Team:Utah State/Secretion
From 2009.igem.org
(7 intermediate revisions not shown) | |||
Line 87: | Line 87: | ||
<a href="https://2009.igem.org/Team:Utah_State/Introduction">Introduction</a><br /> | <a href="https://2009.igem.org/Team:Utah_State/Introduction">Introduction</a><br /> | ||
<a href="https://2009.igem.org/Team:Utah_State/Broad-HostVectors">Broad-Host Vectors</a><br /> | <a href="https://2009.igem.org/Team:Utah_State/Broad-HostVectors">Broad-Host Vectors</a><br /> | ||
- | <a href="https://2009.igem.org/Team:Utah_State/Secretion">Secretion</a> | + | <a href="https://2009.igem.org/Team:Utah_State/Secretion">Secretion</a> <br /> |
- | <a href="https://2009.igem.org/Team:Utah_State/Experiments">Experiments</a> | + | <a href="https://2009.igem.org/Team:Utah_State/Experiments">Experiments</a><br /> |
- | <a href="https://2009.igem.org/Team:Utah_State/FutureWork">Future Work</a> | + | <a href="https://2009.igem.org/Team:Utah_State/FutureWork">Future Work</a><br /> |
- | + | <a href="https://2009.igem.org/Team:Utah_State/References">References</a><br /> | |
- | + | ||
- | + | ||
- | + | ||
</tr> | </tr> | ||
+ | |||
<tr> | <tr> | ||
<td id="nav"><a href="https://2009.igem.org/Team:Utah_State/Parts"><font size = 4>BIOBRICKS</font></a></td> | <td id="nav"><a href="https://2009.igem.org/Team:Utah_State/Parts"><font size = 4>BIOBRICKS</font></a></td> | ||
Line 133: | Line 131: | ||
<p class="class">Costs associated with the PHA manufacturing process have limited the widespread application of the bioplastic material (Lee, 1996). Economic analyses for industrial scale PHA production place the cost of PHAs at about $4-5/kg (Choi, 1997; Choi, 1999). In contrast, the average cost of petrochemically-derived plastic lies between $0.62-0.96/kg (Steinbüchel and Füchtenbusch, 1998). This significant discrepancy in expense is largely attributable to downstream processing. Traditional methods involving the use of solvents, enzymatic digestion, or mechanical disruption are expensive and impractical for industrial-scale recovery (Jung, 2005). As a result, the development of alternative methods for PHA recovery is necessary.</p> | <p class="class">Costs associated with the PHA manufacturing process have limited the widespread application of the bioplastic material (Lee, 1996). Economic analyses for industrial scale PHA production place the cost of PHAs at about $4-5/kg (Choi, 1997; Choi, 1999). In contrast, the average cost of petrochemically-derived plastic lies between $0.62-0.96/kg (Steinbüchel and Füchtenbusch, 1998). This significant discrepancy in expense is largely attributable to downstream processing. Traditional methods involving the use of solvents, enzymatic digestion, or mechanical disruption are expensive and impractical for industrial-scale recovery (Jung, 2005). As a result, the development of alternative methods for PHA recovery is necessary.</p> | ||
- | <p class="class">Genetic engineering strategies have been used in attempts to simplify PHA recovery and eliminate the need for mechanical or chemical cellular disruption. Jung et al. (2005) used recombinant E. coli MG1655 harboring PHA biosynthesis genes from C. necator to instigate spontaneous autolysis of the cell wall. Up to 80% of the cells in culture released PHA granules, which were subsequently recovered using centrifugation and washing with distilled H2O (Jung, 2005). Resch et al. (1998) used recombinant PHA-producing E. coli transformed with the E-lysis gene of bacteriophage PhiX174 from plasmid pSH2. Amorphous PHB in is pushed out of the cell through an E-lysis tunnel structure, which is an opening in the cell envelope (Resch, 1998). In this procedure, the osmotic pressure difference between the cytoplasm and the culture medium provides the driving force for PHA movement into the extracellular medium. The PHA is then recovered by centrifugation or through the addition of divalent cations (Resch, 1998). Although these methods use genetic means to bring about cellular disruption, these mechanisms still require cellular death and fail to promote a continuous production system. </p> | + | <p class="class">Genetic engineering strategies have been used in attempts to simplify PHA recovery and eliminate the need for mechanical or chemical cellular disruption. Jung et al. (2005) used recombinant <i>E. coli</i> MG1655 harboring PHA biosynthesis genes from C. necator to instigate spontaneous autolysis of the cell wall. Up to 