Sheryl A. Rakowski

Regulatory implications of protein assemblies at the gamma origin of plasmid R6K - a review.

Recognition of the replication origin (ori) by initiator protein is a recurring theme for the regulated initiation of DNA replication in diverse biological systems. The objective of the work reviewed here is to understand the initiation process focusing specifically on the gamma-ori of the antibiotic-resistance plasmid R6K. The control of gamma-ori copy number is determined by both plasmid-encoded and host-encoded factors. The two central regulatory elements of the plasmid are a multifunctional initiator protein pi, and sequence-related DNA target sites, the inverted half-repeats (IRs) and the direct repeats (DRs). The replication activator and inhibitor activities of pi seem to be at least partially distributed between two naturally occurring pi polypeptides (designated by their molecular weights pi35.0 and pi30.5). Regulatory variants of pi with altered states of oligomerization in nucleoprotein complexes with DRs and IRs have been isolated. The properties of these mutants laid the foundation for our model of pi protein activity which proposes that different protein surfaces are required for the formation of functionally distinct complexes of pi with DRs and IRs. These mutants also suggest that pi polypeptides have a modular structure; the C-terminus contains the DNA-binding domain while the N-terminus controls protein oligomerization. Additionally, pi35.0 binds to a novel DNA sequence in the A+T-rich segment of gamma-ori. This binding site is at or near the site from which synthesis of the leading strand begins.

Bacterial conjugation-based antimicrobial agents.

A clear imperative exists to generate radically different antibacterial technologies that will reduce the usage of conventional chemical antibiotics. Here we trace one route into this new frontier of drug discovery, a concept that we call the bacterial conjugation-based technologies (BCBT). One of the objectives of the BCBT is to exploit plasmid biology for combating the rising tide of antibiotic-resistant bacteria. Specifically, the concept utilizes conjugationally delivered plasmids as antimicrobial agents, and it builds on the accumulated work of many scientists dating back to the discoveries of conjugation and plasmids themselves. Each of the individual components that comprise the approach has been demonstrated to be feasible. We discuss the properties of bacterial plasmids to be employed in BCBT.

Role of π Dimers in Coupling (“Handcuffing”) of Plasmid R6K's γ 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 π protein with the seven 22-bp iterons of the γ origin of replication. Like other related Rep proteins, π exists as both monomers and dimers. However, the ability of π 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 π protein are involved in the formation of handcuffed complexes. Standard ligation enhancement assays were done using π variants with different propensities to bind iterons as monomers or dimers. Consistent with observations from several ICPs, a hyperreplicative variant (π·P106L∧F107S) exhibits deficiencies in handcuffing. Additionally, a novel dimer-biased variant of π protein (π·M36A∧M38A), which lacks initiator function, handcuffs iteron-containing DNA more efficiently than does wild-type π. The data suggest that π dimers mediate handcuffing, supporting our previously proposed model of handcuffing in the γ ori system. Thus, dimers of π appear to possess three distinct inhibitory functions with respect to R6K replication: transcriptional autorepression of π expression, in cis competition (for origin binding) with monomeric activator π, and handcuffing-mediated inhibition of replication in trans.

Plasmid R6K replication control.

The focus of this minireview is the replication control of the 39.9-kb plasmid R6K and its derivatives. Historically, this plasmid was thought to have a narrow host range but more recent findings indicate that its derivatives can replicate in a variety of enteric and non-enteric bacterial species (Wild et al., 2004). In the four-plus decades since it was first described, R6K has proven to be an excellent model for studies of plasmid DNA replication. In part this is because of its similarities to other systems in which replication is activated and regulated by Rep protein and iteron-containing DNA. However its apparent idiosynchracies have also added to its significance (e.g., independent and co-dependent replication origins, and Rep dimers that stably bind iterons). Here, we survey the current state of knowledge regarding R6K replication and place individual regulatory elements into a proposed homeostatic model with implications for the biological significance of R6K and its multiple origins of replication.

Structure-Based Functional Analysis of the Replication Protein of Plasmid R6K: Key Amino Acids at the π/DNA Interface

In previous work, we characterized the bases in an iteron of plasmid R6K that are important for the binding of pi protein monomers and dimers. Here we investigate the following six amino acids of pi, encoded by pir, hypothesized to be important for DNA contact: Ser71, Try74, Gly131, Gly211, Arg225, and Arg254.

Multiple Dictyostelid Species Destroy Biofilms of Klebsiella oxytoca and Other Gram Negative Species

Dictyostelids are free-living phagocytes that feed on bacteria in diverse habitats. When bacterial prey is in short supply or depleted, they undergo multicellular development culminating in the formation of dormant spores. In this work, we tested isolates representing four dictyostelid species from two genera (Dictyostelium and Polysphondylium) for the potential to feed on biofilms preformed on glass and polycarbonate surfaces. The abilities of dictyostelids were monitored for three hallmarks of activity: 1) spore germination on biofilms, 2) predation on biofilm enmeshed bacteria by phagocytic cells and 3) characteristic stages of multicellular development (streaming and fructification). We found that all dictyostelid isolates tested could feed on biofilm enmeshed bacteria produced by human and plant pathogens: Klebsiella oxytoca, Pseudomonas aeruginosa, Pseudomonas syringae, Erwinia amylovora 1189 (biofilm former) and E. amylovora 1189 Δams (biofilm deficient mutant). However, when dictyostelids were fed planktonic E. amylovora Δams the bacterial cells exhibited an increased susceptibility to predation by one of the two dictyostelid strains they were tested against. Taken together, the qualitative and quantitative data presented here suggest that dictyostelids have preferences in bacterial prey which affects their efficiency of feeding on bacterial biofilms.