Kazuhiro Sakakibara’s research while affiliated with The University of Tokyo and other places

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Publications (4)


Siwi levels reversibly regulate secondary piRISC biogenesis by affecting Ago3 body morphology in Bombyx mori
  • Article
  • Full-text available

September 2020

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61 Reads

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12 Citations

The EMBO Journal

Kazumichi M Nishida

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Kazuhiro Sakakibara

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Tetsutaro Sumiyoshi

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[...]

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Mikiko C Siomi

Silkworm ovarian germ cells produce the Siwi-piRNA-induced silencing complex (piRISC) through two consecutive mechanisms, the primary pathway and the secondary ping-pong cycle. Primary Siwi-piRISC production occurs on the outer mitochondrial membrane in an Ago3-independent manner, where Tudor domain-containing Papi binds unloaded Siwi via its symmetrical dimethylarginines (sDMAs). Here, we now show that secondary Siwi-piRISC production occurs at the Ago3-positive nuage Ago3 bodies, in an Ago3-dependent manner, where Vreteno (Vret), another Tudor protein, interconnects unloaded Siwi and Ago3-piRISC through their sDMAs. Upon Siwi depletion, Ago3 is phosphorylated and insolubilized in its piRISC form with cleaved RNAs and Vret, suggesting that the complex is stalled in the intermediate state. The Ago3 bodies are also enlarged. The aberrant morphology is restored upon Siwi re-expression without Ago3-piRISC supply. Thus, Siwi depletion aggregates the Ago3 bodies to protect the piRNA intermediates from degradation until the normal cellular environment returns to re-initiate the ping-pong cycle. Overall, these findings reveal a unique regulatory mechanism controlling piRNA biogenesis.

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Production of monoclonal antibodies against Papi, Trim and Zuc, and analysis of depletion upon RNA interference treatment
a, Quantitative PCR with reverse transcription (qRT–PCR) shows that Nbr was efficiently depleted by RNA interference (RNAi) in BmN4 cells. Data are mean ± s.e.m. of three independent experiments. b, Western blotting shows the specificity of anti-Papi, anti-Trim and anti-Zuc monoclonal antibodies raised in this study. HSP60 and tubulin were used as loading controls. The images show the domain structures of Papi, Trim and Zuc. Underlines indicate the antigen regions used for producing the monoclonal antibodies. c, Western blotting shows that Papi and Trim were efficiently depleted by RNAi in BmN4 cells.
Siwi/Ago3-associated small RNAs upon Trim or Nbr depletion
a, Length distribution of transposon-mapped Flag-Siwi- and Flag-Ago3-associated piRNAs. piRNAs appear to be slightly longer when Trim was depleted. b, Sequence logos showing unaffected levels of 1U and 10A under Trim- or Nbr-depleted conditions. c, Strand bias and frequency of piRNAs mapped to each transposon consensus sequence. Depletion of Trim or Nbr has little effect on strand bias or the frequency of piRNAs mapped to each transposon consensus sequence.
SDMA modification of Siwi and Ago3
a, A synthesized short interfering RNA (siRNA) (26 nucleotides) was downshifted by β-elimination, indicating that this siRNA is not 2′-O-methylated. b, The amino acid sequences of the N-terminal regions of wild-type Siwi, the Siwi-9RK mutant, wild-type Ago3 and the Ago3-5RK mutant are shown. Arginine residues shown in red were determined to be sDMAs in BmN4 cells. Arginine residues mutated to lysines are shown in green. c, Representative ETD tandem mass spectra for Siwi and Ago3 peptides, which include arginine modifications. Ac, acetylation; Di, demethylation; Me, monomethylation. Charge, m/z and Mascot score are shown on the top right of each spectrum. All identified Siwi and Ago3 peptides are listed in Supplementary Table 1.
Analysis of Siwi and Ago3 mutants
a, Wild-type Flag–Siwi and Flag–Ago3, but not Flag–Siwi-9RK and Flag-Ago3-5RK mutants, are co-immunoprecipitated with Papi from BmN4 cells. b, Wild-type Flag–Siwi and Flag–Ago3, but not Flag–Siwi-9RK and Flag–Ago3-5RK mutants, are loaded with piRNAs in BmN4 cells. The middle (sDMA) shows that neither the Flag–Siwi-9RK nor Flag–Ago3-5RK mutant reacts with the Y12 antibody, which specifically recognizes sDMA. c, Wild-type Flag–Siwi and Flag–Ago3, but not Flag–Siwi-9RK and Flag–Ago3-5RK mutants, are localized to nuage in BmN4 cells (shown in green). Blue (DAPI staining) indicates the location of the nucleus. Scale bars, 10 μm. d, Papi depletion has little effect on sDMA modification of Flag–Siwi and Flag–Ago3 expressed in BmN4 cells.
Papi complex analysis
a, Top, Flag–Siwi and Flag–Ago3 expressed in BmN4 cells were immunoisolated with anti-Flag antibody and probed with anti-Flag antibody after sequential dilution. Bottom, Flag–Siwi and Flag–Ago3 immunoisolated from BmN4 cells (the same samples as in the top panel) were probed with anti-Siwi and anti-Ago3 antibodies, respectively. Siwi and Ago3 co-immunoprecipitated with Papi were simultaneously probed with anti-Siwi and anti-Ago3 antibodies, respectively. The Papi complex was equally divided into two fractions and each fraction was used for each blot. Examination of the signal intensity revealed that the amount of Siwi within the Papi complex was approximately equal to 1/1.6 volume of Flag–Siwi and that the amount of Ago3 within the Papi complex was approximately equal to 1/16 volume of Flag–Ago3. Comparison of the signal intensity on the top and bottom blots suggests that the ratio of abundance of Siwi and Ago3 in the Papi complex is 10:1. b, Northern blotting shows that the Papi complex contains RT3-1 int-piRNAs. c, Northern blotting shows that Siwi in a form associated with Papi on mitochondria binds RT3-1 int-piRNAs independently of Papi. The Siwi–int-piRNA association is maintained even after Zuc depletion. d, CLIP analysis shows that only the long form, but not the short form, of endogenous Papi in BmN4 cells interacts with RNA in vivo. e, Western blotting using anti-Papi (top) and anti-Flag (second from the top) antibodies shows that wild-type Papi–Flag and the KH mutant are equally expressed in BmN4 cells, in which endogenous Papi has been depleted by RNAi. Western blotting using anti-Myc (third from the top) shows that the levels of Myc–Siwi are approximately equal in the cells. Tubulin was used as a loading control (bottom). Both wild-type Papi–Flag and the KH mutant were mutated to be RNAi resistant. f, Flag–Siwi-9RK and Flag–Ago3-5RK mutants bind with little int-piRNA. g, Flag–Siwi binds with little int-piRNA in Papi-lacking BmN4 cells. h, Northern blotting shows that int-piRNAs are still present in Siwi-depleted BmN4 cells.

