Helicase Activity Research Articles

RECQL4 requires PARP1 for recruitment to DNA damage, and PARG dePARylation facilitates its associated role in end joining.

RecQ helicases, highly conserved proteins with pivotal roles in DNA replication, DNA repair and homologous recombination, are crucial for maintaining genomic integrity. Mutations in RECQL4 have been associated with various human diseases, including Rothmund-Thomson syndrome. RECQL4 is involved in regulating major DNA repair pathways, such as homologous recombination and nonhomologous end joining (NHEJ). RECQL4 has more prominent single-strand DNA annealing activity than helicase activity. Its ability to promote DNA damage repair and the precise role of its DNA annealing activity in DNA repair are unclear. Here we demonstrate that PARP1 interacts with RECQL4, increasing its single-stranded DNA strand annealing activity. PARP1 specifically promoted RECQL4 PARylation at both its N- and C-terminal regions, promoting RECQL4 recruitment to DNA double-strand breaks (DSBs). Inhibition or depletion of PARP1 significantly diminished RECQL4 recruitment and occupancy at specific DSB sites on chromosomes. After DNA damage, PARG dePARylated RECQL4 and stimulated its end-joining activity. RECQL4 actively displaced replication protein A from single-stranded DNA, promoting microhomology annealing in vitro. Furthermore, depletion of PARP1 or RECQL4 substantially impacted classical-NHEJ- and alternative-NHEJ-mediated DSB repair. Consequently, the combined activities of PARP1, PARG and RECQL4 modulate DNA repair.

Phosphorylation-dependent WRN-RPA interaction promotes recovery of stalled forks at secondary DNA structure

The WRN protein is vital for managing perturbed replication forks. Replication Protein A strongly enhances WRN helicase activity in specific in vitro assays. However, the in vivo significance of RPA binding to WRN has largely remained unexplored. We identify several conserved phosphorylation sites in the acidic domain of WRN targeted by Casein Kinase 2. These phosphorylation sites are crucial for WRN-RPA interaction. Using an unphosphorylable WRN mutant, which lacks the ability to bind RPA, we determine that the WRN-RPA complex plays a critical role in fork recovery after replication stress countering the persistence of G4 structures after fork stalling. However, the interaction between WRN and RPA is not necessary for the processing of replication forks when they collapse. The absence of WRN-RPA binding hampers fork recovery, causing single-strand DNA gaps, enlarged by MRE11, and triggering MUS81-dependent double-strand breaks, which require repair by RAD51 to prevent excessive DNA damage.

High-resolution fleezers reveal duplex opening and stepwise assembly by an oligomer of the DEAD-box helicase Ded1p

DEAD-box RNA-dependent ATPases are ubiquitous in all domains of life where they bind and remodel RNA and RNA-protein complexes. DEAD-box ATPases with helicase activity unwind RNA duplexes by local opening of helical regions without directional movement through the duplexes and some of these enzymes, including Ded1p from Saccharomyces cerevisiae, oligomerize to effectively unwind RNA duplexes. Whether and how DEAD-box helicases coordinate oligomerization and unwinding is not known and it is unclear how many base pairs are actively opened. Using high-resolution optical tweezers and fluorescence, we reveal a highly dynamic and stochastic process of multiple Ded1p protomers assembling on and unwinding an RNA duplex. One Ded1p protomer binds to a duplex-adjacent ssRNA tail and promotes binding and subsequent unwinding of the duplex by additional Ded1p protomers in 4–6 bp steps. The data also reveal rapid duplex unwinding and rezipping linked with binding and dissociation of individual protomers and coordinated with the ATP hydrolysis cycle.

Phylogenetic analysis and molecular structure of NS1 proteins of porcine parvovirus 5 isolates from Mexico

