Bacterial Genomic DNA Isolation Kit
For the rapid preparation of genomic DNA from bacteria
For research use only and NOT intended for in vitro diagnostics.
Bacterial Genomic DNA Isolation Kit
For the rapid preparation of genomic DNA from bacteria
Register today to receive an exclusive 15% off* on your first order.
Features and Benefits
- Isolate genomic DNA from all types of bacteria (both Gram-positive and Gram-negative)
- Rapid and convenient spin column protocol
- 96-well format available for high throughput
- High yield, high quality DNA for sensitive downstream applications including sequencing, PCR, qPCR and more
This kit is designed for the rapid spin column preparation of genomic DNA from 2 x 109 viable bacterial cells (between 0.5 and 1.0 mL of culture). This kit can be used for both Gram-negative and Gram-positive bacteria including Escherichia coli and Bacillus cereus. Purified genomic DNA is of an excellent quality and yield, and is fully compatible with restriction enzyme digestions, sequencing, PCR, qPCR and more. Also available in 96-well format for high throughput applications.
Details
Supporting Data
Kit Specifications (Spin Columns)
|
|
Input
|
2 x 109 bacterial cells
|
Column Binding Capacity
|
25 µg
|
Average Yield*
|
Up to 20 µg
|
Time to Complete 10 Purifications |
1 hour
|
* Yield will vary depending on the type of sample processed
Storage Conditions and Product Stability
All solutions should be kept tightly sealed and stored at room temperature. This kit is stable for 2 years after the date of shipment. The kit contains a ready-to-use Proteinase K, which is dissolved in a specially prepared storage buffer. The buffered Proteinase K is stable for up to 2 years after the date of shipment when stored at room temperature.
Component | Cat. 17900 (50 preps) | Cat. 17950 (192 preps) |
---|---|---|
Resuspension Solution A | 20 mL | 60 mL |
Lysis Buffer P | 18 mL | 60 mL |
Solution BX | 28 mL | 110 mL |
Wash Solution A | 18 mL | 2 x 38 mL |
Elution Buffer B | 30 mL | 2 x 30 mL |
Proteinase K | 12 mg | 50 mg |
Spin Columns | 50 | - |
96-Well Plate | - | 2 |
Adhesive Tape | - | 4 |
Collection Plate | - | 2 |
Collection Tubes | 50 | - |
Elution Tubes (1.7 mL) | 50 | - |
Elution Plate | - | 2 |
Product Insert | 1 | 1 |
Documentation
FAQs
Spin Column, High Throughput
Column clogging can result from the following:
- The sample is too large.
Too many cells were applied to the column. Ensure that the amount of cells used is less than 2 x 109 viable cells, and that no more than 1 mL of culture is applied to the column/well. Clogging can be alleviated by increasing the g force and/or centrifuging for a longer period of time until the lysate passes through the column.
- Insufficient Vacuum (for High-throughput only).
Ensure that a vacuum pressure of at least -650 mbar or -25 in. Hg is developed.
- Centrifuge temperature is too low.
Ensure that the centrifuge remains at room temperature throughout the procedure. Temperatures below 15℃ may cause precipitates to form that can cause the wells to clog.
Experiencing gelatinous lysate prior to loading onto the column may be due to:
- The lysate/binding solution mixture is not homogeneous.
To ensure a homogeneous solution, vortex for 10-15 seconds before applying the lysate to the spin column.
- The sample is too large.
Too many cells are in the lysate preparation. Ensure that the amount of cells used is less than 2 x 109 viable cells, and that no more than 1 mL of culture is applied to the column/well.
A low genomic DNA yield may be caused by the following:
- The sample is old/overgrown.
The culture may have been overgrown, allowing lysis of older cells to occur more readily. This will lead to premature degradation of the genomic DNA. It may be necessary to use bacterial cultures before they reach maximum density.
- Incomplete lysis of cells.
Extend the incubation time of Proteinase K digestion or reduce the amount of bacterial cells used for lysis. Increase the lysozyme incubation time for gram-positive strains.
- The DNA elution is incomplete.
Ensure that centrifugation at 20,000 x g is performed after the 3,000 x g centrifugation cycle to ensure that all the DNA is eluted.
