FUNCTIONAL SCREENING OF CYTOCHROME P450 ACTIVITY AND UNCOUPLING BY CAPILLARY ELECTROPHORESIS

Harskamp, James G.

10 1900

<p>Cytochrome P450s are a super-family of heme containing proteins that are found in all domains of life and are involved in the synthesis and breakdown of steroids, xenobiotics, and pharmaceuticals. Using five heterologously expressed zebrafish (Danio rerio) CYP1s, an assay was developed for CYP activity in order to monitor the consumption of the cofactor NADPH, providing a label-free screening tool to determine function of novel CYP genes. Using well-established fluorogenic substrates, NADPH and NADP+ were separated by capillary electrophoresis (CE) from stopped CYP1 reactions and measured with UV absorbance detection as a surrogate to assess the rate of substrate metabolism. Product formation was confirmed by fluorometric detection of metabolites, giving rates of enzyme activity which could be compared to the rates of cofactor turn-over measured by CE. 17β-estradiol, four alkoxyresorufin and two coumarin based synthetic fluorogenic CYP substrates were screened for activity with recombinant zebrafish CYP1A, 1B1, 1C2, 1C2 and 1D1. Cofactor consumption was generally much larger than product formation for the majority of substrates and CYP1 isoforms, suggesting that the majority of metabolic events were uncoupled. Large uncoupling was seen in CYP1 when metabolizing estradiol, showing that endogenous compounds can also show severe uncoupling. Reactive oxygen species (ROS), a product of uncoupled events, were detected with 2,7- dichorofluorescein. Attempts for concomitant detection of ROS production and cofactor consumption with CE-UV detection were investigated, however, detection limits for 2,7-dichlorofluorescein were not adequate for detection of hydrogen peroxide production from CYP1 mediated reactions. Future work will be required to develop a single assay to quantitatively measure CYP activity by CE for functional determination of CYPs with unknown function.</p> / Master of Science (MSc)

cytochrome p450

Uncoupling

capillary electrophoresis

reactive oxygen species

enzyme kinetics

Biology

Biology

A Novel Approach to Detecting Listeria monocytogenes: Creating Species-Specific Ribonuclease (RNase)-Cleaved Fluorescent Substrate (RFS) by In Vitro Selection

Kanda, Pushpinder S.

19 August 2014

<p>The food-borne pathogen, <em>Listeria monocytogenes</em>, is a global health concern as it has been responsible for multiple food contamination outbreaks over the past century. Current detection methods like the enzyme-linked immunoassays (ELISA), and polymerase chain reaction (PCR) take over 24 h to attain results, are costly, require specialized equipment and trained personnel. In this study we investigated the use of functional nucleic acid (FNA) to develop a rapid and cost-effective detection method for <em>L. monocytogenes</em>. We carried out in<em> vitro</em> selection in order to isolate a fluorescently labeled DNA-RNA hybrid strand that can be bound and cleaved by specific endoribonucleases (RNase) from <em>L. monocytogenes</em>. We termed these DNA-RNA hybrid strands RNase-cleaved fluorescent substrate (RFS). Since no past studies have isolated RNases from <em>L. monocytogenes</em>, we first identified the genes based on sequence similarities with well characterized RNases. We purified and characterized RNase HII, RNase III and RNase G. Since this study focused primarily on developing RFS for RNase HII, we performed an in depth <em>in vitro</em> biochemical analysis to characterize this enzyme. We found that RNase HII from <em>L. monocytogenes</em> plays an important role in DNA replication and repair. Furthermore, we obtained six sequence classes by <em>in vitro</em> selection which could interact with RNase HII. The key nucleotide regions involved with RNase HII interactions were identified. In the final study, we showed the sequences isolated by <em>in vitro</em> selection could also be used as a tool to study ribonuclease function and identify new interaction between enzyme and substrate.</p> / Master of Science (MSc)

Ribonuclease

SELEX

Biosensor

Enzyme Kinetics

Listeria monocytogenes

Functional nucleic acid

Biochemistry

Biology

Biophysics

Molecular Biology

Biochemistry

Investigating the ATPase site of the cytosolic iron sulfur cluster assembly scaffold through regulated interactions with its partner proteins

