Home Polymerase Chain Reaction ApplicationsDNA Concentration for Forensic Genotyping with DNAstable^®

DNA Concentration for Forensic Genotyping with DNAstable^®

Ethan Smith², Anna Wilson², Jeremy Sanderson³, Philip Hodge⁴, Rolf Muller¹, Judy Muller-Cohn¹, Gary Shutler⁴

¹Biomatrica, 5627 Oberlin Drive, Suite 120, San Diego, CA 92121, ²Washington State Patrol Crime Laboratory, Cheney, WA, ³Washington State Patrol Crime Laboratory, Tacoma, WA, ⁴Washington State Patrol Crime Laboratory, Standards and Accountability Section, Seattle, WA

Introduction

Forensic laboratories routinely use STR genotyping for identity testing of biological samples. However, forensic samples often contain low copy numbers of target DNA, making it difficult to obtain complete STR profiles. Increasing PCR amplification cycles is commonly performed to address this issue, but it can lead to stochastic effects that call into question the accuracy of the data analysis. To overcome this challenge, forensic scientists use a variety of techniques to concentrate samples in an attempt to increase the total amount of DNA available for amplification prior to the PCR step. These techniques include centrifugal filtration, sample dry-down and re-suspension, as well as precipitation with ethanol and polyethylene glycol. Such concentrating techniques have a variety of drawbacks, with the most critical being sample loss. We describe a technique for easily and effectively concentrating DNA from forensic samples using the commercially available reagent, DNAstable^®. This method minimizes sample loss. We provide a case study from the Washington State Patrol Crime Laboratory, which has successfully used DNAstable to concentrate DNA for STR analysis. We show that this technique avoids many of the drawbacks associated with other DNA concentration strategies while providing accurate STR analysis results.

Methods & Materials

Preparation and Quantitation of DNA Samples DNA from eight reference swabs (Samples A - H) was extracted using a Biorobot^® EZ1^®. (Qiagen). Samples A - C and G - H were eluted in low T_10mME_0.1mM buffer, (pH 8.0) and samples D - F were eluted in deionized water. All samples were immediately stored in a -20ºC freezer. Additionally, all sample extracts were quantified using the Quantifiler^® Human DNA Quantification Kit (Life Technologies/Applied Biosystems) using a 7500 Real-Time PCR System (Life Technologies/Applied Biosystems).

Experiment 1
The purpose of the first part of this study was to examine differences in DNA recovery between Microcon^® (Millipore) microfiltration and Vacufuge^® (Eppendorf) vacuum centrifugation methods when DNAstable^® (Biomatrica) is or is not incorporated. The AmpflSTR^® Yfiler^® Amplification kit (Life Technologies) was used to demonstrate any differences in recovery.

Experiment 2
The second part of this study sought to determine if increases in TE concentration would lead to inhibition during amplification and used the AmpflSTR^® Identifiler^® Plus Amplification kit (Life Technologies) as a detector.

Experiment 3
The third part of this study examined the effect of increasing concentrations of DNAstable on downstream applications using both amplification kits.

Amplification of Extracts
Ten microliters from each set was amplified using the AmpflSTR Identifiler^® Plus and/or AmpflSTR Yfiler Amplification kits (Applied Biosystems) using a final reaction volume of 25 µL. Amplification was performed on the 9700 Thermocycler (Life Technologies/Applied Biosystems). Fragment analysis was performed on the 3130 Genetic Analyzer (Applied Biosystems) with a five second injection time. Experiment 1 samples were amplified using only the AmpflSTR Yfiler Amplification kit. Experiment 2 and 3 samples were amplified using only the AmpflSTR Identifiler Plus Amplification kit.

Results

Figure 1. Impact of DNAstable on DNA recovery quant values and Yfiler STR peak heights in samples in TE buffer or water.

Set 1: Microcon ultrafiltration with DNA sample containing DNAstable. Set 2: Vacufuge vacuum centrifugation with DNA sample containing DNAstable. Set 3: Microcon ultrafiltration without DNAstable. Set 4: Vacufuge vacuum centrifugation without DNAstable. A. Average DNA recovery of samples in TE Buffer. B. Average peak heights of samples in TE buffer. C. Average DNA recovery of samples in water. D. Average peak heights of samples in water.

