Studium mechanismu účinku metallakarboranových inhibitorů HIV proteasy / Analysis of the mechanism of action of metallacarborane inhibitors of HIV PR

Svoboda, Michal

January 2011

English Abstract Shortly after the identification of HIV as a causative agent of AIDS, an aspartic protease was identified in the viral genetic information. The very same time protease has become one of the dominant therapeutical targets in AIDS therapy. The introduction of protease inhibitors into the antiretroviral therapy has led to a significant improvement in the quality and length of life of HIV patients. However, the virus is still able to effectively prevent the impact of an inhibitor via generating inhibitor-resistant mutated protease variants. Thus, there is a constant need for novel types of inhibitors that would be capable of effectively blocking these resistant variants and simultaneously not supporting the development of novel resistant viral strains. One way to identify such inhibitors could be searching for compounds interacting with the enzyme at different sites than the active cavity, via the mechanisms of noncompetitive or uncompetitive inhibition. The group of compounds called metallacarboranes - inorganic compounds consisting of carbon, boron, hydrogen and metall ion - were shown to exhibit such an activity against HIV-1 protease. However, for further optimization of these inhibitors, detailed biophysical investigation of the enzyme-inhibitor complex is needed. This work focuses on the...

Expression of Recombinant Human Mast Cell Chymase With Asn-Linked Glycans in Glycoengineered Pichia Pastoris

Smith, Eliot T., Perry, Evan T., Sears, Megan B., Johnson, David A.

01 January 2014

Recombinant human mast cell chymase (rhChymase) was expressed in secreted form as an active enzyme in the SuperMan5 strain of GlycoSwitch® Pichia pastoris, which is engineered to produce proteins with (Man) 5(GlcNAc)2 Asn-linked glycans. Cation exchange and heparin affinity chromatography yielded 5 mg of active rhChymase per liter of fermentation medium. Purified rhChymase migrated on SDS-PAGE as a single band of 30 kDa and treatment with peptide N-glycosidase F decreased this to 25 kDa, consistent with the established properties of native human chymase (hChymase). Polyclonal antibodies against hChymase detected rhChymase by Western blot. Active site titration with Eglin C, a potent chymase inhibitor, quantified the concentration of purified active enzyme. Kinetic analyses with succinyl-Ala-Ala-Pro-Phe (suc-AAPF) p-nitroanilide and thiobenzyl ester synthetic substrates showed that heparin significantly reduced KM, whereas heparin effects on kcat were minor. Pure rhChymase with Asn-linked glycans closely resembles hChymase. This bioengineering approach avoided hyperglycosylation and provides a source of active rhChymase for other studies as well as a foundation for production of recombinant enzyme with human glycosylation patterns.

chymase

enzyme kinetics

fermentation

glycosylation

pichia pastoris

serine protease

Biomedical Sciences

Kinetic and Structural Characterization of Isoenzyme-Selective Aldehyde Dehydrogenase 1A Inhibitors

Chtcherbinine, Mikhail

January 2016

Indiana University-Purdue University Indianapolis (IUPUI) / The human aldehyde dehydrogenase superfamily consists of 19 distinct genetic loci that play key roles in both health and disease. Aldehyde dehydrogenases are primarily involved in the metabolism of reactive aldehyde substrates; the ALDH1A subfamily, in particular, metabolizes retinaldehyde and is involved in a pathway regulating tissue differentiation, cell proliferation, and apoptosis. Recently, ALDH1 isoenzymes have been implicated as significant elements in cancer progression. ALDH1 activity has been used as a marker of cancer stem cells, a subpopulation of cancer stem cells with high drug resistance, proliferative potential, and ability to differentiate into multiple cell types. In accordance with this, ALDH1 activity and expression has been shown to correlate with lower survival, increased chemoresistance, and increased chance of relapse in multiple solid cancer types, including breast, ovarian, lung, and colorectal. Despite the clear relevance of ALDH1 enzymes in cancer, the specific roles of individual isoenzymes are unclear. Isoenzyme-selective small molecule modulators of the ALDH1A subfamily would allow the probing of the function of individual isoenzymes in healthy and disease states. Two ALDH1A1 inhibitors, CM38 and C10, were previously identified in a high-throughput screen. In this study, CM38, an ALDH1A1-selective inhibitor, and CM10, an ALDH1A inhibitor, were characterized using kinetic assays, structural biology, and cell culture experiments. A structure-activity relationship was built for each series, and an X-ray crystallography structure was used to determine the binding mode. These approaches allowed the investigation of the ALDH1A active site and identification of structural features that can be used to design and improve selective modulators of this subfamily. CM38 and CM10 were also tested in a breast cancer cell line to determine their efficacy in a cellular environment. While the CM38 series showed warning signs of potential off-target toxicity, members of the CM10 compound series showed excellent initial characteristics as potential chemical tools. The results of this study may be useful in the design of new chemical tools to delineate the functions of individual ALDH1 isoenzymes in cancer biology, as well as in the development of drugs to selectively target cancer stem cells.