80% of the cells in culture released PHA granules, which were subsequently recovered using centrifugation and washing with distilled H2O (Jung, 2005). Resch et al. (1998) used recombinant PHA-producing <i>E. coli</i> transformed with the E-lysis gene of bacteriophage PhiX174 from plasmid pSH2. Amorphous PHB in is pushed out of the cell through an E-lysis tunnel structure, which is an opening in the cell envelope (Resch, 1998). In this procedure, the osmotic pressure difference between the cytoplasm and the culture medium provides the driving force for PHA movement into the extracellular medium. The PHA is then recovered by centrifugation or through the addition of divalent cations (Resch, 1998). Although these methods use genetic means to bring about cellular disruption, these mechanisms still require cellular death and fail to promote a continuous production system. </p> |
- | <p class="class">Recently, extracellular deposition of PHA granules was observed in a mutant strain of Alcanivorax borkumensis SK2, which is a marine bacterium that uses hydrocarbons as its source of carbon and energy (Sabirova, 2006). This finding by Sabirova et al (2006) is the first account of PHA accumulation outside of the cell (Prieto, 2007). However, the mechanism by which this deposition occurs is unknown (Sabirova, 2006; Prieto, 2007). A defined system for microbial excretion of PHAs has yet to be created. Such a system would be of value due to the potential to optimize and introduce the mechanism into other organisms with advantageous characteristics, such as fast-growing E. coli or photoautotrophic PHA-producers R. sphaeroides and Synechocystis PCC6803. </p> | + | <p class="class">Recently, extracellular deposition of PHA granules was observed in a mutant strain of Alcanivorax borkumensis SK2, which is a marine bacterium that uses hydrocarbons as its source of carbon and energy (Sabirova, 2006). This finding by Sabirova et al (2006) is the first account of PHA accumulation outside of the cell (Prieto, 2007). However, the mechanism by which this deposition occurs is unknown (Sabirova, 2006; Prieto, 2007). A defined system for microbial excretion of PHAs has yet to be created. Such a system would be of value due to the potential to optimize and introduce the mechanism into other organisms with advantageous characteristics, such as fast-growing <i>E. coli</i> or photoautotrophic PHA-producers <i>R. sphaeroides</i> and <i>Synechocystis</i> PCC6803. </p> |
- | <p class="class">PHA-associated proteins, called phasins, strongly interact with the PHA granule surface (York, 2001; Maehara, 1999). Accordingly, PHA recovery may be possible by tagging the phasin protein for translocation. Specifically, the Silver fusion Biobrick standard can be used to create constructs in which a targeting signal peptide sequence is genetically fused to the phasin protein (Phillips, 2006). Fusing a signal peptide to a protein promotes export of the complex out of the cytoplasm (Choi, 2004; Mergulhão, 2005). The interaction of phasin with PHA is required for secretion-based granule recovery because PHA is a non-proteinaceous compound produced by the action of three enzymes (Suriyanmongkol 2007; Verlinden 2007). Consequently, the signal peptide cannot be directly attached PHA granules. The phasin protein with attached signal peptide binds to PHA granules, thereby creating a PHA-phasin-signal peptide complex that may be recognized by the cell for export. Figure | + | <p class="class">PHA-associated proteins, called phasins, strongly interact with the PHA granule surface (York, 2001; Maehara, 1999). Accordingly, PHA recovery may be possible by tagging the phasin protein for translocation. Specifically, the Silver fusion Biobrick standard can be used to create constructs in which a targeting signal peptide sequence is genetically fused to the phasin protein (Phillips, 2006). Fusing a signal peptide to a protein promotes export of the complex out of the cytoplasm (Choi, 2004; Mergulhão, 2005). The interaction of phasin with PHA is required for secretion-based granule recovery because PHA is a non-proteinaceous compound produced by the action of three enzymes (Suriyanmongkol 2007; Verlinden 2007). Consequently, the signal peptide cannot be directly attached PHA granules. The phasin protein with attached signal peptide binds to PHA granules, thereby creating a PHA-phasin-signal peptide complex that may be recognized by the cell for export. Figure 1 depicts this export process in general terms. Green fluorescent protein (GFP) translocation has been documented (Barrett, 2003; Santini, 2001; Thomas, 2001). Due to its ease of detection, studying GFP in parallel with phasin secretion mechanisms could provide a framework for determining the functionality of secretion systems.</p> |
