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Northern blot

April 21, 2023

The northern blot, or RNA blot,[1] is a technique used in molecular biology research to study gene expression by detection of RNA (or isolated mRNA) in a sample.[2][3]

Flow diagram outlining the general procedure for RNA detection by northern blotting.

With northern blotting it is possible to observe cellular control over structure and function by determining the particular gene expression rates during differentiation and morphogenesis, as well as in abnormal or diseased conditions.[4] Northern blotting involves the use of electrophoresis to separate RNA samples by size, and detection with a hybridization probe complementary to part of or the entire target sequence. Strictly speaking, the term 'northern blot' refers specifically to the capillary transfer of RNA from the electrophoresis gel to the blotting membrane. However, the entire process is commonly referred to as northern blotting.[5] The northern blot technique was developed in 1977 by James Alwine, David Kemp, and George Stark at Stanford University.[6] Northern blotting takes its name from its similarity to the first blotting technique, the Southern blot, named for biologist Edwin Southern.[2] The major difference is that RNA, rather than DNA, is analyzed in the northern blot.[7]

Procedure

A general blotting procedure[5] starts with extraction of total RNA from a homogenized tissue sample or from cells. Eukaryotic mRNA can then be isolated through the use of oligo (dT) cellulose chromatography to isolate only those RNAs with a poly(A) tail.[8][9] RNA samples are then separated by gel electrophoresis. Since the gels are fragile and the probes are unable to enter the matrix, the RNA samples, now separated by size, are transferred to a nylon membrane through a capillary or vacuum blotting system.

 
Capillary blotting system setup for the transfer of RNA from an electrophoresis gel to a blotting membrane.

A nylon membrane with a positive charge is the most effective for use in northern blotting since the negatively charged nucleic acids have a high affinity for them. The transfer buffer used for the blotting usually contains formamide because it lowers the annealing temperature of the probe-RNA interaction, thus eliminating the need for high temperatures, which could cause RNA degradation.[10] Once the RNA has been transferred to the membrane, it is immobilized through covalent linkage to the membrane by UV light or heat. After a probe has been labeled, it is hybridized to the RNA on the membrane. Experimental conditions that can affect the efficiency and specificity of hybridization include ionic strength, viscosity, duplex length, mismatched base pairs, and base composition.[11] The membrane is washed to ensure that the probe has bound specifically and to prevent background signals from arising. The hybrid signals are then detected by X-ray film and can be quantified by densitometry. To create controls for comparison in a northern blot, samples not displaying the gene product of interest can be used after determination by microarrays or RT-PCR.[11]

Gels

 
RNA run on a formaldehyde agarose gel to highlight the 28S (top band) and 18S (lower band) ribosomal subunits.

The RNA samples are most commonly separated on agarose gels containing formaldehyde as a denaturing agent for the RNA to limit secondary structure.[11][12] The gels can be stained with ethidium bromide (EtBr) and viewed under UV light to observe the quality and quantity of RNA before blotting.[11] Polyacrylamide gel electrophoresis with urea can also be used in RNA separation but it is most commonly used for fragmented RNA or microRNAs.[13] An RNA ladder is often run alongside the samples on an electrophoresis gel to observe the size of fragments obtained but in total RNA samples the ribosomal subunits can act as size markers.[11] Since the large ribosomal subunit is 28S (approximately 5kb) and the small ribosomal subunit is 18S (approximately 2kb) two prominent bands appear on the gel, the larger at close to twice the intensity of the smaller.[11][14]

Probes

Probes for northern blotting are composed of nucleic acids with a complementary sequence to all or part of the RNA of interest, they can be DNA, RNA, or oligonucleotides with a minimum of 25 complementary bases to the target sequence.[5] RNA probes (riboprobes) that are transcribed in vitro are able to withstand more rigorous washing steps preventing some of the background noise.[11] Commonly cDNA is created with labelled primers for the RNA sequence of interest to act as the probe in the northern blot.[15] The probes must be labelled either with radioactive isotopes (32P) or with chemiluminescence in which alkaline phosphatase or horseradish peroxidase (HRP) break down chemiluminescent substrates producing a detectable emission of light.[16] The chemiluminescent labelling can occur in two ways: either the probe is attached to the enzyme, or the probe is labelled with a ligand (e.g. biotin) for which the ligand (e.g., avidin or streptavidin) is attached to the enzyme (e.g. HRP).[11] X-ray film can detect both the radioactive and chemiluminescent signals and many researchers prefer the chemiluminescent signals because they are faster, more sensitive, and reduce the health hazards that go along with radioactive labels.[16] The same membrane can be probed up to five times without a significant loss of the target RNA.[10]

