Interferon beta-1b therapy in chronic viral dilated cardiomyopathy--is there a role for specific therapy?

BACKGROUND: Myocardial biopsy can be used for the detection of viral genome in dilated cardiomyopathy (DCM). Pilot studies have previously reported beneficial effects on clinical outcome and safety of an antiviral therapy using interferon beta-1b in chronic viral DCM. METHODS AND RESULTS: Myocardial biopsies were taken from patients with DCM. Using polymerase chain reaction and Southern Blot analysis, viral genome could be detected in 49% of patients. In 42 patients with viral infection, off-label use with interferon beta-1b was initiated. A further 68 patients formed the control group. The outcome was evaluated after follow-up with echocardiography, exercise electrocardiogram, and New York Heart Association class. A total of 81 men and 29 women with a median left ventricular ejection fraction of 34% were included. The follow-up period was 36 months. In 33 (79%) patients with interferon beta-1b treatment, minor adverse reactions occurred, but no major adverse events were reported. No significant benefit for interferon beta-1b treatment on clinical outcome could be detected during follow-up. CONCLUSIONS: Off-label use with interferon beta-1b in patients with viral DCM is feasible and safe under routine clinical practice. Concerning the herein evaluated clinical outcome parameters, promising results from pilot studies could not be confirmed. High prevalence of parvovirus B19 (92%) might influence the results.

Successful use of mRNA-nucleofection for overexpression of interleukin-10 in murine monocytes/macrophages for anti-inflammatory therapy in a murine model of autoimmune myocarditis.

BACKGROUND: Overexpression of interleukin-10 (IL-10) in murine CD11b(+) monocytes/macrophages via GMP-adapted mRNA-nucleofection was expected to improve clinical outcome and reduce adverse side effects in autoimmune myocarditis. This study represents the proof of principle for a novel anti-inflammatory therapy using overexpression of IL-10 in murine monocytes/macrophages by mRNA-nucleofection for the treatment of autoimmune myocarditis. METHODS AND RESULTS: Autoimmune myocarditis was induced in A/J mice by subcutaneous immunization with troponin I. CD11b(+) monocytes/macrophages were isolated from the peritoneum and IL-10 was overexpressed by mRNA-nucleofection. These cells were injected intravenously. Myocardial inflammation was assessed via histological and immunohistochemical examinations. Myocardial fibrosis was analyzed with Masson's trichrome staining. Antitroponin I antibodies were determined within the serum. Physical performance was evaluated using a running wheel and echocardiography. In vitro overexpression of IL-10 in CD11b(+) monocytes/macrophages resulted in a 7-fold increased production of IL-10 (n=3). In vivo higher levels of IL-10 and less inflammation were detected within the myocardium of treated compared with control mice (n=4). IL-10-treated mice showed lower antitroponin I antibodies (n=10) and a better physical performance (n=10). CONCLUSIONS: Application of IL-10-overexpressing CD11b(+) monocytes/macrophages reduced inflammation and improved physical performance in a murine model of autoimmune myocarditis. Thus, the use of genetically modified monocytes/macrophages facilitated a targeted therapy of local inflammation and may reduce systemic side effects. Because the nucleofection technique is GMP adapted, an in vivo use in humans seems basically feasible and the transfer to other inflammatory diseases seems likely.

Potential myogenic stem cell populations: sources, plasticity, and application for cardiac repair.

The ability of unspecialized stem cells to differentiate into mature, specialized cell types has made them attractive as potential agents for enhanced tissue repair and regenerative medicine. This is especially true of diseases and disorders for which no or only partially effective treatments are currently available. Recently, increased focus has been placed on the regenerative potential of satellite cells (myogenic precursor cells found in the adult skeletal muscle) in various muscular disorders, such as dystrophy and myocardial injury following ischemia. Animal studies and clinical trials are in progress using satellite cells as cellular candidates; however, this early rollout in the clinical setting has deflected attention from the potential of other less specialized, but potentially more maliable, stem cell sources. Published data is still lacking on the best methods for identification, isolation, and further expansion or nuclear manipulation of these cells in vitro. Also, although differentiation capacity has been proven in terms of protein expression patterns characteristic of myogenesis, proof of contractile and energetic compatibility between graft and host is more difficult to establish. In this regard, although future animal model studies will be invaluable, they must be designed with short- and long-term functional outcomes in mind. This review moves beyond initial excitement regarding the acknowledged potential of cell therapy and provides a realistic exposition of the themes and specific issues that should be considered in current experimental research study designs.

mRNA-mediated gene delivery into human progenitor cells promotes highly efficient protein expression.

Gene transfer into human CD34+ haematopoietic progenitor cells (HPC) and multi-potent mesenchymal stromal cells (MSC) is an essential tool for numerous in vitro and in vivo applications including therapeutic strategies, such as tissue engineering and gene therapy. Virus based methods may be efficient, but bear risks like tumorigenesis and activation of immune responses. A safer alternative is non-viral gene transfer, which is considered to be less efficient and accomplished with high cell toxicity. The truncated low affinity nerve growth factor receptor (ALNGFR) is a marker gene approved for human in vivo application. Human CD34+ HPC and human MSC were transfected with in vitro-transcribed mRNA for DeltaLNGFR using the method of nucleofection. Transfection efficiency and cell viability were compared to plasmid-based nucleofection. Protein expression was assessed using flow cytometry over a time period of 10 days. Nucleofection of CD34+ HPC and MSC with mRNA resulted in significantly higher transfection efficiencies compared to plasmid transfection. Cell differentiation assays were performed after selecting DeltaLNGFR positive cells using a fluorescent activating cell sorter. Neither cell differentiation of MSC into chondrocytes, adipocytes and osteoblasts, nor differentiation of HPC into burst forming unit erythroid (BFU-E) colony forming unit-granulocyte, erythrocyte, macrophage and megakaryocyte (CFU-GEMM), and CFU-granulocyte-macrophage (GM) was reduced. mRNA based nucleofection is a powerful, highly efficient and non-toxic approach for transient labelling of human progenitor cells or, via transfection of selective proteins, for transient manipulation of stem cell function. It may be useful to transiently manipulate stem cell characteristics and thus combine principles of gene therapy and tissue engineering.

Efficient transient genetic labeling of human CD34+ progenitor cells for in vivo application.

Genetic labeling of human hematopoietic progenitor cells (HPC) and their consecutive fate-mapping in vivo is an approach to answer intriguing questions in stem cell biology. We recently reported efficient transient genetic labeling of human CD34+ HPC with the truncated low-affinity nerve growth factor receptor (DeltaLNGFR) for in vivo application. Here we investigate whether HPC labeling with DeltaLNGFR affects lineage-specific cell differentiation, whether DeltaLNGFR expression is maintained during lineage-specific cell differentiation and which leukemia cell line might be an appropriate cell culture model for human CD34+ HPC. Human CD34+ peripheral blood stem cells and various leukemia cell lines were characterized by immunophenotyping. Cells were transfected using nucleofection. Hematopoietic differentiation was studied by colony-forming assays. DeltaLNGFR expression was assessed using reverse transcription-PCR, immunofluorescence and flow cytometry. Nucleofection was efficient and did not significantly reduce hematopoietic cell differentiation. Mature myeloid cells (CD66b+) derived from human CD34+ HPC and Mutz2 cells maintained DeltaLNGFR expression at a high percentage (70 +/- 2% and 58 +/- 2%, respectively). Mutz2 cells may serve as an in vitro model for human myeloid HPC. The method described herein has been adopted to Good Manufacturing Practices (GMP) guidelines and is ready for in vivo application.