Human PrimPol Research Articles

Remdesivir triphosphate is a valid substrate to initiate synthesis of DNA primers by human PrimPol

Remdesivir is a broad-spectrum antiviral drug which has been approved to treat COVID-19. Remdesivir is in fact a prodrug, which is metabolized in vivo into the active form remdesivir triphosphate (RTP), an analogue of adenosine triphosphate (ATP) with a cyano group substitution in the carbon 1’ of the ribose (1’-CN). RTP is a substrate for RNA synthesis and can be easily incorporated by viral RNA-dependent RNA polymerases (RdRp). Importantly, once remdesivir is incorporated (now monophosphate), it will act as a delayed chain terminator, thus blocking viral RNA synthesis. It has been reported that mitochondrial Polγ is also blocked in vitro by RTP, but the low impact in vivo on mitochondrial DNA replication stalling is likely due to repriming by the human DNA-directed DNA Primase/Polymerase (HsPrimPol), which also operates in mitochondria. In this work, we have tested if RTP is a valid substrate for both DNA primase and DNA polymerase activities of HsPrimPol, and its impact in the production of mature DNA primers. RTP resulted to be an invalid substrate for elongation, but it can be used to initiate primers at the 5´site, competing with ATP. Nevertheless, RTP-initiated primers are abortive, ocassionally reaching a maximal length of 4–5 nucleotides, and do not support elongation mediated by primer/template distortions. However, considering that the concentration of ATP, the natural substrate, is much higher than the intracellular concentration of RTP, it is unlikely that HsPrimPol would use RTP for primer synthesis during a remdesivir treatment in real patients.

3'dNTP Binding Is Modulated during Primer Synthesis and Translesion by Human PrimPol.

PrimPol is a DNA primase/polymerase from the Archaeo-Eukaryotic Primase (AEP) superfamily that enables the progression of stalled replication forks by synthesizing DNA primers ahead of blocking lesions or abnormal structures in the ssDNA template. PrimPol's active site is formed by three AEP-conserved motifs: A, B and C. Motifs A and C of human PrimPol (HsPrimPol) harbor the catalytic residues (Asp114, Glu116, Asp280) acting as metal ligands, whereas motif B includes highly conserved residues (Lys165, Ser167 and His169), which are postulated to stabilize 3' incoming deoxynucleotides (dNTPs). Additionally, other putative nucleotide ligands are situated close to motif C: Lys297, almost invariant in the whole AEP superfamily, and Lys300, specifically conserved in eukaryotic PrimPols. Here, we demonstrate that His169 is absolutely essential for 3'dNTP binding and, hence, for both primase and polymerase activities of HsPrimPol, whereas Ser167 and Lys297 are crucial for the dimer synthesis initiation step during priming, but dispensable for subsequent dNTP incorporation on growing primers. Conversely, the elimination of Lys165 does not affect the overall primase function; however, it is required for damage avoidance via primer-template realignments. Finally, Lys300 is identified as an extra anchor residue to stabilize the 3' incoming dNTP. Collectively, these results demonstrate that individual ligands modulate the stabilization of 3' incoming dNTPs to optimize DNA primer synthesis efficiency during initiation and primer maturation.

Regulation of human dna primase-polymerase primpol

Transmission of genetic information depends on successful completion of DNA replication. Genomic DNA is subjected to damage on a daily basis. DNA lesions create obstacles for DNA polymerases and can lead to replication blockage, DNA break formation, cell cycle disruption and apoptosis. Cells have adapted to DNA damage evolving mechanisms allowing to eliminate lesions prior to DNA replication (DNA repair) and mechanisms which help to bypass lesions during DNA synthesis (DNA damage tolerance). The second group of pathways includes the mechanism of DNA synthesis restart at the damaged sites by DNA primase-polymerase PrimPol. Human PrimPol was first described in 2013. The properties and functions of PrimPol have been extensively studied in recent years, but very little is known about the regulation of PrimPol and the association of the enzyme dysfunction with diseases. The present review is devoted to an analysis of the mechanisms of human PrimPol regulation in the context of DNA replication. The interaction of PrimPol with other proteins is discussed in detail and an attempt is made to compile a possible pathway for the regulation of human PrimPol activity. The paper also addresses the relationship of PrimPol dysfunction with human diseases.

