Polymerase chain reaction additives

The use of agarose as an electrophoretic method is widespread (32—35). An example of its use is in the evaluation and typing of DNA both in forensics (see Forensic chemistry) and to study heritable diseases (36). Agarose electrophoresis is combined with other analytical tools such as Southern blotting, polymerase chain reaction, and fluorescence. The advantages of agarose electrophoresis are that it requires no additives or cross-linkers for polymerization, it is not hazardous, low concentration gels are relatively sturdy, it is inexpensive, and it can be combined with many other analytical methods. 

FIGURE 28.14 The polymerase chain reaction (PCR). Three cycles are shown the target region appears after the third cycle. Additional cycles lead to amplification of the target region. 

Krahmer, M. T. Johnson, Y. A. Walters, J. J. Fox, K. F. Fox, A. Nagpal, M. Electrospray quadrupole mass spectrometry analysis of model oligonucleotides and polymerase chain reaction products determination of base substitutions, nucleotide additions/deletions, and chemical modifications. Anal. Chem. 1999, 71, 2893-2900. 

Additionally it has been our experience that mass spectrometry as a routine detection/identification technique for bacteria is not well received by microbiologists and clinicians who prefer less expensive, less complicated approaches to bacterial typing and identification, such as methods based on polymerase chain reaction (PCR) and enzyme-linked immunosorbent assays (ELISA). For that reason we have adapted our MS approach to serve as a means of biomarker discovery that feeds candidate proteins or leads into development as PCR targets or other immunoassay techniques. 

Patino B, Medina A, Domenech M, Gonzalez-Jaen MT, Jimenez M and Vazquez C. 2007. Polymerase chain reaction (PCR) identification of Penicillium brevicompactum, a grape contaminant and mycophenolic acid producer. Food Addit Contam 24(2) 165-172. 

Figure 3.25 Polymerase chain reaction. The steps involved in the chain reaction are as follows (i) Incubation of the DNA at a temperature above 90 °C in order to separate the two strands of the DNA duplex, (ii) Cooling of the solution to about 50 °C to allow annealing of the primers to the template (i.e. the nucleotides bind to the template DNA according to the basepairing rules), (iii) Finally, addition of the polymerase and Mg ions to extend the nucleotide primer and complete the synthesis of the complementary DNA, which takes place at about 70 °C. (iv) The sequence (i) to (iii) is repeated to allow another extension to occur many repetitions can be carried out which results in enormous multiplication of the DNA strands. NTPs - deoxyri-bonucleoside triphosphates.

Fig. 1. Comparison of enzyme-linked immuno sorbent assay (ELISA, left) and immuno-polymerase chain reaction (IPCR, right). During ELISA, an antibody-enzyme conjugate is bound to the target antigen. The enzyme converts a substrate in solution to a detectable product. In IPCR, the antibody-enzyme conjugate is replaced by an antibody-DNA conjugate. The subsequent addition of a DNA polymerase enzyme (e.g., Taq), nucleotides and a specific primer pair uses the antibody-linked DNA marker sequence as a template for amplification of the DNA. The PCR product is finally detected as an indicator of the initial amount of antigen.

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