New-generation multicistronic expression platform: pTRIDENT vectors containing size-optimized IRES elements enable homing endonuclease-based cistron swapping into lentiviral expression vectors

Designing molecules: directing stem cell differentiation

Stem cells have been widely applied in regenerative and therapeutic medicine for their unique regenerative properties. Although much research has shown their potential, it remains tricky in directing stem cell differentiation. The advancement of genetic and therapeutic technologies, however, has facilitated this issue through development of design molecules. These molecules are designed to overcome the drawbacks previously faced, such as unexpected differentiation outcomes and insufficient migration of endogenous or exogenous MSCs. Here, we introduced aptamer, bacteriophage, and biological vectors as design molecules and described their characteristics. The methods of designing/developing discussed include various Systematic Evolution of Ligands by Exponential Enrichment (SELEX) procedures, in silico approaches, and non-SELEX methods for aptamers, and genetic engineering methods such as homologous recombination, Bacteriophage Recombineering of Electroporated DNA (BRED), Bacteriophage Recombineering with Infectious Particles (BRIP), and genome rebooting for bacteriophage. For biological vectors, methods such as alternate splicing, multiple promoters, internal ribosomal entry site, CRISPR-Cas9 system and Cre recombinase mediated recombination were used to design viral vectors, while non-viral vectors like exosomes are generated through parental cell-based direct engineering. Besides that, we also discussed the pros and cons, and applications of each design molecule in directing stem cell differentiation to illustrate their great potential in stem cells research. Finally, we highlighted some safety and efficacy concerns to be considered for future studies.

Cold-inducible proteins CIRP and RBM3, a unique couple with activities far beyond the cold

Cold-inducible RNA-binding protein (CIRP) and RNA-binding motif protein 3 (RBM3) are two evolutionarily conserved RNA-binding proteins that are transcriptionally upregulated in response to low temperature. Featuring an RNA-recognition motif (RRM) and an arginine-glycine-rich (RGG) domain, these proteins display many similarities and specific disparities in the regulation of numerous molecular and cellular events. The resistance to serum withdrawal, endoplasmic reticulum stress, or other harsh conditions conferred by RBM3 has led to its reputation as a survival gene. Once CIRP protein is released from cells, it appears to bolster inflammation, contributing to poor prognosis in septic patients. A variety of human tumor specimens have been analyzed for CIRP and RBM3 expression. Surprisingly, RBM3 expression was primarily found to be positively associated with the survival of chemotherapy-treated patients, while CIRP expression was inversely linked to patient survival. In this comprehensive review, we summarize the evolutionary conservation of CIRP and RBM3 across species as well as their molecular interactions, cellular functions, and roles in diverse physiological and pathological processes, including circadian rhythm, inflammation, neural plasticity, stem cell properties, and cancer development.

Efficient and graded gene expression in glia and neurons of primary cerebellar cultures transduced by lentiviral vectors

Lentiviral vectors are valuable tools to express genes of interest in living animals and stem cell cultures. The use of promoters in lentiviral constructs has been successfully used to drive gene expression in particular cell types including neurons and glia of the central nervous system in vivo. However, their suitability in cell culture is less well documented. In this paper, we describe lentiviral vectors containing neuronal promoters of the murine stem cell virus, of the synapsin 1 gene, the tubulin alpha 1 gene, and the calmodulin kinase II gene, and the glial promoter of the glial fibrillary acidic protein gene to drive reporter gene expression in primary dissociated cerebellar cell cultures and in slice cultures. While the glial promoter was highly specific for glia, the neuronal promoters were active in neurons and glia of dissociated cultures to a comparable extent. In slice cultures, neuronal and glial promoters demonstrated higher, but not absolute selectivity for particular cell types. In addition, the promoters allowed for an efficient and graded expression of genes in dissociated cultures. By using selected combinations of vectors, it was also possible to drive the expression of two genes in one cell type with high efficiency. A gene of interest in combination with a reporter gene can thus be expressed in a graded manner to reveal gene function in a rather short time and in a complex cellular environment.

Construction and application of a novel hepatocyte-directed vector to simultaneous knockdown and overexpression of multiple genes

BACKGROUND & AIMS

Liver disease, such as malignancy and hepatitis, often correlates with several genetic disorders. We aimed to construct a hepatocyte-specific vector that could manipulate multiple genes simultaneously.

