The impact of dendritic cell-tumor fusion cells on cancer vaccines - past progress and future strategies.

Dendritic cells (DCs) are potent antigen-presenting cells that can be used in cancer vaccines. Thus, various strategies have been developed to deliver tumor-associated antigens via DCs. One strategy includes administering DC-tumor fusion cells (DC-tumor FCs) to induce antitumor immune responses in cancer patients. However, clinical trials using this strategy have fallen short of expectations. Several factors might limit the efficacy of these anticancer vaccines. To induce efficient antitumor immune responses and enhance potential clinical benefits, DC-tumor FC-based cancer vaccines require manipulations that improve immunogenicity for both DCs and whole tumor cells. This review addresses recent progress in improving clinical outcomes using DC-tumor FC-based cancer vaccines.

Lipid function at synapses.

Chemical neurotransmission between neurons is a major point for modulation of neuronal activity. The neuronal synapse is the site of continuous cycles of rapid vesicle fusion (exocytosis) followed by their retrieval (endocytosis). Ongoing research efforts are largely focused on synaptic proteins involved in membrane fusion-and-fission, but it is now becoming clear that the dynamic lipid environment, where these proteins operate, also plays a key role in the modulation of chemical transmission. Growing evidence suggests that lipid metabolites regulate both vesicle fusion and retrieval highlighting the fact that membrane lipids have functions beyond the structural role. Furthermore, direct involvement of lipid metabolism in the pathogenesis of neurodegenerative disorders, such as Alzheimer's and Parkinson's diseases, necessitates rigorous investigation of the effects of lipids on synaptic mechanisms. Recent findings and possible lines of further investigation will be discussed in this review.

Cancer vaccine by fusions of dendritic and cancer cells.

Dendritic cells (DCs) are potent antigen-presenting cells and play a central role in the initiation and regulation of primary immune responses. Therefore, their use for the active immunotherapy against cancers has been studied with considerable interest. The fusion of DCs with whole tumor cells represents in many ways an ideal approach to deliver, process, and subsequently present a broad array of tumor-associated antigens, including those yet to be unidentified, in the context of DCs-derived costimulatory molecules. DCs/tumor fusion vaccine stimulates potent antitumor immunity in the animal tumor models. In the human studies, T cells stimulated by DC/tumor fusion cells are effective in lysis of tumor cells that are used as the fusion partner. In the clinical trials, clinical and immunological responses were observed in patients with advanced stage of malignant tumors after being vaccinated with DC/tumor fusion cells, although the antitumor effect is not as vigorous as in the animal tumor models. This review summarizes recent advances in concepts and techniques that are providing new impulses to DCs/tumor fusions-based cancer vaccination.

Reprogramming mediated by stem cell fusion.

Advances in mammalian cloning prove that somatic nuclei can be reprogrammed to a state of totipotency by transfer into oocytes. An alternative approach to reprogram the somatic genome involves the creation of hybrids between somatic cells and other cells that contain reprogramming activities. Potential fusion partners with reprogramming activities include embryonic stem cells, embryonic germ cells, embryonal carcinoma cells, and even differentiated cells. Recent advances in fusion-mediated reprogramming are discussed from the standpoints of the developmental potency of hybrid cells, genetic and epigenetic correlates of reprogramming, and other aspects involved in the reprogramming process. In addition, the utility of fusion-mediated reprogramming for future cell-based therapies is discussed.

Cell fusion: an alternative to stem cell plasticity and its therapeutic implications.

Cell fusion has long been known to produce viable cells and to have a major role in mammalian development and differentiation. As gene expression profiles can change after cell fusion, this event must be also considered as an alternative explanation for the many cases of 'stem cell plasticity' that have been recently described and are promoted as a promising therapeutic strategy. Cell fusion has been demonstrated to occur in some recent studies, and the available evidence is often not inconsistent with cell fusion in others. Cell fusion itself has therapeutic potential, but low rates of spontaneous fusion and safety concerns may ultimately limit its use.

Plastic adult stem cells: will they graduate from the school of hard knocks?

Notwithstanding the fact that adult bone marrow cell engraftment to epithelial organs seems a somewhat uncommon event, there is no doubt it does occur, and under appropriate conditions of a strong and positive selection pressure these cells will expand clonally and make a significant contribution to tissue replacement. Likewise, bone-marrow-derived cells can be amplified in vitro and differentiated into a multitude of tissues. These in essence are the goals of regenerative medicine using any source of stem cells, be it embryonic or adult. Despite such irrefutable evidence of what is possible, a veritable chorus of detractors of adult stem cell plasticity has emerged, some doubting its very existence, motivated perhaps by more than a little self-interest. The issues that have led to this state of affairs have included the inability to reproduce certain widely quoted data, one case where the apparent transdifferentiation was due to contamination of the donor tissue with haematopoietic cells and, most notoriously, extrapolating from the behaviour of embryonic stem cells to suggest that adult bone marrow cells simply fuse with other cells and adopt their phenotype. While these issues need resolving, slamming this whole new field because not everything is crystal clear is not good science. The fact that a phenomenon is quite rare in no way mitigates against its very existence: asteroid collisions with the Earth are rare, but try telling the dinosaurs they do not occur! When such events do occur (transdifferentiation or collision), they certainly can make an impact.

Veterinary sources of nonrodent monoclonal antibodies: interspecific and intraspecific hybridomas.

The generation of monoclonal antibodies from species other than rats and mice has developed slowly over the last 20 years. The advent of antibody engineering and realization of the advantages of nonmurine antibodies, in terms of their superior affinities and specificities, and their potential as components of human and veterinary therapeutics has increased their relevance recently. There have been significant advances in the development of myeloma and heteromyeloma fusion partners. This is an opportune moment to consolidate experiences of MAb production across the range of species of veterinary interest and place it into context with other developments in the field of monoclonal antibodies. The background to the development of antibodies from species other than the mouse is discussed. The species and antigens used to date are reviewed, as are the methods and results reported. A suggested protocol is provided for first attempts to exploit the huge potential of this aspect of hybridoma technology and suggestions are made for its further expansion.