Team:Cornell/notebook/wetlab

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Revision as of 22:00, 26 October 2012

Wet Lab - Overview

Overview

We began the summer by holding a synthetic biology bootcamp in the DeLisa Lab. The purpose of this bootcamp was both to introduce new members to techniques in molecular biology and to get a running start on the cloning work for our project. During bootcamp, we successfully constructed both versions of our arsenic reporter, and attempted a Gibson assembly of a naphthalene-degrading plasmid.

In late June, we transitioned from bootcamp to our permanent bench space in Dr. Archer’s lab in Weill Hall. After spending a few weeks setting up the lab space troubleshooting general issues, we successfully constructed both versions of our salicylate reporter and began an alternative approach to construct a plasmid with a naphthalene-degrading (nah) operon. In parallel, we realized that electroporation efficiency for Shewanella transformation is less than optimal—to say the least. However, we were able to conjugate our constructs into Shewanella using a protocol provided by Dr. Gralnick.

As we transitioned into the fall semester in late August, wetlab work was divided into subprojects that could be accomplished in parallel. Subproject leaders independently worked on (1) characterizing our engineered Shewanella strains using reactors in the Angenent lab, (2) characterizing inducible promoters via qPCR of mtrB transcript in response to analyte, (3) characterizing inducible promoters in Shewanella via fluorescent reporters,(4) appending His-tags to MtrB in order to perform immunoassays, (5) performing site-directed mutagenesis on the nah operon to delete BioBrick cutsites, (6) constructing our final naphthalene-degrading plasmid to be conjugated into Shewanella, and (7) confirming that strains carrying the naphthalene-degrading plasmid can actually eat naphthalene.