Fungi/Yeast Genomic DNA Isolation Kits

Overview

Rapid spin column purification of genomic DNA from viable yeast cells, fungal spores or mycelium, and bacteria including Gram-positive
Bead tubes (provided) allow for effective mechanical homogenization
Purified DNA is of high quality and integrity and compatible with any sensitive downstream applications such as PCR, qPCR, RFLP and more

These kits provide fast and reliable procedures for the purification of genomic DNA from viable yeast cells, fungal spores or mycelium, and bacteria including Gram-positive. Genomic DNA is efficiently extracted from the cells by a combination of heat treatment, detergents and Bead Tubes (provided). An optional lyticase treatment allows for improved DNA yields with certain fungal and yeast species. Recovered genomic DNA is of excellent yield and purity for any downstream application including PCR, qPCR, Restriction Fragment Length Polymorphism (RFLP), Amplified Fragment Length Polymorphism (AFLP), sequencing, SNP analysis and more.

Fungi/Yeast Genomic DNA Isolation Kit (Spin Column)

This kit provides rapid spin column purification of genomic DNA from viable yeast cells, fungal spores or mycelium, and bacteria including Gram-positive. Preparation time for a single sample is less then 30 minutes, and each kit contains sufficient materials for 50 preparations.

Fungi/Yeast Genomic DNA Isolation 96-Well Kit (HT)

Norgen’s Fungi/Yeast Genomic DNA Isolation 96-Well Kit provides a fast, reliable and simple procedure for high throughput isolation of DNA from viable yeast cells, fungal spores or mycelium and Gram-positive bacteria. The purification could be performed on either a vacuum manifold or using centrifugation. Complete 96 purifications in 40 minutes.

Details

Supporting Data

Figure 1. DNA Isolation from Different Fungi Species and Yeast. To demonstrate the purification of DNA from different fungal species, 30 mg of fungi were collected from plate cultures of Pichia sp, Aspergillus niger, Cladosporium cladasporioides, Botrytis cinerea and Mucor racemosus, and the DNA was extracted using Norgen's Fungi/Yeast Genomic DNA Isolation Kit. The bead system efficiently lysed the fungal cell walls with the provided Lysis Solution, and total DNA was eluted in 100 µL. For analysis, 10 µL from each elution was loaded in 1% 1xTAE agarose gel. Lane 1: Yeast (Pichia sp.), Lane 2: Aspergillus Niger; Lane 3: Cladosporium cladosporioides; Lane 4: Botrytis cinerea; Lane 5: Mucor racemosus; Lane M: Norgen's HighRanger 1kb DNA Ladder. The optional RNase treatment was not performed during the process.

Figure 2. DNA can be Isolated from Spores and Mycelium. Genomic DNA was extracted from the spores and mycelium of Botrytis cinera using Norgen's Fungi/Yeast Genomic DNA Isolation Kit. For the spores, 10⁵ spores/mL were collected from a plate culture by adding 3 mL of 0.9% NaCl to the fungi culture plate and gently shaking to extract the spores. For mycelium, 20 mg of mycellium was collected with sterilized forceps. DNA was isolated using Norgen's Fungi/Yeast Genomic DNA Isolation Kit with the provided Bead Tubes. For analysis, 10 µL from each 100 µL elution was loaded on a 1% 1xTAE agarose gel. Lane M: Norgen's HighRanger 1kb DNA Ladder. Optional RNase treatment was not performed during the extraction. As it can be seen, DNA could be successfully isolated from both the spores and mycelium.

Figure 3. Identification of Fungal and Yeast Species in a Real-time PCR (SYBR Green). DNA was isolated from 50 mg samples (wet weight) of yeast (Pichia sp) and fungi including Aspergillus niger, Cladosporium cladasporioides, Botrytis cinerea and Mucor racemosus using Norgen's Fungi/Yeast Genomic DNA Isolation Kit, and 2 µL of each of the 100 µL DNA elutions was used in a qPCR (SYBR Green) reaction with specific fungal and yeast primers. The qPCR was successful in amplifying and detecting all the yeast and fungal DNA, indicating that the DNA is of a high quality and can be used in sensitive downstream applications.

