Novel promoter/transactivator configurations for macrolide- and streptogramin-responsive transgene expression in mammalian cells

Engineering natural molecule-triggered genetic control systems for tunable gene- and cell-based therapies

The ability to precisely control activities of engineered designer cells provides a novel strategy for modern precision medicine. Dynamically adjustable gene- and cell-based precision therapies are recognized as next generation medicines. However, the translation of these controllable therapeutics into clinical practice is severely hampered by the lack of safe and highly specific genetic switches controlled by triggers that are nontoxic and side-effect free. Recently, natural products derived from plants have been extensively explored as trigger molecules to control genetic switches and synthetic gene networks for multiple applications. These controlled genetic switches could be further introduced into mammalian cells to obtain synthetic designer cells for adjustable and fine tunable cell-based precision therapy. In this review, we introduce various available natural molecules that were engineered to control genetic switches for controllable transgene expression, complex logic computation, and therapeutic drug delivery to achieve precision therapy. We also discuss current challenges and prospects in translating these natural molecule-controlled genetic switches developed for biomedical applications from the laboratory to the clinic.

Synthetic gene circuits for cell state detection and protein tuning in human pluripotent stem cells

During development, cell state transitions are coordinated through changes in the identity of molecular regulators in a cell type‐ and dose‐specific manner. The ability to rationally engineer such transitions in human pluripotent stem cells (hPSC) will enable numerous applications in regenerative medicine. Herein, we report the generation of synthetic gene circuits that can detect a desired cell state using AND‐like logic integration of endogenous miRNAs (classifiers) and, upon detection, produce fine‐tuned levels of output proteins using an miRNA‐mediated output fine‐tuning technology (miSFITs). Specifically, we created an “hPSC ON” circuit using a model‐guided miRNA selection and circuit optimization approach. The circuit demonstrates robust PSC‐specific detection and graded output protein production. Next, we used an empirical approach to create an “hPSC‐Off” circuit. This circuit was applied to regulate the secretion of endogenous BMP4 in a state‐specific and fine‐tuned manner to control the composition of differentiating hPSCs. Our work provides a platform for customized cell state‐specific control of desired physiological factors in hPSC, laying the foundation for programming cell compositions in hPSC‐derived tissues and beyond.

Design of Synthetic Promoters for Gene Circuits in Mammalian Cells

Synthetic biology, the synthesis of engineering and biology, has rapidly matured and has dramatically increased the complexity of artificial gene circuits in recent years. The deployment of intricate synthetic gene circuits in mammalian cells requires the establishment of very precise and orthogonal control of transgene expression. In this chapter, we describe methods of modulating the expression of transgenes at the transcriptional level. Using cAMP-response element-binding protein (CREB)-dependent promoters as examples, a tool for the precise tuning of gene expression by using different core promoters and by varying the binding affinity of transcription factor operator sites is described.

Model-guided combinatorial optimization of complex synthetic gene networks

Constructing gene circuits that satisfy quantitative performance criteria has been a long-standing challenge in synthetic biology. Here, we show a strategy for optimizing a complex three-gene circuit, a novel proportional miRNA biosensor, using predictive modeling to initiate a search in the phase space of sensor genetic composition. We generate a library of sensor circuits using diverse genetic building blocks in order to access favorable parameter combinations and uncover specific genetic compositions with greatly improved dynamic range. The combination of high-throughput screening data and the data obtained from detailed mechanistic interrogation of a small number of sensors was used to validate the model. The validated model facilitated further experimentation, including biosensor reprogramming and biosensor integration into larger networks, enabling in principle arbitrary logic with miRNA inputs using normal form circuits. The study reveals how model-guided generation of genetic diversity followed by screening and model validation can be successfully applied to optimize performance of complex gene networks without extensive prior knowledge.

Precision multidimensional assay for high-throughput microRNA drug discovery

Development of drug discovery assays that combine high content with throughput is challenging. Information-processing gene networks can address this challenge by integrating multiple potential targets of drug candidates' activities into a small number of informative readouts, reporting simultaneously on specific and non-specific effects. Here we show a family of networks implementing this concept in a cell-based drug discovery assay for miRNA drug targets. The networks comprise multiple modules reporting on specific effects towards an intended miRNA target, together with non-specific effects on gene expression, off-target miRNAs and RNA interference pathway. We validate the assays using known perturbations of on- and off-target miRNAs, and evaluate an ∼700 compound library in an automated screen with a follow-up on specific and non-specific hits. We further customize and validate assays for additional drug targets and non-specific inputs. Our study offers a novel framework for precision drug discovery assays applicable to diverse target families.

Progress in drug discovery can be hampered by a limited exploration of chemical space and the difficulty in assessing the full range of drug candidates' effects on living cells. Here the authors describe a cell-based assay to distinguish between off-target and specific effects of candidate compounds targeting micro RNAs.

Digital switching in a biosensor circuit via programmable timing of gene availability

Transient delivery of gene circuits is required in many potential applications of synthetic biology, yet the pre-steady-state processes that dominate this delivery route pose major challenges for robust circuit deployment. Here we show that site-specific recombinases can rectify undesired effects by programmable timing of gene availability in multigene circuits. We exemplify the concept with a proportional sensor for endogenous microRNA (miRNA) and show a marked reduction in its ground state leakage due to desynchronization of the circuit's repressor components and their repression target. The new sensors display a dynamic range of up to 1,000-fold compared to 20-fold in the standard configuration. We applied the approach to classify cell types on the basis of miRNA expression profile and measured >200-fold output differential between positively and negatively identified cells. We also showed major improvements in specificity with cytotoxic output. Our study opens new venues in gene circuit design via judicious temporal control of circuits' genetic makeup.

