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Optimization of PCRs 97 f. Magnesium concentration is too low. Increase magnesium concentration in increments of 0.1 mM. g. The denaturation time is too long or too short. Adjust denaturation time in increments of 5 s. h. Add cosolvents that enhance PCR amplification. i. The denaturation temperature is too high or too low. Change denaturation temperature in increments of 1°C. j. The primer annealing temperature is too high. Lower annealing temperature in increments of 2°C. k. The primer extension period is too short. Increase extension time in increments of 1 minute. l. Re-amplify dilutions (110 to 11000) of the first round of PCR amplification using nested primers. m. Perform hot start. n. Perform Touchdown (TD)/Stepdown (SD) PCR cycling program. TD or SD PCR uses a temperature cycling protocol that is performed at decreasing annealing temperatures. The cycling program begins at an annealing temperature a few degrees above the calculated Tm of the primers. This ensures that the first primer-template hybridization events involve only those sequences with the greatest specificity. The annealing temperature is decreased 1 to 4°C every other cycle to approx 10°C below the calculated Tm to permit exponential amplification (39). Here is an example of a typical TD/SD cycling program: initial denaturation at 94°C for 1 mi followed by 20 cycles of 10 s at 92°C and 20 s at 70°C with an 0.5°C decrease of temperature per cycle, then another 20 cycles of 10 s at 92°C and 30 s at 60°C with a 1-s extension per cycle and hold at 4°C. Hot start must be used with these cycling programs. o. Review primer design and composition. Design new primers and try PCR again. If multiple product bands or smear is detected: a. Too much DNA template is present in the reactions. Decrease the amount of DNA template in the reaction mix. b. Annealing temperature is too low. Increase annealing temperature in increments of 2°C. c. DNA polymerase concentration is too high. Decrease enzyme concentration in increments of 0.5 units per 100-µL reaction. d. Magnesium concentration is too high. Decrease the magnesium concentration in increments of 0.1 mM. e. Denaturation time is too short. Increase the denaturation time in increments of 5 s. f. Denaturation temperature is too low. Increase the denaturation time in increments of 1°C. g. Cycle number is too high. Reduce the cycle number by 5 to 10 cycle. h. Perform hot start. i. Alter concentrations of cosolvents. j. Perform TD/SD PCR. k. Extension time is too long. Reduce the extension time in increments of 1 min. l. Check for carry-over contamination. Set up PCR in a different area. m. Review primer design and composition. Design new primers and try PCR again. References 1. Higuchi, R. (1989) Using PCR to engineer DNA, in PCR Technology: Principles and Applications for DNA Amplifications (Erlich, H. A., ed.), Stockton Press, Inc., New York, pp. 61–70.
98 Grunenwald 2. Foord, O. S. and Rose, E. A. (1995) Long-distance PCR, in PCR Primer (Dieffenback, C. W. and Dveksler, G. S., ed.), Cold Spring Harbor Laboratory Press, Cold Spring, NY, pp. 63–77. 3. Edwards, A., Civitello, A., Hammond, H. A., and Caskey, C. T. (1991) DNA typing and genetic mapping with trimeric and tetrameric tandem repeats. Am. J. Hum. Genet. 49, 746–756. 4. Edwards, A., Hammond, H. A., Jin, L., Caskey, C. T., and Chakroborty, R. (1992) Geneticvariation at five trimeric and tetrameric tandem repeat loci in four human population groups. Genomics 12, 241–253. 5. Klimpton, C. P., Gill, P., Walton, A., Urquhart, A., Millican, E. S., and Adams, M. (1993) Automated DNA profiling employing multiplex amplification of short tandem repeat loci. PCR Methods Appl. 3, 13–21. 6. Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A laboratory Manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York. 7. Lindahl, T. and Nyberg, B. (1972) Rate of depurination of native deoxyribonucleic acid. Biochemistry 11, 3610–3618. 8. Rychlik, W. and Rhoads, R. E. (1989) A computer program for choosing optimal oligonucleotides for filter hybridization, sequencing and in vitro amplification of DNA. Nucleic Acids Res. 17, 8543–8551. 