Cytoplasmic and Nuclear RNA Purification Kit

Features and Benefits

Excellent separation and purification of cytoplasmic and nuclear RNA
Convenient and fast spin column format
High quality and yield of RNA
Isolate full diversity of RNA (including microRNA) without phenol
Purified RNA is ready for any application including RT-PCR, qRT-PCR, RNA-Seq, arrays and more
Cytoplasmic RNA is free of DNA and ready for direct use in RT-PCR/qRT-PCR
Purification is based on spin column chromatography that uses Norgen’s proprietary resin separation matrix

This kit provides a rapid method for the isolation and purification of both cytoplasmic and nuclear RNA from cultured animal cells and small tissue samples. The kit can be used to isolate all sizes of RNA from the cytoplasmic and nuclear RNA fractions, including all small RNA species without any requirement for phenol. Included in the kit are sufficient reagents to perform either 50 cytoplasmic RNA preparations or 25 cytoplasmic and 25 nuclear RNA preparations. Ten samples can be processed in approximately 45 minutes. This kit is also available in a 100 prep size.

Background

In certain circumstances it is desirable to be able to isolate fractionated RNA as opposed to total RNA. For example, it may be preferable to isolate only mature, cytoplasmic RNA for some studies on expression profiling. Alternatively it may be desirable to isolate nuclear RNA in order to investigate and study pre-processed (non-spliced) RNA. Furthermore, this kit can be used to isolate RNA for downstream applications where it is necessary to avoid DNA contamination, since the cytoplasmic fraction has been shown to be free of all traces of genomic DNA.

Details

Supporting Data

Figure 1. Effective Separation of HeLa Cell Cytoplasmic & Nuclear RNA. Norgen's Cytoplasmic & Nuclear RNA Purification Kit was used to effectively separate cytoplasmic and nuclear RNA from 0.75 million HeLa cells in triplicate. Panel A: High quality cytoplasmic and nuclear RNA was purified using Norgen's kit. Note the integrity and quality of both cytoplasmic and nuclear RNA. Ten microliters of each 50 µL elution were run on a 1.5% formaldehyde-agarose gel. Lane M is Norgen's 1 kb RNA Ladder, lanes 1-3 contain nuclear RNA and lanes 4-6 contain cytoplasmic RNA. Panel B: Ten microliters of the above cytoplasmic and nuclear RNA isolated from HeLa cells using Norgen's kit was run on a 0.9% agarose DNA gel. Genomic DNA is clearly visible in the nuclear RNA fractions (lanes 1-3), however, no genomic DNA can be detected in the cytoplasmic RNA fractions (lanes 4-6). Note that an optional on-column DNase treatment protocol is provided to remove the genomic DNA in the nuclear fraction.

Figure 2. Superior Separation of HeLa Cell Cytoplasmic & Nuclear RNA. Norgen's Cytoplasmic & Nuclear RNA Purification Kit provides better separation of cytoplasmic and nuclear RNA from 0.8 million HeLa cells when compared to a leading competitor’s product. Panel A: Cytoplasmic and nuclear RNA purified from HeLa cells using Norgen's kit and a competitor's kit. Ten microliters of each 50 µL elution (Norgen or competitor's kit) of the cytoplasmic (C) or nuclear (N) RNA were run on a 1.5% formaldehyde-agarose gel. Higher yields of RNA with good integrity were isolated using Norgen's kit. Panel B: Ten microliters of the cytoplasmic and nuclear RNA isolated from HeLa cells using Norgen's kit and the competitor's kit was run on a 0.9% agarose gel. Genomic DNA only co-migrates with the nuclear fraction in RNA isolated using Norgen’s Cytoplasmic & Nuclear RNA Purification Kit, not the cytoplasmic fraction. Note that an optional on-column DNase treatment protocol is provided to remove the genomic DNA in the nuclear fraction. In contrast, significant genomic DNA contamination was observed in the cytoplasmic fraction of the RNA isolated using the competitor's kit.

Figure 3. Genomic DNA-free Cytoplasmic RNA. RT-PCR was performed using human beta actin primers on 2 µL of the 50 µL of cytoplasmic RNA isolated from 1 million HeLa cells using Norgen's Cytoplasmic & Nuclear RNA Purification Kit. Lane M is Norgen's PCR Sizer DNA ladder, Lanes 1 and 3 are the negative control (PCR only, without reverse transcript), and Lanes 2 and 4 are the actual RT-PCR that show the expected 166 bp RT-PCR product. The expected amplicon size from the gene copy is the same as that from the RNA transcript. The lack of product in lanes 1 and 3 indicates that no genomic DNA contamination is present in the isolated cytoplasmic RNA. All PCR products were resolved on a 1X TAE, 2% agarose gel.

