Murine DNA polymerase.alpha-primase initiates RNA-primed DNA synthesis preferentially upstream of a 3'-CC(C/A)-5' motif

Replication-induced DNA secondary structures drive fork uncoupling and breakage

Sequences that form DNA secondary structures, such as G-quadruplexes (G4s) and intercalated-Motifs (iMs), are abundant in the human genome and play various physiological roles. However, they can also interfere with replication and threaten genome stability. Multiple lines of evidence suggest G4s inhibit replication, but the underlying mechanism remains unclear. Moreover, evidence of how iMs affect the replisome is lacking. Here, we reconstitute replication of physiologically derived structure-forming sequences to find that a single G4 or iM arrest DNA replication. Direct single-molecule structure detection within solid-state nanopores reveals structures form as a consequence of replication. Combined genetic and biophysical characterisation establishes that structure stability and probability of structure formation are key determinants of replisome arrest. Mechanistically, replication arrest is caused by impaired synthesis, resulting in helicase-polymerase uncoupling. Significantly, iMs also induce breakage of nascent DNA. Finally, stalled forks are only rescued by a specialised helicase, Pif1, but not Rrm3, Sgs1, Chl1 or Hrq1. Altogether, we provide a mechanism for quadruplex structure formation and resolution during replication and highlight G4s and iMs as endogenous sources of replication stress.

The monomeric archaeal primase from Nanoarchaeum equitans harbours the features of heterodimeric archaeoeukaryotic primases and primes sequence-specifically

The marine thermophilic archaeon Nanoarchaeum equitans possesses a monomeric primase encompassing the conserved domains of the small catalytic and the large regulatory subunits of archaeoeukaryotic heterodimeric primases in one protein chain. The recombinant protein primes on templates containing a triplet with a central thymidine, thus displaying a pronounced sequence specificity typically observed with bacterial type primases only. The N. equitans primase (NEQ395) is a highly active primase enzyme synthesizing short RNA primers. Termination occurs preferentially at about nine nucleotides, as determined by HPLC analysis and confirmed with mass spectrometry. Possibly, the compact monomeric primase NEQ395 represents the minimal archaeoeukaryotic primase and could serve as a functional and structural model of the heterodimeric archaeoeukaryotic primases, whose study is hindered by engagement in protein assemblies and rather low activity.

Cytokine- and chemokine-induced inflammatory colorectal tumor microenvironment: Emerging avenue for targeted therapy

Colorectal cancer (CRC) is a predominant life-threatening cancer, with liver and peritoneal metastases as the primary causes of death. Intestinal inflammation, a known CRC risk factor, nurtures a local inflammatory environment enriched with tumor cells, endothelial cells, immune cells, cancer-associated fibroblasts, immunosuppressive cells, and secretory growth factors. The complex interactions of aberrantly expressed cytokines, chemokines, growth factors, and matrix-remodeling enzymes promote CRC pathogenesis and evoke systemic responses that affect disease outcomes. Mounting evidence suggests that these cytokines and chemokines play a role in the progression of CRC through immunosuppression and modulation of the tumor microenvironment, which is partly achieved by the recruitment of immunosuppressive cells. These cells impart features such as cancer stem cell-like properties, drug resistance, invasion, and formation of the premetastatic niche in distant organs, promoting metastasis and aggressive CRC growth. A deeper understanding of the cytokine- and chemokine-mediated signaling networks that link tumor progression and metastasis will provide insights into the mechanistic details of disease aggressiveness and facilitate the development of novel therapeutics for CRC. Here, we summarized the current knowledge of cytokine- and chemokine-mediated crosstalk in the inflammatory tumor microenvironment, which drives immunosuppression, resistance to therapeutics, and metastasis during CRC progression. We also outlined the potential of this crosstalk as a novel therapeutic target for CRC. The major cytokine/chemokine pathways involved in cancer immunotherapy are also discussed in this review.

Small tandem DNA duplications result from CST-guided Pol α-primase action at DNA break termini

Small tandem duplications of DNA occur frequently in the human genome and are implicated in the aetiology of certain human cancers. Recent studies have suggested that DNA double-strand breaks are causal to this mutational class, but the underlying mechanism remains elusive. Here, we identify a crucial role for DNA polymerase α (Pol α)-primase in tandem duplication formation at breaks having complementary 3′ ssDNA protrusions. By including so-called primase deserts in CRISPR/Cas9-induced DNA break configurations, we reveal that fill-in synthesis preferentially starts at the 3′ tip, and find this activity to be dependent on 53BP1, and the CTC1-STN1-TEN1 (CST) and Shieldin complexes. This axis generates near-blunt ends specifically at DNA breaks with 3′ overhangs, which are subsequently repaired by non-homologous end-joining. Our study provides a mechanistic explanation for a mutational signature abundantly observed in the genomes of species and cancer cells.

Error-prone repair of DNA double-strand breaks have been implied to cause cancer-associated genome alterations, but the mechanism of their formation remains unclear. Here the authors find that DNA polymerase α primase plays part in tandem duplication formation at CRISPR/Cas9-induced complementary 3′ ssDNA protrusions.

