DNA binding of Escherichia coli arginine repressor mutants altered in oligomeric state

The Escherichia coli arginine repressor (ArgR) controls expression of the arginine biosynthetic genes and acts as an accessory protein in Xer site-specific recombination at cer and related plasmid recombination sites. The hexameric wild-type protein shows L -arginine-dependent DNA binding. In this work, ArgR mutants that are defective in trimer–trimer interactions and bind DNA as trimers in an L -arginine-independent manner are isolated and characterized. Whereas the wild-type ArgR hexamer exhibits high-affinity binding to two repeated ARG boxes separated by 3 bp (each ARG box containing two identical dyad symmetrical 9 bp half-sites), the trimeric mutants bind to and footprint three adjacent half-sites of this 'idealized' substrate. Trimeric ArgR is impaired in its ability to repress the arginine biosynthetic genes and in Xer site-specific recombination. In the absence of L -arginine, residual wild-type ArgR-binding occurs as trimers. The binding of an N-terminal 77-amino-acid DNA-binding domain to idealized ARG boxes is also characterized.     

Communication between accessory factors and the Cre recombinase at hybrid psi-loxP sites

By placing loxP adjacent to the accessory sequences from the Xer/psi multimer resolution system, we have imposed topological selectivity and specificity on Cre/loxP recombination. In this hybrid recombination system, the Xer accessory protein PepA binds to psi accessory sequences, interwraps them, and brings the loxP sites together such that the product of recombination is a four-node catenane. Here, we investigate communication between PepA and Cre by varying the distance between loxP and the accessory sequences, and by altering the orientation of loxP. The yield of four-node catenane and the efficiency of recombination in the presence of PepA varied with the helical phase of loxP with respect to the accessory sequences. When the orientation of loxP was reversed, or when half a helical turn was added between the accessory sequences and loxP, PepA reversed the preferred order of strand exchange by Cre at loxP. The results imply that PepA and the accessory sequences define precisely the geometry of the synapse formed by the loxP sites, and that this overcomes the innate preference of Cre to initiate recombination on the bottom strand of loxP. Further analysis of our results demonstrates that PepA can stimulate strand exchange by Cre in two distinct synaptic complexes, with the C-terminal domains of Cre facing either towards or away from PepA. Thus, no specific PepA-recombinase interaction is required, and correct juxtaposition of the loxP sites is sufficient to activate Cre in this system.     

Nucleoprotein architecture and ColE1 dimer resolution: a hypothesis

Dimers of plasmid ColE1 are converted to monomers by site-specific recombination, a process that requires 240 bp of DNA ( cer ) and four host-encoded proteins (XerC, XerD, ArgR and PepA). Here, we propose structures for nucleoprotein complexes involved in cer –Xer recombination based upon existing knowledge of the structures of component proteins and computational analyses of protein structure and DNA curvature. We propose that, in the nucleoprotein complex at a single cer site, a PepA hexamer acts as an adaptor, connecting the heterodimeric recombinase (XerCD) to an ArgR hexamer. This provides a protein core around which the cer site wraps, its exact path being defined by strong sequence-specific interactions with ArgR and XerCD, weak interactions with PepA and sequence-dependent flexibility of cer . The initial association of single-site complexes (pairing) is proposed to occur via an ArgR–PepA interaction. Pairing between sites in a plasmid dimer is stabilized by DNA supercoiling and is followed by a structural isomerization to form a recombination-proficient synaptic complex. We propose that paired structures formed between sites in trans are too short-lived to permit synaptic complex formation. There is thus an energetic barrier to inappropriate recombination reactions. Our proposals are consistent with a wide range of experimental observations.     

Control of Cre recombination by regulatory elements from Xer recombination systems

Site-specific recombination by the Cre recombinase takes place at a simple DNA site (loxP), requires no additional proteins and gives topologically simple recombination products. In contrast, cer and psi sites for Xer recombination contain approximately 150 bp of accessory sequences, require accessory proteins PepA, ArgR and ArcA, and the products are specifically linked to form a four-noded catenane. Here, we use hybrid sites consisting of accessory sequences of cer or psi fused to loxP to probe the function of accessory proteins in site-specific recombination. We show that PepA instructs Cre to produce four-noded catenane, but is not required for recombination at these hybrid sites. Mutants of Cre that require PepA and accessory sequences for efficient recombination were selected. PepA-dependent Cre gave products with a specific topology and displayed resolution selectivity. Our results reveal that PepA acts autonomously in the synapsis of psi and cer accessory sequences and is the main architectural element responsible for intertwining accessory site DNA. We suggest that accessory proteins can activate recombinases simply by synapsing the regulatory DNA sequences, thus bringing the recombination sites together with a specific geometry. This may occur without the need for protein-protein interactions between accessory proteins and the recombinases.     

