Modulation of DNA synthesis in Saccharomyces cerevisiae nuclear extract by DNA polymerases and the origin recognition complex

We have analyzed the modulation of DNA synthesis on a supercoiled plasmid DNA template by DNA polymerases (pol), minichromosome maintenance protein complex (Mcm), topoisomerases, and the origin recognition complex (ORC) using an in vitro assay system. Antisera specific against the four-subunit pol alpha, the catalytic subunit of pol delta, and the Mcm467 complex each inhibited DNA synthesis. However, DNA synthesis in this system appeared to be independent of polepsilon. Consequently, DNA synthesis in the in vitro system appeared to depend only on two polymerases, alpha and delta, as well as the Mcm467 DNA helicase. This system requires supercoiled plasmid DNA template and DNA synthesis absolutely required DNA topoisomerase I. In addition, we also report here a novel finding that purified recombinant six subunit ORC significantly stimulated the DNA synthesis on a supercoiled plasmid DNA template containing an autonomously replicating sequence, ARS1.     

Detection of new Francisella-like tick endosymbionts in Hyalomma spp. and Rhipicephalus spp. (Acari: Ixodidae) from Bulgaria

We report on the identification of two new Francisella-like endosymbionts (FLEs) found in three different tick species from Bulgaria. The FLEs were characterized by 16S rRNA and tul4 gene sequencing and seem to lack the molecular marker RD1. These two new taxa seem to be facultative secondary endosymbionts of ticks.     

DNA bending versus DNA end joining activity of HMGB1 protein is modulated in vitro by acetylation

The ability of HMGB1 protein to recognize bent DNA and to induce bending in linear duplex DNA defines HMGB1 as an architectural factor. It has already been demonstrated that the binding affinity of the protein for various bent DNA structures is enhanced upon in vivo acetylation at Lys2. Here we investigate how this modification of HMGB1 affects its ability to bend DNA. We report that the modified protein cannot bend short DNA fragments but, instead, stimulates joining of the same fragments via their ends. The same properties are exhibited in vivo by acetylated HMGB1 lacking its acidic tail. Further, in vitro acetylation of the truncated protein at Lys81 (possible upon tail removal only) restores the protein's bending ability, while the level of stimulation of DNA end joining is strongly reduced. We conclude, therefore, that the ability of HMGB1 to bend DNA or to stimulate end joining is modulated in vitro by acetylation. In an attempt to explain the properties of in vivo-acetylated HMGB1, its complexes with DNA have been analyzed by both protein-DNA cross-linking and atomic force microscopy. Unlike the parental protein, bound mainly within the internal sequences, acetylated HMGB1 binds preferentially to DNA ends. We propose that the loading of acetylated protein on DNA ends accounts for both the failure to bend DNA and the stimulation of DNA end joining.     

Use of inert gas jets to measure the forces required for mechanical gene transfection

Background

Abnormal blood glucose (BG) concentrations have been associated with increased morbidity and mortality in both critically ill adults and infants. Furthermore, hypoglycaemia and glycaemic variability have both been independently linked to mortality in these patients. Continuous Glucose Monitoring (CGM) devices have the potential to improve detection and diagnosis of these glycaemic abnormalities. However, sensor noise is a trade-off of the high measurement rate and must be managed effectively if CGMs are going to be used to monitor, diagnose and potentially help treat glycaemic abnormalities.

Aim

To develop a tool that will aid clinicians in identifying unusual CGM behaviour and highlight CGM data that potentially need to be interpreted with care.

Methods

CGM data and BG measurements from 50 infants at risk of hypoglycaemia were used. Unusual CGM measurements were classified using a stochastic model based on the kernel density method and historical CGM measurements from the cohort. CGM traces were colour coded with very unusual measurements coloured red, highlighting areas to be interpreted with care. A 5-fold validation of the model was Monte Carlo simulated 25 times to ensure an adequate model fit.

Results

The stochastic model was generated using ~67,000 CGM measurements, spread across the glycaemic range ~2-10?mmol/L. A 5-fold validation showed a good model fit: the model 80% confidence interval (CI) captured 83% of clinical CGM data, the model 90% CI captured 91% of clinical CGM data, and the model 99% CI captured 99% of clinical CGM data. Three patient examples show the stochastic classification method in use with 1) A stable, low variability patient which shows no unusual CGM measurements, 2) A patient with a very sudden, short hypoglycaemic event (classified as unusual), and, 3) A patient with very high, potentially un-physiological, glycaemic variability after day 3 of monitoring (classified as very unusual).

Conclusions

This study has produced a stochastic model and classification method capable of highlighting unusual CGM behaviour. This method has the potential to classify important glycaemic events (e.g. hypoglycaemia) as true clinical events or sensor noise, and to help identify possible sensor degradation. Colour coded CGM traces convey the information quickly and efficiently, while remaining computationally light enough to be used retrospectively or in real-time.     

