Team:Potsdam Bioware/Project/Details

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Details

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Microviridin

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Phage Display



Cloning

The phage display vector pPDV089 was derived from the plasmid pARW089 which carries the whole mdn-cluster. This plasmid contains a plasmid origin of replication and additionally a f1 ori which enables the packaging of single strand DNA into phages. For selective amplification ampcillin and kanamycin resistance genes are included. To create the phagemid pPDV089 standard cloning procedure were performed. First mdnA was deleted by excising using the restriction enzymes SfoI and AatII. The next step comprised the introduction of a mdnA-gene III-fusion gene. Therefore gene III was amplified from pak100blaKDIR and mdnA from pARW089 by PCR. The primers were designed to enable the introduction of iGEM and other restriction sites required for further cloning steps. The purified PCR product gene III was digested by NgoMIV and AatII whereas the PCR product mdnA was digested by SfoI and AgeI. Subsequent the three fragment ligation of mdnA and gene III into the digested vector has been conducted. Thus a mdnA-gene III-fusion part according to RFC25 was generated whereby AgeI and NgoMIV overhangs are compatible and placed in frame with the protein sequence. The ligation of AgeI and NgoMIV overhangs resulted in a scar coding for the threonine and glycine. Because the introduction of restriction sites before mdnA leaded to a great distance between ribosome binding site and mdnA a second RBS was inserted among SfoI and XbaI recognition sites to ensure a sufficiently expression rate of the mdnA-gene III-fusion gene. The myc sequence located between mdnA and gene III allows the detection of the expression of the mdnA-gene III-fusion protein on the surface of the phage using western blot or ELISA. In the last step the kanamycin resistance gene was disturbed because for phage display the selection of cells carriyng both helper phages and the phagemid is beneficial and the helper phages have a kanamycin resistance too. Therefore a 300 bp fragment of the kanamycin resistance gene was deleted using the restriction enzyme NsiI which had two recognition sites in the kanamycin gene.


UP cloning strategy.png UP pPDV089.png
cloning strategy of the BioBrick phagemid pPDV089 |



ELISA

The next step was the detection of the expression of the mdnA-myc-geneIII-fusion gene on the surface of the phage. So E. coli cells XL1-Blue were first transformed with the phagemid pPDV089 before they were infected with helper phages. E. coli cells containing both plasmids were selected. An ELISA test was performed to determine whether these cells are able to produce phage particles carrying the mdnA peptide on their surface. To perform this test anti-myc-antibodies were immobilized on ELISA plates and incubated with purified phages. For detection a second antibody coupled with horse radish peroxidase (HRP) was used which binds the gene VIII protein of the phages. The HRP substrate 3,3'-5,5'-Tetramethylbenzidine (TMB) was added and in case of binding a colour reaction was expected. The colour shift from achromatic to yellow showed the successful expression of mdnA-gene III-fusion protein on the phages.

UP Excel ELISA.png

In Vivo Selection

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Modelling

There is no synthetic biology without modeling, of course. In principle there is structure modeling and system modeling. In structure-modeling the conformation and structure of proteins is examined and steric consequences for reactions or the whole system can be estimated. We focused on the second sort of modeling: The systems modeling in which the reaction kinetics of the whole system is analysed and outcomes are predicted. Thus a synthetic biology approach can be chosen because a better understanding of the system is achieved and further changes can be planed - just like in engineering.
The following schema shows the major reactions taking place in our cell system. The Romanic numbers indicate the place of reactions that were written down as equations and then numerically propagated through time. We were able to see that our system works very well in theory. We learned about correct time-scales for our triggering and we were able to identify expected cell-division rates as reference for lab work.

Figure xx: Simplified schema of our cell system including labels and markers for the chemical reactions in it. Marked reactions are considered in our system modeling.

The schema shows the triggered expression of mircoviridin (our inhibitor), the protease (that needs to be inhibited for medical reasons) and the lactamase (that is destroyed by the protease and works as an indicator for our system because it is a protection against ampicillin).
There are three important trigger activation times:
. (t0) - beginn (microviridin added already)
. t1 - start expression of protease
. t2 - start expression of lactamase
. t3 - ampicillin added into medium
. (t4) - end of the experiment: cellcultures survive or die.
Keeping these times in mind, the reactions can be written down in seven chemical reaction equations of different sort and order.

Figure xxx: Reaction equations between relevant molekules in the microviridin-inhibitor-concept including indications about the triggered time period (t1,t2,t3).


From the above reaction equations differentialequations can be derived that describe the change of substance concentrations. Three concentrations are fixed, however:

Figure xxx: Given substance concentrations for differentialequations. Those concentrations are added to the system and will not increase over time.