Generation and annotation of the DNA sequences of human chromosomes 2 and 4.

Human chromosome 2 is unique to the human lineage in being the product of a head-to-head fusion of two intermediate-sized ancestral chromosomes. Chromosome 4 has received attention primarily related to the search for the Huntington's disease gene, but also for genes associated with Wolf-Hirschhorn syndrome, polycystic kidney disease and a form of muscular dystrophy. Here we present approximately 237 million base pairs of sequence for chromosome 2, and 186 million base pairs for chromosome 4, representing more than 99.6% of their euchromatic sequences. Our initial analyses have identified 1,346 protein-coding genes and 1,239 pseudogenes on chromosome 2, and 796 protein-coding genes and 778 pseudogenes on chromosome 4. Extensive analyses confirm the underlying construction of the sequence, and expand our understanding of the structure and evolution of mammalian chromosomes, including gene deserts, segmental duplications and highly variant regions.

Enhanced protein production using HBV X protein (HBx), and synergy when used in combination with XBP1s in BHK21 cells.

The demand of therapeutic protein production from mammalian cells has expanded greatly since the first biologic was approved in 1982. It remains a major challenge to exploit the exocytic pathway and increase cell viability during the production process. Hepatitis B virus X protein (HBx) is a multifunctional viral transcription activator that regulates a variety of cellular events including transcription, cell cycle and proliferation, survival, and apoptosis. As such it may address some of the current production challenges. In this study we demonstrate that HBx can enhance protein production during transient transfection and in stable cell lines. XBP1s is a potent transcription factor and has been demonstrated to enlarge the ER secretion pathway and increase protein production. We explored the possibility of combinational engineering of HBx with XBP1s in BHK21 cells. Our data revealed that combinational engineering of HBx with XBP1s further enhances protein production compared with HBx or XBP1s alone.

The DNA sequence of human chromosome 7.

Human chromosome 7 has historically received prominent attention in the human genetics community, primarily related to the search for the cystic fibrosis gene and the frequent cytogenetic changes associated with various forms of cancer. Here we present more than 153 million base pairs representing 99.4% of the euchromatic sequence of chromosome 7, the first metacentric chromosome completed so far. The sequence has excellent concordance with previously established physical and genetic maps, and it exhibits an unusual amount of segmentally duplicated sequence (8.2%), with marked differences between the two arms. Our initial analyses have identified 1,150 protein-coding genes, 605 of which have been confirmed by complementary DNA sequences, and an additional 941 pseudogenes. Of genes confirmed by transcript sequences, some are polymorphic for mutations that disrupt the reading frame.

Characterization of virus-like particle assembly for DNA delivery using asymmetrical flow field-flow fractionation and light scattering.

This study illustrates the application of asymmetrical flow field-flow fractionation (AF4) and light scattering analysis during the development of a gene delivery vehicle based on virus-like particles (VLPs) derived from the human polyoma JC virus. The analytical system was created by connecting an AF4 apparatus to the following detectors: diode array, fluorescence, multiangle light scattering, dynamic light scattering, and refractometer. From a single analysis, the molar mass, root mean square and hydrodynamic radii, composition, and purity of the sample could be determined. The VLPs were purified from baculovirus-infected Sf158 insect cells overexpressing the recombinant VP1 protein using weak anion exchange chromatography. The VLPs were dissociated to VP1 pentamers, and the contaminating DNA and proteins were removed using strong anion exchange chromatography. The gene delivery vehicle was created by reassembling the VP1 pentamers in the presence of the desired DNA. The newly formed VLPs encapsulated the DNA and were shown to be capable of delivering the gene of interest to target cells where it was translated into protein. This paper describes the scalable process that was derived to produce the VLPs and demonstrates how the AF4-based analytical characterization was indispensable during the development process.

Development and validation of a robust and versatile one-plasmid regulated gene expression system.