METHODS

We selected a highly efficient hepatocyte-specific α-foetoprotein (AFP) enhancer/albumin promoter (an RNA polymerase II promoter) to express our gene of interest and transcribe microRNA-based shRNAs (shRNAmir). Multiple shRNAmirs were assembled together in tandem to enhance the gene-silencing effect. By employing the AFP enhancer/albumin promoter and inserting an internal ribosome entry site (IRES), a hepatocyte-specific, multi-reporter vector that overexpressed both β-galactosidase (LacZ) and DsRed2 while simultaneously knocking down both EGFP and luciferase expression was successfully constructed and functionally tested in vitro.

RESULTS

The reporter genes in the multireporter vector were easily replaced by immune-related genes to construct the Multi-Vector, which overexpressed human interleukin 10 and silenced both CCL5 and CX3CL1 (FKN) simultaneously in vivo; visualization of DsRed2 coexpressed to monitor vector function in vivo confirmed that the Multi-Vector was successfully introduced into the host. Simultaneous manipulation of these multiple genes by the Multi-Vector synergistically inhibited acute liver injury induced by Poly I:C/D-GalN injection in mice. The multifunctional cassette was also packaged in and successfully delivered by an adenoviral vector.

CONCLUSIONS

We successfully engineered a vector that can simultaneously regulate multiple genes from a single multigene-containing vector in a hepatocyte-specific manner, suggesting the possibility that this method could be extensively and practically utilized in liver gene therapy.

Vector systems for prenatal gene therapy: principles of retrovirus vector design and production

Vectors derived from the Retroviridae family have several attributes required for successful gene delivery. Retroviral vectors have an adequate payload size for the coding regions of most genes; they are safe to handle and simple to produce. These vectors can be manipulated to target different cell types with low immunogenicity and can permanently insert genetic information into the host cells' genome. Retroviral vectors have been used in gene therapy clinical trials and successfully applied experimentally in vitro, in vivo, and in utero.

Modified gateway system for double shRNA expression and Cre/lox based gene expression

BACKGROUND

The growing need for functional studies of genes has set the stage for the development of versatile tools for genetic manipulations.

RESULTS

Aiming to provide tools for high throughput analysis of gene functions, we have developed a modified short hairpin RNA (shRNA) and gene expression system based on Gateway Technology. The system contains a series of entry and destination vectors that enables easy transfer of shRNA or cDNA into lentiviral expression systems with a variety of selection or marker genes (i.e. puromycin, hygromycin, green fluorescent protein-EGFP, yellow fluorescent protein-YFP and red fluorescent protein-dsRed2). Our shRNA entry vector pENTR.hU6.hH1 containing two tandem human shRNA expression promoters, H1 and U6, was capable of co-expressing two shRNA sequences simultaneously. The entry vector for gene overexpression, pENTR.CMV.ON was constructed to contain CMV promoter with a multiple cloning site flanked by loxP sites allowing for subsequent Cre/lox recombination. Both shRNA and cDNA expression vectors also contained attL sites necessary for recombination with attR sites in our destination expression vectors. As proof of principle we demonstrate the functionality and efficiency of this system by testing expression of several cDNA and shRNA sequences in a number of cell lines.

CONCLUSION

Our system is a valuable addition to already existing library of Gateway based vectors and can be an essential tool for many aspects of gene functional studies.

In vitro and in vivo comparison of viral and cellular internal ribosome entry sites for bicistronic vector expression

Bicistronic vectors are essential to achieve efficient expression of multiple genes in gene therapy protocols and biomedical applications. Internal ribosome entry site (IRES) elements have been utilized to initiate expression of an additional protein from a bicistronic vector. The IRES element commonly used in current bicistronic vectors originates from the encephalomyocarditis virus (EMCV). As IRES-mediated translation is dependent on availability of IRES trans-acting factors, which vary between cell types and species, adequate gene expression from the EMCV IRES element is not always achieved. To identify a novel IRES element that mediates gene expression consistently with a higher efficiency than the EMCV IRES, we tested 13 bicistronic reporter constructs containing different viral and cellular IRES elements. The in vitro screening in human and mouse fibroblast and hepatocarcinoma cells revealed that the vascular endothelial growth factor and type 1 collagen-inducible protein (VCIP) IRES was the only IRES element that directed translation more efficiently than the EMCV IRES in all cell lines. Furthermore, the VCIP IRES initiated greater reporter expression levels than the EMCV IRES in transfected mouse livers. These results suggest that VCIP-IRES containing vectors improve gene expression compared with those harboring an EMCV-IRES. This could increase the potential benefits of bicistronic vectors for experimental and therapeutic purposes.

