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Discusses very widely-used techniques. Aimed specifically at the newcomer. Provides detailed explanations unavailable elsewhere. Points out pitfalls and provides solutions
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Discusses very widely-used techniques. Aimed specifically at the newcomer. Provides detailed explanations unavailable elsewhere. Points out pitfalls and provides solutions
Produktdetails
- Produktdetails
- Verlag: Routledge
- Seitenzahl: 123
- Erscheinungstermin: 15. Juni 1994
- Englisch
- Abmessung: 246mm x 189mm x 7mm
- Gewicht: 236g
- ISBN-13: 9780199634460
- ISBN-10: 0199634467
- Artikelnr.: 22595697
- Verlag: Routledge
- Seitenzahl: 123
- Erscheinungstermin: 15. Juni 1994
- Englisch
- Abmessung: 246mm x 189mm x 7mm
- Gewicht: 236g
- ISBN-13: 9780199634460
- ISBN-10: 0199634467
- Artikelnr.: 22595697
The Medical Molecular Biology Unit Department of Molecular Pathology University College London Medical School The Windeyer Building, Cleveland Street, London WI P 6DB.
CHAPTER I How it all got started
1. The development of blotting and hybridization techniques
1.1 Southern blotting
1.2 Northern blotting
1.3 Further advances
2. This book
3. Further reading
4. Laboratory safety
5. References
CHAPTER 2 Southern blotting I: electrophoresis of DNA
1. Different sources of DNA
1.1 Genomic DNA
1.2 Plasmid DNA
1.3 Bacteriophage and cosmid DNA
1.4 YACDNA
1.5 PCR product DNA
2. Before you load the DNA on to the gel
3. Preparing and running the gel
3.1 Agarose
3.2 Electrophoresis buffers
3.3 Casting the gel
3.4 Assembling the gel electrophoresis tank
3.5 Loading your samples
3.6 Running the gel
3.7 Visualizing the DNA with UV radiation
3.8 Photographing your gel
3.9 Interpretation of gels
3.9.1 Genomic DNA
3.9.2 Cloned DNA
3.10 What can go wrong with electrophoresis?
4. Further reading
5. References
CHAPTER 3 Southern blotting II: performing the blot
I. Uni
directional capillary blotting on to a single membrane at neutral pH
1.1 Preparing the gel for blotting
1.1.1 Partial depurination
1.1.2 Denaturation
1.1.3 Neutralization
1.2 Assembling the blot
1.2.1 Cutting and preparing the membrane
1.2.2 Assembly and blotting
1.3 Dismantling the blot
1.4 Checking the efficiency of transfer
1.5 Fixing the DNA to the membrane
1.5.1 UV treatment
1.5.2 Drying
1.6 Storing membranes before hybridization
2. Capillary blotting on to multiple membranes at neutral pH
2.1 Uni
directional capillary blotting on to several membranes
2.2 Bi
directional capillary blotting
3. Capillary blotting at alkaline pH
4. Other methods of blotting
4.1 Electrophoretic transfer ( electro blotting)
4.2 Vacuum blotting and positive
pressure blotting
4.3 Which method of blotting should you use?
5. Further reading
6. References
CHAPTER 4 Electrophoresis of RNA and northern blotting
1. How does northern blotting differ from Southern blotting?
2. What information can a northern blot give?
3. Comparing the levels of an mRNA species in different cell types
3.1 Equal loading
3.2. Quantitation
3.2.1 Scintillation counting of excised bands
3.2.2 Scanning densitometry
