Haase, Astrid-Desiree. Identification and analysis of dicer associated proteins in human cells. 2007, Doctoral Thesis, University of Basel, Faculty of Science.
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Official URL: http://edoc.unibas.ch/diss/DissB_7985
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Abstract
Dicer is a multidomain RNase III like enzyme involved in the initial steps of RNA
interference (RNAi) and microRNA (miRNA) pathways, two mechanisms of
posttranscriptional gene silencing conserved throughout most eukaryotic species.
Dicer has been shown to be necessary and sufficient to cut long dsRNA and
miRNA precursors into small (21-25 nt) RNAs. In metazoa, the small RNA
products of Dicer are further incorporated into a multiprotein RNA induced
silencing complex (RISC), which target mRNAs in a sequence specific manner to
induce mRNA cleavage (guided by siRNAs) or inhibition of translation (guided by
miRNAs).
We aimed to identify proteins interacting with human Dicer. Specific anti-
Dicer antibodies were used to immunoprecipitate Dicer from HEK293 and HeLa
cells and co-immunoprecipitating proteins were analyzed by mass spectrometry.
Proteins identified to specifically co-purify with Dicer fall into different categories:
(1) known components of RNA silencing pathways, such as Argonaute proteins;
(2) translation factors; (3) RNA helicases; (4) RNA binding proteins, and others.
Among the proteins characterized by mass spectrometry we identified
TRBP [HIV-1 transactivating response (TAR) RNA-binding protein], as a protein
containing three dsRNA binding domains (dsRBD). We found that this protein
interacts with human Dicer in vivo and in vitro, and that this interaction involves
Dicer’s N-terminal helicase domain and TRBP’s third dsRBD. TRBP has
previously been assigned several different functions, including inhibition of the
interferon (IFN)-induced dsRNA-regulated protein kinase PKR, modulation of
HIV-1 gene expression through its association with TAR, and control of cell
growth. To analyze TRBP’s function in miRNA and siRNA pathways, we
generated stable TRBP knock down cell lines. Using a Luciferase reporter
system we showed that TRBP is necessary for efficient silencing mediated by
endogenous miRNAs. Dicer cleavage activity tested in vitro using a pre-miRNA
substrate was impaired in TRBP knock down extracts. However, endogenous
miRNA levels were not significantly changed upon knock down of TRBP. We also
found that RNAi against an endogenous gene, induced by transfection of
siRNAs, was impaired in TRBP knock down cell lines. Taken together our
observations show that TRBP interacts with Dicer, and suggest that, besides its
impact on Dicer cleavage activity in vitro, TRBP functions mainly downstream of
Dicer cleavage in miRNA and siRNA pathways. Our data provide support to the
notion that large RNaseIII-type Drosha and Dicer nucleases work in conjunction
with small dsRBD protein partners. They also raise the possibility of a cross talk
between RNA silencing and the IFN/PKR pathways in normal and virus-infected
cells.
To further characterize the Dicer/TRBP complex, we generated anti-TRBP
antibodies, and analyzed TRBP immunoprecipitates by mass spectrometry. Data
obtained from peptide sequencing of Dicer and TRBP immunopurifications were
compared, and proteins identified in both preparations, among them the E3
Ubiquitin ligase Ro52, were considered for further analyses as likely components
of a Dicer/TRBP complex. Ro52, also known as Sjoegren Syndrome Antigen 1
(SSA-1) or Tripartite motif protein 21 (TRIM21) was first identified as one of the
major autoantigens in Sjoegren Syndrome and Systemic Lupus Erythematosus
(SLE), two severe human autoimmune diseases. Recently, it was demonstrated
that Ro52 can act as a RING dependent E3 Ubiquitin ligase, and the E3 ligase
activity of Ro52 was shown to be required for S-phase progression in mammalian
cells.
We found that Ro52 associates with the Dicer/TRBP complex, and
interacts with TRBP in vitro. The presence of an E3 Ubiquitin ligase in the
Dicer/TRBP complex raised the possibility that components of the RNA silencing
complexes are post-translationally modified by Ubiquitin. Our data indicate that
TRBP can be covalently tagged by Ubiquitin. It appears that TRBP is
monoubiquitinated, rather than polyubiquitinated and degraded by the
proteasome. Future work will be required to establish the function of
ubiquitination of TRBP, and the role of Ro52 in RNA silencing pathways.
interference (RNAi) and microRNA (miRNA) pathways, two mechanisms of
posttranscriptional gene silencing conserved throughout most eukaryotic species.
