The study of complex-formation of DNA with the antimicrobial drug decamethoxine

The interaction of effective antibacterial drug decametoxyn with natural DNA was studied by UV-spectroscopy. Decametoxyn shows a specificity to nucleotides: it decreases the cooperativity of melting and the thermal stability of DNA parts enriched by AT pairs. The characteristics of the helix-coil transition on the DNA parts enriched by GC-pairs are invariable. Interaction with AT-pairs results in their partial or complete melting at room temperature, followed by intermolecule aggregation. Interacting with phosphates decametoxyn manifests itself not as a dication but as two single-charged ions.     

Microcalorimetric study of the oncogene EJ and proto-oncogene EC in the plasmid pBR 322

Thermodynamic parameters were obtained of melting of the linear form of plasmids pBR 322 and plasmids pBR 322 with incorporated oncogene EC. The melting temperature of the main stage of heat absorption of the oncogene EJ was shown to be 1.6 degrees C lower than in the norm (EC). It is suggested that the thermostability change observed is related not only with point mutations of high-melting GC-pairs of bases for more low melting AT-pairs, but evidently with the structural changes in the DNA double helix as well.     

Comparative study of human chromosome replication in primary cultures of embryonic fibroblasts and in cultures of peripheral blood leucocytes

By autoradiography with ³H-thymidine and ³H-deoxycytidine it is shown that chromosomes 1 and 16 in cultures of embryonic fibroblasts at the termination of the S period synthesise AT- and GC-rich DNA at different rats: in both chromosomes the labelling of AT-bases is more intensive. In leucocyte cultures both nucleotide pairs label equally in these chromosomes. Chromosomes 2, 3, 4–5 and 21–22 are labelled equally in both cultures with respect to AT-and GC-pairs. Fibroblasts and leucocytes differ in the relative intensity of DNA synthesis at the end of the S period: chromosomes 1,16 and 21–22 contain more label in the case of fibroblasts (chromosome 1 solely due to AT-pairs) and chromosome 4–5 in the case of leucocytes. Analysis of distribution of late label along chromosome 1 showed that in fibroblast cultures the pericentromeric regions of both arms are labelled more intensively in respect to both nucleotide pairs than in leucocyte cultures. Both in fibroblast and leucocyte cultures no significant distinctions in the distribution of AT-and GC-pairs along chromosome 2 were established. In fibroblast cultures the pericentromeric regions of both arms of chromosome 3 are labelled more intensively than other regions. In leucocyte cultures the pericentromeric region of the short arm of this chromosome is labelled with the same intensively as in fibroblasts, whereas in the pericentromeric region of the long arm the intensity of incorporation of labelled synthesis precursors decreases. — Analysis of results obtained in the present study together with data of previous studied (Slesinger et al., 1974; Lozovskaya et al., 1976; Lozovskaya et al., 1977) shows that differences between the two types of cells in the intensity of late ³H-thymidine labelling in the C-heterochromatin regions of chromosomes 1 and 16 may be explained both by variation of replication time in leucocytes as compared with fibroblasts and by variation of the content of AT- rich DNA. Differences observed in other chromosomes are probably due to different times of replication of these chromosomes in leucocytes and fibroblasts. — Thus, the process of cell system differentiation involves not only differential activity of the genome (the main mechanism) that is connected with differences in the replication time of chromosomes and of their regions but also variation of the quantity of genetic material.     

Compositional Heterogeneity and Patterns of Molecular Evolution in the Drosophila Genome

The rates and patterns of molecular evolution in many eukaryotic organisms have been shown to be influenced by the compartmentalization of their genomes into fractions of distinct base composition and mutational properties. We have examined the Drosophila genome to explore relationships between the nucleotide content of large chromosomal segments and the base composition and rate of evolution of genes within those segments. Direct determination of the G + C contents of yeast artificial chromosome clones containing inserts of Drosophila melanogaster DNA ranging from 140-340 kb revealed significant heterogeneity in base composition. The G + C content of the large segments studied ranged from 36.9% G + C for a clone containing the hunchback locus in polytene region 85, to 50.9% G + C for a clone that includes the rosy region in polytene region 87. Unlike other organisms, however, there was no significant correlation between the base composition of large chromosomal regions and the base composition at fourfold degenerate nucleotide sites of genes encompassed within those regions. Despite the situation seen in mammals, there was also no significant association between base composition and rate of nucleotide substitution. These results suggest that nucleotide sequence evolution in Drosophila differs from that of many vertebrates and does not reflect distinct mutational biases, as a function of base composition, in different genomic regions. Significant negative correlations between codon-usage bias and rates of synonymous site divergence, however, provide strong support for an argument that selection among alternative codons may be a major contributor to variability in evolutionary rates within Drosophila genomes.     

