Team:SDU-Denmark/project-p

From 2010.igem.org

(Difference between revisions)
(Flagella staining)
(Computerized analysis of the bacterial motility with the THOR prototype by Unisensor A/S and the Unify software)
Line 74: Line 74:
[[Image:Red_blue_PS_noPS.jpg|750px|center]]<br>
[[Image:Red_blue_PS_noPS.jpg|750px|center]]<br>
Contrary to our expectations the plot over mean velocity/frame did not show a noticeable difference between the four samples. The photosensor had about the same velocity/frame in blue and red light and there was no clear difference either when compared to the wildtype. The reason for this could be that we were were not effective enough at excluding non-informative paths from the data file (bacteria that are trapped in a circular motion, bacteria only exhibiting brownian motion) and / or that the environment the experiments were done in, was not optimal in the meaning of that the photosensor was exposed to light, before the measurements.<br>
Contrary to our expectations the plot over mean velocity/frame did not show a noticeable difference between the four samples. The photosensor had about the same velocity/frame in blue and red light and there was no clear difference either when compared to the wildtype. The reason for this could be that we were were not effective enough at excluding non-informative paths from the data file (bacteria that are trapped in a circular motion, bacteria only exhibiting brownian motion) and / or that the environment the experiments were done in, was not optimal in the meaning of that the photosensor was exposed to light, before the measurements.<br>
-
Since the results from the experiment with the red and blue light were inconclusive, we went on to analyse the data from the experiment, where we set up a light gradient in the area that was observed through the microscope. We recorded this for 40 seconds with a framerate of 4 frames/second, waited for 100 seconds and recorded again for 40 seconds. We did 10 iterations of this, which would give us a long-term overview of migration (if there is any) along the light gradient. Afterwards we repeated the same experiment without stimulating the bacteria through a light gradient. A track diagram was created, which should show us if the tracked microbes would show any preference in one direction. In the circular diagram each abcteria starts at point zero and then moves is plotted by its angle and distance traveled. This will give us an idea if there is any tendency to either move towards or away from the light:
+
Since the results from the experiment with the red and blue light were inconclusive, we went on to analyse the data from the experiment, where we set up a light gradient in the area that was observed through the microscope. We recorded this for 40 seconds with a framerate of 4 frames/second, waited for 100 seconds and recorded again for 40 seconds. We did 10 iterations of this, which would give us a long-term overview of migration (if there is any) along the light gradient. Afterwards we repeated the same experiment without stimulating the bacteria through a light gradient. A track diagram was created, which should show us if the tracked microbes would show any preference in one direction. In the circular diagram each abcteria starts at point zero and then moves is plotted by its angle and distance traveled. This will give us an idea if there is any tendency to either move towards or away from the light. The lightsource was placed at 90 degrees in the diagram, which means that bacteria that moved in that general direction moved towards the source of light:
-
[[Image:TrackDiagramGradient.png|thumb|400px|center|Track diagram of phototaxic bacteria swimming, when exposed to a blue light gradient (470nm). ]]
+
[[Image:TrackDiagramGradient.png|thumb|400px|center|Track diagram of phototaxic bacteria swimming, when exposed to a blue light gradient (470nm). ]]<br>
 +
The diagram shows that the bacteria that exhibit proper swimming motility (paths longer than 40, no circular movement, no brownian movement) show a slight tendency to move towards the more illuminated areas of the gradient. This can be interpreted as blue light acting as an attractant on the phototaxis pathway. Even though we can see this tendency, it should only be used as an indicator, since because of time constraints this experiment could not be repeated and the number of sampled bacteria is rather low (around 40), which means that the shown tendency could also be coincidence.<br>
 +
The data from the experiments with varying light intensity could not be analysed because of lack of time, but if there is any interest in it, we will gladly provide all the data that we collected.<br>
 +
From these experiments, we cannot definitely conclude that blue light acts as an attractant stimulus on the part K343007, but the experiment only indicates that this could be the case. The gradient experiment would have to be repeated, to see if the shown tendency would still show up with a greater pool of samples. The data analysis also needs more time, since our team could only spend one day doing the experiments and another two days analysing the results. So there are still a lot of parameters, that simply have not been calculated, like tumbling frequency.

Revision as of 18:44, 27 October 2010