在单个PCR管内快捷完成定点突变

采用大引物方法,利用质粒多克隆位点两侧的普通测序引物作为旁侧引物,在单个PCR管内,经2个步骤共34个循环进行定点突变. 该方法通过优化模板和引物的量达到降低PCR循环次数, 通过加入10个在68℃复性条件下的PCR循环达到增加突变效率而无需胶纯化.本方法达到平均62%的突变效率,而且全长扩增产物的产率很高.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. II. Frequency of primer synthesis and efficiency of primer utilization control Okazaki fragment size.

To investigate the role of the priming apparatus at the replication fork in determining Okazaki fragment size, the products of primer synthesis generated in vitro during rolling-circle DNA replication catalyzed by the DNA polymerase III holoenzyme, the single-stranded DNA binding protein, and the primosome on a tailed form II DNA template were isolated and characterized. The abundance of oligoribonucleotide primers and the incidence of covalent DNA chain extension of the primer population was measured under different reaction conditions known to affect the size of the products of lagging-strand DNA synthesis. These analyses demonstrated that the factors affecting Okazaki fragment length could be distinguished by either their effect on the frequency of primer synthesis or by their influence on the efficiency of initiation of DNA synthesis from primer termini. Primase and the ribonucleoside triphosphates were found to stimulate primer synthesis. The observed trend toward smaller fragment size as the concentration of these effectors was raised was apparently a direct consequence of the increased frequency of primer synthesis. The beta subunit of the DNA polymerase III holoenzyme and the deoxyribonucleoside triphosphates did not alter the priming frequency; instead, the concentration of these factors influenced the ability of the lagging-strand DNA polymerase to efficiently utilize primers to initiate DNA synthesis. Maximum utilization of the available primers correlated with the lowest mean value of Okazaki fragment length. These data were used to draw general conclusions concerning the temporal order of enzymatic steps that operate during a cycle of Okazaki fragment synthesis on the lagging-strand DNA template.     

Key role of template sequence for primer synthesis by the herpes simplex virus 1 helicase-primase

We investigated the effects of ssDNA template sequence on both primer synthesis and NTP hydrolysis by herpes simplex virus 1 helicase-primase. Primer synthesis was found to be profoundly dependent upon template sequence. Although not absolutely required, an important sequence feature for significant production of longer primers (beyond four nucleotides in length) is a deoxyguanylate-pyrimidine-pyrimidine (3'-G-pyr-pyr-5') triplet in the template. The deoxyguanylate serves both to direct primase to initiate synthesis opposite the adjacent pyrimidine and to dramatically increase primer length. While primase synthesized significantly more long primers on those templates containing a G-pyr-pyr triplet, the enzyme still synthesized massive quantities of di- and trinucleotides on many templates containing this sequence. Varying the sequences around the G-pyr-pyr recognition sequence dramatically altered both the rate of primer synthesis and the fraction of primers longer than four nucleotides, indicating that primase must interact with both the G-pyr-pyr and flanking sequences in the template. In contrast to the large effects that varying the template sequence had on primase activity, ssDNA-dependent NTPase activity was essentially unaffected by changes in template sequence, including the presence or absence of the G-pyr-pyr trinucleotide. In addition to hydrolyzing NTPs the NTPase could also hydrolyze the 5'-terminal phosphate from newly synthesized primers.     

Blocking primers to enhance PCR amplification of rare sequences in mixed samples – a case study on prey DNA in Antarctic krill stomachs

Background

Identification of DNA sequence diversity is a powerful means for assessing the species present in environmental samples. The most common molecular strategies for estimating taxonomic composition depend upon PCR with universal primers that amplify an orthologous DNA region from a range of species. The diversity of sequences within a sample that can be detected by universal primers is often compromised by high concentrations of some DNA templates. If the DNA within the sample contains a small number of sequences in relatively high concentrations, then less concentrated sequences are often not amplified because the PCR favours the dominant DNA types. This is a particular problem in molecular diet studies, where predator DNA is often present in great excess of food-derived DNA.

Results

We have developed a strategy where a universal PCR simultaneously amplifies DNA from food items present in DNA purified from stomach samples, while the predator's own DNA is blocked from amplification by the addition of a modified predator-specific blocking primer. Three different types of modified primers were tested out; one annealing inhibiting primer overlapping with the 3' end of one of the universal primers, another annealing inhibiting primer also having an internal modification of five dI molecules making it a dual priming oligo, and a third elongation arrest primer located between the two universal primers. All blocking primers were modified with a C3 spacer. In artificial PCR mixtures, annealing inhibiting primers proved to be the most efficient ones and this method reduced predator amplicons to undetectable levels even when predator template was present in 1000 fold excess of the prey template. The prey template then showed strong PCR amplification where none was detectable without the addition of blocking primer. Our method was applied to identifying the winter food of one of the most abundant animals in the world, the Antarctic krill, Euphausia superba. Dietary item DNA was PCR amplified from a range of species in krill stomachs for which we had no prior sequence knowledge.