Figure 4. Specific Separation and Subsequent Amplification of Cytoplasmic and Nuclear Transcripts. Norgen's Cytoplasmic & Nuclear RNA Purification Kit effectively separates cytoplasmic and nuclear RNA. RT-PCR was performed using human U2 snRNA (Panel A) or S14 (Panel B) primers on 0.5 µg of either cytoplasmic or nuclear RNA fractions isolated from 1 million HeLa cells using Norgen's Cytoplasmic & Nuclear RNA Purification Kit. In Panel A, an intense PCR product was observed only in the nuclear fraction when the nuclear-specific U2 snRNA primers were used. In Panel B, the majority of the PCR product for the house-keeping transcript of S14 was observed in the cytoplasmic fraction. The two results combined showed effective separation of the cytoplasmic and nuclear RNA using Norgen's Cytoplasmic & Nuclear RNA Purification Kit. All PCR products were resolved on a 1X TAE, 1.5% agarose DNA gel.

Kit Specifications
Maximum Column Binding Capacity	Up to 50 µg RNA
Maximum Column Loading Volume	650 µL
Size of RNA Purified	All sizes, including small RNA (< 200 nt)
Time to Complete 10 Purifications	45 minutes
RNA Yield HeLa (1 x 10⁶) - Cytoplasmic RNA HeLa (1 x 10⁶) - Nuclear RNA	15 µg ≤ 3.5 µg

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.

Component	Cat. 21000 (50 preps)	Cat. 37400 (100 preps)
Lysis Buffer J	20 mL	2 x 20 mL
Buffer SK	40 mL	2 x 40 mL
Wash Solution A	38 mL	2 x 38 mL
Elution Buffer E	6 mL	2 x 6 mL
Mini Spin Columns	50	100
Collection Tubes	50	100
Elution Tubes (1.7 mL)	50	100
Product Insert	1	1

Documentation

RELATED BLOGS

FAQs

Spin Column

Why do I have poor RNA recovery?

Poor RNA recovery could be due to one or more of the following:

Insufficient solubilization of cells or tissue.
Ensure that the appropriate amount of Lysis Buffer J was used for the amount of cells or tissue.
Column has become clogged.
Do not exceed the recommended amounts of starting materials. The amount of starting material may need to be decreased if the column shows clogging below the recommended levels. See FAQ related to “Clogged Column” below.
An alternative elution solution was used.
It is recommended that the Elution Buffer E supplied with this kit be used for maximum RNA recovery.
Ethanol was not added to the lysate.
Ensure that the appropriate amount of ethanol is added to the lysate before binding to the column.
Ethanol was not added to the Wash Solution A.
Ensure that 90 mL of 96-100% ethanol is added to the supplied Wash Solution A prior to use.
Cell Culture: Cell monolayer was not washed with PBS.
Ensure that the cell monolayer is washed with the appropriate amount of PBS in order to remove residual media from cells.

I noticed the column was clogged. What causes this?

Column clogging can result from one or a combination of the following factors:

Insufficient solubilization of cells or tissues.
Ensure that the appropriate amount of Lysis Buffer J was used for the amount of cells or tissue.
Maximum number of cells or amount of tissue exceeds kit specifications.
Refer to specifications to determine if the amount of starting material falls within kit specifications.
High amounts of genomic DNA present in sample.
The nuclear lysate fraction may be passed through a 25 gauge needle attached to a syringe 5-10 times in order to shear the genomic DNA prior to loading onto the column.
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 columns to clog.

Why is the RNA degraded?

RNA can be degraded due to the following factors:

RNase contamination.
RNases may be introduced during the use of the kit. Ensure proper procedures are followed when working with RNA. Please refer to “Working with RNA” at the beginning of this user guide.
Procedure not performed quickly enough.
In order to maintain the integrity of the RNA, it is important that the procedure be performed quickly. This is especially important for the Cell Lysate Preparation Step in the Animal Tissue protocol, since the RNA in animal tissues is not protected after harvesting until it is disrupted and homogenized.
Improper storage of the purified RNA.
For short term storage, RNA samples may be stored at –20℃ for a few days. It is recommended that samples be stored at –70℃ for longer term storage.
Frozen tissues or cell pellets were allowed to thaw prior to RNA isolation.
Do not allow frozen tissues to thaw prior to grinding with the mortar and pestle in order to ensure that the integrity of the RNA is not compromised.
Tissue samples were frozen improperly.
Samples should be flash-frozen in liquid nitrogen and transferred immediately to a -70℃ freezer for long-term storage.

