Your search keyword '"VP35"' showing total 149 results

1. Structural and Dynamical Basis of VP35-RBD Inhibition by Marine Fungi Compounds to Combat Marburg Virus Infection.

Author

Alawam, Abdullah S., Alawam, Hadil Sultan, Alshahrani, Mohammed Merae, Alwethaynani, Maher S., Alneghery, Lina M., and Alamri, Mubarak A.

Abstract

The Marburg virus (MBV), a deadly pathogen, poses a serious threat to world health due to the lack of effective treatments, calling for an immediate search for targeted and efficient treatments. In this study, we focused on compounds originating from marine fungi in order to identify possible inhibitory compounds against the Marburg virus (MBV) VP35-RNA binding domain (VP35-RBD) using a computational approach. We started with a virtual screening procedure using the Lipinski filter as a guide. Based on their docking scores, 42 potential candidates were found. Four of these compounds—CMNPD17596, CMNPD22144, CMNPD25994, and CMNPD17598—as well as myricetin, the control compound, were chosen for re-docking analysis. Re-docking revealed that these particular compounds had a higher affinity for MBV VP35-RBD in comparison to the control. Analyzing the chemical interactions revealed unique binding properties for every compound, identified by a range of Pi–cation interactions and hydrogen bond types. We were able to learn more about the dynamic behaviors and stability of the protein–ligand complexes through a 200-nanosecond molecular dynamics simulation, as demonstrated by the compounds' consistent RMSD and RMSF values. The multidimensional nature of the data was clarified by the application of principal component analysis, which suggested stable conformations in the complexes with little modification. Further insight into the energy profiles and stability states of these complexes was also obtained by an examination of the free energy landscape. Our findings underscore the effectiveness of computational strategies in identifying and analyzing potential inhibitors for MBV VP35-RBD, offering promising paths for further experimental investigations and possible therapeutic development against the MBV. [ABSTRACT FROM AUTHOR]

Published

2024

2. Ebola virus sequesters IRF3 in viral inclusion bodies to evade host antiviral immunity

Author

Lin Zhu, Jing Jin, Tingting Wang, Yong Hu, Hainan Liu, Ting Gao, Qincai Dong, Yanwen Jin, Ping Li, Zijing Liu, Yi Huang, Xuan Liu, and Cheng Cao

Subjects

Ebola virus, VP35, VP24, virus infection, virus inclusion bodies, Medicine, Science, Biology (General), QH301-705.5

Abstract

Viral inclusion bodies (IBs) commonly form during the replication of Ebola virus (EBOV) in infected cells, but their role in viral immune evasion has rarely been explored. Here, we found that interferon regulatory factor 3 (IRF3), but not TANK-binding kinase 1 (TBK1) or IκB kinase epsilon (IKKε), was recruited and sequestered in viral IBs when the cells were infected by EBOV transcription- and replication-competent virus-like particles (trVLPs). Nucleoprotein/virion protein 35 (VP35)-induced IBs formation was critical for IRF3 recruitment and sequestration, probably through interaction with STING. Consequently, the association of TBK1 and IRF3, which plays a vital role in type I interferon (IFN-I) induction, was blocked by EBOV trVLPs infection. Additionally, IRF3 phosphorylation and nuclear translocation induced by Sendai virus or poly(I:C) stimulation were suppressed by EBOV trVLPs. Furthermore, downregulation of STING significantly attenuated VP35-induced IRF3 accumulation in IBs. Coexpression of the viral proteins by which IB-like structures formed was much more potent in antagonizing IFN-I than expression of the IFN-I antagonist VP35 alone. These results suggested a novel immune evasion mechanism by which EBOV evades host innate immunity.

Published

2024

3. Novel Antiviral Molecules against Ebola Virus Infection.

Author

Collados Rodríguez, Mila, Maillard, Patrick, Journeaux, Alexandra, Komarova, Anastassia V., Najburg, Valérie, David, Raul-Yusef Sanchez, Helynck, Olivier, Guo, Mingzhe, Zhong, Jin, Baize, Sylvain, Tangy, Frédéric, Jacob, Yves, Munier-Lehmann, Hélène, and Meurs, Eliane F.

Subjects

*EBOLA virus disease, *MEASLES virus, *HEMORRHAGIC fever, *RNA viruses, *EBOLA virus, *CHEMICAL libraries

Abstract

Infection with Ebola virus (EBOV) is responsible for hemorrhagic fever in humans with a high mortality rate. Combined efforts of prevention and therapeutic intervention are required to tackle highly variable RNA viruses, whose infections often lead to outbreaks. Here, we have screened the 2P2I3D chemical library using a nanoluciferase-based protein complementation assay (NPCA) and isolated two compounds that disrupt the interaction of the EBOV protein fragment VP35IID with the N-terminus of the dsRNA-binding proteins PKR and PACT, involved in IFN response and/or intrinsic immunity, respectively. The two compounds inhibited EBOV infection in cell culture as well as infection by measles virus (MV) independently of IFN induction. Consequently, we propose that the compounds are antiviral by restoring intrinsic immunity driven by PACT. Given that PACT is highly conserved across mammals, our data support further testing of the compounds in other species, as well as against other negative-sense RNA viruses. [ABSTRACT FROM AUTHOR]

Published

2023

4. Cheminformatics Strategies Unlock Marburg Virus VP35 Inhibitors from Natural Compound Library.

Author

Alsaady, Isra M., Bajrai, Leena H., Alandijany, Thamir A., Gattan, Hattan S., El-Daly, Mai M., Altwaim, Sarah A., Alqawas, Rahaf T., Dwivedi, Vivek Dhar, and Azhar, Esam I.

Subjects

*MARBURG virus, *CHEMICAL libraries, *VIRUS inhibitors, *ESTRADIOL benzoate, *BINDING energy, *EBOLA virus

Abstract

The Ebola virus and its close relative, the Marburg virus, both belong to the family Filoviridae and are highly hazardous and contagious viruses. With a mortality rate ranging from 23% to 90%, depending on the specific outbreak, the development of effective antiviral interventions is crucial for reducing fatalities and mitigating the impact of Marburg virus outbreaks. In this investigation, a virtual screening approach was employed to evaluate 2042 natural compounds for their potential interactions with the VP35 protein of the Marburg virus. Average and worst binding energies were calculated for all 20 poses, and compounds that exhibited binding energies <−6 kcal/mol in both criteria were selected for further analysis. Based on binding energies, only six compounds (Estradiol benzoate, INVEGA (paliperidone), Isosilybin, Protopanaxadiol, Permethrin, and Bufalin) were selected for subsequent investigations, focusing on interaction analysis. Among these selected compounds, Estradiol benzoate, INVEGA (paliperidone), and Isosilybin showed strong hydrogen bonds, while the others did not. In this study, the compounds Myricetin, Isosilybin, and Estradiol benzoate were subjected to a molecular dynamics (MD) simulation and free binding energy calculation using MM/GBSA analysis. The reference component Myricetin served as a control. Estradiol benzoate exhibited the most stable and consistent root-mean-square deviation (RMSD) values, whereas Isosilybin showed significant fluctuations in RMSD. The compound Estradiol benzoate exhibited the lowest ΔG binding free energy (−22.89 kcal/mol), surpassing the control compound's binding energy (−9.29 kcal/mol). Overall, this investigation suggested that Estradiol benzoate possesses favorable binding free energies, indicating a potential inhibitory mechanism against the VP35 protein of the Marburg virus. The study proposes that these natural compounds could serve as a therapeutic option for preventing Marburg virus infection. However, experimental validation is required to further corroborate these findings. [ABSTRACT FROM AUTHOR]

Published

2023

5. Structural and Dynamical Basis of VP35-RBD Inhibition by Marine Fungi Compounds to Combat Marburg Virus Infection

Author

Abdullah S. Alawam, Hadil Sultan Alawam, Mohammed Merae Alshahrani, Maher S. Alwethaynani, Lina M. Alneghery, and Mubarak A. Alamri

Subjects

Marburg virus, marine fungi, VP35, RNA binding domain, Biology (General), QH301-705.5

Abstract

The Marburg virus (MBV), a deadly pathogen, poses a serious threat to world health due to the lack of effective treatments, calling for an immediate search for targeted and efficient treatments. In this study, we focused on compounds originating from marine fungi in order to identify possible inhibitory compounds against the Marburg virus (MBV) VP35-RNA binding domain (VP35-RBD) using a computational approach. We started with a virtual screening procedure using the Lipinski filter as a guide. Based on their docking scores, 42 potential candidates were found. Four of these compounds—CMNPD17596, CMNPD22144, CMNPD25994, and CMNPD17598—as well as myricetin, the control compound, were chosen for re-docking analysis. Re-docking revealed that these particular compounds had a higher affinity for MBV VP35-RBD in comparison to the control. Analyzing the chemical interactions revealed unique binding properties for every compound, identified by a range of Pi–cation interactions and hydrogen bond types. We were able to learn more about the dynamic behaviors and stability of the protein–ligand complexes through a 200-nanosecond molecular dynamics simulation, as demonstrated by the compounds’ consistent RMSD and RMSF values. The multidimensional nature of the data was clarified by the application of principal component analysis, which suggested stable conformations in the complexes with little modification. Further insight into the energy profiles and stability states of these complexes was also obtained by an examination of the free energy landscape. Our findings underscore the effectiveness of computational strategies in identifying and analyzing potential inhibitors for MBV VP35-RBD, offering promising paths for further experimental investigations and possible therapeutic development against the MBV.

Published

2024

6. Structure-Based Virtual Screening of Phytochemicals from Phyllanthus Amarus as Potent Inhibitory Phytocompounds Against Marburg Virus Disease.

Author

Singh, Neeharika and Singh, Prem Pal

Subjects

MARBURG virus disease, PHYLLANTHUS, PHYTOCHEMICALS, ANTIVIRAL agents, MEDICAL screening

Published

2023

7. Novel Antiviral Molecules against Ebola Virus Infection

Author

Mila Collados Rodríguez, Patrick Maillard, Alexandra Journeaux, Anastassia V. Komarova, Valérie Najburg, Raul-Yusef Sanchez David, Olivier Helynck, Mingzhe Guo, Jin Zhong, Sylvain Baize, Frédéric Tangy, Yves Jacob, Hélène Munier-Lehmann, and Eliane F. Meurs

Subjects

Ebola virus, measles virus, VP35, PKR, PACT, RIG-I, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Infection with Ebola virus (EBOV) is responsible for hemorrhagic fever in humans with a high mortality rate. Combined efforts of prevention and therapeutic intervention are required to tackle highly variable RNA viruses, whose infections often lead to outbreaks. Here, we have screened the 2P2I3D chemical library using a nanoluciferase-based protein complementation assay (NPCA) and isolated two compounds that disrupt the interaction of the EBOV protein fragment VP35IID with the N-terminus of the dsRNA-binding proteins PKR and PACT, involved in IFN response and/or intrinsic immunity, respectively. The two compounds inhibited EBOV infection in cell culture as well as infection by measles virus (MV) independently of IFN induction. Consequently, we propose that the compounds are antiviral by restoring intrinsic immunity driven by PACT. Given that PACT is highly conserved across mammals, our data support further testing of the compounds in other species, as well as against other negative-sense RNA viruses.

