Purification of Genomic DNA from Mouse Feces Using the Maxwell(R) 16 System-eNotes

Focus: Genomic DNA Purification

Purification of Genomic DNA from Mouse Feces Using the Maxwell^® 16 System

The Maxwell^® 16 System combines compact instrumentation, optimized automated methods, prefilled reagent cartridges, service and support. The system provides time savings, enhanced productivity and improved consistency of results. We were able to amplify mouse fecal DNA purified using the Maxwell^® 16 Tissue DNA Purification Kit.

By Doug Wieczorek, Ph.D. and Trista Schagat, Ph.D.
Promega Corporation

Published in July 2007

Introduction

Genomic DNA is frequently isolated from animal fecal samples to detect bacterial pathogens. Often DNA isolated from these sample types will contain significant amounts of inhibitors, such as phenolics and polysaccharides, which may prevent DNA amplification. In many cases, it may be necessary to dilute the purified DNA or treat with Chelex^® resin or PVPP (polyvinylpolypyrrolydone) for successful amplification. Using the Maxwell^® 16 Tissue DNA Purification Kit, bacterial DNA from mouse fecal samples was successfully isolated and the ability to amplify the purified DNA was achieved.

Methods

Genomic DNA Isolation: Fecal pellets collected from three-day old mouse bedding were stored at
–20 °C until use. A single fecal pellet (average weight = 38 mg) was placed directly into the Maxwell^® 16 Tissue DNA Purification Kit (Cat.# AS1030) sample cartridge. Genomic DNA was purified using the Maxwell^® 16 Instrument (Cat.# AS1000; firmware version 3.2) as described in the Maxwell^® 16 DNA Purification Kits Technical Manual #TM284. For some experiments, the eluted DNA was transferred to a prepared Zymo-Spin™ IV-HRC Spin Filter (Zymo Research Cat.# C1010-50) and centrifuged at 8,000 × g for 1 minute per the manufacturer’s instructions. DNA yield and purity were determined using the NanoDrop^® spectrophotometer.

PCR Analysis: PCR was performed on aliquots of DNA from a minimum of six separate purifications using conserved eubacterial 16S ribosomal RNA primers (1). E. coli JM109 genomic DNA [isolated from 0.4 ml overnight culture using the Maxwell^® 16 Cell DNA Purification Kit (Cat.# AS1020)] was used as a positive control. One microliter of eluted DNA or DNA diluted 1:100 in water was used per 50 µl amplification reaction.

Results

Using single fecal pellets, we obtained an average of 48 µg DNA per sample (n = 8). The DNA had an average concentration of 308 ng/µl with a 260nm/280nm absorbance purity ratio of 1.62.

As seen in Figure 1, the Maxwell^® 16 Tissue DNA Purification Kit consistently isolated high-molecular-weight DNA from the fecal pellets. The mechanical action of the Maxwell^® 16 Instrument plungers was sufficient to break apart the samples with minimal DNA shearing; so the conventional preprocessing method of bead beating was not necessary.

Figure 1. Genomic DNA isolated from mouse feces. Each lane represents 5 µl of purified genomic DNA. Lane M, Lambda DNA/EcoRI Markers (Cat.# G1721); lane 1, DNA isolated by a fecal DNA extraction kit using bead beating; lanes 2–4, DNA isolated using Maxwell^® 16 Tissue DNA Purification Kit with no preprocessing.

The ability to detect microbial flora in the fecal DNA was then tested using conserved eubacterial 16S ribosomal RNA primers (1; Figure 2). One out of 8 samples gave amplifiable product without dilution or further treatment of the purified DNA. When the DNA was diluted 1:100 in water prior to amplification, we were able to amplify DNA from all samples.

To improve amplification from undiluted DNA, we also tested a subsequent treatment of the Maxwell^® 16 purified DNA that removes PCR inhibitors. After pipetting the eluate onto a Zymo-Spin™ IV-HRC Spin Filter (filled with crosslinked polyvinylpyrrolidone) and centrifuging for 1 minute, the DNA could be used directly in PCR (Figure 2, lane 8; example is representative of six replicates).

Figure 2. Amplification of eubacterial 16S rRNA from fecal DNA extracted using the Maxwell^® 16 Tissue DNA Purification Kit. Each lane represents 10% of the 50 µl amplification reaction containing 1 µl of template. The amplicon size is 350 bp. Lane M, BenchTop PCR Markers (Cat.# G7531); lane 1, no template control; lanes 2–4, undiluted fecal DNA; lanes 5–7, DNA diluted 1:100 in water; lane 8, DNA processed over a Zymo-Spin™ IV-HRC Spin Filter; lane 9, JM109 DNA control.

Conclusion

The Maxwell^® 16 System, which includes the Maxwell^® 16 Tissue DNA Purification Kit and the Maxwell^® 16 Instrument, can be used to isolate genomic DNA from mouse fecal pellets without any initial preprocessing steps. For subsequent PCR amplification, dilution of the purified DNA or removal of inhibitors over a Zymo-Spin™ IV-HRC Spin Filter is recommended for greatest success. To learn more about the Maxwell^® 16 System, visit: www.promega.com/maxwell16

Reference

Brow, M.A. et al. (1996) J. Clin. Microbiol. 34, 3129–37.

Products may be covered by pending or issued patents or may have certain limitations on use. Please visit our patent and trademark web page for more information.

Maxwell is a registered trademark of Promega Corporation.

Chelex is a registered trademark of Bio-Rad Laboratories, Inc. NanoDrop is a registered trademark of NanoDrop Technologies. Zymo-Spin is a trademark of Zymo Research Corporation.