Helicobacter pylori is a gram-negative bacterium, which colonizes the gastric mucosa of humans and is implicated in a wide range of gastroduodenal diseases. The genomic sequences of two H.pylori strains, 26695 and J99, have been published recently. About two dozen potential restrictionmodification (R-M) systems have been annotated in both genomes, which is far above the average number of R-M systems in other sequenced genomes. Here we describe a functional analysis of the 16 putative Type II R-M systems in the H.pylori J99 genome. To express potentially toxic endonuclease genes, a unique vector was constructed, which features repression and antisense transcription as dual control elements. To determine the methylation activities of putative DNA methyltransferases, we developed polyclonal antibodies able to detect DNA containing N6-methyladenine or N4-methylcytosine. We found that <30% of the potential Type II R-M systems in H.pylori J99 strain were fully functional, displaying both endonuclease and methyltransferase activities. Helicobacter pylori may maintain a variety of functional R-M systems, which are believed to be a primitive bacterial 'immune' system, by alternatively turning on/off a subset of numerous R-M systems.
SummaryDNA relaxases play an essential role in the initiation and termination of conjugative DNA transfer. Purification and characterization of relaxases from several plasmids has revealed the reaction mechanism: relaxases nick duplex DNA in a site-and strand-specific manner by catalysing a transesterification. The product of the reaction is a nicked double-stranded DNA molecule with a sequestered 3Ј-OH and the relaxase covalently bound to the 5Ј end of the cleaved strand via a phosphotyrosyl linkage. The relaxase-catalysed transesterification is isoenergetic and reversible; a second transesterification ligates the nicked DNA. However, the covalent nucleoprotein complex is relatively long-lived, a property that is likely to be essential for its role as an intermediate in the process of conjugative DNA transfer. Subsequent unwinding of the nicked DNA intermediate is required to produce the single strand of DNA transferred to the recipient cell. This reaction is catalysed by a DNA helicase, an activity intrinsic to the relaxase protein in some, but not all, plasmid systems. The first relaxase-catalysed transesterification is essential for initiation of conjugative strand transfer, whereas the second is presumably required for termination of the process. The relaxase, in conjunction with several auxiliary proteins, forms the relaxation complex or relaxosome first described nearly 30 years ago as being associated with conjugative and mobilizable plasmids.
Concerted Assembly and Cloning of Multiple DNA Segments Using In Vitro Site-Specific Recombination: Functional Analysis of Multi-Segment Expression Clones
The ability to clone and manipulate DNA segments is central to molecular methods that enable expression, screening, and functional characterization of genes, proteins, and regulatory elements. We previously described the development of a novel technology that utilizes in vitro site-specific recombination to provide a robust and flexible platform for high-throughput cloning and transfer of DNA segments. By using an expanded repertoire of recombination sites with unique specificities, we have extended the technology to enable the high-efficiency in vitro assembly and concerted cloning of multiple DNA segments into a vector backbone in a predefined order, orientation, and reading frame. The efficiency and flexibility of this approach enables collections of functional elements to be generated and mixed in a combinatorial fashion for the parallel assembly of numerous multi-segment constructs. The assembled constructs can be further manipulated by directing exchange of defined segments with alternate DNA segments. In this report, we demonstrate feasibility of the technology and application to the generation of fusion proteins, the linkage of promoters to genes, and the assembly of multiple protein domains. The technology has broad implications for cell and protein engineering, the expression of multidomain proteins, and gene function analysis.[Supplemental material is available online at www.genome.org.]The cloning and manipulation of DNA segments, typically encoding functional elements such as promoters, genes, protein domains, or fusion tags, are central to methods of cell engineering, protein production, and gene-function analysis. The large number of available genome sequences now makes it possible to create and apply repositories of defined functional elements to conduct high-throughput, genome-wide analyses. The Gateway Cloning Technology (Hartley et al. 2000) uses in vitro sitespecific recombination to clone and subsequently transfer DNA segments between vector backbones. This approach has been used to generate several large clone collections (Entry Clones), in some cases comprising the entire or nearly entire coding capacity of model genomes as open reading frames (ORFs). These ORFeomes include Caenorhabditis elegans (Walhout et al. 2000b;Reboul et al. 2001Reboul et al. , 2003, Pseudomonas aeruginosa (LaBaer et al. 2004), and Saccharomyces cerevisiae (G. Marsischky, pers. comm.), Arabidopsis (Yamada et al. 2003; also see Atome project http:// genoplante-info.infobiogen.fr/Databases/CT_Nouveaux_Outils/ NO2001054/), human (clones available from several commercial sources), and an incipient collection of Drosophila ORFs (http:// www.fruitfly.org/EST/gateway.shtml). A collection of sequenced, full-length Arabidopsis cDNAs in the Gateway Vector pCMV-SPORT6 will shortly be made available through INRA-Genoscope (Castelli et al. 2004). Repositories of full-length clones, some of which are in the Gateway format, are available for Xenopus (http://xgc.nci.nih.gov/), zebrafish (http://zgc.nci.nih.gov/), as well as many hu...
