Distinct functional contributions of three potential secondary structures in the phage G4 origin of complementary DNA strand synthesis

Three potential secondary structures, stem-loops I, II, and III, are contained in the phage G4 origin of complementary DNA strand synthesis, G4oric, and are believed to be involved in its recognition by dnaG-encoded primase and the synthesis of primer RNA. In a previous publication [Sakai et al., Gene 71 (1988) 323-330], we suggested that base pairing between the loops of stem-loops I, and II, and/or II and III, might play a role in G4oric function. To test this hypothesis, site-directed mutagenesis was used to construct mutants which carried base substitutions in loops I, II and III that destroyed possible interloop base pairing. These mutations, however, did not seriously affect G4oric activity. This indicates that base pairing between the loops is not essential for G4oric functional activity, and also that base substitutions which do not affect the secondary structure of stem-loops I, II and III, do not affect G4oric activity. To complete an analysis of the effects of altering the structure of the G4oric stem-loops, insertions were made into stem-loop III. In contrast to stem-loops I and II, all insertions into stem-loop III destroyed in vivo G4oric activity.     

Replication origin (oric) on the complementary DNA strand of Escherichia coli phage G4: biological properties of mutants

Phage G4 origin of complementary DNA strand synthesis (oric) consists of three stable secondary loop structures. In a cloned 274-bp DNA fragment that is active as an ori in the filamentous phage cloning vector R199, insertion mutants have been constructed by introducing EcoRI and HindIII linkers at the base of loop III. The in vivo activity of these oric mutants (conversion of single-strand form to replicative form in the presence of rifampicin) was significantly reduced (50-70%) but not completely abolished. Nucleotide sequences and/or potential secondary structure of loop III centered at the AvaII site are therefore an important functional part of oric.     

Comparative analysis of functional and structural features in the primase-dependent priming signals, G sites, from phages and plasmids.

The primase-dependent priming signals, G sites, are directly recognized by the Escherichia coli primase (dnaG gene product) and conduct the synthesis of primer RNAs. In nucleotide sequence and secondary structure, there is no striking resemblance between the phage- and plasmid-derived G sites, except for the limited sequence homology near the start position of primer RNA synthesis. In this study, we analyzed the structure and function of a G site of plasmid R100, G site (R100), and discovered the necessity of the coexistence of two domains (domains I and III), which contains blocks A, B, and C, which are nucleotide sequences highly conserved among the plasmid-derived G sites. However, neither the internal region, domain II, between domains I and III nor the potential secondary structure proposed by Bahk et al. (J. D. Bahk, N. Kioka, H. Sakai, and T. Komano, Plasmid 20:266-270, 1988) is essential for single-stranded DNA initiation activity. Furthermore, chimeric G sites constructed between a G site of phage G4, G site(G4), and G site(R100) maintained significant single-stranded DNA initiation activities. These results strongly suggest that phage- and plasmid-derived G sites have functionally equivalent domains. The primase-dependent priming mechanisms of phage- and plasmid-derived G sites are discussed.     

The nucleotide sequence and protein-coding capability of the transposable element IS5

The nucleotide sequence of IS5, a bacterial insertion sequence, has been determined. It is 1195 bp long and contains an inverted terminal repetition of 16 bp with one mismatch. One open reading frame, spanning nearly the entire length of the element, could encode a polypeptide of 338 amino acids. Upon insertion into a DNA segment, IS5 causes a duplication of 4 bp. Based on seven examples, this site of insertion appears to be nonrandom, and the consensus target site sequence is C . T/A . A . G/A (or C/T . T . A/T . G on the opposite strand). The nucleotide sequences of IS5 insertions into the B and cim genes of bacteriophage Mu have allowed tentative identification of the protein-coding frames of B and cim.     

Use of oligonucleotides to define the site of interstrand cross-links induced by Adriamycin.

