Crystal structures of RNA-dependent RNA polymerases from Jingmen tick virus and Alongshan virus

Jingmenviruses are a group of flavi-like viruses with segmented genome and have been found in various types of hosts,including humans,cattle,monkeys,bats,rodents,sheep,ticks,mosquitoes and nematodes.Jingmenviruses,including the Jingmen tick virus(JMTV)and Alongshan virus(ALSV),have been associated with febrile illness and flu-like symptoms in humans.Viral polymerase plays critical roles in genome replication and transcription and is an ideal target for antiviral drugs.Here,we determined the crystal structures of RNA-dependent RNA polymerase(RdRp)domains of JMTV and ALSV at 2.6Åand 3.2Åresolutions,respectively.The overall structures of JMTV and ALSV RdRp domains are similar to those from the typical unsegmented viruses in Flaviviridae family,especially the Flavivirus genus.JMTV and ALSV RdRps can be divided into three subdomains and the catalytical Motif A-G are conserved like the typical flaviviruses,whereas the zinc-binding pockets are absent from the JMTV and ALSV RdRps.The 50-ends of jingmenvirus genomes are varied in length and sequence,and a highly conserved 8-nucleotide element located on the tip of stem loop A was identified and shown to be required for binding with RdRp and performing de novo replication activity.These findings provide important structural insights into RdRp of segmented flavivirus and reveal the key region of virus genome responsible for replication initiation,which would promote molecular understanding of segmented flavivirus replication and the structure-based design of antiviral drugs against flaviviruses.

Predictions in Clinical Efficiency of SARS-CoV-2 RNA-Dependent RNA Polymerase (RdRp) Inhibitors by Molecular Docking

This study utilizes the enzyme-substrate complex theory to predict the clinical efficacy of COVID-19 treatments at the biological systems level, using molecular docking stability indicators. Experimental data from the Protein Data Bank and molecular structures generated by AlphaFold 3 were used to create macromolecular complex templates. Six templates were developed, including the holo nsp7-nsp8-nsp12 (RNA-dependent RNA polymerase) complex with dsRNA primers (holo-RdRp-RNA). The study evaluated several ligands—Favipiravir-RTP, Remdesivir, Abacavir, Ribavirin, and Oseltamivir—as potential viral RNA polymerase inhibitors. Notably, the first four of these ligands have been clinically employed in the treatment of COVID-19, allowing for comparative analysis. Molecular docking simulations were performed using AutoDock 4, and statistical differences were assessed through t-tests and Mann-Whitney U tests. A review of the literature on COVID-19 treatment outcomes and inhibitors targeting RNA polymerase enzymes was conducted, and the inhibitors were ranked according to their clinical efficacy: Remdesivir > Favipiravir-RTP > Oseltamivir. Docking results obtained from the second and third templates aligned with clinical observations. Furthermore, Abacavir demonstrated a predicted efficacy comparable to Favipiravir-RTP, while Ribavirin exhibited a predicted efficacy similar to that of Remdesivir. This research, focused on inhibitors of SARS-CoV-2 RNA-dependent RNA polymerase, establishes a framework for screening AI-generated drug templates based on clinical outcomes. Additionally, it develops a drug screening platform based on molecular docking binding energy, enabling the evaluation of novel or repurposed drugs and potentially accelerating the drug development process.

Potential and application of abortive transcripts as a novel molecular marker of cancers

Abortive transcript(AT)is a 2-19 nt long non-coding RNA that is produced in the abortive initiation stage.Abortive initiation was found to be closely related to RNA polymerase through in vitro experiments.Therefore,the distribution of AT length and the scale of abortive initiation are correlated to the promoter,discriminator,and transcription initiation sequence,and can be affected by transcription elongation factors.AT plays an important role in the occurrence and development of various diseases.Here we summarize the discovery of AT,the factors responsible for AT formation,the detection methods and biological functions of AT,to provide new clues for finding potential targets in the early diagnosis and treatment of cancers.

Epigenetics： heterochromatin meets RNAi

The term epigenetics refers to heritable changes not encoded by DNA. The organization of DNA into chromatin fibers affects gene expression in a heritable manner and is therefore one mechanism of epigenetic inheritance. Large parts of eukaryotic genomes consist of constitutively highly condensed heterochromatin, important for maintaining genome integrity but also for silencing of genes within. Small RNA, together with factors typically associated with RNA interference （RNAi） targets homologous DNA sequences and recruits factors that modify the chromatin, com- monly resulting in formation of heterochromatin and silencing of target genes. The scope of this review is to provide an overview of the roles of small RNA and the RNAi components, Dicer, Argonaute and RNA dependent polymerases in epigenetic inheritance via heterochromatin formation, exemplified with pathways from unicellular eukaryotes, plants and animals.

