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<a class="item" href="//2016.igem.org/Team:Slovenia/Demonstrate" style="color:#DB2828;"> | <a class="item" href="//2016.igem.org/Team:Slovenia/Demonstrate" style="color:#DB2828;"> | ||
<i class="selected radio icon"></i> | <i class="selected radio icon"></i> | ||
− | <b>Protease-based inducible secretion</b> | + | <b>Protease-based</b> <br /> |
+ | <b style="margin-left: 12%">inducible secretion</b> | ||
</a> | </a> | ||
− | <a class="item" href=" | + | <a class="item" href="#ach" style="margin-left: 10%"> |
<i class="selected radio icon"></i> | <i class="selected radio icon"></i> | ||
<b>Achievements</b> | <b>Achievements</b> | ||
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<div> | <div> | ||
<div class="main ui citing justified container"> | <div class="main ui citing justified container"> | ||
− | + | <div> | |
− | + | <h1 class="ui left dividing header"><span id="ach" class="section colorize"> </span>Protease-based inducible | |
+ | secretion</h1> | ||
− | + | <div class="ui segment" style="background-color: #ebc7c7;"> | |
− | + | ||
− | + | <p><b> | |
− | + | <ul> | |
− | + | <li>Retention of proteins in ER lumen was demonstrated by confocal microscopy and | |
− | + | detection of the protein in the cell medium. | |
− | + | <li>A variant of TEVp active in the ER lumen was implemented to control protein | |
− | + | secretion from the ER lumen. | |
− | + | <li>Retention of proteins on the ER membrane was also demonstrated by confocal | |
− | + | microscopy and detection of the protein in the cell medium. | |
− | + | <li>Rapamycin induced cleavage was used for controlled and inducible secretion of | |
− | + | proteins from the ER membrane. | |
− | + | </ul> | |
− | + | </b></p> | |
+ | </div> | ||
</div> | </div> | ||
<div class="ui segment"> | <div class="ui segment"> | ||
<div> | <div> | ||
<h4><span id = "intro" class="section colorize"> </span></h4> | <h4><span id = "intro" class="section colorize"> </span></h4> | ||
− | <p>To achieve a fast regulated cellular response resulting in the | + | <p>To achieve a fast regulated cellular response resulting in the protein release, we |
decided to mimic the release of insulin from beta cells where the protein of | decided to mimic the release of insulin from beta cells where the protein of | ||
− | interest is pre-formed and present | + | interest is pre-formed and present intracellularly in secretory granules. In contrast to the |
specialized storage and release mechanism of insulin from beta cells we wanted to | specialized storage and release mechanism of insulin from beta cells we wanted to | ||
develop a more general and modular solution by making use of components already existing | develop a more general and modular solution by making use of components already existing | ||
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motif on their C-terminus (cytosolic side) | motif on their C-terminus (cytosolic side) | ||
<x-ref>Munro1987, Jackson1990, Stornaiuolo2003</x-ref>. | <x-ref>Munro1987, Jackson1990, Stornaiuolo2003</x-ref>. | ||
− | . The mechanism that allows these proteins to stay in the ER is | + | . The mechanism that allows these proteins to stay in the ER is retrieval rather than |
retention. However, we decided to use the term retention for | retention. However, we decided to use the term retention for | ||
description of this process. ER luminal proteins interact with the KDEL receptor, a | description of this process. ER luminal proteins interact with the KDEL receptor, a | ||
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<div class="ui segment"> | <div class="ui segment"> | ||
<div> | <div> | ||
− | <h3><span id = "lum" class="section colorize"> </span> | + | <h3><span id = "lum" class="section colorize"> </span>Release from the ER lumen and secretion from the cell</h3> |
<p>To achieve and detect the inducible secretion from the ER lumen, we created two reporter | <p>To achieve and detect the inducible secretion from the ER lumen, we created two reporter | ||
constructs with a cleavable KDEL sequence targeted to the ER lumen: SEAP<sup>KDEL</sup> | constructs with a cleavable KDEL sequence targeted to the ER lumen: SEAP<sup>KDEL</sup> | ||
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</figure> | </figure> | ||
</div> | </div> | ||
− | <p>When the TagRFP<sup>KDEL</sup> reporter ( | + | <p>When the TagRFP<sup>KDEL</sup> reporter (<ref>1</ref>A) was expressed in the ER without an active erTEVp we confirmed its localization in the |
− | + | ||
− | + | ||
ER with confocal microscopy | ER with confocal microscopy | ||
