DNA Mutation Frequency in Vitamin C Deficient Mice Using Big Blue Mice

Shaban, Thuraya

January 2007

<p> Gulonolactone oxidase enzyme is important in the final stage of ascorbic acid biosynthesis. Gulonolactone oxidase is encoded by the Gulo gene. Most animals, such as mice, have the Gulo gene, through which they produce ascorbic acid from glucose, while humans, guinea pigs and primate animals carry a non functional Gulo gene. Ascorbic acid plays an important role in many biological processes. However, it is primarily essential as an antioxidant. Ascorbic acid protects genomic DNA from free radicals resulting from oxidative stress that might otherwise cause a variety of diseases such as cancer or heart disease. This thesis focuses on investigating the role of ascorbic acid in the elimination of oxidative stress-induced mutagenesis.</p> <p> To investigate how vitamin C decreases level of the DNA mutation frequency and protects DNA from free radicals, knockout Gulo and Big Blue mice were used as models to determine the ability of vitamin C to minimize oxidative stress. The Big Blue mice carry the cll gene which is a reporter gene through which DNA mutation rate can be detected in any part of body. Therefore, we generated double transgenic mice which are Gulo deficient or a Big Blue background. Homozygote Gulo cll positive (Gulo-/- cll+) were obtained by crossing heterozygote Gulo cll Positive and homozygote Gulo mice. Five Gulo-/-cll mice were placed under vitamin C deficient diet and another five were supplemented with vitamin C. DNA mutation frequency was analyzed in the two groups. There were no significant differences in mutation frequencies between homozygote Gulo-/- cll mice on vitamin C deficient diet and homozygote Gulo-/- cll+ mice fed vitamin C rich diet. One treatment mouse showed increased frequency in mutations but a second did not. Further tests can be done on other treated knockout mice to identify the mutation types generated by oxidative stress in the absence of vitamin C.</p> / Thesis / Master of Science (MSc)

Encephalitozoon Intestinalis Infection Increases Host Cell Mutation Frequency

Leonard, Cory Ann, Schell, Maria, Schoborg, Robert Vincent, Hayman, James Russell

06 November 2013

Background: Microsporidia are obligate intracellular opportunistic fungi that cause significant pathology in immunocompromised hosts. However, 11 percent of immunocompetent individuals in the general population are microsporidia-seropositive, indicating that severe immune suppression may not be a prerequisite for infection. Encephalitozoon intestinalis is transmitted in contaminated water and initially infects gastro-intestinal enterocytes, leading to diarrheal disease. This organism can also disseminate to many other organs. A recent report suggests that microsporidia can establish persistent infections, which anti-fungal treatment does not eradicate. Like other intracellular pathogens, microsporidia infection stresses the host cell and infected individuals have elevated hydrogen peroxide and free radical levels. Findings. As oxidative stress can lead to DNA damage, we hypothesized that E. intestinalis-infection would increase host cell nuclear mutation rate. Embryo fibroblasts from Big Blue§ssup§TM§esup§ transgenic mice were E. intestinalis-infected and host nuclear mutation frequency was determined by selection of temperature-sensitive c-II gene mutant λ phage. The host mutation frequency in E. intestinalis-infected cultures was 2.5-fold higher than that observed in either mock-infected cells or cells infected with UV-inactivated E. intestinalis spores. Conclusions: These data provide the first evidence that microsporidia infection can directly increase host cellular mutation frequency. Additionally, some event in the microsporidia developmental cycle between host cell attachment and parasitophorous vacuole formation is required for the observed effect. As there is considerable evidence linking infection with other intracellular pathogens and cancer, future studies to dissect the mechanism by which E. intestinalis infection increases host mutation frequency are warranted.

Big Blue™ mouse

Encephalitozoon intestinalis

microsporidia infection

microsporidiosis

mutation frequency

opportunistic infections and cancer

Biomedical Sciences

Encephalitozoon Intestinalis Infection Increases Host Cell Mutation Frequency

Leonard, Cory Ann, Schell, Maria, Schoborg, Robert Vincent, Hayman, James Russell

