Synthesis of ribosomal RNA (rRNA) by RNA polymerase (Pol) I is the first step in ribosome biogenesis and a regulatory switch in eukary-otic cell growth. Here we report the 12 A ˚ cryo-electron microscopic structure for the complete 14-subunit yeast Pol I, a homology model for the core enzyme, and the crystal structure of the subcomplex A14/43. In the resulting hybrid structure of Pol I, A14/43, the clamp, and the dock domain contribute to a unique surface interacting with promoter-specific initiation factors. The Pol I-specific subunits A49 and A34.5 form a heterodimer near the enzyme funnel that acts as a built-in elongation factor and is related to the Pol II-associated factor TFIIF. In contrast to Pol II, Pol I has a strong intrinsic 3 0-RNA cleavage activity, which requires the C-terminal domain of subunit A12.2 and, apparently, enables ribosomal RNA proofreading and 3 0-end trimming.
The eukaryotic RNA polymerases Pol I, Pol II, and Pol III are the central multiprotein machines that synthesize ribosomal, messenger, and transfer RNA, respectively. Here we provide a catalog of available structural information for these three enzymes. Most structural data have been accumulated for Pol II and its functional complexes. These studies have provided insights into many aspects of the transcription mechanism, including initiation at promoter DNA, elongation of the mRNA chain, tunability of the polymerase active site, which supports RNA synthesis and cleavage, and the response of Pol II to DNA lesions. Detailed structural studies of Pol I and Pol III were reported recently and showed that the active center region and core enzymes are similar to Pol II and that strong structural differences on the surfaces account for gene class-specific functions.
Cell growth is regulated during RNA polymerase (Pol) I transcription initiation by the conserved factor Rrn3/TIF-IA in yeast/humans. Here we provide a structure-function analysis of Rrn3 based on a combination of structural biology with in vivo and in vitro functional assays. The Rrn3 crystal structure reveals a unique HEAT repeat fold and a surface serine patch. Phosphorylation of this patch represses human Pol I transcription, and a phosphomimetic patch mutation prevents Rrn3 binding to Pol I in vitro and reduces cell growth and Pol I gene occupancy in vivo. Cross-linking indicates that Rrn3 binds Pol I between its subcomplexes, AC40/19 and A14/43, which faces the serine patch. The corresponding region of Pol II binds the Mediator head that cooperates with transcription factor (TF) IIB. Consistent with this, the Rrn3-binding factor Rrn7 is predicted to be a TFIIB homolog. This reveals the molecular basis of Rrn3-regulated Pol I initiation and cell growth, and indicates a general architecture of eukaryotic transcription initiation complexes.
RNA polymerase (Pol) I contains a 10-subunit catalytic core that is related to the core of Pol II and includes subunit A12.2. In addition, Pol I contains the heterodimeric subcomplexes A14/43 and A49/34.5, which are related to the Pol II subcomplex Rpb4/7 and the Pol II initiation factor TFIIF, respectively. Here we used lysine-lysine crosslinking, mass spectrometry (MS) and modeling based on five crystal structures, to extend the previous homology model of the Pol I core, to confirm the location of A14/43 and to position A12.2 and A49/34.5 on the core. In the resulting model of Pol I, the C-terminal ribbon (C-ribbon) domain of A12.2 reaches the active site via the polymerase pore, like the C-ribbon of the Pol II cleavage factor TFIIS, explaining why the intrinsic RNA cleavage activity of Pol I is strong, in contrast to the weak cleavage activity of Pol II. The A49/34.5 dimerization module resides on the polymerase lobe, like TFIIF, whereas the A49 tWH domain resides above the cleft, resembling parts of TFIIE. This indicates that Pol I and also Pol III are distantly related to a Pol II–TFIIS–TFIIF–TFIIE complex.
Transcription initiation by eukaryotic RNA polymerase (Pol) III relies on the TFIIE-related subcomplex C82/34/31. Here we combine crosslinking and hydroxyl radical probing to position the C82/34/31 subcomplex around the Pol III active center cleft. The extended winged helix (WH) domains 1 and 4 of C82 localize to the polymerase domains clamp head and clamp core, respectively, and the two WH domains of C34 span the polymerase cleft from the coiled-coil region of the clamp to the protrusion. The WH domains of C82 and C34 apparently cooperate with other mobile regions flanking the cleft during promoter DNA binding, opening, and loading. Together with published data, our results complete the subunit architecture of Pol III and indicate that all TFIIE-related components of eukaryotic and archaeal transcription systems adopt an evolutionarily conserved location in the upper part of the cleft that supports their functions in open promoter complex formation and stabilization. R NA polymerase III (Pol III) is the largest eukaryotic RNA polymerase, composed of 17 subunits with a total molecular weight of ∼0.7 MDa (1). Pol III synthesizes certain small untranslated RNAs (e.g., tRNAs, 5S rRNA, U6 snRNA, and 7SL RNA) involved in RNA processing and translation and in protein translocation (2, 3). Human Pol III mutations have been implicated in a neurodegenerative disorder, hypomyelinating leukodystrophy (4-6).The three eukaryotic RNA polymerases share a similar 12-subunit core as represented by the X-ray structure of yeast Pol II (1). In addition to the core, Pol III contains five specific subunits forming two subcomplexes, C37/53 and C82/34/31. The C37/53 subcomplex participates in promoter opening, transcription termination, and polymerase reinitiation (7-9). The C34 subunit of the C82/34/31 subcomplex plays a role in open complex formation and in recruiting Pol III to the preinitiation complex (PIC) through interaction with TFIIB-related factor 1 (Brf1) (10-13). The human RPC62/39/32 subcomplex, homologous to the yeast C82/34/31 complex, is dissociable and required for promoter-specific initiation (11).The two Pol III-specific subcomplexes contain structural domains homologous to domains in the Pol II transcription factors TFIIF and TFIIE, including the TFIIF-related dimerization module in the C37/53 subcomplex and several TFIIE-related winged helix (WH) domains in subunits C82 and C34 (14-20). TFIIE is composed of two subunits, Tfa1 and Tfa2, in yeast, or TFIIEα and TFIIEβ in humans. Whereas Tfa1 bears an extended WH (eWH) domain in its N-terminal region, Tfa2 has two adjacent WH domains (21,22). Two adjacent Tfa2-related WH domains are also present in the C34 subunit and its human homolog RPC39. Pol I contains the A49/34.5 subcomplex that features a TFIIF-like dimerization module and a tandem WH domain that contains two Tfa2-like WH folds in the C-terminal region of the A49 subunit (18). The crystal structure of the human C82 homolog RPC62 contains four Tfa1-like eWH domains (eWH1-4) that are structurally organized aroun...
SUMMARYSynthesis of ribosomal RNA (rRNA) by RNA polymerase (Pol) I is the first step in ribosome biogenesis and a regulatory switch in eukaryotic cell growth. Here we report the 12 Å cryoelectron microscopic structure for the complete 14-subunit yeast Pol I, a homology model for the core enzyme, and the crystal structure of the subcomplex A14/43. In the resulting hybrid structure of Pol I, A14/43, the clamp, and the dock domain contribute to a unique surface interacting with promoter-specific initiation factors. The Pol I-specific subunits A49 and A34.5 form a heterodimer near the enzyme funnel that acts as a built-in elongation factor and is related to the Pol II-associated factor TFIIF. In contrast to Pol II, Pol I has a strong intrinsic 3 0 -RNA cleavage activity, which requires the C-terminal domain of subunit A12.2 and, apparently, enables ribosomal RNA proofreading and 3 0 -end trimming.
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