Difference between revisions of "HTGAA"

From Hackuarium
Jump to navigation Jump to search
 
(2 intermediate revisions by the same user not shown)
Line 58: Line 58:
 
[[File:Gel_Hack_HTGAA.jpg |400px|]]
 
[[File:Gel_Hack_HTGAA.jpg |400px|]]
  
The Gel contained:
+
The Gel result was pretty good!
 +
[[File:IMG 1348.JPG |400px|]]
 +
 
 +
Size markers, are in the first lane...
 +
[[File:IMG 1350.PNG |200px|]]
 +
 
 +
The plasmid ypp 3-3 (Yann Pierson's) was used for these test digests, and the further lanes on this 1% Agarose mini-gel were:
 +
uncut (no enzyme, but incubated) <br>
 +
KpnI digest (should linearize for 6.48Kb band, but got partial digest) <br>
 +
PvuII digest (expected at least 5 bands, 93/125, 470, 762, 2062 & 2968 base pairs)<br>
 +
SacI digest (should linearize also) <br>
 +
KpnI+SacI (for double digest, expected 1.3 & 5.2Kb) <br>
 +
 
 +
More to come!
  
 
=== wk3: next generation synthesis ===
 
=== wk3: next generation synthesis ===

Latest revision as of 10:15, 21 November 2017

HTGAA

From the official webpage: Bio Academy is a Synthetic Biology Program directed by George Church, professor of Genetics at Harvard medical school. The Bio Academy is a part of the growing Academy of (almost) Anything, or the Academany.

It's a 15 week experimental course covering the major Synthetic Biology applications today.

HTGAA course 2017

2017 is the first year that the course is being taken by students at Hackuarium. The course is being followed by Daniel Hernandez and Thomas Jordan.

Important Links

Hackuarium Specific Links

Hackuarium Official Course Page: http://bio.fabcloud.io/hackuarium_2017/

Hackuarium Working Assignments Folder: https://drive.google.com/open?id=0B26FGn9YdUxQVmZuaTBNNWlGR0k


General Course Links

Course page: http://bio.fabcloud.io/2017/ This includes all the weekly lectures and homework discussions in the left-hand sidebar. At the bottom there are additional learning resources.

Students: https://docs.google.com/spreadsheets/d/1WRnoyLbWejQslRvaRNfQBxJkjgmKWHNfFT9BOZqdEGM/edit#gid=0

Curriculum: https://docs.google.com/spreadsheets/d/1Xg_GtrFb8wYJVUPlrbUb6pP0dWGmkoAKU4xP6qhBKVE/edit#gid=0

Recommended Hardware: https://docs.google.com/spreadsheets/d/1iu57Ct9NiPPVxzK_PBd_JlX4dlB68pQOxFCOnThnZPs/edit#gid=0

Inventory: https://docs.google.com/spreadsheets/d/1YRWQRTBSgn1aUY-WVLG3K8riCbV-ZATtPElDXcY88gQ/edit#gid=580981494

Weekly topics / Experiments

wk1: Principles and Practices

Link to weekly page: http://bio.fabcloud.io/2017/principles_practices_hardware.html


wk2: Bio Design / Plasmid digest

Theory class: George Church spoke about the capacity to modify biological material/organisms.

Lab Task: Design and verify restriction digest of a circular DNA plasmid by gel electrophoresis. Compare your experimental result with what you would predict from the plasmid map.

Link to weekly page: http://bio.fabcloud.io/2017/bio_design.html

The protocol designed for this experiment is:

https://docs.google.com/document/d/1Rs1ElrSjuLlmIEhpxZ6856ivZJBkXE4BnWnDYquZZ0w/edit?usp=sharing

The experiment was carried out on wednesday, 11th of of October 2017 with the help of Rachel.

The gel prepared was 20 mL of 1% agarose in 1x TAE buffer. It was prepared by dissolving 0.2g agarose in 20 mL of a 1x TAE buffer solution in the microwave. Upon full dissolution of the agarose, the sample was allowed to cool a bit, SYBR safe dye was added, and the liquid cast into an old horizontal mini gel box tray. A special 'hack' with magnets kept the comb from going too deep into the liquid, as shown. Gel Hack HTGAA.jpg

The Gel result was pretty good! IMG 1348.JPG

Size markers, are in the first lane... IMG 1350.PNG

The plasmid ypp 3-3 (Yann Pierson's) was used for these test digests, and the further lanes on this 1% Agarose mini-gel were: uncut (no enzyme, but incubated)
KpnI digest (should linearize for 6.48Kb band, but got partial digest)
PvuII digest (expected at least 5 bands, 93/125, 470, 762, 2062 & 2968 base pairs)
SacI digest (should linearize also)
KpnI+SacI (for double digest, expected 1.3 & 5.2Kb)

More to come!

wk3: next generation synthesis

Theory task: design a gene with a detailed workflow of how to build it.

Lab task: Recode a GFP plasmid to another variant of fluorescent protein using a golden gate assembly.

Ideally this task should be started ASAP as soon as the oligos arrive for the golden gate assembly

Headline text