Team:UCL/Project/Degradation

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Latest revision as of 00:36, 5 October 2013

Matrix

Metalloproteinase-9

For β-amyloid Degradation

The pathological hallmark of Alzheimer's disease (AD) is the senile plaques primarily composed of tightly aggregated β-amyloid (Aβ) fibrils. Matrix metalloproteinase-9 (MMP-9) can degrade Aβ fibrils and soluble Aβ, an ability that is not shared by other soluble Aβ degrading enzymes, including endothelin-converting enzyme, insulin-degrading enzyme, and neprilysin (Yan et al. 2006), all of which we had been considering for our circuit. Therefore, using MMP-9 satisfies both those theories that hold fibrillar Aβ senile plaques responsible for AD. This also supports some of the newer ideas that amyloid plaque forms protectively to seal away more soluble Aβ. By expressing it in inactive microglia, we can engender plaque removal without neuroinflammation. To characterise MMP-9, we carried out a β-amyloid degradation assay.

MMP-9 is a Zinc II dependent endopeptidase that in humans is encoded by the MMP9 gene. MMP-9 is readily synthesised and secreted by microglia upon activation. The primary function of MMP-9 is to degrade proteins in the extracellular matrix. Physiologically, MMP-9 in coordination with other MMPs, play a role in normal tissue remodelling events such as neurite growth, embryonic development, angiogenesis, ovulation, mammary gland involution and wound healing. Initially synthesised as an inactive proenzyme, pro-MMP-9 is cleaved into an active form upon cellular release by other proteases. (Nagase & Woessner Jr., 1996) This property puts MMP-9 in a unique position to regulate extracellular Aβ levels. For ease of demonstration, we have our cells synthesise the already active version of the enzyme.

Constructing The BioBrick

We created a BioBrick containing the active form of Matrix Metallopeptidase-9 (BBa_K1018000), by ligating CMV promoter with BBa_K1018001 to enable expression in mammalian cells. This biobrick could not be submitted to the registry in time.

In order for MMP-9 to be expressed in mammalian chassis, we ligated CMV to our BBa_K1018001 biobrick. Below shows gel photo indicates our successfully ligated plasmid.

The pSB1C3+CMV promoter+MMP-9 biobrick contains one EcoRI restriction site and one PstI restriction site.

7U - Uncut: As expected, the band appears at <3.7kb, which is the length of the whole pSB1C3+CMV promoter+MMP-9 biobrick, due to supercoiling.

7C - EcoRI single digest: As expected, a band appears at 3.7kb indicating linearised biobrick.

7D - EcoRI and PstI double digest: As expected, a band appears at 2kb and another weak band at 1.7kb.

This gel indicates successful construction of pSB1C3+CMV promoter+MMP-9 biobrick.

Amyloid Degradation Assay

The 42-amino acid peptide (Aβ1-42), the predominant peptide length found in senile plaques, has a remarkable propensity to aggregate at high concentrations to form a β-pleated sheet structure. While plaques and amyloid fibrils have been viewed by some as resistant to proteolytic degradation, it is possible that certain proteases, such as MMP-9 may contribute to endogenous mechanisms leading to plaque clearance. Our assay, inspired by Yan et al., demonstrates our BioBrick's capability to do this.

EXPERIMENTS AND RESULTS

Protocol: Preparation

Dissolve Aβ in dimethyl sulfoxide (Me2SO, Sigma) to a concentration of 5mM. Dilute in MQ water to a final concentration of 25 μm immediately prior to use.

To prepare Aβ fibrils (fAβ), dilute 5 mm Aβ1-42 or Aβ1-40 in Me2SO in 10 mm HCl to 100 μm (for Aβ1-42) or 200 μm (for Aβ1-40), vortex for 30 s, and incubate at 37 °C for 5 days.

Protocol: Amyloid Degradation Assay

a. Activate pro-MMP-9 with 1 mm p-aminophenylmercuric acetate at 37 °C for 24 h prior to use. This step is not necessary with (BBa_K1018000), as it contains the active form.

b. For fAβ digestions, 200 nm protease was added to 10 μl of fAβ in reaction buffer and incubated at 37 °C for 4 h to 5 days.

c. After digestion, analyse the reaction by Congo red assay.

At the time of wiki freeze, the amyloid fibrils necessary for this assay had not yet arrived from SynoBiologicals despite being ordered a month prior. We expect to be able to present the results from our assay after wiki thaw.

