Matt Gethers

From OpenWetWare

(Difference between revisions)
Jump to: navigation, search
(2.27.09 Refactoring Work)
Line 72: Line 72:
===2.27.09 Refactoring Work===
===2.27.09 Refactoring Work===
-
My refactoring work generally followed the guidelines set out by Chan et al's "Refactoring T7". I started by designing [[http://parts.mit.edu/registry/index.php/Part:BBa_M31530| BBa_M31530]] directly from the germane promoters, RBSs, and ORFs. As an exercise in abstraction, I then started defining more complex functional units. First I defined a gene with its transcriptional and translational regulatory regions as a part. In this way, I don't have to think about how the gene is expressed so much as the end result. An example is [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31532| Gene X (BBa_M31532)]]. By the same token, I was able to create functional units of several genes related by their functions. For example, I created [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31538| BBa_M31538]] which is made of all the genes responsible for gene amplification of M13K07 while in a host and I made [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31540| BBa_M31540]] for phage coat proteins. Within each of these, I attempted to address the possibility of intergenetic cross-talk by introducing transcriptional terminators between the genes [[http://parts.mit.edu/registry/index.php/Part:BBa_B0015| BBa_0015]]. From my work with Heather Keller, I also know that hair pins (5' and 3' UTRs) can play a role in stabilization of DNA and posit that they may be helpful in preventing recombination events. I was unable to locate hairpins as parts in the registry, but I would like to add them and make us of them in my refactored M13K07.  
+
My refactoring work generally followed the guidelines set out by Chan et al's "Refactoring T7". I started by designing [[http://parts.mit.edu/registry/index.php/Part:BBa_M31530| BBa_M31530]] directly from the germane promoters, RBSs, and ORFs. As an exercise in abstraction, I then started defining more complex functional units. First I defined a gene with its transcriptional and translational regulatory regions as a part. In this way, I don't have to think about how the gene is expressed so much as the end result. An example is [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31532| Gene X (BBa_M31532)]]. By the same token, I was able to create functional units of several genes related by their functions. For example, I created [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31538| BBa_M31538]] which is made of all the genes responsible for gene amplification of M13K07 while in a host and I made [[http://parts.mit.edu/r/parts/partsdb/part_info.cgi?part_name=BBa_M31540| BBa_M31540]] for phage coat proteins. Within each of these, I attempted to address the possibility of intergenetic cross-talk by introducing transcriptional terminators between the genes [[http://parts.mit.edu/registry/index.php/Part:BBa_B0015| BBa_0015]]. From my work with Heather Keller, I also know that hair pins (5' and 3' UTRs) can play a role in stabilization of DNA and posit that they may be helpful in preventing recombination events. I was unable to locate hairpins as parts in the registry, but I would like to add and make use of them in my refactored M13K07.  
Here are a few tables of my work.  
Here are a few tables of my work.  

Revision as of 03:13, 28 February 2007

I'm currently a sophomore in course 20. When I'm behaving myself, I'm allowed to work in the Endy Lab at MIT. I will be documenting my UROP projects here. I will put my 20.109 work directly below.

Contents

20.109 Work

M13 Engineering Ideas

Extractions, separations, etc. include ensuring that each gene has its own promoter, RBS, terminator, and any other pertinent regulatory sequences. In addition to separating the genes, it would also be wise to develop or utilize/modify an existing system like Biobricks to build the genome so that convenient restriction sites exist between the genes so they can be easily removed or replaced. I used the following annotation to locate and design changes to the genome.
Gene Modification
XExtract from gene II.
IIExtract gene X.
V Add some base pairs between V and VII to allow for a restriction site.
VIISeparate from gene IX.
IIIChange the GTG to ATG Start?
VI Add some base pairs between III and VI and VI anda I to allow for restriction sites.
ISeparate from genes IV and XI.
XISeparate from genes I and IV.
IVSeparate from genes I and XI.
M13 ORI 1 & 2 Are two ORIs necessary? If so, can they be consolidated?
KanR Possible to remove bps 6600 - 7100 upstream of KanR? Does this DNA have functional significance?

2.27.06 Ligation and Transformation Data

We didn't determine the concentration of the prepped DNA from the ligation reactions, so we cannot calculate the transformation efficiency of these transformations. We do know, however, that 5 ng of vector was used to transform the control plasmid, so efficiency = (1184 colonies)/(5*10^-3 micrograms of DNA)= 5.92*10^6 colonies/microgram of DNA.

The control plasmid transformation serves as a positive control. It should work. If this transformation didn't work (along with some or all of the others), we might suspect an issue with the competency of the cells or with the transformation process. The appearance of colonies on this plate, however, demonstrates that this is not the case. The cells are indeed competent and our protocol worked.

The backbone with and without ligase mixed with the killcut cocktail serve as negative controls. They should not work. If a significant number of colonies were to show up on these plates, this would first mean that the restriction endonucleases weren't cutting. This could be because they had expired or because the sites no longer existed in the DNA. Assuming the latter for the ligated vector, this would mean that the vector sequence was somehow modified during the initial digest. For the linearized vector, the appearance of colonies would suggest that the DNA somehow became ligated and lost restriction sites, or the cell accepted cut vector.

The controls do not provide a definitive diagnosis of the problem should the experimental ligations fail, but they provide starting points for the inquiry into the failure.

2.27.09 Refactoring Work

My refactoring work generally followed the guidelines set out by Chan et al's "Refactoring T7". I started by designing [BBa_M31530] directly from the germane promoters, RBSs, and ORFs. As an exercise in abstraction, I then started defining more complex functional units. First I defined a gene with its transcriptional and translational regulatory regions as a part. In this way, I don't have to think about how the gene is expressed so much as the end result. An example is [Gene X (BBa_M31532)]. By the same token, I was able to create functional units of several genes related by their functions. For example, I created [BBa_M31538] which is made of all the genes responsible for gene amplification of M13K07 while in a host and I made [BBa_M31540] for phage coat proteins. Within each of these, I attempted to address the possibility of intergenetic cross-talk by introducing transcriptional terminators between the genes [BBa_0015]. From my work with Heather Keller, I also know that hair pins (5' and 3' UTRs) can play a role in stabilization of DNA and posit that they may be helpful in preventing recombination events. I was unable to locate hairpins as parts in the registry, but I would like to add and make use of them in my refactored M13K07.

Here are a few tables of my work.

' 2.27.07 Ligation and Transformation Data '
DNA Ligation Sample Expected Number of Transformants Observed Number of Transformants
Control PlasmidMany1184
BKB with cocktail but no ligase00
BKB with ligase and cocktail06
BKB with insert and ligase and cocktail #1A few0-1
BKB with insert and ligase and cocktail #2A few5
Gene Modification
XExtract from gene II.
VIISeparate from gene IX.
VIIISeparate from gene IX.
Abstraction (Functional Unit) Components of Functional Unit
The Regulatory/Coding RegionStrings of DNA
The GeneThe Promoter, RBS, and ORF
A Portion of the Life CycleThe genes responsible for a certain part of the life cycle
Personal tools