Coordination of Primer Initiation Within the Catalytic Domain of Human PrimPol

To facilitate the eukaryotic repriming pathway of DNA damage tolerance, PrimPol synthesises de novo oligonucleotide primers downstream of polymerase-stalling obstacles. These primers enable replicative polymerases to resume synthesis and ensure the timely completion of DNA replication. Initiating synthesis de novo requires the coordination of single-stranded DNA, initiating nucleotides, and metal ions within PrimPol’s active site to catalyze the formation of the first phosphodiester bond. Here we examine the interactions between human PrimPol’s catalytic domain, nucleotides, and DNA template during each of the various catalytic steps to determine the ‘choreography’ of primer synthesis, where substrates bind in an ordered manner. Our findings show that the ability of PrimPol to conduct de novo primer synthesis is underpinned by a network of stabilising interactions between the enzyme, template, and nucleotides, as we previously observed for related primase CRISPR-Associated Prim-Pol (CAPP). Together, these findings establish a detailed model for the initiation of DNA synthesis by human PrimPol, which appears highly conserved.

Regulation of Human DNA Primase-Polymerase PrimPol.

Transmission of genetic information depends on successful completion of DNA replication. Genomic DNA is subjected to damage on a daily basis. DNA lesions create obstacles for DNA polymerases and can lead to the replication blockage, formation of DNA breaks, cell cycle arrest, and apoptosis. Cells have evolutionary adapted to DNA damage by developing mechanisms allowing elimination of lesions prior to DNA replication (DNA repair) and helping to bypass lesions during DNA synthesis (DNA damage tolerance). The second group of mechanisms includes the restart of DNA synthesis at the sites of DNA damage by DNA primase-polymerase PrimPol. Human PrimPol was described in 2013. The properties and functions of this enzyme have been extensively studied in recent years, but very little is known about the regulation of PrimPol and association between the enzyme dysfunction and diseases. In this review, we described the mechanisms of human PrimPol regulation in the context of DNA replication, discussed in detail interactions of PrimPol with other proteins, and proposed possible pathways for the regulation of human PrimPol activity. The article also addresses the association of PrimPol dysfunction with human diseases.

The role of catalytic and regulatory domains of human PrimPol in DNA binding and synthesis.

Human PrimPol possesses DNA primase and DNA polymerase activities and restarts stalled replication forks protecting cells against DNA damage in nuclei and mitochondria. The zinc-binding motif (ZnFn) of the C-terminal domain (CTD) of PrimPol is required for DNA primase activity but the mechanism is not clear. In this work, we biochemically demonstrate that PrimPol initiates de novo DNA synthesis in cis-orientation, when the N-terminal catalytic domain (NTD) and the CTD of the same molecule cooperate for substrates binding and catalysis. The modeling studies revealed that PrimPol uses a similar mode of initiating NTP coordination as the human primase. The ZnFn motif residue Arg417 is required for binding the 5'-triphosphate group that stabilizes the PrimPol complex with a DNA template-primer. We found that the NTD alone is able to initiate DNA synthesis, and the CTD stimulates the primase activity of NTD. The regulatory role of the RPA-binding motif in the modulation of PrimPol binding to DNA is also demonstrated.

Translesion Synthesis across the N2-Ethyl-deoxyguanosine Adduct by Human PrimPol.

