Your search keyword '"Kaneil K. Zadrozny"' showing total 15 results

1. Structural basis of HIV-1 maturation inhibitor binding and activity

Author

Sucharita Sarkar, Kaneil K. Zadrozny, Roman Zadorozhnyi, Ryan W. Russell, Caitlin M. Quinn, Alex Kleinpeter, Sherimay Ablan, Hamed Meshkin, Juan R. Perilla, Eric O. Freed, Barbie K. Ganser-Pornillos, Owen Pornillos, Angela M. Gronenborn, and Tatyana Polenova

Subjects

Science

Abstract

HIV maturation inhibitors such as bevirimat (BVM) interfering with Gag processing are emerging as alternative anti-retroviral drug candidates. Here, the authors report structures of assemblies of HIV-1 Gag fragments spanning the CA C-terminal domain and SP1 region bound to BVM.

Published

2023

2. Determination of Histidine Protonation States in Proteins by Fast Magic Angle Spinning NMR

Author

Roman Zadorozhnyi, Sucharita Sarkar, Caitlin M. Quinn, Kaneil K. Zadrozny, Barbie K. Ganser-Pornillos, Owen Pornillos, Angela M. Gronenborn, and Tatyana Polenova

Subjects

Magic angle spinning (MAS), nuclear magnetic resonance (NMR) spectroscopy, histidine protonation state, transferred echo double resonance (TEDOR), Fast MAS NMR, solid-state NMR, Biology (General), QH301-705.5

Abstract

Histidine residues play important structural and functional roles in proteins, such as serving as metal-binding ligands, mediating enzyme catalysis, and modulating proton channel activity. Many of these activities are modulated by the ionization state of the imidazole ring. Here we present a fast MAS NMR approach for the determination of protonation and tautomeric states of His at frequencies of 40–62 kHz. The experiments combine 1H detection with selective magnetization inversion techniques and transferred echo double resonance (TEDOR)–based filters, in 2D heteronuclear correlation experiments. We illustrate this approach using microcrystalline assemblies of HIV-1 CACTD-SP1 protein.

Published

2021

3. Purification and structure of luminal domain C of human Niemann–Pick C1 protein

Author

Laura Odongo, Kaneil K. Zadrozny, William E. Diehl, Jeremy Luban, Judith M. White, Barbie K. Ganser-Pornillos, Lukas K. Tamm, and Owen Pornillos

Subjects

Structural Biology, Genetics, Biophysics, Condensed Matter Physics, Biochemistry

Abstract

Niemann–Pick C1 protein (NPC1) is a membrane protein that primarily resides in late endosomes and lysosomes, and plays an important role in cholesterol homeostasis in the cell. The second luminal domain of NPC1 (NPC1-C) serves as the intracellular receptor for Ebola and Marburg viruses. Here, the recombinant production of nonglycosylated and glycosylated NPC1-C and a new crystal form of the nonglycosylated protein are reported. The crystals belonged to space group P21 and diffracted to 2.3 Å resolution. The structure is similar to other reported structures of NPC1-C, with differences observed in the protruding loops when compared with NPC1-C in complex with Ebola virus glycoprotein or NPC2.

Published

2023

4. A molecular switch modulates assembly and host factor binding of the HIV-1 capsid

Author

Randall T. Schirra, Nayara F. B. dos Santos, Kaneil K. Zadrozny, Iga Kucharska, Barbie K. Ganser-Pornillos, and Owen Pornillos

Subjects

Structural Biology, Molecular Biology

Abstract

Upon entry into a new host cell, the HIV-1 capsid performs multiple essential functions, which include shielding the genome from innate immune sensors1, promoting reverse transcription2 and transporting the core from the entry site at the plasma membrane to the integration site inside the nucleus3,4. The HIV-1 capsid is a fullerene cone made of hexamers and pentamers of the viral CA protein5,6. The two types of capsomers are quasi-equivalent, with the same structural elements mediating distinct inter-subunit contacts. In other studied quasi-equivalent viruses, the capacity of genetically identical subunits to form hexamers and pentamers is conferred by molecular switches. Such a switch has not been previously found in retroviral CA proteins. Here, we report cryoEM structures of the HIV-1 CA pentamer within assembled in vitro capsids at nominal resolutions of 2.4-3.4 Å. Comparison with the hexamer identified an internal loop that adopts distinct conformations, 310 helix in the pentamer and random coil in the hexamer. Designed manipulations of the coil/helix configuration allowed us to control pentamer and hexamer formation in a predictable manner, thus proving its function as a molecular switch. Importantly, the switch controls not only fullerene cone assembly, but also the capsid’s capacity to bind post-entry host factors that are critical for viral replication. Furthermore, the switch forms part of the binding site of the new ultra-potent HIV-1 inhibitor, lenacapavir. These studies reveal that a critical assembly element also controls the post-assembly functions of the capsid, and provide new insights on capsid inhibition and uncoating.

