The "megaprimer" method of site-directed mutagenesis

We describe a simple and efficient method of mutagenesis which we term the "megaprimer" method. The method utilizes three oligonucleotide primers to perform two rounds of polymerase chain reaction. In the method, the product of the first polymerase chain reaction is used as one of the polymerase chain reaction primers (a "megaprimer") for the second polymerase chain reaction. When a phage promoter and a translational initiation signal are attached to the appropriate oligonucleotide primer, the mutant protein can be generated without any in vivo manipulations. To illustrate the method, two mutations in the catalytic domain of the human factor IX gene have been generated. The substitution of megaprimers for oligonucleotide primers may have utility in other polymerase chain reaction-based methods.     

Rapid nested-PCR for tyrosinase gene detection on chip

The availability of non-invasive, fast and sensitive technologies for detection of circulating cancer cells is still a critical need of clinical oncology, particularly for diagnosis of aggressive and highly metastatic tumors, like malignant melanoma. Here we present the first nested polymerase chain reaction process carried out by a microfabricated, hybrid plastic-glass microfluidic chip on the tyrosinase gene, a predictive marker for melanoma diagnosis. The device is a hybrid system consisting of a glass microchannel embedded in an elastomeric matrix, and operating in flow-oscillating modality on a droplet of biological sample. The convection heat transfer and the temperature distribution inside the carrier fluid in the device are investigated. The oil responds to temperature changes with a characteristic time around 53 s, and exhibits three different thermal gradients along the capillary, with temperature variations below 4°C in correspondence of heater electrodes. The sample heating/cooling rates in the chip are as high as 16°C/s, allowing rapid processes. The nested polymerase chain reaction process is performed in less than 50 min, namely more than four times faster than in a standard thermocycler. The rapidity of the analysis method, combined with the simple and low-cost fabrication, reduced sample evaporation, and flexibility of the overall microfluidic platform, make it promising for the detection of events of tumor spreading.     

Neuro-genetic optimization of temperature control for a continuous flow polymerase chain reaction microdevice

In this study, a hybridized neuro-genetic optimization methodology realized by embedding finite element analysis (FEA) trained artificial neural networks (ANN) into genetic algorithms (GA), is used to optimize temperature control in a ceramic based continuous flow polymerase chain reaction (CPCR) device. The CPCR device requires three thermally isolated reaction zones of 94 degrees C, 65 degrees C, and 72 degrees C for the denaturing, annealing, and extension processes, respectively, to complete a cycle of polymerase chain reaction. The most important aspect of temperature control in the CPCR is to maintain temperature distribution at each reaction zone with a precision of +/-1 degree C or better, irrespective of changing ambient conditions. Results obtained from the FEA simulation shows good comparison with published experimental work for the temperature control in each reaction zone of the microfluidic channels. The simulation data are then used to train the ANN to predict the temperature distribution of the microfluidic channel for various heater input power and fluid flow rate. Once trained, the ANN analysis is able to predict the temperature distribution in the microchannel in less than 20 min, whereas the FEA simulation takes approximately 7 h to do so. The final optimization of temperature control in the CPCR device is achieved by embedding the trained ANN results as a fitness function into GA. Finally, the GA optimized results are used to build a new FEA model for numerical simulation analysis. The simulation results for the neuro-genetic optimized CPCR model and the initial CPCR model are then compared. The neuro-genetic optimized model shows a significant improvement from the initial model, establishing the optimization method's superiority.     

Integration of multiple PCR amplifications and DNA mutation analyses by using oligonucleotide microchip

We have developed a method for parallel independent on-chip amplification and the following sequence variation analysis of multiple DNA regions directly using microchip with an array of nanoliter gel pads containing specific sets of tethered primers. The method has three key features. First, DNA to be amplified is enriched at gel pads by its hybridization with immobilized primers. Second, different sets of specific primers are immobilized within various gel pads, and primers are detached within gel pads just before polymerase chain reaction to enhance the amplification. A gel pad may contain an additional permanently immobilized dormant primer that is activated to carry out the allele-specific primer extension reaction to detect mutations. Third, multiple polymerase chain reactions are confined within nanoliter gel pads covered and separated from each other with mineral oil. The method was applied to simultaneously identify several abundant drug-resistant mutations in three genes of Mycobacterium tuberculosis.     

