Evidence for the N-Acetylglucosaminidase Activity of a Cell Wall-associated Autolysin ISPC and its Suitability as a Diagnostic Marker for 'Listeria Monocytogenes' Serotype 4B

Ronholm, Jennifer

January 2013

Listeria monocytogenes is the etiological agent of a life-threatening, opportunistic infection caused by the ingestion of contaminated foods. Although L. monocytogenes is divided into 13 serotypes, 98% of human illness is caused by serotype 1/2a, 1/2b and 4b strains, with serotype 4b accounting for almost all the major outbreaks of human listeriosis. The principle objective of this work was to develop surface-binding monoclonal antibodies (MAbs) highly specific for serotype 4b, as well as characterize their antigen targets to aid in the detection and isolation of serotype 4b strains using an antibody based procedure. To create such antibodies, mice were immunized with formalin killed whole cells of L. monocytogenes serotype 4b strain LI0521. A total of 15 MAbs reactive to serotype 4b isolates were shown to recognize a ~77 kDa surface antigen subsequently identified by mass spectrometry as surface associated autolysin, IspC. Epitope mapping experiments further revealed that each of the 15 MAbs bound to the cell wall binding GW domain of IspC and can be essentially divided into 4 major groups based on epitope localization. ELISA analysis of the reactivity of each of the MAbs with various L. monocytogenes serotypes indicated that several MAbs were 100% specific for serotype 4b isolates. Surface plasmon resonance experiments showed that the affinity constants for each of these MAbs fell within the range of 1.0 x 10-7 to 6.4 x 10-9 M. To determine whether IspC, shown to be well conserved among various serotype 4b strains, is a useful diagnostic marker with antibody-based methods, the expression of IspC was assessed in L. monocytogenes cultured under normal and stress conditions. A functional promoter directing the transcription of ispC gene was identified immediately upstream of the ispC open reading frame by constructing the promoterless lacZ gene fusion with the putative ispC promoter region and by 5'RACE analysis. Data obtained with the lacZ reporter gene system and immunofluorescent microscopy revealed that IspC is expressed on the cell surface under all growth conditions tested (temperature, osmotic stress, pH, ethanol, oxidative stress, anaerobic conditions, carbon source and enrichment media) that allow for cellular division, although the level of ispC gene expression varies. In addition, a significant effort were put into elucidating the hydrolytic bond specificity of IspC by HPLC and mass spectrometry analysis of muropeptides released from IspC-mediated hydrolysis of L. monocytogenes peptidoglycan (PG). The results demonstrated that IspC functions as an N-acetylglucosaminidase capable of cleaving the β-1,4-glycosidic bond of the PG glycan strand. Furthermore, IspC was more efficient at hydrolysing fully Nacetylated PG from a PG deacetylase gene (pgdA) deletion mutant of L. monocytogenes than partially de-N-acetylated wild-type PG, indicating that modification of PG by de-Nacetylation of GlcNAc residues renders PG resistant to IspC hydrolysis. In conclusion, the surface autolysin IspC with the N-acetylglucosaminidase activity is a novel diagnostic marker for the 4b serotype strains, which can be explored , in conjunction with specific MAbs developed here, for detection and isolation of L. monocytogenes serotype 4b strains directly from food, environmental and clinical samples with the need for minimal or no culture enrichment.

listeria

peptidoglycan hydrolase

food safety

antibody

Alterations in Fatty Acid Amide Hydrolase (Faah) Transcript Levels and Activity Lead to Changes in the Abiotic Stress Susceptibility of Arabidopsis Thaliana