<br> | <br> | ||
<div align="center"><img src="https://static.igem.org/mediawiki/2009/2/25/Bioplasticscheme.jpg"" align = "middle" height="200" style="padding:.5px; border-style:solid; border-color:#999" alt="Team USU" /> </div> | <div align="center"><img src="https://static.igem.org/mediawiki/2009/2/25/Bioplasticscheme.jpg"" align = "middle" height="200" style="padding:.5px; border-style:solid; border-color:#999" alt="Team USU" /> </div> | ||
<div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
- | <b>Figure | + | <b>Figure 1.</b> Schematic for bioplastic recovery by secretion |
</div> | </div> | ||
<br> | <br> | ||
<p class="class"> | <p class="class"> | ||
- | Secretion-based product recovery mechanisms hold great potential to improve the economics of industrial-scale production systems. In addition to reduced downstream processing requirements, secretory production has additional benefits, such as potentially improved product stability and solubility (Mergulhão, 2005). Recombinant E. coli do not typically secrete high levels of proteins and functionality of proteins secretion is difficult to predict (Sandkvist, 1996; Choi, 2004). Accordingly, a trial-and-error approach with different combinations of signal peptides and promoters is recommended for any given protein, and will be discussed in more detail in subsequent sections (Choi, 2004). | + | Secretion-based product recovery mechanisms hold great potential to improve the economics of industrial-scale production systems. In addition to reduced downstream processing requirements, secretory production has additional benefits, such as potentially improved product stability and solubility (Mergulhão, 2005). Recombinant <i>E. coli</i> do not typically secrete high levels of proteins and functionality of proteins secretion is difficult to predict (Sandkvist, 1996; Choi, 2004). Accordingly, a trial-and-error approach with different combinations of signal peptides and promoters is recommended for any given protein, and will be discussed in more detail in subsequent sections (Choi, 2004). |
</p></p> | </p></p> | ||
Line 155: | Line 153: | ||
<p class="class"> | <p class="class"> | ||
There are five pathways observed for secretion of recombinant proteins in gram-negative prokaryotes, numbered I through V (Desvaux, 2004; Mergulhão, 2005). While all of these pathways differ mechanistically, they each promote secretion while maintaining the integrity of the cell structure (Koster, 2000). Types I and II are the most common pathways for recombinant protein secretion (Mergulhao, 2005) and will be discussed here. </p> | There are five pathways observed for secretion of recombinant proteins in gram-negative prokaryotes, numbered I through V (Desvaux, 2004; Mergulhão, 2005). While all of these pathways differ mechanistically, they each promote secretion while maintaining the integrity of the cell structure (Koster, 2000). Types I and II are the most common pathways for recombinant protein secretion (Mergulhao, 2005) and will be discussed here. </p> | ||
- | <p class="class">Type I secretion is a single-step translocation of protein across both inner and outer membranes. (Binet, 1997). The constituents of this system include inner membrane proteins HlyB and HlyD, as well as the TolC outer membrane protein (Mergulhão, 2005; Desveax, 2004). These three proteins interact to form a channel that spans the periplasm (Mergulhão, 2005). Appending the last 42-60 amino acids of the HlyA protein C-terminus to the C-terminus of a recombinant protein targets the protein for secretion (Mergulhão, 2005; Gentschev, 2003; Hess, 1990). The HlyA signal sequence binds to the channel complex, resulting in ATP hydrolysis by HlyB to drive protein secretion (Gentschev, 2003). Proteins as large as 4000 amino acids can be secreted through the type I channel, which has an internal diameter of 3.5 nm and a length of 14 nm (Sapriel, 2003; Fernandez and de Lorenzo, 2001). Unlike in the Type II pathway, the signal peptides of Type I secretion remain attached to the protein after export out of the cytoplasm (Blight and