9. Lowe, T. M. J., Sharefkin, J., Yang, S. Q., and Dieffenback, C. W. (1990) A computer program for selection of oligonucleotide primers for polymerase chain reaction. Nucleic Acids Res. 18, 1757–1761. 10. O’Hara, P. J. and Venezia, D. (1991) PRIMGEN, a tool for designing primers from multiple alignments. CABIOS 7, 533–534. 11. Montpetit, M. L., Cassol, S., Salas, T., and O’Shaughnessy, M. V. (1992) OLIGOSCAN: A computer program to assist in the design of PCR primers homologous to multiple DNA sequences. J. Virol. Methods 36, 119–128. 12. Suggs, S. V., Hirose, T., Myake, D. H., Kawashima, M. J., Johnson, K. I., and Wallace, R. B. (1981) Using purified genes, ICN-UCLA Symp. Mol. Cell. Biol. 23, 683–693. 13. Breslauer, K. J., Ronald, F., Blocker, H., and Marky, L. A. (1986) Predicting DNA duplex stability from the base sequence. Proc. Natl. Acad. Sci. USA 83, 3746–3750. 14. Freier, S. M., Kierzek, R., Jaeger, J. A., Sugimoto, N., Caruthers, M. H., Neilson, T., et al. (1986) Improved free-energy parameters for predictions of RNA duplex stability. Proc. Natl. Acad. Sci. USA 83, 9373–9377. 15. Innis, M. A. and Gelfand, D. H. (1990) Optimization of PCRs, in PCR Protocols: A Guide to Methods and Applications (Gelfand, D. H., Sninsky, J. J., Innis, M. A., and White, H., eds.), Academic Press, San Diego, CA, pp. 3–12. 16. Innis, M. A., Myambo, K. B., Gelfand, D. H., and Brow, M. A. D. (1988) DNA sequencing with Thermus aquaticus DNA polymerase and direct sequencing of polymerase chain reaction-amplified DNA. Proc. Natl. Acad. Sci. USA 85, 9436–9440. 17. Ohler, L. and Rose, E. A. (1992) Optimization of long distance PCR using a transposonbased model system. PCR Methods Appl. 2, 51–59. 18. Gelfand, D. H. (1989) Taq DNA polymerase, in PCR Technology: Principles and Applications for DNA Amplification (Erlich, H. A., ed.), Stockton Press, New York, pp. 17–22. 19. Cheng, S. (1995) Longer PCR amplifications, in PCR Strategies (Innis, M. A., Gelfand, D. H., and Sninsky, J. J., eds.) Academic Press, San Diego, CA, pp. 313–324. 20. Brock, T. D. and Freeze, H. (1969) Thermus aquaticus gene, a non-sporulating extreme thermophile. J. Bacteriol. 98, 289–297. 21. Giebel, L. B. and Spritz, R. A. (1990) Site-directed mutagenesis using the double-stranded DNA fragment as a PCR primer. Nucleic Acids Res. 18, 4947.
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TM Methods in Molecular Biology Vol
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Xin Wang and W. Scott Young III 105
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63. Primed In Situ Nucleic Acid Lab
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4 Bartlett and Stirling The thing t
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6 Bartlett and Stirling Fig. 2. Res
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8 Carroll and Casimir of PCR. Such
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10 Carroll and Casimir cost more th
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12 Carroll and Casimir are no longe
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14 Carroll and Casimir Should these
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16 McDonagh Fig. 1. Unidirectional
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18 McDonagh stored. This means that
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20 McDonagh
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22 Stirling which will either not a
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24 Stirling
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28 Bartlett References 1. US Depart
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30 Bartlett and White 11. 5 M sodiu
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32 Bartlett and White
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34 Pearson and Stirling 11. Microfu
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36 Going 3. Methods 3.1. Section Cu
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38 Going pipet filler. Spread the p
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40 Going digitally to record the di
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42 Going
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Page 123 and 124: 124 Iannone et al. Fig. 1. Diagram
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148 Benjamin, Smith, and Waites 8.
