Team:Shenzhen BGIC ATCG/Project
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In our project we utilized 19 peptides target to 9 sub-locations in yeast cells, and when combined with fluorescent proteins, such region can be marked by different colors. | In our project we utilized 19 peptides target to 9 sub-locations in yeast cells, and when combined with fluorescent proteins, such region can be marked by different colors. | ||
- | OMM | + | ***OMM*** |
Mitochondria | Mitochondria | ||
Though it accounts a small ratio in the cell space, mitochondria possess about 10% to 15% proteins encoded by nuclear genes in eukaryotic organisms. These proteins are synthesized in cytosol and then recognized by the membrane receptors of mitochondria. Translocases in the outer and inner membrane of mitochondria mediate the import and intra-mitochondrial sorting of these proteins. ATP is used as an energy source; Chaperones and auxiliary factors assist in folding and assembly of mitochondrial proteins into their native, three-dimensional structures. | Though it accounts a small ratio in the cell space, mitochondria possess about 10% to 15% proteins encoded by nuclear genes in eukaryotic organisms. These proteins are synthesized in cytosol and then recognized by the membrane receptors of mitochondria. Translocases in the outer and inner membrane of mitochondria mediate the import and intra-mitochondrial sorting of these proteins. ATP is used as an energy source; Chaperones and auxiliary factors assist in folding and assembly of mitochondrial proteins into their native, three-dimensional structures. | ||
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[[File:Figure1.protein-import_pathways_for_mitochondrial_proteins.png]] | [[File:Figure1.protein-import_pathways_for_mitochondrial_proteins.png]] | ||
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+ | Figure 1 | Protein-import pathways for mitochondrial proteins. | ||
As shown in figure1, beta-barrel outer-membrane proteins (dark green), precursor proteins (brown) with positively charged amino-terminal presequences and multispanning inner-membrane proteins (blue) with internal targeting signals are recognized by specific receptors of the outer mitochondrial membrane (TOM) translocases Tom20, Tom22 and/or Tom70. The precursor proteins are then translocated through a small Tom proteins of the TOM complex, Tom40 pore, which the TOM complex contains two or three. | As shown in figure1, beta-barrel outer-membrane proteins (dark green), precursor proteins (brown) with positively charged amino-terminal presequences and multispanning inner-membrane proteins (blue) with internal targeting signals are recognized by specific receptors of the outer mitochondrial membrane (TOM) translocases Tom20, Tom22 and/or Tom70. The precursor proteins are then translocated through a small Tom proteins of the TOM complex, Tom40 pore, which the TOM complex contains two or three. | ||
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+ | *** peroxisomes *** | ||
+ | The import of post-translational matrix protein into peroxisomes depends on either of the two peroxisomal targeting signals (PTS), PTS1 and PTS2. PTS2-driven import is facilitated by a complex in the membrane. Under oleic acid-inducing growth conditions, there is a ternary core complex of approximate 150 kDa in the cytosol, which consists of Fox3p,Pex7p and Pex18p. Fox3p is imported as a dimer, while other two are bind in monomeric forms. | ||
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+ | [[File:Figure2._Schematical_model_of_the_early_steps_of_PTS2-driven_import.png]] | ||
+ | Figure2._Schematical_model_of_the_early_steps_of_PTS2-driven_import.png | ||
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+ | As study mentioned there are four steps involved in PTS2-driven import. The first step is the recognition of dimerized Fox3p by Pex7p through its PTS2 in the cytosol. In a second step, the Pex7p–Fox3p complex interacts with Pex18p, which targets the PTS2 pre-import complex to the peroxisomal membrane. The third step is the docking process, involving the interaction between Pex7p and the integral membrane protein Pex13p. As a final step of these early steps in the PTS2 import cascade, PTS2 receptor dissociation takes place during or after its assembly into large oligomeric complexes containing Pex14p and Pex13p. Pex18p remains at the peroxisomal membrane in the form of a large-molecular-weight complex in conjunction with Pex14p and/or Pex13p, from where it might be released to the cytosol. | ||
=== Targeting Peptide === | === Targeting Peptide === |
Revision as of 07:36, 7 September 2013
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Contents |
Overall project
This year, our project named "Cell Magic" we engineered the budding yeast in time level as well as space level. The "Cell Magic", like a movie,can be divided into two parts: the actor related and the time regulation related one. In the first part, our actor, signal peptides, were all made up with colorful clothes by the fluorescent proteins. Furthermore, the intron and degradation biobricks as make-up artists can decide how the clothes be matched. Through these steps, our actors may wearing in green, yellow or even mixed, appear in their specific sub-locations of yeast cell. With respect to the time level, we took advantages of the natural cell cycle in budding yeast to improve the time process to be more suitable for our movie.In general, the movie director, the promoters from five cycline gene, can decide the expression of downstream gene in G1 and G2 phase phase, respectively. Also, freezer Sic1 help our movie stay a longer time in the G1 phase which is important for the actor performing their stories. And the last tools we utilized is the microfluidics, through which numerous cells can project our "Cell Magic", thus ensuring our observation by naked eyes.