Holland, 1994). Figure | + | <p class="class">Type I secretion is a single-step translocation of protein across both inner and outer membranes. (Binet, 1997). The constituents of this system include inner membrane proteins HlyB and HlyD, as well as the TolC outer membrane protein (Mergulhão, 2005; Desveax, 2004). These three proteins interact to form a channel that spans the periplasm (Mergulhão, 2005). Appending the last 42-60 amino acids of the HlyA protein C-terminus to the C-terminus of a recombinant protein targets the protein for secretion (Mergulhão, 2005; Gentschev, 2003; Hess, 1990). The HlyA signal sequence binds to the channel complex, resulting in ATP hydrolysis by HlyB to drive protein secretion (Gentschev, 2003). Proteins as large as 4000 amino acids can be secreted through the type I channel, which has an internal diameter of 3.5 nm and a length of 14 nm (Sapriel, 2003; Fernandez and de Lorenzo, 2001). Unlike in the Type II pathway, the signal peptides of Type I secretion remain attached to the protein after export out of the cytoplasm (Blight and Holland, 1994). Figure 2 depicts the secretion of a protein with a C-terminal fused HlyA signal peptide by Type I secretion (Mergulão, 2005). |
<br> | <br> | ||
</p> | </p> | ||
<div align="center"><img src="https://static.igem.org/mediawiki/2009/e/ed/FigureHlyATypeI.png"" align = "middle" height="150" style="padding:.5px; border-style:solid; border-color:#999" alt="HlyA" /> </div> | <div align="center"><img src="https://static.igem.org/mediawiki/2009/e/ed/FigureHlyATypeI.png"" align = "middle" height="150" style="padding:.5px; border-style:solid; border-color:#999" alt="HlyA" /> </div> | ||
<div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
- | <b>Figure | + | <b>Figure 2.</b> HlyA Type I Secretion Pathway |
</div> | </div> | ||
<br> | <br> | ||
<p class="class"> | <p class="class"> | ||
- | The type II secretion pathway is a two-step process. The cytoplasmic protein must first be exported into the periplasm through the action of a translocase. Specifically, the Sec and Twin-arginine translocation (TAT) machinery facilitate protein movement across the inner membrane and will be discussed in detail in the next section. After entering the periplasm, the protein can be translocated into the extracellular medium through the action of a secreton, which is a 12-16 core protein complex present in many gram-negative strains, such as E. coli K-12 (Cianciotto, 2005). Although the secreton functionality is not completely understood, it is known that protein conformational changes are necessary for this process to be carried out (Mergulhão, 2005; Sandkvist, 2001).</p> | + | The type II secretion pathway is a two-step process. The cytoplasmic protein must first be exported into the periplasm through the action of a translocase. Specifically, the Sec and Twin-arginine translocation (TAT) machinery facilitate protein movement across the inner membrane and will be discussed in detail in the next section. After entering the periplasm, the protein can be translocated into the extracellular medium through the action of a secreton, which is a 12-16 core protein complex present in many gram-negative strains, such as <i>E. coli</i> K-12 (Cianciotto, 2005). Although the secreton functionality is not completely understood, it is known that protein conformational changes are necessary for this process to be carried out (Mergulhão, 2005; Sandkvist, 2001).</p> |
<p class="class"> | <p class="class"> | ||
- | Translocation of cellular products into the periplasm is advantageous over cytoplasmic production because recovery of periplasmic products is relatively simpler (Mergulhão, 2005). There are additional mechanisms for recovering periplasmic proteins if the secreton machinery is either not present in the host strain or incompatible with the protein of interest. These mechanisms are depicted in Figure | + | Translocation of cellular products into the periplasm is advantageous over cytoplasmic production because recovery of periplasmic products is relatively simpler (Mergulhão, 2005). There are additional mechanisms for recovering periplasmic proteins if the secreton machinery is either not present in the host strain or incompatible with the protein of interest. These mechanisms are depicted in Figure 3. L-form and Q-cells are mutant strains that have a weakened outer membrane, which allows for some proteins to leak into the extracellular