Epicardial GATA factors regulate early coronary vascular plexus formation.

During early development, GATA factors have been shown to be important for key events of coronary vasculogenesis, including formation of the epicardium. Myocardial GATA factors are required for coronary vascular (CV) formation; however, the role of epicardial localized GATAs in this process has not been addressed. The current study was conducted to investigate the molecular mechanisms by which the epicardium controls coronary vasculogenesis, focusing on the role of epicardial GATAs in establishing the endothelial plexus during early coronary vasculogenesis. To address the role of epicardial GATAs, we ablated GATA4 and GATA6 transcription factors specifically from the mouse epicardium and found that the number of endothelial cells in the sub-epicardium was drastically reduced, and concomitant coronary vascular plexus formation was significantly compromised. Here we present evidence for a novel role for epicardial GATA factors in controlling plexus formation by recruiting endothelial cells to the sub-epicardium.

Serum response factor is required for cell contact maintenance but dispensable for proliferation in visceral yolk sac endothelium.

BACKGROUND: Endothelial-specific knockout of the transcription factor serum response factor (SRF) results in embryonic lethality by mid-gestation. The associated phenotype exhibits vascular failure in embryos as well as visceral yolk sac (VYS) tissues. Previous data suggest that this vascular failure is caused by alterations in cell-cell and cell-matrix contacts. In the current study, we sought to more carefully address the role of SRF in endothelial function and cell contact interactions in VYS tissues. RESULTS: Tie2-Cre recombinase-mediated knockout of SRF expression resulted in loss of detectable SRF from VYS mesoderm by E12.5. This loss was accompanied by decreased expression of smooth muscle alpha-actin as well as vascular endothelial cadherin and claudin 5, endothelial-specific components of adherens and tight junctions, respectively. Focal adhesion (FA) integrins alpha5 and beta1 were largely unchanged in contrast to loss of the FA-associated molecule vinculin. The integrin binding partner fibronectin-1 was also profoundly decreased in the extracellular matrix, indicating another aspect of impaired adhesive function and integrin signaling. Additionally, cells in SRF-null VYS mesoderm failed to reduce proliferation, suggesting not only that integrin-mediated contact inhibition is impaired but also that SRF protein is not required for proliferation in these cells. CONCLUSIONS: Our data support a model in which SRF is critical in maintaining functional cell-cell and cell-matrix adhesion in endothelial cells. Furthermore, we provide evidence that supports a model in which loss of SRF protein results in a sustained proliferation defect due in part to failed integrin signaling.

Hepatocyte expression of serum response factor is essential for liver function, hepatocyte proliferation and survival, and postnatal body growth in mice.

UNLABELLED: Serum response factor (SRF) is a transcription factor that binds to a CarG box motif within the serum response element of genes that are expressed in response to mitogens. SRF plays essential roles in muscle and nervous system development; however, little is known about the role of SRF during liver growth and function. To examine the function of SRF in the liver, we generated mice in which the Srf gene was specifically disrupted in hepatocytes. The survival of mice lacking hepatic SRF activity was lower than that of control mice; moreover, surviving mutant mice had lower blood glucose and triglyceride levels compared with control mice. In addition, Srf(loxP/loxP)AlfpCre mice were smaller and had severely depressed levels of serum insulin-like growth factor 1 (IGF-1). Srf-deficient livers were also smaller than control livers, and liver cell proliferation and viability were compromised. Gene array analysis of SRF depleted livers revealed a reduction in many messenger RNAs, including those encoding components of the growth hormone/IGF-1 pathway, cyclins, several metabolic regulators, and cytochrome p450 enzymes. CONCLUSION: SRF is essential for hepatocyte proliferation and survival, liver function, and control of postnatal body growth by regulating hepatocyte gene expression.

Endothelial-specific ablation of serum response factor causes hemorrhaging, yolk sac vascular failure, and embryonic lethality.

