Your search keyword '"virus engineering"' showing total 40 results

1. Optimization of PCA Error Correction Conditions to Improve Efficiency of Virus Genome De Novo Synthesis.

Author

Cui, Jiazhen, Hu, Ao, Xiong, Xianghua, Wang, Qingyang, Zhu, Chen, Chen, Zhili, Lu, Yuanyuan, Xia, Xianzhu, Chen, Huipeng, and Liu, Gang

Subjects

*VIRAL genomes, *DNA synthesis, *POLYMERASE chain reaction, *VACCINE development, *MONKEYPOX

Abstract

In recent years, there have been frequent global outbreaks of viral epidemics such as Zika, COVID-19, and monkeypox, which have had a huge impact on human health and society and have also spurred innovation in virus engineering technology. The rise of synthetic virus genome technology has provided researchers with a new platform to accelerate vaccine and drug development. Although DNA synthesis technology has made significant progress, the current virus genome synthesis technology still requires the assembly of short oligonucleotides of around 60 bp into kb-level lengths when constructing long segments, a process in which the commonly used polymerase chain reaction assembly (PCA) technology has high error rates and is cumbersome to operate. This study optimized the error correction conditions after PCA assembly, increasing the accuracy of synthesizing 1 kb DNA fragments from 4.2 ± 2.1% before error correction to 31.3 ± 3.1% after two rounds of correction, an improvement of over 6 times. This study provides a more efficient operational process for synthesizing virus genomes from scratch, indicating greater potential for virus engineering in epidemic prevention and control and the field of biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

2. Leveraging Synthetic Virology for the Rapid Engineering of Vesicular Stomatitis Virus (VSV).

Author

Moles, Chad M., Basu, Rupsa, Weijmarshausen, Peter, Ho, Brenda, Farhat, Manal, Flaat, Taylor, and Smith, Bruce F.

Subjects

*MOLECULAR biology, *VESICULAR stomatitis, *VIROLOGY, *SYNTHETIC biology, *CONTRACTING out

Abstract

Vesicular stomatitis virus (VSV) is a prototype RNA virus that has been instrumental in advancing our understanding of viral molecular biology and has applications in vaccine development, cancer therapy, antiviral screening, and more. Current VSV genome plasmids for purchase or contract virus services provide limited options for modification, restricted to predefined cloning sites and insert locations. Improved methods and tools to engineer VSV will unlock further insights into long-standing virology questions and new opportunities for innovative therapies. Here, we report the design and construction of a full-length VSV genome. The 11,161 base pair synthetic VSV (synVSV) was assembled from four modularized DNA fragments. Following rescue and titration, phenotypic analysis showed no significant differences between natural and synthetic viruses. To demonstrate the utility of a synthetic virology platform, we then engineered VSV with a foreign glycoprotein, a common use case for studying viral entry and developing anti-virals. To show the freedom of design afforded by this platform, we then modified the genome of VSV by rearranging the gene order, switching the positions of VSV-P and VSV-M genes. This work represents a significant technical advance, providing a flexible, cost-efficient platform for the rapid construction of VSV genomes, facilitating the development of innovative therapies. [ABSTRACT FROM AUTHOR]

Published

2024

3. Leveraging Synthetic Virology for the Rapid Engineering of Vesicular Stomatitis Virus (VSV)

Author

Chad M. Moles, Rupsa Basu, Peter Weijmarshausen, Brenda Ho, Manal Farhat, Taylor Flaat, and Bruce F. Smith

Subjects

VSV, virology, synthetic biology, synthetic virology, genome assembly, virus engineering, Microbiology, QR1-502

Abstract

Vesicular stomatitis virus (VSV) is a prototype RNA virus that has been instrumental in advancing our understanding of viral molecular biology and has applications in vaccine development, cancer therapy, antiviral screening, and more. Current VSV genome plasmids for purchase or contract virus services provide limited options for modification, restricted to predefined cloning sites and insert locations. Improved methods and tools to engineer VSV will unlock further insights into long-standing virology questions and new opportunities for innovative therapies. Here, we report the design and construction of a full-length VSV genome. The 11,161 base pair synthetic VSV (synVSV) was assembled from four modularized DNA fragments. Following rescue and titration, phenotypic analysis showed no significant differences between natural and synthetic viruses. To demonstrate the utility of a synthetic virology platform, we then engineered VSV with a foreign glycoprotein, a common use case for studying viral entry and developing anti-virals. To show the freedom of design afforded by this platform, we then modified the genome of VSV by rearranging the gene order, switching the positions of VSV-P and VSV-M genes. This work represents a significant technical advance, providing a flexible, cost-efficient platform for the rapid construction of VSV genomes, facilitating the development of innovative therapies.

Published

2024

4. Oncolytic Virotherapy: A New Paradigm in Cancer Immunotherapy.

Author

Volovat, Simona Ruxandra, Scripcariu, Dragos Viorel, Vasilache, Ingrid Andrada, Stolniceanu, Cati Raluca, Volovat, Constantin, Augustin, Iolanda Georgiana, Volovat, Cristian Constantin, Ostafe, Madalina-Raluca, Andreea-Voichița, Slevoacă-Grigore, Bejusca-Vieriu, Toni, Lungulescu, Cristian Virgil, Sur, Daniel, and Boboc, Diana

Subjects

*ONCOLYTIC virotherapy, *RECOMBINANT viruses, *IMMUNOTHERAPY, *CANCER treatment, *LUNGS, *BRAF genes, *DENDRITIC cells, *ENERGY metabolism

Abstract

Oncolytic viruses (OVs) are emerging as potential treatment options for cancer. Natural and genetically engineered viruses exhibit various antitumor mechanisms. OVs act by direct cytolysis, the potentiation of the immune system through antigen release, and the activation of inflammatory responses or indirectly by interference with different types of elements in the tumor microenvironment, modification of energy metabolism in tumor cells, and antiangiogenic action. The action of OVs is pleiotropic, and they show varied interactions with the host and tumor cells. An important impediment in oncolytic virotherapy is the journey of the virus into the tumor cells and the possibility of its binding to different biological and nonbiological vectors. OVs have been demonstrated to eliminate cancer cells that are resistant to standard treatments in many clinical trials for various cancers (melanoma, lung, and hepatic); however, there are several elements of resistance to the action of viruses per se. Therefore, it is necessary to evaluate the combination of OVs with other standard treatment modalities, such as chemotherapy, immunotherapy, targeted therapies, and cellular therapies, to increase the response rate. This review provides a comprehensive update on OVs, their use in oncolytic virotherapy, and the future prospects of this therapy alongside the standard therapies currently used in cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2024

5. TheraVision: Engineering platform technology for the development of oncolytic viruses based on herpes simplex virus type 1

Author

Christina Funk, Nadja Uhlig, Zsolt Ruzsics, Florentin Baur, Matthias Peindl, Sarah Nietzer, Karina Epting, Gabriele Vacun, Gudrun Dandekar, Catherine Botteron, Christian Werno, Thomas Grunwald, and Susanne M. Bailer