Mole, Christa Nicole

19 September 2022

Complex biosynthetic pathways are required for the assembly and insertion of iron-sulfur (Fe-S) cluster cofactors. The four cluster biogenesis systems that have been discovered require at least one ATPase, but generally the function of nucleotide hydrolysis is understudied. In the cytosolic iron sulfur cluster assembly (CIA) system, responsible for delivering [Fe4-S4] cluster cofactors for cytosolic and nuclear enzymes, the assembly scaffold comprises two homologous ATPases, called Nbp35 and Cfd1 in Saccharomyces cerevisiae. Genetic studies have discovered that the ATPase sites are required for scaffold function in vivo, but in vitro studies have failed to reveal why. The ATPase sites of the Nbp35 and Cfd1 contain a conserved P-loop nucleotide-binding protein fold with a deviant Walker A motif. Known metal trafficking P-loop NTPases’ metallochaperone mechanisms rely on both nucleotide binding and hydrolysis to properly assemble and deliver metal cargo. Furthermore, P-loop NTPases with a deviant Walker A motif commonly serve as central regulatory switches whose hydrolysis activity is modulated by small molecule cargos and/or protein partners. Therefore, it is proposed that the role of Nbp35-Cfd1’s ATPase sites is to direct Fe-S cluster movement by regulating protein and metal cargo interactions. The goal of this thesis is to better understand the scaffold reaction cycle by investigating the metallochaperone mechanism through Nbp35-Cfd1’s protein communications with its ATPase sites. To do this, the identification of at least one nucleotide-dependent partner protein must first be discovered. Herein, in vitro methods have been developed to uncover the scaffold’s ATPase site regulation of protein interactions. We describe a qualitative affinity copurification assay and a quantitative analysis for evaluating the dissociation constant and the kcat and Km values for ATP hydrolysis for the scaffold–partner protein complex. Additionally, the execution of these ATPase assays in an anaerobic environment can be applied to study nucleotide hydrolases involved in metallocluster biogenesis. These in vitro methods are applied to Nbp35-Cfd1 and it is discovered that ATP binding and hydrolysis regulates Nbp35-Cfd1 binding with two CIA factors: Dre2, a reductase proposed to assist in Fe-S cluster assembly, and Nar1, an adaptor between the early and late CIA factors. Although reconstitution of the scaffold’s Fe-S clusters results in a two-fold increase in its ATPase activity, the Dre2 and Nar1 ATP hydrolysis stimulation is dampened, demonstrating that both the Fe-S cargo and partner proteins regulate the scaffold’s ATPase reaction cycle. Next, the domains required for binding and ATPase stimulation were identified for Nbp35-Cfd1 with its partner proteins Dre2 and Nar1. The C-terminal Fe-S binding domain of Dre2 is sufficient for ATPase stimulation, while the Nar1 requires both its N- and C-terminal Fe-S binding domains to activate Nbp35-Cfd1’s ATP hydrolysis. The N-terminal Fe-S binding domain of Nbp35 is dispensable for binding and ATPase stimulation of both Dre2 and Nar1. The CIA targeting complex protein Cia1, which binds to Nar1, competes off Nbp35-Cfd1, indicating a shared binding domain. This data both validates and refines the current working model of the CIA system. To test whether the communication between the ATPase and Fe-S cluster binding domains of the CIA scaffold functions in an analogous manner across multiple species, a preliminary analysis was completed for whether Chaetomium thermophilum and Homo sapien Nbp35-Cfd1 exhibit similar ATPase characteristics and partner protein interaction as their S. cerevisiae ortholog. Human and fungal Nbp35-Cfd1 exhibit ATP binding and demonstrate nucleotide-dependent interactions with Dre2 and Nar1, suggesting that these interactions in a similar manner to effectively communicate in the CIA pathway. Overall, our study uncovers striking similarities between the CIA pathway and other systems which exploit a deviant Walker A NTPase to coordinate complex, multiprotein processes. Identification of the scaffold’s partner proteins significantly advances our understanding as to why the Nbp35/MRP-type Fe-S cluster biogenesis proteins are nucleotide hydrolases. This work provides some mechanistic insight into the functions of these proteins and provides a roadmap for how to investigate this large and widely distributed family and other P-loop NTPase metallochaperones. / 2024-09-19T00:00:00Z