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150 Benjamin, Smith, and Waites
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152 Olmos et al. Fig. 1. RT-hemines
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154 Olmos et al. This nested RT-PCR
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156 Olmos et al. Table 2 Volume and
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158 Olmos et al. 8. The sensitivity
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160 Olmos et al.
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162 Abe 5. Moloney murine leukemia
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164 Abe Table 2 Detection Rate of H
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166 Abe 4. For HBV, nested PCR usin
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168 Tellier et al. of Pfu (and ther
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170 Tellier et al. 2. Cline, J., Br
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172 Tellier et al. 38. Tamiya, S.,
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174 Tellier et al. 13. Thin-wall PC
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176 Tellier et al. 13 min for the l
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178 Tellier et al.
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182 Stirling efficiency of the reac
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184 Stirling
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186 Cremer and Moos Fig. 1. Rearran
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188 Cremer and Moos 4. Count cells
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190 Cremer and Moos Fig. 3. Alignme
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192 Cremer and Moos Fig. 4. Testing
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194 Cremer and Moos 5. Compare the
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196 Cremer and Moos 11. Klein, E.,
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198 McDonagh the dilution method is
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200 McDonagh 2.2. Basic PCR 1. dNTP
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202 McDonagh Fig. 2. Quantitative P
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204 McDonagh
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206 Bartlett Table 1 Example Assay
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208 Bartlett 3.4. Calculation of Re
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210 Bartlett 11. Cerenkov counting
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212 Kerr Fig. 1. Fluorescent probes
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214 Kerr after the PCR. This reduce
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218 Bartlett As with any experiment
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220 Bartlett Even once novel regula
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222 Bartlett Notwithstanding these
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224 Bartlett
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226 Dominguez et al. Table 1 Primer
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228 Dominguez et al. 4. Oligonucleo
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230 Dominguez et al. Fig. 2. cDNA n
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232 Dominguez et al. 3.4. Gel Elect
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234 Dominguez et al. 3. If the cont
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236 Dominguez et al. 11. Joshi, C.
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238 Khalturin, Kuznetsov, and Bosch
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246 Ringquist et al. In this chapte
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248 Ringquist et al. 5. Total RNA s
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250 Ringquist et al. 3. Purificatio
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252 Ringquist et al. 2. The present
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254 Ringquist et al.
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256 Case-Green, Pritchard, and Sout
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272 Oien Fig. 1. A schematic diagra
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274 Oien 4. 100% and 70% ethanol. 5
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276 Oien 2. Purify polyA + mRNA fro
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278 Oien 50-mL conical tubes. Resus
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280 Oien Forward Primer, and then r
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282 Oien 8. PCR. With SAGE, achievi
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284 Oien
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288 Edwards and Bartlett technology
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290 Edwards and Bartlett ing less p
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292 Edwards and Bartlett Stepwise m
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294 Edwards and Bartlett
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296 Rithidech and Dunn 11. Ethidium
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298 Rithidech and Dunn Fig. 1. PCR
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300 Rithidech and Dunn
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302 Edwards and Bartlett Studies th
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304 Edwards and Bartlett 11. Hot st
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306 Edwards and Bartlett Fig. 1. Ex
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308 Edwards and Bartlett 3. Sartor,
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310 Schmerer the investigation conc
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312 Schmerer References 1. Kunkel,
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314 Schmerer
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316 Aubele and Smida 2.2. Chemicals
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318 Aubele and Smida References 1.
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320 Nakashima, Akahoshi, and Tanaka
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322 Nakashima, Akahoshi, and Tanaka
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324 Stirling 9. TAE (20×): 484 g o
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326 Stirling
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328 Han and Robinson Fig. 1. Basic
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330 Han and Robinson sequence diffe
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332 Han and Robinson 4. Notes 1. PC
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334 Han and Robinson
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338 Stirling of simple and improved
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340 Stirling concentrations interfe
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342 Daniels to sequence a 500-bp PC
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344 Daniels 4. Load all of the samp
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346 Daniels References 1. Orita, M.