Figure 2. Effect of various TE buffer concentrations on DNA recovery quant values and peak heights in DNA samples with or without DNAstable.

Set 1: 20 µL DNAstable in 5X TE. Set 2: 20 µL DNAstable in 10X TE. Set 3: No DNAstable in 5X TE. Set 4: No DNAstable in 10X TE. A. Average DNA recovery after dry down using Vacufuge vacuum centrifugation. B. Average Identifiler Plus STR peak heights after dry down using Vacufuge vacuum centrifugation.

Effect of increasing concentrations of DNAstable on peak heights using either AmpflSTR Yfiler Amplification kit or AmpflSTR Identifiler Plus Amplification kit

Figure 3. Effect of increasing concentrations of DNAstable on peak heights using either AmpflSTR Yfiler Amplification kit or AmpflSTR Identifiler Plus Amplification kit.

Each tube contained 0.6 ng DNA. Reference sample G & H were DNA eluted in TE buffer during purification. Set 1 was the control with 1X DNAstable in TE buffer. Set 2 contained increasing concentrations of DNAstable from 2X to 10X. Set 3 contained increasing concentrations of DNAstable from 2X to 10X, and were dried and reconstituted in water. A. Peak heights determined using AmpflSTR Yfiler Amplification kit, B. Peak heights determined using AmpflSTR Identifiler Plus Amplification kit.

Conclusions

The process of concentrating DNA to obtain more accurate and interpretable STR profiles warrants careful examination. Based on our results, the presence of DNAstable is beneficial when concentrating via vacuum centrifugation or using a microfiltration device. However, when TE approaches 10X, then a desalting method such as using a Microcon ultrafiltration device should be considered. This holds true for both AmpFlSTR Identifiler Plus and AmpFlSTR YFiler amplification kits. With the issues that can arise from low levels of DNA, the use of optimal concentration methods needs to be carefully assessed to ensure the greatest chance of generating an accurate and robust profile.

Materials

产品编号	产品名称	说明
MSQC16	SILu^™Lite SigmaMAb Adalimumab Monoclonal Antibody	recombinant, expressed in CHO cells
31417	葡聚糖来源于肠系膜明串珠菌	analytical standard, Mw 5,000
I4506	IgG 来源于人类血清	reagent grade, ≥95% (SDS-PAGE), essentially salt-free, lyophilized powder
50933	盐酸胍盐酸盐	BioUltra, ≥99.5% (AT)
09830	碳酸氢铵	BioUltra, ≥99.5% (T)
F8435	糖苷酶F 来源于脑膜脓毒性伊丽莎白菌	lyophilized powder, recombinant, expressed in E. coli
EMS0011	Low-Artifact Digestion Buffer	Minimizes artifactual deamidation and oxidation during trypsin digestion prior to peptide mapping
MRCF0R030	Microcon^®离心超滤管	NMWCO 30 kDa, Ultracel^® regenerated cellulose membrane (low binding), sample volume 0.5 mL
156159	氰基硼氢化钠	reagent grade, 95%
PHR1252	普鲁卡因胺盐酸盐	Pharmaceutical Secondary Standard; Certified Reference Material
D8418	二甲基亚砜
695092	乙酸	glacial, ACS reagent, ≥99.7%
55465-U	Discovery^® Glycan SPE Tube	bed wt. 50 mg, volume 1 mL, pk of 108
1.00029	乙腈	hypergrade for LC-MS LiChrosolv^®
VM20	VM20真空歧管	For processing up to 20 plasmid purification samples simultaneously
50994-U	BIOshell Glycan HPLC Columns	L × I.D. 15 cm × 2.1 mm, 2.7 μm particle size
1.00029	乙腈	hypergrade for LC-MS LiChrosolv^®
70221	甲酸铵	eluent additive for LC-MS, LiChropur^™, ≥99.0%
5.33002	甲酸98％-100％	for LC-MS LiChropur^™
ZIQ7000T0C	Milli-Q^® IQ 7000 超纯水净化系统	output: type 1 water (18.2 MΩ·cm), the most advanced Milli-Q^® ultrapure (Type 1) water purification system that is intelligent, intuitive, and green.