Spelling suggestions: "subject:"ethylpyruvat"" "subject:"ethylpyruvate""
1 |
Ethyl pyruvateDebebe, Tewodros, Krüger, Monika, Huse, Klaus, Kacza, Johannes, Mühlberg, Katja, König, Brigitte, Birkenmeier, Gerd 27 October 2016 (has links) (PDF)
The microbiota has a strong influence on health and disease in humans. A causative shift favoring pathobionts is strongly linked to diseases. Therefore, anti-microbial agents selectively targeting potential pathogens as well as their biofilms are urgently demanded. Here we demonstrate the impact of ethyl pyruvate, so far known as ROS scavenger and antiinflammatory agent, on planktonic microbes and biofilms. Ethyl pyruvate combats preferably the growth of pathobionts belonging to bacteria and fungi independent of the genera and prevailing drug resistance. Surprisingly, this anti-microbial agent preserves symbionts like Lactobacillus species. Moreover, ethyl pyruvate prevents the formation of biofilms and promotes matured biofilms dissolution. This potentially new anti-microbial and anti-biofilm
agent could have a tremendous positive impact on human, veterinary medicine and technical industry as well.
|
2 |
Die immunmodulatorische Wirkung von EthylpyruvatHollenbach, Marcus 06 December 2011 (has links) (PDF)
In einer Vielzahl von Arbeiten konnten anti-inflammatorische Eigenschaften von Ethylpyruvat (EP) aufgezeigt werden. An verschiedenen Modellen der Sepsis, des hämorrhagischen Schocks, von Verbrennungsschäden, des Apoplex oder der Ischämie und Reperfusion wurde bei der Behandlung mit EP ein protektiver Effekt sowie eine verminderte Produktion von pro-inflammatorischen Zytokinen nachgewiesen. Als biochemische Grundlage wurde die Interaktion von EP mit dem Transkriptionsfaktor NF-κB identifiziert, die spezifischen Regulationsmechanismen konnten bisher allerdings nicht zufriedenstellend aufgeklärt werden. In dieser Arbeit wurde als eine neue mögliche Erklärung für die anti-inflammatorischen Eigenschaften des EP und weiterer α-oxo-Karbonsäureester die Inhibierung der Glyoxalase I (Glo-I) aufgezeigt. In vitro-Experimente zur Enzymaktivität belegten die Hemmung der Glo-I durch EP, während α-Hydroxy-Karbonsäureester wie L-Ethyllaktat (EL) keine inhibierenden Eigenschaften aufwiesen. Dennoch waren sowohl EP als auch EL und weitere Laktatester in der Lage, die LPS-induzierte Produktion von pro-inflammatorischen Zytokinen wie IL-1β, IL-6, IL-8 und TNF-α von humanen immunkompetenten Zellen zu supprimieren und die Expression von Immunrezeptoren wie HLA-DR, CD14 und CD91 zu modulieren. Somit konnten erstmals anti-inflammatorische Eigenschaften von Laktatestern nachgewiesen sowie eine Verbindung zwischen den Glyoxalase-Enzymen und dem Immunsystem etabliert werden. Diese und weitere Ergebnisse zur Einflussnahme der Karbonsäureester auf die Zellvitalität präsentieren das Glyoxalasesystem als mögliches Ziel neuer Therapiekonzepte für die Immunsuppression und bestätigen dessen Bedeutung für die Entwicklung von Anti-Tumor-Agenzien.
|
3 |
Ethyl pyruvateDebebe, Tewodros, Krüger, Monika, Huse, Klaus, Kacza, Johannes, Mühlberg, Katja, König, Brigitte, Birkenmeier, Gerd January 2016 (has links)
The microbiota has a strong influence on health and disease in humans. A causative shift favoring pathobionts is strongly linked to diseases. Therefore, anti-microbial agents selectively targeting potential pathogens as well as their biofilms are urgently demanded. Here we demonstrate the impact of ethyl pyruvate, so far known as ROS scavenger and antiinflammatory agent, on planktonic microbes and biofilms. Ethyl pyruvate combats preferably the growth of pathobionts belonging to bacteria and fungi independent of the genera and prevailing drug resistance. Surprisingly, this anti-microbial agent preserves symbionts like Lactobacillus species. Moreover, ethyl pyruvate prevents the formation of biofilms and promotes matured biofilms dissolution. This potentially new anti-microbial and anti-biofilm
agent could have a tremendous positive impact on human, veterinary medicine and technical industry as well.