Systematic identification of endogenous RNA polymeraseⅢpromoters for efficient RNA guidebased genome editing technologies in maize

Single-guide RNA(sg RNA) is one of the two core components of the CRISPR(clustered regularly interspaced short palindromic repeat)/Cas(CRISPR-associated) genome-editing technology. We established an in vitro Traffic Light Reporter(TLR) system, which is designated as the same colors as traffic lights such as green, red and yellow were produced in cells. The TLR can be readily used in maize mesophyll protoplast for a quick test of promoter activity. The TLR assay indicates the variation in transcription activities of the seven Pol III promoters, from 3.4%(U6-1) to over 21.0%(U6-6). The U6-2 promoter, which was constructed to drive sg RNA expression targeting the Zm Wx1 gene, yielded mutation efficiencies ranging from 48.5% to 97.1%. Based on the reported and unpublished data, the in vitro TLR assay results were confirmed to be a readily system and may be extended to other plant species amenable to efficient genome editing via CRISPR/Cas. Our efforts provide an efficient method of identifying native Pol III-recognized promoters for RNA guide-based genome-editing systems in maize.

The VP2 protein of grass carp reovirus(GCRV) expressed in a baculovirus exhibits RNA polymerase activity

The double-shelled grass carp reovirus （GCRV） is capable of endogenous RNA transcription and processing.Genome sequence analysis has revealed that the protein VP2,encoded by gene segment 2 （S2）,is the putative RNA-dependent RNA polymerase （RdRp）.In previous work,we have ex-pressed the functional region of VP2 that is associated with RNA polymerase activity （denoted as rVP2390-900） in E.coil and have prepared a polyclonal antibody against VP2.To characterize the GCRV RNA polymerase,a recombinant full-length VP2 （rVP2） was first constructed and expressed in a baculovirus system,as a fusion protein with an attached His-tag.Immunofluorescence （IF） assays,together with immunoblot （IB） analyses from both expressed cell extracts and purified Histagged rVP2,showed that rVP2 was successfully expressed in Sf9 cells.Further characterization of the replicase activity showed that purified rVP2 and GCRV particles exhibited poly（C）-dependent poly（G） polymerase activity.The RNA enzymatic activity required the divalent cation Mg2＋,and was optimal at 28 ℃.The results provide a foundation for further studies on the RNA polymerases of aquareoviruses during viral transcription and replication.

Hordatines as a Potential Inhibitor of COVID-19 Main Protease and RNA Polymerase: An In-Silico Approach

Total 40 natural compounds were selected to perform the molecular docking studies to screen and identify the potent antiviral agents specifically for Severe Acute Respiratory Syndrome Coronavirus 2 that causes coronavirus disease 2019(COVID-19).The key targets of COVID-19,protease(PDB ID:7BQY)and RNA polymerase(PDB ID:7bV2)were used to dock our target compounds by Molecular Operating Environment(MOE)version 2014.09.We used 3 different conformations of protease target(6M0K,6Y2F and 7BQY)and two different score functions to strengthen the probability of inhibitors discovery.After an extensive screening analysis,20 compounds exhibit good binding affinities to one or both COVID-19 targets.7 out of 20 compounds were predicted to overcome the activity of both targets.The top 7 hits are,flacourticin(3),sagerinic acid(16),hordatine A(23),hordatine B(24),N-feruloyl tyramine dimer(25),bisavenanthramides B-5(29)and vulnibactins(40).According to our results,all these top hits was found to have a better binding scores than remdesivir,the native ligand in RNA polymerase target(PDB ID:7bV2).Hordatines are phenolic compounds present in barley,were found to exhibit the highest binding affinity to both protease and polymerase through forming strong hydrogen bonds with the catalytic residues,as well as significant interactions with other receptor-binding residues.These results probably provided an excellent lead candidate for the development of therapeutic drugs against COVID-19.Eventually,animal experiment and accurate clinical trials are needed to confirm the preventive potentials of these compounds.