Published

2023

8. Hsp90 Regulates GCRV-II Proliferation by Interacting with VP35 as Its Receptor and Chaperone.

Author

Lin Jiang, An-qi Liu, Chu Zhang, Yong-An Zhang, and Jiagang Tu

Subjects

*HEAT shock proteins, *CTENOPHARYNGODON idella, *MOLECULAR chaperones, *ENDOCYTOSIS, *LIFE cycles (Biology), *RECOMBINANT proteins, *HEMORRHAGIC diseases

Abstract

The frequent outbreak of grass carp hemorrhagic disease caused by grass carp reovirus (GCRV), especially the mainly prevalent type II GCRV (GCRV-II), has seriously affected the grass carp culture in China. However, its pathogenic mechanism is still far from clear. In this study, the GCRV-II outer capsid protein VP35 was used as bait to capture interacting partners from Ctenopharyngon idellus kidney (CIK) cells, and heat shock protein 90 (Hsp90) was selected and confirmed interacting with VP35 through the C-terminal domain of Hsp90. Knockdown of Hsp90 or inhibition of Hsp90 activity suppressed GCRV-II proliferation, demonstrating that Hsp90 is an essential factor for GCRV-II proliferation. The confocal microscopy and flow cytometry showed that Hsp90 localized at both membrane and cytoplasm of CIK cells. The entry of GCRV-II into CIK cells was efficiently blocked by incubating the cells with Hsp90 antibody or by pretreating the virus with recombinant Hsp90 protein. Whereas overexpression of Hsp90 in CIK cells, grass carp ovary (GCO) cells, or 293T cells promoted GCRV-II entry, indicating that the membrane Hsp90 functions as a receptor of GCRV-II. Furthermore, Hsp90 interacted with clathrin and mediated GCRV-II entry into CIK cells through clathrin endocytosis pathway. In addition, we found that the cytoplasmic Hsp90 acted as a chaperone of VP35 because inhibition of Hsp90 activity enhanced VP35 polyubiquitination and degraded VP35 through the proteasome pathway. Collectively, our data suggest that Hsp90 functions both as a receptor for GCRV-II entry and a chaperone for the maturation of GCRV-II VP35, thus ensuring efficient proliferation of GCRV-II. IMPORTANCE Identification of viral receptors has always been the research hot spot in virus research field as receptor functions at the first stage of viral infection, which can be designed as efficient antiviral drug targets. GCRV-II, the causative agent of the grass carp epidemic hemorrhagic disease, has caused tremendous losses in grass carp culture in China. To date, the receptor of GCRV-II remains unknown. This study focused on identifying cellular receptor interacting with the GCRV-II outer capsid protein VP35, studying the effects of their interaction on GCRV-II proliferation, and revealing the underlying mechanisms. We demonstrated that Hsp90 acts both as a receptor of GCRV-II by interacting with VP35 and as a chaperone for the maturation of VP35, thus ensuring efficient proliferation of GCRV-II. Our data provide important insights into the role of Hsp90 in GCRV-II life cycle, which will help understand the mechanism of reovirus infection. [ABSTRACT FROM AUTHOR]

Published

2022

9. Cheminformatics Strategies Unlock Marburg Virus VP35 Inhibitors from Natural Compound Library

Author

Isra M. Alsaady, Leena H. Bajrai, Thamir A. Alandijany, Hattan S. Gattan, Mai M. El-Daly, Sarah A. Altwaim, Rahaf T. Alqawas, Vivek Dhar Dwivedi, and Esam I. Azhar

Subjects

Marburg virus, VP35, natural compounds, isosilybin, Estradiol benzoate, virtual screening, Microbiology, QR1-502

Abstract

The Ebola virus and its close relative, the Marburg virus, both belong to the family Filoviridae and are highly hazardous and contagious viruses. With a mortality rate ranging from 23% to 90%, depending on the specific outbreak, the development of effective antiviral interventions is crucial for reducing fatalities and mitigating the impact of Marburg virus outbreaks. In this investigation, a virtual screening approach was employed to evaluate 2042 natural compounds for their potential interactions with the VP35 protein of the Marburg virus. Average and worst binding energies were calculated for all 20 poses, and compounds that exhibited binding energies

Published

2023

10. Identification of potential inhibitor against Ebola virus VP35: insight into virtual screening, pharmacoinformatics profiling, and molecular dynamic studies.

Author

Bhowmik, Ratul, Manaithiya, Ajay, Vyas, Bharti, Nath, Ranajit, Rehman, Sara, Roy, Shubham, and Roy, Ratna

Subjects

*EBOLA virus, *INTERFERON regulatory factors, *MOLECULAR interactions, *HEMORRHAGIC fever, *VIRUS inhibitors, *MEDICAL informatics

Abstract

The Ebola virus is a deadly pathogen that causes a highly lethal hemorrhagic fever illness in humans, sometimes known as Ebola virus sickness (EVD). The Ebola virus polymerase cofactor VP35 acts by preventing the establishment of a cellular antiviral state by blocking virus-induced phosphorylation and activation of interferon regulatory factor 3 (IRF3), a transcription factor required for the induction of interferons alpha and beta, thus making it an appealing therapeutic target because there are currently not many available and effective therapeutic agents available against this virus. This study presented a molecular docking–based virtual screening (VS) of 10,829 compounds acquired from multiple databases against the VP35 receptor using Auto Dock Vina software to discover potential inhibitors. According to the results of the screening, the top two drugs, irinotecan and fexofenadine, exhibited a high affinity for the VP35 binding region. Their binding affinities were −8.2 and −8.0 kJ/mol, indicating that they were tightly bound to the target receptor. These results outperformed those obtained with the co-crystallized ligand, which exhibited a binding affinity of −6.8 kJ/mol. As a result of the VS and molecular docking techniques, novel VP35 inhibitors from diverse databases were discovered using the Lipinski rule of five and functional molecular interactions with the target protein, as proven by the findings of this work. The findings suggest that the compounds discovered may offer viable avenues for the development of Ebola virus VP35 inhibitors and that they need further evaluation and investigation. [ABSTRACT FROM AUTHOR]

Published

2022

11. The Host E3-Ubiquitin Ligase TRIM6 Ubiquitinates the Ebola Virus VP35 Protein and Promotes Virus Replication

Author

Bharaj, Preeti, Atkins, Colm, Luthra, Priya, Giraldo, Maria Isabel, Dawes, Brian E, Miorin, Lisa, Johnson, Jeffrey R, Krogan, Nevan J, Basler, Christopher F, Freiberg, Alexander N, and Rajsbaum, Ricardo

Subjects

Prevention, Infectious Diseases, Vaccine Related, Immunization, Rare Diseases, Emerging Infectious Diseases, Biodefense, Aetiology, 2.2 Factors relating to the physical environment, 2.1 Biological and endogenous factors, Infection, Good Health and Well Being, Animals, Cell Line, Ebolavirus, Host-Pathogen Interactions, Humans, Immunoprecipitation, Mass Spectrometry, Tripartite Motif Proteins, Ubiquitin-Protein Ligases, Ubiquitination, Viral Regulatory and Accessory Proteins, Virus Replication, TRIM6, tripartite motif (TRIM) protein, VP35, viral RNA polymerase, Ebola virus, innate immunity, ubiquitination, unanchored ubiquitin, virus-host interactions, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences, Virology

Abstract

Ebola virus (EBOV), a member of the Filoviridae family, is a highly pathogenic virus that causes severe hemorrhagic fever in humans and is responsible for epidemics throughout sub-Saharan, central, and West Africa. The EBOV genome encodes VP35, an important viral protein involved in virus replication by acting as an essential cofactor of the viral polymerase as well as a potent antagonist of the host antiviral type I interferon (IFN-I) system. By using mass spectrometry analysis and coimmunoprecipitation assays, we show here that VP35 is ubiquitinated on lysine 309 (K309), a residue located on its IFN antagonist domain. We also found that VP35 interacts with TRIM6, a member of the E3-ubiquitin ligase tripartite motif (TRIM) family. We recently reported that TRIM6 promotes the synthesis of unanchored K48-linked polyubiquitin chains, which are not covalently attached to any protein, to induce efficient antiviral IFN-I-mediated responses. Consistent with this notion, VP35 also associated noncovalently with polyubiquitin chains and inhibited TRIM6-mediated IFN-I induction. Intriguingly, we also found that TRIM6 enhances EBOV polymerase activity in a minigenome assay and TRIM6 knockout cells have reduced replication of infectious EBOV, suggesting that VP35 hijacks TRIM6 to promote EBOV replication through ubiquitination. Our work provides evidence that TRIM6 is an important host cellular factor that promotes EBOV replication, and future studies will focus on whether TRIM6 could be targeted for therapeutic intervention against EBOV infection.IMPORTANCE EBOV belongs to a family of highly pathogenic viruses that cause severe hemorrhagic fever in humans and other mammals with high mortality rates (40 to 90%). Because of its high pathogenicity and lack of licensed antivirals and vaccines, EBOV is listed as a tier 1 select-agent risk group 4 pathogen. An important mechanism for the severity of EBOV infection is its suppression of innate immune responses. The EBOV VP35 protein contributes to pathogenesis, because it serves as an essential cofactor of the viral polymerase as well as a potent antagonist of innate immunity. However, how VP35 function is regulated by host cellular factors is poorly understood. Here, we report that the host E3-ubiquitin ligase TRIM6 promotes VP35 ubiquitination and is important for efficient virus replication. Therefore, our study identifies a new host factor, TRIM6, as a potential target in the development of antiviral drugs against EBOV.