medium (Mergulhão, 2005). However, these organisms have reduced growth rates and are not ideal candidates for general cellular production. The permeability of the outer membrane may be enhanced mechanically, such as by application of ultrasound, or through chemical treatment, such as through addition of Triton X-100 or 2% glycine (Kaderbhai, 1997; Choi, 2004). As another example, enzymatic digestion with lysozyme breaks the outer membrane to release periplasmic proteins (Shokri, 2003). Yet another alternative involves coexpression of genes, such as kil, out, and tolAIII, that cause cellular lysis and subsequent release of recombinant proteins (Choi, 2004; Mergulhão, 2005). The downside to these alternatives is the weakening of cell integrity. |
</p><br> | </p><br> | ||
Line 175: | Line 173: | ||
<p class="class"> | <p class="class"> | ||
- | Several membrane-associated components mediate translocation of proteins across the inner membrane of gram-negative E. coli (Luirink, 2004). This machinery includes translocases, ATPases, and accessory proteins (Luirink, 2004; Veenendaal, 2004). The Sec pathway and the TAT system are the two general mechanisms by which proteins are transported into the periplasm, with the Sec-translocon providing most common export route (Luirink, 2004; Veenendaal, 2004). Within the Sec-dependent category, proteins are exported either via the SecB-dependent pathway or by the action of the signal recognition particle (SRP). The attachment of a short sequence, called a signal peptide, to the N-terminus of a protein is generally necessary for targeting proteins to any of the three translocation pathways (Luirink, 2004; Choi, 2004; Mergulhão, 2005). </p> | + | Several membrane-associated components mediate translocation of proteins across the inner membrane of gram-negative <i>E. coli</i> (Luirink, 2004). This machinery includes translocases, ATPases, and accessory proteins (Luirink, 2004; Veenendaal, 2004). The Sec pathway and the TAT system are the two general mechanisms by which proteins are transported into the periplasm, with the Sec-translocon providing most common export route (Luirink, 2004; Veenendaal, 2004). Within the Sec-dependent category, proteins are exported either via the SecB-dependent pathway or by the action of the signal recognition particle (SRP). The attachment of a short sequence, called a signal peptide, to the N-terminus of a protein is generally necessary for targeting proteins to any of the three translocation pathways (Luirink, 2004; Choi, 2004; Mergulhão, 2005). </p> |
<p class="class">In the Sec pathway, SecA is attached peripherally to the inner membrane and drives peptide translocation through ATPase activity (van der Does, 2004). Integral membrane proteins SecY and SecE form the core of the Sec translocon, and SecG interacts with this core to form a multimeric protein complex, SecYEG (Veenendaal, 2004). This complex functions as a protein-conducting channel for both post-translational and co-translational protein export (Luirink, 2004; Veenendaal, 2004). Interestingly, the SecYEG translocon can be found in all domains of life, reiterating the prevalence and importance of this mechanism for protein export (Cao, 2002). </p> | <p class="class">In the Sec pathway, SecA is attached peripherally to the inner membrane and drives peptide translocation through ATPase activity (van der Does, 2004). Integral membrane proteins SecY and SecE form the core of the Sec translocon, and SecG interacts with this core to form a multimeric protein complex, SecYEG (Veenendaal, 2004). This complex functions as a protein-conducting channel for both post-translational and co-translational protein export (Luirink, 2004; Veenendaal, 2004). Interestingly, the SecYEG translocon can be found in all domains of life, reiterating the prevalence and importance of this mechanism for protein export (Cao, 2002). </p> | ||
Line 182: | Line 180: | ||
<p class="class"> | <p class="class"> | ||