Subjects

MT: Regular Issue, oncolytic virotherapy, combined virus immunotherapy, tumor therapy, NSCLC, virus engineering, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Viruses are able to efficiently penetrate cells, multiply, and eventually kill infected cells, release tumor antigens, and activate the immune system. Therefore, viruses are highly attractive novel agents for cancer therapy. Clinical trials with first generations of oncolytic viruses (OVs) are very promising but show significant need for optimization. The aim of TheraVision was to establish a broadly applicable engineering platform technology for combinatorial oncolytic virus and immunotherapy. Through genetic engineering, an attenuated herpes simplex virus type 1 (HSV1) was generated that showed increased safety compared to the wild-type strain. To demonstrate the modularity and the facilitated generation of new OVs, two transgenes encoding retargeting as well as immunomodulating single-chain variable fragments (scFvs) were integrated into the platform vector. The resulting virus selectively infected epidermal growth factor receptor (EGFR)-expressing cells and produced a functional immune checkpoint inhibitor against programmed cell death protein 1 (PD-1). Thus, both viral-mediated oncolysis and immune-cell-mediated therapy were combined into a single viral vector. Safety and functionality of the armed OVs have been shown in novel preclinical models ranging from patient-derived organoids and tissue-engineered human in vitro 3D tumor models to complex humanized mouse models. Consequently, a novel and proprietary engineering platform vector based on HSV1 is available for the facilitated preclinical development of oncolytic virotherapy.

Published

2024

6. Attenuating RNA Viruses with Expanded Genetic Codes to Evoke Adjustable Immune Response in PylRS- tRNA CUA Pyl Transgenic Mice.

Author

Zheng, Zhetao, Wu, Xuesheng, Wang, Yu, Yang, Xu, Chen, Hongmin, Shen, Yuxuan, Yang, Yuelin, and Xia, Qing

Subjects

VIRAL genetics, TRANSGENIC mice, RNA viruses, TRANSFER RNA, IMMUNE response

Abstract

Ribonucleic acid (RNA) viruses pose heavy burdens on public-health systems. Synthetic biology holds great potential for artificially controlling their replication, a strategy that could be used to attenuate infectious viruses but is still in the exploratory stage. Herein, we used the genetic-code expansion technique to convert Enterovirus 71 (EV71), a prototypical RNA virus, into a controllable EV71 strain carrying the unnatural amino acid (UAA) Nε-2-azidoethyloxycarbonyl-L-lysine (NAEK), which we termed an EV71-NAEK virus. After NAEK supplementation, EV71-NAEK could recapitulate an authentic NAEK time- and dose-dependent infection in vitro, which could serve as a novel method to manipulate virulent viruses in conventional laboratories. We further validated the prophylactic effect of EV71-NAEK in two mouse models. In susceptible parent mice, vaccination with EV71-NAEK elicited a strong immune response and protected their neonatal offspring from lethal challenges similar to that of commercial vaccines. Meanwhile, in transgenic mice harboring a PylRS- tRNA CUA Pyl pair, substantial elements of genetic-code expansion technology, EV71-NAEK evoked an adjustable neutralizing-antibody response in a strictly external NAEK dose-dependent manner. These findings suggested that EV71-NAEK could be the basis of a feasible immunization program for populations with different levels of immunity. Moreover, we expanded the strategy to generate controllable coxsackieviruses for conceptual verification. In combination, these results could underlie a competent strategy for attenuating viruses and priming the immune system via artificial control, which might be a promising direction for the development of amenable vaccine candidates and be broadly applied to other RNA viruses. [ABSTRACT FROM AUTHOR]

Published

2023

7. ORACLE reveals a bright future to fight bacteria.

Author

Coyote-Maestas, Willow and Fraser, James S

Subjects

Humans, Bacteria, Bacteriophages, bacteriophage, biochemistry, chemical biology, deep mutational scanning, phage, synthetic biology, tail fiber, virus, virus engineering, Biochemistry and Cell Biology

Abstract

A new way to alter the genome of bacteriophages helps produce large libraries of variants, allowing these bacteria-killing viruses to be designed to target species harmful to human health.

Published

2021

8. Attenuating RNA Viruses with Expanded Genetic Codes to Evoke Adjustable Immune Response in PylRS-tRNACUAPyl Transgenic Mice

Author

Zhetao Zheng, Xuesheng Wu, Yu Wang, Xu Yang, Hongmin Chen, Yuxuan Shen, Yuelin Yang, and Qing Xia

Subjects

genetic code expansion, virus engineering, defective interfering particles, replication-incompetent virus, virus evolution, Medicine

Abstract

Ribonucleic acid (RNA) viruses pose heavy burdens on public-health systems. Synthetic biology holds great potential for artificially controlling their replication, a strategy that could be used to attenuate infectious viruses but is still in the exploratory stage. Herein, we used the genetic-code expansion technique to convert Enterovirus 71 (EV71), a prototypical RNA virus, into a controllable EV71 strain carrying the unnatural amino acid (UAA) Nε-2-azidoethyloxycarbonyl-L-lysine (NAEK), which we termed an EV71-NAEK virus. After NAEK supplementation, EV71-NAEK could recapitulate an authentic NAEK time- and dose-dependent infection in vitro, which could serve as a novel method to manipulate virulent viruses in conventional laboratories. We further validated the prophylactic effect of EV71-NAEK in two mouse models. In susceptible parent mice, vaccination with EV71-NAEK elicited a strong immune response and protected their neonatal offspring from lethal challenges similar to that of commercial vaccines. Meanwhile, in transgenic mice harboring a PylRS-tRNACUAPyl pair, substantial elements of genetic-code expansion technology, EV71-NAEK evoked an adjustable neutralizing-antibody response in a strictly external NAEK dose-dependent manner. These findings suggested that EV71-NAEK could be the basis of a feasible immunization program for populations with different levels of immunity. Moreover, we expanded the strategy to generate controllable coxsackieviruses for conceptual verification. In combination, these results could underlie a competent strategy for attenuating viruses and priming the immune system via artificial control, which might be a promising direction for the development of amenable vaccine candidates and be broadly applied to other RNA viruses.

Published

2023

9. Construction and Rescue of a Rabies Virus with Duplicated Glycoprotein Gene

Author

Ashkan Alamdary, Alireza Gholami, Mohammad Azizi, and Zahra Noormohammadi

Subjects

rabies, reverse genetics, rabies glycoprotein, virus engineering, Medicine, Science

Abstract

Introduction: Rabies is almost always fatal but entirely preventable through proper vaccination. Inadequacy of costly high-quality cell culture vaccines is sometimes a bottleneck for expanded rabies control plans. Reverse genetics along with other molecular biology means are trying to improve the immunogenicity and yield of rabies vaccine products. Methods: An additional glycoprotein gene of the rabies virus PV strain was inserted between the glycoprotein and polymerase genes of the virus. The viral proteins were expressed at the T7BHK cell line to rescue the recombinant virus. Results: The recombinant virus containing two consecutive glycoprotein genes was rescued from T7BHK cells. The virus particles were functional and successfully infected the permissive BSR cell line. Conclusion: The new virus strain with an additive copy of the glycoprotein gene has a good potential to be utilized in different studies, including cell biology and immunological properties of the rabies virus. In this study, the recombinant rabies virus was successfully rescued from cell culture which would pave the way for further investigations on this virus.