− | ( | + | (<ref>1</ref>B). Additionally, we could not detect any TagRFP in the cell medium with Western |
− | + | ||
− | + | ||
blotting. When erTEVp was present and active in the ER, the KDEL sequence was | blotting. When erTEVp was present and active in the ER, the KDEL sequence was | ||
removed from the reporter and the protein was secreted from the cell, which we detected | removed from the reporter and the protein was secreted from the cell, which we detected | ||
− | with Western blot ( | + | with Western blot (<ref>1</ref>C). This demonstrated that proteolytic activity in the ER can |
− | + | ||
− | + | ||
regulate protein secretion. | regulate protein secretion. | ||
</p> | </p> | ||
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not present in the cell medium without coexpression of erTEVp. When erTEVp was | not present in the cell medium without coexpression of erTEVp. When erTEVp was | ||
cotransfected with | cotransfected with | ||
− | the reporter, we detected a large increase in enzymatic activity in the medium ( | + | the reporter, we detected a large increase in enzymatic activity in the medium (<ref>2</ref>). |
− | + | ||
− | + | ||
</p> | </p> | ||
<div style="float:left; width:40%"> | <div style="float:left; width:40%"> | ||
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<div> | <div> | ||
− | <h3 style="clear:both"><span id = "mem" class="section colorize"> </span> | + | <h3 style="clear:both"><span id = "mem" class="section colorize"> </span>Release from the ER membrane and secretion from the cell</h3> |
<p>The second approach to regulate protein secretion from the ER by protease was to used | <p>The second approach to regulate protein secretion from the ER by protease was to used | ||
KKMP ER retention peptide linked to the transmembrane protein with a protease target | KKMP ER retention peptide linked to the transmembrane protein with a protease target | ||
− | motif on the cytoplasmic side, N- | + | motif on the cytoplasmic side, N-terminally to the KKMP peptide. A transmembrane (TM) |
domain from the B-cell receptor | domain from the B-cell receptor | ||
(<a href="http://parts.igem.org/Part:BBa_K157010">Bba_K157010</a>) was used for the | (<a href="http://parts.igem.org/Part:BBa_K157010">Bba_K157010</a>) was used for the | ||
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were designed and the constructs also contained a signal sequence at their N-terminus | were designed and the constructs also contained a signal sequence at their N-terminus | ||
and a | and a | ||
− | proteolytically cleavable ER retention signal at their C-terminus. In case of | + | proteolytically cleavable ER retention signal at their C-terminus. In case of |
transmembrane targeted reporters we used the KKMP retention signal preceded by 3 copies | transmembrane targeted reporters we used the KKMP retention signal preceded by 3 copies | ||
of the | of the | ||
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<p>Additionally, either one or four furin cleavage sites were inserted between the protein | <p>Additionally, either one or four furin cleavage sites were inserted between the protein | ||
of interest on the luminal side of the ER, which enable cleavage of the reporter | of interest on the luminal side of the ER, which enable cleavage of the reporter | ||
− | protein from the membrane, but this could | + | protein from the membrane, but this could only occur after the KKMP had been removed and |
the protein could enter the trans-GA. Furin is a native cellular endoprotease that is | the protein could enter the trans-GA. Furin is a native cellular endoprotease that is | ||
active only in the trans-GA.</x-ref>Henrich2003</x-ref> This allowed us to design our | active only in the trans-GA.</x-ref>Henrich2003</x-ref> This allowed us to design our | ||
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<figcaption><b>Inducible secretion of reporter localized on ER membrane.</b><br/> | <figcaption><b>Inducible secretion of reporter localized on ER membrane.</b><br/> | ||
<p style="text-align:justify">SEAP activity was increased in the medium of cells | <p style="text-align:justify">SEAP activity was increased in the medium of cells | ||
− | induced with rapamycin. | + | induced with rapamycin. Scheme of the transmembrane reporter with |
cleavable KKMP retention signal and inducible protease. | cleavable KKMP retention signal and inducible protease. | ||
HEK293T cells were transfected with the indicated reporter and rapamycin | HEK293T cells were transfected with the indicated reporter and rapamycin | ||