Analysis of DNA degradation in the thymocytes of irradiated rats by flow cytometry

The method of flow cytofluorometry of cells treated with probes specifically bound to AT- or GC-pairs of DNA was used to study DNA degradation in thymocytes of irradiated and hydrocortisone-treated rats. Death of thymocytes was shown to be accompanied by the decrease in the DNA content. The main regularities in the formation and accumulation of cells, the DNA content of which being lower than that of diploid cells, were the same as those of the internucleosome DNA fragmentation.     

DNA and the theory of stabilizing selection

A comparison of structural-functional features of genomic DNAs allowed to estimate the role of internal and external factors in evolution of different groups of organisms. The basic difference between higher and lower organisms has been demonstrated. It is reflected in the difference of their reaction on to external factors in accordance with two adaptation types, the openness and autonomization. There is a correlation between structural-functional organization of genomic DNAs of higher and lower organisms and the above mentioned types of adaptation. DNA of lower organisms has been proposed to be characterized as "labile", and that of higher organisms, as "stable". The "DNA lability" means high mutation ability, which characterizes the existence of and evolution of lower organisms (genetic inconstancy of the lower organisms). On the contrary, "DNA stability" means the creation of stable genetic apparatus, reduction of variability in higher organisms (genetic constancy of higher organisms). This suggests the existence of the two principal ways of evolution.     

DNA-binding and antiviral activities of bis-netropsins

The DNA-binding and antiviral activitus of bis-netropsins in which two monomers are attached covalently via three glycin residue were studied. These compounds have the same C-end groups but contain clusters with different numbers of lysine residues at the N-end of the molecule. In the homologous series of these compounds, bis-neropsins containing 15 and 31 branched lysine residues at the N-end of the molecule appear to be the most effective inhibitors of reproduction of the simplex herpes virus of type I in the Vero cell culture, including the virus versions resistant to aciclovir, ganciclovir, and other medicinal preparations. It was shown that the cytotoxicity of all the compounds studied is much lower than that of netropsin. The antiviral activity of the compounds correlates with their ability to selectively interact with the expanded clusters of the AT-pairs of DNA bases in the form of a monomer or a dimer, stabilized by interaction between the C-end halves of two bis-netropsin molecules bound at the neighboring overlapping binding sites on the DNA. The possible sites of their binding are the expanded clusters of AT-pairs at the origin of replication of OriS and OriL of the herpes virus.     

Effect of inversion polymorphism on the neutral nucleotide variability of linked chromosomal regions in Drosophila

Recombination is a main factor determining nucleotide variability in different regions of the genome. Chromosomal inversions, which are ubiquitous in the genus Drosophila, are known to reduce and redistribute recombination, and thus their specific effect on nucleotide variation may be of major importance as an explanatory factor for levels of DNA variation. Here, we use the coalescent approach to study this effect. First, we develop analytical expressions to predict nucleotide variability in old inversion polymorphisms that have reached mutation-drift-flux equilibrium. The effects on nucleotide variability of a new arrangement appearing in the population and reaching a stable polymorphism are then studied by computer simulation. We show that inversions modulate nucleotide variability in a complex way. The establishment of an inversion polymorphism involves a partial selective sweep that eliminates part of the variability in the population. This is followed by a slow convergence to the equilibrium values. During this convergence, regions close to the breakpoints exhibit much lower variability than central regions. However, at equilibrium, regions close to the breakpoints have higher levels of variability and differentiation between arrangements than regions in the middle of the inverted segment. The implications of these findings for overall variability levels during the evolution of Drosophila species are discussed.     

Selective effect of ionization of nitrogen bases on the thermostability of AT- and GC-pairs of DNA

The ionization specific influence of nitrogen bases on thermostability of AT- and GC-pairs of DNA has been investigated by the method of DNAs melting temperature analysis. It has been shown that the change of temperature interval of DNA helix-coil transition when changing pH environment is due to specific ionization of AT- and GC-pairs of nitrogen bases.     

