The single-subunit bacteriophage T7 RNA polymerase carries out the transcription cycle in an identical manner to that of bacterial and eukaryotic multisubunit enzymes. Here we report the crystal structure of a T7 RNA polymerase elongation complex, which shows that incorporation of an 8-base-pair RNA-DNA hybrid into the active site of the enzyme induces a marked rearrangement of the amino-terminal domain. This rearrangement involves alternative folding of about 130 residues and a marked reorientation (about 130 degrees rotation) of a stable core subdomain, resulting in a structure that provides elements required for stable transcription elongation. A wide opening on the enzyme surface that is probably an RNA exit pathway is formed, and the RNA-DNA hybrid is completely buried in a newly formed, deep protein cavity. Binding of 10 base pairs of downstream DNA is stabilized mostly by long-distance electrostatic interactions. The structure implies plausible mechanisms for the various phases of the transcription cycle, and reveals important structural similarities with the multisubunit RNA polymerases.
The mechanism by which nucleotide polymerases select the correct substrate is of fundamental importance to the fidelity of DNA replication and transcription. During the nucleotide addition cycle, pol I DNA polymerases undergo the transition from a catalytically inactive "open" to an active "closed" conformation. All known determinants of substrate selection are associated with the "closed" state. To elucidate if this mechanism is conserved in homologous single subunit RNA polymerases (RNAPs), we have determined the structure of T7 RNAP elongation complex with the incoming substrate analog. Surprisingly, the substrate specifically binds to RNAP in the "open" conformation, where it is base paired with the acceptor template base, while Tyr639 provides discrimination of ribose versus deoxyribose substrates. The structure therefore suggests a novel mechanism, in which the substrate selection occurs prior to the isomerization to the catalytically active conformation. Modeling of multisubunit RNAPs suggests that this mechanism might be universal for all RNAPs.
Summary Transcription in human mitochondria is carried out by a single-subunit, T7-like RNA polymerase assisted by several auxiliary factors. We demonstrate that an essential initiation factor, TFB2, forms a network of interactions with DNA near the transcription start site and facilitates promoter melting but may not be essential for promoter recognition. Unexpectedly, catalytic autolabeling reveals that TFB2 interacts with the priming substrate, suggesting that TFB2 acts as a transient component of the catalytic site of the initiation complex. Mapping of TFB2 identifies a region of its N-terminal domain that is involved in simultaneous interactions with the priming substrate and the templating (+1) DNA base. Our data indicate that the transcriptional machinery in human mitochondria has evolved into a system that combines features inherited from self-sufficient, T7-like RNA polymerase and those typically found in systems comprising cellular multi-subunit polymerases, and provide insights into the molecular mechanisms of transcription regulation in mitochondria.
Coordinated replication and expression of mitochondrial genome is critical for metabolically active cells during various stages of development. However, it is not known whether replication and transcription can occur simultaneously without interfering with each other and whether mtDNA copy number can be regulated by the transcription machinery. We found that interaction of human transcription elongation factor, TEFM with mitochondrial RNA polymerase (mtRNAP) and nascent transcript prevents generation of replication primers and increases transcription processivity thereby serving as a molecular switch between replication and transcription, which appear to be mutually exclusive processes in mitochondria. TEFM may allow mitochondria to increase transcription rates and, as consequence, respiration and ATP production without the need to replicate mtDNA, which has been observed during spermatogenesis and early stages of embryogenesis.
Human mitochondrial transcription is driven by a single subunit RNA polymerase and a set of basal transcription factors. The development of a recombinant in vitro transcription system has allowed for a detailed molecular characterization of the individual components and their contribution to transcription initiation. We found that TFAM and TFB2M act synergistically and increase transcription efficiency 100 -200-fold as compared with RNA polymerase alone. Both the light-strand promoter (LSP) and the HSP1 promoters displayed maximal levels of in vitro transcription when TFAM was present in an amount equimolar to the DNA template. Importantly, we did not detect any significant transcription activity in the presence of the TFB2M paralog, TFB1M, or when templates containing the putative HSP2 promoter were used. These data confirm previous observations that TFB1M does not function as a bona fide transcription factor and raise questions as to whether HSP2 serves as a functional promoter in vivo. In addition, we did not detect transcription stimulation by the ribosomal protein MRPL12. Thus, only two essential initiation factors, TFAM and TFB2M, and two promoters, LSP and HSP1, are required to drive transcription of the mitochondrial genome.Transcription of the human mitochondrial genome is governed by a nuclear-encoded single-subunit RNA polymerase (POLRMT) that is assisted by two transcription initiation factors, TFAM and TFB2M (see Refs. 1 and 2 and references therein). POLRMT possesses promoter recognition functions but depends on TFAM and TFB2M for promoter melting (3). TFAM, a high mobility group class protein, binds to mitochondrial DNA, protects a region 14 -35 bp upstream of the lightstrand promoter (LSP) 4 transcription start site, and assists in assembly of the initiation complex by attracting POLRMT-TFB2M and/or by causing initial melting of the promoter (4). The primary role of TFB2M is to melt the promoter and to stabilize the open promoter complex by simultaneous binding of the priming substrate and the templating DNA base (5). Although the basic requirements for mitochondrial transcription have been established, a number of existing controversial observations preclude a comprehensive view of gene transcription and its regulation in mitochondria. For example, in addition to TFB2M, human mitochondria also contain a homologous factor TFB1M that was reported to stimulate transcription initiation in vitro with 10 -100-fold lower efficiency (6, 7). However, in vivo studies demonstrated that although TFB1M is an essential methyltransferase required to methylate 12 S ribosomal RNA, it plays no role in transcription (8).Another paradox in the field of mitochondrial transcription concerns the existence of an additional promoter in the heavy strand of mtDNA. Transcription initiated at the LSP results in synthesis of a single mRNA that encodes subunit 6 of the NADH dehydrogenase and eight tRNAs (9). The heavy strand of mtDNA encodes 12 polypeptides, two rRNAs, and the rest of the tRNAs; transcription of this strand...
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