Sequence specificity of DNA cleavage by bis(1,10-phenanthroline)copper(I)

The bis(1,10-phenanthroline)copper(I) complex is a relatively simple molecule previously shown to cause DNA cleavage with a strong preference for gene control regions such as the Pribnow box. Sequence level mapping of sites of [(Phen)2CuI]+ cleavage in greater than 2000 bases in histone genes and the plasmid pUC9 showed that the specificity for control regions is related to a predominant preference for minor groove binding at TAT triplets, which were cleaved most strongly at the adenosine sugar ring. The related sequences TGT, TAAT, TAGPy, and CAGT (Py = pyrimidine) were moderately preferred, while CAT and TAC triplets, PyPuPuPu quartets, PuPuPuPy quartets, and CG-rich PyPuPuPy quartets were cleaved with low to average frequency. Polypurine and polypyrimidine sequences were cleaved with low frequency. The sequence preferences of [(Phen)2CuI]+ can be ascribed predominantly to (i) a requirement for binding in the minor groove at a pyrimidine 3'----5' step and (ii) stereoelectronic effects of the 2-amino group of guanine in the minor groove, which inhibit binding. Although the reagent appears primarily to recognize sequence features at the triplet or quartet level, lower than expected cleavage was observed for two TAT sequences adjacent to several other preferred sequences and higher than expected cleavage was observed at CAAGC sequences, suggesting that longer range sequence-dependent DNA conformational effects influence specificity in certain cases.     

On Negative Selection Against ATG Triplets Near Start Codons in Eukaryotic and Prokaryotic Genomes

The frequencies of ATG triplets in the genomes of various species were systematically analyzed, and the frequency of ATG triplets was significantly low around start codons in both prokaryotic and eukaryotic genomes. In eukaryotes, however, the frequency decrease before the start codon is much more evident than that after the start codon. In prokaryotes, on the other hand, the ATG frequency pattern around the start codon is less evident, and—more importantly—symmetric. We also computed average distances between a start codon and its nearest upstream-located ATG triplet and found a general tendency for the average distances to be longer in higher organisms. Received: 2 April 1998 / Accepted: 12 August 1998     

On the frequencies of nucleotides and nucleotide substitutions in conservative regulatory DNA sequences

We present data on the frequencies of nucleotides and nucleotide substitutions in conservative DNA regions involved in the regulation of gene expression. Data on prokaryotes and eukaryotes are considered separately. In both cases DNA strands complementary to those which serve as templates for RNA-polymerase have low frequencies of cytosine. The most conservative positions also have an increased frequency of adenine. Various substitutions in the series of homologous regulatory DNA sequences, as compared to their consensuses, have different frequencies. In prokaryotes guanine in a consensus sequence is substituted for at the lowest and adenine at the highest frequency, whereas in eukaryotes cytosine is substituted for at the lowest and guanine at the highest frequency. In both cases the nucleotides substituted for are most frequently replaced with cytosine. Deviations from consensus sequences tend to cluster in adjacent positions. The more pronounced the consequences of a nucleotide substitution are the higher is the frequency of substitutions in adjacent positions. Possible explanations for these phenomena are discussed.     

3-base periodicity in coding DNA is affected by intercodon dinucleotides

All coding DNAs exhibit 3-base periodicity (TBP), which may be defined as the tendency of nucleotides and higher order n-tuples, e.g. trinucleotides (triplets), to be preferentially spaced by 3, 6, 9 etc, bases, and we have proposed an association between TBP and clustering of same-phase triplets. We here investigated if TBP was affected by intercodon dinucleotide tendencies and whether clustering of same-phase triplets was involved. Under constant protein sequence intercodon dinucleotide frequencies depend on the distribution of synonymous codons. So, possible effects were revealed by randomly exchanging synonymous codons without altering protein sequences to subsequently document changes in TBP via frequency distribution of distances (FDD) of DNA triplets. A tripartite positive correlation was found between intercodon dinucleotide frequencies, clustering of same-phase triplets and TBP. So, intercodon C|A (where "|" indicates the boundary between codons) was more frequent in native human DNA than in the codon-shuffled sequences; higher C|A frequency occurred along with more frequent clustering of C|AN triplets (where N jointly represents A, C, G and T) and with intense CAN TBP. The opposite was found for C|G, which was less frequent in native than in shuffled sequences; lower C|G frequency occurred together with reduced clustering of C|GN triplets and with less intense CGN TBP. We hence propose that intercodon dinucleotides affect TBP via same-phase triplet clustering. A possible biological relevance of our findings is briefly discussed.     