Published

2021

10. Recombinant Rabies Virus With a Multiple Cloning Site: A Platform Capable of Immunological Alterations.

Author

Naghi Mousavi, Seyed Hamidreza, Gholami, Alireza, Jafarinia, Mojtaba, and Ajorloo, Mehdi

Subjects

RABIES virus, VIRUS cloning, RECOMBINANT viruses, IMMUNE system, VIRAL genomes

Abstract

Background: Rabies is fatal encephalitis, i.e., preventable by appropriate vaccination. Reverse genetics has proved promising for manipulating the rabies virus immunological characteristics. The insertion or deletion of a gene from the rabies genome could render specific functions to the rabies virus. Materials and Methods: A multiple cloning site including 111 nucleotides long harboring 10 singlecut restriction sites have been designed. The designed fragment was cloned between the G and L genes of the rabies virus genome. The recombinant rabies virus was rescued, and its infectivity was confirmed in the BHK-21 cell line. The recombinant virus propagation was compared with the initial rabies virus strain. Statistical analysis was performed using GraphPad Prism. Results: The cloning and localization of the multiple cloning site were verified by nucleotide sequencing. The recombinant virus properly propagated and rescued in the BHK-21 cell line. Comparing the recombinant virus with the initial rabies virus has shown that both viruses had similar functionality and propagation rate. Conclusion: The recombinant virus obtained in the present study could facilitate further cloning experiments. Examples include constructing a marker virus, carrying green fluorescent protein to be used either in rabies immunity assays or tracking the virus infection in relevant tissues. [ABSTRACT FROM AUTHOR]

Published

2022

11. ORACLE reveals a bright future to fight bacteria

Author

Willow Coyote-Maestas and James S Fraser

Subjects

bacteriophage, phage, virus engineering, deep mutational scanning, synthetic biology, tail fiber, Medicine, Science, Biology (General), QH301-705.5

Abstract

A new way to alter the genome of bacteriophages helps produce large libraries of variants, allowing these bacteria-killing viruses to be designed to target species harmful to human health.

Published

2021

12. Biotechnological and Biomedical Applications of Protein Engineering Methods

Author

Poluri, Krishna Mohan, Gulati, Khushboo, Kacprzyk, Janusz, Series editor, Poluri, Krishna Mohan, and Gulati, Khushboo

Published

2017

13. Viro-antibody therapy: engineering oncolytic viruses for genetic delivery of diverse antibody-based biotherapeutics

Author

Roland E. Kontermann, Guy Ungerechts, and Dirk M. Nettelbeck

Subjects

Oncolytic virus, therapeutic antibody, gene therapy, genetic antibody delivery, virus engineering, antibody engineering, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

Cancer therapeutics approved for clinical application include oncolytic viruses and antibodies, which evolved by nature, but were improved by molecular engineering. Both facilitate outstanding tumor selectivity and pleiotropic activities, but also face challenges, such as tumor heterogeneity and limited tumor penetration. An innovative strategy to address these challenges combines both agents in a single, multitasking therapeutic, i.e., an oncolytic virus engineered to express therapeutic antibodies. Such viro-antibody therapies genetically deliver antibodies to tumors from amplified virus genomes, thereby complementing viral oncolysis with antibody-defined therapeutic action. Here, we review the strategies of viro-antibody therapy that have been pursued exploiting diverse virus platforms, antibody formats, and antibody-mediated modes of action. We provide a comprehensive overview of reported antibody-encoding oncolytic viruses and highlight the achievements of 13 years of viro-antibody research. It has been shown that functional therapeutic antibodies of different formats can be expressed in and released from cancer cells infected with different oncolytic viruses. Virus-encoded antibodies have implemented direct tumor cell killing, anti-angiogenesis, or activation of adaptive immune responses to kill tumor cells, tumor stroma cells or inhibitory immune cells. Importantly, numerous reports have shown therapeutic activity complementary to viral oncolysis for these modalities. Also, challenges for future research have been revealed. Established engineering technologies for both oncolytic viruses and antibodies will enable researchers to address these challenges, facilitating the development of effective viro-antibody therapeutics.

Published

2021

14. Design of Novel Synthetic RNA Replicons Based on Emesvirus zinderi .

Author

Wagner A and Mutschler H

Subjects

Synthetic Biology methods, RNA-Dependent RNA Polymerase genetics, RNA-Dependent RNA Polymerase metabolism, RNA, Viral genetics, Replicon genetics

Abstract

Self-replicating RNAs (srRNAs) are synthetic molecules designed to mimic the self-replicating ability of viral RNAs. srRNAs hold significant promise for a range of applications, including enhancing protein expression, reprogramming cells into pluripotent stem cells, and creating cell-free systems for experimental evolution. However, the development of srRNAs for use in bacterial systems remains limited. Here, we demonstrate how a srRNA scaffold from Emesvirus zinderi can be engineered into a self-encoding srRNA by incorporating the coding region of the catalytically active replicase subunit. With the help of in vitro replication assays, including an in vitro translation-coupled replication approach, we show that the resulting system enables complete replication cycles of RNA both in cis and trans, including long cargo RNAs such as tethered 5S, 16S, and 23S rRNAs. In summary, our findings suggest that these srRNAs have significant potential for fundamental research, synthetic biology, and general in vitro evolution.

Published

2024

15. Corrigendum: Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC

Author

Mubalake Abudoureyimu, Yongting Lai, Chuan Tian, Ting Wang, Rui Wang, and Xiaoyuan Chu

Subjects

gene-targeted oncolytic viral therapy, adenovirus, HCC, immunotherapy, virus engineering, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2020

16. Virotherapy in Germany—Recent Activities in Virus Engineering, Preclinical Development, and Clinical Studies

Author

Dirk M. Nettelbeck, Mathias F. Leber, Jennifer Altomonte, Assia Angelova, Julia Beil, Susanne Berchtold, Maike Delic, Jürgen Eberle, Anja Ehrhardt, Christine E. Engeland, Henry Fechner, Karsten Geletneky, Katrin Goepfert, Per Sonne Holm, Stefan Kochanek, Florian Kreppel, Lea Krutzke, Florian Kühnel, Karl Sebastian Lang, Antonio Marchini, Markus Moehler, Michael D. Mühlebach, Ulrike Naumann, Roman Nawroth, Jürg Nüesch, Jean Rommelaere, Ulrich M. Lauer, and Guy Ungerechts

Subjects

oncolytic virus, virotherapy, research in Germany, virus engineering, virus targeting, therapeutic transgene, Microbiology, QR1-502

Abstract

Virotherapy research involves the development, exploration, and application of oncolytic viruses that combine direct killing of cancer cells by viral infection, replication, and spread (oncolysis) with indirect killing by induction of anti-tumor immune responses. Oncolytic viruses can also be engineered to genetically deliver therapeutic proteins for direct or indirect cancer cell killing. In this review—as part of the special edition on “State-of-the-Art Viral Vector Gene Therapy in Germany”—the German community of virotherapists provides an overview of their recent research activities that cover endeavors from screening and engineering viruses as oncolytic cancer therapeutics to their clinical translation in investigator-initiated and sponsored multi-center trials. Preclinical research explores multiple viral platforms, including new isolates, serotypes, or fitness mutants, and pursues unique approaches to engineer them towards increased safety, shielded or targeted delivery, selective or enhanced replication, improved immune activation, delivery of therapeutic proteins or RNA, and redirecting antiviral immunity for cancer cell killing. Moreover, several oncolytic virus-based combination therapies are under investigation. Clinical trials in Germany explore the safety and potency of virotherapeutics based on parvo-, vaccinia, herpes, measles, reo-, adeno-, vesicular stomatitis, and coxsackie viruses, including viruses encoding therapeutic proteins or combinations with immune checkpoint inhibitors. These research advances represent exciting vantage points for future endeavors of the German virotherapy community collectively aimed at the implementation of effective virotherapeutics in clinical oncology.