Highly modular bow-tie gene circuits with programmable dynamic behaviour

Synthetic gene circuits often require extensive mutual optimization of their components for successful operation, while modular and programmable design platforms are rare. A possible solution lies in the 'bow-tie' architecture, which stipulates a focal component-a 'knot'-uncoupling circuits' inputs and outputs, simplifying component swapping, and introducing additional layer of control. Here we construct, in cultured human cells, synthetic bow-tie circuits that transduce microRNA inputs into protein outputs with independently programmable logical and dynamic behaviour. The latter is adjusted via two different knot configurations: a transcriptional activator causing the outputs to track input changes reversibly, and a recombinase-based cascade, converting transient inputs into permanent actuation. We characterize the circuits in HEK293 cells, confirming their modularity and scalability, and validate them using endogenous microRNA inputs in additional cell lines. This platform can be used for biotechnological and biomedical applications in vitro, in vivo and potentially in human therapy.

Tuning response curves for synthetic biology

Synthetic biology may be viewed as an effort to establish, formalize, and develop an engineering discipline in the context of biological systems. The ability to tune the properties of individual components is central to the process of system design in all fields of engineering, and synthetic biology is no exception. A large and growing number of approaches have been developed for tuning the responses of cellular systems, and here we address specifically the issue of tuning the rate of response of a system: given a system where an input affects the rate of change of an output, how can the shape of the response curve be altered experimentally? This affects a system's dynamics as well as its steady-state properties, both of which are critical in the design of systems in synthetic biology, particularly those with multiple components. We begin by reviewing a mathematical formulation that captures a broad class of biological response curves and use this to define a standard set of varieties of tuning: vertical shifting, horizontal scaling, and the like. We then survey the experimental literature, classifying the results into our defined categories, and organizing them by regulatory level: transcriptional, post-transcriptional, and post-translational.

Rewiring and dosing of systems modules as a design approach for synthetic mammalian signaling networks

Modularly structured signaling networks coordinate the fate and function of complex biological systems. Each component in the network performs a discrete computational operation, but when connected to each other intricate functionality emerges. Here we study such an architecture by connecting auxin signaling modules and inducible protein biotinylation systems with transcriptional control systems to construct synthetic mammalian high-detect, low-detect and band-detect networks that translate overlapping gradients of inducer molecules into distinct gene expression patterns. Guided by a mathematical model we apply fundamental computational operations like conjunction or addition to rewire individual building blocks to qualitatively and quantitatively program the way the overall network interprets graded input signals. The design principles described in this study might serve as a conceptual blueprint for the development of next-generation mammalian synthetic gene networks in fundamental and translational research.

The food additive vanillic acid controls transgene expression in mammalian cells and mice

Trigger-inducible transcription-control devices that reversibly fine-tune transgene expression in response to molecular cues have significantly advanced the rational reprogramming of mammalian cells. When designed for use in future gene- and cell-based therapies the trigger molecules have to be carefully chosen in order to provide maximum specificity, minimal side-effects and optimal pharmacokinetics in a mammalian organism. Capitalizing on control components that enable Caulobacter crescentus to metabolize vanillic acid originating from lignin degradation that occurs in its oligotrophic freshwater habitat, we have designed synthetic devices that specifically adjust transgene expression in mammalian cells when exposed to vanillic acid. Even in mice transgene expression was robust, precise and tunable in response to vanillic acid. As a licensed food additive that is regularly consumed by humans via flavoured convenience food and specific fresh vegetable and fruits, vanillic acid can be considered as a safe trigger molecule that could be used for diet-controlled transgene expression in future gene- and cell-based therapies.

De novo design and construction of an inducible gene expression system in mammalian cells

Inducible expression systems represent the founding technology for the emergence of synthetic biology in mammalian cells. The core molecules in these systems are bacterial regulator proteins that bind to or dissociate from a cognate DNA operator sequence in response to an exogenous stimulus like a small-molecule inducer. In this chapter, we describe a generic protocol of how bacterial regulator proteins can be applied to the design, construction, and optimization of an inducible expression system in mammalian cells. By choosing regulator proteins with an appropriate small-molecule inducer, this protocol provides a straightforward approach for establishing biosensors, cell-to-cell communication systems, or tools to control gene expression in vivo.

A synthetic low-frequency mammalian oscillator

Circadian clocks have long been known to be essential for the maintenance of physiological and behavioral processes in a variety of organisms ranging from plants to humans. Dysfunctions that subvert gene expression of oscillatory circadian-clock components may result in severe pathologies, including tumors and metabolic disorders. While the underlying molecular mechanisms and dynamics of complex gene behavior are not fully understood, synthetic approaches have provided substantial insight into the operation of complex control circuits, including that of oscillatory networks. Using iterative cycles of mathematical model-guided design and experimental analyses, we have developed a novel low-frequency mammalian oscillator. It incorporates intronically encoded siRNA-based silencing of the tetracycline-dependent transactivator to enable the autonomous and robust expression of a fluorescent transgene with periods of 26 h, a circadian clock-like oscillatory behavior. Using fluorescence-based time-lapse microscopy of engineered CHO-K1 cells, we profiled expression dynamics of a destabilized yellow fluorescent protein variant in single cells and real time. The novel oscillator design may enable further insights into the system dynamics of natural periodic processes as well as into siRNA-mediated transcription silencing. It may foster advances in design, analysis and application of complex synthetic systems in future gene therapy initiatives.

