Difference between revisions of "Part:BBa K4365000"
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The Factor-Induced Gene 1 (FIG1) promoter is a pheromone-induced promoter that is activated by the alpha mating factor. The FIG1 promoter is a great device for synthetic biology applications. It can be used to engineer productive stationary-phase systems in S. cerevisiae and has been used to improve heterologous protein yield [4] or for the controlled cell-cell communication in yeast cultures [6]. | The Factor-Induced Gene 1 (FIG1) promoter is a pheromone-induced promoter that is activated by the alpha mating factor. The FIG1 promoter is a great device for synthetic biology applications. It can be used to engineer productive stationary-phase systems in S. cerevisiae and has been used to improve heterologous protein yield [4] or for the controlled cell-cell communication in yeast cultures [6]. | ||
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The induction of the *FIG1* promoter by the alpha mating factor, in addition to activating the expression of a gene of interest, leads to the arrest of growth and maintenance ****of active metabolism in *S. cerevisiae*. As a result, the synthesis of a product of interest is decoupled from population growth, and cellular resources, such as carbon and nitrogen, can be redirected from biomass production to the synthesis of the desired bioproduct [4]. | The induction of the *FIG1* promoter by the alpha mating factor, in addition to activating the expression of a gene of interest, leads to the arrest of growth and maintenance ****of active metabolism in *S. cerevisiae*. As a result, the synthesis of a product of interest is decoupled from population growth, and cellular resources, such as carbon and nitrogen, can be redirected from biomass production to the synthesis of the desired bioproduct [4]. | ||
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Moreover, the *FIG1* promoter is strictly regulated by a well-understood signaling cascade, which avoids the cross-activation of other pathways and has enabled the construction and fine-tuning of a multitude of synthetic regulatory circuits [1,4]. | Moreover, the *FIG1* promoter is strictly regulated by a well-understood signaling cascade, which avoids the cross-activation of other pathways and has enabled the construction and fine-tuning of a multitude of synthetic regulatory circuits [1,4]. | ||
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The *S. cerevisiae* mating system has become a cornerstone of eukaryotic synthetic biology [7]. The key regulator of the mating system is the alpha mating factor pheromone, functioning as an inductor of the pheromone response. | The *S. cerevisiae* mating system has become a cornerstone of eukaryotic synthetic biology [7]. The key regulator of the mating system is the alpha mating factor pheromone, functioning as an inductor of the pheromone response. | ||
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When large-scale production by means of engineered organisms is conducted in parallel with biomass growth, the organism uses carbon and nitrogen for both growth and synthesis of the desired bioproduct. Biomass accumulation is essential to achieve the productivity required for commercial processes; yet, excess biomass limits yields because of the aforementioned competition for resource allocation and the accumulation of toxic intermediates. | When large-scale production by means of engineered organisms is conducted in parallel with biomass growth, the organism uses carbon and nitrogen for both growth and synthesis of the desired bioproduct. Biomass accumulation is essential to achieve the productivity required for commercial processes; yet, excess biomass limits yields because of the aforementioned competition for resource allocation and the accumulation of toxic intermediates. | ||
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*S. cerevisiae* undergoes an exponential growth phase where carbon and nitrogen resources are consumed until they limit further biomass accumulation. During this phase, 90% of the energy is directed toward ribosome biogenesis [8]. After the growth phase, the cells enter a ‘stationary phase’, which is characterized by the induction of survival mechanisms and a drastic reduction in the rate of protein synthesis. | *S. cerevisiae* undergoes an exponential growth phase where carbon and nitrogen resources are consumed until they limit further biomass accumulation. During this phase, 90% of the energy is directed toward ribosome biogenesis [8]. After the growth phase, the cells enter a ‘stationary phase’, which is characterized by the induction of survival mechanisms and a drastic reduction in the rate of protein synthesis. | ||
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The alpha mating factor pheromone induces the pheromone-response in *S. cerevisiae*, which leads to the arrest of growth. Moreover, the pheromone response triggered by the alpha mating factor has been shown to maintain an active metabolism in *S. cerevisiae*. This stationary phase phenotype induced by the pheromone response has the potential to improve heterologous protein yield [4]. | The alpha mating factor pheromone induces the pheromone-response in *S. cerevisiae*, which leads to the arrest of growth. Moreover, the pheromone response triggered by the alpha mating factor has been shown to maintain an active metabolism in *S. cerevisiae*. This stationary phase phenotype induced by the pheromone response has the potential to improve heterologous protein yield [4]. | ||
