Characterization of His-tagged, R6K-encoded pi protein variants

Cooperative binding mode of the inhibitors of R6K replication, pi dimers

The replication initiator protein, pi, plays an essential role in the initiation of plasmid R6K replication. Both monomers and dimers of pi bind to iterons in the gamma origin of plasmid R6K, yet monomers facilitate open complex formation, while dimers, the predominant form in the cell, do not. Consequently, pi monomers activate replication, while pi dimers inhibit replication. Recently, it was shown that the monomeric form of pi binds multiple tandem iterons in a strongly cooperative fashion, which might explain how monomers outcompete dimers for replication initiation when plasmid copy number and pi supply are low. Here, we examine cooperative binding of pi dimers and explore the role that these interactions may have in the inactivation of gamma origin. To examine pi dimer/iteron interactions in the absence of competing pi monomer/iteron interactions using wild-type pi, constructs were made with key base changes to each iteron that eliminate pi monomer binding yet have no impact on pi dimer binding. Our results indicate that, in the absence of pi monomers, pi dimers bind with greater cooperativity to alternate iterons than to adjacent iterons, thus preferentially leaving intervening iterons unbound and the origin unsaturated. We discuss new insights into plasmid replication control by pi dimers.

Conjugal transfer of plasmid R6K gamma ori minireplicon derivatives from Escherichia coli to various genera of pathogenic bacteria

Three R6K-derived gamma ori minireplicons were successfully transferred by conjugation from Escherichia coli to several species of pathogenic bacteria. The pFL129 replicon encodes the wild-type initiation replication protein pi, while plasmids pFL130 and pAG101 encode mutant forms of the pi protein conferring the plasmid copy-up phenotype. Plasmids could be transferred to all recipient species tested, although high efficiency conjugal transfer was only obtained with genera of the Enterobacteriaceae. The efficiency of plasmid transfer to all recipients was lower for the copy-up derivatives, pFL130 and pAG101, than for pFL129. The three gamma ori replicons were stably maintained in all transconjugants except pFL129 in Listeria monocytogenes. The two mutant plasmids retained their copy-up phenotype in the new bacterial hosts.

Mechanism of origin activation by monomers of R6K-encoded pi protein

One recurring theme in plasmid duplication is the recognition of the origin of replication (ori) by specific Rep proteins that bind to DNA sequences called iterons. For plasmid R6K, this process involves a complex interplay between monomers and dimers of the Rep protein, pi, with seven tandem iterons of gamma ori. Remarkably, both pi monomers and pi dimers can bind to iterons, a new paradigm in replication control. Dimers, the predominant form in the cell, inhibit replication, while monomers facilitate open complex formation and activate the ori. Here, we investigate a mechanism by which pi monomers out-compete pi dimers for iteron binding, and in so doing activate the ori. With an in vivo plasmid incompatibility assay, we find that pi monomers bind cooperatively to two adjacent iterons. Cooperative binding is eliminated by insertion of a half-helical turn between two iterons but is diminished only slightly by insertion of a full helical turn between two iterons. These studies show also that pi bound to a consensus site promotes occupancy of an adjacent mutated site, another hallmark of cooperative interactions. pi monomer/iteron interactions were quantified using a monomer-biased pi variant in vitro with the same collection of two-iteron constructs. The cooperativity coefficients mirror the plasmid incompatibility results for each construct tested. pi dimer/iteron interactions were quantified with a dimer-biased mutant in vitro and it was found that pi dimers bind with negligible cooperativity to two tandem iterons.

Production of Hev b5 as a fluorescent biotin-binding tripartite fusion protein in insect cells

The presented green fluorescent protein and streptavidin core-based tripartite fusion system provides a simple and efficient way for the production of proteins fused to it in insect cells. This fusion protein forms a unique tag, which serves as a multipurpose device enabling easy optimization of production, one-step purification via streptavidin-biotin interaction, and visualization of the fusion protein during downstream processing and in applications. In the present study, we demonstrate the successful production, purification, and detection of a natural rubber latex allergen Hev b5 with this system. We also describe the production of another NRL allergen with the system, Hev b1, which formed large aggregates and gave small yields in purification. The aggregates were detected at early steps by microscopical inspection of the infected insect cells producing this protein. Therefore, this fusion system can also be utilized as a fast indicator of the solubility of the expressed fusion proteins and may therefore be extremely useful in high-throughput expression approaches.

Role of pi dimers in coupling ("handcuffing") of plasmid R6K's gamma ori iterons

One proposed mechanism of replication inhibition in iteron-containing plasmids (ICPs) is "handcuffing," in which the coupling of origins via iteron-bound replication initiator (Rep) protein turns off origin function. In minimal R6K replicons, copy number control requires the interaction of plasmid-encoded pi protein with the seven 22-bp iterons of the gamma origin of replication. Like other related Rep proteins, pi exists as both monomers and dimers. However, the ability of pi dimers to bind iterons distinguishes R6K from most other ICPs, where only monomers have been observed to bind iterons. Here, we describe experiments to determine if monomers or dimers of pi protein are involved in the formation of handcuffed complexes. Standard ligation enhancement assays were done using pi variants with different propensities to bind iterons as monomers or dimers. Consistent with observations from several ICPs, a hyperreplicative variant (pi.P106L(wedge)F107S) exhibits deficiencies in handcuffing. Additionally, a novel dimer-biased variant of pi protein (pi.M36A(wedge)M38A), which lacks initiator function, handcuffs iteron-containing DNA more efficiently than does wild-type pi. The data suggest that pi dimers mediate handcuffing, supporting our previously proposed model of handcuffing in the gamma ori system. Thus, dimers of pi appear to possess three distinct inhibitory functions with respect to R6K replication: transcriptional autorepression of pi expression, in cis competition (for origin binding) with monomeric activator pi, and handcuffing-mediated inhibition of replication in trans.

pi protein- and ATP-dependent transitions from 'closed' to 'open' complexes at the gamma ori of plasmid R6K

R6K-encoded pi protein can bind to the seven, 22 bp tandem iterons of the gamma origin. In this work, we use a variant of pi, His-pi.F107S, that is hyperactive in replication. In vitro, His-pi.F107S-dependent local DNA melting (open complex formation) occurs in the absence of host proteins (IHF/HU or DnaA) and it is positioned in the A + T-rich region adjacent to iterons. Experiments described here examine the effects of ATP, Mg2+ and temperature on the opening reaction. We show that the opening of the gamma origin can occur in the presence of ATP as well as AMP-PCP (a non-hydrolyzable ATP analog). This suggests that, for gamma origin, ATP hydrolysis may be unnecessary for open complex formation facilitated by His-pi.F107S. In the absence of ATP or Mg2+, His-pi.F107S yielded data suggestive of distortions in the iteron attributable to DNA bending rather than DNA melting. Our findings also demonstrate that ATP and pi stimulate open complex formation over a wide range of temperatures, but not at 0 degrees C. These and other results indicate that ATP and/or Mg2+ are not needed for His-pi.F107S binding to iterons and that ATP effects an allosteric change in the protein bound to gamma origin.