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<p class="makeresponsive" style="width: 50%;">Synthetic biology wants to go beyond the pure biological by integrating concepts from chemistry or physics into the living world. At this interphase, our project wants to introduce Peptidosomes as a new fundamental approach for generating and applying encapsulated bacteria.
alt="An example picture to show how to include them.">
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<figcaption><b>Figure 1: Example.</b> This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture End of the figures caption is here.</figcaption>
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Synthetic biology wants to go beyond the pure biological by integrating concepts from chemistry or physics into the living world. At this interphase, our project wants to introduce Peptidosomes as a new fundamental approach for generating and applying encapsulated bacteria.
These spheres possess advantageous properties like stability in different media and a mesh-like structure that allows for the selective exchange of compounds via diffusion. Therefore, we are able to benefit from the entrapped cells' abilities, while ensuring that they are not released into their surroundings.
These spheres possess advantageous properties like stability in different media and a mesh-like structure that allows for the selective exchange of compounds via diffusion. Therefore, we are able to benefit from the entrapped cells' abilities, while ensuring that they are not released into their surroundings.
Using the powerful genetics of <i>Bacillus subtilis</i> and its secretory capabilities we demonstrate communication and cooperation between separately encapsulated bacterial populations as well as the environment. Peptidosomes can be further enhanced by incorporating magnetic or biological beads - which can be functionalized with proteins - into their peptide-based shell.
Using the powerful genetics of <i>Bacillus subtilis</i> and its secretory capabilities we demonstrate communication and cooperation between separately encapsulated bacterial populations as well as the environment. Peptidosomes can be further enhanced by incorporating magnetic or biological beads - which can be functionalized with proteins - into their peptide-based shell.
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With this unique setup, we provide a whole new universe of applications to the iGEM community.</p>
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With this unique setup, we provide a whole new universe of applications to the iGEM community.
alt="An example picture to show how to include them.">
alt="An example picture to show how to include them.">
<figcaption><b>Figure 1: Example.</b> This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture End of the figures caption is here.</figcaption>
<figcaption><b>Figure 1: Example.</b> This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture This is an example picture End of the figures caption is here.</figcaption>
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</figure>
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Synthetic biology wants to go beyond the pure biological by integrating concepts from chemistry or physics into the living world. At this interphase, our project wants to introduce Peptidosomes as a new fundamental approach for generating and applying encapsulated bacteria.
+
These spheres possess advantageous properties like stability in different media and a mesh-like structure that allows for the selective exchange of compounds via diffusion. Therefore, we are able to benefit from the entrapped cells' abilities, while ensuring that they are not released into their surroundings.
+
Using the powerful genetics of <i>Bacillus subtilis</i> and its secretory capabilities we demonstrate communication and cooperation between separately encapsulated bacterial populations as well as the environment. Peptidosomes can be further enhanced by incorporating magnetic or biological beads - which can be functionalized with proteins - into their peptide-based shell.
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With this unique setup, we provide a whole new universe of applications to the iGEM community.
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</figure>
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Revision as of 14:00, 24 October 2017
Entering A Whole New Universe Of Applications!
Section title
Subsection title
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This is example text. I copied the abstract here to fill some space: Synthetic biology wants to go beyond the pure biological by integrating concepts from chemistry or physics into the living world. At this interphase, our project wants to introduce Peptidosomes as a new fundamental approach for generating and applying encapsulated bacteria.
These spheres possess advantageous properties like stability in different media and a mesh-like structure that allows for the selective exchange of compounds via diffusion. Therefore, we are able to benefit from the entrapped cells' abilities, while ensuring that they are not released into their surroundings.
Using the powerful genetics of Bacillus subtilis and its secretory capabilities we demonstrate communication and cooperation between separately encapsulated bacterial populations as well as the environment. Peptidosomes can be further enhanced by incorporating magnetic or biological beads - which can be functionalized with proteins - into their peptide-based shell.
With this unique setup, we provide a whole new universe of applications to the iGEM community.
Synthetic biology wants to go beyond the pure biological by integrating concepts from chemistry or physics into the living world. At this interphase, our project wants to introduce Peptidosomes as a new fundamental approach for generating and applying encapsulated bacteria.
These spheres possess advantageous properties like stability in different media and a mesh-like structure that allows for the selective exchange of compounds via diffusion. Therefore, we are able to benefit from the entrapped cells' abilities, while ensuring that they are not released into their surroundings.
Using the powerful genetics of Bacillus subtilis and its secretory capabilities we demonstrate communication and cooperation between separately encapsulated bacterial populations as well as the environment. Peptidosomes can be further enhanced by incorporating magnetic or biological beads - which can be functionalized with proteins - into their peptide-based shell.
With this unique setup, we provide a whole new universe of applications to the iGEM community.