Applications

Northern blotting allows one to observe a particular gene's expression pattern between tissues, organs, developmental stages, environmental stress levels, pathogen infection, and over the course of treatment.[9][15][17] The technique has been used to show overexpression of oncogenes and downregulation of tumor-suppressor genes in cancerous cells when compared to 'normal' tissue,[11] as well as the gene expression in the rejection of transplanted organs.[18] If an upregulated gene is observed by an abundance of mRNA on the northern blot the sample can then be sequenced to determine if the gene is known to researchers or if it is a novel finding.[18] The expression patterns obtained under given conditions can provide insight into the function of that gene. Since the RNA is first separated by size, if only one probe type is used variance in the level of each band on the membrane can provide insight into the size of the product, suggesting alternative splice products of the same gene or repetitive sequence motifs.[8][14] The variance in size of a gene product can also indicate deletions or errors in transcript processing. By altering the probe target used along the known sequence it is possible to determine which region of the RNA is missing.[2]

Advantages and disadvantages

Analysis of gene expression can be done by several different methods including RT-PCR, RNase protection assays, microarrays, RNA-Seq, serial analysis of gene expression (SAGE), as well as northern blotting.[4][5] Microarrays are quite commonly used and are usually consistent with data obtained from northern blots; however, at times northern blotting is able to detect small changes in gene expression that microarrays cannot.[19] The advantage that microarrays have over northern blots is that thousands of genes can be visualized at a time, while northern blotting is usually looking at one or a small number of genes.[17][19]

A problem in northern blotting is often sample degradation by RNases (both endogenous to the sample and through environmental contamination), which can be avoided by proper sterilization of glassware and the use of RNase inhibitors such as DEPC (diethylpyrocarbonate).[5] The chemicals used in most northern blots can be a risk to the researcher, since formaldehyde, radioactive material, ethidium bromide, DEPC, and UV light are all harmful under certain exposures.[11] Compared to RT-PCR, northern blotting has a low sensitivity, but it also has a high specificity, which is important to reduce false positive results.[11]

The advantages of using northern blotting include the detection of RNA size, the observation of alternate splice products, the use of probes with partial homology, the quality and quantity of RNA can be measured on the gel prior to blotting, and the membranes can be stored and reprobed for years after blotting.[11]

For northern blotting for the detection of acetylcholinesterase mRNA the nonradioactive technique was compared to a radioactive technique and found as sensitive as the radioactive one, but requires no protection against radiation and is less time-consuming.[20]

Reverse northern blot

Researchers occasionally use a variant of the procedure known as the reverse northern blot. In this procedure, the substrate nucleic acid (that is affixed to the membrane) is a collection of isolated DNA fragments, and the probe is RNA extracted from a tissue and radioactively labelled. The use of DNA microarrays that have come into widespread use in the late 1990s and early 2000s is more akin to the reverse procedure, in that they involve the use of isolated DNA fragments affixed to a substrate, and hybridization with a probe made from cellular RNA. Thus the reverse procedure, though originally uncommon, enabled northern analysis to evolve into gene expression profiling, in which many (possibly all) of the genes in an organism may have their expression monitored.

