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== Introduction == | == Introduction == | ||
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Controlling gene expression in a condition and tissue specific manner is a desirable tool for a wide variety of applications ranging from fundamental bioscience research to gene therapy. Having this idea in mind, it is inevitable to consider the starting point of gene expression: the promoter. Most efforts of obtaining any promoter focus on cloning them from nature. In eukaryotes, this approach leads to several problems. The one major issue is the complexity of eukaryotic systems resulting in cross-talk between pathways. In particular, promoters tend to respond to several transcription factors and are thus activated by more than one pathway. That way, one cannot determine which signal originally induced the promoter. Alongside this specificity, induction under a desired combination of conditions and at defined strengths would be valuable implementations. <br> | Controlling gene expression in a condition and tissue specific manner is a desirable tool for a wide variety of applications ranging from fundamental bioscience research to gene therapy. Having this idea in mind, it is inevitable to consider the starting point of gene expression: the promoter. Most efforts of obtaining any promoter focus on cloning them from nature. In eukaryotes, this approach leads to several problems. The one major issue is the complexity of eukaryotic systems resulting in cross-talk between pathways. In particular, promoters tend to respond to several transcription factors and are thus activated by more than one pathway. That way, one cannot determine which signal originally induced the promoter. Alongside this specificity, induction under a desired combination of conditions and at defined strengths would be valuable implementations. <br> |
Revision as of 17:14, 6 October 2014
Contents |
Introduction
<ref name="Bezeichner">Blablablub</ref>
Controlling gene expression in a condition and tissue specific manner is a desirable tool for a wide variety of applications ranging from fundamental bioscience research to gene therapy. Having this idea in mind, it is inevitable to consider the starting point of gene expression: the promoter. Most efforts of obtaining any promoter focus on cloning them from nature. In eukaryotes, this approach leads to several problems. The one major issue is the complexity of eukaryotic systems resulting in cross-talk between pathways. In particular, promoters tend to respond to several transcription factors and are thus activated by more than one pathway. That way, one cannot determine which signal originally induced the promoter. Alongside this specificity, induction under a desired combination of conditions and at defined strengths would be valuable implementations.
Therefore, efforts have emerged to synthetically construct promoters. Two concepts of synthetic promoters in mammalian cells co-exist independently from each other. One is the concept of "genetic switches" (see [2] for a recent review) - promoters which can specifically be induced by a stimulus mammalian cells and are usually insensitive to, e.g. tetracycline [3]. Much fewer efforts have been put into developing promoters sensitive to endogenous signals (referred to as "synthetic promoters" in the rest of this article). Such promoters are of very high value for a broad variety of applications. Three examples should demonstrate this: First, in virotherapy for cancer and other diseases, it has become a desire to express toxic genes only in affected cells (reviewed in [4]). For example, breast cancer cells are characterized by high levels of estrogen receptor. Constructing a promoter which is active only at high estrogen receptor levels (preferable only in cells which are irradiated, as ER can be very active in other tissues of the female reproductive tract[17]) might therefore help developing novel breast cancer therapies. Second, biologists studying pathway interactions are in need for transcriptional assays, that being promoters which are specifically activated by a single transcription factor. Third, the concept can be transferred to plants, where synthetic promoters can be very valuable, as plant biotechnology is always in need for novel tissue- or development-specific promoters.
In order to be able to design synthetic promoters, an understanding of natural promoters is required. Mammalian promoters can be subdivided into several "domains". The core promoter is the binding site of the basal transcription machinery, i.e. RNA polymerase and associated factors. Core promoters differ in composition, but are more or less similar for most genes (reviewed in [11]). The main regulatory domain is the proximal promoter, which is where regulatory elements bind. It can be very large (4kb), meaning that some transcription factors regulate transcription despite being very far away from the RNA polymerase. This is mainly possible because of the three-dimensional structure the DNA adopts. In addition to this, there are even more distal elements that are referred to as "enhancers" and "silencers". A further challenge is that some transcription factors are not able to initiate transcription on their own, but rather they require other transcription factors for their activity [5].
Results
RA-PCR, a method for the generation of randomized promoter libraries
We have developed a standard method (termed "Random Assembly PCR / RA-PCR") for the construction of randomized promoter libraries. We modified Assembly PCR [12] to create promoters with randomized spacing and frequency of Transcription Factor Binding Sites. It relies on using different oligos containing a transcription factor binding site (or random DNA) plus two annealing sequences (see Fig. 1 for a comprehensive explanation of the method). We use two sets of oligos, one for the top strand, one for the bottom strand. The oligos for each strand have the same annealing sequences (which are complementary to the annealing sequences of the other strand). If these oligos are pooled, they will randomly anneal to each other, thus generating randomized repeats of the transcription factor binding sites of interest at varying spacing. In order to be able to clone the construct, we also add two stop oligos (termed stop 5' and top 3') which contain only one annealing sequence, plus a cutsite (SpeI 5', HindIII 3'). Double-stranded DNA is created by running a seven-cycle PCR, and amplified by a 25-cycle PCR. Then, the resulting (proximal) promoter is cloned 5' of a core promoter (we used the core promoter of JeT [10]) by inserting it into pSMB_MEASURE ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K203100 Part:BBa_K203100]), the promoter measurement plasmid we developed (from there, it can be excised like any standard biological part in a submission plasmid). Thus, a mixture of different promoters in the same plasmid backbone is generated. These can then be transformed into bacteria. Each colony represents a single putative promoter, which can be transfected into mammalian cell. 24 hours after transfection cells are exposed to the conditions of interest and control conditions, serving as a reference. Promoters active under the desired conditions, but not under control conditions, are selected for further characterization.
Please see a detailed protocol for RA-PCR below.
Generation of a library of constitutive promoters
As a first application of RA-PCR, we have created a library of constitutive promoters. We performed RA-PCR on oligos containing binding sites for some well-known generally activating transcription factors (Sp1, Ap1,CREB, NF-Y) which we identified from literature search [8],[7],[10]. We also added NF-κB responsive oligos as NF-κB has non-specific activity and is therefore used by a variety of viral constitutive promoters, e.g. the HIV promoter [13]. We picked 24 colonies, two of which we dismissed after a test digest (not shown). Fig. 3 shows the sequence analysis of some randomly selected clones and demonstrates that RA-PCR is able to generate randomized repeats of oligos. We then measured the activity of the clones we picked by applying the Concept of Relative Expression Units (REU) we developed. Fig. 2 shows that we have been able to create a library of promoters of varying strength, some of which have an expression strength higher than JeT (which was attempted but not accomplished by JeT's developers [10]). Such a library is of great value for fine-tuning gene expression levels.
References
[1] Alberts, Bruce. "3 Blabla." Molecular Biology of the Cell. 4th ed. New York: Garland Science, 2002. Print.