obtained with a U.V. excitation at wavelengths of 300 nm and 280 nm are presented. The main Raman hands are assigned to the convenient nucleic bases by comparison with the spectra of mononucleotides obtained under the same experimental conditions. In particular, with a 300 nm excitation, the 1582 cm-1 line is provided by adenine, while the 1492 cm-1 one is almost exclusively due to guanine. Then, the DNA-Actinomycin D complex has been studied: the line enhancements and the specificity of the resonance permits the displaying of the DNA spectrum free of any contribution of Actinomycin. The interaction provides a large intensity decrease of the 1492 cm-1 guanine line: this is a direct consequence of the orbital overlapping of the guanine 2-aminogroup with the ring nitrogen of Actinomycin in the DNA-Actinomycin pi complex.     

Inducible cellular responses to ultraviolet light irradiation and other mediators of DNA damage in mammalian cells

Summary Both naturally occuring and carcinogen-induced tumors display not only point mutations in cellular oncogenes but also more complex changes in cellular oncogenes and other cellular genes. For this and other reasons, it seems likely that DNA damage in mammalian cells can induce alterations in gene expression that may have both short and long term consequences in the target cell. The purpose of this review is to summarize current available information on inducible responses to UV-irradiation and other mediators of DNA damage in mammalian cells, and to provide some working hypotheses. We have divided these responses into three time frames, immediate (0–12 hours), early (12–48) and late (beyond 48 hours). Immediate responses include the action of DNA repair enzymes, some of which are induced as a consequence of DNA damage, and transient inhibition of DNA synthesis. Within the past few years considerable evidence has accumulated that during this immediate period there is increased expression of certain cellular oncogenes, proteases and proteins whose functions remain to be identified. It is of interest that the expression of some of these genes is also induced by certain growth factors, tumor promoters and heat shock. Alterations in gene expression during the subsequent early period (12–48 hrs.) have not been studied in detail, but it is during this period that one can detect increased replication of several types of viruses in cells that harbor these viruses. We have examined in detail the induction of asynchronous polyoma DNA replication (APR) in a rat fibroblast cell line carrying integrated copies of this DNA. We have obtained evidence that UV-irradiation of these cells leads to the synthesis of a 40 kd protein, within the first 1–24 hrs after irradiation, that binds to a specific sequence TGACAACA in the regulatory region of polyoma DNA. We suggest that this protein acts together with other proteins to induce APR and that this serves as a useful model for understanding the mechanisms responsible for amplification of cellular genes, a phenomenon often seen in malignant tumors. Finally, we discuss how the events occurring during the immediate and early periods following DNA damage might lead to late effects in the target cell that are stable and contribute to the genotype and phenotype of some of the progeny of these cells that are destined to become tumor cells.     

Identification of a putative ribosomal protein mRNA in Chironomus riparius and its response to cadmium, heat shock, and actinomycin D

A putative ribosomal protein (rp) mRNA in Chironomus riparius has been found using differential display (DD). Its sequence has 84.8% identity with mosquito rp L8, Aedes albopictus, and is approximately 0.9 kb. Studies were undertaken in order to evaluate rp as a control for environmentally relevant genes. Responses of Drosophila heat shock 70 gene (hsp70) were used to establish heat shock temperatures and cadmium (Cd) concentrations for Chironomus experiments and to validate DD. Expression of hsp70 was induced over control by 28 degrees C at 30 minutes and 1 mM Cd at 24 hours (p< or =0.05). For Chironomus, DD, Northern blot, and nuclease sensitivity were used to measure responses to two stressors: heat shock for 30 minutes and Cd for 24 or 48 hours. Differential display and nuclease sensitivity assays found expression of rp mRNA at 37 degrees C and 16 mM Cd to be similar to controls. Northern blots indicated statistically significant effects for heat shock (p = 0.046) but not Cd (p = 0.406). However, mRNA levels at 37 degrees C were increased only 1.72-fold over controls. A concentration of 24 nM actinomycin D suppressed rp expression as measured by nuclease sensitivity assays. Stressors should not affect rp mRNA levels below their LC-50s.     

Dimerization of Escherichia coli UvrA and its binding to undamaged and ultraviolet light damaged DNA

The initial stages in the repair of damaged DNA by the Escherichia coli uvr system involve the recognition of damage by UvrA. We have examined in detail the binding of UvrA to DNA randomly damaged by ultraviolet light, undamaged DNA, and single-stranded DNA using nitrocellulose filter binding and gel mobility shift assays to arrive at the following model: UvrA dimers bind specifically to damaged DNA both in the presence and in the absence of ATP. The dimerization of UvrA is promoted by UvrA concentrations greater than 1 nM, the presence of ATP, or physiological temperatures, and the dimerization step dominates the temperature dependence of UvrA binding to DNA damaged by ultraviolet light. The apparent association constant for specific binding is dependent on the concentration of UvrA due to coupled dimerization, aggregation, and nonspecific binding reactions. At 1 nM UvrA, either with or without ATP, Kuv approximately 10(9) M-1. The binding of UvrA to undamaged DNA is 10(3)-10(4)-fold weaker than the damage-specific binding. Both the strength of damage-specific binding and the discrimination between damaged and undamaged sites are affected by the salt concentration. The kinetics of association and dissociation reactions indicate that the primary effects of ATP are on the extent of UvrA dimerization rather than on the properties of the UvrA-uvDNA complex. The complexity of the interaction of UvrA, ATP, and DNA is indicated by the opposing effects of ATP binding and hydrolysis on UvrA dimerization.