Functional cross-kingdom conservation of mammalian and moss (Physcomitrella patens) transcription, translation and secretion machineries

Plants and mammals are separated by a huge evolutionary distance. Consequently, biotechnology and genetics have traditionally been divided into 'green' and 'red'. Here, we provide comprehensive evidence that key components of the mammalian transcription, translation and secretion machineries are functional in the model plant Physcomitrella patens. Cross-kingdom compatibility of different expression modalities originally designed for mammalian cells, such as native and synthetic promoters and polyadenylation sites, viral and cellular internal ribosome entry sites, secretion signal peptides and secreted product proteins, and synthetic transactivators and transrepressors, was established. This mammalian expression portfolio enabled constitutive, conditional and autoregulated expression of different product genes in a multicistronic expression format, optionally adjusted by various trigger molecules, such as butyrolactones, macrolide antibiotics and ethanol. Capitalizing on a cross-kingdom-compatible expression platform, we pioneered a prototype biopharmaceutical manufacturing scenario using microencapsulated transgenic P. patens protoplasts cultivated in a Wave Bioreactor. Vascular endothelial growth factor 121 (VEGF(121)) titres matched those typically achieved by standard protonema populations grown in stirred-tank bioreactors. The full compatibility of mammalian expression systems in P. patens further promotes the use of moss as a cost-effective alternative for the manufacture of complex biopharmaceuticals, and as a valuable host system to advance synthetic biology in plants.

Quorum-Sensing-Based Toolbox for Regulatable Transgene and siRNA Expression in Mammalian Cells

Technologies for regulated expression of multiple transgenes in mammalian cells have gathered momentum for bioengineering, gene therapy, drug discovery, and gene-function analyses. Capitalizing on recently developed mammalian transgene modalities (QuoRex) derived from Streptomyces coelicolor, we have designed a flexible and highly compatible expression vector set that enables desired transgene/siRNA control in response to the nontoxic butyrolactone SCB1. The construction-kit-like expression portfolio includes (i) multicistronic (pTRIDENT), (ii) autoregulated, (iii) bidirectional (pBiRex), (iv) oncoretro- and lentiviral transduction, and (v) RNA polymerase II-based siRNA transcription-fine-tuning vectors for straightforward implementation of QuoRex-controlled (trans)gene modulation in mammalian cells.

Sorting vector producer cells for high transgene expression increases retroviral titer

Vector producer cells are derived from helper cell lines expressing viral proteins that have been transduced to express a transgene-carrying retroviral genome. Vector producing cells express two relevant forms of RNA in their cytoplasm: vector RNA (vRNA) that is packaged as the actual gene transfer agent, and messenger RNA (mRNA) from which transgene is translated. Two premises underlie this study: (1) vRNA is limiting for virus production and (2) mRNA is proportional to vRNA. Together, these premises predict that transgene expression in the vector producing cells will be predictive of the viral titer from those cells. In this case, sorting the vector producing cells for high transgene expression should select for more virus production in vector producing cell supernatants. This prediction was supported, with a greater than fivefold benefit in viral titer. This demonstrates a rapid and simple method by which to obtain significantly increased viral titers from the same vector producing cell preparation.

Pluripotentiality and Conditional Transgene Regulation in Human Embryonic Stem Cells Expressing Insulated Tetracycline-ON Transactivator

Conditional manipulation of gene expression by using tetracycline (TET)-ON based approaches has proven invaluable to study fundamental aspects of biology; however, the functionality of these systems in human embryonic stem cells (hESC) has not been established. Given the sensitivity of these cells to both genetic manipulation and variations of culture conditions, constitutive expression of TET transactivators might not only be toxic for hESC but might also impair their ability to self-renew or differentiate into multiple tissues. Therefore, the effect of these transactivators on the biology and pluripotentiality of hESC must first be evaluated before broad use of TET-ON methodologies is applied in these cells. Improved insulated lentivectors that display stable transgene expression and minimal insertional transactivation have been described for hESC. By using insulated lentivectors that allow simultaneous expression of TET components and fluorescent reporters, here we demonstrate that hESC constitutively expressing the TET-ON transactivator rtTA2SM2 can be derived and expanded in culture while retaining inducible transgene expression and pluripotentiality, including marker expression, a normal karyotype, and the ability to generate multiple tissues of different germ layer origin in teratomas. We also show that these cells retain the ability to control the expression of a stable integrated transgene in a doxycycline-dependent manner, which demonstrates that an insulated TET-ON lentiviral system is functional in hESC. Together, our results indicate that improved TET regulators like rtTA2SM2 in combination with insulated lentiviral-based systems offer alternative strategies for conditional gene expression in hESC. Disclosure of potential conflicts of interest is found at the end of this article.

