User:Justin Tan
Registration/Questionnaire: 20.109 Fall 2007
Last Name
Tan
First Name
Justin
Preferred name
Justin
Course/Minor
20 - Biological Engineering 15 - Management
Year of Graduation
2009
Telephone #
339-221-2455
jtan_87 AT mit DOT edu
Have you taken
7.05/5.07 (Biochemistry) - YES 7.06 (Cell Biology) - NO 7.02 (General Biology Lab) - NO 5.310 (General Chemistry Lab) - NO
Do you have any experience culturing cells (mammalian, yeast or microbial)?
YES
Do you have any experience in molecular biology (electrophoresis, PCR, etc)?
YES
Please briefly describe any previous laboratory experience
In high school, I did a lot of biochemistry research. When I arrived at MIT, I worked at the Langer Lab doing tissue engineering research, specifically with regards to the osteogenic stem cell line. Finally, throughout my sophomore year, I worked in the Hamad-Schifferli lab designing temperature-sensitive biomedical devices for drug delivery.
Anything else you would like us to know?
I am really excited to be in this class! Although I have already had significant experience working in lab, I would really like to diversify the types of research that I do since I haven't really found a "passion" in any of the work that I've done in the past. I am also very enthusiastic about improving my oral/writing skills since it is something that I have always struggled with in the past.
M13 Re-Engineering Ideas
Protein | Function | Re-engineering Ideas |
---|---|---|
I | Assembly | Re-engineering of PI will undoubtedly cause some very drastic changes since it works in conjunction with several other genes (PIV and PXI) in the assembly process. Perhaps by altering the C-terminalof PI (and PXI), Different |
II | Replication of DNA + strand | From 7.03, I learned of various pathways that can control promoter sequences. If the natural promoter on M13 can be altered to become inducible, the rate
of M13 replication within the host bacteria could potentially be controlled. Consequently, this will also have an impact on the life-cycle of M13 | | bacteriophage. |
III | Phage tail protein (5 copies) | Since PIII is responsible for the initial binding of M13 to the bacteria at the TolA of the F pilus, if this protein-binding process can be modified to bind in more varied conditions, we can potentially construct an M13 bacteriophage that can bind to bacteria without the F pilus factor. |
IV | Assembly | Alter the gene in such a way as to destabalize the outer membrane (e.g. no longer detergent-resistant)- test varying environments for phage survival rate |
V | Binds ssDNA | Vary the activity of the gene and thus the competition between dsDNA formation and the sequestering of ssDNA- compare the results to find the optimum level of phage production possible |
VI | Phage tail protein (5 copies) | Add some sort of tag to the gene that is only visible when p6 is outside of the bacteria- thus we would be able to determine when the phage has been secreted |
VII | Phage head protein (5 copies) | Alter the gene so that p8 cannot be substituted for p5- see how this affects the phage (e.g. can it still be secreted?) |
VIII | Phage coat protein (2700 copies) | Add a small protein to the gene that we would like to amplify becuase p8 is synthesized so many times- see if this method works and if yes, what applications could this be used for? |
IX | Phage head protein (5 copies) | Modify the gene so that it can bind to bacterial surface proteins (like p3 does)- see if this allows the phage to interact with other bacteria (now that both ends can bind) |
X | DNA replication | Altering this gene will also alter gene 2 so any alteration would affect both genes, so make any number of small modifications - see what interesting phenomena result |
XI | Assembly | Modify the gene so that it is longer, hopefully resulting in a larger channel- see if this could allow multiple phages to pass through, thus making the channels more effective |
M13’s Closest evolutionary relatives
M13’s closest relatives are the bacteriophages fd and fl. Although they originate from the same bacteriophage family, Inoviridae, and exhibit the same circular single-stranded-DNA components, M13 differs from fd and fl in their protein coats. Whereas fd and fl both have carboxyl groups from aspartate, M13 has an amide group from its attached asparagine. As a result, M13 has a lower charge density along its surface than its bacteriophage relatives.
”Bba_M1307 is not a standard biological part and does not belong in the registry”
The M1307 sequence has been modified to include an origin of replication from the pACYC177 sequence as well as a kanamycin resistance gene so that it can propagate on Kan(+) plates. Hence, it has obviously been biologically engineered for in-vitro substrate building. However, a unique aspect of its function exists in the presence of other phage plasmids, whereyby it adopts an indirect “helper phage” role (i.e. providing the protein coat while allowing another phage plasmid (if present) into the phage capsid/host bacteria for substrate building.