Transgenic model of cardiac rhabdomyosarcoma formation.

OBJECTIVES: Cardiac rhabdomyosarcomas are rare, and the pathogenesis of this detrimental disease is widely unknown. Most data are obtained from case reports or small series, and models for systematic pathogenetic studies are lacking. We aimed to establish a transgenic mouse model of cardiac rhabdomyosarcoma formation. METHODS: Standard techniques were used to construct a minigene comprised of the 5' region of the 1.4-kb SM22alpha gene (expressed in embryonic cardiac muscle) and the 2.7-kb SV40 T antigen early region. This T antigen fragment includes the coding sequences for the binding sites of p53 and the proteins of the pRb family. Genotyping of transgenic mice was performed by means of polymerase chain reaction, and phenotypic expression was evaluated by means of immunohistochemistry. RESULTS: Transgenic mice were studied at the age of approximately 8 to 12 weeks. Cardiac tumors were found of variable size in the left or right sides of the heart and were associated with T antigen expression. Histologic analysis revealed a 3.1-fold enhanced cell density, enlarged cell nuclei, and a 3.4-fold enhanced DNA content. Phenotypic characterization of cardiac tumors resulted in positive staining for desmin, smooth muscle alpha-actin, troponin C, and Myo D1, which met the criteria for rhabdomyosarcomas. CONCLUSIONS: To the best of our knowledge, the present study is the first description of a mouse model of cardiac rhabdomyosarcoma formation based on genetic modulation. Our model will be a valuable tool for illuminating the pathogenesis of cardiac rhabdomyosarcomas and will allow the testing of new therapeutic approaches to fight this dreadful disease.

Transgenic model of smooth muscle cell cycle reentry: expression pattern of the collageneous matrix.

BACKGROUND: We have previously shown that genetically induced smooth muscle cell (SMC) cycle reentry in transgenic mouse models expressing the SV40 T antigen (TAg) resulted in adaptive arterial remodeling. The present investigation targeted the in vitro expression pattern of the collageneous matrix associated with TAg-induced SMC cycle modulation. METHODS: SMC cultures were established from the transgenic model expressing temperature-sensitive TAg. This allowed inducible transgene expression at the permissive temperature of 33 degrees C compared with the restrictive temperature of 39.5 degrees C. To distinguish a transgene effect from a temperature effect, SMCs with constitutively expressed TAg were used as controls. Data were obtained using array technology, Northern blotting, reverse transcription polymerase chain reaction, and zymography. RESULTS: TAg-induced SMC cycle reentry resulted in significant down-regulation of matrix metalloproteinase (MMP)-3, whereas MMP-2, -9, and -11 were not influenced. In addition, SMC cycle reentry resulted in significantly increased RNA levels of procollagen alpha2(IV), procollagen alpha2(V), and procollagen alpha1(XI), whereas procollagen alpha1(III) and procollagen alpha1(VIII) were down-regulated. Studies of the RNA expression levels of granulocyte-macrophage colony-stimulating factor revealed an up-regulation of this proinflammatory and matrix-modulating cytokine. CONCLUSIONS: This transgenic model provides evidence that TAg-induced cell cycle reentry is associated with a complex modulation of the collageneous matrix. Factors identified in this in vitro study reveal a comprehensive expression pattern of candidates, which might allow the vessel to undergo adaptive arterial remodeling under in vivo conditions. Our results will give rise to further investigations to elaborate on this hypothesis and to improve understanding of the role of such factors in vascular diseases.

Low-energy electromagnetic fields promote proliferation of vascular smooth muscle cells.

The rationale was to investigate the effects of low-energy electromagnetic fields (EMF) on the proliferation of bovine coronary and murine aortic smooth muscle cells (SMC). EMF were applied to SMC at field frequencies of 25, 50, or 100 Hz, and exposure time was set to 5, 15, or 30 minutes. Significant increases in SMC-counts compared with sham exposed controls were found for all EMF-frequencies tested. The effect was most pronounced for 50 Hz fields with maximum increases of 1.2-fold over controls. Sequential double exposure of mouse aortic SMC to 50 Hz fields revealed significantly enhanced cell proliferation by 1.2 fold compared with single exposure (p < 0.05). Experiments performed on bovine SMC also revealed significant increases in cell proliferation. The results demonstrate that EMF are capable of significantly enhancing the proliferation of vascular SMC. These results rise the question whether EMF would qualify as supportive means to angio-/arteriogenic approaches.

Vascular injury response in mice is dependent on genetic background.

