Similarities in periodical structures in the position of nucleotides in regions of initiation of replication of bacterial genomes

The regions of initiation of replication of some bacterial genomes were studied by the method of Fourier matrix analysis. A generalized spectral portrait of the primary structures of E. coli-like regions of initiation of replication in bacteria was obtained, which reflects the features of their structural and functional organization. It contains well-pronounced peaks that correspond to the periods T = 2, 11, 17, 27, 86-105 of nucleotides. The peaks corresponding to T = 9, 13, 14, 18, 19, 33-35, 45-47, 74-85, 106-110 are less pronounced. The uniqueness of the Fourier spectrum corresponding to the region of initiation of replication of E. coli oriC was considered by the example of the complete genome of E. coli. Some regions of the E. coli genome were identified that differ from oriC in the primary structure but have Fourier spectra resembling the spectrum of oriC. A number of these regions are alternative points of initiation of replication in sdrA(rnh) mutants of E. coli, the others are localized in yet unidentified regions of the E. coli genome but are capable, in our opinion, to participate in the initiation of replication. Thus, from the similarity of spectral portraits of different regions of the genome, it was possible to reveal several regions that have similar functions, i.e., are involved in initiation of replication.     

Anticodons, frameshifts, and hidden periodicities in tRNA sequences

Fourier analysis of the short-range periodicities for the complete set of sequences coding for tRNA genes in genome of Bacillus subtilis proves that periodicities with periods p = 2, 3, 4, and 6 sites are the inherent properties of tRNAs. The related periodicities should be understood in a broad statistical sense and their identifying needs the elaborate statistical methods. To improve the statistics, the analysis of significant periodicities was performed for the binary R-Y, S-W, and K-M sequences. Generally, such short-range periodicities are produced via biased positioning of particular nucleotides rather than via the tandem multiplication and subsequent modifications of repeats, though the latter mechanism may also be realized. Quasi-coherently piercing long segments of tRNA, the short-range periodicities create the effective long-range structural coupling between the acceptor stem and the anticodon loop and may participate in the mechanisms of molecular recognition. The periodicities with p = 2 and 4 provide the natural ground for the translation with spontaneous or programmed frameshifting and are present in tRNAs decoding the most frameshift-prone codons. The observation of short-range periodicities suggests that the mechanisms of amino-acylation of tRNAs and codon-anticodon pairing are not independent. Their study may also provide the important information related to the origin and evolution of the genetic code.     

Anticodons,Frameshifts, and Hidden Periodicities in tRNA Sequences

Abstract

Fourier analysis of the short-range periodicities for the complete set of sequences coding for tRNA genes in genome of Bacillus subtilis proves that periodicities with periods p = 2, 3, 4, and 6 sites are the inherent properties of tRNAs. The related periodicities should be understood in a broad statistical sense and their identifying needs the elaborate statistical methods. To improve the statistics, the analysis of significant periodicities was performed for the binary R-Y, S-W, and K-M sequences. Generally, such short-range periodicities are produced via biased positioning of particular nucleotides rather than via the tandem multiplication and subsequent modifications of repeats, though the latter mechanism may also be realized. Quasi-coherently piercing long segments of tRNA, the short-range periodicities create the effective long-range structural coupling between the acceptor stem and the anticodon loop and may participate in the mechanisms of molecular recognition. The periodicities with p = 2 and 4 provide the natural ground for the translation with spontaneous or programmed frameshifting and are present in tRNAs decoding the most frameshift-prone codons. The observation of short-range periodicities suggests that the mechanisms of amino-acylation of tRNAs and codon-anticodon pairing are not independent. Their study may also provide the important information related to the origin and evolution of the genetic code.     

Acidic phospholipids inhibit the DNA-binding activity of DnaA protein,the initiator of chromosomal DNA replication in Escherichia coli

In order to initiate chromosomal DNA replication in Escherichia coli, the DnaA protein must bind to both ATP and the origin of replication (oriC). Acidic phospholipids are known to inhibit DnaA binding to ATP, and here we examine the effects of various phospholipids on DnaA binding to oriC. Among the phospholipids in E. coli membrane, cardiolipin showed the strongest inhibition of DnaA binding to oriC. Synthetic phosphatidylglycerol containing unsaturated fatty acids inhibited binding more potently than did synthetic phosphatidylglycerol containing saturated fatty acids, suggesting that membrane fluidity is important. Thus, acidic phospholipids seem to inhibit DnaA binding to both oriC and adenine nucleotides in the same manner. Adenine nucleotides bound to DnaA did not affect the inhibitory effect of cardiolipin on DnaA binding to oriC. A mobility-shift assay re-vealed that acidic phospholipids inhibited formation of a DnaA-oriC complex containing several DnaA molecules. DNase I footprinting of DnaA binding to oriC showed that two DnaA binding sites (R2 and R3) were more sensitive to cardiolipin than other DnaA binding sites. Based on these in vitro data, the physiological relevance of this inhibitory effect of acidic phospholipids on DnaA binding to oriC is discussed.     

