Your search keyword '"Andrew P. AhYoung"' showing total 9 results

1. An ancient mechanism of arginine-specific substrate cleavage: What's ‘up’ with NSP4?

Author

Andrew P. AhYoung, Stefan Gerhardy, Menno van Lookeren Campagne, Daniel Kirchhofer, and S. Jack Lin

Subjects

0301 basic medicine, Arginine, Neutrophils, viruses, Cathepsin G, Biochemistry, Substrate Specificity, Serine, Mice, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, medicine, Animals, Humans, Peptide sequence, Serine protease, 030102 biochemistry & molecular biology, biology, Serine Endopeptidases, Active site, General Medicine, biochemical phenomena, metabolism, and nutrition, Trypsin, Kinetics, 030104 developmental biology, chemistry, Neutrophil elastase, Proteolysis, biology.protein, medicine.drug

Abstract

The recently discovered neutrophil serine protease 4 (NSP4) is the fourth member of the NSP family, which includes the well-studied neutrophil elastase, proteinase 3 and cathepsin G. Like the other three NSP members, NSP4 is synthesized by myeloid precursors in the bone marrow and, after cleavage of the two-amino acid activation peptide, is stored as an active protease in azurophil granules of neutrophils. Based on its primary amino acid sequence, NSP4 is predicted to have a shallow S1 specificity pocket with elastase-like substrate specificity. However, NSP4 was found to preferentially cleave after an arginine residue. Structural studies resolved this paradox by revealing an unprecedented mechanism of P1-arginine recognition. In contrast to the canonical mechanism in which the P1-arginine residue points down into a deep S1 pocket, the arginine side chain adopts a surface-exposed 'up' conformation in the NSP4 active site. This conformation is stabilized by the Phe190 residue, which serves as a hydrophobic platform for the aliphatic portion of the arginine side chain, and a network of hydrogen bonds between the arginine guanidium group and the NSP4 residues Ser192 and Ser216. This unique configuration allows NSP4 to cleave even after naturally modified arginine residues, such as citrulline and methylarginine. This non-canonical mechanism, characterized by the hallmark 'triad' Phe190-Ser192-Ser216, is largely preserved throughout evolution starting with bony fish, which appeared about 400 million years ago. Although the substrates and physiological role of NSP4 remain to be determined, its remarkable evolutionary conservation, restricted tissue expression and homology to other neutrophil serine proteases anticipate a function in immune-related processes.

Published

2019

2. Identification of a Helical Segment within the Intrinsically Disordered Region of the PCSK9 Prodomain

Author

Yvonne Franke, M.T. Lipari, Yongmei Chen, D. Kirchhofer, Andrew P. AhYoung, Andrew S. Peterson, P. Di Lello, John G. Quinn, Stefan Gerhardy, Charles Eigenbrot, Wei Li, Mark Ultsch, and M. Kong Beltran

Subjects

Mutation, Missense, Context (language use), Crystallography, X-Ray, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Cell Line, Tumor, Humans, Amino Acid Sequence, Molecular Biology, 030304 developmental biology, 0303 health sciences, Transition (genetics), Chemistry, Serine Endopeptidases, Subtilisin, Hep G2 Cells, Proprotein convertase, Folding (chemistry), Receptors, LDL, Helix, Biophysics, Kexin, Proprotein Convertase 9, Peptides, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, Function (biology)

Abstract

Proprotein convertase subtilisin/kexin 9 (PCSK9) is a key regulator of lipid metabolism by degrading liver LDL receptors. Structural studies have provided molecular details of PCSK9 function. However, the N-terminal acidic stretch of the PCSK9 prodomain (Q31-T60) has eluded structural investigation, since it is in a disordered state. The interest in this region is intensified by the presence of human missense mutations associated with low and high LDL-c levels (E32K, D35Y, and R46L, respectively), as well as two posttranslationally modified sites, sulfated Y38 and phosphorylated S47. Herein we show that a segment within this region undergoes disorder-to-order transition. Experiments with acidic stretch-derived peptides demonstrated that the folding is centered at the segment Y38-L45, which adopts an α-helix as determined by NMR analysis of free peptides and by X-ray crystallography of peptides in complex with antibody 6E2 (Ab6E2). In the Fab6E2-peptide complexes, the structured region features a central 2 1/4-turn α-helix and encompasses up to 2/3 of the length of the acidic stretch, including the missense mutations and posttranslationally modified sites. Experiments with helix-breaking proline substitutions in peptides and in PCSK9 protein indicated that Ab6E2 specifically recognizes the helical conformation of the acidic stretch. Therefore, the observed quantitative binding of Ab6E2 to native PCSK9 from various cell lines suggests that the disorder-to-order transition is a true feature of PCSK9 and not limited to peptides. Because the helix provides a constrained spatial orientation of the missense mutations and the posttranslationally modified residues, it is probable that their biological functions take place in the context of an ordered conformational state.

