Rita Przybilski
University of Otago
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Featured researches published by Rita Przybilski.
PLOS Genetics | 2013
Reuben B. Vercoe; James T. Chang; Ron L. Dy; Corinda Taylor; Tamzin Gristwood; James S. Clulow; Corinna Richter; Rita Przybilski; Andrew R. Pitman; Peter C. Fineran
In prokaryotes, clustered regularly interspaced short palindromic repeats (CRISPRs) and their associated (Cas) proteins constitute a defence system against bacteriophages and plasmids. CRISPR/Cas systems acquire short spacer sequences from foreign genetic elements and incorporate these into their CRISPR arrays, generating a memory of past invaders. Defence is provided by short non-coding RNAs that guide Cas proteins to cleave complementary nucleic acids. While most spacers are acquired from phages and plasmids, there are examples of spacers that match genes elsewhere in the host bacterial chromosome. In Pectobacterium atrosepticum the type I-F CRISPR/Cas system has acquired a self-complementary spacer that perfectly matches a protospacer target in a horizontally acquired island (HAI2) involved in plant pathogenicity. Given the paucity of experimental data about CRISPR/Cas–mediated chromosomal targeting, we examined this process by developing a tightly controlled system. Chromosomal targeting was highly toxic via targeting of DNA and resulted in growth inhibition and cellular filamentation. The toxic phenotype was avoided by mutations in the cas operon, the CRISPR repeats, the protospacer target, and protospacer-adjacent motif (PAM) beside the target. Indeed, the natural self-targeting spacer was non-toxic due to a single nucleotide mutation adjacent to the target in the PAM sequence. Furthermore, we show that chromosomal targeting can result in large-scale genomic alterations, including the remodelling or deletion of entire pre-existing pathogenicity islands. These features can be engineered for the targeted deletion of large regions of bacterial chromosomes. In conclusion, in DNA–targeting CRISPR/Cas systems, chromosomal interference is deleterious by causing DNA damage and providing a strong selective pressure for genome alterations, which may have consequences for bacterial evolution and pathogenicity.
RNA Biology | 2011
Rita Przybilski; Corinna Richter; Tamzin Gristwood; James S. Clulow; Reuben B. Vercoe; Peter C. Fineran
CRISPR/Cas systems provide bacteria and archaea with small RNA-based adaptive immunity against foreign elements such as phages and plasmids. An important step in the resistance mechanism involves the generation of small guide RNAs (crRNAs) that, in combination with Cas proteins, recognize and inhibit foreign nucleic acids in a sequence specific manner. The generation of crRNAs requires processing of the primary CRISPR RNA by an endoribonuclease. In this study we have characterized the Ypest subtype CRISPR/Cas system in the plant pathogen Pectobacterium atrosepticum. We analyse the transcription of the cas genes and the 3 CRISPR arrays. The cas genes are expressed as an operon and all three CRISPR arrays are transcribed and processed into small RNAs. The Csy4 protein was identified as responsible for processing of CRISPR RNA in vivo and in vitro into crRNAs and appears to interact with itself in the absence of other Cas proteins. This study furthers our understanding of the CRISPR/Cas mechanism by providing the first in vivo evidence that the CRISPR endoribonuclease Csy4 generates crRNAs in its native host and characterizes the operonic transcription of the cas cluster.
Nucleic Acids Research | 2014
Ron L. Dy; Rita Przybilski; Koen Semeijn; George P. C. Salmond; Peter C. Fineran
Bacterial abortive infection (Abi) systems are ‘altruistic’ cell death systems that are activated by phage infection and limit viral replication, thereby providing protection to the bacterial population. Here, we have used a novel approach of screening Abi systems as a tool to identify and characterize toxin–antitoxin (TA)-acting Abi systems. We show that AbiE systems are encoded by bicistronic operons and function via a non-interacting (Type IV) bacteriostatic TA mechanism. The abiE operon was negatively autoregulated by the antitoxin, AbiEi, a member of a widespread family of putative transcriptional regulators. AbiEi has an N-terminal winged-helix-turn-helix domain that is required for repression of abiE transcription, and an uncharacterized bi-functional C-terminal domain, which is necessary for transcriptional repression and sufficient for toxin neutralization. The cognate toxin, AbiEii, is a predicted nucleotidyltransferase (NTase) and member of the DNA polymerase β family. AbiEii specifically bound GTP, and mutations in conserved NTase motifs (I-III) and a newly identified motif (IV), abolished GTP binding and subsequent toxicity. The AbiE systems can provide phage resistance and enable stabilization of mobile genetic elements, such as plasmids. Our study reveals molecular insights into the regulation and function of the widespread bi-functional AbiE Abi-TA systems and the biochemical properties of both toxin and antitoxin proteins.
