Your search keyword '"Füzik T"' showing total 29 results

1. Structure and replication of Pseudomonas aeruginosa phage JBD30.

Author

Valentová L, Füzik T, Nováček J, Hlavenková Z, Pospíšil J, and Plevka P

Subjects

Fimbriae, Bacterial metabolism, Fimbriae, Bacterial ultrastructure, Fimbriae, Bacterial virology, Capsid Proteins metabolism, Capsid Proteins chemistry, Capsid Proteins genetics, DNA, Viral metabolism, DNA, Viral genetics, Siphoviridae genetics, Siphoviridae ultrastructure, Siphoviridae physiology, Siphoviridae metabolism, Pseudomonas aeruginosa virology, Pseudomonas aeruginosa metabolism, Pseudomonas Phages ultrastructure, Pseudomonas Phages genetics, Pseudomonas Phages metabolism, Pseudomonas Phages physiology, Cryoelectron Microscopy, Virus Replication

Abstract

Bacteriophages are the most abundant biological entities on Earth, but our understanding of many aspects of their lifecycles is still incomplete. Here, we have structurally analysed the infection cycle of the siphophage Casadabanvirus JBD30. Using its baseplate, JBD30 attaches to Pseudomonas aeruginosa via the bacterial type IV pilus, whose subsequent retraction brings the phage to the bacterial cell surface. Cryo-electron microscopy structures of the baseplate-pilus complex show that the tripod of baseplate receptor-binding proteins attaches to the outer bacterial membrane. The tripod and baseplate then open to release three copies of the tape-measure protein, an event that is followed by DNA ejection. JBD30 major capsid proteins assemble into procapsids, which expand by 7% in diameter upon filling with phage dsDNA. The DNA-filled heads are finally joined with 180-nm-long tails, which bend easily because flexible loops mediate contacts between the successive discs of major tail proteins. It is likely that the structural features and replication mechanisms described here are conserved among siphophages that utilize the type IV pili for initial cell attachment., (© 2024. The Author(s).)

Published

2024

2. The structure of immature tick-borne encephalitis virus supports the collapse model of flavivirus maturation.

Author

Anastasina M, Füzik T, Domanska A, Pulkkinen LIA, Šmerdová L, Formanová PP, Straková P, Nováček J, Růžek D, Plevka P, and Butcher SJ

Subjects

Models, Molecular, Flavivirus physiology, Animals, Virion, Encephalitis, Tick-Borne virology, Humans, Encephalitis Viruses, Tick-Borne physiology, Viral Envelope Proteins chemistry, Viral Envelope Proteins metabolism

Abstract

We present structures of three immature tick-borne encephalitis virus (TBEV) isolates. Our atomic models of the major viral components, the E and prM proteins, indicate that the pr domains of prM have a critical role in holding the heterohexameric prM3E3 spikes in a metastable conformation. Destabilization of the prM furin-sensitive loop at acidic pH facilitates its processing. The prM topology and domain assignment in TBEV is similar to the mosquito-borne Binjari virus, but is in contrast to other immature flavivirus models. These results support that prM cleavage, the collapse of E protein ectodomains onto the virion surface, the large movement of the membrane domains of both E and M, and the release of the pr fragment from the particle render the virus mature and infectious. Our work favors the collapse model of flavivirus maturation warranting further studies of immature flaviviruses to determine the sequence of events and mechanistic details driving flavivirus maturation.

Published

2024

3. Structure and replication cycle of a virus infecting climate-modulating alga Emiliania huxleyi .

Author

Homola M, Büttner CR, Füzik T, Křepelka P, Holbová R, Nováček J, Chaillet ML, Žák J, Grybchuk D, Förster F, Wilson WH, Schroeder DC, and Plevka P

Subjects

Virion, Climate, Haptophyta metabolism, Phycodnaviridae genetics, Viruses

Abstract

The globally distributed marine alga Emiliania huxleyi has cooling effect on the Earth's climate. The population density of E. huxleyi is restricted by Nucleocytoviricota viruses, including E. huxleyi virus 201 (EhV-201). Despite the impact of E. huxleyi viruses on the climate, there is limited information about their structure and replication. Here, we show that the dsDNA genome inside the EhV-201 virion is protected by an inner membrane, capsid, and outer membrane. EhV-201 virions infect E. huxleyi by using fivefold vertices to bind to and fuse the virus' inner membrane with the cell plasma membrane. Progeny virions assemble in the cytoplasm at the surface of endoplasmic reticulum-derived membrane segments. Genome packaging initiates synchronously with the capsid assembly and completes through an aperture in the forming capsid. The genome-filled capsids acquire an outer membrane by budding into intracellular vesicles. EhV-201 infection induces a loss of surface protective layers from E. huxleyi cells, which enables the continuous release of virions by exocytosis.

Published

2024

4. Structure of the Borrelia Bacteriophage φBB1 Procapsid.

Author

Rūmnieks J, Füzik T, and Tārs K

Subjects

Capsid Proteins metabolism, Cryoelectron Microscopy, Virus Assembly, Bacteriophages chemistry, Bacteriophages genetics, Borrelia virology, Capsid chemistry

Abstract

Bacteriophages of Borrelia burgdorferi are a biologically important but under-investigated feature of the Lyme disease-causing spirochete. No virulent borrelial viruses have been identified, but all B. burgdorferi isolates carry a prophage φBB1 as resident circular plasmids. Like its host, the φBB1 phage is quite distinctive and shares little sequence similarity with other known bacteriophages. We expressed φBB1 head morphogenesis proteins in Escherichia coli which resulted in assembly of homogeneous prolate procapsid structures and used cryo-electron microscopy to determine the three-dimensional structure of these particles. The φBB1 procapsids consist of 415 copies of the major capsid protein and an equal combined number of three homologous capsid decoration proteins that form trimeric knobs on the outside of the particle. One of the end vertices of the particle is occupied by a portal assembled from twelve copies of the portal protein. The φBB1 scaffolding protein is entirely α-helical and has an elongated shape with a small globular domain in the middle. Within the tubular section of the procapsid, the internal scaffold is built of stacked rings, each composed of 32 scaffolding protein molecules, which run in opposite directions from both caps with a heterogeneous part in the middle. Inside the portal-containing cap, the scaffold is organized asymmetrically with ten scaffolding protein molecules bound to the portal. The φBB1 procapsid structure provides better insight into the vast structural diversity of bacteriophages and presents clues of how elongated bacteriophage particles might be assembled., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

