Exam3Lec1GeneTherapyandGeneEng Flashcards
What are the genetic therapies that we have?
- Production of recombinant therapeutic proteins: if we identify a protein that is impt and hard to come by, we can generate a recomb version and express it in milk of large animal
- production of genetically engineered antibodies
- production of genetically engineered vaccines
- production of reagents for gene therapies
- testing of treatments in genetically modified animals: human protein in a mouse then use a drug to target it and see the side effects (pre-clinical trial)
- genetic modification of patient or donor cells in gene and cell therapy
What is the effect of using siRNA inside a cell
is it used to silence a sequence (no transcription. There are two ways, the exogenous way and through the use of a vector
Explain using siRNA exogenously
siRNA is directly added to the cell and is taken up by risc pathway, then binds to the sequence, and cleaves RNA out. This is NOT permanent
temporary
Explain using siRNA with a vector
- Incorportate siRNA ds DNA vector and is now integrated into the genome, making it permanent.
- We cleave vector and get shRNA, and this is turned into siRNA
- Continues same process as exo, pathway. Binds to risc comples, binds to seq, cleaves RNA out
note that come cells might not make shRNA but can use CRISPR/CAS 9 to integrate it
THIS IS PERMANENT
__ is a valid targeting technique to induce KO of a dominant negative mutant to resolve the normal phenotype
shRNA
The artificial (exogenous)__ would become a part of RISC complex just like natural siRNA from a ds RNA virus
siRNA
What is this picture an example of?
Transcription and cellular processing of the shRNA primary transcript
shRNA integrate into DNA, and will always create siRNA, will always knock out . The artificial (exogenous) siRNA would become a part of RISC complex just like natural siRNA from a double stranded RNA virus
In Dr. Blanck’s study what was it an example of?
example use of shRNAi vector to knock-down expression of the transcroption factor, YY1. So he silence a gene,that gene is a repressor, it incr gene expresssion
shRNAi equals shRNA
Explain the results of George’s study in relation to YY1
- YY1 shRNAi expression vector resulted in no protein because shRNA targeted mRNA and silenced it. (shRNA makes siRNA, and siRNA cleaves it out, no gene expression)
- Empty expression vector as a control (no sequence incorporated), there is protein
- No transfection (no vector): there is protein
Explain the real time PCR assay for HLA-DRA mRNA
When YY1 is eliminated, the mRNA for HLA-DRA gene is increased, which encodes for MHC class II protein. Since we had more mRNA for HLA-DRA genes we needed less cycles of PCR.
when we add shRNA, we remove YY1 (which is a repressor of HLA-DRA gen) so we increase HLA-DRA transcription, and we need less cycles of PCR.
What is transfection?
adding nucleic acids (DNA or RNA) to cell but doesn’t tell you about the fate or effect
What is transformation?
The DNA integrates into the genome, changing cell fate (PERMANENT)
shRNAi expression vector integrated into genome
There is NO transformation with siRNA treatment (this is NOT integrated into genome)
What is exogenous DNA, gene, protein, etc
this is not natural/produces in cell=exogenous
What does knock out (KO) mean?
you took out a specific gene
Explain the example given with a KO mouse lacking EVC gene with associated dysplasia
There is the wild type mouse which is normal, and the EVC (-/-) mouse which is a gene associated with dysplasia. The neg/neg shows that we took out the gene and there is no more dysplasia. With this procedure, the added gene could integrate anywhere in the genome.
True or false the First generation of mice is not going to give you a KO in every cell
True
What is knock in?
put something in place of the endogenous gene
means taking exons and replacing exons
Gene targeting vecotors can alter the natural gene in many different ways, What are two ways?
Some vectors will be used to “knock out” gene (remove sequence)
Other gene targeting vectors could replace exons that have as little as one base pair change, which is “knock in”
In order for knock in to occur, what two things are needed?
Both neo and tk. Neo is incorporated, TK is not.
When you get correct Homologous Recombination (HR), Tk is not included but Neo is; the Tk gene is outside of the Homologous region since Tk is not flanked on both sides by the “A” and “B” sequences and is therefore not included during HR
When knocking-in, we need a piece of DNA that will recombine at the proper position in the genome. This is really hard to do by itlsef, how can it wcbp at the right position?