Biochemistry

ATPases

Cytosolic iron-sulfur cluster assembly

Enzyme kinetics

Iron-sulfur

Metal trafficking

Nbp35-Cfd1

Grape Extracts for Type 2 Diabetes Treatment Through Specific Inhibition of α-Glucosidase and Antioxidant Protection

Hogan, Shelly Patricia

30 April 2009

Research was conducted to investigate the effect of phenolic compounds derived from inherently rich antioxidant grape extracts (GE) on α-glucosidase inhibitory activity in vitro and in vivo blood glucose control, oxidative stress, and inflammation associated with obesity-induced type 2 diabetes. Because intestinal α-glucosidase plays a key role in the digestion and absorption of complex carbohydrates, the inhibition of this enzyme is a metabolic target for managing diabetes by improving post-prandial blood glucose control. Initially, red Norton wine grape (Vitis aestivalis) and pomace extracts were evaluated and determined to have notable phenolic content and antioxidant properties. Next, grape skin (GSE) and pomace extract (GPE) were tested and both had in vitro yeast and mammalian α-glucosidase inhibitory activity. The GSE was 32-times more potent at inhibiting yeast α-glucosidase than acarbose, a commercial oral hypoglycemic agent. From HPLC and LC-MS analysis, three phenolics from the GSE (resveratrol, ellagic acid, and catechin) were identified as active inhibitory compounds. The acute administration of GPE (400 mg/kg bw) to mice reduced postprandial blood glucose level by 35% following an oral glucose tolerance test compared to the control. The daily supplementation (250 mg/kg bw) of GSE and GPE for 12-weeks to mice affected fasting blood glucose levels, oxidative stress, and inflammatory biomarkers associated with obesity and type 2 diabetes. At the end of the study, the GSE group gained significantly (P < 0.05) more weight (24.6 g) than the control, high fat, or GPE groups (11.2, 20.2, 19.6 g, respectively). Both GSE and GPE groups had lower fasting blood glucose levels (119.3 and 134.2 mg/dL, respectively) compared to the high fat group (144.6 mg/dL). The 12-week supplementation of GSE was associated with a higher plasma oxygen radical absorbance capacity (ORAC), lower liver lipid peroxidation as measure by TBARS, and lower levels of inflammation as measured by plasma C-reactive protein compared to the high fat group. In conclusion, our collective observations from these studies provide insight into the potential effects of antioxidant rich grape extracts on diabetes-related biomarkers through a dual mechanism of antioxidant protection and specific inhibition of intestinal α-glucosidases. / Ph. D.

oxidative stress

diabetes

bioactive phenolic compounds

α-glucosidase

enzyme kinetics

macromolecule

Functional foods

Kinetic Characterization And Newly Discovered Inhibitors For Various Constructs Of Human T-Cell Leukemia Virus-I Protease And Inhibition Effect Of Discovered Molecules On HTLV-1 Infected Cells