Primase-DNA polymerase (PrimPol) is involved in reinitiating DNA synthesis at stalled replication forks. PrimPol also possesses DNA translesion (TLS) activity and bypasses several endogenous nonbulky DNA lesions in vitro. Little is known about the TLS activity of PrimPol across bulky carcinogenic adducts. We analyzed the DNA polymerase activity of human PrimPol on DNA templates with seven N2-dG lesions of different steric bulkiness. In the presence of Mg2+ ions, bulky N2-isobutyl-dG, N2-benzyl-dG, N2-methyl(1-naphthyl)-dG, N2-methyl(9-anthracenyl)-dG, N2-methyl(1-pyrenyl)-dG, and N2-methyl(1,3-dimethoxyanthraquinone)-dG adducts fully blocked PrimPol activity. At the same time, PrimPol incorporated complementary deoxycytidine monophosphate (dCMP) opposite N2-ethyl-dG with moderate efficiency but did not extend DNA beyond the lesion. We also demonstrated that mutation of the Arg288 residue abrogated dCMP incorporation opposite the lesion in the presence of Mn2+ ions. When Mn2+ replaced Mg2+, PrimPol carried out DNA synthesis on all DNA templates with N2-dG adducts in standing start reactions with low efficiency and accuracy, possibly utilizing a lesion "skipping" mechanism. The TLS activity of PrimPol opposite N2-ethyl-dG but not bulkier adducts was stimulated by accessory proteins, polymerase delta-interacting protein 2 (PolDIP2), and replication protein A (RPA). Molecular dynamics studies demonstrated the absence of stable interactions with deoxycytidine triphosphate (dCTP), large reactions, and C1'-C1' distances for the N2-isobutyl-dG and N2-benzyl-dG PrimPol complexes, suggesting that the size of the adduct is a limiting factor for efficient TLS across minor groove adducts by PrimPol.

PrimPol: A Breakthrough among DNA Replication Enzymes and a Potential New Target for Cancer Therapy.

DNA replication can encounter blocking obstacles, leading to replication stress and genome instability. There are several mechanisms for evading this blockade. One mechanism consists of repriming ahead of the obstacles, creating a new starting point; in humans, PrimPol is responsible for carrying out this task. PrimPol is a primase that operates in both the nucleus and mitochondria. In contrast with conventional primases, PrimPol is a DNA primase able to initiate DNA synthesis de novo using deoxynucleotides, discriminating against ribonucleotides. In vitro, PrimPol can act as a DNA primase, elongating primers that PrimPol itself sythesizes, or as translesion synthesis (TLS) DNA polymerase, elongating pre-existing primers across lesions. However, the lack of evidence for PrimPol polymerase activity in vivo suggests that PrimPol only acts as a DNA primase. Here, we provide a comprehensive review of human PrimPol covering its biochemical properties and structure, in vivo function and regulation, and the processes that take place to fill the gap-containing lesion that PrimPol leaves behind. Finally, we explore the available data on human PrimPol expression in different tissues in physiological conditions and its role in cancer.

Human PrimPol Discrimination against Dideoxynucleotides during Primer Synthesis.

PrimPol is required to re-prime DNA replication at both nucleus and mitochondria, thus facilitating fork progression during replicative stress. ddC is a chain-terminating nucleotide that has been widely used to block mitochondrial DNA replication because it is efficiently incorporated by the replicative polymerase Polγ. Here, we show that human PrimPol discriminates against dideoxynucleotides (ddNTP) when elongating a primer across 8oxoG lesions in the template, but also when starting de novo synthesis of DNA primers, and especially when selecting the 3′nucleotide of the initial dimer. PrimPol incorporates ddNTPs with a very low efficiency compared to dNTPs even in the presence of activating manganese ions, and only a 40-fold excess of ddNTP would significantly disturb PrimPol primase activity. This discrimination against ddNTPs prevents premature termination of the primers, warranting their use for elongation. The crystal structure of human PrimPol highlights Arg291 residue as responsible for the strong dNTP/ddNTP selectivity, since it interacts with the 3′-OH group of the incoming deoxynucleotide, absent in ddNTPs. Arg291, shown here to be critical for both primase and polymerase activities of human PrimPol, would contribute to the preferred binding of dNTPs versus ddNTPs at the 3′elongation site, thus avoiding synthesis of abortive primers.