Initiation site of deoxyribonucleotide polymerization at the replication origin of the Escherichia coli chromosome

A new round of chromosomal replication of a temperature-sensitive initiation mutant (dnaC) of Escherichia coli was initiated synchronously by a temperature shift from a nonpermissive to a permissive condition in the presence of arabinosyl cytosine. Increased amounts of nascent DNA fragments with homology for the chromosomal segment containing the replication origin (oriC) were found. The nascent DNA fragments were purified and treated with alkali to hydrolyze putative primer RNA and to expose 5'-hydroxyl DNA ends at the RNA-DNA junctions. The ends were then labeled selectively with T4 polynucleotide kinase and [gamma-32P]ATP at 0 degrees C and the terminally-labeled initiation fragments were purified by hybridization with origin probe DNAs containing one each of the constituent strands of oriC-DNA segment. The 32P-labeled initiation sites were then located at the resolution of single nucleotides in the nucleotide sequence of the oriC segment after cleavage with restriction enzymes. Two initiation sites of DNA synthesis, 37 nucleotides apart, were detected in one of the component strands of the oriC; in other words, in the strand whose 5' to 3' polynucleotide polarity lies counterclockwise on the E. coli genetic map. The results support the involvement of the primer RNA in the initiation of DNA synthesis at the origin of the E. coli genome and suggest that the first initiation event is asymmetric.     

Periodicities of 10-11bp as indicators of the supercoiled state of genomic DNA

DNA sequences contain information about the bendability and native conformation of DNA. For example, a repetition of certain dinucleotides at distances of 10-11bp supports wrapping around nucleosomes and supercoiled structures of bacterial DNA. We analyzed 86 eubacterial genomes, 16 archaea, and six genomes of higher eukaryotes. First, we discuss whether or not the observed periodicities represent indeed bendability signals. This claim is confirmed since: (1) dinucleotide signals are of comparable size to mononucleotide signals, (2) the signals are present in non-coding DNA as well, and (3) repeat masking has only a minor effect on 10-11bp periodicities. Moreover, the periodicities persist up to 150bp, comparable to the nucleosome size. We show that doublet peaks in Caenorhabditis elegans and some prokaryotes can be traced back to long-ranging modulations. In mammalian genomes, we find consistently spectral peaks as observed earlier in human chromosomes 20, 21 and 22. It has been shown in previous studies that archaea have periods of 10bp, whereas eubacteria exhibit 11bp periodicities. These differences reflect different supercoiled states of microbial DNA. Is the period of 10bp an archaeal or a thermophilic feature? This question is addressed by relating periodicities to optimal growth temperatures. It turns out that the archaea Methanopyrus kandleri (t(opt)=80 degrees C) and a Halobacterium strain (t(opt)=42 degrees C) both have longer periods of about 11bp. Eubacterial genomes have consistently periods around 11bp indicative of negative supercoiling.     

Importance of state of methylation of oriC GATC sites in initiation of DNA replication in Escherichia coli.

In vivo and in vitro evidence is presented implicating a function of GATC methylation in the Escherichia coli replication origin, oriC, during initiation of DNA synthesis. Transformation frequencies of oriC plasmids into E. coli dam mutants, deficient in the GATC-specific DNA methylase, are greatly reduced compared with parental dam+ cells, particularly for plasmids that must use oriC for initiation. Mutations that suppress the mismatch repair deficiency of dam mutants do not increase these low transformation frequencies, implicating a new function for the Dam methylase. oriC DNA isolated from dam- cells functions 2- to 4-fold less well in the oriC-specific in vitro initiation system when compared with oriC DNA from dam+ cells. This decreased template activity is restored 2- to 3-fold if the DNA from dam- cells is first methylated with purified Dam methylase. Bacterial origin plasmids or M13-oriC chimeric phage DNA, isolated from either base substitution or insertion dam mutants of E. coli, exhibit some sensitivity to digestion by DpnI, a restriction endonuclease specific for methylated GATC sites, showing that these dam mutants retain some Dam methylation activity. Sites of preferred cleavage are found within the oriC region, as well as in the ColE1-type origin.     