Published

2019

3. Neutrophil serine protease 4 is required for mast cell-dependent vascular leakage

Author

Qui T. Phung, Stefan Gerhardy, Mike Reichelt, Michele A. Grimbaldeston, Lucinda W Tam, Patrick Caplazi, Alvin Gogineni, Andrew P. AhYoung, Christian Cox, Robby M. Weimer, Daniel Kirchhofer, Jason A. Hackney, Sterling C Eckard, Wyne P. Lee, Robert J. Newman, Merone Roose-Girma, Jennie R. Lill, Anand Kumar Katakam, Hongkang Xi, Juan Zhang, Aditya Murthy, S. Jack Lin, Paolo Manzanillo, and Menno Van Lookeren Campagne

Subjects

0301 basic medicine, Serotonin, Neutrophils, viruses, Immunology, Medicine (miscellaneous), Antigen-Antibody Complex, Article, Gene Expression Regulation, Enzymologic, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Immune system, Rheumatology, medicine, Animals, Mast Cells, Progenitor cell, lcsh:QH301-705.5, Mice, Knockout, Serine protease, biology, Heparan sulfate, Heparin, biochemical phenomena, metabolism, and nutrition, Mast cell, Adoptive Transfer, Cell biology, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), chemistry, biology.protein, Serine Proteases, General Agricultural and Biological Sciences, Histamine, 030215 immunology, medicine.drug

Abstract

Vascular leakage, or edema, is a serious complication of acute allergic reactions. Vascular leakage is triggered by the release of histamine and serotonin from granules within tissue-resident mast cells. Here, we show that expression of Neutrophil Serine Protease 4 (NSP4) during the early stages of mast cell development regulates mast cell-mediated vascular leakage. In myeloid precursors, the granulocyte–macrophage progenitors (GMPs), loss of NSP4 results in the decrease of cellular levels of histamine, serotonin and heparin/heparan sulfate. Mast cells that are derived from NSP4-deficient GMPs have abnormal secretory granule morphology and a sustained reduction in histamine and serotonin levels. Consequently, in passive cutaneous anaphylaxis and acute arthritis models, mast cell-mediated vascular leakage in the skin and joints is substantially reduced in NSP4-deficient mice. Our findings reveal that NSP4 is required for the proper storage of vasoactive amines in mast cell granules, which impacts mast cell-dependent vascular leakage in mouse models of immune complex-mediated diseases., AhYoung, Eckard et al. show that the expression of Neutrophil Serine Protease 4 (NSP4) during the early stages of mast cell development regulates the levels of histamine and serotonin in mast cell granules. This study reveals an important physiological function of NSP4 in mast cell-mediated vascular leakage in mice, establishing NSP4 as a potential therapeutic target for mast cell-dependent immune disorders.

Published

2020

4. Crystal structure of Mdm12 and combinatorial reconstitution of Mdm12/Mmm1 ERMES complexes for structural studies

Author

Brian Lu, Duilio Cascio, Andrew P. AhYoung, and Pascal F. Egea

Subjects

Models, Molecular, Small Angle, 0301 basic medicine, Biochemistry & Molecular Biology, Protein Conformation, Sequence analysis, Protozoan Proteins, Biophysics, Mdm12/Mmm1 complex reconstitution, Medical Biochemistry and Metabolomics, Biology, Endoplasmic Reticulum, Biochemistry, Article, SMP domain, Fungal Proteins, Scattering, Saccharomyces, Medicinal and Biomolecular Chemistry, 03 medical and health sciences, ERMES, Protein structure, X-Ray Diffraction, Models, Scattering, Small Angle, Organelle, Dictyostelium, Molecular Biology, Membrane contact sites, Fungal protein, Small-angle X-ray scattering, Crystal structure, Endoplasmic reticulum, Molecular, SAXS, Cell Biology, Protein engineering, Mitochondria, Crystallography, 030104 developmental biology, Biochemistry and Cell Biology