Translesion activity of PrimPol on DNA with cisplatin and DNA\u2013protein cross-links

Human PrimPol belongs to the archaeo-eukaryotic primase superfamily of primases and is involved in de novo DNA synthesis downstream of blocking DNA lesions and non-B DNA structures. PrimPol possesses both DNA/RNA primase and DNA polymerase activities, and also bypasses a number of DNA lesions in vitro. In this work, we have analyzed translesion synthesis activity of PrimPol in vitro on DNA with an 1,2-intrastrand cisplatin cross-link (1,2-GG CisPt CL) or a model DNA–protein cross-link (DpCL). PrimPol was capable of the 1,2-GG CisPt CL bypass in the presence of Mn2+ ions and preferentially incorporated two complementary dCMPs opposite the lesion. Nucleotide incorporation was stimulated by PolDIP2, and yeast Pol ζ efficiently extended from the nucleotides inserted opposite the 1,2-GG CisPt CL in vitro. DpCLs significantly blocked the DNA polymerase activity and strand displacement synthesis of PrimPol. However, PrimPol was able to reach the DpCL site in single strand template DNA in the presence of both Mg2+ and Mn2+ ions despite the presence of the bulky protein obstacle.

Motif WFYY of human PrimPol is crucial to stabilize the incoming 3'-nucleotide during replication fork restart.

PrimPol is the second primase in human cells, the first with the ability to start DNA chains with dNTPs. PrimPol contributes to DNA damage tolerance by restarting DNA synthesis beyond stalling lesions, acting as a TLS primase. Multiple alignment of eukaryotic PrimPols allowed us to identify a highly conserved motif, WxxY near the invariant motif A, which contains two active site metal ligands in all members of the archeo-eukaryotic primase (AEP) superfamily. In vivo and in vitro analysis of single variants of the WFYY motif of human PrimPol demonstrated that the invariant Trp87 and Tyr90 residues are essential for both primase and polymerase activities, mainly due to their crucial role in binding incoming nucleotides. Accordingly, the human variant F88L, altering the WFYY motif, displayed reduced binding of incoming nucleotides, affecting its primase/polymerase activities especially during TLS reactions on UV-damaged DNA. Conversely, the Y89D mutation initially associated with High Myopia did not affect the ability to rescue stalled replication forks in human cells. Collectively, our data suggest that the WFYY motif has a fundamental role in stabilizing the incoming 3′-nucleotide, an essential requisite for both its primase and TLS abilities during replication fork restart.

Structural basis of DNA synthesis opposite 8-oxoguanine by human PrimPol primase-polymerase

PrimPol is a human DNA polymerase-primase that localizes to mitochondria and nucleus and bypasses the major oxidative lesion 7,8-dihydro-8-oxoguanine (oxoG) via translesion synthesis, in mostly error-free manner. We present structures of PrimPol insertion complexes with a DNA template-primer and correct dCTP or erroneous dATP opposite the lesion, as well as extension complexes with C or A as a 3′−terminal primer base. We show that during the insertion of C and extension from it, the active site is unperturbed, reflecting the readiness of PrimPol to accommodate oxoG(anti). The misinsertion of A opposite oxoG(syn) also does not alter the active site, and is likely less favorable due to lower thermodynamic stability of the oxoG(syn)•A base-pair. During the extension step, oxoG(syn) induces an opening of its base-pair with A or misalignment of the 3′-A primer terminus. Together, the structures show how PrimPol accurately synthesizes DNA opposite oxidatively damaged DNA in human cells.

