Vascular endothelial adrenomedullin-RAMP2 system is essential for vascular integrity and organ homeostasis.

BACKGROUND: Revealing the mechanisms underlying the functional integrity of the vascular system could make available novel therapeutic approaches. We previously showed that knocking out the widely expressed peptide adrenomedullin (AM) or receptor activity-modifying protein 2 (RAMP2), an AM-receptor accessory protein, causes vascular abnormalities and is embryonically lethal. Our aim was to investigate the function of the vascular AM-RAMP2 system directly. METHODS AND RESULTS: We generated endothelial cell-specific RAMP2 and AM knockout mice (E-RAMP2(-/-) and E-AM(-/-)). Most E-RAMP2(-/-) mice died perinatally. In surviving adults, vasculitis occurred spontaneously. With aging, E-RAMP2(-/-) mice showed severe organ fibrosis with marked oxidative stress and accelerated vascular senescence. Later, liver cirrhosis, cardiac fibrosis, and hydronephrosis developed. We next used a line of drug-inducible E-RAMP2(-/-) mice (DI-E-RAMP2(-/-)) to induce RAMP2 deletion in adults, which enabled us to analyze the initial causes of the aforementioned vascular and organ damage. Early after the induction, pronounced edema with enhanced vascular leakage occurred. In vitro analysis revealed the vascular leakage to be caused by actin disarrangement and detachment of endothelial cells. We found that the AM-RAMP2 system regulates the Rac1-GTP/RhoA-GTP ratio and cortical actin formation and that a defect in this system causes the disruption of actin formation, leading to vascular and organ damage at the chronic stage after the gene deletion. CONCLUSIONS: Our findings show that the AM-RAMP2 system is a key determinant of vascular integrity and homeostasis from prenatal stages through adulthood. Furthermore, our models demonstrate how endothelial cells regulate vascular integrity and how their dysregulation leads to organ damage.

Time-lapse videomicrographic observations of blastocyst hatching in cattle.

Morphological changes of cultured bovine blastocysts during hatching were observed using time-lapse videomicrography in order to investigate the patterns of the hatching process that occurred in the blastocysts and to determine whether the hatching patterns differed between blastocysts developed from fresh and cryopreserved embryos. Compacted morulae (CMs) were collected from superovulation-treated Japanese Black and Holstein dairy cattle and cultured in a medium in a CO(2) culture chamber equipped with an inverted microscope at 38.5 C. Images of resultant blastocysts during the period from blastocoel formation to completion of hatching were taken at 4-sec intervals by a CCD color camera connected to an inverted microscope and recorded by a time-lapse video cassette recorder. In blastocysts developed from fresh CMs, hatching was found to begin with protrusion of trophectoderm cells from zonae pellucidae at the expanded stage. Protrusion of the cells occurred in any site of the trophectoderm. After protrusion, a large or small slit was formed in the zona pellucida in all blastocysts as a result of blastocyst expansion or enlargement of the protrusion. Then, blastocysts completely escaped from the zona pellucida through the slit in the state of expansion. From these findings, the hatching patterns of cattle blastocysts could be classified into 5 types. In blastocysts developed from frozen-thawed CMs, the hatching pattern and length of time needed for hatching are similar to those in blastocysts developed from fresh CMs. In addition, the pregnancy rate of recipients following transfer of frozen-thawed CMs (52.4%) did not differ from that of recipients following transfer with fresh CMs (58.3%). These results suggested that the quality of frozen-thawed cattle embryos is comparable to that of fresh embryos and that there could be a relationship between the hatching pattern of blastocysts and the viability of embryos after transfer.