5. Virion structure of Leishmania RNA virus 1.

Author

Procházková M, Füzik T, Grybchuk D, Yurchenko V, and Plevka P

Abstract

The presence of Leishmania RNA virus 1 (LRV1) enables Leishmania protozoan parasites to cause more severe disease than the virus-free strains. The structure of LRV1 virus-like particles has been determined previously, however, the structure of the LRV1 virion has not been characterized. Here we used cryo-electron microscopy and single-particle reconstruction to determine the structures of the LRV1 virion and empty particle isolated from Leishmania guyanensis to resolutions of 4.0 Å and 3.6 Å, respectively. The capsid of LRV1 is built from sixty dimers of capsid proteins organized with icosahedral symmetry. RNA genomes of totiviruses are replicated inside the virions by RNA polymerases expressed as C-terminal extensions of a sub-population of capsid proteins. Most of the virions probably contain one or two copies of the RNA polymerase, however, the location of the polymerase domains in LRV1 capsid could not be identified, indicating that it varies among particles. Importance. Every year over 200 000 people contract leishmaniasis and more than five hundred people die of the disease. The mucocutaneous form of leishmaniasis produces lesions that can destroy the mucous membranes of the nose, mouth, and throat. Leishmania parasites carrying Leishmania RNA virus 1 (LRV1) are predisposed to cause aggravated symptoms in the mucocutaneous form of leishmaniasis. Here, we present the structure of the LRV1 virion determined using cryo-electron microscopy., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

6. Polyelectrolyte coating of cryo-EM grids improves lateral distribution and prevents aggregation of macromolecules.

Author

Hrebík D, Gondová M, Valentová L, Füzik T, Přidal A, Nováček J, and Plevka P

Subjects

Cryoelectron Microscopy, Polyelectrolytes, Macromolecular Substances, DNA, Single-Stranded, Specimen Handling

Abstract

Cryo-electron microscopy (cryo-EM) is one of the primary methods used to determine the structures of macromolecules and their complexes. With the increased availability of cryo-electron microscopes, the preparation of high-quality samples has become a bottleneck in the cryo-EM structure-determination pipeline. Macromolecules can be damaged during the purification or preparation of vitrified samples for cryo-EM, making them prone to binding to the grid support, to aggregation or to the adoption of preferential orientations at the air-water interface. Here, it is shown that coating cryo-EM grids with a negatively charged polyelectrolyte, such as single-stranded DNA, before applying the sample reduces the aggregation of macromolecules and improves their distribution. The single-stranded DNA-coated grids enabled the determination of high-resolution structures from samples that aggregated on conventional grids. The polyelectrolyte coating reduces the diffusion of macromolecules and thus may limit the negative effects of the contact of macromolecules with the grid support and blotting paper, as well as of the shear forces on macromolecules during grid blotting. Coating grids with polyelectrolytes can readily be employed in any laboratory dealing with cryo-EM sample preparation, since it is fast, simple, inexpensive and does not require specialized equipment., (open access.)

Published

2022

7. Tail proteins of phage SU10 reorganize into the nozzle for genome delivery.

Author

Šiborová M, Füzik T, Procházková M, Nováček J, Benešík M, Nilsson AS, and Plevka P

Subjects

DNA, Viral genetics, Genome, Viral genetics, Bacteriophages genetics, Bacteriophages metabolism, Phosmet, Podoviridae genetics

Abstract

Escherichia coli phage SU10 belongs to the genus Kuravirus from the class Caudoviricetes of phages with short non-contractile tails. In contrast to other short-tailed phages, the tails of Kuraviruses elongate upon cell attachment. Here we show that the virion of SU10 has a prolate head, containing genome and ejection proteins, and a tail, which is formed of portal, adaptor, nozzle, and tail needle proteins and decorated with long and short fibers. The binding of the long tail fibers to the receptors in the outer bacterial membrane induces the straightening of nozzle proteins and rotation of short tail fibers. After the re-arrangement, the nozzle proteins and short tail fibers alternate to form a nozzle that extends the tail by 28 nm. Subsequently, the tail needle detaches from the nozzle proteins and five types of ejection proteins are released from the SU10 head. The nozzle with the putative extension formed by the ejection proteins enables the delivery of the SU10 genome into the bacterial cytoplasm. It is likely that this mechanism of genome delivery, involving the formation of the tail nozzle, is employed by all Kuraviruses., (© 2022. The Author(s).)

Published

2022

8. Structure of Human Enterovirus 70 and Its Inhibition by Capsid-Binding Compounds.

Author

Füzik T, Moravcová J, Kalynych S, and Plevka P

Subjects

Capsid Proteins, Conjunctivitis, Acute Hemorrhagic virology, Cryoelectron Microscopy, Humans, Oxadiazoles pharmacology, Oxazoles pharmacology, Virion drug effects, Virion ultrastructure, Antiviral Agents pharmacology, Capsid ultrastructure, Enterovirus D, Human drug effects, Enterovirus D, Human ultrastructure

Abstract

Enterovirus 70 (EV70) is a human pathogen belonging to the family Picornaviridae . EV70 is transmitted by eye secretions and causes acute hemorrhagic conjunctivitis, a serious eye disease. Despite the severity of the disease caused by EV70, its structure is unknown. Here, we present the structures of the EV70 virion, altered particle, and empty capsid determined by cryo-electron microscopy. The capsid of EV70 is composed of the subunits VP1, VP2, VP3, and VP4. The partially collapsed hydrophobic pocket located in VP1 of the EV70 virion is not occupied by a pocket factor, which is commonly present in other enteroviruses. Nevertheless, we show that the pocket can be targeted by the antiviral compounds WIN51711 and pleconaril, which block virus infection. The inhibitors prevent genome release by stabilizing EV70 particles. Knowledge of the structures of complexes of EV70 with inhibitors will enable the development of capsid-binding therapeutics against this virus. IMPORTANCE Globally distributed enterovirus 70 (EV70) causes local outbreaks of acute hemorrhagic conjunctivitis. The discharge from infected eyes enables the high-efficiency transmission of EV70 in overcrowded areas with low hygienic standards. Currently, only symptomatic treatments are available. We determined the structures of EV70 in its native form, the genome release intermediate, and the empty capsid resulting from genome release. Furthermore, we elucidated the structures of EV70 in complex with two inhibitors that block virus infection, and we describe the mechanism of their binding to the virus capsid. These results enable the development of therapeutics against EV70.