It has been known for several years that Adriamycin forms adducts and interstrand cross-links when reacted for long periods of time with bacterial and mammalian DNA in vitro, with the cross-link being restricted to 2 bp elements containing GpC sequences. The self-complementary 20mer deoxyoligonucleotide TA4T4GCA4T4A has been used in this study as a model of the apparent G-G cross-linking site at GpC sequences. The rate of formation of cross-links, as well as the dependence on both Adriamycin and Fe(III) concentration, were similar with this oligonucleotide as compared with calf thymus DNA. The cross-linking was demonstrated on both denaturing and non-denaturing sequencing gels. The half-life of the G-G cross-link was 40 h, consistent with that implied with high molecular weight, heterogeneous sequence DNA. Exonuclease III digests of adducts formed with 20mer deoxyoligonucleotides containing single, central G-G, G-I and I-I potential cross-links revealed that a guanine residue is required at both ends of the cross-link. No cross-linking was observed with a similar oligonucleotide containing only a single central (G.C) bp.     

Structural features of the integration site of foreign DNA in the transgenic mouse genome

The structure of the transgenic mouse DNA region containing an integrated transgene (fragment of pBR322 sequence) was analysed. In one of the sequences flanking the transgene, short direct and inverted overlapping repeats were revealed at a distance of 60 bp from the integration site. In the same flanking sequence, there is an extended sequence (3.5 kbp) 0.3-1 kbp away from the transgene. It repeats 100-300 times in the mouse genome and is highly conservative (the homologs of the repeat have been revealed in other mammalian, bird, fish and insect genomes). This up-to-date unknown family of highly-conserved dispersed repeats has been denoted by T1. We believe that both the revealed short inverted repeats capable of forming hairpins with loops and the T1 repeat are structures involved in the process of non-homologous insertion of foreign DNA into the region of the transgenic mouse genome.     

Fine-Structure Mapping of Meiosis-Specific Double-Strand DNA Breaks at a Recombination Hotspot Associated with an Insertion of Telomeric Sequences Upstream of the His4 Locus in Yeast

Meiotic recombination in Saccharomyces cerevisiae is initiated by double-strand DNA breaks (DSBs). Using two approaches, we mapped the position of DSBs associated with a recombination hotspot created by insertion of telomeric sequences into the region upstream of HIS4. We found that the breaks have no obvious sequence specificity and localize to a region of ~50 bp adjacent to the telomeric insertion. By mapping the breaks and by studies of the exonuclease III sensitivity of the broken ends, we conclude that most of the broken DNA molecules have blunt ends with 3'-hydroxyl groups.     

Complete mitochondrial genome of Locusta migratoria migratoria (Orthoptera: Oedipodidae): three tRNA-like sequences on the N-strand

The complete 16053 bp mitochondrial genome (mitogenome) sequence of Locusta migratoria migratoria has been determined. This mitogenome contains the base compositional biases and codon usage typical of metazoans, and the RSCU values indicate a negative correlation with the C and G contents in codon. The orientation and gene order of the L. migratoria migratoria is identical to Locusta migratoria migratoiodes. An unusual feature of the L. migratoria migratoria mitogenome is the presence of three tRNA-like structures on the N-strand: one tRNA(Ile)-like and two tRNA(Leu(CUN))-like sequences. The tRNA-like sequences have proper folding structures and anticodons sequences. Two repeated DNA sequences, Rpt I and Rpt II, were found in the A+T-rich region of the L. migratoria migratoria mitogenome. Both repeated sequences have various features. In the 5' region of Rpt I, a 51 bp fragment is localized in the srRNA gene; and there are two tandemly sub-repeated DNA sequences (sub-Rpts), Rpt 1-4, within Rpt I and Rpt II. One stem-loop structure on the N-strand that may be involved in the N-strand replication initiation was found in the A+T-rich region.     

A prediction of the amino acids and structures involved in DNA recognition by type I DNA restriction and modification enzymes.

The S subunits of type I DNA restriction/modification enzymes are responsible for recognising the DNA target sequence for the enzyme. They contain two domains of approximately 150 amino acids, each of which is responsible for recognising one half of the bipartite asymmetric target. In the absence of any known tertiary structure for type I enzymes or recognisable DNA recognition motifs in the highly variable amino acid sequences of the S subunits, it has previously not been possible to predict which amino acids are responsible for sequence recognition. Using a combination of sequence alignment and secondary structure prediction methods to analyse the sequences of S subunits, we predict that all of the 51 known target recognition domains (TRDs) have the same tertiary structure. Furthermore, this structure is similar to the structure of the TRD of the C5-cytosine methyltransferase, Hha I, which recognises its DNA target via interactions with two short polypeptide loops and a beta strand. Our results predict the location of these sequence recognition structures within the TRDs of all type I S subunits.     