3.2.3 Phosphorimagery
4. Gel electrophoresis of RNA samples
4.1 Gel systems
4.2 Formaldehyde gels
4.2.1 Preparing formaldehyde gels
4.2.2 Preparing RNA samples for formaldehyde gels
4.2.3 How much RNA should be loaded?
4.2.4 Running formaldehyde gels
4.3 Glyoxal gels
4.3.1 Preparing glyoxal gels
4.3.2 Preparing RNA samples for glyoxal gels
4.3.3 Running glyoxal gels
4.4 Molecular size markers
4.4.1 28S and 18S rRNA size markers
4.4.2 Other RNA size markers
5. Blotting the gel
6. Further reading
7. References
CHAPTERS Dot and slot blotting
1. What are dot blots and slot blots
1.1 Why do a DNA dot /slot blot?
1.2 Why do an RNA dot /slot blot?
2. How to perform a dot /slot blot
2.1 Preparing the sample
2.1.1 How much DNA or RNA should you load?
2.1.2 DNA samples
2.1.3 RNA samples
2.2 Preparing the membrane
2.3 Assembling the manifold
2.4 Applying the sample
2.5 Blotting
2.6 Processing the membrane
3. Quantitation of dot /slot blots and interpretation of results
4. Limitations of dot /slot blotting
5. Further reading
6. References
CHAPTER 6 Plaque and colony screening
1. Screening bacteriophage 11, plaques by the Benton and Davis method
1.1 Plating
1.1.1 Petri dishes
1.1.2 Base agar
1.1.3 Top agarose
1.1.4 Plating cells
1.1.5 Bacteriophage
1.1.6 Plating
1.2 Taking membrane lifts
1.2.1 Getting the membranes ready
1.2.2 Taking the first membrane lift
1.2.3 Taking the second membrane lift
1.2.4 Storing the plates
1.3 Treating membranes before hybridization
1.3.1 Denaturation
1.3.2 Neutralization
1.3.3 Treatment with 2 x SSC
1.3.4 Fixing the DNA to the membrane
1.4 A brief note about hybridization probes
1.5 Orientating the membranes and X
ray film before autoradiography
1.6 Identifying hybridization signals after autoradiography
1. 7 Picking plaques
1.8 Further rounds of screening
2. Determining the titre of a bacteriophage "A suspension
3. Screening bacterial colonies by the Grunstein
Hogness method
3.1 Plating
3.2 Making replica membranes
3.2.1 Making the first replica
3.2.2 Making the second replica
3.2.3 What to do with the master membrane while you are screening the replicas
3.3 Treating membranes before hybridization
3.4 Another brief note about hybridization probes
3.5 Orientating the membranes and X
ray film before autoradiography
3.6 Picking colonies
4. Further reading
5. References
CHAPTER 7 Filters and membranes
1. The advantages and disadvantages of nitrocellulose filters and nylon membranes?
1.1 Nylon membranes are physically strong
1.2 DNA and RNA bind covalently to nylon membranes
1.3 Nylon membranes have a high nucleic acid binding capacity
1.4 Nylon membranes are hydrophilic
1.5 Nylon membranes retain"their size and shape at high temperatures
1.6 Nylon membranes are not inflammable
1. 7 Nylon membranes do not require solutions of high ionic strength to bind nucleic acids efficiently
1.8 Nylon membranes may give higher backgrounds than nitrocellulose filters, but this can be overcome easily
1.9 Nylon membranes are sometimes 'single
sided'
1.10 Nylon membranes and nitrocellulose filters must be handled with care
2. Which membrane should be used?
3. References
Glossary
Index.