Published

2022

9. Cryo-electron microscopy and image classification reveal the existence and structure of the coxsackievirus A6 virion.

Author

Büttner CR, Spurný R, Füzik T, and Plevka P

Subjects

Antibodies, Viral, Antigens, Viral, Capsid Proteins genetics, Cryoelectron Microscopy, Humans, Virion, Enterovirus genetics, Hand, Foot and Mouth Disease

Abstract

Coxsackievirus A6 (CV-A6) has recently overtaken enterovirus A71 and CV-A16 as the primary causative agent of hand, foot, and mouth disease worldwide. Virions of CV-A6 were not identified in previous structural studies, and it was speculated that the virus is unique among enteroviruses in using altered particles with expanded capsids to infect cells. In contrast, the virions of other enteroviruses are required for infection. Here we used cryo-electron microscopy (cryo-EM) to determine the structures of the CV-A6 virion, altered particle, and empty capsid. We show that the CV-A6 virion has features characteristic of virions of other enteroviruses, including a compact capsid, VP4 attached to the inner capsid surface, and fatty acid-like molecules occupying the hydrophobic pockets in VP1 subunits. Furthermore, we found that in a purified sample of CV-A6, the ratio of infectious units to virions is 1 to 500. Therefore, it is likely that virions of CV-A6 initiate infection, like those of other enteroviruses. Our results provide evidence that future vaccines against CV-A6 should target its virions instead of the antigenically distinct altered particles. Furthermore, the structure of the virion provides the basis for the rational development of capsid-binding inhibitors that block the genome release of CV-A6., (© 2022. The Author(s).)

Published

2022

10. Structures of L-BC virus and its open particle provide insight into Totivirus capsid assembly.

Author

Grybchuk D, Procházková M, Füzik T, Konovalovas A, Serva S, Yurchenko V, and Plevka P

Subjects

Animals, Capsid metabolism, Capsid Proteins metabolism, Cryoelectron Microscopy, Totivirus chemistry, Totivirus genetics, Viruses

Abstract

L-BC virus persists in the budding yeast Saccharomyces cerevisiae, whereas other viruses from the family Totiviridae infect a diverse group of organisms including protists, fungi, arthropods, and vertebrates. The presence of totiviruses alters the fitness of the host organisms, for example, by maintaining the killer system in yeast or increasing the virulence of Leishmania guyanensis. Despite the importance of totiviruses for their host survival, there is limited information about Totivirus structure and assembly. Here we used cryo-electron microscopy to determine the structure of L-BC virus to a resolution of 2.9 Å. The L-BC capsid is organized with icosahedral symmetry, with each asymmetric unit composed of two copies of the capsid protein. Decamers of capsid proteins are stabilized by domain swapping of the C-termini of subunits located around icosahedral fivefold axes. We show that capsids of 9% of particles in a purified L-BC sample were open and lacked one decamer of capsid proteins. The existence of the open particles together with domain swapping within a decamer provides evidence that Totiviridae capsids assemble from the decamers of capsid proteins. Furthermore, the open particles may be assembly intermediates that are prepared for the incorporation of the virus (+) strand RNA., (© 2022. The Author(s).)

Published

2022

11. ICAM-1 induced rearrangements of capsid and genome prime rhinovirus 14 for activation and uncoating.

Author

Hrebík D, Füzik T, Gondová M, Šmerdová L, Adamopoulos A, Šedo O, Zdráhal Z, and Plevka P

Subjects

Amino Acid Sequence, Capsid Proteins chemistry, Capsid Proteins genetics, Capsid Proteins metabolism, Cryoelectron Microscopy, Crystallography, X-Ray, Enterovirus Infections metabolism, Enterovirus Infections virology, Genome, Viral genetics, HeLa Cells, Humans, Intercellular Adhesion Molecule-1 chemistry, Intercellular Adhesion Molecule-1 genetics, Models, Molecular, Nucleic Acid Conformation, Protein Binding, Protein Conformation, RNA, Viral chemistry, RNA, Viral genetics, Rhinovirus genetics, Rhinovirus physiology, Sequence Homology, Amino Acid, Virion genetics, Virion metabolism, Virion ultrastructure, Capsid metabolism, Intercellular Adhesion Molecule-1 metabolism, RNA, Viral metabolism, Rhinovirus metabolism, Virus Activation physiology, Virus Uncoating physiology

Abstract

Most rhinoviruses, which are the leading cause of the common cold, utilize intercellular adhesion molecule-1 (ICAM-1) as a receptor to infect cells. To release their genomes, rhinoviruses convert to activated particles that contain pores in the capsid, lack minor capsid protein VP4, and have an altered genome organization. The binding of rhinoviruses to ICAM-1 promotes virus activation; however, the molecular details of the process remain unknown. Here, we present the structures of virion of rhinovirus 14 and its complex with ICAM-1 determined to resolutions of 2.6 and 2.4 Å, respectively. The cryo-electron microscopy reconstruction of rhinovirus 14 virions contains the resolved density of octanucleotide segments from the RNA genome that interact with VP2 subunits. We show that the binding of ICAM-1 to rhinovirus 14 is required to prime the virus for activation and genome release at acidic pH. Formation of the rhinovirus 14-ICAM-1 complex induces conformational changes to the rhinovirus 14 capsid, including translocation of the C termini of VP4 subunits, which become poised for release through pores that open in the capsids of activated particles. VP4 subunits with altered conformation block the RNA-VP2 interactions and expose patches of positively charged residues. The conformational changes to the capsid induce the redistribution of the virus genome by altering the capsid-RNA interactions. The restructuring of the rhinovirus 14 capsid and genome prepares the virions for conversion to activated particles. The high-resolution structure of rhinovirus 14 in complex with ICAM-1 explains how the binding of uncoating receptors enables enterovirus genome release., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

12. Virion structure and in vitro genome release mechanism of dicistrovirus Kashmir bee virus.

Author

Mukhamedova L, Füzik T, Nováček J, Hrebík D, Přidal A, Marti GA, Guérin DMA, and Plevka P

