BISC 219/2009: Mod 3 Experiment 2 Assaying the transgenic plants: Difference between revisions
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[[BISC 219/2009: Mod 3 Leaf Extract Preparation| Leaf Extract Preparation]] <br> | [[BISC 219/2009: Mod 3 GUS Activity Assay by Histochemistry| GUS Activity Assay by Histochemistry]] <br><br> | ||
[[BISC 219/2009: Mod 3 Spectrophotometric Assay for GUS activity| Spectrophotometric Assay for GUS activity]] <br> | |||
[[BISC 219/2009: Mod 3 Calculations| Calculations]] <br> | [[BISC 219/2009: Mod 3 Leaf Extract Preparation| Leaf Extract Preparation]]<br> | ||
[[BISC 219/2009: Mod 3 Spectrophotometric Assay for GUS activity| Spectrophotometric Assay for GUS activity]]<br> | |||
[[BISC 219/2009: Mod 3 Structural Evidence for Transgenic Plants| Structural Evidence for Transgenic Plants]] <br> | [[BISC 219/2009: Mod 3 Calculations| Calculations]]<br><br> | ||
[[BISC 219/2009: Mod 3 Structural Evidence for Transgenic Plants| Structural Evidence for Transgenic Plants]]<br> |
Revision as of 11:15, 4 September 2009
β-Glucuronidase (GUS) Activity Assays of Transformed Plants
The goal of these assays is to obtain evidence that your kanamycin-resistant plants are transgenic and that your reporter gene (gusA) is being expressed by testing for the function of the protein encoded by gusA, β-glucuronidase (GUS).
The gusA gene of E. coli, which encodes a β-glucuronidase (GUS), is a valuable reporter gene for use in plant systems for several reasons. β-glucuronidase activity is not detected in most plant species, therefore the detection of GUS activity in plant extracts is excellent evidence that the gusA gene has been introduced and is being expressed. Furthermore, GUS activity is a very easy to assay because a wide variety of substrates for spectrophotometric, fluorometric and histochemical assays are available. GUS specifically hydrolyzes β-conjugated D-glucuronides. We will use two GUS activity assays that use different alternative substrates. One is p-nitrophenyl glucuronide (PNPG). GUS catalyzes the cleavage of the glucuronide moiety from this substrate releasing p-nitrophenol which absorbs at 415 nm (see illustration below). We will follow the production of the yellow reaction product, p-nitrophenol, by measuring the A415 in leaf extracts. The second way we will measure gusA expression is through a histochemical semi-quantitative assay using a different substrate for beta glucuronidase, X-glucuronide (5Bromo4 chloro3indolyl-beta-D glucuronide in DMSO). This substrate, like PNPG, is colorless until cleaved by beta glucuronidase, but this time the cleavage product is blue rather than yellow. We will use a relative scale to judge amount of blue color in intact leaf tissue in this assay.
GUS Activity Assay by Histochemistry
Leaf Extract Preparation
Spectrophotometric Assay for GUS activity
Calculations