1. The development of blotting and hybridization techniques
1.1 Southern blotting
1.2 Northern blotting
1.3 Further advances
2. This book
3. Further reading
4. Laboratory safety
5. References
CHAPTER 2 Southern blotting I: electrophoresis of DNA
1. Different sources of DNA
1.1 Genomic DNA
1.2 Plasmid DNA
1.3 Bacteriophage and cosmid DNA
1.4 YACDNA
1.5 PCR product DNA
2. Before you load the DNA on to the gel
3. Preparing and running the gel
3.1 Agarose
3.2 Electrophoresis buffers
3.3 Casting the gel
3.4 Assembling the gel electrophoresis tank
3.5 Loading your samples
3.6 Running the gel
3.7 Visualizing the DNA with UV radiation
3.8 Photographing your gel
3.9 Interpretation of gels
3.9.1 Genomic DNA
3.9.2 Cloned DNA
3.10 What can go wrong with electrophoresis?
4. Further reading
5. References
CHAPTER 3 Southern blotting II: performing the blot
I. Uni
directional capillary blotting on to a single membrane at neutral pH
1.1 Preparing the gel for blotting
1.1.1 Partial depurination
1.1.2 Denaturation
1.1.3 Neutralization
1.2 Assembling the blot
1.2.1 Cutting and preparing the membrane
1.2.2 Assembly and blotting
1.3 Dismantling the blot
1.4 Checking the efficiency of transfer
1.5 Fixing the DNA to the membrane
1.5.1 UV treatment
1.5.2 Drying
1.6 Storing membranes before hybridization
2. Capillary blotting on to multiple membranes at neutral pH
2.1 Uni
directional capillary blotting on to several membranes
2.2 Bi
directional capillary blotting
3. Capillary blotting at alkaline pH
4. Other methods of blotting
4.1 Electrophoretic transfer ( electro blotting)
4.2 Vacuum blotting and positive
pressure blotting
4.3 Which method of blotting should you use?
5. Further reading
6. References
CHAPTER 4 Electrophoresis of RNA and northern blotting
1. How does northern blotting differ from Southern blotting?
2. What information can a northern blot give?
3. Comparing the levels of an mRNA species in different cell types
3.1 Equal loading
3.2. Quantitation
3.2.1 Scintillation counting of excised bands
3.2.2 Scanning densitometry
3.2.3 Phosphorimagery
4. Gel electrophoresis of RNA samples
4.1 Gel systems
4.2 Formaldehyde gels
4.2.1 Preparing formaldehyde gels
4.2.2 Preparing RNA samples for formaldehyde gels
4.2.3 How much RNA should be loaded?
4.2.4 Running formaldehyde gels
4.3 Glyoxal gels
4.3.1 Preparing glyoxal gels
4.3.2 Preparing RNA samples for glyoxal gels
4.3.3 Running glyoxal gels
4.4 Molecular size markers
4.4.1 28S and 18S rRNA size markers
4.4.2 Other RNA size markers
5. Blotting the gel
6. Further reading
7. References
CHAPTERS Dot and slot blotting
1. What are dot blots and slot blots
1.1 Why do a DNA dot /slot blot?
1.2 Why do an RNA dot /slot blot?
2. How to perform a dot /slot blot
2.1 Preparing the sample
2.1.1 How much DNA or RNA should you load?
2.1.2 DNA samples
2.1.3 RNA samples
2.2 Preparing the membrane
2.3 Assembling the manifold
2.4 Applying the sample
2.5 Blotting
2.6 Processing the membrane
3. Quantitation of dot /slot blots and interpretation of results
4. Limitations of dot /slot blotting
5. Further reading
6. References
CHAPTER 6 Plaque and colony screening
1. Screening bacteriophage 11, plaques by the Benton and Davis method
1.1 Plating
1.1.1 Petri dishes
1.1.2 Base agar
1.1.3 Top agarose
1.1.4 Plating cells
1.1.5 Bacteriophage
1.1.6 Plating
1.2 Taking membrane lifts
1.2.1 Getting the membranes ready
1.2.2 Taking the first membrane lift
1.2.3 Taking the second membrane lift
1.2.4 Storing the plates
1.3 Treating membranes before hybridization
1.3.1 Denaturation
1.3.2 Neutralization
1.3.3 Treatment with 2 x SSC
1.3.4 Fixing the DNA to the membrane
1.4 A brief note about hybridization probes
1.5 Orientating the membranes and X
ray film before autoradiography
1.6 Identifying hybridization signals after autoradiography
1. 7 Picking plaques
1.8 Further rounds of screening
2. Determining the titre of a bacteriophage "A suspension
3. Screening bacterial colonies by the Grunstein
Hogness method
3.1 Plating
3.2 Making replica membranes
3.2.1 Making the first replica
3.2.2 Making the second replica
3.2.3 What to do with the master membrane while you are screening the replicas
3.3 Treating membranes before hybridization
3.4 Another brief note about hybridization probes
3.5 Orientating the membranes and X
ray film before autoradiography
3.6 Picking colonies
4. Further reading
5. References
CHAPTER 7 Filters and membranes
1. The advantages and disadvantages of nitrocellulose filters and nylon membranes?
1.1 Nylon membranes are physically strong
1.2 DNA and RNA bind covalently to nylon membranes
1.3 Nylon membranes have a high nucleic acid binding capacity
1.4 Nylon membranes are hydrophilic
1.5 Nylon membranes retain"their size and shape at high temperatures
1.6 Nylon membranes are not inflammable
1. 7 Nylon membranes do not require solutions of high ionic strength to bind nucleic acids efficiently
1.8 Nylon membranes may give higher backgrounds than nitrocellulose filters, but this can be overcome easily
1.9 Nylon membranes are sometimes 'single
sided'
1.10 Nylon membranes and nitrocellulose filters must be handled with care
2. Which membrane should be used?
3. References
Glossary
Index.