Abstract

Infections of Kashmir bee virus (KBV) are lethal for honeybees and have been associated with colony collapse disorder. KBV and closely related viruses contribute to the ongoing decline in the number of honeybee colonies in North America, Europe, Australia, and other parts of the world. Despite the economic and ecological impact of KBV, its structure and infection process remain unknown. Here we present the structure of the virion of KBV determined to a resolution of 2.8 Å. We show that the exposure of KBV to acidic pH induces a reduction in inter-pentamer contacts within capsids and the reorganization of its RNA genome from a uniform distribution to regions of high and low density. Capsids of KBV crack into pieces at acidic pH, resulting in the formation of open particles lacking pentamers of capsid proteins. The large openings of capsids enable the rapid release of genomes and thus limit the probability of their degradation by RNases. The opening of capsids may be a shared mechanism for the genome release of viruses from the family Dicistroviridae Importance The western honeybee ( Apis mellifera ) is indispensable for maintaining agricultural productivity as well as the abundance and diversity of wild flowering plants. However, bees suffer from environmental pollution, parasites, and pathogens, including viruses. Outbreaks of virus infections cause the deaths of individual honeybees as well as collapses of whole colonies. Kashmir bee virus has been associated with colony collapse disorder in the US, and no cure of the disease is currently available. Here we report the structure of an infectious particle of Kashmir bee virus and show how its protein capsid opens to release the genome. Our structural characterization of the infection process determined that therapeutic compounds stabilizing contacts between pentamers of capsid proteins could prevent the genome release of the virus., (Copyright © 2021 Mukhamedova et al.)

Published

2021

13. Capsid Structure of Leishmania RNA Virus 1.

Author

Procházková M, Füzik T, Grybchuk D, Falginella FL, Podešvová L, Yurchenko V, Vácha R, and Plevka P

Subjects

Capsid metabolism, Capsid Proteins genetics, Capsid Proteins metabolism, Cryoelectron Microscopy, Genome, Viral, Leishmaniavirus genetics, Leishmaniavirus metabolism, RNA, Viral genetics, Capsid chemistry, Capsid Proteins chemistry, Leishmaniavirus chemistry, RNA, Viral metabolism

Abstract

Leishmania parasites cause a variety of symptoms, including mucocutaneous leishmaniasis, which results in the destruction of the mucous membranes of the nose, mouth, and throat. The species of Leishmania carrying Leishmania RNA virus 1 (LRV1), from the family Totiviridae , are more likely to cause severe disease and are less sensitive to treatment than those that do not contain the virus. Although the importance of LRV1 for the severity of leishmaniasis was discovered a long time ago, the structure of the virus remained unknown. Here, we present a cryo-electron microscopy reconstruction of the virus-like particle of LRV1 determined to a resolution of 3.65 Å. The capsid has icosahedral symmetry and is formed by 120 copies of a capsid protein assembled in asymmetric dimers. RNA genomes of viruses from the family Totiviridae are synthetized, but not capped at the 5' end, by virus RNA polymerases. To protect viral RNAs from degradation, capsid proteins of the L-A totivirus cleave the 5' caps of host mRNAs, creating decoys to overload the cellular RNA quality control system. Capsid proteins of LRV1 form positively charged clefts, which may be the cleavage sites for the 5' cap of Leishmania mRNAs. The putative RNA binding site of LRV1 is distinct from that of the related L-A virus. The structure of the LRV1 capsid enables the rational design of compounds targeting the putative decapping site. Such inhibitors may be developed into a treatment for mucocutaneous leishmaniasis caused by LRV1-positive species of Leishmania IMPORTANCE Twelve million people worldwide suffer from leishmaniasis, resulting in more than 30 thousand deaths annually. The disease has several variants that differ in their symptoms. The mucocutaneous form, which leads to disintegration of the nasal septum, lips, and palate, is caused predominantly by Leishmania parasites carrying Leishmania RNA virus 1 (LRV1). Here, we present the structure of the LRV1 capsid determined using cryo-electron microscopy. Capsid proteins of a related totivirus, L-A virus, protect viral RNAs from degradation by cleaving the 5' caps of host mRNAs. Capsid proteins of LRV1 may have the same function. We show that the LRV1 capsid contains positively charged clefts that may be sites for the cleavage of mRNAs of Leishmania cells. The structure of the LRV1 capsid enables the rational design of compounds targeting the putative mRNA cleavage site. Such inhibitors may be used as treatments for mucocutaneous leishmaniasis., (Copyright © 2021 Procházková et al.)

Published

2021

14. Capsid opening enables genome release of iflaviruses.

Author

Škubník K, Sukeník L, Buchta D, Füzik T, Procházková M, Moravcová J, Šmerdová L, Přidal A, Vácha R, and Plevka P

Abstract

The family Iflaviridae includes economically important viruses of the western honeybee such as deformed wing virus, slow bee paralysis virus, and sacbrood virus. Iflaviruses have nonenveloped virions and capsids organized with icosahedral symmetry. The genome release of iflaviruses can be induced in vitro by exposure to acidic pH, implying that they enter cells by endocytosis. Genome release intermediates of iflaviruses have not been structurally characterized. Here, we show that conformational changes and expansion of iflavirus RNA genomes, which are induced by acidic pH, trigger the opening of iflavirus particles. Capsids of slow bee paralysis virus and sacbrood virus crack into pieces. In contrast, capsids of deformed wing virus are more flexible and open like flowers to release their genomes. The large openings in iflavirus particles enable the fast exit of genomes from capsids, which decreases the probability of genome degradation by the RNases present in endosomes., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License 4.0 (CC BY).)

Published

2021

15. Virion structures and genome delivery of honeybee viruses.

Author

Procházková M, Škubník K, Füzik T, Mukhamedova L, Přidal A, and Plevka P

Subjects

Acids, Animals, Capsid chemistry, Capsid metabolism, Crystallography, X-Ray, Hydrogen-Ion Concentration, Models, Molecular, Protein Conformation, RNA Viruses metabolism, Bees virology, Capsid Proteins chemistry, Genome, Viral, Virion chemistry, Virion genetics, Virus Diseases veterinary

Abstract

The western honeybee is the primary pollinator of numerous food crops. Furthermore, honeybees are essential for ecosystem stability by sustaining the diversity and abundance of wild flowering plants. However, the worldwide population of honeybees is under pressure from environmental stress and pathogens. Viruses from the families Iflaviridae and Dicistroviridae, together with their vector, the parasitic mite Varroa destructor, are the major threat to the world's honeybees. Dicistroviruses and iflaviruses have capsids with icosahedral symmetries. Acidic pH triggers the genome release of both dicistroviruses and iflaviruses. The capsids of iflaviruses expand, whereas those of dicistroviruses remain compact until the genome release. Furthermore, dicistroviruses use inner capsid proteins, whereas iflaviruses employ protruding domains or minor capsid proteins from the virion surface to penetrate membranes and deliver their genomes into the cell cytoplasm. The structural characterization of the infection process opens up possibilities for the development of antiviral compounds., (Copyright © 2020 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2020

