Extensive unwinding of the plasmid template during staged enzymatic initiation of DNA replication from the origin of the Escherichia coli chromosome

Early in the staged initiation of enzymatic replication of plasmids containing the unique origin of the E. coli chromosome (oriC), the plasmid is converted to a new topological form which is highly underwound, two to 15 times more than native supercoiled DNA. The underwinding reaction precedes priming of DNA synthesis and follows an initial complex formation, requiring ATP and proteins dnaA, dnaB, and dnaC; underwinding depends on the further addition of gyrase and SSB. DnaB protein as a helicase and gyrase as a topoisomerase drive the underwinding with the energy of ATP hydrolysis. The underwound template, extensively single-stranded and complexed with proteins, is an active form for priming by primase and elongation by DNA polymerase III holoenzyme.     

DNA binding and antigenic specifications of DNA gyrase.

Complexes of DNA gyrase and minichromosomal DNA containing the origin of replication of Escherichia coli (oriC) can be formed without metabolic energy and visualised by electron microscopy. The A subunit, part of the A2B2-DNA gyrase complex is the binding protein. Various binding sites are scattered around the minichromosomal DNA including oriC. The minimal origin contains the only prominent and reproducible binding site. Binding to this site is suppressed by oxolinic acid and the ATP analogue beta-y-imido ATP. If gyrase isolated from the gram-positive bacterium Bacillus subtilis is used no binding to oriC is seen. This observation is consistent with antigenic differences between the A subunits of the two microorganisms. The binding to oriC might reflect a requirement for DNA gyrase during the initiation of DNA replication.     

The unique DNA topology and DNA topoisomerases of hyperthermophilic archaea

Abstract: Hyperthermophilic archaea exhibit a unique pattern of DNA topoisomerase activities. They have a peculiar enzyme, reverse gyrase, which introduces positive superturns into DNA at the expense of ATP. This enzyme has been found in all hyperthermophiles tested so far (including Bacteria) but never in mesophiles. Reverse gyrases are formed by the association of a helicase-like domain and a 5'-type I DNA topoisomerase. These two domains might be located on the same polypeptide. However, in the methanogenic archaeon Methanopyrus kandleri , the topoisomerase domain is divided between two subunits. Besides reverse gyrase, Archaea contain other type I DNA topoisomerases; in particular, M. kandleri harbors the only known procaryotic 3'-type I DNA topoisomerase (Topo V). Hyperthermophilic archaea also exhibit specific type II DNA topoisomerases (Topo II), i.e. whereas mesophilic Bacteria have a Topo II that produces negative supercoiling (DNA gyrase), the Topo II from Sulfolobus and Pyrococcus lack gyrase activity and are the smallest enzymes of this type known so far. This peculiar pattern of DNA topoisomerases in hyperthermophilic archaea is paralleled by a unique DNA topology, i.e. whereas DNA isolated from Bacteria and Eucarya is negatively supercoiled, plasmidic DNA from hyperthermophilic archaea are from relaxed to positively supercoiled. The possible evolutionary implications of these findings are discussed in this review. We speculate that gyrase activity in mesophiles and reverse gyrase activity in hyperthermophiles might have originated in the course of procaryote evolution to balance the effect of temperature changes on DNA structure.     

Plasmodium falciparum possesses a classical glutaredoxin and a second, glutaredoxin-like protein with a PICOT homology domain

The genes coding for two different proteins with homologies to glutaredoxins have been identified in the genome of the malarial parasite Plasmodium falciparum. Both genes were amplified from a gametocytic cDNA and overexpressed in Escherichia coli. The smaller protein (named PfGrx-1) with 12.4 kDa in size exhibits the typical glutaredoxin active site motif "CPYC," shows glutathione-dependent glutaredoxin activity in the beta-hydroxyethyl disulfide (HEDS) assay, and reduces Trypanosoma brucei ribonucleotide reductase. Glutathione:HEDS transhydrogenase activity (approximately 60 milliunits/mg of protein) was clearly detectable in trophozoite extracts from eight different P. falciparum strains and did not differ between chloroquine-resistant and -sensitive parasites. Five different antimalarial drugs at 100 microm did not significantly influence isolated PfGrx-1 activity. In contrast, the second protein (deduced mass 19.9 kDa) with homology to glutaredoxins (31% identity to Schizosaccharomyces pombe in a 140-amino acid overlap) was not active in the HEDS assay; however, its general dithiol reducing activity was demonstrated in the insulin assay in the presence of dithiothreitol. Interestingly, the sequence contains a PICOT (for protein kinase C-interacting cousin of thioredoxin) homology domain, which might suggest regulatory functions of the protein. We named this protein PfGLP-1, for P. falciparum 1-Cys-glutaredoxin-like protein-1. In contrast to glutaredoxins, PfGLP-1 could not be reduced by glutathione. This is the first report on glutaredoxin-like proteins in the family of Plasmodia.     