Published

2021

17. Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC

Author

Mubalake Abudoureyimu, Yongting Lai, Chuan Tian, Ting Wang, Rui Wang, and Xiaoyuan Chu

Subjects

gene-targeted oncolytic viral therapy, adenovirus, HCC, immunotherapy, virus engineering, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Hepatocellular carcinoma (HCC) is one of the most frequent cancers worldwide, particularly in China. Despite the development of HCC treatment strategies, the survival rate remains unpleasant. Gene-targeted oncolytic viral therapy (GTOVT) is an emerging treatment modality—a kind of cancer-targeted therapy—which creates viral vectors armed with anti-cancer genes. The adenovirus is a promising agent for GAOVT due to its many advantages. In spite of the oncolytic adenovirus itself, the host immune response is the determining factor for the anti-cancer efficacy. In this review, we have summarized recent developments in oncolytic adenovirus engineering and the development of novel therapeutic genes utilized in HCC treatment. Furthermore, the diversified roles the immune response plays in oncolytic adenovirus therapy and recent attempts to modulate immune responses to enhance the anti-cancer efficacy of oncolytic adenovirus have been discussed.

Published

2019

18. TheraVision: Engineering platform technology for the development of oncolytic viruses based on herpes simplex virus type 1.

Author

Funk C, Uhlig N, Ruzsics Z, Baur F, Peindl M, Nietzer S, Epting K, Vacun G, Dandekar G, Botteron C, Werno C, Grunwald T, and Bailer SM

Abstract

Viruses are able to efficiently penetrate cells, multiply, and eventually kill infected cells, release tumor antigens, and activate the immune system. Therefore, viruses are highly attractive novel agents for cancer therapy. Clinical trials with first generations of oncolytic viruses (OVs) are very promising but show significant need for optimization. The aim of TheraVision was to establish a broadly applicable engineering platform technology for combinatorial oncolytic virus and immunotherapy. Through genetic engineering, an attenuated herpes simplex virus type 1 (HSV1) was generated that showed increased safety compared to the wild-type strain. To demonstrate the modularity and the facilitated generation of new OVs, two transgenes encoding retargeting as well as immunomodulating single-chain variable fragments (scFvs) were integrated into the platform vector. The resulting virus selectively infected epidermal growth factor receptor (EGFR)-expressing cells and produced a functional immune checkpoint inhibitor against programmed cell death protein 1 (PD-1). Thus, both viral-mediated oncolysis and immune-cell-mediated therapy were combined into a single viral vector. Safety and functionality of the armed OVs have been shown in novel preclinical models ranging from patient-derived organoids and tissue-engineered human in vitro 3D tumor models to complex humanized mouse models. Consequently, a novel and proprietary engineering platform vector based on HSV1 is available for the facilitated preclinical development of oncolytic virotherapy., Competing Interests: A patent is pending filed by Funk and Bailer entitled "platform vector based on herpes simplex virus 1 (HSV1) for the modular insertion of transgenes for use in oncolytic virus therapy.”, (© 2024 The Authors.)

Published

2024

19. Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC.

Author

Abudoureyimu, Mubalake, Lai, Yongting, Tian, Chuan, Wang, Ting, Wang, Rui, and Chu, Xiaoyuan

Subjects

ADENOVIRUSES, HEPATOCELLULAR carcinoma, IMMUNE response

Abstract

Hepatocellular carcinoma (HCC) is one of the most frequent cancers worldwide, particularly in China. Despite the development of HCC treatment strategies, the survival rate remains unpleasant. Gene-targeted oncolytic viral therapy (GTOVT) is an emerging treatment modality—a kind of cancer-targeted therapy—which creates viral vectors armed with anti-cancer genes. The adenovirus is a promising agent for GAOVT due to its many advantages. In spite of the oncolytic adenovirus itself, the host immune response is the determining factor for the anti-cancer efficacy. In this review, we have summarized recent developments in oncolytic adenovirus engineering and the development of novel therapeutic genes utilized in HCC treatment. Furthermore, the diversified roles the immune response plays in oncolytic adenovirus therapy and recent attempts to modulate immune responses to enhance the anti-cancer efficacy of oncolytic adenovirus have been discussed. [ABSTRACT FROM AUTHOR]

Published

2019

20. Engineered Small-Molecule Control of Influenza A Virus Replication.

Author

Fay, Elizabeth J., Aron, Stephanie L., Stone, Ian A., Waring, Barbara M., Plemper, Richard K., and Langlois, Ryan A.

Subjects

*INFLUENZA A virus, *VIRAL replication, *SMALL molecules, *VIRAL vaccines, *VIRAL proteins

Abstract

Influenza A virus (IAV) remains a global health concern despite the availability of a seasonal vaccine. It is difficult to predict which strains will circulate during influenza season, and therefore, it is extremely challenging to test novel vaccines in the human population. To overcome this obstacle, new vaccines must be tested in challenge studies. This approach poses significant safety problems, since current pharmacological interventions for IAV are poorly efficacious. New methods are needed to enhance the safety of these challenge studies. In this study, we have generated a virus expressing a small-molecule-assisted shutoff (SMASh) tag as a safety switch for IAV replication. The addition of the SMASh tag to an essential IAV protein allows for small-molecule-mediated inhibition of replication. Treatment with this drug controls the replication of a SMASh-tagged virus in vitro and in vivo. This model for restriction of viral replication has potential for broad applications in vaccine studies, virotherapy, and basic virus research. IMPORTANCE Influenza A virus (IAV) causes significant morbidity and mortality annually worldwide, despite the availability of new formulations of the vaccine each season. There is a critical need to develop more-efficacious vaccines. However, testing novel vaccines in the human population in controlled studies is difficult due to the limited availability and efficacy of intervention strategies should the vaccine fail. There are also significant safety concerns for work with highly pathogenic IAV strains in the laboratory. Therefore, novel strategies are needed to improve the safety of vaccine studies and of research on highly pathogenic IAV. In this study, we developed an IAV strain engineered to contain a small-molecule-mediated safety switch. This tag, when attached to an essential viral protein, allows for the regulation of IAV replication in vitro and in vivo. This strategy provides a platform for the regulation of virus replication without targeting viral proteins directly. [ABSTRACT FROM AUTHOR]

Published

2019

21. Mechanical Properties of Viruses

Author

de Pablo, Pedro J., Mateu, Mauricio G., and Mateu, Mauricio G., editor

Published

2013

22. Attenuating RNA Viruses with Expanded Genetic Codes to Evoke Adjustable Immune Response in PylRS-tRNACUAPyl Transgenic Mice.