Published

2022

5. Crystal structure of an HIV assembly and maturation switch

Author

Jonathan M Wagner, Kaneil K Zadrozny, Jakub Chrustowicz, Michael D Purdy, Mark Yeager, Barbie K Ganser-Pornillos, and Owen Pornillos

Subjects

HIV, capsid, assembly, Medicine, Science, Biology (General), QH301-705.5

Abstract

Virus assembly and maturation proceed through the programmed operation of molecular switches, which trigger both local and global structural rearrangements to produce infectious particles. HIV-1 contains an assembly and maturation switch that spans the C-terminal domain (CTD) of the capsid (CA) region and the first spacer peptide (SP1) of the precursor structural protein, Gag. The crystal structure of the CTD-SP1 Gag fragment is a goblet-shaped hexamer in which the cup comprises the CTD and an ensuing type II β-turn, and the stem comprises a 6-helix bundle. The β-turn is critical for immature virus assembly and the 6-helix bundle regulates proteolysis during maturation. This bipartite character explains why the SP1 spacer is a critical element of HIV-1 Gag but is not a universal property of retroviruses. Our results also indicate that HIV-1 maturation inhibitors suppress unfolding of the CA-SP1 junction and thereby delay access of the viral protease to its substrate.

Published

2016

6. Poly(ADP-ribose) potentiates ZAP antiviral activity

Author

Kaneil K. Zadrozny, Daria M. Dawidziak, Guangai Xue, H. Ong, Barbie K. Ganser-Pornillos, D. Goncalves-Carneiro, Owen Pornillos, W. Yueping, K. Braczyk, Paul D. Bieniasz, and K. Zawada

Subjects

Poly Adenosine Diphosphate Ribose, Protein Conformation, RNA Stability, Immunology, Antiviral protein, chemical and pharmacologic phenomena, Crystallography, X-Ray, Microbiology, Antiviral Agents, chemistry.chemical_compound, Mice, Stress granule, Protein Domains, Virology, Genetics, Animals, Humans, Binding site, Molecular Biology, Polymerase, Zinc finger, biology, Chemistry, RNA, RNA-Binding Proteins, hemic and immune systems, Zinc Fingers, Molecular biology, Leukemia Virus, Murine, HEK293 Cells, Polynucleotide, Mutation, biology.protein, HIV-1, RNA, Viral, Parasitology, DNA, HeLa Cells, Protein Binding

Abstract

Zinc-finger antiviral protein (ZAP), also known as poly(ADP-ribose) polymerase 13 (PARP13), is an antiviral factor that selectively targets viral RNA for degradation. ZAP is active against both DNA and RNA viruses, including important human pathogens such as hepatitis B virus and type 1 human immunodeficiency virus (HIV-1). ZAP selectively binds CpG dinucleotides through its N-terminal RNA-binding domain, which consists of four zinc fingers. ZAP also contains a central region that consists of a fifth zinc finger and two WWE domains. Through structural and biochemical studies, we found that the fifth zinc finger and tandem WWEs of ZAP combine into a single integrated domain that binds to poly(ADP-ribose) (PAR), a cellular polynucleotide. PAR binding is mediated by the second WWE module of ZAP and likely involves specific recognition of iso(ADP-ribose), a repeating structural unit of PAR. Mutation of the putative iso(ADP-ribose) binding site in ZAP abrogates the interaction in vitro and diminishes ZAP activity against a CpG-rich HIV-1 reporter virus. In cells, PAR facilitates formation of non-membranous sub-cellular compartments such as DNA repair foci, spindle poles and cytosolic RNA stress granules. Our results suggest that ZAP-mediated viral mRNA degradation is facilitated by PAR, and provides a biophysical rationale for the reported association of ZAP with RNA stress granules.

