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Abstract
Fuselloviridae infecting thermoacidophilic Sulfolobales are undoubtedly the best-studied archaeoviruses, with the SSV1-Saccharolobus solfataricus interaction as a model. Around one-third of fusellovirus core genes encode putative DNA-binding proteins (DBPs), which, although little is known about their functions and mechanisms of action, suggests that DNA-binding processes such as transcription regulation are a critical aspect of the infection cycle.
In this work, we aim to identify and characterize SSV1-encoded DBPs to elucidate transcription regulatory mechanisms in the virus-host interaction.
Host and virus transcriptome dynamics post-infection and post-induction are being studied by performing high-resolution, long-read ONT-cappable RNA-sequencing. This end-to-end sequencing of primary transcripts will provide a full transcriptional blueprint of SSV1, including transcription start and stop sites, operon structures and UTRs. This transcriptomic study will be complemented with genome-wide binding profiles of all SSV1 putative DBPs by performing ChIP-seq experiments using engineered virus variants in which each DBP is epitope-tagged.
Molecular mechanisms of individual SSV1-encoded DBPs will be characterized through protein-DNA binding assays and in vitro transcription. To date, we have already cloned, heterologously overexpressed and purified 6 SSV1 putative transcription regulators: F93, F112, B115, A100, C80 and E51. Through EMSAs, we have confirmed their DNA-binding properties, exhibiting different DNA-binding behavior on native PAGE gels.
This work is expected to greatly enhance our understanding of the SSV virus-host interaction by applying state-of-the-art techniques to study SSV1. By bridging critical knowledge gaps, we might contribute to the development of virus-based biological parts for gene expression engineering in Sulfolobales, an archaeal order with great biotechnological potential.
In this work, we aim to identify and characterize SSV1-encoded DBPs to elucidate transcription regulatory mechanisms in the virus-host interaction.
Host and virus transcriptome dynamics post-infection and post-induction are being studied by performing high-resolution, long-read ONT-cappable RNA-sequencing. This end-to-end sequencing of primary transcripts will provide a full transcriptional blueprint of SSV1, including transcription start and stop sites, operon structures and UTRs. This transcriptomic study will be complemented with genome-wide binding profiles of all SSV1 putative DBPs by performing ChIP-seq experiments using engineered virus variants in which each DBP is epitope-tagged.
Molecular mechanisms of individual SSV1-encoded DBPs will be characterized through protein-DNA binding assays and in vitro transcription. To date, we have already cloned, heterologously overexpressed and purified 6 SSV1 putative transcription regulators: F93, F112, B115, A100, C80 and E51. Through EMSAs, we have confirmed their DNA-binding properties, exhibiting different DNA-binding behavior on native PAGE gels.
This work is expected to greatly enhance our understanding of the SSV virus-host interaction by applying state-of-the-art techniques to study SSV1. By bridging critical knowledge gaps, we might contribute to the development of virus-based biological parts for gene expression engineering in Sulfolobales, an archaeal order with great biotechnological potential.
Original language | English |
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Publication status | Unpublished - 9 May 2023 |
Event | Viruses of Microbes 2023 - Tbilisi, Georgia Duration: 3 Jul 2023 → 7 Jul 2023 https://vom2023.org |
Conference
Conference | Viruses of Microbes 2023 |
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Abbreviated title | VOM2023 |
Country/Territory | Georgia |
City | Tbilisi |
Period | 3/07/23 → 7/07/23 |
Internet address |
Fingerprint
Dive into the research topics of 'Transcription regulatory program of SSV1 infecting Saccharolobus solfataricus'. Together they form a unique fingerprint.Projects
- 2 Active
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FWOTM1125: Exploiting viral regulators for synthetic biology toolbox development for Sulfolobales
1/11/22 → 31/10/26
Project: Fundamental
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iBOF/21/092: Unlocking powerful nonmodel organisms in microbial synthetic biology - Possibl.
Peeters, E., Lavigne, R., Verstrepen, K., Pinheiro, V., De Mey, M. & Lebeer, S.
1/01/21 → 31/12/24
Project: Fundamental
Research output
- 1 Poster
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Transcription regulatory program of SSV1 infecting Saccharolobus solfataricus
Magnus, W., Thys, F. O. A., Neckebroeck, N., Boon, M., Rob, L. & Peeters, E., 3 Jul 2023.Research output: Unpublished contribution to conference › Poster
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Activities
- 1 Participation in conference
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Viruses of Microbes 2023
Wouter Magnus (Participant)
3 Jul 2023 → 7 Jul 2023Activity: Participating in or organising an event › Participation in conference