Modulation of cardiomyocyte electrical properties using regulated bone morphogenetic protein-2 expression

Because cardiomyocytes lose their ability to divide after birth, any subsequent cell loss or dysfunction results in pathologic cardiac rhythm initiation or impulse conduction. Strategies to restore and control the electrophysiological activity of the heart may, therefore, greatly affect the regeneration of cardiac tissue functionality. Using lentivirus-derived particles to regulate the bone morphogenetic protein-2 (BMP-2) gene expression in a pristinamycin- or gaseous acetaldehyde-inducible manner, we demonstrated the adjustment of cardiomyocyte electrophysiological characteristics. Complementary metal oxide semiconductor-based high-density microelectrode arrays (HD-MEAs) were used to monitor the electrophysiological activity of neonatal rat cardiomyocytes (NRCs) cultured as monolayers (NRCml) or as microtissues (NRCmt). NRCmt more closely resembled heart tissue physiology than did NRCml and could be conveniently monitored using HD-MEAs because of their ability to detect low-signal events and to sub-select the region of interest, namely, areas where the microtissues were placed. Cardiomyocyte-forming microtissues, transduced using lentiviral vectors encoding BMP-2, were capable of restoring myocardial microtissue electrical activity. We also engineered NRCmt to functionally couple within a cardiomyocyte monolayer, thus showing pacemaker-like activity upon local regulation of transgenic BMP-2 expression. The controlled expression of therapeutic transgenes represents a crucial advance for clinical interventions and gene-function analysis.

Intronically encoded siRNAs improve dynamic range of mammalian gene regulation systems and toggle switch

Applications of conditional gene expression, whether for therapeutic or basic research purposes, are increasingly requiring mammalian gene control systems that exhibit far tighter control properties. While numerous approaches have been used to improve the widely used Tet-regulatory system, many applications, particularly with respect to the engineering of synthetic gene networks, will require a broader range of tightly performing gene control systems. Here, a generically applicable approach is described that utilizes intronically encoded siRNA on the relevant transregulator construct, and siRNA sequence-specific tags on the reporter construct, to minimize basal gene activity in the off-state of a range of common gene control systems. To demonstrate tight control of residual expression the approach was successfully used to conditionally express the toxic proteins RipDD and Linamarase. The intronic siRNA concept was also extended to create a new generation of compact, single-vector, autoinducible siRNA vectors. Finally, using improved regulation systems a mammalian epigenetic toggle switch was engineered that exhibited superior in vitro and in vivo induction characteristics in mice compared to the equivalent non-intronic system.

RepTAGs: universal tags for isolation and labeling of proteins, for labeling live mammalian cells and for drug discovery

Methods for specific immobilization, isolation and labeling of proteins are central to the elucidation of cellular functions. Based on bacterial repressor proteins, which bind to specific target sequences in response to small molecules (macrolide and tetracycline antibiotics) or environmental parameters (temperature), we have developed a set of protein tags (RepTAGs), which enable reversible immobilization of the protein of interest on a solid support for the isolation and quantification as well as for the specific labeling of target proteins with fluorescent dyes for tracking them within a complex protein mixture. Similarly, live mammalian cells were specifically labeled with a fluorescent operator sequence bound to RepTAGs, which were directed towards the cell surface for easy discrimination between transfected and untransfected cell populations. Based on the drug-responsive RepTAG-DNA interactions, it was also possible to quantify or discover antibiotics in environmental samples or compound libraries by means of rapid, sensitive detection methods involving fluorescence polarization and bioluminescence. We believe that the universally applicable RepTAGs will become essential for the analysis and manipulation of proteins in the most diverse areas of protein chemistry and cell biology.

An engineered L-arginine sensor of Chlamydia pneumoniae enables arginine-adjustable transcription control in mammalian cells and mice

For optimal compatibility with biopharmaceutical manufacturing and gene therapy, heterologous transgene control systems must be responsive to side-effect-free physiologic inducer molecules. The arginine-inducible interaction of the ArgR repressor and the ArgR-specific ARG box, which synchronize arginine import and synthesis in the intracellular human pathogen Chlamydia pneumoniae, was engineered for arginine-regulated transgene (ART) expression in mammalian cells. A synthetic arginine-responsive transactivator (ARG), consisting of ArgR fused to the Herpes simplex VP16 transactivation domain, reversibly adjusted transgene transcription of chimeric ARG box-containing mammalian minimal promoters (P_ART) in an arginine-inducible manner. Arginine-controlled transgene expression showed rapid induction kinetics in a variety of mammalian cell lines and was adjustable and reversible at concentrations which were compatible with host cell physiology. ART variants containing different transactivation domains, variable spacing between ARG box and minimal promoter and several tandem ARG boxes showed modified regulation performance tailored for specific expression scenarios and cell types. Mice implanted with microencapsulated cells engineered for ART-inducible expression of the human placental secreted alkaline phosphatase (SEAP) exhibited adjustable serum phosphatase levels after treatment with different arginine doses. Using a physiologic inducer, such as the amino acid l-arginine, to control heterologous transgenes in a seamless manner which is devoid of noticeable metabolic interference will foster novel opportunities for precise expression dosing in future gene therapy scenarios as well as the manufacturing of difficult-to-produce protein pharmaceuticals.

