Single-nucleotide polymorphisms: analysis by mass spectrometry

Matrix-assisted laser desorption-ionization (MALDI) mass spectrometry has evolved as a powerful method for analyzing nucleic acids. Here we provide protocols for genotyping single-nucleotide polymorphisms (SNPs) by MALDI based on PCR and primer extension to generate allele-specific products. Furthermore, we present three different approaches for sample preparation of primer-extension products before MALDI analysis and discuss their potential areas of application. The first approach, the 'GOOD' assay, is a purification-free procedure that uses DNA-modification chemistry, including alkylation of phosphorothioate linkages in the extension primers. The other two approaches use either solid-phase extraction or microarray purification for the purification of primer-extension products. Depending on the reaction steps of the various approaches, the protocols take about 6-8 hours.     

Functional interplay of DnaE polymerase,DnaG primase and DnaC helicase within a ternary complex,and primase to polymerase hand-off during lagging strand DNA replication in Bacillus subtilis

Bacillus subtilis has two replicative DNA polymerases. PolC is a processive high-fidelity replicative polymerase, while the error-prone DnaE_Bs extends RNA primers before hand-off to PolC at the lagging strand. We show that DnaE_Bs interacts with the replicative helicase DnaC and primase DnaG in a ternary complex. We characterize their activities and analyse the functional significance of their interactions using primase, helicase and primer extension assays, and a ‘stripped down’ reconstituted coupled assay to investigate the coordinated displacement of the parental duplex DNA at a replication fork, synthesis of RNA primers along the lagging strand and hand-off to DnaE_Bs. The DnaG–DnaE_Bs hand-off takes place after de novo polymerization of only two ribonucleotides by DnaG, and does not require other replication proteins. Furthermore, the fidelity of DnaE_Bs is improved by DnaC and DnaG, likely via allosteric effects induced by direct protein–protein interactions that lower the efficiency of nucleotide mis-incorporations and/or the efficiency of extension of mis-aligned primers in the catalytic site of DnaE_Bs. We conclude that de novo RNA primer synthesis by DnaG and initial primer extension by DnaE_Bs are carried out by a lagging strand–specific subcomplex comprising DnaG, DnaE_Bs and DnaC, which stimulates chromosomal replication with enhanced fidelity.     

Initiation of RNA-primed DNA synthesis in vitro by DNA polymerase alpha-primase.

The initiation of new DNA strands at origins of replication in animal cells requires de novo synthesis of RNA primers by primase and subsequent elongation from RNA primers by DNA polymerase alpha. To study the specificity of primer site selection by the DNA polymerase alpha-primase complex (pol alpha-primase), a natural DNA template containing a site for replication initiation was constructed. Two single-stranded DNA (ssDNA) molecules were hybridized to each other generating a duplex DNA molecule with an open helix replication 'bubble' to serve as an initiation zone. Pol alpha-primase recognizes the open helix region and initiates RNA-primed DNA synthesis at four specific sites that are rich in pyrimidine nucleotides. The priming site positioned nearest the ssDNA-dsDNA junction in the replication 'bubble' template is the preferred site for initiation. Using a 40 base oligonucleotide template containing the sequence of the preferred priming site, primase synthesizes RNA primers of 9 and 10 nt in length with the sequence 5'-(G)GAAGAAAGC-3'. These studies demonstrate that pol alpha-primase selects specific nucleotide sequences for RNA primer formation and suggest that the open helix structure of the replication 'bubble' directs pol alpha-primase to initiate RNA primer synthesis near the ssDNA-dsDNA junction.     

Interplay between primase and replication factor C in the hyperthermophilic archaeon Sulfolobus solfataricus

The heterodimeric primase from the hyperthermophilic archaeon Sulfolobus solfataricus synthesizes long RNA and DNA products in vitro. How primer synthesis by primase is coupled to primer extension by DNA polymerase in this organism is unclear. Here we show that the small subunit of the clamp loader replication factor C (RFC) of S. solfataricus interacted with both the catalytic and non-catalytic subunits of the primase by yeast two-hybrid and co-immunoprecipitation assays. Further, the primase-RFC interaction was also identified in the cell extract of S. solfataricus. Deletion analysis indicated that the small subunit of RFC interacted strongly with the N-terminal domain of the catalytic subunit of the primase. RFC stimulated dinucleotide formation but decreased the amount of primers synthesized by the primase. The inhibition of primer synthesis is consistent with the observation that RFC reduced the affinity of the primase for DNA templates. On the other hand, primase stimulated the ATPase activity of RFC. These findings suggest that the primase-RFC interaction modulates the activities of both enzymes and therefore may be involved in the regulation of primer synthesis and the transfer of primers to DNA polymerase in Archaea.     