16. Structure and mechanism of DNA delivery of a gene transfer agent.

Author

Bárdy P, Füzik T, Hrebík D, Pantůček R, Thomas Beatty J, and Plevka P

Subjects

Bacteriophages genetics, Bacteriophages ultrastructure, Cryoelectron Microscopy, DNA, Bacterial genetics, Gene Expression Regulation, Bacterial, Gene Transfer, Horizontal, Siphoviridae genetics, Siphoviridae ultrastructure, Bacteriophages physiology, Gene Transfer Techniques, Rhodobacter capsulatus genetics, Rhodobacter capsulatus virology, Siphoviridae physiology

Abstract

Alphaproteobacteria, which are the most abundant microorganisms of temperate oceans, produce phage-like particles called gene transfer agents (GTAs) that mediate lateral gene exchange. However, the mechanism by which GTAs deliver DNA into cells is unknown. Here we present the structure of the GTA of Rhodobacter capsulatus (RcGTA) and describe the conformational changes required for its DNA ejection. The structure of RcGTA resembles that of a tailed phage, but it has an oblate head shortened in the direction of the tail axis, which limits its packaging capacity to less than 4,500 base pairs of linear double-stranded DNA. The tail channel of RcGTA contains a trimer of proteins that possess features of both tape measure proteins of long-tailed phages from the family Siphoviridae and tail needle proteins of short-tailed phages from the family Podoviridae. The opening of a constriction within the RcGTA baseplate enables the ejection of DNA into bacterial periplasm.

Published

2020

17. Structure and genome ejection mechanism of Staphylococcus aureus phage P68.

Author

Hrebík D, Štveráková D, Škubník K, Füzik T, Pantůček R, and Plevka P

Subjects

Capsid Proteins genetics, Cell Membrane genetics, Cytoplasm genetics, DNA, Viral genetics, Virion genetics, Bacteriophages genetics, Genome, Viral genetics, Staphylococcus aureus genetics

Abstract

Phages infecting Staphylococcus aureus can be used as therapeutics against antibiotic-resistant bacterial infections. However, there is limited information about the mechanism of genome delivery of phages that infect Gram-positive bacteria. Here, we present the structures of native S. aureus phage P68, genome ejection intermediate, and empty particle. The P68 head contains 72 subunits of inner core protein, 15 of which bind to and alter the structure of adjacent major capsid proteins and thus specify attachment sites for head fibers. Unlike in the previously studied phages, the head fibers of P68 enable its virion to position itself at the cell surface for genome delivery. The unique interaction of one end of P68 DNA with one of the 12 portal protein subunits is disrupted before the genome ejection. The inner core proteins are released together with the DNA and enable the translocation of phage genome across the bacterial membrane into the cytoplasm., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2019

18. Enterovirus particles expel capsid pentamers to enable genome release.

Author

Buchta D, Füzik T, Hrebík D, Levdansky Y, Sukeník L, Mukhamedova L, Moravcová J, Vácha R, and Plevka P

Subjects

Animals, Capsid chemistry, Chlorocebus aethiops, Cryoelectron Microscopy, Enterovirus B, Human genetics, Epithelial Cells ultrastructure, Epithelial Cells virology, Humans, Hydrogen-Ion Concentration, Molecular Dynamics Simulation, RNA, Double-Stranded chemistry, RNA, Double-Stranded genetics, RNA, Viral chemistry, Virion genetics, Capsid ultrastructure, Enterovirus B, Human ultrastructure, Genome, Viral, RNA, Viral genetics, Virion ultrastructure, Virus Uncoating genetics

Abstract

Viruses from the genus Enterovirus are important human pathogens. Receptor binding or exposure to acidic pH in endosomes converts enterovirus particles to an activated state that is required for genome release. However, the mechanism of enterovirus uncoating is not well understood. Here, we use cryo-electron microscopy to visualize virions of human echovirus 18 in the process of genome release. We discover that the exit of the RNA from the particle of echovirus 18 results in a loss of one, two, or three adjacent capsid-protein pentamers. The opening in the capsid, which is more than 120 Å in diameter, enables the release of the genome without the need to unwind its putative double-stranded RNA segments. We also detect capsids lacking pentamers during genome release from echovirus 30. Thus, our findings uncover a mechanism of enterovirus genome release that could become target for antiviral drugs.

Published

2019

19. Conserved cysteines in Mason-Pfizer monkey virus capsid protein are essential for infectious mature particle formation.

Author

Píchalová R, Füzik T, Vokatá B, Rumlová M, Llano M, Dostálková A, Křížová I, Ruml T, and Ulbrich P

Subjects

Capsid Proteins chemistry, Cell Line, Genetic Vectors, HEK293 Cells, Humans, Mason-Pfizer monkey virus physiology, Mutation, Proviruses genetics, Virion physiology, Capsid Proteins genetics, Cysteine genetics, Mason-Pfizer monkey virus genetics, Virus Assembly

Abstract

Retrovirus assembly is driven mostly by Gag polyprotein oligomerization, which is mediated by inter and intra protein-protein interactions among its capsid (CA) domains. Mason-Pfizer monkey virus (M-PMV) CA contains three cysteines (C82, C193 and C213), where the latter two are highly conserved among most retroviruses. To determine the importance of these cysteines, we introduced mutations of these residues in both bacterial and proviral vectors and studied their impact on the M-PMV life cycle. These studies revealed that the presence of both conserved cysteines of M-PMV CA is necessary for both proper assembly and virus infectivity. Our findings suggest a crucial role of these cysteines in the formation of infectious mature particles., (Copyright © 2018. Published by Elsevier Inc.)