Porcine parvovirus 5 (PPV5) is an unclassified member of the family Parvoviridae with no reported pathogenicity, although it is associated with multisystemic, reproductive, and respiratory diseases. Its open reading frame 1 (ORF1) encodes non-structural protein 1 (NS1), which is predicted to have helicase activity that is essential for viral replication. This protein contains a C-motif with an invariant asparagine residue that forms the core of the enzyme's active site, in conjunction with the Walker A and B motifs. The aim of this study was the phylogenetic and molecular characterization of the NS1 of PPV5 through nested PCR and sequencing of three Mexican PPV5-positive samples. Subsequently, a phylogenetic tree, identity matrices of nucleotide and amino acid sequences, and a three-dimensional model of NS1 were constructed. The amplified sequences, which represented 96.9% of the PPV5 ORF1, occupied the same branch in the phylogenetic tree and exhibited the most nucleotide sequence similarity to the corresponding region of PPV4 and the most amino acid sequence similarity to the NS1 proteins of PPV4 and PPV6. A three-dimensional model of NS1 displayed a C-motif characteristic of superfamily 3 (SF3) helicases. The phylogenetic proximity of PPV5 to PPV4 and PPV6 suggests that it may belong to the genus Copiparvovirus. Further studies on helicases from viruses infecting domestic animals may be useful in developing antiviral drugs for both human and veterinary medicine.

A novel ADP-directed chaperone function facilitates the ATP-driven motor activity of SARS-CoV helicase.

Helicase is a nucleicacid motor that catalyses the unwinding of double-stranded (ds) RNA and DNA via ATP hydrolysis. Helicases can act either as a nucleicacid motor that unwinds its ds substrates or as a chaperone that alters the stability of its substrates, but the two activities have not yet been reported to act simultaneously. Here, we used single-molecule techniques to unravelthe synergistic coordination of helicase and chaperone activities, and found that the severe acute respiratory syndrome coronavirushelicase (nsp13) is capable of two modes of action: (i) binding of nsp13 in tandem with the fork junction of the substrate mechanically unwinds the substrate by an ATP-driven synchronous power stroke; and (ii) free nsp13, which is not bound to the substrate but complexed with ADP in solution, destabilizes the substrate through collisions between transient binding and unbinding events with unprecedented melting capability. Our findings provide new insights into how the same enzyme works via two modes on different parts of the substrate and synergistically catalyses the unwinding reaction, utilizing ATP and recycling its by-product ADP as an energy source.

Yeast Eukaryotic Initiation Factor 4B Remodels the MRNA Entry Site on the Small Ribosomal Subunit.

Eukaryotic Initiation Factor 4 (eIF4) is a group of factors that activates mRNA for translation and recruit 43S preinitiation complex (PIC) to the mRNA 5' end, forming the 48S PIC. The eIF4 factors include mRNA 5' cap-binding protein eIF4E, ATP-dependent RNA helicase eIF4A, and scaffold protein eIF4G, which anchors eIF4A and eIF4E. Another eIF4 factor, eIF4B, stimulates the RNA helicase activity of eIF4A and facilitates mRNA recruitment. However, the mechanisms by which eIF4B binds the 40S ribosomal subunit and promotes mRNA recruitment remain poorly understood. Using cryo-Eletron Microscopy (cryo-EM), we obtained a map of the yeast 40S ribosomal subunit in a complex with eIF4B (40S-eIF4B complex). An extra density, tentatively assigned to yeast eIF4B, was observed near the mRNA entry channel of the 40S, contacting ribosomal proteins uS10, uS3, and eS10 as well as rRNA helix h16. Predictive modeling of the 40S-eIF4B complex suggests that the N-terminal domain of eIF4B binds near the mRNA entry channel, overlapping with the extra density observed in the 40S-eIF4B map. The partially open conformation of 40S in the 40S-eIF4B map is incompatible with eIF3j binding observed in the 48S PIC. Additionally, the extra density at the mRNA entry channel poses steric hindrance for eIF3g binding in the 48S PIC. Thus, structural insights suggest that eIF4B facilitates the release of eIF3j and the relocation of the eIF3b-g-i module during mRNA recruitment, thereby advancing our understanding of eIF4B's role in translation initiation.

Functions of the Bloom Syndrome Helicase N-terminal Intrinsically Disordered Region.