Topology of Xer recombination on catenanes produced by lambda integrase.

Xer site-specific recombination at the psi site from plasmid pSC101 displays topological selectivity, such that recombination normally occurs only between directly repeated sites on the same circular DNA molecule. This intramolecular selectivity is important for the biological role of psi, and is imposed by accessory proteins PepA and ArcA acting at accessory DNA sequences adjacent to the core recombination site. Here we show that the selectivity for intramolecular recombination at psi can be bypassed in multiply interlinked catenanes. Xer site-specific recombination occurred relatively efficiently between antiparallel psi sites located on separate rings of right-handed torus catenanes containing six or more nodes. This recombination introduced one additional node into the catenanes. Antiparallel sites on four-noded right-handed catenanes, the normal product of Xer recombination at psi, were not recombined efficiently. Furthermore, parallel psi sites on right-handed torus catenanes were not substrates for Xer recombination. These findings support a model in which psi sites are plectonemically interwrapped, trapping a precise number of supercoils that are converted to four catenation nodes by Xer strand exchange.     

FtsK activities in Xer recombination, DNA mobilization and cell division involve overlapping and separate domains of the protein

Escherichia coli FtsK is a multifunctional protein that couples cell division and chromosome segregation. Its N-terminal transmembrane domain (FtsK(N)) is essential for septum formation, whereas its C-terminal domain (FtsK(C)) is required for chromosome dimer resolution by XerCD-dif site-specific recombination. FtsK(C) is an ATP-dependent DNA translocase. In vitro and in vivo data point to a dual role for this domain in chromosome dimer resolution (i) to directly activate recombination by XerCD-dif and (ii) to bring recombination sites together and/or to clear DNA from the closing septum. FtsK(N) and FtsK(C) are separated by a long linker region (FtsK(L)) of unknown function that is highly divergent between bacterial species. Here, we analysed the in vivo effects of deletions of FtsK(L) and/or of FtsK(C), of swaps of these domains with their Haemophilus influenzae counterparts and of a point mutation that inactivates the walker A motif of FtsK(C). Phenotypic characterization of the mutants indicated a role for FtsK(L) in cell division. More importantly, even though Xer recombination activation and DNA mobilization both rely on the ATPase activity of FtsK(C), mutants were found that can perform only one or the other of these two functions, which allowed their separation in vivo for the first time.     

Lipooligosaccharide biosynthesis in Neiseria gonorrhoeae: cloning, identification and characterization of the α1,5 heptosyltransferase I gene (rfaC)

The Escherichia coli arginine repressor (ArgR) is an l -arginine-dependent DNA-binding protein that controls expression of the arginine biosynthetic genes and is required as an accessory protein in Xer site-specific recombination at cer and related recombination sites in plasmids. Site-directed mutagenesis was used to isolate two mutants of E. coli ArgR that were defective in arginine binding. Results from in vivo and in vitro experiments demonstrate that these mutants still act as repressors and bind their specific DNA sequences in an arginine-independent manner. Both mutants support Xer site-specific recombination at cer. One of the mutant proteins was purified and shown to bind to its DNA target sequences in vitro with different affinity and as a different molecular species to wild-type ArgR.     

Peptidase activity of Escherichia coli aminopeptidase A is not required for its role in Xer site-specific recombination

Xer site-specific recombination is required for the stable inheritance of multicopy plasmids and the normal segregation of the bacterial chromosome in Escherichia coli.Two related recombinases and two accessory proteins are essential for Xer-mediated recombination at cer, a recombination site in the plasmid ColE1 The accessory proteins, ArgR and PepA, function in ensuring that the Xer recombination reaction acts exclusively intramolecularly, converting plasmid dimers into monomers and not vice versa. PepA is an amino-exopeptidase, but its molecular role in the Xer recombination mechanism is unclear. Here we show that a mutation directed at the presumptive active site of PepA creates a protein with no detectable peptidase activity in vitro or in vivo, but which still functions normality in Xer site-specific recombination at cer.     

Xer-mediated site-specific recombination at cer generates Holliday junctions in vivo.