Published

2018

20. Virion structure and genome delivery mechanism of sacbrood honeybee virus.

Author

Procházková M, Füzik T, Škubník K, Moravcová J, Ubiparip Z, Přidal A, and Plevka P

Subjects

Animals, Crystallography, X-Ray, Endosomes chemistry, Endosomes metabolism, Bees virology, Capsid Proteins chemistry, Capsid Proteins metabolism, Endosomes virology, Genome, Viral, RNA Viruses chemistry, RNA Viruses metabolism, Virion chemistry, Virion metabolism

Abstract

Infection by sacbrood virus (SBV) from the family Iflaviridae is lethal to honey bee larvae but only rarely causes the collapse of honey bee colonies. Despite the negative effect of SBV on honey bees, the structure of its particles and mechanism of its genome delivery are unknown. Here we present the crystal structure of SBV virion and show that it contains 60 copies of a minor capsid protein (MiCP) attached to the virion surface. No similar MiCPs have been previously reported in any of the related viruses from the order Picornavirales. The location of the MiCP coding sequence within the SBV genome indicates that the MiCP evolved from a C-terminal extension of a major capsid protein by the introduction of a cleavage site for a virus protease. The exposure of SBV to acidic pH, which the virus likely encounters during cell entry, induces the formation of pores at threefold and fivefold axes of the capsid that are 7 Å and 12 Å in diameter, respectively. This is in contrast to vertebrate picornaviruses, in which the pores along twofold icosahedral symmetry axes are currently considered the most likely sites for genome release. SBV virions lack VP4 subunits that facilitate the genome delivery of many related dicistroviruses and picornaviruses. MiCP subunits induce liposome disruption in vitro, indicating that they are functional analogs of VP4 subunits and enable the virus genome to escape across the endosome membrane into the cell cytoplasm., Competing Interests: The authors declare no conflict of interest., (Copyright © 2018 the Author(s). Published by PNAS.)

Published

2018

21. Description and Comparative Genomics of Macrococcus caseolyticus subsp. hominis subsp. nov., Macrococcus goetzii sp. nov., Macrococcus epidermidis sp. nov., and Macrococcus bohemicus sp. nov., Novel Macrococci From Human Clinical Material With Virulence Potential and Suspected Uptake of Foreign DNA by Natural Transformation.

Author

Mašlaňová I, Wertheimer Z, Sedláček I, Švec P, Indráková A, Kovařovic V, Schumann P, Spröer C, Králová S, Šedo O, Krištofová L, Vrbovská V, Füzik T, Petráš P, Zdráhal Z, Ružičková V, Doškař J, and Pantuček R

Abstract

The genus Macrococcus is a close relative of the genus Staphylococcus . Whilst staphylococci are widespread as human pathogens, macrococci have not yet been reported from human clinical specimens. Here we investigated Gram-positive and catalase-positive cocci recovered from human clinical material and identified as Macrococcus sp. by a polyphasic taxonomic approach and by comparative genomics. Relevant phenotypic, genotypic and chemotaxonomic methods divided the analyzed strains into two separate clusters within the genus Macrococcus . Comparative genomics of four representative strains revealed enormous genome structural plasticity among the studied isolates. We hypothesize that high genomic variability is due to the presence of a com operon, which plays a key role in the natural transformation of bacilli and streptococci. The possible uptake of exogenous DNA by macrococci can contribute to a different mechanism of evolution from staphylococci, where phage-mediated horizontal gene transfer predominates. The described macrococcal genomes harbor novel plasmids, genomic islands and islets, as well as prophages. Capsule gene clusters, intracellular protease, and a fibronectin-binding protein enabling opportunistic pathogenesis were found in all four strains. Furthermore, the presence of a CRISPR-Cas system with 90 spacers in one of the sequenced genomes corresponds with the need to limit the burden of foreign DNA. The highly dynamic genomes could serve as a platform for the exchange of virulence and resistance factors, as was described for the methicillin resistance gene, which was found on the novel composite SCC mec -like element containing a unique mec gene complex that is considered to be one of the missing links in SCC evolution. The phenotypic, genotypic, chemotaxonomic and genomic results demonstrated that the analyzed strains represent one novel subspecies and three novel species of the genus Macrococcus , for which the names Macrococcus caseolyticus subsp. hominis subsp. nov. (type strain CCM 7927 T = DSM 103682 T ), Macrococcus goetzii sp. nov. (type strain CCM 4927 T = DSM 103683 T ), Macrococcus epidermidis sp. nov. (type strain CCM 7099 T = DSM 103681 T ), and Macrococcus bohemicus sp. nov. (type strain CCM 7100 T = DSM 103680 T ) are proposed. Moreover, a formal description of Macrococcus caseolyticus subsp. caseolyticus subsp. nov. and an emended description of the genus Macrococcus are provided.

Published

2018

22. Structure of tick-borne encephalitis virus and its neutralization by a monoclonal antibody.

Author

Füzik T, Formanová P, Růžek D, Yoshii K, Niedrig M, and Plevka P

Subjects

Antibodies, Neutralizing biosynthesis, Antibodies, Viral biosynthesis, Cell Line, Tumor, Cryoelectron Microscopy, Encephalitis Viruses, Tick-Borne genetics, Encephalitis Viruses, Tick-Borne metabolism, Gene Expression, Humans, Hydrogen-Ion Concentration, Immunoglobulin Fab Fragments biosynthesis, Membrane Fusion genetics, Neurons pathology, Neurons virology, Protein Domains, Protein Multimerization, Viral Proteins genetics, Viral Proteins metabolism, Virion genetics, Virion metabolism, Virus Internalization, Antibodies, Neutralizing chemistry, Antibodies, Viral chemistry, Encephalitis Viruses, Tick-Borne ultrastructure, Immunoglobulin Fab Fragments chemistry, Viral Proteins chemistry, Virion ultrastructure

Abstract

Tick-borne encephalitis virus (TBEV) causes 13,000 cases of human meningitis and encephalitis annually. However, the structure of the TBEV virion and its interactions with antibodies are unknown. Here, we present cryo-EM structures of the native TBEV virion and its complex with Fab fragments of neutralizing antibody 19/1786. Flavivirus genome delivery depends on membrane fusion that is triggered at low pH. The virion structure indicates that the repulsive interactions of histidine side chains, which become protonated at low pH, may contribute to the disruption of heterotetramers of the TBEV envelope and membrane proteins and induce detachment of the envelope protein ectodomains from the virus membrane. The Fab fragments bind to 120 out of the 180 envelope glycoproteins of the TBEV virion. Unlike most of the previously studied flavivirus-neutralizing antibodies, the Fab fragments do not lock the E-proteins in the native-like arrangement, but interfere with the process of virus-induced membrane fusion.

