Within and Beyond the Nucleotide Addition Cycle of Viral RNA-dependent RNA Polymerases

Nucleotide addition cycle (NAC) is a fundamental process utilized by nucleic acid polymerases when carrying out nucleic acid biosynthesis. An induced-fit mechanism is usually taken by these polymerases upon NTP/dNTP substrate binding, leading to active site closure and formation of a phosphodiester bond. In viral RNA-dependent RNA polymerases, the post-chemistry translocation is stringently controlled by a structurally conserved motif, resulting in asymmetric movement of the template-product duplex. This perspective focuses on viral RdRP NAC and related mechanisms that have not been structurally clarified to date. Firstly, RdRP movement along the template strand in the absence of catalytic events may be relevant to catalytic complex dissociation or proofreading. Secondly, pyrophosphate or non-cognate NTP-mediated cleavage of the product strand 3′-nucleotide can also play a role in reactivating paused or arrested catalytic complexes. Furthermore, non-cognate NTP substrates, including NTP analog inhibitors, can not only alter NAC when being misincorporated, but also impact on subsequent NACs. Complications and challenges related to these topics are also discussed.

Mandatory coupling of zygotic transcription to DNA replication in early Drosophila embryos

Collisions between transcribing RNA polymerases and DNA replication forks are disruptive. The threat of collisions is particularly acute during the rapid early embryonic cell cycles of Drosophila when S phase occupies the entirety of interphase. We hypothesized that collision-avoidance mechanisms safeguard the onset of zygotic transcription in these cycles. To explore this hypothesis, we used real-time imaging of transcriptional events at the onset of each interphase. Endogenously tagged RNA polymerase II (RNAPII) abruptly formed clusters before nascent transcripts accumulated, indicating recruitment prior to transcriptional engagement. Injection of inhibitors of DNA replication prevented RNAPII clustering, blocked formation of foci of the pioneer factor Zelda, and largely prevented expression of transcription reporters. Knockdown of Zelda or the histone acetyltransferase CBP prevented RNAPII cluster formation except at the replication-dependent (RD) histone gene locus. We suggest a model in which the passage of replication forks allows Zelda and a distinct pathway at the RD histone locus to reconfigure chromatin to nucleate RNAPII clustering and promote transcriptional initiation. The replication dependency of these events defers initiation of transcription and ensures that RNA polymerases transcribe behind advancing replication forks. The resulting coordination of transcription and replication explains how early embryos circumvent collisions and promote genome stability.

The host factor ANP32A is required for influenza A virus vRNA and cRNA synthesis

Influenza A viruses are negative-sense RNA viruses that rely on their own viral replication machinery to replicate and transcribe their segmented single-stranded RNA genome. The viral ribonucleoprotein complexes in which viral RNA is replicated consist of a nucleoprotein scaffold around which the RNA genome is bound, and a heterotrimeric RNA-dependent RNA polymerase that catalyzes viral replication. The RNA polymerase copies the viral RNA (vRNA) via a replicative intermediate, called the complementary RNA (cRNA), and subsequently uses this cRNA to make more vRNA copies. To ensure that new cRNA and vRNA molecules are associated with ribonucleoproteins in which they can be amplified, the active RNA polymerase recruits a second polymerase to encapsidate the cRNA or vRNA. Host factor ANP32A has been shown to be essential for viral replication and to facilitate the formation of a dimer between viral RNA polymerases. Differences between mammalian and avian ANP32A proteins are sufficient to restrict viral replication. It has been proposed that ANP32A is only required for the synthesis of vRNA molecules from a cRNA, but not vice versa. However, this view does not match recent molecular evidence. Here we use minigenome assays, virus infections, and viral promoter mutations to demonstrate that ANP32A is essential for both vRNA and cRNA synthesis. Moreover, we show that ANP32 is not only needed for the actively replicating polymerase, but also for the polymerase that is encapsidating nascent viral RNA products. Overall, these results provide new insights into influenza A virus replication and host adaptation. IMPORTANCE Zoonotic avian influenza A viruses pose a constant threat to global health, and they have the potential to cause pandemics. Species variations in host factor ANP32A play a key role in supporting the activity of avian influenza A virus RNA polymerases in mammalian hosts. Here we show that ANP32A acts at two stages in the influenza A virus replication cycle, supporting recent structural experiments, in line with its essential role. Understanding how ANP32A supports viral RNA polymerase activity and how it supports avian polymerase function in mammalian hosts is important for understanding influenza A virus replication and the development of antiviral strategies against influenza A viruses.

Several Isoforms for Each Subunit Shared by RNA Polymerases are Differentially Expressed in the Cultivated Olive Tree (Olea europaea L.)