Vitamin H-regulated transgene expression in mammalian cells

Although adjustable transgene expression systems are considered essential for future therapeutic and biopharmaceutical manufacturing applications, the currently available transcription control modalities all require side-effect-prone inducers such as immunosupressants, hormones and antibiotics for fine-tuning. We have designed a novel mammalian transcription-control system, which is reversibly fine-tuned by non-toxic vitamin H (also referred to as biotin). Ligation of vitamin H, by engineered Escherichia coli biotin ligase (BirA), to a synthetic biotinylation signal fused to the tetracycline-dependent transactivator (tTA), enables heterodimerization of tTA to a streptavidin-linked transrepressor domain (KRAB), thereby abolishing tTA-mediated transactivation of specific target promoters. As heterodimerization of tTA to KRAB is ultimately conditional upon the presence of vitamin H, the system is vitamin H responsive. Transgenic Chinese hamster ovary cells, engineered for vitamin H-responsive gene expression, showed high-level, adjustable and reversible production of a human model glycoprotein in bench-scale culture systems, bioreactor-based biopharmaceutical manufacturing scenarios, and after implantation into mice. The vitamin H-responsive expression systems showed unique band pass filter-like regulation features characterized by high-level expression at low (0–2 nM biotin), maximum repression at intermediate (100–1000 nM biotin), and high-level expression at increased (>100 000 nM biotin) biotin concentrations. Sequential ON-to-OFF-to-ON, ON-to-OFF and OFF-to-ON expression profiles with graded expression transitions can all be achieved by simply increasing the level of a single inducer molecule without exchanging the culture medium. These novel expression characteristics mediated by an FDA-licensed inducer may foster advances in therapeutic cell engineering and manufacturing of difficult-to-produce protein therapeutics.

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.

Using cell engineering and omic tools for the improvement of cell culture processes

Significant strides have been made in mammalian cell based biopharmaceutical process and cell line development over the past years. With several established mammalian host cell lines and expression systems, optimization of selection systems to reduce development times and improvement of glycosylation patterns are only some of the advances being made to improve cell culture processes. In this article, the advances pertaining to cell line development and cell engineering strategies are discussed. An overview of the cell engineering strategies to enhance cellular characteristics by genetic manipulation are illustrated, focusing on the use of genomics and proteomics tools and their application in such endeavors. Included in this review are some of the early studies using the 'omic' technique to understand cellular mechanisms of product synthesis and secretion, apoptosis, cell proliferation and the influence of the physicochemical environment. The article highlights the significance of integrating genomics and proteomics data with the vast amounts of bioprocess data for improved analysis of the biological pathways involved. Further improvements of the techniques and methodologies used are needed but ultimately, the new cell engineering strategies should provide great insight into the regulatory networks within the cell in a bioprocess environment and how to manipulate them to increase overall productivity.

Islet cell differentiation in liver by combinatorial expression of transcription factors neurogenin-3, BETA2, and RIPE3b1

Transcription factors, such as PDX-1, that normally mediate pancreatic development are capable of inducing hepatic progenitor cells to differentiate into cells with pancreatic islet characteristics. We hypothesized that simultaneous expression of multiple transcription factors involved in islet development might enhance the differentiation of hepatic progenitor cells. Bi- or tri-cistronic constructs were generated in hybrid adenovirus/adeno-associated virus (Ad/AAV) vectors containing neurogenin 3 (NGN3), BETA2 (NeuroD), and RIPE3b1 (MafA), each of which plays a role in islet cell differentiation. These vectors efficiently express multiple transcription factors and stimulate insulin promoter activity in a combinatorial manner. When these multi-cistronic constructs were administered in vivo, they induce hepatic expression of islet-specific markers, including PDX-1, insulin, glucagon, somatostatin, and islet-amyloid peptide. Administration of the Ad/AAV hybrid vectors to streptozotocin-induced diabetic mice reversed hyperglycemia, consistent the differentiation of functional hepatic insulin-secreting cells. These results indicate that Ad/AAV hybrid vectors can be used to administer combinations of factors that induce islet cell differentiation in hepatic progenitor cells.