See also

References

  1. ^ Gilbert, S. F. (2000) Developmental Biology, 6th Ed. Sunderland MA, Sinauer Associates.
  2. ^ a b c Alberts, B., Johnson, A., Lewis, J. Raff, M., Roberts, K., Walter, P. 2008. Molecular Biology of the Cell, 5th ed. Garland Science, Taylor & Francis Group, NY, pp 538–539.
  3. ^ Kevil, C. G., Walsh, L., Laroux, F. S., Kalogeris, T., Grisham, M. B., Alexander, J. S. (1997) An Improved, Rapid Northern Protocol. Biochem. and Biophys. Research Comm. 238:277–279.
  4. ^ a b Schlamp, K.; Weinmann, A.; Krupp, M.; Maass, T.; Galle, P. R.; Teufel, A. (2008). "BlotBase: A northern blot database". Gene. 427 (1–2): 47–50. doi:10.1016/j.gene.2008.08.026. PMID 18838116.
  5. ^ a b c d e Trayhurn, P. (1996) Northern Blotting. Pro. Nutrition Soc. 55:583–589.
  6. ^ Alwine JC, Kemp DJ, Stark GR (1977). "Method for detection of specific RNAs in agarose gels by transfer to diazobenzyloxymethyl-paper and hybridization with DNA probes". Proc. Natl. Acad. Sci. U.S.A. 74 (12): 5350–4. Bibcode:1977PNAS...74.5350A. doi:10.1073/pnas.74.12.5350. PMC 431715. PMID 414220.
  7. ^ Bor, Y.C.; Swartz, J.; Li, Y.; Coyle, J.; Rekosh, D.; Hammarskjold, Marie-Louise (2006). "Northern Blot analysis of mRNA from mammalian polyribosomes". Nature Protocols. doi:10.1038/nprot.2006.216.
  8. ^ a b Durand, G. M.; Zukin, R. S. (1993). "Developmental Regulation of mRNAs Encoding Rat Brain Kainate/AMPA Receptors: A Northern Analysis Study". J. Neurochem. 61 (6): 2239–2246. doi:10.1111/j.1471-4159.1993.tb07465.x. PMID 8245974. S2CID 33955961.
  9. ^ a b Mori, H.; Takeda-Yoshikawa, Y.; Hara-Nishimura, I.; Nishimura, M. (1991). "Pumpkin malate synthase Cloning and sequencing of the cDNA and Northern blot analysis". Eur. J. Biochem. 197 (2): 331–336. doi:10.1111/j.1432-1033.1991.tb15915.x. PMID 1709098.
  10. ^ a b Yang, H.; McLeese, J.; Weisbart, M.; Dionne, J.-L.; Lemaire, I.; Aubin, R. A. (1993). "Simplified high throughput protocol for Northern hybridization". Nucleic Acids Research. 21 (14): 3337–3338. doi:10.1093/nar/21.14.3337. PMC 309787. PMID 8341618.
  11. ^ a b c d e f g h i j k l Streit, S.; Michalski, C. W.; Erkan, M.; Kleef, J.; Friess, H. (2009). "Northern blot analysis for detection of RNA in pancreatic cancer cells and tissues". Nature Protocols. 4 (1): 37–43. doi:10.1038/nprot.2008.216. PMID 19131955. S2CID 24980302.
  12. ^ Yamanaka, S.; Poksay, K. S.; Arnold, K. S.; Innerarity, T. L. (1997). "A novel translational repressor mRNA is edited extensively in livers containing tumors caused by the transgene expression of the apoB mRNA-editing enzyme". Genes Dev. 11 (3): 321–333. doi:10.1101/gad.11.3.321. PMID 9030685.
  13. ^ Valoczi, A., Hornyik, C., Varga, N., Burgyan, J., Kauppinen, S., Havelda, Z. (2004) Sensitive and specific detection of microRNAs by northern blot analysis using LNA-modified oligonucleotide probes. Nuc. Acids Research. 32: e175.
  14. ^ a b Gortner, G.; Pfenninger, M.; Kahl, G.; Weising, K. (1996). "Northern blot analysis of simple repetitive sequence transcription in plants". Electrophoresis. 17 (7): 1183–1189. doi:10.1002/elps.1150170702. PMID 8855401. S2CID 36857667.
  15. ^ a b Liang, P. Pardee, A. B. (1995) Recent advances in differential display. Current Opinion Immunol. 7: 274–280.
  16. ^ a b Engler-Blum, G.; Meier, M.; Frank, J.; Muller, G. A. (1993). "Reduction of Background Problems in Nonradioactive Northern and Southern Blot Analysis Enables Higher Sensitivity Than 32P-Based Hybridizations". Anal. Biochem. 210 (2): 235–244. doi:10.1006/abio.1993.1189. PMID 7685563.
  17. ^ a b Baldwin, D., Crane, V., Rice, D. (1999) A comparison of gel-based, nylon filter and microarray techniques to detect differential RNA expression in plants. Current Opinion in Plant Biol. 2: 96–103.
  18. ^ a b Utans, U.; Liang, P.; Wyner, L. R.; Karnovsky, M. J.; Russel, M. E. (1994). "Chronic cardiac rejection: Identification of five upregulated genes in transplanted hearts by differential mRNA display". Proc. Natl. Acad. Sci. USA. 91 (14): 6463–6467. Bibcode:1994PNAS...91.6463U. doi:10.1073/pnas.91.14.6463. PMC 44222. PMID 8022806.
  19. ^ a b Taniguchi, M.; Miura, K.; Iwao, H.; Yamanaka, S. (2001). "Quantitative Assessment of DNA Microarrays – Comparison with Northern Blot Analysis". Genomics. 71 (1): 34–39. doi:10.1006/geno.2000.6427. PMID 11161795.
  20. ^ Kreft, K., Kreft, S., Komel, R., Grubič, Z. (2000). Nonradioactive northern blotting for the determination of acetylcholinesterase mRNA. Pflügers Arch – Eur J Physiol, 439:R66-R67