The Alarmone (p)ppGpp Regulates Primer Extension by Bacterial Primase

Primase is an essential component of the DNA replication machinery, responsible for synthesizing RNA primers that initiate leading and lagging strand DNA synthesis. Bacterial primase activity can be regulated by the starvation-inducible nucleotide (p)ppGpp. This regulation contributes to a timely inhibition of DNA replication upon amino acid starvation in the Gram-positive bacterium Bacillus subtilis. Here, we characterize the effect of (p)ppGpp on B. subtilis DnaG primase activity in vitro. Using a single-nucleotide resolution primase assay, we dissected the effect of ppGpp on the initiation, extension, and fidelity of B. subtilis primase. We found that ppGpp has a mild effect on initiation, but strongly inhibits primer extension and reduces primase processivity, promoting termination of primer extension. High (p)ppGpp concentration, together with low GTP concentration, additively inhibit primase activity. This explains the strong inhibition of replication elongation during starvation which induces high levels of (p)ppGpp and depletion of GTP in B. subtilis. Finally, we found that lowering GTP concentration results in mismatches in primer base pairing that allow priming readthrough, and that ppGpp reduces readthrough to protect priming fidelity. These results highlight the importance of (p)ppGpp in protecting replisome integrity and genome stability in fluctuating nucleotide concentrations upon onset of environmental stress.     

Studies of the DNA helicase-RNA primase unit from bacteriophage T4. A trinucleotide sequence on the DNA template starts RNA primer synthesis

The purified DNA replication proteins encoded by genes 41 and 61 of bacteriophage T4 catalyze efficient RNA primer synthesis on a single-stranded DNA template. In the presence of additional T4 replication proteins, we demonstrate that the template sequences 5'-GTT-3' and 5'-GCT-3' serve as necessary and sufficient signals for RNA primer-dependent initiation of new DNA chains. These chains start with primers that have the sequences pppApCpNpNpN and pppGpCpNpNpN, where N can be any one of the four ribonucleotides. Each primer is initiated from the T (A-start primers) or C (G-start primers) in the center of the recognized template sequence. A subset of the DNA chain starts is observed when one of the four ribonucleoside triphosphates used as the substrates for primer synthesis is omitted; the starts observed reveal that both pentaribonucleotide and tetraribonucleotide primers can be used for efficient initiation of new DNA chains, whereas primers that are only 3 nucleotides long are inactive. It was known previously that, when 61 protein is present in catalytic amounts, the 41 and 61 proteins are both required for observing RNA primer synthesis. However, by raising the concentration of the 61 protein to a much higher level, a substantial amount of RNA-primed DNA synthesis is obtained in the absence of 41 protein. The DNA chains made are initiated by primers that seem to be identical to those made when both 41 and 61 proteins are present; however, only those template sites containing the 5'-GCT-3' sequence are utilized. The 61 protein is, therefore, the RNA primase, whereas the 41 protein should be viewed as a DNA helicase that is required (presumably via a 41/61 complex) for efficient primase recognition of both the 5'-GCT-3' and 5'-GTT-3' DNA template sequences.     

Precise mapping and characterization of the RNA primers of DNA replication for a yeast hypersuppressive petite by in vitro capping with guanylyltransferase.

The active origins of DNA replication for yeast (Saccharomyces cerevisiae) mitochondrial DNA share 280 conserved base pairs and have a promoter. Since intact replication intermediates retain their initiating ribonucleotide triphosphate, we used guanylyltransferase to in vitro cap the replication intermediates present in restriction enzyme-cut DNA from an ori-5 hypersuppressive petite. Restriction mapping and RNA sequencing of these labeled intermediates showed that each DNA strand is primed at a single discrete nucleotide, that one primer starts at the promoter and that the other primer starts 34 nt away, outside the conserved region. Deoxyribonuclease digestion of the capped fragments left resistant RNA primers, which enabled identification of zones of transition from RNA to DNA synthesis. Some of the results contradict the prevailing model for priming at the yeast mitochondrial origins.     

In vitro reconstitution reveals a key role of human mitochondrial EXOG in RNA primer processing

The removal of RNA primers is essential for mitochondrial DNA (mtDNA) replication. Several nucleases have been implicated in RNA primer removal in human mitochondria, however, no conclusive mechanism has been elucidated. Here, we reconstituted minimal in vitro system capable of processing RNA primers into ligatable DNA ends. We show that human 5′-3′ exonuclease, EXOG, plays a fundamental role in removal of the RNA primer. EXOG cleaves short and long RNA-containing flaps but also in cooperation with RNase H1, processes non-flap RNA-containing intermediates. Our data indicate that the enzymatic activity of both enzymes is necessary to process non-flap RNA-containing intermediates and that regardless of the pathway, EXOG-mediated RNA cleavage is necessary prior to ligation by DNA Ligase III. We also show that upregulation of EXOG levels in mitochondria increases ligation efficiency of RNA-containing substrates and discover physical interactions, both in vitro and in cellulo, between RNase H1 and EXOG, Pol γA, Pol γB and Lig III but not FEN1, which we demonstrate to be absent from mitochondria of human lung epithelial cells. Together, using human mtDNA replication enzymes, we reconstitute for the first time RNA primer removal reaction and propose a novel model for RNA primer processing in human mitochondria.     

