Engineered Cell Therapy for Sustained Local Myocardial Delivery of Nonsecreted Proteins

Bian, Jing; Kiedrowski, Matt; Mal, Niladri; Forudi, Farhad; Penn, Marc S.

doi:10.3727/000000006783982197

Cited by 15 publications

(8 citation statements)

References 32 publications

(14 reference statements)

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“…101 Another approach that is being developed to direct cardiac differentiation of adult stem cells is the delivery of chimeric proteins encoding cell penetrating peptides and cardiac specific transcription factors. 24,102 Cell penetrating peptides (CPP) cause nonsecreted proteins to be secreted and to be internalized by surrounding cells. We have demonstrated that the transplantation into the myocardium of cells genetically enhanced to express a CPP-GFP protein results in GFP expression in native cardiac myocytes.…”

Section: Directed Stem Cell Differentiation To Cardiac Myocytesmentioning

confidence: 99%

“…We have demonstrated that the transplantation into the myocardium of cells genetically enhanced to express a CPP-GFP protein results in GFP expression in native cardiac myocytes. 102 To determine whether we could deliver functional transcription factors to the myocardium, we developed a CPP-GATA4 construct and transplanted cardiac fibroblasts that were stably transfected with the CPP-GATA4 construct 1 month after myocardial infarction in the Lewis rat. The infarct border zone of animals that received CPP-GATA4 demonstrated increased cardiac myosin and Bcl-2 expression.…”

Section: Directed Stem Cell Differentiation To Cardiac Myocytesmentioning

confidence: 99%

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Genetic Enhancement of Stem Cell Engraftment, Survival, and Efficacy

Penn¹,

Mangi

2008

Circulation Research

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134

103

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Abstract-Cell-based therapies for the prevention and treatment of cardiac dysfunction offer the potential to significantly modulate cardiac function and improve outcomes in patients with cardiovascular disease. To date several clinical studies have suggested the potential efficacy of several different stem cell types; however, the benefits seen in clinical trials have been inconsistent and modest. In parallel, preclinical studies have identified key events in the process of cell-based myocardial repair, including stem cell homing, engraftment, survival, paracrine factor release, and differentiation that need to be optimized to maximize cardiac repair and function. The inconsistent and modest benefits seen in clinical trials combined with the preclinical identification of mediators responsible for key events in cell-based cardiac repair offers the potential for cell-based therapy to advance to cell-based gene therapy in an attempt to optimize these key events in the hope of maximizing clinical benefit. Below we discuss potential key events in cardiac repair and the mediators of these events that could be of potential interest for genetic enhancement of stem cell-based cardiac repair. (Circ Res.

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Section: Directed Stem Cell Differentiation To Cardiac Myocytesmentioning

confidence: 99%

Section: Directed Stem Cell Differentiation To Cardiac Myocytesmentioning

confidence: 99%

Genetic Enhancement of Stem Cell Engraftment, Survival, and Efficacy

Penn¹,

Mangi

2008

Circulation Research

Self Cite

134

103

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“…3,4 Before clinical applications of these cells is possible, researchers and clinicians must overcome several problems including improved survival rate for the implanted cells, differentiation into the target cell type, and structural support that enables the reconstruction of the recipient tissues. [5][6][7][8] To overcome the problems, the utilization of scaffolds, 9,10 growth factors, 11 and combinations of these materials 12,13 has been investigated. The survival, differentiation, and reorganization of the implanted cells are affected by the microenvironment within the recipient tissues [14][15][16][17] ; however, our understanding of these microenvironmental variables is currently insufficient to provide for clinically effective and reliable resources for regenerative medicine.…”

mentioning

confidence: 99%

The Microenvironment of Freeze-Injured Mouse Urinary Bladders Enables Successful Tissue Engineering