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348 Kösel et al. Fig. 1. Schematic
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350 Kösel et al. 3. Methods 3.1. P
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352 Kösel et al. Fig. 2. Sequencin
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354 Kösel et al. 5. Kwok, S. and H
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356 Mazars and Theillet Fig. 1. Sch
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358 Mazars and Theillet of genomic
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360 Mazars and Theillet
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362 Suomalainen and Syvänen Fig. 1
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364 Suomalainen and Syvänen detect
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366 Suomalainen and Syvänen temper
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368 Shen et al. ladder. Also, direc
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370 Shen et al. 3. Mineral oil. 4.
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372 Shen et al. extended primers, w
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374 Quivy and Becker Fig. 1. The us
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376 Quivy and Becker that decreases
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378 Quivy and Becker 2. Solution of
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380 Quivy and Becker 7. Precipitate
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382 Quivy and Becker 7. Prepare a p
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384 Quivy and Becker
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386 Walsh by most, but not all M13
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388 Walsh PCR products are now flus
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390 Walsh 5. For palindromic restri
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392 Walsh
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394 McAleer, Coffey, and Dunham Fig
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396 McAleer, Coffey, and Dunham Tab
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398 McAleer, Coffey, and Dunham Tab
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400 McAleer, Coffey, and Dunham
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402 Stirling 5. Homopolymer Regions
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406 Speel, Ramaekers, and Hopman Ta
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408 Speel, Ramaekers, and Hopman Fi
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410 Speel, Ramaekers, and Hopman po
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Table 2 Comparison of PRINS, in Sit
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414 Speel, Ramaekers, and Hopman te
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Table 3 Summary of Control Experime
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418 Speel, Ramaekers, and Hopman 3.
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420 Speel, Ramaekers, and Hopman ad
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422 Speel, Ramaekers, and Hopman 25
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426 Bull and Paskins Fig. 1. Result
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428 Bull and Paskins 2.3. Detection
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430 Bull and Paskins 6. Shake the s
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432 Bull and Paskins
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434 Wiedorn and Goldmann Fig. 1. IS
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436 Wiedorn and Goldmann 41. Protei
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438 Wiedorn and Goldmann 2. Incubat
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440 Wiedorn and Goldmann 3.15. Prim
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442 Wiedorn and Goldmann ficient se
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444 Wiedorn and Goldmann 25. Kommin
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446 Gilchrist and Befus Fig. 1. Sch
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448 Gilchrist and Befus 2. Cells ar
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450 Gilchrist and Befus Fig. 3. RT
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452 Gilchrist and Befus References
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454 Speel, Ramaekers, and Hopman of
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456 Speel, Ramaekers, and Hopman Fi
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462 Speel, Ramaekers, and Hopman bu
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468 Pearson and Stirling into PCR p
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470 Wang 2. Materials 2.1. PCR 1. D
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472 Wang Fig. 1. A brief outline of
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474 Wang
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476 Horton, Raju, and Conti-Fine Fi
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478 Horton, Raju, and Conti-Fine th
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480 Horton, Raju, and Conti-Fine 1.
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482 Horton, Raju, and Conti-Fine ot
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484 Horton, Raju, and Conti-Fine
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486 Preston amplification approach
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488 Preston 1. 10× PCR buffer: 100
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490 Preston Fig. 1. Design of degen
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492 Preston 2. Remove the AmpliTaq
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494 Preston 3.3. Cloning and DNA Se
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496 Preston MgCl 2 concentrations b
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498 Preston 21. Hung, T., Mak, K.,
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500 Ravassard et al. Fig. 1. Constr
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502 Ravassard et al. size dispersio
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504 Ravassard et al. 9. ddH 2 O. 10
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506 Ravassard et al. 3.2.2. RNA Mix
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508 Ravassard et al. 4. Wash twice
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510 Ravassard et al.
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512 Pont-Kingdon Fig. 1. Constructi
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514 Pont-Kingdon 9. Invert tube and
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516 Pont-Kingdon
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518 Jones and Winistorfer Fig. 1. D
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520 Jones and Winistorfer Fig. 2. D
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522 Jones and Winistorfer The yield
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524 Jones and Winistorfer 7. Goulde
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526 Burke and Barik Fig. 1. The bas
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528 Burke and Barik concentration o
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530 Burke and Barik purified mutant
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532 Burke and Barik
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