Cortical potential imaging using L-curve and GCV method to choose the regularisation parameter

Background

The electroencephalography (EEG) is an attractive and a simple technique to measure the brain activity. It is attractive due its excellent temporal resolution and simple due to its non-invasiveness and sensor design. However, the spatial resolution of EEG is reduced due to the low conducting skull. In this paper, we compute the potential distribution over the closed surface covering the brain (cortex) from the EEG scalp potential. We compare two methods – L-curve and generalised cross validation (GCV) used to obtain the regularisation parameter and also investigate the feasibility in applying such techniques to N170 component of the visually evoked potential (VEP) data.

Methods

Using the image data set of the visible human man (VHM), a finite difference method (FDM) model of the head was constructed. The EEG dataset (256-channel) used was the N170 component of the VEP. A forward transfer matrix relating the cortical potential to the scalp potential was obtained. Using Tikhonov regularisation, the potential distribution over the cortex was obtained.

Results

The cortical potential distribution for three subjects was solved using both L-curve and GCV method. A total of 18 cortical potential distributions were obtained (3 subjects with three stimuli each – fearful face, neutral face, control objects).

Conclusions

The GCV method is a more robust method compared to L-curve to find the optimal regularisation parameter. Cortical potential imaging is a reliable method to obtain the potential distribution over cortex for VEP data.

     

Nonglutamate pore residues in ion selection and conduction in voltage-gated Ca(2+) channels

High-affinity, intrapore binding of Ca(2+) over competing ions is the essential feature in the ion selectivity mechanism of voltage-gated Ca(2+) channels. At the same time, several million Ca(2+) ions can travel each second through the pore of a single open Ca(2+) channel. How such high Ca(2+) flux is achieved in the face of tight Ca(2+) binding is a current area of inquiry, particularly from a structural point of view. The ion selectivity locus comprises four glutamate residues within the channel's pore. These glutamates make unequal contributions to Ca(2+) binding, underscoring a role for neighboring residues in pore function. By comparing two Ca(2+) channels (the L-type alpha(1C), and the non-L-type alpha(1A)) that differ in their pore properties but only differ at a single amino acid position near the selectivity locus, we have identified the amino-terminal neighbor of the glutamate residue in motif III as a determinant of pore function. This position is more important in the function of alpha(1C) channels than in alpha(1A) channels. For a systematic series of mutations at this pore position in alpha(1C), both unitary Ba(2+) conductance and Cd(2+) block of Ba(2+) current varied with residue volume. Pore mutations designed to make alpha(1C) more like alpha(1A) and vice versa revealed that relative selectivity for Ba(2+) over K(+) depended almost solely on pore sequence and not channel type. Analysis of thermodynamic mutant cycles indicates that the motif III neighbor normally interacts in a cooperative fashion with the locus, molding the functional behavior of the pore.     

Combined prime-boost vaccination against tick-borne encephalitis (TBE) using a recombinant vaccinia virus and a bacterial plasmid both expressing TBE virus non-structural NS1 protein

Background  

Heterologous prime-boost immunization protocols using different gene expression systems have proven to be successful tools in protecting against various diseases in experimental animal models. The main reason for using this approach is to exploit the ability of expression cassettes to prime or boost the immune system in different ways during vaccination procedures. The purpose of the project was to study the ability of recombinant vaccinia virus (VV) and bacterial plasmid, both carrying the NS1 gene from tick-borne encephalitis (TBE) virus under the control of different promoters, to protect mice against lethal challenge using a heterologous prime-boost vaccination protocol.     

Cell cycle specific plasmid DNA replication in the nuclear extract of Saccharomyces cerevisiae: modulation by replication protein A and proliferating cell nuclear antigen

Plasmid DNA replication in nuclear extracts of Saccharomyces cerevisiae in vitro has been shown to be S-phase specific, similar to that observed in vivo. We report here a reconstituted in vitro system with partially purified replication proteins, purified replication protein A (RPA), and recombinant proliferating cell nuclear antigen (PCNA). Nuclear extracts from S-phase, G(1)-phase, and unsynchronized yeast cells were fractionated by phosphocellulose chromatography. Protein fraction (polymerase fraction) enriched with replication proteins, including DNA polymerases (alpha, delta, etc.), was isolated, which was not capable of in vitro replication of supercoiled plasmid DNA. However, when purified yeast RPA and recombinant PCNA together were added to the polymerase fraction obtained from S-phase synchronized cells, in vitro plasmid DNA replication was restored. In vitro plasmid DNA replication with polymerase fractions from unsynchronized and G(1)-phase cells could not be reconstituted upon addition of purified RPA and PCNA. RPA and PCNA isolated from various phases of the cell cycle complemented the S-phase polymerase pool to the same extent. Reconstituted systems with the S-phase polymerase pool, complemented with either the RPA- and PCNA-containing fraction or purified RPA and recombinant PCNA together, were able to produce replication intermediates (ranging in size from 50 to 1500 bp) similar to that observed with the S-phase nuclear extract. Results presented here demonstrate that both RPA and PCNA are cell cycle-independent in their ability to stimulate in vitro plasmid DNA replication, whereas replication factors in the polymerase fractions are strictly S-phase dependent.