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<p>Localization of the TagRFP:TM<sup>KKMP</sup> reporter was confirmed by the confocal | <p>Localization of the TagRFP:TM<sup>KKMP</sup> reporter was confirmed by the confocal | ||
microscopy. We used a control reporter without the KKMP retention signal (TagRFP:TM) | microscopy. We used a control reporter without the KKMP retention signal (TagRFP:TM) | ||
− | which we detected both on the ER and the plasma membrane ( | + | which we detected both on the ER and the plasma membrane (<ref>3</ref>A). In case of present KKMP retention signal, the reporter was detected only on the |
− | + | ||
− | + | ||
ER | ER | ||
− | ( | + | (<ref>3</ref>B). When TagRFP:TM<sup>KKMP</sup> was coexpressed with TEVp, localization of the |
− | + | ||
− | + | ||
reporter was similar to the localization of the positive control (TagRFP:TM) | reporter was similar to the localization of the positive control (TagRFP:TM) | ||
− | on the plasma membrane and the ER ( | + | on the plasma membrane and the ER (<ref>3</ref>C). |
− | + | ||
− | + | ||
</p> | </p> | ||
<p>A band with a slightly larger apparent size than the expected size of TagRFP (28 kDa) was | <p>A band with a slightly larger apparent size than the expected size of TagRFP (28 kDa) was | ||
− | detected by | + | detected by Western blotting in cells transfected with TagRFP:TM. We showed that the |
unexpected difference in size was due to glycosylation, as we detected the protein at | unexpected difference in size was due to glycosylation, as we detected the protein at | ||
the expected size after deglycosylation of the medium sample with N-glycosidase F. We | the expected size after deglycosylation of the medium sample with N-glycosidase F. We | ||
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activity in the medium of | activity in the medium of | ||
cells stimulated with rapamycin, which was dose dependent with respect to the amount of | cells stimulated with rapamycin, which was dose dependent with respect to the amount of | ||
− | the transfected reporter-coding plasmid ( | + | the transfected reporter-coding plasmid (<ref>4</ref>). These results confirm that |
− | + | ||
− | + | ||
secretion of a target protein can be made inducible by an externally supplied signal, | secretion of a target protein can be made inducible by an externally supplied signal, | ||
processed through our split protease system. | processed through our split protease system. | ||
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</div> | </div> | ||
</div> | </div> | ||
− | < | + | <h3 class="ui left dividing header"><span id="ref-title" class="section"> </span>References |
− | </ | + | </h3> |
<div class="ui segment citing" id="references"></div> | <div class="ui segment citing" id="references"></div> | ||
</div> | </div> |
Latest revision as of 18:28, 19 October 2016
Protease-based inducible secretion
To achieve a fast regulated cellular response resulting in the protein release, we decided to mimic the release of insulin from beta cells where the protein of interest is pre-formed and present intracellularly in secretory granules. In contrast to the specialized storage and release mechanism of insulin from beta cells we wanted to develop a more general and modular solution by making use of components already existing in different types of cells. Additionally, there should be minimal leakage from the protein depot in the uninduced state and after induction secretion from the cell should be fast.
Not many systems for the inducible release of proteins have been engineered to
date. In one of the few examples Rivera et al. developed a system where the
protein of interest
was fused to a conditional aggregation domain (CAD)
Many proteins that reside on the membrane or in the lumen of the ER contain short
peptide signals. Proteins present in the lumen of the ER contain a KDEL C-terminal
sequence
(Lys-Asp-Glu-Leu) while type I transmembrane (TM) proteins contain a dilysine (KKXX)
motif on their C-terminus (cytosolic side)
Our idea was that if we proteolytically remove the retention signal, the protein of interest would no longer be retrieved back to the ER and could be secreted from the cell. To achieve this we designed two types of secretory reporters, one type based on the luminal retention using KDEL sequence and the other based on the transmembrane retention with a KKMP sequence. In each case, the retention sequence was preceded by a TEVp cleavage site to allow for inducible secretion, which could be replaced by any other peptide target of our orthogonal protease set.