Gonzalez, Gabriel

05 1900

N-Acylethanolamines (NAEs) are a class of bioactive lipids, and FAAH is one of the enzymes responsible for degrading NAEs in both plants and animals. in plants, FAAH appears to be closely associated with ABA, a phytohormone which has long been associated with plant stress responses, since the overexpression of FAAH in Arabidopsis results in ABA hypersensitivity. Therefore, it is reasonable to speculate that alterations in FAAH transcript levels will result in altered stress responses in plants. to investigate this hypothesis experiments were carried out in which wild type (WT), FAAH-overexpressing (OE), and T-DNA insertional FAAH knockouts of Arabidopsis (faah) were grown in MS media under stress conditions. the stress conditions tested included chilling stress, heavy metal stress induced by cadmium or copper, nutrient limitations induced by low phosphorus or low nitrogen, salt stress induced with NaCl, and osmotic stress induced with mannitol. the OE plants were consistently hypersensitive to all stress conditions in relation to wild type plants. Inactive FAAH overexpressors did not have the hypersensitivity to the salt and osmotic stress of the active OE plants and were instead tolerant to these stresses. FAAH2 (faah2) knockouts and FAAH 1 and 2 double knockouts (faah 1+2) were based on some root development parameters somewhat more tolerant than WT plants, but more sensitive in terms of shoot growth. Collectively the data suggests that FAAH activity may interact with stress-responsive pathways in plants, perhaps including pathways involving ABA.

Abiotic stress

fatty acid amide hydrolase

Arabidopsis

Functional Characterization of Serine Hydrolases Mediating Lipid Metabolism and Protein Depalmitoylation in Asexual Stage Plasmodium Falciparum

Liu, Jiapeng

05 June 2023

Malaria is an infectious disease caused by Plasmodium parasites and transferred by Anopheles mosquitos. Due to Artemisinin resistance, new druggable targets identification and new drug development are urgently needed. Serine hydrolases (SHs) are one of the largest classes of enzymes having important roles in life processes. The deadliest malaria parasite, P. falciparum, encodes more than 50 SHs including proteases, lipases, esterase and others, while only several of them have been characterized. The study of uncharacterized SHs will shed light on future drug development to treat malaria. In this study, we applied chemical biology and genetic approaches to identify SHs important for the pathogenic asexual stage growth of P. falciparum parasites. We mainly focused on a depalmitoylase essential for merozoite invasion and lysophospholipases (LPLs) essential for acquiring fatty acids (FAs) from the host. Identifying essential metabolic enzymes will benefit the treatment to malaria. We focused on metabolic SHs and identified two SHs were refractory to knock out. We studied a likely essential SH named PfABHD17A, which is a human depalmitoylase homolog. PfABHD17A is localized on the rhoptry, an organelle essential for invasion. We expressed the recombinant PfABHD17A, conducted inhibitor screen and discovered that human depalmitoylase inhibitor ML211 inhibits PfABHD17A in vitro. ML211 inhibits merozoite invasion but not egress, which together with the localization of PfABHD17A on the rhoptries, suggested that PfABHD17A is essential in merozoite invasion. We also purified PfABHD17A and verified that PfABHD17A may exhibit depalmitoylase activity in vitro. LPLs are important for asexual stage parasites acquiring FAs from the host. The P. falciparum genome includes 17 putative LPLs while LPLs responsible for hydrolyzing FA from lysophosphatidylcholine (LPC) in the asexual stage are currently unknown. Using a chemical biology approach, we identified serine hydrolase inhibitor AKU-010 inhibits LPC hydrolysis effectively. Using activity-based protein profiling (ABPP) and genetic approaches, we identified that AKU-010 inhibits a series of SHs including Exported Lipases (XLs), Exported Lipases Homolog (XLH) and Plasmodium falciparum prodrug activation and resistance esterase (PfPARE). We generated a series of knockout parasite lines on the AKU-010 targets and identified that red blood cell (RBC)-localized XL2 and cytosolic XLH4 contribute to most LPC hydrolysis activity in the asexual stage. XLs and XLHs are important for parasites using LPC for growth and contribute to detoxification from accumulated LPC. XL2 and XL4 together are essential for parasite growth under high LPC concentration medium, such as human serum. XL/XLH-deficient parasites could still acquire FA from LPC, which is mainly contributed by parasite membrane- localized PfPARE. PfPARE has little impact on parasite growth and LPC metabolism with the existence of XLs and XLHs but is important after the loss of XLs and XLHs. Parasites deficient in PfPARE, XLs and XLHs have little ability to release FA from LPC and cannot use LPC as FAs source for growth. In summary, we identified metabolic SHs mediating protein depalmitoylation and lipid metabolism and in asexual stage Plasmodium falciparum, which may benefit future drug development to treat malaria. / Doctor of Philosophy / Malaria is an infectious disease caused by Plasmodium parasites and transferred by mosquitos. New druggable target identification and drug development are urgently needed to deal with the malaria issue. We focused on an understudied enzyme superfamily termed serine hydrolase (SHs), which includes more than 50 members in the deadliest malaria parasite, P. falciparum. We identified that several druggable enzymes, which can mediate protein depalmitoylation and lipid metabolism, are important for parasite growth in the pathogenic stage. Identifying essential metabolic enzymes will benefit the treatment to malaria. We screened eleven SHs and discovered that two of them are likely essential in the pathogenic stage. We focused on one human depalmitoylase homolog termed PfABHD17A. We screened the inhibitors on PfABHD17A and used the inhibitor to suggest that PfABHD17A is essential for the growth of pathogenic stage parasites. We also identified lipases important for acquiring fatty acids (FAs) from the host. Using chemical biology and genetic approaches, we discovered that three lipases are important for acquiring FAs form the host in the pathogenic stage. Inhibiting these enzymes may kill the parasite in the host.