Conclusion

We present a simple, robust and cheap method that is easily adaptable to many situations where a rare DNA template is to be PCR amplified in the presence of a higher concentration template with identical PCR primer binding sites.     

通过PCR进行长片段DNA的合成

利用PCR合成DNA长片段(Synthesis Large Frament DNA using PCR,SLFD PCR)是一种有效的合成长片段DNA的方法。采用一段已知的500～600bp碱基的DNA片段为PCR模板,根据所要合成的DNA序列可以设计一系列的PCR引物,这些引物都位于模板DNA的5’端,长度为50～60bp,且从5’到3’方向顺序重叠,重叠碱基数目为12～15,全部引物叠加所得到的DNA正是自己所要合成的DNA。这组引物中最3’端的一条含有一个BamH Ⅰ酶切位点,在该位点后面有15碱基与模板DNA5’端一致的序列。另外还设计一条与该模板匹配的下游引物,引物内也含有一个BamH Ⅰ酶切位点。首先采用5’端最右侧的引物与下游引物进行PCR,在PCR进行10个循环后,以此次PCR的产物为下一轮PCR的模板,该轮PCR采用右侧倒数第二个引物为上游引物,下游引物保持不变。采用类似的方法,完成所有的PCR循环,就可以得到所需要合成的DNA长片段。该方法尤其适合100～200碱基左右的长片段DNA的快速合成与克隆。     

DNA聚合酶与引物/模板的相互作用对PCR效率的影响

PCR是体外酶促合成特异DNA片段的一种方法,引物的优劣直接关系到PCR的特异性与成功与否。传统的PCR引物设计软件基本上忽略了DNA聚合酶与引物/模板的亲和性对PCR效率的影响。为揭示DNA聚合酶与引物/模板的相互作用是否对PCR的效率有影响,通过构建Taq DNA 聚合酶与不同序列引物/模板DNA相互作用的三维结构模型,采用MM/GBSA方法计算复合物的结合自由能,以结合自由能为参数,为人血清白蛋白基因(Human Serum Albumin gene,HSA gene)和结核杆菌pyrF基因(Mycobacterium tuberculosis pyrF gene)设计了PCR引物。PCR实验结果表明,引物的PCR效率与结合自由能相关：引物与聚合酶的结合自由能越低,PCR实验的效率相对越高。这说明DNA聚合酶与引物/模板的相互作用对PCR效率有重要影响。因此,引物/模板DNA与聚合酶的结合自由能可以作为PCR引物设计的新参数。     

DNA sequencing by synthesis with degenerate primers

The degenerate primer-based sequencing Was developed by a synthesis method(DP-SBS)for high-throughput DNA sequencing,in which a set of degenerate primers are hybridized on the arrayed DNA templates and extended by DNA polymerase on microarrays.In this method,adifferent set of degenerate primers containing a give nnumber(n)of degenerate nucleotides at the 3'-ends were annealed to the sequenced templates that were immobilized on the solid surface.The nucleotides(n 1)on the template sequences were determined by detecting the incorporation of fluorescent labeled nucleotides.The fluorescent labeled nucleotide was incorporated into the primer in a base-specific manner after the enzymatic primer extension reactions and nine-base length were read out accurately.The main advanmge of the DP-SBS is that the method only uses very conventional biochemical reagents and avoids the complicated special chemical reagents for removing the labeled nucleotides and reactivating the primer for further extension.From the present study,it is found that the DP-SBS method is reliable,simple,and cost-effective for laboratory-sequencing a large amount of short DNA fragments.     

Chemical primer extension: individual steps of spontaneous replication

The replication of genetic information, as we know it from today's biology, relies on template-directed, polymerase-catalyzed extension of primers. It is known that short stretches of complementary RNA can form on templates in the absence of enzymes. This account summarizes recent work on efficient enzyme-free primer extension, both with 3'-amino-terminal deoxyribonucleotide primers and with primers made of unmodified RNA. Near-quantitative primer extension with half-life times on the order of hours has been demonstrated by using azaoxybenzotriazolides of nucleotides and downstream-binding oligomers. Further, small non-nucleosidic substituents placed on the terminus of the template or the downstream-binding oligomer have been shown to increase the rate and fidelity of primer-extension reactions. Since all four templating bases (A, C, G, T/U) direct sequence-selective primer-extension steps, we feel that there is renewed hope that full, nonenzymatic replication from monomers may eventually be achieved.     