Enzyme Kinetics

Small-Molecule Inhibitors

X-Ray Crystallography

Structural Biology

Aldehyde Dehydrogenase

Enzymatic and structural studies of glutathione S-transferases of white-rot fungus Ceriporiopsis subvermispora which is a selective degrader of lignin in woody biomass / 木質バイオマス中のリグニンを選択的に分解する白色腐朽菌Ceriporiopsis subvermisporaのグルタチオンS-トランスフェラーゼに関する酵素学的および構造学的研究

WAN, HASNIDAH BINTI WAN OSMAN

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第21885号 / エネ博第386号 / 新制||エネ||75(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 片平 正人, 教授 森井 孝, 教授 木下 正弘 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM

Ceriporiopsis subvermispora

glutathione S-transferases

woody biomass

enzyme kinetics

crystal structure

501

The Natural and Pharmacological Inhibition of Ribonucleotide Reductase

Misko, Tessianna, Misko

01 February 2019

No description available.

Biomedical Research

Pharmacology

Biochemical characterization of resurrected ancestral ammonia lyases

Holmberg Larsson, Albin

January 2019

This study set out to express, purify and characterize twelve ammonia lyase enzymes for potential application as a supplement to a treatment of an inborn error of metabolism disease. The DNA sequence for two wild-type ammonia lyases, three modified ammonia lyases and seven resurrected ancestral ammonia lyases had been synthesized and cloned in vectors. These were transformed into Escherichia coli, expressed, purified using immobilized metal affinity chromatography and size exclusion chromatography and characterized. Ten of the enzymes were successfully expressed and purified. All enzymes had a higher turnover number with substrate 1 than with substrate 2. The wild-types showed the highest catalytic turnover and one of them displayed substrate cooperativity. The modified enzymes were inactive. Some ancestral enzymes were active and had decreasing kcat with age. A promising ancestral enzymes was found that showed a kcat of 2,85 s-1 with substrate 1 and 1,82 s-1 with substrate 2. The ancestral enzymes had a lower Km with substrate 2 compared to substrate 1, while one of the wild-types had a higher Km with substrate 2 than with substrate 1, indicating that the substrate affinity has switched. The ancestral enzymes had increased thermostability compared to the wild-types which increased with age. Ranging from a +7C increase in melting temperature with the youngest ancestral enzyme to +10,7C with the oldest tested enzyme, comparing with one of the wild-types. The promising ancestral enzyme displayed a higher stability than the wild-types during long term incubation in 37_C and 25_C, since it did not become prone to aggregation,it did not show visible degradation on SDS-PAGE and it retained the highest activity following incubation. It was also demonstrated that neither wild-types nor the promising ancestral enzyme were stable in a simulated gut environment. The promising ancestral enzyme and one of the wild-types degraded substrate 1 and 2 in serum. Using the resurrection of ancestral sequences a promising enzyme has been produced and characterized, displaying properties that are desired in therapeutic enzymes. The enzyme did not aggregate or become prone to aggregation over time, it was thermostable, it was active in serum and had acceptable catalytic properties. For therapeutic application of the ancestral enzyme, immunogenicty should be analyzed in silico and in vitro followed by further investigation in vivo. / Målet med denna studie var att uttrycka, rena och karaktärisera tolv ammonia lyase enzymer, för potentiell användning som komplement till en behandling utav en sjukdom, som tillhör sjukdomsgruppen medfödda ämnesomsättningsrubbningar. DNA sekvensen för två vild-typammonia lyaser, tre modifierade ammonia lyaser och sju återuppväckta ammonia lyaser hade blivit syntetiserade och klonade i vektorer. E.coli celler blev transformerade med vektorerna, vilka uttryckte enzymerna, som renades med hjälp av immobilized metal affinity chromatography och gelfiltrering och karaktäriserades. Tio utav enzymerna kunde uttryckas och renas. Alla enzymer hade högre katalytisk omsättning av substrat 1 än substrat 2. Vildtyperna hade högst kcat med båda substrat och en utav dem uppvisade substratsammarbete. De modifierade enzymerna var inaktiva. Några av de återuppväckta ammonia lyaserna var aktiva och kcat minskade med ålder. Ett av de återuppväckta enzymerna var lovande och hade ett kcat värde av 2,85 s-1 med substrat 1 och 1,82 s-1 med substrat 2. De återuppväckta enzymerna hade ett lägre Km värde för substrat 2 än substrat 1, jämfört med en utav vildtyperna som hade ett högre Km värde för substrat 2 än substrat 1, vilket indikerar ett skifte i substrataffinitet. De återuppväckta enzymerna var mer termostabilia än vild-typerna och termostabiliteten ökar med ålder. Ökningen i smälttemperatur låg i spannet av +7C för de yngsta återuppväckta enzymerna till + 10,7C för det äldsta testade återuppväckta enzymet, vid jämförelse med en utav vild-typerna. Det lovande återuppväckta enzymet demonstrerade även en högre stabilitet än vild-typerna under långtidsinkubering, eftersom den inte blev benägen att aggregera, den uppvisade ingen nedbrytning på SDS-PAGE och den behöll högst aktivitet efter inkubering. Det bevisades även att varken vild-typerna eller det lovande återuppväckta enzymet var stabila i en simulerad magsäcksmiljö. Både det lovande återuppväckta enzymet och en av vild-typerna bröt ner substrat 1 och 2 i serum. Genom att återuppväcka sekvenser kunde ett lovande enzym produceras och karaktäriseras, vilket uppvisade egenskaper som är eftertraktade i terapeutiska enzymer. Enzymet aggregerade ej, det blev inte benäget att aggregera över tid, det var termostabilt, det var aktivt i serum och hade acceptabla katalytiska egenskaper. För terapeutisk applikation av det återuppväckta enzymet, borde analys av dess immunogenicitet utföras in silico och in vitro följt av vidare undersökning in vivo.