Crisper Cas 9 ( randomly putting it in, not every singel cell is going to uptake it and wcbp at the right postion so we use crisper cas 9)
Making a knock-out or knock-in mouse summary
- The recombinant gene is first generated by transfecting DNA into embryonic stem cells (ES cells) in a laboratory dish.
- Very few transformed ES cells have the proper recombination of vector with host DNA. The cells that do are selected with antibiotic treatments that kill off the cells that do NOT have the proper recombination.
- The desired gene structure is verified by PCR and DNA sequencing of the ES cell DNA, ie, PCR of the section of the DNA that contains the desired gene structure.
- The ES cells with proper gene structure are injected into an embryo.
- A mouse is obtained with desired gene structure in the germ cells. That mouse is termed a “founder mouse” and is used for subsequent breeding to generate mice where every cell has the genetic alteration.
- Recomb gene generated via transfecting (adding Nucleic acids) to embryonic stem cell whihc is pluripotent in a petri dish
- Few have the PROPER recomb, destroy the rest
- Verify and amplified by PCR and DNA seq
- Inject ES into embryo and this developed mouse is the FOUNDER MOUSE
Note that after a few generation of mice, we get mice with every cell and every gene that we want ki or ko
Explain this picture
- Take out stem cell (isolate blastocyst eg. eggs, sperm)
- add DNA (recombinant gene)
- Look to see which cells took it at the right place and incorporate into genome
- Once we find it we select and expand
- Put back into mouse
- Founder mouse has ko gene in the germ cells
- Founder used to make heterozygous mice mate to make homozygous muce
Generation of embryonic stem (ES) cells, usually for the purpose of mutating or “knocking out” a particular gene, and then using the ES cells lacking the gene to generate a mouse.
Not every cell will have the ko at first, long process
Why do we knock in a gene?
We want to figure out where a gene is expressed. So we ko a gene, (in this case EVC) and ki a diff gene (in this case lacz) and note with flourescence. We see where it lights up and where it was expressed.
KI and replaced EVC gene with lac z to see where expressed
Gene targeting vectors can also carry a completely new coding sequence (in this case, one that, when expressed, turns cells blue) to the site of the original gene, which can allow for a very simple method of learning where that gene is expressed.
Genetic engineering that is directly relevant to human medicine
- Genetically engineered cells, especially stem cells
- Pharmaceuticals produced from genetically engineered bacteria
Take stem cells and genetically engineer them
Take bacteria and genetically engineer them
What are the two parts of CRISPR/cas9?
- guide RNA guiding to right complimentary sequence
- Cas9 for cleavage of seq (uses RNP targeting RNA)
Cas 9 system allows for
Site specific DNA targeting
Explain CRISPR/Cas9 approach to genome editing
- Guide RNA guides the endonuclease cas 9 to the complimentary sequence creating a triple helix
- Cas9 cleaves seq
- If you have donor DNA you replace seq.
- If you donot have donor DNA you have NHEJ which ends up being degrades
RNP with targeting RNA and Cas9 for DNA cleavage.
Explain Recombinant DNA cloning
similar to bac clones process
We can use bacteria to produce proteins for human purposes (proteins like insulin and growth hormone)
If we want a specific protein or DNA for protein, we can take a gene and insert it into receptor (replication origin). So when the bacteria replicates, so does the DNA that we want.
EX: get gene that makes insulin, put into bacteria, let bacteria divide, insulin is produces and we extract insulin
amplyfing protein
The cloning process ultimately leads to one bacterial clone that is producing the protein insulin. The bacterial clone can be amplified extensively, particularly in a liquid culture, and the insulin recovered from the liquid media.
What is dedifferentiation?
We can dediffeerentiate cells that are far/completely diff from each other by taking the cell (in this case skin fibroblasts) and we completely de-differentiate and induce them to be pluripotents (iPS cells) and then you can get a neuron
dedifferentiation for cells that are far from each other (stripping away differentation)
We start with differentiated cell, use transcription factors to get a different cell type with same MHC (no rejection), so we use own embryonic stem cells for no allorxn
What two types of deletions cause muscular dystrophy?
- In-frame deletion of multple central exons: still in the right frame, just lost a few, this is MILD, and leads to BECKER muscular dys.
- Out-of-frame deletion of central exon or frameshift: coding for a diff aa, diff protein, this is SEVERE, and leads to DUCHENNE muscular dys