DNA rearrangements associated with a transposable element in yeast

The his4-912 mutation results from insertion of a 6200 bp transposable element into the his4 gene of yeast. In order to clone the his4-912 mutation, the plasmid pBR322 was integrated into the his4 gene by means of yeast transformation, and then the vector sequences and the his4-912 insertion element were excised as a single restriction fragment. This his 4-912 insertion element is homologous to Ty1, a family of repetitive yeast DNA sequences. His+ revertants derived from the his4-912 mutant carry a number of chromosomal aberrations including deletions, translocations, a transposition and an inversion. The majority of His+ revertants result from deletions which have both endpoints within the element and which leave behind only 300 bp of the insertion element. Other derivatives of the his4-912 mutant carry deletions which have one endpoint in the insertion element and one endpoint in the his4 coding sequence. In two His+ revertants carrying reciprocal translocations, the chromosome III translocation breakpoints occur within the his4-912 insertion element. A His+ revertant carrying an inversion of most of the left arm of chromosome III may be an intermediate in transposition of the his4-912 insertion element to a new site on chromosome III.     

High-affinity DNA binding of HU protein from the hyperthermophile Thermotoga maritima

Prokaryotic genomes are compacted by association with small basic proteins, generating what has been termed bacterial chromatin. The ubiquitous DNA-binding protein HU serves this function. DNA-binding properties of HU from the hyperthermophilic eubacterium Thermotoga maritima are shown here to differ significantly from those characteristic of previously described HU homologs. Electrophoretic mobility shift analyses show that T. maritima HU (TmHU) binds double-stranded DNA with high affinity (K(d)=5.6(+/-0.7) nM for 37 bp DNA). Equivalent affinity is observed between 4 degrees C and 45 degrees C. TmHU has higher affinity for DNA containing a set of 4 nt loops separated by 9 bp (K(d)=1.4(+/-0.3) nM), consistent with its introduction of two DNA kinks. Using DNA probes of varying length, the optimal binding site for TmHU is estimated at 37 bp, in sharp contrast to the 9-10 bp binding site reported for other HU homologs. Alignment of >60 HU sequences demonstrates significant sequence conservation: A DNA-intercalating proline residue is almost universally conserved, and it is preceded by arginine and asparagine in most sequences, generating a highly conserved RNP motif; V substitutes for R only in HU from Thermotoga, Thermus and Deinococcus. A fivefold increase in DNA-binding affinity is observed for TmHU in which V is replaced with R (TmHU-V61R; K(d)=1.1(+/-0.2) nM), but a change in the trajectory of DNA flanking the sites of DNA intercalation is inferred from analysis of TmHU-V61R binding to DNA modified with 4 nt loops or with substitutions of 5-hydroxymethyluracil for thymine. Survival in extreme environments places unique demands on protection of genomic DNA from thermal destabilization and on access of DNA to the cellular machinery, demands that may be fulfilled by the specific DNA-binding properties of HU and by the fine structure of the bacterial chromatin.     

Identification of splicing signals in introns of yeast mitochondrial split genes: mutational alterations in intron bI1 and secondary structures in related introns.

Four mitochondrial mutations are known to block excision of intron I1 of the cob gene in S.cerevisiae. The nucleotide sequence alteration of one of them, M4873, has been determined. It is a deletion of 1 bp in a run of five G's at a distance of 30 to 34 bp upstream to the 3' splice point. Reversion is found to occur by restoration of the run of five G's either by insertion of 1 G (wild type reversion) or by transition A leads to G next to this run of G's (pseudo-wild type reversion). The effect of mutation and reversion on RNA splicing indicates that the run of five G's is of critical importance for intron I1 excision, possibly in participating in the formation of a splice signal with a helical structure. This presumption is confirmed by the observation that this sequence is part of a larger sequence of some 80 bp next to the 3' splice point which is conserved to some extend in the four mitochondrial introns (bI1, aI1, aI2, aI5) that survive after excision as circular RNAs. Most striking is the conservation of this sequence at the level of secondary structure.     