Medical Biotechnology

Medicinsk bioteknologi

KINETIC AND MECHANISTIC CHARACTERIZATION OF HUMAN SULFOTRANSFERASES (SULT2B1b AND SULT1A1): DRUG TARGETS TO TREAT CANCERS

Yamasingha Pathiranage Kulathunga (16384296)

26 July 2023

<p>  </p> <p>Sulfonation is a widespread biological reaction catalyzed by a supergene family of enzymes called sulfotransferases (SULTs). SULTs utilize 3’-phosphoadenosine-5’-phospho-sulfate (PAPS) as the universal sulfonate donor to conjugate with a diverse range of endo- and xenobiotic substrates, including neurotransmitters, hormones, and drugs resulting in altering their biological activity. This reaction serves as a major detoxification pathway as conjugation with a sulfonate group renders substrates more hydrophilic and facilitates excretion. Therefore, this process is responsible for reducing the bioavailability of some drugs. In some cases, sulfo-conjugation causes the bio-activation of pro-mutagens and pro-carcinogens, leading to SULTs being risk factors in some cancers. Despite the biological relevance, understanding of this family of enzymes is still scarce. One SULT member that is the focus of the studies described herein is human sulfotransferase 2B1b (SULT2B1b), which had been identified as a potential drug target in prostate cancer. However, the inconsistency in reported kinetic data obtained using radiolabeled assays and the lack of robust assays have become significant limitations for SULT2B1b-targeted drug discovery studies. A label-free assay was developed to bridge this knowledge gap that directly quantifies SULT2B1b sulfonated products. This novel assay utilized high-throughput technology based on Desorption Electrospray Ionization Mass Spectrometry (DESI-MS). Results obtained from the DESI-MS-based assay were compared with those from a fluorometric, coupled-enzyme assay already developed in the Mesecar lab. Both methods provided consistent kinetic data for the reaction of SULT2B1b. Therefore, this novel assay is promising for the application of drug discovery efforts aiming at identifying SULT2B1b inhibitors. The other SULT member studied and described herein is human sulfotransferase 1A1 (SULT1A1), one of humans' most vital detoxifying and drug-metabolizing SULT isoforms that can also be a potential drug target in some cancers. The detailed kinetic mechanism of SULT1A1 was elucidated using steady-state kinetic, product inhibition, dead-end inhibition, and X-crystallographic studies. to gain insights into the role of this enzyme in detoxification, drug metabolism, and the development of inhibitors.</p>

Enzymes

Analytical spectrometry

enzyme kinetics experiment

structure-based drug design studies

Assay development studies

Synthesis and Evaluation of 1,2,4-oxadiazolidinones: The Search for A Potential Non-β-lactam β-lactamase Inhibitors.

