1. No category

iGEM Team
TU Darmstadt 2014
Linear Response
Theory (LRT)
TAL
Introduction of a new ANS
(eANS) with a shorter
C-terminus leads to enhanced
pelargonidin production
F3´H
CHI
TAL
4CL
ANS
Residue position
Problem region
C4H
F3H
Residue position
All models show a
destabilized C-terminus
Membrane
DFR
CHS
Residue position
Plants
Heterologous systems
CHI
ΔRMSD
The anthocyanidin pathway in plants is able to form a multi-enzyme
complex. This complex increases the reaction efficiency of
anthocyanidin synthase (ANS) [1]. In heterologous systems (e.g. E. coli)
this complex is not formed and side reaction products are produced
[2]. We identified and re-engineered the potential interaction site of
the ANS and increased the yield of pelargonidin.
Rigid core
RMSF
LRT Model of ANS
Gaussian Network Molecular Dynamics
Model (GNM)
Simulation (MD)
Slow modes
Engineering and modeling of the anthocyanidin synthase
E. grätzel
F3H
DFR
CHS
ANS
4CL
Protein
engineering
Policy & Practices
With engineered ANS
more pelargonidin
Naringenin Biosensor
Naringenin
Government /
NGOs
Purchasing
machines
Developing
concepts
Training
Villagers
Selling
DSCs
Cooperation
Lending money
Providing
capital
No access to
electricity
Modified E. coli produce
anthocyanins
DSC producer
Grätzel cell
construction
Grätzel cells are an
alternative for conventional Sensor
solar cells. They generate
construction
electricity without rare
earth metals.
Application
 Small market for Grätzel cells
 Easy handling
 Adjustment of the pathway
required!
 No glycosylation
 Extraction with organic solvent
Grätzel
cell
Grätzel cell function
chs
R
chi
Dependent on the promotor the
operon produces 1-3 µM
naringenin.
Naringenin is
detectable and can
be quantified.
GFP fluorescense
pH
T7-BBa_K1497023
E. coli BL21(DE3)
Fluorescence (RFU)
R
Plate with
100 µM
Naringenin
Control
under
UV light.
mKate fluorescense
pelargonidin is visible
4000
tal
CFP fluorescense
Anthocyanidin biosynthesis and production
Control
BBa_K1497007
R
3 Sensors with different
fluorophores were
constructed.
Naringenin [µM]
The implementation of the naringenin
operon was necessary for pelargonidin
production.
4-cl
Solar
cell
Metabolic
engineering
Anthocyanidin precursor biosynthesis
R
gfp
BBa_K1497019-22
Mutual
learning
Purchasing
DSCs
30 kDa
fdeR
Dye
Local
partner
Local
microcredit
bank
FdeR
Fluorescense [RFU]
Local
industry
The goal: Harvesting solar power
with anthocyanins
Naringenin
SDS-Page
+ -
BBa_K1497023
3000
f3h
R
R
dfr
R
eans
2000
Control
T7–BBa_K1497007
1000
0
E. coli BL21(DE3)
E. coli BL21(DE3)
+ BBa_K1497020
+ BBa_K1497020
The biosynthesis of pelargonidin in
E. coli is feasible. Pelargonidin can be
extracted by dichloromethane. At pH 1
pelargonidin has a dark red color.
Pelargonidin
Naringenin
Conclusions
 Full pelargonidin and naringenin biosynthesis pathways are
deposited in the parts registry
 3 new Biosensors for naringenin detection
 Successfull pelargonidin production and Grätzel cell
construction
 33 new Biobricks for the parts registry
 Novel mutual learning approach for Policy and Practices
Refernces:
[1] Yan Y, Chemler J, Huang L, [2] Winkel BSJ (2004)
Metabolic channeling in
et al. (2005) Metabolic
plants.
Engineering of Anthocyanin
Biosynthesis in Escherichia coli.
Our supporters:
Special thanks to:






A
Prof. Dr. Michael Grätzel
Prof. Dr. Katja Schmitz
Dr. Toby Meier
Dr. Stefan Martens
Wieke Betten
…and many more
B