- | The TAT system is used to export folded proteins into the periplasmic space (Choi, 2004). Like the Sec-dependent pathways, specific N-terminal signal peptide sequences target a protein for export by the TAT machinery. Although similar, TAT signal peptides differ from those that target proteins to the Sec machinery. TAT signal peptides contain a conserved sequence of seven amino acids, (S/T)-R-R-x-F-L-K, at the interface between the N- and H-regions, where x represents a polar amino acid (Berks, 2000; Palmer, 2004). The twin-arginine residues are consistently present in TAT signal peptides, and the occurrence of the other amino acids is greater than 50% (Berks 1996, Berks 2000, Palmer, 2004). Figure | + | The TAT system is used to export folded proteins into the periplasmic space (Choi, 2004). Like the Sec-dependent pathways, specific N-terminal signal peptide sequences target a protein for export by the TAT machinery. Although similar, TAT signal peptides differ from those that target proteins to the Sec machinery. TAT signal peptides contain a conserved sequence of seven amino acids, (S/T)-R-R-x-F-L-K, at the interface between the N- and H-regions, where x represents a polar amino acid (Berks, 2000; Palmer, 2004). The twin-arginine residues are consistently present in TAT signal peptides, and the occurrence of the other amino acids is greater than 50% (Berks 1996, Berks 2000, Palmer, 2004). Figure 3 illustrates the mechanism for protein export by the Sec and TAT pathways.</p> |
<br> | <br> | ||
<div align="center"><img src="https://static.igem.org/mediawiki/2009/9/91/FigureSecTAT.png"" align = "middle" height="200" style="padding:.5px; border-style:solid; border-color:#999" alt="Team USU" /> </div> | <div align="center"><img src="https://static.igem.org/mediawiki/2009/9/91/FigureSecTAT.png"" align = "middle" height="200" style="padding:.5px; border-style:solid; border-color:#999" alt="Team USU" /> </div> | ||
<div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
- | <b>Figure | + | <b>Figure 3.</b> Mechanism of protein translocation by Sec and Tat |
</div> | </div> | ||
<br> | <br> | ||
Line 198: | Line 196: | ||
</font></b></i> | </font></b></i> | ||
<p class="class"> | <p class="class"> | ||
- | Signal peptides consist of about 15-30 amino acids and are generally required to direct a secretory protein to the translocons of the cytoplasmic membrane (Pugsley, 1993; Choi, 2004; Luirink, 2004). Despite overall sequence variability, structural similarities exist between different signal peptides, including a positively-charged 2-10 amino acid N-region, a hydrophobic core H-region, and a neutral C-domain of about 6 residues (Pugsley, 1993; Molhoj, 2004; Berks, 2000). The C-domain conforms to the -3, -1 rule in which amino acids with short and neutral side-chains, such as alanine, are required in positions -3 and -1 of the sequence (Choi, 2004; von Heijne, 1984). A signal peptidase interacts with a cleavage recognition site within the C-domain to release the protein into the periplasmic space (Luiritz, 2004; Choi, 2004). The absence or mutation of the cleavage site can lead to the targeted protein remaining fixed to the inner membrane (Luiritz, 2004). Figure | + | Signal peptides consist of about 15-30 amino acids and are generally required to direct a secretory protein to the translocons of the cytoplasmic membrane (Pugsley, 1993; Choi, 2004; Luirink, 2004). Despite overall sequence variability, structural similarities exist between different signal peptides, including a positively-charged 2-10 amino acid N-region, a hydrophobic core H-region, and a neutral C-domain of about 6 residues (Pugsley, 1993; Molhoj, 2004; Berks, 2000). The C-domain conforms to the -3, -1 rule in which amino acids with short and neutral side-chains, such as alanine, are required in positions -3 and -1 of the sequence (Choi, 2004; von Heijne, 1984). A signal peptidase interacts with a cleavage recognition site within the C-domain to release the protein into the periplasmic space (Luiritz, 2004; Choi, 2004). The absence or mutation of the cleavage site can lead to the targeted protein remaining fixed to the inner membrane (Luiritz, 2004). Figure 4 shows the typical composition of a signal peptide sequence.</p><br> |
<div align="center"><img src="https://static.igem.org/mediawiki/2009/f/f2/Signal_peptide.png"" align = "middle" height="50" style="padding:.5px; alt="signal peptide" /> </div> | <div align="center"><img src="https://static.igem.org/mediawiki/2009/f/f2/Signal_peptide.png"" align = "middle" height="50" style="padding:.5px; alt="signal peptide" /> </div> | ||
<div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
- | <b>Figure | + | <b>Figure 4.</b> Typical signal peptide sequence |
</div> | </div> | ||
<br> | <br> | ||
<p class="class"> | <p class="class"> | ||
