Team:Cambridge/Project/Microscopy

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We used a confocal microscope to observe iridescent behaviour in eye and mantle tissue, by the following [https://2011.igem.org/Team:Cambridge/Protocols/Confocal_Microscopy_of_Loligo_Eye_and_Mantle_Dermis_Samples protocol]. The stunning images produced provided a very useful reference to help us to identify what recombinant (well folded) reflectin could look like in E. coli, and definitely enthused the team to obtain bactiridescence!
We used a confocal microscope to observe iridescent behaviour in eye and mantle tissue, by the following [https://2011.igem.org/Team:Cambridge/Protocols/Confocal_Microscopy_of_Loligo_Eye_and_Mantle_Dermis_Samples protocol]. The stunning images produced provided a very useful reference to help us to identify what recombinant (well folded) reflectin could look like in E. coli, and definitely enthused the team to obtain bactiridescence!
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==Confocal Microscopy==
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==Microscopy==
=Squid Tissues=
=Squid Tissues=

Revision as of 10:31, 20 September 2011

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OVERVIEW
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Preliminary observations

In order to get a real sense of what we were looking to achieve in our project, we felt that it was important to make some observations of native squid reflectin in vivo. We therefore obtained several specimens of Loligo opalescens and Loligo vulgaris squid from a local seafood restaurant and an online fishing bait store for dissection. We chose these species because the whole family of loliginid squid has been identified to contain reflectin, and these particular species were the only members of the family available to us. We used a confocal microscope to observe iridescent behaviour in eye and mantle tissue, by the following protocol. The stunning images produced provided a very useful reference to help us to identify what recombinant (well folded) reflectin could look like in E. coli, and definitely enthused the team to obtain bactiridescence!

Microscopy

Squid Tissues

File:Squideye reflectin250repeat.gif
This animation is composed of layers taken as the microscope was focused through the layers of a sample of reflective squid cells from the eye cup mounted in Phosphate buffered saline

We set the microscope to collect light reflected from the sample (emission and collection wavelengths overlap) as we were searching for iridescence. We'd like to thank Paul Grant who optimised the settings on the microscope. We then overlaid the images ourselves to produce the animated gif on the right.

We are very grateful to Fernan Federici who helped us, taking the image below using the 405nm, 488nm, 633nm laser beams and with the pinhole opened to a wider aperture.

Iridescent cells from around the squid eye, with thanks to Fernan Federici and Paul Grant

We used the enzyme trypsin to isolate cells from the mantle of the squid as this frees them from the extracellular matrix. Again we used the confocal microscope in a configuration that detects reflected light.

Spindle shaped cell from the squid mantle, isolated using trypsin. Thanks to Paul Grant for helping us take this image.

Reflectin Expressing Cells

These cells are producing a reflectin A1-GFP fusion protein and display display fluorescent inclusion bodies. Suggesting expression of the protein is too high for the protein to fold properly.

E. coli transformed with our pBAD-ReflectinA1-GFP construct, induced by adding 1mM arabinose

We fused a TorA export sequence to a reflectin A1-green fluorescent protein fusion in an attempt to export reflectin to the periplasm of E coli. Unfortunately, even on a low copy plasmid, it appears that the export tag has failed or we have saturated the export pathway and a backlog has occured. This means all cells have a detectable amount of GFP in their cytoplasm and fluorescent inclusion bodies in several of the transformed cells.

Bacteria expressing a TorA-ReflectinA1-GFP construct appear to produce fluorescent inclusion bodies, not a green halo in the periplasm as hoped.

The following confocal micrographs show control bacteria, transformed but uninduced bacteria and bacteria containing our construct and induced to produce reflectin A1. Interestingly, all cells display some reflectance, and perhaps surprsingly the induced cells show the least overall reflectanct. The induced cells display punctate dots of reflectance, which suggests inclusion bodies have been formed. However, despite uniform imaging settings across the data set, there is a differing amount of reflectance from the medium the cells are growing on. Further work we would like to carry out would involve producing slides of the same bacteria but using gelatin and PBS to minimise the background reflectance, compare reflectin and non-reflectin inclusion bodies under various imaging techniques and make use of a spectrometer to gather spectral data on the reflectin expressing bacteria, as the limitations of reflected light confocal microscopy - namely background reflectance, is highlighted by these images.

E. coli negative control
E. coli transformed with our pBAD-His-ReflectinA1 construct, but not induced - no addition of arabinose
E. coli transformed with our pBAD-His-ReflectinA1 construct, induced by adding 1mM arabinose

Reflectin Thin Films

A Confocal Micrograph of one of our first reflectin thin films, showing a great deal of impurities and non-uniformity. ‎