Live in vivo imaging of Egr-1 promoter activity during neonatal development, liver regeneration and wound healing.

BACKGROUND: The zinc finger transcription factor Egr-1 (Early growth response 1) is central to several growth factors and represents an important activator of target genes not only involved in physiological processes like embryogenesis and neonatal development, but also in a variety of pathophysiological processes, for example atherosclerosis or cancer. Current options to investigate its transcription and activation in vivo are end-point measurements that do not provide insights into dynamic changes in the living organism. RESULTS: We developed a transgenic mouse (Egr-1-luc) in which the luciferase reporter gene is under the control of the murine Egr-1 promoter providing a versatile tool to study the time course of Egr-1 activation in vivo. In neonatal mice, bioluminescence imaging revealed a high Egr-1 promoter activity reaching basal levels three weeks after birth with activity at snout, ears and paws. Using a model of partial hepatectomy we could show that Egr-1 promoter activity and Egr-1 mRNA levels were increased in the regenerating liver. In a model of wound healing, we demonstrated that Egr-1 promoter activity was upregulated at the site of injury. CONCLUSION: Taken together, we have developed a transgenic mouse model that allows real time in vivo imaging of the Egr-1 promoter activity. The ability to monitor and quantify Egr-1 activity in the living organism may facilitate a better understanding of Egr-1 function in vivo.

MEK hyperphosphorylation coincides with cell cycle shut down of cultured smooth muscle cells.

Smooth muscle cells (SMCs) form the backbone of arteries and their proliferation hallmarks collateral vessel growth, a process termed arteriogenesis, as well as pathogenic responses such as restenosis. Since signaling pathways in SMCs are the main targets for therapeutic interventions, we aimed to determine how and to what extent the activation of the ubiquitous MEK-ERK signaling pathway correlates with important in vivo phenomena such as dedifferentiation, nuclear activation and proliferation of SMCs. Specificity of this pathway was monitored using MEK inhibitors UO126 and PD98059 in platelet derived growth factor-AB (PDGF-AB)- and fibroblast growth factor-2 (FGF-2)-stimulated SMCs. PDGF-AB induced a rapid MEK activation followed by phosphorylation of the MEK substrates ERK1/2 while FGF-2 showed a less pronounced and delayed activation. Both growth factors triggered a marked phosphorylation of c-Myc and expression of Egr1. Pretreatment with MEK inhibitors suppressed the activation of the ERK cascade, abolished the down-regulation of desmin and led to cell cycle arrest. However, the reversibility of p27Kip1 down-regulation by UO126 was mainly observed after PDGF-AB stimulation, indicating MEK independent p27Kip1 down-regulation by FGF-2. Surprisingly, treatment of SMCs with UO126 or PD98059 increased the level of MEK phosphorylation in a dose dependent manner at serine residues 217/221 in the presence as well as in the absence of both growth factors. Our results strongly imply that depending on the environmental context phosphorylation of serines 217/221 serves as an "on" as well as an "off " switch.

SUMO keeps a check on recombination during DNA replication.

The small ubiquitin-related modifier SUMO plays an important role in the maintenance of genome stability. Accordingly, DNA replication, repair and recombination factors as well as mediators of chromosome dynamics and cohesion are among its many targets. Attachment of SUMO can modulate the properties of the modified proteins by affecting localization, conformation, stability or enzymatic activity, but often its mechanism of action remains poorly defined. Recent findings demonstrate how SUMO modification of PCNA, the processivity clamp for replicative DNA polymerases, prevents unscheduled recombination during DNA replication by means of directly enhancing physical interactions with an anti-recombinogenic helicase, Srs2. This review highlights how the SUMO conjugation system exerts its effect on the replication fork and discusses the implications for ubiquitin-dependent DNA damage tolerance.

Porcine aortic endothelial cells show little effects on smooth muscle cells but are potent stimulators of cardiomyocyte growth.

Smooth muscle cells (SMC) and endothelial cells (EC) play a pivotal role in arteriogenesis and atherosclerosis. We evaluated the role of EC on the growth of SMC and neonatal cardiomyocytes (NEO) by using serum-free EC-supernatant (AoCM). Five percent fetal calf serum was used in order to mimic growth effects of blood. EC and SMC purities were 99% as determined by absence or presence of markers such as CD31, desmin, alpha-smooth muscle actin and tropomyosin using immunostaining and FACS analysis. AoCM markedly influenced the morphology of NEO as determined by alpha-actinin staining but showed only little effect on the phenotype of SMC. Protein synthesis after 2 days increased 2.5-fold in SMC and 3.7-fold in NEO as determined by tritium incorporation. The values for serum (2.8 and 2.3-fold, respectively) were comparable. The induction of DNA-synthesis by serum in NEO was twice that of AoCM (3.9-fold). However, proliferative effects of serum and AoCM on SMC differed markedly: Serum induced a 66-fold increase in DNA-synthesis resulting in a 54% higher cell number. DNA-synthesis after AoCM treatment lead to a nonsignificant small increase and no proliferation was detected. Platelet derived growth factor (PDGF-AB), present in blood, induced a 47-fold increase in DNA-synthesis and a 38% increase in cell number. Our data suggest that EC in the absence of physical forces exert strong morphogenic effects on cardiomyocytes but they lack specific effects on smooth muscle cells. In vessels EC might function as a border to isolate SMC from key regulators in blood such as PDGFs.

Exogenous application of transforming growth factor beta 1 stimulates arteriogenesis in the peripheral circulation.

Increased expression of transforming growth factor beta1 (TGF-beta1) during collateral artery growth, as well as its numerous effects on monocytes/macrophages and the smooth muscle cell cycle and differentiation, suggest a modulating role for this growth factor during arteriogenesis. We studied the effects of exogenously applied TGF-beta1 on arteriogenesis as well as its interactions with monocytes, endothelial cells, and smooth muscle cells. In a New Zealand White (NZW) rabbit model of femoral artery ligation, increased expression of active TGF-beta1 was found around proliferating arteries in NZW rabbits. The exogenous application of TGF-beta1 led to an increase in both the number of visible collateral arteries as well as the conductance of the collateral circulation (4.0 +/- 0.5 ml/min/100 mmHg vs. 28.9 +/- 3.7 ml/min/100 mmHg, P<0.05). Fluorescence activated cell sorting analysis showed an increase in the expression of the MAC-1 receptor in both rabbit and human monocytes after treatment with TGF-beta1 (control: 91.2 +/- 4.2/482 +/- 21.7; TGF-beta1 200 ng/ml 193.9 +/- 6.7/ 675.5 +/- 25.7, P<0.05 for all differences). TGF-beta1 treated monocytes showed an increased endothelial adhesion and transmigration in transendothelial migration assays (5.75 +/- 0.63 x 10(5) vs. 10.11 +/- 0.04 x 10(5), P<0.05). TGF-beta1 had no direct pro-angiogenic effect on human umbilical vein endothelial cells in a spheroid model of angiogenesis and inhibited the angiogenic effects of vascular endothelial growth factor.