Imamura

Yamamoto²,

Ishizuka³

et al. 2009

Tissue Engineering Part A

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Mouse bone marrow-derived cells implanted into freeze-injured bladder walls form smooth muscle layers, but not in intact walls. We determined if the microenvironment within injured urinary bladders was supportive of smooth muscle layer development. The urinary bladders of female nude mice were freeze-injured for 30 s. Three days later, the rate of blood flow in the wounded areas and in comparable areas of intact control urinary bladders was observed by charge-coupled device (CCD) video microscopy. Injured and control bladder walls were also analyzed histologically and cytologically. Growth factor mRNA expression was determined by real-time reverse transcription polymerase chain reaction arrays. The injured regions maintained a partial microcirculation in which blood flow velocity was significantly less than in controls. The injured bladder walls had few typical smooth muscle layers, and blood vessels in the walls had reduced smooth muscle content. The loss of smooth muscle cells in the bladder walls may have resulted in the formation of large porous spaces seen by scanning electron microscopy of the injured areas. The expression of nineteen growth-related mRNAs, including secreted phosphoprotein 1, inhibin b-A, glial cell line-derived neurotrophic factor, and transforming growth factor b1, were significantly upregulated in the injured urinary bladders. In conclusion, the microenvironment in freeze-injured urinary bladders enables successful tissue engineering.

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“…We recently demonstrated the utility of this strategy to deliver the nonsecreted marker protein green fluorescent protein (GFP) to myocardial tissue. 12 In this previous study, we demonstrated that VP22 chimeric proteins are delivered to Ϸ1 mm 2 of myocardium in a direction radial to the needle track. In the present study, we quantified the effects of sustained GATA4:VP22 release into the infarct border zone in a rat model of ischemic cardiomyopathy induced by left anterior descending (LAD) ligation 1 month before cell delivery.…”

mentioning

confidence: 88%

Effect of Cell-Based Intercellular Delivery of Transcription Factor GATA4 on Ischemic Cardiomyopathy

Bian

Popović

Benejam

et al. 2007

Circulation Research

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Abstract-Recent loss-of-function studies highlight the importance of the transcription factor GATA4 in the myocardial response to injury in the adult heart. However, the potential effects of gain-in-function of GATA4 overexpression, and transcription factors in general, is hindered by the fact that transcription factors are neither secreted nor taken up by cells. Key Words: GATA4 Ⅲ myocardial infarct Ⅲ cell-based gene therapy Ⅲ VP22 Ⅲ intercellular delivery of protein G ATA4 is critical for the viability and hypertrophic response of cardiac myocytes following myocardial injury. 1,2 Consistent with these findings, GATA4 has been shown to directly induce the expression of BCL2 in cardiac myocytes in vitro. 3 These findings suggest that the local overexpression of GATA4 could lead to local cardiac hypertrophy and improved cardiac myocyte survival. The goal of this study was to assess, for the first time, the effects of local GATA4 overexpression in the infarct border zone at a time remote from myocardial infarction in a model of ischemic cardiomyopathy. To do so, because transcription factors are neither secreted nor internalized by surrounding cells, we used a novel method of local GATA4 delivery to the infarct border zone.We achieved local GATA4 delivery by combining cellbased gene therapy with a cell-penetrating protein (CPP). Cell-based gene therapy has been shown to be an effective strategy for stimulating angiogenesis and improving heart function. 4 -6 Moreover CPPs, by serving as vectors for the transmembrane intercellular delivery of fused proteins, have emerged as a tool to modulate biological activities. 7-11 Cardiac fibroblasts were engineered in culture to overexpress a chimeric protein encoding GATA4 and the CPP VP22. We recently demonstrated the utility of this strategy to deliver the nonsecreted marker protein green fluorescent protein (GFP) to myocardial tissue. 12 In this previous study, we demonstrated that VP22 chimeric proteins are delivered to Ϸ1 mm 2 of myocardium in a direction radial to the needle track. In the present study, we quantified the effects of sustained GATA4:VP22 release into the infarct border zone in a rat model of ischemic cardiomyopathy induced by left anterior descending (LAD) ligation 1 month before cell delivery. We aim to show that the cell-based sustained delivery of nonsecreted functional proteins offers a potential novel strategy to study the effects of nonsecreted proteins in adult hearts at a time remote from myocardial injury, as well as a potentially interesting strategy for the optimization of cardiac function following myocardial injury.

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Engineered Cell Therapy for Sustained Local Myocardial Delivery of Nonsecreted Proteins

Cited by 15 publications

References 32 publications

Genetic Enhancement of Stem Cell Engraftment, Survival, and Efficacy

Genetic Enhancement of Stem Cell Engraftment, Survival, and Efficacy

The Microenvironment of Freeze-Injured Mouse Urinary Bladders Enables Successful Tissue Engineering

Effect of Cell-Based Intercellular Delivery of Transcription Factor GATA4 on Ischemic Cardiomyopathy

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