Published

2020

7. Capsid lattice destabilization leads to premature loss of the viral genome and integrase enzyme during HIV-1 infection

Author

Owen Pornillos, Sebla B. Kutluay, Alan Engelman, Keanu Davis, Shawn J. Mohammed, Wen Li, Jennifer L Elliott, Jenna E. Eschbach, Kaneil K. Zadrozny, and Dana Q. Lawson

Subjects

viruses, Immunology, Cell, Human immunodeficiency virus (HIV), Genome, Viral, HIV Integrase, medicine.disease_cause, Microbiology, Genome, Cell Line, Capsid, Viral envelope, Virology, Cricetinae, Virus Uncoating, medicine, Animals, Humans, Ribonucleoprotein, chemistry.chemical_classification, biology, Chemistry, Viral Core Proteins, Virion, Reverse Transcription, Reverse transcriptase, In vitro, Virus-Cell Interactions, Integrase, Cell biology, medicine.anatomical_structure, Enzyme, Cytoplasm, Insect Science, Mutation, HIV-1, biology.protein, RNA, Viral, Capsid Proteins

Abstract

The human immunodeficiency virus type 1 (HIV-1) capsid (CA) protein forms a conical lattice around the viral ribonucleoprotein complex (vRNP) consisting of a dimeric viral genome and associated proteins, together constituting the viral core. Upon entry into target cells, the viral core undergoes a process termed uncoating, during which CA molecules are shed from the lattice. Although the timing and degree of uncoating are important for reverse transcription and integration, the molecular basis of this phenomenon remains unclear. Using complementary approaches, we assessed the impact of core destabilization on the intrinsic stability of the CA lattice in vitro and fates of viral core components in infected cells. We found that substitutions in CA can impact the intrinsic stability of the CA lattice in vitro in the absence of vRNPs, which mirrored findings from assessment of CA stability in virions. Altering CA stability tended to increase the propensity to form morphologically aberrant particles, in which the vRNPs were mislocalized between the CA lattice and the viral lipid envelope. Importantly, destabilization of the CA lattice led to premature dissociation of CA from vRNPs in target cells, which was accompanied by proteasomal-independent losses of the viral genome and integrase enzyme. Overall, our studies show that the CA lattice protects the vRNP from untimely degradation in target cells and provide the mechanistic basis of how CA stability influences reverse transcription.AUTHOR SUMMARYThe human immunodeficiency virus type 1 (HIV-1) capsid (CA) protein forms a conical lattice around the viral RNA genome and the associated viral enzymes and proteins, together constituting the viral core. Upon infection of a new cell, viral cores are released into the cytoplasm where they undergo a process termed “uncoating”, i.e. shedding of CA molecules from the conical lattice. Although proper and timely uncoating has been shown to be important for reverse transcription, the molecular mechanisms that link these two events remain poorly understood. In this study, we show that destabilization of the CA lattice leads to premature dissociation of CA from viral cores, which exposes the viral genome and the integrase enzyme for degradation in target cells. Thus, our studies demonstrate that the CA lattice protects the viral ribonucleoprotein complexes from untimely degradation in target cells and provide the first causal link between how CA stability affects reverse transcription.

Published

2020

8. Biochemical Reconstitution of HIV-1 Assembly and Maturation

Author

Pengfei Ding, Owen Pornillos, Michael F. Summers, Iga Kucharska, Barbie K. Ganser-Pornillos, Kaneil K. Zadrozny, and Robert A. Dick

Subjects

Models, Molecular, Phytic Acid, viruses, Immunology, Biology, gag Gene Products, Human Immunodeficiency Virus, Microbiology, Genome, Virus, Cofactor, 03 medical and health sciences, Capsid, Retrovirus, Virology, Humans, 030304 developmental biology, 0303 health sciences, Virus Assembly, Structure and Assembly, 030302 biochemistry & molecular biology, Virion, RNA, Group-specific antigen, biology.organism_classification, Small molecule, In vitro, Cell biology, Microscopy, Electron, Insect Science, HIV-1, biology.protein