Normal segregation of the Escherichia coli chromosome and stable inheritance of multicopy plasmids such as ColE1 requires the Xer site-specific recombination system. Two putative lambda integrase family recombinases, XerC and XerD, participate in the recombination reactions. We have constructed an E. coli strain in which the expression of xerC can be tightly regulated, thereby allowing the analysis of controlled recombination reactions in vivo. Xer-mediated recombination in this strain generates Holliday junction-containing DNA molecules in which a specific pair of strands has been exchanged in addition to complete recombinant products. This suggests that Xer site-specific recombination utilizes a strand exchange mechanism similar or identical to that of other members of the lambda integrase family of recombination systems. The controlled in vivo recombination reaction at cer requires recombinase and two accessory proteins, ArgR and PepA. Generation of Holliday junctions and recombinant products is equally efficient in RuvC- and RuvC+ cells, and in cells containing a multicopy RuvC+ plasmid. Controlled XerC expression is also used to analyse the efficiency of recombination between variant cer sites containing sequence alterations and heterologies within their central regions.     

Docking dinucleotides to HIV-1 integrase carboxyl-terminal domain to find possible DNA binding sites

HIV-1 integrase mediates a processed viral DNA into the host genome DNA. The binding modes between HIV-1 integrase and viral/host DNA have not been clarified until now. The C-terminal domain of integrase has been found to be a DNA-binding domain. In this work, we have explored the possible DNA binding sites of dimeric C-terminal domain by docking dinucleotides to HIV-1 integrase. The docking results suggest that two symmetrical DNA-binding sites are likely located on the outside surface of the dimeric C-terminal domain and not located in the groove. Those sites are in agreement with the experimental data.     

Determination of the origin-specific DNA-binding domain of polyomavirus large T antigen.

To map the DNA-binding domain of polyomavirus large T antigen, we constructed a set of plasmids coding for unidirectional carboxy- or amino-terminal deletion mutations in the large T antigen. Analysis of origin-specific DNA binding by mutant proteins expressed in Cos-1 cells revealed that the C-terminal boundary of the DNA-binding domain is at or near Glu-398. Fusion proteins of large T antigen lacking the first 200 N-terminal amino acids bound specifically to polyomavirus origin DNA; however, deletions beyond this site resulted in unstable proteins which could not be tested for DNA binding. Testing of point mutants and internal deletions by others suggested that the N-terminal boundary of the DNA-binding domain lies between amino acids 282 and 286. Taken together, these results locate the DNA-binding domain of polyomavirus large T antigen to the 116-amino-acid region between residues 282 and 398.     

Direct interaction of aminopeptidase A with recombination site DNA in Xer site-specific recombination.

Xer site-specific recombination at ColE1 cer converts plasmid multimers into monomers, thus ensuring the heritable stability of ColE1. Two related recombinase proteins, XerC and XerD, catalyse the strand exchange reaction at a 30 bp recombination core site. In addition, two accessory proteins, PepA and ArgR, are required for recombination at cer. These two accessory proteins are thought to act at 180 bp of accessory sequences adjacent to the cer recombination core to ensure that recombination only occurs between directly repeated sites on the same molecule. Here, we demonstrate that PepA and ArgR interact directly with cer, forming a complex in which the accessory sequences of two cer sites are interwrapped approximately three times in a right-handed fashion. We present a model for this synaptic complex, and propose that strand exchange can only occur after the formation of this complex.     

Comparison between TRF2 and TRF1 of their telomeric DNA-bound structures and DNA-binding activities

Mammalian telomeres consist of long tandem arrays of double-stranded telomeric TTAGGG repeats packaged by the telomeric DNA-binding proteins TRF1 and TRF2. Both contain a similar C-terminal Myb domain that mediates sequence-specific binding to telomeric DNA. In a DNA complex of TRF1, only the single Myb-like domain consisting of three helices can bind specifically to double-stranded telomeric DNA. TRF2 also binds to double-stranded telomeric DNA. Although the DNA binding mode of TRF2 is likely identical to that of TRF1, TRF2 plays an important role in the t-loop formation that protects the ends of telomeres. Here, to clarify the details of the double-stranded telomeric DNA-binding modes of TRF1 and TRF2, we determined the solution structure of the DNA-binding domain of human TRF2 bound to telomeric DNA; it consists of three helices, and like TRF1, the third helix recognizes TAGGG sequence in the major groove of DNA with the N-terminal arm locating in the minor groove. However, small but significant differences are observed; in contrast to the minor groove recognition of TRF1, in which an arginine residue recognizes the TT sequence, a lysine residue of TRF2 interacts with the TT part. We examined the telomeric DNA-binding activities of both DNA-binding domains of TRF1 and TRF2 and found that TRF1 binds more strongly than TRF2. Based on the structural differences of both domains, we created several mutants of the DNA-binding domain of TRF2 with stronger binding activities compared to the wild-type TRF2.