06 November 2013

Background: Microsporidia are obligate intracellular opportunistic fungi that cause significant pathology in immunocompromised hosts. However, 11 percent of immunocompetent individuals in the general population are microsporidia-seropositive, indicating that severe immune suppression may not be a prerequisite for infection. Encephalitozoon intestinalis is transmitted in contaminated water and initially infects gastro-intestinal enterocytes, leading to diarrheal disease. This organism can also disseminate to many other organs. A recent report suggests that microsporidia can establish persistent infections, which anti-fungal treatment does not eradicate. Like other intracellular pathogens, microsporidia infection stresses the host cell and infected individuals have elevated hydrogen peroxide and free radical levels. Findings. As oxidative stress can lead to DNA damage, we hypothesized that E. intestinalis-infection would increase host cell nuclear mutation rate. Embryo fibroblasts from Big Blue§ssup§TM§esup§ transgenic mice were E. intestinalis-infected and host nuclear mutation frequency was determined by selection of temperature-sensitive c-II gene mutant λ phage. The host mutation frequency in E. intestinalis-infected cultures was 2.5-fold higher than that observed in either mock-infected cells or cells infected with UV-inactivated E. intestinalis spores. Conclusions: These data provide the first evidence that microsporidia infection can directly increase host cellular mutation frequency. Additionally, some event in the microsporidia developmental cycle between host cell attachment and parasitophorous vacuole formation is required for the observed effect. As there is considerable evidence linking infection with other intracellular pathogens and cancer, future studies to dissect the mechanism by which E. intestinalis infection increases host mutation frequency are warranted.

Big Blue™ mouse

Encephalitozoon intestinalis

microsporidia infection

microsporidiosis

mutation frequency

opportunistic infections and cancer

Biomedical Sciences

Caracterização do fenótipo mutador de isolados de Proteus mirabilis. / Characterization of the mutator phenotype in isolates of P. mirabilis.

Fonseca, Marina Rocha Borges da

03 February 2017

Cepas com altas taxas de mutação (mutadoras) foram detectadas em diversos gêneros bacterianos. A alta taxa de mutação está relacionada a defeitos em sistemas de reparo de DNA. Uma alta incidência de isolados clínicos de Proteus mirabilis com altas frequências de mutação foi descrita anteriormente. O fenômeno foi induzido em Escherichia coli, quando transformada com um plasmídeo de P. mirabilis. Com coleção de 77 isolados clínicos de P. mirabilis, medimos a frequência de mutantes espontâneos e verificamos a presença do elemento conjugativo ICE SXT/R391, para desvendar possível relação entre a presença do ICE e a frequência de mutação. 9 isolados clínicos apresentam o ICE. A frequência de mutantes mostrou que não existem mutadores verdadeiros, mas 11 isolados apresentam uma alta frequência de mutantes FosR. Considerando o alto índice de infecções por P. mirabilis, é importante entender a resistência à fosfomicina, já que esta é usada na clínica. Não existe relação entre uma frequência de mutantes espontânea e a presença de ICE SXT/R391 em isolados de P. mirabilis. / Strains with high mutation rates (mutators) were detected in several bacterial genera. The increased mutation rate is related to defects in DNA repair systems. A high incidence of Proteus mirabilis clinical isolates with high mutation frequencies were described previously. The phenomenon was induced in Escherichia coli, when transformed with a plasmid of P. mirabilis. 77 P. mirabilis clinical isolates were tested for the frequency of spontaneous mutants and the presence of a conjugative element found in this species, ICEs SXT/R391, to verify if there is a relation between the element and the mutation frequencies. 9 isolates carry the ICE SXT/R391. The frequency of mutants showed no true mutators among the isolates. 11 isolates show a high frequency of FosR mutants. Considering the high rate of infections by P. mirabilis, it is important to understand the fosfomycin phenomenon, since it is currently used to treat urinary infections. We have seen no relation between a high spontaneous mutation frequency and the presence of ICE SXT/R391 in isolates of P. mirabilis.

Proteus mirabilis

Proteus mirabilis

Fosfomicina

Fosfomycin

Frequência de mutação

Heteroresistence

Heteroresistência

ICE SXT/R391

ICE SXT/R391

Infecções do trato urinário

Mutadores

Mutation frequency

Mutators

Unrinary tract infections

Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance

Gustafsson, Ingegerd

January 2003

<p>Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. </p><p>The relative biological fitness cost of resistance in <i>Staphylococcus epidermidis</i> was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. </p><p>An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. </p><p>Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h.</p>