Biochimica et Biophysica Acta | 2013
Gregory M. Cook; Jennifer Robson; Rebekah A. Frampton; Joanna Leigh McKenzie; Rita Przybilski; Peter C. Fineran; Vickery L. Arcus
Toxin-antitoxin (TA) systems are widespread in bacteria and archaea and play important roles in a diverse range of cellular activities. TA systems have been broadly classified into 5 types and the targets of the toxins are diverse, but the most frequently used cellular target is mRNA. Toxins that target mRNA to inhibit translation can be classified as ribosome-dependent or ribosome-independent RNA interferases. These RNA interferases are sequence-specific endoribonucleases that cleave RNA at specific sequences. Despite limited sequence similarity, ribosome-independent RNA interferases belong to a limited number of structural classes. The MazF structural family includes MazF, Kid, ParE and CcdB toxins. MazF members cleave mRNA at 3-, 5- or 7-base recognition sequences in different bacteria and have been implicated in controlling cell death (programmed) and cell growth, and cellular responses to nutrient starvation, antibiotics, heat and oxidative stress. VapC endoribonucleases belong to the PIN-domain family and inhibit translation by either cleaving tRNA(fMet) in the anticodon stem loop, cleaving mRNA at -AUA(U/A)-hairpin-G- sequences or by sequence-specific RNA binding. VapC has been implicated in controlling bacterial growth in the intracellular environment and in microbial adaptation to nutrient limitation (nitrogen, carbon) and heat shock. ToxN shows structural homology to MazF and is also a sequence-specific endoribonuclease. ToxN confers phage resistance by causing cell death upon phage infection by cleaving cellular and phage RNAs, thereby interfering with bacterial and phage growth. Notwithstanding our recent progress in understanding ribonuclease action and function in TA systems, the environmental triggers that cause release of the toxin from its cognate antitoxin and the precise cellular function of these systems in many bacteria remain to be discovered. This article is part of a Special Issue entitled: RNA Decay mechanisms.
PLOS Genetics | 2012
Tim R. Blower; Terry J. Evans; Rita Przybilski; Peter C. Fineran; George P. C. Salmond
Abortive infection, during which an infected bacterial cell commits altruistic suicide to destroy the replicating bacteriophage and protect the clonal population, can be mediated by toxin-antitoxin systems such as the Type III protein–RNA toxin-antitoxin system, ToxIN. A flagellum-dependent bacteriophage of the Myoviridae, ΦTE, evolved rare mutants that “escaped” ToxIN-mediated abortive infection within Pectobacterium atrosepticum. Wild-type ΦTE encoded a short sequence similar to the repetitive nucleotide sequence of the RNA antitoxin, ToxI, from ToxIN. The ΦTE escape mutants had expanded the number of these “pseudo-ToxI” genetic repeats and, in one case, an escape phage had “hijacked” ToxI from the plasmid-borne toxIN locus, through recombination. Expression of the pseudo-ToxI repeats during ΦTE infection allowed the phage to replicate, unaffected by ToxIN, through RNA–based molecular mimicry. This is the first example of a non-coding RNA encoded by a phage that evolves by selective expansion and recombination to enable viral suppression of a defensive bacterial suicide system. Furthermore, the ΦTE escape phages had evolved enhanced capacity to transduce replicons expressing ToxIN, demonstrating virus-mediated horizontal transfer of genetic altruism.
Molecular Cell | 2016
Adrian G. Patterson; Simon A. Jackson; Corinda Taylor; Gary B. Evans; George P. C. Salmond; Rita Przybilski; Raymond H.J. Staals; Peter C. Fineran
Summary Bacteria commonly exist in high cell density populations, making them prone to viral predation and horizontal gene transfer (HGT) through transformation and conjugation. To combat these invaders, bacteria possess an arsenal of defenses, such as CRISPR-Cas adaptive immunity. Many bacterial populations coordinate their behavior as cell density increases, using quorum sensing (QS) signaling. In this study, we demonstrate that QS regulation results in increased expression of the type I-E, I-F, and III-A CRISPR-Cas systems in Serratia cells in high-density populations. Strains unable to communicate via QS were less effective at defending against invaders targeted by any of the three CRISPR-Cas systems. Additionally, the acquisition of immunity by the type I-E and I-F systems was impaired in the absence of QS signaling. We propose that bacteria can use chemical communication to modulate the balance between community-level defense requirements in high cell density populations and host fitness costs of basal CRISPR-Cas activity.
