Pole Research Articles

Collapsed State Mediates the Low Fidelity of the DNA Polymerase β I260 Mutant.

DNA polymerase β (Pol β) fills single nucleotide gaps during base excision repair. Deficiencies in Pol β can lead to increased mutagenesis and genomic instability in the cell, resulting in cancer. Our laboratory has previously shown that the I260 M somatic mutation of Pol β, which was first identified in prostate cancer, has reduced nucleotide discrimination in a sequence context-dependent manner. I260 M incorporates the incorrect G opposite A in this context more readily than WT. To identify the molecular mechanism of the reduced fidelity of I260M, we studied incorporation using single turnover kinetics and the nature and rates of conformational changes using steady-state fluorescence and Förster resonance energy transfer (FRET). Our data indicate that the I260 M mutation affects the fingers region of rat Pol β by creating a "collapsed" state in both the open (in the absence of nucleotide) and closed (prior to chemistry) states. I260 M is a temperature-sensitive mutator and binds nucleotides tighter than the WT protein, resulting in reduced fidelity compared to the WT. Additionally, we have generated a kinetic model of WT and I260 M using FRET and single turnover data, which demonstrates that I260 M precatalytic conformation changes differ compared to the WT as it is missing a precatalytic noncovalent step. Taken together, these results suggest that the collapsed state of I260 M may decrease its ability for nucleotide discrimination, illustrating the importance of the "fingers closing" conformational change for polymerase fidelity and accurate DNA synthesis.

DNA polymerase mediated CRISPR/Cas12a trans-cleavage for dual-mode quantification of uracil DNA glycosylase activity

Since an unusual expression of uracil-DNA glycosylase (UDG) is often associated with the pathogenesis of numerous disorders, the detection of UDG activity is regarded as a promising application in disease diagnosis. Here, we develop a DNA polymerase-mediated CRISPR/Cas12a trans cleavage strategy, which can achieve dual-mode determination of UDG activity. By introducing a hairpin DNA probe containing a single uracil base, the probe undergoes specific cleavage and elongation under the existence of UDG only, thus activating the trans cleavage of ssDNA regardless of its length and sequence. To accommodate different detection modes, the ssDNA was further modified by fluorophore-quencher pairs or designed for connecting magnetic microparticles (MMPs) and polystyrene microparticles (PMPs). Finally, the UDG activity is quantified by fluorescence signal and microparticle accumulation length on a microfluidic chip visible to the naked eye. This strategy provides a detectable minimum UDG concentration of 0.00047 U/mL for fluorescent mode and 0.0048 U/mL for microfluidic mode. Furthermore, we performed the UDG inhibition test and detected UDG activity in cell lysates, suggesting its potential for inhibitor screening and detection of UDG in biological samples.

139 (PB127): ART6043: a first-in-class clinical DNA Polymerase Theta polymerase domain inhibitor for potentiating PARP inhibitor efficacy

139 (PB127): ART6043: a first-in-class clinical DNA Polymerase Theta polymerase domain inhibitor for potentiating PARP inhibitor efficacy

Inhibiting KSHV replication by targeting the essential activities of KSHV processivity protein, PF-8.

Kaposi's Sarcoma Herpesvirus (KSHV) is the causative agent of several human diseases. There are no cures for KSHV infection. KSHV establishes biphasic lifelong infections. During the lytic phase, new genomes are replicated by seven viral DNA replication proteins. The processivity factor's (PF-8) functions to tether DNA polymerase to DNA, so new viral genomes are efficiently synthesized. PF-8 self-associates, interacts with KSHV DNA replication proteins and the viral DNA. Inhibition of viral DNA replication would diminish the infection within a host and reduce transmission to new individuals. In this review we summarize PF-8 molecular and structural studies, detail the essential protein-protein and nucleic acid interactions needed for efficient lytic DNA replication, identify future areas for investigation and propose PF-8 as a promising antiviral target. Additionally, we discuss similarities that the processivity factor from Epstein-Barr virus shares with PF-8, which could promote a pan-herpesvirus antiviral therapeutic targeting strategy.

