Phenotypic Characterization of Self- Assembling Protein Fragments Using Negative Dominance

Zweifel, Adrienne Elizabeth

2010 May 1900

Protein oligomerization provides a way for cells to modulate function in vivo. In this study, self-assembling protein fragments from ParC, DnaX, and proteins of unknown function were used to generate phenotypes in a dominant negative manner. These fragments were expressed as Thioredoxin (TRX) fusions under the control of the inducible araBAD promoter. Fragments chosen contain only the oligomerization domain of the protein, lacking the regions necessary for catalytic function. Fragments of ParC, a subunit of Topoisomerase (Topo) IV, generated fragment-specific phenotypes. Regions that expressed both the oligomerization domain and CTD of ParC (ParC206-752 and ParC332-752) yielded filamentous cells with several different nucleoid segregation phenotypes. Another ParC fragment containing only the oligomerization domain of ParC (ranging from 333-485) yields a recA-dependent septation defect in a subset of the population. This phenotype suggests that Topo IV may be inhibiting chromosome dimer resolution. The overexpression of DnaX247-455, a fragment containing regions of both the tau and gamma subunits of the DNA Polymerase III holoenzyme, led to a severe plating defect. Upon further investigation, this fragment caused filamentation, a nucleoid defect, and induction of sulA, similar to the effects seen with the dnaX temperature-sensitive alleles. The overexpression of the various y-protein fragments yielded a variety of mediaspecific plating defects on over 50% of the proteins tested. The overexpression of the protein fragments yielded effects that were not seen by other overexpression or deletion experiments, even under similar growth conditions. The results presented here show that the overexpression of self-assembling fragments yield a variety of dominant negative phenotypes. Reducing the activity of protein complexes allows for new aspects of the physiological process to be investigated.

Topoisomerase IV:

ParC

Negative Dominance

DnaX

Resistance to Fluoroquinolones in <i>Escherichia coli</i>: Prevention, Genetics and Fitness Costs

Marcusson, Linda L.

January 2007

<p>Antibiotic-resistant bacteria are increasingly a major healthcare problem but very few new classes of antibiotics have been discovered or launched in recent decades. Approaches to dealing with the problem include learning how bacteria evolve to resistance and improving dosing regimens with current antibiotics so as to reduce the selection of resistant bacteria. </p><p>This thesis presents studies examining whether antibiotic dosing at high levels can prevent the selection of fluoroquinolone-resistant mutants in <i>Escherichia coli</i>. It also addresses the genetics of fluoroquinolone resistance in <i>E. coli</i> in relation to fitness costs for the resistant bacteria, and the evolution of <i>E. coli</i> to reduce the costs of resistance.</p><p>The mutant prevention concentration (MPC) of ciprofloxacin was measured for a set of clinical urinary tract infection <i>E. coli</i> strains showing that MPC could not be predicted from the minimum inhibitory concentration (MIC). Results from an <i>in vitro</i> kinetic model showed that an AUC/MPC >22 for ciprofloxacin was the single best pharmacodynamic index that predicted prevention of resistance emergence in the wild-type. Simulating currently approved dosing regimens for three different fluoroquinolones it was found that only a few were effective in preventing the selection of a small sub-population of pre-existing mutants. </p><p>Step-wise selection of fluoroquinolone resistance showed that the accumulation of mutations usually reduced bacterial fitness<i> in vitro</i> and <i>in vivo</i>. Systematic construction of isogenic resistant strains confirmed this result and revealed that some combinations of resistance mutations mutually compensate and increase both resistance and fitness. It was discovered that mutations altering RNA polymerase could ameliorate the fitness costs of fluoroquinolone resistance. Thus, the major fitness cost of fluoroquinolone resistance is due to defective transcription. </p><p>The finding that fluoroquinolone resistance mutations can increase resistance while mutually compensating their fitness costs, shows that resistance to fluoroquinolones can continue to evolve in the absence of antibiotic selection.</p>

Biology

Fluoroquinolone

Escherichia coli

Resistance

Gyrase

Topoisomerase IV

MPC

Fitness compensation

Urinary Tract Infection

Biologi

Resistance to Fluoroquinolones in Escherichia coli: Prevention, Genetics and Fitness Costs

Marcusson, Linda L.

