This part is composed of 3 subparts :
Lysine descarboxylase DesA from Streptomyces coelicolor is an enzyme from the lyase family that converts lysine into cadaverin. The enzyme releases the carbonyl group of the lysin amino acid. Cadaverine (1,5-diaminopentane) is a primary diamine which alkaline environment. Acidic pH and an anaerobic environment both induce the synthesis of Lysine decarboxylase. In bacteriology, this enzyme is sought through the middle of Moeller lysine or medium lysine Taylor.
We registered the original sequence of this subpart in the iGEM registry of standard parts ([http://parts.igem.org/Part:BBa_K1951000 BBa_K1951000]). We optimized our sequence for E. coli and ordered the synthesis by addition of an inducible promoter.
As you can see in [http://parts.igem.org/Part:BBa_K1951004 the registry] all our expectations on this BioBrick were validated and it worked fine.
The purpose of this biobrick is to produce desferrioxamine B siderophore by a controled manner, for controlled potential toxicity.
This biobrick was made from 6 parts:
Available in the registry :
Designed by our team :
Siderophores are small, high-affinity iron chelating compounds secreted by microorganisms such as bacteria, fungi and grasses. Siderophores are amongst the strongest soluble Fe3+ binding agents known.
Previous work showed that siderophores are able to catch other metals by default. Especifically, many articles showed a high affinity of Desferrioxamine B ( produce by Streptomyces coelicolor) for tetravalent metal ions like platinum. These results encouraged us to make a biobrick coding the sequence corresponding to the 4 enzymes involved on the metabolic pathway of Desferrioxamine B. E. coli was used to produce this biobrick. Produce a gram positive bacteria pathway in a gram negative bacteria is restrictive [1] , considering the risk of toxicity for the conductress bacteria. To counter this potential issue, we regulate trasnscription using the control of an inductible promotor (pBAD/araC).
Desferrioxamine B is a really well referenced siderophore.
Deferoxamine acts by binding free iron in the bloodstream and enhancing its elimination in the urine. By removing excess iron, the agent reduces the damage done to various organs and tissues, such as the liver. Also, it speeds healing of nerve damage (and minimizes the extent of recent nerve trauma).
We also improved an existing BioBrick, Glasgow 2014 team's BioBrick ([http://parts.igem.org/Part:BBa_K1463604 BBa K1463604]), making our brick ([http://parts.igem.org/Part:BBa_K1951008 BBa K1951008]). This BioBrick is an improvement of the orignial BioBrick in three ways:
All the functional tests and experiments, show this part is functional, are listed here.
This part is a composite part composed of 2 Biobricks :
Flagellin C (FliC) protein from Escherichia coli strain is the main protein constitutive of the flagelar filament and is involved to promote bacterial swimming. This sequence is conserved in many bacterial strains. It has been demonstrated that flagellin has the ability to adsorb precious metal such as platinum or gold. We made a FliC mutant by transduction using phage P1 in a E. Coli W3110 strain. Then we have complemented the fliC mutant W3110 with [http://parts.igem.org/Part:BBa_K1951008 BBa_K1951008] and performed a swimming test for every background. The result has shown that swimming was recovered into the complemented fliC mutant W3110
The subparts were assembled using standard BioBrick Assembly.
This biobrick has been improved from a previous one designed by Glasgow 2014 team. Please find the link of this biobrick below :
http://parts.igem.org/Part:BBa_K1463601
Instead of [http://parts.igem.org/Part:BBa_J23106 BBa_J23106] and [http://parts.igem.org/Part:BBa_J23116 BBa_J23116], we used strong promoter, strong RBS combination for high expression levels of the flagellin. By the combination of [http://parts.igem.org/Part:BBa_Bba_K880005 BBa_Bba_K880005] and [http://parts.igem.org/Part:BBa_K1951005 BBa_K1951005], we made a high flagellin expression vector able to recover swimming.
Flagellin C (FliC) protein from Desulfovibrio vulgaris strain is the main protein constitutive of the flagellum filament and is involved to promote bacterial swimming. This sequence is conserved in many bacterial strains as the capacity of swimming given by the flagellum confers a great selective advantage.
It has been demonstrated that Flagellin has the ability to adsorb precious metal on its surface such as platinum, palladium gold [3][4] and this was important for our project Highway to platinum
The propensity of the immune response to flagellin may be explained by two facts:
CsgA is the major structural subunit of the curli fimbriae. Curli are coiled surface structures that assemble preferentially at growth temperatures below 37 degrees Celsius. Curli are the major proteinaceous component of a complex extracellular matrix produced by many Enterobacteriaceae. Curli were first discovered in the late 1980s on Escherichia coli strains that caused bovine mastitis, and have since been implicated in many physiological and pathogenic processes of E. coli and Salmonella spp. Curli fibers are involved in adhesion to surfaces, cell aggregation, and biofilm formation. Curli also mediate host cell adhesion and invasion, and they are potent inducers of the host inflammatory response. The biobrick contains a strong promotor.