Mammalian synthetic biology: Engineering of sophisticated gene networks

With the recent development of a wide range of inducible mammalian transgene control systems it has now become possible to create functional synthetic gene networks by linking and connecting systems into various configurations. The past 5 years has thus seen the design and construction of the first synthetic mammalian gene regulatory networks. These networks have built upon pioneering advances in prokaryotic synthetic networks and possess an impressive range of functionalities that will some day enable the engineering of sophisticated inter- and intra-cellular functions to become a reality. At a relatively simple level, the modular linking of transcriptional components has enabled the creation of genetic networks that are strongly analogous to the architectural design and functionality of electronic circuits. Thus, by combining components in different serial or parallel configurations it is possible to produce networks that follow strict logic in integrating multiple independent signals (logic gates and transcriptional cascades) or which temporally modify input signals (time-delay circuits). Progressing in terms of sophistication, synthetic transcriptional networks have also been constructed which emulate naturally occurring genetic properties, such as bistability or dynamic instability. Toggle switches which possess "memory" so as to remember transient administered inputs, hysteric switches which are resistant to stochastic fluctuations in inputs, and oscillatory networks which produce regularly timed expression outputs, are all examples of networks that have been constructed using such properties. Initial steps have also been made in designing the above networks to respond not only to exogenous signals, but also endogenous signals that may be associated with aberrant cellular function or physiology thereby providing a means for tightly controlled gene therapy applications. Moving beyond pure transcriptional control, synthetic networks have also been created which utilize phenomena, such as post-transcriptional silencing, translational control, or inter-cellular signaling to produce novel network-based control both within and between cells. It is envisaged in the not-too-distant future that these networks will provide the basis for highly sophisticated genetic manipulations in biopharmaceutical manufacturing, gene therapy and tissue engineering applications.

A novel vector platform for vitamin H-inducible transgene expression in mammalian cells

Inducible transgene control systems have been instrumental to gene therapy, biopharmaceutical manufacturing, drug discovery, synthetic biology and functional genomic research. The most widely used heterologous gene regulation systems are responsive to antibiotics of the tetracycline, streptogramin and macrolide classes. Although these antibiotics are clinically licensed, concerns about the emergence of resistant bacteria, side-effects in animal studies, and economic considerations associated with clearance of antibiotics in biopharmaceutical manufacturing, have limited the use of heterologous transgene control modalities to basic research activities. We have therefore designed a strategy to convert antibiotic-responsive transcription factors into gene regulation systems responsive to non-toxic biotin, also known as vitamin H. Constitutive ligation of biotin to the Avitag-containing VP16 transactivation domain by the Escherichia coli biotin ligase BirA enables heterodimerization with tetracycline- (TetR), streptogramin- (Pip), and macrolide- (E) dependent repressors fused to streptavidin, which creates synthetic transactivators able to activate specific promoters (P(hCMV-1), P(PIR), P(ETR)). We have demonstrated (i) that exogenous biotin (40nM) can induce heterologous transgene expression in a biotin- (serum-) free culture environment (biotin-dependent heterodimerization of transactivator); (ii) that excess biotin (above 200microM) gradually represses transgene expression in a biotin- (serum-) containing environment (saturation of streptavidin by excess biotin prevents heterodimerization of the transactivator); and (iii) that avidin can sequestrate endogenous biotin in serum-containing cultures and so repress transgene expression in a dose-dependent manner. In addition, by engineering all off the components required for biotin-controlled transgene expression (Avitag-VP16, repressor-streptavidin, BirA) into a tricistronic (lenti)vector configuration, it was possible to transfect (transduce) a variety of mammalian cell lines and primary cells and enable biotin-controlled transgene expression in a simple and straightforward manner. The conversion of generic antibiotic-responsive transcription control modalities into systems adjustable by non-toxic vitamin H may foster novel advances in reprogramming of mammalian cells and production of difficult-to-produce protein pharmaceuticals.

Improved transgene expression fine-tuning in mammalian cells using a novel transcription–translation network

Following the discovery of RNA interference (RNAi) and related phenomena, novel regulatory processes, attributable to small non-protein-coding RNAs, continue to emerge. Capitalizing on the ability of artificial short interfering RNAs (siRNAs) to trigger degradation of specific target transcripts, and thereby silence desired gene expression, we designed and characterized a generic transcription-translation network in which it is possible to fine-tune heterologous protein production by coordinated transcription and translation interventions using macrolide and tetracycline antibiotics. Integration of siRNA-specific target sequences (TAGs) into the 5' or 3' untranslated regions (5'UTR, 3'UTR) of a desired constitutive transcription unit rendered transgene-encoded protein (erythropoietin, EPO; human placental alkaline phosphatase, SEAP; human vascular endothelial growth factor 121, VEGF(121)) production in mammalian cells responsive to siRNA levels that can be fine-tuned by macrolide-adjustable RNA polymerase II- or III-dependent promoters. Coupling of such macrolide-responsive siRNA-triggered translation control with tetracycline-responsive transcription of tagged transgene mRNAs created an antibiotic-adjustable two-input transcription-translation network characterized by elimination of detectable leaky expression with no reduction in maximum protein production levels. This transcription-translation network revealed transgene mRNA depletion to be dependent on siRNA and mRNA levels and that translation control was able to eliminate basal expression inherent to current transcription control modalities. Coupled transcription-translation circuitries have the potential to lead the way towards composite artificial regulatory networks, to enable complex therapeutic interventions in future biopharmaceutical manufacturing, gene therapy and tissue engineering initiatives.

