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Microwave-Assisted Synthesis of C<sub>2</sub>-Symmetric HIV-1 Protease Inhibitors : Development and Applications of <i>In Situ</i> Carbonylations and other Palladium(0)-Catalyzed ReactionsWannberg, Johan January 2005 (has links)
<p>The HIV protease is an essential enzyme for HIV replication and constitutes an important target in the treatment of HIV/AIDS. Efficient combination therapies using inhibitors of the reverse transcriptase and protease enzymes have led many to reevaluate HIV infections from a terminal condition to a chronic-but-manageable disease in the developed world. Unfortunately, the emergence of drug resistant viral strains and severe treatment-related adverse effects limit the benefits of current anti-HIV/AIDS drugs for many patients. Furthermore, less than one in ten patients infected with HIV in low- and middle-income countries have access to proper treatment. These important shortcomings highlight the need for new, cost effective anti-HIV/AIDS drugs with unique properties.</p><p>Microwave heating has recently emerged as a productivity-enhancing tool for the medicinal chemist. Reaction times can often be reduced from hours to minutes or seconds and chemistry previously considered impractical or unattainable can now be accessed.</p><p>In this thesis, the search for unique HIV-1 protease inhibitors and the development and application of new microwave-promoted synthetic methods useful in small-scale medicinal chemistry applications are presented. Protocols for rapid amino- and hydrazidocarbonylations were developed. Mo(CO)<sub>6</sub> was used as a solid source of carbon monoxide, enabling a safe, efficient and simple way to exploit carbonylation chemistry without the direct use of toxic carbon monoxide gas. The aminocarbonylation methodology was applied in the synthesis of two series of new HIV-1 protease inhibitors. A biological evaluation suggested that <i>ortho</i>-substitution of P1 and/or P1’ benzyl side chains might provide a new approach to HIV-1 protease inhibitors with novel properties. To assess the scope and limitations of the <i>ortho</i>-substitution concept, a new series of compounds exhibiting fair potency was prepared by various microwave-heated, palladium-catalyzed coupling reactions. Finally, computer modeling was applied to rationalize the binding-modes and structure-activity relationships of these HIV-1 protease inhibitors.</p>
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Microwave-Assisted Synthesis of C2-Symmetric HIV-1 Protease Inhibitors : Development and Applications of In Situ Carbonylations and other Palladium(0)-Catalyzed ReactionsWannberg, Johan January 2005 (has links)
The HIV protease is an essential enzyme for HIV replication and constitutes an important target in the treatment of HIV/AIDS. Efficient combination therapies using inhibitors of the reverse transcriptase and protease enzymes have led many to reevaluate HIV infections from a terminal condition to a chronic-but-manageable disease in the developed world. Unfortunately, the emergence of drug resistant viral strains and severe treatment-related adverse effects limit the benefits of current anti-HIV/AIDS drugs for many patients. Furthermore, less than one in ten patients infected with HIV in low- and middle-income countries have access to proper treatment. These important shortcomings highlight the need for new, cost effective anti-HIV/AIDS drugs with unique properties. Microwave heating has recently emerged as a productivity-enhancing tool for the medicinal chemist. Reaction times can often be reduced from hours to minutes or seconds and chemistry previously considered impractical or unattainable can now be accessed. In this thesis, the search for unique HIV-1 protease inhibitors and the development and application of new microwave-promoted synthetic methods useful in small-scale medicinal chemistry applications are presented. Protocols for rapid amino- and hydrazidocarbonylations were developed. Mo(CO)6 was used as a solid source of carbon monoxide, enabling a safe, efficient and simple way to exploit carbonylation chemistry without the direct use of toxic carbon monoxide gas. The aminocarbonylation methodology was applied in the synthesis of two series of new HIV-1 protease inhibitors. A biological evaluation suggested that ortho-substitution of P1 and/or P1’ benzyl side chains might provide a new approach to HIV-1 protease inhibitors with novel properties. To assess the scope and limitations of the ortho-substitution concept, a new series of compounds exhibiting fair potency was prepared by various microwave-heated, palladium-catalyzed coupling reactions. Finally, computer modeling was applied to rationalize the binding-modes and structure-activity relationships of these HIV-1 protease inhibitors.
