Correction of Murine Diabetic Hyperglycaemia With A Single Systemic Administration of An AAV2/8 Vector Containing A Novel Codon Optimized Human Insulin Gene.

We report the correction of hyperglycemia of STZ induced diabetic mice using one intravenous systemic administration of a single stranded serotype 8 pseudotyped adeno-associated virus (ssAAV2/8) vector encoding the human proinsulin gene under a constitutive liver specific promoter. In vivo dose titration experiments were carried out and we identified an optimal range that achieved maintenance of euglycaemia or a mild diabetic condition for at least 9 months and ongoing to beyond 1 year for some animals, accompanied by human C-peptide secretion and weight gain. Further DNA codon optimization of the insulin gene construct resulted in approximately 3-10 times more human C-peptide secreted in the blood of codon optimized treated animals thereby reducing the number of vector particles required to achieve the same extent of reduction in blood glucose levels as the non-codon optimized vector. The constitutive secretion of insulin achieved with a single administration of the vector could be of therapeutic value for some diabetic patients.

Transplantation: current developments and future directions.

An historical overview of transplantation is presented in which the medical, legal, ethical, physiological and immunological issues are reviewed in the context of the definition of death. A discussion of the benefits of minimal immunosuppression is presented as an attractive proposal compared with conventional immunosuppression. Prope tolerance was first used with the powerful lympholytic monoclonal antibody Campath 1H. The five-year follow-up of the first renal transplant patients treated with Campath induction and maintenance low-dose cyclosporine has been satisfactory, thus indicating considerable experience of the use of induction followed by steroid-free minimal maintenance immunosuppression. It appears likely that this will become a favoured method of recipient management.

Possible advantages of stem cell transfusion into the peripheral circulation, as opposed to localized transplantation in situ.

Studies to date have overlooked the possible limitations of transplanting stem cells locally (in situ), directly at the site of tissue or organ damage. This approach is contrary to the intrinsic physiological process of tissue and organ regeneration in vivo, which is thought to involve the activation of stem cells resident within the transplanted tissues or their mobilization from ectopic sites, in particular the bone marrow. Signaling pathways and other molecular processes within stem cells transplanted in situ may not be primed to achieve optimal tissue regeneration and may even be confused by the sudden rapid transition in the cellular microenvironment encountered during transplantation. Moreover, there is a risk of the transplanted cells giving rise to undesired lineages at the transplantation site. A novel alternative would be to transfuse stem cells into the peripheral blood circulation, followed by induced homing to the site of tissue damage. This could better replicate the natural physiological process of tissue repair in vivo. Transfusion into the peripheral blood circulation could be a strategy to augment the inadequate mobilization of endogenous adult stem cells from ectopic sites for tissue repair, which may be the case for older patients. The transfused stem cells can then be induced to home in on a damaged tissue or organ, via the controlled release of specific cytokines or chemokines (i.e., stromal cell derived factor-1) emanating from that particular tissue or organ. The gradient of released cytokines/ chemokines within the peripheral blood circulation would then direct the chemotactic migration and homing of the transfused stem cells to the target tissue or organ.