Difference between revisions of "Team:Ruperto Carola/Description"

 
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<h1 class="title" style= "line-height: 3rem !important">Project Inspiration and Description</h1>
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<h1 class="title" >Project Inspiration and Description</h1>
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<p>We aimed to harness the naturally occuring yeast mating pathway to detect custom peptides by evolving the yeast alpha-mating GPCR (Ste2) to detect alternate ligands. For this we were inspired by an already established approach for the directed evolution of Ste2 by gradually diversifying the ligand by incrementally changing the alpha mating factor and performing repetitive rounds of mutagenesis (diversification) and subsequent selection.</p><p>
 +
  The reported approach used in-vitro error-prone PCR, we improved on this by postulating an in-vivo approach using a yeast strain with a hyper-faulty engineered DNA polymerase with a staggering error rate 100000 times higher than the endogenous DNA polymerase. The strain also harbours a linear cytoplasmic plasmid with the specific ORI for the orthogonal error-prone polymerase. The error-prone polymerase was validated to exclusively replicate the orthogonal cytoplasmic plasmid sparing the endogenous chromosomes. Integrating target genes into the orthogonal P1 plasmid renders them a susceptible to elevated mutation rate and accelerated evolution. </p><p>
 +
  Integrating the mating receptor into the orthogonal plasmid gives rise to an in-vivo workhorse to drive the evolution of Ste2 and screen for variants that bind the desired ligands, while also maintaining the intracellular mating-inducing downstream interactions. </p>
  
<p>Peptide-detection has been a major topic in the biotechnological community for several decades. The continuous developments in this field continue to improve early diagnosis in a wide range of diseases, setting new trends like personalized medicine or lab-on-a-chip methods which allow for detection of peptides in a wide size range, as well as ensuring high specificity and sensitivity.</p>
+
 