Bloom Syndrome helicase (Blm) is a RecQ family helicase involved in DNA repair, cell-cycle progression, and development. Pathogenic variants in human BLM cause the autosomal recessive disorder Bloom Syndrome, characterized by predisposition to numerous types of cancer. Prior studies of Drosophila Blm mutants lacking helicase activity or protein have shown sensitivity to DNA damaging agents, defects in repairing DNA double-strand breaks (DSBs), female sterility, and improper segregation of chromosomes in meiosis. Blm orthologs have a well conserved and highly structured RecQ helicase domain, but more than half of the protein, particularly in the N-terminus, is predicted to be intrinsically disordered. Because this region is poorly conserved across metazoa, we compared closely related species to identify regions of conservation that might be associated with important functions. We deleted two Drosophila-conserved regions in D. melanogaster using CRISPR/Cas9 gene editing and assessed the effects on several Blm functions. Each deletion had distinct effects. Deletion of either conserved region 1 (CR1) or conserved region 2 (CR2) compromised DSB repair through synthesis-dependent strand annealing and resulted in increased mitotic crossovers. In contrast, CR2 is critical for embryonic development but CR1 is less important. Loss of CR1 leads to defects in meiotic crossover designation and patterning but does not impact meiotic chromosome segregation, whereas deletion of CR2 does not result in significant meiotic defects. Thus, while the two regions have overlapping functions, there are distinct roles facilitated by each. These results provide novel insights into functions of the N-terminal region of Blm helicase.

SSB promotes DnaB helicase passage through DnaA complexes at the replication origin oriC for bidirectional replication.

For bidirectional replication in E. coli, higher-order complexes are formed at the replication origin oriC by the initiator protein DnaA, which locally unwinds the left edge of oriC to promote the loading of two molecules of DnaB onto the unwound region via dynamic interactions with the helicase-loader DnaC and the oriC-bound DnaA complex. One of the two helicases must translocate rightwards through oriC-bound DnaA complex. Here, we used a synthetic forked oriC DNA, which mimics the unwound state of oriC, to examine DnaB translocation through the oriC-bound DnaA complex. We found that DnaB helicase alone cannot pass through the oriC-bound DnaA complex without the help of single strand-binding protein (SSB). In the presence of SSB, DnaB passed through this complex along with its helicase function, releasing DnaA molecules. In addition, DnaB helicase activity is known to be inhibited by oversupply of DnaC, but this inhibition was relieved by SSB. These results suggest a mechanism that when two DnaB helicases are loaded at oriC, one translocates leftwards to expand the DnaA-unwound region and allows SSB binding to the single-stranded DNA, and such SSB molecules then stimulate translocation of the other helicase rightwards through the oriC-bound DnaA complex.

RTEL1 is upregulated in gastric cancer and promotes tumor growth

Gastric cancer (GC) is one of the most common cancers worldwide, with increasing incidence and mortality rates. It is typically diagnosed at advanced stages, leading to a poor prognosis. GC is a highly heterogeneous disease and its progression is associated with complex interplay between genetic and environmental factors. Identifying novel genes and pathways involved in GC development is crucial for improving the therapeutic outcome. Regulator of Telomerase Length 1 (RTEL1) has been found to maintain telomere stability through its helicase activity, facilitating telomere reconstruction and repair. However, the precise role of RTEL1 in human cancers, particularly in GC, is not yet fully understood. In this study, we observed significantly increased RTEL1 expression in GC tissues, which was associated with a poor prognosis. Functionally, RTEL1 promotes GC cell proliferation both in vitro and in vivo. Additionally, RTEL1 appears to regulate multiple signaling pathways, with a particular promoting effect on the cell cycle progression. Notably, CDC23 and TRIP13 are potential downstream target genes of RTEL1, which may mediate its tumor-promoting effects in GC. These findings suggest that RTEL1 plays a critical role in GC tumorigenesis and could be a promising target for the therapy and prognosis of GC.