6-hydroxy-nicotine-inducible multilevel transgene control in mammalian cells

The precise control of transgene expression is essential for biopharmaceutical manufacturing, gene therapy and tissue engineering. We have designed a novel conditional transcription technology, which enables reversible induction, repression and adjustment of desired transgene expression using the clinically inert 6-hydroxy-nicotine (6HNic). The 6-hydroxy-nicotine oxidase (6HNO) repressor (HdnoR), which manages nicotine metabolism in Arthrobacter nicotinovorans pAO1 by binding to a specific operator of the 6-hydroxy-nicotine oxidase (O(NIC)), was fused to the Krueppel-associated box protein of the human kox-1 gene (KRAB) to create a synthetic 6HNic-dependent transsilencer (NS) that controls chimeric mammalian promoters, which are assembled by cloning tandem O(NIC) operators 3' of a constitutive promoter. In the absence of 6HNic, NS binds to O(NIC) and silences the constitutive promoter, which otherwise drives high-level transgene expression when the NS-O(NIC) interaction stops in the presence of 6HNic. Generic NICE(ON) technology was compatible with a variety of constitutive viral and mammalian housekeeping promoters, each of which enabled specific induced, repressed, adjusted and reversible transgene expression profiles in Chinese hamster ovary (CHO-K1), baby hamster kidney (BHK-21) as well as in human fibrosarcoma (HT-1080) cells. NICE(ON) also proved successful in controlling multicistronic expression units for coordinated transcription of up to three transgenes and in the fine-tuning of transcription-translation networks, in which RNA polymerase II- and III-dependent promoters, engineered for 6HNic responsiveness, drove expression of siRNAs that triggered specific transgene knockdown. NICE(ON) represents a robust and versatile technology for the precise tuning of transgene expression in mammalian cells.

A genetic redox sensor for mammalian cells

Nutrient and oxygen availability are key metabolic parameters for biopharmaceutical manufacturing. In order to enable mammalian cells to manifest their intracellular nutrient and oxygen levels we engineered a genetic sensor circuitry which converts signals impinging on the cellular redox balance into a robust reporter gene expression readout. Capitalizing on the Streptomyces coelicolor redox control system, consisting of REX modulating ROP-containing promoters in an NADH-dependent manner, we designed a mammalian dual sensor transcription control system by fusing REX to the generic VP16 transactivation domain of Herpes simplex, which reconstitutes an artificial transactivator (REDOX) able to bind and activate chimeric promoters assembled by placing a ROP operator module 5' of a minimal eukaryotic promoter (P(ROP)). When nutrient levels were low and resulted in depleted NADH pools REDOX-dependent P(ROP)-driven expression of secreted (human-secreted alkaline phosphatase; SEAP) or intracellular (Renilla reniformis luciferase; rLUC) reporter genes was high as a consequence of increased REDOX-P(ROP) affinity. Conversely, at hypoxic conditions leading to high intracellular NADH levels, strongly reduced REDOX-P(ROP) interaction mediated low-level transgene expression in Chinese hamster ovary (CHO-K1) cells. Other molecules (for example, 2,4-dinitrophenol, cyanide or hydrogen peroxide) which are known to imbalance the intracellular NADH/NAD+ poise could also be detected using the REDOX-P(ROP) sensor circuitry. REDOX's sensor capacity (nutrient and oxygen levels) operated seamlessly in transgenic CHO-K1 cell derivatives adapted for growth in serum-free suspension cultures and enabled precise monitoring of the population's metabolic state. As the first genetic metabolic sensor designed for mammalian cells, REDOX may foster advances in process development and biopharmaceutical manufacturing.

Pharmacologic transgene control systems for gene therapy

Pharmacologic transgene-expression dosing is considered essential for future gene therapy scenarios. Genetic interventions require precise transcription or translation fine-tuning of therapeutic transgenes to enable their titration into the therapeutic window, to adapt them to daily changing dosing regimes of the patient, to integrate them seamlessly into the patient's transcriptome orchestra, and to terminate their expression after successful therapy. In recent years, decisive progress has been achieved in designing high-precision trigger-inducible mammalian transgene control modalities responsive to clinically licensed and inert heterologous molecules or to endogenous physiologic signals. Availability of a portfolio of compatible transcription control systems has enabled assembly of higher-order control circuitries providing simultaneous or independent control of several transgenes and the design of (semi-)synthetic gene networks, which emulate digital expression switches, regulatory transcription cascades, epigenetic expression imprinting, and cellular transcription memories. This review provides an overview of cutting-edge developments in transgene control systems, of the design of synthetic gene networks, and of the delivery of such systems for the prototype treatment of prominent human disease phenotypes.

