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228 Publications visible to you, out of a total of 228
Factor-independent transcription pausing caused by recognition of the RNA-DNA hybrid sequence

Abstract (Expand)

Pausing of transcription is an important step of regulation of gene expression in bacteria and eukaryotes. Here we uncover a factor-independent mechanism of transcription pausing, which is determined by the ability of the elongating RNA polymerase to recognize the sequence of the RNA-DNA hybrid. We show that, independently of thermodynamic stability of the elongation complex, RNA polymerase directly 'senses' the shape and/or identity of base pairs of the RNA-DNA hybrid. Recognition of the RNA-DNA hybrid sequence delays translocation by RNA polymerase, and thus slows down the nucleotide addition cycle through 'in pathway' mechanism. We show that this phenomenon is conserved among bacterial and eukaryotic RNA polymerases, and is involved in regulatory pauses, such as a pause regulating the production of virulence factors in some bacteria and a pause regulating transcription/replication of HIV-1. The results indicate that recognition of RNA-DNA hybrid sequence by multi-subunit RNA polymerases is involved in transcription regulation and may determine the overall rate of transcription elongation.

Authors: Aleksandra Bochkareva, , Vasisht R Tadigotla,

Date Published: 29th Nov 2011

Publication Type: Not specified

Fast sampling for quantitative microbial metabolomics: new aspects on cold methanol quenching: metabolite co-precipitation

Abstract (Expand)

The intra- and extracellular concentrations of 16 metabolites were measured in chemostat (D = 0.1 h−1) anaerobic cultures of the yeast Saccharomyces cerevisiae CEN.PK-113-7D growing on minimal medium. Two independent sampling workflows were employed: (i) conventional cold methanol quenching and (ii) a differential approach. Metabolites were quantified in different sample fractions (total, extracellular, quenching supernatant, methanol/water extract and pellet) in order to derive their mass balance. The differential method in combination with absolute metabolite quantification by gas-chromatography with isotope dilution mass spectrometry (GC–IDMS) was used as a benchmark to assess quality of the cold methanol quenching procedure. Quantitative comparison of metabolite concentrations in all fractions collected by different quenching techniques indicates asystematic loss of the total mass of various metabolites in course of the cold methanol quenching. Pellet resulting from the cold methanol quenching besides biomass contains considerable amounts of precipitated inorganic salts from the fermentation media. Quantitative analysis has revealed significant co-precipitation of polar extracellular metabolites together with these salts. This phenomenon is especially significant for metabolites with large extracellular mass-fraction. We report that the co-precipitation is a hitherto neglected phenomenon and concluded that its degree strongly linked to culturing conditions (i.e. media composition) and chemical properties of the particular metabolite. Thus, intracellular metabolite levels measured from samples collected by cold methanol quenching might be uncertain and variably biased due to corruption by described phenomena.

Authors: Maksim Zakhartsev, Oliver Vielhauer, Thomas Horn, Xuelian Yang, Matthias Reuss

Date Published: 1st Apr 2015

Publication Type: Not specified

From steady-state to synchronized yeast glycolytic oscillations I: model construction

Abstract (Expand)

An existing detailed kinetic model for the steady-state behavior of yeast glycolysis was tested for its ability to simulate dynamic behavior. Using a small subset of experimental data, the original model was adapted by adjusting its parameter values in three optimization steps. Only small adaptations to the original model were required for realistic simulation of experimental data for limit-cycle oscillations. The greatest changes were required for parameter values for the phosphofructokinase reaction. The importance of ATP for the oscillatory mechanism and NAD(H) for inter-and intra-cellular communications and synchronization was evident in the optimization steps and simulation experiments. In an accompanying paper [du Preez F et al. (2012) FEBS J doi:10.1111/j.1742-4658.2012.08658.x], we validate the model for a wide variety of experiments on oscillatory yeast cells. The results are important for re-use of detailed kinetic models in modular modeling approaches and for approaches such as that used in the Silicon Cell initiative. Database The mathematical models described here have been submitted to the JWS Online Cellular Systems Modelling Database and can be accessed at http://jjj.biochem.sun.ac.za/database/dupreez/index.html.

Authors: , David D van Niekerk, Bob Kooi, Johann M Rohwer,

Date Published: 21st Jun 2012

Publication Type: Not specified

From steady-state to synchronized yeast glycolytic oscillations II: model validation

Abstract (Expand)

In an accompanying paper [du Preez et al., (2012) FEBS J doi: 10.1111/j.1742-4658.2012.08665.x], we adapt an existing kinetic model for steady-state yeast glycolysis to simulate limit-cycle oscillations. Here we validate the model by testing its capacity to simulate a wide range of experiments on dynamics of yeast glycolysis. In addition to its description of the oscillations of glycolytic intermediates in intact cells and the rapid synchronization observed when mixing out-of-phase oscillatory cell populations (see accompanying paper), the model was able to predict the Hopf bifurcation diagram with glucose as the bifurcation parameter (and one of the bifurcation points with cyanide as the bifurcation parameter), the glucose- and acetaldehyde-driven forced oscillations, glucose and acetaldehyde quenching, and cell-free extract oscillations (including complex oscillations and mixed-mode oscillations). Thus, the model was compliant, at least qualitatively, with the majority of available experimental data for glycolytic oscillations in yeast. To our knowledge, this is the first time that a model for yeast glycolysis has been tested against such a wide variety of independent data sets. Database The mathematical models described here have been submitted to the JWS Online Cellular Systems Modelling Database and can be accessed at http://jjj.biochem.sun.ac.za/database/dupreez/index.html.

