Difference between revisions of "Part:BBa K4380000:Design"
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Vilnius-Lithuania Igem 2022 team used this part as a novel way for peptide immobilization. The team was working to create an easily accessible nanoplastic detection tool, using peptides, whose interaction with nanoplastic particles would lead to an easily interpretable response. The system itself focused on smaller protein molecules, peptides, which are modified to acquire the ability to connect to the surface of synthetic polymers – plastics. The detection system works when peptides and nanoplastic particles combine and form a "sandwich" complex - one nanoplastic particle is surrounded by two peptides, attached to their respective protein. The sandwich complex consisted of two main parts – one is peptide bound to a fluorescent protein, other peptide immobilized on cellulose membrane by cellulose binding domain. | Vilnius-Lithuania Igem 2022 team used this part as a novel way for peptide immobilization. The team was working to create an easily accessible nanoplastic detection tool, using peptides, whose interaction with nanoplastic particles would lead to an easily interpretable response. The system itself focused on smaller protein molecules, peptides, which are modified to acquire the ability to connect to the surface of synthetic polymers – plastics. The detection system works when peptides and nanoplastic particles combine and form a "sandwich" complex - one nanoplastic particle is surrounded by two peptides, attached to their respective protein. The sandwich complex consisted of two main parts – one is peptide bound to a fluorescent protein, other peptide immobilized on cellulose membrane by cellulose binding domain. | ||
− | + | Design of proteins attached to cellulose binding domain is relatively easy. One of the things that is important when designing a part with this domain is a linker sequence between the domain and corresponding protein or other biomolecule. | |
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===References=== | ===References=== |
Revision as of 20:52, 1 October 2022
Cellulose Binding domain (CBD)
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Design
Design Vilnius-Lithuania Igem 2022 team used this part as a novel way for peptide immobilization. The team was working to create an easily accessible nanoplastic detection tool, using peptides, whose interaction with nanoplastic particles would lead to an easily interpretable response. The system itself focused on smaller protein molecules, peptides, which are modified to acquire the ability to connect to the surface of synthetic polymers – plastics. The detection system works when peptides and nanoplastic particles combine and form a "sandwich" complex - one nanoplastic particle is surrounded by two peptides, attached to their respective protein. The sandwich complex consisted of two main parts – one is peptide bound to a fluorescent protein, other peptide immobilized on cellulose membrane by cellulose binding domain.
Design of proteins attached to cellulose binding domain is relatively easy. One of the things that is important when designing a part with this domain is a linker sequence between the domain and corresponding protein or other biomolecule.