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Part:BBa_K3286010

Designed by: Paul Alexander Niederau   Group: iGEM19_Wageningen_UR   (2019-10-16)
Revision as of 17:47, 21 October 2019 by AlexNiederau (Talk | contribs)


dCas9-AcrIIA4 gene circuit

Usage and Biology

CRISPR interference (CRISPRi) makes use of catalytically inactive variants of Cas9 proteins to suppress gene expression [1]. Identical to their active counterparts, the co-expression of guide RNAs directs the ribonuclease protein (RNP) to its specific DNA target sequence. However, introduction of mutations in the RuvC1 and HNH nuclease domains of Cas9 cause the Cas9 to lose endonuclease activity, without impeding the DNA binding [2; 3]. This enables the reversible transcriptional inhibition by tightly DNA-bound dCas proteins, contrary to irreversible cleavage by active Cas9. One way to reverse the effect of dCas-mediated gene repression is through their natural inhibitors, known as anti-CRISPR (Acr) proteins. Acrs are small, phage-derived proteins blocking the natural CRISPR immune system of bacteria [4]. In most cases, they directly interfere with Cas nucleases, blocking binding or cleavage of the target DNA [5]. Therefore, Acrs may represent a powerful tool for the optimization of CRISPR/Cas-based genome editing approaches or the construction of synthetic circuits [6].

Sequence and Features

The dCas9-AcrIIA4 gene circuit mainly consists out of three parts; the AcrIIA4, the dCas9, and the sgRNA expression module (Part:BBa_K3286009, Part:BBa_K3286008, Part:BBa_K3286003). The acr expression is under the control of the L-rhamnose inducible promoter (Prha) and shares a bi-directional terminator with the dCas9 gene. The dCas9 is being expressed via the tetracyclin promoter regulated via the IPTG-inducible lacI/lac operator (Ptet/lac). The sgRNA (spacer and scaffold) are expressed by the strong constitutive J23119 promoter. The circuit was inserted and tested in the pACYC184 vector with p15a ori and chloramphenicol resistance using High Fidelity Assembly.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 1200
    Illegal NheI site found at 5911
    Illegal NheI site found at 5934
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 3479
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Functional Characterization

Fluorescence Loss Assay

dCas9 and Acr-dCas9 constructs with three different spacers each where tested in a plate reader experiment for the loss of Gfp fluorescence and restoration of Gfp signal upon acr induction. Assays were conducted in the E. coli DH10B strain carrying a genomically inserted lacUV5_gfp expression cassette. Spacers were designed to either target the –10 element of the lacUV5 promoter or within the first 100 nucleotides of the gfp cds. Figure 1 shows reduction of relative Gfp fluorescence by 90 – 99% for constructs dCas9 spacer 1 – 3. A trend is visible pointing towards spacer 1 being most effective, spacer 2 less, and spacer 3 least. The effectiveness of gfp repression correlates with the distance of the spacers from the lacUV5 promoter region. The results therefore confirm the findings of Larson et al., 2013 [7], who stated that targeting the promoter region is most effective as compared to targeting the 5’ UTR or cds further downstream. For constructs Acr-dCas spacer 1 – 3 the effect of the Acr is clearly visible as 0,2 and 1% L-rhamnose induction results in up to 90% of Gfp signal restoration. However, even if not induced via L-rhamnose, leaky acr expression restores fluorescence to an extend of 50 - 80%. Again, the efficiency of repression decreases from Spacer 1 to Spacer 3. The strong influence of acr promoter leakiness does not meet the requirements of a tight genetic switch mechanism.

Figure 1: dCas9(-AcrIIA4) targeting GFP. dCas9 targeting gfp expression with three different spacers, either with or without AcrIIA4. Different shades of green represent different amounts of L-rhamnose added inducing acrIIA4 expression levels. E. coli DH10B served as a negative control and was subtracted from samples. Fluorescence is relative to (Acr-)dCas9 with non-targeting spacer. Data represent the averages of three biological replicates.

