Regulated assembly Idea Approach.html
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Between GyrB and foldon or CutA1 subunits we introduced two or four amino acid linker composed of serine and glycine (SG, SGSG). We decided to vary the length of the linker in order to allow more flexibility of dimerization domains (gyrase B) in comparison to coiled-coils. Length of linker may define if the structure would form a nanocage or a planar lattice. | Between GyrB and foldon or CutA1 subunits we introduced two or four amino acid linker composed of serine and glycine (SG, SGSG). We decided to vary the length of the linker in order to allow more flexibility of dimerization domains (gyrase B) in comparison to coiled-coils. Length of linker may define if the structure would form a nanocage or a planar lattice. | ||
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Figure 4: Scheme of polypeptides containing GyrB and foldon or CutA1 with corresponding BioBrick part numbers. | Figure 4: Scheme of polypeptides containing GyrB and foldon or CutA1 with corresponding BioBrick part numbers. | ||
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Figure 5: Hexagonal packing model of GyrB-CutA1 fusion. A: GyrB dimers are shown in blue, green or yellow color, while the trimerization domain of CutA1 is shown in grey. B: Hexagonal packing can cover the planar lattice. | Figure 5: Hexagonal packing model of GyrB-CutA1 fusion. A: GyrB dimers are shown in blue, green or yellow color, while the trimerization domain of CutA1 is shown in grey. B: Hexagonal packing can cover the planar lattice. | ||
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Latest revision as of 02:38, 22 October 2009
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Summary
Figure 1: Basic structural element of the fusion protein gyrB-CutA1, which is trimeric in the solution, due to the trimerization by CutA1 (A). Transmission electron microscopic image of gyrB-CutA1 (B) material crosslinked by coumermycin, which forms hexagonal pores (shown in cyan). The idea
Figure 2: Aminocoumarin antibiotics: A - coumermycin, B- novobiocin, C – coumermycin binds to two gyrase B binding sites so that those two polypeptide chains form a tight dimmer. The approach
Figure 3: Molecular representation of a CutA1 (A) and foldon (B) trimer with chains shown in different colours. Each of those trimerization domains was fused to the 24 kDa fragment of gyrase subunit B (GyrB), connected by a short flexible linker. We could in principle use any other multimerization domain found in nature and put it in a combination with another to create assemblies of different geometry. All of the selected trimerization-dimerization polypeptides additionally include a tag of 6 histidines at N-terminus as added in our new vector (BBa_K245005). Scheme of these constructs (linki na biobricke) is shown on Figure 4. Between GyrB and foldon or CutA1 subunits we introduced two or four amino acid linker composed of serine and glycine (SG, SGSG). We decided to vary the length of the linker in order to allow more flexibility of dimerization domains (gyrase B) in comparison to coiled-coils. Length of linker may define if the structure would form a nanocage or a planar lattice. Figure 4: Scheme of polypeptides containing GyrB and foldon or CutA1 with corresponding BioBrick part numbers. We constructed a molecular model of GyrB-CutA1 fusion protein, shown on Figure 5. Assembly of a fusion polypeptide by the addition of coumermycin may result in hexagonal assembly forming planar lattice and formation of pores of defined size (Figure 5B). Figure 5: Hexagonal packing model of GyrB-CutA1 fusion. A: GyrB dimers are shown in blue, green or yellow color, while the trimerization domain of CutA1 is shown in grey. B: Hexagonal packing can cover the planar lattice.
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