Assessing Diversity of DNA Structure-Related Sequence Features in Prokaryotic Genomes

Prokaryotic genomes are diverse in terms of their nucleotide and oligonucleotide composition as well as presence of various sequence features that can affect physical properties of the DNA molecule. We present a survey of local sequence patterns which have a potential to promote non-canonical DNA conformations (i.e. different from standard B-DNA double helix) and interpret the results in terms of relationships with organisms'' habitats, phylogenetic classifications, and other characteristics. Our present work differs from earlier similar surveys not only by investigating a wider range of sequence patterns in a large number of genomes but also by using a more realistic null model to assess significant deviations. Our results show that simple sequence repeats and Z-DNA-promoting patterns are generally suppressed in prokaryotic genomes, whereas palindromes and inverted repeats are over-represented. Representation of patterns that promote Z-DNA and intrinsic DNA curvature increases with increasing optimal growth temperature (OGT), and decreases with increasing oxygen requirement. Additionally, representations of close direct repeats, palindromes and inverted repeats exhibit clear negative trends with increasing OGT. The observed relationships with environmental characteristics, particularly OGT, suggest possible evolutionary scenarios of structural adaptation of DNA to particular environmental niches.     

A systematic comparative and structural analysis of protein phosphorylation sites based on the mtcPTM database

mtcPTM is an online repository of human and mouse phosphosites in which data are hierarchically organized to preserve biologically relevant experimental information, thus allowing straightforward comparisons of phosphorylation patterns found under different conditions. The database also contains the largest available collection of atomic models of phosphorylatable proteins. Detailed analysis of this structural dataset reveals that phosphorylation sites are found in a heterogeneous range of structural and sequence contexts. mtcPTM is available on the web .     

Modeling the mechanics of a DNA oligomer

DNA stretching and strand separation have been studied by molecular mechanics using an oligomer which has been the subject of nanomanipulation experiments (Noy et al., Chem. Biol. 4, 519, 1997). Adiabatic mapping of conformational energy carried out as a function of stretching leads to force/extension curves in good correlation with the experimental results. Other types of deformation are also modeled and compared with the experimental results obtained on polymeric DNA. The results highlight overall similarities, but point to thermodynamic differences and also to local base sequence effects which can be expected to play an important role at the level of biologically induced structural deformations.     

逆转座子样元件Tca1用于白色念珠菌的分类鉴定

已分离到一中等重复序列以及具有逆转座子样结构的元件Tcal(Transposon Candida albicans)。Tcal两端存在两个完全相同同向排列的序列LTR(Long Terminal Repeat)388bp,中间被一5.5kbDNA片段隔开。以alpha及Tcal为探针对40多种来自美国和中国的临床分离到的致病菌株进行杂交分析,根据杂交图谱,这些白色念株菌可被分成若干组,令人感兴趣的是来自同一地区菌种的遗传相关性比来自不同地区的大。比较URA3等基因的杂交结果,支持这种分析。尚未观察到alpha重复序列与其他酵母菌染色体DNA杂交的杂交条带,认为Tcal元件也许与C. albicans的遗传进化及其致病性有某种内在联系。     

Protein-DNA interactions: structural, thermodynamic and clustering patterns of conserved residues in DNA-binding proteins

Amino acid residues, which play important roles in protein function, are often conserved. Here, we analyze thermodynamic and structural data of protein-DNA interactions to explore a relationship between free energy, sequence conservation and structural cooperativity. We observe that the most stabilizing residues or putative hotspots are those which occur as clusters of conserved residues. The higher packing density of the clusters and available experimental thermodynamic data of mutations suggest cooperativity between conserved residues in the clusters. Conserved singlets contribute to the stability of protein-DNA complexes to a lesser extent. We also analyze structural features of conserved residues and their clusters and examine their role in identifying DNA-binding sites. We show that about half of the observed conserved residue clusters are in the interface with the DNA, which could be identified from their amino acid composition; whereas the remaining clusters are at the protein-protein or protein-ligand interface, or embedded in the structural scaffolds. In protein-protein interfaces, conserved residues are highly correlated with experimental residue hotspots, contributing dominantly and often cooperatively to the stability of protein-protein complexes. Overall, the conservation patterns of the stabilizing residues in DNA-binding proteins also highlight the significance of clustering as compared to single residue conservation.     

Structural characterization of intrinsically curved AT-rich DNA sequences.

AT-rich DNA sequences other than AnTm tracts (n + m > or = 4) are known to be intrinsically curved. The AATAT-element constitutes one known example of these sequences. In this paper, the elucidation of the structural basis of the curvature induced by this sequence element was addressed. As judged by the patterns of cleavage by the hydroxyl radical and DNase I, the AATAT sequence shows a narrow minor groove. Furthermore, the 5' adenine residue of the AA dinucleotide contained within the sequence is hyperreactive to diethylpyrocarbonate. Similar structural properties are shown by several sequences inducing intrinsic DNA curvature, such as an A5-tract or the closely related ATAAT, AATATA and TAATAT sequences, which are also shown here to induce curvature. On the other hand, other related sequences, such as TATAA and ATATA, that do not induce curvature, show different structural characteristics.     