Structure and function of the region of the replication origin of the Bacillus subtilis chromosome. III. Nucleotide sequence of some 10,000 base pairs in the origin region.

Approximately 10,000 nucleotides were sequenced in the oriC region of the Bacillus subtilis chromosome. The first replicating DNA strands are hybridized with a SalI-EcoRI fragment (nucleotide #1206-2954) in one direction (left to right) and an EcoRI-PstI fragment (#2949-4233) in the other. Seven open reading frames (ORF) accompanied with Shine-Dalgarno (SD) sequences were identified. ORF638 and ORF821 were identified as gyrB and gyrA genes respectively based on genetic evidences and amino acid sequence data. Comparison of amino acid sequences revealed that ORF44, ORF446, ORF378 and ORF323 are homologous with rpmH, dnaA, dnaN and recF of Escherichia coli, respectively. Thus, the organization of the ORFs from ORF44 to ORF638 resembles the organization of genes in the rpmH-gyrB region of the E. coli chromosome. Two non-coding regions characteristic for oriC signals were found near the site of initiation of the first replicating DNA. They are composed of repeating sequences whose consensus sequence TTAT(C/A)CACA is identical to that of 4 repeating sequences in the oriC of E. coli.     

DnaA Protein of Escherichia coli: oligomerization at the E. coli chromosomal origin is required for initiation and involves specific N-terminal amino acids

Iterated DnaA box sequences within the replication origins of bacteria and prokaryotic plasmids are recognized by the replication initiator, DnaA protein. At the E. coli chromosomal origin, oriC, DnaA is speculated to oligomerize to initiate DNA replication. We developed an assay of oligomer formation at oriC that relies on complementation between two dnaA alleles that are inactive by themselves. One allele is dnaA46; its inactivity at the non-permissive temperature is due to a specific defect in ATP binding. The second allele, T435K, does not support DNA replication because of its inability to bind to DnaA box sequences within oriC. We show that the T435K allele can complement the dnaA46(Ts) allele. The results support a model of oligomer formation in which DnaA box sequences of oriC are bound by DnaA46 to which T435K then binds to form an active complex. Relying on this assay, leucine 5, tryptophan 6 and cysteine 9 in a predicted alpha helix were identified that, when altered, interfere with oligomer formation. Glutamine 8 is additionally needed for oligomer formation on an oriC-containing plasmid, suggesting that the structure of the DnaA-oriC complex at the chromosomal oriC locus is similar but not identical to that assembled on a plasmid. Other evidence suggests that proline 28 of DnaA is involved in the recruitment of DnaB to oriC. These results provide direct evidence that DnaA oligomerization at oriC is required for initiation to occur.     

Topoisomerase I confers specificity in enzymatic replication of the Escherichia coli chromosomal origin

Crude soluble enzyme fractions that initiate bidirectional replication from the unique Escherichia coli chromosomal origin (oriC) have been fractionated further to identify the components and mechanisms of this complex system. Among the necessary factors is a class of specificity proteins that suppress initiations on plasmids which lack the oriC sequence and which do not depend on dnaA protein. One such specificity factor has been identified as RNase H (Ogawa, T., Pickett, G. G., Kogoma, T., and Kornberg, A. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 1040-1044). Another, described here, has proved to be topoisomerase I. A protein was purified to near homogeneity based on assays of (i) inhibition of the replication of plasmids (and other supercoiled DNA) lacking oriC and (ii) conferral of dnaA protein dependence on the replication of an oriC plasmid. This specificity protein is indistinguishable from authentic E. coli topoisomerase I by several criteria: (i) molecular weight under denaturing conditions, (ii) relaxation activity on negatively supercoiled DNA, (iii) cleavage pattern of single-stranded DNA, (iv) specificity factor activity, and (v) neutralization of activity by antibody against topoisomerase I. One possible mechanism of the specificity action of topoisomerase I is destabilization of primers for replication except when they are preserved at an oriC sequence bound by dnaA protein and other replication proteins.     

Parental strand recognition of the DNA replication origin by the outer membrane in Escherichia coli.

