Team:HKU-HKBU/Polar Expression Results

From 2009.igem.org

(Difference between revisions)
(New page: {{Team:HKU-HKBU/style.css}} {{Team:HKU-HKBU/script.js}} {{Team:HKU-HKBU/header}} ='''Strain Selecion'''= ===Swimming ability assay=== The swimming plates of ''BL21'', ''NCM3722'' and ''...)
Line 22: Line 22:
Plasmid in the BL21 strain showed the polar expression of GFP protein under the fluorescent microscope. In the merge picture, the fluorescent proteins were showed at one end of the bacteria.
Plasmid in the BL21 strain showed the polar expression of GFP protein under the fluorescent microscope. In the merge picture, the fluorescent proteins were showed at one end of the bacteria.
   
   
-
[[Image:HKU-HKBU_polar_expression_results_E_coli_fluorescent.png | center]]
+
[[Image:HKU-HKBU_polar_expression_results_E_coli_fluorescent.png | right|thumb]]
However, in the E.coli 2443 with the plasmid sample, the polar expression of GFP couldn’t be observerd.
However, in the E.coli 2443 with the plasmid sample, the polar expression of GFP couldn’t be observerd.
Line 30: Line 30:
Via SDS PAGE and Western Blotting, the relatively higher GFP protein concentration was observed on the outer membrane, which corresponded with the expected result of the specific expression of proteins on the outer membrane.
Via SDS PAGE and Western Blotting, the relatively higher GFP protein concentration was observed on the outer membrane, which corresponded with the expected result of the specific expression of proteins on the outer membrane.
-
[[Image:HKU-HKBU_polar_expression_results_E_coli_western.png | center]]
+
[[Image:HKU-HKBU_polar_expression_results_E_coli_western.png | right|thumb]]
When observing the moving strains in the microscope, we could find that all the GFP were expressed at the forehead end of the rod shaped bacteria. Therefore, this system was a perfect choice for binding with biotin-coated motor. It can express streptavidin at pole(s), which allows cells to adhere in the same orientation to a microrotatory motor through biotin-streptavidin interaction.  
When observing the moving strains in the microscope, we could find that all the GFP were expressed at the forehead end of the rod shaped bacteria. Therefore, this system was a perfect choice for binding with biotin-coated motor. It can express streptavidin at pole(s), which allows cells to adhere in the same orientation to a microrotatory motor through biotin-streptavidin interaction.  
Line 39: Line 39:
plasmids showed the expression of GFP in the bacteria and the polar expression pattern of the GFP protein. The left panel is a scan of salmonella 7207 with Lpp-OmpA-HA, which acts as a control. The right panel can show the successful expression of GFP in the bacteria.  
plasmids showed the expression of GFP in the bacteria and the polar expression pattern of the GFP protein. The left panel is a scan of salmonella 7207 with Lpp-OmpA-HA, which acts as a control. The right panel can show the successful expression of GFP in the bacteria.  
-
[[Image:HKU-HKBU_polar_expression_results_Salmonella_fluorescent.png | center]]
+
[[Image:HKU-HKBU_polar_expression_results_Salmonella_fluorescent.png | right|thumb]]
===Western Blotting===
===Western Blotting===
To verify this hypothesis in a more convincing way, Western Blotting was conducted, which could reflect the surface expression by studying the relative concentrations of expressed proteins. The relative higher concentrations of specific proteins on the outer membrane show that the GFP proteins are particularly expressed on the outer membrane.
To verify this hypothesis in a more convincing way, Western Blotting was conducted, which could reflect the surface expression by studying the relative concentrations of expressed proteins. The relative higher concentrations of specific proteins on the outer membrane show that the GFP proteins are particularly expressed on the outer membrane.
-
[[Image:HKU-HKBU_polar_expression_results_Salmonella_western.png | center]]
+
[[Image:HKU-HKBU_polar_expression_results_Salmonella_western.png | right|thumb]]
Unfortunately, the expression of GFP at the two ends is of equal opportunity, which couldn’t be an effective propelling system to push motor’s directional rotation. It’s better for proteins to specifically express proteins at the head of the bacteria, which ensures the pushing force to the motion of the motor.
Unfortunately, the expression of GFP at the two ends is of equal opportunity, which couldn’t be an effective propelling system to push motor’s directional rotation. It’s better for proteins to specifically express proteins at the head of the bacteria, which ensures the pushing force to the motion of the motor.