Authors: , David D van Niekerk,

Date Published: 13th Jun 2012

Publication Type: Not specified

Functional analysis of new transporters involved in stress tolerance inPseudomonas putidaDOT-T1E

Abstract (Expand)

Pseudomonas putida DOT-T1E is a highly solvent-tolerant strain. Although the main mechanism that confers solvent tolerance to the strain is the TtgGHI efflux pump, a number of other proteins are also involved in the response to toluene. Previous proteomic and transcriptomic analysis carried out in our lab with P. putida DOT-T1E, and the solvent-sensitive strain, P. putida KT2440, revealed several transporters that were induced in the presence of toluene. We prepared five mutants of the corresponding genes in P. putida DOT-T1E and analysed their phenotypes with respect to solvent tolerance, stress endurance and growth with different carbon, nitrogen and sulfur sources. The data clearly demonstrated that two transporters (Ttg2ABC and TtgK) are involved in multidrug resistance and toluene tolerance, whereas another (homologous to PP0219 of P. putida KT2440) is a sulfate/sulfite transporter. No clear function could be assigned to the other two transporters. Of the transporters shown to be involved in toluene tolerance, one (ttg2ABC) belongs to the ATP-Binding Cassette (ABC) family, and is involved in multidrug resistance in P. putida DOT-T1E, while the other belongs to the Major Facilitator Superfamily and exhibits homology to a putative transporter of the Bcr/CflA family that has not previously been reported to be involved in toluene tolerance.

Authors: Vanina García, Patricia Godoy, Craig Daniels, Ana Hurtado, , Ana Segura

Date Published: 1st Nov 2009

Publication Type: Not specified

Functional analysis of the sortase YhcS in Bacillus subtilis

Abstract (Expand)

Sortases of Gram-positive bacteria catalyze the covalent C-terminal anchoring of proteins to the cell wall. Bacillus subtilis, a well-known host organism for protein production, contains two putative sortases named YhcS and YwpE. The present studies were aimed at investigating the possible sortase function of these proteins in B. subtilis. Proteomics analyses revealed that sortase-mutant cells released elevated levels of the putative sortase substrate YfkN into the culture medium upon phosphate starvation. The results indicate that YfkN required sortase activity of YhcS for retention in the cell wall. To analyze sortase function in more detail, we focused attention on the potential sortase substrate YhcR, which is co-expressed with the sortase YhcS. Our results showed that the sortase recognition and cell-wall-anchoring motif of YhcR is functional when fused to the Bacillus pumilus chitinase ChiS, a readily detectable reporter protein that is normally secreted. The ChiS fusion protein is displayed at the cell wall surface when YhcS is co-expressed. In the absence of YhcS, or when no cell-wall-anchoring motif is fused to ChiS, the ChiS accumulates predominately in the culture medium. Taken together, these novel findings show that B. subtilis has a functional sortase for anchoring proteins to the cell wall.

Authors: Hamidreza Fasehee, Helga Westers, Albert Bolhuis, Haike Antelmann, , Wim J Quax, Agha F Mirlohi, , Gholamreza Ahmadian

Date Published: 31st Aug 2011

Publication Type: Not specified

Functional dissection of a trigger enzyme: mutations of the bacillus subtilis glutamate dehydrogenase RocG that affect differentially its catalytic activity and regulatory properties

Abstract (Expand)

Any signal transduction requires communication between a sensory component and an effector. Some enzymes engage in signal perception and transduction, as well as in catalysis, and these proteins are known as "trigger" enzymes. In this report, we detail the trigger properties of RocG, the glutamate dehydrogenase of Bacillus subtilis. RocG not only deaminates the key metabolite glutamate to form alpha-ketoglutarate but also interacts directly with GltC, a LysR-type transcription factor that regulates glutamate biosynthesis from alpha-ketoglutarate, thus linking the two metabolic pathways. We have isolated mutants of RocG that separate the two functions. Several mutations resulted in permanent inactivation of GltC as long as a source of glutamate was present. These RocG proteins have lost their ability to catabolize glutamate due to a strongly reduced affinity for glutamate. The second class of mutants is exemplified by the replacement of aspartate residue 122 by asparagine. This mutant protein has retained enzymatic activity but has lost the ability to control the activity of GltC. Crystal structures of glutamate dehydrogenases that permit a molecular explanation of the properties of the various mutants are presented. Specifically, we may propose that D122N replacement affects the surface of RocG. Our data provide evidence for a correlation between the enzymatic activity of RocG and its ability to inactivate GltC, and thus give insights into the mechanism that couples the enzymatic activity of a trigger enzyme to its regulatory function.

Authors: Katrin Gunka, , Fabian M Commichau, Christina Herzberg, Cecilia Rodrigues, Lorraine Hewitt, , Jörg Stülke

Date Published: 22nd Feb 2010

Publication Type: Not specified

Functional genomics of the initial phase of cold adaptation of Pseudomonas putida KT2440

Abstract (Expand)

The cold stress response of Pseudomonas putida KT2440 was investigated by genomewide deep cDNA sequencing and gel-free MS-based protein profiling. Transcriptome and proteome profiles were assessed at 30 degrees C and 2 h after a downshift from 30 to 10 degrees C. Pseudomonas putida adapted to lower ambient temperature by the activation of ribosome-associated functional modules that facilitate translational efficiency. The outer membrane profile was reorganized, anabolic pathways and core as well as energy metabolism were repressed and the alginate regulon and sugar catabolism were activated. At the investigated early time point of cold adaptation, the transcriptome was reprogrammed in almost all functional categories, but the protein profile had still not adapted to the change of living conditions in the cold.

Authors: , F. Schmidt, , C. F. Davenport, M. Gesell Salazar, U. Volker,

Date Published: 1st Mar 2011

Publication Type: Not specified

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