Biological Chemistry | 2007
Rita Przybilski; Christian Hammann
Abstract The hammerhead ribozyme is a small RNA endonuclease found in sub-viral plant pathogens, in transcripts from certain animal satellite DNAs and encoded at distinct loci of Arabidopsis thaliana. Kinetic analyses of tertiary stabilised ribozymes from peach latent mosaic viroid (PLMVd), Schistosoma mansoni and A. thaliana revealed a ten-fold difference in cleavage rates. Core nucleotide variations affected cleavage reactions least in the A. thaliana ribozyme, and most in the S. mansoni ribozyme. The reverse ligation reaction was catalysed efficiently by the PLMVd and A. thaliana ribozymes. The different behaviour of the individual hammerhead ribozymes is discussed in terms of structure and function.
ChemBioChem | 2006
Rita Przybilski; Christian Hammann
RNA catalysis seems to be considerably more wide spread than originally thought, with the most prominent example being the ribosome, where RNA catalyses the peptidyl-transferase reaction. Among the most and longest studied catalytic RNAs are the small nucleolytic ribozymes, such as the hairpin, VS, HDV and hammerhead ribozymes. They all catalyse the site-specific cleavage of their own phosphodiester backbone in cis or that of a substrate RNA in trans through a transesterification reaction involving the 2’-OH. A novel crystal structure of the hammerhead ribozyme has just been reported, and this should help to clarify a long-standing debate on the mechanism of catalysis. First identified in the 1980s as a catalytically active element in the replication cycle of certain viroids and the satellite RNA of plant viruses, the hammerhead ribozyme is the smallest naturally occurring RNA endonuclease. The motif has also been found in transcripts from the satellite DNA of amphibians, schistosomes, cave cricket and, most recently, encoded in the genomes of other eukaryotic organisms. The hammerhead ribozyme consists of a catalytic core of 11 conserved nucleotides that are flanked by three helices (Figure 1A). In the absence of divalent metal ions, the structure is extended, but upon addition of Mg , the RNA folds in two well-defined steps into a Y-shaped structure (Figure 1B), as deduced by Lilley and coworkers in studies using comparative gel electrophoresis, FRET, NMR and calorimetry. In this active conformation, a reversible transesterification reaction is catalysed by the hammerhead ribozyme (Scheme 1). 9] During cleavage, the 2’OH of nucleotide C17 is deprotonated and attacks the scissile 3’,5’ phosphodiester bond. Of the two cleavage products one carries a 2’,3’-cyclic phosphate, the other a 5’-hydroxy terminus. In the reverse (ligation) reaction, the 5’-oxygen attacks the cyclic phosphate. For the hammerhead ribozyme, however, the ligation does not proceed as efficiently as seen for the hairpin ribozyme. Both reactions proceed through the same, trigonal-bipyramidal pentacoordinated transition state (Scheme 1), thus meeting the principle of microscopic reversibility. This transition state was deduced from the observation that the chirality of the scissile phosphate, when exchanged for a phosphorothioate, was inverted during the course of the reaction, a hallmark of the SN2 mechanism. In the transition state, the 2’-OH of C17 has to be in line with the adjacent phosphorus and the 5’-oxygen of nucleotide 1.1 (Scheme 1). This requirement and other data detailed below gave rise to presumably the longest-standing debate in the ribozyme field. The first hammerhead ribozyme crystal structures showed a maximal deviation from the ACHTUNGTRENNUNGrequired in-line orientation of the three atoms, at 908. Hammerhead cleavage, however, could be achieved by soaking all RNA crystals with divalent metal ions. While the first observation argued for a ground-state structure to be present in the crystal, the second would indicate that no major rearrangements were necessary to reach the tran[a] R. Przybilski, Dr. C. Hammann AG Molecular Interactions Department of Genetics, University of Kassel Heinrich-Plett-Strasse 40 34132 Kassel (Germany) Fax: (+49)561-804-4800 E-mail : [email protected] Figure 1. The hammerhead ribozyme. A) Secondary structure with stems I, II and III and the 11 conserved nucleotides (bold). Cleavage takes place between nucleotides 17 and 1.1, as indicated by an arrow. Numbers are given according to the conventional scheme. In minimal versions of the ribozyme, either stem I or II is closed by loops (dashed lines). B) Y-shaped conformation of the minimal version of the ribozyme upon addition of magnesium. Naturally occurring ribozymes are endowed with tertiary stabilising structures formed between C) loops L1 and L2 or D) loop L1 and bulge B2 in stem II. The ribozyme format shown in (D) was used for crystallisation.