Snapshots of a Viral RNA Polymerase Switching Gears from Transcription Initiation to Elongation

During transcription initiation,RNA polymerase binds tightly to the promoter DNA defining the start of transcription,transcribes comparatively slowly,and frequently releases short transcripts(3-8 nucleotides)in a process called abortive cycling.Transitioning to elongation,the second phase of transcription,the polymerase dissociates from the promoter while RNA synthesis continues.Elongation is characterized by higher rates of transcription and tight binding to the RNA transcript.The RNA polymerase from enterophage T7 (T7 RNAP) has been used as a model to understand the mechanism of transcription in general,and the transition from initiation to elongation specifically.This single-subunit enzyme undergoes dramatic conformational changes during this transition to support the changing requirements of nucleic acid interactions while continuously maintaining polymerase function.Crystal structures,available of multiple stages of the initiation complex and of the elongation complex,combined with biochemical and biophysical data,offer molecular detail of the transition.Some of the crystal structures contain a variant of T7 RNAP where proline 266 is substituted by leucine.This variant shows less abortive products and altered timing of transition,and is a valuable tool to study these processes.The structural transitions from early to late initiation are well understood and are consistent with solution data.The timing of events and the structural intermediates in the transition from late initiation to elongation are less well understood,but the available data allows one to formulate testable models of the transition to guide further research.

Brownian ratchet mechanism of translocation in T7 RNA polymerase facilitated by a post-translocation energy bias arising from the conformational change of the enzyme

T7 RNA polymerase can transcribe DNA to RNA by translocating along the DNA. Structural studies suggest that the pivoting rotation of the O helix in the fingers domain may drive the movement of the O helix C-terminal Tyr639 from pre- to post-translocation positions. In a series of all-atom molecular dynamics simulations, we show that the movement of Tyr639 is not tightly coupled to the rotation of the O helix, and that the two processes are only weakly dependent on each other. We also show that the internal potential of the enzyme itself generates a small difference in free energy （△E） between the post- and pre-translocation positions of Tyr639. The calculated value of △E is consistent with that obtained from single-molecule experimental data. These findings lend support to a model in which the translocation takes place via a Brownian ratchet mechanism, with the small free energy bias △E arising from the conformational change of the enzyme itself.

An intermediate state of T7 RNA polymerase provides another pathway of nucleotide selection

Phage T7 RNA polymerase is a single-subunit transcription enzyme, transcribing template DNA to RNA. Nucleoside triphosphate （NTP） selection and translocation are two critical steps of the transcription elongation. Here, using all-atom molecular dynamics simulations, we found that between pre- and post-translocation states of T7 RNA polymerase an intermediate state exists, where the O helix C-terminal residue tyrosine 639, which plays important roles in translocation, locates between its pre- and post-translocation positions and the side chain of the next template DNA nucleotide has moved into the active site. NTP selection in this intermediate state was studied, revealing that the selection in the intermediate state can be achieved relying on the effect of Watson-Crick interaction between NTP and template DNA nucleotide, effect of stability of the components near the active site such as the nascent DNA-RNA hybrid and role of tyrosine 639. This indicates that another NTP-selection pathway can also exist besides the main pathway where NTP selection begins at the post-translocation state upon the entry of NTE

Probing conformational change of T7 RNA polymerase and DNA complex by solid-state nanopores

Proteins are crucial to most biological processes, such as enzymes, and in various catalytic processes a dynamic motion is required. The dynamics of protein are embodied as a conformational change, which is closely related to the flexibility of protein. Recently, nanopore sensors have become accepted as a low cost and high throughput method to study the features of proteins. In this article, we used a SiN nanopore device to study the flexibility of T7 RNA polymerase（RNAP） and its complex with DNA promoter. By calculating full-width at half-maximum（FWHM） of Gaussian fits to the blockade histograms, we found that T7 RNAP becomes more flexible after binding DNA promoter. Moreover, the distribution of fractional current blockade suggests that flexibility alters due to a breath-like change of the volume.

Alternative Role of Motif B in Template Dependent Polymerase Inhibition

Severe acute respiratory syndrome coronavirus 2(SARS-Co V-2) relies on the central molecular machine RNA-dependent RNA polymerase(Rd Rp) for the viral replication and transcription. Remdesivir at the template strand has been shown to effectively inhibit the RNA synthesis in SARS-Co V-2 Rd Rp by deactivating not only the complementary UTP incorporation but also the next nucleotide addition. However, the underlying molecular mechanism of the second inhibitory point remains unclear. In this work, we have performed molecular dynamics simulations and demonstrated that such inhibition has not directly acted on the nucleotide addition at the active site. Instead, the translocation of Remdesivir from +1 to-1 site is hindered thermodynamically as the posttranslocation state is less stable than the pre-translocation state due to the motif B residue G683. Moreover, another conserved residue S682 on motif B further hinders the dynamic translocation of Remdesivir due to the steric clash with the 1′-cyano substitution. Overall,our study has unveiled an alternative role of motif B in mediating the translocation when Remdesivir is present in the template strand and complemented our understanding about the inhibitory mechanisms exerted by Remdesivir on the RNA synthesis in SARS-Co V-2 Rd Rp.