Prokaryote diversity and taxonomy: current status and future challenges

The prokaryotes are by far the most abundant organisms inhabiting planet Earth. They are also by far the most diverse, both metabolically and phylogenetically; they encompass the Bacteria and the Archaea, two out of the three major divisions of living organisms. The current prokaryote species classification is based on a combination of genomic and phenotypic properties. The recommended cut-off value of 70% DNA-DNA similarity to delineate species signifies an extremely broad species definition for the prokaryotes compared with the higher eukaryotes. The number of validly named species of prokaryotes is currently slightly more than 6200. However, on the basis of small-subunit rDNA characterization of whole communities and other approaches, the more exact number of species present can be inferred to be at least two orders of magnitude larger. Classic culturing methods based on colony formation on agar are generally unsatisfactory for the recovery of bacteria from the environment. Many of the most abundant prokaryotes in nature have not yet been brought into culture. Some of these may thrive by means of as yet unknown modes of energy generation. Several novel methods have recently enabled the isolation of some interesting organisms of environmental significance. A better coverage of the prokaryote diversity on Earth depends on such innovative approaches, combined with appropriate funding.     

Genotypic characteristics of the Cladocera

Work on the genetics of cladocerans reproducing by cyclic parthenogenesis has indicated that populations usually include a large number of genotypes, whose frequencies are in close approximation to Hardy-Weinberg equilibrium. Less diverse genotypic arrays and pronounced instability in genotype frequencies occur only in permanent populations exposed to limited ephippial recruitment. Genetic diversification among local cladoceran populations is greater than in most other organisms as a consequence of the inefficiency of passive dispersal. Genotypic characteristics of cladocerans reproducing by obligate parthenogenesis are markedly different from those of cyclic parthenogens. Local populations include few clones, but genetic distances between them are often large and accompanied by significant ecological and morphological divergence. When considered over their entire range, cladoceran taxa reproducing by obligate asexuality are the most genotypically diverse asexual organisms known. This diversity has originated from the spread of a sex-limited meiosis suppressor through species that originally reproduced by cyclic parthenogenesis. The confused state of cladoceran taxonomy is partially a consequence of the presence of such obligately asexual groups, but also results from the occurrence of hybridization and sibling species. The genome size of cladocerans is exceptionally small and is associated with a large amount of endopolyploidy. Somatic tissues in adult cladocerans show a range in nuclear DNA content from 2–2048 c. DNA quantification studies have additionally revealed the frequent occurrence of polyploid clones in obligately asexual taxa.     

An interpretation of the frequencies of host specific phenotypes of Phytophthora infestans in North Wales

Race surveys of Phytophthora infestans over 4 years in North Wales have shown that races unselected by host resistance are frequent. In most cases frequencies of complex races are those expected from the frequencies of simple race characters if these assort at random. These results suggest that recombination between races may be unrestricted. The significance of unexpected deviations from the predicted frequencies are discussed.     

Within-breed heterozygosity of canine single nucleotide polymorphisms identified by across-breed comparison

Identification of single nucleotide polymorphisms (SNPs) by DNA sequence comparison across breeds is a strategy for developing genetic markers that are useful for many breeds. However, the heterozygosity of SNPs identified in this way might be severely reduced within breeds by inbreeding or genetic drift in the small effective population size of a breed (population subdivision). The effect of inbreeding and population subdivision on heterozygosity of SNPs in dog breeds has never been investigated in a systematic way. We determined the genotypes of dogs from three divergent breeds for SNPs in four canine genes (ACTC, LMNA, SCGB, and TYMS) identified by across-breed DNA sequence comparison, and compared the genotype frequencies to those expected under Hardy-Weinberg equilibrium (HWE). Although population subdivision significantly skewed allele frequencies across breeds for two of the SNPs, the deviations of observed heterozygosities compared with those expected within breeds were minimal. These results indicate that across-breed DNA sequence comparison is a reasonable strategy for identifying SNPs that are useful within many canine breeds.     

The terminal amino acids of protein sequences and protein maturation

A comparison is made of the N- and C-terminal amino acids from 96 published protein sequences, 26 from prokaryotes, 70 from eukaryotes. The observed frequencies of the N-terminal amino acids methionine, alanine and serine in prokaryotes, and alanine and serine in eukaryotes are significantly higher than expected for a random arrangement of amino acids. At the C-terminal end, the observed frequencies of lysine, asparagine and glutamine in prokaryotes and phenylalanine, asparagine and glutamine in eukaryotes exceed random expectation. These results could be explained by specific proteolytic cleavage during protein synthesis.     

