Team:Tokyo Tech/Projects/PHAs/index.htm

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=Perspective=
=Perspective=

Revision as of 07:37, 24 September 2012

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PHAs Production

Contents

Achivement

We made a new biobrick part and succeeded synthesizing Polyhydroixyalkanoates(PHAs). In our project, we designed rose silhouette to enhance the balcony scene of “Romeo and Juliet” by the synthesis of PHAs.

What is PHA?

Polyhydroixyalkanoates(PHAs) are biological polyester synthesized by a wide range of bacteria, and can be produced by fermentation from renewable carbon sources such as sugars and vegetable oils. These polyesters are biodegradable thermoplastics and elastomers, which exhibit interesting material properties. Bacteria produce PHAs for the storage of carbon and energy. When the bacteria can’t get enough nutrients from outside, these PHAs will be degraded and used as energy source. This function is quite similar to the one of lipid in human body. PHAs are also a kind of bio plastics, which can be biodegraded a lot faster than fossil-fuel plastics in the environment. Poly-3-hydroxybutyrate, P(3HB) is the most common type of PHAs. P(3HB) is synthesized by the enzymes coded in the gene of PHA synthesis (phaC1-A-B1) from Ralstonia eutropha H16.


Poly-3-hydroxybutyrate, P(3HB) is synthesized by three enzymes.

fig1
fig2

The A gene encodes for the 393 amino acids protein, 3-ketothiolase (PhaA)

The B gene encodes for the 246 amino acids protein, acetoacetyl-CoA reductase (PhaB)

The C gene encodes for the 589 amino acids protein, PHA Synthase (PhaC)




The pathway and regulation of P(3HB) synthesis in Ralstonia eutropha H16 is shown in Fig2. Acetyl CoA is metabolized from glucose by glycolysis and Pyruvate dehydrogenase complex (PDC). At first, two molecules of acetyl-CoA are ligated to one molecule acetoacetyl-CoA by the action of 3-ketothiolase (coded in phaA). Acetoacetyl-CoA is transformed into (R)-3-hydroxybutyl-CoA by NADPH dependent acetoacetyl-CoA reductase(coded in phaB). P(3HB) polymers are then synthesized by the polymerization of (R)-3-hydroxybutyryl-CoA by the action of PHA synthase (PhaC). In most of the cases, PHA synthase determines the characteristic of PHA being synthesized in microorganism.

Other teams

In this study, we constructed a part containing pha-C1-A-B1 in Biobrick format. We introduce some attempts in the past iGEM to show how great our work is in iGEM. There is no Biobrick part which worked as expected though some teams had tried to synthesize PHA in the past.[see more]

Construction of phaC1-A-B1 in Biobrick format

To make pha-C1-A-B1 operon meets Biobrick format, we used artificial composition of gene from IDT/MBL. Wild type pha-C1-A-B1 operon contains one NotI and three PstI recognition sites that are not allowed in Biobrick format. In this chemically synthesized DNA, coding is optimized for E.coli. That is to say, we got Poly[(R)-3-hydroxybutyrate] synthesizing gene in Biobrick format ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K934001 BBa_K934001]). [see more]

PHB production by E.coli & Confirmation of PHB

To synthesize PHB by E.coli, we transformed E.coli JM109 with the constructed phaC1-A-B1 parts on pSB1C3 ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K934001 BBa_K934001]). E.coli JM109 is used to synthesize PHB, because it tends to have a high density accumulation of PHB.As a negative control, we transformed E.coli JM109 with PlasI-gfp on pSB1C3.[see more]

fig6,Cross-diffusion and pattern formation in reaction–diffusion systems
fig6,Cross-diffusion and pattern formation in reaction–diffusion systems
fig6,Cross-diffusion and pattern formation in reaction–diffusion systems
fig6,Cross-diffusion and pattern formation in reaction–diffusion systems

Perspective

fig6,Cross-diffusion and pattern formation in reaction–diffusion systems

The achievement of our project “Organic synthesis of PHA” is that we registered available PHA synthetic gene in Biobrick parts. We can control the expression of the PHA synthetic gene spatially by using combination of Biobrick parts. What we want to claim as an example of the spatial manipulation of gene expression is water-repellent. A stronger water-repellent requires hydrophobicity as well as the increase in real surface area that can be achieved as ruggedness of PHA adsorbed on particular surface. If we can control the expression of the PHA synthetic gene spatially by using genetic parts which are registered in Biobrick parts, the application of a super water-repellent sheet will become available. We note this as to the future prospects of our project.

Reference

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