Use of the permitted daily exposure (PDE) concept for contaminants of intravitreal (IVT) drugs in multipurpose manufacturing facilities.

A toxicological evaluation to determine the product specific permitted daily exposure (PDE) value is an accepted method to determine a safe limit for the carry-over of product residues in multipurpose manufacturing facilities. The PDE calculation for intravitreal (IVT) injection of small and large molecular weight (MW) drugs follows the guiding principles set for systemic administration. However, there are specific differences with respect to the volume administered with IVT administration, pharmacokinetic and pharmacodynamics (PK-PD) parameters and potential for toxicity. In this publication, we have proposed a method to derive PDEIVT in the presence of IVT dose. In the absence of an IVT dose we have a proposed default extrapolationof the systemic PDE for intravenous (IV) administration to the PDEIVT dose by applying a factor of 500 based on comparison of the volume of vitreous humour with the plasma volume, as well as provided examples for PK-PD and toxicity considerations.

Recombinant protein production by transient gene transfer into Mammalian cells.

The timely availability of recombinant proteins in sufficient quantity and of validated quality is of utmost importance in driving drug discovery and the development of low molecular weight compounds, as well as for biotherapeutics. Transient gene expression (TGE) in mammalian cells has emerged as a promising technology for protein generation over the past decade as TGE meets all the prerequisites with respect to quantity and quality of the product as well as cost-effectiveness and speed of the process. Optimized protocols have been developed for both HEK293 and CHO cell lines which allow protein production at any desired scale up to >100 l and in milligram to gram quantities. Along with an overview on current scientific and technological knowledge, detailed protocols for expression of recombinant proteins on small, medium, and large scale are discussed in the following chapter.

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.

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.

A novel mammalian cell-based approach for the discovery of anticancer drugs with reduced cytotoxicity on non-dividing cells.

A key asset of cytotoxic drugs in cancer therapeutics is their ability to discriminate between proliferating and mitotically inert cells and eliminate preferentially neoplastic ones. We have designed a high throughput-compatible mammalian cell-based assay for the discovery of cytotoxic drugs, which selectively kill proliferation-competent target cells. This cytotoxic drug discovery assay is based on a transgenic CHO-K1-derived cell line engineered for a conditional G1-specific growth arrest following tetracycline-responsive overexpression of the human cyclin-dependent kinase inhibitor p27(Kip1). The CHO-derived cell line CHO-p27(Kip1) shows wild type proliferation rates and can be expanded in the presence of tetracycline antibiotics when p27(Kip1) expression is repressed. Upon withdrawal of regulating antibiotics CHO-p27(Kip1) differentiates into a 1:1 mixed population consisting of two different proliferation phenotypes: (i) a G1-arrested cell population induced by heterologous expression of p27(Kip1) which mimics mitotically inactive terminally differentiated cells and (ii) a proliferation-competent cell population which eliminated the p27(Kip1) expression unit and imitates neoplastic cell characteristics. Addition of chemical or metabolic libraries to CHO-p27(Kip1) populations cultivated in tetracycline-free medium followed by scoring for cell viability will reveal cytotoxic drug candidates associated with a high viability ratio of proliferation-competent/arrested populations. We have validated the cell-based cytotoxic drug discovery assay using the clinically licensed cancer drugs mitomycin C, doxorubicin, etoposide and 5-fluorouracil. Comparative proof-of-concept studies showed that these top-prescribed cancer therapeutics preferentially eliminate proliferating cells while showing less interference with the viability of G1-arrested cell populations. These results demonstrate the CHO-p27(Kip1)-based cytotoxic drug finder technology is ready-to-apply for high throughput screenings of chemical as well as metabolic libraries to discover novel cancer therapeutics which show reduced cytotoxicity on terminally differentiated cells.