BACKGROUND: Serum response factor (SRF), a member of the MADS box family of nuclear transcription factors, plays an important role in cardiovascular development and function. Numerous studies demonstrate a central role for SRF in regulating smooth and cardiac muscle cell gene expression. Consistent with this, loss of SRF function blocks differentiation of coronary vascular smooth muscle cells from proepicardial precursors, indicating SRF is necessary for coronary vasculogenesis. The role of SRF in endothelial cell contribution during early vascular development, however, has not been addressed. To investigate this, we generated transgenic mice lacking expression of SRF in endothelial cells. Mice expressing Cre recombinase (Tie2Cre+) under Tie2 promoter control were bred to mice homozygous for Srf alleles containing loxP recombination sites within the Srf gene (Srff/f). Tie2 is a tyrosine kinase receptor expressed predominantly on endothelial cells that mediates signalling during different stages of blood vessel remodelling. Resulting embryos were harvested at specific ages for observation of physical condition and analysis of genotype. RESULTS: Tie2Cre+/-Srff/f embryos appeared to develop normally compared to wild-type littermates until embryonic day 10.5 (E10.5). Beginning at E11.5, Tie2Cre+/-Srff/f embryos exhibited cerebrovascular hemorrhaging and severely disrupted vascular networks within the yolk sac. Hemorrhaging in mutant embryos became more generalized with age, and by E14.5, most Tie2Cre+/-Srff/f embryos observed were nonviable and grossly necrotic. Hearts of mutant embryos were smaller relative to overall body weight compared to wild-type littermates. Immunohistochemical analysis revealed the presence of vascular endothelial cells; however, vessels failed to undergo appropriate remodelling. Initial analysis by electron microscopy suggested a lack of appropriate cell-cell contacts between endothelial cells. Consistent with this, disrupted E-cadherin staining patterns were observed in mutant embryos. CONCLUSION: These results provide the first in vivo evidence in support of a role for SRF in endothelial cell function and strongly suggest SRF is required for appropriate vascular remodelling.

Conserved enhancer in the serum response factor promoter controls expression during early coronary vasculogenesis.

Serum response factor (SRF) is a transcription factor required for mesoderm formation in the developing mouse embryo that is important for myogenic differentiation, including notably, the differentiation of the proepicardial organ (PEO) into coronary vascular cells during early development. To identify regulatory sequences that control SRF expression during early mouse development, we used a novel transgenic approach to study the role of conserved noncoding DNA sequences (CNCS) in the SRF gene. Embryonic stem (ES) cells containing a targeted single-copy of putative SRF regulatory sequences were used to directly generate transgenic embryos by tetraploid aggregation. Because the ES cell-derived targeted embryos are genetically equivalent, except for the putative regulatory sequence of interest, differences in transgene expression can be attributed directly to these sequences. Using this approach, we identified an E-box/Ets containing 270-bp cis-acting module in the SRF promoter that mediates expression in the PEO. Reporter transgenes containing this module express in derivatives of the PEO that give rise to the coronary vasculature, but do not express in the PEO-derived epicardium. These results are the first reported in vivo analysis of SRF regulatory elements that control expression during early development. Using this reporter module and this approach, it should be possible to begin to elucidate molecular mechanisms involved in the differentiation of coronary vasculature progenitor cells, as well as identify additional SRF regulatory elements important during mammalian development.

Basic calcium phosphate crystals activate c-fos expression through a Ras/ERK dependent signaling mechanism.

Diseases caused by calcium pyrophosphate dihydrate (CPPD) and basic calcium phosphate (BCP) crystals occur frequently in osteoarthritic joints. Both crystals induce mitogenesis, metalloproteinase synthesis and secretion by fibroblasts and chondrocytes, promoting degradation of articular tissue. We investigated the mechanism by which BCP activates the c-fos proto-oncogene, which has been shown to activate various matrix metalloproteinases (MMPs). We demonstrate that BCP crystals induce c-fos expression primarily through a Ras/ERK-dependent signaling mechanism targeting two highly conserved regulatory binding sites, the serum response element (SRE) and the cAMP response element (CRE). These results establish a calcium crystal induced, calcium/calmodulin independent, signaling pathway in which BCP crystals activate Ras/MAPK, which can directly target an SRF-containing transcription factor complex, to induce fibroblasts to secrete metalloproteinases.

Role of the serum response factor in regulating contractile apparatus gene expression and sarcomeric integrity in cardiomyocytes.

The serum response factor (SRF) is a transcriptional regulator required for mesodermal development, including heart formation and function. Previous studies have described the role of SRF in controlling expression of structural genes involved in conferring the myogenic phenotype. Recent studies by us and others have demonstrated embryonic lethal cardiovascular phenotypes in SRF-null animals, but have not directly addressed the mechanistic role of SRF in controlling broad regulatory programs in cardiac cells. In this study, we used a loss-of-function approach to delineate the role of SRF in cardiomyocyte gene expression and function. In SRF-null neonatal cardiomyocytes, we observed severe defects in the contractile apparatus, including Z-disc and stress fiber formation, as well as mislocalization and/or attenuation of sarcomeric proteins. Consistent with this, gene array and reverse transcription-PCR analyses showed down-regulation of genes encoding key cardiac transcriptional regulatory factors and proteins required for the maintenance of sarcomeric structure, function, and regulation. Chromatin immunoprecipitation analysis revealed that at least a subset of these proteins are likely regulated directly by SRF. The results presented here indicate that SRF is an essential coordinator of cardiomyocyte function due to its ability to regulate expression of numerous genes (some previously identified and at least 28 targets newly identified in this study) that are involved in multiple and disparate levels of sarcomeric function and assembly.

