Acute inflammation follows defined phases of induction, inflammation and resolution, and resolution occurs by an active process that requires cyclooxygenase-2 (COX-2) activity. This study aims to address whether this paradigm extends to recognized model of chronic inflammation. We demonstrated that murine collagen-induced arthritis follows a similar sequential course. Interestingly, COX-2 and its metabolite, the presumably proinflammatory PGE2, are present in the joints during resolution, and blocking COX-2 activity and PGE2 production within this period perpetuated, instead of attenuated, inflammation. Repletion with PGE2 analogs restored homeostasis, and this function is mediated by the proresolving lipoxygenase metabolite, lipoxin A4, a potent stop signal. Thus, the study provided in vivo evidence for a natural, endogenous link between the cyclooxygenase–lipoxygenase pathways and showed that PGE2 serves as a feedback inhibitor essential for limiting chronic inflammation in autoimmune arthritis. These findings may explain the enigma regarding why COX-2 inhibitors are palliative rather than curative in humans, because blocking resolution may mitigate the benefit of preventing induction.
Drawing on what we learned from the impact of SARS on our hospital, we had the opportunity to improve our organization's preparedness for the pandemic. Our results suggest that an evidence-based approach to interventions that target known mediators of distress and meet standards of continuing professional development is not only possible and relevant, but readily supportable by senior hospital administration.
The single-stranded genome of adeno-associated viral (AAV) vectors is one of the key factors leading to slowrising but long-term transgene expression kinetics. Previous molecular studies have established what is now considered a textbook molecular model of AAV genomes with two copies of inverted tandem repeats at either end. In this study, we profiled hundreds of thousands of individual molecules of AAV vector DNA directly isolated from capsids, using single-molecule sequencing (SMS), which avoids any intermediary steps such as plasmid cloning. The sequence profile at 3¢ ends of both the regular and oversized vector did show the presence of an inverted terminal repeat (ITR), which provided direct confirmation that AAV vector packaging initiates from its 3¢ end. Furthermore, the vector 5¢-terminus profile showed inconsistent termination for oversized vectors. Such incomplete vectors would not be expected to undergo canonical synthesis of the second strand of their genomic DNA and thus could function only via annealing of complementary strands of DNA. Furthermore, low levels of contaminating plasmid DNA were also detected. SMS may become a valuable tool during the development phase of vectors that are candidates for clinical use and for facilitating/accelerating studies on vector biology.
Recombinant adeno-associated viral (rAAV) vectors have gained attention for human gene therapy because of their high safety and clinical efficacy profile. For factor VIII gene delivery, splitting the coding region between two AAV vectors remains a viable strategy to avoid the packaging capacity limitation (*5.0 kb). However, it is time-consuming and labor-intensive to produce two rAAV vectors in separate batches. Here we demonstrated successful production of dual rAAV vectors for hemophilia A gene therapy in a single preparation. When the AAV vector plasmids carrying the human factor VIII heavy chain (hHC) and the light chain (hLC) expression cassettes were cotransfected into 293 cells along with the AAV rep&cap and mini-adenovirus helper plasmids, both rAAV-hHC and rAAV-hLC were produced at the desired ratio and in high titer. Interestingly, the rAAVhHC vectors always yielded higher titers than rAAV-hLC vectors as a result of more efficient replication of rAAV-hHC genomes. The resulting vectors were effective in transducing the tissue culture cells in vitro. When these vectors were administered to hemophilia A mice, factor VIII was detected in the mouse plasma by both the activated partial thromboplastin time assay and enzyme-linked immunosorbent assay. The functional activity as well as the antigen levels of secreted factor VIII were similar to those of vectors produced by the traditional method. The dual-vector production method has been successfully extended to both AAV2 and AAV8 serotypes. In conclusion, cotransfection of vector plasmids presents an efficient method for producing dual or multiple AAV vectors at significantly reduced cost and labor.
Scalable and efficient production of high-quality recombinant adeno-associated virus (rAAV) for gene therapy remains a challenge despite recent clinical successes. We developed a new strategy for scalable and efficient rAAV production by sequestering the AAV helper genes and the rAAV vector DNA in two different subcellular compartments, made possible by using cytoplasmic vaccinia virus as a carrier for the AAV helper genes. For the first time, the contamination of replication-competent AAV particles (rcAAV) can be completely eliminated in theory by avoiding ubiquitous nonhomologous recombination. Vector DNA can be integrated into the host genomes or delivered by a nuclear targeting vector such as adenovirus. In suspension HeLa cells, the achieved vector yield per cell is similar to that from traditional triple-plasmid transfection method. The rcAAV contamination was undetectable at the limit of our assay. Furthermore, this new concept can be used not only for production of rAAV, but also for other DNA vectors.
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