Prokaryotic expression and helicase activity analysis of PDCoV NSP13

Porcine deltacoronavirus (PDCoV) is a major pathogen causing fatal diarrhea in suckling piglets, and there is currently a lack of effective vaccines and drugs to prevent and control the virus. The nonstructural protein 13 (NSP13) serves as a virus-coded helicase and is considered to be a crucial target for antiviral drugs, making it imperative to investigate the helicase activity of NSP13. In this study, the NSP13 gene of PDCoV was synthesized and integrated into the prokaryotic expression vector pET-28a to construct the recombinant plasmid pET-28a-NSP13. NSP13 was successfully expressed in BL21 (DE3) and subsequently purified. The study also verified the helicase activity of the purified NSP13 and explored the factors that influence this activity. The results indicated that NSP13 from PDCoV was effectively expressed in the prokaryotic system and exhibited helicase activity, capable of unwinding double-stranded DNA with a tail at the 5' end. Additionally, NSP13 demonstrated an annealing function by promoting the complementary pairing of single-stranded nucleotide chains to form double strands. The helicase activity of NSP13 was affected by metal ions, but Mg2+concentrations in the range of 0.5-6.0 mmol/L had no significant effect on helicase activity of NSP13. When the solution pH was in the range of 4-9, there was no difference in helicase activity. ATP concentrations in the range of 0.25-6.00 mmol/L had a weak effect on helicase activity, and NSP13 concentration ≥80 nmol/L inhibited the helicase activity. We obtained the NSP13 of PDCoV and investigated its helicase activity. These findings provided a theoretical foundation for the further research on the regulatory mechanism of NSP13 in PDCoV replication and the development of anti-coronaviral drugs.

Identification of a novel nuclease activity in human DDX49 helicase.

Human DDX49 is an emerging target in cancer progression and retroviral diseases through its essential roles in nucleolar RNA processing. Here, we identify nuclease activity of human DDX49, which requires active site aspartate residues within a conserved region of metazoan DDX49s that is absent from yeast and archaeal DDX49 homologues. We provide evidence that DDX49 nuclease activity is facilitated by its helicase activity. Using CRISPR-Cas9 genetic editing, we show that a heterozygous (DDX49 +/-) U2OS cell line is defective at cell migration, a phenotype supporting the association of DDX49 with cancer cell invasiveness. Measurement of RNAs in DDX49 +/- indicates that DDX49 is required to sustain levels of 5.8S rRNA.

A Potent, Selective, Small-Molecule Inhibitor of DHX9 Abrogates Proliferation of Microsatellite Instable Cancers with Deficient Mismatch Repair.

DHX9 is a multifunctional DExH-box RNA helicase with important roles in the regulation of transcription, translation, and maintenance of genome stability. Elevated expression of DHX9 is evident in multiple cancer types, including colorectal cancer (CRC). Microsatellite instable-high (MSI-H) tumors with deficient mismatch repair (dMMR) display a strong dependence on DHX9, making this helicase an attractive target for oncology drug discovery. In this report, we show that DHX9 knockdown increased RNA/DNA secondary structures and replication stress, resulting in cell cycle arrest and the onset of apoptosis in cancer cells with MSI-H/dMMR. ATX968 was identified as a potent and selective inhibitor of DHX9 helicase activity. Chemical inhibition of DHX9 enzymatic activity elicited similar selective effects on cell proliferation as seen with genetic knockdown. In addition, ATX968 induced robust and durable responses in an MSI-H/dMMR xenograft model but not in a microsatellite stable (MSS)/proficient mismatch repair (pMMR) model. These preclinical data validate DHX9 as a target for the treatment of patients with MSI-H/dMMR. Additionally, this potent and selective inhibitor of DHX9 provides a valuable tool with which to further explore the effects of inhibition of DHX9 enzymatic activity on the proliferation of cancer cells in vitro and in vivo.

Abstract A011: Binding of the exon junction complex shapes the landscape of m6A in RNA - a possible source of m6A dysregulation in cancer

Abstract N6-methyladenosine (m6A) is the most prevalent modification in eukaryotic mRNA. Increasing evidence shows that m6A is involved in the biological functions of cancer cells, including proliferation, invasion, metastasis, and drug resistance. Dysregulation of m6A deposition and its associated machinery, including writers, erasers and readers, is observed in multiple cancer types, and the dysregulation profiles have potential as diagnostic, prognostic and/or predictive biomarkers. In healthy cells, m6A modifications are installed co-transcriptionally by the writer enzyme METTL3, resulting in an enrichment of m6A in the 3’UTR of genes. For many years, the mechanistic origin for the m6A enrichment in the 3’UTR was unclear. Recently, the Gregory lab and others have developed a model where the exon junction complex (EJC) plays a key role in directing m6A deposition by hindering access of METTL3 to short exons and exon/intron junctions. In this study, we build on this model using a novel, proximity-barcoding based assay (EpiPlex™) for the simultaneous detection of m6A and inosine. Working with HEK293T cells, we modulated the activity of a central component of the EJC, the RNA helicase EIF4A3. Both genetic knockdown and chemical inhibition of EIF4A3 resulted in increased m6A levels and more diffuse localization at the 3’UTR. New m6A sites appear on short exons and near exon/intron junctions. These data corroborate the necessity of EIF4A3 for EJC assembly and confirm the model that the EJC prevents METTL3 from accessing and methylating exon junctions. Additionally, we find that blocking of the exon junction is reliant on EIF4A3’s helicase activity. Although the role of EJC in the cell cycle and cancer are still investigational, it is likely that m6A dysregulation is induced by aberrant EJC function, which presents a potential molecular mechanism for the dysregulation of multiple genetic pathways in cancer progression. Citation Format: Andrew Price, Erdem Sendinc, Byron Purse, Richard I Gregory, Gudrun Stengel. Binding of the exon junction complex shapes the landscape of m6A in RNA - a possible source of m6A dysregulation in cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr A011.

