Team:University College London/Module 2/Modelling

From 2012.igem.org

Contents

Module 2: Aggregation

Description | Design | Construction | Characterisation | Shear Device | Modelling | Results | Conclusions

Curli synthesis

Our cell model for aggregation describes the pathways through which curli cluster coding genes interact to make up up curli fibrils which are produced on detection of microplastics. This particular curli cluster (BBa_K540000) contains five genes that later on interact and make up curli fibrils, however, we are looking into synthesis and interaction of only two of them: CsgA and CsgB due to complex nature of the system.

Aim

Using this we aim to find out to which extent is curli fibrils' production is dependent on the persistent organic pollutant presence in the surrounding environment. In addition to that we would like to estimate how much fibrils are produced over time.The following diagram shows the genes, molecules and reaction involved in the synthesis of the curli fibrils, on which further description is provided below.

Aggnet.png

Description of the model

As with our degradation model, this SimBiology model is divided into three compartments, with each DNA species and reaction explained in further detail below:


1. Outside1: in this compartment we see the association, adherence, and dissociation of persistent organic pollutants (POPs) from polyethylene (PE) (R1). We rely on the POPs to induce our curli synthesis system. As it will be described later on, POPs have a tendency to adhere to the plastic 105 to 106 times more than reamin in the ocean. As curli synthesis is induced by the POPs this means that curli synthesis will be the specificity to our system.


2. Cell: NahR is a constitutively produced mRNA product (R9) of which around 3% degrades (R10). When POP diffuses into the cell (R2), it forms a complex with intact NahR (R3) which then binds to the pSal promoter (R4) to induce the curli gene cluster (R5). This starts translation of five proteins which make up curli fibrils. Here we focus on those controlled by the CsgAB operon, CsgA (R7) and CsgB (R6), as these are the most important in curli synthesis as described on our research page. The CsgA and CsgB that do not degrade (R11, R12) diffuse out of the cell.


3. Outside2: Outside of the cell the polymerization of CsgA by CsgB takes place (R8) to make a curli fibril.

Species

Species Initial value (molecules) Notes & Assumptions
PE 0.044 Polyethylene found in North Pacific Gyre (value per cubic metre)1,2
POPex 0.0 Persistent organic pollutants (ex = extracellular) that are not adhered to plastic surface
PEPOPex 9.24E-5 Persistent organic pollutants (ex = extracellular) that are adhered to the plastic surface6
POPin 0.5 Persistent organic pollutants (in = intracellular) assumed from E. coli membrane permeability 4
mRNANahR 0.0 NahR mRNA product
POPinNahR 0.0 Complex of the above two molecules
POPinNahRpSal 0.0 Complex of the above molecule and pSal (promoter that induces laccase transcription)
mRNACurli 0.0 Polycistronic mRNA as it codes for more than one protein, in reality curli cluster contains five or more proteins but as mentioned previously we are concentrating only on the synthesis of CsgA and CsgA therefore we assume that only two genes are present in this polycistronic mRNA.
CsgA 0.0 One of the polypeptides that is coded for in curli cluster, it is a structural component secreted in subunits outside of the cell
CsgB 0.0 One of the polypeptides that is coded for in curli cluster, it is secreted outside of the cell allowing polymerization of CsgA
Fibril 0.0 Result of CsgA and CsgB interaction

Reactions taking place in the model

Number Reaction Reaction rate (molecules/sec) Notes & Assumptions
R1 PE + POPex ↔ PEPOPex Forward: 1000
Backward: 1
Pops have 100000 to 1000000 times greater tendency to adhere to plastic than float free in the ocean6
R2 POPex ↔ POPin Forward: 0.6
Backward: 0.4
Rate based on membrane permeability4 and diffusion gradient
R3 POPin + mRNA.Nahr ↔ POPin.mRNA.Nahr Forward: 1
Backward: 0.0001
Based on the assumption that the chemical structure/size of POPs is similar to salycilate7. Salycilate binds to the NahR mRNA product, which complex then binds to the pSal promoter.
R4 POPinmRNANahr ↔ POPinmRNANahr.Psal Forward: 78200
Backward: 0.191 10
NahR to pSal binding based on the assumption that POP-NahR binding has no effect on NahR-pSal binding
R5 POPexmRNANahr.Psal → mRNAcurli 0.054 Transcription rate of curli cluster in molecules/sec (for cluster size 1500bp11, transcription rate in E.coli 80bp/sec9)
R6 mRNAcurli → CsgB 0.13 Translation rate of CsgB in molecules/sec (for CsgB size 151aa12, translation rate in E.coli 20aa/sec9)
R7 mRNAcurli → CsgA 0.13 Translation rate of CsgA in molecules/sec (for CsgA size 151aa13, translation rate in E.coli 20aa/sec9)
R8 CsgB + CsgA -> fibril 0.003 See calculations below
R9 0 ↔ mRNA.Nahr Forward: 0.088
Backward: 0.6
Transcription rate of NahR in molecules/sec (for NahR size 909 bp8, transcription rate in E.coli 80bp/sec9) under constitutive promoter control
R10 mRNA.Nahr → 0 0.03 Degradation rate of NahR mRNA product14
R11 CsgA → 0 0.03 Degradation rate of CsgA 14 must be taken into account due to suboptimal conditions
R12 CsgB → 0 0.03 Degradation rate of CsgB 14 must be taken into account due to suboptimal conditions


