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

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

Role of RNA Genome Structure and Paraspeckle Proteins In Hepatitis Delta Virus Replication

Beeharry, Yasnee

January 2016

The Hepatitis Delta Virus (HDV) is an RNA pathogen that uses the host DNA-dependent RNA polymerase II (RNAP II) to replicate. Previous studies identified the right terminal domain of genomic polarity (R199G) of HDV RNA as an RNAP II promoter, but the features required for HDV RNA to be used as an RNA promoter were unknown. In order to identify the structural features of an HDV RNA promoter, I analyzed 473,139 sequences representing 2,351 new R199G variants generated by high-throughput sequencing of a viral population replicating in 293 cells. To complement this analysis, I also analyzed the same region from HDV sequences isolated from various hosts. Base pair covariation analysis indicates a strong selection for the rod-like conformation. Several selected RNA motifs were identified, including a GC-rich stem, a CUC/GAG motif and a uridine at the initiation site of transcription. In addition, a polarization of purine/pyrimidine content was identified, which might represent a motif favourable for the binding of the host Polypyrimidine tract-binding protein-associated-splicing-factor (PSF), p54 and Paraspeckle Protein 1 (PSP1). Previously, it was shown that R199G binds both RNAP II and PSF, that PSF increased the HDV levels during in vitro transcription and that p54 binds R199G. In the present study, I showed that PSP1 also associates with HDV RNA and I investigated whether these proteins are required for HDV replication. My results show that knockdown of PSF, p54 and PSP1 resulted in a decrease of HDV accumulation. These proteins are highly concentrated in paraspeckles, which are nuclear structures involved in storage of transcripts generated by RNAP II. I found that upon viral replication in 293 cells, PSP1 appeared as bigger foci present outside of the nucleus, while PSF and p54 foci remained in the nucleus. NEAT1 is a long non-coding RNA essential for the formation of paraspeckles. Upon HDV replication, I found an increase of the intensity and size of NEAT1 foci that correlates with an increase of NEAT1 transcripts. Altogether, these data suggest that HDV replication results in an alteration of the paraspeckles structures, providing foundation for further investigation of the paraspeckles role in HDV cycle. Overall, the present study addresses the importance of the HDV RNA structure and of the host paraspeckle proteins for HDV replication.

Hepatitis Delta Virus

RNA promoter

paraspeckle

replication

covariation

RNA structure

DBHS proteins

Involvement of the Polypyrimidine Tract-Binding Protein-Associated Splicing Factor (PSF) in the Hepatitis Delta Virus (HDV) RNA-Templated Transcription

Zhang, Da Jiang

13 May 2014

Hepatitis delta virus (HDV) is the smallest known mammalian RNA virus, containing a genome of ~ 1700 nt. Replication of HDV is extremely dependent on the host transcription machinery. Previous studies indicated that RNA polymerase II (RNAPII) directly binds to and forms an active preinitiation complex on the right terminal stem-loop fragment (R199G) of HDV genomic RNA, and that the polypyrimidine tract-binding protein-associated splicing factor (PSF) directly binds to the same region. Further studies demonstrated that PSF also binds to the carboxyl-terminal domain (CTD) of RNAP II. In my thesis, co-immunoprecipitation assays were performed to show that PSF stimulates the interaction of RNAPII with R199G. Results of co-immunoprecipitation experiments also suggest that both the RNA recognition motif 2 (RRM2) and N-terminal proline-rich region (PRR) of PSF are required for the interaction between PSF and RNAPII, while the two RNA recognition motifs (RRM1 and RRM2) might be required for the interaction of PSF with R199G. Furthermore, in vitro run-off transcription assays suggest that PSF facilitates the HDV RNA transcription from the R199G template. Together, the above experiments suggest that PSF might act as a transcription factor for the RNAPII transcription of HDV RNA by linking the CTD of RNAPII and the HDV RNA promoter. My experiments provide a better understanding of the mechanism of HDV RNA-dependent transcription by RNAP II.

Hepatitis delta virus

RNA polymerase II

RNA promoter

Co-immunoprecipitation

RNA recognition motif RRM

Proline-rich region PRR

Carboxyl-terminal domain CTD

Transcription

Involvement of the Polypyrimidine Tract-Binding Protein-Associated Splicing Factor (PSF) in the Hepatitis Delta Virus (HDV) RNA-Templated Transcription

Zhang, Da Jiang

January 2014

Hepatitis delta virus (HDV) is the smallest known mammalian RNA virus, containing a genome of ~ 1700 nt. Replication of HDV is extremely dependent on the host transcription machinery. Previous studies indicated that RNA polymerase II (RNAPII) directly binds to and forms an active preinitiation complex on the right terminal stem-loop fragment (R199G) of HDV genomic RNA, and that the polypyrimidine tract-binding protein-associated splicing factor (PSF) directly binds to the same region. Further studies demonstrated that PSF also binds to the carboxyl-terminal domain (CTD) of RNAP II. In my thesis, co-immunoprecipitation assays were performed to show that PSF stimulates the interaction of RNAPII with R199G. Results of co-immunoprecipitation experiments also suggest that both the RNA recognition motif 2 (RRM2) and N-terminal proline-rich region (PRR) of PSF are required for the interaction between PSF and RNAPII, while the two RNA recognition motifs (RRM1 and RRM2) might be required for the interaction of PSF with R199G. Furthermore, in vitro run-off transcription assays suggest that PSF facilitates the HDV RNA transcription from the R199G template. Together, the above experiments suggest that PSF might act as a transcription factor for the RNAPII transcription of HDV RNA by linking the CTD of RNAPII and the HDV RNA promoter. My experiments provide a better understanding of the mechanism of HDV RNA-dependent transcription by RNAP II.

Hepatitis delta virus

RNA polymerase II

RNA promoter

Co-immunoprecipitation

RNA recognition motif RRM

Proline-rich region PRR

Carboxyl-terminal domain CTD

Transcription