We have developed a one-plasmid regulated gene expression system, pBRES, based on a mifepristone (MFP)-inducible two-plasmid system. The various expression elements of the pBRES system (promoters, 5' and 3' untranslated regions (UTRs), introns, target gene, and polyA sequences) are bounded by restriction enzyme sites so that each module can be conveniently replaced by alternate DNA elements in order to tailor the system for particular tissues, organs, or conditions. There are four possible orientations of the two expression units relative to each other, and insertion of a variety of expression elements and target genes into the four different orientations revealed orientation- and gene-dependent effects on induced and uninduced levels of gene expression. Induced target gene expression from the pBRES system was shown to be comparable to the two-plasmid system and higher than the expression from the cytomegalovirus (CMV) promoter in vivo, while maintaining low uninduced levels of expression. Finally, a pBRES expression cassette was transferred to an adeno-associated virus (AAV) vector and shown to be capable of regulated gene expression in vivo for nearly 1 year.

Mx1 and IP-10: biomarkers to measure IFN-beta activity in mice following gene-based delivery.

Recombinant interferon-beta (IFN-beta) protein is used successfully for the treatment of multiple sclerosis (MS). Gene therapy might be an alternative approach to overcome drawbacks occurring with IFN-beta protein therapy. A critical issue in developing a new approach is detection of biologically active IFN-beta in preclinical models. The goal of the present study was to determine if Mx1 and IP-10, which are known to be activated after IFN-beta treatment in humans, can be used as biomarkers in mice. In three in vivo experiments, the correlation between different methods of murine IFN-beta (MuIFN-beta) delivery and biomarker induction was studied: (1) bolus protein delivery by intravenous (i.v.) or intramuscular (i.m.) injection, (2) gene-based delivery of IFN- beta by i.m. injection of plasmid DNA, followed by electroporation, and (3) gene-based delivery of IFN-beta by i.m. injection of adenovirus-associated type 1 (AAV1). Short-term induction of Mx1 mRNA and IP-10 was observed after treatment with bolus MuIFN-beta protein. Long-term induction of both biomarkers was observed after IFN-beta plasmid DNA delivery or when AAV1 was used as the vector. The experiments demonstrate that gene-based delivery provides sustained levels of IFN-beta compared with bolus protein injection and that Mx1 RNA and IP-10 can be used to monitor biologically active circulating plasma MuIFN-beta protein in mice.

Gene-based delivery of IFN-beta is efficacious in a murine model of experimental allergic encephalomyelitis.

Experimental allergic encephalomyelitis (EAE) is a model of central nervous system (CNS) inflammation that follows immunization with certain CNS antigens. The course and clinical manifestations of EAE are similar to those of multiple sclerosis (MS) in humans; therefore, EAE has become an accepted animal model to study MS. The purpose of this study was to demonstrate that systemic expression of murine interferon-beta (IFN-beta) (MuIFN-beta), following intramuscular (i.m.) delivery of plasmid DNA encoding MuIFN-beta to the hind limb of mice, is effective in reducing the clinical manifestations of disease in a model of EAE. The results of the study demonstrate that gene-based delivery of MuIFN-beta caused significantly decreased clinical scores compared with delivery of the null vector. A single injection of the MuIFN-beta plasmid was as effective in reducing the severity of the disease as an every other day injection of MuIFN-beta protein.

Development and validation of an improved inducer-regulator protein complex in the pBRES-regulated expression system.

Widespread adaptation of small molecule-regulated expression systems requires the development of selective inducer molecules that do not have any significant side effects on the endogenous receptors from which the regulated expression system is derived. Here we report the identification and in vitro validation of a novel inducer-receptor pair for the single-plasmid regulated expression system termed pBRES, which contains the ligand-binding domain from the human progesterone receptor (hPR). A small molecule inducer, BLX-913, has been identified as having a 30-fold lower IC(50) for the human progesterone receptor than mifepristone (MFP), the previously best characterized inducer for pBRES. Using modeling-guided protein engineering, compensatory mutations were installed at positions W755 and V729 (hPR numbering) in the ligand-binding pocket of the pBRES regulator protein (pBRES RP) to accommodate the new inducer and allow induction of transgene expression to levels previously seen with MFP. The improved inducer-pBRES RP complex was validated in vitro by monitoring the induction of luciferase, murine secreted alkaline phosphatase, and human interferon beta transgenes in mouse skeletal muscle cells. The engineered pBRES demonstrated low levels of transgene expression in the absence, and high expression levels in the presence, of the new BLX-913 inducer. Findings presented here allow induction of the pBRES-regulated gene expression system by a compound with markedly lower anti-hPR activity than MFP, the previously best characterized inducer.