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This means that, after a rapid growth phase where biomass accumulates to a sufficient level to enable high productivity, the alpha mating factor can be easily added by the operator to switch to a metabolically active stationary phase. This phase can be maintained in the presence of high concentrations of resources such as carbon and nitrogen. With cells metabolically active but not growing and dividing, a greater proportion of resources can therefore be directed towards target metabolites. | This means that, after a rapid growth phase where biomass accumulates to a sufficient level to enable high productivity, the alpha mating factor can be easily added by the operator to switch to a metabolically active stationary phase. This phase can be maintained in the presence of high concentrations of resources such as carbon and nitrogen. With cells metabolically active but not growing and dividing, a greater proportion of resources can therefore be directed towards target metabolites. | ||
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In addition to bioprocess engineering, the pheromone response has been successfully adopted into synthetic biology applications in the field of artificial cell-cell communication systems to directly activate and finetune a desired function in yeast cells [6]. | In addition to bioprocess engineering, the pheromone response has been successfully adopted into synthetic biology applications in the field of artificial cell-cell communication systems to directly activate and finetune a desired function in yeast cells [6]. | ||
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For example, a quorum sensing circuit was developed in yeast by utilizing the alpha factor pheromone [9]. In this system, yeast populations were engineered to produce and respond to extracellular alpha mating factor pheromone by expressing GFP in a population-density-dependent manner. | For example, a quorum sensing circuit was developed in yeast by utilizing the alpha factor pheromone [9]. In this system, yeast populations were engineered to produce and respond to extracellular alpha mating factor pheromone by expressing GFP in a population-density-dependent manner. | ||
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Moreover, the pheromone response is a well characterized pathway that can engineered to allow couple positive or negative regulators to of the pheromone response cascade to modify sensitivity or timing of the cellular response of yeast-based sensing systems [10]. | Moreover, the pheromone response is a well characterized pathway that can engineered to allow couple positive or negative regulators to of the pheromone response cascade to modify sensitivity or timing of the cellular response of yeast-based sensing systems [10]. | ||
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A further example of the potential of the pheromone response and the induction by the alpha mating factor pheromone is illustrated by the development of synthetic inter-species communication systems between *S. cerevisiae* and *S. pombe* (Figure 4) [11]. *S. cerevisiae* cells were engineered to secrete the P-factor pheromone of *S. pombe*, whereas *S. pombe* cells were engineered to secrete the alpha mating factor pheromone of *S. cerevisiae*. Co-cultures of the two engineered species were shown to be able to communicate using their respective pheromones. | A further example of the potential of the pheromone response and the induction by the alpha mating factor pheromone is illustrated by the development of synthetic inter-species communication systems between *S. cerevisiae* and *S. pombe* (Figure 4) [11]. *S. cerevisiae* cells were engineered to secrete the P-factor pheromone of *S. pombe*, whereas *S. pombe* cells were engineered to secrete the alpha mating factor pheromone of *S. cerevisiae*. Co-cultures of the two engineered species were shown to be able to communicate using their respective pheromones. |
Revision as of 16:26, 10 October 2022
FIG1 inducible promoter
The Factor-Induced Gene 1 (FIG1) is a pheromone-induced promoter in yeast that is activated by the alpha mating factor. The FIG1 promoter is a great device for synthetic biology applications aiming to engineer productive stationary-phase systems in S. cerevisiae. This is because the induction of the FIG1 promoter by the alpha mating factor, in addition to activating expression, leads to the arrest of growth and maintenance of active metabolism in S. cerevisiae. As a result, the synthesis of a product of interest is decoupled from population growth, and cellular resources, such as carbon and nitrogen, can be redirected from biomass production to the synthesis of the desired bioproduct. Moreover, the FIG1 promoter is strictly regulated by a well-understood signaling cascade, which avoids cross-activation of other pathways and has enabled the construction and fine-tuning of a multitude of synthetic regulatory circuits.