External links

 
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April 21, 2023
northern, blot, northern, blot, blot, technique, used, molecular, biology, research, study, gene, expression, detection, isolated, mrna, sample, flow, diagram, outlining, general, procedure, detection, northern, blotting, with, northern, blotting, possible, ob. The northern blot or RNA blot 1 is a technique used in molecular biology research to study gene expression by detection of RNA or isolated mRNA in a sample 2 3 Flow diagram outlining the general procedure for RNA detection by northern blotting With northern blotting it is possible to observe cellular control over structure and function by determining the particular gene expression rates during differentiation and morphogenesis as well as in abnormal or diseased conditions 4 Northern blotting involves the use of electrophoresis to separate RNA samples by size and detection with a hybridization probe complementary to part of or the entire target sequence Strictly speaking the term northern blot refers specifically to the capillary transfer of RNA from the electrophoresis gel to the blotting membrane However the entire process is commonly referred to as northern blotting 5 The northern blot technique was developed in 1977 by James Alwine David Kemp and George Stark at Stanford University 6 Northern blotting takes its name from its similarity to the first blotting technique the Southern blot named for biologist Edwin Southern 2 The major difference is that RNA rather than DNA is analyzed in the northern blot 7 Contents 1 Procedure 1 1 Gels 1 2 Probes 2 Applications 3 Advantages and disadvantages 4 Reverse northern blot 5 See also 6 References 7 External linksProcedure EditA general blotting procedure 5 starts with extraction of total RNA from a homogenized tissue sample or from cells Eukaryotic mRNA can then be isolated through the use of oligo dT cellulose chromatography to isolate only those RNAs with a poly A tail 8 9 RNA samples are then separated by gel electrophoresis Since the gels are fragile and the probes are unable to enter the matrix the RNA samples now separated by size are transferred to a nylon membrane through a capillary or vacuum blotting system Capillary blotting system setup for the transfer of RNA from an electrophoresis gel to a blotting membrane A nylon membrane with a positive charge is the most effective for use in northern blotting since the negatively charged nucleic acids have a high affinity for them The transfer buffer used for the blotting usually contains formamide because it lowers the annealing temperature of the probe RNA interaction thus eliminating the need for high temperatures which could cause RNA degradation 10 Once the RNA has been transferred to the membrane it is immobilized through covalent linkage to the membrane by UV light or heat After a probe has been labeled it is hybridized to the RNA on the membrane Experimental conditions that can affect the efficiency and specificity of hybridization include ionic strength viscosity duplex length mismatched base pairs and base composition 11 The membrane is washed to ensure that the probe has bound specifically and to prevent background signals from arising The hybrid signals are then detected by X ray film and can be quantified by densitometry To create controls for comparison in a northern blot samples not displaying the gene product of interest can be used after determination by microarrays or RT PCR 11 Gels Edit RNA run on a formaldehyde agarose gel to highlight the 28S top band and 18S lower band ribosomal subunits The RNA samples are most commonly separated on agarose gels containing formaldehyde as a denaturing agent for the RNA to limit secondary structure 11 12 The gels can be stained with ethidium bromide EtBr and viewed under UV light to observe the quality and quantity of RNA before blotting 11 Polyacrylamide gel electrophoresis with urea can also be used in RNA separation but it is most commonly used for fragmented RNA or microRNAs 13 An RNA ladder is often run alongside the samples on an electrophoresis gel to observe the size of fragments obtained but in total RNA samples the ribosomal subunits can act as size markers 11 Since the large ribosomal subunit is 28S approximately 5kb and the small ribosomal subunit is 18S approximately 2kb two prominent bands appear on the gel the larger at close to twice the intensity of the smaller 11 14 Probes Edit Probes for northern blotting are composed of nucleic acids with a complementary sequence to all or part of the RNA of interest they can be DNA RNA or oligonucleotides