Development of a competitive polymerase chain reaction assay for the ruminal bacterium Butyrivibrio fibrisolvens OB156 and its use for tracking an OB156-derived recombinant

A competitive polymerase chain reaction assay targeting the 16S rDNA was developed for quantitating the rumen bacterium Butyrivibrio fibrisolvens OB156. A competitor DNA, serving as an internal control in the competitive polymerase chain reaction reaction, was constructed by polymerase chain reaction using a looped oligo longer than the normal primer. Coamplification of the target DNA with known amounts of the competitor DNA allowed quantitation of the target DNA in both pure culture and mixed culture systems, where minimum quantifiable level of OB156 was 1.7x10(2) and 5.6x10(4) cells, respectively. When an erythromycin-resistant recombinant derived from OB156 was inoculated into a rumen fluid culture, its numbers decreased with time. The rate of decrease measured by the competitive polymerase chain reaction assay was much slower than the rate determined by culture enumeration using erythromycin selection. The competitive polymerase chain reaction assay also showed 48 h persistence of the recombinant at 10(4) ml(-1) even after disappearance of culturable recombinant, suggesting maintenance of the target DNA from uncultivable cells. In an in vivo tracking trial, the recombinant became undetectable within 72 h with either assay, indicating rapid hydrolysis and/or outflow of the cells from the rumen.     

An immunomagnetic separation polymerase chain reaction assay for rapid and ultra-sensitive detection of Cryptosporidium parvum in drinking water

A sensitive and rapid method was developed to detect Cryptosporidium parvum oocysts in drinking water. This molecular assay combined immunomagnetic separation with polymerase chain reaction amplification to detect very low levels of C. parvum oocysts. Magnetic beads coated with anti-cryptosporidium were used to capture oocysts directly from drinking water membrane filter concentrates, at the same time removing polymerase chain reaction inhibitory substances. The DNA was then extracted by the freeze-boil Chelex-100 treatment, followed by polymerase chain reaction. The immunomagnetic separation-polymerase chain reaction product was identified by non-radioactive hybridization using an internal oligonucleotide probe labelled with digoxigenin. This immunomagnetic separation-polymerase chain reaction assay can detect the presence of a single seeded oocyst in 5-100-1 samples of drinking water, thereby assuring the absence of C. parvum contamination in the sample under analysis.     

Identification of Trichinella isolates by polymerase chain reaction--restriction fragment length polymorphism of the mitochondrial cytochrome c-oxidase subunit I gene.

We developed a polymerase chain reaction based approach using restriction fragment length polymorphisms of the mitochondrial cytochrome c-oxidase subunit I to identify nine genotypes (Trichinella spiralis, Trichinella britovi-European strains, Trichinella britovi-Japanese strains, Trichinella nativa, Trichinella nelsoni, Trichinella T5, Trichinella T6, Trichinella T8 and Trichinella pseudospiralis) in the genus Trichinella. Partial mitochondrial cytochrome c-oxidase subunit I genes of nine genotypes were amplified by polymerase chain reaction, sequenced, and digested with three restriction endonucleases (Mse I, Alu I and Bsp1248 I). This polymerase chain reaction based restriction fragment length polymorphism method allowed the identification of Trichinella genotypes. Trichinella spiralis, Trichinella britovi-Japanese strains, Trichinella nelsoni, T5 and Trichinella pseudospiralis were distinguishable by digestion with Mse I. Trichinella britovi-European strains and Trichinella T8 were distinguishable by digestion using Alu I, and Trichinella nativa and Trichinella T6 were distinguishable by double-digestion with Mse I and Bsp1286 I. The results obtained with this polymerase chain reaction based restriction fragment length polymorphism assay confirmed those previously reported by others and support the separation of the Japanese isolates as a new genotype, namely Trichinella T9.     