Results
Release from the ER lumen and secretion from the cell
To achieve and detect the inducible secretion from the ER lumen, we created two reporter constructs with a cleavable KDEL sequence targeted to the ER lumen: SEAPKDEL and TagRFPKDEL. Those proteins contained a protease target motif between the reporter domain and the KDEL domain, aimed to enable protein secretion after the proteolytic cleavage. We used a TEVp variant (erTEVp) for all of our experiments with luminal retention.
In order to rely on TEVp cleavage in the ER lumen, we had to take some additional considerations into account. Cesaratto et al. Cesaratto2015 reported that the wild type TEV protease is not active in the lumen of ER. They designed a TEV protease variant active in the endoplasmic reticulum by preventing two major types of post-translational modifications: N-glycosylation and cysteine oxidation. To avoid these inhibiting modifications, mutations N23Q, C130S and N171T were made. To ensure correct localization and accumulation of this TEVp variant inside the endoplasmic reticulum, we also attached an ER signal sequence at the N-terminus and KDEL at the C-terminus of the protein.
When the TagRFPKDEL reporter (1A) was expressed in the ER without an active erTEVp we confirmed its localization in the ER with confocal microscopy (1B). Additionally, we could not detect any TagRFP in the cell medium with Western blotting. When erTEVp was present and active in the ER, the KDEL sequence was removed from the reporter and the protein was secreted from the cell, which we detected with Western blot (1C). This demonstrated that proteolytic activity in the ER can regulate protein secretion.
Using SEAPKDEL we were able to confirm that the reporter is not present in the cell medium without coexpression of erTEVp. When erTEVp was cotransfected with the reporter, we detected a large increase in enzymatic activity in the medium (2).
Release from the ER membrane and secretion from the cell
The second approach to regulate protein secretion from the ER by protease was to used KKMP ER retention peptide linked to the transmembrane protein with a protease target motif on the cytoplasmic side, N-terminally to the KKMP peptide. A transmembrane (TM) domain from the B-cell receptor (Bba_K157010) was used for the integration of target proteins in the ER membrane. Similar as described above, two reporter constructs with SEAP and TagRFP (SEAP:TMKKMP and TagRFP:TMKKMP) were designed and the constructs also contained a signal sequence at their N-terminus and a proteolytically cleavable ER retention signal at their C-terminus. In case of transmembrane targeted reporters we used the KKMP retention signal preceded by 3 copies of the TEVp cleavage site on the cytosolic side of the membrane.
Additionally, either one or four furin cleavage sites were inserted between the protein of interest on the luminal side of the ER, which enable cleavage of the reporter protein from the membrane, but this could only occur after the KKMP had been removed and the protein could enter the trans-GA. Furin is a native cellular endoprotease that is active only in the trans-GA.Henrich2003 This allowed us to design our constructs so that they are cleaved off of the membrane without any modified scar sequences attached to them.
Localization of the TagRFP:TMKKMP reporter was confirmed by the confocal microscopy. We used a control reporter without the KKMP retention signal (TagRFP:TM) which we detected both on the ER and the plasma membrane (3A). In case of present KKMP retention signal, the reporter was detected only on the ER (3B). When TagRFP:TMKKMP was coexpressed with TEVp, localization of the reporter was similar to the localization of the positive control (TagRFP:TM) on the plasma membrane and the ER (3C).
A band with a slightly larger apparent size than the expected size of TagRFP (28 kDa) was detected by Western blotting in cells transfected with TagRFP:TM. We showed that the unexpected difference in size was due to glycosylation, as we detected the protein at the expected size after deglycosylation of the medium sample with N-glycosidase F. We were unable to detect a corresponding band in the medium of cells transfected with TagRFP:TMKKMP in the absence of the protease.
Together, these results confirm that localization and secretion of the protein reporter with the transmembrane domain depends on the presence and proteolysis of the KKMP retention signal and that proteolysis can be used to induce secretion of already synthesized protein.
Finally, we cotransfected cells with SEAP:TMKKMP and rapamycin-inducible split TEVp. We detected increased levels of the SEAP enzymatic activity in the medium of cells stimulated with rapamycin, which was dose dependent with respect to the amount of the transfected reporter-coding plasmid (4). These results confirm that secretion of a target protein can be made inducible by an externally supplied signal, processed through our split protease system.