Difference between revisions of "Team:MIT/Experiments/miRNA/more experiments"
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Program Used:<a href=http://bpteague.github.io/cytoflow/>CytoFlo</a> by <a href=https://2016.igem.org/Team:MIT/Team> Brian Teague </a> | Program Used:<a href=http://bpteague.github.io/cytoflow/>CytoFlo</a> by <a href=https://2016.igem.org/Team:MIT/Team> Brian Teague </a> | ||
<img src = "https://static.igem.org/mediawiki/2016/9/97/T--MIT--transient_transfection.PNG" style = 'padding: 5px'; width: 500px; height = 150px; float: center; border:5px;'> | <img src = "https://static.igem.org/mediawiki/2016/9/97/T--MIT--transient_transfection.PNG" style = 'padding: 5px'; width: 500px; height = 150px; float: center; border:5px;'> | ||
| − | <p style="font-family: Verdana;"> Flow cytometry occurs 48 hours after transfection, and if applicable, 24 hours after induction of a small molecule (such as the hormone estrogen). After the data is collected, anaylsis of the flow cytometry data commences. | + | <p style="font-family: Verdana;"> Flow cytometry occurs 48 hours after transfection, and if applicable, 24 hours after induction of a small molecule (such as the hormone estrogen). After the data is collected, anaylsis of the flow cytometry data commences.<br> |
| − | 1) After inputting each unique sample with their respective variables, we observe the total cell population using forward scatter height vs. width. The upper right of the graph represents pieces that are most likely cell aggregates and the lower left represents debris and dead cells. The middle oval is the desired cell population we wish the analyze.<br> | + | <br> |
| − | 2)Only looking at the experimental samples, we look at a graph with the transfection marker vs. cell count. The threshold of transfection is set in the dip between the untransfected cell population and the hump of known transfected cell. From now on, we will only be analyzing the population above this threshold, the transfected cells.<br> | + | 1) After inputting each unique sample with their respective variables, we observe the total cell population using forward scatter height vs. width. The upper right of the graph represents pieces that are most likely cell aggregates and the lower left represents debris and dead cells. The middle oval is the desired cell population we wish the analyze.<br><br> |
| − | 3)The next step is when the cell population is divided into specific bins. This distinguishes sections of the cell population by different number of copies of the transfection marker taken up. To avoid the strange behavior seen at low and high transfection marker copy number, we might decide to only analyze the middle bin(s).<br> | + | 2)Only looking at the experimental samples, we look at a graph with the transfection marker vs. cell count. The threshold of transfection is set in the dip between the untransfected cell population and the hump of known transfected cell. From now on, we will only be analyzing the population above this threshold, the transfected cells.<br><br> |
| + | 3)The next step is when the cell population is divided into specific bins. This distinguishes sections of the cell population by different number of copies of the transfection marker taken up. To avoid the strange behavior seen at low and high transfection marker copy number, we might decide to only analyze the middle bin(s).<br><br> | ||
4)After deciding the bins to look at, we apply the variable we specified in the very beginning. For example, we can look at the varying red fluorescence output due to different amounts of siRNA induction, as seen in our first experiment. | 4)After deciding the bins to look at, we apply the variable we specified in the very beginning. For example, we can look at the varying red fluorescence output due to different amounts of siRNA induction, as seen in our first experiment. | ||
<br> | <br> | ||
Revision as of 03:43, 19 October 2016
General Experimental Set-Up and Data Analysis
miRNA Sensor
Read miRNA sensors about here
Transient Transfection
Electroporation
Our team carried out electroporation using the Neon Transfection System. First the cells are washed, resuspended in buffers, and and DNA is added. Next, the cells undergo electroporation. Electroporation is the process of subjecting cells to high-voltage electric shocks in order to break holes through the membrane and allow the uptake of DNA.(1) After the transfection, the cells are returned to normal culture conditions in order to heal and replicate.
Flow Cytometry Analysis
Program Used:CytoFlo by Brian Teague
Flow cytometry occurs 48 hours after transfection, and if applicable, 24 hours after induction of a small molecule (such as the hormone estrogen). After the data is collected, anaylsis of the flow cytometry data commences.
1) After inputting each unique sample with their respective variables, we observe the total cell population using forward scatter height vs. width. The upper right of the graph represents pieces that are most likely cell aggregates and the lower left represents debris and dead cells. The middle oval is the desired cell population we wish the analyze.
2)Only looking at the experimental samples, we look at a graph with the transfection marker vs. cell count. The threshold of transfection is set in the dip between the untransfected cell population and the hump of known transfected cell. From now on, we will only be analyzing the population above this threshold, the transfected cells.
3)The next step is when the cell population is divided into specific bins. This distinguishes sections of the cell population by different number of copies of the transfection marker taken up. To avoid the strange behavior seen at low and high transfection marker copy number, we might decide to only analyze the middle bin(s).
4)After deciding the bins to look at, we apply the variable we specified in the very beginning. For example, we can look at the varying red fluorescence output due to different amounts of siRNA induction, as seen in our first experiment.
Sensitivity of miRNA Target Sites
Purpose
We want to understand the sensitivity of our miRNA target site constructs.
Set Up
We chose one miRNA target site, 451a, and designed and ordered siRNA complementary to the target site. We co-transfected tert-immortalized human endometrial stromal cells with our miRNA sensors and varying concentrations of siRNA then measured the red fluorescence output to gauge repression.
Results
When increasing siRNA-451a 0 to 1 nM, there is a 10 fold repression of red fluorescence. Saturation occurs at approximately 10 nM. More experiments would need to be done to understand the responsiveness between 0 to 1 nM.
miRNA Profile of tHESC
Purpose
Set Up
Results