Plasmodium falciparum

malaria

serine hydrolase

depalmitoylase

lysophospholipases

Developmental Regulation of the Expression of Nutrient Transporter and BrushBorder Membrane Hydrolase Genes in the Small Intestine of Piglets

Xiao, Xunjun

08 February 2006

The objective of this study was to evaluate developmental regulation of the expression of nutrient transporter and brushborder hydrolase genes in the small intestine of piglets. Seventy piglets from seven sows were killed at birth (d 0), during suckling (d 1, 3, 7, 14, 21) and postweaning (d 22, 24, 28, 35), and intestinal segments (duodenum, jejunum and ileum) were collected. The mRNA abundance was determined by Northern blot using specific cDNA probes for three disaccharidases (lactase-phlorizin hydrolase, LPH, sucrase-isomaltase, SI, and maltase-glucoamylase, MGA), three peptide hydrolases (aminopeptidase A, APA, aminopeptidase N, APN, and dipeptidyl peptidase IV, DPP IV), two sugar transporters (Na+-dependent glucose transporter 1, SGLT1, and facilitated glucose transporter 5, GLUT5), a peptide transporter (H+-dependent peptide transporter 1, PepT1), four amino acid transporters (excitatory amino acid carrier 1, EAAC1, Na+-dependent neutral amino acid transporter, ATB0, the light chain of a heterodimeric transport system b0,+ involved in the heteroexchange of cationic and neutral amino acids, b0,+AT, and Na+-independent large branched and aromatic neutral amino acid transporter 2, LAT2), and two iron transporters (divalent metal ion transporter 1, DMT1, and iron-regulated transporter 1, IREG1). Protein expression was quantified by Western blot using specific antibodies for LPH, SI, SGLT1, and PepT1. During suckling, the abundance of LPH, APA, APN, DPP IV, b0,+AT mRNA increased quadratically (P < 0.001) with age from birth to d 7 or 14 then remained unchanged or slightly declined with age to d 21. The mRNA abundance of SI increased and LAT2 decreased linearly (P < 0.001) with age, and the abundance of MGA and GLUT5 mRNA remained unchanged with age. There was an age x intestinal segment interaction (P < 0.001) for the abundance of EAAC1 and ATB0 mRNA. The abundance of EAAC1 mRNA increased from d 0 through 14 and remained stable to d 21 in the ileum, and it was low and slightly increased with age through d 21 in the duodenum and jejunum. The abundance of ATB0 mRNA generally increased from d 0 to 21 in the duodenum and ileum, and increased from d 0 to 7 and then decreased to d 21 in the jejunum. The abundance of SGLT1 and PepT1 mRNA was substantial at birth and transiently declined to d 1. The abundance of SGLT1 mRNA generally increased from d 1 to 21, and PepT1 mRNA abundance increased to d 3 and then plateaued through d 21. Postweaning, the mRNA abundance of all of these carbohydrate and protein assimilation related genes increased during the first day (3 d for ATB0) after weaning then declined to the levels at weaning in the jejunum and ileum, followed by a subsequent change pattern that varied among genes. During suckling, the mRNA abundance of LPH, SGLT1, and APA was greater in the duodenum and jejunum than the ileum (P < 0.001). The PepT1 and APN mRNA was evenly distributed among intestinal segments, and the expression of MGA, DPP IV, EAAC1, b0,+AT, ATB0, and LAT2 mRNA was generally greater in the jejunum and ileum than the duodenum or greatest in the ileum. Postweaning, the mRNA abundance of all of these carbohydrate and protein assimilation related genes examined was generally greater in the jejunum and ileum than the duodenum or highest in the ileum. From d 0 through 35, DMT1 and IREG1 mRNA was predominantly (P < 0.05) distributed in the duodenum, where the abundance of DMT1 and IREG1 mRNA increased with age during suckling, and then rapidly decreased after weaning. The protein expression of LPH and SI exhibited a similar developmental pattern as that for the mRNA abundance. Unlike the developmental regulation of their respective mRNA abundance, the protein expression of SGLT1 exhibited a general decline from suckling to postweaning. The protein expression of PepT1 gradually decreased with age from birth to d 35 in the duodenum, and initially declined from birth to the lowest value then slightly increased with age through d 21, followed by an increase to d 35 in the jejunum and ileum. In conclusion, the gene expression of these brushborder hydrolases and nutrient transporters was not only differentially regulated by age but also differentially distributed along the small intestine of piglets at early stages of life. These differences in ontogenetic regulation and the distribution may be related to the luminal substrate concentration as well as the nutrient categories, and the developmental regulation of these genes may occur not only at the transcriptional level but also at the posttranscriptional level. / Ph. D.