Published

2017

12. Analysis of tissue tropism of GCRV-II infection in grass carp using a VP35 monoclonal antibody.

Author

Lu, Yanan, Zhao, Weihua, Ji, Ning, Xu, Dan, Li, Yaoguo, Xiao, Tiaoyi, Wang, Junya, and Zou, Jun

Subjects

*CTENOPHARYNGODON idella, *MONOCLONAL antibodies, *TISSUE analysis, *TROPISMS, *RECOMBINANT proteins

Abstract

Grass carp, one of the major freshwater aquaculture species in China, is susceptible to grass carp reovirus (GCRV). GCRV is a non-enveloped RNA virus and has a double-layered capsid, causing hemorrhagic disease and high mortalities in infected fish. However, the tropism of GCRV infection has not been investigated. In this study, monoclonal antibodies against recombinant VP35 protein were generated in mice and characterized. The antibodies exhibited specific binding to the N terminal region (1–155 aa) of the recombinant VP35 protein expressed in the HEK293 cells, and native VP35 protein in the GCRV-II infected CIK cells. Immunofluorescent staining revealed that viruses aggregated in the cytoplasm of infected cells. In vivo challenge experiments showed that high levels of GCRV-II viruses were present in the gills, intestine, spleen and liver, indicating that they are the major sites for virus infection. Our study showed that the VP35 antibodies generated in this study exhibited high specificity, and are valuable for the development of diagnostic tools for GCRV-II infection. • Monoclonal antibodies against GCRV-II VP35 were generated and characterized. • GCRV-II VP35 monoclonal antibodies could specifically detect GCRV-II in the CIK cells and tissues. • Gills, intestine, spleen and liver of GCRV-II infected grass carp showed high levels of viruses. [ABSTRACT FROM AUTHOR]

Published

2024

13. Epidemiological Trends and Current Challenges in Ebola: Pathogen Biology, Drug Targets, and Therapeutic Strategies

Author

Sharma, Sandeep, Gupta, Jeena, Hameed, Saif, editor, and Fatima, Zeeshan, editor

Published

2019

14. Differential Regulation of Interferon Responses by Ebola and Marburg Virus VP35 Proteins

Author

Basler, Christopher [Icahn School of Medicine at Mount Sinai, New York, NY (United States)]

Published

2016

15. Structural studies on a hepatitis C virus-related immunological complex and on Ebola virus polymerase cofactor VP35

Author

Fadda, Valeria and Taylor, Garry L.

Subjects

616.3, HCV, Hepatitis C virus-neutralizing antibody, Anti-idiotype, Immunological complex, VP35, Ebola virus, Molecular virology, Structural biology, X-ray crystallography, QR201.H46F2, Hepatitis C virus--Morphology, Ebola virus disease, Molecular virology

Abstract

Hepatitis C virus (HCV) is one of the leading causes of hepatocellular carcinoma worldwide. HCV-neutralizing antibody AP33 recognizes a linear, highly conserved epitope on the viral entry protein E2, disrupting the interaction with the cellular receptor CD81 that leads to viral entry. AP33-related anti-idiotypes (Ab₂s) have the potential to carry the internal image of the antigen E2, eliciting the production of AP33-like antibodies in humans. This study reports the mid-resolution structure of the Fab fragment of anti-idiotype A164.3 and the high-resolution structure of the Fab fragment of AP33 in complex with the Fv fragment of anti-idiotype B2.1A. Analysis of the structures and comparison with the previously published structure of AP33 in complex with a peptide corresponding to the E2 epitope, suggests that while A164.3 does not mimic the antigen E2, B2.1A is characterized by high surface complementarity with AP33 and functional antigen mimicry. Thus, B2.1A can be classified as an Ab₂-β, a subgroup of anti-idiotypes carrying the internal image of the antigen. Preliminary binding studies show that AP33 binds B2.1A with nanomolar affinity, supporting the role of B2.1A as an idiotypic vaccine candidate. Zaire ebola virus causes severe, often lethal hemorrhagic fever in humans. Ebola virus polymerase cofactor VP35 is a multifunctional protein involved in, among other functions, dsRNA binding and inhibition of the host's interferon pathways. VP35 contains an N-terminal oligomerization domain and a C-terminal dsRNA-binding domain (RBD). Preliminary results on the oligomerization domain of VP35 suggest that this region contains a coiled-coil motif, as previously reported. In order to validate a recently-discovered dsRNA end-capping pocket as a drug target, the structure of VP35 RBD I278A mutant was solved at high resolution, showing that even a small perturbation in the binding pocket can cause dramatic binding impairment due to loss of contacts with dsRNA.

Published

2015

16. Intracellular human antibody fragments recognizing the VP35 protein of Zaire Ebola filovirus inhibit the protein activity

Author

Michela Flego, Aldo Frau, Luisa Accardi, Alessandra Mallano, Alessandro Ascione, Mara Gellini, Elisa Fanunza, Stefano Vella, Paola Di Bonito, and Enzo Tramontano

Subjects

Zaire ebolavirus, VP35, scFv, Intrabody, Biotechnology, TP248.13-248.65

Abstract

Abstract Background Ebola hemorrhagic fever is caused by the Ebola filovirus (EBOV), which is one of the most aggressive infectious agents known worldwide. The EBOV pathogenesis starts with uncontrolled viral replication and subversion of both the innate and adaptive host immune response. The multifunctional viral VP35 protein is involved in this process by exerting an antagonistic action against the early antiviral alpha/beta interferon (IFN-α/β) response, and represents a suitable target for the development of strategies to control EBOV infection. Phage display technology permits to select antibodies as single chain Fragment variable (scFv) from an artificial immune system, due to their ability to specifically recognize the antigen of interest. ScFv is ideal for genetic manipulation and to obtain antibody constructs useful for targeting either antigens expressed on cell surface or intracellular antigens if the scFv is expressed as intracellular antibody (intrabody) or delivered into the cells. Results Monoclonal antibodies (mAb) in scFv format specific for the EBOV VP35 were isolated from the ETH-2 library of human recombinant antibodies by phage display technology. Five different clones were identified by sequencing, produced in E.coli and expressed in CHO mammalian cells to be characterized in vitro. All the selected scFvs were able to react with recombinant VP35 protein in ELISA, one of the scFvs being also able to react in Western Blot assay (WB). In addition, all scFvs were expressed in cell cytoplasm as intrabodies; a luciferase reporter gene inhibition assay performed in A549 cells showed that two of the scFvs can significantly hamper the inhibition of the IFN-β-induced RIG-I signaling cascade mediated by EBOV VP35. Conclusion Five antibodies in scFv format recognize an active form of EBOV VP35 in ELISA, while one antibody also recognizes VP35 in WB. Two of these scFvs were also able to interfere with the intracellular activity of VP35 in a cell system in vitro. These findings suggest that such antibodies in scFv format might be employed to develop therapeutic molecules able to hamper EBOV infections.

Published

2019

17. Grass Carp Reovirus VP35 Degrades MAVS Through the Autophagy Pathway to Inhibit Fish Interferon Production

Author

Long-Feng Lu, Can Zhang, Zhuo-Cong Li, Xiao-Yu Zhou, Jing-Yu Jiang, Dandan Chen, Yong-An Zhang, and Shun Li

Subjects

VP35, GCRV, immune evasion, MAVS, interferon, Immunologic diseases. Allergy, RC581-607

Abstract

Fish interferon (IFN) is a crucial cytokine for a host to resist external pathogens, conferring cells with antiviral capacity. Meanwhile, grass carp reovirus (GCRV) is a strong pathogen that causes high mortality in grass carp. Therefore, it is necessary to study the strategy used by GCRV to evade the cellular IFN response. In this study, we found that GCRV 35-kDa protein (VP35) inhibited the host IFN production by degrading mitochondrial antiviral signaling (MAVS) protein through the autophagy pathway. First, the overexpression of VP35 inhibited the IFN activation induced by polyinosinic-polycytidylic acid (poly I:C) and MAVS, and the expression of downstream IFN-stimulated genes (ISGs) was also decreased by using VP35 under the stimulation. Second, VP35 interacted with MAVS; the experiments of truncated mutants of MAVS demonstrated that the caspase recruitment domain (CARD) and proline-rich (PRO) domains of MAVS were not necessary for this binding. Then, MAVS was degraded by using VP35 in a dose-dependent manner, and 3-MA (the autophagy pathway inhibitor) significantly blocked the degradation, meaning that MAVS was degraded by using VP35 in the autophagy pathway. The result of MAVS degradation suggested that the antiviral capacity of MAVS was remarkably depressed when interrupted by VP35. Finally, in the host cells, VP35 reduced ifn transcription and made the cells vulnerable to virus infection. In conclusion, our results reveal that GCRV VP35 impairs the host IFN response by degrading MAVS through the autophagy pathway, supplying evidence of a fish virus immune evasion strategy.

Published

2021

18. IMPURITY D OF ANTICANCER DRUG FULVESTRANT AS A POTENTIAL MULTIFUNCTIONAL INHIBITOR FOR THE MARBURG VIRUS.

Author

Haoqi Wang, Mulgaonkar, Nirmitee, Mallawarachchi, Samavath, and Fernando, Sandun

Abstract

A commonality between viruses and cancer is their ability to seize cellular machinery to rapidly proliferate while suppressing the host's innate immune response. Using probe molecules, specific sites within the virion protein 35 (VP35) of the Marburg virus that have a high affinity to dsRNA (also known as the interferon inhibitory domain, IID), RNA-dependent RNA polymerase (RdRp), and nucleoside triphosphates (NTPs) were identified in silico. Using the dsRNA-binding site as the target, three potential drug molecules FID, CBSMA, and DOCHE were screened. We discovered that FID has a unique ability to simultaneously bind to all the three key binding domains with high affinity - a property that none of the other screened drug-like candidates possessed. The ability of FID to bind onto multiple domains of VP35 is significant since this provides the potential to thwart a viral infection from several fronts simultaneously using a single drug to combat rapidly mutating viruses. [ABSTRACT FROM AUTHOR]

Published

2021

19. Crystal structure of human LC8 bound to a peptide from Ebola virus VP35.

Author

Lim, Dahwan, Shin, Ho-Chul, Choi, Joon Sig, Kim, Seung Jun, and Ku, Bonsu

Abstract

Zaire ebolavirus, commonly called Ebola virus (EBOV), is an RNA virus that causes severe hemorrhagic fever with high mortality. Viral protein 35 (VP35) is a virulence factor encoded in the EBOV genome. VP35 inhibits host innate immune responses and functions as a critical cofactor for viral RNA replication. EBOV VP35 contains a short conserved motif that interacts with dynein light chain 8 (LC8), which serves as a regulatory hub protein by associating with various LC8-binding proteins. Herein, we present the crystal structure of human LC8 bound to the peptide comprising residues 67–76 of EBOV VP35. Two VP35 peptides were found to interact with homodimeric LC8 by extending the central β-sheets, constituting a 2:2 complex. Structural analysis demonstrated that the intermolecular binding between LC8 and VP35 is mainly sustained by a network of hydrogen bonds and supported by hydrophobic interactions in which Thr73 and Thr75 of VP35 are involved. These findings were verified by binding measurements using isothermal titration calorimetry. Biochemical analyses also verified that residues 67–76 of EBOV VP35 constitute a core region for interaction with LC8. In addition, corresponding motifs from other members of the genus Ebolavirus commonly bound to LC8 but with different binding affinities. Particularly, VP35 peptides originating from pathogenic species interacted with LC8 with higher affinity than those from noninfectious species, suggesting that the binding of VP35 to LC8 is associated with the pathogenicity of the Ebolavirus species. [ABSTRACT FROM AUTHOR]