Dissection of the nucleotide cycle of B. subtilis DNA gyrase and its modulation by DNA

DNA topoisomerases catalyze the inter-conversion of different topological forms of DNA. While all type II DNA topoisomerases relax supercoiled DNA, DNA gyrase is the only enyzme that introduces negative supercoils into DNA at the expense of ATP hydrolysis. We present here a biophysical characterization of the nucleotide cycle of DNA gyrase from Bacillus subtilis, both in the absence and presence of DNA. B. subtilis DNA gyrase is highly homologous to its well-studied Escherichia coli counterpart, but exhibits unique mechanistic features. The active heterotetramer of B. subtilis DNA gyrase is formed by mixing the GyrA and GyrB subunits. GyrB undergoes nucleotide-induced dimerization and is an ATP-operated clamp. The intrinsic ATPase activity of gyrase is stimulated tenfold in the presence of plasmid DNA. However, in contrast to the E. coli homolog, the rate-limiting step in the nucleotide cycle of B. subtilis GyrB is ATP hydrolysis, not product dissociation or an associated conformational change. Furthermore, there is no cooperativity between the two DNA and ATP binding sites in B. subtilis DNA gyrase. Nevertheless, the enzyme is as efficient in negative supercoiling as the E. coli DNA gyrase. Our results provide evidence that the evolutionary goal of efficient DNA supercoiling can be realized by similar architecture, but differences in the underlying mechanism. The basic mechanistic features are conserved among DNA gyrases, but the kinetics of individual steps can vary significantly even between closely related enzymes. This suggests that each topoisomerase represents a different solution to the complex reaction sequence in DNA supercoiling.     

Plasmodium falciparum: an intervening sequence in the GBP 130/96 tR gene

The 96 tR antigen is a heat stable protein produced during the late stages of the intraerythrocytic development of the malaria parasite Plasmodium falciparum and is released into the culture supernatant or the sera of infected patients at the time of schizont rupture. This antigen, identified as a putative protective antigen, was shown to be identical to the glycophorin-binding protein GBP 130 (Perkins 1988, Bonnefoy et al. 1988). We report here that the gene contains a small undescribed intervening sequence located immediately after the sequence coding for the signal sequence. This shows that in P. falciparum, all the genes described so far coding for proteins exported outside the parasitophorous vacuole share a common organization.     

Streptococcus pneumononiae gyrase ATPase: development and validation of an assay for inhibitor discovery and characterization

The rise in bacterial resistance to antibiotics demonstrates the medical need for new antibacterial agents. One approach to this problem is to identify new antibacterials that act through validated drug targets such as bacterial DNA gyrase. DNA gyrase uses the energy of ATP hydrolysis to introduce negative supercoils into plasmid and chromosomal DNA and is essential for DNA replication. Inhibition of the ATPase activity of DNA gyrase is the mechanism by which coumarin-class antibiotics such as novobiocin inhibit bacterial growth. Although ATPase inhibitors exhibit potent antibacterial activity against gram-positive pathogens, no gyrase ATPase activity from a gram-positive organism is described in the literature. To address this, we developed and optimized an enzyme-coupled phosphate assay and used this assay to characterize the ATPase kinetics of Streptococcus pneumoniae gyrase. The S. pneumoniae enzyme exhibits cooperativity with ATP and requires organic potassium salts. We also studied inhibition of the enzyme by novobiocin. Apparent inhibition constants for novobiocin increased linearly with ATP concentration, indicative of an ATP-competitive mechanism. Similar binding affinities were measured by isothermal titration calorimetry. These results reveal unique features of the S. pneumoniae DNA gyrase ATPase and demonstrate the utility of the assay for screening and kinetic characterization of ATPase inhibitors.     

DNA-dependent ATPase activity associated with phage P22 gene 12 protein

The product of bacteriophage P22 gene 12 is known from genetic experiments to be essential for phage DNA replication. The P22 12 protein has been purified to near homogeneity from Escherichia coli lysogenic for lambda-P22 hybrid phage containing the replication genes of P22. The protein has a subunit molecular weight of 46,000. The purified protein contains ATPase activity that is stimulated by single-stranded DNA. The ATPase is poorly stimulated by double-stranded DNA. All four ribonucleoside triphosphates are hydrolyzed; none of the deoxynucleoside triphosphates are hydrolyzed. In addition, the P22 12 protein binds to single-stranded DNA in the presence of ATP. Studies of oligonucleotide synthesis by P22 12 protein in conjunction with E. coli dnaG primase are presented in the succeeding paper (Wickner, S. (1984) J. Biol. Chem. 259, 14044-14047).     