Semi-synthetic mammalian gene regulatory networks

In recent years gene network engineers have celebrated spectacular success: Genetic devices such as epigenetic toggle switches and oscillating networks have been engineered and pioneered a new ever-increasing scientific community known as synthetic biology. While synthetic biology was until recently restricted to network assembly and testing in prokaryotes, decisive advances have been achieved in eukaryotic systems based on current availability of different human-compatible transgene control technologies. Most prominent examples include the epigenetic gene network enabling metastable fully inheritable transgene expression states in mice, artificial regulatory cascades managing multi-level expression control and Boolean-type BioLogic gates supporting near-digital expression readout. The majority of transgene control networks available to date are fully synthetic and integrate artificial extracellular signals in a desired host metabolism-independent manner. Yet, in order to develop their full anticipated therapeutic potential, synthetic transgene control circuits need to be well interconnected with the host cell's regulatory networks in order to enable physiologic control of prosthetic molecular expression units. We have designed three semi-synthetic transcription control networks able to integrate physiologic oxygen levels and artificial antibiotic signals to produce expression readout with NOT IF or NOR-type Boolean logic or discrete multi-level control of several intracellular and secreted model product proteins. Subtle differences in the regulation performance of the endogenous oxygen-sensing system in CHO-K1 and human HT-1080 switched the semi-synthetic network's readout from a classic four-level (high, medium, low, basal) regulatory cascade to a network enabling six discrete transgene expression levels. These findings are in excellent correspondence with a mathematical model. Prosthetic networks, precisely embedded in host regulatory networks and co-fine-tuned by physiologic as well as pharmacologic input signals, will foster future advances in gene therapy and tissue engineering.

A novel mammalian expression system derived from components coordinating nicotine degradation in arthrobacter nicotinovorans pAO1

We describe the design and detailed characterization of 6-hydroxy-nicotine (6HNic)-adjustable transgene expression (NICE) systems engineered for lentiviral transduction and in vivo modulation of angiogenic responses. Arthrobacter nicotinovorans pAO1 encodes a unique catabolic machinery on its plasmid pAO1, which enables this Gram-positive soil bacterium to use the tobacco alkaloid nicotine as the exclusive carbon source. The 6HNic-responsive repressor-operator (HdnoR-O(NIC)) interaction, controlling 6HNic oxidase production in A.nicotinovorans pAO1, was engineered for generic 6HNic-adjustable transgene expression in mammalian cells. HdnoR fused to different transactivation domains retained its O(NIC)-binding capacity in mammalian cells and reversibly adjusted transgene transcription from chimeric O(NIC)-containing promoters (P(NIC); O(NIC) fused to a minimal eukaryotic promoter [P(min)]) in a 6HNic-responsive manner. The combination of transactivators containing various transactivation domains with promoters differing in the number of operator modules as well as in their relative inter-O(NIC) and/or O(NIC)-P(min) spacing revealed steric constraints influencing overall NICE regulation performance in mammalian cells. Mice implanted with microencapsulated cells engineered for NICE-controlled expression of the human glycoprotein secreted placental alkaline phosphatase (SEAP) showed high SEAP serum levels in the absence of regulating 6HNic. 6HNic was unable to modulate SEAP expression, suggesting that this nicotine derivative exhibits control-incompatible pharmacokinetics in mice. However, chicken embryos transduced with HIV-1-derived self-inactivating lentiviral particles transgenic for NICE-adjustable expression of the human vascular endothelial growth factor 121 (VEGF121) showed graded 6HNic response following administration of different 6HNic concentrations. Owing to the clinically inert and highly water-soluble compound 6HNic, NICE-adjustable transgene control systems may become a welcome alternative to available drug-responsive homologs in basic research, therapeutic cell engineering and biopharmaceutical manufacturing.

Macrolide- and tetracycline-adjustable siRNA-mediated gene silencing in mammalian cells using polymerase II-dependent promoter derivatives

RNA interference has emerged as a powerful technology for downregulation of specific genes in cells and animals. We have pioneered macrolide- and tetracycline-adjustable short interfering RNA (siRNA) expression for conditional target gene translation fine-tuning in mammalian/human cell lines based on modified RNA polymerase II promoters. Established macrolide- and tetracycline-dependent transactivators/trans-silencers bound and activated modified target promoters tailored for optimal siRNA expression in response to clinical antibiotics' dosing regimes and modulated desired target genes in Chinese hamster ovary (CHO-K1) and human fibrosarcoma (HT-1080) cells with high precision. Further optimization of adjustable RNA polymerase II-based siRNA-specific promoters as well as their combination with various transmodulators enabled near-perfect regulation configurations in specific cell types. Devoid of major genetic constraints compared to basic RNA polymerase III-based siRNA-specific promoters, we expect RNA polymerase II counterparts to significantly advance siRNA-based molecular interventions in biopharmaceutical manufacturing and gene-function analysis as well as gene therapy and tissue engineering.

Gas-inducible transgene expression in mammalian cells and mice

We describe the design and detailed characterization of a gas-inducible transgene control system functional in different mammalian cells, mice and prototype biopharmaceutical manufacturing. The acetaldehyde-inducible AlcR-P(alcA) transactivator-promoter interaction of the Aspergillus nidulans ethanol-catabolizing regulon was engineered for gas-adjustable transgene expression in mammalian cells. Fungal AlcR retained its transactivation characteristics in a variety of mammalian cell lines and reversibly adjusted transgene transcription from chimeric mammalian promoters (P(AIR)) containing P(alcA)-derived operators in a gaseous acetaldehyde-dependent manner. Mice implanted with microencapsulated cells engineered for acetaldehyde-inducible regulation (AIR) of the human glycoprotein secreted placental alkaline phosphatase showed adjustable serum phosphatase levels after exposure to different gaseous acetaldehyde concentrations. AIR-controlled interferon-beta production in transgenic CHO-K1-derived serum-free suspension cultures could be modulated by fine-tuning inflow and outflow of acetaldehyde-containing gas during standard bioreactor operation. AIR technology could serve as a tool for therapeutic transgene dosing as well as biopharmaceutical manufacturing.