Sheared genomic DNA could be caused by:
- Improper handling of genomic DNA.
Pipetting steps should be handled as gently as possible. Reduce vortexing times during mixing steps (no more than 10-15 seconds).
- The cells are old.
Older cultures contain prematurely lysed cells which release endonucleases and can degrade DNA. Fresh cultures are recommended.
If the DNA does not perform well in downstream applications, it may be due to one or more of the following:
- DNA was not washed two times with the provided Wash Solution A.
Ensure the column/plate was washed two times with Wash Solution A. An additional wash with Wash Solution A can improve DNA performance in downstream applications, although it may reduce DNA yield.
- Ethanol carryover.
Ensure that the column/plate drying step after the Wash procedure is performed in order to remove traces of ethanol prior to elution. Ethanol is known to interfere with many downstream applications.
Yes, the DNA from this kit is good for both Nanopore sequencing and Long-read sequencing. Please contact our Tech support team at support@norgenbiotek.com and ask for reference publications.
Citations
Title | Large-scale analysis of putative plasmids in clinical multidrug-resistant Escherichia coli isolates from Vietnamese patients |
Citation | Frontiers in Microbiology 2023. |
Authors | Quang Huy Nguyen, Thi Thu Hang Le, Son Thai Nguyen, Kieu-Oanh Thi Nguyen, Dong Van Quyen, Juliette Hayer, Anne-Laure Bañuls, Tam Thi Thanh Tran |
Title | Microbial ecology, biochemical and nutritional features in sprouted composite type I sourdough made of wheat and blend flours |
Citation | LWT 2023. |
Authors | Maria Calasso, Arianna Ressa, Francesco Maria Calabrese, Fabio Minervini and Maria De Angelis |
Title | Uncovering the diversity of heterotrophic culturable bacteria within the gut of bay scallop Argopecten purpuratus (Lamarck, 1819) from two geographically distant natural banks |
Citation | bioRxiv 2023. |
Authors | Wilbert Serrano, Ulrike I. Tarazona-Janampa, Raul M. Olaechea, Sonia Valle |
Title | Bacteriophage and Their Potential Use in Bioaugmentation of Biological Wastewater Treatment Processes |
Citation | Sustainability 2023. |
Authors | Suheda Reisoglu and Sevcan Aydin |
Title | Screening of mitochondrial mutations in Saudi women diagnosed with gestational diabetes mellitus: A non-replicative case-control study |
Citation | Saudi Journal of Biological Sciences 2022. |
Authors | Alharbi KK, Alsaikhan AS, Alshammary AF, Al-Hakeem MM, Ali Khan I. |
Title | Banana peel as an inexpensive carbon source for microbial polyhydroxyalkanoate (PHA) production |
Citation | International Journal of Environmental Sciences 2018. |
Authors | Vijay, R., & Tarika, K. |
Title | Streptomyces exploration is triggered by fungal interactions and volatile signals |
Citation | eLIFE 2017. |
Authors | Jones, S. E., Ho, L., Rees, C. A., Hill, J. E., Nodwell, J. R., & Elliot, M. A |
Title | Phenotypic and genomic identification of Staphylococcus epidermidis GOI1153754-03-14 isolated from an infected orthopedic prosthesis |
Citation | International Journal of Health & Animal Science Food Safety 2017. |
Authors | Bottagisio, M., Soggiu, A., Lovati, A. B., Toscano, M., Piras, C., Romanò, C. L., ... & Drago, L. (2017). |
Title | Pyrosequencing Analysis of Cryogenically Ground Samples from Primary and Secondary/Persistent Endodontic Infections |
Citation | Journal of Endodontics 2017. |
Authors | Keskin, C., Demiryürek, E. Ö., & Onuk, E. E. (2017). |
Title | Characterizing the endometrial microbiome by analyzing the ultra-low bacteria from embryo transfer catheter tips in IVF cycles: Next generation sequencing (NGS) analysis of the 16S ribosomal gene |
Citation | Human Microbiome Journal 2017. |
Authors | Tao, X., Franasiak, J. M., Zhan, Y., Scott, R. T., Rajchel, J., Bedard, J., ... & Chu, T |