Enhanced purification and characterization of the PfeIF4A (PfH45) helicase from Plasmodium falciparum using a codon-optimised clone.

With the intention of investigating the DNA strand displacement properties of Plasmodium falciparum helicase PfeIF4A (formerly known as PfH45) a codon-optimized gene for expression in Escherichia coli has been produced. Several histidine-containing proteins with intrinsic helicase activity were captured from the bacterial sonicate by initial Ni(2+)-chromatography. Heparin and size-exclusion steps were subsequently required for unambiguous PfeIF4A purification.

A Synthetic Biology Project - Developing a single-molecule device for screening drug-target interactions.

This review describes a European-funded project in the area of Synthetic Biology. The project seeks to demonstrate the application of engineering techniques and methodologies to the design and construction of a biosensor for detecting drug-target interactions at the single-molecule level. Production of the proteins required for the system followed the principle of previously described "bioparts" concepts (a system where a database of biological parts - promoters, genes, terminators, linking tags and cleavage sequences - is used to construct novel gene assemblies) and cassette-type assembly of gene expression systems (the concept of linking different "bioparts" to produce functional "cassettes"), but problems were quickly identified with these approaches.

Mechanistic insight into Type I restriction endonucleases.

Restriction and modification are two opposing activities that are used to protect bacteria from cellular invasion by DNA (e.g. bacteriophage infection).

Production and single-step purification of EGFP and a biotinylated version of the Human Rhinovirus 14 3C protease.

The fluorescent reporter enhanced Green Fluorescent Protein (EGFP) has been used for assaying a wide range of biological activities ranging from gene expression, or localization of target proteins through to intermolecular interactions. However, over-production of this protein in Escherichia coli has resulted in the presence of inclusion bodies, which complicates recovery of the protein in significant quantities. In this paper, we describe a single-step method for isolating the protein from a Glutathione-S-Transferase (GST) fusion protein, release of the EGFP protein from the fusion was demonstrated using a biotinylated variant of Human Rhinovirus 14 3C protease that we have also constructed.

EcoR124I: from plasmid-encoded restriction-modification system to nanodevice.

Plasmid R124 was first described in 1972 as being a new member of incompatibility group IncFIV, yet early physical investigations of plasmid DNA showed that this type of classification was more complex than first imagined. Throughout the history of the study of this plasmid, there have been many unexpected observations. Therefore, in this review, we describe the history of our understanding of this plasmid and the type I restriction-modification (R-M) system that it encodes, which will allow an opportunity to correct errors, or misunderstandings, that have arisen in the literature.

Structural model for the multisubunit Type IC restriction-modification DNA methyltransferase M.EcoR124I in complex with DNA.

Recent publication of crystal structures for the putative DNA-binding subunits (HsdS) of the functionally uncharacterized Type I restriction-modification (R-M) enzymes MjaXIP and MgeORF438 have provided a convenient structural template for analysis of the more extensively characterized members of this interesting family of multisubunit molecular motors. Here, we present a structural model of the Type IC M.EcoR124I DNA methyltransferase (MTase), comprising the HsdS subunit, two HsdM subunits, the cofactor AdoMet and the substrate DNA molecule.

Dynamics of initiation, termination and reinitiation of DNA translocation by the motor protein EcoR124I.

Type I restriction enzymes use two motors to translocate DNA before carrying out DNA cleavage. The motor function is accomplished by amino-acid motifs typical for superfamily 2 helicases, although DNA unwinding is not observed. Using a combination of extensive single-molecule magnetic tweezers and stopped-flow bulk measurements, we fully characterized the (re)initiation of DNA translocation by EcoR124I.

Initiation of translocation by Type I restriction-modification enzymes is associated with a short DNA extrusion.

Recognition of 'foreign' DNA by Type I restriction-modification (R-M) enzymes elicits an ATP-dependent switch from methylase to endonuclease activity, which involves DNA translocation by the restriction subunit HsdR. Type I R-M enzymes are composed of three (Hsd) subunits with a stoichiometry of HsdR2:HsdM2:HsdS1 (R2-complex). However, the EcoR124I R-M enzyme can also exist as a cleavage deficient, sub-assembly of HsdR1:HsdM2:HsdS1 (R1-complex).

Control of a multisubunit DNA motor by a thermoresponsive polymer switch.

