RBS
SD 4

Part:BBa_K1084102

Designed by: Ami Kawahata   Group: iGEM13_HokkaidoU_Japan   (2013-08-27)

SD4

Synthetic RBS with Enhancer sequence and 4 bp SD sequence


We made these constructs to measure translation efficiency of our RBSs (SD2: BBa_K1084101, SD4: this part, SD6: BBa_K1084103, SD8: BBa_K1084104). We used TetR repressible promoter (pTet: BBa_R0040), LacZα (BBa_I732006) and double terminator (dT: BBa_B0015).

positive control
pTet-B0034-LacZα-dT
negative control
No insert
SD2
pTet-SD2-LacZα-dT (BBa_K1084121)
SD4
pTet-SD4-LacZα-dT (BBa_K1084122)
SD6
pTet-SD6-LacZα-dT (BBa_K1084123)
SD8
pTet-SD8-LacZα-dT (BBa_K1084124)

We moved our constructs to pSB3K3 plasmid, cultured for 9 hrs in 5 mL LB media round tubes, and performed β-Galactisidase assay. Reaction time was 2 hrs. We did this assay for 24 times.

fig.1: Picture of β-Galactosidase assay. orange: strong LacZα expression, yellow: weak expression.
fig.2: LacZα expression. x axis: sample name, y axis: standardized expression (positive control = 1.0), bar: standard error.

LacZα protein hydrolyses substrate (Chlorophenol red-β-D-galactopyranoside), which is yellow. Product of this reaction has red color. Therefore, solution will turn deep orange if LacZα expression is strong (fig.1).

We measured absorbance of catalytic reaction solution at 595 nm, standardized using positive control and made into graph (fig.2). Construct with SD4 showed the strongest LacZα activity. Second strongest was the SD8, followed by SD6. SD2 had the weakest activity. There is a significant difference in translation efficiency of our RBSs. Translation efficiency of SD4 and SD8 is the same as BBa_B0034, which is most used RBS.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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Parameters
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