DNA requirements at the bacteriophage G4 origin of complementary-strand DNA synthesis

Integrative and Conjugative Elements (ICEs): What They Do and How They Work

Horizontal gene transfer plays a major role in microbial evolution, allowing microbes to acquire new genes and phenotypes. Integrative and conjugative elements (ICEs, a.k.a. conjugative transposons) are modular mobile genetic elements integrated into a host genome and are passively propagated during chromosomal replication and cell division. Induction of ICE gene expression leads to excision, production of the conserved conjugation machinery (a type IV secretion system), and the potential to transfer DNA to appropriate recipients. ICEs typically contain cargo genes that are not usually related to the ICE life cycle and that confer phenotypes to host cells. We summarize the life cycle and discovery of ICEs, some of the regulatory mechanisms, and how the types of cargo have influenced our view of ICEs. We discuss how ICEs can acquire new cargo genes and describe challenges to the field and various perspectives on ICE biology.

Folded DNA in action: hairpin formation and biological functions in prokaryotes

Structured forms of DNA with intrastrand pairing are generated in several cellular processes and are involved in biological functions. These structures may arise on single-stranded DNA (ssDNA) produced during replication, bacterial conjugation, natural transformation, or viral infections. Furthermore, negatively supercoiled DNA can extrude inverted repeats as hairpins in structures called cruciforms. Whether they are on ssDNA or as cruciforms, hairpins can modify the access of proteins to DNA, and in some cases, they can be directly recognized by proteins. Folded DNAs have been found to play an important role in replication, transcription regulation, and recognition of the origins of transfer in conjugative elements. More recently, they were shown to be used as recombination sites. Many of these functions are found on mobile genetic elements likely to be single stranded, including viruses, plasmids, transposons, and integrons, thus giving some clues as to the manner in which they might have evolved. We review here, with special focus on prokaryotes, the functions in which DNA secondary structures play a role and the cellular processes giving rise to them. Finally, we attempt to shed light on the selective pressures leading to the acquisition of functions for DNA secondary structures.

Dynamics of beta and proliferating cell nuclear antigen sliding clamps in traversing DNA secondary structure

Chromosomal replicases of cellular organisms utilize a ring shaped protein that encircles DNA as a mobile tether for high processivity in DNA synthesis. These "sliding clamps" have sufficiently large linear diameters to encircle duplex DNA and are perhaps even large enough to slide over certain DNA secondary structural elements. This report examines the Escherichia coli beta and human proliferating cell nuclear antigen clamps for their ability to slide over various DNA secondary structures. The results show that these clamps are capable of traversing a 13-nucleotide ssDNA loop, a 4-base pair stem-loop, a 4-nucleotide 5' tail, and a 15-mer bubble within the duplex. However, upon increasing the size of these structures (20-nucleotide loop, 12-base pair stem-loop, 28-nucleotide 5' tail, and 20-nucleotide bubble) the sliding motion of the beta and proliferating cell nuclear antigen over these elements is halted. Studies of the E. coli replicase, DNA polymerase III holoenzyme, in chain elongation with the beta clamp demonstrate that upon encounter with an oligonucleotide annealed in its path, it traverses the duplex and resumes synthesis on the 3' terminus of the oligonucleotide. This sliding and resumption of synthesis occurs even when the oligonucleotide contains a secondary structure element, provided the beta clamp can traverse the structure. However, upon encounter with a downstream oligonucleotide containing a large internal secondary structure, the holoenzyme clears the obstacle by strand displacing the oligonucleotide from the template. Implications of these protein dynamics to DNA transactions are discussed.

