Molecular targets of gene therapy

Beneficial effects of carbon monoxide-releasing molecules on post-ischemic myocardial recovery

There is increasing evidence corroborating a protective role of carbon monoxide releasing molecules (CORMs) in injured tissues. Carbon monoxide (CO) carriers have been recently developed as a pharmacological tool to simulate the effect of heme oxygenase-1-derived CO. The effects of CORM-3, a water-soluble CO releaser, on the incidence of reperfusion-induced ventricular fibrillation (VF) and tachycardia (VT) were studied in isolated rat hearts. Hearts were treated with different doses of CORM-3 before the induction of 30 min global ischemia followed by 120 min reperfusion. We found that at concentrations of 25 microM and 50 microM of CORM-3 promoted a significant reduction in the incidence of VF and VT. Thus, the incidence of VF was reduced by 67% (p<0.05) and 92% (p<0.05) with 25 microM and 50 microM of CORM-3, respectively. The protective effect of CORM-3 on the incidence of VT followed the same pattern. The antiarrhythmic protection was associated with a marked attenuation in infarct size, significant decreases in cellular Na(+) and Ca(2+) gains and K(+) loss. Consequently, the recovery of post-ischemic function was significantly improved. In conclusion, CORM-3 exerts beneficial effects against ischemia/reperfusion-induced injury through its abilities to release CO which mediates a cardioprotective action by regulating tissue Na(+), K(+), and Ca(2+) levels.

Perioperative myocardial ischemia reperfusion injury

Myocardial I-R injury contributes to adverse cardiovascular outcomes after cardiac surgery. The pathogenesis of I-R injury is complex and involves the activation, coordination, and amplification of several systemic and local proinflammatory pathways (Fig. 4). Treatment and prevention of perioperative morbidity associated with myocardial I-R will ultimately require a multifocal approach. Combining preoperative risk stratification (co-morbidity and surgical complexity), minimizing initiating factors predisposing to SIRS, limiting ischemia duration, and administering appropriate immunotherapy directed toward systemic and local proinflammatory mediators of I-R injury, should all be considered. In addition, the role of the genetic-environmental interactions in the pathogenesis of cardiovascular disease is also being examined. Thus, in the near future, preoperative screening for polymorphisms of certain inflammatory and coagulation genes should inevitably help reduce morbidity by permitting the identification of high-risk cardiac surgical patients and introducing the opportunity for gene therapy or pharmacogenetic intervention [42,64].

Development of an in vivo ischemia-reperfusion model in heterotopically transplanted rat hearts

BACKGROUND

Heart transplantation has been extensively used in animal models, including studies on gene therapy for myocardial preservation. We investigated the feasibility of in situ left coronary artery (LCA) ligation as a physiological system for the examination of strategies to modulate myocardial tolerance against ischemia-reperfusion injury, such as gene therapy, using heterotopically transplanted rat hearts.

METHODS

Lewis rat hearts that had been transplanted into syngeneic recipients' abdomens were subjected to 30-min ischemia, by occluding the LCA, and subsequent blood reperfusion by releasing the suture in situ (I/R group). Transplanted hearts in the sham group underwent laparotomy only.

RESULTS

At 24 hr of reperfusion, the size of the ischemic region was 40.1+/-3.1% of the total left ventricular mass, and the infarct size was 47.5+/-3.3% of the area at risk in the I/R group. Cardiac function was reduced in the I/R group compared with the sham group, associated with higher myeloperoxidase activity (5.12+/-1.35 vs. 0.97+/-0.33 U/g wt) and higher incidence of apoptosis as defined by TUNEL (29.8+/-3.2 vs. 3.8+/-0.7%) and DNA ladder. In the I/R group, up-regulation of Bax, Bak, and caspase-3 was observed.

CONCLUSIONS

These data on myocardial damage of transplanted hearts are consistent and equivalent to those of the usual LCA occlusion model, suggesting that this method is useful to investigate strategies for modulating myocardial tolerance against ischemia-reperfusion injury using heterotopically transplanted rat hearts in a more physiological blood-perfused model.

Gene therapy for ischemic heart disease: therapeutic potential

Gene therapy is evolving as an alternative mode to pharmacological intervention in the treatment of cardiovascular diseases. Experimental observations indicating that introduction of genes encoding for angiogenic peptide growth factors could result in improvement in perfusion to ischemic myocardium have led to the initiation of a number of preliminary clinical trials to evaluate this therapeutic modality. Sustained expression of the growth factor product from somatic cells transfected with the DNA for that protein has proven to be one of the major advantages of a gene therapy based approach over administration of the recombinant protein. A number of gene therapy vectors have been developed, prominent among these being adenoviral vectors and naked plasmid DNA. Whereas plasmid DNA results in less efficient transfection, its tolerability profile may be superior to adenoviral vectors. Plasmid DNA is particularly suitable when the gene product to be produced is capable of being secreted by the cell which is producing it. Vascular endothelial growth factor (VEGF) is not only essential to the process of angiogenesis, but, because it can be secreted from intact cells, appears to be ideal for gene transfer therapy aimed at improving perfusion to ischemic myocardium. The DNA can be delivered to the myocardium by intra-arterial or intramuscular injection. At present, direct injection into the muscle either via a small thoracotomy incision or by use of a recently developed percutaneous catheter technique appears to be superior to arterial administration. Several clinical trials based on intramyocardial injection of VEGF DNA in patients with otherwise inoperable coronary artery disease and intractable angina pectoris have recently been completed. These phase I trials have documented the tolerability of gene transfer using plasmid DNA and show promise of being able to improve myocardial perfusion and reduce anginal symptoms in the majority of patients treated thus far. While the trials involving gene transfer via a thoracotomy did not allow for randomization to a placebo group, the recent advent of a percutaneous delivery modality has allowed for randomization which should enhance our ability to determine whether angiogenic gene therapy will prove to be as effective as initial results suggest. In the future, results from such randomized placebo-controlled trials, improvement in vectors utilized for gene transfer and innovative new delivery techniques will undoubtedly enhance the potential of this novel approach to myocardial revascularization.