DNA gyrase subunit stoichiometry and the covalent attachment of subunit A to DNA during DNA cleavage.

Escherichia coli DNA gyrase contains a 1:1 ratio of protomers coded by the genes gyrA and gyrB. This along with previous results shows that the enzyme has two copies of each protomer and thus a molecular weight of 400,000. Abortion of the gyrase reaction results in double-strand breakage of the DNA and covalent attachment of both gyrA protomers to the 5'-cut ends. We conclude that the gyrA protomer contains a critical part of the active site for the concerted breakage and reunion reaction of gyrase, the topoisomerase activity of the enzyme.     

Mechanism of inhibition of DNA gyrase by quinolone antibacterials: a cooperative drug--DNA binding model

We have proposed a cooperative quinolone-DNA binding model for the inhibition of DNA gyrase. The essential feature of the model is that bound gyrase induces a specific quinolone binding site in the relaxed DNA substrate in the presence of ATP. The binding affinity and specificity are derived from two unique and equally important functional features: the specific conformation of the proposed single-stranded DNA pocket induced by the enzyme and the unique self-association phenomenon (from which the cooperativity is derived) of the drug molecules to fit the binding pocket with a high degree of flexibility. Supporting evidence for and implications of this model are provided.     

Replication of lambda dv DNA in vitro.

Exogenous lambda dv DNA was replicated in extracts prepared from E. coli cells carrying plasmids with inducible lambda O and /or P genes. Extracts from cells carrying only one of the two lambda replication functions complement each other in this reaction. The reaction further requires ribonucleotide triphosphates, an ATP regenerating system, DNA gyrase and RNA polymerase functions. Density labelling of the superhelical reaction products results in hybrid density indicating that one complete round of replication has taken place in vitro.     

Genome-wide detection of serpentine receptor-like proteins in malaria parasites

Serpentine receptors comprise a large family of membrane receptors distributed over diverse organisms, such as bacteria, fungi, plants and all metazoans. However, the presence of serpentine receptors in protozoan parasites is largely unknown so far. In the present study we performed a genome-wide search for proteins containing seven transmembrane domains (7-TM) in the human malaria parasite Plasmodium falciparum and identified four serpentine receptor-like proteins. These proteins, denoted PfSR1, PfSR10, PfSR12 and PfSR25, show membrane topologies that resemble those exhibited by members belonging to different families of serpentine receptors. Expression of the pfsrs genes was detected by Real Time PCR in P. falciparum intraerythrocytic stages, indicating that they potentially code for functional proteins. We also found corresponding homologues for the PfSRs in five other Plasmodium species, two primate and three rodent parasites. PfSR10 and 25 are the most conserved receptors among the different species, while PfSR1 and 12 are more divergent. Interestingly, we found that PfSR10 and PfSR12 possess similarity to orphan serpentine receptors of other organisms. The identification of potential parasite membrane receptors raises a new perspective for essential aspects of malaria parasite host cell infection.     

Replication of pBR322 DNA in vitro with purified proteins. Requirement for topoisomerase I in the maintenance of template specificity

The replication of plasmid pBR322 DNA has been reconstituted with purified proteins from Escherichia coli. Initiation of the leading-strand requires RNA polymerase holoenzyme, DNA polymerase I, RNase H, and DNA gyrase. Initiation of the lagging-strand requires the primosomal proteins (the dnaB, dnaC, and dnaG proteins, replication factor Y (protein n') and proteins i, n, and n") and the single-stranded DNA binding protein. DNA polymerase III holoenzyme is required for extensive elongation of the nascent DNA chains. The products of this replication reaction are primarily nonsegregated daughter molecules. However, the addition of small amounts of soluble extract from E. coli results in the completion and segregation of these molecules to give mature form I DNA, suggesting that additional factors are required for this process. Topoisomerase I is necessary to make the replication system specific for pBR322 DNA as a template, indicating that the linking number of the DNA, determined by an equilibrium between the opposing activities of topoisomerase I and DNA gyrase, plays a crucial role in determining the reactivity of the DNA molecule toward initiating DNA replication. The function of the proteins involved in the replication of this closed-circular, double-stranded, superhelical DNA is discussed.     