January 2007

Antibiotic-resistant bacteria are increasingly a major healthcare problem but very few new classes of antibiotics have been discovered or launched in recent decades. Approaches to dealing with the problem include learning how bacteria evolve to resistance and improving dosing regimens with current antibiotics so as to reduce the selection of resistant bacteria. This thesis presents studies examining whether antibiotic dosing at high levels can prevent the selection of fluoroquinolone-resistant mutants in Escherichia coli. It also addresses the genetics of fluoroquinolone resistance in E. coli in relation to fitness costs for the resistant bacteria, and the evolution of E. coli to reduce the costs of resistance. The mutant prevention concentration (MPC) of ciprofloxacin was measured for a set of clinical urinary tract infection E. coli strains showing that MPC could not be predicted from the minimum inhibitory concentration (MIC). Results from an in vitro kinetic model showed that an AUC/MPC &gt;22 for ciprofloxacin was the single best pharmacodynamic index that predicted prevention of resistance emergence in the wild-type. Simulating currently approved dosing regimens for three different fluoroquinolones it was found that only a few were effective in preventing the selection of a small sub-population of pre-existing mutants. Step-wise selection of fluoroquinolone resistance showed that the accumulation of mutations usually reduced bacterial fitness in vitro and in vivo. Systematic construction of isogenic resistant strains confirmed this result and revealed that some combinations of resistance mutations mutually compensate and increase both resistance and fitness. It was discovered that mutations altering RNA polymerase could ameliorate the fitness costs of fluoroquinolone resistance. Thus, the major fitness cost of fluoroquinolone resistance is due to defective transcription. The finding that fluoroquinolone resistance mutations can increase resistance while mutually compensating their fitness costs, shows that resistance to fluoroquinolones can continue to evolve in the absence of antibiotic selection.

Biology

Fluoroquinolone

Escherichia coli

Resistance

Gyrase

Topoisomerase IV

MPC

Fitness compensation

Urinary Tract Infection

Biologi

Mapping Topoisomerase IV Binding and Activity Sites on the E. coli genome / Distribution des sites de liaison et activité de la Topoisomérase IV sur le génome d’Escherichia coli

El Sayyed, Hafez

26 October 2016

Des liens de caténation sont progressivement crées lors de la réplication de l’ADN et sont responsables de la cohésion des chromatides sœurs. La topoisomérase IV est une topoisomérase de type II impliquée dans la résolution de ces liens de caténation accumulés derrière la fourche de réplication, et lors de la dernière étape de séparation des chromatides sœurs à la fin de la réplication. Nous avons étudié la liaison de la topoIV à l’ADN ainsi que son activité catalytique à l’aide de méthodes de biologie moléculaire et de génomique. Une expérience de ChIPseq a révélé que l’interaction de la topoIV de chez E.coli avec l’ADN est contrôlée par la réplication. Durant la réplication, la topoIV a accès à des centaines de sites sur l’ADN mais ne se lie qu’à quelques sites où elle exerce son activité catalytique. La conformation locale de la chromatine et l’expression des gènes influencent la sélection de certains sites. De plus, une forte liaison et une activité catalytique renforcée a été trouvée au site de résolution des dimers, dif. Le site dif est situé à l’opposé de l’origine de réplication dans le macrodomaine ter. Nous avons montré qu’il existe une interaction physique et fonctionnelle entre la topoIV et la recombinase XerCD, qui agit au site dif. Cette interaction est médiée par MatP, une protéine essentielle dans l’organisation du macrodomaine ter. L’ensemble de ces résultats montre que la topoIV, XerCD/dif et MatP œuvrent ensemble pour permettre l’étape finale de ségrégation des chromosomes lors du cycle cellulaire. / Catenation links between sister chromatids are formed progressively during DNA replication and are involved in the establishment of sister chromatid cohesion. Topo IV is a bacterial type II topoisomerase involved in the removal of catenation links both behind replication forks and after replication during the final separation of sister chromosomes. We have investigated the global DNA-binding and catalytic activity of Topo IV in E. coli using genomic and molecular biology approaches. ChIP-seq revealed that Topo IV interaction with the E. coli chromosome is controlled by DNA replication. During replication, Topo IV has access to most of the genome but only selects a few hundred specific sites for its activity. Local chromatin and gene expression context influence site selection. Moreover strong DNA-binding and catalytic activities are found at the chromosome dimer resolution site, dif, located opposite the origin of replication. We reveal a physical and functional interaction between Topo IV and the XerCD recombinases acting at the dif site. This interaction is modulated by MatP, a protein involved in the organization of the Ter macrodomain. These results show that Topo IV, XerCD/dif and MatP are part of a network dedicated to the final step of chromosome management during the cell cycle.

Topoisomérase IV

Cycle cellulaire

Topologie de l’ADN

Réplication de l’ADN

ChIP-Seq

Décaténation

Chromatides-sœurs

Topoisomerase IV

Cell cycle

DNA topology

DNA replication

ChIP-Seq

Decatenation

Sister chromatids