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Hierarchical roles of mitochondrial Papi and Zucchini in Bombyx germline piRNA biogenesis

March 2018

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332 Reads

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42 Citations

Nature

PIWI-interacting RNAs (piRNAs) are small regulatory RNAs that bind to PIWI proteins to control transposons and maintain genome integrity in animal germ lines. piRNA 3' end formation in the silkworm Bombyx mori has been shown to be mediated by the 3'-to-5' exonuclease Trimmer (Trim; known as PNLDC1 in mammals), and piRNA intermediates are bound with PIWI anchored onto mitochondrial Tudor domain protein Papi. However, it remains unclear whether the Zucchini (Zuc) endonuclease and Nibbler (Nbr) 3'-to-5' exonuclease, both of which have pivotal roles in piRNA biogenesis in Drosophila, are required for piRNA processing in other species. Here we show that the loss of Zuc in Bombyx had no effect on the levels of Trim and Nbr, but resulted in the aberrant accumulation of piRNA intermediates within the Papi complex, and that these were processed to form mature piRNAs by recombinant Zuc. Papi exerted its RNA-binding activity only when bound with PIWI and phosphorylated, suggesting that complex assembly involves a hierarchical process. Both the 5' and 3' ends of piRNA intermediates within the Papi complex showed hallmarks of PIWI 'slicer' activity, yet no phasing pattern was observed in mature piRNAs. The loss of Zuc did not affect the 5'- and 3'-end formation of the intermediates, strongly supporting the idea that the 5' end of Bombyx piRNA is formed by PIWI slicer activity, but independently of Zuc, whereas the 3' end is formed by the Zuc endonuclease. The Bombyx piRNA biogenesis machinery is simpler than that of Drosophila, because Bombyx has no transcriptional silencing machinery that relies on phased piRNAs.