Abstract

The assembly of an orthoretrovirus such as HIV-1 requires the coordinated functioning of multiple biochemical activities of the viral Gag protein. These activities include membrane targeting, lattice formation, packaging of the RNA genome, and recruitment of cellular cofactors that modulate assembly. In most previous studies, these Gag activities have been investigated individually, which provided somewhat limited insight into how they functionally integrate during the assembly process. Here, we report the development of a biochemical reconstitution system that allowed us to investigate how Gag lattice formation, RNA binding, and the assembly cofactor inositol hexakisphosphate (IP6) synergize to generate immature virus particles in vitro. The results identify an important rate-limiting step in assembly and reveal new insights into how RNA and IP6 promote immature Gag lattice formation. The immature virus-like particles can be converted into mature capsid-like particles by the simple addition of viral protease, suggesting that it is possible in principle to fully biochemically reconstitute the sequential processes of HIV-1 assembly and maturation from purified components. IMPORTANCE Assembly and maturation are essential steps in the replication of orthoretroviruses such as HIV-1 and are proven therapeutic targets. These processes require the coordinated functioning of the viral Gag protein’s multiple biochemical activities. We describe here the development of an experimental system that allows an integrative analysis of how Gag’s multiple functionalities cooperate to generate a retrovirus particle. Our current studies help to illuminate how Gag synergizes the formation of the virus compartment with RNA binding and how these activities are modulated by the small molecule IP6. Further development and use of this system should lead to a more comprehensive understanding of the molecular mechanisms of HIV-1 assembly and maturation and may provide new insights for the development of antiretroviral drugs.

Published

2020

9. Nup153 Unlocks the Nuclear Pore Complex for HIV-1 Nuclear Translocation in Nondividing Cells

Author

Owen Pornillos, Luca Petiti, Ingrid Cifola, Cindy Buffone, Barbie K. Ganser-Pornillos, Francesca Di Nunzio, Stella Frabetti, Alicia Martinez-Lopez, Thomas Fricke, Felipe Diaz-Griffero, Marco Severgnini, Kaneil K. Zadrozny, Silvana Opp, Katarzyna Skorupka, Albert Einstein College of Medicine [New York], Institute for Biomedical Technologies (ITB), Consiglio Nazionale delle Ricerche [Roma] (CNR), Virologie moléculaire et Vaccinologie, Centre National de la Recherche Scientifique (CNRS)-Institut Pasteur [Paris], University of Virginia [Charlottesville], The work was funded by NIH grants R01-GM123540 and R01-AI087390 to F.D.-G., R01-AI129678 to O.P. and B.K.G.-P., and R01-AI120956 to F.D.-G. and O.P. The work was also supported by grants from the Agence Nationale des Recherches Scientifiques (ANRS ECTZ4469), Sidaction/FRM and the Pasteur Institute, and the Italian Ministry of Health (GR-2011-02352026)., National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS), and University of Virginia

Subjects

0301 basic medicine, [SDV]Life Sciences [q-bio], viruses, HIV integration, integration, MESH: HIV-1, capsid binding, MESH: Capsid, Nup153, nuclear impor, Nuclear pore, HIV nuclear import, 3. Good health, Chromatin, Cell biology, Virus-Cell Interactions, Capsid, Gene Knockdown Techniques, Nucleoporin, NPC, MESH: Nuclear Pore, MESH: mRNA Cleavage and Polyadenylation Factors, Cell Division, Immunology, Active Transport, Cell Nucleus, Mutagenesis (molecular biology technique), MESH: Active Transport, Cell Nucleus, Biology, Microbiology, CPSF6, Cell Line, 03 medical and health sciences, Virology, Humans, Gene, mRNA Cleavage and Polyadenylation Factors, MESH: Humans, HIV, nucleoporin, nondividing cells, MESH: Gene Knockdown Techniques, nuclear import, MESH: Cell Line, Nuclear Pore Complex Proteins, 030104 developmental biology, Insect Science, Mutation, HIV-1, Nuclear Pore, Nuclear transport, MESH: Nuclear Pore Complex Proteins