The DNA ligands Arg47 and Arg76 are crucial for catalysis by human PrimPol

Human primase and DNA polymerase PrimPol re-starts stalled replication forks by repriming downstream DNA lesions and protects cells against DNA damage. Structure of the catalytic core of PrimPol with DNA primer, template and incoming dATP was solved but the mechanisms of DNA polymerase and primase activities of PrimPol are not fully understood. In this work, using site-directed mutagenesis we biochemically analyzed the role of active site residues Arg47 and Arg76 contacting DNA template in DNA polymerase and primase activities of PrimPol. The substitution R47A diminished the DNA polymerase and primase activities of PrimPol whereas the single amino acid substitution R76A caused almost complete loss of catalytic activities. Both amino acid substitutions affected the spectrum of dNMPs incorporation on undamaged DNA templates and opposite 8-oxoguanine. Finally, substitutions of the Arg47 and Arg76 residues attenuated the formation of the stable PrimPol:DNA complex in the presence of ATP/dNTPs. Together, these findings suggest a key role of the Arg47 and Arg76 in DNA synthesis by PrimPol.

Template Properties of 5-Methyl-2'-Deoxycytidine and 5-Hydroxymethyl-2'-Deoxycytidine in Reactions with Human Translesion and Reparative DNA Polymerases

5-Methyl-2'-deoxycytidine (mC) and the product of its controlled oxidation, 5-hydroxymethyl-2'-cytidine (hmC), play a key role in the epigenetic regulation of gene expression, the cell differentiation, and the carcinogenesis. Due to spontaneious deamination, genomic CpG sites containing mC and hmC serve as mutagenesis hotspots. In addition, error-prone translesion and reparative DNA polymerases may serve as additional source of mutations in the lesion-containing regions with CpG sites. In the present work, we performed in vitro analysis of the accuracy of nucleotide incorporation opposite to mC and hmC by human DNA polymerases Polβ, Polλ, Polη, Polι, PoIκ and primase polymerase PrimPol. The results of the study show a high accuracy of copying mC and hmC by the reparative DNA polymerases polymerases Polβ and Polλ, while Polη, Polι, PoIκ, and PrimPol copied mC and hmC with less accuracy evident by incorporation of dAMP and dTMP. The same spectrum of error-prone dNMP incorporation was also noted at sites with unmodified cytosines.

Strand Displacement Activity of PrimPol.

Human PrimPol is a unique enzyme possessing DNA/RNA primase and DNA polymerase activities. In this work, we demonstrated that PrimPol efficiently fills a 5-nt gap and possesses the conditional strand displacement activity stimulated by Mn2+ ions and accessory replicative proteins RPA and PolDIP2. The DNA displacement activity of PrimPol was found to be more efficient than the RNA displacement activity and FEN1 processed the 5′-DNA flaps generated by PrimPol in vitro.

The invariant glutamate of human PrimPol DxE motif is critical for its Mn2+-dependent distinctive activities

PrimPol is a human primase/polymerase specialized in downstream repriming of stalled forks during both nuclear and mitochondrial DNA replication. Like most primases and polymerases, PrimPol requires divalent metal cations, as Mg2+ or Mn2+, used as cofactors for catalysis. However, little is known about the consequences of using these two metal cofactors in combination, which would be the most physiological scenario during PrimPol-mediated reactions, and the individual contribution of the putative carboxylate residues (Asp114, Glu116 and Asp280) acting as metal ligands. By site-directed mutagenesis in human PrimPol, we confirmed the catalytic relevance of these three carboxylates, and identified Glu116 as a relevant enhancer of distinctive PrimPol reactions, which are highly dependent on Mn2+. Herein, we evidenced that PrimPol Glu116 contributes to error-prone tolerance of 8oxodG more markedly when both Mg2+ and Mn2+ ions are present. Moreover, Glu116 was important for TLS events mediated by primer/template realignments, and crucial to achieving an optimal primase activity, processes in which Mn2+ is largely preferred. EMSA analysis of PrimPol:ssDNA:dNTP pre-ternary complex indicated a critical role of each metal ligand, and a significant impairment when Glu116 was changed to a more conventional aspartate. These data suggest that PrimPol active site requires a specific motif A (DxE) to favor the use of Mn2+ ions in order to achieve optimal incoming nucleotide stabilization, especially required during primer synthesis.