The conjugation of thermoresponsive polymers to multisubunit, multifunctional hybrid type 1 DNA restriction-modification (R-M) enzymes enables temperature-controlled "switching" of DNA methylation by the conjugate. Polymers attached to the enzyme at a subunit distal to the methylation subunit allow retention of DNA recognition and ATPase activity while controlling methylation of plasmid DNA. This regulation of enzyme activity arises from the coil-globule phase transitions of the polymer as shown in light scattering and gel retardation assays.

Protein-polymer nano-machines. Towards synthetic control of biological processes.

The exploitation of nature's machinery at length scales below the dimensions of a cell is an exciting challenge for biologists, chemists and physicists, while advances in our understanding of these biological motifs are now providing an opportunity to develop real single molecule devices for technological applications. Single molecule studies are already well advanced and biological molecular motors are being used to guide the design of nano-scale machines. However, controlling the specific functions of these devices in biological systems under changing conditions is difficult.

Real-time observation of DNA translocation by the type I restriction modification enzyme EcoR124I.

Type I restriction enzymes bind sequence-specifically to unmodified DNA and subsequently pull the adjacent DNA toward themselves. Cleavage then occurs remotely from the recognition site. The mechanism by which these members of the superfamily 2 (SF2) of helicases translocate DNA is largely unknown.

Cellular localization of Type I restriction-modification enzymes is family dependent.

Cellular localization of Type I restriction-modification enzymes EcoKI, EcoAI, and EcoR124I-the most frequently studied representatives of IA, IB, and IC families-was analyzed by immunoblotting of subcellular fractions isolated from Escherichia coli strains harboring the corresponding hsd genes. EcoR124I shows characteristics similar to those of EcoKI. The complex enzymes are associated with the cytoplasmic membrane via DNA interaction as documented by the release of the Hsd subunits from the membrane into the soluble fraction following benzonase treatment.

Characterization of an EcoR124I restriction-modification enzyme produced from a deleted form of the DNA-binding subunit, which results in a novel DNA specificity.

We purified and characterized both the methyltransferase and the endonuclease containing the HsdS delta 50 subunit (type I restriction endonucleases are composed of three subunits--HsdR required for restriction, HsdM required for methylation and HsdS responsible for DNA recognition) produced from the deletion mutation hsdS delta 50 of the type IC R-M system EcoR 124I; this mutant subunit lacks the C-terminal 163 residues of HsdS and produces a novel DNA specificity. Analysis of the purified HsDs delta 50 subunit indicated that during purification it is subject to partial proteolysis resulting in removal of approximately 1 kDa of the polypeptide at the C-terminus. This proteolysis prevented the purification of further deletion mutants, which were determined as having a novel DNA specificity in vivo.

A nomenclature for restriction enzymes, DNA methyltransferases, homing endonucleases and their genes.

A nomenclature is described for restriction endonucleases, DNA methyltransferases, homing endonucleases and related genes and gene products. It provides explicit categories for the many different Type II enzymes now identified and provides a system for naming the putative genes found by sequence analysis of microbial genomes.

A novel mutant of the type I restriction-modification enzyme EcoR124I is altered at a key stage of the subunit assembly pathway.

The HsdS subunit of a type I restriction-modification (R-M) system plays an essential role in the activity of both the modification methylase and the restriction endonuclease. This subunit is responsible for DNA binding, but also contains conserved amino acid sequences responsible for protein-protein interactions. The most important protein-protein interactions are those between the HsdS subunit and the HsdM (methylation) subunit that result in assembly of an independent methylase (MTase) of stoichiometry M(2)S(1).

Measuring motion on DNA by the type I restriction endonuclease EcoR124I using triplex displacement.

The type I restriction enzyme EcoR124I cleaves DNA following extensive linear translocation dependent upon ATP hydrolysis. Using protein-directed displacement of a DNA triplex, we have determined the kinetics of one-dimensional motion without the necessity of measuring DNA or ATP hydrolysis. The triplex was pre-formed specifically on linear DNA, 4370 bp from an EcoR124I site, and then incubated with endonuclease.

Localization of the type I restriction-modification enzyme EcoKI in the bacterial cell.

To localise the type I restriction-modification (R-M) enzyme EcoKI within the bacterial cell, the Hsd subunits present in subcellular fractions were analysed using immunoblotting techniques. The endonuclease (ENase) as well as the methylase (MTase) were found to be associated with the cytoplasmic membrane. HsdR and HsdM subunits produced individually were soluble, cytoplasmic polypeptides and only became membrane-associated when coproduced with the insoluble HsdS subunit.