Figure 4. High Yields of DNA Isolated from Saccharomyces cerevisiae overnight culture. DNA was isolated from S. cerevisiae overnight culture using Norgen's Fungi/Yeast Genomic DNA Isolation 96-Well Kit. Following isolation of 10 samples, 10 µL from each 100 µL elution was loaded on 1% TAE agarose gel. Norgen's Fungi/Yeast Genomic DNA Isolation 96-Well Kit demonstrated a good and consistent DNA yield and integrity. Lane M: Norgen's HighRanger 1kb DNA Ladder.

Figure 5. High quality of yeast DNA measured by NanoDrop. DNA isolated from Saccharomyces cerevisiae overnight culture using Norgen's Fungi/Yeast Genomic DNA Isolation 96-Well Kit showed a high quality of DNA based on A260/280 and A260/230. This indicates that the isolated DNA from all samples is of a high quality and can be used in sensitive downstream applications.

Figure 6. Purified DNA Can be Amplified in a Real-time PCR (SYBER GREEN) Reaction. DNA was isolated from Saccharomyces cerevisiae overnight culture using Norgen's Fungi/Yeast Genomic DNA Isolation 96-Well Kit. Five µL of the DNA from each 100 µL elution was used in a real-time PCR reaction (total reaction volume of 20 µL) with S. cerevisiae primers. The real-time PCR was successful in amplifying the S. cerevisiae from all 10 isolated samples. This indicates that the isolated DNA from all samples is of a high quality and can be used in sensitive downstream applications. The black line is a no-template control.

Kit Specifications
Column Binding Capacity	50 μg
Maximum Column Loading Volume	650 μL
Maximum Amount of Starting Material: Fungi (wet weight) Yeast or Bacteria Culture	50 mg 0.5mL - 1mL
Average Yield* Pichia sp. (yeast) Botrytis cinerea Fusarium sp. Aspergillis niger Mucor racemosus Cladosporium cladosporioides Penicillium sp. Rhizopus oryzae Alternaria tenuissima	25 μg 32 μg 42 μg 26 μg 15 μg 12 μg 40 μg 7 μg 30 μg
Time to Complete 10 purifications	30 minutes

* 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 1 year after the date of shipment.

Component	Cat. 27300 (50 preps)	Cat. 27350 (192 preps)
Lysis Buffer L	30 mL	2 x 60 mL
Resuspension Solution A	20 mL	60 mL
Solution BX	28 mL	2 x 28 mL
Wash Solution A	18 mL	2 x 38 mL
Elution Buffer B	15 mL	30 mL
Bead Tubes	50	200
Spin Columns	50	-
Collection Tubes	50	-
96-Well Plate	-	2
96-Well Collection Plate	-	2
Adhesive Tape	-	4
Elution Tubes (1.7 mL)	50	-
96-Well Elution Plate	-	2
Product Insert	1	1

Documentation

FAQs

Spin Column, High Throughput

I noticed the columns/wells were clogged. What causes this?

Clogged columns/wells may occur due to the sample being too large:

Too many cells were applied to the column.
Ensure that the amount of cells used is less than 1 x 10⁸ viable yeast cells or 50 mg (wet weight) of fungal culture. 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.

Why is the elution turbid?

Turbidity in elution may be due to the sample being too large:

Depending on fungi species, sometimes turbidity can be observed in the elution. This may inhibit downstream applications. Reduce the amount of cells used, and perform a third wash during the Wash step.

Why do I have poor DNA recovery?

Poor DNA recovery could be due to one or more of the following: Lysis was not completed. Increase the incubation time at 65ºC to 15 minutes. Ethanol was not added to the Wash Solution A. Ensure that 42 mL of 96 - 100% ethanol is added to the supplied Wash Solution A prior to use. Solution BX was not added to the lysate. Solution BX enhances DNA binding to the column for maximum DNA recovery.

Why is the purified DNA not performing well in downstream applications?