Author

Zheng Z, Wu X, Wang Y, Yang X, Chen H, Shen Y, Yang Y, and Xia Q

Abstract

Ribonucleic acid (RNA) viruses pose heavy burdens on public-health systems. Synthetic biology holds great potential for artificially controlling their replication, a strategy that could be used to attenuate infectious viruses but is still in the exploratory stage. Herein, we used the genetic-code expansion technique to convert Enterovirus 71 (EV71), a prototypical RNA virus, into a controllable EV71 strain carrying the unnatural amino acid (UAA) Nε-2-azidoethyloxycarbonyl-L-lysine (NAEK), which we termed an EV71-NAEK virus. After NAEK supplementation, EV71-NAEK could recapitulate an authentic NAEK time- and dose-dependent infection in vitro, which could serve as a novel method to manipulate virulent viruses in conventional laboratories. We further validated the prophylactic effect of EV71-NAEK in two mouse models. In susceptible parent mice, vaccination with EV71-NAEK elicited a strong immune response and protected their neonatal offspring from lethal challenges similar to that of commercial vaccines. Meanwhile, in transgenic mice harboring a PylRS-tRNACUAPyl pair, substantial elements of genetic-code expansion technology, EV71-NAEK evoked an adjustable neutralizing-antibody response in a strictly external NAEK dose-dependent manner. These findings suggested that EV71-NAEK could be the basis of a feasible immunization program for populations with different levels of immunity. Moreover, we expanded the strategy to generate controllable coxsackieviruses for conceptual verification. In combination, these results could underlie a competent strategy for attenuating viruses and priming the immune system via artificial control, which might be a promising direction for the development of amenable vaccine candidates and be broadly applied to other RNA viruses.

Published

2023

23. Small But Increasingly Mighty: Latest Advances in AAV Vector Research, Design, and Evolution.

Author

Grimm, Dirk and Büning, Hildegard

Subjects

*GENE therapy, *GENETIC engineering, *ADENO-associated virus, *GENETIC barcoding, *GENETIC vectors

Abstract

Recombinant gene delivery vectors derived from naturally occurring or genetically engineered adeno-associated viruses (AAV) have taken center stage in human gene therapy, fueled by rapidly accumulating and highly encouraging clinical data. Nonetheless, it has also become evident that the current generation of AAV vectors will require improvements in transduction potency, antibody evasion, and cell specificity in order to realize their full potential and to widen applicability in larger patient cohorts. Fortunately, in the recent past, the field has seen a flurry of exciting new developments that enhance our understanding of AAV vector biology, including virus-host interactions, and/or that expand our arsenal of technologies for AAV capsid design and evolution. This review highlights a collection of latest advances in these areas, which, in the authors' opinion, hold particular promise to propel the AAV vector field forward in the near future, especially when applied in combination. These include fundamental novel insights into the AAV life cycle, from an unexpected role of autophagy and interactions with other viruses to the (re-)discovery of a universal AAV receptor and the function of AAV-AAP for capsid assembly. Concurrently, recent successes in the rational design of next-generation synthetic AAV capsids are pointed out, exemplified by the structure-guided derivation of AAV mutants displaying robust in vivo immune evasion. Finally, a variety of new and innovative strategies for high-throughput generation and screening of AAV capsid libraries are briefly reviewed, including Cre recombinase-based selection, ancestral AAV capsid reconstruction, and DNA barcoding of AAV genomes. All of these examples showcase the present momentum in the AAV field and, together with work by many other academic or industrial entities, raise substantial optimism that the remaining hurdles for human gene therapy with AAV vectors will (soon) be overcome. [ABSTRACT FROM AUTHOR]

Published

2017

24. Designing and building oncolytic viruses.

Author

Maroun, Justin, Muñoz-Alía, Miguel, Ammayappan, Arun, Schulze, Autumn, Peng, Kah-Whye, and Russell, Stephen

Abstract

Oncolytic viruses (OVs) are engineered and/or evolved to propagate selectively in cancerous tissues. They have a dual mechanism of action; direct killing of infected cancer cells cross-primes anticancer immunity to boost the killing of uninfected cancer cells. The goal of the field is to develop OVs that are easily manufactured, efficiently delivered to disseminated sites of cancer growth, undergo rapid intratumoral spread, selectively kill tumor cells, cause no collateral damage and pose no risk of transmission in the population. Here we discuss the many virus engineering strategies that are being pursued to optimize delivery, intratumoral spread and safety of OVs derived from different virus families. With continued progress, OVs have the potential to transform the paradigm of cancer care. [ABSTRACT FROM AUTHOR]

Published

2017

25. Synthetic biology approach for the development of conditionally replicating HIV-1 vaccine.

Author

Wang, Nanxi, Yuan, Zhe, Niu, Wei, Li, Qingsheng, and Guo, Jiantao

Subjects

HIV infections, THERAPEUTICS, ANTIRETROVIRAL agents, COMBINATION drug therapy, SYNTHETIC biology, VIRAL replication, TREATMENT effectiveness

Abstract

While the combined antiretroviral therapy has resulted in a significant decrease in HIV-1 related morbidity and mortality, the HIV-1 pandemic has not been substantially averted. To curtail the 2.4 million new infections each year, a prophylactic HIV-1 vaccine is urgently needed. This review first summarizes four major completed clinical efficacy trials of prophylactic HIV-1 vaccine and their outcomes. Next, it discusses several other approaches that have not yet advanced to clinical efficacy trials, but provided valuable insights into vaccine design. Among them, live-attenuated vaccines ( LAVs) provided excellent protection in a non-human primate model. However, safety concerns have precluded the current version of LAVs from clinical application. As the major component of this review, two synthetic biology approaches for improving the safety of HIV-1 LAVs through controlling HIV-1 replication are discussed. Particular focus is on a novel approach that uses unnatural amino acid-mediated suppression of amber nonsense codon to generate conditionally replicating HIV-1 variants. The objective is to attract more attention towards this promising research field and to provoke creative designs and innovative utilization of the two control strategies. © 2016 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2017

26. Construction of a Live-Attenuated HIV-1 Vaccine through Genetic Code Expansion.

Author

Wang, Nanxi, Li, Yue, Niu, Wei, Sun, Ming, Cerny, Ronald, Li, Qingsheng, and Guo, Jiantao

Subjects

*GENETIC code, *VACCINATION, *HIV, *REPLICATION (Experimental design), *BIOSYNTHESIS

Abstract

A safe and effective vaccine against human immunodeficiency virus type 1 (HIV-1) is urgently needed to combat the worldwide AIDS pandemic, but still remains elusive. The fact that uncontrolled replication of an attenuated vaccine can lead to regaining of its virulence creates safety concerns precluding many vaccines from clinical application. We introduce a novel approach to control HIV-1 replication, which entails the manipulation of essential HIV-1 protein biosynthesis through unnatural amino acid (UAA*)-mediated suppression of genome-encoded blank codon. We successfully demonstrate that HIV-1 replication can be precisely turned on and off in vitro. [ABSTRACT FROM AUTHOR]