Analysis of RNA-Dependent RNA Polymerase Sequence of Infectious Flacherie Virus Isolated in China and Its Expression in BmN Cells

Full gene sequence of RNA-dependent RNA polymerase （RdRp） from Bombyx mori infectious flacherie virus isolated in Zhejiang Province, China （Zhejiang01/CHN/2002） was cloned. The sequence was 1 920 nucleotides in length coding 639 amino acid residues. Sequences comparison of RdRp showed Zhejiang01/CHN/2002 was 99.7% nucleotide sequence and 99.1% amino acids sequence homology with Japanese strain. The RdRp sequence was aligned with 8 representative picorna（-like） viruses and 8 highly conserved regions were detected. The result indicated their relevance function. Phylogenetic tree of 14 picorna（-like） viruses which RdRp presumed protein sequences revealed that the viruses from Iflavirus genus formed an independent clade. The RdRp was successfully expressed in BmN cells using Bac-to-Bac expression system.

Future of the current anticoronaviral agents: A viewpoint on thevalidation for the next COVIDs and pandemics

Despite the global decline in the severity of the coronavirus disease 2019 (COVID-19) cases, the disease stillrepresents a major concern to the relevant scientific and medical communities. The primary concern of drug scientists,virologists, and other concerned specialists in this respect is to find ready-to-use suitable and potent anticoronaviraltherapies that are broadly effective against the different species/strains of the coronaviruses in general, not only againstthe current and previous coronaviruses (e.g., the recently-appeared severe acute respiratory syndrome coronavirus 2“SARS-CoV-2”), i.e., effective antiviral agents for treatment and/or prophylaxis of any coronaviral infections, includingthose of the coming ones from the next species and strains (if any). As an expert in this field, I tried, in this up-to-dateperspective “viewpoint” article, to evaluate the suitability and applicability of using the currently-availableanticoronaviral agents for the next coronavirus diseases (COVIDs) and coronaviral pandemics, highlighting the mostimportant general guidelines that should be considered in the next pandemics from the therapeutic points of view.

Promoting the production of challenging proteins via induced expression in CHO cells and modified cell-free lysates harboring T7 RNA polymerase and mutant eIF2α

Chinese hamster ovary(CHO)cells are crucial in biopharmaceutical production due to their scalability and capacity for human-like post-translational modifications.However,toxic proteins and membrane proteins are often difficult-to-express in living cells.Alternatively,cell-free protein synthesis can be employed.This study explores innovative strategies for enhancing the production of challenging proteins through the modification of CHO cells by investigating both,cell-based and cell-free approaches.A major result in our study involves the integration of a mutant eIF2 translation initiation factor and T7 RNA polymerase into CHO cell lysates for cell-free protein synthesis.This resulted in elevated yields,while eliminating the necessity for exogenous additions during cell-free production,thereby substantially enhancing efficiency.Additionally,we explore the potential of the Rosa26 genomic site for the integration of T7 RNA polymerase and cell-based tetracycline-controlled protein expression.These findings provide promising advancements in bioproduction technologies,offering flexibility to switch between cell-free and cell-based protein production as needed.

Inhibiting the oligomerization of mycobacterial DNA-directed RNA polymerase(RNAP)using natural compound via in-silico techniques

Mycobacterium tuberculosis(Mtb)is responsible for the spread of tuberculosis(TB).The current study employed virtual screening of 2569 natural compounds against the DNA-directed RNA polymerase(RNAP)of Mtb to identify the possible binders that can inhibit its function.The in-silico methodology included molecular docking to the compounds,further,the stability and flexibility of the best complexes were studied using molecular dynamics simulation,the MM/GBSA binding free energy technique with energy decomposition,PCA,FEL,steered MD simulation,and umbrella sampling.Individual virtual screenings were conducted for the five RNAP subunits(chains A,B,C,D,and E)to identify a compound capable of inhibiting RNAP oligomerization.A promising compound,isoestradiol 3-benzoate,exhibited a low binding score(−7.28kcal/mol to−8.21kcal/mol)and showed binding ability with all subunits of the protein.Thus,the five complexes with isoestradiol 3-benzoate were selected for molecular dynamics simulation analysis.Furthermore,RMSD showed that isoestradiol 3-benzoate bound with chain E showed the lowest RMSD of 0.49nm,while with chains A and B it had the most stable and consistent conformations with RMSD of 1.75nm and 1.2nm,respectively.The H-bond between isoestradiol 3-benzoate and chains C and E showed the highest occupancy(58.27%,45.33%,and 50.80%,42.25%,11.75%).Moreover,the MMPBSA technique showed that isoestradiol 3-benzoate had a strong association with chains B and C(ΔGbind=−126.25±2.03 and−129.27±2.25).Additionally,free energy decomposition,PCA,FEL-steered MD simulation,and umbrella sampling were also performed to validate the association of the ligand with the protein.Isoestradiol 3-benzoate binds strongly to chains B and E;therefore,it should be considered as viable candidate for inhibiting the formation of RNAP protein complex,concluded in this study.