Abstract

International audience; Human immunodeficiency virus type 1 (HIV-1) displays the unique ability to infect nondividing cells. The capsid of HIV-1 is the viral determinant for viral nuclear import. To understand the cellular factors involved in the ability of HIV-1 to infect nondividing cells, we sought to find capsid mutations that allow the virus to infect dividing but not nondividing cells. Because the interaction of capsid with the nucleoporin protein 153 (Nup153) is important for nuclear import of HIV-1, we solved new crystal structures of hexameric HIV-1 capsid in complex with a Nup153-derived peptide containing a phenylalanine-glycine repeat (FG repeat), which we used to guide structure-based mutagenesis of the capsid-binding interface. HIV-1 viruses with mutations in these capsid residues were tested for their ability to infect dividing and nondividing cells. HIV-1 viruses with capsid N57 substitutions infected dividing but not nondividing cells. Interestingly, HIV-1 viruses with N57 mutations underwent reverse transcription but not nuclear translocation. The mutant capsids also lost the ability to interact with Nup153 and CPSF6. The use of small molecules PF74 and BI-2 prevented the interaction of FG-containing nucleoporins (Nups), such as Nup153, with the HIV-1 core. Analysis of integration sites in HIV-1 viruses with N57 mutations revealed diminished integration into transcriptionally active genes in a manner resembling that of HIV-1 in CPSF6 knockout cells or that of HIV-1-N74D. The integration pattern of the N57 mutant HIV-1 can be explained by loss of capsid interaction with CPSF6, whereas capsid interaction with Nup153 is required for HIV-1 to infect nondividing cells. Additionally, the observed viral integration profiles suggested that integration site selection is a multiparameter process that depends upon nuclear factors and the state of the cellular chromatin.IMPORTANCE One of the key advantages that distinguish lentiviruses, such as HIV-1, from all other retroviruses is its ability to infect nondividing cells. Interaction of the HIV-1 capsid with Nup153 and CPSF6 is important for nuclear entry and integration; however, the contribution of each of these proteins to nuclear import and integration is not clear. Using genetics, we demonstrated that these proteins contribute to different processes: Nup153 is essential for the HIV-1 nuclear import in nondividing cells, and CPSF6 is important for HIV-1 integration. In addition, nuclear factors such as CPSF6 and the state of the chromatin are known to be important for integration site selection; nevertheless, the preferential determinant influencing integration site selection is not known. This work demonstrates that integration site selection is a multiparameter process that depends upon nuclear factors and the state of the cellular chromatin.

Published

2018

10. Inositol phosphates are assembly co-factors for HIV-1

Author

Florian K. M. Schur, Chaoyi Xu, Marc C. Johnson, Owen Pornillos, Juan R. Perilla, Volker M. Vogt, Clifton L. Ricana, Jonathan M. Wagner, Robert A. Dick, Barbie K. Ganser-Pornillos, Kaneil K. Zadrozny, and Terri D. Lyddon

Subjects

0301 basic medicine, Models, Molecular, Viral protein, viruses, Proteolysis, Inositol Phosphates, Peptide, Random hexamer, In Vitro Techniques, Molecular Dynamics Simulation, medicine.disease_cause, Arginine, Crystallography, X-Ray, gag Gene Products, Human Immunodeficiency Virus, 03 medical and health sciences, chemistry.chemical_compound, Capsid, Virus maturation, medicine, Inositol, Binding site, chemistry.chemical_classification, Multidisciplinary, 030102 biochemistry & molecular biology, medicine.diagnostic_test, Lysine, Virus Assembly, Virion, 3. Good health, 030104 developmental biology, chemistry, Biophysics, HIV-1

Abstract

A short, 14-amino-acid segment called SP1, located in the Gag structural protein1, has a critical role during the formation of the HIV-1 virus particle. During virus assembly, the SP1 peptide and seven preceding residues fold into a six-helix bundle, which holds together the Gag hexamer and facilitates the formation of a curved immature hexagonal lattice underneath the viral membrane2,3. Upon completion of assembly and budding, proteolytic cleavage of Gag leads to virus maturation, in which the immature lattice is broken down; the liberated CA domain of Gag then re-assembles into the mature conical capsid that encloses the viral genome and associated enzymes. Folding and proteolysis of the six-helix bundle are crucial rate-limiting steps of both Gag assembly and disassembly, and the six-helix bundle is an established target of HIV-1 inhibitors4,5. Here, using a combination of structural and functional analyses, we show that inositol hexakisphosphate (InsP6, also known as IP6) facilitates the formation of the six-helix bundle and assembly of the immature HIV-1 Gag lattice. IP6 makes ionic contacts with two rings of lysine residues at the centre of the Gag hexamer. Proteolytic cleavage then unmasks an alternative binding site, where IP6 interaction promotes the assembly of the mature capsid lattice. These studies identify IP6 as a naturally occurring small molecule that promotes both assembly and maturation of HIV-1.