A three-dimensional representation for base composition of protein-coding DNA sequences

Multi-dimensional scaling is applied to our codon space data on the protein coding sequences of DNA from a wide variety of organisms in an attempt to find the smallest number of parameters which will accurately represent these sequences. I find that a three-dimensional representation is satisfactory. One of the three resulting co-ordinates separates eukaryotes and their associated viruses from prokaryotes and their associated phages, while an orthogonal co-ordinate separates those organisms capable of synthesizing proteins (eukaryotes and prokaryotes) from those not so capable (viruses and phages). Mitochondria show no relation in our plots to any of these groups.     

Too many mutants with multiple mutations

It has recently become clear that the classical notion of the random nature of mutation does not hold for the distribution of mutations among genes: most collections of mutants contain more isolates with two or more mutations than predicted by the mutant frequency on the assumption of a random distribution of mutations. Excesses of multiples are seen in a wide range of organisms, including riboviruses, DNA viruses, prokaryotes, yeasts, and higher eukaryotic cell lines and tissues. In addition, such excesses are produced by DNA polymerases in vitro. These "multiples" appear to be generated by transient, localized hypermutation rather than by heritable mutator mutations. The components of multiples are sometimes scattered at random and sometimes display an excess of smaller distances between mutations. As yet, almost nothing is known about the mechanisms that generate multiples, but such mutations have the capacity to accelerate those evolutionary pathways that require multiple mutations where the individual mutations are neutral or deleterious. Examples that impinge on human health may include carcinogenesis and the adaptation of microbial pathogens as they move between individual hosts.     

Collaborative protein filaments

It is now well established that prokaryotic cells assemble diverse proteins into dynamic cytoskeletal filaments that perform essential cellular functions. Although most of the filaments assemble on their own to form higher order structures, growing evidence suggests that there are a number of prokaryotic proteins that polymerise only in the presence of a matrix such as DNA, lipid membrane or even another filament. Matrix‐assisted filament systems are frequently nucleotide dependent and cytomotive but rarely considered as part of the bacterial cytoskeleton. Here, we categorise this family of filament‐forming systems as collaborative filaments and introduce a simple nomenclature. Collaborative filaments are frequent in both eukaryotes and prokaryotes and are involved in vital cellular processes including chromosome segregation, DNA repair and maintenance, gene silencing and cytokinesis to mention a few. In this review, we highlight common principles underlying collaborative filaments and correlate these with known functions.     

Microbial horizontal gene transfer and the DNA release from transgenic crop plants

Intraspecific and interspecific horizontal gene transfers among prokaryotes by mechanisms like conjugation, transduction and transformation are part of their life style. Experimental data and nucleotide sequence analyses show that these processes appear to occur in any prokaryotic habitat and have shaped microbial genomes throughout evolution over hundreds of million years. Here we summarize studies with a focus on the possibility of the transfer of free recombinant DNA released from transgenic plants to microorganisms by transformation. A list of 87 species capable of natural transformation is presented. We discuss monitoring techniques which allowed detection of the spread of intact DNA from plants during their growth, in the process of decay and by pollen dispersal including novel biomonitoring assays for measuring the transforming potential of DNA in the environment. Also, studies on the persistence of free DNA in soil habitats and the potential of bacteria to take up DNA in soil are summarized. On the other hand, the various barriers evolved in prokaryotes which suppress interspecific gene transfer and recombination will be addressed along with studies aiming to estimate the chance of a gene transfer from plant to microbe. The results suggest that, although such transfers could be possible in principle, each of the many steps involved from the release of intact DNA from a plant cell to integration into a prokaryotic genome has such a low probability that a successful transfer event be extremely rare. Further, interspecies transfer of chromosomal DNA is mostly negative for the recipient, and, if not, in the absence of a selective advantage the transformant will be lost. It is stressed that the nucleotide sequences introduced into transgenic plants are much less likely to be captured from the transgenic plants than directly from those organisms (often bacteria or viruses) from which they were originally derived.     

