ABSTRACT
Ghrelin O-acyltransferase (GOAT) is an integral membrane acyltransferase responsible for catalyzing a serine-octanoylation posttranslational modification within the peptide hormone ghrelin. Ghrelin requires this octanoylation for its biological activity in stimulating appetite and in regulating other physiological pathways involved in energy balance. Blocking ghrelin acylation using GOAT inhibitors is a new potential avenue to treat health conditions impacted by ghrelin signaling, such as obesity and diabetes. Designing novel and potent GOAT inhibitors as potential therapeutics requires insight into the interactions between the ghrelin and octanoyl coenzyme A substrates and the GOAT active site. Through structure-activity investigation of ghrelin-mimetic peptide substrates and inhibitors, we have analyzed the amino acid selectivity of the enzyme as well as the functional groups involved in substrate recognition by human GOAT (hGOAT). This analysis reveals that hGOAT both prefers and tolerates a distinct set of chemical properties at each position within the N-terminal sequence of ghrelin and that sequence elements downstream of the ghrelin N-terminal sequence contribute to ghrelin binding to hGOAT. We also found that the hGOAT active site exhibits a marked preference for binding an eight-carbon acyl chain, which potentially explains the biological observation of ghrelin octanoylation in light of the acyl donor promiscuity reported for GOAT. Bioinformatics analysis, guided by our reactivity data, supports the conclusion that ghrelin is a unique substrate for hGOAT within the human proteome, providing further justification for the ghrelin-hGOAT system as a desirable drug target. By defining an array of substrate-enzyme interactions used by hGOAT to bind, recognize, and acylate ghrelin, this study yields novel insight into the character of the hGOAT active site that can serve as a guide toward the rational design of hGOAT inhibitors.
Subject(s)
Acyltransferases/chemistry , Acyltransferases/metabolism , Ghrelin/chemistry , Ghrelin/metabolism , Acylation/physiology , Acyltransferases/genetics , Amino Acid Sequence , Animals , Cell Line , Ghrelin/genetics , Humans , Insecta , Molecular Sequence Data , Protein Binding/physiology , Structure-Activity RelationshipABSTRACT
Inhibitors of ghrelin O-acyltransferase (GOAT) have untapped potential as therapeutics targeting obesity and diabetes. We report the first examples of GOAT inhibitors incorporating a triazole linkage as a biostable isosteric replacement for the ester bond in ghrelin and amide bonds in previously reported GOAT inhibitors. These triazole-containing inhibitors exhibit sub-micromolar inhibition of the human isoform of GOAT (hGOAT), and provide a foundation for rapid future chemical diversification and optimization of hGOAT inhibitors.
Subject(s)
Acyltransferases/antagonists & inhibitors , Enzyme Inhibitors/chemistry , Triazoles/chemistry , Acyltransferases/metabolism , Enzyme Inhibitors/chemical synthesis , Enzyme Inhibitors/metabolism , Humans , Protein Binding , Protein Isoforms/antagonists & inhibitors , Protein Isoforms/metabolism , Structure-Activity Relationship , Triazoles/chemical synthesis , Triazoles/metabolismABSTRACT
Ghrelin is a peptide hormone involved in regulation of appetite, glucose homeostasis, and a range of other physiological processes. Ghrelin requires a unique posttranslational modification, octanoylation of a serine side chain, to bind its cognate receptor to activate signaling. The enzyme that catalyzes this modification, ghrelin O-acyltransferase (GOAT), is receiving increased interest as a potential drug target for the treatment of obesity, diabetes, and other diseases proposed to be linked to ghrelin signaling. In this study, we report the development of a novel fluorescence-based assay for GOAT activity and the use of this assay to investigate GOAT inhibition and interactions underlying human GOAT (hGOAT) substrate selectivity. Using a series of mutations and chemical modifications of our fluorescent peptide substrate, we have identified specific groups on the first two amino acids of ghrelin that potentially contribute to ghrelin recognition by hGOAT. These data provide the first molecular-level information regarding interactions within the ghrelin-hGOAT complex. Defining the interactions used by hGOAT to bind and recognize ghrelin will provide insight into the structure of the hGOAT active site, aid in the design and optimization of targeted hGOAT inhibitors, and help to assess the possibility of novel hGOAT substrates beyond ghrelin.