Published

2021

20. Grass Carp Reovirus VP35 Degrades MAVS Through the Autophagy Pathway to Inhibit Fish Interferon Production.

Author

Lu, Long-Feng, Zhang, Can, Li, Zhuo-Cong, Zhou, Xiao-Yu, Jiang, Jing-Yu, Chen, Dandan, Zhang, Yong-An, and Li, Shun

Subjects

CTENOPHARYNGODON idella, AUTOPHAGY, INTERFERONS, VIRUS diseases, GENES

Abstract

Fish interferon (IFN) is a crucial cytokine for a host to resist external pathogens, conferring cells with antiviral capacity. Meanwhile, grass carp reovirus (GCRV) is a strong pathogen that causes high mortality in grass carp. Therefore, it is necessary to study the strategy used by GCRV to evade the cellular IFN response. In this study, we found that GCRV 35-kDa protein (VP35) inhibited the host IFN production by degrading mitochondrial antiviral signaling (MAVS) protein through the autophagy pathway. First, the overexpression of VP35 inhibited the IFN activation induced by polyinosinic-polycytidylic acid (poly I:C) and MAVS, and the expression of downstream IFN-stimulated genes (ISGs) was also decreased by using VP35 under the stimulation. Second, VP35 interacted with MAVS; the experiments of truncated mutants of MAVS demonstrated that the caspase recruitment domain (CARD) and proline-rich (PRO) domains of MAVS were not necessary for this binding. Then, MAVS was degraded by using VP35 in a dose-dependent manner, and 3-MA (the autophagy pathway inhibitor) significantly blocked the degradation, meaning that MAVS was degraded by using VP35 in the autophagy pathway. The result of MAVS degradation suggested that the antiviral capacity of MAVS was remarkably depressed when interrupted by VP35. Finally, in the host cells, VP35 reduced ifn transcription and made the cells vulnerable to virus infection. In conclusion, our results reveal that GCRV VP35 impairs the host IFN response by degrading MAVS through the autophagy pathway, supplying evidence of a fish virus immune evasion strategy. [ABSTRACT FROM AUTHOR]

Published

2021

21. Transcriptional Analysis of Lymphoid Tissues from Infected Nonhuman Primates Reveals the Basis for Attenuation and Immunogenicity of an Ebola Virus Encoding a Mutant VP35 Protein.

Author

Pinski, Amanda, Woolsey, Courtney, Jankeel, Allen, Cross, Robert, Basler, Christopher F., Geisbert, Thomas, and Messaoudi, Ilhem

Subjects

*LYMPHOID tissue, *EBOLA virus, *MUTANT proteins, *EBOLA virus disease, *TYPE I interferons, *AXILLA

Abstract

Infection with Zaire ebolavirus (EBOV), a member of the Filoviridae family, causes a disease characterized by high levels of viremia, aberrant inflammation, coagulopathy, and lymphopenia. EBOV initially replicates in lymphoid tissues and disseminates via dendritic cells (DCs) and monocytes to liver, spleen, adrenal gland, and other secondary organs. EBOV protein VP35 is a critical immune evasion factor that inhibits type I interferon signaling and DC maturation. Nonhuman primates (NHPs) immunized with a high dose (5 x 105 PFU) of recombinant EBOV containing a mutated VP35 (VP35m) are protected from challenge with wild-type EBOV (wtEBOV). This protection is accompanied by a transcriptional response in the peripheral blood reflecting a regulated innate immune response and a robust induction of adaptive immune genes. However, the host transcriptional response to VP35m in lymphoid tissues has not been evaluated. Therefore, we conducted a transcriptional analysis of axillary and inguinal lymph nodes and spleen tissues of NHPs infected with a low dose (2 x 104 PFU) of VP35m and then back-challenged with a lethal dose of wtEBOV. VP35m induced early transcriptional responses in lymphoid tissues that are distinct from those observed in wtEBOV challenge. Specifically, we detected robust antiviral innate and adaptive responses and fewer transcriptional changes in genes with roles in angiogenesis, apoptosis, and inflammation. Two of three macaques survived wtEBOV back-challenge, with only the nonsurvivor displaying a transcriptional response reflecting Ebola virus disease. These data suggest that VP35 is a key modulator of early host responses in lymphoid tissues, thereby regulating disease progression and severity following EBOV challenge. [ABSTRACT FROM AUTHOR]

Published

2021

22. Ebola virus replication is regulated by the phosphorylation of viral protein VP35.

Author

Zhu, Lin, Gao, Ting, Yang, Weihong, Liu, Yaoning, Liu, Xuan, Hu, Yong, Jin, Yanwen, Li, Ping, Xu, Ke, Zou, Gang, Zhao, Lei, Cao, Ruiyuan, Zhong, Wu, Xia, Xianzhu, and Cao, Cheng

Subjects

*EBOLA virus, *VIRAL proteins, *VIRAL replication, *RNA replicase, *RNA polymerases, *PHOSPHORYLATION

Abstract

Ebola virus (EBOV) is a zoonotic pathogen, the infection often results in severe, potentially fatal, systematic disease in human and nonhuman primates. VP35, an essential viral RNA-dependent RNA polymerase cofactor, is indispensable for Ebola viral replication and host innate immune escape. In this study, VP35 was demonstrated to be phosphorylated at Serine/Threonine by immunoblotting, and the major phosphorylation sites was S187, S205, T206, S208 and S317 as revealed by LC-MS/MS. By an EBOV minigenomic system, EBOV minigenome replication was shown to be significantly inhibited by the phosphorylation-defective mutant, VP35 S187A, but was potentiated by the phosphorylation mimic mutant VP35 S187D. Together, our findings demonstrate that EBOV VP35 is phosphorylated on multiple residues in host cells, especially on S187, which may contribute to efficient viral genomic replication and viral proliferation. • EBOV VP35 is phosphorylated in host cells. • The major phosphorylation site in EBOV VP35 is S187. • VP35 S187 phosphorylation potentiates EBOV minigenome replication. [ABSTRACT FROM AUTHOR]

Published

2020

23. Functional Importance of Hydrophobic Patches on the Ebola Virus VP35 IFN-Inhibitory Domain

Author

Nodoka Kasajima, Keita Matsuno, Hiroko Miyamoto, Masahiro Kajihara, Manabu Igarashi, and Ayato Takada

Subjects

Ebola virus, VP35, polymerase cofactor, interferon antagonist, IFN-inhibitory domain, hydrophobic patch, Microbiology, QR1-502

Abstract

Viral protein 35 (VP35) of Ebola virus (EBOV) is a multifunctional protein that mainly acts as a viral polymerase cofactor and an interferon antagonist. VP35 interacts with the viral nucleoprotein (NP) and double-stranded RNA for viral RNA transcription/replication and inhibition of type I interferon (IFN) production, respectively. The C-terminal portion of VP35, which is termed the IFN-inhibitory domain (IID), is important for both functions. To further identify critical regions in this domain, we analyzed the physical properties of the surface of VP35 IID, focusing on hydrophobic patches, which are expected to be functional sites that are involved in interactions with other molecules. Based on the known structural information of VP35 IID, three hydrophobic patches were identified on its surface and their biological importance was investigated using minigenome and IFN-β promoter-reporter assays. Site-directed mutagenesis revealed that some of the amino acid substitutions that were predicted to disrupt the hydrophobicity of the patches significantly decreased the efficiency of viral genome replication/transcription due to reduced interaction with NP, suggesting that the hydrophobic patches might be critical for the formation of a replication complex through the interaction with NP. It was also found that the hydrophobic patches were involved in the IFN-inhibitory function of VP35. These results highlight the importance of hydrophobic patches on the surface of EBOV VP35 IID and also indicate that patch analysis is useful for the identification of amino acid residues that directly contribute to protein functions.

Published

2021

24. Human Parainfluenza Virus 3 Phosphoprotein Is a Tetramer and Shares Structural and Interaction Features with Ebola Phosphoprotein VP35

Author

Joaquin Rodriguez Galvan, Brianna Donner, Cat Hoang Veseley, Patrick Reardon, Heather M. Forsythe, Jesse Howe, Gretchen Fujimura, and Elisar Barbar

Subjects

HPIV3, EBOV, phosphoprotein, intrinsically disordered proteins, VP35, LC8, Microbiology, QR1-502

Abstract

The human parainfluenza virus 3 (HPIV3) poses a risk for pneumonia development in young children and immunocompromised patients. To investigate mechanisms of HPIV3 pathogenesis, we characterized the association state and host protein interactions of HPIV3 phosphoprotein (HPIV3 P), an indispensable viral polymerase cofactor. Sequence analysis and homology modeling predict that HPIV3 P possesses a long, disordered N-terminal tail (PTAIL) a coiled-coil multimerization domain (PMD), similar to the well-characterized paramyxovirus phosphoproteins from measles and Sendai viruses. Using a recombinantly expressed and purified construct of PMD and PTAIL, we show that HPIV3 P in solution is primarily an alpha-helical tetramer that is stable up to 60 °C. Pulldown and isothermal titration calorimetry experiments revealed that HPIV3 P binds the host hub protein LC8, and turbidity experiments demonstrated a new role for LC8 in increasing the solubility of HPIV3 P in the presence of crowding agents such as RNA. For comparison, we show that the multimerization domain of the Zaire Ebola virus phosphoprotein VP35 is also a tetramer and binds LC8 but with significantly higher affinity. Comparative analysis of the domain architecture of various virus phosphoproteins in the order Mononegavirales show multiple predicted and verified LC8 binding motifs, suggesting its prevalence and importance in regulating viral phosphoprotein structures. Our work provides evidence for LC8 binding to phosphoproteins with multiple association states, either tetrameric, as in the HPIV3 and Ebola phosphoproteins shown here, or dimeric as in rabies virus phosphoprotein. Taken together the data suggest that the association states of a virus-specific phosphoprotein and the complex formed by binding of the phosphoprotein to host LC8 are important regulators of viral function.

