Result: Wetlab

Approach

Our experimental approach can be summarized as follows:

1. 1. Organisms and surface proteins selection

2. 2. Surface protein amplification and cloning

3. 3. Yeast two-hybrid assay with an existing peptide library

4. 4. Peptide functionalization

Results summary

These are the genes and the organisms we selected:

Gene	Organism
mp65	C. albicans
tos1	C. albicans
sim1	C. albicans
ssr1	C. glabrata
pir4	C. glabrata
scw4	C. glabrata
pir3	C. glabrata
utr2	C. glabrata
crf2full	A. fumigatus
crf2act	A. fumigatus
bgleno	A. fumigatus
ecm33	A. fumigatus
sun1	A. fumigatus
als1	C. albicans
als3	C. albicans
roda	A. fumigatus
roda	A. nidulans
xlna	A. nidulans
npc2	A. nidulans
sho1	A. nidulans
mid2	S. cerevisiae
sed1	S. cerevisiae
prm1 b	A. fumigatus
crf1	A. fumigatus
ama1	T. gondii
eglc	A. fumigatus
cwp1	S. cerevisiae
cwp2	S. cerevisiae
tir4	S. cerevisiae
rom5	T. gondii
rom4	T. gondii
gra7	T. gondii
eglc	A. nidulans
tir1	S. cerevisiae
bgleex	A. fumigatus

The results for all the genes we selected are summarized in this file.

Result: Dry lab

Homology modelling

We modeled the 3D structure of our peptide-containing scaffolds (domain B1 of protein G from Staphylococcus aureus) by homology modelling. We used the Modeller library to accomplish that; since the peptide is about 20-25 amino acids long, it can be modeled as a loop inside the B1 domain scaffold for which there are already a number of 3D structures available at the Protein Data Bank.

This is the general homology modeling procedure we followed. All peptides were cloned inside a scaffold (B1 domain of protein G from Staphylococcus aureus. The peptides were short enough to be modeled as an internal loop by loop refinement; these structures should only be considered as a working model, since we do not have direct crystallographic data. A detailed procedure can be found in this link.

Results summary

Protein G scaffold

The following table is a summary of the models we generated for our peptides inside the protein G scaffold. Their main purpose is to give us an idea if the calculated energy profile matches our assumption that the peptide is being exposed to the exterior of the scaffold. These models are in no way definitive, since we lack direct crystalographic data.

Peptide	Video	PDB	Peptide location	QMEAN score	Overall DOPE score	Energy profile
Prey 3		Download	K17-E42	0.512	-7053.966797	Download
Prey 4.1		Download	K17-E44	0.468	-7246.956055	Download
Prey 5		Download	K17-E44	0.495	-7501.071777	Download
Prey 13		Download	K17-E42	0.535	-7729.056152	Download
Prey 15		Download	K17-E42	0.441	-7685.998535	Download

*The peptide is shown in red and the scaffold in blue.

GFP scaffold

These are the structures we generated for our peptides inside a GFP scaffold.

Peptide	Video	PDB	Peptide location	QMEAN score	Overall DOPE score	Energy profile
Prey 3		Download	E103-E127	0.43	-26798.28125	Download
Prey 4.1		Download	E103-E127	0.448	-27891.212891	Download
Prey 5		Download	E103-E127	0.483	-26633.4375	Download
Prey 13		Download	E103-E127	0.404	-27075.160156	Download
Prey 15		Download	E103-E127	0.413	-26713.355469	Download

*The peptide is shown in red and the scaffold in green.

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References

1. 1. N. Eswar, M. A. Marti-Renom, B. Webb, M. S. Madhusudhan, D. Eramian, M. Shen, U. Pieper, A. Sali. Comparative Protein Structure Modeling With MODELLER. Current Protocols in Bioinformatics, John Wiley & Sons, Inc., Supplement 15, 5.6.1-5.6.30, 2006.




2. 2. M.A. Marti-Renom, A. Stuart, A. Fiser, R. Sánchez, F. Melo, A. Sali. Comparative protein structure modeling of genes and genomes. Annu. Rev. Biophys. Biomol. Struct. 29, 291-325, 2000.




3. 3. A. Sali & T.L. Blundell. Comparative protein modelling by satisfaction of spatial restraints. J. Mol. Biol. 234, 779-815, 1993.




4. 4. A. Fiser, R.K. Do, & A. Sali. Modeling of loops in protein structures, Protein Science 9. 1753-1773, 2000.