Abstract

Membrane contact sites between organelles serve as molecular hubs for the exchange of metabolites and signals. In yeast, the Endoplasmic Reticulum − Mitochondrion Encounter Structure (ERMES) tethers these two organelles likely to facilitate the non-vesicular exchange of essential phospholipids. Present in Fungi and Amoebas but not in Metazoans, ERMES is composed of five distinct subunits; among those, Mdm12, Mmm1 and Mdm34 each contain an SMP domain functioning as a lipid transfer module. We previously showed that the SMP domains of Mdm12 and Mmm1 form a hetero-tetramer. Here we describe our strategy to diversify the number of Mdm12/Mmm1 complexes suited for structural studies. We use sequence analysis of orthologues combined to protein engineering of disordered regions to guide the design of protein constructs and expand the repertoire of Mdm12/Mmm1 complexes more likely to crystallize. Using this combinatorial approach we report crystals of Mdm12/Mmm1 ERMES complexes currently diffracting to 4.5 Å resolution and a new structure of Mdm12 solved at 4.1 Å resolution. Our structure reveals a monomeric form of Mdm12 with a conformationally dynamic N-terminal β-strand; it differs from a previously reported homodimeric structure where the N-terminal β strands where swapped to promote dimerization. Based on our electron microscopy data, we propose a refined pseudo-atomic model of the Mdm12/Mmm1 complex that agrees with our crystallographic and small-angle X-ray scattering (SAXS) solution data.

Published

2017

5. Determining the Lipid-Binding Specificity of SMP Domains: An ERMES Subunit as a Case Study

Author

Pascal F. Egea and Andrew P. AhYoung

Subjects

Protein subunit, Phospholipid, Mitochondrion, Endoplasmic Reticulum, Article, Mitochondrial Proteins, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, ERMES, 0302 clinical medicine, Yeasts, Protein Interaction Domains and Motifs, Phospholipids, 030304 developmental biology, 0303 health sciences, Liposome, Bacteria, Chemistry, Endoplasmic reticulum, Biological Transport, Biological membrane, Recombinant Proteins, Protein Subunits, Gene Expression Regulation, Biochemistry, Liposomes, lipids (amino acids, peptides, and proteins), Chromatography, Thin Layer, Carrier Proteins, Plant lipid transfer proteins, 030217 neurology & neurosurgery, Chromatography, Liquid

Abstract

Membrane contact sites between the endoplasmic reticulum (ER) and mitochondria function as a central hub for the exchange of phospholipids and calcium. The yeast Endoplasmic Reticulum–Mitochondrion Encounter Structure (ERMES) complex is composed of five subunits that tether the ER and mitochondria. Three ERMES subunits (i.e., Mdm12, Mmm1, and Mdm34) contain the synaptotagmin-like mitochondrial lipid-binding protein (SMP) domain. The SMP domain belongs to the tubular lipid-binding protein (TULIP) superfamily, which consists of ubiquitous lipid scavenging and transfer proteins. Herein, we describe the methods for expression and purification of recombinant Mdm12, a bona fide SMP-containing protein, together with the subsequent identification of its bound phospholipids by high-performance thin-layer chromatography (HPTLC) and the characterization of its lipid exchange and transfer functions using lipid displacement and liposome flotation in vitro assays with liposomes as model biological membranes. These methods can be applied to the study and characterization of novel lipid-binding and lipid-transfer proteins.