Published

2021

25. Ebola virus sequesters IRF3 in viral inclusion bodies to evade host antiviral immunity.

Author

Zhu L, Jin J, Wang T, Hu Y, Liu H, Gao T, Dong Q, Jin Y, Li P, Liu Z, Huang Y, Liu X, and Cao C

Subjects

Humans, Ebolavirus, Hemorrhagic Fever, Ebola immunology, Inclusion Bodies, Viral, Interferon Regulatory Factor-3, Interferon Type I, Immune Evasion

Abstract

Viral inclusion bodies (IBs) commonly form during the replication of Ebola virus (EBOV) in infected cells, but their role in viral immune evasion has rarely been explored. Here, we found that interferon regulatory factor 3 (IRF3), but not TANK-binding kinase 1 (TBK1) or IκB kinase epsilon (IKKε), was recruited and sequestered in viral IBs when the cells were infected by EBOV transcription- and replication-competent virus-like particles (trVLPs). Nucleoprotein/virion protein 35 (VP35)-induced IBs formation was critical for IRF3 recruitment and sequestration, probably through interaction with STING. Consequently, the association of TBK1 and IRF3, which plays a vital role in type I interferon (IFN-I) induction, was blocked by EBOV trVLPs infection. Additionally, IRF3 phosphorylation and nuclear translocation induced by Sendai virus or poly(I:C) stimulation were suppressed by EBOV trVLPs. Furthermore, downregulation of STING significantly attenuated VP35-induced IRF3 accumulation in IBs. Coexpression of the viral proteins by which IB-like structures formed was much more potent in antagonizing IFN-I than expression of the IFN-I antagonist VP35 alone. These results suggested a novel immune evasion mechanism by which EBOV evades host innate immunity., Competing Interests: LZ, JJ, TW, YH, HL, TG, QD, YJ, PL, ZL, YH, XL, CC No competing interests declared, (© 2023, Zhu et al.)

Published

2024

26. Marburg Virus Viral Protein 35 Inhibits Protein Kinase R Activation in a Cell Type-Specific Manner.

Author

Hume, Adam and Mühlberger, Elke

Subjects

*PROTEIN kinases, *MARBURG virus, *VIRAL proteins, *ROUSETTUS aegyptiacus, *FILOVIRIDAE, *METABOLISM in RNA viruses, *RNA virus infections, *PROTEINS, *RESEARCH, *BATS, *ANIMAL experimentation, *RESEARCH methodology, *EVALUATION research, *MEDICAL cooperation, *COMPARATIVE studies, *IMMUNITY, *RESEARCH funding, *CELL lines, *EPITHELIAL cells, *RNA viruses

Abstract

Protein kinase R (PKR) is a key antiviral protein involved in sensing and restricting viral infections. Here we analyzed the ability of Marburg virus (MARV) viral protein 35 (VP35) to inhibit PKR activation in human and bat cells. Similar to the related Ebola and Lloviu viruses, MARV VP35 was able to inhibit PKR activation in 293T cells. In contrast, we found that MARV VP35 did not inhibit human or bat PKR activation in human glioblastoma U-251-MG cells or a Rousettus aegyptiacus cell line. Additional experiments revealed that PACT, a known PKR regulator, was insufficient to rescue the ability of VP35 to inhibit PKR activation in these cells. Taken together, this study indicates that the ability of VP35 to inhibit PKR is cell type specific, potentially explaining discrepancies between the ability of filoviruses to potently block innate immune responses, and the high levels of interferon and interferon-stimulated genes observed in filovirus patients. [ABSTRACT FROM AUTHOR]

Published

2018

27. FRAGMENT-BASED LEAD COMPOUND DESIGN TO INHIBIT EBOLA VP35 THROUGH COMPUTATIONAL STUDIES.

Author

Marnolia, Atika, Toepak, Erwin Prasetya, and Tambunan, Usman Sumo Friend

Subjects

EBOLA virus disease, MOLECULAR docking, LIGANDS (Biochemistry)

Abstract

Ebola virus (EBOV) is a virus that is classified under Filoviridae family as a pathogenic organism. On March 2016, World Health Organization (WHO) reported that 28.646 cases caused by EBOV. Thus, it is important to find the antiviral drug for this disease because it can create the epidemic around the world. EBOV VP35 is a potential drug target because it has the component of the viral RNA polymerase complex that will hamper the host interferon (IFN) production. In this research, about 6.662 fragments were obtained from ZINC15 Biogenic Database after the Rules of Three, and pharmacological properties parameters were applied. After that, these fragments were docked into the active side of EBOV VP35 using MOE 2014.09 software. The potential fragments from previous docking simulations were linked each other, resulting 91 ligands in the process. Furthermore, the docking simulation was conducted again and discovered the best three ligands that have lower Gibbs free binding energy than the standards. Moreover, the pharmacological prediction tests were also done to find the ligand with excellent molecular properties. The best three ligands from these tests were continued into molecular dynamics simulation. In the end, we conclude that the LEB 31 ligand can be the new drug candidate as EBOV VP35 inhibitor based on molecular docking, pharmacological prediction test, and molecular dynamic. [ABSTRACT FROM AUTHOR]

Published

2018

28. Insights into the homo-oligomerization properties of N-terminal coiled-coil domain of Ebola virus VP35 protein.

Author

Ramaswamy, Venkata Krishnan, Di Palma, Francesco, Vargiu, Attilio V., Corona, Angela, Piano, Dario, Ruggerone, Paolo, Zinzula, Luca, and Tramontano, Enzo

Subjects

*EBOLA virus, *OLIGOMERIZATION, *RNA polymerases, *TYPE I interferons, *GEL permeation chromatography, *VIRAL proteins

Abstract

The multifunctional Ebola virus (EBOV) VP35 protein is a key determinant of virulence. VP35 is essential for EBOV replication, is a component of the viral RNA polymerase and participates in nucleocapsid formation. Furthermore, VP35 contributes to EBOV evasion of the host innate immune response by suppressing RNA silencing and blocking RIG-I like receptors’ pathways that lead to type I interferon (IFN) production. VP35 homo-oligomerization has been reported to be critical for its replicative function and to increase its IFN-antagonism properties. Moreover, homo-oligomerization is mediated by a predicted coiled-coil (CC) domain located within its N-terminal region. Here we report the homo-oligomerization profile of full-length recombinant EBOV VP35 (rVP35) assessed by size-exclusion chromatography and native polyacrylamide gel electrophoresis. Based on our biochemical results and in agreement with previous experimental observations, we have built an in silico 3D model of the so-far structurally unsolved EBOV VP35 CC domain and performed self-assembly homo-oligomerization simulations by means of molecular dynamics. Our model advances the understanding of how VP35 may associate in different homo-oligomeric species, a crucial process for EBOV replication and pathogenicity. [ABSTRACT FROM AUTHOR]

Published

2018

29. Naïve antibody library derived monoclonal antibody against VP35 of Ebola virus.

Author

Lai, Jing Yi, Corona, Angela, Ng, Chong Lee, Tramontano, Enzo, Choong, Yee Siew, and Lim, Theam Soon

Subjects

*EBOLA virus, *MONOCLONAL antibodies, *EBOLA virus disease, *HEMORRHAGIC fever, *RNA polymerases, *REPORTER genes

Abstract

Ebola virus is notorious for causing severe and even deadly haemorrhagic fever in infected humans and non-human primates. The high fatality rate of Ebola virus disease (EVD) has highlighted the need for effective diagnosis and treatment. Two monoclonal antibodies (mAbs) have been approved by USFDA for treatment of EVD. Virus surface glycoprotein is the common target for diagnostic and therapy including vaccines. Even so, VP35, a viral RNA polymerase cofactor and interferon inhibitor could be a potential target to curb EVD. The present work describes the isolation of three mAb clones from a phage-displayed human naïve scFv library against recombinant VP35. The clones showed binding against rVP35 in vitro and inhibition of VP35 in luciferase reporter gene assay. Structural modelling analysis was also carried out to identify the binding interactions involved in the antibody-antigen interaction model. This allows some insight into the "fitness" of the binding pocket between the paratope and target epitope which would be useful for the design of new mAbs through in silico means in the future. In conclusion, the information obtained from the 3 isolated mAbs could be potentially useful in the quest to improve VP35 targeting for therapeutic development in the future. [ABSTRACT FROM AUTHOR]

Published

2023

30. Contribution of SUMO to the replication of Ebola virus

Author

Rivas Vázquez, Mª Carmen, Universidade de Santiago de Compostela. Escola de Doutoramento Internacional (EDIUS), Universidade de Santiago de Compostela. Programa de Doutoramento en Medicina Molecular, Vidal Freire, Santiago, Rivas Vázquez, Mª Carmen, Universidade de Santiago de Compostela. Escola de Doutoramento Internacional (EDIUS), Universidade de Santiago de Compostela. Programa de Doutoramento en Medicina Molecular, and Vidal Freire, Santiago

Abstract

Neste traballo demostramos a relevancia de SUMO e ubiquitina á hora de modular as proteínas VP24 e VP35 do EBOV. Tamén identificamos novas actividades da proteína VP24 que poderían explicar o fenotipo altamente inflamatorio observado nos pacientes infectados con EBOV así como a falta de maduración das células dendríticas infectadas có virus. Algúns interactores e rutas de sinalización identificadas neste estudo aparecen coma prometedoras dianas terapéuticas. Ademais os nosos descubrementos axudan a incrementar o coñecemento e entender mellor a infección por EBOV e a súa patoxenicidade.

Published

2022

31. Crystal Structure of the Marburg Virus Nucleoprotein Core Domain Chaperoned by a VP35 Peptide Reveals a Conserved Drug Target for Filovirus.

Author

Tengfei Zhu, Hao Song, Ruchao Peng, Yi Shi, Jianxun Qi, and George F. Gao

Subjects

*MARBURG virus, *VIRAL replication, *FILOVIRIDAE, *NUCLEOCAPSIDS, *N-terminal residues, *CRYSTAL structure

Abstract

Filovirus nucleoprotein (NP), viral protein 35 (VP35), and polymerase L are essential for viral replication and nucleocapsid formation. Here, we identify a 28-residue peptide (NP binding peptide [NPBP]) from Marburg virus (MARV) VP35 through sequence alignment with previously identified Ebola virus (EBOV) NPBP, which bound to the core region (residues 18 to 344) of the N-terminal portion of MARV NP with high affinity. The crystal structure of the MARV NP core/NPBP complex at a resolution of 2.6 Å revealed that NPBP binds to the C-terminal region of the NP core via electrostatic and nonpolar interactions. Further structural analysis revealed that the MARV and EBOV NP cores hold a conserved binding pocket for NPBP, and this pocket could serve as a promising target for the design of universal drugs against filovirus infection. In addition, cross-binding assays confirmed that the NP core of MARV or EBOV can bind the NPBP from the other virus, although with moderately reduced binding affinities that result from termini that are distinct between the MARV and EBOV NPBPs. [ABSTRACT FROM AUTHOR]

Published

2017

32. Herbal Lead as Ideal Bioactive Compounds Against Probable Drug Targets of Ebola Virus in Comparison with Known Chemical Analogue: A Computational Drug Discovery Perspective.

