Double-stranded DNA segments can efficiently prime the amplification of human genomic DNA

Improvement in the Thermal Stability of Pyrophosphatase by Conjugation to Poly(N-isopropylacrylamide): Application to the Polymerase Chain Reaction

Polymerase chain reaction (PCR) is a powerful method for nucleic acid amplification. However, the PCR is inhibited in its yield due to its byproduct, pyrophosphate (PPi), a byproduct of the reaction; the yield is thereby limited. The conventional method for hydrolysis of PPi by pyrophosphatase (PPase) is not well adapted for operation at elevated temperatures over long times as required during the PCR. In this work, we reported a strategy to improve the PCR yield using a conjugate of the enzyme with the thermally responsive polymer poly(N-isopropylacrylamide) (PNIPAM). Pyrophosphatase (PPase) was conjugated to PNIPAM site-specifically near the active center. As compared to the free enzyme, the optimum temperature of the conjugate was shown to increase from 45 to 60 °C. For the conjugate, about 77% enzyme activity was retained after incubation at 60 °C for 3 h, representing a 6.8-fold increase as compared to the unconjugated enzyme. For the PCR using the conjugate, the yield was 1.5-fold greater than using the unconjugated enzyme. As well as improving the yield of the PCR (and possibly other biological reactions) at elevated temperature, polymer conjugation may also provide a strategy to improve the heat resistance of proteins more generally.

Megaprimer-mediated capsid swapping for the construction of custom-engineered chimeric foot-and-mouth disease virus

Foot-and-mouth disease (FMD) is a highly contagious, economically important disease of transboundary importance. Regular vaccination with chemically inactivated FMD vaccine is the major means of controlling the disease in endemic countries like India. However, the selection of appropriate candidate vaccine strain and its adaptation in cell culture to yield high titer of virus is a cumbersome process. An attractive approach to circumvent this tedious process is to replace the capsid coding sequence of an infectious full-genome length cDNA clone of a good vaccine strain with those of appropriate field strain, to produce custom-made chimeric FMD virus (FMDV). Nevertheless, the construction of chimeric virus can be difficult if the necessary endonuclease restriction sites are unavailable or unsuitable for swapping of the capsid sequence. Here we described an efficient method based on megaprimer-mediated capsid swapping for the construction of chimeric FMDV cDNA clones. Using FMDV vaccine strain A IND 40/2000 infectious clone (pA(40/2000)) as a donor plasmid, we exchanged the capsid sequence of pA(40/2000) with that of the viruses belonging to serotypes O (n = 5), A (n = 2), and Asia 1 (n = 2), and subsequently generated infectious FMDV from their respective chimeric cDNA clones. The chimeric viruses exhibited comparable infection kinetics, plaque phenotypes, antigenic profiles, and virion stability to the parental viruses. The results from this study suggest that megaprimer-based reverse genetics technology is useful for engineering chimeric vaccine strains for use in the control and prevention of FMD in endemic countries.

Improving the protein activity and stability under acidic conditions via site-specific conjugation of a pH-responsive polyelectrolyte

Maintaining the protein activity and stability under acidic conditions is important in bioengineering and biomedical applications. Polyelectrolyte conjugation as a means of stabilizing proteins has received much recent attention. Retention of protein activity, and especially, improvement of protein stability by minimizing the number of polymer chains in the conjugate, as well as by choosing the optimal site for conjugation, is critical in practical applications. In this research, the cationic polyelectrolyte poly(2-(dimethylamino)ethyl methacrylate) (pDMAEMA) was conjugated to the inorganic pyrophosphatase (PPase) site specifically. Conjugation of pDMAEMA to the specific site N124 on the protein surface led to a significant increase in activity at acidic pH. At pH 4.0, the activity of the pDMAEMA-conjugated protein was increased 3-fold relative to the unconjugated one. Dynamic light scattering (DLS) measurements showed that the aggregation state of the protein depended on the polymer charge as the pH was varied. Protein aggregation at low pH was prevented by pDMAEMA conjugation, resulting in an increase in protein stability under acidic conditions. The conjugate retained 60% of its initial activity after 4 h at pH 4.0, whereas the unconjugated protein lost 40% of its initial activity within 15 min at this pH. These results suggest an approach for preserving the protein activity and stability at low pH based on site-specific polyelectrolyte conjugation to the protein surface, thereby providing a new strategy for expanding the use of proteins in an acidic environment.