Enzymatic methylation of regulatory elements in controlling the activity of genes from various groups of organisms]

About 1800 sequences of gene promoters, enhancers and other types of regulatory elements (REG) have been statistically analysed for investigation of a role for enzymatic DNA methylation in prokaryotes, yeasts, plants, invertebrates, animal viruses, vertebrates and human. The frequencies and localizations of CG and CNG methylated sites and also the number of CG-->TG+CA transitions in different series of REGs have been studied. It was showed that the pro- and eukaryotic REGs with the exception of yeast and drosophila ones have higher CpG-suppression values than the main genome in the same species. About 40% of all the point substitutions in pro- and eukaryotic REGs were found in the CG and CNG methylated sites, that are "hot spots" for C-->T transitions. More than 30% of all analysed REGs have neither sites CG nor CNG and so they are not capable of methylation in vivo. The methylated sites have not been localized in any specific regions of promoters and other types of REGs nor in the flanking sequences of the same genes. Only part of the homological REG's sequences have CG and CNG methylated sites. Therefore the methylation of cytosine residues in any REGs may be not an obligatory condition for normal regulation of the REG activity in cells. Two main REG's families of different length were unexpectedly found in the study. The length of the first one is 9-12 n. and the second is 17-20 n. The families are about 60-80% of other REGs. The essential deficiency of cytosine residues and also triplets of CGG, CCG, CTG and CAG has been showed in the "sense" chain of the REGs. The chain has some abundance of TTG, CCA and CAA triplets. The REG's chains have a strong asymmetry in purine and pyrimidine contents and also in duplets TG and CA frequencies. It may be the result of different reparation effectivity of G-T pairs produced by 5-meC residues deamination in DNA complementary chains. Therefore cytosine methylation in REGs may strongly destabilize the structure, accelerate its divergence in evolution, and disturb the REGs binding with protein factors regulating activity of the genes. The results showed that a function of DNA enzymatic methylation may be hardly realized through the modification of gene regulatory elements.     

Preferred amino acids and thermostability

Most organisms grow at temperatures from 20 to 50 degrees C, but some prokaryotes, including Archaea and Bacteria, are capable of withstanding higher temperatures, from 60 to >100 degrees C. Their biomolecules, especially proteins, must be sufficiently stable to function under these extreme conditions; however, the basis for thermostability remains elusive. We investigated the preferential usage of certain groupings of amino acids and codons in thermally adapted organisms, by comparative proteome analysis, using 28 complete genomes from 18 mesophiles (M), 4 thermophiles (T), and 6 hyperthermophiles (HT). Whenever the percent of glutamate (E) and lysine (K) increased in the HT proteomes, the percent of glutamine (Q) and histidine (H) decreased, so that the E + K/Q + H ratio was >4.5; it was <2.5 in the M proteomes, and 3.2 to 4.6 in T. The E + K/Q + H ratios for chaperonins, potentially thermostable proteins, were higher than their proteome ratios, whereas for DNA ligases, which are not necessarily thermostable, they followed the proteome ratios. Analysis of codon usage revealed that HT had more AGR codons for Arg than they did CGN codons, which were more common in mesophiles. The E + K/Q + H ratio may provide a useful marker for distinguishing HT, T and M prokaryotes, and the high percentage of the amino acid couple E + K, consistently associated with a low percentage of the pair Q + H, could contribute to protein thermostability. The preponderance of AGR codons for Arg is a signature of all HT so far analyzed. The E + K/Q + H ratio and the codon bias for Arg are apparently not related to phylogeny. HT members of the Bacteria show the same values as the HT members of the Archaea; the values for T organisms are related to their lifestyle (intermediate temperature) and not to their domain (Archaea) and the values for M are similar in Eukarya, Bacteria and Archaea.     

Reinvestigation on the causes of genomic GC variation between the orthologous genes of Mycobacterium tuberculosis and Mycobacterium leprae

Genomic GC (overall G+C content of the coding sequences) variations were reinvestigated between the orthologous genes of Mycobacterium tuberculosis and Mycobacterium leprae species. It was observed that overall genomic GC variation between the species mainly originates from the combined effects GC(1) and GC(2) variations. But codons having identical amino acids with different codons (IA) (between the orthologous codon pairs) are responsible for the genomic GC(3) variation between the organisms, whereas orthologous codons having different amino acids (DA) between the two organisms are responsible for the variation of GC(1) levels. Further analyses indicate that duets and quartets are going in the same direction with same magnitude in changing the GC(3) levels for IA category, whereas GC(1) levels of duets of DA category decreases significantly from the overall GC(1) levels but GC(1) levels of quartets increases significantly from the overall GC(1) levels. GC(3) levels of informational genes for the IA category decrease more rapidly than the other functional categories of genes. The biological implications of these results have been discussed in this paper.