Efficient site directed in vitro mutagenesis using ampicillin selection.

A novel plasmid vector pSELECT-1 is described which can be used for highly efficient site-directed in vitro mutagenesis. The mutagenesis method is based on the use of single-stranded DNA and two primers, one mutagenic primer and a second correction primer which corrects a defect in the ampicillin resistance gene on the vector and reverts the vector to ampicillin resistance. Using T4 DNA polymerase and T4 DNA ligase the two primers are physically linked on the template. The non-mutant DNA strand is selected against by growth in the presence of ampicillin. In tests of the vector, highly efficient (60-90%) mutagenesis was obtained.     

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.     

Deconstructing the Polymerase Chain Reaction: Understanding and Correcting Bias Associated with Primer Degeneracies and Primer-Template Mismatches

The polymerase chain reaction (PCR) is sensitive to mismatches between primer and template, and mismatches can lead to inefficient amplification of targeted regions of DNA template. In PCRs in which a degenerate primer pool is employed, each primer can behave differently. Therefore, inefficiencies due to different primer melting temperatures within a degenerate primer pool, in addition to mismatches between primer binding sites and primers, can lead to a distortion of the true relative abundance of targets in the original DNA pool. A theoretical analysis indicated that a combination of primer-template and primer-amplicon interactions during PCR cycles 3–12 is potentially responsible for this distortion. To test this hypothesis, we developed a novel amplification strategy, entitled “Polymerase-exonuclease (PEX) PCR”, in which primer-template interactions and primer-amplicon interactions are separated. The PEX PCR method substantially and significantly improved the evenness of recovery of sequences from a mock community of known composition, and allowed for amplification of templates with introduced mismatches near the 3’ end of the primer annealing sites. When the PEX PCR method was applied to genomic DNA extracted from complex environmental samples, a significant shift in the observed microbial community was detected. Furthermore, the PEX PCR method provides a mechanism to identify which primers in a primer pool are annealing to target gDNA. Primer utilization patterns revealed that at high annealing temperatures in the PEX PCR method, perfect match annealing predominates, while at lower annealing temperatures, primers with up to four mismatches with templates can contribute substantially to amplification. The PEX PCR method is simple to perform, is limited to PCR mixes and a single exonuclease step which can be performed without reaction cleanup, and is recommended for reactions in which degenerate primer pools are used or when mismatches between primers and template are possible.     

A novel PCR strategy for high-efficiency, automated site-directed mutagenesis

We have developed a novel three-primer, one-step PCR-based method for site-directed mutagenesis. This method takes advantage of the fact that template plasmid DNA cannot be efficiently denatured at its reannealing temperature (T_ra), which is otherwise a troublesome problem in regular PCR. Two flanking primers and one mutagenic primer with different melting temperatures (T_m) are used together in a single PCR tube continuously without any intervention. A single-stranded mutagenic DNA (smDNA) is synthesized utilizing the high T_m mutagenic primer at a high annealing temperature, which prevents the priming of the low T_m primers (i.e. the two flanking primers). A megaprimer is then produced using this smDNA as the template at a denaturing temperature that prevents wild-type template DNA activity. The desired mutant DNA is then obtained by cycling again through these first two steps, resulting in a mutagenic efficiency of 100% in all tested cases. This highly automated method not only eliminates the necessity of any intermediate manipulation and accomplishes the mutagenesis process in a single round of PCR but, most notably, enables complete success of mutagenesis. This novel method is also both cost and time efficient and fully automated.     

DNA sequencing using differential extension with nucleotide subsets (DENS).

Here we describe template directed enzymatic synthesis of unique primers, avoiding the chemical synthesis step in primer walking. We have termed this conceptually new technique DENS (differential extension with nucleotide subsets). DENS works by selectively extending a short primer, making it a long one at the intended site only. The procedure starts with a limited initial extension of the primer (at 20-30 degrees C) in the presence of only two out of the four possible dNTPs. The primer is extended by 6-9 bases or longer at the intended priming site, which is deliberately selected, (as is the two-dNTP set), to maximize the extension length. The subsequent termination reaction at 60-65 degrees C then accepts the extended primer at the intended site, but not at alternative sites, where the initial extension (if any) is generally much shorter. DENS allows the use of primers as long as 8mers (degenerate in two positions) which prime much more strongly than modular primers involving 5-7mers and which (unlike the latter) can be used with thermostable polymerases, thus allowing cycle-sequencing with dye-terminators compatible with Taq DNA polymerase, as well as making double-stranded DNA sequencing more robust.     