Dicer has been shown to be necessary and sufficient to cut long dsRNA and
miRNA precursors into small (21-25 nt) RNAs. In metazoa, the small RNA
products of Dicer are further incorporated into a multiprotein RNA induced
silencing complex (RISC), which target mRNAs in a sequence specific manner to
induce mRNA cleavage (guided by siRNAs) or inhibition of translation (guided by
miRNAs).
We aimed to identify proteins interacting with human Dicer. Specific anti-
Dicer antibodies were used to immunoprecipitate Dicer from HEK293 and HeLa
cells and co-immunoprecipitating proteins were analyzed by mass spectrometry.
Proteins identified to specifically co-purify with Dicer fall into different categories:
(1) known components of RNA silencing pathways, such as Argonaute proteins;
(2) translation factors; (3) RNA helicases; (4) RNA binding proteins, and others.
Among the proteins characterized by mass spectrometry we identified
TRBP [HIV-1 transactivating response (TAR) RNA-binding protein], as a protein
containing three dsRNA binding domains (dsRBD). We found that this protein
interacts with human Dicer in vivo and in vitro, and that this interaction involves
Dicer’s N-terminal helicase domain and TRBP’s third dsRBD. TRBP has
previously been assigned several different functions, including inhibition of the
interferon (IFN)-induced dsRNA-regulated protein kinase PKR, modulation of
HIV-1 gene expression through its association with TAR, and control of cell
growth. To analyze TRBP’s function in miRNA and siRNA pathways, we
generated stable TRBP knock down cell lines. Using a Luciferase reporter
system we showed that TRBP is necessary for efficient silencing mediated by
endogenous miRNAs. Dicer cleavage activity tested in vitro using a pre-miRNA
substrate was impaired in TRBP knock down extracts. However, endogenous
miRNA levels were not significantly changed upon knock down of TRBP. We also
found that RNAi against an endogenous gene, induced by transfection of
siRNAs, was impaired in TRBP knock down cell lines. Taken together our
observations show that TRBP interacts with Dicer, and suggest that, besides its
impact on Dicer cleavage activity in vitro, TRBP functions mainly downstream of
Dicer cleavage in miRNA and siRNA pathways. Our data provide support to the
notion that large RNaseIII-type Drosha and Dicer nucleases work in conjunction
with small dsRBD protein partners. They also raise the possibility of a cross talk
between RNA silencing and the IFN/PKR pathways in normal and virus-infected
cells.
To further characterize the Dicer/TRBP complex, we generated anti-TRBP
antibodies, and analyzed TRBP immunoprecipitates by mass spectrometry. Data
obtained from peptide sequencing of Dicer and TRBP immunopurifications were
compared, and proteins identified in both preparations, among them the E3
Ubiquitin ligase Ro52, were considered for further analyses as likely components
of a Dicer/TRBP complex. Ro52, also known as Sjoegren Syndrome Antigen 1
(SSA-1) or Tripartite motif protein 21 (TRIM21) was first identified as one of the
major autoantigens in Sjoegren Syndrome and Systemic Lupus Erythematosus
(SLE), two severe human autoimmune diseases. Recently, it was demonstrated
that Ro52 can act as a RING dependent E3 Ubiquitin ligase, and the E3 ligase
activity of Ro52 was shown to be required for S-phase progression in mammalian
cells.
We found that Ro52 associates with the Dicer/TRBP complex, and
interacts with TRBP in vitro. The presence of an E3 Ubiquitin ligase in the
Dicer/TRBP complex raised the possibility that components of the RNA silencing
complexes are post-translationally modified by Ubiquitin. Our data indicate that
TRBP can be covalently tagged by Ubiquitin. It appears that TRBP is
monoubiquitinated, rather than polyubiquitinated and degraded by the
proteasome. Future work will be required to establish the function of
ubiquitination of TRBP, and the role of Ro52 in RNA silencing pathways.
Advisors: | Filipowicz, Witold |
---|---|
Committee Members: | Keller, Walter |
Faculties and Departments: | 09 Associated Institutions > Friedrich Miescher Institut FMI |
UniBasel Contributors: | Keller, Walter |
Item Type: | Thesis |
Thesis Subtype: | Doctoral Thesis |
Thesis no: | 7985 |
Thesis status: | Complete |
Number of Pages: | 123 |
Language: | English |
Identification Number: |
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edoc DOI: | |
Last Modified: | 02 Aug 2021 15:05 |
Deposited On: | 13 Feb 2009 16:11 |
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