Published

2018

23. Structure of deformed wing virus, a major honey bee pathogen.

Author

Škubník K, Nováček J, Füzik T, Přidal A, Paxton RJ, and Plevka P

Subjects

Amino Acid Sequence, Animals, Capsid ultrastructure, Capsid Proteins chemistry, Capsid Proteins ultrastructure, Cryoelectron Microscopy, Image Processing, Computer-Assisted, Models, Molecular, Protein Conformation, Protein Domains, Virion ultrastructure, Bees virology, Insect Viruses ultrastructure, RNA Viruses ultrastructure

Abstract

The worldwide population of western honey bees ( Apis mellifera ) is under pressure from habitat loss, environmental stress, and pathogens, particularly viruses that cause lethal epidemics. Deformed wing virus (DWV) from the family Iflaviridae , together with its vector, the mite Varroa destructor , is likely the major threat to the world's honey bees. However, lack of knowledge of the atomic structures of iflaviruses has hindered the development of effective treatments against them. Here, we present the virion structures of DWV determined to a resolution of 3.1 Å using cryo-electron microscopy and 3.8 Å by X-ray crystallography. The C-terminal extension of capsid protein VP3 folds into a globular protruding (P) domain, exposed on the virion surface. The P domain contains an Asp-His-Ser catalytic triad that is, together with five residues that are spatially close, conserved among iflaviruses. These residues may participate in receptor binding or provide the protease, lipase, or esterase activity required for entry of the virus into a host cell. Furthermore, nucleotides of the DWV RNA genome interact with VP3 subunits. The capsid protein residues involved in the RNA binding are conserved among honey bee iflaviruses, suggesting a putative role of the genome in stabilizing the virion or facilitating capsid assembly. Identifying the RNA-binding and putative catalytic sites within the DWV virion structure enables future analyses of how DWV and other iflaviruses infect insect cells and also opens up possibilities for the development of antiviral treatments.

Published

2017

24. Cryo-electron Microscopy Study of the Genome Release of the Dicistrovirus Israeli Acute Bee Paralysis Virus.

Author

Mullapudi E, Füzik T, Přidal A, and Plevka P

Subjects

Animals, Bees virology, Capsid metabolism, Capsid Proteins chemistry, Capsid Proteins genetics, Models, Molecular, Protein Conformation, Virion physiology, Virion ultrastructure, Virus Assembly, Cryoelectron Microscopy, Dicistroviridae physiology, Dicistroviridae ultrastructure, Genome, Viral, Virus Uncoating

Abstract

Viruses of the family Dicistroviridae can cause substantial economic damage by infecting agriculturally important insects. Israeli acute bee paralysis virus (IAPV) causes honeybee colony collapse disorder in the United States. High-resolution molecular details of the genome delivery mechanism of dicistroviruses are unknown. Here we present a cryo-electron microscopy analysis of IAPV virions induced to release their genomes in vitro We determined structures of full IAPV virions primed to release their genomes to a resolution of 3.3 Å and of empty capsids to a resolution of 3.9 Å. We show that IAPV does not form expanded A particles before genome release as in the case of related enteroviruses of the family Picornaviridae The structural changes observed in the empty IAPV particles include detachment of the VP4 minor capsid proteins from the inner face of the capsid and partial loss of the structure of the N-terminal arms of the VP2 capsid proteins. Unlike the case for many picornaviruses, the empty particles of IAPV are not expanded relative to the native virions and do not contain pores in their capsids that might serve as channels for genome release. Therefore, rearrangement of a unique region of the capsid is probably required for IAPV genome release., Importance: Honeybee populations in Europe and North America are declining due to pressure from pathogens, including viruses. Israeli acute bee paralysis virus (IAPV), a member of the family Dicistroviridae, causes honeybee colony collapse disorder in the United States. The delivery of virus genomes into host cells is necessary for the initiation of infection. Here we present a structural cryo-electron microscopy analysis of IAPV particles induced to release their genomes. We show that genome release is not preceded by an expansion of IAPV virions as in the case of related picornaviruses that infect vertebrates. Furthermore, minor capsid proteins detach from the capsid upon genome release. The genome leaves behind empty particles that have compact protein shells., (Copyright © 2017 Mullapudi et al.)

Published

2017

25. Cryo-EM study of slow bee paralysis virus at low pH reveals iflavirus genome release mechanism.

Author

Kalynych S, Füzik T, Přidal A, de Miranda J, and Plevka P

Subjects

Animals, Capsid ultrastructure, Capsid Proteins chemistry, Capsid Proteins ultrastructure, Cryoelectron Microscopy, Dicistroviridae genetics, Dicistroviridae physiology, Dicistroviridae ultrastructure, Genome, Viral, Hydrogen-Ion Concentration, Insect Viruses physiology, Models, Molecular, Picornaviridae physiology, Protein Conformation, Static Electricity, Virus Uncoating physiology, Bees virology, Insect Viruses genetics, Insect Viruses ultrastructure, Picornaviridae genetics, Picornaviridae ultrastructure

Abstract

Viruses from the family Iflaviridae are insect pathogens. Many of them, including slow bee paralysis virus (SBPV), cause lethal diseases in honeybees and bumblebees, resulting in agricultural losses. Iflaviruses have nonenveloped icosahedral virions containing single-stranded RNA genomes. However, their genome release mechanism is unknown. Here, we show that low pH promotes SBPV genome release, indicating that the virus may use endosomes to enter host cells. We used cryo-EM to study a heterogeneous population of SBPV virions at pH 5.5. We determined the structures of SBPV particles before and after genome release to resolutions of 3.3 and 3.4 Å, respectively. The capsids of SBPV virions in low pH are not expanded. Thus, SBPV does not appear to form "altered" particles with pores in their capsids before genome release, as is the case in many related picornaviruses. The egress of the genome from SBPV virions is associated with a loss of interpentamer contacts mediated by N-terminal arms of VP2 capsid proteins, which result in the expansion of the capsid. Pores that are 7 Å in diameter form around icosahedral threefold symmetry axes. We speculate that they serve as channels for the genome release. Our findings provide an atomic-level characterization of the genome release mechanism of iflaviruses., Competing Interests: The authors declare no conflict of interest.