Rapid Recovery of Classical Swine Fever Virus Directly from Cloned cDNA

The reverse genetics for classical swine fever virus （CSFV） is currently based on the transfection of in vitro transcribed RNA from a viral genomic cDNA clone, which is inefficient and time-consuming. This study was aimed to develop an improved method for rapid recovery of CSFV directly from cloned cDNA. Full-length genomic cDNA from the CSFV Shimen strain, which was flanked by a T7 promoter, the hepatitis delta virus ribozyme and T7 terminator sequences, was cloned into the low- copy vector pOK12, producing pOKShimen-RzTФ. Direct transfection of pOKShimen-RzTqb into PK/T7 cells, a PK-15- derived cell line stably expressing bacteriophage T7 RNA polymerase, allowed CSFV to be rescued rapidly and efficiently, i.e., at least 12 h faster and 31.6-fold greater viral titer when compared with the in vitro transcription-based rescue system. Furthermore, the progeny virus rescued from PK/T7 cells was indistinguishable, both in vitro and in vivo, from its parent virus and the virus rescued from classical reverse genetics. The reverse genetics based on intracellular transcription is efficient, convenient and cost-effective. The PK/T7 cell line can be used to rescue CSFV directly from cloned cDNA and it can also be used as an intracellular transcription and expression system for studying the structure and function of viral genes.

Rifampicin for COVID-19

Vaccinations for coronavirus disease-2019(COVID-19)have begun more than a year before,yet without specific treatments available.Rifampicin,critically important for human medicine(World Health Organization’s list of essential medicines),may prove pharmacologically effective for treatment and chemoprophylaxis of healthcare personnel and those at higher risk.It has been known since 1969 that rifampicin has a direct selective antiviral effect on viruses which have their own RNA polymerase(severe acute respiratory syndrome coronavirus 2),like the main mechanism of action of remdesivir.This involves inhibition of late viral protein synthesis,the virion assembly,and the viral polymerase itself.This antiviral effect is dependent on the administration route,with local application resulting in higher drug concentrations at the site of viral replication.This would suggest also trying lung administration of rifampicin by nebulization to increase the drug’s concentration at infection sites while minimizing systemic side effects.Recent in silico studies with a computer-aided approach,found rifampicin among the most promising existing drugs that could be repurposed for the treatment of COVID-19.

How to make the end of a gene,the simple way

Transcription termination of nearly all protein-coding genes in mammals requires 3’end processing by a multiprotein complex that will cleave and polyadenylate the messenger RNA precursor.Because a variety of enzyme complexes intervene,3’end processing was thought to be fundamentally complex and subject to a multitude of regulatory effects.The possibility to select just one out of several polyadenylation sites,in particular,has caused much questioning and speculation.What appear to be separate mechanisms however can be combined into a defined set of rules,allowing for a relatively simple interpretation of 3’end processing.Ultimately,readiness of the terminal exon splice site determines when a transcript reaches the maturity to select a nearby polyadenylation signal.Transcriptional pausing then acts in concert,extending the timeframe during which the transcription complex is close to polyadenylation sites.Since RNA polymerase pausing is governed by the same type of sequences in bacteria and metazoans,mammalian transcription termination resembles its prokaryote counterpart more than generally thought.

Advanced pancreatic ductal adenocarcinoma-Complexities of treatment and emerging therapeutic options

Pancreatic ductal adenocarcinoma is a devastating disease with a poor prognosis regardless of stage. To date the mainstay of therapy for advanced disease has been chemotherapy with little incremental im-provements in outcome. Despite extensive research investigating new treatment options the current practices continue to utilise fluorouracil or gemcitabine containing combinations. The need for novel the-rapeutic approaches is mandated by the ongoing poor survival rates associated with this disease. One such approach may include manipulation of ribosome biogenesis and the nucleolar stress response, which has recently been applied to haematological malignancies such as lymphoma and prostate cancer with promising results. This review will focus on the current therapeutic options for pancreatic ductal adenocarcinoma and the complexities associated with developing novel treatments, with a particular emphasis on the role of the nucleolus as a treatment strategy.