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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.
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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
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Design, Synthesis and Applications of Novel Thiosugars & Amino Acid DerivativesGunasundari, T January 2012 (has links) (PDF)
Glycosidases are carbohydrate processing essential enzymes necessary for the growth and development of all organisms such as intestinal digestion, post-translational processing of glycoproteins and the lysosomal catabolism of glycoconjugates. The function of these glycosidases is limited and studies are still in progress to understand their function at cellular level. In recent years, biological role of carbohydrates has resulted in various carbohydrate-based therapeutics2. These carbohydrates serve as a tool to study the function of glycosidases by inhibiting their active site. The concept of inhibition is yet another approach for the discovery of drugs.
Glycosidase inhibitors studied are often sugar analogs and a wide range of such inhibitors are reported in the literature.3, 4 Thiosugars, in particular, have gained new perspectives owing to their electronic, geometric, conformational and flexibility differences, as sulfide moiety being less electronegative and more polarizable than the oxygen counter-part.5 These differences make the thiosugars distinct from their oxygen analogs and hence can mimic the active site of the enzyme. Many molecules are reported to be promising glycosidase inhibitors but are not easily accessible due to difficulties in their synthesis. Hence, the chemical synthesis of thio-analogs of carbohydrates, by synthetic routes, remains a major challenge. To address the complexity of synthesis and to make available new strategies, we envisioned the use of benzyltriethylammonium tetrathiomolybdate [BnEt3N]2MoS4, a versatile and efficient sulfur transfer reagent.
Objectives of the study:
a. Design novel thiosugars as glycosidase inhibitors.
b. Devise strategy for the synthesis of novel thiosugars through a simple, practical approach.
c. Evaluate the synthesized molecules as glycosidase and HIV-1 protease inhibitors, in silico.
d. Study miscellaneous applications of the novel thiosugar-derived thialactones.
The thesis is divided into five sections:
Section A entitled “Synthesis of deoxythiosugars and thiosugar-based lactones” is divided into two parts, Part A and Part B.
Part A – “An introduction and background on thiosugars and sulfur transfer reagents” has been provided. A brief discussion of sulfur transfer reagents in carbohydrate synthesis and earlier work related to the use of benzyltriethylammonium tetrathiomolybdate, [BnEt3N]2MoS4, as an efficient sulfur transfer reagent have been provided.
Part B –“Design of inhibitors of glycosidases and HIV-1 protease” deals with the design of inhibitors of glycosidase and HIV-1 protease. The designed thiosugar molecules exhibit the characteristics of sugars and will act as planar molecules to mimic the active site conformation of a good inhibitor. Synthetic methodologies devised and adopted for the synthesis of constrained sugar-derived thialactones include: (a) Double displacement, (b) Displacement-cum-intramolecular thia-Michael addition, (c) Epoxide ring-opening-cum-intramolecular thia-Michael addition, and (d) Displacement-cum-epoxide ring opening in an intramolecular fashion. In all the above mentioned strategies, sulfur transfer step is the crucial step which was achieved by the use of benzyltriethylammonium tetrathiomolybdate [BnEt3N]2MoS46 as the key reagent.
(a) Various constrained thialactones synthesized by double displacement strategy using tetrathiomolybdate as the sulfur transfer reagent are shown in Scheme – 1.
(b) A number of constrained thialactones were synthesized following nucleophilic displacement-cum-intramolecular thia-Michael addition strategy as shown in Scheme – 2.
(c) Synthesis of bicyclic thiolactones was achieved using the strategy of epoxide ring-opening-cum-intramolecular thia-Michael addition. (Scheme – 3)
(d) A few bicyclic thialactones were synthesized through displacement-epoxide ring opening-cyclization as shown in Scheme – 4.