Published

2017

11. A Cleavage-potentiated Fragment of Tear Lacritin Is Bactericidal

Author

Rose K. Sia, Kaneil K. Zadrozny, Denise S. Ryan, Andrea M. Deleault, Ronald W. Raab, Gordon W. Laurie, Erin V. Coleman Frazier, Robert L. McKown, and Jae K. Lee

Subjects

genetic structures, Molecular Sequence Data, Antimicrobial peptides, medicine.disease_cause, complex mixtures, Microbiology, Biochemistry, Serine, chemistry.chemical_compound, Protein targeting, Escherichia coli, Staphylococcus epidermidis, medicine, Humans, Amino Acid Sequence, Molecular Biology, Glycoproteins, Serine protease, Lacritin, biology, Leupeptin, Cell Biology, equipment and supplies, eye diseases, Immunity, Innate, Peptide Fragments, Recombinant Proteins, Protein Structure, Tertiary, Spermidine, chemistry, Tears, Proteolysis, Metabolome, Putrescine, biology.protein, bacteria, Antimicrobial Cationic Peptides

Abstract

Antimicrobial peptides are important as the first line of innate defense, through their tendency to disrupt bacterial membranes or intracellular pathways and potentially as the next generation of antibiotics. How they protect wet epithelia is not entirely clear, with most individually inactive under physiological conditions and many preferentially targeting Gram-positive bacteria. Tears covering the surface of the eye are bactericidal for Gram-positive and -negative bacteria. Here we narrow much of the bactericidal activity to a latent C-terminal fragment in the prosecretory mitogen lacritin and report that the mechanism combines membrane permeabilization with rapid metabolic changes, including reduced levels of dephosphocoenzyme A, spermidine, putrescine, and phosphatidylethanolamines and elevated alanine, leucine, phenylalanine, tryptophan, proline, glycine, lysine, serine, glutamate, cadaverine, and pyrophosphate. Thus, death by metabolic stress parallels cellular attempts to survive. Cleavage-dependent appearance of the C-terminal cationic amphipathic α-helix is inducible within hours by Staphylococcus epidermidis and slowly by another mechanism, in a chymotrypsin- or leupeptin protease-inhibitable manner. Although bactericidal at low micromolar levels, within a biphasic 1-10 nM dose optimum, the same domain is mitogenic and cytoprotective for epithelia via a syndecan-1 targeting mechanism dependent on heparanase. Thus, the C terminus of lacritin is multifunctional by dose and proteolytic processing and appears to play a key role in the innate protection of the eye, with wider potential benefit elsewhere as lacritin flows from exocrine secretory cells.

Published

2014

12. Crystal structure of an HIV assembly and maturation switch

Author

Owen Pornillos, Jakub Chrustowicz, Michael D. Purdy, Jonathan M. Wagner, Barbie K. Ganser-Pornillos, Mark Yeager, and Kaneil K. Zadrozny

Subjects

0301 basic medicine, Models, Molecular, Protein Conformation, alpha-Helical, viruses, Random hexamer, medicine.disease_cause, Crystallography, X-Ray, gag Gene Products, Human Immunodeficiency Virus, Biochemistry, chemistry.chemical_compound, capsid, Cloning, Molecular, Biology (General), Peptide sequence, General Neuroscience, General Medicine, Biophysics and Structural Biology, Recombinant Proteins, 3. Good health, Cell biology, Capsid, Medicine, Research Article, assembly, Viral protein, QH301-705.5, Science, Protein domain, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Protein Domains, medicine, Escherichia coli, Amino Acid Sequence, 030102 biochemistry & molecular biology, General Immunology and Microbiology, Maturation inhibitor, Virus Assembly, Virion, HIV, Molecular biology, 030104 developmental biology, Structural biology, chemistry, Proteolysis, HIV-1, Capsid Proteins, Protein Conformation, beta-Strand, Other, Protein Multimerization, Bevirimat