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-<div class="main_image"></div>
+<div class="small_image_right" style="background-image:url('https://static.igem.org/mediawiki/2013/6/6e/MMP9-circuit.png');height:430px;width:550px"></div>
-<p class="major_title">MAJOR TITLE</p>
+<p class="major_title">Matrix</p>
-<p class="minor_title">Minor Title</p>
+<p class="major_title">Metalloproteinase-9</p>
+<p class="minor_title">For β-amyloid Degradation</p>
 <p class="body_text">
-Lorem ipsum dolor sit amet, consectetur adipiscing elit. Vivamus vel fringilla diam. Integer placerat sapien sed risus mollis, eget hendrerit lorem tincidunt. Cras a sem eros. Ut nec ligula eget tortor ornare tempus sit amet quis risus. Quisque condimentum, ipsum ac rhoncus ornare, tellus augue imperdiet libero, in venenatis justo arcu quis tellus. Vivamus magna libero, tempus ac augue at, placerat vulputate nunc. Praesent fringilla id erat ut sagittis. Sed nec semper risus, nec condimentum leo. Vestibulum pharetra pellentesque augue, non ultrices leo varius et. Vestibulum id egestas orci. Vestibulum metus ipsum, iaculis nec sapien in, fringilla cursus orci. Class aptent taciti sociosqu ad litora torquent per conubia nostra, per inceptos himenaeos. Curabitur eget vulputate ligula. Sed venenatis nulla et porta pharetra. Suspendisse pharetra suscipit justo sagittis consequat. Morbi eu iaculis diam, ac rhoncus urna. Pellentesque eros ligula, mollis vitae metus sit amet, interdum gravida nunc. Duis tempor quam id rhoncus sodales. Nunc commodo accumsan orci ut faucibus. Quisque vitae luctus libero. Nullam risus libero, convallis et viverra sit amet, convallis a neque. Integer adipiscing ac arcu sit amet luctus. In dignissim mauris non justo tempor, in rhoncus augue volutpat. Duis euismod sodales blandit. Vivamus volutpat molestie dignissim. Quisque cursus quam cursus dui faucibus convallis. Praesent dignissim, sem ut posuere accumsan, libero diam consequat libero, vel tempor dui mi sed massa. Aenean eros arcu, sollicitudin a euismod eu, placerat vel nunc. Nunc consequat blandit fermentum. Curabitur ante erat, lobortis ac faucibus a, sollicitudin egestas nisi. Morbi ut dolor scelerisque, fermentum est vitae, commodo tortor. Vestibulum ornare semper lorem vel volutpat. In erat ligula, auctor eu pellentesque vitae, sollicitudin id sapien. Duis pharetra sagittis purus hendrerit pharetra. Lorem ipsum dolor sit amet, consectetur adipiscing elit. Vivamus elementum iaculis neque nec fringilla. Nunc a scelerisque nulla, et varius massa. In eu pretium eros. Quisque nec lacus elit. Mauris malesuada luctus dapibus. Vivamus eget ultricies sem. Quisque nulla tellus, euismod vel vehicula adipiscing, ornare sit amet dui. Sed eget mauris aliquam, feugiat diam vel, lacinia nunc. Ut vel est facilisis, dictum sem sit amet, lobortis arcu. In hac habitasse platea dictumst. Fusce ut accumsan sapien. Sed pharetra ullamcorper dolor vitae rutrum. Aliquam luctus mattis felis vitae semper. Vivamus id sodales purus. Cras quis quam non tortor tincidunt laoreet varius suscipit lectus. Curabitur faucibus et libero quis vulputate. Nunc sed gravida libero. Phasellus eleifend, metus mattis molestie luctus, augue libero lacinia massa, ac volutpat tortor tortor quis sapien. Donec ultrices felis ut arcu rutrum sollicitudin. Praesent nec ligula at risus hendrerit aliquam. Etiam vestibulum aliquam ultricies. Ut semper libero volutpat, rutrum enim et, eleifend nibh. Nulla ornare, elit sed laoreet condimentum, quam nunc auctor sem, eu commodo elit ante id magna.
+The pathological hallmark of <a href="https://2013.igem.org/Team:UCL/Background/Alzheimers" target="_blank">Alzheimer's disease (AD)</a> is the <a href="https://2013.igem.org/Team:UCL/Background/Neuropathology" target="_blank"> senile plaques </a> primarily composed of tightly aggregated β-amyloid (Aβ) fibrils. Matrix metalloproteinase-9 (MMP-9) can degrade Aβ fibrils and soluble Aβ, an ability that is not shared by other soluble Aβ degrading enzymes, including endothelin-converting enzyme, insulin-degrading enzyme, and neprilysin <a href="http://www.ncbi.nlm.nih.gov/pubmed/16787929" target="_blank">(Yan et al. 2006)</a>, all of which we had been considering for our circuit. Therefore, using MMP-9 satisfies both those theories that hold fibrillar Aβ senile plaques responsible for AD. This also supports some of the newer ideas that amyloid plaque forms protectively to seal away more soluble Aβ. By expressing it in inactive microglia, we can engender plaque removal without neuroinflammation. To characterise MMP-9, we carried out a β-amyloid degradation assay.
 </p>
+<p class="body_text">