small intestine

pig

developmental regulation

hydrolase

transporter

Nouvelles enzymes pour l'amélioration de l'hydrolyse des lignocelluloses : identification, étude structure-fonction et ingénierie de deux mannanases fongiques

Couturier, Marie

07 December 2012

Les procédés de bioraffinerie, et notamment les agrocarburants, sont aujourd'hui reconnus comme essentiels pour sortir de l'économie actuelle basée sur le pétrole. Dans le cas du bioéthanol produit à partir de biomasse lignocellulosique, l'hydrolyse enzymatique par les enzymes de Trichoderma reesei est le principal point faible du procédé et doit être améliorée. Ces travaux de thèse s'intègrent dans le cadre du projet Futurol, et ont pour objectif d'identifier de nouvelles enzymes capables d'améliorer l'activité de T. reesei sur la lignocellulose. Une analyse post-génomique réalisée sur les secrétomes de vingt souches fongiques s'est révélée particulièrement prometteuse pour l'identification d'enzymes lignocellulolytiques d'intérêt. Une approche de génomique comparative a également abouti à la sélection de deux endo-mannanases de famille GH5 et GH26 chez le champignon Podospora anserina. Ces hémicellulases ont permis d'améliorer significativement la libération de glucose par T. reesei à partir d'épicéa. Une étude fondamentale approfondie a permis de résoudre les structures cristallographiques et de mettre en évidence les relations entre les spécificités enzymatiques de chaque enzyme et leurs caractéristiques structurales. La structure tridimensionnelle de la mannanase GH26 couplée à son CBM35 présente un linker court et rigide et une organisation du site actif atypique. Les deux mannanases ont également fait l'objet d'un travail d'ingénierie aléatoire qui a abouti à des variants des deux enzymes présentant une amélioration de l'efficacité catalytique et/ou une modification de spécificité. / Biorefineries such as biofuels are nowadays considered as essential to reduce our dependence on oil products. In the production process of bioethanol from lignocellulosic biomass, enzymatic hydrolysis performed by Trichoderma reesei enzymes is the main bottleneck of the process and requires improvements.The present work is part of the Futurol project, and aims at identifying new enzymes to improve the activity of T. reesei toward lignocellulose. Post-genomic analyses on twenty fungal strains have revealed the potential of this approach to identify lignocellulolytic enzymes of interest. Comparative genomics also led to the selection of two endo-mannanases from families GH5 and GH26 from the fungus Podospora anserina. These hemicellulases significantly improved glucose release upon T. reesei hydrolysis of spruce. An in-depth fondamental study allowed the solving of cristallographic structures and revealed the relationships between enzymatic specificities and structural characteristics. The structure of GH26 catalytic module appended to CBM35 highlighted a short and rigid linker and an atypical active site organization. The two mannanases were subjected to molecular engineering. Variants displaying improved catalytic efficiency and/or modified specificity were identified for both enzymes.

