Techniques in Molecular Biology

Genetic Engineering - Efforts to manipulate DNA sequences in organisms

Goals of Genetic Engineering

Improve our understanding of how genes work
advance biotechnology - the manipulations of organisms to create products or cure disease

An Example - the Use of Recombinant DNA Technology to Produce a Save Supply of Growth Hormone

Pituitary dwarfism - a disease caused by the lack of growth hormone (created by the gene GH1)
Early research showed that the condition could be treated w/ injections of human growth hormone
- Growth hormone could only be obtained from human pituitary glands
- These were obtained from cadavers
- Later studies showed that the cadaver supplied growth hormones were often contaminated, so other methods needed to be developed to artificially produce human growth hormone
Use of Recombinant DNA Technology to Produce a Safe Supply of Growth Hormone
- Isolate mRNAs from cells in pituitary glands
- use reverse transcriptase to synthesize cDNA from each mRNA
- Attach restriction endonuclease recognition site to ends of each cDNA
- Cut cDNAs and plasmids w/ restriction endonucleases - remaining sticky ends join by complementary base pairing
- Ligate cDNAs and plasmids w/ ligase
  - plasmids also contain antibiotic resistance gene
- Introduce recombinant plasmids into E. coli cells to create a cDNA library
  - grow colonies on plate w/ an antibiotic
  - only those bacteria that have taken in the plasmid will be able to grow
  - this collection of bacteria is known as a cDNA library
- Now, the problem is to find bacteria with the specific gene in question
  - remember, we isolated lots of mRNA from the cells, not just the specific one we wanted
  - the specific gene is found w/ a probe
- Creation of a probe
  - the amino acid structure of growth hormone is know
  - using the genetic code, they can create a codon sequence that would create this protein
  - they could then create DNA complementary to this sequence - hopefully this sequence (probe) would bind to the DNA
  - the probe is radioactive - this will allow us to identify the bacteria w/ the specific gene in question
- Isolation of specific colonies of bacteria that have taken in the GH1 gene
  - Lay a filter paper on the colonies - some bacteria will stick to the filter
  - treat filter with chemicals to make double stranded DNA single stranded
  - wash colonies with radioactive probes - these will stick to the DNA that codes for the growth hormone
  - lay filter on film - radioactivity will create exposure, so you know where the gene was
  - look back at the original colony - this colony contains the bacteria w/ the gene
- Mass Produce the Growth Hormone
  - Transfer cDNA to a new plasmid, one with a bacterial promoter
  - Transform more E. coli w/ the new plasmid - it will now start to produce human growth hormone
  - Isolate and purify the human growth hormone!!

Description of this process

Plasmids - small loops of bacterial DNA

The main bacterial genome is a large loop of naked DNA - this is where all the "important" genes are stored
Bacteria also contain smaller loops of DNA called plasmids - supplemental genes are stored there
Bacteria have the ability to take in foreign DNA and plasmids from the environment (especially when under stress) - this process is known as transformation
- Bacterial plasma membranes don't normally take in foreign DNA
- They must be treated w/ chemicals or with electric shock
Bacteria can also exchange plasmids - this process is known as conjugation

Restriction Endonucleases - enzymes which cut DNA

Restriction Endonucleases (aka restriction enzymes) cut enzymes at specific DNA sequences
- Used by bacteria to cut invading viral DNA
- the sequences of DNA cut are frequently palindromes (the same forwards and backwards - RACECAR)
  - the recognition site (aka restriction site) in bacteria are frequently methylated (have a -CH₃ associated with them) to protect the bacterial DNA from being cut
  - viral DNA does not have methylated restriction sites, so it will be cut by restriction endonucleases
- Frequently, restriction sites are not cut evenly, but leave "sticky ends," like the enzyme EcoRI
- the sticky ends can be used to insert DNA into plasmids
  - A plasmid with an appropriate restriction site is cut, leaving a long, linear piece of DNA w/ two sticky ends
  - A piece of DNA (typically w/ a gene of interest) is created with sticky ends
  - The cut plasmid and DNA are mixed - some of the plasmids will join with the DNA, creating a recombinant plasmid

Polymer Chain Reaction (PCR)

A method of replicating DNA millions of times (amplification)

Processes created by Kary Mullis in the early 80's (sources vary from '83 to '85)
PCR utilizes Taq polymerase, a DNA polymerase from Thermus aquaticus, a bacterium found in hot springs
- These bacteria live in hot springs in Yellowstone
- have DNA polymerase stable at near boiling conditions
The DNA to be amplified is mixed w/ Taq polymerase and lots of dNTPs (deoxynucleoside triphoshates, the nucleotides used to replicate DNA), and RNA primers
Denature the DNA - Heating to 94ºC breaks the H-bonds joining the DNA doubles strands, making it single stranded
Primer Annealing - at cooler temperatures (50-60ºC), the primers anneal to the DNA
Incubation - Taq polymerase used dNTP's to synthesize complementary DNA strands, starting with the primers
Repeat 20-30 times to make millions of copies of DNA

Description of this process

Dideoxy Sequencing

A method to sequence DNA

Process created by Frederick Sanger in 1975
Utilizes dideoxyribonucleoside triphosphates (ddNTP)
- Normal DNA replication adds the new dNTP to the 3'-OH found on the end of the growing chain
- if a ddNTP is added to the growing chain, there will be no 3'-OH, so no new replication
When template DNA is mixed with one type of ddNTP (like ddGTP), there will be fragments of different length created

Do this four times, one for each ddNTP
Run these on a gel - the gel will separate them based on length
Read the sequence from the gel

Recent advances
- The Sanger method has be modified - ddNTP's with fluorescent markers have been developed
- Now we can mix all four types together and do one reaction instead of four
- The resulting fragments are still of different lengths
- Separate fragments via electrophoresis in mass-produced, gel-filled capillary tubes.
- Automatic sequencing machines read output

RFLP Method of Paternity Testing

RFLP - "Riff-Lips" - Restrictino Fragment Length Polymorphisms

A RFLP is a pice of DNA that has a "target sequence" surrounded by two restriction enzyme sites

This can be used to identify DNA left behind in a crime scene - if RFLP's of the sample will exactly match that of a suspect, the suspect can be convicted (assuming they don't have an identical twin or a clone)
A Southern Blot can be made to identify these RFLP's
- Isolate DNA
- Cut the DNA with restriction enzymes
- Run the fragments on an electrophoresis gel
- Treat DNA with chemicals to make them single stranded
- Blotting - put a blotting paper on the gel to wick the DNA upwards to a nylon filter, where it is permanently bound
- Hybridization with a radioactive probe - the complement will bind to the single stranded DNA
- Autoradiography - place X-ray film over filter - radioactivity will expose film

For paternity testing, samples are taken from mother, offspring, and potential fathers
The offspring's DNA is a combination of maternal and paternal DNA - so, all of the offspring's bands should correspond to the mother's, father's or both
- There is a slight chance of getting unique bands, due to mutation and/or crossing over events

Paternity Testing Demonstration

Not only is this method useful for paternity testing, but also for genetic markers for diseases
- In the above picture, the normal - B-globin gene produces three bands, a sickle cell allele produces two bands.
- By taking samples of blood, the person's genotype can be determined