|
4 |
Die immunmodulatorische Wirkung von EthylpyruvatHollenbach, Marcus 23 August 2011 (has links)
In einer Vielzahl von Arbeiten konnten anti-inflammatorische Eigenschaften von Ethylpyruvat (EP) aufgezeigt werden. An verschiedenen Modellen der Sepsis, des hämorrhagischen Schocks, von Verbrennungsschäden, des Apoplex oder der Ischämie und Reperfusion wurde bei der Behandlung mit EP ein protektiver Effekt sowie eine verminderte Produktion von pro-inflammatorischen Zytokinen nachgewiesen. Als biochemische Grundlage wurde die Interaktion von EP mit dem Transkriptionsfaktor NF-κB identifiziert, die spezifischen Regulationsmechanismen konnten bisher allerdings nicht zufriedenstellend aufgeklärt werden. In dieser Arbeit wurde als eine neue mögliche Erklärung für die anti-inflammatorischen Eigenschaften des EP und weiterer α-oxo-Karbonsäureester die Inhibierung der Glyoxalase I (Glo-I) aufgezeigt. In vitro-Experimente zur Enzymaktivität belegten die Hemmung der Glo-I durch EP, während α-Hydroxy-Karbonsäureester wie L-Ethyllaktat (EL) keine inhibierenden Eigenschaften aufwiesen. Dennoch waren sowohl EP als auch EL und weitere Laktatester in der Lage, die LPS-induzierte Produktion von pro-inflammatorischen Zytokinen wie IL-1β, IL-6, IL-8 und TNF-α von humanen immunkompetenten Zellen zu supprimieren und die Expression von Immunrezeptoren wie HLA-DR, CD14 und CD91 zu modulieren. Somit konnten erstmals anti-inflammatorische Eigenschaften von Laktatestern nachgewiesen sowie eine Verbindung zwischen den Glyoxalase-Enzymen und dem Immunsystem etabliert werden. Diese und weitere Ergebnisse zur Einflussnahme der Karbonsäureester auf die Zellvitalität präsentieren das Glyoxalasesystem als mögliches Ziel neuer Therapiekonzepte für die Immunsuppression und bestätigen dessen Bedeutung für die Entwicklung von Anti-Tumor-Agenzien.
|
5 |
Ethyl Pyruvate and HIV-1 Protease Inhibitors in Drug Discovery of Human African TrypanosomiasisMengistu, Netsanet 28 September 2015 (has links) (PDF)
Referat:
Background: Human African Trypanosomiasis (HAT) also called sleeping sickness is an infectious disease of humans caused by an extracellular protozoan parasite. The disease, if left untreated, results in 100% mortality. However, the available drugs are full of severe drawbacks and fail to escape the fast development of trypanosoma resistance. Due to the probable similarities in cell metabolism among tumor and trypanosoma cells, some of the current registered drugs against HAT were derived from cancer chemotherapeutic research. Here too, for the first time, we have demonstrated that the simple ester, ethyl pyruvate, comprises such properties. On the other hand initial studies have confirmed the efficacy of protease inhibitors in treatment of Trypanosoma cruzi, Plasmodium falciparum and Leishmania major. However, studies on efficacy and specific proteases inhibition using HIV-1 protease inhibitors on T. brucei cells remain untouched.
Methodology/Principal findings: The current study covers efficacy and corresponding target evaluation of ethyl pyruvate and HIV-1 protease inhibitors (ritonavir and saquinavir) on T. brucei cell lines using a combination of biochemical techniques including cell proliferation assays, enzyme kinetics, zymography, phase contrast microscopic video imaging and ex vivo drug toxicity tests. We have shown that ethyl pyruvate effectively kills trypanosomes most probably by net ATP depletion through inhibition of pyruvate kinase (Ki=3.0±0.29 mM). The potential of this compound as an anti-trypanosomal drug is also strengthened by its fast acting property, killing cells within three hours post exposure. This was demonstrated using video imaging of live cells as well as concentration and time dependency experiments. Most importantly, this drug produced minimal side effects in human erythrocytes and is known to easily cross the blood-brain-barrier (BBB) which makes it a promising candidate for effective treatment of the two clinical stages of sleeping sickness. Trypanosome drug resistance tests indicate irreversible killing of cells and a low chance of drug resistance development under applied experimental conditions. In addition to ethyl pyruvate our experimental study on HIV-1 protease inhibitors showed that both ritonavir (RTV) (IC50=12.23 µM) and saquinavir (SQV) (IC50=11.49 µM) effectively inhibited T. brucei cells proliferation. The major proteases identified in these cells were the cysteine- (~29kDa Mr) and metallo- (~66kDa Mr) proteases. Their proteolytic activity was, however, not hampered by either of these two protease inhibitors.
