Enhancing viral vaccine production using engineered knockout vero cell lines - A second look.

The global adoption of vaccines to combat disease is hampered by the high cost of vaccine manufacturing. The work described herein follows two previous publications (van der Sanden et al., 2016; Wu et al., 2017) that report a strategy to enhance poliovirus and rotavirus vaccine production through genetic modification of the Vero cell lines used in large-scale vaccine manufacturing. CRISPR/Cas9 gene editing tools were used to knockout Vero target genes previously shown to play a role in polio- and rotavirus production. Subsequently, small-scale models of current industry manufacturing systems were developed and adopted to assess the increases in polio- and rotavirus output by multiple stable knockout cell lines. Unlike previous studies, the Vero knockout cell lines failed to achieve desired target yield increases. These findings suggest that additional research will be required before implementing the genetically engineered Vero cell lines in the manufacturing process for polio- and rotavirus vaccines to be able to supply vaccines at reduced prices.

Highly efficient targeted transduction of undifferentiated human hematopoietic cells by adenoviral vectors displaying fiber knobs of subgroup B.

Human hematopoietic stem cells (HSCs) are poorly transduced by vectors based on adenovirus serotype 5 (Ad5). This is primarily due to the paucity of the coxsackievirus-Ad receptor on these cells. In an attempt to change the tropism of Ad5, we constructed a series of chimeric E1-deleted Ad5 vectors in which the shaft and knob of the capsid fibers were exchanged with those of other Ad serotypes. In all these vectors, the Ad E1 region was replaced by an expression cassette containing the cytomegalovirus immediate-early promoter and the gene for enhanced green fluorescent protein (GFP). Experiments performed in vitro showed an efficient transduction of umbilical cord blood (UCB) monocytes, granulocytes, and their precursors as well as the undifferentiated CD34(+) CD33(-) CD38(-) CD71(-) cells by Ad5 vectors carrying Ad subgroup B-specific fiber chimeras (Ad5FBs). In the latter subpopulation, which comprises less than 1% of the CD34(+) cells and is highly enriched with cells repopulating immunodeficient mice, more than 90% of the cells were GFP(+). Transduction by Ad5FBs of the less primitive fraction within UCB CD34(+) cells was significant lower. Actually, the transduction frequency and GFP level declined gradually with increased expression of the CD33, CD38, and CD71 antigens. Flow cytometric analysis of transduced UCB CD34(+) cells that were cultured for 5 days on an allogeneic human bone marrow stroma layer showed maintenance of the phenotypically defined HSCs at levels similar to those of control cultures. The latter finding indicates that neither the transduction procedure nor the high levels of GFP were toxic for these cells.

Infection efficiency of type 5 adenoviral vectors in synovial tissue can be enhanced with a type 16 fiber.

OBJECTIVE: To obtain an adenoviral vector with increased infection efficiency in the synovial tissue compared with conventional vectors based on adenovirus serotype 5 (Ad5), without compromising the specificity of infection. METHODS: Coxsackie adenovirus receptor (CAR) expression was assessed in cultured synoviocytes. Chimeric adenoviruses based on Ad5 but carrying the DNA encoding the fiber of adenovirus from subgroup B (Adll, 16, 35) or D (Ad24, 28, 33, 45, or 47) were constructed and produced on PER.C6 cells. The gene transfer efficiency of these chimera was tested on cultured synoviocytes and peripheral blood mononuclear cells (PBMC). RESULTS: No surface expression of CAR protein was observed on synoviocytes. CAR messenger RNA expression of synoviocytes was found to be low. Of all fiber chimeric vectors tested, vectors carrying the fiber of Ad16 (Ad5.fib16) were most potent, yielding approximately150 times increased transgene expression in cultured synoviocytes compared with those of Ad5. Flow cytometry showed that the increase in transgene expression was caused by the transduction of higher percentages of synoviocytes and higher gene expression per synoviocyte. Experiments with 500 virus particles/cell of Ad5.GFP or Ad5.fib16.GFP resulted in an infection efficiency of 0.6% and 1% in PBMC and 43% and 76% in synoviocytes, respectively. CONCLUSION: Synoviocytes hardly express CAR, which hampers Ad5-mediated gene transfer. Ad5.fib16 is superior to Ad5 vectors for transducing synoviocytes, without compromising the specificity of infection. Our data suggest that Ad5.fib16-mediated gene transfer to synovial tissue improves the therapeutic window.

Improved adenovirus vectors for infection of cardiovascular tissues.

To identify improved adenovirus vectors for cardiovascular gene therapy, a library of adenovirus vectors based on adenovirus serotype 5 (Ad5) but carrying fiber molecules of other human serotypes, was generated. This library was tested for efficiency of infection of human primary vascular endothelial cells (ECs) and smooth muscle cells (SMCs). Based on luciferase, LacZ, or green fluorescent protein (GFP) marker gene expression, several fiber chimeric vectors were identified that displayed improved infection of these cell types. One of the viruses that performed particularly well is an Ad5 carrying the fiber of Ad16 (Ad5.Fib16), a subgroup B virus. This virus showed, on average, 8- and 64-fold-increased luciferase activities on umbilical vein ECs and SMCs, respectively, compared to the parent vector. GFP and lacZ markers showed that approximately 3-fold (ECs) and 10-fold (SMCs) more cells were transduced. Experiments performed with both cultured SMCs and organ cultures derived from different vascular origins (saphenous vein, iliac artery, left interior mammary artery, and aorta) and from different species demonstrated that Ad5.Fib16 consistently displays improved infection in primates (humans and rhesus monkeys). SMCs of the same vessels of rodents and pigs were less infectable with Ad5.Fib16 than with Ad5. This suggests that either the receptor for human Ad16 is not conserved between different species or that differences in the expression levels of the putative receptor exist. In conclusion, our results show that an Ad5-based virus carrying the fiber of Ad16 is a potent vector for the transduction of primate cardiovascular cells and tissues.

Exploiting the natural diversity in adenovirus tropism for therapy and prevention of disease.

Since targeting of recombinant adenovirus vectors to defined cell types in vivo is a major challenge in gene therapy and vaccinology, we explored the natural diversity in human adenovirus tissue tropism. Hereto, we constructed a library of Ad5 vectors carrying fibers from other human serotypes. From this library, we identified vectors that efficiently infect human cells that are important for diverse gene therapy approaches and for induction of immunity. For several medical applications (prenatal diagnosis, artificial bone, vaccination, and cardiovascular disease), we demonstrate the applicability of these novel vectors. In addition, screening cell types derived from different species revealed that cellular receptors for human subgroup B adenoviruses are not conserved between rodents and primates. These results provide a rationale for utilizing elements of human adenovirus serotypes to generate chimeric vectors that improve our knowledge concerning adenovirus biology and widen the therapeutic window for vaccination and many different gene transfer applications.