Bioéthanol

Glycosyl hydrolase

Mannanase

Ingénierie moléculaire

Champignons filamenteux

Bioethanol

Glycoside hydrolase

Mannanase

Molecular engineering

Filamentous fungi

Biochemische und mechanistische Charakterisierung von Enzymen der Glycosidhydrolase-Familie 4 / Biochemical and mechanical characterization of glycosid-hydrolase-family 4 enzymes

Hoffmann, Volker

27 April 2005

No description available.

570 Biowissenschaften

Biologie

Agricultural Sciences

Reaktionsmechanismus

thermophil

Hydrolase

reactionmechanism

thermophilic

hydrolase

42.30

42.20

WJ

WU

Caractérisation structurale de la régulation de l'ubiquitine-hydrolase AMSH / Structural basis for AMSH ubiquitine hydrolase regulation

Poudevigne, Emilie

24 September 2013

La voie endo-lysosomale dirige les récepteurs membranaires vers le processus de dégradation lysosomale. En bref, les récepteurs sont marqués par l'ubiquitine, envoyés vers les endosomes précoces puis, pris en charge pas le système ESCRT (Endosomal Sorting Complexes Required for Transport) et intégrés dans des vésicules intraluminales. Ce système est composé des complexes ESCRT-0, I, II, II et VPS4. Certaines protéines ESCRT sont aussi recrutées lors de processus topologiquement similaires comme la cytokinèse ou le bourgeonnment viral de certains virus enveloppés. AMSH (Associated Molecule of the SH3 domain of STAM) est une ubiquitine-hydrolase associée au système ESCRT qui hydrolyse les chaînes d'ubiquitine liées par leur lysine K63. Elle interagit directement avec ESCRT-0 via la sous-unité STAM et avec les membres CHMP1A, 1B et 3 d'ESCRT-III. Bien qu'AMSH pourait recruter ces protéines ESCRT ou être elle-même recrutée par celles-ci, le mécanisme d'activation de son activité d'hydrolase est encore méconnu. Afin de mieux comprendre les bases structurales de l'activation d'AMSH, j'ai essayé danalyser des formes recombinantes de cette protéine par cristallographie aux rayons X et par diffusion des rayons X aux petits angles (SAXS) ce qui m'a permis d'obtenir deux modèles à basse résolution. De plus, j'ai caractérisé par SPR (Surface Plasmon Resonance) les interactions entre AMSH et CHMP1A, 1B et 3 et déterminé les résidus clefs du dernier complexe. Cela a montré que les surfaces d'interaction employées par le domaine MIT d'AMSH ne sont pas les mêmes pour CHMP3 et CHMP1A/1B. J'ai aussi découvert que l'activité enzymatique d'AMSH seule est très faible ce qui impliquerait une auto-inhibition en solution. L'hydrolyse des chaînes d'ubiquitine liées par leur lysine K63 pourrait alors être activée par une construction de STAM comprenant le domaine SH3 ainsi que les domaines liant l'ubiquitine VHS et/ou UIM. / The endosomal pathway targets plasma membrane receptors for lysosomal degradation. Briefly, receptors are tagged by an ubiquitin, delivered to the early endosome and sorted into intraluminal vesicles by the ESCRT (Endosomal Sorting Complexes Required for Transport) machinery, composed of ESCRT-0, -I, -II- -III and the VPS4 complex. Some ESCRts are also recruited during topologically similar processes such as cytokinesis and budding of some enveloped viruses. AMSH (Associated Molecule of the SH3 domain of STAM) is an ESCRT associated ubiquitin-hydrolase which hydrolyses K63-linked ubiquitin chains. AMSH interacts directly with the ESCRT-0 subunit STAM and ESCRT-III members CHMP1A, CHMP1B and CHMP3. Although AMSH may either recruit these ESCRTs are maybe recruited by these ESCRTs, little is known about the activation mechanism of its hydrolase activity. In order to understand the structural basis for AMSH activation I attempted to analyze recombinant forms of AMSH by X-ray crystallography and SAXS, which produced low resolution models of AMSH. I further characterized AMSH interactions with CHMP1A, CHMP1B and CHMP3 by SPR and determined the key residues for interaction. This showed that the AMSH MIT domain employs two different surfaces for CHMP3 and CHMP1A/B interactions. I also found that recombinant AMSH has very poor enzymatic activity on its own, which indicates an auto-inhibited state in solution. K63-linked uibiquitin hydrolysis could be activated by STAM constructs containing the SH3 and ubiquitin binding domains (UIM and/or VHS), which were shown to interact directly with AMSH via SPR. Thus activation of the hydrolase activity by STAM corroborates indirectly the autoinhibited native state.