We calculated the reaction rate of R8 (CsgB + CsgA -> fibril) as follows:

The average length of an amino acid is 0.8nm15. The length of CsgA is 82 amino acids16, so a non-folded CsgA protein is 65.6 nm in length. CsgA's tertiary structure is folded into 517 so the length of a CsgA protein in a curli is 13.1 nm. A curli is several micrometers long (~3000nm)18 so there are around 299 CsgA molecules per curli. The production of CsgA is the limiting step in the production of curli fibrils (compared to production of CsgB) so the forward rate for this reaction is 1/299.

Results

The following graph shows that fibrils are produced at a rate of around 1 every three hours.

Agggraph3.jpg

References

1. Goldstein M, Rosenberg M, Cheng L (2012) Increased oceanic microplastic debris enhances oviposition in an endemic pelagic insect. Biology Letters 10.1098

2. Andrady AL (2011) Microplastics in the marine environment. Marine Pollution Bulletin 62: 1596-1605

4. Kay J, Koivusalo M, Ma X, Wohland T, Grinstein S (2012) Phosphatidylserine Dynamics in Cellular Membranes. Molecular Biology of the Cell

5. Nenninger AA, Robinson LS, Hammer ND, Epstein EA, Badtke MP, Hultgren SJ, Chapman MR (2011) CsgE is a curli secretion specificity factor that prevents amyloid fibre aggregation. Mol Microbiol 81: 486-499

6. Mato Y, Isobe T, Takada H, Kanehiro H, Ohtake C, Kaminuma T (2001) Plastic Resin Pellets as a Transport Medium for Toxic Chemicals in the Marine Environment. Environ. Sci. Technol. 35: 318-324

7. https://2011.igem.org/Team:Peking_S/project/wire/harvest

8. http://www.xbase.ac.uk/genome/azoarcus-sp-bh72/NC_008702/azo2419;nahR1/viewer

9. http://kirschner.med.harvard.edu/files/bionumbers/fundamentalBioNumbersHandout.pdf

10. Park H, Lim W, Shin H (2005) In vitro binding of purified NahR regulatory protein with promoter Psal. Biochimica et Biophysica Acta 1775: 247-255

11. Shala AA, Restrepo S, Gonzalez Barrios AF (2011) A network model for biofilm development in Escherichia coli K-12. Theoretical Biology and Medical Modelling 8: 34 doi:10.1186/1742-4682-8-34

12. http://www.ecogene.org//?q=gene/EG12621

13. http://www.ecogene.org/?q=gene/EG11489

14. Kushner S (2002) mRNA Decay in Escherichia coli Comes of Age. J Bacteriol. 184: 4658-4665

15. http://en.wikibooks.org/wiki/Cell_Biology/Introduction/Cell_size

16. http://bacteria.ensembl.org/b_subtilis/Transcript/Summary?g=EBBACG00000004082;r=Chromosome:228066-228314;t=EBBACT00000004090

17. Shu Q, Crick S, Pinkner J, Ford B, Hultgren S, Frieden C (2012) The E. coli CsgB nucleator of curli assembles to β-sheet oligomers that alter the CsgA fibrillization mechanism. Proceedings of the National Academy of Sciences of the United States of America 109: 6502-6507. DOI: 10.1073/pnas.1204161109

18. Pitkanen M, Honkalampi U, von Wright A, Sneck A, Hentze H-P, Sievanen J, Hiltunen J, Hellen EKO (2010) Nanofibrillar cellulose - assessment of cytotoxic and genotoxic properties in vitro. International conference on nanotechnology for the forest products industry