Multi-gene engineering: Simultaneous expression and knockdown of six genes off a single platform

Increases in our understanding of gene function have greatly expanded the repertoire of possible genetic interventions at our disposal with the consequence that many genetic engineering applications require multiple manipulations in which target genes can be both overexpressed and silenced in a simple and co-ordinated manner. Using synthetic introns as a source of encoding short-interfering RNA (siRNA), we demonstrate that it is possible to simultaneously express both a transgene and siRNA from a single polymerase (Pol) II promoter. By encoding siRNA as an intron between two protein domains requiring successful splicing for functionality, it was possible to demonstrate that splicing was occurring, that the coding genes (exonic transgenes) resulted in functional protein, and that the spliced siRNA-containing lariat was capable of modulating expression of a separate target gene. We subsequently extended this concept to develop pTRIDENT-based multi-cistronic vectors that were capable of co-ordinated expression of up to three siRNAs and three transgenes off a single genetic platform. Such multi-gene engineering technology, enabling concomitant transgene overexpression and target gene knockdown, should be useful for therapeutic, biopharmaceutical production, and basic research applications.

A novel synthetic mammalian promoter derived from an internal ribosome entry site

Introduction of specific mutations into a synthetic internal ribosome entry site (IRES(GTX)) derived from the GTX homeodomain protein revealed additional transcriptional activity. This novel synthetic P(GTX) promoter exhibited consensus core promoter modules such as the initiator (Inr) and the partial downstream promoter elements (DPE) and mediated high-level expression of a variety of transgenes including the human vascular endothelial growth factor 121 (VEGF(121)), the human placental secreted alkaline phosphatase (SEAP), and the Bacillus stearothermophilus-derived secreted alpha-amylase (SAMY) in Chinese hamster ovary cells (CHO-K1) and a variety of other mammalian and human cell lines. The spacing between Inr and DPE modules was found to be critical for promoter performance since introduction of a single nucleotide (resulting in P(GTX2)) doubled the SEAP expression levels in CHO-K1. P(GTX2) reached near 70% of P(SV40)-driven expression levels and outperformed constitutive phosphoglycerate kinase (P(PGK)) and human ubiquitin C (P(hUBC)) promoters in CHO-K1. Also, P(GTX2) was successfully engineered for macrolide-inducible transgene expression. Owing to its size of only 182 bp, P(GTX2) is one of the smallest eukaryotic promoters. Although P(GTX2) was found to be a potent promoter, it retained its IRES(GTX)-specific translation-initiation capacity. Synthetic DNAs, which combine multiple activities in a most compact sequence format may foster advances in therapeutic engineering of mammalian cells.

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.

Adenoviral vector platform for transduction of constitutive and regulated tricistronic or triple-transcript transgene expression in mammalian cells and microtissues

BACKGROUND

Adenoviral particles can efficiently transduce a broad spectrum of cell types, so they are widely used in basic research and clinical trials.

METHODS

We have developed a novel adenoviral vector platform for delivery of constitutive or streptogramin-inducible expression of up to three therapeutic transgenes into a variety of murine and human cell lines, primary cells and microtissues.