339 (PB327): Discovery and characterisation of DNA polymerase theta inhibitors for the treatment of cancer

339 (PB327): Discovery and characterisation of DNA polymerase theta inhibitors for the treatment of cancer

Discovery of the first sea turtle adenovirus and turtle associated circoviruses

Turtles are an evolutionarily unique and morphologically distinctive order of reptiles, and many species are globally endangered. Although a high diversity of adenoviruses in scaled reptiles is well-documented, turtle adenoviruses remain largely understudied. To investigate their molecular diversity, we focused on the identification and characterisation of adenoviruses in turtle-derived organ, swab and egg samples. Since reptile circoviruses have been scarcely reported and no turtle circoviruses have been documented to date, we also screened our samples for circoviruses. Host−virus coevolution is a common feature of these viral families, so we aimed to investigate possible signs of this as well. Two screening projects were conducted: one on Brazilian samples collected from animals in their natural habitat, and the other on Hungarian pet shop samples. Nested PCR systems were used for the detection of adeno- and circoviruses and purified PCR products were Sanger sequenced. Phylogenetic trees for the viruses were reconstructed based on the adenoviral DNA polymerase and hexon genes, circoviral Rep genes, and for the turtle hosts based on mitochondrial cytochrome b amino acid sequences. During the screening, testadeno-, siadeno-, and circovirus strains were detected. The circovirus strains were classified into the genus Circovirus, exhibiting significant evolutionary divergence but forming a monophyletic clade within a group of fish circoviruses. The phylogenetic tree of turtles reflected their taxonomic relationships, showing a deep bifurcation between suborders and distinct monophyletic clades corresponding to families. A similar clustering pattern was observed among the testadenovirus strains in their phylogenetic tree. As a result, this screening of turtle samples revealed at least three new testadenoviruses, including the first sea turtle adenovirus, evidence of coevolution between testadenoviruses and their hosts, and the first turtle associated circoviruses. These findings underscore the need for further research on viruses in turtles, and more broadly in reptiles, to better understand their viral diversity and the evolutionary processes shaping host–virus interactions.

Cryo-EM Structures of the Plasmodium falciparum Apicoplast DNA Polymerase

The apicoplast DNA polymerase (apPol) from Plasmodium falciparum is essential for the parasite’s survival, making it a prime target for antimalarial therapies. Here, we present cryo-electron microscopy structures of the apPol in complex with DNA and incoming nucleotide, offering insights into its molecular mechanisms. Our structural analysis reveals that apPol contains critical residues for high-fidelity DNA synthesis, but lacks certain structural elements to confer processive DNA synthesis during replication, suggesting the presence of additional accessory factors. The enzyme exhibits large-scale conformational changes transitioning upon DNA and nucleotide binding, particularly within the fingers and thumb subdomains. These movements reveal potential allosteric sites that could serve as targets for drug design. Our findings provide a foundation for advancing the understanding of apPol’s unique functional mechanisms and potentially offering new avenues for the development of novel inhibitors and therapeutic interventions against malaria.

Dynamics and Evolution of Donor-derived Cytomegalovirus Infection in 3 Solid Organ Transplant Recipients With the Same Multiorgan Donor.

Cytomegalovirus (CMV) infection poses a significant risk to immunosuppressed transplant recipients, manifesting through primary infection, reinfection, or reactivation. We analyzed the emergence of drug resistance in CMV infection in 3 patients who were later found to have received an allograft from a shared, deceased donor. The seronegative transplant recipients developed symptomatic CMV infections after bowel/pancreas, kidney, or lung transplantation. Prospective Sanger sequencing was used to identify mutations in the viral DNA polymerase (DP) and protein kinase (PK). DP and PK variants were retrospectively quantified by targeted next-generation sequencing. The impact of the novel DP-A505G substitution on drug susceptibility was assessed using a recombinant virus. Whole-genome sequencing of clinical CMV samples was enabled through target DNA enrichment. The DP-A505G substitution was found in all patient samples and could be associated with a natural polymorphism. A subsequent review of the patients' clinical histories revealed that they had all received organs from a single donor. The CMV infection exhibited divergent evolution among the patients: patient 1 developed resistance to ganciclovir and foscarnet because of 2 DP mutations (V715M and V781I), patient 2 showed no genotypic resistance, and patient 3 developed ganciclovir (PK-L595S) and maribavir resistance (PK-T409M). Interpatient variation across the entire CMV genome was minimal, with viral samples clustering in phylogenetic analysis. All 3 transplant recipients were infected with the same donor-derived CMV strain and readily developed different drug susceptibility profiles. This underscores the importance of judicious antiviral drug use and surveillance in preventing antiviral resistance emergence.