If the DNA does not perform well in downstream applications, it may be due to one or more of 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 1 x 10⁸ viable yeast/bacterial cells or 50 mg (wet weight) of fungal culture.
Ethanol carryover.
Ensure that the dry spin under the Column Wash procedure is performed in order to remove traces of ethanol prior to elution. Ethanol is known to interfere with many downstream applications.
The columns/wells were not washed twice with the provided Wash Solution A.
Traces of salt from the binding step may remain in the sample if the column is not washed twice with the Wash Solution A. Salt may interfere with downstream applications, and thus must be washed from the column.
PCR reaction conditions need to be optimized.
Take steps to optimize the PCR conditions being used, including varying the amount of template (20 ng to 50 ng for 20 µL of PCR reaction), changing the source of Taq polymerase, adding BSA (final concentration is 0.1 µg/µL), looking into the primer design, and adjusting the annealing conditions.

Citations

Title	Identification of key physical, chemical and biological components invlved in soil and root health as a means to develop sustainable production systems for corn and soybeans
Citation	A&L Grain and Growers Report 2023.
Authors	G. Lazarovits, R. Islam, K. Delaney, B. P. Chennupati, D. Rodriguez, A. Zarir, S. Authier, C. Jouan, J. Park

Title	Induction of the antiviral factors APOBEC3A and RSAD2 upon CCL2
Citation	Mycological Progress 2023.
Authors	Oguzhan Kaygusuz, Kai Reschke, Abdullah Kaya, Bálint Dima, Olga Morozova, Machiel Evert Noordeloos & Meike Piepenbring

Title	Isolation and Characterization of Hydrocarbon Utilizing Yeast (HUY) Isolates from Palm Wine
Citation	American Journal of Molecular Biology 2023.
Authors	Okerentugba, P. O., Ataikiru, T. L., & Ichor, T

Title	Natural Diversity in Pentose Fermentation Is Explained by Variations in Histone Deacetylases
Citation	Cell Reports 2023.
Authors	Zvi Tamari, Naama Barkai

Title	Natural occurrence of Alternaria toxins in pomegranate fruit and the influence of some technological processing on their levels in juice
Citation	Acta Alimentaria 2023.
Authors	Elhariry, H. M., Khiralla, G. M., Gherbawy, Y., & Abd ElRahman, H

Title	Occurrence of QoI fungicide resistance in Cercospora sojina from Mississippi soybean
Citation	Plant Disease 2023.
Authors	JR Standish, M Tomaso-Peterson, TW Allen, S Sabandazovic, N Aboughanem-Sabanadzovic

Title	Phenotypic and genotypic characterization of Colombian clinical isolates of Sporothrix spp.
Citation	Biomedica. 2023.
Authors	Laura C. Álvarez-Acevedo, María C. Zuleta-González, Óscar M. Gómez-Guzmán, Álvaro L. Rúa-Giraldo, Orville Hernández-Ruiz, Juan G. McEwen-Ochoa, Martha E. Urán-Jiménez, Myrtha Arango-Arteaga, Rosely M. Zancopé-Oliveira, Manoel Marques Evangelista de Oliveira and María del P. Jiménez-Alzate

Title	Phylogeographic Analysis of Blastomyces dermatitidis and Blastomyces gilchristii Reveals an Association with North American Freshwater Drainage Basins
Citation	PLoS One 2023.
Authors	McTaggart, L. R., Brown, E. M., & Richardson, S. E

Title	Premature failure of utility poles in Switzerland and Germany related to wood decay basidiomycetes
Citation	International Journal of the Biology, Chemistry, Physics, and Technology of Wood 2023.
Authors	Ribera, J., Schubert, M., Fink, S., Cartabia, M., & Schwarze, F. W

Title	Sea foam as a source of fungal inoculum for the isolation of biologically active natural products
Citation	Mycology 2023.
Authors	DP Overy, F Berrue, H Correa, N Hanif, K Hay, M Lanteigne, K Mquilian, S Duffy, P Boland, R Jagannathan, GS Carr, M Vansteeland, RG Kerr

Fungi/Yeast Genomic DNA Isolation Kits