Kalu, Chimdi Eke

01 May 2019

β-lactam antibiotics have been the most widely used drug of choice to combat infectious disease caused by bacteria. Unfortunately, their effectiveness is drastically threatened by bacterial β-lactamases. β-lactamases is responsible for the resistance to most antibiotic drugs. For decades, β-lactam β-lactamases inhibitors have been used to reduce bacterial resistance; however, in this study 1,2,4-oxadiazolidinone derivatives as a non-β-lactam β-lactamases inhibitor against TEM-1 and P99 β-lactamases. The significance of oxadiazolidinone is the prominent five-membered ring scaffold in its structure, which is configurationally stable and present in other biologically active compounds such as linezolid and avibactam. Oxadiazolidinones were synthesized by treating nitrones with isocyanates. The synthesized compounds were characterized using 1H and 13C NMR, GC-MS, and FTIR. Afterward, they were tested using Nitrocefin as substrate to determine their effectiveness against TEM-1 and P99 serine β-lactamase. Compound 2a-2c, and 3 showed inhibition ranging from 12-38%.

Antibiotic resistance

β-Lactamases inhibitors

Nitrones

Cycloaddition Reaction

Oxadiazolidinones and Enzyme kinetics

Organic Chemistry

A Study of Mitochondrial Malate Dehydrogenase in <i>Gallus gallus</i> and Other Avian Species

Reidenbach, Kendall

January 2020

No description available.

Biochemistry

Bioinformatics

Malate Dehydrogenase

mitochondrial

MDH2

avian

chicken

migration

biochemistry

enzyme kinetics

bioinformatics

FUNCTIONAL STUDIES WITH DIRECT ORAL ANTICOAGULANTS: INVESTIGATION OF THE REGULATION OF KEY BLOOD COAGULATION PROTEASES

Yeh, Calvin Hsiung

January 2016

Intrinsic structural and conformational mechanisms regulate the functional specificity of the coagulation system. The study of these structure-function relationships is important for understanding the strategies used in the management of clinical thrombosis. Previous studies have shown that the central enzyme in clotting, thrombin, is sequestered inside of a clot, and protected from the natural downregulator antithrombin (AT). This is problematic for anticoagulants like heparin which depend on AT. Subsequently, it was found that the key upstream propagator of thrombin, the prothrombinase enzyme complex, is also resistant to the AT-heparin. Our data show that further upstream of prothrombinase, the intrinsic tenase is only moderately protected, while there is no protection at the level of the initiator complex, extrinsic tenase. This protection phenomenon possibly reflects steric and allosteric mechanisms that ensure maximal activation of the coagulation system once a threshold stimulus is achieved. These mechanisms likely evolved as a result of conformational rearrangement, as evidenced by the proteolytic activation of thrombin activity following proteolysis of prothrombin. Indeed, subtle differences in the structural interaction of ligands with the active site can lead to substantial differences in enzyme activity. The binding of rivaroxaban and apixaban to factor Xa is nearly identical; both interact with the active site with comparable affinity. Despite this, a 3-fold faster rate of the rivaroxaban on-rate yields significantly greater prolongation of the prothrombin time (PT) and activated partial thromboplastin time (aPTT), global tests of coagulation. These small differences in ligand interaction also have allosteric consequences. Structural differences between the direct thrombin inhibitors dabigatran and argatroban yield divergent exosite-mediated thrombin binding to physiologic ligands like yA-fibrin, y'-fibrin, factor Va, and factor VIII, interactions that govern clot-mediated protection from AT inhibition, and the various functions of thrombin. These divergent effects were robust and ligand-dependent, suggesting conserved energetic scaffolds within the thrombin molecule that govern allosteric changes throughout the molecule. Because proteolysis of prothrombin yields significant allosteric and structural rearrangement that capacitates the active site for substrate recognition amd catalytic ability, we investigated the role of Ser195, a key residue in the thrombin catalytic triad in also regulating thrombin allostery. Site directed mutagenesis of Ser195 to Ala yielded a significant increase in the flexibility of the entire thrombin molecule, as evidenced by increased potency of dabigatran and argatroban in terms of their capacity to modulate exosite binding through the active site, and increased interexosite cooperative and competitive allostery. Together, these studies represent an advance in our understanding of the consequences of both small molecule ligation of coagulation proteases, as well as the consequences of subtle structural modification for overall allosteric function. / Thesis / Doctor of Philosophy (PhD)

Coagulation

Proteases

Enzyme kinetics

Direct oral inhibitors

Dabigatran

Argatroban

Thrombin

Heparin

Factor Xa

Prothrombinase