Abstract

Virus assembly and maturation proceed through the programmed operation of molecular switches, which trigger both local and global structural rearrangements to produce infectious particles. HIV-1 contains an assembly and maturation switch that spans the C-terminal domain (CTD) of the capsid (CA) region and the first spacer peptide (SP1) of the precursor structural protein, Gag. The crystal structure of the CTD-SP1 Gag fragment is a goblet-shaped hexamer in which the cup comprises the CTD and an ensuing type II β-turn, and the stem comprises a 6-helix bundle. The β-turn is critical for immature virus assembly and the 6-helix bundle regulates proteolysis during maturation. This bipartite character explains why the SP1 spacer is a critical element of HIV-1 Gag but is not a universal property of retroviruses. Our results also indicate that HIV-1 maturation inhibitors suppress unfolding of the CA-SP1 junction and thereby delay access of the viral protease to its substrate. DOI: http://dx.doi.org/10.7554/eLife.17063.001, eLife digest Viruses like HIV must undergo a process called maturation in order to successfully infect cells. Maturation involves a dramatic rearrangement in the architecture of the virus. That is to say, the virus’s internal protein coat – called the capsid – must change from an immature sphere into a mature cone-shaped coat. Notably, this maturation process is what is disrupted by the protease inhibitors that are a major component of anti-HIV drug cocktails. Structural changes in small portions of the capsid protein, termed molecular switches, commonly trigger the viral capsids to reorganize. The HIV capsid has two of these switches, and Wagner, Zadrozny et al. set out to understand how one of them – called the CA-SP1 switch – works. Solving the three-dimensional structure of the immature form of the CA-SP1 switch revealed that it forms a well-structured bundle of six helices. This helical bundle captures another section of the capsid protein that would otherwise be cut by a viral protease. The CA-SP1 switch therefore controls how quickly the protein is cut and the start of the maturation process. Wagner, Zadrozny et al. then discovered that other small molecule inhibitors of HIV, called maturation inhibitors, work by binding to and disrupting the transformation of the CA-SP1 switch. Finally, further experiments showed that the formation of the CA-SP1 helical bundle controls when the immature capsid shell forms and coordinates the process with the capsid gaining the genetic material of the virus. The new structure means that researchers now know what the HIV capsid looks like at the start and end of maturation. The next challenge will be to figure out exactly how the capsid changes from one form to the next as HIV matures. DOI: http://dx.doi.org/10.7554/eLife.17063.002

Published

2016

13. Author Correction: Inositol phosphates are assembly co-factors for HIV-1

Author

Clifton L. Ricana, Chaoyi Xu, Jonathan M. Wagner, Juan R. Perilla, Florian K. M. Schur, Barbie K. Ganser-Pornillos, Kaneil K. Zadrozny, Owen Pornillos, Robert A. Dick, Terri D. Lyddon, Volker M. Vogt, and Marc C. Johnson

Subjects

Multidisciplinary, viruses, Published Erratum, Protein Data Bank (RCSB PDB), Human immunodeficiency virus (HIV), computer.file_format, Computational biology, Biology, Protein Data Bank, medicine.disease_cause, Article, chemistry.chemical_compound, chemistry, Co factor, medicine, Inositol, computer

Abstract

Information of the HIV-1 virus particle, a short, 14-amino acid segment called SP1, located in the Gag structural protein1, plays a critical role. During virus assembly the SP1 peptide and seven preceding residues fold into a six-helix bundle (6HB) that holds together the Gag hexamer and facilitates formation of a curved immature hexagonal lattice underneath the viral membrane2,3. Upon completion of assembly and budding, proteolytic cleavage of Gag leads to virus maturation, in which the immature lattice is broken down; the liberated CA domain of Gag then re-assembles into the mature conical capsid that encloses the viral genome and associated enzymes. Folding and proteolysis of the 6HB are critical rate-limiting steps of both Gag assembly and disassembly, and the 6HB is an established target of HIV-1 inhibitors4,5. Using a combination of structural and functional analyses, we show here that inositol hexakisphosphate (IP6) facilitates formation of the 6HB and assembly of the immature HIV-1 Gag lattice. IP6 makes ionic contacts with two rings of lysine residues at the center of the Gag hexamer. Proteolytic cleavage then unmasks an alternative binding site, where IP6 interaction promotes assembly of the mature capsid lattice. These studies identify IP6 as a naturally occurring small molecule that promotes both HIV-1 assembly and maturation.

