Transcription activator like effectors or TAL effectors (TALEs) are DNA binding proteins which are secreted by many species of the pathogenic Xanthonomas genus via a type III secretion system. They gain entry to the host plant through natural openings such as the stomata or hydathodes (glands which secrete water). They are major virulence factors involved in the activation of specific genes that allow colonisation and spread of bacteria in plant species such as rice and cotton. TALEs
share a characteristic C-terminus configuration consisting of nuclear
localisation signals along with an acidic activating domain which allow them to
enter the nucleus and begin affecting gene expression. The area in which they differ is the central
domain which contains 1.5 to 33.5 tandem repeats and is the domain responsible
for DNA binding. (Deng et al., 2012) (Boch, Bonas 2010)
Figure 1. This figure has been adapted from Boch, J., Bonas U., (2010), and shows how the TALE enters the cell, via the type III secretion system. Using this method, the bacterial cell secretes a mixture of effector proteins into the plant cell which disguise the TALEs and allow them to enter the cell undetected. These effector proteins are shown as the red structure attached to the bacteria on the diagram.
Figure 1. This figure has been adapted from Boch, J., Bonas U., (2010), and shows how the TALE enters the cell, via the type III secretion system. Using this method, the bacterial cell secretes a mixture of effector proteins into the plant cell which disguise the TALEs and allow them to enter the cell undetected. These effector proteins are shown as the red structure attached to the bacteria on the diagram.
Previous studies have found that mutants in the type III secretory proteins have been unable to create disease symptoms in sensitive plants, highlighting the significant role that these effectors have in pathogenicity (Kay, Bonas 2009). Thus it is important to study TAL effectors to aid our understanding of plant diseases and identify possible mechanisms for control/prevention. Also, TALEs DNA binding properties can be exploited so that artificially constructed TALEs can be used for gene expression control, displaying their great potential in the field of biotechnology (Boch et al., 2009).
Materials and Methods
Recombinant dHax3 including a histidine tag was cloned into Escherichia Coli using a vector plasmid. Overexpression was induced through the use of
IPTG and cells were harvested after growth.
The protein was then purified through affinity chromatography using
nickel resin (affinity for histidine) and a heparin (affinity for positively
charged proteins) column. (Deng et al., 2012)
Purified proteins could then be concentrated and put through
gel filtration chromatography to prepare for crystallisation. Several dHax3 fragments were tried for
crystallisation, however only the fragment containing residues 270-703 gave a
usable diffraction. Crystals were formed
via the hanging-drop vapour-diffusion method and grown to complete size over
the course of 3-4 days. In order to
acquire the crystals for the protein bound to DNA, a 17 base pair DNA strand
was used with the fragment containing residues 231- 720. X-ray diffraction data was then collected
with the use of a Synchrotron. (Deng et al., 2012)
The introduction section was nicely done. Although it was a little bit too long, it gave a clear main idea of the web-page and the figure was very informative. The materials and methods section was well-grapsed, summarizing everything that is needed.
ReplyDeleteOverall, this web-page was very good. Nice choice of background image and the tabs were represented very clearly. White background colour is a good choice because it makes it easy to read the text. Well done!
ReplyDeleteHey guys, I found your webpage very informative and enjoyed the writing style. I thought that your grass theme was great, and I think that the red references worked really well against the white and green background.
ReplyDeleteI do however feel that more use could have been made of the PyMol images, for example on the second page the important residues in the TAL repeat could have been highlighted. I’m also not sure that the conjecture at the end of the conclusion adds anything particularly.
Other than this I thought the web page was very good, so well done.
Hi Lauren and Alptekin - Good clear webpage, clear text, well explained. Thought that a few more Pymol images could have been used to show interactions etc. Figure legends gave additional detail which was useful, and didn't repeat man body text. I also like the 'real life' considerations, so we understand why this piece of research has been done. I also like how the references in the text are linked straight to the original paper. Materials and methods could have gone on a separate tab - don't really need to be part of the introduction. Overall, clear and concise!
ReplyDeleteHey guys, very impressive blog! It is clear, easy to navigate, concise and easy to understand due to the complimentary pymol images.
ReplyDelete