Revision as of 12:57, 16 October 2009

Contents

Strain Selecion

Swimming ability assay

The swimming plates of BL21, NCM3722 and MG1655 yielded negative results. Although the clouded area of the MG3 plate showed augmentation in diameter, the colony was of the shape of dispersed clouds whereas a positive result would show distinct circles as a result of chemotaxis. We attributed this to contamination by other bacteria. Salmonella - a bacteria with well known swimming abilities (~4.5mm/hr) - was employed as our positive control. However, surprisingly, E.coli 2443 showed even more impressive performance, with a speed of approximate 5.5mm increase in radius every hour at the end of eight-hour-experiment.

LPS completeness search

LPS takes vital part in specifically expressing streptavidin, the protein enabling the binding of bacteria to motor in our project. After literature reviews, E. coli 2443 [1] and Salmonella [2] are identified to possess complete LPS layer. Their ability to express desirable proteins on the head is examined in later experiment.


Polar Expression

E. coli polar expression system

Fluorescent Microscope

Plasmid in the BL21 strain showed the polar expression of GFP protein under the fluorescent microscope. In the merge picture, the fluorescent proteins were showed at one end of the bacteria.

HKU-HKBU polar expression results E coli fluorescent.png

However, in the E.coli 2443 with the plasmid sample, the polar expression of GFP couldn’t be observerd.

SDS PAGE and Western Blotting

Via SDS PAGE and Western Blotting, the relatively higher GFP protein concentration was observed on the outer membrane, which corresponded with the expected result of the specific expression of proteins on the outer membrane.

HKU-HKBU polar expression results E coli western.png

When observing the moving strains in the microscope, we could find that all the GFP were expressed at the forehead end of the rod shaped bacteria. Therefore, this system was a perfect choice for binding with biotin-coated motor. It can express streptavidin at pole(s), which allows cells to adhere in the same orientation to a microrotatory motor through biotin-streptavidin interaction.

Salmonella polar expression system

Fluorescent Microscope

plasmids showed the expression of GFP in the bacteria and the polar expression pattern of the GFP protein. The left panel is a scan of salmonella 7207 with Lpp-OmpA-HA, which acts as a control. The right panel can show the successful expression of GFP in the bacteria.

HKU-HKBU polar expression results Salmonella fluorescent.png

Western Blotting

To verify this hypothesis in a more convincing way, Western Blotting was conducted, which could reflect the surface expression by studying the relative concentrations of expressed proteins. The relative higher concentrations of specific proteins on the outer membrane show that the GFP proteins are particularly expressed on the outer membrane.

HKU-HKBU polar expression results Salmonella western.png

Unfortunately, the expression of GFP at the two ends is of equal opportunity, which couldn’t be an effective propelling system to push motor’s directional rotation. It’s better for proteins to specifically express proteins at the head of the bacteria, which ensures the pushing force to the motion of the motor.

Reference

  1. Sumita Jain, Peter van Ulsen, Inga Benz, M. Alexander Schmidt, Rachel Fernandez, Jan Tommassen, and Marcia B. Goldberg, Polar Localization of the Autotransporter Family of Large Bacterial Virulence Proteins, Journal of Bacteriology, July 2006, p. 4841-4850, Vol. 188, No. 13
  2. Maurien M. A. Olsthoorn, Bent O. Petersen, Siegfried Schlecht, Johan Haverkamp, Klaus Bock, Jane E. Thomas-Oates and Otto Holst, Identification of a Novel Core Type in Salmonella Lipopolysaccharide, The Journal of Biological Chemistry, Vol. 273, No. 7, Issue of February 13, pp. 3817-3829, 1998

Sponsors