DNA polymerase ζ is a robust reverse transcriptase.

Cell biology and genetic studies have demonstrated that DNA double strand break (DSB) repair can be performed using an RNA transcript that spans the site of the DNA break as a template for repair. This type of DSB repair requires a reverse transcriptase to convert an RNA sequence into DNA to facilitate repair of the break, rather than copying from a DNA template as in canonical DSB repair. Translesion synthesis (TLS) DNA polymerases (Pol) are often more promiscuous than DNA Pols, raising the notion that reverse transcription could be performed by a TLS Pol. Indeed, several studies have demonstrated that human Pol η has reverse transcriptase activity, while others have suggested that the yeast TLS Pol ζ is involved. Here, we purify all seven known nuclear DNA Pols of Saccharomyces cerevisiae and compare their reverse transcriptase activities. The comparison shows that Pol ζ far surpasses Pol η and all other DNA Pols in reverse transcriptase activity. We find that Pol ζ reverse transcriptase activity is not affected by RPA or RFC/PCNA and acts distributively to make DNA complementary to an RNA template strand. Consistent with prior S. cerevisiae studies performed in vivo, we propose that Pol ζ is the major DNA Pol that functions in the RNA templated DSB repair pathway.

From RNA to DNA: Emergence of reverse transcriptases from an ancestral RNA-dependent RNA polymerase

The transition from RNA as the informational molecule of primordial biological systems to the DNA genomes of modern organisms represents one of the greatest evolutionary transitions in the history of life. One way to understand this transition is to comprehend the origin of the enzymes responsible for the metabolism of nucleic acid polymers. In the present work, we reconstructed the ancestral sequence of RNA-dependent DNA polymerase (RdDp) and modeled its structure. The data demonstrate that, in terms of primary sequence, the ancestral sequences exhibit characteristic elements of RdDp; however, structurally, they are more similar to RNA-dependent RNA polymerase (RdRp). The presented data suggest that RdDp may have originated through modifications and neofunctionalization from an RdRp-like ancestor.

Canonical and Non-Canonical Roles of Human DNA Polymerase η.

DNA damage tolerance pathways that allow for the completion of replication following fork arrest are critical in maintaining genome stability during cell division. The main DNA damage tolerance pathways include strand switching, replication fork reversal and translesion synthesis (TLS). The TLS pathway is mediated by specialised DNA polymerases that can accommodate altered DNA structures during DNA synthesis, and are important in allowing replication to proceed after fork arrest, preventing fork collapse that can generate more deleterious double-strand breaks in the genome. TLS may occur directly at the fork, or at gaps remaining behind the fork, in the process of post-replication repair. Inactivating mutations in the human POLH gene encoding the Y-family DNA polymerase Pol η causes the skin cancer-prone genetic disease xeroderma pigmentosum variant (XPV). Pol η also contributes to chemoresistance during cancer treatment by bypassing DNA lesions induced by anti-cancer drugs including cisplatin. We review the current understanding of the canonical role of Pol η in translesion synthesis following replication arrest, as well as a number of emerging non-canonical roles of the protein in other aspects of DNA metabolism.

Single-Molecule Real-Time Visualization of DNA Unwinding by CMG Helicase.