Abstract 4141486: Site-Specific Transcriptomic Patterns and Cell Types Associated with Hypertension

Introduction: The biology of early human hypertensive heart disease (HHD) is largely unexplored due to limited cardiac tissue access. Site-specific transcriptomics of human cardiac tissue before development of overt HHD offers a unique vantage to understand the biology of HHD in human cardiac tissue. Hypothesis: We hypothesize that transcriptomic signatures and cell subtype proportions differ in human heart tissue from HTN donors compared to normotensive (NTN) donors in a site-specific manner. Methods: We performed bulk RNA-seq on rRNA-depleted libraries from left (LV) and right (RV) mid-ventricular-wall tissue (average depth 114 million reads/sample) collected postmortem from HTN (n=3, 67% Black/Latinx) and NTN (n=2, 50% Black/Latinx) donors. We performed single-nucleus RNA-seq (snRNA-Seq) on cardiac tissue from the same donors (average of 4,062 LV nuclei). Differential gene expression, lineage identification, and Gene Set Enrichment Analysis (GSEA) were performed with publicly available software. Results: All donors were female with matched postmortem intervals (time from death to tissue preservation; HTN 19±9 hours, NTN 18±6 hours). HTN donors were older (65±7 years) than NTN donors (36±16 years). A total of 416 genes were associated with HTN (Wald test, FDR q <0.05) across both ventricles (correcting for site). When tested separately, 72 (LV) or 83 (RV) genes were associated with HTN (FDR q <0.05), with 13 common genes, indicating site-specific differences. GSEA of genes ranked by Wald statistic computed across both ventricles showed that transcripts involved in single-stranded DNA helicase activity, branched-chain amino acid catabolism, and NAD-dependent deacetylase activity were coordinately associated with HTN (FDR q <0.05). snRNA-seq revealed 9 cell types in these samples, including immune cells and chamber-specific cardiomyocytes (CMs) with higher proportions of LV CMs and lymphocytes associated with HTN compared to NTN. MYH6 and MYL7 expression was unchanged with respect to HTN by RNA-seq but lower in LV HTN CMs compared to NTN by snRNA-seq, suggesting dysregulation of contractile programming in HTN LV CMs. Conclusion: HTN is associated with altered cardiomyocyte/lymphocyte ratios, and site-specific differential expression of cardiac contractile elements. Further study is required to validate these findings with additional samples and elucidate mechanisms driving transcriptional program differences in the hypertensive human heart.

Role of SIRPG gene in type 1 diabetes and lichen planus.