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

Capitalizing on a proven multicistronic expression vector platform we have designed novel pTRIDENT vectors which (1). enable coordinated expression of three desired transgenes, (2). are size-optimized, (3). take advantage of small highly efficient internal ribosome entry sites of the GTX or Rbm3 type, (4). harbor various sites specific for homing endonucleases facilitating promoter/multicistronic expression unit/polyadenylation site swapping as well as (5). straightforward integration into human HIV-l-based lentiviral expression vectors tailored to contain compatible homing endonucleases. Multicistronic expression profiles of novel pTRIDENT vectors engineered for different tricistronic expression configurations encoding human low-molecular-weight urokinase-type plasminogen activator (u-PA(LMW)) or Bacillus stearothermophilus-derived alpha-amylase (SAMY), human vascular endothelial growth factor (hVEGF), and human placental secreted alkaline phosphatase (SEAP) have been quantified in Chinese hamster ovary cells (CHO-K1), mouse fibroblasts (NIH/3T3), and/or human fibrosarcoma (HT-1080) cells. In addition, a pTRIDENT-derived SAMY-VEGF-SEAP expression cassette transferred into a compatible lentiviral expression vector enabled simultaneous high-level transgene expression following transduction of transgenic lentiviral particles into primary human chondrocytes.

Dual-regulated expression of C/EBP-alpha and BMP-2 enables differential differentiation of C2C12 cells into adipocytes and osteoblasts.

CCAAT/enhancer-binding proteins (C/EBPs) as well as bone morphogenic proteins (BMPs) play essential roles in mammalian cell differentiation in shaping adipogenic and osteoblastic lineages in particular. Recent evidence suggested that adipocytes and osteoblasts share a common mesenchymal precursor cell phenotype. Yet, the molecular details underlying the decision of adipocyte versus osteoblast differentiation as well as the involvement of C/EBPs and BMPs remains elusive. We have engineered C2C12 cells for dual-regulated expression of human C/EBP-alpha and BMP-2 to enable independent transcription control of both differentiation factors using clinically licensed antibiotics of the streptogramin (pristinamycin) and tetracycline (tetracycline) classes. Differential as well as coordinated expression of C/EBP-alpha and BMP-2 revealed that (i) C/EBP-alpha may differentiate C2C12 myoblasts into adipocytes as well as osteoblasts, (ii) BMP-2 prevents myotube differentiation, (iii) is incompetent in differentiating C2C12 into osteoblasts and (iv) even decreases C/EBP-alpha's osteoblast-specific differentiation potential but (v) cooperates with C/EBP-alpha on adipocyte differentiation, (vi) osteoblast formation occurs at low C/EBP-alpha levels while adipocyte-specific differentiation requires maximum C/EBP-alpha expression and that (vii) BMP-2 may bias the C/EBP-alpha-mediated adipocyte versus osteoblast differentiation switch towards fat cell formation. Dual-regulated expression technology enabled precise insight into combinatorial effects of two key differentiation factors involved in adipocyte/osteoblast lineage control which could be implemented in rational reprogramming of multipotent cells into desired cell phenotypes tailored for gene therapy and tissue engineering.

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.

Identification of a novel proliferation-inducing determinant using lentiviral expression cloning.

One of the major challenges in the post-genome era is the correlation between genes and function or phenotype. We have pioneered a strategy for screening of cDNA libraries, which is based on sequential combination of lentiviral and oncoretroviral expression systems and can be used to identify proliferation-modulating genes. Screening of a lentiviral expression library derived from adult human brain cDNA resulted in cloning of the potent proliferation-inducing determinant termed pi1 (proliferation inducer 1). Transduction experiments using GFP-expressing oncoretroviruses to target proliferation-competent cells suggested that overexpression of pi1 initiates proliferation of human umbilical vein endothelial cells (HUVECs). Growth induction of HUVECs as well as Swiss3T3 fibroblasts was confirmed by Brd-uridine incorporation assays, which correlated increased DNA synthesis with expression of pi1. The identified pi1 cDNA is 297 bp long and encodes a 10 kDa polypeptide. Since deregulation of proliferation control accounts for a number of today's untreatable human diseases such as neurodegenerative disorders and cancer, discovery of novel proliferation-modulating genes is essential for developing new strategies for gene therapy and tissue engineering.