The PIWI-Interacting RNA Molecular Pathway: Insights From Cultured Silkworm Germline Cells

November 2017

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55 Reads

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22 Citations

BioEssays

The PIWI-interacting RNA (piRNA) pathway, one of the major eukaryotic small RNA silencing pathways, is a genome surveillance system that silences selfish genes in animal gonads. piRNAs guide PIWI protein to target genes through Watson–Crick RNA–RNA base-parings. Loss of piRNA function causes genome instability, inducing failure in gametogenesis and infertility. Studies using fruit flies and mice as key experimental models have resulted in tremendous progress in understanding the mechanism underlying the piRNA pathway. Recent work using cultured silkworm germline cells has also expanded our knowledge of piRNA biogenesis in particular, since these silkworm cells are the only cells of germline origin that can be cultured. In this review, we describe elucidation of the piRNA pathway using cultured silkworm cells as an experimental model by focusing on recent work in biochemistry and structural biology. Earlier studies that made important contributions to the field are also described.


Crystal Structure of Silkworm PIWI-Clade Argonaute Siwi Bound to piRNA

October 2016

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74 Reads

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119 Citations

Cell

PIWI-clade Argonaute proteins associate with PIWI-interacting RNAs (piRNAs) and silence transposable elements in animal gonads. Here, we report the crystal structure of a silkworm PIWI-clade Argonaute, Siwi, bound to the endogenous piRNA, at 2.4 Å resolution. Siwi adopts a bilobed architecture consisting of N-PAZ and MID-PIWI lobes, in which the 5′ and 3′ ends of the bound piRNA are anchored by the MID-PIWI and PAZ domains, respectively. A structural comparison of Siwi with AGO-clade Argonautes reveals notable differences in their nucleic-acid-binding channels, likely reflecting the distinct lengths of their guide RNAs and their mechanistic differences in guide RNA loading and cleavage product release. In addition, the structure reveals that Siwi and prokaryotic, but not eukaryotic, AGO-clade Argonautes share unexpected similarities, such as metal-dependent 5′-phosphate recognition and a potential structural transition during the catalytic-tetrad formation. Overall, this study provides a critical starting point toward a mechanistic understanding of piRNA-mediated transposon silencing.

Citations (4)


... Consistently, catalytic mutants of Siwi (Piwi homolog in silkworm) disrupt the proper distribution of nuage structure [137]. IDRs within PIWIs are thought to facilitate the phase separation necessary for RNP granule formation [70,166,167]. Tej, a Drosophila homolog of Tdrd5 that serves as a core component in the proper nuage formation, recruits Vas and Spn-E and contributes to the dynamics of Vas through IDR in the ovaries [111] (Fig. 4A-D). Thus, IDRs of nuage components emphasize their significance across species in contributing to RNP granule formation and protecting the germline genomes. ...

Reference:

piRNA processing within non‐membrane structures is governed by constituent proteins and their functional motifs
Siwi levels reversibly regulate secondary piRISC biogenesis by affecting Ago3 body morphology in Bombyx mori

The EMBO Journal

... A unified model of piRNA biogenesis has been proposed encapsulating two interrelated mechanisms: ping-pong amplification, which occur in the perinuclear granule and phasing, which takes place at the mitochondrial outer membrane (Fig. 2) [2,25,52]. While there remains some controversy regarding the presence of the phasing process in silkworm BmN4 cells [52,53], these multifaceted piRNA biogenesis pathways are believed to have co-evolved in the last common ancestor of metazoans, spanning an evolutionary timeline of approximately 800 million years [54]. ...

Hierarchical roles of mitochondrial Papi and Zucchini in Bombyx germline piRNA biogenesis

Nature

... Eukaryotic organisms are continuously challenged from genomic parasites called transposable elements (TEs) [1][2][3][4]. Unchecked transposon activity often results in reduced reproductive fitness [5][6][7][8]. To negate the detrimental effects posed by TE mobilisation, vital regulatory pathways evolved that efficiently suppress transposon activity. ...

The PIWI-Interacting RNA Molecular Pathway: Insights From Cultured Silkworm Germline Cells
  • Citing Article
  • November 2017

BioEssays

... This Zuc-mediated processing, known as phasing, strongly biases the initial nucleotide of piRNAs toward uracil (1U), which aligns with the preference for 5 0 end of Piwi-bound mature piRNAs. This specific nucleotide preference enhances the stability of piRNA binding to the MID domain of PIWI [70,71]. In Drosophila, phasing not only generates new piRNA sequences but also integrates these phased piRNAs into the ping-pong cycle for further amplification of piRNAs. ...

Crystal Structure of Silkworm PIWI-Clade Argonaute Siwi Bound to piRNA
  • Citing Article
  • October 2016

Cell