DEMIR, AHU

21 October 2010

Discovered in 1980, HTLV-1 (Human T-cell Leukemia Virus-1), was the first identified human retrovirus and is shown to be associated with a variety of diseases including: adult T-cell leukemia lymphoma (ATLL), tropical spastic paraparesis/HTLV-1 associated myelopathy (TSP/HAM), chronic arthropathy, uveitis, infective dermatitis, and polymyositis. The mechanism by which the virus causes disease is still unknown. HTLV- 1 infection has been reported in many regions of the world but is most prevalent in Southern Japan, the Caribbean basin, Central and West Africa, the Southeastern United States, Melanesia, parts of South Africa, the Middle East and India. Approximately 30 million people are infected by HTLV-1 worldwide, although only 3-5% of the infected individuals evolve Adult T-cell Leukemia (ATL) during their life and the prognosis for those infected is still poor. The retroviral proteases (PRs) are essential for viral replication because they process viral Gag and Gag-(Pro)-Pol polyproteins during maturation, much like the PR from Human Immunodeficiency Virus-1 (HIV-1). Various antiviral inhibitors are in clinical use and one of the most significant classes is HIV-1 PR inhibitors, which have used for antiretroviral therapy in the treatment of AIDS. HTLV-1 PR and HIV-1 PR are homodimeric aspartic proteases with 125 and 99 residues, respectively. Even though substrate specificities of these two enzymes are different, HTLV-1 PR shares 28% similarity with HIV-1 PR overall and the substrate binding sites have 45% similarity. In addition to the 125-residue full length HTLV-1 PR, constructs with various C- terminal deletions (giving proteases with lengths of 116, 121, or 122 amino acids) were made in order to elucidate the effect of the residues in the C-terminal region. It was suggested that five amino acids in the C-terminal region are not necessary for the enzymatic activity in Hayakawa et al. 1992. In 2004 Herger et al. had suggested that 10 amino acids at the C-terminal region are not necessary for catalytic activity. A recent paper suggested that C-terminal residues are essential; and that catalytic activity lowers upon truncation, with even the last 5 amino acids necessary for full catalytic activity (1). The mutation L40I has been made to prevent autoproteolysis and the W98V mutation was made to make the active site of HTLV-1 PR similar to HIV-1 PR. We have characterized C-terminal amino acids of HTLV-1 PR as not being essential for full catalytic activity. We have discovered potential new inhibitors by in silico screening of 116-HTLV-1 PR. These small molecules were tested kinetically for various constructs including the 116, 121 and 122-amino acid forms of HTLV-1 PR. Inhibitors with the best inhibition constants were used in HTLV-1 infected cells and one of the inhibitors seems to inhibit gag processing.

Protease

Human T-cell Leukemia Virus-1 (HTLV-1)