Subject(s)
Acyltransferases/metabolism , Enzyme Assays/methods , Fluorescent Dyes/metabolism , Ghrelin/metabolism , Peptidomimetics/metabolism , Acylation , Acyltransferases/antagonists & inhibitors , Amino Acid Sequence , Enzyme Inhibitors/pharmacology , Fluorescent Dyes/chemistry , Ghrelin/chemistry , Glycine/metabolism , Humans , Molecular Sequence Data , Peptidomimetics/chemistry , Protein Binding , Serine/chemistry , Serine/metabolism , Structure-Activity Relationship , Substrate SpecificityABSTRACT
Malaria parasites use the RhopH complex for erythrocyte invasion and channel-mediated nutrient uptake. As the member proteins are unique to Plasmodium spp., how they interact and traffic through subcellular sites to serve these essential functions is unknown. We show that RhopH is synthesized as a soluble complex of CLAG3, RhopH2, and RhopH3 with 1:1:1 stoichiometry. After transfer to a new host cell, the complex crosses a vacuolar membrane surrounding the intracellular parasite and becomes integral to the erythrocyte membrane through a PTEX translocon-dependent process. We present a 2.9 Å single-particle cryo-electron microscopy structure of the trafficking complex, revealing that CLAG3 interacts with the other subunits over large surface areas. This soluble complex is tightly assembled with extensive disulfide bonding and predicted transmembrane helices shielded. We propose a large protein complex stabilized for trafficking but poised for host membrane insertion through large-scale rearrangements, paralleling smaller two-state pore-forming proteins in other organisms.
Malaria is an infectious disease caused by the family of Plasmodium parasites, which pass between mosquitoes and animals to complete their life cycle. With one bite, mosquitoes can deposit up to one hundred malaria parasites into the human skin, from where they enter the bloodstream. After increasing their numbers in liver cells, the parasites hijack, invade and remodel red blood cells to create a safe space to grow and mature. This includes inserting holes in the membrane of red blood cells to take up nutrients from the bloodstream. A complex of three tightly bound RhopH proteins plays an important role in these processes. These proteins are unique to malaria parasites, and so far, it has been unclear how they collaborate to perform these specialist roles. Here, Schureck et al. have purified the RhopH complex from Plasmodium-infected human blood to determine its structure and reveal how it moves within an infected red blood cell. Using cryo-electron microscopy to visualise the assembly in fine detail, Schureck et al. showed that the three proteins bind tightly to each other over large areas using multiple anchor points. As the three proteins are produced, they assemble into a complex that remains dissolved and free of parasite membranes until the proteins have been delivered to their target red blood cells. Some hours after delivery, specific sections of the RhopH complex are inserted into the red blood cell membrane to produce pores that allow them to take up nutrients and to grow. The study of Schureck et al. provides important new insights into how the RhopH complex serves multiple roles during Plasmodium infection of human red blood cells. The findings provide a framework for the development of effective antimalarial treatments that target RhopH proteins to block red blood cell invasion and nutrient uptake.
Subject(s)
Erythrocytes/parasitology , Genes, Protozoan/physiology , Plasmodium falciparum/physiology , Multigene Family/physiology , Nutrients/metabolism , Plasmodium falciparum/geneticsABSTRACT
We report the determination of the structure of Escherichia coli ß-galactosidase at a resolution of â¼1.8â Å using data collected on a 200â kV CRYO ARM microscope equipped with a K3 direct electron detector. The data were collected in a single 24â h session by recording images from an array of 7 × 7 holes at each stage position using the automated data collection program SerialEM. In addition to the expected features such as holes in the densities of aromatic residues, the map also shows density bumps corresponding to the locations of hydrogen atoms. The hydrogen densities are useful in assigning absolute orientations for residues such as glutamine or asparagine by removing the uncertainty in the fitting of the amide groups, and are likely to be especially relevant in the context of structure-guided drug design. These findings validate the use of electron microscopes operating at 200â kV for imaging protein complexes at atomic resolution using cryo-EM.
ABSTRACT
Malaria is a devastating disease caused by a protozoan parasite. It affects over 300 million individuals and results in over 400â 000 deaths annually, most of whom are young children under the age of five. Hexokinase, the first enzyme in glucose metabolism, plays an important role in the infection process and represents a promising target for therapeutic intervention. Here, cryo-EM structures of two conformational states of Plasmodium vivax hexokinase (PvHK) are reported at resolutions of â¼3â Å. It is shown that unlike other known hexokinase structures, PvHK displays a unique tetrameric organization (â¼220â kDa) that can exist in either open or closed quaternary conformational states. Despite the resemblance of the active site of PvHK to its mammalian counterparts, this tetrameric organization is distinct from that of human hexokinases, providing a foundation for the structure-guided design of parasite-selective antimalarial drugs.