RESULTS

Coordinated expression of three independent transgenes in a compact genetic format was achieved by two different expression configurations: (i) The multicistronic expression format consisting of a single constitutive (simian virus 40 promoter, P(SV40); murine or human cytomegalovirus immediate-early promoter, P(mCMV), P(hCMV)) or regulated (streptogramin-inducible) promoters (P(PIR)ON2) driving the expression of a single multicistronic transcript of which the first cistron is translated in a cap-dependent manner and the two subsequent ones by internal ribosome entry site (IRES)-mediated translation initiation. (ii) The triple-transcript expression configuration, in which a combination of well-established (P(SV40), P(hCMV), P(mCMV)) and novel synthetic constitutive promoters (P(GTX)) control transcription of three expression units. The constitutive multigene expression design enabled coordinated high-level expression of the Bacillus stearothermophilus-derived secreted alpha-amylase (SAMY), the human vascular endothelial growth factor 121 (VEGF(121)) and the human placental secreted alkaline phosphatase (SEAP) in monolayer populations and microtissues of Chinese hamster ovary cells (CHO-K1), human fibrosarcoma cells (HT-1080), primary neonatal rat cardiomyocytes (NRCs) and primary human aortic fibroblasts (HAFs). Streptogramin-inducible tricistronic SAMY-VEGF(121)-SEAP expression provided excellent regulation performance-high-level induction in the presence of the streptogramin antibiotic pristinamycin I (PI), near-undetectable basal expression in the absence of PI, optimal adjustability and perfect reversibility-in all cell types, in particular in NRCs and NRC-derived myocardial microtissues.

CONCLUSIONS

Triple-transcript and tricistronic expression configurations conserve the DNA packaging capacity of the size-constrained viral transduction systems and enable coordinated and regulated expression of up to three therapeutic transgenes for concerted clinical interventions in future gene therapy scenarios.

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.

Conditional MN1-TEL knock-in mice develop acute myeloid leukemia in conjunction with overexpression of HOXA9

The chromosomal translocation t(12; 22)(p13;q11) in human myeloid leukemia generates an MN1-TEL (meningioma 1-translocation-ETS-leukemia) fusion oncoprotein. This protein consists of N-terminal MN1 sequences, a transcriptional coactivator fused to C-terminal TEL sequences, an ETS (E26 transformation-specific) transcription factor. Enforced expression of MN1-TEL in multipotent hematopoietic progenitors in knock-in mice perturbed growth and differentiation of myeloid as well as lymphoid cells. Depending on obligatory secondary mutations, these mice developed T-cell lympholeukemia. Here we addressed the role of MN1-TEL in myeloid leukemogenesis using the same mouse model. Expression of MN1-TEL enhanced the growth of myeloid progenitors in an interleukin 3/stem cell factor (IL-3/SCF)-dependent manner in vitro whereas 10% of MN1-TEL-expressing mice developed altered myelopoiesis with severe anemia after long latency. Coexpression of MN1-TEL and IL-3, but not SCF, rapidly caused a fatal myeloproliferative disease rather than acute myeloid leukemia (AML). Because MN1-TEL+ AML patient cells overexpress HOXA9 (homeobox A9), we tested the effect of coexpression of MN1-TEL and HOXA9 in mice and found that 90% of MN1-TEL+/HOXA9+ mice developed AML much more rapidly than control HOXA9+ mice. Thus, the leukemogenic effect of MN1-TEL in our knock-in mice is pleiotropic, and the type of secondary mutation determines disease outcome.

An mRNA-rRNA base-pairing mechanism for translation initiation in eukaryotes

Base-pairing of messenger RNA to ribosomal RNA is a mechanism of translation initiation in prokaryotes. Although analogous base-pairing has been suggested to affect the translation of various eukaryotic mRNAs, direct evidence has been lacking. To test such base-pairing, we developed a yeast system that uses ribosomes containing a mouse-yeast hybrid 18S rRNA. Using this system, we demonstrate that a 9-nucleotide element found in the mouse Gtx homeodomain mRNA facilitates translation initiation by base-pairing to 18S rRNA. Various point mutations in the Gtx element and in either the hybrid or wild-type yeast 18S rRNAs confirmed the requirement for an intact complementary match. The presence of the Gtx element in various mRNAs suggests that this element affects the translation of groups of mRNAs. We discuss the possibility that other mRNA elements affect translation by base-pairing to different sites in the 18S rRNA.

A picornaviral 2A-like sequence-based tricistronic vector allowing for high-level therapeutic gene expression coupled to a dual-reporter system

The 2A-like sequences from members of the picornavirus family were utilized to construct a tricistronic vector bearing the human iduronidase (IDUA) gene along with the firefly luciferase and DsRed2 reporter genes. The 2A-like sequences mediate a cotranslational cleavage event resulting in the release of each individual protein product. Efficient cleavage was observed and all three proteins were functional in vitro and in vivo, allowing for supratherapeutic IDUA enzyme levels and the coexpression of luciferase and DsRed2 expression, which enabled us to track gene expression.