Flow cytometry analysis of DNA degradation in thymocytes of gamma-irradiated or hydrocortisone treated rats

The pattern of DNA degradation in thymocytes of irradiated or hydrocortisone-treated rats has been studied by means of flow cytometry of the cells, treated with probes specifically bound to the AT or GC-pairs of DNA. It has been shown that the death of thymocytes is accompanied by a decrease in their DNA content. The main features of the occurrence and accumulation of cells with a DNA content less than the normal diploid level correspond with those of internucleosomal DNA fragmentation: such cells appear after a 1 hour lag-period, their accumulation is prevented by cycloheximide injection and is lower at 300 Gy than at doses of 10 to 30 Gy. At the same time, no increase in permeability of the cell membrane to ethidium bromide was observed up to the sixth hour after irradiation. Most of the thymocytes dying under the action of irradiation or hydrocortisone are in the G0 or G1 phases of the cell cycle. The method used allows detection of the cells with cleaved but not removed DNA.     

87 The melting of DNA in the presence of meso-tetra-pyridyl porphyrins with different peripheral substituents

The influence of water-soluble cationic 3N- and 4N-pyridyl porphyrins with different peripheral substituents (oxyethyl, buthyl, allyl, and metallyl) on melting parameters of DNA has been studied. Results indicate that the presence of porphyrin changes the shape and parameters of DNA melting curve. The increase of porphyrins concentration results in the increase of the melting temperature (Tm) and the melting interval (ΔT) of DNA. At the porphyrin-DNA concentration ratio r?=?0.01, changes in the melting temperature have not been observed. The melting intervals almost do not change upon adding of the 4N-porphyrins, while the decrease of ΔT, in the presence of 3N-porphyrins, is observed. Because the intercalation binding mechanism occurs in GC-rich regions of DNA, we assume that 3N-porphyrins, intercalated in GC-rich regions, reduce the thermal stability of these sites, bringing them closer to the thermal stability of the AT-sites, which is the reason for the decrease in the melting interval. While at the relative concentration r?=?0.01 for 4-N porphyrins, already the external binding mechanism “turns on” and the destabilizing effect of porphyrins on GC-pairs compensates stabilizing effect on AT-pairs, as a result of which change in the melting of DNA upon complexation with these porphyrins is not observed. The decrease of the hypochromic effect also indicates the intercalation of investigated porphyrins in the DNA structure, which weakens the staking interaction of base pairs of DNA. The increase of the hypochromic effect of DNA upon binding with porphyrin depends on the type of peripheral substituents of the porphyrin. The results show that porphyrins with butyl and allyl substituents weaken staking interaction of base pairs less than porphyrins with other substituents. The largest change was observed for metallyl porphyrins. It can be the result of bulky peripheral substituents, which make significant local changes in DNA structure.     

Ribonucleotide discrimination by translesion synthesis DNA polymerases

The well-being of all living organisms relies on the accurate duplication of their genomes. This is usually achieved by highly elaborate replicase complexes which ensure that this task is accomplished timely and efficiently. However, cells often must resort to the help of various additional “specialized” DNA polymerases that gain access to genomic DNA when replication fork progression is hindered. One such specialized polymerase family consists of the so-called “translesion synthesis” (TLS) polymerases; enzymes that have evolved to replicate damaged DNA. To fulfill their main cellular mission, TLS polymerases often must sacrifice precision when selecting nucleotide substrates. Low base-substitution fidelity is a well-documented inherent property of these enzymes. However, incorrect nucleotide substrates are not only those which do not comply with Watson–Crick base complementarity, but also those whose sugar moiety is incorrect. Does relaxed base-selectivity automatically mean that the TLS polymerases are unable to efficiently discriminate between ribonucleoside triphosphates and deoxyribonucleoside triphosphates that differ by only a single atom? Which strategies do TLS polymerases employ to select suitable nucleotide substrates? In this review, we will collate and summarize data accumulated over the past decade from biochemical and structural studies, which aim to answer these questions.     

Theoretical melting profiles and denaturation maps of DNA with known sequence: fdDNA.

Differential melting profiles and denaturation maps are calculated for fdDNA whose sequence of nucleotides has been determined recently. The melting profiles for the total DNA and a number of its restriction fragments are compared with experimental data taken from literature. The comparison enables one to correlate a number of peaks on experimental melting profiles with the melting out of concrete regions of the nucleotide sequence. For three fragments very strong end effects are demonstrated on both theoretical and experimental profiles. These anomalous end effects are shown to be connected with a region highly enriched with AT-pairs. A possible influence of the heterogeneity of stacking interaction on the results obtained is discussed in detail.     