enzyme kinetics

small molecule inhibitors

Study of Enantiomeric Discrimination and Enzyme Kinetics using NMR Spectroscopy

Reddy, U Venkateswara

January 2013

Obtaining enantio pure drug molecules is a long standing challenge in asymmetric synthesis implying that the identification of enantiomers and the determination of enantiomeric purity from a racemic mixture are of profound importance. In achieving this target NMR spectroscopy has proven to be an excellent analytical tool. It is well known that normal achiral NMR solvents do not distinguish the spectra of enantiomers. On the other hand, the conversion of substrates to diastereomers using one of the enantiopure chiral auxiliaries, such as, chiral solvating agent, chiral derivatizing agent and chiral lanthanide shift reagent, circumvents this problem. The imposition of diasteomeric interactions circumvents this problem. There is a pool of chiral auxiliaries available in the literature, each of which is specific to molecules of certain functionalities and has its own advantages and limitations. These classical methods have two limitations as they demand the presence of a targeted functional group in the chiral molecule and utilize only chemical shifts to visualize enantiomers. On the other hand in chiral anisotropic medium, due to differential ordering effect, the order-sensitive NMR observables, viz. chemical shift anisotropies (∆σi), dipolar couplings (Dij) and for nuclei with spin >1/2 the quadrupolar couplings (Qi) have enormous power of exhibiting different spectrum for each enantiomer permitting their discrimination. Numerous weakly ordered chiral aligning media have been reported in the literature. Nevertheless there is a scarcity of water compatible medium. Research work presented in this thesis is focused on various aspects, such as, the discovery of new chiral aligning medium for the enantiodiscrimination of water soluble chiral molecules, potential utility of DNA liquid crystal for discrimination of amino acids, on-the-fly monitoring of enzyme kinetics and the preparation of novel composite liquid crystals, hydrogels and thin films. The derived results are discussed in different chapters. Chapter 1 provides a brief introduction to NMR spectroscopy with special emphasis on the conceptual understanding of the tensorial interaction parameters, such as chemical shifts, scalar and dipolar couplings, quadrupolar couplings, effect of r.f pulses, basic introduction to 2D NMR experiments. Subsequently, a broad overview of the enantiomers, specification of their configurations, chirality without stereogenic carbon, chirality in molecules containing different atoms, are discussed. Following this a brief introduction to liquid crystals and their properties, their classification, their orientation in the magnetic field, order parameter are also discussed. The description on the chiral liquid crystals, the differential ordering effect, employment of the orientation dependent NMR interactions, utility of 2H NMR experiments for the visualization of enantiomers and the measurement of enantiomeric composition has been set out in brief. Chapter 2: As far as the organo soluble chiral molecules is concerned (in solvents such as, chloroform, dioxane, tetrahydrofuran and dimethylformamide), it has been well established that an ideal choice of chiral liquid crystal for enantiodiscrimination is poly-�-benzyl-L-glutamate (PBLG). Nevertheless, there is a scarcity of weak aligning medium for water soluble chiral molecules. This chapter introduces the chiral liquid crystal derived from the polysaccharide xanthan, which has numerous applications. The detailed discussion on the preparation of polysaccharide xanthan mesophase is given. The appearance of the mesophse is established by detecting the quadrupole split doublet of dissolved water. Subsequently enantiodiscrimination power of this new medium has been investigated on deuterated D/L-Alanine and (R/S)-β-butyrolactone. For such a purpose the selective 2D-SERF (SElective ReFocussing) experiment has been employed. It has been convincingly demonstrated that the medium has wide applicability for the discrimination of enantiomers, enantiotopic directions in prochiral molecules, measurement of enantiomeric excess and the RDCs in medium sized molecules. The new medium is sustainable over a wide range of temperature and concentration of ingredients, the mesophase is reversible, reproducible, easy to prepare besides being cost effective. It is possible to have the controlled tuning of the degree of order for specific application. Chapter 3: In this chapter the real discriminatory potential of DNA liquid crystalline phase has been explored. It is unambiguously established that; i) the fragmented DNA liquid crystal is able to differentiate between enantiomers of structurally different chiral amino acids; ii) the T1 (2H) values for L/D (alanine) is nearly equal indicating the similar dynamics for both the enantiomers, thus permitting the measurement of ee from the integral areas of the peaks of the contours of 2D spectrum; iii) the enantiotopic discrimination in prochiral compounds has also been successfully explored. Furthermore the analyses of NMR results yielded fruitful information on the analytical potential of DNA chiral liquid crystal, such as, (a) the chiral discrimination is effective on a large range of amino acids with spectral differences ΔΔʋQ‘s and ΔʋQ‘s varying from 80 to 338 Hz, and 50 to 900 Hz respectively; (b) the discrimination phenomenon remain active irrespective of the structure and the electronic nature (polarity) of the fourth substituent around the stereogenic center; (c) compared to an alkyl moiety, the presence of a terminal –OH or –SH group seems to slightly increase both the degree of alignment of the solute and the enantiodiscrimination efficiency compared to alanine; (d) The enantiodiscrimination can be detected easily not only on CD3 and CD groups, but also on CD2 sites exhibiting inequivalent diastereotopic directions; (e) discriminations with rather large differential ordering effect were obtained even for the sites that are situated far away from the asymmetric center; (f) The relative position of quadrupolar doublets from one 2H site to another can be reversed with regard to the absolute configuration (L/D). Chapter 4: Racemases recognize a chiral substrate such as (L-Alanine) and convert it into its enantiomer, i.e., (D-Alanine) and vice versa. Alanine racemase plays a vital role for certain bacteria, providing D-Alanine for peptidoglycan cell-wall biosynthesis. Elucidating the mechanism of enzymatic racemization is crucial for designing new inhibitors that may be useful as a novel class of antibiotics. This requires techniques to discriminate L-and D-Alanine and follow their concentrations as a function of time, so that one can determine the kinetic parameters and study the effect of inhibitors. In this chapter the utility of DNA liquid crystal media for in situ and real-time monitoring of the interconversion of L-and D-alanine-d3 by alanine racemase from Bacillus stearothermophilus has been demonstrated. The enantiomeric excess has been measured at different time intervals to monitor the enzymatic racemization at different time intervals in pseudo 2D NMR. The study unambiguously ascertains the reliability and robustness of utility of NMR in chiral anisotropic phase for monitoring the enzymatic racemization. The method thus provides new mechanistic insight and a better understanding of enzymatic reactions, in particular for alanine racemase. Chapter 5: In continuation with the development of weakly ordered liquid crystals, this chapter reports the spontaneous formation of composite graphene oxide (GO)/double stranded DNA (dsDNA) liquid crystals at higher concentrations of ingredients, and hydrogels at lower concentrations of ingredients, the process of which involves simple mixing in an aqueous phase has been demonstrated. The liquid crystalline phases and hydrogels have been characterized using optical polarized microscopy (OPM), scanning electron microscopy (SEM), Raman spectroscopy and 2H NMR spectroscopy. The observation of strong birefringence in the optical polarized microscope gives evidence for the formation of GO/dsDNA liquid crystals. The strong interaction between the dsDNA and GO was confirmed using Raman spectroscopic analysis. Furthermore, GO/dsDNA thin films have also been prepared and characterized using SEM and OPM. The GO/dsDNA thin film was prepared and its liquid crystal nature was established using OPM and 2H NMR. Importantly, the GO/dsDNA hydrogels were formed without any heat treatment to unwind dsDNA molecules and the porosity of hydrogels can be controlled by changing concentration of the dsDNA. This novel multifunctional composite liquid crystals and hydrogels of GO/dsDNA thus opens up new avenues for many applications like security papers, optical devices such as circular polarizers, reflective displays and drug delivery as well as tissue engineering using GO composite hydrogels.