Why is the RNA not performing well in downstream applications?

If the RNA does not perform well in downstream applications, it may be due to one or more of the following:

RNA was not washed 3 times with the provided Wash Solution A.
Traces of salt from the binding step may remain in the sample if the column is not washed 3 times with Wash Solution A. Salt may interfere with downstream applications, and thus must be washed from the column.
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.

I noticed genomic DNA contamination in cytoplasmic fraction. How to prevent this?

Genomic DNA contamination could be because traces of nuclear pellet remained in cytoplasmic fraction. Ensure that a solid pellet is formed at the end of the Cell Fraction Preparation step, and that none of the pellet is removed when the supernatant is transferred to another tube.

What are suggested markers to differentiate between the cytoplasmic and nuclear fractions using RT-PCR?

Please refer to supporting data Fig 4 where we have shown a qPCR for U2 snRNA which is amplified only in nuclear fraction, and also a qPCR for S14 RNA which is amplified in cytoplasmic fraction.

Citations

Title	Satellite RNAs promote pancreatic oncogenic processes via the dysfunction of YBX1
Citation	Nature Communications 2016.
Authors	Kishikawa, T., Otsuka, M., Yoshikawa, T., Ohno, M., Ijichi, H., & Koike, K

Title	Global transcript structure resolution of high gene density genomes through multi-platform data integration
Citation	Nucleic Acids Research 2016.
Authors	O'Grady, T., Wang, X., zu Bentrup, K. H., Baddoo, M., Concha, M., & Flemington, E. K

Title	Long noncoding RNA GPC3-AS1 promotes hepatocellular carcinoma progression via epigenetically activating GPC3
Citation	The FEBS Journal 2016.
Authors	Zhu, X. T., Yuan, J. H., Zhu, T. T., Li, Y. Y., & Cheng, X. Y.

Title	Long noncoding RNA GIHCG promotes hepatocellular carcinoma progression through epigenetically regulating miR-200b/a/429
Citation	Journal of Molecular Medicine 2016.
Authors	Sui, C. J., Zhou, Y. M., Shen, W. F., Dai, B. H., Lu, J. J., Zhang, M. F., & Yang, J. M

Title	Long noncoding RNA FGFR3-AS1 promotes osteosarcoma growth through regulating its natural antisense transcript FGFR3
Citation	Molecular Biology Reports 2016.
Authors	Sun, J., Wang, X., Fu, C., Wang, X., Zou, J., Hua, H., & Bi, Z.

Title	Bovine Adenovirus-3 pVIII Suppresses Cap-Dependent mRNA Translation Possibly by Interfering with the Recruitment of DDX3 and Translation Initiation Factors to the mRNA Cap
Citation	Frontiers in Microbiology 2016.
Authors	Ayalew, L. E., Patel, A. K., Gaba, A., Islam, A., & Tikoo, S. K

Title	The microRNA cluster miR-183/96/182 contributes to long-term memory in a protein phosphatase 1-dependent manner
Citation	Nature Communications 2016.
Authors	Woldemichael, B. T., Jawaid, A., Kremer, E. A., Gaur, N., Krol, J., Marchais, A., & Mansuy, I. M

Title	Extracellular Vesicles Including Exosomes Regulate Innate Immune Responses to Hepatitis B Virus Infection
Citation	Fronteirs in Immunology 2016.
Authors	Kouwaki, T., Fukushima, Y., Daito, T., Sanada, T., Yamamoto, N., Mifsud, E. J., ... & Seya, T.

Title	Evidence for a role of a lncRNA encoded from the p53 tumor suppressor gene in maintaining the undifferentiated state of human myeloid leukemias
Citation	Gene Reports 2016.
Authors	Reisman, D., Gibson, A., Patel, M., & Wang, Y

Title	Regulation of p53 during senescence in normal human keratinocytes
Citation	Aging Cell 2015.
Authors	RH Kim, MK Kang, T Kim, P Yang, S Bae, DW Williams, S Phung, Kh Shin, C Hong, HN Park

Cytoplasmic and Nuclear RNA Purification Kit