Difference between revisions of "Part:BBa K581003"

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We have constructed two types of plasmids presented in Figure 5.<P>
 
We have constructed two types of plasmids presented in Figure 5.<P>
  
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<p><i>Fig.5 Plasmids constructed for characterizing ptsG/SgrS orthogonal silencing matrix</i></p>
 
<p><i>Fig.5 Plasmids constructed for characterizing ptsG/SgrS orthogonal silencing matrix</i></p>
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Revision as of 00:01, 6 October 2011

SgrS2+Terminator (small RNA regulator, conjugate part of ptsG2)

This is the conjugate part of ptsG2-gfp.

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]


This BioBrick has been sequence verified.

Background

SgrS is an Hfq-binding small antisense RNA that is induced upon phosphosugar stress (Vanderpool, 2007). It forms a ribonucleoprotein complex with RNase E through Hfq to mediate silencing of the target ptsG mRNA encoding the major glucose transporter (Geissmann and Touati, 2004). A 31-nt-long stretch in the 3’ region of SgrS is partially complementary to the translation initiation region of ptsG mRNA, and a 6 nt region overlapping the Shine-Dalgarno sequence of the target mRNA turns out to be crucial for SgrS’ function, shown as Fig.1 (Kawamoto et al., 2006; Maki et al., 2010).

Fig.1 Sequence alignment of wildtype ptsG/SgrS pair and its mutant complementary pairs. (A) The partial complementary region of ptsG (wt) mRNA and its corresponding sRNA SgrS. (B) The complementary pair site-mutant version of ptsG2 mRNA and corresponding SgrS2.

Teppei Morita et.al’ s work suggests that two mutations (C85G and C87G) in ptsG mRNA could completely impair the ability of SgrS to downregulate its expression, while compensatory mutations of SgrS (G178C and G176C) restore the gene silencing ability. These results indicate that it is the base pairing of the two RNAs rather than particular nucleotides that is important for SgrS action. They have also illustrated that sequence outside this region, even though complementary, is rather dispensable for the efficient silencing (Kawamoto et al., 2006). This makes mutant ptsG/SgrS pairs orthogonal to genetic context of the host cell. By employing two sets of mutant ptsG mRNA as well as its complementary SgrS in the design shown in Fig 1, we set to biologically implement the comparator. In detail, ptsG1 refers to a C85G mutant of ptsG (wt) while ptsG2 is a C87G mutant. SgrS1 (G178C) and SgrS2 (G176C) are the corresponding revertants which could help restore their complementarity. And as a proof-of-concept experiment, we constructed synthetic gene circuits, in which the 5’ untranslated region of ptsG mRNA was translationally fused to the coding sequence of the reporter gfp (Levine et al., 2007),as shown in Fig 2.

Fig. 2 The modular experimental subunits of the comparator. (A) Salicylate leads to the transcription of ptsG-gfp mRNA, which is the target of constitutively expressed SgrS. This is how we implement both reporting and repressing outputs as a result of the activation of Psal. When there is more salicylate in the media, the GFP fluorescence intensity is expected to be stronger. (B) Salicylate leads to the transcription of SgrS, while the ptsG-gfp mRNA is downstream a constitutive promoter. In this scenario, as the concentration of salicylate increases, the repression effect SgrS exerts on ptsG would in turn be stronger, so the GFP fluorescence intensity is supposed to be weaker.

Experimental Data

To qualitatively and quantitatively characterize the performance of our competitor, we conducted the following experiments.

Part I. The Orthogonal Silencing Matrix

The repression capacity of each ptsG/SgrS pair was indicated by the ratio of the average fluorescence intensity before to after the trigger of SgrS. What we expected was a significant repression within the cognate pairs (ptsG1/SgrS1, ptsG2/SgrS2, and ptsG (wt)/SgrS (wt)), and a minor repression folds among different pairs. As Figure 3 shows, the highest ratio lie at the diagonal from the upper left to the lower right as expected, which is 5 to 6 folds. As for the ptsG (wt)/SgrS1&2, ptsG1/SgrS (wt), and ptsG2/SgrS (wt), given that these crosses differ at only one base pair, the repression efficacy is around 3 folds. By contrast, the inhibiting effect of on ptsG2 and SgrS2 on ptsG1 is rather unapparent, which can be seen as an appropriate characteristic fitting our competitor requirements. The original data also provided below (Fig.3).

Fig.3 A graphical representation of the repression matrix associated with SgrS and its mutants, and ptsG and its mutants. The values represent the repression ratios, defined as the repression capacity of each ptsG/SgrS pair, denoted by the ratio of fluorescence intensity before to after the induction of SgrS, suggesting within-subgroup pairwise specificity.

Part II. Response Curves

The sRNA-mediated gene silencing can be formulated quantitatively via a simple kinetic model. The model is cast in terms of two mass-action equations for the cellular concentrations of the sRNA (s) and its target mRNA (m):

To verify this, we performed experiments to get the dose-response curve. The result is shown in Figure 4.

Fig.4 The dose-response curve of SgrS/ptsG-gfp interaction. Salicylate-induced SgrS repressing the expression of ptsG-GFP. The promoter activity is defined as the GFP expression of the Psal+gfp strain grown in identical media. Different promoter activities were obtained by varying salicylate concentration in the media. The conjugate pairs fit into dose-response curve with variable Hill slope given as a parameter, and the R^2 0.9607 corresponding to salicylate-induced, a dose-response curve is also fitted with an R2 of 0.9301.

Methods

Materials: We have constructed two types of plasmids presented in Figure 5.

Fig.5 Plasmids constructed for characterizing ptsG/SgrS orthogonal silencing matrix

References

[1] Geissmann, T.A., and Touati, D. (2004). Hfq, a new chaperoning role: binding to messenger RNA determines access for small RNA regulator. The EMBO journal 23: 396-405

[2] Kawamoto, H., Koide, Y., Morita, T., and Aiba, H. (2006). Base-pairing requirement for RNA silencing by a bacterial small RNA and acceleration of duplex formation by Hfq. Molecular microbiology 61: 1013-1022

[3] Levine, E., Zhang, Z., Kuhlman, T., and Hwa, T. (2007). Quantitative characteristics of gene regulation by small RNA. PLoS biology 5: e229