Type 1 diabetes (T1D) is a form of diabetes caused by pancreatic β-cell destruction and absolute insulin deficiency. Lichen planus (LP) is an idiopathic inflammatory skin disease of unclear etiology. The role of SIRPG gene dysregulation in T1D and LP remains unclear. Mendelian randomization (MR) using matched samples was employed to study causal relationship between T1D and increased risk of LP. T1D-related single nucleotide polymorphism identification was conducted. Datasets GSE156035 for T1D and GSE52130 for LP were obtained from gene expression omnibus. Differentially expressed genes were identified, analyses included weighted gene co-expression network analysis, functional enrichment, gene set enrichment analysis, and protein-protein interaction network construction and analysis. Heatmaps of gene expression levels were generated. Comparative toxicogenomics database was used to identify diseases most relevant to core genes. Inverse variance weighted, MR-Egger, weighted median methods estimated genetic predisposition between T1D and LP, showing consistent positive correlations using both weighted median and inverse variance weighted methods. Horizontal pleiotropy analysis with MR-Egger intercept indicated no evidence of significant directional pleiotropy (P = .70645) for LP. There was no evidence of directional pleiotropy effects between T1D and LP. One hundred eighteen differentially expressed genes were identified. In biological processes, they were mainly enriched in apoptosis, inflammatory response, insulin receptor signaling pathway, glucose metabolism. In cellular components, enrichment was observed in mediator complex and replication fork. In molecular function, they were concentrated in leukotriene receptor activity and helicase activity. Kyoto Encyclopedia of Genes and Genomes analysis revealed enrichment in metabolic pathways, PI3K-Akt signaling pathway, cell cycle, p53 signaling pathway, AGE-RAGE signaling pathway in diabetic complications. Weighted gene co-expression network analysis with a soft threshold power of 4. SIRPG showing high expression in both T1D and LP samples. There is a positive causal relationship between T1D and LP. Comparative toxicogenomics database analysis revealed associations of core genes with metabolic syndrome, lipid metabolism disorders, cardiovascular diseases, immune system diseases, peripheral neuropathic pain, and inflammation. SIRPG is highly expressed in both T1D and LP, providing a new insight into the pathogenesis of T1D and LP.

Contribution of ERCC2 rs13181 (Lys751Gln) and rs1799793 (Asp312Asn) polymorphisms to the risk of bladder cancer in Bangladesh

BackgroundHuman Excision Repair Cross-Complementation Group 2 (ERCC2) proteins play a vital role in the nucleotide excision repair pathway through ATP-dependent helicase activity. Several studies found that polymorphisms in the ERCC2 gene are associated with susceptibility to different cancers, although the outcomes were confusing. ObjectiveAs a result, in this retrospective study, we investigated the relationship between genetic polymorphisms of the ERCC2 gene at codons 312 (rs1799793) and 751 (rs13181) and bladder cancer susceptibility in Bangladesh, as well as the disease's aggressiveness. MethodsGenetic polymorphisms of ERCC2 were assayed by the polymerase chain reaction-based restriction fragment length polymorphism (PCR-RFLP) method with 121 bladder cancer patients and 130 healthy controls. ResultsPatients who had the Gln/Gln polymorphism of ERCC2 at codon 751 (OR=3.27; 95% CI=1.19-8.67; p<0.05) and Asp/Asn at codon 312 (OR=2.14; 95% CI=1.03-4.29; p<0.05) were significantly associated with a higher risk of developing bladder cancer. Again, Gln/Gln polymorphisms in bladder cancer (p<0.05) were more likely to be present in individuals with cancer in the family. ConclusionsThis study reveals that susceptibility and bladder cancer aggressiveness are associated with polymorphisms at codon 751 and Asp/Asn at codon 312 of the ERCC2 gene.

Genome integrity sensing by the broad-spectrum Hachiman antiphage defense complex.

Hachiman is a broad-spectrum antiphage defense system of unknown function. We show here that Hachiman is a heterodimeric nuclease-helicase complex, HamAB. HamA, previously a protein of unknown function, is the effector nuclease. HamB is the sensor helicase. HamB constrains HamA activity during surveillance of intact double-stranded DNA (dsDNA). When the HamAB complex detects DNA damage, HamB helicase activity activates HamA, unleashing nuclease activity. Hachiman activation degrades all DNA in the cell, creating "phantom" cells devoid of both phage and host DNA. We demonstrate Hachiman activation in the absence of phage by treatment with DNA-damaging agents, suggesting that Hachiman responds to aberrant DNA states. Phylogenetic similarities between the Hachiman helicase and enzymes from eukaryotes and archaea suggest deep functional symmetries with other important helicases across domains of life.

Investigating the Activities of CAF20 and ECM32 in the Regulation of PGM2 mRNA Translation.