TA strategy for rapid and efficient site-directed mutagenesis

A simple, rapid, and efficient site-directed mutagenesis method using TA strategy with synthetic mutagenic oligonucleotides is described. Briefly, a 3' A-overhang vector was prepared by polymerase chain reaction (PCR) using a classical Taq polymerase with terminal transferase activity, a reverse vector primer starting the complement nucleotide prior to the 5' end adenosine of the target, and a forward vector primer starting the nucleotide posterior to the 3' end thymidine. The 3' T-overhang mutagenic double-strand oligonucleotide was synthesized and cloned directly into the PCR-amplified 3' A-overhang vector. Thus, direct ligation of synthetic mutagenic oligonucleotides and PCR-amplified vector via TA sticky ends provides us with simple, rapid, and efficient site-directed mutagenesis.

Large-scale production of the immunomodulator c-di-GMP from GMP and ATP by an enzymatic cascade

(3'-5')-Cyclic diguanylate (c-di-GMP) is a bacterial second messenger with immunomodulatory activities in mice suggesting potential applications as a vaccine adjuvant and as a therapeutic agent. Clinical studies in larger animals or humans will require larger doses that are difficult and expensive to generate by currently available chemical or enzymatic synthesis and purification methods. Here we report the production of c-di-GMP at the multi-gram scale from the economical precursors guanosine monophosphate (GMP) and adenosine triphosphate by a "one-pot" three enzyme cascade consisting of GMP kinase, nucleoside diphosphate kinase, and a mutated form of diguanylate cyclase engineered to lack product inhibition. The c-di-GMP was purified to apparent homogeneity by a combination of anion exchange chromatography and solvent precipitation and was characterized by reversed phase high performance liquid chormatography and mass spectrometry, nuclear magnetic resonance spectroscopy, and further compositional analyses. The immunomodulatory activity of the c-di-GMP preparation was confirmed by its potentiating effect on the lipopolysaccharide-induced interleukin 1β, tumor necrosis factor α, and interleukin 6 messenger RNA expression in J774A.1 mouse macrophages.

Megaprimer-mediated domain swapping for construction of chimeric viruses

Clones that encode viral genomes constructed from two viruses with contrasting biological properties have been widely used in studies of viral-host interactions, particularly when the objective is to determine the identity of the viral component recognized by the host in a resistant response, known as the avirulence factor. This paper presents an efficient method based on megaprimer-mediated domain swapping for the construction of clones encoding chimeric viral genomes as a versatile and widely applicable alternative to conventional restriction enzyme digestion and ligation methods. Potato virus X (PVX)-derived vectors expressing genes encoding fluorescent proteins were used to demonstrate this concept. The cyan fluorescent protein (CFP) gene was cloned into a binary PVX vector and subsequently replaced with the yellow fluorescent protein (YFP) gene using the megaprimer amplification reaction. DNA fragments up to 1480 bp could be replaced efficiently and quickly. Most viral clones showed the expected change in phenotype without altered infectivity. Sequence analysis revealed mutations were not introduced into the four domain-swapped plasmids. This approach will provide a valuable tool for determining which domains of a viral genome are essential for infectivity, avirulence, or otherwise determine biologically significant properties of plant viruses.

Single-step DGGE-based mutation scanning of the p53 gene: application to genetic diagnosis of colorectal cancer

We present a simple nonradioactive assay based on polymerase chain reaction (PCR) in combination with denaturing gradient gel electrophoresis (DGGE), which allows comprehensive mutation scanning of the entire coding sequence and splice junctions of the p53 gene in one analytical step. The key features of the present method are (1) all fragments can be amplified using one common PCR protocol; (2) all fragments can be scanned for mutations on a single "broad-range" denaturing gradient gel; and (3) all fragments were tailored by the attachment of appropriate GC clamps and otherwise manipulated to consist of only two melting domains in order to maximize resolution of mutations by DGGE. The entire procedure starting with a sample of genomic DNA can be completed within 6 hr and has the potential to detect any sequence variation, irrespective of its location in the p53 gene. The mutation detection sensitivity was demonstrated by the analysis of 26 constructed control mutations distributed over the whole of the p53 gene. We have applied the method to genetic diagnosis in 43 cases of colorectal cancer. Overall, a point mutation, microdeletion, or microinsertion was found in 26 (61%) of the tumors. In addition to missense and frameshift mutations within exons 4-8, a 20-bp insertion in exon 11 was found in one sample, illustrating the importance of comprehensive gene scanning for reliable diagnosis.

