Chiba/Engeneering Flagella
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**Beadsとヒスチジンの反応では、Co2+が中心に位置し、ヒスチジンの空間的位置に対する要求性が厳密になっています。連続するヒスチジンや空間的に適切に配置する隣接ヒスチジンのみがこの反応中心でコバルトに結合します。Ni2+ではこのような空間的要求性はあまり厳密ではありません。このため、Ni2+つきのBeadsを用いた場合、His タグ融合タンパク質以外に存在するヒスチジンも結合してしまいます。 | **Beadsとヒスチジンの反応では、Co2+が中心に位置し、ヒスチジンの空間的位置に対する要求性が厳密になっています。連続するヒスチジンや空間的に適切に配置する隣接ヒスチジンのみがこの反応中心でコバルトに結合します。Ni2+ではこのような空間的要求性はあまり厳密ではありません。このため、Ni2+つきのBeadsを用いた場合、His タグ融合タンパク質以外に存在するヒスチジンも結合してしまいます。 | ||
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==References== | ==References== |
Revision as of 04:59, 27 October 2007
Introduction | Project Design ( 1.Affinity Tag | 2.Communication Module | 3.Size Control ) | Making Marimos | Our Goal |
Stickey Tags
Our Aim
To make stickey hands on E.coli, we focused on their flagella that are located outside the cells. We used the following mechanisms:
- Display sticky peptides in flagellar filament.
- His-tag. The imidazole group in histidines make a complex with metal ions.
We combined these two and made a His-tagged flagella in the hope to stick them together via metal ions.
[http://www.npn.jst.go.jp/index.html About flagella]
E.Coli have 5-10 flagella. The flagella is used for swimming and for chemotaxis; the bacteria run when they find attractant, tumble when there is a repellent.
E.coli flagella consist of three parts: a basal body, a hook, and a filament. The filament of E.Coli is a rigid, helical, and cylindrical structure which is 10-15μm long and 23nm thick in diameter. It is built from ~20000 subunits of a ~55kDa single protein, FliC. FliC has three domains, D1,D2,D3; although D1 and D2 are needed for the formation of the functional flagellar filament, D3 domain which sticks outside of the fillament are not essential[3].
"Variable" FliC D3 domain
It is reported that the proteins up to 49.4kDa could be displayed on the cell surface of E.Coli using flagellin fusion protein.[4]
About Histidine Tag
See [http://en.wikipedia.org/wiki/His-tag wikipedia article].
Experiments
Making |frame|FliC-his gene
- We inserted the short peptide with six histidine (“His-Tag”) into the fliC D3 domain.
Checking the "Stickiness": Beads Adsorption
Purpose
Confirm that the his-tags are displaied on the flagella and are capable of binding to Co2+- or Ni2+- surface.
Samples
- ⊿fliC strain(JW1908 in KEIO collections [5]) transformed with
- pUC19-fliC-his
- no plasmid
- ⊿fliC,⊿motB strain(GI826)transformed with
- pUC19-fliC-his
- no plasmid
Testing Procedure
- pUC19-FliC-His was transformed to JW1908(fliC) and GI826(fliC motB).
- Grown to stationary phase
- Culture suspended with Dynabeads (Metal-IDA), allowing to the affinity adsorption
- Beads washed with a phosphate buffer (x4)
- E" coli" detached from beads by adding imidazole then spreaded on agar plates.
- The number of the colonies on resultant plates.
Results&Discussion
1.Stickiness check using FliC strain
- Cell without His-FliC bound better to the Beads? No way!
- We thought the problem might be the super-fast revolution of flagella itself. We decided to try MotB strain.
2.Stickiness check using MotB strain
- Mot B deletion provides cell with the flagella completely assembled but not rotating.
- This time it worked! Only in the presence of Co2+Bacteria with His-FliC sticked to the Co-IDA beads very well.
- In this strain, FliC-His is assembled with wildtype FliC coded in genomic DNA. Nevertheless, the binding efficiency was at the same level (not shown). it seems that His-Tag displayed on the flagella is enough to do its work.
- On the other hand, the deletion of MotB turned out to be vital for sticking the tagged flagella together.
- In the presence of FliC-His, cobalt ion adsorb bacteria stronger than nickel ion, this was more or less the expected result.
References
3. Kuwajima, G. et al.: J. Bacteriol., 170, 3305-3309 (1988)
4. Ezaki, S. et. al.: J. Ferment. Bioeng., 86, 500-503 (1998)
5. Baba, T. et. al.: Mol. Systems. Biol., 21, 1-10 (2006)