Chiral Analysis

Nuclear Magnetic Resonance

Enzyme Kinetics

Chiral Molecules - Enantiodiscrimination

Water Soluble Chiral Molecules

Enzymatic Racemization

Enantiomers

On-the-fly Enzyme Kinetics

Amino Acids - Enantiodiscrimination

DNA Liquid Crystals

Graphene Oxides

Hydrogels

Chiral Liquid Crystals (CLC)

NMR Hamiltonians

Liquid Crystals

Enzymatic Racemization

Biochemistry

Exploring the mechanism of action of spore photoproduct lyase

Nelson, Renae

27 August 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Spore photoproduct lyase (SPL) is a radical SAM (S-adenosylmethionine) enzyme that is responsible for the repair of the DNA UV damage product 5-thyminyl-5,6-dihydrothymine (also called spore photoproduct, SP) in the early germination phase of bacterial endospores. SPL initiates the SP repair process using 5'-dA• (5'-deoxyadenosyl radical) generated by SAM cleavage to abstract the H6proR atom which results in a thymine allylic radical. These studies provide strong evidence that the TpT radical likely receives an H atom from an intrinsic H atom donor, C141 in B. subtilis SPL. I have shown that C141 can be alkylated in native SPL by iodoacetamide treatment indicating that it is accessible to the TpT radical. Activity studies demonstrate a 3-fold slower repair rate of SP by C141A which produces TpTSO2 - and TpT simultaneously with no lag phase observed for TpTSO2- formation. Additionally, formation of both products shows a Dvmax kinetic isotope effect (KIE) of 1.7 ± 0.2 which is smaller than the DVmax KIE of 2.8 ± 0.3 for the WT SPL reaction. Removal of the intrinsic H atom donor by this single mutation disrupts the rate-limiting process in the enzyme catalysis. Moreover, C141A exhibits ~0.4 turnover compared to the > 5 turnovers in the WT SPL reaction. In Y97 and Y99 studies, structural and biochemical data suggest that these two tyrosine residues are also crucial in enzyme catalysis. It is suggested that Y99 in B. subtilis SPL uses a novel hydrogen atom transfer pathway utilizing a pair of cysteinetyrosine residues to regenerate SAM. The second tyrosine, Y97, structurally assists in SAM binding and may also contribute to SAM regeneration by interacting with radical intermediates to lower the energy barrier for the second H-abstraction step.

Lyases -- Research -- Analysis

Adenosylmethionine -- Research

Bacillus subtilis -- Research

DNA repair

DNA damage -- Research

DNA-binding proteins

Bacterial spores

Gram-positive bacteria

Transmethylation

Ultraviolet radiation

Bioorganic chemistry -- Research

Zinc Environment in Proteins: The Flexible and Reactive Core of HIV-1 NCp7 and The Inhibitory Site of Caspase-3