Faithful genome duplication is essential for preserving the genetic stability of dividing cells. DNA replication is carried out during the S phase by a dynamic complex of proteins termed the replisome. At the heart of the replisome is theCDC45-MCM2-7-GINS (CMG) helicase, which separates the two strands of the DNA double helix such that DNA polymerases can copy each strand. During genome duplication, replisomes must overcome a plethora of obstacles and challenges. Each of these threatens genome stability, as failure to replicate DNA completely and accurately can lead to mutations, diseases, or cell death. Therefore, it is of great interest to understand how CMG functions in the replisome during both normal replication and replication stress. Here, we describe a total internal reflection fluorescence (TIRF) microscopy assay using recombinant purified proteins, which allows for real-time visualization of surface-tethered stretched DNA molecules by individual CMG complexes. This assay provides a powerful platform to investigate CMG behavior at the single-molecule level, allowing helicase dynamics to be directly observed with real-time control over reaction conditions.

Promising Drug Delivery System for Cervical Cancer – A Future Approach

There is evidence that peptide targeting can be applied in cervical cancer therapy and for diagnosis involving the use of molecular imaging, hence developing peptide probes for this disease. Cervical cancer, which also has a high possibility of being prevented, is among the common tumors affecting women globally. Despite the occurrence being reduced greatly by screening, the illness remains fatal and its claims many lives annually, especially in the developing nations. In exercising such a perspective, specific public health efforts known to encourage physical activity, proper diet, and early detection of cervical cancer must begin to be taken seriously. When combined, doctors, health officers, and lawmakers could speed up the global deployment of such programs. California’s American Cancer Society, the present review enlists a host of pharmaceutical goods available in the market. This perspective of present-day research and manufacturing is devoted to the development of various types of nanocarriers for possible utilization in medication transport. Thus, overall cancer mortality appears to be not substantially different, though cancer incidence rates for both sexes are 50% lower in impoverished countries when compared to affluent nations. At the moment, there are new peptide probes that are developed solely for cervical cancer-perfectly suitable for targeting peptides applicable in therapeutic and diagnostic imaging. M13KE phage dodecapeptide (12-mer) peptide library was screened for recognition of human immunodeficiency virus type 1 (HIV-1) by immunofluorescence and flow cytometry; the S7 clone was identified as most suitable. A disease that affects many women is gynecologic health problems, and cervical cancer is the leading presenting complaint experienced regularly. Among these studies, QSAR, drug-likeness, PCA, dynamic cross-correlation matrix, molecular docking, molecular dynamics and quantum calculation properties can be listed. In the first literature survey, after identifying the potent antibacterial and anticancer activity of the molecule apigenin, some other promising derivatives were identified and more research has been carried out on them, focusing on their synthesized derivatives as inhibitors of DNA polymerase theta and cervical cancer caused by human papillomavirus. The results were streamlined by the use of in-silico molecular docking, which showed that all Apigenin derivatives and the targeted proteins had potential energy-binding relationships. Further validation is essential because this study used in-silico computational methodologies and produced excellent results. Applying in-silico molecular docking made the data more comprehensible, which showed the possible energy bindings of the targeted proteins and all the Apigenin variants. Due to the fact that this work utilized in-silico computational methods and obtained significant results, further validation is required. Hence, the present wet-lab experiments coupled with both in-vitro and in-vivo conditions, additional validation of the results.

Highly sensitive detection of RNase H via a novel DNA/RNA heteroduplex combining isothermal exponential amplification strategy

Ribonuclease H (RNase H) plays a crucial role in a variety of cellular processes and is emerging as an essential therapeutic target for many diseases. Various methods have been constructed to assay RNase H activity, but these methods are either time-consuming or have poor sensitivity. In this study, we developed a novel strategy that combined a specially designed DNA/RNA chimeric substrate with exponential amplification reaction (EXPAR) for rapid and sensitive detection of RNase H activity. In the presence of RNase H, the RNA strand of the DNA/RNA heteroduplex was specifically degraded, forming a 3′-hydroxyl group in the locking primer for recognition and extension by DNA polymerase. This ultimately triggered EXPAR and produced a large number of single-stranded DNA, which was monitored in real-time with fluorescent dye. Under optimized conditions, the proposed strategy can detect as low as 6 × 10−10 U/μL of RNase H, which was at least 1000 times more sensitive than several reported methods. Furthermore, we demonstrated the usage of this method for RNase H inhibitor analysis and practical application in complex biological samples, including serum and tumor cell extracts. Therefore, these results suggested that the developed method is a promising tool for highly sensitive detection of RNase H and RNase H-associated disease diagnosis.