DnaB helicase stimulates primer synthesis activity on short oligonucleotide templates

DnaB helicase stimulated the second-order RNA primer synthesis activity of primase by over 5000-fold on DNA templates that were 23 nucleotides long. This template length is the same as the DnaB helicase thermodynamic binding site size [Jezewska, M. J., and Bujalowski, W. (1996) Biochemistry 35, 2117-2128]. This phenomenal stimulation was achieved by increasing the template affinity of primase by over 300-fold and increasing the catalytic rate by over 15-fold. It was necessary to determine the optimal amount of DnaB helicase to achieve this stimulation because helicase stimulation was cooperative at low concentration and inhibitory at high helicase concentration. The cooperative stimulation at low concentration indicated the presence of a time-dependent assembly step that preceded the active state. Besides stimulating primase activity, DnaB helicase also prevented primase from synthesizing RNA primers that were longer than the template sequence. In the absence of DnaB helicase, the majority of primers synthesized by primase were longer than the template and were named "overlong primers" [Swart, J. R., and Griep, M. A. (1995) Biochemistry 34, 16097-16106]. In contrast, the helicase-stimulated RNA primers were from 10 to 14 nucleotides in length with the 12-mer representing the majority of the total RNA primers produced. It was shown that DnaB helicase stabilized the open or single-stranded conformation of the template, which favored the synthesis of the template-length-dependent primers. In contrast, when primase acted alone, it stabilized the 3'-end hairpin conformation of the template so that the template's 3'-hydroxyl served as a "DNA primer" from which primase elongated to create the overlong primers.     

Comparative study of the efficacy of modifying DNA polymerase and DNA matrix by different photoactive groups at the 3'-end of the DNA primer

The dependence of the modification efficiency of DNA polymerases and DNA template on the nature of photoactivatable group and the length of the linker that joins the group with the heterocyclic base of the primer 3'-terminal nucleotide was studied. The primers that contained the photoreactive groups at their 3'-termini were obtained using the rat DNA polymerase beta or the DNA polymerase from Thermus thermophilus in the presence of one of the dTTP analogues carrying the photoreactive group in position 5 of thymidine residue. After irradiating the reaction mixture with UV light and separating the modification products, the level of covalent binding of the [5'-32P]primer to DNA polymerases and template was determined. The primers containing 4-azido-2,5-difluoro-3-chloropyridyl group were shown to be the most effective in the modification of DNA polymerases.     

Effect of primer mismatch, annealing temperature and PCR cycle number on 16S rRNA gene-targetting bacterial community analysis

In the attempt to explore complex bacterial communities of environmental samples, primers hybridizing to phylogenetically highly conserved regions of 16S rRNA genes are widely used, but differential amplification is a recognized problem. The biases associated with preferential amplification of multitemplate PCR were investigated using 'universal' bacteria-specific primers, focusing on the effect of primer mismatch, annealing temperature and PCR cycle number. The distortion of the template-to-product ratio was measured using predefined template mixtures and environmental samples by terminal restriction fragment length polymorphism analysis. When a 1 : 1 genomic DNA template mixture of two strains was used, primer mismatches inherent in the 63F primer presented a serious bias, showing preferential amplification of the template containing the perfectly matching sequence. The extent of the preferential amplification showed an almost exponential relation with increasing annealing temperature from 47 to 61 degrees C. No negative effect of the various annealing temperatures was observed with the 27F primer, with no mismatches with the target sequences. The number of PCR cycles had little influence on the template-to-product ratios. As a result of additional tests on environmental samples, the use of a low annealing temperature is recommended in order to significantly reduce preferential amplification while maintaining the specificity of PCR.     

Transcriptional role in DNA replication: degradation of RNA primer during DNA synthesis

DNA synthesis catalyzed in vitro by E. coli DNA polymeraseI in the presence of single stranded fd DNA or poly (dT) as template is stimulated by RNA primers. When poly(dT) fully or partially saturated with polyriboadenylic acid strands is used as template - primer, DNA synthesis proceeds with concomitant degradation of the ribostrands to 5′-adenosine monophosphate. The fragment of DNA polymerase lacking the 5′→3′ exonuclease shows comparable RNA primer dependency but reduced efficiency for the degradation of the RNA primer from the 5′-end.