Molecular basis of viroid RNA-templated transcription

Dissanayaka Mudiyanselage, Shachinthaka D

09 December 2022

Transcription is a fundamental process catalyzed by DNA-dependent RNA polymerases (DdRPs). Interestingly, some DdRPs can use both DNA and RNA as templates for transcription. This RNA-dependent RNA polymerase (RdRP) activity of DdRPs is used by RNA-based pathogens such as viroids and hepatitis delta virus for replication. In addition, RdRP activity of DdRPs widely occurs in various organisms to regulate gene transcription. Despite the importance of this intrinsic RdRP activity of DdRPs, associated factors and mechanisms are in their infancy stage. We employed potato spindle tuber viroid (PSTVd) as a model to study RNA-templated transcription. Here, we present evidence showing that circular PSTVd templates are critical for the synthesis of longer-than-unit-length (-) strand products. Further, we show transcription factor IIS is dispensable for PSTVd replication supporting de novo transcription on PSTVd RNA templates. The absence of canonical general transcription factor, TFIIS from PSTVd-templated transcription complex led to the hypothesis that RNA-templated transcription has a distinct organization on the RNA template. To test this hypothesis, we used our well-established in vitro transcription (IVT) system and demonstrated that RNA polymerase II (Pol II) accepts minus-strand for transcription. In addition, transcription factor TFIIIA-7ZF is needed to aid Pol II transcription activity. Further analyses of the critical zinc finger domains in TFIIIA-7ZF revealed that the first three zinc finger domains are pivotal for template binding. Notably, we identified a remodeled Pol II complex for viroid transcription that is missing Rpb4, Rpb5, Rpb6, Rpb7, and Rpb9. General transcription factors for DNA-templated transcription are also absent in the transcription complex on the RNA template. This remodeled Pol II complex still possesses the transcription activity on PSTVd RNA template. Collectively, our data illustrate a distinct organization of Pol II complex on viroid RNA templates, providing new insights into viroid replication, the evolution of transcription machinery, as well as the mechanism of RNA-templated transcription.

PSTVd

Pol II

TFIIIA-7ZF

Biochemistry

Molecular Biology

Hepatitis Delta Virus: Identification of Host Factors Involved in the Viral Life Cycle, and the Investigation of the Evolutionary Relationship Between HDV and Plant Viroids

Sikora, Dorota

19 June 2012

Hepatitis delta virus (HDV) is the smallest known human RNA pathogen. It requires the human hepatitis B virus (HBV) for virion production and transmission, and is hence closely associated with HBV in natural infections. HDV RNA encodes only two viral proteins - the small and the large delta antigens. Due to its limited coding capacity, HDV needs to exploit host factors to ensure its propagation. However, few human proteins are known to interact with the HDV RNA genome. The current study has identified several host proteins interacting with an HDV-derived RNA promoter by multiple approaches: mass spectrometry of a UV-crosslinked ribonucleoprotein complex, RNA affinity chromatography, and screening of a library of purified RNA-binding proteins. Co-immunoprecipitation, both in vitro and ex vivo, confirmed the interactions of eEF1A1, p54nrb, PSF, hnRNP-L, GAPDH and ASF/SF2 with both polarities of the HDV RNA genome. In vitro transcription assays suggested a possible involvement of eEF1A1, GAPDH and PSF in HDV replication. At least three of these proteins, eEF1A1, GAPDH and ASF/SF2, have also been shown to associate with potato spindle tuber viroid (PSTVd) RNA. Because HDV’s structure and mechanism of replication share many similarities with viroids, subviral helper-independent plant pathogens, I transfected human hepatocytes with RNA derived from PSTVd. Here, I show that PSTVd RNA can replicate in human hepatocytes. I further demonstrate that a mutant of HDV, lacking the delta antigen coding region (miniHDV), can also replicate in human cells. However, both PSTVd and miniHDV require the function of the small delta antigen for successful replication. Our discovery that HDV and PSTVd RNAs associate with similar RNA-processing pathways and translation machineries during their replication provides new insight into HDV biology and its evolution.

hepatitis delta virus

RNA virus

PSTVd

viroid

ASF/SF2

GAPDH

eEF1A1

p54nrb

hnRNP-L

RNA promoter

Hepatitis Delta Virus: Identification of Host Factors Involved in the Viral Life Cycle, and the Investigation of the Evolutionary Relationship Between HDV and Plant Viroids