Yeast α Mating Factor Structure-Activity Relationship Derived from Genetically Selected Peptide Agonists and Antagonists of Ste2p
␣-Factor, a 13-amino-acid pheromone secreted by haploid ␣ cells of Saccharomyces cerevisiae, binds to Ste2p, a seven-transmembrane, G-protein-coupled receptor present on haploid a cells, to activate a signal transduction pathway required for conjugation and mating. To determine the structural requirements for ␣-factor activity, we developed a genetic screen to identify from random and semirandom libraries novel peptides that function as agonists or antagonists of Ste2p. The selection scheme was based on autocrine strains constructed to secrete random peptides and respond by growth to those that were either agonists or antagonists of Ste2p. Analysis of a number of peptides obtained by this selection procedure indicates that Trp1, Trp3, Pro8, and Gly9 are important for agonist activity specifically. His2, Leu4, Leu6, Pro10, a hydrophobic residue 12, and an aromatic residue 13 are important for both agonist and antagonist activity. Our results also show that activation of Ste2p can be achieved with novel, unanticipated combinations of amino acids. Finally, the results suggest the utility of this selection scheme for identifying novel ligands for mammalian G-protein-coupled receptors heterologously expressed in S. cerevisiae.Haploid Saccharomyces cells of mating type ␣ secrete a 13-amino-acid pheromone, ␣-factor (Trp1-His2-Trp3-Leu4-Gln5-Leu6-Lys7-Pro8-Gly9-Gln10-Pro11-Met12-Tyr13), that can bind and stimulate Ste2p, a G-protein-coupled receptor expressed on the surface of haploid cells of mating type a (reviewed in reference 26). Binding of ␣-factor to Ste2p activates the pheromone signaling pathway by promoting on the cytoplasmic side of the plasma membrane dissociation of a coupled heterotrimeric G protein into its constituent ␣ subunit and ␥ complex. The ␥ complex in conjunction with Cdc42p initiates a kinase cascade that results in activation of mitogenactivated protein kinase homologs, Kss1p and Fus3p (reviewed in reference 17). These activated kinases promote both cell cycle arrest, through inactivation of the cyclin B/p34 cdc28 complex in a process mediated by Far1p, and transcription of a variety of genes required for mating and conjugation, mediated by the Ste12p transcriptional activator. Activation of this signal transduction pathway is essential for productive mating, and mutations that attenuate this pathway result in sterility.Current knowledge of ␣-factor suggests a complex structurefunction relationship. Although determinants of its various biological activities are not restricted to discrete peptide regions, the determinants may be more heavily concentrated in certain domains. For example, residues that initiate signaling may be concentrated in the N terminus, while those that mediate binding may dominate the C-terminal region. This suggestion is based on observations that removal or substitution of Trp1, His2, or Trp3 results in loss of biological activity that exceeds the relatively small reductions in binding affinity (10,22). For example, removal of Trp1 to form des-Trp1-␣-factor yields a pep...
The product of the Escherichia coli F plasmid traI gene is required for DNA transfer via bacterial conjugation. This bifunctional protein catalyzes the unwinding of duplex DNA and is a sequence-specific DNA transesterase. The latter activity provides the site-and strandspecific nick required to initiate DNA transfer. To address the role of the TraI helicase activity in conjugative DNA transfer traI mutants were constructed and their function in DNA transfer was evaluated using genetic and biochemical methods. A traI deletion/insertion mutant was transfer-defective as expected. A traI C-terminal deletion that removed the helicase-associated motifs was also transfer-defective despite the fact that the region of traI encoding the transesterase activity was intact. Biochemical studies demonstrated that the N-terminal domain was sufficient to catalyze oriT-dependent transesterase activity. Thus, a functional transesterase was not sufficient to support DNA transfer. Finally, a point mutant, TraI-K998M, that lacked detectable helicase activity was characterized. This protein catalyzed oriT-dependent transesterase activity in vitro and in vivo but failed to complement a traI deletion strain in conjugative DNA transfer assays. Thus, both the transesterase and helicase activities of TraI are essential for DNA strand transfer.
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