Conclusion/Significance: Our results present ethyl pyruvate as a safe and fast acting drug. Hence, because of its predefined property to easily cross the BBB, it can probably be a new candidate agent to treat the heamolymphatic as well as neurological stages of sleeping sickness. Similarly, HIV-1 protease inhibitors, SQV and RTV, exhibited their antitrypanosomal potential but require further anlysis to identify their specific targets.
|
6 |
Ethyl Pyruvate and HIV-1 Protease Inhibitors in Drug Discovery of Human African TrypanosomiasisMengistu, Netsanet 21 September 2015 (has links)
Referat:
Background: Human African Trypanosomiasis (HAT) also called sleeping sickness is an infectious disease of humans caused by an extracellular protozoan parasite. The disease, if left untreated, results in 100% mortality. However, the available drugs are full of severe drawbacks and fail to escape the fast development of trypanosoma resistance. Due to the probable similarities in cell metabolism among tumor and trypanosoma cells, some of the current registered drugs against HAT were derived from cancer chemotherapeutic research. Here too, for the first time, we have demonstrated that the simple ester, ethyl pyruvate, comprises such properties. On the other hand initial studies have confirmed the efficacy of protease inhibitors in treatment of Trypanosoma cruzi, Plasmodium falciparum and Leishmania major. However, studies on efficacy and specific proteases inhibition using HIV-1 protease inhibitors on T. brucei cells remain untouched.
Methodology/Principal findings: The current study covers efficacy and corresponding target evaluation of ethyl pyruvate and HIV-1 protease inhibitors (ritonavir and saquinavir) on T. brucei cell lines using a combination of biochemical techniques including cell proliferation assays, enzyme kinetics, zymography, phase contrast microscopic video imaging and ex vivo drug toxicity tests. We have shown that ethyl pyruvate effectively kills trypanosomes most probably by net ATP depletion through inhibition of pyruvate kinase (Ki=3.0±0.29 mM). The potential of this compound as an anti-trypanosomal drug is also strengthened by its fast acting property, killing cells within three hours post exposure. This was demonstrated using video imaging of live cells as well as concentration and time dependency experiments. Most importantly, this drug produced minimal side effects in human erythrocytes and is known to easily cross the blood-brain-barrier (BBB) which makes it a promising candidate for effective treatment of the two clinical stages of sleeping sickness. Trypanosome drug resistance tests indicate irreversible killing of cells and a low chance of drug resistance development under applied experimental conditions. In addition to ethyl pyruvate our experimental study on HIV-1 protease inhibitors showed that both ritonavir (RTV) (IC50=12.23 µM) and saquinavir (SQV) (IC50=11.49 µM) effectively inhibited T. brucei cells proliferation. The major proteases identified in these cells were the cysteine- (~29kDa Mr) and metallo- (~66kDa Mr) proteases. Their proteolytic activity was, however, not hampered by either of these two protease inhibitors.
Conclusion/Significance: Our results present ethyl pyruvate as a safe and fast acting drug. Hence, because of its predefined property to easily cross the BBB, it can probably be a new candidate agent to treat the heamolymphatic as well as neurological stages of sleeping sickness. Similarly, HIV-1 protease inhibitors, SQV and RTV, exhibited their antitrypanosomal potential but require further anlysis to identify their specific targets.:Bibliographic description ii
Acronyms iii
1. Introduction 1
1.1. Disease background 1
1.2. Epidemiological distribution and disease transmission dynamics 1
1.3. Biology and life cycle of the trypanosomatidea 3
1.4. Public health significance 4
1.5. Clinical stages and disease progression 5
1.6. Current challenges of disease control 6
1.7. Current drugs and their clinical applications 9
1.8. Targets for drug discovery 12
1.8.1. Energy metabolism 12
1.8.2. Proteolysis 17
1.9. Ethyl pyruvate 18
1.10. HIV-1 Protease Inhibitors 21
2. Aim of the study 22
3. Materials and Methods 24
4. Results 31
5. Discussion 45
6. Conclusion 53
7. Supporting information 54
8. Summary 56
9. References 62
Erklärung über die eigenständige Abfassung der Arbeit 77
Curriculum vitae 78
Publications and Presentations 81
Acknowledgement 83
|
Page generated in 0.0403 seconds