A cancer-associated point mutation disables the steric gate of human PrimPol

PrimPol is a human primase/polymerase specialized in re-starting stalled forks by repriming beyond lesions such as pyrimidine dimers, and replication-perturbing structures including G-quadruplexes and R-loops. Unlike most conventional primases, PrimPol proficiently discriminates against ribonucleotides (NTPs), being able to start synthesis using deoxynucleotides (dNTPs), yet the structural basis and physiological implications for this discrimination are not understood. In silico analyses based on the three-dimensional structure of human PrimPol and related enzymes enabled us to predict a single residue, Tyr100, as the main effector of sugar discrimination in human PrimPol and a change of Tyr100 to histidine to boost the efficiency of NTP incorporation. We show here that the Y100H mutation profoundly stimulates NTP incorporation by human PrimPol, with an efficiency similar to that for dNTP incorporation during both primase and polymerase reactions in vitro. As expected from the higher cellular concentration of NTPs relative to dNTPs, Y100H expression in mouse embryonic fibroblasts and U2OS osteosarcoma cells caused enhanced resistance to hydroxyurea, which decreases the dNTP pool levels in S-phase. Remarkably, the Y100H PrimPol mutation has been identified in cancer, suggesting that this mutation could be selected to promote survival at early stages of tumorigenesis, which is characterized by depleted dNTP pools.

Mechanism of DNA primer synthesis by human PrimPol.

PrimPol is the second primase discovered in eukaryotic cells, whose function is to restart the stalled replication forks during both mitochondrial and nuclear DNA replication. This chapter revises our current knowledge about the mechanism of synthesis of DNA primers by human PrimPol, and the importance of its distinctive Zn-finger domain (ZnFD). After PrimPol forms a binary complex with ssDNA, the formation of the pre-ternary complex strictly requires the presence of Mn2+ ions to stabilize the interaction of the incoming deoxynucleotide at the 3'-site. The capacity to bind both ssDNA template and 3'-deoxynucleotide was shown to reside in the AEP core of PrimPol, with ZnFD being dispensable at these two early steps of the primase reaction. Sugar selection favoring dNTPs versus NTPs at the 3' site is mediated by a specific tyrosine (Tyr100) acting as a steric gate. Besides, a specific glutamate residue (Glu116) conforming a singular A motif (DxE) promotes the use of Mn2+ to stabilize the pre-ternary complex. Mirroring the function of the PriL subunit of dimeric AEP primases, the ZnFD of PrimPol is crucial to stabilize the initiating 5'-nucleotide, specifically interacting with the gamma-phosphate. Such an interaction is crucial to optimize dimer formation and the subsequent translocation events leading to the processive synthesis of a mature DNA primer. Finally, the capacity of PrimPol to tolerate lesions is discussed in the context of its DNA primase function, and its potential as a TLS primase.

In vitro lesion bypass by human PrimPol

In vitro lesion bypass by human PrimPol

In vitro lesion bypass by human PrimPol

Many human DNA polymerases bypass DNA damage during translesion synthesis (TLS). Human primase and polymerase, PrimPol, assists fork progression by repriming DNA synthesis downstream of the lesion using its DNA primase activity. We tested the properties of PrimPol as a TLS polymerase in the presence of different metal ions in vitro. We demonstrate that in the presence of Mg2+ ions PrimPol carries out efficient and relatively accurate synthesis past 8-oxoguanine and 5-formyluracil. It also bypasses an abasic site and O6-methylguanine, but is blocked by thymine glycol and 1,N6-ethenoadenine. Substitution of Mg2+ with Mn2+ stimulates the TLS activity of PrimPol and allows for efficient, but error-prone, synthesis on DNA templates containing all tested DNA lesions, including thymine glycol and 1,N6-ethenoadenine. The TLS activity of PrimPol has possible relevant functions in vivo; e.g., the combined primase and DNA polymerase activities of PrimPol might facilitate replication of DNA with clustered damage.