Synthesis of polyribonucleotide chains from the 3'-hydroxyl terminus of oligodeoxynucleotides by Escherichia coli primase

Escherichia coli primase synthesizes RNA primers on DNA templates for the initiation of DNA replication. The sole known activity of primase is to catalyze synthesis of short RNA chains de novo. We now report a novel activity of primase, namely that it can synthesize RNA from the 3'-hydroxyl terminus of a pre-existing oligodeoxynucleotide. The oligonucleotide-primed synthesis of RNA by primase occurs in both of the G4oric-specific priming system and the dnaB protein associated general priming system. This priming reaction of primase is verified by a number of biochemical methods, including inhibition by modified 3'-phosphate of oligonucleotides and deoxyribonuclease I and ribonuclease H cleavages. We also show that the primed RNA is an effective primer for the synthesis of DNA chain by E. coli DNA polymerase III holoenzyme. The significance of this finding to primases generating multimeric length RNA is discussed.

Structure of the Escherichia coli primase/single-strand DNA-binding protein/phage G4oric complex required for primer RNA synthesis

Escherichia coli primase/SSB/single-stranded phage G4oric is a simple system to study how primase interacts with DNA template to synthesize primer RNA for initiation of DNA replication. By a strategy of deletion analysis and antisense oligonucleotide protection on small single-stranded G4oric fragments, we have identified the DNA sequences required for binding primase and the critical location of single-strand DNA-binding (SSB) protein. Together with the previous data, we have defined the structure of the primase/SSB/G4oric priming complex. Two SSB tetramers bind to the G4oric secondary structure, which dictates the spacing of 3' and 5' bound adjacent SSB tetramers and leaves SSB-free regions on both sides of the stem-loop structure. Two primase molecules then bind separately to specific DNA sequences in the 3' and 5' SSB-free G4oric regions. Binding of the 3' SSB tetramer, upstream of the primer RNA initiation site, is also necessary for priming. The generation of a primase-recognition target by SSB phasing at DNA hairpin structures may be applicable to the binding of initiator proteins in other single-stranded DNA priming systems. Novel techniques used in this study include antisense oligonucleotide protection and RNA synthesis on an SSB-melted, double-stranded DNA template.

Inverted repeats, stem-loops, and cruciforms: significance for initiation of DNA replication

Inverted repeats occur nonrandomly in the DNA of most organisms. Stem-loops and cruciforms can form from inverted repeats. Such structures have been detected in pro- and eukaryotes. They may affect the supercoiling degree of the DNA, the positioning of nucleosomes, the formation of other secondary structures of DNA, or directly interact with proteins. Inverted repeats, stem-loops, and cruciforms are present at the replication origins of phage, plasmids, mitochondria, eukaryotic viruses, and mammalian cells. Experiments with anti-cruciform antibodies suggest that formation and stabilization of cruciforms at particular mammalian origins may be associated with initiation of DNA replication. Many proteins have been shown to interact with cruciforms, recognizing features like DNA crossovers, four-way junctions, and curved/bent DNA of specific angles. A human cruciform binding protein (CBP) displays a novel type of interaction with cruciforms and may be linked to initiation of DNA replication.

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.

pR plasmid replication provides evidence that single-stranded DNA induces the SOS system in vivo

Evidence is presented that the pR bat gene is essential for plasmid replication and for spontaneous induction of the SOS response in Escherichia coli. Mutations preventing single-stranded DNA production, needed for pR plasmid replication, also prevent the induction of the SOS system. The following experimental design was used. Firstly, we identified the minima rep region, defined as the minimal DNA sequence necessary for pR plasmid replication and, secondly, analyzed the nucleotide sequence of this region. This identified structures and functions (ori-plus, ori-minus and Rep protein) homologous to those found in phages and plasmids replicating by the rolling-circle mechanism. Finally, mutations were introduced either in the replication protein catalytic site or in the nick site consensus sequence, which caused the pR plasmid to lose its ability to induce the SOS system. We conclude that, in this system, the in vivo SOS-inducing signal appears to be the single-stranded DNA produced during pR replication.