CHAPTER I How it all got started
1. The development of blotting and hybridization techniques
1.1 Southern blotting
1.2 Northern blotting
1.3 Further advances
2. This book
3. Further reading
4. Laboratory safety
5. References
CHAPTER 2 Southern blotting I: electrophoresis of DNA
1. Different sources of DNA
1.1 Genomic DNA
1.2 Plasmid DNA
1.3 Bacteriophage and cosmid DNA
1.4 YACDNA
1.5 PCR product DNA
2. Before you load the DNA on to the gel
3. Preparing and running the gel
3.1 Agarose
3.2 Electrophoresis buffers
3.3 Casting the gel
3.4 Assembling the gel electrophoresis tank
3.5 Loading your samples
3.6 Running the gel
3.7 Visualizing the DNA with UV radiation
3.8 Photographing your gel
3.9 Interpretation of gels
3.9.1 Genomic DNA
3.9.2 Cloned DNA
3.10 What can go wrong with electrophoresis?
4. Further reading
5. References
CHAPTER 3 Southern blotting II: performing the blot
I. Uni
directional capillary blotting on to a single membrane at neutral pH
1.1 Preparing the gel for blotting
1.1.1 Partial depurination
1.1.2 Denaturation
1.1.3 Neutralization
1.2 Assembling the blot
1.2.1 Cutting and preparing the membrane
1.2.2 Assembly and blotting
1.3 Dismantling the blot
1.4 Checking the efficiency of transfer
1.5 Fixing the DNA to the membrane
1.5.1 UV treatment
1.5.2 Drying
1.6 Storing membranes before hybridization
2. Capillary blotting on to multiple membranes at neutral pH
2.1 Uni
directional capillary blotting on to several membranes
2.2 Bi
directional capillary blotting
3. Capillary blotting at alkaline pH
4. Other methods of blotting
4.1 Electrophoretic transfer ( electro blotting)
4.2 Vacuum blotting and positive
pressure blotting
4.3 Which method of blotting should you use?
5. Further reading
6. References
CHAPTER 4 Electrophoresis of RNA and northern blotting
1. How does northern blotting differ from Southern blotting?
2. What information can a northern blot give?
3. Comparing the levels of an mRNA species in different cell types
3.1 Equal loading
3.2. Quantitation
3.2.1 Scintillation counting of excised bands
3.2.2 Scanning densitometry
3.2.3 Phosphorimagery
4. Gel electrophoresis of RNA samples
4.1 Gel systems
4.2 Formaldehyde gels
4.2.1 Preparing formaldehyde gels
4.2.2 Preparing RNA samples for formaldehyde gels
4.2.3 How much RNA should be loaded?
4.2.4 Running formaldehyde gels
4.3 Glyoxal gels
4.3.1 Preparing glyoxal gels
4.3.2 Preparing RNA samples for glyoxal gels
4.3.3 Running glyoxal gels
4.4 Molecular size markers
4.4.1 28S and 18S rRNA size markers
4.4.2 Other RNA size markers
5. Blotting the gel
6. Further reading
7. References
CHAPTERS Dot and slot blotting