<p>These tools are largely available for peptides bigger than 15 kDa <i>[1]</i> ,  but there are still challenges present in the detection of smaller peptides. Because of this, improvements in small-peptide assays would allow the early detection of harmful pathogens, even before the immune response is initiated by the body. Our first thoughts turned towards neglected viral diseases like African swine fever (ASF) affecting pigs. Because of its long latency period where the virus is hardly detectable but easily transmitted. In the recent years ASF transformed to a major problem in the pork industry, with multiple outbreaks detected in eastern Europe, forcing several countries to straighten border controls and even stop pork import. (hier INFOS nachgucken)</p>
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<p>The prospect of simplifying the ASF detetction procedure, thus mitigating the risk for farmers, wild bore populations, inspired us to address this issue by developing a yeast based biosensor capable of detecting peptides around 1.5 kDa. Extensive research on further possible application made us realize the potential of such a system for detection of various biomarkers for not only viruses but also different metabolic disorders, cancer markers, environmental pollutants as well as for less explored topics like bio-contaminant monitoring and mirror biology structure detection.</p>
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<p>Using the yeast Ste2 mating receptor as a backbone we are aiming to develop a directed evolution-based platform for customizing the receptor for detection of a wide range of targets. Furthermore, we are going to explore cell-cell communication for selectivity and sensitivity enhancement in a life-cell bio detector system as well as the possible modification of our project for in-vitro work. In line with iGEM’s focus on solving problems relevant to the wider community we also strive to provide the world with <b>bioinformatical tools for</b> </p>
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<li><b>Target selection</b> – software that helps you to choose the appropriate peptide target that would be accessible for the receptor</li>
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<li><b>Modelling of the receptor ligand</b>-interactions and definition of target receptor structure
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Planning of optimal intermediate steps for your substrate walking based directed evolution</li>
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<li><b>Adapting </b> the established wet-lab protocols for your needs</li>
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<img style="width: 33%; float:left;" class="mr-3" src="https://2019.igem.org/File:T--Ruperto_Carola--img-bindingpocketposter.png" alt="">
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 +
<p>
 +
  In addition to the in-vivo approach we also devised an improved in-vitro mutagenesis pipeline by harnessing the remarkable recombination capacity of yeast to perform DNA shuffling of gene-blocks with diversified ligand-interacting segments.
 +
  For any directed evolution approach to yield receptors with desired ligand specificity within humanly acceptable time-frames the following three variables have to be optimized;</p><p>  
 +
  1) The types and steepness of selective pressures.
 +
  2) The increments of changing the ligand (size of evolutionary steps)
 +
  3) The intracellular ques used to couple desired ligand-receptor affinity to an evolutionary advantage (reward signal).
 +
  To tackle these issues we used a complementary combination of experimental and in-silico approach to determine the optimal levels and type of each variable. </p><p>
 +
  The simple setting of mutagenizing the Ura3 gene was used to validate the orthorep system and characterize the dynamics of mutagenesis/evolution. Ura3 gene allows biphasic selection by alternating between drop-out medium and Ura3 conveyed toxicity using 5-FOA treatment. </p><p>
 +
  To render the orthorep strain suitable for Ste2 directed-evolution and ligand affinity selection we deleted the genomic Ste2 gene and integrated the Ste2 into the P1 orthogonal plasmid. </p><p>
 +
  We also developed an array of reporter constructs to enable the selection for successful evolutionary variants that bind the desired ligands. These include fluorescent proteins under two different mating promoters in addition to receptor fusions with other proteins that can serve as indicators of mating (e.g fluorescent proteins with NLS) or to modulate the outcome of successful binding (transcriptional modulators with NLS). In both cases the binding of the receptor to a suitable ligand renders linker of the fusion protein susceptible to protease cutting and sets the fused protein free to translocate from the memrane to the nucleus. </p><p>
 +
  A rational design approach was also implemented, in which chimeras of the intercellular parts of the yeast GPCR with the ligand binding domains of particular receptors were created.</p>
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<p>
 +
  We also conceived a full in-silico toolbox to support experimental runs of directed evolution. </p><p>
 +
 +
  In order to guide the evolution of the STE2 receptor, we lay out the mathematics for finding the shortest evolutionary path between the native and a target variant, allowing in the best case scenario binding to a custom ligand.</p><p>
 +
 +
  To ensure that the requirements of viable evolution are being met along this journey, the fitness landscape must be simulated. We suggested the use of machine learning to solve this problem by leveraging a recently developed neural network - MaSiF <x-ref>test<x-ref> . </p><p>
 +
  To lay the groundwork for this machine learning approach, we used well-established protein folding algorithms to create a database of modified mating receptors, as well as an array of potential “theoretical” ligands. By using topological and chemical information, MaSiF should gives a measurement the affinity of evolved receptor to diverse ligands. </p><p>
 +
 +
  To complement this general model of directed evolution. Once the optimal evolutionary path has been found, we are able to use game theory to provide insights into the optimal duration and steepness of the selection steps necessary  to arrive at the desired outcome. As an example of this, we developed a model for the evolutionary landscape of the Ura3 gene under various concentration of 5-FOA.</p><p>
 +
  The aforementioned tools are the base for a comprehensive toolbox to implement directed-evolution of yeast mating receptors. This contributes towards our goal of recognizing and bind alternate peptide ligands, hence supporting and complementing our experimental approach and biological parts.
 +
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<h1 class="title" style= "line-height: 3rem !important">Project Inspiration and Description</h1>
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            <h4 style="color: white;">More coming soon <a href="#top" style="font-weight: bolder important!; text-decoration: none; color: white;"> &#8634; </a></h4>
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<p> Our brainstorming for a suitable project with maximal relevance and impact for society was majorly by the news of the rapid worldwide spread of african swine fever virus. At that point the virus had just spread across Poland, with cases reported in Belgium and it seemed a matter of time till cases would be registered in Germany. Indeed the risk level of the economically devastating virus has been assigned to the level “high”.</p><p>
 +
We envisaged that a point of care POC test for ASFV would be useful in the early detection of the virus and therefore help intercepting its path before it becomes endemic.
 +
Inspired by the success of directed evolution approaches for evolving enzymes, and fresh reports of successful directed evolution of the yeast mating GPCR (alpha mating factor), we aimed at evolving the Ste2 to detect ASF-specific peptides<x-ref><x-ref>.
 +
This was also encouraged by the robustness of yeast cells and the low cost of yeast cultivation and genetic manipulation, all rendering yeast as a good candidate for a live-cell biosensor of ASFV. </p>
 +
<p class="mb-1">As we reached out to assess the relevance of such a potential POC diagnosis of ASFV to the stakeholders in farms and the meet industry we were rather disappointed that their business model did not accommodate such on-site testing for animal specific pathogens. Moreover, kulling in general seemed to be the widely accepted practice to deal with animal epidemics such as ASF.
 +
Faced by these realizations and reports on the first efficacious vaccine against ASFV, we reevaluated out project concept and plan. Consequently, we ended up realizing the wide potential of directed evolution of yeast mating receptors to create an adaptable platform for live-cell detection of any peptide ligand of comparable size to the yeast alpha mating factor (14 amino acids). For this all we needed, conceptually, was to determine the variables required for a successful and predictable directed evolution including the optimal levels and steepness of selection pressure, transitionary steps in the step-walking, and intra cellular mating responsive elements to be used in coupling receptor binding to a survival and evolutionary advantage.</p>
 +
We therefore set on an in-vivo and in-silico quest to characterize these variables and built the ideal yeast life-cell peptide detection platform based on the directed evolution of the alpha mating factor. 
 +
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 +
<div class="row">
 +
<div class="col-12">
 +
<div class="highlight decoration_B_full">
 +
<ul>
 +
<li><b>Target selection</b> —i.e. software which helps one choose the appropriate peptide target accessible to the receptor</li>
 +
<li><b>Modelling</b> of the receptor-ligand interactions in order to enable planning of optimal intermediate steps (substrate walking)</li>
 +
<li><b>Adapting</b> our wet-lab protocols and procedures to be useful for future yeast directed evolution projects.</li>
 