Sikora, Dorota

19 June 2012

Hepatitis delta virus (HDV) is the smallest known human RNA pathogen. It requires the human hepatitis B virus (HBV) for virion production and transmission, and is hence closely associated with HBV in natural infections. HDV RNA encodes only two viral proteins - the small and the large delta antigens. Due to its limited coding capacity, HDV needs to exploit host factors to ensure its propagation. However, few human proteins are known to interact with the HDV RNA genome. The current study has identified several host proteins interacting with an HDV-derived RNA promoter by multiple approaches: mass spectrometry of a UV-crosslinked ribonucleoprotein complex, RNA affinity chromatography, and screening of a library of purified RNA-binding proteins. Co-immunoprecipitation, both in vitro and ex vivo, confirmed the interactions of eEF1A1, p54nrb, PSF, hnRNP-L, GAPDH and ASF/SF2 with both polarities of the HDV RNA genome. In vitro transcription assays suggested a possible involvement of eEF1A1, GAPDH and PSF in HDV replication. At least three of these proteins, eEF1A1, GAPDH and ASF/SF2, have also been shown to associate with potato spindle tuber viroid (PSTVd) RNA. Because HDV’s structure and mechanism of replication share many similarities with viroids, subviral helper-independent plant pathogens, I transfected human hepatocytes with RNA derived from PSTVd. Here, I show that PSTVd RNA can replicate in human hepatocytes. I further demonstrate that a mutant of HDV, lacking the delta antigen coding region (miniHDV), can also replicate in human cells. However, both PSTVd and miniHDV require the function of the small delta antigen for successful replication. Our discovery that HDV and PSTVd RNAs associate with similar RNA-processing pathways and translation machineries during their replication provides new insight into HDV biology and its evolution.

hepatitis delta virus

RNA virus

PSTVd

viroid

ASF/SF2

GAPDH

eEF1A1

p54nrb

hnRNP-L

RNA promoter

Studium exprese cílových mRNA při pospiviroidní patogenezi v systému "leaf factory" / Expression of target mRNAs during Popsipviroid pathogenesis in the "leaf factory" system

SELINGER, Martin

January 2013

The aim of this work was to identify potential mRNA targets of PTGS triggered by viroid-derived small RNAs (vsRNAs) in PSTVd-infected tomato plants (S. lycopersicum L.). We selected 47 possible gene targets using data provided by Prof. Dr. Steger (Heinrich Heine Universität, Düsseldorf, Germany) - the list of 1633 possible target mRNAs from tomato based on vsRNA:mRNA duplex prediction. The vsRNA sequences were obtained by Illumina sequencing of small RNA libraries from healthy and PSTVd-infected tomato plants. By qRT-PCR analysis we identified 6 genes with significantly altered levels of mRNA in PSTVd-infected tomato plants: CUL1 (protein ubiquitination), ERF4 (transcription factor of abiotic stress signalling pathway), H/ACA1 (rRNA pseudouridylation), NPH3 (transcription factor of fototropic signalling pathway), Sl-MYB (transcription factor regulating leaf development) and TCP3 (transcription factor regulating leaf development). The binary vector pLV07 with inserted expression cassette containing coding sequence of Sl-MYB was prepared for experiments in ?leaf factory? system in N. benthamiana plants. Expression analyses in ?leaf factory? system after 1,5 DPI using qRT-PCR and RNA blots revealed strong inhibition of expression of Sl-MYB in leaf sectors infiltrated with severe PSTVd AS1 strain, while mild PSTVd QFA strain showed minimal change in expression comparing to control sectors. Moreover, the overexpression of Sl-MYB in leaf sectors resulted in development of necroses after 2,5-3 DPI, in presence of silencing suppressor p19 after 2 DPI. The development of necroses was largely inhibited in PSTVd AS1-infiltrated leaf sectors in comparison with PSTVd QFA- and control-infiltrated sectors.

Hepatitis Delta Virus: Identification of Host Factors Involved in the Viral Life Cycle, and the Investigation of the Evolutionary Relationship Between HDV and Plant Viroids

Sikora, Dorota

January 2012

Hepatitis delta virus (HDV) is the smallest known human RNA pathogen. It requires the human hepatitis B virus (HBV) for virion production and transmission, and is hence closely associated with HBV in natural infections. HDV RNA encodes only two viral proteins - the small and the large delta antigens. Due to its limited coding capacity, HDV needs to exploit host factors to ensure its propagation. However, few human proteins are known to interact with the HDV RNA genome. The current study has identified several host proteins interacting with an HDV-derived RNA promoter by multiple approaches: mass spectrometry of a UV-crosslinked ribonucleoprotein complex, RNA affinity chromatography, and screening of a library of purified RNA-binding proteins. Co-immunoprecipitation, both in vitro and ex vivo, confirmed the interactions of eEF1A1, p54nrb, PSF, hnRNP-L, GAPDH and ASF/SF2 with both polarities of the HDV RNA genome. In vitro transcription assays suggested a possible involvement of eEF1A1, GAPDH and PSF in HDV replication. At least three of these proteins, eEF1A1, GAPDH and ASF/SF2, have also been shown to associate with potato spindle tuber viroid (PSTVd) RNA. Because HDV’s structure and mechanism of replication share many similarities with viroids, subviral helper-independent plant pathogens, I transfected human hepatocytes with RNA derived from PSTVd. Here, I show that PSTVd RNA can replicate in human hepatocytes. I further demonstrate that a mutant of HDV, lacking the delta antigen coding region (miniHDV), can also replicate in human cells. However, both PSTVd and miniHDV require the function of the small delta antigen for successful replication. Our discovery that HDV and PSTVd RNAs associate with similar RNA-processing pathways and translation machineries during their replication provides new insight into HDV biology and its evolution.

hepatitis delta virus

RNA virus

PSTVd

viroid

ASF/SF2

GAPDH

eEF1A1

p54nrb

hnRNP-L

RNA promoter