- | A small signal sequence is typically necessary for all translocation pathways. However, certain protein-coding sequences can be secreted without having an attached signal sequence due to the presence of additional targeting information within the sequence (Luiritz, 2004). Additionally, an attached signal sequence does not guarantee export of a protein, which further suggests that information in the protein sequence itself can affect secretion efficiency (Luiritz, 2004). However, the fusion of a signal sequence to a recombinant protein can lead to export of a previously non-secretable protein. There are many reported examples of recombinant protein translocation through signal sequence gene fusion. For example, fusion with the Tat-dependent signal peptide TorA allowed for export of folded GFP into the periplasm of E. coli (Palmer, 2004; Barrett, 2003; Santini, 2001; Thomas, 2001). </p> | + | A small signal sequence is typically necessary for all translocation pathways. However, certain protein-coding sequences can be secreted without having an attached signal sequence due to the presence of additional targeting information within the sequence (Luiritz, 2004). Additionally, an attached signal sequence does not guarantee export of a protein, which further suggests that information in the protein sequence itself can affect secretion efficiency (Luiritz, 2004). However, the fusion of a signal sequence to a recombinant protein can lead to export of a previously non-secretable protein. There are many reported examples of recombinant protein translocation through signal sequence gene fusion. For example, fusion with the Tat-dependent signal peptide TorA allowed for export of folded GFP into the periplasm of <i>E. coli</i> (Palmer, 2004; Barrett, 2003; Santini, 2001; Thomas, 2001). </p> |
<p class="class"> | <p class="class"> | ||
Line 226: | Line 224: | ||
<p class="class"> | <p class="class"> | ||
- | Due to their physical interaction with the PHA granule, phasins can be used in recombinant protein purification (Banki, 2005), or PHA recovery as this project is investigating. For protein purification, genetic fusion of a protein product, a self-splicing element called an intein, and phasin can be used (Banki, 2005). The genetically-fused protein is produced in E. coli harboring the PHB production genes (Banki, 2005). The phasin protein binds to the surface of the PHB granule, and a cleavage-inducing buffer stimulates the release of the product protein into the soluble fraction of the solution (Banki, 2005). </p> | + | Due to their physical interaction with the PHA granule, phasins can be used in recombinant protein purification (Banki, 2005), or PHA recovery as this project is investigating. For protein purification, genetic fusion of a protein product, a self-splicing element called an intein, and phasin can be used (Banki, 2005). The genetically-fused protein is produced in <i>E. coli</i> harboring the PHB production genes (Banki, 2005). The phasin protein binds to the surface of the PHB granule, and a cleavage-inducing buffer stimulates the release of the product protein into the soluble fraction of the solution (Banki, 2005). </p> |
<p class="class"> | <p class="class"> | ||
Line 232: | Line 230: | ||
<p class="class"> | <p class="class"> | ||
- | The recovery of PHA granules via secretion of a signal peptide/phasin/PHA complex may be inhibited due to the size of PHA granules. However, the binding of phasins decreases PHA molecular weight and encourages the formation of numerous, small granules (Maehara, 1999). Though the actual size of PHA granules varies, Maehara et al (1999) observed spherical granules approximately 20 – 60 nm in diameter in the presence of phasin and absence of the PhaR repressor | + | The recovery of PHA granules via secretion of a signal peptide/phasin/PHA complex may be inhibited due to the size of PHA granules. However, the binding of phasins decreases PHA molecular weight and encourages the formation of numerous, small granules (Maehara, 1999). Though the actual size of PHA granules varies, Maehara et al (1999) observed spherical granules approximately 20 – 60 nm in diameter in the presence of phasin and absence of the PhaR repressor. This indicates that enhanced production of phasin may further reduce granule size, which may make PHAs more suitable for export. </p> |
<b><i><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <b><i><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
Line 239: | Line 237: | ||
<p class="class"> | <p class="class"> | ||