Two temperature-sensitive mutations in the DNA binding subunit of EcoKI with differing properties.

Two temperature-sensitive mutations in the hsdS gene, which encodes the DNA specificity subunit of the type IA restriction-modification system EcoKI, designated Sts1 (Ser(340)Phe) and Sts2 (Ala(204)Thr) had a different impact on restriction-modification functions in vitro and in vivo. The enzyme activities of the Sts1 mutant were temperature-sensitive in vitro and were reduced even at 30 degrees C (permissive temperature). Gel retardation assays revealed that the Sts1 mutant had significantly decreased DNA binding, which was temperature-sensitive.

A highly conserved plasmid from the extreme thermophile Thermotoga maritima MC24 is a member of a family of plasmids distributed worldwide.

We have screened Thermotoga strains, isolated from hydrothermal vents near the Kuril Islands, for the presence of plasmid DNA. The miniplasmid pMC24 was isolated from the extreme thermophilic eubacteria Thermotoga maritima and sequenced, showing it to be a plasmid of 846 bp. It was found, from a search of the databases, to be closely related to the previously described Thermotoga miniplasmid pRQ7, isolated from a strain found on the Azore Islands, and was distinguished by only two point mutations.

Analysis of the subunit assembly of the typeIC restriction-modification enzyme EcoR124I.

Type I restriction-modification (R-M) enzymes are composed of three different subunits, of which HsdS determines DNA specificity, HsdM is responsible for DNA methylation and HsdR is required for restriction. The HsdM and HsdS subunits can also form an independent DNA methyltransferase with a subunit stoichiometry of M2S1. We found that the purified Eco R124I R-M enzyme was a mixture of two species as detected by the presence of two differently migrating specific DNA-protein complexes in a gel retardation assay.

Isolation of a non-classical mutant of the DNA recognition subunit of the type I restriction endonuclease R.EcoR124I.

We have used deletion mutagenesis and PCR-based misincorporation mutagenesis to produce a collection of mutations in the central conserved region of the DNA binding subunit of the type IC restriction endonuclease EcoR124I. It has been proposed that this domain is involved in protein-protein interactions during the assembly of the endonuclease. While a large percentage of these mutations gave a classical Res- Mod- phenotype, one mutant was isolated with a nonclassical Res- Mod+ phenotype.

Protein-protein and protein-DNA interactions in the type I restriction endonuclease R.EcoR124I.

The type I restriction-modification system EcoR124I recognizes and binds to the split DNA recognition sequence 5'-GAAN(6)RTCG-3'. The methyltransferase, consisting of HsdM and HsdS subunits with the composition M2S, can interact with one or more subunits of the HsdR subunit to form the endonuclease. The interaction of the methyltransferase with HsdR has been investigated by surface plasmon resonance, showing that there are two non-equivalent binding sites for HsdR which differ in binding affinity by at least two orders of magnitude.

Selection of non-specific DNA cleavage sites by the type IC restriction endonuclease EcoR124I.

The Type IC restriction endonuclease EcoR124I binds specifically to its recognition sequence but subsequently translocates non-specific DNA past the complex in an ATP-dependent mechanism. The enzyme thus has the potential to cleave DNA at loci distant from the recognition site. We have scrutinised the link between translocation and cleavage on linear and circular DNA substrates.

The HsdR subunit of R.EcoR124II: cloning and over-expression of the gene and unexpected properties of the subunit.

Type I restriction endonucleases are composed of three subunits, HsdR, HsdM and HsdS. The HsdR subunit is absolutely required for restriction activity; while an independent methylase is composed of HsdM and HsdS subunits. DNA cleavage is associated with a powerful ATPase activity during which DNA is translocated by the enzyme prior to cleavage.

Repercussions of DNA tracking by the type IC restriction endonuclease EcoR124I on linear, circular and catenated substrates.

Type I restriction endonucleases such as EcoR124I cleave DNA at undefined loci, distant from their recognition sequences, by a mechanism that involves the enzyme tracking along the DNA between recognition and cleavage sites. This mechanism was examined on plasmids that carried recognition sites for EcoR124I and recombination sites for resolvase, the latter to create DNA catenanes. Supercoiled substrates with either one or two restriction sites were linearized by EcoR124I at similar rates, although the two-site molecule underwent further cleavage more readily than the one-site DNA.