</ul>
 
</ul>
 
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<p style="font-weight: lighter;"> [1]: Detection of a Peptide Biomarker by Engineered Yeast Receptors;
 +
Adeniran A. e, Sarah Stainbrook, John W. Bostick, and Keith E. J. Tyo;
 +
ACS Synthetic Biology 2018 7 (2), 696-705
 +
DOI: 10.1021/acssynbio.7b00410
 +
</p>
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Latest revision as of 17:30, 11 December 2019

We aimed to harness the naturally occuring yeast mating pathway to detect custom peptides by evolving the yeast alpha-mating GPCR (Ste2) to detect alternate ligands. For this we were inspired by an already established approach for the directed evolution of Ste2 by gradually diversifying the ligand by incrementally changing the alpha mating factor and performing repetitive rounds of mutagenesis (diversification) and subsequent selection.

The reported approach used in-vitro error-prone PCR, we improved on this by postulating an in-vivo approach using a yeast strain with a hyper-faulty engineered DNA polymerase with a staggering error rate 100000 times higher than the endogenous DNA polymerase. The strain also harbours a linear cytoplasmic plasmid with the specific ORI for the orthogonal error-prone polymerase. The error-prone polymerase was validated to exclusively replicate the orthogonal cytoplasmic plasmid sparing the endogenous chromosomes. Integrating target genes into the orthogonal P1 plasmid renders them a susceptible to elevated mutation rate and accelerated evolution.

Integrating the mating receptor into the orthogonal plasmid gives rise to an in-vivo workhorse to drive the evolution of Ste2 and screen for variants that bind the desired ligands, while also maintaining the intracellular mating-inducing downstream interactions.

In addition to the in-vivo approach we also devised an improved in-vitro mutagenesis pipeline by harnessing the remarkable recombination capacity of yeast to perform DNA shuffling of gene-blocks with diversified ligand-interacting segments. For any directed evolution approach to yield receptors with desired ligand specificity within humanly acceptable time-frames the following three variables have to be optimized;

1) The types and steepness of selective pressures. 2) The increments of changing the ligand (size of evolutionary steps) 3) The intracellular ques used to couple desired ligand-receptor affinity to an evolutionary advantage (reward signal). To tackle these issues we used a complementary combination of experimental and in-silico approach to determine the optimal levels and type of each variable.

The simple setting of mutagenizing the Ura3 gene was used to validate the orthorep system and characterize the dynamics of mutagenesis/evolution. Ura3 gene allows biphasic selection by alternating between drop-out medium and Ura3 conveyed toxicity using 5-FOA treatment.

To render the orthorep strain suitable for Ste2 directed-evolution and ligand affinity selection we deleted the genomic Ste2 gene and integrated the Ste2 into the P1 orthogonal plasmid.