Author

Setlur, Anagha, Naik, Sujay, and Skariyachan, Sinosh

Subjects

LEAD, TREATMENT of Ebola virus diseases, BIOACTIVE compounds, DRUG development, DRUG target, THERAPEUTICS

Abstract

Ebola is a deadly virus that has recently emerged as an enormous public health concern which causes dangerous illness with high fatality rates of 90 %. The virus is not receptive to known antivirals, and hence, there is a promising need to identify novel inhibitors to combat the disease. The present study deals with identification of potential herbal leads that probably subdue the activity of four major drug targets of Ebola virus such as VP24, VP30, VP35 and VP40 by computer-aided virtual screening. The selection of receptors was performed based on their functional roles in the disease. The drug likeliness and ADMET parameters of 150 herbal ligands were computationally predicted. Those molecules that qualified these parameters were preferred for docking studies with the protein targets. An existing chemical antiviral drug, BCX4430 was also docked and its theoretical binding energy was scrutinized. The docking studies suggested that herbal ligand Limonin demonstrated high binding properties with VP24 and VP35 (binding energy −9.7 kcal/mol). Similarly, curcumin exhibited good binding with VP30 (binding energy −9.6 kcal/mol). Further, Mahanine displayed superior interaction with VP40 (binding energy −7.7 kcal/mol). These herbal leads demonstrated better binding potential than the known chemical analogue in the computational studies. This study serves to bestow paramount information for further experimental studies concerning the utility of herbal ligands as probable lead molecules against Ebola viral targets. [ABSTRACT FROM AUTHOR]

Published

2017

33. Molecular dynamics exploration of the binding mechanism and properties of single-walled carbon nanotube to WT and mutant VP35 FBP region of Ebola virus.

Author

Zhang, Yan-Jun, Ding, Jing-Na, Zhong, Hui, Sun, Chang-Ping, and Han, Ju-Guang

Subjects

*EBOLA virus, *MOLECULAR dynamics, *SINGLE walled carbon nanotubes, *CHEMICAL affinity, *MOLECULAR docking

Abstract

VP35 of Ebola viruses (EBOVs) is an attractive potential target because of its multifunction. All-atom molecular dynamics (MD) simulations and Molecular Mechanics Generalized Born surface area (MM/GBSA) energy calculations are performed to investigate the single-walled carbon nanotube (SWCNT) as an inhibitor in wild-type (WT) VP35 as well as in three primary mutants (K248A, I295A, and K248A/I295A) through docking the SWCNT in the first basic patch (FBP) of VP35. The SWCNTs of all the four systems effectively bind to the FBP. Interestingly, the sites and orientations of the SWCNT binding to the I295A mutant and K248A/I295A double mutants change significantly to accommodate the variation of the VP35 conformation. Moreover, the VDW can provide the major forces for affinity binding in all four systems. [ABSTRACT FROM AUTHOR]

Published

2017

34. Ebola virus: A gap in drug design and discovery - experimental and computational perspective.

Author

Balmith, Marissa, Faya, Mbuso, and Soliman, Mahmoud E. S.

Subjects

*EBOLA virus, *DRUG development, *EBOLA virus disease, *DRUGS, *DIAGNOSIS, TREATMENT of Ebola virus diseases

Abstract

The Ebola virus, formally known as the Ebola hemorrhagic fever, is an acute viral syndrome causing sporadic outbreaks that have ravaged West Africa. Due to its extreme virulence and highly transmissible nature, Ebola has been classified as a category A bioweapon organism. Only recently have vaccine or drug regimens for the Ebola virus been developed, including Zmapp and peptides. In addition, existing drugs which have been repurposed toward anti-Ebola virus activity have been re-examined and are seen to be promising candidates toward combating Ebola. Drug development involving computational tools has been widely employed toward target-based drug design. Screening large libraries have greatly stimulated research toward effective anti-Ebola virus drug regimens. Current emphasis has been placed on the investigation of host proteins and druggable viral targets. There is a huge gap in the literature regarding guidelines in the discovery of Ebola virus inhibitors, which may be due to the lack of information on the Ebola drug targets, binding sites, and mechanism of action of the virus. This review focuses on Ebola virus inhibitors, drugs which could be repurposed to combat the Ebola virus, computational methods which study drug-target interactions as well as providing further insight into the mode of action of the Ebola virus. [ABSTRACT FROM AUTHOR]

Published

2017

35. Ebola virus VP35 blocks stress granule assembly.

Author

Le Sage, Valerie, Cinti, Alessandro, McCarthy, Stephen, Amorim, Raquel, Rao, Shringar, Daino, Gian Luca, Tramontano, Enzo, Branch, Donald R., and Mouland, Andrew J.

Subjects

*EBOLA virus, *STRESS granules, *MESSENGER RNA, *ANTIVIRAL agents, *IMMUNOPRECIPITATION

Abstract

Stress granules (SGs) are dynamic cytoplasmic aggregates of translationally silenced mRNAs that assemble in response to environmental stress. SGs appear to play an important role in antiviral innate immunity and many viruses have evolved to block or subvert SGs components for their own benefit. Here, we demonstrate that intracellular Ebola virus (EBOV) replication and transcription-competent virus like particles (trVLP) infection does not lead to SG assembly but leads to a blockade to Arsenite-induced SG assembly. Moreover we show that EBOV VP35 represses the assembly of canonical and non-canonical SGs induced by a variety of pharmacological stresses. This SG blockade requires, at least in part, the C-terminal domain of VP35. Furthermore, results from our co-immunoprecipitation studies indicate that VP35 interacts with multiple SG components, including G3BP1, eIF3 and eEF2 through a stress- and RNA-independent mechanism. These data suggest a novel function for EBOV VP35 in the repression of SG assembly. [ABSTRACT FROM AUTHOR]

Published

2017

36. Crystal Structure of the Marburg Virus VP35 Oligomerization Domain.

Author

Bruhn, Jessica F., Kirchdoerfer, Robert N., Urata, Sarah M., Sheng Li, Tickle, Ian J., Bricogne, Gérard, and Saphire, Erica Ollmann

Subjects

*MARBURG virus, *OLIGOMERIZATION, *CRYSTAL structure, *EBOLA virus, *VIRAL replication, *IMMUNE response, *SOLUTION (Chemistry)

Abstract

Marburg virus (MARV) is a highly pathogenic filovirus that is classified in a genus distinct from that of Ebola virus (EBOV) (genera Marburgvirus and Ebolavirus, respectively). Both viruses produce a multifunctional protein termed VP35, which acts as a polymerase cofactor, a viral protein chaperone, and an antagonist of the innate immune response. VP35 contains a central oligomerization domain with a predicted coiled-coil motif. This domain has been shown to be essential for RNA polymerase function. Here we present crystal structures of the MARV VP35 oligomerization domain. These structures and accompanying biophysical characterization suggest that MARV VP35 is a trimer. In contrast, EBOV VP35 is likely a tetramer in solution. Differences in the oligomeric state of this protein may explain mechanistic differences in replication and immune evasion observed for MARV and EBOV. [ABSTRACT FROM AUTHOR]

Published

2017

37. Ebola virus disease: In vivo protection provided by the PAMP restricted TLR3 agonist rintatolimod and its mechanism of action.

Author

Corona, Angela, Strayer, David, Distinto, Simona, Daino, Gian Luca, Paulis, Annalaura, Tramontano, Enzo, and Mitchell, William M.

Subjects

*EBOLA virus disease, *EBOLA virus, *TYPE I interferons, *DNA helicases

Abstract

Ebola virus (EBOV) is a highly infectious and lethal pathogen responsible for sporadic self-limiting clusters of Ebola virus disease (EVD) in Central Africa capable of reaching epidemic status. 100% protection from lethal EBOV-Zaire in Balb/c mice was achieved by rintatolimod (Ampligen) at the well tolerated human clinical dose of 6 mg/kg. The data indicate that the mechanism of action is rintatolimod's dual ability to act as both a competitive decoy for the IID domain of VP35 blocking viral dsRNA sequestration and as a pathogen-associated molecular pattern (PAMP) restricted agonist for direct TLR3 activation but lacking RIG-1-like cytosolic helicase agonist properties. These data show promise for rintatolimod as a prophylactic therapy against human Ebola outbreaks. • Rintatolimod offers 100% protection against Ebola virus in a 100% lethal mouse model. • Protection from in mice is at easily achievable human IV doses of 6 mg/kg. • Rintatolimod is generally well-tolerated in humans at 6 mg/kg. • Rintatolimod blocks EBOV VP35 viral dsRNA binding and is not a RIG-1-like agonist. • Rintatolimod acts as PAMP restricted agonist for direct TLR3 activation. [ABSTRACT FROM AUTHOR]

Published

2023

38. Ebola Virus VP35 Interacts Non-Covalently with Ubiquitin Chains to Promote Viral Replication Creating New Therapeutic Opportunities.

Author

Rodríguez-Salazar CA, van Tol S, Mailhot O, Galdino G, Teruel N, Zhang L, Warren AN, González-Orozco M, Freiberg AN, Najmanovich RJ, Giraldo MI, and Rajsbaum R

Abstract

Ebolavirus (EBOV) belongs to a family of highly pathogenic viruses that cause severe hemorrhagic fever in humans. EBOV replication requires the activity of the viral polymerase complex, which includes the co-factor and Interferon antagonist VP35. We previously showed that the covalent ubiquitination of VP35 promotes virus replication by regulating interactions with the polymerase complex. In addition, VP35 can also interact non-covalently with ubiquitin (Ub); however, the function of this interaction is unknown. Here, we report that VP35 interacts with free (unanchored) K63-linked polyUb chains. Ectopic expression of Isopeptidase T (USP5), which is known to degrade unanchored polyUb chains, reduced VP35 association with Ub and correlated with diminished polymerase activity in a minigenome assay. Using computational methods, we modeled the VP35-Ub non-covalent interacting complex, identified the VP35-Ub interacting surface and tested mutations to validate the interface. Docking simulations identified chemical compounds that can block VP35-Ub interactions leading to reduced viral polymerase activity that correlated with reduced replication of infectious EBOV. In conclusion, we identified a novel role of unanchored polyUb in regulating Ebola virus polymerase function and discovered compounds that have promising anti-Ebola virus activity., Competing Interests: Competing Interest Statement: The authors declare no competing interest.