An Allosteric Switch Primes Sequence-Specific DNA Recognition

Regulation of protein-DNA binding specificity occurs through myriad mechanisms. Boudet et al. discover yet a new form of specificity through allosteric regulation, an ATP-induced structural switch that mediates specific DNA recognition in an archaeoeukaryotic primase.

The Yeast Mitochondrial RNA Polymerase and Transcription Factor Complex Catalyzes Efficient Priming of DNA Synthesis on Single-stranded DNA

Primases use single-stranded (ss) DNAs as templates to synthesize short oligoribonucleotide primers that initiate lagging strand DNA synthesis or reprime DNA synthesis after replication fork collapse, but the origin of this activity in the mitochondria remains unclear. Herein, we show that the Saccharomyces cerevisiae mitochondrial RNA polymerase (Rpo41) and its transcription factor (Mtf1) is an efficient primase that initiates DNA synthesis on ssDNA coated with the yeast mitochondrial ssDNA-binding protein, Rim1. Both Rpo41 and Rpo41-Mtf1 can synthesize short and long RNAs on ssDNA template and prime DNA synthesis by the yeast mitochondrial DNA polymerase Mip1. However, the ssDNA-binding protein Rim1 severely inhibits the RNA synthesis activity of Rpo41, but not the Rpo41-Mtf1 complex, which continues to prime DNA synthesis efficiently in the presence of Rim1. We show that RNAs as short as 10-12 nt serve as primers for DNA synthesis. Characterization of the RNA-DNA products shows that Rpo41 and Rpo41-Mtf1 have slightly different priming specificity. However, both prefer to initiate with ATP from short priming sequences such as 3'-TCC, TTC, and TTT, and the consensus sequence is 3'-Pu(Py)2-3 Based on our studies, we propose that Rpo41-Mtf1 is an attractive candidate for serving as the primase to initiate lagging strand DNA synthesis during normal replication and/or to restart stalled replication from downstream ssDNA.

Novel interaction of the bacterial-Like DnaG primase with the MCM helicase in archaea

DNA priming and unwinding activities are coupled within bacterial primosome complexes to initiate synthesis on the lagging strand during DNA replication. Archaeal organisms contain conserved primase genes homologous to both the bacterial DnaG and archaeo-eukaryotic primase families. The inclusion of multiple DNA primases within a whole domain of organisms complicates the assignment of the metabolic roles of each. In support of a functional bacterial-like DnaG primase participating in archaeal DNA replication, we have detected an interaction of Sulfolobus solfataricus DnaG (SsoDnaG) with the replicative S. solfataricus minichromosome maintenance (SsoMCM) helicase on DNA. The interaction site has been mapped to the N-terminal tier of SsoMCM analogous to bacterial primosome complexes. Mutagenesis within the metal binding site of SsoDnaG verifies a functional homology with bacterial DnaG that perturbs priming activity and DNA binding. The complex of SsoDnaG with SsoMCM stimulates the ATPase activity of SsoMCM but leaves the priming activity of SsoDnaG unchanged. Competition for binding DNA between SsoDnaG and SsoMCM can reduce the unwinding ability. Fluorescent gel shift experiments were used to quantify the binding of the ternary SsoMCM-DNA-SsoDnaG complex. This direct interaction of a bacterial-like primase with a eukaryotic-like helicase suggests that formation of a unique but homologous archaeal primosome complex is possible but may require other components to stimulate activities. Identification of this archaeal primosome complex broadly impacts evolutionary relationships of DNA replication.

Mechanism and evolution of DNA primases

DNA primase synthesizes short RNA primers that replicative polymerases further elongate in order to initiate the synthesis of all new DNA strands. Thus, primase owes its existence to the inability of DNA polymerases to initiate DNA synthesis starting with 2 dNTPs. Here, we discuss the evolutionary relationships between the different families of primases (viral, eubacterial, archael, and eukaryotic) and the catalytic mechanisms of these enzymes. This includes how they choose an initiation site, elongate the growing primer, and then only synthesize primers of defined length via an inherent ability to count. Finally, the low fidelity of primases along with the development of primase inhibitors is described.

Properties of an unusual DNA primase from an archaeal plasmid

Primases are specialized DNA-dependent RNA polymerases that synthesize a short oligoribonucleotide complementary to single-stranded template DNA. In the context of cellular DNA replication, primases are indispensable since DNA polymerases are not able to start DNA polymerization de novo.

The primase activity of the replication protein from the archaeal plasmid pRN1 synthesizes a rather unusual mixed primer consisting of a single ribonucleotide at the 5′ end followed by seven deoxynucleotides. Ribonucleotides and deoxynucleotides are strictly required at the respective positions within the primer. Furthermore, in contrast to other archaeo-eukaryotic primases, the primase activity is highly sequence-specific and requires the trinucleotide motif GTG in the template. Primer synthesis starts outside of the recognition motif, immediately 5′ to the recognition motif. The fidelity of the primase synthesis is high, as non-complementary bases are not incorporated into the primer.