Approaches to DNA mutagenesis: an overview

In the last several years, the use of double-stranded DNA templates together with thermostable-polymerase PCR has essentially replaced the use single-stranded DNA templates using the thermolabile polymerase for in vitro mutagenesis. Numerous PCR methods are now available, such as overlap-extension PCR, megaprimer PCR, and inverse PCR. All these PCR methods are reliable, effective, and convenient, although they are more prone to high rates of spontaneous error in mutant DNAs than are methods using thermolabile polymerases. Some improvements, such as the introduction of methylated templates, have been employed to minimize PCR errors. On the other hand, because of the introduction of many selection measures (e.g., restoration of antibiotic resistance, restoration of replication origin and unique site elimination), both double-stranded and single-stranded DNAs can now be used as templates for mutagenesis using thermolabile polymerase methods. For PCR methods, selection measures such as nested PCR has developed. All these selection measures have greatly improved the efficiency of mutagenesis by removing wild-type templates prior to transformation. Many efficient methods are available for both SDM and REM. Mutations can be introduce in vitro or in vivo, either by mutagenic primers or by erroneous DNA synthesis. Thus, choices largely depend on the experimental needs and resources of the investigator.

Rapid and efficient site-directed mutagenesis by single-tube 'megaprimer' PCR method

We describe a rapid and efficient megaprimer PCR procedure for site-directed mutagenesis that does not require any intermediate purification of DNA between the two rounds of PCR. This protocol is based on the design of forward and reverse flanking primers with significantly different melting temperatures ( T m). A megaprimer is synthesized in the first PCR reaction using a mutagenic primer, the low T m flanking primer and a low annealing temperature. The second PCR reaction is performed in the same tube as the first PCR and utilizes the high T m flanking primer, the megaprimer product of the first PCR and a high annealing temperature, which prevents priming by the low T m primer from the first PCR reaction. We have used this protocol with two different plasmids to produce cDNAs encoding seven distinct mutated proteins. We have observed an average mutagenesis efficiency of 82% in these experiments.

Overlapping PCR for bidirectional PCR amplification of specific alleles: a rapid one-tube method for simultaneously differentiating homozygotes and heterozygotes

Rapid detection of single-base changes is fundamental to molecular medicine. PASA (PCR Amplification of Specific Alleles) is a rapid method of genotyping single-base changes, but one reaction is required for each allele. Bidirectional PASA (Bi-PASA) was developed to distinguish between homozygotes and heterozygotes in one PCR reaction by utilizing novel primer design with appropriate cycling conditions. In Bi-PASA, one of the alleles is amplified by a PASA reaction in one direction while the second allele is amplified by a PASA reaction in the opposite direction. Two outer (P and Q) and two inner allele-specific (A and B) primers are required. In heterozygotes, three segments are amplified: a segment of size AQ resulting from one allele, another segment of size PB resulting from the second allele, and a combined segment of size PQ. In homozygotes, segment PQ and either segments AQ or PB amplify. The two inner primers (A and B) contain a relatively short complementary region and a 10-nucleotide G + C-rich 5' tail. The inner primers "switch" from low-efficiency to high-efficiency amplification when genomic DNA is replaced by previously amplified template DNA. In addition, the 5' tails prevent "megapriming". The parameters for optimizing Bi-PASA were investigated in detail for common mutations in the human factor V and catechol-O-methyltransferase genes. Guidelines for optimization of Bi-PASA also were developed and tested in a prospective study. Three additional Bi-PASA assays were optimized rapidly by utilizing these guidelines. In conclusion, Bi-PASA is a simple and rapid method for detecting the zygosity of known mutations in a single PCR reaction.

Identification of class II major histocompatibility complex and T cell receptor binding sites in the superantigen toxic shock syndrome toxin 1

Superantigens, in association with class II major histocompatibility complex (MHC) molecules, activate T cells bearing particular beta chain variable domains of the T cell receptor (TCR). Unlike conventional peptide antigens, superantigens bind as intact proteins to TCR and MHC molecules outside their peptide binding sites. To characterize these interactions at the molecular level, random point mutations were generated in the gene encoding toxic shock syndrome toxin 1, a bacterial superantigen associated with toxic shock syndrome. Functionally impaired mutants were identified based on their lack of murine and human T cell stimulatory activities, and experiments analyzing binding to human histocompatibility leukocyte antigen-DR molecules differentiated residues involved in MHC from TCR binding. The results showed that the great majority of mutations are clustered in two distinct regions of the toxic shock syndrome toxin 1 molecule. The class II MHC binding site is located in the hydrophobic region of the NH2-terminal domain, and the TCR binding site is primarily in the major central groove of the COOH-terminal domain. These studies provide insight into the interactions necessary for superantigen-mediated disease in humans.

An efficient 1-tube PCR method for internal site-directed mutagenesis of large amplified molecules

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