Published

2019

6. Structure of a putative ClpS N-end rule adaptor protein from the malaria pathogenPlasmodium falciparum

Author

Christina L. Vizcarra, Pascal F. Egea, Antoine Koehl, Andrew P. AhYoung, and Duilio Cascio

Subjects

0301 basic medicine, Proteases, Apicoplast, 030102 biochemistry & molecular biology, Signal transducing adaptor protein, N-end rule, Plasmodium falciparum, Biology, biology.organism_classification, Biochemistry, Transport protein, Apicomplexa, 03 medical and health sciences, 030104 developmental biology, Chaperone (protein), parasitic diseases, biology.protein, Molecular Biology

Abstract

The N-end rule pathway uses an evolutionarily conserved mechanism in bacteria and eukaryotes that marks proteins for degradation by ATP-dependent chaperones and proteases such as the Clp chaperones and proteases. Specific N-terminal amino acids (N-degrons) are sufficient to target substrates for degradation. In bacteria, the ClpS adaptor binds and delivers N-end rule substrates for their degradation upon association with the ClpA/P chaperone/protease. Here, we report the first crystal structure, solved at 2.7 A resolution, of a eukaryotic homolog of bacterial ClpS from the malaria apicomplexan parasite Plasmodium falciparum (Pfal). Despite limited sequence identity, Plasmodium ClpS is very similar to bacterial ClpS. Akin to its bacterial orthologs, plasmodial ClpS harbors a preformed hydrophobic pocket whose geometry and chemical properties are compatible with the binding of N-degrons. However, while the N-degron binding pocket in bacterial ClpS structures is open and accessible, the corresponding pocket in Plasmodium ClpS is occluded by a conserved surface loop that acts as a latch. Despite the closed conformation observed in the crystal, we show that, in solution, Pfal-ClpS binds and discriminates peptides mimicking bona fide N-end rule substrates. The presence of an apicoplast targeting peptide suggests that Pfal-ClpS localizes to this plastid-like organelle characteristic of all Apicomplexa and hosting most of its Clp machinery. By analogy with the related ClpS1 from plant chloroplasts and cyanobacteria, Plasmodium ClpS likely functions in association with ClpC in the apicoplast. Our findings open new venues for the design of novel anti-malarial drugs aimed at disrupting parasite-specific protein quality control pathways.

Published

2016

7. Structural mapping of the ClpBATPases ofPlasmodium falciparum: Targeting protein folding and secretion for antimalarial drug design

Author

Pascal F. Egea, Antoine Koehl, Duilio Cascio, and Andrew P. AhYoung

Subjects

Apicoplast, biology, Plasmodium falciparum, Protein superfamily, Translocon, biology.organism_classification, Biochemistry, Proteostasis, Chaperone (protein), biology.protein, Protein folding, CLPB, Molecular Biology

Abstract

Caseinolytic chaperones and proteases (Clp) belong to the AAA+ protein superfamily and are part of the protein quality control machinery in cells. The eukaryotic parasite Plasmodium falciparum, the causative agent of malaria, has evolved an elaborate network of Clp proteins including two distinct ClpB ATPases. ClpB1 and ClpB2 are involved in different aspects of parasitic proteostasis. ClpB1 is present in the apicoplast, a parasite-specific and plastid-like organelle hosting various metabolic pathways necessary for parasite growth. ClpB2 localizes to the parasitophorous vacuole membrane where it drives protein export as core subunit of a parasite-derived protein secretion complex, the Plasmodium Translocon of Exported proteins (PTEX); this process is central to parasite virulence and survival in the human host. The functional associations of these two chaperones with parasite-specific metabolism and protein secretion make them prime drug targets. ClpB proteins function as unfoldases and disaggregases and share a common architecture consisting of four domains-a variable N-terminal domain that binds different protein substrates, followed by two highly conserved catalytic ATPase domains, and a C-terminal domain. Here, we report and compare the first crystal structures of the N terminal domains of ClpB1 and ClpB2 from Plasmodium and analyze their molecular surfaces. Solution scattering analysis of the N domain of ClpB2 shows that the average solution conformation is similar to the crystalline structure. These structures represent the first step towards the characterization of these two malarial chaperones and the reconstitution of the entire PTEX to aid structure-based design of novel anti-malarial drugs.