Microbiology

Human microflora

antibiotic resistance

selection

mutation frequency

biological fitness

pharmacokinetics

pharmacodynamics

β-lactam antibiotics

suboptimal dosing regimen

Mikrobiologi

Microbiology

Mikrobiologi

Development and Stability of Antibiotic Resistance

Sjölund, Maria

January 2004

<p>Antibiotic resistance is of current concern. Bacteria have become increasingly resistant to commonly used antibiotics and we are facing a growing resistance problem. The present thesis was aimed at studying the impact of antibiotic treatment on pathogenic bacteria as well as on the normal human microbiota, with focus on resistance development.</p><p>Among the factors that affect the appearance of acquired antibiotic resistance, the mutation frequency and biological cost of resistance are of special importance. Our work shows that the mutation frequency in clinical isolates of <i>Helicobacter pylori</i> was generally higher than for other studied bacteria such as <i>Enterobacteriaceae; </i>¼ of the isolates displayed a mutation frequency higher than<i> Enterobacteriaceae </i>defective<i> </i>mismatch repair mutants and could be regarded as mutator strains.</p><p>In <i>H. pylori</i>, clarithromycin resistance confers a biological cost, as measured by decreased competitive ability of the resistant mutants in mice. In clinical isolates, this cost could be reduced, consistent with compensatory evolution stabilizing the presence of the resistant phenotype in the population. Thus, compensation is a clinically relevant phenomenon that can occur in vivo.</p><p>Furthermore, our results show that clinical use of antibiotics selects for stable resistance in the human microbiota. This is important for several reasons. First, many commensals occasionally can cause severe disease, even though they are part of the normal microbiota. Therefore, stably resistant populations increase the risk of unsuccessful treatment of such infections. Second, resistance in the normal microbiota might contribute to increased resistance development among pathogens by interspecies transfer of resistant determinants.</p>

Microbiology

antibiotic resistance

selection

mutation frequency

biological cost of resistance

compensatory evolution

Helicobacter pylori

normal microbiota

Mikrobiologi

Development and Stability of Antibiotic Resistance

Sjölund, Maria

January 2004

Antibiotic resistance is of current concern. Bacteria have become increasingly resistant to commonly used antibiotics and we are facing a growing resistance problem. The present thesis was aimed at studying the impact of antibiotic treatment on pathogenic bacteria as well as on the normal human microbiota, with focus on resistance development. Among the factors that affect the appearance of acquired antibiotic resistance, the mutation frequency and biological cost of resistance are of special importance. Our work shows that the mutation frequency in clinical isolates of Helicobacter pylori was generally higher than for other studied bacteria such as Enterobacteriaceae; ¼ of the isolates displayed a mutation frequency higher than Enterobacteriaceae defective mismatch repair mutants and could be regarded as mutator strains. In H. pylori, clarithromycin resistance confers a biological cost, as measured by decreased competitive ability of the resistant mutants in mice. In clinical isolates, this cost could be reduced, consistent with compensatory evolution stabilizing the presence of the resistant phenotype in the population. Thus, compensation is a clinically relevant phenomenon that can occur in vivo. Furthermore, our results show that clinical use of antibiotics selects for stable resistance in the human microbiota. This is important for several reasons. First, many commensals occasionally can cause severe disease, even though they are part of the normal microbiota. Therefore, stably resistant populations increase the risk of unsuccessful treatment of such infections. Second, resistance in the normal microbiota might contribute to increased resistance development among pathogens by interspecies transfer of resistant determinants.

Microbiology

antibiotic resistance

selection

mutation frequency

biological cost of resistance

compensatory evolution

Helicobacter pylori

normal microbiota

Mikrobiologi

The mutant-prevention concentration concept and its application to <i>Staphylococcus aureus</i>