Project Details
Actor - signal peptides
A target peptide is a short (3-70 amino acids long) peptide chain that directs the transport of a protein to a specific region in cell, including nucleus, mitochondria, endoplasmic reticulums (ERs), chloroplasts, apoplasts, peroxisomes and plasma membrane. Targeting peptide can exists in both N-terminal, C-terminal and internal sequence of a precursor protein. And after transported, some target peptides are cleaved by signal peptidases. In our project we utilized 19 peptides target to 9 sub-locations in yeast cells, and when combined with fluorescent proteins, such region can be marked by different colors.
- OMM***
Mitochondria Though it accounts a small ratio in the cell space, mitochondria possess about 10% to 15% proteins encoded by nuclear genes in eukaryotic organisms. These proteins are synthesized in cytosol and then recognized by the membrane receptors of mitochondria. Translocases in the outer and inner membrane of mitochondria mediate the import and intra-mitochondrial sorting of these proteins. ATP is used as an energy source; Chaperones and auxiliary factors assist in folding and assembly of mitochondrial proteins into their native, three-dimensional structures.
Figure 1 | Protein-import pathways for mitochondrial proteins. As shown in figure1, beta-barrel outer-membrane proteins (dark green), precursor proteins (brown) with positively charged amino-terminal presequences and multispanning inner-membrane proteins (blue) with internal targeting signals are recognized by specific receptors of the outer mitochondrial membrane (TOM) translocases Tom20, Tom22 and/or Tom70. The precursor proteins are then translocated through a small Tom proteins of the TOM complex, Tom40 pore, which the TOM complex contains two or three.
- peroxisomes ***
The import of post-translational matrix protein into peroxisomes depends on either of the two peroxisomal targeting signals (PTS), PTS1 and PTS2. PTS2-driven import is facilitated by a complex in the membrane. Under oleic acid-inducing growth conditions, there is a ternary core complex of approximate 150 kDa in the cytosol, which consists of Fox3p,Pex7p and Pex18p. Fox3p is imported as a dimer, while other two are bind in monomeric forms.
Figure2._Schematical_model_of_the_early_steps_of_PTS2-driven_import.png
As study mentioned there are four steps involved in PTS2-driven import. The first step is the recognition of dimerized Fox3p by Pex7p through its PTS2 in the cytosol. In a second step, the Pex7p–Fox3p complex interacts with Pex18p, which targets the PTS2 pre-import complex to the peroxisomal membrane. The third step is the docking process, involving the interaction between Pex7p and the integral membrane protein Pex13p. As a final step of these early steps in the PTS2 import cascade, PTS2 receptor dissociation takes place during or after its assembly into large oligomeric complexes containing Pex14p and Pex13p. Pex18p remains at the peroxisomal membrane in the form of a large-molecular-weight complex in conjunction with Pex14p and/or Pex13p, from where it might be released to the cytosol.