with a minimum of 25 complementary bases to the target sequence 5 RNA probes riboprobes that are transcribed in vitro are able to withstand more rigorous washing steps preventing some of the background noise 11 Commonly cDNA is created with labelled primers for the RNA sequence of interest to act as the probe in the northern blot 15 The probes must be labelled either with radioactive isotopes 32P or with chemiluminescence in which alkaline phosphatase or horseradish peroxidase HRP break down chemiluminescent substrates producing a detectable emission of light 16 The chemiluminescent labelling can occur in two ways either the probe is attached to the enzyme or the probe is labelled with a ligand e g biotin for which the ligand e g avidin or streptavidin is attached to the enzyme e g HRP 11 X ray film can detect both the radioactive and chemiluminescent signals and many researchers prefer the chemiluminescent signals because they are faster more sensitive and reduce the health hazards that go along with radioactive labels 16 The same membrane can be probed up to five times without a significant loss of the target RNA 10 Applications EditNorthern blotting allows one to observe a particular gene s expression pattern between tissues organs developmental stages environmental stress levels pathogen infection and over the course of treatment 9 15 17 The technique has been used to show overexpression of oncogenes and downregulation of tumor suppressor genes in cancerous cells when compared to normal tissue 11 as well as the gene expression in the rejection of transplanted organs 18 If an upregulated gene is observed by an abundance of mRNA on the northern blot the sample can then be sequenced to determine if the gene is known to researchers or if it is a novel finding 18 The expression patterns obtained under given conditions can provide insight into the function of that gene Since the RNA is first separated by size if only one probe type is used variance in the level of each band on the membrane can provide insight into the size of the product suggesting alternative splice products of the same gene or repetitive sequence motifs 8 14 The variance in size of a gene product can also indicate deletions or errors in transcript processing By altering the probe target used along the known sequence it is possible to determine which region of the RNA is missing 2 Advantages and disadvantages EditAnalysis of gene expression can be done by several different methods including RT PCR RNase protection assays microarrays RNA Seq serial analysis of gene expression SAGE as well as northern blotting 4 5 Microarrays are quite commonly used and are usually consistent with data obtained from northern blots however at times northern blotting is able to detect small changes in gene expression that microarrays cannot 19 The advantage that microarrays have over northern blots is that thousands of genes can be visualized at a time while northern blotting is usually looking at one or a small number of genes 17 19 A problem in northern blotting is often sample degradation by RNases both endogenous to the sample and through environmental contamination which can be avoided by proper sterilization of glassware and the use of RNase inhibitors such as DEPC diethylpyrocarbonate 5 The chemicals used in most northern blots can be a risk to the researcher since formaldehyde radioactive material ethidium bromide DEPC and UV light are all harmful under certain exposures 11 Compared to RT PCR northern blotting has a low sensitivity but it also has a high specificity which is important to reduce false positive results 11 The advantages of using northern blotting include the detection of RNA size the observation of alternate splice products the use of probes with partial homology the quality and quantity of RNA can be measured on the gel prior to blotting and the membranes can be stored and reprobed for years after blotting 11 For northern blotting for the detection of acetylcholinesterase mRNA the nonradioactive technique was compared to a radioactive technique and found as sensitive as the radioactive one but requires no protection against radiation and is less time consuming 20 Reverse northern blot EditResearchers occasionally use a variant of the procedure known as the reverse northern blot In this procedure the substrate nucleic acid that is affixed to the membrane is a collection of isolated DNA fragments and the probe is RNA extracted from a tissue and radioactively labelled The use of DNA microarrays that have come into widespread use in the late 1990s and early 2000s is more akin to the