MN1-TEL myeloid oncoprotein expressed in multipotent progenitors perturbs both myeloid and lymphoid growth and causes T-lymphoid tumors in mice

The MN1-TEL (meningioma 1-translocation-ETS-leukemia) fusion oncoprotein is the product of the t(12;22)(p13;q11) in human myeloid leukemia consisting of N-terminal MN1 sequences, a transcriptional coactivator, fused to C-terminal TEL sequences, an E26-transformation-specific (ETS) transcription factor. To analyze the role of MN1-TEL in leukemogenesis, we created a site-directed transgenic (knock-in) mouse model carrying a conditional MN1-TEL transgene under the control of the Aml1 regulatory sequences. After induction, MN1-TEL expression was detected in both myeloid and lymphoid cells. Activation of MN1-TEL expression enhanced the repopulation ability of myeloid progenitors in vitro as well as partially inhibited their differentiation in vivo. MN1-TEL also promoted the proliferation of thymocytes while it blocked their differentiation from CD4-/CD8- to CD4+/CD8+ in vivo. After long latency, 30% of the MN1-TEL-positive mice developed T-lymphoid tumors. This process was accelerated by N-ethyl-N-nitrosourea-induced mutations. MN1-TEL-positive T-lymphoid tumors showed elevated expression of the Notch-1, Hes-1, c-Myc, and Lmo-2 genes while their Ink4a/pRB and Arf/p53 pathways were impaired, suggesting that these alterations cooperatively transform T progenitors. We conclude that MN1-TEL exerts its nonlineage-specific leukemogenic effects by promoting the growth of primitive progenitors and blocking their differentiation, but cooperative mutations are necessary to fully induce leukemic transformation.

Autoregulated, bidirectional and multicistronic gas-inducible mammalian as well as lentiviral expression vectors

We present a novel set of autoregulated, bidirectional and multicistronic mammalian as well as lentiviral expression vectors which enable transgene expression fine-tuning by gaseous acetaldehyde. The acetaldehyde-inducible regulation (AIR) technology capitalizes on Aspergillus nidulans components evolved to convert ethanol into metabolic energy. AIR is based on functional interaction of the fungal transactivator AlcR and AlcR-specific chimeric promoters (P(AIR)) which drive desired transgene expression in mammalian cells only in the presence of gaseous acetaldehyde. We have engineered AIR technology into a variety of different mammalian and lentiviral expression vector systems including (i) a most compact autoregulated expression format harboring alcR and the transgene in a single P(AIR)-driven transcription unit, (ii) a bidirectional P(AIR) derivative supporting expression of two transgenes with strict 1:1 transcription stoichiometry and (iii) a multicistronic expression arrangement providing simultaneous translation of three independent transgenes from a single P(AIR)-controlled transcript. All expression vectors have been validated in Chinese hamster ovary (CHO-K1), baby hamster kidney (BHK-21) and human HeLa cells for gas-inducible (co-)expression of the reporter transgenes such as Bacillus stearothermophilus-derived secreted alpha-amylase (SAMY), human vascular endothelial growth factor 121 (VEGF121), human placental-secreted alkaline phosphatase (SEAP) and Escherichia coli-derived chloramphenicol acetyl-transferase (CAT). The panoply of mammalian/lentiviral vectors presented here provides a robust and versatile expression platform for the first gas-inducible transgene control system which we expect to foster future advances in gene therapy, tissue engineering as well as biopharmaceutical manufacturing.

Toward construction of a self-sustained clock-like expression system based on the mammalian circadian clock

Despite recent advances in circadian biology, detailed understanding of how a biological pacemaker system is assembled, maintained, and regulated continues to be a significant challenge. We have assembled and characterized a first-generation, regulatable, self-sustained clock-like expression system based on key components of the mammalian circadian clock. The molecular setup of the clock-like oscillator was reduced to the core set of positive and negative elements common to all known circadian pacemakers. Sophisticated tetracycline-responsive multi-cistronic expression integrated with forefront lentiviral transduction tools enabled autoregulated reporter transgene expression in a human cell line. We characterized transgene expression kinetics of an artificial oscillator and showed that its expression profiles could be modulated by a serum shock and administration of regulating tetracycline antibiotics. Design of a generic mammalian clock-like expression system will offer novel opportunities to study circadian biology and may provide a unique tool for rhythmic expression of desired transgenes fostering advances in biopharmaceutical manufacturing, gene therapy, and tissue engineering.