Directed evolution generates a novel oncolytic virus for the treatment of colon cancer.

BACKGROUND: Viral-mediated oncolysis is a novel cancer therapeutic approach with the potential to be more effective and less toxic than current therapies due to the agents selective growth and amplification in tumor cells. To date, these agents have been highly safe in patients but have generally fallen short of their expected therapeutic value as monotherapies. Consequently, new approaches to generating highly potent oncolytic viruses are needed. To address this need, we developed a new method that we term "Directed Evolution" for creating highly potent oncolytic viruses. METHODOLOGY/PRINCIPAL FINDINGS: Taking the "Directed Evolution" approach, viral diversity was increased by pooling an array of serotypes, then passaging the pools under conditions that invite recombination between serotypes. These highly diverse viral pools were then placed under stringent directed selection to generate and identify highly potent agents. ColoAd1, a complex Ad3/Ad11p chimeric virus, was the initial oncolytic virus derived by this novel methodology. ColoAd1, the first described non-Ad5-based oncolytic Ad, is 2-3 logs more potent and selective than the parent serotypes or the most clinically advanced oncolytic Ad, ONYX-015, in vitro. ColoAd1's efficacy was further tested in vivo in a colon cancer liver metastasis xenograft model following intravenous injection and its ex vivo selectivity was demonstrated on surgically-derived human colorectal tumor tissues. Lastly, we demonstrated the ability to arm ColoAd1 with an exogenous gene establishing the potential to impact the treatment of cancer on multiple levels from a single agent. CONCLUSIONS/SIGNIFICANCE: Using the "Directed Evolution" methodology, we have generated ColoAd1, a novel chimeric oncolytic virus. In vitro, this virus demonstrated a >2 log increase in both potency and selectivity when compared to ONYX-015 on colon cancer cells. These results were further supported by in vivo and ex vivo studies. Furthermore, these results have validated this methodology as a new general approach for deriving clinically-relevant, highly potent anti-cancer virotherapies.

Transcriptional silencing is associated with extensive methylation of the CMV promoter following adenoviral gene delivery to muscle.

BACKGROUND: Although the transient nature of transgene expression using first-generation adenovirus (Ad) vectors is well known, the exact mechanisms responsible for this phenomenon are uncertain. METHODS: Rats were given intramuscular (i.m.) injections of a first-generation Ad containing the human fibroblast growth factor 4 (hFGF-4) gene driven by the cytomegalovirus (CMV) promoter and enhancer (CMV-PE). The copy number of hFGF-4 mRNA and viral DNA was measured in the same muscles by quantitative RT-PCR and quantitative PCR at times between 1 h and 84 days after virus injection. Quantitative Southern blot analysis for the intact hFGF-4 transcription unit DNA was also performed, and the methylation status of the CMV-PE DNA in the muscle was determined using bisulfite sequencing. RESULTS: The copy number of hFGF-4 mRNA peaked at 6 h then decreased 56-fold by 24 h, and a further 240-fold between days 3 and 28. Although the viral DNA copy number also decreased 23-fold between 6 h and 28 days, the ratio of copies of hFGF-4 mRNA per copy of viral DNA decreased 385-fold over this period. Methylation of the CMV-PE DNA in the muscle at both CpG and non-CpG sites was observed 24 h after virus administration and had increased at day 7. CONCLUSIONS: Decreased transcription associated with extensive methylation of the CMV-PE was the major mechanism responsible for the decrease in transgene mRNA levels. Strategies for preventing transcriptional silencing will be valuable for improving the duration of transgene expression from adenoviral vectors.