Translation is a fundamental process in biology, and understanding its mechanisms is crucial to comprehending cellular functions and diseases. The regulation of this process is closely linked to the structure of mRNA, as these regions prove vital to modulating translation efficiency and control. Thus, identifying and investigating these fundamental factors that influence the processing and unwinding of structured mRNAs would be of interest due to the widespread impact in various fields of biology. To this end, we employed a computational approach and identified genes that may be involved in the translation of structured mRNAs. The approach is based on the enrichment of interactions and co-expression of genes with those that are known to influence translation and helicase activity. The in silico prediction found CAF20 and ECM32 to be highly ranked candidates that may play a role in unwinding mRNA. The activities of neither CAF20 nor ECM32 have previously been linked to the translation of PGM2 mRNA or other structured mRNAs. Our follow-up investigations with these two genes provided evidence of their participation in the translation of PGM2 mRNA and several other synthetic structured mRNAs.

Structure-based discovery of first inhibitors targeting the helicase activity of human PIF1.

PIF1 is a conserved helicase and G4 DNA binding and unwinding enzyme, with roles in genome stability. Human PIF1 (hPIF1) is poorly understood, but its functions can become critical for tumour cell survival during oncogene-driven replication stress. Here we report the discovery, via an X-ray crystallographic fragment screen (XChem), of hPIF1 DNA binding and unwinding inhibitors. A structure was obtained with a 4-phenylthiazol-2-amine fragment bound in a pocket between helicase domains 2A and 2B, with additional contacts to Valine 258 from domain 1A. The compound makes specific interactions, notably through Leucine 548 and Alanine 551, that constrain conformational adjustments between domains 2A and 2B, previously linked to ATP hydrolysis and DNA unwinding. We next synthesized a range of related compounds and characterized their effects on hPIF1 DNA-binding and helicase activity in vitro, expanding the structure activity relationship (SAR) around the initial hit. A systematic analysis of clinical cancer databases is also presented here, supporting the notion that hPIF1 upregulation may represent a specific cancer cell vulnerability. The research demonstrates that hPIF1 is a tractable target through 4-phenylthiazol-2-amine derivatives as inhibitors of its helicase action, setting a foundation for creation of a novel class of anti-cancer therapeutics.

NAT10 resolves harmful nucleolar R-loops depending on its helicase domain and acetylation of DDX21

BackgroundAberrant accumulation of R-loops leads to DNA damage, genome instability and even cell death. Therefore, the timely removal of harmful R-loops is essential for the maintenance of genome integrity. Nucleolar R-loops occupy up to 50% of cellular R-loops due to the frequent activation of Pol I transcription. However, the mechanisms involved in the nucleolar R-loop resolution remain elusive. The nucleolar acetyltransferase NAT10 harbors a putative RecD helicase domain (RHD), however, if NAT10 acts in the R-loop resolution is still unknown.MethodsNAT10 knockdown cell lines were constructed using CRISPR/Cas9 technology and short hairpin RNA targeting NAT10 mRNA, respectively. The level of R-loops was detected by immunofluorescent staining combined with RNase H treatment. The helicase activity of NAT10 or DDX21 was determined by in vitro helicase experiment. The interaction between NAT10 and DDX21 was verified by co-immunoprecipitation, immunofluorescent staining and GST pull-down experiments. Acetylation sites of DDX21 by NAT10 were analyzed by mass spectrometry. NAT10 knockdown-induced DNA damage was evaluated by immunofluorescent staining and Western blot detecting γH2AX.ResultsDepletion of NAT10 led to the accumulation of nucleolar R-loops. NAT10 resolves R-loops through an RHD in vitro and in cells. However, Flag-NAT10 ∆RHD mutant still partially reduced R-loop levels in the NAT10-depleted cells, suggesting that NAT10 might resolve R-loops through additional pathways. Further, the acetyltransferase activity of NAT10 is required for the nucleolar R-loop resolution. NAT10 acetylates DDX21 at K236 and K573 to enhance the helicase activity of DDX21 to unwind nucleolar R-loops. The helicase activity of DDX21 significantly decreased by Flag-DDX21 2KR and increased by Flag-DDX21 2KQ in cells and in vitro. Consequently, NAT10 depletion-induced nucleolar R-loop accumulation led to DNA damage, which was rescued by co-expression of Flag-DDX21 2KQ and Flag-NAT10 G641E, demonstrating that NAT10 resolves nucleolar R-loops through bipartite pathways.ConclusionWe demonstrate that NAT10 is a novel R-loop resolvase and it resolves nucleolar R-loops depending on its helicase activity and acetylation of DDX21. The cooperation of NAT10 and DDX21 provides comprehensive insights into the nucleolar R-loop resolution for maintaining genome stability.