1. What are dot blots and slot blots
1.1 Why do a DNA dot /slot blot?
1.2 Why do an RNA dot /slot blot?
2. How to perform a dot /slot blot
2.1 Preparing the sample
2.1.1 How much DNA or RNA should you load?
2.1.2 DNA samples
2.1.3 RNA samples
2.2 Preparing the membrane
2.3 Assembling the manifold
2.4 Applying the sample
2.5 Blotting
2.6 Processing the membrane
3. Quantitation of dot /slot blots and interpretation of results
4. Limitations of dot /slot blotting
5. Further reading
6. References
CHAPTER 6 Plaque and colony screening
1. Screening bacteriophage 11, plaques by the Benton and Davis method
1.1 Plating
1.1.1 Petri dishes
1.1.2 Base agar
1.1.3 Top agarose
1.1.4 Plating cells
1.1.5 Bacteriophage
1.1.6 Plating
1.2 Taking membrane lifts
1.2.1 Getting the membranes ready
1.2.2 Taking the first membrane lift
1.2.3 Taking the second membrane lift
1.2.4 Storing the plates
1.3 Treating membranes before hybridization
1.3.1 Denaturation
1.3.2 Neutralization
1.3.3 Treatment with 2 x SSC
1.3.4 Fixing the DNA to the membrane
1.4 A brief note about hybridization probes
1.5 Orientating the membranes and X
ray film before autoradiography
1.6 Identifying hybridization signals after autoradiography
1. 7 Picking plaques
1.8 Further rounds of screening
2. Determining the titre of a bacteriophage "A suspension
3. Screening bacterial colonies by the Grunstein
Hogness method
3.1 Plating
3.2 Making replica membranes
3.2.1 Making the first replica
3.2.2 Making the second replica
3.2.3 What to do with the master membrane while you are screening the replicas
3.3 Treating membranes before hybridization
3.4 Another brief note about hybridization probes
3.5 Orientating the membranes and X
ray film before autoradiography
3.6 Picking colonies
4. Further reading
5. References
CHAPTER 7 Filters and membranes
1. The advantages and disadvantages of nitrocellulose filters and nylon membranes?
1.1 Nylon membranes are physically strong
1.2 DNA and RNA bind covalently to nylon membranes
1.3 Nylon membranes have a high nucleic acid binding capacity
1.4 Nylon membranes are hydrophilic
1.5 Nylon membranes retain"their size and shape at high temperatures
1.6 Nylon membranes are not inflammable
1. 7 Nylon membranes do not require solutions of high ionic strength to bind nucleic acids efficiently
1.8 Nylon membranes may give higher backgrounds than nitrocellulose filters, but this can be overcome easily
1.9 Nylon membranes are sometimes 'single
sided'
1.10 Nylon membranes and nitrocellulose filters must be handled with care
2. Which membrane should be used?
3. References
Glossary
Index.