We also developed an array of reporter constructs to enable the selection for successful evolutionary variants that bind the desired ligands. These include fluorescent proteins under two different mating promoters in addition to receptor fusions with other proteins that can serve as indicators of mating (e.g fluorescent proteins with NLS) or to modulate the outcome of successful binding (transcriptional modulators with NLS). In both cases the binding of the receptor to a suitable ligand renders linker of the fusion protein susceptible to protease cutting and sets the fused protein free to translocate from the memrane to the nucleus.

A rational design approach was also implemented, in which chimeras of the intercellular parts of the yeast GPCR with the ligand binding domains of particular receptors were created.

We also conceived a full in-silico toolbox to support experimental runs of directed evolution.

In order to guide the evolution of the STE2 receptor, we lay out the mathematics for finding the shortest evolutionary path between the native and a target variant, allowing in the best case scenario binding to a custom ligand.

To ensure that the requirements of viable evolution are being met along this journey, the fitness landscape must be simulated. We suggested the use of machine learning to solve this problem by leveraging a recently developed neural network - MaSiF test .

To lay the groundwork for this machine learning approach, we used well-established protein folding algorithms to create a database of modified mating receptors, as well as an array of potential “theoretical” ligands. By using topological and chemical information, MaSiF should gives a measurement the affinity of evolved receptor to diverse ligands.

To complement this general model of directed evolution. Once the optimal evolutionary path has been found, we are able to use game theory to provide insights into the optimal duration and steepness of the selection steps necessary to arrive at the desired outcome. As an example of this, we developed a model for the evolutionary landscape of the Ura3 gene under various concentration of 5-FOA.

The aforementioned tools are the base for a comprehensive toolbox to implement directed-evolution of yeast mating receptors. This contributes towards our goal of recognizing and bind alternate peptide ligands, hence supporting and complementing our experimental approach and biological parts.

Project Inspiration and Description

Our brainstorming for a suitable project with maximal relevance and impact for society was majorly by the news of the rapid worldwide spread of african swine fever virus. At that point the virus had just spread across Poland, with cases reported in Belgium and it seemed a matter of time till cases would be registered in Germany. Indeed the risk level of the economically devastating virus has been assigned to the level “high”.

We envisaged that a point of care POC test for ASFV would be useful in the early detection of the virus and therefore help intercepting its path before it becomes endemic. Inspired by the success of directed evolution approaches for evolving enzymes, and fresh reports of successful directed evolution of the yeast mating GPCR (alpha mating factor), we aimed at evolving the Ste2 to detect ASF-specific peptides. This was also encouraged by the robustness of yeast cells and the low cost of yeast cultivation and genetic manipulation, all rendering yeast as a good candidate for a live-cell biosensor of ASFV.

As we reached out to assess the relevance of such a potential POC diagnosis of ASFV to the stakeholders in farms and the meet industry we were rather disappointed that their business model did not accommodate such on-site testing for animal specific pathogens. Moreover, kulling in general seemed to be the widely accepted practice to deal with animal epidemics such as ASF. Faced by these realizations and reports on the first efficacious vaccine against ASFV, we reevaluated out project concept and plan. Consequently, we ended up realizing the wide potential of directed evolution of yeast mating receptors to create an adaptable platform for live-cell detection of any peptide ligand of comparable size to the yeast alpha mating factor (14 amino acids). For this all we needed, conceptually, was to determine the variables required for a successful and predictable directed evolution including the optimal levels and steepness of selection pressure, transitionary steps in the step-walking, and intra cellular mating responsive elements to be used in coupling receptor binding to a survival and evolutionary advantage.

We therefore set on an in-vivo and in-silico quest to characterize these variables and built the ideal yeast life-cell peptide detection platform based on the directed evolution of the alpha mating factor.

  • Target selection —i.e. software which helps one choose the appropriate peptide target accessible to the receptor
  • Modelling of the receptor-ligand interactions in order to enable planning of optimal intermediate steps (substrate walking)
  • Adapting our wet-lab protocols and procedures to be useful for future yeast directed evolution projects.

[1]: Detection of a Peptide Biomarker by Engineered Yeast Receptors; Adeniran A. e, Sarah Stainbrook, John W. Bostick, and Keith E. J. Tyo; ACS Synthetic Biology 2018 7 (2), 696-705 DOI: 10.1021/acssynbio.7b00410