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.

Toward higher order control modalities in mammalian cells-independent adjustment of two different gene activities.

Heterologous higher order control modalities will be important tools for targeted multigene interventions in next-generation gene therapy, tissue engineering, and sophisticated gene-function studies. In this study, we present the design and rigorous quantitative analysis of a variety of different dual-regulated gene transcription control configurations combining streptogramin- and tetracycline-responsive expression systems in a one-vector format. Quantitative assessment of dual-regulated expression performance in various mammalian and human cell lines is based on two compatible secreted reporter genes, SEAP, the human placental secreted alkaline phosphatase, and the recently developed SAMY, the secreted alpha-amylase. Assembly of streptogramin- and tetracycline-responsive transgene control units in consecutive (--> -->), divergent (<-- -->), and convergent (--> <--) orientation showed excellent regulation characteristics in most genetic arrangements exemplified by neglectable interference and high transgene induction ratios in all four control settings (ON/ON, OFF/ON, ON/OFF, OFF/OFF). The overall regulation performance of divergent dual-regulated expression configurations could be substantially increased when placing noncoding stuffer fragments or insulator modules between the divergently oriented antibiotic-responsive promoters. Dual-regulated expression technology pioneers artificial higher order gene control networks that will likely enable new opportunities in multigene metabolic engineering and generate significant therapeutic impact.

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

BACKGROUND: The recently developed heterologous macrolide- (E.REX system) and streptogramin- (PIP system) responsive gene regulation systems show significant differences in their regulation performance in diverse cell lines. METHODS: In order to provide optimal regulation modalities for a wide variety of mammalian cell lines, we have performed a detailed analysis of E.REX and PIP systems modified in (i) the transactivation domains of the antibiotic-dependent transactivators, (ii) the type of minimal promoter used, and (iii) the spacing between the operator module and the minimal promoter. RESULTS: These novel E.REX and PIP regulation components showed not only dramatically improved regulation performance in some cell types, but also enabled their use in cell lines which had previously been inaccessible to regulated transgene expression. CONCLUSIONS: Due to their modular set-up the novel E.REX and PIP regulation systems presented here are most versatile and ready for future upgrades using different cell-specific key regulation components.

Macrolide-based transgene control in mammalian cells and mice.

Heterologous mammalian gene regulation systems for adjustable expression of multiple transgenes are necessary for advanced human gene therapy and tissue engineering, and for sophisticated in vivo gene-function analyses, drug discovery, and biopharmaceutical manufacturing. The antibiotic-dependent interaction between the repressor (E) and operator (ETR) derived from an Escherichia coli erythromycin-resistance regulon was used to design repressible (E(OFF)) and inducible (E(ON)) mammalian gene regulation systems (E.REX) responsive to clinically licensed macrolide antibiotics (erythromycin, clarithromycin, and roxithromycin). The E(OFF) system consists of a chimeric erythromycin-dependent transactivator (ET), constructed by fusing the prokaryotic repressor E to a eukaryotic transactivation domain that binds and activates transcription from ETR-containing synthetic eukaryotic promoters (P(ETR)). Addition of macrolide antibiotic results in repression of transgene expression. The E(ON) system is based on E binding to artificial ETR-derived operators cloned adjacent to constitutive promoters, resulting in repression of transgene expression. In the presence of macrolides, gene expression is induced. Control of transgene expression in primary cells, cell lines, and microencapsulated human cells transplanted into mice was demonstrated using the E.REX (E(OFF) and E(ON)) systems. The macrolide-responsive E.REX technology was functionally compatible with the streptogramin (PIP-regulated and tetracycline (TET-regulated expression systems, and therefore may be combined for multiregulated multigene therapeutic interventions in mammalian cells and tissues.