DNA ANALYSIS OF EUKARYOTIC ALGAL SPECIES1

Plastid genomes of algae resemble those of terrestrial plants in form, size, and rate of nucleotide sequence change. They are circular and range in size from 73 kilobases (kb) to over 400 kb. Their many copies per cell can compose >15% of total cell DNA. Mitochondrial genomes, like plastid genomes, are present in high copy number in preparations of total algal cell DNA. Almost all known algal mitochondrial DNA genomes are relatively small, <50 kb; in some species they are linear, whereas in others they are circular. One of the persistent perplexities for phycologists is the question of what relationship two clones or two groups of organisms bear to each other. Several relatively simple techniques can reveal whether or not two organisms belong to the same clone. Total mitochondrial genome size can be compared directly between isolates, although identity in size does not necessarily mean identity in sequence. Restriction endonuclease digestion combined with probing permits comparison of DNA fragment patterns to see if there is identity or near identity between two samples. This methodology can be applied both to organelle genomes and to nuclear genomes. So far, restriction endonucleases cleave plastid and mitochondrial DNA of organisms belonging to the same gene pool into nearly identical fragment patterns, whereas organisms nearly or totally incapable of interbreeding display patterns wherein ? 50% of restriction fragments differ in position on an agarose gel after electrophoresis. Thus, organelle genomes may be the first choice for comparing both total size and restriction endonuclease fragment patterns to obtain an indication of whether two organisms are closely related. This methodology can be applied both to organisms in which interbreeding is easy to test and to the many algae in which homothallism or lack of sexual clones has precluded standard breeding analyses. With further data on variability levels within and between fertile populations, it may be possible to state with confidence whether a sample of morphologically similar organisms shares a common gene pool, even if their breeding cannot be manipulated experimentally.     

Characterization and Relatedness of Marine Vibrios Pathogenic to Fish: Deoxyribonucleic Acid Homology and Base Composition

Deoxyribonucleic acid (DNA) isolated from several pathogenic marine vibrios was utilized in studies of base composition and nucleotide sequence relationships. Patterns of relatedness inferred from DNA criteria were found to correlate closely with those inferred from morphological, physiological, and serological analysis of the same organisms. The utility of the phenotypic and genotypic approaches to the determination of relatedness is discussed.     

Relative roles of mutation and selection in the maintenance of genetic variability

The extent and pattern of protein and DNA polymorphisms are discussed with emphasis on the mechanism of maintenance of the polymorphisms. Statistical studies suggest that a large proportion of genetic variability at the molecular level is maintained by a mutation-drift balance. At some loci, such as those for histocompatibility in mammals, however, a form of overdominant selection seems to be involved. In the presence of overdominant selection, polymorphic alleles may be maintained for tens of millions of years, so that the number of nucleotide differences between alleles is often very large, as in the case of self-incompatibility alleles in plants. There are also an increasing number of examples in which an adaptive change of a morphological or physiological character is caused by a single nucleotide substitution. Nevertheless, these mutations seem to be a small proportion of the total nucleotide changes that contribute to genetic variability and evolution. Although there are many examples of frequency-dependent selection, this form of selection is apparently unimportant for the maintenance of genetic variability except in some special cases. Observations on the evolutionary change of DNA suggest that the driving force of evolution is mutation rather than selection.     

Directional mutation pressure,mutator mutations,and dynamics of molecular evolution

Using a general form of the directional mutation theory, this paper analyzes the effect of mutations in mutator genes on the G + C content of DNA, the frequency of substitution mutations, and evolutionary changes (cumulative mutations) under various degrees of selective constraints. Directional mutation theory predicts that when the mutational bias between A/T and G/C nucleotide pairs is equilibrated with the base composition of a neutral set of DNA nucleotides, the mutation frequency per gene will be much lower than the frequency immediately after the mutator mutation takes place. This prediction explains the wide variation of the DNA G + C content among unicellular organisms and possibly also the wide intragenomic heterogeneity of third codon positions for the genes of multicellular eukaryotes. The present analyses lead to several predictions that are not consistent with a number of the frequently held assumptions in the field of molecular evolution, including belief in a constant rate of evolution, symmetric branching of phylogenetic trees, the generality of higher mutation frequency for neutral sets of nucleotides, the notion that mutator mutations are generally deleterious because of their high mutation rates, and teleological explanations of DNA base composition. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