Tandem-repetitive noncoding DNA: forms and forces

A model of sequence-dependent, unequal crossing-over and gene amplification (slippage replication) has been stimulated in order to account for various structural features of tandemly repeated DNA sequences. It is shown that DNA whose sequence is not maintained by natural selection will exhibit repetitive patterns over a wide range of recombination rates as a result of the interaction of unequal crossing-over and slippage replication, processes that depend on sequence similarity. At high crossing-over frequencies, the nucleotide patterns generated in the simulations are simple and highly regular, with short, nearly identical sequences repeated in tandem. Decreasing recombination rates increase the tendency to longer and more-complex repeat units. Periodicities have been observed down to very low recombination rates (one or more orders of magnitude lower than mutation rate). At such low rates, most of the sequences contain repeats which have an extensive substructure and a high degree of heterogeneity among each other; often higher-order structures are superimposed on a tandem array. These results are compared with various structural properties of tandemly repeated DNAs known from eukaryotes, the spectrum ranging from simple-sequence DNAs, particularly the hypervariable mini-satellites, to the classical satellite DNAs, located in chromosomal regions of low recombination, e.g., heterochromatin.     

Yeast nucleosome DNA pattern: deconvolution from genome sequences of S. cerevisiae

Positional correlation analysis for the complete genome of Saccharomyces cerevisiae is performed with the aim to reveal possible chromatin-related sequence features. A strong periodicity with the period 10.4 bases is detected in the distance histograms for the dinucleotides AA and TT, with the characteristic decay distance of approximately 50 base pairs. The oscillations are observed as well in the distributions of other dinucleotides. However, the respective amplitudes are small, consistent with secondary effects, due to dominant periodicity of AA and TT. The observations are in accord with earlier data on the chromatin sequence periodicities and nucleosome DNA sequence patterns. The autocorrelations of AA and TT dinucleotides in yeast include also a counter-phase component. A tentative DNA sequence pattern for the yeast nucleosomes is suggested and verified by comparison of its autocorrelation plots with the respective natural autocorrelations. The nucleosome mapping guided by the pattern is in accord with experimental data on the linker length distribution in yeast.     

Yeast Nucleosome DNA Pattern: Deconvolution from Genome Sequences of S. cerevisiae

Abstract

Positional correlation analysis for the complete genome of Saccharomyces cerevisiae is performed with the aim to reveal possible chromatin-related sequence features. A strong periodicity with the period 10.4 bases is detected in the distance histograms for the dinucleotides AA and TT, with the characteristic decay distance of approximately 50 base pairs. The oscillations are observed as well in the distributions of other dinucleotides. However, the respective amplitudes are small, consistent with secondary effects, due to dominant periodicity of AA and TT. The observations are in accord with earlier data on the chromatin sequence periodicities and nucleosome DNA sequence patterns. The autocorrelations of AA and TT dinucleotides in yeast include also a counter-phase component. A tentative DNA sequence pattern for the yeast nucleosomes is suggested and verified by comparison of its autocorrelation plots with the respective natural autocorrelations. The nucleosome mapping guided by the pattern is in accord with experimental data on the linker length distribution in yeast.     

Nonspecific prion protein-nucleic Acid interactions lead to different aggregates and cytotoxic species

A misfolded form of the prion protein (PrP) is the primary culprit in mammalian prion diseases. It has been shown that nucleic acids catalyze the misfolding of cellular PrP into a scrapie-like conformer. It has also been observed that the interaction of PrP with nucleic acids is nonspecific and that the complex can be toxic to cultured cells. No direct correlation has yet been drawn between changes in PrP structure and toxicity due to nucleic acid binding. Here we asked whether different aggregation, stability, and toxicity effects are detected when nonrelated DNA sequences interact with recombinant PrP. Using spectroscopic techniques to analyze PrP tertiary and secondary structure and cellular assays to assess toxicity, we found that rPrP-DNA interactions lead to different aggregated species, depending on the sequence and size of the oligonucleotide tested. A 21-mer DNA sequence (D67) induced higher levels of aggregation and also dissimilar structural changes in rPrP, compared to binding to oligonucleotides with the same length and different nucleotide sequences or different GC contents. The rPrP-D67 complex induced significant cell dysfunction, which appears to be correlated with the biophysical properties of the complex. Although sequence specificity is not apparent for PrP-nucleic acid interactions, we believe that particular nucleic acid patterns, possibly related to GC content, oligonucleotide length, and structure, govern PrP recognition. Understanding the structural and cellular effects observed for PrP-nucleic acid complexes may shed light on the still mysterious pathology of the prion protein.