Cristallographie

Bourgeonnement viral

Ubiquitine hydrolase

Système ESCRT

Ubiquitine hydrolase

Cristallography

Viral budding

Escrt machinary

Formation des acides gras poly-hydroxylés et incorporation dans la cutine chez Arabidopsis thaliana / Formation of poly-hydroxylated fatty acids and incorporation Arabidopsis thaliana’s cutin

Pineau, Emmanuelle

20 September 2017

Les plantes sont des organismes sessiles qui ne peuvent fuir des conditions souvent défavorables et doivent par conséquent s’adapter à un environnement hostile pour survivre. La cutine partie intégrante de la cuticule qui joue un rôle de barrière pour la plante est un polymère lipidique constitué principalement d’acides gras en C16 et C18 hydroxylés et époxydés reliés entre eux par des liaisons ester mettant en jeu les fonctions carboxyl et ω-hydroxyl des acides gras. La cutine ne joue pas seulement un rôle de barrière physique mais joue un rôle de réservoir de molécules possédant des propriétés physiologiques fondamentales. Grâce à des approches biochimiques et génétiques, nos travaux ont permis de mettre en évidence AtEH1, une époxyde hydrolase responsable de la formation des diols incorporés dans la cutine d’Arabidopsis thaliana. Ces diols sont décrits dans la littérature comme intervenant dans les interactions plante-pathogène. Nous avons également montré que ces composés ainsi que d’autres dérivés d’acides gras sont perçus par la plante. Nous avons identifié et caractérisé CYP77B1, une époxygénase d’acide gras qui a un rôle potentiel à jouer dans la formation d’acides gras polyhydroxylés incorporés dans la cutine. / Plants are sessile organisms that are not able to escape from difficult environmental conditions and therefore have to adapt to multiple abiotic and biotic stress to survive. Cutin is a part of the cuticle which plays a major role as a barrier for the plant. It’s a lipid polymer composed mainly by hydroxylated and epoxidized C16 and C18 fatty acids linked together by ester links involving the carboxyl and ω-hydroxyl functions of those fatty acids. Cutin plays also a role as a reservoir of molecules with fundamental physiological properties. With biochemical and genetic approaches, we characterized AtEH1, an epoxide hydrolase responsible for the formation of diols incorporated in Arabidopsis thaliana cutin. These diols are described as being involved in plant-pathogen interactions. We also showed that these compounds as well as others fatty acids derivatives are perceived by plants. We have also identified and characterized CYP77B1, an epoxidase that has a potential role in the formation of polyhydroxylated fatty acids incorporated in cutin.