Plants contain five nuclear RNA polymerases, with RNA pols IV and V in addition to conserved eukaryotic RNA pols I, II, and III. These transcriptional complexes share five common subunits, which have been extensively analyzed only in yeasts. By taking advantage of the recently published olive tree cultivar (Olea europaea L. cv. Picual) genome, we performed a genome-wide analysis of the genomic composition corresponding to subunits common to RNA pols. The cultivated olive tree genome is quite complex and contains many genes with several copies. We also investigated, for the first time, gene expression patterns for subunits common to RNA pols using RNA-Seq under different economically and biologically relevant conditions for the cultivar “Picual”: tissues/organs, biotic and abiotic stresses, and early development from seeds. Our results demonstrated the existence of a multigene family of subunits common to RNA pols, and a variable number of paralogs for each subunit in the olive cultivar “Picual.” Furthermore, these isoforms display specific and differentiated expression profiles depending on the isoform and growth conditions, which may be relevant for their role in olive tree biology.

Structure and RNA template requirements of Arabidopsis RNA-DEPENDENT RNA POLYMERASE 2

RNA-dependent RNA polymerases play essential roles in RNA-mediated gene silencing in eukaryotes. In Arabidopsis, RNA-DEPENDENT RNA POLYMERASE 2 (RDR2) physically interacts with DNA-dependent NUCLEAR RNA POLYMERASE IV (Pol IV) and their activities are tightly coupled, with Pol IV transcriptional arrest, induced by the nontemplate DNA strand, somehow enabling RDR2 to engage Pol IV transcripts and generate double-stranded RNAs. The double-stranded RNAs are then released from the Pol IV–RDR2 complex and diced into short-interfering RNAs that guide RNA-directed DNA methylation and silencing. Here we report the structure of full-length RDR2, at an overall resolution of 3.1 Å, determined by cryoelectron microscopy. The N-terminal region contains an RNA-recognition motif adjacent to a positively charged channel that leads to a catalytic center with striking structural homology to the catalytic centers of multisubunit DNA-dependent RNA polymerases. We show that RDR2 initiates 1 to 2 nt internal to the 3′ ends of its templates and can transcribe the RNA of an RNA/DNA hybrid, provided that 9 or more nucleotides are unpaired at the RNA’s 3′ end. Using a nucleic acid configuration that mimics the arrangement of RNA and DNA strands upon Pol IV transcriptional arrest, we show that displacement of the RNA 3′ end occurs as the DNA template and nontemplate strands reanneal, enabling RDR2 transcription. These results suggest a model in which Pol IV arrest and backtracking displaces the RNA 3′ end as the DNA strands reanneal, allowing RDR2 to engage the RNA and synthesize the complementary strand.

Heterogeneous recruitment abilities to RNA polymerases generate nonlinear scaling of gene expression with cell volume

While most genes’ expression levels are proportional to cell volumes, some genes exhibit nonlinear scaling between their expression levels and cell volume. Therefore, their mRNA and protein concentrations change as the cell volume increases, which often have crucial biological functions such as cell-cycle regulation. However, the biophysical mechanism underlying the nonlinear scaling between gene expression and cell volume is still unclear. In this work, we show that the nonlinear scaling is a direct consequence of the heterogeneous recruitment abilities of promoters to RNA polymerases based on a gene expression model at the whole-cell level. Those genes with weaker (stronger) recruitment abilities than the average ability spontaneously exhibit superlinear (sublinear) scaling with cell volume. Analysis of the promoter sequences and the nonlinear scaling of Saccharomyces cerevisiae’s mRNA levels shows that motifs associated with transcription regulation are indeed enriched in genes exhibiting nonlinear scaling, in concert with our model.

Comprehensive determination of transcription start sites derived from all RNA polymerases using ReCappable-seq

Determination of eukaryotic Transcription Start Sites (TSS) has been based on methods that require the cap structure at the 5-prime end of transcripts derived from Pol-II RNA polymerase. Consequently, these methods do not reveal TSS derived from the other RNA polymerases which also play critical roles in various cell functions. To address this limitation, we developed ReCappable-seq which comprehensively identifies TSS for both Pol-lI and non-Pol-II transcripts at single-nucleotide resolution. The method relies on specific enzymatic exchange of 5-prime m7G caps and 5-prime triphosphates with a selectable tag. When applied to human transcriptomes, ReCappable-seq identifies Pol-II TSS that are in agreement with orthogonal methods such as CAGE. Additionally, ReCappable-seq reveals a rich landscape of TSS associated with Pol-III transcripts which have not previously been amenable to study at genome-wide scale. Novel TSS from non-Pol-II transcription can be located in the nuclear and mitochondrial genomes. ReCappable-seq interrogates the regulatory landscape of coding and noncoding RNA concurrently and enables the classification of epigenetic profiles associated with Pol-lI and non-Pol-II TSS.