Mouse models are employed to unravel the pathophysiology of vascular restenosis. Although much effort has been spent on how to apply an adequate arterial injury, the influence of the genetic background of mice has not yet received sufficient consideration. The study presented herein was designed to demonstrate the influence of the mouse strain on vascular injury response. Mice of a defined background (50% 129 strain and 50% DBA strain) were backcrossed into either the 129 strain or the DBA strain. Male offspring were subjected to a femoral artery injury model by applying an electric current. Morphometric analysis revealed that backcrossing into the 129 strain resulted in a significant (P < 0.001) 17-fold increase in neointima formation (n = 17 mice) compared with backcrossing into the DBA strain (n = 19). The values of neointima area were 9.18 x 10(3) +/- 2.13 x 10(3) and 0.54 x 10(3) +/- 0.39 x 10(3) microm2, respectively. In conjunction, the vessel wall area was enhanced by 1.8-fold (P < 0.001). In contrast, no significant differences were found for the areas of the lumen and the tunica media. Similarly, a significant increase in neointima formation was also found for mice of pure 129 strain compared with pure DBA strain. The results underline the importance of the genetic background for studies on vascular injury response. Furthermore, because the mouse genome of the various strains is well defined, serial testing of the genetic background of mice will provide candidate genes and/or genetic modifiers controlling vascular injury response.

Vascular ligation response is independent of p107: stressing the role of the related p130.

Recent studies have revealed the role of the pRb family members pRb and p130 in the response to vascular injury. We evaluated the arterial injury response in the absence of p107, a protein that shares a high degree of homology with the injury-controlling p130. Carotid artery ligation and perivascular electric injury of the femoral artery were applied to p107 knockout (p107 -/-) mice, and morphometric analysis was performed 3 wk after ligation and electric injury. Arterial vessels of p107 -/- mice were indistinguishable from controls under basal conditions. After carotid artery ligation the p107 -/- mice (n = 7) did not display an enhanced ligation response compared with controls (n = 9), which was studied over a distance of approximately 450 microm proximal and approximately 200 microm distal from the ligation site, with regard to vessel wall area, neointima area, and lumen area. Corresponding with this, morphometric data obtained from the perivascular electric injury of the femoral artery confirmed the lack of enhanced ligation and injury response in the absence of p107. We conclude that the pRb family member p107 is not a key regulator in vascular injury response. These data, in conjunction with previously reported results, indicate that the control of vascular injury response is not a redundant feature of pRb proteins but primarily specific for p130. Further studies on functional domains of p130 and p107 will help to resolve the pathways in vascular injury response.

Smooth muscle-specific expression of SV40 large TAg induces SMC proliferation causing adaptive arterial remodeling.

To study the effects of enhanced smooth muscle cell (SMC) proliferation on arterial vessel geometry in the absence of vessel trauma, we developed a transgenic mouse model expressing SV40 large T antigen under control of the 2.3-kb smooth muscle-myosin heavy chain promoter. Transgenic mice studied at ages from 3 to 13 wk showed a 3.2-fold increase in arterial wall SMC density, with 28% of SMC exhibiting proliferative cell nuclear antigen staining, confirming enhanced SMC proliferation, which was accompanied by two- to threefold increases in arterial wall areas (P < 0.05). Remarkably, despite increased vessel wall mass, the lumen area was not compromised, but rather was increased. A tightly conserved linear relationship was found between arterial circumference and wall thickness with slopes of 0.036 for both transgenics (r = 0.93, P < 0.01) and controls (r = 0.77, P < 0.01), suggesting the hypothesis that the conservation of wall stress functions as a primary determinant of adaptive arterial remodeling. This establishes a new model of adaptive vessel remodeling occurring in response to a proliferative input in the absence of mechanical injury or primary flow perturbation.

Direct evidence for the importance of p130 in injury response and arterial remodeling following carotid artery ligation.

OBJECTIVE: Remodeling of arterial morphology in atherosclerosis, hypertension, and restenosis following angioplasty involves controlled alterations in total vascular circumference which critically modulate sequelae of changes in vessel wall mass. Despite the clinical relevance of this process little is known about the pathophysiology, especially the correlation between smooth muscle cell proliferation and remodeling. METHODS: Carotid artery ligation was applied to mice with targeted disruption of the p130 gene (p130 -/-). Mice were allowed to recover for 3 weeks after ligation and then perfusion fixed for histologic and morphometric analysis. RESULTS: P130 -/- mice were indistinguishable from control littermates concerning size and weight. As for the aorta, carotid arteries and femoral arteries, no significant differences were found between the groups with regard to vessel size and cellular density of the vessel wall of non-instrumented vessels. In contrast, following carotid artery ligation we found p130 -/- mice (n=8) to develop a significant increase in vessel wall area compared to controls (n=9). Mean values ranged from 3.07 x 10(-2)+/-0.20 x 10(-2)-3.56 x 10(-2)+/-0.62 x 10(-2) mm(2) for p130 -/- mice versus 2.26 x 10(-2)+/-0.13 x 10(-2)-2.57 x 10(-2)+/-0.26 x 10(-2) mm(2) for controls (p=0.02) along the lesion studied. This increase in vessel wall area was primarily due to a sevenfold mean increase in neointima in p130 -/- mice yielding mean values of 0.43+/-0.18 - 1.19+/-0.70 x 10(-2) mm(2). Remarkably, despite vessel wall increase, the lumen area was not statistically different for both groups. CONCLUSIONS: The data indicate that the loss of the cell cycle inhibitor p130 leads to an enhanced injury response, implicating a central role of p130 in cell cycle control during response to injury in the vessel wall. The enhanced injury response in the context of p130 -/- preserves the ability to perform perfect remodeling, thus the remodeling capacity is preserved even in the context of this injury model.