DNA primases

DNA primases are enzymes whose continual activity is required at the DNA replication fork. They catalyze the synthesis of short RNA molecules used as primers for DNA polymerases. Primers are synthesized from ribonucleoside triphosphates and are four to fifteen nucleotides long. Most DNA primases can be divided into two classes. The first class contains bacterial and bacteriophage enzymes found associated with replicative DNA helicases. These prokaryotic primases contain three distinct domains: an amino terminal domain with a zinc ribbon motif involved in binding template DNA, a middle RNA polymerase domain, and a carboxyl-terminal region that either is itself a DNA helicase or interacts with a DNA helicase. The second major primase class comprises heterodimeric eukaryotic primases that form a complex with DNA polymerase alpha and its accessory B subunit. The small eukaryotic primase subunit contains the active site for RNA synthesis, and its activity correlates with DNA replication during the cell cycle.

The effects of cytosine arabinoside on RNA-primed DNA synthesis by DNA polymerase alpha-primase

Oligonucleotides containing a specific initiation site for polymerase alpha-primase (pol alpha-primase) were used to measure the effects of cytosine arabinoside triphosphate and cytosine arabinoside monophosphate (araCMP) in DNA on RNA-primed DNA synthesis. Primase inserts araCMP at the 3' terminus of a full-length RNA primer with a 400-fold preference over CMP. The araCMP is elongated efficiently by pol alpha in the primase-coupled reaction. Extension from RNA 3'-araCMP is 50-fold less efficient than from CMP, and extension from DNA 3'-araCMP is 1600-fold less efficient than from dCMP. Using araCMP-containing templates, primer synthesis is reduced 2-3-fold, and RNA-primed DNA synthesis is reduced 2-8-fold. The efficiency of polymerization past a template araCMP by pol alpha is reduced 180-fold during insertion of dGMP opposite araCMP and 35-fold during extension from the araCMP:dGMP 3' terminus. These results show that the pol alpha-primase efficiently incorporates araCMP as the border nucleotide between RNA and DNA and suggest that the inhibitory effects of araC most likely result from slowed elongation of pol alpha and less so from inhibition of primer synthesis by primase.

Mechanism of calf thymus DNA primase: slow initiation, rapid polymerization, and intelligent termination

The mechanism by which calf thymus DNA primase synthesizes RNA primers was examined. Primase first binds a single-stranded DNA template (KD << 100 nM) and can then slide along the DNA in order to find a start for initiating primer synthesis. NTP binding appears ordered, such that the NTP which eventually becomes the second nucleotide of the primer binds the E.DNA complex first. The NTP that becomes the second nucleotide of the primer thereby influences where primase initiates. Primer synthesis is remarkably slow (0.0027 s-1 at 20 microM NTP). The rate-limiting step is after formation of the E.DNA.NTP.NTP complex and before or during dinucleotide synthesis. After synthesis of the dinucleotide, additional NTPs are rapidly polymerized. Primase products are 2-10 nucleotides long. If the enzyme fails to synthesize a primer at least 7 nucleotides long, it reinitiates rather than dissociating from the template. Once a primer at least 7 nucleotides long has been generated, however, subsequent primase activity is inhibited. This inhibition is due to the generation of a stable primer-template complex, which likely remains associated with pol alpha.primase. The role of primase is to synthesize primers that pol alpha can elongate. The ability of primase to distinguish between primers at least 7 nucleotides long and shorter products therefore likely reflects the fact that pol alpha only utilizes primers at least 7 nucleotides long.

Isolation of temperature-sensitive DNA polymerase III from Saccharomyces cerevisiae cdc2-2

DNA polymerase III of the yeast Saccharomyces cerevisiae has been reported to be encoded at the CDC2 locus based on two observations. First, the CDC2 gene has homology to known DNA polymerase genes [Boulet et al. (1989) EMBO J. 8, 1849-1854], and second, the mutants cdc2-1 and cdc2-2 yield little or no DNA polymerase III activity in vitro [Boulet et al. (1989); Sitney et al. (1989) Cell 56, 599-605]. We describe here the isolation of temperature-sensitive DNA polymerase III from cdc2-2 strains. Our results provide direct experimental confirmation of the previously inferred gene/enzyme relationship and verify the conclusion that DNA polymerase III is required to replicate the genome. We isolated DNA polymerase III from two cdc2-2 strains, one containing the wild-type allele for DNA polymerase I (CDC17) and the other a mutant DNA polymerase I allele (cdc17-1). Yields from cdc2-2 cells of both DNA polymerase III activity and an associated 3'-5'-exonuclease activity [exonuclease III; Bauer et al. (1988) J. Biol. Chem. 263, 917-924] were decreased relative to yields from CDC2 cells. DNA polymerase III activity from cdc2-2 strains is thermolabile, displaying at least a 4-fold reduction in half-life at 44 degrees C. The activity is also labile at 37 degrees C, a temperature which is restrictive for growth of cdc2-2 but not CDC2 strains. At 23 degrees C, a temperature which is permissive for growth of both cdc2-2 and CDC2 strains, the mutant and wild-type DNA polymerase III activities display equal stability. These observations provide a demonstrable biochemical basis for the thermosensitive phenotype of cdc2-2 cells.