The outer membrane of Escherichia coli binds the origin of DNA replication (oriC) only when it is hemimethylated. We report here the results of a footprinting analysis with the outer membrane which demonstrate that its interaction with oriC occurs mainly at the left moiety of the minimal oriC, where 10 out of 11 Dam methylation sites are concentrated. Two regions, flanking the Integration Host Factor (IHF) sites, are preferentially recognized at the minimum membrane concentration at which oriC plasmid replication is inhibited in vitro. We have identified the putative proteins involved in hemimethylated oriC binding and cloned one of the corresponding genes (hobH). The purified LacZ-HobH fusion protein specifically binds oriC DNA at the same preferential sites as the membrane. A mutant of the hobH gene reveals partial asynchronous initiation of DNA replication.     

Sites of dnaA protein-binding in the replication origin of the Escherichia coli K-12 chromosome

On the basis of the observation that dnaA protein binds preferentially to DNA fragments carrying the Escherichia coli chromosomal replication origin (oriC), the binding sites were investigated by DNase I footprinting. As a result, three strong binding sites were identified in the minimal oriC sequence. The respective binding sites were 16 to 17 base-pairs long, and contained a common sequence (5') T-G-T-G-(G/T)-A-T-A-A-C (3') in the middle, although their polarities were not the same. Since mutants defective in function for autonomous replication have been isolated in the corresponding positions of the common sequence at each binding site, dnaA protein-binding at these sites seems to be significant for replication initiation.     

Classification analysis of a latent dinucleotide periodicity of plant genomes

The information decomposition (ID) method has been used for searching dinucleotide periodicities, including latent ones, in plant genomes. In nucleotide sequences of genomes of various plants from the GenBank database, 14766 sequences with a periodicity of two nucleotides have been found. Classification of the periodicity matrices of the detected DNA sequences has yielded 141 classes of dinucleotide periodicity. Since ID does not detect periodicities with nucleotide deletions or insertions, modified profile analysis (MPA) has been applied to the obtained classes to reveal DNA sequences with dinucleotide periodicities containing nucleotide deletions and insertions. Combined use of ID and MPA has permitted the detection of 80 396 DNA sequences with dinucleotide periodicities in the genomes of various plants. The biological role of dinucleotide periodicity in the detected sequences is discussed.     

Classification analysis of a latent dinucleotide periodicity of plant genomes

The information decomposition (ID) method has been used for searching dinucleotide periodicities, including latent ones, in plant genomes. In nucleotide sequences of genomes of various plants from the Gen-Bank database, 14 766 sequences with a periodicity of two nucleotides have been found at a high level of statistical significance. Classification of the periodicity matrices of the detected DNA sequences has yielded 141 classes of dinucleotide periodicity. Since ID does not detect periodicities with nucleotide deletions or insertions, modified profile analysis (MPA) has been applied to the obtained classes to reveal DNA sequences with dinucleotide periodicities containing nucleotide deletions and insertions. Combined use of ID and MPA has permitted the detection of 80 396 DNA sequences with dinucleotide periodicities in the genomes of various plants. The biological role of dinucleotide periodicity in the detected sequences is discussed.     

Replisome assembly at oriC, the replication origin of E. coli, reveals an explanation for initiation sites outside an origin.

This study outlines the events downstream of origin unwinding by DnaA, leading to assembly of two replication forks at the E. coli origin, oriC. We show that two hexamers of DnaB assemble onto the opposing strands of the resulting bubble, expanding it further, yet helicase action is not required. Primase cannot act until the helicases move 65 nucleotides or more. Once primers are formed, two molecules of the large DNA polymerase III holoenzyme machinery assemble into the bubble, forming two replication forks. Primer locations are heterogeneous; some are even outside oriC. This observation generalizes to many systems, prokaryotic and eukaryotic. Heterogeneous initiation sites are likely explained by primase functioning with a moving helicase target.     

Helicase action of dnaB protein during replication from the Escherichia coli chromosomal origin in vitro

Initiation of bidirectional replication from the origin of the Escherichia coli chromosome (oriC) proceeds through stages in which the components of the two replication forks are assembled. From a complex containing proteins dnaA, dnaB, and dnaC bound at oriC, the dnaB helicase moves in both directions to unwind the duplex. In the absence of replication, this unwinding generates a bubble at oriC coated by single strand binding protein. Addition of gyrase allows unwinding to proceed extensively in both directions from oriC at 60 base pairs/s/fork at 37 degrees C. This rate is sharply dependent on temperature and also stimulated by both primase and DNA polymerase III holoenzyme, even in the absence of DNA synthesis. Primer and DNA synthesis are efficient when coupled to template unwinding. DNA synthesis proceeds bidirectionally from oriC at a rate limited by unwinding. With extensive unwinding preceding DNA synthesis, initiations are not limited to oriC.