Published

2017

26. Structure of Aichi Virus 1 and Its Empty Particle: Clues to Kobuvirus Genome Release Mechanism.

Author

Sabin C, Füzik T, Škubník K, Pálková L, Lindberg AM, and Plevka P

Abstract

Aichi virus 1 (AiV-1) is a human pathogen from the Kobuvirus genus of the Picornaviridae family. Worldwide, 80 to 95% of adults have antibodies against the virus. AiV-1 infections are associated with nausea, gastroenteritis, and fever. Unlike most picornaviruses, kobuvirus capsids are composed of only three types of subunits: VP0, VP1, and VP3. We present here the structure of the AiV-1 virion determined to a resolution of 2.1 Å using X-ray crystallography. The surface loop puff of VP0 and knob of VP3 in AiV-1 are shorter than those in other picornaviruses. Instead, the 42-residue BC loop of VP0 forms the most prominent surface feature of the AiV-1 virion. We determined the structure of AiV-1 empty particle to a resolution of 4.2 Å using cryo-electron microscopy. The empty capsids are expanded relative to the native virus. The N-terminal arms of capsid proteins VP0, which mediate contacts between the pentamers of capsid protein protomers in the native AiV-1 virion, are disordered in the empty capsid. Nevertheless, the empty particles are stable, at least in vitro , and do not contain pores that might serve as channels for genome release. Therefore, extensive and probably reversible local reorganization of AiV-1 capsid is required for its genome release. IMPORTANCE Aichi virus 1 (AiV-1) is a human pathogen that can cause diarrhea, abdominal pain, nausea, vomiting, and fever. AiV-1 is identified in environmental screening studies with higher frequency and greater abundance than other human enteric viruses. Accordingly, 80 to 95% of adults worldwide have suffered from AiV-1 infections. We determined the structure of the AiV-1 virion. Based on the structure, we show that antiviral compounds that were developed against related enteroviruses are unlikely to be effective against AiV-1. The surface of the AiV-1 virion has a unique topology distinct from other related viruses from the Picornaviridae family. We also determined that AiV-1 capsids form compact shells even after genome release. Therefore, AiV-1 genome release requires large localized and probably reversible reorganization of the capsid., (Copyright © 2016 Sabin et al.)

Published

2016

27. Nucleic Acid Binding by Mason-Pfizer Monkey Virus CA Promotes Virus Assembly and Genome Packaging.

Author

Füzik T, Píchalová R, Schur FKM, Strohalmová K, Křížová I, Hadravová R, Rumlová M, Briggs JAG, Ulbrich P, and Ruml T

Subjects

Amino Acid Sequence, Amino Acid Substitution, Capsid Proteins genetics, Cell Line, Cryoelectron Microscopy, Gene Products, gag, Humans, Mason-Pfizer monkey virus ultrastructure, Mutation, Protein Binding, Protein Transport, Recombinant Proteins, Capsid Proteins metabolism, Genome, Viral, Mason-Pfizer monkey virus physiology, RNA, Viral metabolism, Virus Assembly genetics

Abstract

Unlabelled: The Gag polyprotein of retroviruses drives immature virus assembly by forming hexameric protein lattices. The assembly is primarily mediated by protein-protein interactions between capsid (CA) domains and by interactions between nucleocapsid (NC) domains and RNA. Specific interactions between NC and the viral RNA are required for genome packaging. Previously reported cryoelectron microscopy analysis of immature Mason-Pfizer monkey virus (M-PMV) particles suggested that a basic region (residues RKK) in CA may serve as an additional binding site for nucleic acids. Here, we have introduced mutations into the RKK region in both bacterial and proviral M-PMV vectors and have assessed their impact on M-PMV assembly, structure, RNA binding, budding/release, nuclear trafficking, and infectivity using in vitro and in vivo systems. Our data indicate that the RKK region binds and structures nucleic acid that serves to promote virus particle assembly in the cytoplasm. Moreover, the RKK region appears to be important for recruitment of viral genomic RNA into Gag particles, and this function could be linked to changes in nuclear trafficking. Together these observations suggest that in M-PMV, direct interactions between CA and nucleic acid play important functions in the late stages of the viral life cycle., Importance: Assembly of retrovirus particles is driven by the Gag polyprotein, which can self-assemble to form virus particles and interact with RNA to recruit the viral genome into the particles. Generally, the capsid domains of Gag contribute to essential protein-protein interactions during assembly, while the nucleocapsid domain interacts with RNA. The interactions between the nucleocapsid domain and RNA are important both for identifying the genome and for self-assembly of Gag molecules. Here, we show that a region of basic residues in the capsid protein of the betaretrovirus Mason-Pfizer monkey virus (M-PMV) contributes to interaction of Gag with nucleic acid. This interaction appears to provide a critical scaffolding function that promotes assembly of virus particles in the cytoplasm. It is also crucial for packaging the viral genome and thus for infectivity. These data indicate that, surprisingly, interactions between the capsid domain and RNA play an important role in the assembly of M-PMV., (Copyright © 2016, American Society for Microbiology. All Rights Reserved.)

Published

2016

28. Mitigation of Fe(0) nanoparticles toxicity to Trichosporon cutaneum by humic substances.

Author

Pádrová K, Maťátková O, Šiková M, Füzik T, Masák J, Čejková A, and Jirků V

Subjects

Static Electricity, Trichosporon growth & development, Trichosporon ultrastructure, Humic Substances analysis, Iron toxicity, Metal Nanoparticles toxicity, Trichosporon drug effects

Abstract

Zero-valent iron nanoparticles (nZVI) are a relatively new option for the treatment of contaminated soil and groundwater. However, because of their apparent toxicity, nZVI in high concentrations are known to interfere with many autochthonous microorganisms and, thus, impact their participation in the remediation process. The effect of two commercially available nZVI products, Nanofer 25 (non-stabilized) and Nanofer 25S (stabilized), was examined. Considerable toxicity to the soil yeast Trichosporon cutaneum was observed. Two chemically different humic substances (HSs) were studied as a possible protection agent that mitigates nZVI toxicity: oxidized oxyhumolite X6 and humic acid X3A. The effect of addition of HSs was studied in different phases of the experiment to establish the effect on cells and nZVI. SEM and TEM images revealed an ability of both types of nZVI and HSs to adsorb on surface of the cells. Changes in cell surface properties were also observed by zeta potential measurements. Our results indicate that HSs can act as an electrosteric barrier, which hinders mutual interaction between nZVI and treated cell. Thus, the application of HS seems to be a promising solution to mitigating the toxic action of nZVI., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

29. Efficient Mutagenesis Independent of Ligation (EMILI).

Author

Füzik T, Ulbrich P, and Ruml T

Subjects

Mutagenesis, Insertional, Point Mutation, Sequence Deletion, Molecular Biology methods, Mutagenesis

Abstract

Site-directed mutagenesis is one of the most widely used techniques in life sciences. Here we describe an improved and simplified method for introducing mutations at desired sites. It consists of an inverse PCR using a plasmid template and two partially complementary primers. The synthesis step is followed by annealing of the PCR product's sticky ends, which are generated by exonuclease digestion. This method is fast, extremely efficient and cost-effective. It can be used to introduce large insertions and deletions, but also for multiple point mutations in a single step. To show the principle and to prove the efficiency of the method, we present a series of basic mutations (insertions, deletions, point mutations) on pUC19 plasmid DNA., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014