Identification of eleven single-strand initiation sequences (ssi) for priming of DNA replication in the F, R6K, R100 and ColE2 plasmids

Based on the ability to complement the poor growth of an M13 phage derivative lacking the complementary strand origin, eleven single-strand initiation sequences (ssi) for DNA replication are identified in the F, R6K, R100 and ColE2 plasmids. Six of them were from F, two from near the gamma and alpha origins (ori) of R6K, two from the vicinity of the basic replicon of R100 and one from near the ori of ColE2. They can be classified into two groups based on the morphology of the plaques and the length of nucleotide (nt) sequences required for ssi activity; one group that gives rise to larger and clearer plaques and can be reduced to nearly 100 nt (seven out of eleven), and another that generates smaller and less clear plaques and requires more than 200 nt for full activity (four out of eleven). Sequence homology is detected among some members from both groups. The possible biological roles of the ssi are discussed.

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.

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.

Mutational analysis of the primer RNA template region in the replication origin (oric) of bacteriophage G4: priming signal recognition by Escherichia coli primase

The primase-dependent phage G4 origin of complementary DNA strand synthesis (G4oric) contains three stable stem-loops (I, II, and III) upstream from the initiation point of primer RNA (pRNA). Site-directed mutagenesis was used to introduce alterations into the nucleotide (nt) sequence of the G4oric pRNA template region. Mutations in stem-loop I, that changed the length of the stem and the sequence of the loop, slightly depressed, but did not abolish, G4oric activity. However, functional G4oric activity was destroyed when the sequence containing the starting position of pRNA synthesis was deleted, or when insertions were introduced between the pRNA starting position (5'-CTG-3') and stem-loop I. Reintroducing a CTG as part of a PstI linker close to stem-loop I, however, resulted in recovery of G4oric functional activity. These results suggest that the specific nt sequence, containing 5'-CTG-3', between nt 3994 and 4007, and also the distance between the starting position of pRNA synthesis and stem-loop I, are essential structural features for G4oric function.

Identification of single-strand initiation signals in the terC region of the Escherichia coli chromosome

On the basis of clear-plaque formation, we detected initiation signals in the terC region of the Escherichia coli chromosome. At least two single-strand initiation signals were identified from the terC region. The nucleotide sequences of these two signals were determined. Sequence homologies, variations of the consensus of n' protein recognition sites, 5'-GAAGCGG-3', were found within these signals. A novel conserved sequence was also found within these signals. Their initiation activities were measured both by the infection growth assay and by the ability to convert the single-stranded DNA to the duplex replicative form DNA in vivo.

Role of the potential secondary structures in phage G4 origin of complementary DNA strand synthesis

Phage G4 origin of complementary DNA strand synthesis (oric) consists of three stable stem-loop structures (I, II, and III). Mutant oric sequences with alterations in the structure of stem-loop II, stem-loop III, and the stem-loop II-III spacer region have been constructed and cloned into the filamentous phage vectors to assay their functional activity. Changes in the lowermost GC base pair in the stem of stem-loop III, in the 9-bp spacer region between the stems of stem-loops II and III, and in the loop of stem-loop II, impair or abolish in vivo oric function. The results suggest that recognition sequences for dnaG primase must be present in the loop of stem-loop II, and in the spacer region between the stems of stem-loops II and III.

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.

Secondary structure at the bacteriophage G4 origin of complementary-strand DNA synthesis: in vivo requirements

The bacteriophage G4 origin of complementary strand DNA synthesis, G4 ori, contains several regions of potential secondary structure. In this study, we ask whether DNA secondary structure is important for G4 ori function in vivo. Point mutations were generated within a region of potential secondary structure so as to disrupt intrastrand base pairing. These mutations led to a strong temperature-dependent reduction in ori function in vivo. A double point mutation which introduces the same base substitutions without destabilizing intrastrand base pairing did not cause a temperature-dependent disruption in ori function. The double mutant did display a slight temperature-independent reduction in ori function compared to the wild-type G4 ori. Based on these findings, we conclude that DNA secondary structure, as well as recognition of specific sequences, is required for G4 ori activity in vivo.