Plastic microfluidic chip for continuous-flow polymerase chain reaction: simulations and experiments

A continuous flow polymerase chain reaction (CF-PCR) device comprises a single fluidic channel that is heated differentially to create spatial temperature variations such that a sample flowing through it experiences the thermal cycling required to induce amplification. This type of device can provide an effective means to detect the presence of a small amount of nucleic acid in very small sample volumes. CF-PCR is attractive for global health applications due to its less stringent requirements for temperature control than for other designs. For mass production of inexpensive CF-PCR devices, fabrication via thermoplastic molding will likely be necessary. Here we study the optimization of a PCR assay in a polymeric CF-PCR device. Three channel designs, with varying residence time ratios for the three PCR steps (denaturation, annealing, and extension), were modeled, built, and tested. A standardized assay was run on the three different chips, and the PCR yields were compared. The temperature gradient profiles of the three designs and the residence times of simulated DNA molecules flowing through each temperature zone were predicted using computational methods. PCR performance predicted by simulation corresponded to experimental results. The effects of DNA template size and cycle time on PCR yield were also studied. The experiments and simulations presented here guided the CF-PCR chip design and provide a model for predicting the performance of new CF-PCR designs prior to actual chip manufacture, resulting in faster turn around time for new device and assay design. Taken together, this framework of combined simulation and experimental development has greatly reduced assay development time for CF-PCR in our lab.     

Reflex: intramolecular barcoding of long-range PCR products for sequencing multiple pooled DNAs

We present an intramolecular reaction, Reflex™, to derive shorter, sequencer-ready, daughter polymerase chain reaction products from a pooled population of barcoded long-range polymerase chain reaction products, whilst still preserving the cognate DNA barcodes. Our Reflex workflow needs only a small number of primer extension steps to rapidly enable uniform sequence coverage of long contiguous sequence targets in large numbers of samples at low cost on desktop next-generation sequencers.     

The polymerase chain reaction: a new epidemiological tool for investigating cervical human papillomavirus infection.

The polymerase chain reaction is an in vitro method for primer directed enzymatic amplification of specific target DNA sequences. The technique was used to detect human papillomavirus types 11 and 16 simultaneously in cellular DNA recovered from cervical smears in 38 women referred for colposcopy to evaluate cytological abnormality and 10 women with no history of cytological abnormality. The polymerase chain reaction was shown to be both specific and sensitive in detecting human papillomavirus DNA such that a single human papillomavirus molecule was detected in 10(5) cells. Of the 38 women with cytological abnormality, all were positive for human papillomavirus on testing with the polymerase chain reaction; 36 were infected with human papillomavirus type 16 and 22 dually infected with human papillomavirus types 11 and 16. Seven of the 10 women with no cytological abnormality were also infected with human papillomavirus type 11 or 16. The use of the polymerase chain reaction will facilitate epidemiological investigation of the aetiological role of human papillomavirus in cervical neoplasia. This preliminary analysis suggests that the prevalence of human papillomavirus infection is greater than previously reported.     

Polymerase chain reaction of 2-kb cyanobacterial gene and human anti-alpha1-chymotrypsin gene from genomic DNA on the In-Check single-use microfabricated silicon chip

The microfabricated chip is a promising format for automating and miniaturizing the multiple steps of genotyping. We tested an innovative silicon biochip (In-Check Lab-on-Chip; STMicroelectronics, Agrate Brianza, Italy) designed for polymerase chain reaction (PCR) analysis of complex biological samples. The chip is mounted on a 1x3-in(2). plastic slide that provides the necessary mechanical, thermal, electrical, and fluidic connections. A temperature control system drives the chip to the desired temperatures, and a graphical user interface allows experimenters to define cycling conditions and monitor reactions in real time. During thermal cycling, we recorded a cooling rate of 3.2 degrees C/s and a heating rate of 11 degrees C/s. The temperature maintained at each thermal plateau was within 0.13 degrees C of the programmed temperature at three sensors. From 0.5 ng/microl genomic DNA, the In-Check device successfully amplified the 2060-bp cyanobacterial 16S rRNA gene and the 330-bp human anti-alpha(1)-chymotrypsin gene. The shortest PCR protocol that produced an amplicon by capillary electrophoresis comprised 30 cycles and was 22.5 min long. These thermal cycling characteristics suggest that the In-Check device will permit future development of a genotyping lab-on-a-chip device, yielding results in a short time from a limited amount of biological starting material.     

