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Klosterneuburg, Austria

Kudela P.,Bird C GmbH and CoKEG | Kudela P.,Slovak Academy of Sciences | Koller V.J.,Bird C GmbH and CoKEG | Lubitz W.,Bird C GmbH and CoKEG | Lubitz W.,University of Vienna
Vaccine | Year: 2010

Bacterial ghosts (BGs) are empty bacterial envelopes of Gram-negative bacteria produced by controlled expression of cloned gene E, forming a lysis tunnel structure within the envelope of the living bacteria. BGs are devoid of cytoplasmic content and possess all bacterial bio-adhesive surface properties in their original state while not posing any infectious threat. BGs are ideally suited as an advanced drug delivery system (ADDS) for toxic substances in tumor therapy. The inner space of BGs can be loaded with either single components or combinations of peptides, drugs or DNA which provides an opportunity to design new types of (polyvalent) drug delivery vehicles. Uptake of BGs loaded with Doxorubicin (Dox) by CaCo2 cells led to effective Dox release from endo-lysosomal compartments and accumulation in the nucleus. Viability and proliferative capacity of the cells were significantly decreased (2-3 orders of magnitude) after internalization of Dox loaded BGs as compared to cells incubated with free Dox. The same effect was observed with leukemia cells. Melanoma cells also revealed a high capability to internalize BGs. These results indicate that BGs are able to target a range of types of cancer. BGs have also been investigated as DNA delivery vectors. Studies show DNA loaded BGs are efficiently phagocytosed and internalized by both professional APCs and tumor cells with up to 82% of cells expressing the plasmid-encoded reporter gene. Our studies with BGs as an ADDS system contribute (i) to optimize drug delivery for the treatment of cancer; (ii) define specific conditions for selection and preparation of BG formulations; (iii) and provide a background for the clinical application of BGs in cancer therapy. © 2010 Elsevier Ltd. Source


Langemann T.,Bird C GmbH and CoKEG | Langemann T.,University of Vienna | Koller V.J.,Bird C GmbH and CoKEG | Koller V.J.,University of Vienna | And 6 more authors.
Bioengineered Bugs | Year: 2010

The Bacterial Ghost (BG) platform technology is an innovative system for vaccine, drug or active substance delivery and for technical applications in white biotechnology. BGs are cell envelopes derived from Gram-negative bacteria. BGs are devoid of all cytoplasmic content but have a preserved cellular morphology including all cell surface structures. Using BGs as delivery vehicles for subunit or DNA-vaccines the particle structure and surface properties of BGs are targeting the carrier itself to primary antigenpresenting cells. Furthermore, BGs exhibit intrinsic adjuvant properties and trigger an enhanced humoral and cellular immune response to the target antigen. Multiple antigens of the native BG envelope and recombinant protein or DNA antigens can be combined in a single type of BG. Antigens can be presented on the inner or outer membrane of the BG as well as in the periplasm that is sealed during BG formation. Drugs or supplements can also be loaded to the internal lumen or periplasmic space of the carrier. BGs are produced by batch fermentation with subsequent product recovery and purification via tangential flow filtration. For safety reasons all residual bacterial DNA is inactivated during the BG production process by the use of staphylococcal nuclease A and/or the treatment with β propiolactone. After purification BGs can be stored long-term at ambient room temperature as lyophilized product. The production cycle from the inoculation of the pre-culture to the purified BG concentrate ready for lyophilization does not take longer than a day and thus meets modern criteria of rapid vaccine production rather than keeping large stocks of vaccines. The broad spectrum of possible applications in combination with the comparably low production costs make the BG platform technology a safe and sophisticated product for the targeted delivery of vaccines and active agents as well as carrier of immobilized enzymes for applications in white biotechnology. © 2010 Landes Bioscience. Source


Cui X.,Landcare Research | Duckworth J.A.,Landcare Research | Lubitz P.,University of Vienna | Lubitz P.,Bird C GmbH and CoKEG | And 6 more authors.
Vaccine | Year: 2010

The introduced common brushtail possum (Trichosurus vulpecula) is a major pest in New Zealand and immunocontraceptive vaccines are being developed for biocontrol of possum populations, with bacterial ghosts (BGs) being evaluated as a means of oral delivery. Recombinant BGs expressing possum zona pellucida 3 protein (ZP3) as an L′ membrane-anchored protein (ZP3-L′) or as an S-layer SbsA-fusion protein (MBP-SbsA-ZP3) were produced by the expression of the cloned bacteriophage φ{symbol}X174 lysis gene E in E. coli NM522. The humoral immune responses of possums immunised with BGs expressing possum ZP3 were investigated following oral, intranasal/conjunctival, parenteral, and intraduodenal administration to evaluate the BG-ZP3 system for possum fertility control. Antibodies to possum ZP3 were detected in the serum, oviduct secretions, and follicular fluid of immunised animals. Intranasal/conjunctival immunisation elicited reliable antibody immune response in serum and at a key effector site, the ovarian follicular fluid. Intraduodenal administration of possum ZP3 BG vaccine as a priming immunisation elicited significant systemic immune responses, but oral immunisation did not, indicating that protection of BG vaccines from degradation by gastric acidity would enhance the effectiveness of orally delivered vaccines. The detection of antibodies at elevated levels at target sites in the reproductive tract following mucosal delivery demonstrates, for the first time, the potential of BGs as an effective system for vaccine delivery to wild animals, and intranasal/conjunctival immunisation as a promising means for delivery of immunocontraceptive vaccines to wild animals. © 2010 Elsevier Ltd. All rights reserved. Source

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