Microsatellite instability in yeast: dependence on repeat unit size and DNA mismatch repair genes.

We examined the stability of microsatellites of different repeat unit lengths in Saccharomyces cerevisiae strains deficient in DNA mismatch repair. The msh2 and msh3 mutations destabilized microsatellites with repeat units of 1, 2, 4, 5, and 8 bp; a poly(G) tract of 18 bp was destabilized several thousand-fold by the msh2 mutation and about 100-fold by msh3. The msh6 mutations destabilized microsatellites with repeat units of 1 and 2 bp but had no effect on microsatellites with larger repeats. These results argue that coding sequences containing repetitive DNA tracts will be preferred target sites for mutations in human tumors with mismatch repair defects. We find that the DNA mismatch repair genes destabilize microsatellites with repeat units from 1 to 13 bp but have no effect on the stability of minisatellites with repeat units of 16 or 20 bp. Our data also suggest that displaced loops on the nascent strand, resulting from DNA polymerase slippage, are repaired differently than loops on the template strand.     

Mutational and in vitro protein-binding studies on centromere DNA from Saccharomyces cerevisiae.

Centromeres on chromosomes in the yeast Saccharomyces cerevisiae contain approximately 140 base pairs (bp) of DNA. The functional centromere (CEN) region contains three important sequence elements (I, PuTCACPuTG; II, 78 to 86 bp of high-AT DNA; and III, a conserved 25-bp sequence with internal bilateral symmetry). Various point mutations or deletions in the element III region have a profound effect on CEN function in vivo, indicating that this DNA region is a key protein-binding site. This has been confirmed by the use of two in vitro assays to detect binding of yeast proteins to DNA fragments containing wild-type or mutationally altered CEN3 sequences. An exonuclease III protection assay was used to demonstrate specific binding of proteins to the element III region of CEN3. In addition, a gel DNA fragment mobility shift assay was used to characterize the binding reaction parameters. Sequence element III mutations that inactivate CEN function in vivo also prevent binding of proteins in the in vitro assays. The mobility shift assay indicates that double-stranded DNAs containing sequence element III efficiently bind proteins in the absence of sequence elements I and II, although the latter sequences are essential for optimal CEN function in vivo.     

Structural features of the priming signal recognized by primase: mutational analysis of the phage G4 origin of complementary DNA strand synthesis.

45 mutations (insertion, deletion and base substitution) of the G4 Goric were tested for their functional activity in M13 and R199 in vivo. The critical mutants were also assayed for their ability to synthesize pRNA in vitro using SSB and primase. The results demonstrate that the secondary structure and spacing of stem-loops I and III are essential for Goric activity and that the 5'-CTG-3' sequence flanking stem-loop I is essential for initiation of pRNA synthesis.     

Genetic instability of an artificial palindrom DNA sequence

A short DNA palindrom, produced by head to head ligation of a 29 bp DNA fragment, was inserted into a 27,000 bp plasmid DNA element composed of two functional replicons (R6K, ColE1). Several plasmid types containing a single copy of this palindrom in different locations of insertion on the R6K sequence were obtained. The palindrom was engineered to possess a unique EcoRI recognition sequence at its axis of symmetry. The presence of this restriction site allowed to monitor the genetic stability of the artificial palindrom at their different insertion loci. Out of 5 different insertion locations, one (in pAS807) was found to lead to a significant destabilization of the palindrom. This insertion site lies within the replication control region of R6K. We have shown that the inserted palindrom in pAS8O7 does not affect the functionality of the R6K replication origins. Excission of the palindrom sequences from pAS8O7 was not accompanied by loss of the adjacent R6K DNA sequences. Different deletion derivatives of pAS807 were generated in-vitro in order to determine the driving unit of DNA sequences around the palindrom that are involved in its excision. The results imply that large DNA structure(s) around the palindrom are involved in its excission. Complete deletion of R6K sequences from either the left or the right side of the palindrom resulted in new configurations which stabilized the palindrom. A configuration of R6K DNA sequences exceeding 270 bp long sequence from both sides of the palindrom are necessary for the transition from a palindrom stable to palindrom unstable state. In addition evidence is presented to show that the excision process of palindrom sequences requires a functional polymerase I but not the gene product of recA.