Rapid genome-wide profiling of DNA methylation and genetic variation using guide positioning sequencing (GPS).

Whole-genome bisulfite sequencing (WGBS) has been extensively utilized for DNA methylation profiling over the past decade. However, it has shown limitations in terms of high costs and inefficiencies. The productivity and accuracy of DNA methylation detection rely critically on the optimization of methodologies and the continuous refinements of related sequencing platforms. Here, we describe a detailed protocol of guide positioning sequencing (GPS), a bisulfite-based, location-specific sequencing technology designed for comprehensive DNA methylation characterization across the genome. The fundamental principle of GPS lies in the substitution of dCTP with 5-methyl-dCTP (5mC) at the 3'-end of DNA fragments by T4 DNA polymerase, which protects cytosines from bisulfite conversion to preserve the integrity of the base composition. This alteration allows the 3'-end to independently facilitate genetic variation profiling and guides the 5'-end, enriched with methylation information, to align more rapidly to the reference genome. Hence, GPS enables the concurrent detection of both genetic and epigenetic variations. Additionally, we provide an accessible description of the data processing, specifically involving certain software and scripts. Overall, the entire GPS procedure can be completed within a maximum of 15days, starting with a low initial DNA input of 100-500ng, followed by 4-5days for library construction, 8-10days for high-throughput sequencing (HTS) and data analysis, which can greatly facilitate the promotion and application of DNA methylation detection, especially for the rapid clinical diagnosis of diverse disease pathologies associated with concurrent genetic and epigenetic variations.

Evidence that DNA polymerase δ proofreads errors made by DNA polymerase α across the Saccharomyces cerevisiae nuclear genome

We show that the rates of single base substitutions, additions, and deletions across the nuclear genome are strongly increased in a strain harboring a mutator variant of DNA polymerase α combined with a mutation that inactivates the 3´-5´ exonuclease activity of DNA polymerase δ. Moreover, tetrad dissections attempting to produce a haploid triple mutant lacking Msh6, which is essential for DNA mismatch repair (MMR) of base•base mismatches made during replication, result in tiny colonies that grow very slowly and appear to be aneuploid and/or defective in oxidative metabolism. These observations are consistent with the hypothesis that during initiation of nuclear DNA replication, single-base mismatches made by naturally exonuclease-deficient DNA polymerase α are extrinsically proofread by DNA polymerase δ, such that in the absence of this proofreading, the mutation rate is strongly elevated. Several implications of these data are discussed, including that the mutational signature of defective extrinsic proofreading in yeast could appear in human tumors.

Development and validation of a quantitative PCR assay for detection of Sulawesi tortoise adenovirus

In 2007, a mortality event involving over 100 Sulawesi tortoises (Indotestudo forsteni), two Impressed tortoises (Manouria impress) and a critically endangered Burmese star tortoise (Geochelone platynota) was attributed to Sulawesi tortoise adenovirus (STADV; genus Siadenovirus). We developed a TaqMan quantitative PCR assay targeting the DNA polymerase gene of STADV for use in clinical diagnosis and epidemiologic surveillance. This assay failed to amplify five closely-related chelonian adenoviruses, indicating high analytical specificity. The assay performed with high efficiency (slope = −3.337; R2 = 0.999) and high inter- and intra-assay repeatability (coefficient of variation <1.36 % at all standard curve dilutions). Dynamic range included 1.00 × 107 to 1.00 × 101 target copies per reaction and limit of detection was 101 target copies per reaction, though 100 target copies per reaction were intermittently detected. This qPCR assay provides a valuable diagnostic tool for characterization of STADV epidemiology, including potential identification of the North American reservoir host.

Modulating DNA Polα Enhances Cell Reprogramming Across Species.

