Team:Imperial College London/Genetic Circuit
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Here we go through the genetic circuit of <b><i>The E.ncapsulator</i></b> system. The design of the circuit has been kept very modular to facilitate reusability.<br> | Here we go through the genetic circuit of <b><i>The E.ncapsulator</i></b> system. The design of the circuit has been kept very modular to facilitate reusability.<br> | ||
- | We will go through the genetic design of the system, module by module. If you are unfamiliar with genetic circuit diagrams, check out our key to familiarise yourself with each symbol and what it means. Otherwise scroll down to view our modular genetic circuits.<br><br> | + | We will go through the genetic design of the system, module by module. If you are unfamiliar with genetic circuit diagrams, check out our key to familiarise yourself with each symbol and what it means. Otherwise scroll down to view our [[Team:Imperial_College_London/Genetic_Circuit#Modular_Genetic_Circuits|modular genetic circuits]].<br><br> |
===Key to Genetic Circuit Diagrams=== | ===Key to Genetic Circuit Diagrams=== |
Revision as of 13:43, 14 October 2009
Genetic Circuits
Here we go through the genetic circuit of The E.ncapsulator system. The design of the circuit has been kept very modular to facilitate reusability.
We will go through the genetic design of the system, module by module. If you are unfamiliar with genetic circuit diagrams, check out our key to familiarise yourself with each symbol and what it means. Otherwise scroll down to view our modular genetic circuits.
Key to Genetic Circuit Diagrams
This key explains some of the symbols used for the genetic circuit diagrams.
A promoter is a genetic element in DNA that regulates the transcription of a downstream gene. Promoters can be induced or repressed by external factors and the expression of the downstream gene is consequently under control of the same external factors. We use promoters as the control mechanisms under which the expression of our genes are controlled.
An RBS is a ribosome binding site. This is a region of DNA required so that the ribosome must bind in order to initiate protein translation. An RBS is required adjacent to each coding sequence to have expression.
A Protein Coding Sequence is commonly referred to as a gene. This is a section of DNA of which the nucleotide sequence is translated by ribosomes into the amino acid sequence of proteins.
Terminators are required at the end of each operon (genes under control of one promoter) in order to signal to the RNA polymerase that the operon has finished, and to release from the DNA strand during DNA transcription.
Modular Genetic Circuits