SRF-dependent gene expression in isolated cardiomyocytes: regulation of genes involved in cardiac hypertrophy.

Serum response factor (SRF) is a transcription factor required for the regulation of genes important for cardiac structure and function. Notably, the "fetal gene expression profile" that is characteristic of cardiac hypertrophy consists of genes known to be regulated by SRF. Transgenic animal studies suggest that cardiac-specific overexpression of SRF induces this pattern of hypertrophic genes and subsequently causes the progression of pathologic adaptations. Furthermore, studies examining cardiac tissues from patients with severe heart failure indicate significant alterations in SRF expression that correspond with alterations in expression of SRF-dependent genes. Based on these observations, it has been postulated that SRF may be critical for stimulating pathologic gene expression at the onset of hypertrophic adaptation. To address the role of SRF in cardiac hypertrophy we investigated whether SRF is necessary and sufficient for the expression of genes associated with the hypertrophic response. We used isolated cardiomyocytes from both neonatal rats, and transgenic mice containing floxed SRF alleles, to examine cardiac gene expression in response to overexpression and absence of SRF. Using this approach, we demonstrate that SRF is required for the induction of atrial naturetic factor (ANF), c-fos, NCX1, BNP, alpha-actins, alpha-myosin heavy chain, and beta-myosin heavy chain genes. However, overexpression of exogenous SRF in isolated cardiomyocytes is only sufficient to induce NCX1 and alpha-myosin heavy chain. These results indicate that SRF is critical for the regulation and induction of genes associated with the progression of pathologic cardiac hypertrophy, however, the pattern of genes induced by overexpression of SRF in isolated cardiomyocytes is different from those genes expressed in hypertrophic transgenic hearts. This suggests that SRF-dependent gene expression is modulated in a complex manner by in vivo physiologic systems prior to and during heart failure as the organism adapts to cardiac stress.

Gene targeting in the mouse: advances in introduction of transgenes into the genome by homologous recombination.

The ability to stably introduce genes into the germline of animals provides a powerful means to address the genetic basis of physiology. Introduction of genes to generate transgenic animals has facilitated the development of complex genetic models of disease, as well as the in vivo study of gene function. However, one drawback of traditional transgenic technologies in which genes are microinjected into early-stage embryos is that there is little control over where and in how many copies genes are introduced into the genome. The development of animal transgenic technologies, which take advantage of homologous recombination mechanisms and the manipulation of embryonic stem (ES) cells, allows investigators to target and alter specific loci. In mouse transgenic systems, a plethora of sophisticated gene-targeting strategies now permit investigators to manipulate the genome in ways that essentially allow one to introduce virtually any desired change into the genome. Furthermore, when coupled with systems that allow for conditional gene expression, these gene-targeting strategies allow both temporal and tissue specific control of alterations to the genome. In the present review we briefly discuss some of the more recent gene-targeting strategies that have been developed to address the limitations of traditional animal transgenesis.

Restricted inactivation of serum response factor to the cardiovascular system.

Serum response factor (SRF) directs programs of gene expression linked to growth and muscle differentiation. To investigate the role of SRF in cardiovascular development, we generated mice in which SRF is knocked out in >80% of cardiomyocytes and >50% of vascular smooth muscle cells (SMC) through SM22alpha-Cre-mediated excision of SRF's promoter and first exon. Mutant mice display vascular patterning, cardiac looping, and SRF-dependent gene expression through embryonic day (e)9.5. At e10.5, attenuation in cardiac trabeculation and compact layer expansion is noted, with an attendant decrease in vascular SMC recruitment to the dorsal aorta. Ultrastructurally, cardiac sarcomeres and Z disks are highly disorganized in mutant embryos. Moreover, SRF mutant mice exhibit vascular SMC lacking organizing actin/intermediate filament bundles. These structural defects in the heart and vasculature coincide with decreases in SRF-dependent gene expression, such that by e11.5, when mutant embryos succumb to death, no SRF-dependent mRNA expression is evident. These results suggest a vital role for SRF in contractile/cytoskeletal architecture necessary for the proper assembly and function of cardiomyocytes and vascular SMC.