Metzler, Kelli Leigh

17 June 2004

<i>Staphylococcus aureus</i> is a ubiquitous organism causing world-wide morbidity and mortality. This species readily develops resistance to antimicrobial agents. Current dosing strategies are based, in part, on minimum inhibitory concentrations (MICs). This susceptibility test fails to detect the presence of first-step resistant mutants often present in large heterogeneous populations of infecting bacteria. Dosing strategies based on MIC results may, in fact, allow for the selective proliferation of resistant subpopulations. The mutant-prevention concentration (MPC) is the drug concentration at which all first-step resistant mutants will be eradicated along with the susceptible cells. Determination of the mutant-selection window (MSW) is possible using MIC and MPC data. When considered together with achievable drug concentrations in human bodily sites, the MSW helps determine which antimicrobials are likely to select for resistance. MIC and MPC testing on clinical isolates of methicillin-susceptible (MSSA) and -resistant (MRSA) S. aureus was performed. Characterization via the polymerase chain reaction, sequencing, and electron microscopy (EM) was done on selected organisms recovered from MPC studies (MPC-recovered). MIC and MPC testing was performed on organisms isolated sequentially from patients with recurring S. aureus infections. Pulsed field gel electrophoresis was performed on these sequential isolates. Based on the MIC and the MPC values, the most potent agents for systemic MSSA and MRSA infections are gemifloxacin and vancomycin, respectively. Re-testing MPC-recovered populations by the MIC showed increased MIC results compared to the parent populations. Macrolide-resistance genes were discovered in S. aureus MPC-recovered populations; in contrast, parental isolates lacked these resistance determinants. EM revealed an increase in cell wall thickness of a vancomycin MPC-recovered population compared to its parental population. Moxifloxacin and vancomycin had the lowest and narrowest MSWs for systemic MSSA and MRSA infections, respectively, compared to the other agents tested. Sequential isolates showed no change in MIC and MPC values. The data presented provides evidence for the application of the MPC test to S. aureus organisms. The MPC data is significant when determining appropriate dosing strategies aimed at preventing resistance.

spontaneous mutation frequency

large bacterial populations

MRSA

MIC

minimum inhibitory concentration

MSW

mutant-selection window

pharmacokinetic curves

VRSA

heterogeneous

fluoroquinolones

MPC

antimicrobial agents

Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance

Gustafsson, Ingegerd

January 2003

Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. The relative biological fitness cost of resistance in Staphylococcus epidermidis was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h.

Microbiology

Human microflora

antibiotic resistance

selection

mutation frequency

biological fitness

pharmacokinetics

pharmacodynamics

β-lactam antibiotics

suboptimal dosing regimen

Mikrobiologi

Microbiology

Mikrobiologi

The mutant-prevention concentration concept and its application to <i>Staphylococcus aureus</i>

Metzler, Kelli Leigh

17 June 2004

<i>Staphylococcus aureus</i> is a ubiquitous organism causing world-wide morbidity and mortality. This species readily develops resistance to antimicrobial agents. Current dosing strategies are based, in part, on minimum inhibitory concentrations (MICs). This susceptibility test fails to detect the presence of first-step resistant mutants often present in large heterogeneous populations of infecting bacteria. Dosing strategies based on MIC results may, in fact, allow for the selective proliferation of resistant subpopulations. The mutant-prevention concentration (MPC) is the drug concentration at which all first-step resistant mutants will be eradicated along with the susceptible cells. Determination of the mutant-selection window (MSW) is possible using MIC and MPC data. When considered together with achievable drug concentrations in human bodily sites, the MSW helps determine which antimicrobials are likely to select for resistance. MIC and MPC testing on clinical isolates of methicillin-susceptible (MSSA) and -resistant (MRSA) S. aureus was performed. Characterization via the polymerase chain reaction, sequencing, and electron microscopy (EM) was done on selected organisms recovered from MPC studies (MPC-recovered). MIC and MPC testing was performed on organisms isolated sequentially from patients with recurring S. aureus infections. Pulsed field gel electrophoresis was performed on these sequential isolates. Based on the MIC and the MPC values, the most potent agents for systemic MSSA and MRSA infections are gemifloxacin and vancomycin, respectively. Re-testing MPC-recovered populations by the MIC showed increased MIC results compared to the parent populations. Macrolide-resistance genes were discovered in S. aureus MPC-recovered populations; in contrast, parental isolates lacked these resistance determinants. EM revealed an increase in cell wall thickness of a vancomycin MPC-recovered population compared to its parental population. Moxifloxacin and vancomycin had the lowest and narrowest MSWs for systemic MSSA and MRSA infections, respectively, compared to the other agents tested. Sequential isolates showed no change in MIC and MPC values. The data presented provides evidence for the application of the MPC test to S. aureus organisms. The MPC data is significant when determining appropriate dosing strategies aimed at preventing resistance.

spontaneous mutation frequency

large bacterial populations

MRSA

MIC

minimum inhibitory concentration

MSW

mutant-selection window

pharmacokinetic curves

VRSA

heterogeneous

fluoroquinolones

MPC

antimicrobial agents