Use of tRNA consensus primers to indicate subgroups of Pseudomonas solanacearum by polymerase chain reaction amplification.

Polymerase chain reaction amplification of DNA from 112 Pseudomonas solanacearum strains with the tRNA consensus primers T3A and T5A divided the species into three fingerprint groups. These groups correspond well with previous divisions made by restriction fragment length polymorphism analysis. This polymerase chain reaction test is a facile method for rapidly classifying P. solanacearum strains.     

Polymerase chain reaction amplification of single-stranded DNA containing a base analog, 2-chloradenine.

By utilization of polymerase chain reaction techniques, single-stranded DNA of defined length and sequence containing a purine analog, 2-chloroadenine, in place of adenine was synthesized. This was accomplished by a combination of standard polymerase chain amplification reactions with Thermus aquaticus DNA polymerase in the presence of four normal deoxynucleoside triphosphates, M13 duplex DNA as template, and two primers to generate double-stranded DNA 118 bases in length. An asymmetric polymerase chain reaction, which produced an excess of single-stranded 98-base DNA, was then conducted with 2-chloro-2'-deoxy-adenosine 5'-triphosphate in place of dATP and with only one primer that annealed internal to the original two primers. Standard polymerase chain reaction techniques alone conducted in the presence of the analog as the fourth nucleotide did not produce duplex DNA that was modified within both strands. This asymmetric technique allows the incorporation of an altered nucleotide at specific sites into large quantities of single-stranded DNA without using chemical phosphoramidite synthesis procedures and circumvents the apparent inability of DNA polymerase to synthesize fully substituted double-stranded DNA during standard amplification reactions. The described method will permit the study of the effects of modified bases in template DNA on a variety of protein-DNA interactions and enzymes.     

Cloning and characterization of gene TNF alpha encoding equine tumor necrosis factor alpha.

We report the molecular cloning and nucleotide sequence of the equine gene encoding tumor necrosis factor alpha. The 2610-bp genomic sequence was derived from three overlapping polymerase chain reaction products.     

Nucleic acid purification using microfabricated silicon structures

A microfluidic device has been designed, fabricated and tested for its ability to purify bacteriophage lambda DNA and bacterial chromosomal DNA, a necessary prerequisite for its incorporation into a biosensor. This device consists of a microfabricated channel in which silica-coated pillars were etched to increase the surface area within the channel by 300-600%, when the etch depth is varied from 20 to 50 microm. DNA was selectively bound to these pillars in the presence of the chaotropic salt guanidinium isothiocyanate, followed by washing with ethanol and elution with low-ionic strength buffer. Positive pressure was used to move solutions through the device, removing the need for centrifugation steps. The binding capacity for DNA in the device was approximately 82 ng/cm2 and on average, 10% of the bound DNA could be purified and recovered in the first 50 microl of elution buffer. Additionally, the device removed approximately 87% of the protein from a cell lysate. Nucleic acids recovered from the device were efficiently amplified by the polymerase chain reaction suggesting the utility of these components in an integrated, DNA amplification-based biosensor. The miniaturized format of this purification device, along with its excellent purification characteristics make it an ideal component for nucleic acid-based biosensors, especially those in which nucleic acid amplification is a critical step.     

Polymerase chain reaction]

Principles of the polymerase chain reaction, its modifications and applications are discussed. Guidelines for performance of the polymerase chain reaction are briefly summarized.     

Combination primer polymerase chain reaction for multi-site mutagenesis of close proximity sites.

We describe a rapid and efficient polymerase chain reaction procedure for multi-site-directed mutagenesis for cases in which the sites to be mutated are in close proximity. The combination primer polymer chain reaction method is based on a multi-site directed mutagenesis protocol together with a splicing by overlapping extension polymerase chain reaction protocol. several different combinations of multiple mutations were successfully performed with this method and are reported in this study.