+MMP-9 is a Zinc II dependent endopeptidase that in humans is encoded by the MMP9 gene. MMP-9 is readily synthesised and secreted by microglia upon activation. The primary function of MMP-9 is to degrade proteins in the extracellular matrix.  Physiologically, MMP-9 in coordination with other MMPs, play a role in normal tissue remodelling events such as neurite growth, embryonic development, angiogenesis, ovulation, mammary gland involution and wound healing. Initially synthesised as an inactive proenzyme, pro-MMP-9 is cleaved into an active form upon cellular release by other proteases. <a href="http://www.jbc.org/content/274/31/21491.full?ijkey=875a77f6b9239459a92e85c272d0a2e6cd4170f7&keytype2=tf_ipsecsha" target="_blank">(Nagase & Woessner Jr., 1996)</a> This property puts MMP-9 in a unique position to regulate extracellular Aβ levels. For ease of demonstration, we have our cells synthesise the already active version of the enzyme.
+</p>
+<div class="gap">
+</div>
+<div class="small_image_left" style="background-image:url('https://static.igem.org/mediawiki/2013/2/2d/Amyllid_Degradation.png');height:413px;width:550px"></div>
+<div class="gap">
+</div>
+<p class="minor_title">Constructing The BioBrick</p>
+<p class="body_text">
+We created a BioBrick containing the active form of Matrix Metallopeptidase-9 <a href="http://parts.igem.org/Part:BBa_K1018001" target="_blank">(BBa_K1018000)</a>, by ligating CMV promoter with BBa_K1018001 to enable expression in mammalian cells. This biobrick could not be submitted to the registry in time.
+</p>
+<p class="body_text">
+In order for MMP-9 to be expressed in mammalian chassis, we ligated CMV to our BBa_K1018001 biobrick. Below shows gel photo indicates our successfully ligated plasmid.
+</p>
+<div class="small_image_right" style="background-image:url('https://static.igem.org/mediawiki/2013/3/39/Screen_Shot_2013-10-05_at_00.59.33.png');height:265px;width:410px"></div>
+</p>
+<p class="body_text">
+The pSB1C3+CMV promoter+MMP-9 biobrick contains one EcoRI restriction site and one PstI restriction site.
+</p>
+<p class="body_text">
+U - Uncut: As expected, the band appears at <3.7kb, which is the length of the whole pSB1C3+CMV promoter+MMP-9 biobrick, due to supercoiling.
+</p>
+<p class="body_text">
+C - EcoRI single digest: As expected, a band appears at 3.7kb indicating linearised biobrick.
+</p>
+<p class="body_text">
+D - EcoRI and PstI double digest: As expected, a band appears at 2kb and another weak band at 1.7kb.
+</p>
+<p class="body_text">
+This gel indicates successful construction of pSB1C3+CMV promoter+MMP-9 biobrick.
+</p>
+<div class="gap">
+</div>
+<div class="gap">
+</div>
+<p class="minor_title">Amyloid Degradation Assay</p>
+<p class="body_text">
+The 42-amino acid peptide (Aβ1-42), the predominant peptide length found in senile plaques, has a remarkable propensity to aggregate at high concentrations to form a β-pleated sheet structure. While plaques and amyloid fibrils have been viewed by some as resistant to proteolytic degradation, it is possible that certain proteases, such as MMP-9 may contribute to endogenous mechanisms leading to plaque clearance. Our assay, inspired by Yan et al., demonstrates our BioBrick's capability to do this.
+</p>
+</p>
+</div>
 <div class="gap"></div>
+<p class="major_title">EXPERIMENTS AND RESULTS</p>
+<div class="gap"></div>
+<div class="row_small">
+<div class="part">
+<p class="minor_title">Protocol: Preparation</p>
+<p class="body_text">
+Dissolve Aβ in dimethyl sulfoxide (Me2SO, Sigma) to a concentration of 5mM. Dilute in MQ water to a final concentration of 25 μm immediately prior to use.
+</p>
+<p class="body_text">
+To prepare Aβ fibrils (fAβ), dilute 5 mm Aβ1-42 or Aβ1-40 in Me2SO in 10 mm HCl to 100 μm (for Aβ1-42) or 200 μm (for Aβ1-40), vortex for 30 s, and incubate at 37 °C for 5 days.
+</p>
+</div>
+<div class="description">
+<p class="minor_title">Protocol: Amyloid Degradation Assay</p>
+</p>
+<p class="body_text">
+a.  Activate pro-MMP-9 with 1 mm p-aminophenylmercuric acetate at 37 °C for 24 h prior to use. This step is not necessary with <a href="http://parts.igem.org/Part:BBa_K1018001" target="_blank">(BBa_K1018000)</a>, as it contains the active form.
+</p>
+<p class="body_text">
+b. For fAβ digestions, 200 nm protease was added to 10 μl of fAβ in reaction buffer and incubated at 37 °C for 4 h to 5 days.
+</p>
+<p class="body_text">
+c. After digestion, analyse the reaction by Congo red assay.
+</p>
+<p class="body_text">
+At the time of wiki freeze, the amyloid fibrils necessary for this assay had not yet arrived from SynoBiologicals despite being ordered a month prior. We expect to be able to present the results from our assay after wiki thaw.
+</p>
+</div>
+</div>
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