Daniel, A. Gerard

02 December 2013

Zinc is an essential cofactor of several proteins. The roles of zinc in these proteins are classified as catalytic, structural or regulatory. Zinc present in structural sites is considered to be a chemically inert, static structural element. On the contrary, previous studies on a C2H2 type zinc finger model compound and the C3H type HIV-1 NCp7 C-terminal zinc knuckle have shown that zinc at these sites can undergo coordination sphere expansion under the influence of a Pt based electrophile. The pentacoordination observed around zinc in these experiments raises an important question: are the structural zinc motifs found in the proteins susceptible to coordination sphere expansion? Through DFT modeling, the existence and nature of the five coordinate zinc species was investigated. mPW1PW91 was chosen as the DFT method by benchmarking against the experimental parameters of a molecule that closely resembles those to be modeled. The results suggest that the observed coordination sphere expansion is due to the flexible nature of thiolate and chloride ligands that are part of the structure. However, if certain conditions are not met, the same flexibility can lead to the destabilization of these rather fragile structures. Unlike the stable three or four coordinate catalytic and structural zinc sites, at regulatory sites, zinc is typically bound to one or two protein ligands. Zinc inhibition of caspases which are central to the process of apoptosis is one such scenario. Several of the caspases are inhibited by zinc at low micromolar range. Regulation of caspases is a strategy for drug development toward apoptosis related diseases; thus it is important to know the molecular details of zinc inhibition of caspases. Currently, it is speculated that zinc binds to the active site His and Cys residues of caspases thus competing with the substrate. However our studies on caspase-3, using enzyme kinetics and biophysical methods, imply more than one zinc binding sites. Contrary to current beliefs, more than 50% of the inhibition is achieved by zinc without affecting substrate binding. Using DFT models, an alternative inhibitory zinc binding site, which better fits our experimental observations, is predicted.

caspase

DFT

enzyme kinetics

HIV-1 NCp7

caspase inhibition

zinc finger

platinum drug

Chemistry

Physical Sciences and Mathematics

Analysa substrátové specifity a mechanismu GlpG, intramembránové proteasy z rodiny rhomboidů. / Analysis of substrate specificity and mechanism of GlpG, an intramembrane protease of the rhomboid family.

Peclinovská, Lucie

January 2014

Membrane proteins of the rhomboid-family are evolutionarily widely conserved and include rhomboid intramembrane serine proteases and rhomboid-like proteins. The latter have lost their catalytic activity in evolution but retained the ability to bind transmembrane helices. Rhomboid-family proteins play important roles in intercellular signalling, membrane protein quality control and trafficking, mitochondrial dynamics, parasite invasion and wound healing. Their medical potential is steeply increasing, but in contrast to that, their mechanistic and structural understanding lags behind. Rhomboid protease GlpG from E.coli has become the main model rhomboid-family protein and the main model intramembrane protease - it was the first one whose X-ray structure was solved. GlpG cleaves single-pass transmembrane proteins in their transmembrane helix, but how substrates bind to GlpG and how is substrate specificity achieved is still poorly understood. This thesis investigates the importance of the transmembrane helix of the substrate in its recognition by GlpG using mainly enzyme kinetics and site-directed mutagenesis. We find that the transmembrane helix of the substrate contributes significantly to the binding affinity to the enzyme, hence to cleavage efficiency, but it also plays a role in cleavage site...

Inhibitory myší serinracemasy / Inhibitors of mouse serine racemase

Vorlová, Barbora

January 2013

Serine racemase (SR) is a pyridoxal-5'-phosphate-dependent enzyme responsible for biosynthesis of D-serine, a recognized neurotransmitter acting as a co-activator of N-methyl- D-aspartate (NMDA) type of glutamate receptors in the mammalian central nervous system. The hyperfunction of the mentioned receptors have been shown to be implicated in many neuropathological conditions including Alzheimer's disease, amyotrophic lateral sclerosis and epilepsy. To alleviate the symptoms of these diseases, several artificial blockers of NMDA receptors have been introduced into the clinical practice. However, many of these compounds cause undesirable side effects and it is thus necessary to search for either less harmful blockers or regulators of other targets of pharmaceutical intervention that are involved in NMDA receptor activation. In this context, specific inhibition of serine racemase seems to be a promising strategy for regulation of NMDA receptor overstimulation. Mouse serine racemase shares 89% identity with its human ortholog and it was also shown that both enzymes possess similar kinetic parameters and inhibitor specificity. Therefore, the mouse models can be used to search for a potent human serine racemase inhibitor. Although many different compounds for their inhibitory potency towards serine...