Approaches for trigger-inducible viral transgene regulation in gene-based tissue engineering

Recent advances in mammalian transgene expression dosing have resulted in a portfolio of mutually compatible systems that can adjust therapeutic transgene levels in response to antibiotics, hormone analogues, quorum-sensing messengers and secondary metabolites. The molecular merger of trigger-inducible expression technology with the latest generation of virus-derived transduction systems has enabled unmatched clinical interventions to shape desired therapeutic cell and tissue phenotypes for the treatment of complex human diseases.

Novel macrolide-adjustable bidirectional expression modules for coordinated expression of two different transgenes in mice

BACKGROUND

Precise control of transgene expression is essential for a variety of applications ranging from gene-function analysis, biopharmaceutical manufacturing to next-generation molecular interventions in gene therapy and tissue engineering. The regulation of gene expression is currently a key issue for clinical implementation of gene-therapy-based treatments since desired transgene expression may need to be maintained within a narrow therapeutic window for successful treatment of a particular human disease.

METHODS

We have designed a novel bidirectional expression module that enables adjustable coregulation of two different transgenes in response to clinical doses of macrolide antibiotics. A bidirectional macrolide-responsive promoter consisting of a central operator module (ETR) specific for the macrolide-dependent transactivator (ET1) is flanked by two minimal promoters (P(hCMVmin); P(hsp70min)) which drive expression of two divergently oriented transgenes. Macrolide antibiotics modulate the binding affinity of ET1 to ETR and adjust expression of both transgenes to desired levels.

RESULTS

Bidirectional expression configurations enabled excellent macrolide-adjustable coregulation profiles of two secreted reporter genes or one-vector-based autoregulated fine-tuning of a single transgene in various transgenic rodent and human cell lines. Following implantation of microencapsulated CHO-K1 cell derivatives transgenic for macrolide-controlled bidirectional expression of erythropoietin (EPO) and the human secreted alkaline phosphatase (SEAP) intraperitoneally into mice, serum EPO and SEAP levels could be coadjusted to desired levels by administration of different erythromycin doses.

CONCLUSIONS

Based on their in vivo compatibility, the versatile bidirectional and macrolide-responsive expression modules represent an important advancement on the way to implementing targeted and conditional molecular interventions into a clinical reality.

Design and in vivo characterization of self-inactivating human and non-human lentiviral expression vectors engineered for streptogramin-adjustable transgene expression

Adjustable transgene expression is considered key for next-generation molecular interventions in gene therapy scenarios, therapeutic reprogramming of clinical cell phenotypes for tissue engineering and sophisticated gene-function analyses in the post-genomic era. We have designed a portfolio of latest generation self-inactivating human (HIV-derived) and non-human (EIAV-based) lentiviral expression vectors engineered for streptogramin-adjustable expression of reporter (AmyS(DeltaS), EYFP, SAMY, SEAP), differentiation-modulating (human C/EBP-alpha) and therapeutic (human VEGF) transgenes in a variety of rodent (CHO-K1, C2C12) and human cell lines (HT-1080, K-562), human and mouse primary cells (NHDF, PBMC, CD4+) as well as chicken embryos. Lentiviral design concepts include (i) binary systems harboring constitutive streptogramin-dependent transactivator (PIT) and PIT-responsive transgene expression units on separate lentivectors; (ii) streptogramin-responsive promoters (P(PIR8)) placed 5' of desired transgenes; (iii) within modified enhancer-free 3'-long terminal repeats; and (iv) bidirectional autoregulated configurations providing streptogramin-responsive transgene expression in a lentiviral one-vector format. Rigorous quantitative analysis revealed HIV-based direct P(PIR)-transgene configurations to provide optimal regulation performance for (i) adjustable expression of intracellular and secreted product proteins, (ii) regulated differential differentiation of muscle precursor cell lines into adipocytes or osteoblasts and (iii) conditional vascularization fine-tuning in chicken embryos. Similar performance could be achieved by engineering streptogramin-responsive transgene expression into an autoregulated one-vector format. Powerful transduction systems equipped with adjustable transcription modulation options are expected to greatly advance sophisticated molecular interventions in clinically and/or biotechnologically relevant primary cells and cell lines.

Gene therapy progress and prospects: transcription regulatory systems

The clinical efficacy and safety as well as the application range of gene therapy will be broadened by developing systems capable of finely modulating the expression of therapeutic genes. Transgene regulation will be crucial for maintaining appropriate levels of a gene product within the therapeutic range, thus preventing toxicity. Moreover, the possibility to modulate, stop or resume transgene expression in response to disease evolution would facilitate the combination of gene therapy with more conventional therapeutic modalities. The development of ligand-dependent transcription regulatory systems is thus of great importance. Here, we summarize the most recent progress in the field.

Dual-regulated myoD- and msx1-based interventions in C2C12-derived cells enable precise myogenic/osteogenic/adipogenic lineage control

BACKGROUND

Advanced gene therapy, tissue engineering and biopharmaceutical manufacturing require sophisticated and well-balanced multiregulated multigene interventions to reprogram desired mammalian cell phenotypes.

METHODS

We have combined the streptogramin (PIP)- and tetracycline (TET)-responsive gene regulation systems for independent expression control of the differentiation determinants myoD and msx1 in C2C12-derived cells.