reverse procedure in that they involve the use of isolated DNA fragments affixed to a substrate and hybridization with a probe made from cellular RNA Thus the reverse procedure though originally uncommon enabled northern analysis to evolve into gene expression profiling in which many possibly all of the genes in an organism may have their expression monitored See also EditWestern blot Eastern blot Northwestern blot Far eastern blot Far western blot Differential displayReferences Edit Gilbert S F 2000 Developmental Biology 6th Ed Sunderland MA Sinauer Associates a b c Alberts B Johnson A Lewis J Raff M Roberts K Walter P 2008 Molecular Biology of the Cell 5th ed Garland Science Taylor amp Francis Group NY pp 538 539 Kevil C G Walsh L Laroux F S Kalogeris T Grisham M B Alexander J S 1997 An Improved Rapid Northern Protocol Biochem and Biophys Research Comm 238 277 279 a b Schlamp K Weinmann A Krupp M Maass T Galle P R Teufel A 2008 BlotBase A northern blot database Gene 427 1 2 47 50 doi 10 1016 j gene 2008 08 026 PMID 18838116 a b c d e Trayhurn P 1996 Northern Blotting Pro Nutrition Soc 55 583 589 Alwine JC Kemp DJ Stark GR 1977 Method for detection of specific RNAs in agarose gels by transfer to diazobenzyloxymethyl paper and hybridization with DNA probes Proc Natl Acad Sci U S A 74 12 5350 4 Bibcode 1977PNAS 74 5350A doi 10 1073 pnas 74 12 5350 PMC 431715 PMID 414220 Bor Y C Swartz J Li Y Coyle J Rekosh D Hammarskjold Marie Louise 2006 Northern Blot analysis of mRNA from mammalian polyribosomes Nature Protocols doi 10 1038 nprot 2006 216 a b Durand G M Zukin R S 1993 Developmental Regulation of mRNAs Encoding Rat Brain Kainate AMPA Receptors A Northern Analysis Study J Neurochem 61 6 2239 2246 doi 10 1111 j 1471 4159 1993 tb07465 x PMID 8245974 S2CID 33955961 a b Mori H Takeda Yoshikawa Y Hara Nishimura I Nishimura M 1991 Pumpkin malate synthase Cloning and sequencing of the cDNA and Northern blot analysis Eur J Biochem 197 2 331 336 doi 10 1111 j 1432 1033 1991 tb15915 x PMID 1709098 a b Yang H McLeese J Weisbart M Dionne J L Lemaire I Aubin R A 1993 Simplified high throughput protocol for Northern hybridization Nucleic Acids Research 21 14 3337 3338 doi 10 1093 nar 21 14 3337 PMC 309787 PMID 8341618 a b c d e f g h i j k l Streit S Michalski C W Erkan M Kleef J Friess H 2009 Northern blot analysis for detection of RNA in pancreatic cancer cells and tissues Nature Protocols 4 1 37 43 doi 10 1038 nprot 2008 216 PMID 19131955 S2CID 24980302 Yamanaka S Poksay K S Arnold K S Innerarity T L 1997 A novel translational repressor mRNA is edited extensively in livers containing tumors caused by the transgene expression of the apoB mRNA editing enzyme Genes Dev 11 3 321 333 doi 10 1101 gad 11 3 321 PMID 9030685 Valoczi A Hornyik C Varga N Burgyan J Kauppinen S Havelda Z 2004 Sensitive and specific detection of microRNAs by northern blot analysis using LNA modified oligonucleotide probes Nuc Acids Research 32 e175 a b Gortner G Pfenninger M Kahl G Weising K 1996 Northern blot analysis of simple repetitive sequence transcription in plants Electrophoresis 17 7 1183 1189 doi 10 1002 elps 1150170702 PMID 8855401 S2CID 36857667 a b Liang P Pardee A B 1995 Recent advances in differential display Current Opinion Immunol 7 274 280 a b Engler Blum G Meier M Frank J Muller G A 1993 Reduction of Background Problems in Nonradioactive Northern and Southern Blot Analysis Enables Higher Sensitivity Than 32P Based Hybridizations Anal Biochem 210 2 235 244 doi 10 1006 abio 1993 1189 PMID 7685563 a b Baldwin D Crane V Rice D 1999 A comparison of gel based nylon filter and microarray techniques to detect differential RNA expression in plants Current Opinion in Plant Biol 2 96 103 a b Utans U Liang P Wyner L R Karnovsky M J Russel M E 1994 Chronic cardiac rejection Identification of five upregulated genes in transplanted hearts by differential mRNA display Proc Natl Acad Sci USA 91 14 6463 6467 Bibcode 1994PNAS 91 6463U doi 10 1073 pnas 91 14 6463 PMC 44222 PMID 8022806 a b Taniguchi M Miura K Iwao H Yamanaka S 2001 Quantitative Assessment of DNA Microarrays Comparison with Northern Blot Analysis Genomics 71 1 34 39 doi 10 1006 geno 2000 6427 PMID 11161795 Kreft K Kreft S Komel R Grubic Z 2000 Nonradioactive northern blotting for the determination of acetylcholinesterase mRNA Pflugers Arch Eur J Physiol 439 R66 R67External links Edit Wikimedia Commons has media related to Northern blot OpenWetWare Retrieved from https en wikipedia org w index php title Northern blot amp oldid 1136157156, wikipedia, wiki, book, books, library,

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