Published

2015

8. Structure of a putative ClpS N-end rule adaptor protein from the malaria pathogen Plasmodium falciparum

Author

Andrew P, AhYoung, Antoine, Koehl, Christina L, Vizcarra, Duilio, Cascio, and Pascal F, Egea

Subjects

Models, Molecular, Protein Conformation, parasitic diseases, Plasmodium falciparum, Humans, Amino Acid Sequence, Endopeptidase Clp, Articles, Malaria, Falciparum, Crystallography, X-Ray, Sequence Alignment, Substrate Specificity

Abstract

The N‐end rule pathway uses an evolutionarily conserved mechanism in bacteria and eukaryotes that marks proteins for degradation by ATP‐dependent chaperones and proteases such as the Clp chaperones and proteases. Specific N‐terminal amino acids (N‐degrons) are sufficient to target substrates for degradation. In bacteria, the ClpS adaptor binds and delivers N‐end rule substrates for their degradation upon association with the ClpA/P chaperone/protease. Here, we report the first crystal structure, solved at 2.7 Å resolution, of a eukaryotic homolog of bacterial ClpS from the malaria apicomplexan parasite Plasmodium falciparum (Pfal). Despite limited sequence identity, Plasmodium ClpS is very similar to bacterial ClpS. Akin to its bacterial orthologs, plasmodial ClpS harbors a preformed hydrophobic pocket whose geometry and chemical properties are compatible with the binding of N‐degrons. However, while the N‐degron binding pocket in bacterial ClpS structures is open and accessible, the corresponding pocket in Plasmodium ClpS is occluded by a conserved surface loop that acts as a latch. Despite the closed conformation observed in the crystal, we show that, in solution, Pfal‐ClpS binds and discriminates peptides mimicking bona fide N‐end rule substrates. The presence of an apicoplast targeting peptide suggests that Pfal‐ClpS localizes to this plastid‐like organelle characteristic of all Apicomplexa and hosting most of its Clp machinery. By analogy with the related ClpS1 from plant chloroplasts and cyanobacteria, Plasmodium ClpS likely functions in association with ClpC in the apicoplast. Our findings open new venues for the design of novel anti‐malarial drugs aimed at disrupting parasite‐specific protein quality control pathways.

Published

2015

9. Structural mapping of the ClpB ATPases of Plasmodium falciparum: Targeting protein folding and secretion for antimalarial drug design

Author

Andrew P, AhYoung, Antoine, Koehl, Duilio, Cascio, and Pascal F, Egea

Subjects

Adenosine Triphosphatases, Models, Molecular, Protein Folding, Molecular Sequence Data, Plasmodium falciparum, Protozoan Proteins, Articles, Crystallography, X-Ray, Protein Structure, Secondary, Antimalarials, Protein Transport, Drug Design, Humans, Amino Acid Sequence, Molecular Targeted Therapy, Molecular Chaperones

Abstract

Caseinolytic chaperones and proteases (Clp) belong to the AAA+ protein superfamily and are part of the protein quality control machinery in cells. The eukaryotic parasite Plasmodium falciparum, the causative agent of malaria, has evolved an elaborate network of Clp proteins including two distinct ClpB ATPases. ClpB1 and ClpB2 are involved in different aspects of parasitic proteostasis. ClpB1 is present in the apicoplast, a parasite-specific and plastid-like organelle hosting various metabolic pathways necessary for parasite growth. ClpB2 localizes to the parasitophorous vacuole membrane where it drives protein export as core subunit of a parasite-derived protein secretion complex, the Plasmodium Translocon of Exported proteins (PTEX); this process is central to parasite virulence and survival in the human host. The functional associations of these two chaperones with parasite-specific metabolism and protein secretion make them prime drug targets. ClpB proteins function as unfoldases and disaggregases and share a common architecture consisting of four domains—a variable N-terminal domain that binds different protein substrates, followed by two highly conserved catalytic ATPase domains, and a C-terminal domain. Here, we report and compare the first crystal structures of the N terminal domains of ClpB1 and ClpB2 from Plasmodium and analyze their molecular surfaces. Solution scattering analysis of the N domain of ClpB2 shows that the average solution conformation is similar to the crystalline structure. These structures represent the first step towards the characterization of these two malarial chaperones and the reconstitution of the entire PTEX to aid structure-based design of novel anti-malarial drugs.

Published

2015