RESULTS

Different dual-regulated expression scenarios which induce either both, only one or none of the lineage control genes triggered differential differentiation and precise control of myogenic, osteogenic or adipogenic cell phenotypes.

CONCLUSIONS

Our findings substantiate the use of multiregulated multigene interventions in reprogramming cellular differentiation pathways in a desired manner.

Broad-spectrum protein biosensors for class-specific detection of antibiotics

The dramatically increasing prevalence of multi-drug-resistant human pathogenic bacteria and related mortality requires two key actions: (i) decisive initiatives for the detection of novel antibiotics and (ii) a global ban for use of antibiotics as growth promotants in stock farming. Both key actions entail technology for precise, high-sensitive detection of antibiotic substances either to detect and validate novel anti-infective structures or to enforce the non-use of clinically relevant antibiotics. We have engineered prokaryotic antibiotic response regulators into a molecular biosensor configuration able to detect tetracycline, streptogramin, and macrolide antibiotics in spiked liquids including milk and serum at ng/mL concentrations and up to 2 orders of magnitude below current Swiss and EC threshold values. This broad-spectrum, class-specific, biosensor-based assay has been optimized for use in a storable ready-to-use and high-throughput-compatible ELISA-type format. At the center of the assay is an antibiotic sensor protein whose interaction with specific DNA fragments is responsive to a particular class of antibiotics. Binding of biosensor protein to the cognate DNA chemically linked to a solid surface is converted into an immuno-based colorimetric readout correlating with specific antibiotics concentrations.

Artificial regulatory networks and cascades for discrete multilevel transgene control in mammalian cells

Prototype drug-adjustable heterologous transcription control systems designed for gene therapy applications typically show sigmoid dose-response characteristics and enable fine-tuning of therapeutic transgenes only within a narrow inducer concentration range of a few nanograms. However, the design of clinical dosing regimes which achieve tissue-specific concentrations with nanogram precision is yet a "mission impossible." Therefore, most of today's transcription control systems operate as ON/OFF switches and not in a true adjustable mode. The availability of robust transcription control configurations which lock expression of a single therapeutic transgene at desired levels in response to fixed clinical doses of different inducers rather than minute concentration changes of a single inducer would be highly desirable. Based on in silico predictions, we have constructed a variety of mammalian artificial regulatory networks by interconnecting the tetracycline- (TET(OFF)), streptogramin- (PIP(OFF)), and macrolide- (E(OFF)) repressible gene regulation systems as linear (auto)regulatory cascades. These networks enable multilevel expression control of several transgenes in response to different antibiotics or allow titration of a single transgene to four discrete expression levels by clinical dosing of a single antibiotic: 1) high expression in the absence of any antibiotic (+++), 2) medium level expression following addition of tetracycline (++), 3) low level expression in response to the macrolide erythromycin (+), and 4) complete repression by streptogramins such as pristinamycin (-). The first-generation artificial regulatory networks exemplify modular interconnections of different heterologous gene regulations systems to achieve multigene expression, fine-tuning, or to design novel control networks with unprecedented transgene regulation properties. Such higher-level transcription control modalities will lead the way towards composite artificial regulatory networks able to effect complex therapeutic interventions in future gene therapy and tissue engineering scenarios.

Bidirectional expression units enable streptogramin-adjustable gene expression in mammalian cells

Serious initiatives in gene therapy and tissue engineering require a sophisticated molecular toolbox combining DNA transfer technologies, human-compatible transcription control systems, as well as compact and robust expression configurations. We have designed several versatile bidirectional expression cassettes that enable coadjustable expression of two desired transgenes in response to clinically licensed antibiotics of the streptogramin class (pristinamycin, Pyostacin, Synercid). The bidirectional expression modules consist of a central operator (PIR) that is specific for the pristinamycin-dependent transactivator (PIT). Streptogramin-adjustable binding of PIT to PIR transactivates two divergently oriented promoters and initiates transcription of the desired transgenes. The bidirectional expression module can be equipped with different minimal promoters and configured for expression of (1) two functional effector genes, (2) one effector gene and a reporter gene, (3) PIT and an effector gene to form a highly compact one-vector expression arrangement. We have validated the streptogramin-adjustable bidirectional expression technology in different basic and autoregulated expression configurations in a variety of mammalian and human cell lines.

Conditional human VEGF-mediated vascularization in chicken embryos using a novel temperature-inducible gene regulation (TIGR) system

Advanced heterologous transcription control systems for adjusting desired transgene expression are essential for gene function assignments, drug discovery, manufacturing of difficult to produce protein pharmaceuticals and precise dosing of gene-based therapeutic interventions. Conversion of the Streptomyces albus heat shock response regulator (RheA) into an artificial eukaryotic transcription factor resulted in a vertebrate thermosensor (CTA; cold-inducible transactivator), which is able to adjust transcription initiation from chimeric target promoters (P(CTA)) in a low-temperature- inducible manner. Evaluation of the temperature-dependent CTA-P(CTA) interaction using a tailored ELISA-like cell-free assay correlated increased affinity of CTA for P(CTA) with temperature downshift. The temperature-inducible gene regulation (TIGR) system enabled tight repression in the chicken bursal B-cell line DT40 at 41 degrees C as well as precise titration of model product proteins up to maximum expression at or below 37 degrees C. Implantation of microencapsulated DT40 cells engineered for TIGR-controlled expression of the human vascular endothelial growth factor A (hVEGF121) provided low-temperature-induced VEGF-mediated vascularization in chicken embryos.