ABSTRACT
Ghrelin is a circulating peptide hormone involved in regulation of a wide array of physiological processes. As an endogenous ligand for growth hormone secretagogue receptor (GHSR1a), ghrelin is responsible for signaling involved in energy homeostasis, including appetite stimulation, glucose metabolism, insulin signaling, and adiposity. Ghrelin has also been implicated in modulation of several neurological processes. Dysregulation of ghrelin signaling is implicated in diseases related to these pathways, including obesity, type II diabetes, and regulation of appetite and body weight in patients with Prader-Willi syndrome. Multiple steps in the ghrelin signaling pathway are available for targeting in the development of therapeutics for these diseases. Agonists and antagonists of GHS-R1a have been widely studied and have shown varying levels of effectiveness within ghrelin-related physiological pathways. Agents targeting ghrelin directly, either through depletion of ghrelin levels in circulation or inhibitors of ghrelin O-acyltransferase whose action is required for ghrelin to become biologically active, are receiving increasing attention as potential therapeutic options. We discuss the approaches utilized to target ghrelin signaling and highlight the current challenges toward developing small-molecule agents as potential therapeutics for ghrelin-related diseases.
Subject(s)
Diabetes Mellitus, Type 2/drug therapy , Ghrelin/metabolism , Obesity/drug therapy , Prader-Willi Syndrome/drug therapy , Signal Transduction/drug effects , Small Molecule Libraries/chemistry , Small Molecule Libraries/therapeutic use , Amino Acid Sequence , Animals , Appetite Regulation/drug effects , Diabetes Mellitus, Type 2/metabolism , Drug Discovery , Ghrelin/chemistry , Humans , Molecular Sequence Data , Molecular Targeted Therapy , Obesity/metabolism , Prader-Willi Syndrome/metabolism , Receptors, Ghrelin/metabolism , Small Molecule Libraries/pharmacologyABSTRACT
Ghrelin is a peptide hormone involved in multiple physiological processes related to energy homeostasis. This hormone features a unique posttranslational serine octanoylation modification catalyzed by the enzyme ghrelin O-acyltransferase, with serine octanoylation essential for ghrelin to bind and activate its cognate receptor. Ghrelin deacylation rapidly occurs in circulation, with both ghrelin and desacyl ghrelin playing important roles in biological signaling. Understanding the regulation and physiological impact of ghrelin signaling requires the ability to rapidly protect ghrelin from deacylation in biological samples such as blood serum or cell lysates to preserve the relative concentrations of ghrelin and desacyl ghrelin. In in vitro ghrelin O-acyltransferase activity assays using insect microsomal protein fractions and mammalian cell lysate and blood serum, we demonstrate that alkyl fluorophosphonate treatment provides rapid, complete, and long-lasting protection of ghrelin acylation against serine ester hydrolysis without interference in enzyme assay or ELISA analysis. Our results support alkyl fluorophosphonate treatment as a general tool for stabilizing ghrelin and improving measurement of ghrelin and desacyl ghrelin concentrations in biochemical and clinical investigations and suggest current estimates for active ghrelin concentration and the ghrelin to desacyl ghrelin ratio in circulation may underestimate in vivo conditions.
Subject(s)
Fluorides/pharmacology , Ghrelin/metabolism , Phosphates/pharmacology , Acylation/drug effects , Acyltransferases/metabolism , Animals , Ghrelin/blood , Ghrelin/chemistry , HEK293 Cells , Humans , Male , Protein Stability/drug effects , Rats , Rats, Wistar , Serine/metabolismABSTRACT
Ghrelin is a 28 amino acid hormonal peptide that is intimately related to the regulation of food intake and body weight. Once secreted, ghrelin binds to the growth hormone secretagogue receptor-1a, the only known receptor for ghrelin and is capable of activating a number of signaling cascades, ultimately resulting in an increase in food intake and adiposity. Because ghrelin has been linked to overeating and the development of obesity, a number of pharmacological interventions have been generated in order to interfere with either the activation of ghrelin or interrupting ghrelin signaling as a means to reducing appetite and decrease weight gain. Here, we present a novel peptide, CF801, capable of reducing circulating acylated ghrelin levels and subsequent body weight gain and adiposity. To this end, we show that IP administration of CF801 is sufficient to reduce circulating plasma acylated ghrelin levels. Acutely, intraperitoneal injections of CF801 resulted in decreased rebound feeding after an overnight fast. When delivered chronically, they decreased weight gain and adiposity without affecting caloric intake. CF801, however, did cause a change in diet preference, decreasing preference for a high-fat diet and increasing preference for regular chow diet. Given the complexity of ghrelin receptor function, we propose that CF801, along with other compounds that regulate ghrelin secretion, may prove to be a beneficial tool in the study of the ghrelin system, and potential targets for ghrelin-based obesity treatments without altering the function of ghrelin receptors.