Cutine

Epoxyde hydrolase

Acides gras

Cytochromes P450s

Cutin

Epoxyde hydrolase

Fatty acids

Cytochrome P450s

572.8

581

Studies on Structures and Functions of Vitamin B[6] Degrading Enzymes / ビタミンB[6]分解酵素群の構造と機能に関する研究

Kobayashi, Jun

24 September 2014

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第18599号 / 農博第2086号 / 新制||農||1027(附属図書館) / 学位論文||H26||N4874(農学部図書室) / 31499 / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 三上 文三, 教授 植田 充美, 教授 栗原 達夫 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

Vitamin B6 degradation pathway

Crystal structure

Zn-dependent hydrolase

Flavoenzyme

a/b hydrolase

610

Proteome-wide Functional Profiling of Serine Hydrolases in the Human Malaria Parasite

Elahi, AEM Rubayet

14 June 2019

The serine hydrolase (SH) enzyme superfamily is one of the largest and most diverse enzyme classes in eukaryotes and prokaryotes. The most virulent human malaria parasite Plasmodium falciparum has over 40 predicted serine hydrolases (SH). Prior investigation on a few of these have suggested their critical role in parasite biology. The majority of the SHs in P. falciparum have not been functionally characterized. Investigation of these uncharacterized SHs will provide new insights into essential features of parasite metabolism and possibly lead to new antimalarial targets. In this study, we have employed activity-based protein profiling (ABPP) and liquid chromatography-tandem mass spectrometry (LC-MS/MS) to functionally characterize SHs. In our effort to profile plasmodial SHs using ABPP, we have identified a human erythrocyte SH, acylpeptide hydrolase (APEH) in the developing parasites. This finding is the first report of internalization of host hydrolytic enzyme by the parasite. Treatment of parasites with an APEH specific triazole urea inhibitor, AA74-1, caused growth inhibition in parasites with poor potency in the first replication cycle, however, the potency dramatically increased in the second cycle. We show that this unique growth inhibition profile is due to the inability of AA74-1 to inhibit parasite-internalized APEH in vivo. These findings suggest that internalization of active APEH by the parasite is essential for parasite survival. Lipases catalyze the hydrolysis of ester bonds of lipid species such as neutral lipids and phospholipids. Although roles of lipases in propagation, as well as virulence in various organisms, have been acknowledged, in P. falciparum lipases remain understudied. We combined LC-MS/MS with the SH-directed ABPP to identify lipases of SH superfamily in P. falciparum. We have identified 16 plasmodial SHs with putative lipase activity. Bioinformatics analysis of our identified lipases is consistent with our findings. We have screened a panel of various classes of SH inhibitors in a competitive ABPP. A plasmodial putative lipase was potently and specifically inhibited by human monoacylglycerol lipase inhibitor. This inhibition profile suggests it as a monoacylglycerol lipase which plays a role in releasing fatty acids from neutral lipid. This finding shows that how inhibitor screening can aid in building hypotheses on biological roles of an enzyme. Altogether, in this dissertation, we have presented a robust strategy of identifying and functionally characterizing SHs in P. falciparum, which opens the door to the discovery of new biological processes. / Doctor of Philosophy / Malaria contributed to nearly a half a million deaths in 2017. The vast majority of malaria-related deaths are due to the parasite Plasmodium falciparum. This parasite resides inside human red blood cells (erythrocytes) and grows rapidly during a 48 hour cycle. There are over 40 serine hydrolase (SH) superfamily proteins in the parasite. Biological functions of the majority of SHs in the parasite remains unknown. Study on these SHs will provide new insights into parasite biology, and possibly present new antimalarial drug targets. We used chemical biology techniques to identify and functionally characterize parasite SHs. In one study, we show the parasite intenalized a human erythrocyte SH, acylpeptide hydrolase (APEH). We used an APEH-specific inhibitor to investigate the biological significance of internalized APEH in parasite biology. Treatment of the parasite with the inhibitor resulted in parasite growth inhibition suggesting internalization of APEH is essential for parasite survival. Lipases are enzymes that aid in break down of lipids and have shown to be crucial for growth and pathogenicity in various organisms. Lipases and lipid catabolism remain understudied in the malaria parasite. We used mass spectrometry in our approach to identify 16 lipases in asexual parasites. We have also shown that screening with highly specific inhibitors can help in predicting biological function of a particular enzyme. In summary, in this body of work, we have presented an approach of studying SHs in the malaria parasite, which will provide new insights into parasite biology.

Plasmodium falciparum

malaria

serine hydrolase

lipase

acylpeptide hydrolase

activity-based protein profiling