Published

2023

39. Contribution of SUMO to the replication of Ebola virus

Author

Vidal Freire, Santiago, Rivas Vázquez, Mª Carmen, Universidade de Santiago de Compostela. Escola de Doutoramento Internacional (EDIUS), and Universidade de Santiago de Compostela. Programa de Doutoramento en Medicina Molecular

Subjects

PML, Laminopathie, Ubiquitin, Investigación::31 Ciencias agrarias::3109 Ciencias veterinarias::310903 Inmunología [Materias], USP7, Investigación::24 Ciencias de la vida::2403 Bioquímica [Materias], Investigación::31 Ciencias agrarias::3108 Fitopatología::310809 Virus [Materias], Ebolavirus, VP24, VP35

Abstract

Neste traballo demostramos a relevancia de SUMO e ubiquitina á hora de modular as proteínas VP24 e VP35 do EBOV. Tamén identificamos novas actividades da proteína VP24 que poderían explicar o fenotipo altamente inflamatorio observado nos pacientes infectados con EBOV así como a falta de maduración das células dendríticas infectadas có virus. Algúns interactores e rutas de sinalización identificadas neste estudo aparecen coma prometedoras dianas terapéuticas. Ademais os nosos descubrementos axudan a incrementar o coñecemento e entender mellor a infección por EBOV e a súa patoxenicidade. 2023-01-10

Published

2022

40. Transcriptomics Reveal Antiviral Gene Induction in the Egyptian Rousette Bat Is Antagonized In Vitro by Marburg Virus Infection

Author

Catherine E. Arnold, Jonathan C. Guito, Louis A. Altamura, Sean P. Lovett, Elyse R. Nagle, Gustavo F. Palacios, Mariano Sanchez-Lockhart, and Jonathan S. Towner

Subjects

transcriptomics, Egyptian rousette bat, Marburg virus, VP35, Microbiology, QR1-502

Abstract

The Egyptian rousette bat (ERB) is the only known Marburg virus (MARV) reservoir host. ERBs develop a productive MARV infection with low viremia and shedding but no overt disease, suggesting this virus is efficiently controlled by ERB antiviral responses. This dynamic would contrast with humans, where MARV-mediated interferon (IFN) antagonism early in infection is thought to contribute to the severe, often fatal disease. The newly-annotated ERB genome and transcriptome have now enabled us to use a custom-designed NanoString nCounter ERB CodeSet in conjunction with RNA-seq to investigate responses in a MARV-infected ERB cell line. Both transcriptomic platforms correlated well and showed that MARV inhibited the antiviral program in ERB cells, while an IFN antagonism-impaired MARV was less efficient at suppressing the response gene induction, phenotypes previously reported for primate cells. Interestingly, and despite the expansion of IFN loci in the ERB genome, neither MARV showed specific induction of almost any IFN gene. However, we detected an upregulation of putative, unannotated ERB antiviral paralogs, as well as an elevated basal expression in uninfected ERB cells of key antiviral genes.

Published

2018

41. Evasion of the Interferon-Mediated Antiviral Response by Filoviruses

Author

Washington B. Cárdenas

Subjects

IFN, VP35, VP24, filovirus, Microbiology, QR1-502

Abstract

The members of the filoviruses are recognized as some of the most lethal viruses affecting human and non-human primates. The only two genera of the Filoviridae family, Marburg virus (MARV) and Ebola virus (EBOV), comprise the main etiologic agents of severe hemorrhagic fever outbreaks in central Africa, with case fatality rates ranging from 25 to 90%. Fatal outcomes have been associated with a late and dysregulated immune response to infection, very likely due to the virus targeting key host immune cells, such as macrophages and dendritic cells (DCs) that are necessary to mediate effective innate and adaptive immune responses. Despite major progress in the development of vaccine candidates for filovirus infections, a licensed vaccine or therapy for human use is still not available. During the last ten years, important progress has been made in understanding the molecular mechanisms of filovirus pathogenesis. Several lines of evidence implicate the impairment of the host interferon (IFN) antiviral innate immune response by MARV or EBOV as an important determinant of virulence. In vitro and in vivo experimental infections with recombinant Zaire Ebola virus (ZEBOV), the best characterized filovirus, demonstrated that the viral protein VP35 plays a key role in inhibiting the production of IFN-α/β. Further, the action of VP35 is synergized by the inhibition of cellular responses to IFN-α/β by the minor matrix viral protein VP24. The dual action of these viral proteins may contribute to an efficient initial virus replication and dissemination in the host. Noticeably, the analogous function of these viral proteins in MARV has not been reported. Because the IFN response is a major component of the innate immune response to virus infection, this chapter reviews recent findings on the molecular mechanisms of IFN-mediated antiviral evasion by filovirus infection.

Published

2010

42. Integrated Computational Approach for Virtual Hit Identification against Ebola Viral Proteins VP35 and VP40.

Author

Mirza, Muhammad Usman and Ikram, Nazia

Subjects

*EBOLA virus, *VIRAL proteins, *PHYTOCHEMICALS, *MOLECULAR docking, *PUBLIC health, *PHARMACOKINETICS, *PHARMACODYNAMICS

Abstract

The Ebola virus (EBOV) has been recognised for nearly 40 years, with the most recent EBOV outbreak being in West Africa, where it created a humanitarian crisis. Mortalities reported up to 30 March 2016 totalled 11,307. However, up until now, EBOV drugs have been far from achieving regulatory (FDA) approval. It is therefore essential to identify parent compounds that have the potential to be developed into effective drugs. Studies on Ebola viral proteins have shown that some can elicit an immunological response in mice, and these are now considered essential components of a vaccine designed to protect against Ebola haemorrhagic fever. The current study focuses on chemoinformatic approaches to identify virtual hits against Ebola viral proteins (VP35 and VP40), including protein binding site prediction, drug-likeness, pharmacokinetic and pharmacodynamic properties, metabolic site prediction, and molecular docking. Retrospective validation was performed using a database of non-active compounds, and early enrichment of EBOV actives at different false positive rates was calculated. Homology modelling and subsequent superimposition of binding site residues on other strains of EBOV were carried out to check residual conformations, and hence to confirm the efficacy of potential compounds. As a mechanism for artefactual inhibition of proteins through non-specific compounds, virtual hits were assessed for their aggregator potential compared with previously reported aggregators. These systematic studies have indicated that a few compounds may be effective inhibitors of EBOV replication and therefore might have the potential to be developed as anti-EBOV drugs after subsequent testing and validation in experiments in vivo. [ABSTRACT FROM AUTHOR]

Published

2016

43. In silico and in vitro methods to identify ebola virus VP35-dsRNA inhibitors.

Author

Glanzer, Jason G., Byrne, Brendan M., McCoy, Aaron M., James, Ben J., Frank, Joshua D., and Oakley, Greg G.

Subjects

*EBOLA virus, *VIRUS identification, *DOUBLE-stranded RNA, *BIOTERRORISM, *ANTIVIRAL agents, *VIRAL genomes

Abstract

Ebola virus continues to be problematic as sporadic outbreaks in Africa continue to arise, and as terrorist organizations have considered the virus for bioterrorism use. Several proteins within the virus have been targeted for antiviral chemotherapy, including VP35, a dsRNA binding protein that promotes viral replication, protects dsRNA from degradation, and prevents detection of the viral genome by immune complexes. To augment the scope of our antiviral research, we have now employed molecular modeling techniques to enrich the population of compounds for further testing in vitro. In the initial docking of a static VP35 structure with an 80,000 compound library, 40 compounds were selected, of which four compounds inhibited VP35 with IC 50 <200 μM, with the best compounds having an IC 50 of 20 μM. By superimposing 26 VP35 structures, we determined four aspartic acid residues were highly flexible and the docking was repeated under flexible parameters. Of 14 compounds chosen for testing, five compounds inhibited VP35 with IC 50 <200 μM and one compound with an IC 50 of 4 μM. These studies demonstrate the value of docking in silico for enriching compounds for testing in vitro, and specifically using multiple structures as a guide for detecting flexibility and provide a foundation for further development of small molecule inhibitors directed towards VP35. [ABSTRACT FROM AUTHOR]

Published

2016

44. Differential Regulation of Interferon Responses by Ebola and Marburg Virus VP35 Proteins.

Author

Edwards, Megan R., Liu, Gai, Mire, Chad E., Sureshchandra, Suhas, Luthra, Priya, Yen, Benjamin, Shabman, Reed S., Leung, Daisy W., Messaoudi, Ilhem, Geisbert, Thomas W., Amarasinghe, Gaya K., and Basler, Christopher F.

Abstract

Summary Suppression of innate immune responses during filoviral infection contributes to disease severity. Ebola (EBOV) and Marburg (MARV) viruses each encode a VP35 protein that suppresses RIG-I-like receptor signaling and interferon-α/β (IFN-α/β) production by several mechanisms, including direct binding to double stranded RNA (dsRNA). Here, we demonstrate that in cell culture, MARV infection results in a greater upregulation of IFN responses as compared to EBOV infection. This correlates with differences in the efficiencies by which EBOV and MARV VP35s antagonize RIG-I signaling. Furthermore, structural and biochemical studies suggest that differential recognition of RNA elements by the respective VP35 C-terminal IFN inhibitory domain (IID) rather than affinity for RNA by the respective VP35s is critical for this observation. Our studies reveal functional differences in EBOV versus MARV VP35 RNA binding that result in unexpected differences in the host response to deadly viral pathogens. [ABSTRACT FROM AUTHOR]

Published

2016

45. Exploring interaction mechanisms of the inhibitor binding to the VP35 IID region of Ebola virus by all atom molecular dynamics simulation method.