Contrasting patterns of gene diversity between microsatellites and mitochondrial SNPs in farm and wild Atlantic salmon

Levels of genetic variability at 12 microsatellite loci and 19 single nucleotide polymorphisms in mitochondrial DNA were studied in four farm strains and four wild populations of Atlantic salmon. Within populations, the farm strains showed significantly lower allelic richness and expected heterozygosity than wild populations at the 12 microsatellite loci, but a significantly higher genetic variability with respect to observed number of haplotypes and haplotype diversity in mtDNA. Significant differences in allele- and haplotype-frequencies were observed between farm strains and wild populations, as well as between different farm strains and between different wild populations. The large genetic differentiation at mitochondrial DNA between wild populations (F_ST = 0.24), suggests that the farm strains attained a high mitochondrial genetic variability when created from different wild populations seven generations ago. A large proportion of this variability remains despite an expected lower effective population size for mitochondrial than nuclear DNA. This is best explained by the particular mating schemes in the breeding programmes, with 2–4 females per male. Our observations suggest that for some genetic polymorphisms farm populations might currently hold equal or higher genetic variability than wild populations, but lower overall genetic variability. In the short-term, genetic interactions between escaped farm salmon and wild salmon might increase genetic variability in wild populations, for some, but not most, genetic polymorphisms. In the long term, further losses of genetic variability in farm populations are expected for all genetic polymorphisms, and genetic variability in wild populations will be reduced if escapes of farm salmon continue.     

Trends in the evolution of reptilian chromosomes

Reptiles are a karyologically heterogeneous group, where some orders and suborders exhibit characteristics similar to those of anamniotes and others share similarities with homeotherms. The class also shows different evolutionary trends, for instance in genome and chromosome size and composition. The turtle DNA base composition is similar to that of mammals, whereas that of lizards and snakes is more similar to that of anamniotes. The major karyological differences between turtles and squamates are the size and composition of the genome and the rate at which chromosomes change. Turtles have larger and more variable genome sizes, and a greater amount of middle repetitive DNA that differs even among related species. In lizards and snakes size of the genome are smaller, single-copy DNA is constant within each suborder, and differences in repetitive DNA involve fractions that become increasingly heterogeneous with widening phylogenetic distance. With regard to variation in karyotype morphology, turtles and crocodiles show low variability in chromosome number, morphology, and G-banding pattern. Greater variability is found among squamates, which have a similar degree of karyotypic change-as do some mammals, such as carnivores and bats-and in which there are also differences among congeneric species. An interesting relationship has been highlighted in the entire class Reptilia between rates of change in chromosomes, number of living species, and rate of extinction. However, different situations obtain in turtles and crocodiles on the one hand, and squamates on the other. In the former, the rate of change in chromosomes is lower and the various evolutionary steps do not seem to have entailed marked chromosomal variation, whereas squamates have a higher rate of change in chromosomes clearly related to the number of living species, and chromosomal variation seems to have played an important role in the evolution of several taxa. The different evolutionary trends in chromosomes observed between turtles and crocodiles on the one hand and squamates on the other might depend on their different patterns of G-banding.     

Ecological aspects of the surface microlayer. I. ATP,ADP, AMP contents,and energy charge ratios of microplanktonic communities

Forty samples of both the surface microlayer (60 to 100 μm) and underlying waters (0.5 m), were collected in a neritic area (Gulf of Marseilles, France) and their microplanktonic composition studied by adenosine, pigment, and organic carbon content. In the surface film, the accumulation of the living fraction was weaker than for inert organic matter; this phenomenon was more marked in the hydrological structures which are named “slicks”. The relationship between nucleotides and chlorophyll provided evidence for a substantial participation of heterotrophic organisms, such as bacteria, in the living biomass of the surface film. In this layer, lower values of the energy charge, as compared with those of water from 0.5 m may indicate the presence of stressed microorganisms. Nevertheless, as was shown by ATP data, part of hyponeustonic microbiomass was alive, and not killed by severe ecological conditions of this biotope. High AMP concentrations may be partially explained by a contribution of non-living organic matter, as was proved by the high enrichment factor for this adenosine form, higher than those of ATP and ADP, closer to those of phaeophytins, degrading products from chlorophylls. Adenylic nucleotide measurements in the paniculate matter of the surface microlayer, as their ratios and relations with chlorophyll, seem to be a practical tool for investigating the sea-air interface, from an ecological point of view.