Biology and Usage
Factor-Induced Gene 1 promoter pathway
The alpha mating factor functions as a mating pheromone in S. cerevisiae. At the molecular level, the pheromone binds to the Ste2, the alpha factor pheromone receptor (a GPCR) found on mating-type-a cells in yeast. This receptor is coupled to a heterotrimeric G protein complex and a cytoplasmic mitogen-activated protein (MAP)1 kinase cascade [1,4]. Transduction of the signal by the MAP kinase cascade (Figure 1) leads, among others, to the phosphorylation and activation of the transcription factor Ste12, which regulates mating by binding to the PRE motif present in pheromone-responsive genes [3]. Among the promoters induced by Ste12 is the Factor-Induced Gene 1 (FIG1) promoter.
FIG1 advantages for synthethic biology in yeast
The Factor-Induced Gene 1 (FIG1) promoter is a pheromone-induced promoter that is activated by the alpha mating factor. The FIG1 promoter is a great device for synthetic biology applications. It can be used to engineer productive stationary-phase systems in S. cerevisiae and has been used to improve heterologous protein yield [4] or for the controlled cell-cell communication in yeast cultures [6].
The induction of the *FIG1* promoter by the alpha mating factor, in addition to activating the expression of a gene of interest, leads to the arrest of growth and maintenance ****of active metabolism in *S. cerevisiae*. As a result, the synthesis of a product of interest is decoupled from population growth, and cellular resources, such as carbon and nitrogen, can be redirected from biomass production to the synthesis of the desired bioproduct [4].
Moreover, the *FIG1* promoter is strictly regulated by a well-understood signaling cascade, which avoids the cross-activation of other pathways and has enabled the construction and fine-tuning of a multitude of synthetic regulatory circuits [1,4].
Use of yeast pheromone response for protein production
The *S. cerevisiae* mating system has become a cornerstone of eukaryotic synthetic biology [7]. The key regulator of the mating system is the alpha mating factor pheromone, functioning as an inductor of the pheromone response.
When large-scale production by means of engineered organisms is conducted in parallel with biomass growth, the organism uses carbon and nitrogen for both growth and synthesis of the desired bioproduct. Biomass accumulation is essential to achieve the productivity required for commercial processes; yet, excess biomass limits yields because of the aforementioned competition for resource allocation and the accumulation of toxic intermediates.
- S. cerevisiae* undergoes an exponential growth phase where carbon and nitrogen resources are consumed until they limit further biomass accumulation. During this phase, 90% of the energy is directed toward ribosome biogenesis [8]. After the growth phase, the cells enter a ‘stationary phase’, which is characterized by the induction of survival mechanisms and a drastic reduction in the rate of protein synthesis.
The alpha mating factor pheromone induces the pheromone-response in *S. cerevisiae*, which leads to the arrest of growth. Moreover, the pheromone response triggered by the alpha mating factor has been shown to maintain an active metabolism in *S. cerevisiae*. This stationary phase phenotype induced by the pheromone response has the potential to improve heterologous protein yield [4].
This means that, after a rapid growth phase where biomass accumulates to a sufficient level to enable high productivity, the alpha mating factor can be easily added by the operator to switch to a metabolically active stationary phase. This phase can be maintained in the presence of high concentrations of resources such as carbon and nitrogen. With cells metabolically active but not growing and dividing, a greater proportion of resources can therefore be directed towards target metabolites.
In addition to bioprocess engineering, the pheromone response has been successfully adopted into synthetic biology applications in the field of artificial cell-cell communication systems to directly activate and finetune a desired function in yeast cells [6].
For example, a quorum sensing circuit was developed in yeast by utilizing the alpha factor pheromone [9]. In this system, yeast populations were engineered to produce and respond to extracellular alpha mating factor pheromone by expressing GFP in a population-density-dependent manner.
Moreover, the pheromone response is a well characterized pathway that can engineered to allow couple positive or negative regulators to of the pheromone response cascade to modify sensitivity or timing of the cellular response of yeast-based sensing systems [10].
A further example of the potential of the pheromone response and the induction by the alpha mating factor pheromone is illustrated by the development of synthetic inter-species communication systems between *S. cerevisiae* and *S. pombe* (Figure 4) [11]. *S. cerevisiae* cells were engineered to secrete the P-factor pheromone of *S. pombe*, whereas *S. pombe* cells were engineered to secrete the alpha mating factor pheromone of *S. cerevisiae*. Co-cultures of the two engineered species were shown to be able to communicate using their respective pheromones.
Characterization of FIG1 promoter
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal NgoMIV site found at 172
- 1000COMPATIBLE WITH RFC[1000]