As a fundamental biological process, DNA replication ensures the accurate copying of genetic information. However, the impact of this process on cellular plasticity in multicellular organisms remains elusive. Here, we find that reducing the level or activity of a replication component, DNA Polymerase α (Polα), facilitates cell reprogramming in diverse stem cell systems across species. In Drosophila male and female germline stem cell lineages, reducing Polα levels using heterozygotes significantly enhances fertility of both sexes, promoting reproductivity during aging without compromising their longevity. Consistently, in C. elegans the pola heterozygous hermaphrodites exhibit increased fertility without a reduction in lifespan, suggesting that this phenomenon is conserved. Moreover, in male germline and female intestinal stem cell lineages of Drosophila, polα heterozygotes exhibit increased resistance to tissue damage caused by genetic ablation or pathogen infection, leading to enhanced regeneration and improved survival during post-injury recovery, respectively. Additionally, fine tuning of an inhibitor to modulate Polα activity significantly enhances the efficiency of reprogramming human embryonic fibroblasts into induced pluripotent cells. Together, these findings unveil novel roles of a DNA replication component in regulating cellular reprogramming potential, and thus hold promise for promoting tissue health, facilitating post-injury rehabilitation, and enhancing healthspan.

A Massively Parallel In Vivo Assay of TdT Mutants Yields Variants with Altered Nucleotide Insertion Biases.

Terminal deoxynucleotidyl transferase (TdT) is a unique DNA polymerase capable of template-independent extension of DNA. TdT's de novo DNA synthesis ability has found utility in DNA recording, DNA data storage, oligonucleotide synthesis, and nucleic acid labeling, but TdT's intrinsic nucleotide biases limit its versatility in such applications. Here, we describe a multiplexed assay for profiling and engineering the bias and overall activity of TdT variants with high throughput. In our assay, a library of TdTs is encoded next to a CRISPR-Cas9 target site in HEK293T cells. Upon transfection of Cas9 and sgRNA, the target site is cut, allowing TdT to intercept the double-strand break and add nucleotides. Each resulting insertion is sequenced alongside the identity of the TdT variant that generated it. Using this assay, 25,623 unique TdT variants, constructed by site-saturation mutagenesis at strategic positions, were profiled. This resulted in the isolation of several altered-bias TdTs that expanded the capabilities of our TdT-based DNA recording system, Cell HistorY Recording by Ordered InsertioN (CHYRON), by increasing the information density of recording through an unbiased TdT and achieving dual-channel recording of two distinct inducers (hypoxia and Wnt) through two differently biased TdTs. Select TdT variants were also tested in vitro, revealing concordance between each variant's in vitro bias and the in vivo bias determined from the multiplexed high throughput assay. Overall, our work and the multiplex assay it features should support the continued development of TdT-based DNA recorders, in vitro applications of TdT, and further study of the biology of TdT.

An efficient approach for overproduction of DNA polymerase from Pyrococcus furiosus using an optimized autoinduction system in Escherichia coli.

High fidelity DNA polymerase from Pyrococcus furiosus (Pfupol) is an attractive alternative to the highly popular DNA polymerase from Thermus aquaticus. Because this enzyme is in great demand for biotechnological applications, optimizing Pfupol production is essential to supplying the industry's expanding demand. T7-induced promoter expression in Escherichia coli expression systems is used to express recombinant Pfupol; however, this method is not cost-effective. Here, we have effectively developed an optimized process for the autoinduction approach of Pfupol expression in a defined medium. To better examine Pfupol's activities, its purified fraction was used. A 71mg/L of pure Pfupol was effectively produced, resulting in a 2.6-fold increase in protein yield when glucose, glycerol, and lactose were added in a defined medium at concentrations of 0.05%, 1%, and 0.6%, respectively, and the condition for production in a 5 L bioreactor was as follow: 200rpm, 3 vvm, and 10% inoculant. Furthermore, the protein exhibited 1445 U/mg of specific activity when synthesized in its active state. This work presents a high level of Pfupol production, which makes it an economically viable and practically useful approach.