Published

2014

27. Corrigendum: Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC

Author

Xiaoyuan Chu, Mubalake Abudoureyimu, Chuan Tian, Rui Wang, Ting Wang, and Yongting Lai

Subjects

Oncolytic adenovirus, Cancer Research, business.industry, medicine.medical_treatment, adenovirus, Immunotherapy, gene-targeted oncolytic viral therapy, virus engineering, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, lcsh:RC254-282, Oncolytic virus, Oncology, medicine, Cancer research, Viral therapy, immunotherapy, HCC, business, Gene

Published

2020

28. Corrigendum: Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC

Author

Yongting Lai, Mubalake Abudoureyimu, Xiaoyuan Chu, Ting Wang, Chuan Tian, and Rui Wang

Subjects

0301 basic medicine, Oncolytic adenovirus, Cancer Research, viruses, medicine.medical_treatment, Review, lcsh:RC254-282, Viral vector, 03 medical and health sciences, 0302 clinical medicine, Immune system, medicine, Viral therapy, HCC, Gene, business.industry, Correction, Immunotherapy, adenovirus, gene-targeted oncolytic viral therapy, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, medicine.disease, virus engineering, Oncolytic virus, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, Hepatocellular carcinoma, Cancer research, immunotherapy, business

Abstract

Hepatocellular carcinoma (HCC) is one of the most frequent cancers worldwide, particularly in China. Despite the development of HCC treatment strategies, the survival rate remains unpleasant. Gene-targeted oncolytic viral therapy (GTOVT) is an emerging treatment modality—a kind of cancer-targeted therapy—which creates viral vectors armed with anti-cancer genes. The adenovirus is a promising agent for GAOVT due to its many advantages. In spite of the oncolytic adenovirus itself, the host immune response is the determining factor for the anti-cancer efficacy. In this review, we have summarized recent developments in oncolytic adenovirus engineering and the development of novel therapeutic genes utilized in HCC treatment. Furthermore, the diversified roles the immune response plays in oncolytic adenovirus therapy and recent attempts to modulate immune responses to enhance the anti-cancer efficacy of oncolytic adenovirus have been discussed.

Published

2020

29. Virotherapy in Germany—Recent Activities in Virus Engineering, Preclinical Development, and Clinical Studies

Author

Maike Delic, Roman Nawroth, Stefan Kochanek, Jürgen Eberle, Jean Rommelaere, Florian Kühnel, Julia Beil, Karl S. Lang, Mathias F. Leber, Antonio Marchini, Anja Ehrhardt, Karsten Geletneky, Susanne Berchtold, Katrin Goepfert, Jennifer Altomonte, Florian Kreppel, Guy Ungerechts, Henry Fechner, Dirk M. Nettelbeck, Per Sonne Holm, Ulrike Naumann, Assia L. Angelova, Jürg P. F. Nüesch, Michael D. Mühlebach, Markus Moehler, Christine E. Engeland, Ulrich M. Lauer, and Lea Krutzke

Subjects

0301 basic medicine, medicine.medical_treatment, Genetic enhancement, virus targeting, Medizin, Review, combination therapy, chemistry.chemical_compound, DDC 570 / Life sciences, Clinical trials, 0302 clinical medicine, Klinisches Experiment, Germany, Neoplasms, Medicine, immunotherapy, therapeutic transgene, Virustherapie, clinical trials, virus engineering, oncolytic virus, research in Germany, virotherapy, Oncolytic Virotherapy, Clinical Trials as Topic, Kombinationstherapie, QR1-502, 3. Good health, Oncolytic Viruses, Infectious Diseases, 030220 oncology & carcinogenesis, Immunotherapy, Genetic Engineering, Microbiology, Virus, Viral vector, 03 medical and health sciences, Immune system, ddc:570, Virology, Animals, Humans, Virotherapy, business.industry, Oncolytic virus, Immuntherapie, 030104 developmental biology, chemistry, Vaccinia, business

Abstract

Virotherapy research involves the development, exploration, and application of oncolytic viruses that combine direct killing of cancer cells by viral infection, replication, and spread (oncolysis) with indirect killing by induction of anti-tumor immune responses. Oncolytic viruses can also be engineered to genetically deliver therapeutic proteins for direct or indirect cancer cell killing. In this review—as part of the special edition on “State-of-the-Art Viral Vector Gene Therapy in Germany”—the German community of virotherapists provides an overview of their recent research activities that cover endeavors from screening and engineering viruses as oncolytic cancer therapeutics to their clinical translation in investigator-initiated and sponsored multi-center trials. Preclinical research explores multiple viral platforms, including new isolates, serotypes, or fitness mutants, and pursues unique approaches to engineer them towards increased safety, shielded or targeted delivery, selective or enhanced replication, improved immune activation, delivery of therapeutic proteins or RNA, and redirecting antiviral immunity for cancer cell killing. Moreover, several oncolytic virus-based combination therapies are under investigation. Clinical trials in Germany explore the safety and potency of virotherapeutics based on parvo-, vaccinia, herpes, measles, reo-, adeno-, vesicular stomatitis, and coxsackie viruses, including viruses encoding therapeutic proteins or combinations with immune checkpoint inhibitors. These research advances represent exciting vantage points for future endeavors of the German virotherapy community collectively aimed at the implementation of effective virotherapeutics in clinical oncology., publishedVersion

Published

2021

30. Designing and building oncolytic viruses

Author

Autumn J Schulze, Kah Whye Peng, Miguel Ángel Muñoz-Alía, Arun Ammayappan, Stephen J. Russell, and Justin W. Maroun

Subjects

0301 basic medicine, Anticancer immunity, education.field_of_study, Population, virus targeting, Cancer, Review, Biology, virus engineering, medicine.disease, Virology, Virus, Oncolytic virus, 03 medical and health sciences, 030104 developmental biology, Cancer cell, medicine, cancer therapy, oncolytic immunotherapy, Virotherapy, education, oncolytic virotherapy, Virus classification

Abstract

Oncolytic viruses (OVs) are engineered and/or evolved to propagate selectively in cancerous tissues. They have a dual mechanism of action; direct killing of infected cancer cells cross-primes anticancer immunity to boost the killing of uninfected cancer cells. The goal of the field is to develop OVs that are easily manufactured, efficiently delivered to disseminated sites of cancer growth, undergo rapid intratumoral spread, selectively kill tumor cells, cause no collateral damage and pose no risk of transmission in the population. Here we discuss the many virus engineering strategies that are being pursued to optimize delivery, intratumoral spread and safety of OVs derived from different virus families. With continued progress, OVs have the potential to transform the paradigm of cancer care.