Biochemical Society Transactions | 2005
Stefan Gräf; Rita Przybilski; Gerhard Steger; Christian Hammann
The hammerhead ribozyme is the smallest naturally occurring RNA endonuclease. It is found in subviral plant pathogens and transcripts of satellite DNA from a limited number of organisms. We have performed a database search for novel examples of this catalytic RNA, taking into consideration the recently defined structural requirements for an efficient cleavage under physiological magnesium ion concentrations. In this search, we find, apart from the known examples, several hundreds of motifs in organisms of all kingdoms of life. In a first set of experiments, we analysed hammerhead ribozymes from Arabidopsis thaliana. We found that these sequences are tissue-specifically expressed and that they undergo self-cleavage in planta. Furthermore, their activity under physiological magnesium ion concentrations depends on functional loop-loop interactions, as shown by the lack of activity of appropriate mutants.
Applied and Environmental Microbiology | 2017
Tim R. Blower; Ray Chai; Rita Przybilski; Shahzad Chindhy; Xinzhe Fang; Samuel E. Kidman; Hui Tan; Ben F. Luisi; Peter C. Fineran; George P. C. Salmond
ABSTRACT Some bacteria, when infected by their viral parasites (bacteriophages), undergo a suicidal response that also terminates productive viral replication (abortive infection [Abi]). This response can be viewed as an altruistic act protecting the uninfected bacterial clonal population. Abortive infection can occur through the action of type III protein-RNA toxin-antitoxin (TA) systems, such as ToxINPa from the phytopathogen Pectobacterium atrosepticum. Rare spontaneous mutants evolved in the generalized transducing phage ΦM1, which escaped ToxINPa-mediated abortive infection in P. atrosepticum. ΦM1 is a member of the Podoviridae and a member of the “KMV-like” viruses, a subset of the T7 supergroup. Genomic sequencing of ΦM1 escape mutants revealed single-base changes which clustered in a single open reading frame. The “escape” gene product, M1-23, was highly toxic to the host bacterium when overexpressed, but mutations in M1-23 that enabled an escape phenotype caused M1-23 to be less toxic. M1-23 is encoded within the DNA metabolism modular section of the phage genome, and when it was overexpressed, it copurified with the host nucleotide excision repair protein UvrA. While the M1-23 protein interacted with UvrA in coimmunoprecipitation assays, a UvrA mutant strain still aborted ΦM1, suggesting that the interaction is not critical for the type III TA Abi activity. Additionally, ΦM1 escaped a heterologous type III TA system (TenpINPl) from Photorhabdus luminescens (reconstituted in P. atrosepticum) through mutations in the same protein, M1-23. The mechanistic action of M1-23 is currently unknown, but further analysis of this protein may provide insights into the mode of activation of both systems. IMPORTANCE Bacteriophages, the viral predators of bacteria, are the most abundant biological entities and are important factors in driving bacterial evolution. In order to survive infection by these viruses, bacteria have evolved numerous antiphage mechanisms. Many of the studies involved in understanding these interactions have led to the discovery of biotechnological and gene-editing tools, most notably restriction enzymes and more recently the clustered regularly interspaced short palindromic repeats (CRISPR)-Cas systems. Abortive infection is another such antiphage mechanism that warrants further investigation. It is unique in that activation of the system leads to the premature death of the infected cells. As bacteria infected with the virus are destined to die, undergoing precocious suicide prevents the release of progeny phage and protects the rest of the bacterial population. This altruistic suicide can be caused by type III toxin-antitoxin systems, and understanding the activation mechanisms involved will provide deeper insight into the abortive infection process.