Endogenous regulation of cardiovascular function by apelin-APJ.

Studies have shown significant cardiovascular effects of exogenous apelin administration, including the potent activation of cardiac contraction. However, the role of the endogenous apelin-APJ pathway is less clear. To study the loss of endogenous apelin-APJ signaling, we generated mice lacking either the ligand (apelin) or the receptor (APJ). Apelin-deficient mice were viable, fertile, and showed normal development. In contrast, APJ-deficient mice were not born in the expected Mendelian ratio, and many showed cardiovascular developmental defects. Under basal conditions, both apelin and APJ null mice that survived to adulthood manifested modest decrements in contractile function. However, with exercise stress both mutant lines demonstrated consistent and striking decreases in exercise capacity. To explain these findings, we explored the role of autocrine signaling in vitro using field stimulation of isolated left ventricular cardiomyocytes lacking either apelin or APJ. Both groups manifested less sarcomeric shortening and impaired velocity of contraction and relaxation with no difference in calcium transient. Taken together, these results demonstrate that endogenous apelin-APJ signaling plays a modest role in maintaining basal cardiac function in adult mice with a more substantive role during conditions of stress. In addition, an autocrine pathway seems to exist in myocardial cells, the ablation of which reduces cellular contraction without change in calcium transient. Finally, differences in the developmental phenotype between apelin and APJ null mice suggest the possibility of undiscovered APJ ligands or ligand-independent effects of APJ.

Identification of endothelial cell genes by combined database mining and microarray analysis.

Vascular endothelial cells maintain the interface between the systemic circulation and soft tissues and mediate critical processes such as inflammation in a vascular bed-selective fashion. To expand our understanding of the genetic pathways that underlie these specific functions, we have focused on the identification of novel genes that are differentially expressed in all endothelial cells, as well as restricted groups of this cell type. Virtual subtraction was conducted employing gene expression data deposited in public databases and 384 genes identified. These genes were spotted on custom microarrays, along with 288 genes identified through subtraction cloning from TGF-beta-stimulated endothelial cells. Arrays were evaluated with RNA samples representing endothelial cells cultured from four vascular sources and five non-endothelial cell types. These studies identified 64 pan-endothelial markers that were differentially expressed with at least a threefold difference (range 3- to 55-fold). In addition, differences in gene expression profiles among endothelial cells from different vascular beds were identified. Validation of these findings was performed by RNA blot expression studies, and a number of the novel genes were shown to be expressed under angiogenic conditions in the developing mouse embryo. The combined tools of database mining and transcriptional profiling thus provide expanded knowledge of endothelial cell gene expression and endothelial cell biology.

Targeted disruption of endothelial cell-selective adhesion molecule inhibits angiogenic processes in vitro and in vivo.

Endothelial cell-selective adhesion molecule (ESAM) is a member of the immunoglobulin receptor family that mediates homophilic interactions between endothelial cells. To address potential in vivo angiogenic functions of this molecule, mice lacking ESAM (ESAM-/-) were generated by gene-targeted deletion. ESAM-/- mice did not show overt morphological defects in the vasculature. To evaluate the role of ESAM in pathological angiogenesis, wild type (WT) and ESAM-/- mice were injected with melanoma and Lewis lung carcinoma cells. By 14 days after injection, tumor volumes of B16F10 and LL/2 in ESAM-/- mice were 48 and 37% smaller, respectively, compared with WT mice. Vascular density of the tumors, as determined by CD31 staining, was also decreased in the ESAM null animals. Matrigel plug assays showed less neovascularization in ESAM-/- mice than in WT mice. ESAM-/- endothelial cells exhibited less in vitro tube formation and decreased migration in response to basic fibroblast growth factor when compared with WT cells, and endothelial-like yolk sac cells engineered to overexpress ESAM showed accelerated tube formation in vitro. These in vitro and in vivo studies suggest that ESAM has a redundant functional role in physiological angiogenesis but serves a unique and essential role in pathological angiogenic processes such as tumor growth.