The Saccharomyces cerevisiae 2-μm plasmid is a multicopy selfish genome that resides in the nucleus. The genetic organization of the plasmid is optimized for stable, high-copy propagation in hostcell populations. The plasmid's partitioning system poaches host factors, including the centromere-specific histone H3-variant Cse4 and the cohesin complex, enabling replicated plasmid copies to segregate equally in a chromosome-coupled fashion. We have characterized the in vivo chromatin topology of the plasmid partitioning locus STB in its Cse4-associated and Cse4-nonassociated states. We find that the occupancy of Cse4 at STB induces positive DNA supercoiling, with a linking difference (ΔLk) contribution estimated between +1 and +2 units. One plausible explanation for this contrary topology is the presence of a specialized Cse4-containing nucleosome with a right-handed DNA writhe at a functional STB, contrasted by a standard histone H3-containing nucleosome with a left-handed DNA writhe at a nonfunctional STB. The similarities between STB and centromere in their nucleosome signature and DNA topology would be consistent with the potential origin of the unusual point centromere of budding yeast chromosomes from the partitioning locus of an ancestral plasmid.CEN evolution | nucleosome topology | reversome T he 2-μm plasmid of Saccharomyces cerevisiae resides in the nucleus at 40 to 60 copies per cell, and propagates itself with nearly the same stability as chromosomes (1, 2). The plasmid is a benign selfish DNA element that seems to provide no advantage to its host, but poses, at its normal copy number, no serious disadvantage either. In haploid cells the plasmid is organized into a cluster of three to five foci, and segregates as a cluster (3). This effective reduction in copy number necessitates an active partitioning system, comprised of two plasmid-coded proteins, Rep1 and Rep2, and a cis-acting partitioning locus STB, to ensure equal or nearly equal plasmid segregation. A decline in plasmid copy number because of rare missegregation events is corrected via DNA amplification triggered by the Flp sitespecific recombination system harbored by the plasmid (4, 5). Positive and negative regulatory circuits implemented through the plasmid-coded Raf1 protein and the Rep proteins ensure quick amplification response without the danger of runaway increase in copy number (6-8).The Rep-STB system channels several host factors involved in chromosome segregation toward the execution of plasmid segregation. These factors include the mitotic spindle, the spindleassociated motor Kip1, the RSC2 chromatin-remodeling complex, the centromere-specific histone H3-variant Cse4 (CenH3), and the yeast cohesin complex (9-15). The de novo assembly of the plasmid-partitioning complex at STB during the G1-S window of each cell cycle (9,12,14,16) is reminiscent of the assembly of the kinetochore complex at centromeres. However, kinetochore components have not been detected at STB by ChIP (13).The assembly of the plasmid-partitioning complex culmin...
The basic networking unit in Bluetooth is piconet, and a larger‐area Bluetooth network can be formed by multiple piconets, called scatternet. However, the structure of scatternets is not defined in the Bluetooth specification and remains as an open issue at the designers' choice. It is desirable to have simple yet efficient scatternet topologies with good supports of routing protocols, considering that Bluetooths are to be used for personal area networks with design goals of simplicity and compactness. In the literature, although many routing protocols have been proposed for mobile ad hoc networks, directly applying them poses a problem due to Bluetooth's special baseband and MAC‐layer features. In this work, we propose an attractive scatternet topology called BlueRing, which connects piconets as a ring interleaved by bridges between piconets, and address its formation, routing, and topology‐maintenance protocols. The BlueRing architecture enjoys the following fine features. First, routing on BlueRing is stateless in the sense that no routing information needs to be kept by any host once the ring is formed. This would be favorable for environments such as Smart Homes where computing capability is limited. Second, the architecture is scalable to median‐size scatternets easily (e.g. around 50 ∼ 70 Bluetooth units). In comparison, most star‐ or treelike scatternet topologies can easily form a communication bottleneck at the root of the tree as the network enlarges. Third, maintaining a BlueRing is an easy job even as some Bluetooth units join or leave the network. To tolerate single‐point failure, we propose a protocol‐level remedy mechanism. To tolerate multipoint failure, we propose a recovery mechanism to reconnect the BlueRing. Graceful failure is tolerable as long as no two or more critical points fail at the same time. As far as we know, the fault‐tolerant issue has not been properly addressed by existing scatternet protocols yet. In addition, we also evaluate the ideal network throughput at different BlueRing sizes and configurations by mathematical analysis. Simulation results are presented, which demonstrate that BlueRing outperforms other scatternet structures with higher network throughput and moderate packet delay. Copyright © 2003 John Wiley & Sons, Ltd.