Published

2017

31. oHSV Genome Editing by Means of galK Recombineering

Author

Andrea Vannini, Tatiana Gianni, Laura Menotti, Valerio Leoni, Biljana Petrovic, Simona Pepe, Gabriella Campadelli-Fiume, Valentina Gatta, Russell J. Diefenbach, Cornel Fraefel, and Laura Menotti, Valerio Leoni, Valentina Gatta, Biljana Petrovic, Andrea Vannini, Simona Pepe, Tatiana Gianni, Gabriella Campadelli-Fiume

Subjects

0301 basic medicine, Bacterial artificial chromosome, Virus arming, viruses, Virus engineering, Computational biology, Amplicon, Biology, Recombinant virus, medicine.disease_cause, Genome, Recombineering, galK recombineering, Interleukin 12, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Herpes simplex virus, Genome editing, 030220 oncology & carcinogenesis, medicine, Herpes simplex viru, Transgene expression, Oncolytic virotherapy, Gene

Abstract

Since the cloning of the herpes simplex virus (HSV) genome as BAC (bacterial artificial chromosome), the genetic engineering of the viral genome has become readily feasible. The advantage is that the modification of the animal virus genome is carried out in bacteria, with no replication or production of viral progeny, and is separated from the reconstitution or regeneration of the recombinant virus in mammalian cells. This allows an easy engineering of essential genes, as well. Many technologies have been developed for herpesvirus BAC engineering. In our hands the most powerful is galK recombineering that exploits a single marker (galK) for positive and negative selection and PCR amplicons for seamless modification in the desired genome locus. Here we describe the engineering of the HSV recombinant BAC 115 by the insertion of a heterologous cassette for the expression of murine interleukin 12 (mIL12) in the intergenic sequence between US1 and US2 ORFs.

Published

2019

32. Virotherapy in Germany—Recent Activities in Virus Engineering, Preclinical Development, and Clinical Studies.

Author

Nettelbeck, Dirk M., Leber, Mathias F., Altomonte, Jennifer, Angelova, Assia, Beil, Julia, Berchtold, Susanne, Delic, Maike, Eberle, Jürgen, Ehrhardt, Anja, Engeland, Christine E., Fechner, Henry, Geletneky, Karsten, Goepfert, Katrin, Holm, Per Sonne, Kochanek, Stefan, Kreppel, Florian, Krutzke, Lea, Kühnel, Florian, Lang, Karl Sebastian, and Marchini, Antonio

Subjects

*IMMUNE checkpoint proteins, *VIROTHERAPY, *GENETIC vectors, *IMMUNE checkpoint inhibitors, *VIRUS diseases, *TISSUE engineering

Abstract

Virotherapy research involves the development, exploration, and application of oncolytic viruses that combine direct killing of cancer cells by viral infection, replication, and spread (oncolysis) with indirect killing by induction of anti-tumor immune responses. Oncolytic viruses can also be engineered to genetically deliver therapeutic proteins for direct or indirect cancer cell killing. In this review—as part of the special edition on "State-of-the-Art Viral Vector Gene Therapy in Germany"—the German community of virotherapists provides an overview of their recent research activities that cover endeavors from screening and engineering viruses as oncolytic cancer therapeutics to their clinical translation in investigator-initiated and sponsored multi-center trials. Preclinical research explores multiple viral platforms, including new isolates, serotypes, or fitness mutants, and pursues unique approaches to engineer them towards increased safety, shielded or targeted delivery, selective or enhanced replication, improved immune activation, delivery of therapeutic proteins or RNA, and redirecting antiviral immunity for cancer cell killing. Moreover, several oncolytic virus-based combination therapies are under investigation. Clinical trials in Germany explore the safety and potency of virotherapeutics based on parvo-, vaccinia, herpes, measles, reo-, adeno-, vesicular stomatitis, and coxsackie viruses, including viruses encoding therapeutic proteins or combinations with immune checkpoint inhibitors. These research advances represent exciting vantage points for future endeavors of the German virotherapy community collectively aimed at the implementation of effective virotherapeutics in clinical oncology. [ABSTRACT FROM AUTHOR]

Published

2021

33. Corrigendum: Oncolytic Adenovirus—A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC.

Author

Abudoureyimu, Mubalake, Lai, Yongting, Tian, Chuan, Wang, Ting, Wang, Rui, and Chu, Xiaoyuan

Subjects

ADENOVIRUSES, IMMUNOTHERAPY, GEOGRAPHIC boundaries, THERAPEUTICS

Abstract

Corrigendum: Oncolytic Adenovirus - A Nova for Gene-Targeted Oncolytic Viral Therapy in HCC Keywords: gene-targeted oncolytic viral therapy; adenovirus; HCC; immunotherapy; virus engineering EN gene-targeted oncolytic viral therapy adenovirus HCC immunotherapy virus engineering 1 1 1 05/08/20 20200505 NES 200505 In the original article, we neglected to include the funder the Excellent Youth Foundation of Jiangsu Province, China, BK20140032 to Rui Wang. Gene-targeted oncolytic viral therapy, adenovirus, HCC, immunotherapy, virus engineering. [Extracted from the article]

Published

2020

34. ORACLE reveals a bright future to fight bacteria.

Author

Coyote-Maestas W and Fraser JS

Subjects

Bacteria genetics, Humans, Bacteriophages genetics

Abstract

A new way to alter the genome of bacteriophages helps produce large libraries of variants, allowing these bacteria-killing viruses to be designed to target species harmful to human health., Competing Interests: WC, JF No competing interests declared, (© 2021, Coyote-Maestas and Fraser.)

Published

2021

35. Viro-antibody therapy: engineering oncolytic viruses for genetic delivery of diverse antibody-based biotherapeutics.

Author

Kontermann RE, Ungerechts G, and Nettelbeck DM

Subjects

Genetic Therapy, Humans, Immunotherapy, Neoplasms pathology, Neoplasms therapy, Oncolytic Virotherapy, Oncolytic Viruses genetics

Abstract

Cancer therapeutics approved for clinical application include oncolytic viruses and antibodies, which evolved by nature, but were improved by molecular engineering. Both facilitate outstanding tumor selectivity and pleiotropic activities, but also face challenges, such as tumor heterogeneity and limited tumor penetration. An innovative strategy to address these challenges combines both agents in a single, multitasking therapeutic, i.e., an oncolytic virus engineered to express therapeutic antibodies. Such viro-antibody therapies genetically deliver antibodies to tumors from amplified virus genomes, thereby complementing viral oncolysis with antibody-defined therapeutic action. Here, we review the strategies of viro-antibody therapy that have been pursued exploiting diverse virus platforms, antibody formats, and antibody-mediated modes of action. We provide a comprehensive overview of reported antibody-encoding oncolytic viruses and highlight the achievements of 13 years of viro-antibody research. It has been shown that functional therapeutic antibodies of different formats can be expressed in and released from cancer cells infected with different oncolytic viruses. Virus-encoded antibodies have implemented direct tumor cell killing, anti-angiogenesis, or activation of adaptive immune responses to kill tumor cells, tumor stroma cells or inhibitory immune cells. Importantly, numerous reports have shown therapeutic activity complementary to viral oncolysis for these modalities. Also, challenges for future research have been revealed. Established engineering technologies for both oncolytic viruses and antibodies will enable researchers to address these challenges, facilitating the development of effective viro-antibody therapeutics.