RBS Randomization

In order to lower the effect of basal acrIIA4 expression, the ribosomal binding site (RBS) of acrIIA4 was mutagenized. Via PCR, using a primer allowing two different nucleotides at four positions of the RBS core region, 16 (2^4 = 16) different RBSs were created (Figure 2). The resulting PCR product containing the mutagenized RBS was cloned upstream of acrIIA4 into the Acr-dCas spacer 1 vector. After transformation, 43 colonies were picked and screened in a fluorescence loss assay for both low basal acrIIA4 expression when not induced, and high acrIIA4 expression, when induced by L-Rhamnose. The results of ten picked colonies represent the full range of lowest to highest basal AcrIIA4 effect on gfp repression are shown in Figure 2. The randomization of the acrIIA4 RBS resulted in different fluorescence repression levels, reaching from almost 0% the original expression level of 28% (spacer 1). Constructs presented in Figure 2 were sequenced to link the point mutations in the RBS core region to the effect of AcrIIA4 mediated dCas9 repression (Figure 3). Sequence identity between various RBSs reduced the extend of the randomized RBS library to seven different sites. Translation initiation rates of RBSs were predicted using the De Novo DNA RBS Library Calculator [8; 9]. Predicted translation initiation rates of acrIIA4 correlate to Acr-mediated Gfp signal restoration to some degree (Figure 2&table). Also, the data indicate a correlation between levels of Gfp signal restoration upon 0,2% L-rhamnose induction and Gfp signal repression levels without induction. As RBS C11 showed lowest basal acrIIA4 expression and highest difference in relative Gfp signal between the two treatments (data not shown) it was chosen for follow-up experiments.

Figure 2: dCas9-AcrIIA4_randomized-RBS targeting gfp. dCas9-Acr spacer 1 targeting gfp expression with either the original RBS (spacer 1) or randomized RBS. Different shades of green represent different amounts of L-rhamnose added inducing acrIIA4 expression. Samples were ordered by lowest to highest basal acrIIA4 expression, except for spacer 1. dCas9 lacking AcrIIA4 served as a negative control and was subtracted from samples to see differences solely caused by AcrIIA4 presence. Fluorescence is relative to dCas9 with a non-targeting spacer. Data represent the averages of two biological replicates.


Name Identifier Sequencea Translation Initiation Rate (au)b
C11 BBa_K3286013 aagaacgtgatata 3.84
B10 (C8) BBa_K3286014 aagaagctgatata 6.03
D2 BBa_K3286015 aagaaggtcatata 6.76
C7 (D8) BBa_K3286016 aagaacgagatata 12.01
A12 BBa_K3286017 aagaaggtgatata 37.75
B6 (C2) BBa_K3286018 aagaaggacatata 50.26
A9 (Sp1) BBa_K3286019 aagaaggagatata 129.33


aNucleotides 2 – 5 of the acrIIA4 associated RBS core region were mutagenized and sequenced. Bold letters represent the RBS core region. Red letters represent point mutations as compared to the randomization template spacer 1.

bTranslation initiation rates of RBS were predicted using the De Novo DNA RBS Library Calculator.



RBS C11 was cloned in the control plasmids to repeat the initial fluorescence loss assay of Figure 1 and compare the effect of AcrIIA4 mediated GFP signal restoration among the different conditions (Figure 3). Relative fluorescence of dCas9 was subtracted from Acr-dCas and Acr-dCas_RBS C11 to see the effect of AcrIIA4 presence on the circuit. Results show that by changes in the RBS, the basal expression of acrIIA4 under no L-rhamnose induction is lowered by ca. 30%. Restoration of fluorescence via acrIIA4 expression is lower in Acr-dCas_C11 as compared to Acr-dCas (Figure 3). Even though this was expected with regard to the data of Figure 2, the effect is stronger than anticipated.


Figure 3: dCas9 targeting gfp expression with different acrIIA4 associated RBSs. Different shades of green represent different amounts of L-rhamnose added inducing acrIIA4 expression levels. E. coli DH10B served as a negative control and was subtracted from samples. dCas9 lacking AcrIIA4 served as a negative control and was subtracted from samples to see differences solely caused by AcrIIA4 presence. Fluorescence is relative to dCas9 with a non-targeting spacer. Data represent the averages of three biological replicates.

Discussion

Presented data show that dCas9 and AcrIIA4 can be combined to construct a switch for control of gene expression. However, the system is leaky and does not guarantee a full inhibition or activation. By fine-tuning the basal expression levels of acrIIA4, the switch can be regulated to have a tighter ON- or OFF-function. Higher basal expression leads to a more sophisticated ON-switch, restoring fluorescence by about 90% (Figure 1) when induced. In contrast, lower basal expression of acrIIA4 allows a tighter OFF-state, limiting GFP signal to below 5% when not induced (Figure 3). However, our data indicate a trade-off between the ON- or the OFF-state, allowing for the tight control of either one of the states. It was shown that reduction of basal acrIIA4 expression can be achieved by varying RBSs, reducing the translation rate of the associated gene. Furthermore, other mechanisms of tight expression control are worth exploring, such as riboswitches or the usage of tighter regulated promoters.

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