Induction of lymphangiogenesis in and around axillary lymph node metastases of patients with breast cancer

We studied the presence of lymphangiogenesis in lymph node (LN) metastases of breast cancer. Lymph vessels were present in 52 of 61 (85.2%) metastatically involved LNs vs 26 of 104 (25.0%) uninvolved LNs (P<0.001). Furthermore, median intra- and perinodal lymphatic endothelial cell proliferation fractions were higher in metastatically involved LNs (P<0.001). This is the first report demonstrating lymphangiogenesis in LN metastases of cancer in general and breast cancer in particular

Gene therapy targeting inflammation in atherosclerosis.

The extensive cross-talk between the immune system and vasculature leading to the infiltration of immune cells into the vascular wall is a major step in atherogenesis. In this process, reactive oxygen species play a crucial role, by inducing the oxidation of LDL and the formation of foam cells, and by activating a number of redox-sensitive transcriptional factors such as nuclear factor kappa B (NFkappa B) or activating protein 1 (AP1), that regulate the expression of multiple pro/anti inflammatory genes involved in atherogenesis. Delivery of genes encoding antioxidant defense enzymes (e.g. superoxide dismutase, catalase, glutathione peroxidase or heme oxygenase- 1) or endothelial nitric oxide synthase (eNOS), suppress atherogenesis in animal models. Similarly, delivery of genes encoding regulators of redox sensitive transcriptional factors (e.g. NF-kappa B, AP-1, Nrf2 etc) or reactive oxygen species scavengers have been successfully used in experimental studies. Despite the promising results from basic science, the clinical applicability of these strategies has proven to be particularly challenging. Issues regarding the vectors used to deliver the genes (and the development of immune responses or other side effects) and the inability of sufficient and sustained local expression of these genes at the target-tissue are some of the main reasons preventing optimism regarding the use of these strategies at a clinical level. Therefore, although premature to discuss about effective "gene therapy" in atherosclerosis at a clinical level, gene delivery techniques opened new horizons in cardiovascular research, and the development of new vectors may allow their extensive use in clinical trials in the future

Gene delivery strategies targeting stable atheromatous plaque.

Conventional therapeutic options to treat chronic angina pectoris are pharmacological interventions, coronary bypass surgery (CABG) and percutaneous coronary intervention (PCI). In animal models, it was shown that gene delivery strategies harbour an exciting potential to support and maybe even replace conventional anti-angina treatments, but the translation of the basic science to clinical practise appears problematic. Gene therapy targeting key elements of neointima formation (e.g. cell cycle regulators, metalloproteinases, inflammation and oxidative stress) reduces vein graft and stent failure in experimental models. Additionally, systemic gene delivery of genes targeting NO production, oxidative stress, inflammation and foam cell formation has been shown to prevent atherosclerosis in different animal models. During CABG the vein graft can be transfected ex vivo and during PCI, a stent carrying transfection vectors can be deployed. Both strategies result in the induction of local transgene expression at the site of interest. This limits unwarranted transgene expression and the toxicity seen with systemic gene delivery. However, with the development of new transfection vectors, able to induce local transgene expression without detrimental side effects, systemic anti-inflammatory and anti-oxidative, gene delivery could be a powerful tool in secondary prevention