The methodology was also utilized for the synthesis of thiosugar derivatives and azido-thialactones. (Fig. 1)
Figure 1
Synthesis of deoxythiosugars: The bicyclic thialactones (designed as inhibitors) on reduction with borohydride exchange resin (BER) easily furnished the deoxythiosugars (Fig. 2). It is worth mentioning that the synthesis of these thiosugars as reported in the literature involved lengthy procedures whereas the present methodology turns out to be short and concise.
Figure 2
Section B entitled “Synthesis of amines, β-amino acids and novel thiosugar-based dehydroamino acids” comprises a brief introduction on the importance of amines, β-amino acids and dehyroamino acids. In this section the effective utilization of benzyltriethylammonium tetrathiomolybdate as a key reagent for reductive transformations and its application in the synthesis of amines, β-amino acids and dehyroamino acids have been presented.
A one pot reduction of azides to amines followed by intermolecular aza-Michael addition employing tetrathiomolybdate was achieved to furnish a number of different β-amino esters as shown in Scheme -4:
Scheme 4
The study was further extended to the reduction of a few anomeric azides to afford the corresponding anomeric amines and derivatives. (Fig. 3)
Figure 3
A one-pot thia-Michael addition-vinyl azide reduction in a tandem fashion employing benzyltriethylammonium tetrathiomolybdate was studied and was shown to be effective for the synthesis of thiosugar derived dehydroamino acid derivatives. (Scheme – 5)
Scheme 5
Section C entitled “Molecular docking studies of deoxythiosugar probes” gives an overview of different glycosidases, HIV-1 protease and their inhibitors. This section also deals with a brief introduction on active site conformations of potent inhibitors. In this connection we have studied the crystal conformations of the synthesized molecules whose conformations were the same as that of the existing inhibitors in the active site. (Fig. 4) With this background in silico study of the synthesized deoxythiosugar probes was conducted on human glycosidases: α-mannosidase, α-galactosidase, β-glucosidase and HIV-1 protease, respectively.
Figure 4
Molecular docking was carried out using Autodock suite, molecular modeling simulation. Separate docking procedures were employed for the four different receptors. The PDBs representing the four enzyme targets were 2V3D, 3H53, 1X9D and 3I8W for β–glucosidase, α–galactosidase, α–mannosidase and HIV–1 protease respectively. The control compounds used for α–mannosidase were mannostatin and kifunensine. NMB, THK, and BED were the positive controls for HIV–1 protease. Similarly, NBV and cyclophellitol were the controls used for β–glucosidase and NOJ, N–methyl calystegine B2 for α–galactosidase. (Fig. 5) Ligands TGSB68 and TGSB482 had the energy value of –6.49 kcal/mol comparable to that of the average reference value of the positive control, and thus, the potent candidate as identified by molecular docking to HIV-1 protease. (Fig. 6a) The control compounds used for α–mannosidase were mannostatin and kifunensine, which bind with mean binding energy of -9.11 and -5.56. In the case of α–mannosidase, the same compounds TGSB68 and TGSB482 were selected due to comparable energy and a good cluster size with that of positive control. (Fig. 6b) For β– glucosidase, ligands TGSC108 and TGSC236, which had comparable values to that of positive control was identified as the
Figure 5
Figure 6
potent candidate. (Fig. 6c) In the case of α–galactosidase, again the ligands TGSB68 and TGSB482 were selected based on binding energies. (Fig. 6d)
In conclusion, the concept analogy (deoxy nature, planarity, thiosugar framework, lactone moiety) for the design of inhibitors indeed worked positively. The results are really encouraging. An in vivo study of the synthesized novel thiosugar probes will certainly provide a potent inhibitor.
Section D entitled “Research methodology” provides experimental procedures adopted with details of synthesis.
Section E entitled “Bibliography” provides the references cited in this work.
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