1. The development of blotting and hybridization techniques
1.1 Southern blotting
1.2 Northern blotting
1.3 Further advances
2. This book
3. Further reading
4. Laboratory safety
5. References
CHAPTER 2 Southern blotting I: electrophoresis of DNA
1. Different sources of DNA
1.1 Genomic DNA
1.2 Plasmid DNA
1.3 Bacteriophage and cosmid DNA
1.4 YACDNA
1.5 PCR product DNA
2. Before you load the DNA on to the gel
3. Preparing and running the gel
3.1 Agarose
3.2 Electrophoresis buffers
3.3 Casting the gel
3.4 Assembling the gel electrophoresis tank
3.5 Loading your samples
3.6 Running the gel
3.7 Visualizing the DNA with UV radiation
3.8 Photographing your gel
3.9 Interpretation of gels
3.9.1 Genomic DNA
3.9.2 Cloned DNA
3.10 What can go wrong with electrophoresis?
4. Further reading
5. References
CHAPTER 3 Southern blotting II: performing the blot
I. Uni
directional capillary blotting on to a single membrane at neutral pH
1.1 Preparing the gel for blotting
1.1.1 Partial depurination
1.1.2 Denaturation
1.1.3 Neutralization
1.2 Assembling the blot
1.2.1 Cutting and preparing the membrane
1.2.2 Assembly and blotting
1.3 Dismantling the blot
1.4 Checking the efficiency of transfer
1.5 Fixing the DNA to the membrane
1.5.1 UV treatment
1.5.2 Drying
1.6 Storing membranes before hybridization
2. Capillary blotting on to multiple membranes at neutral pH
2.1 Uni
directional capillary blotting on to several membranes
2.2 Bi
directional capillary blotting
3. Capillary blotting at alkaline pH
4. Other methods of blotting
4.1 Electrophoretic transfer ( electro blotting)
4.2 Vacuum blotting and positive
pressure blotting
4.3 Which method of blotting should you use?
5. Further reading
6. References
CHAPTER 4 Electrophoresis of RNA and northern blotting
1. How does northern blotting differ from Southern blotting?
2. What information can a northern blot give?
3. Comparing the levels of an mRNA species in different cell types
3.1 Equal loading
3.2. Quantitation
3.2.1 Scintillation counting of excised bands
3.2.2 Scanning densitometry
3.2.3 Phosphorimagery
4. Gel electrophoresis of RNA samples
4.1 Gel systems
4.2 Formaldehyde gels
4.2.1 Preparing formaldehyde gels
4.2.2 Preparing RNA samples for formaldehyde gels
4.2.3 How much RNA should be loaded?
4.2.4 Running formaldehyde gels
4.3 Glyoxal gels
4.3.1 Preparing glyoxal gels
4.3.2 Preparing RNA samples for glyoxal gels
4.3.3 Running glyoxal gels
4.4 Molecular size markers
4.4.1 28S and 18S rRNA size markers
4.4.2 Other RNA size markers
5. Blotting the gel
6. Further reading
7. References
CHAPTERS Dot and slot blotting
1. What are dot blots and slot blots
1.1 Why do a DNA dot /slot blot?
1.2 Why do an RNA dot /slot blot?
2. How to perform a dot /slot blot
2.1 Preparing the sample
2.1.1 How much DNA or RNA should you load?
2.1.2 DNA samples
2.1.3 RNA samples
2.2 Preparing the membrane
2.3 Assembling the manifold
2.4 Applying the sample
2.5 Blotting
2.6 Processing the membrane
3. Quantitation of dot /slot blots and interpretation of results
4. Limitations of dot /slot blotting
5. Further reading
6. References
CHAPTER 6 Plaque and colony screening
1. Screening bacteriophage 11, plaques by the Benton and Davis method
1.1 Plating
1.1.1 Petri dishes
1.1.2 Base agar
1.1.3 Top agarose
1.1.4 Plating cells
1.1.5 Bacteriophage
1.1.6 Plating
1.2 Taking membrane lifts
1.2.1 Getting the membranes ready
1.2.2 Taking the first membrane lift
1.2.3 Taking the second membrane lift
1.2.4 Storing the plates
1.3 Treating membranes before hybridization
1.3.1 Denaturation
1.3.2 Neutralization
1.3.3 Treatment with 2 x SSC
1.3.4 Fixing the DNA to the membrane
1.4 A brief note about hybridization probes
1.5 Orientating the membranes and X
ray film before autoradiography
1.6 Identifying hybridization signals after autoradiography
1. 7 Picking plaques
1.8 Further rounds of screening
2. Determining the titre of a bacteriophage "A suspension
3. Screening bacterial colonies by the Grunstein
Hogness method
3.1 Plating
3.2 Making replica membranes
3.2.1 Making the first replica
3.2.2 Making the second replica
3.2.3 What to do with the master membrane while you are screening the replicas
3.3 Treating membranes before hybridization
3.4 Another brief note about hybridization probes
3.5 Orientating the membranes and X
ray film before autoradiography
3.6 Picking colonies
4. Further reading
5. References
CHAPTER 7 Filters and membranes
1. The advantages and disadvantages of nitrocellulose filters and nylon membranes?
1.1 Nylon membranes are physically strong
1.2 DNA and RNA bind covalently to nylon membranes
1.3 Nylon membranes have a high nucleic acid binding capacity
1.4 Nylon membranes are hydrophilic
1.5 Nylon membranes retain"their size and shape at high temperatures
1.6 Nylon membranes are not inflammable
1. 7 Nylon membranes do not require solutions of high ionic strength to bind nucleic acids efficiently
1.8 Nylon membranes may give higher backgrounds than nitrocellulose filters, but this can be overcome easily
1.9 Nylon membranes are sometimes 'single
sided'
1.10 Nylon membranes and nitrocellulose filters must be handled with care
2. Which membrane should be used?
3. References
Glossary
Index.