An Insight into the Proofreading Functions of Multisubunit DNA-Dependent RNA Polymerases and Their Catalytic Mechanism

Aim: To analyze the active sites of the proofreading (PR) functions in the multisubunit DNA-dependent RNA polymerases (MSU RNAPs) from prokaryotes, chloroplasts and eukaryotes, and propose a plausible unified catalytic mechanism for these enzymes. Study Design: Data collected on these enzymes from bioinformatics, biochemical, site-directed mutagenesis (SDM), X-ray crystallography and cryo-electron microscopy (cryo-EM) were used for the analyses. Methodology: The protein sequence data of MSU RNAPs from prokaryotes, prokaryotic-types (plant chloroplasts) and eukaryotes were obtained from PUBMED and SWISS-PROT databases. The advanced version of Clustal Omega was used for protein sequence analysis. Along with the conserved motifs identified by the bioinformatics analysis, the data already available from biochemical and SDM experiments, and X-ray crystallographic and cryo-EM data on these enzymes are also used to confirm the possible amino acids involved in the active site of the PR function in these MSU RNAPs Results: All the seven types of MSU RNAPs (I-VII) reported from prokaryotes to eukaryotes were analyzed by the multiple sequence alignment (MSA) software, Clustal Omega, to find out conservations among them. The MSA analysis showed many conserved amino acid motifs including small and large peptide regions from the MSU RNAPs of prokaryotes, eukaryotes and plant chloroplasts. Interestingly, the catalytic amino acid and template-binding pairs are highly conserved in all these polymerases, with a few exceptions. Most of them use a basic amino acid (R/K/H) for initiating catalysis and an -YG/FG- pair for template-binding. Some odd type of catalytic amino acids and template-binding pairs are observed in human pathogens, parasites and organisms which cannot ferment sugars. In all the MSU RNAPs, the proposed polymerase catalytic region also possessed three invariant Cs and an invariant H within it. The invariant Cs is shown to bind a zinc atom and proposed to involve in the PR function by excising any misincorporated nucleotide during the transcription process. In the plant-specific MSU RNAPs IV and V, which involve in transcriptional gene silencing in plants, the catalytic and template-binding pairs do not follow the regular distance conservations as observed with other five of the MSU RNAPs. Their polymerase/PR active site regions are similar to RNAP III rather than to RNAP II, as all three make only low molecular weight RNAs. Conclusions: All the known MSU RNAPs possess three invariant Cs and an invariant H embedded within the polymerase active site itself. The three invariant Cs are shown to bind a zinc atom and the invariant H could act as the proton acceptor from a metal-bound water molecule, for initiating excision of the mismatches by a Zn-mediated hydrolysis. Thus, the PR function in MSU RNAPs is integrated within the polymerase active site itself, which is in sharp contrast to the PR functions reported in DNA-dependent DNA polymerases and RNA-dependent RNA polymerases. Therefore, all the seven MSU RNAPs from prokaryotes and eukaryotes are proposed to follow a unified mechanism to excise the mismatches during transcription. The discovery of intrinsic self-correcting RNA transcription mechanism fulfils the missing link in molecular evolution.

Kanglemycin A can overcome rifamycin resistance caused by ADP-ribosylation by Arr protein

Rifamycins, such as rifampicin, are potent inhibitors of bacterial RNA polymerases and widely used antibiotics. Usually rifamycin-resistance is associated with mutations in RNAP that preclude rifamycins binding. However, some bacteria have ADP-ribosyl transferases Arr that ADP-ribosylate rifamycin molecules, thus inactivating their antimicrobial activity. Here we directly show that ADP-ribosylation abolishes inhibition of transcription by rifampicin, the most widely used rifamycin antibiotic. We also show that natural rifamycin, Kanglemycin A, which has a unique sugar moiety at the ansa-chain close to the Arr-modification site, does not bind to Arr from M. smegmatis , and thus is not susceptible to inactivation. We, however, found that Kanglemycin A can still be ADP-ribosylated by Arr of an emerging pathogen M. abscessus . Interestingly, the only part of Arr which exhibits no homology between the species is the part that sterically clashes with sugar moiety of Kanglemycin A in M. smegmatis Arr. This suggests that M. abscessus has encountered KglA or rifamycin with similar sugar modification in the course of evolution. The results show that KglA could be effective antimicrobial against some of the Arr encoding bacteria.