- | GFP is a commonly used reporter of gene regulation. It is expressed in many bioluminescent jellyfish naturally (Shimomura, 1962). Its value in the academic and biotechnology industry was recognized after successful cloning and expression in E. coli (Chalfie, 1994). Purified GFP, composed of 238 amino acids, absorbs blue light (395 nm) and emits green light (Chalfie, 1994). The detection of intracellular GFP is not limited by the availability of substrates, but requires only irradiation by near UV or blue light (Chalfie, 1994). However, to ease the process of GFP detection for many organisms, a stronger whole cell fluorescence signal is desirable. Figure | + | GFP is a commonly used reporter of gene regulation. It is expressed in many bioluminescent jellyfish naturally (Shimomura, 1962). Its value in the academic and biotechnology industry was recognized after successful cloning and expression in <i>E. coli</i> (Chalfie, 1994). Purified GFP, composed of 238 amino acids, absorbs blue light (395 nm) and emits green light (Chalfie, 1994). The detection of intracellular GFP is not limited by the availability of substrates, but requires only irradiation by near UV or blue light (Chalfie, 1994). However, to ease the process of GFP detection for many organisms, a stronger whole cell fluorescence signal is desirable. Figure 5 depicts the GFP barrel structure.</p> |
- | <div align="center"><img src="https://static.igem.org/mediawiki/2009/6/60/GFpbarrel.jpg"" align = "middle" height=" | + | <div align="center"><img src="https://static.igem.org/mediawiki/2009/6/60/GFpbarrel.jpg"" align = "middle" height="200" style="padding:.5px; alt="signal peptide" /> </div> |
<div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | <div align="center"><font size="2.5" face="Helvetica, Arial, San Serif" color =#231f20> | ||
- | <b>Figure | + | <b>Figure 5.</b> The GFP Barrel Structure |
</div> | </div> | ||
- | <p class="class">Many mutant forms of GFP have been created which improve fluorescence photostability and ultimately the ability of GFP to function as a practical reporter. The cycle 3 mutant developed by Crameri et al. (1996) is of special interest because it produces a fluorescence signal 45-fold greater than wild-type GFP. The developed GFP possesses three point mutations of the wild-type GFP. These mutations do not affect the chromophore itself, but reside in the surrounding barrel of the GFP protein. In E. coli, due to its hydrophobic nature, most of the wild-type GFP gathers to form inclusion bodies that limit the ability of blue light to provide the necessary excitation energy to activate fluorescence (Crameri , 1996). The three point mutations in the cycle 3 mutant, have no effect on excitation and emissions maxima, but create a more hydrophilic GFP less prone to form inclusion bodies. The soluble mutant is easily activated by a UV light box or light wand common in the laboratory creating an immediate, practical reporter protein. Furthermore, fusions onto amino- or carboxy-termini of GFP do not inhibit fluorescence, which makes GFP an ideal candidate for fusion studies (LaVallie, 1995).</p> | + | <p class="class">Many mutant forms of GFP have been created which improve fluorescence photostability and ultimately the ability of GFP to function as a practical reporter. The cycle 3 mutant developed by Crameri et al. (1996) is of special interest because it produces a fluorescence signal 45-fold greater than wild-type GFP. The developed GFP possesses three point mutations of the wild-type GFP. These mutations do not affect the chromophore itself, but reside in the surrounding barrel of the GFP protein. In <i>E. coli</i>, due to its hydrophobic nature, most of the wild-type GFP gathers to form inclusion bodies that limit the ability of blue light to provide the necessary excitation energy to activate fluorescence (Crameri , 1996). The three point mutations in the cycle 3 mutant, have no effect on excitation and emissions maxima, but create a more hydrophilic GFP less prone to form inclusion bodies. The soluble mutant is easily activated by a UV light box or light wand common in the laboratory creating an immediate, practical reporter protein. Furthermore, fusions onto amino- or carboxy-termini of GFP do not inhibit fluorescence, which makes GFP an ideal candidate for fusion studies (LaVallie, 1995).</p> |
+ | |||
+ | |||
</td> | </td> |
Latest revision as of 04:28, 12 November 2009
|
|