Published

2021

36. oHSV Genome Editing by Means of galK Recombineering.

Author

Menotti L, Leoni V, Gatta V, Petrovic B, Vannini A, Pepe S, Gianni T, and Campadelli-Fiume G

Subjects

Animals, Mice, Chromosomes, Artificial, Bacterial genetics, Escherichia coli genetics, Escherichia coli Proteins, Galactokinase genetics, Gene Editing, Herpesvirus 1, Human genetics, Viral Proteins genetics

Abstract

Since the cloning of the herpes simplex virus (HSV) genome as BAC (bacterial artificial chromosome), the genetic engineering of the viral genome has become readily feasible. The advantage is that the modification of the animal virus genome is carried out in bacteria, with no replication or production of viral progeny, and is separated from the reconstitution or regeneration of the recombinant virus in mammalian cells. This allows an easy engineering of essential genes, as well. Many technologies have been developed for herpesvirus BAC engineering. In our hands the most powerful is galK recombineering that exploits a single marker (galK) for positive and negative selection and PCR amplicons for seamless modification in the desired genome locus. Here we describe the engineering of the HSV recombinant BAC 115 by the insertion of a heterologous cassette for the expression of murine interleukin 12 (mIL12) in the intergenic sequence between US1 and US2 ORFs.

Published

2020

37. Directed evolution of retroviruses activatable by tumour-associated matrix metalloproteases

Author

Schneider, R M, Medvedovska, Y, Hartl, I, Voelker, B, Chadwick, M P, Russell, S J, Cichutek, K, and Buchholz, C J

Published

2003

38. A Robust and All-Inclusive Pipeline for Shuffling of Adeno-Associated Viruses.

Author

Herrmann AK, Bender C, Kienle E, Grosse S, El Andari J, Botta J, Schürmann N, Wiedtke E, Niopek D, and Grimm D

Subjects

Evolution, Molecular, Gene Transfer Techniques, Dependovirus genetics, Genetic Vectors genetics

Abstract

Adeno-associated viruses (AAV) are attractive templates for engineering of synthetic gene delivery vectors. A particularly powerful technology for breeding of novel vectors with improved properties is DNA family shuffling, i.e., generation of chimeric capsids by homology-driven DNA recombination. Here, to make AAV DNA shuffling available to a wider community, we present a robust experimental and bioinformatical pipeline comprising: (i) standardized and partially codon-optimized plasmids carrying 12 different AAV capsid genes; (ii) a scalable protocol including troubleshooting guide for viral library production; and (iii) the freely available software SALANTO for comprehensive analysis of chimeric AAV DNA and protein sequences. Moreover, we describe a set of 12 premade and ready-to-use AAV libraries. Finally, we demonstrate the usefulness of DNA barcoding technology to trace AAV capsid libraries within a complex mixture. Our protocols and resources facilitate the implementation and tailoring of AAV evolution technology in any laboratory interested in customized viral gene transfer.

Published

2019

39. Engineered Small-Molecule Control of Influenza A Virus Replication.

Author

Fay EJ, Aron SL, Stone IA, Waring BM, Plemper RK, and Langlois RA

Subjects

A549 Cells, Animals, Antiviral Agents pharmacology, Dogs, HEK293 Cells, Humans, Influenza A virus drug effects, Influenza A virus genetics, Isoquinolines pharmacology, Madin Darby Canine Kidney Cells, Oseltamivir pharmacology, Recombinant Fusion Proteins genetics, Sulfonamides pharmacology, Virus Replication drug effects, Influenza A virus physiology, Protein Engineering methods, Recombinant Fusion Proteins metabolism, Small Molecule Libraries pharmacology

Abstract

Influenza A virus (IAV) remains a global health concern despite the availability of a seasonal vaccine. It is difficult to predict which strains will circulate during influenza season, and therefore, it is extremely challenging to test novel vaccines in the human population. To overcome this obstacle, new vaccines must be tested in challenge studies. This approach poses significant safety problems, since current pharmacological interventions for IAV are poorly efficacious. New methods are needed to enhance the safety of these challenge studies. In this study, we have generated a virus expressing a small-molecule-assisted shutoff (SMASh) tag as a safety switch for IAV replication. The addition of the SMASh tag to an essential IAV protein allows for small-molecule-mediated inhibition of replication. Treatment with this drug controls the replication of a SMASh-tagged virus in vitro and in vivo This model for restriction of viral replication has potential for broad applications in vaccine studies, virotherapy, and basic virus research. IMPORTANCE Influenza A virus (IAV) causes significant morbidity and mortality annually worldwide, despite the availability of new formulations of the vaccine each season. There is a critical need to develop more-efficacious vaccines. However, testing novel vaccines in the human population in controlled studies is difficult due to the limited availability and efficacy of intervention strategies should the vaccine fail. There are also significant safety concerns for work with highly pathogenic IAV strains in the laboratory. Therefore, novel strategies are needed to improve the safety of vaccine studies and of research on highly pathogenic IAV. In this study, we developed an IAV strain engineered to contain a small-molecule-mediated safety switch. This tag, when attached to an essential viral protein, allows for the regulation of IAV replication in vitro and in vivo This strategy provides a platform for the regulation of virus replication without targeting viral proteins directly., (Copyright © 2018 American Society for Microbiology.)

Published

2018

40. Controlling Multicycle Replication of Live-Attenuated HIV-1 Using an Unnatural Genetic Switch.

Author

Yuan Z, Wang N, Kang G, Niu W, Li Q, and Guo J

Subjects

Amino Acids genetics, Amino Acids metabolism, Amino Acyl-tRNA Synthetases chemistry, Amino Acyl-tRNA Synthetases genetics, Amino Acyl-tRNA Synthetases metabolism, Azides chemistry, Codon, Terminator genetics, HEK293 Cells, HIV-1 genetics, Humans, Microscopy, Fluorescence, Phenylalanine analogs & derivatives, Phenylalanine chemistry, RNA, Transfer genetics, RNA, Transfer metabolism, Vaccines, Attenuated genetics, Vaccines, Attenuated metabolism, Genes, Switch, HIV-1 physiology, Virus Replication physiology

Abstract

A safe and effective human immunodeficiency virus type 1 (HIV-1) vaccine is urgently needed, but remains elusive. While HIV-1 live-attenuated vaccine can provide potent protection as demonstrated in rhesus macaque-simian immunodeficiency virus model, the potential pathogenic consequences associated with the uncontrolled virus replication preclude such vaccine from clinical applications. We investigated a novel approach to address this problem by controlling live-attenuated HIV-1 replication through an unnatural genetic switch that was based on the amber suppression strategy. Here we report the construction of all-in-one live-attenuated HIV-1 mutants that contain genomic copy of the amber suppression system. This genetic modification resulted in viruses that were capable of multicycle replication in vitro and could be switched on and off using an unnatural amino acid as the cue. This stand-alone, replication-controllable attenuated HIV-1 virus represents an important step toward the generation of a safe and efficacious live-attenuated HIV-1 vaccine. The strategy reported in this work can be adopted for the development of other live-attenuated vaccines.

Published

2017