Linhua Fang scite author profile

Fundamental to most genetic analysis is availability of genomic DNA of adequate quality and quantity. Because DNA yield from human samples is frequently limiting, much effort has been invested in developing methods for whole genome amplification (WGA) by random or degenerate oligonucleotide-primed PCR. However, existing WGA methods like degenerate oligonucleotideprimed PCR suffer from incomplete coverage and inadequate average DNA size. We describe a method, termed multiple displacement amplification (MDA), which provides a highly uniform representation across the genome. Amplification bias among eight chromosomal loci was less than 3-fold in contrast to 4 -6 orders of magnitude for PCR-based WGA methods. Average product length was >10 kb. MDA is an isothermal, strand-displacing amplification yielding about 20 -30 g product from as few as 1-10 copies of human genomic DNA. Amplification can be carried out directly from biological samples including crude whole blood and tissue culture cells. MDA-amplified human DNA is useful for several common methods of genetic analysis, including genotyping of single nucleotide polymorphisms, chromosome painting, Southern blotting and restriction fragment length polymorphism analysis, subcloning, and DNA sequencing. MDA-based WGA is a simple and reliable method that could have significant implications for genetic studies, forensics, diagnostics, and long-term sample storage.F or genomic studies, the quality and quantity of DNA samples is critical. High-throughput genetic analysis requires large amounts of template for testing, yet typically the yield of DNA from individual patient samples is limited. Forensic and paleoarcheology work also can be severely limited by DNA sample size. An important goal is to supply a sufficient amount of genomic sequence for a variety of procedures as well as longterm storage for future work and archiving of patient samples. Methods include the time-consuming process of creating of Epstein-Barr virus-transformed cell lines and whole genome amplification (WGA) by random or degenerate oligonucleotideprimed PCR (DOP-PCR) (1-3). However, PCR-based WGA methods may generate nonspecific amplification artifacts (2), give incomplete coverage of loci (4), and generate DNA less than 1 kb long (1-3) that cannot be used in many applications.Recently, a rolling circle amplification (5) method was developed for amplifying large circular DNA templates such as plasmid and bacteriophage DNA (6). Using 29 DNA polymerase and random exonuclease-resistant primers, DNA was amplified in a 30°C reaction not requiring thermal cycling. This is made possible in part by the great processivity of 29 DNA polymerase, which synthesizes DNA strands 70 kb in length (7). Here we extend the use of exonuclease-resistant primers and 29 DNA polymerase to WGA. The amplification is surprisingly uniform across the genomic target, with the relative representation of different loci differing by less than 3-fold. In contrast, PCR-based WGA methods exhibited strong amplification bias ranging fr...

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The DnaC helicase loader is a dual ATP/ADP switch protein

Davey

et al. 2002

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Helicases are transferred to replication origins by helicase loading factors. The Escherichia coli DnaC and eukaryotic Cdc6/18 helicase loaders contain ATP sites and are both members of the AAA+ family. One might expect that ATP is required for helicase loading; however, this study on DnaC illustrates that ATP is not actually needed for DnaC to load helicase onto single‐strand DNA (ssDNA). In fact, it seems to be a paradox that after transfer of helicase to DNA, DnaC–ATP inhibits helicase action. In addition, ATP is required for DnaC function at an early step in oriC replication in which ATP stimulates ssDNA binding by DnaC, leading to expansion of the ssDNA bubble at the origin. Two cofactors, ssDNA and DnaB, trigger hydrolysis of ATP, converting DnaC to the ADP form that no longer inhibits DnaB. These observations have led to the idea that DnaC is a ‘dual’ switch protein, where both the ATP and the ADP forms are sequentially required for replication. This dual switching process may underlie the sensitivity of DnaB to even small fluctuations in DnaC levels.

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Replisome Assembly at oriC, the Replication Origin of E. coli, Reveals an Explanation for Initiation Sites outside an Origin

1999

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This study outlines the events downstream of origin unwinding by DnaA, leading to assembly of two replication forks at the E. coli origin, oriC. We show that two hexamers of DnaB assemble onto the opposing strands of the resulting bubble, expanding it further, yet helicase action is not required. Primase cannot act until the helicases move 65 nucleotides or more. Once primers are formed, two molecules of the large DNA polymerase III holoenzyme machinery assemble into the bubble, forming two replication forks. Primer locations are heterogeneous; some are even outside oriC. This observation generalizes to many systems, prokaryotic and eukaryotic. Heterogeneous initiation sites are likely explained by primase functioning with a moving helicase target.

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Assembly of a Chromosomal Replication Machine: Two DNA Polymerases, a Clamp Loader, and Sliding Clamps in One Holoenzyme Particle.

Naktinis

Onrust

Fang

et al. 1995

Journal of Biological Chemistry

148

153

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The nine-subunit DNA polymerase (Pol) III* coupled to its beta sliding clamp is a rapid and highly processive replicating machine. The multiple subunits are needed for the complicated task of duplicating the Escherichia coli chromosome. In this report, Pol III* was constituted from individual pure proteins, and its structure was studied. Constitution of the Pol III* particle requires an ordered addition of the subunits, and the final structure contains 14 polypeptides in the ratio alpha 2 epsilon 2 theta 2 tau 2 gamma 2 delta 1 delta' 1 chi 1 psi 1. The structure can be summarized as being composed of two core polymerases (alpha epsilon theta) held together by a dimer of tau and one gamma complex clamp loader (gamma 2 delta 1 delta' 1 chi 1 psi 1) for loading beta onto DNA. At the center of the structure, the related tau and gamma subunits form a heterotetramer upon which the two core polymerases and clamp loader proteins assemble. The single copy nature of the delta, delta', chi, and psi subunits confers a structural asymmetry with respect to the two polymerases, presumably for the different functions of replicating the leading and lagging strands.

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Linhua Fang

Comprehensive human genome amplification using multiple displacement amplification

The DnaC helicase loader is a dual ATP/ADP switch protein

Replisome Assembly at oriC, the Replication Origin of E. coli, Reveals an Explanation for Initiation Sites outside an Origin

Assembly of a Chromosomal Replication Machine: Two DNA Polymerases, a Clamp Loader, and Sliding Clamps in One Holoenzyme Particle.

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