蛋白质起始的DNA病毒复制机制

DNA聚合酶在DNA合成过程中需要的引物包括RNA引物、DNA自我引物和蛋白质引物3种类型。新DNA链(如冈崎片段)的复制多是在DNA模板上合成一段RNA引物,细小病毒利用其基因组末端的反向末端重复序列(ITRs)自我折叠成DNA引物,而一些DNA、RNA病毒及真菌质粒起始复制反应的引物则是蛋白质。以感染原核生物的噬菌体Phi29和真核DNA病毒腺病毒为例,从复制过程所涉及的蛋白质、对复制原点的识别、复制起始反应、新链的延伸、复制终止过程等方面详细阐述DNA病毒由蛋白质引发的复制机制,并对已商品化的Phi29 DNA聚合酶产品多重置换扩增及单细胞测序等的应用以及基于噬菌体Phi29蛋白质起始的最小复制系统体外扩增异源DNA等最新的应用研究作相关总结介绍。     

Flexible tethering of primase and DNA Pol α in the eukaryotic primosome

The Pol α/primase complex or primosome is the primase/polymerase complex that initiates nucleic acid synthesis during eukaryotic replication. Within the primosome, the primase synthesizes short RNA primers that undergo limited extension by Pol α. The resulting RNA–DNA primers are utilized by Pol δ and Pol ε for processive elongation on the lagging and leading strands, respectively. Despite its importance, the mechanism of RNA–DNA primer synthesis remains poorly understood. Here, we describe a structural model of the yeast primosome based on electron microscopy and functional studies. The 3D architecture of the primosome reveals an asymmetric, dumbbell-shaped particle. The catalytic centers of primase and Pol α reside in separate lobes of high relative mobility. The flexible tethering of the primosome lobes increases the efficiency of primer transfer between primase and Pol α. The physical organization of the primosome suggests that a concerted mechanism of primer hand-off between primase and Pol α would involve coordinated movements of the primosome lobes. The first three-dimensional map of the eukaryotic primosome at 25 Å resolution provides an essential structural template for understanding initiation of eukaryotic replication.     

A complex of the bacteriophage T7 primase-helicase and DNA polymerase directs primer utilization

The lagging strand of the replication fork is initially copied as short Okazaki fragments produced by the coupled activities of two template-dependent enzymes, a primase that synthesizes RNA primers and a DNA polymerase that elongates them. Gene 4 of bacteriophage T7 encodes a bifunctional primase-helicase that assembles into a ring-shaped hexamer with both DNA unwinding and primer synthesis activities. The primase is also required for the utilization of RNA primers by T7 DNA polymerase. It is not known how many subunits of the primase-helicase hexamer participate directly in the priming of DNA synthesis. In order to determine the minimal requirements for RNA primer utilization by T7 DNA polymerase, we created an altered gene 4 protein that does not form functional hexamers and consequently lacks detectable DNA unwinding activity. Remarkably, this monomeric primase readily primes DNA synthesis by T7 DNA polymerase on single-stranded templates. The monomeric gene 4 protein forms a specific and stable complex with T7 DNA polymerase and thereby delivers the RNA primer to the polymerase for the onset of DNA synthesis. These results show that a single subunit of the primase-helicase hexamer contains all of the residues required for primer synthesis and for utilization of primers by T7 DNA polymerase.     

Archaeal primase: bridging the gap between RNA and DNA polymerases

In the evolution of life, DNA replication is a fundamental process, by which species transfer their genetic information to their offspring. DNA polymerases, including bacterial and eukaryotic replicases, are incapable of de novo DNA synthesis. DNA primases are required for this function, which is sine qua non to DNA replication. In Escherichia coli, the DNA primase (DnaG) exists as a monomer and synthesizes a short RNA primer. In Eukarya, however, the primase activity resides within the DNA polymerase alpha-primase complex (Pol alpha-pri) on the p48 subunit, which synthesizes the short RNA segment of a hybrid RNA-DNA primer. To date, very little information is available regarding the priming of DNA replication in organisms in Archaea. Available sequenced genomes indicate that the archaeal DNA primase is a homolog of the eukaryotic p48 subunit. Here, we report investigations of a p48-like DNA primase from Pyrococcus furiosus, a hyperthermophilic euryarchaeote. P. furiosus p48-like protein (Pfup41), unlike hitherto-reported primases, does not catalyze by itself the synthesis of short RNA primers but preferentially utilizes deoxynucleotides to synthesize DNA fragments up to several kilobases in length. Pfup41 is the first DNA polymerase that does not require primers for the synthesis of long DNA strands.