Published

2018

14. Poly(ADP-ribose) potentiates ZAP antiviral activity.

Author

Guangai Xue, Klaudia Braczyk, Daniel Gonçalves-Carneiro, Daria M Dawidziak, Katarzyna Sanchez, Heley Ong, Yueping Wan, Kaneil K Zadrozny, Barbie K Ganser-Pornillos, Paul D Bieniasz, and Owen Pornillos

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Zinc-finger antiviral protein (ZAP), also known as poly(ADP-ribose) polymerase 13 (PARP13), is an antiviral factor that selectively targets viral RNA for degradation. ZAP is active against both DNA and RNA viruses, including important human pathogens such as hepatitis B virus and type 1 human immunodeficiency virus (HIV-1). ZAP selectively binds CpG dinucleotides through its N-terminal RNA-binding domain, which consists of four zinc fingers. ZAP also contains a central region that consists of a fifth zinc finger and two WWE domains. Through structural and biochemical studies, we found that the fifth zinc finger and tandem WWEs of ZAP combine into a single integrated domain that binds to poly(ADP-ribose) (PAR), a cellular polynucleotide. PAR binding is mediated by the second WWE module of ZAP and likely involves specific recognition of an adenosine diphosphate-containing unit of PAR. Mutation of the PAR binding site in ZAP abrogates the interaction in vitro and diminishes ZAP activity against a CpG-rich HIV-1 reporter virus and murine leukemia virus. In cells, PAR facilitates formation of non-membranous sub-cellular compartments such as DNA repair foci, spindle poles and cytosolic RNA stress granules. Our results suggest that ZAP-mediated viral mRNA degradation is facilitated by PAR, and provides a biophysical rationale for the reported association of ZAP with RNA stress granules.

Published

2022

15. Structural basis of HIV-1 capsid recognition by PF74 and CPSF6.

Author

Bhattacharya A, Alam SL, Fricke T, Zadrozny K, Sedzicki J, Taylor AB, Demeler B, Pornillos O, Ganser-Pornillos BK, Diaz-Griffero F, Ivanov DN, and Yeager M

Subjects

Capsid metabolism, Crystallography, X-Ray, HIV Infections, HIV-1 metabolism, Indoles pharmacology, Nuclear Pore Complex Proteins chemistry, Nuclear Pore Complex Proteins metabolism, Phenylalanine chemistry, Phenylalanine pharmacology, Protein Binding, mRNA Cleavage and Polyadenylation Factors metabolism, Capsid chemistry, HIV-1 chemistry, Indoles chemistry, Phenylalanine analogs & derivatives, mRNA Cleavage and Polyadenylation Factors chemistry

Abstract

Upon infection of susceptible cells by HIV-1, the conical capsid formed by ∼250 hexamers and 12 pentamers of the CA protein is delivered to the cytoplasm. The capsid shields the RNA genome and proteins required for reverse transcription. In addition, the surface of the capsid mediates numerous host-virus interactions, which either promote infection or enable viral restriction by innate immune responses. In the intact capsid, there is an intermolecular interface between the N-terminal domain (NTD) of one subunit and the C-terminal domain (CTD) of the adjacent subunit within the same hexameric ring. The NTD-CTD interface is critical for capsid assembly, both as an architectural element of the CA hexamer and pentamer and as a mechanistic element for generating lattice curvature. Here we report biochemical experiments showing that PF-3450074 (PF74), a drug that inhibits HIV-1 infection, as well as host proteins cleavage and polyadenylation specific factor 6 (CPSF6) and nucleoporin 153 kDa (NUP153), bind to the CA hexamer with at least 10-fold higher affinities compared with nonassembled CA or isolated CA domains. The crystal structure of PF74 in complex with the CA hexamer reveals that PF74 binds in a preformed pocket encompassing the NTD-CTD interface, suggesting that the principal inhibitory target of PF74 is the assembled capsid. Likewise, CPSF6 binds in the same pocket. Given that the NTD-CTD interface is a specific molecular signature of assembled hexamers in the capsid, binding of NUP153 at this site suggests that key features of capsid architecture remain intact upon delivery of the preintegration complex to the nucleus.

Published

2014