Deletion analysis of the mini-P1 plasmid origin of replication and the role of Escherichia coli DnaA protein

The mini-P1 plasmid origin of replication is contained on a 246 base pair (bp) piece of DNA. At one end there are five 19-bp binding sites for the P1 initiator protein, RepA, and near the other end there are two 9-bp DnaA protein-binding sites. To further define the limits of the origin, we cloned the origin region in M13 and constructed deletions of either end. We sequenced the DNA and tested the replicative form I DNA of the deletion phages for their ability to support RepA-dependent DNA replication in an in vitro system. The origin that is functional in vitro could be reduced to 202 bp. It includes three intact and one incomplete RepA-binding sites at one end and the two DnaA-binding sites at the other end. When the two naturally occurring DnaA-binding sites were replaced with one or two synthetic sites, only the construction containing two sites was active in vitro. We found that the minimal origin that is functional in vivo contains all of the five RepA and the two DnaA-binding sites. Mini-P1 plasmid replication both in vivo and in vitro requires two initiator proteins, the Escherichia coli DnaA protein and the P1 RepA protein. We have found that the ADP form of DnaA is as active as the ATP form of the protein in the in vitro replication of mini-P1. In contrast, only the ATP form is active for in vitro replication of plasmids carrying the E. coli origin (Bramhill, D., and Kornberg, A. (1988) Cell 52, 743-755).     

Unraveling the 'DEAD-box' helicases of Plasmodium falciparum

The causative agent for the most fatal form of malaria, Plasmodium falciparum, has developed insecticide and drug resistance with time. Therefore combating this disease is becoming increasingly difficult and this calls for finding alternate ways to control malaria. One of the feasible ways could be to find out inhibitors/drugs specific for the indispensable enzymes of malaria parasite such as helicases. These helicases, which contain intrinsic nucleic acid-dependent ATPase activity, are capable of enzymatically unwinding energetically stable duplex nucleic acids into single-stranded templates and are required for all the nucleic acid transactions. Most of the helicases contain a set of nine extremely conserved amino acid sequences, which are called 'helicase motifs'. Due to the presence of the DEAD (Asp-Glu-Ala-Asp) in one of the conserved motifs, this family is also known as the 'DEAD-box' family. In this review, using bioinformatic approach, we describe the 'DEAD-box' helicases of malaria parasite P. falciparum. An in depth analysis shows that the parasite contains 22 full-length genes, some of which are homologues of well-characterized helicases of this family from other organisms. Recently we have cloned and characterized the first member of this family, which is a homologue of p68 and is expressed during the schizont stage of the development of the parasite [Pradhan, A., Chauhan, V.S., Tuteja, R., 2005a. A novel 'DEAD-box' DNA helicase from Plasmodium falciparum is homologous to p68. Mol. Biochem. Parasitol. 140, 55-60.; Pradhan A., Chauhan V.S., Tuteja R., 2005b. Plasmodium falciparum DNA helicase 60 is a schizont stage specific, bipolar and dual helicase stimulated by PKC phosphorylation. Mol. Biochem. Parasitol. 144, 133-141.]. It will be really interesting to clone and characterize other members of the 'DEAD-box' family and understand their role in the replication and transmission of the parasite. These detailed studies may help to identify a parasite-specific enzyme, which could be a potential drug target to treat malaria. The various steps at which this probable drug can act are also discussed.     

The reverse gyrase helicase-like domain is a nucleotide-dependent switch that is attenuated by the topoisomerase domain

Reverse gyrase is a topoisomerase that introduces positive supercoils into DNA in an ATP-dependent manner. It is unique to hyperthermophilic archaea and eubacteria, and has been proposed to protect their DNA from damage at high temperatures. Cooperation between its N-terminal helicase-like and the C-terminal topoisomerase domain is required for positive supercoiling, but the precise role of the helicase-like domain is currently unknown. Here, the characterization of the isolated helicase-like domain from Thermotoga maritima reverse gyrase is presented. We show that the helicase-like domain contains all determinants for nucleotide binding and ATP hydrolysis. Its intrinsic ATP hydrolysis is significantly stimulated by ssDNA, dsDNA and plasmid DNA. During the nucleotide cycle, the helicase-like domain switches between high- and low-affinity states for dsDNA, while its affinity for ssDNA in the ATP and ADP states is similar. In the context of reverse gyrase, the differences in DNA affinities of the nucleotide states are smaller, and the DNA-stimulated ATPase activity is strongly reduced. This inhibitory effect of the topoisomerase domain decelerates the progression of reverse gyrase through the nucleotide cycle, possibly providing optimal coordination of ATP hydrolysis with the complex reaction of DNA supercoiling.