Author

Zhang, Yan‐Jun, Ding, Jing‐Na, Feng, Ting‐Ting, and Han, Ju‐Guang

Abstract

Ebola viruses (EBOVs) cause an acute and serious illness which is often fatal if untreated, and there is no effective vaccine until now. Multifunctional VP35 is critical for viral replication, RNA silencing suppression and nucleocapsid formation, and it is considered as a future target for the molecular biology technique. In the present work, the binding of inhibitor pyrrole-based compounds (GA017) to wild-type (WT), single (K248A, K251A, and I295A), and double (K248A/I295A) mutant VP35 were investigated by all-atom molecular dynamic (MD) simulations and Molecular Mechanics Generalized Born surface area (MM/GBSA) energy calculation. The calculated results indicate that the binding with GA017 makes the binding pocket more stable and reduces the space of the binding pocket. Moreover, the electrostatic interactions (ΔEele) and VDW energy (ΔEvdw) provide the major forces for affinity binding, and single mutation I295A and double mutation K248A/I295A have great influence on the conformation of the VP35 binding pocket. Interestingly, the residues R300-G301-D302 of I295A form a new helix and the sheet formed by the residues V294-I295-H296-I297 disappears in the double mutation K248A/I295A as compared with WT. Moreover, the binding free energy calculations show that I295A and K248A/I295A mutations decrease of absolute binding free energies while K248A and K251A mutations increase absolute binding free energy. Our calculated results are in good agreement with the experimental results that K248A/I295A double mutant results in near-complete loss of compound binding. The obtained information will be useful for design effective inhibitors for treating Ebola virus. [ABSTRACT FROM AUTHOR]

Published

2015

46. Functional Importance of Hydrophobic Patches on the Ebola Virus VP35 IFN-Inhibitory Domain

Author

Kasajima, Nodoka, 1000040753306, Matsuno, Keita, Miyamoto, Hiroko, 1000070711894, Kajihara, Masahiro, 1000010374240, Igarashi, Manabu, 1000010292062, Takada, Ayato, Kasajima, Nodoka, 1000040753306, Matsuno, Keita, Miyamoto, Hiroko, 1000070711894, Kajihara, Masahiro, 1000010374240, Igarashi, Manabu, 1000010292062, and Takada, Ayato

Abstract

Viral protein 35 (VP35) of Ebola virus (EBOV) is a multifunctional protein that mainly acts as a viral polymerase cofactor and an interferon antagonist. VP35 interacts with the viral nucleoprotein (NP) and double-stranded RNA for viral RNA transcription/replication and inhibition of type I interferon (IFN) production, respectively. The C-terminal portion of VP35, which is termed the IFN-inhibitory domain (IID), is important for both functions. To further identify critical regions in this domain, we analyzed the physical properties of the surface of VP35 IID, focusing on hydrophobic patches, which are expected to be functional sites that are involved in interactions with other molecules. Based on the known structural information of VP35 IID, three hydrophobic patches were identified on its surface and their biological importance was investigated using minigenome and IFN-beta promoter-reporter assays. Site-directed mutagenesis revealed that some of the amino acid substitutions that were predicted to disrupt the hydrophobicity of the patches significantly decreased the efficiency of viral genome replication/transcription due to reduced interaction with NP, suggesting that the hydrophobic patches might be critical for the formation of a replication complex through the interaction with NP. It was also found that the hydrophobic patches were involved in the IFN-inhibitory function of VP35. These results highlight the importance of hydrophobic patches on the surface of EBOV VP35 IID and also indicate that patch analysis is useful for the identification of amino acid residues that directly contribute to protein functions.

Published

2021

47. Evidence that ebolaviruses and cuevaviruses have been diverging from marburgviruses since the Miocene

Author

Derek J. Taylor, Matthew J. Ballinger, Jack J. Zhan, Laura E. Hanzly, and Jeremy A. Bruenn

Subjects

Ebolavirus, Marburgvirus, Paleovirus, Cricetidae, VP35, NP, Medicine, Biology (General), QH301-705.5

Abstract

An understanding of the timescale of evolution is critical for comparative virology but remains elusive for many RNA viruses. Age estimates based on mutation rates can severely underestimate divergences for ancient viral genes that are evolving under strong purifying selection. Paleoviral dating, however, can provide minimum age estimates for ancient divergence, but few orthologous paleoviruses are known within clades of extant viruses. For example, ebolaviruses and marburgviruses are well-studied mammalian pathogens, but their comparative biology is difficult to interpret because the existing estimates of divergence are controversial. Here we provide evidence that paleoviral elements of two genes (ebolavirus-like VP35 and NP) in cricetid rodent genomes originated after the divergence of ebolaviruses and cuevaviruses from marburgviruses. We provide evidence of orthology by identifying common paleoviral insertion sites among the rodent genomes. Our findings indicate that ebolaviruses and cuevaviruses have been diverging from marburgviruses since the early Miocene.

Published

2014

48. Integrated Computational Approach for Virtual Hit Identification against Ebola Viral Proteins VP35 and VP40

Author

Muhammad Usman Mirza and Nazia Ikram

Subjects

Ebola virus, phytochemicals, molecular docking, VP35, VP40, retrospective validation, virtual screening, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The Ebola virus (EBOV) has been recognised for nearly 40 years, with the most recent EBOV outbreak being in West Africa, where it created a humanitarian crisis. Mortalities reported up to 30 March 2016 totalled 11,307. However, up until now, EBOV drugs have been far from achieving regulatory (FDA) approval. It is therefore essential to identify parent compounds that have the potential to be developed into effective drugs. Studies on Ebola viral proteins have shown that some can elicit an immunological response in mice, and these are now considered essential components of a vaccine designed to protect against Ebola haemorrhagic fever. The current study focuses on chemoinformatic approaches to identify virtual hits against Ebola viral proteins (VP35 and VP40), including protein binding site prediction, drug-likeness, pharmacokinetic and pharmacodynamic properties, metabolic site prediction, and molecular docking. Retrospective validation was performed using a database of non-active compounds, and early enrichment of EBOV actives at different false positive rates was calculated. Homology modelling and subsequent superimposition of binding site residues on other strains of EBOV were carried out to check residual conformations, and hence to confirm the efficacy of potential compounds. As a mechanism for artefactual inhibition of proteins through non-specific compounds, virtual hits were assessed for their aggregator potential compared with previously reported aggregators. These systematic studies have indicated that a few compounds may be effective inhibitors of EBOV replication and therefore might have the potential to be developed as anti-EBOV drugs after subsequent testing and validation in experiments in vivo.

Published

2016

49. In Silico Derived Small Molecules Bind the Filovirus VP35 Protein and Inhibit Its Polymerase Cofactor Activity.

Author

Brown, Craig S., Lee, Michael S., Leung, Daisy W., Wang, Tianjiao, Xu, Wei, Luthra, Priya, Anantpadma, Manu, Shabman, Reed S., Melito, Lisa M., MacMillan, Karen S., Borek, Dominika M., Otwinowski, Zbyszek, Ramanan, Parameshwaran, Stubbs, Alisha J., Peterson, Dayna S., Binning, Jennifer M., Tonelli, Marco, Olson, Mark A., Davey, Robert A., and Ready, Joseph M.

Subjects

*SMALL molecules, *FILOVIRIDAE, *VIRAL proteins, *EBOLA virus, *VIRAL genomes, *POLYMERASE chain reaction, *ANTIVIRAL agents, *MESSENGER RNA

Abstract

Abstract: The Ebola virus (EBOV) genome only encodes a single viral polypeptide with enzymatic activity, the viral large (L) RNA-dependent RNA polymerase protein. However, currently, there is limited information about the L protein, which has hampered the development of antivirals. Therefore, antifiloviral therapeutic efforts must include additional targets such as protein–protein interfaces. Viral protein 35 (VP35) is multifunctional and plays important roles in viral pathogenesis, including viral mRNA synthesis and replication of the negative-sense RNA viral genome. Previous studies revealed that mutation of key basic residues within the VP35 interferon inhibitory domain (IID) results in significant EBOV attenuation, both in vitro and in vivo. In the current study, we use an experimental pipeline that includes structure-based in silico screening and biochemical and structural characterization, along with medicinal chemistry, to identify and characterize small molecules that target a binding pocket within VP35. NMR mapping experiments and high-resolution x-ray crystal structures show that select small molecules bind to a region of VP35 IID that is important for replication complex formation through interactions with the viral nucleoprotein (NP). We also tested select compounds for their ability to inhibit VP35 IID–NP interactions in vitro as well as VP35 function in a minigenome assay and EBOV replication. These results confirm the ability of compounds identified in this study to inhibit VP35–NP interactions in vitro and to impair viral replication in cell-based assays. These studies provide an initial framework to guide development of antifiloviral compounds against filoviral VP35 proteins. [Copyright &y& Elsevier]

Published

2014

50. Hsp90 Regulates GCRV-II Proliferation by Interacting with VP35 as Its Receptor and Chaperone.

Author

Jiang L, Liu AQ, Zhang C, Zhang YA, and Tu J

Subjects

Animals, Antibodies, Viral metabolism, Carps virology, Cell Proliferation, Clathrin metabolism, Molecular Chaperones metabolism, Proteasome Endopeptidase Complex metabolism, Receptors, Virus metabolism, Capsid Proteins metabolism, Fish Diseases virology, Heat-Shock Proteins metabolism, Reoviridae physiology, Reoviridae Infections veterinary

Abstract

The frequent outbreak of grass carp hemorrhagic disease caused by grass carp reovirus (GCRV), especially the mainly prevalent type II GCRV (GCRV-II), has seriously affected the grass carp culture in China. However, its pathogenic mechanism is still far from clear. In this study, the GCRV-II outer capsid protein VP35 was used as bait to capture interacting partners from Ctenopharyngon idellus kidney (CIK) cells, and heat shock protein 90 (Hsp90) was selected and confirmed interacting with VP35 through the C-terminal domain of Hsp90. Knockdown of Hsp90 or inhibition of Hsp90 activity suppressed GCRV-II proliferation, demonstrating that Hsp90 is an essential factor for GCRV-II proliferation. The confocal microscopy and flow cytometry showed that Hsp90 localized at both membrane and cytoplasm of CIK cells. The entry of GCRV-II into CIK cells was efficiently blocked by incubating the cells with Hsp90 antibody or by pretreating the virus with recombinant Hsp90 protein. Whereas overexpression of Hsp90 in CIK cells, grass carp ovary (GCO) cells, or 293T cells promoted GCRV-II entry, indicating that the membrane Hsp90 functions as a receptor of GCRV-II. Furthermore, Hsp90 interacted with clathrin and mediated GCRV-II entry into CIK cells through clathrin endocytosis pathway. In addition, we found that the cytoplasmic Hsp90 acted as a chaperone of VP35 because inhibition of Hsp90 activity enhanced VP35 polyubiquitination and degraded VP35 through the proteasome pathway. Collectively, our data suggest that Hsp90 functions both as a receptor for GCRV-II entry and a chaperone for the maturation of GCRV-II VP35, thus ensuring efficient proliferation of GCRV-II. IMPORTANCE Identification of viral receptors has always been the research hot spot in virus research field as receptor functions at the first stage of viral infection, which can be designed as efficient antiviral drug targets. GCRV-II, the causative agent of the grass carp epidemic hemorrhagic disease, has caused tremendous losses in grass carp culture in China. To date, the receptor of GCRV-II remains unknown. This study focused on identifying cellular receptor interacting with the GCRV-II outer capsid protein VP35, studying the effects of their interaction on GCRV-II proliferation, and revealing the underlying mechanisms. We demonstrated that Hsp90 acts both as a receptor of GCRV-II by interacting with VP35 and as a chaperone for the maturation of VP35, thus ensuring efficient proliferation of GCRV-II. Our data provide important insights into the role of Hsp90 in GCRV-II life cycle, which will help understand the mechanism of reovirus infection.

Published

2022