The Helicobacter pylori (Hp) Asp-tRNAAsn/Glu-tRNAGln amidotransferase (AdT) plays important roles in indirect aminoacylation and translational fidelity. AdT has two active sites, in two separate subunits. Kinetic studies have suggested that interdomain communication occurs between these subunits, however this mechanism is not well understood. To explore domain-domain communication in AdT, an assay was adapted and optimized to kinetically characterize the kinase activity of Hp AdT. This assay was applied to the analysis of a series of point mutations at conserved positions throughout the putative AdT ammonia tunnel that connects the two active sites. Several mutations were identified that caused significant decreases in AdT’s kinase activity (reduced by 55–75 %). Mutations at Thr149 (37 Å distal to the GatB kinase active site) and Lys89 (located at the interface of GatA and GatB) were detrimental to AdT’s kinase activity, suggesting that these mutations have disrupted interdomain communication between the two active sites. Models of wild-type AdT, a valine mutation at Thr149, and an arginine mutation at Lys89 were subjected to molecular dynamics simulations. The comparison of wild-type, T149V and K89R AdT simulation results unmask 59 common residues that are likely involved in connecting the two active sites.
Octaprenyl diphosphate synthase (OPPS) catalyzes consecutive condensation reactions of farnesyl diphosphate (FPP) with five molecules of isopentenyl diphosphates (IPP) to generate C(40) octaprenyl diphosphate, which constitutes the side chain of ubiquinone or menaquinone. To understand the roles of active site amino acids in substrate binding and catalysis, we conducted site-directed mutagenesis studies with Escherichia coli OPPS. In conclusion, D85 is the most important residue in the first DDXXD motif for both FPP and IPP binding through an H-bond network involving R93 and R94, respectively, whereas R94, K45, R48, and H77 are responsible for IPP binding by providing H-bonds and ionic interactions. K170 and T171 may stabilize the farnesyl carbocation intermediate to facilitate the reaction, whereas R93 and K225 may stabilize the catalytic base (MgPP(i)) for H(R) proton abstraction after IPP condensation. K225 and K235 in a flexible loop may interact with FPP when the enzyme becomes a closed conformation, which is therefore crucial for catalysis. Q208 is near the hydrophobic part of IPP and is important for IPP binding and catalysis.
Summary The multi-copy 2 micron plasmid of Saccharomyces cerevisiae, a resident of the nucleus, is remarkable for its high chromosome-like stability. The plasmid does not appear to contribute to the fitness of the host, nor does it impose a significant metabolic burden on the host at its steady state copy number. The plasmid may be viewed as a highly optimized selfish DNA element whose genome design is devoted entirely towards efficient replication, equal segregation and copy number maintenance. A partitioning system comprised of two plasmid coded proteins, Rep1 and Rep2, and a partitioning locus STB is responsible for equal or nearly equal segregation of plasmid molecules to mother and daughter cells. Current evidence supports a model in which the Rep-STB system promotes the physical association of the plasmid with chromosomes and thus plasmid segregation by a hitchhiking mechanism. The Flp site-specific recombination system housed by the plasmid plays a critical role in maintaining steady state plasmid copy number. A decrease in plasmid population due to rare missegregation events is rectified by plasmid amplification via a recombination induced rolling circle replication mechanism. Appropriate plasmid amplification, without runaway increase in copy number, is ensured by positive and negative regulation of FLP gene expression by plasmid coded proteins and by the control of Flp level/activity through host mediated post-translational modification(s) of Flp. The Flp system has been successfully utilized to understand mechanisms of site-specific recombination, to bring about directed genetic alterations for addressing fundamental problems in biology, and as a tool in biotechnological applications.
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