Publications by Year: 2009

2009

Elmasri, Harun, Cagatay Karaaslan, Yaroslav Teper, Elisa Ghelfi, Meiqian Weng, Tan Ince, Harry Kozakewich, Joyce Bischoff, and Sule Cataltepe. (2009) 2009. “Fatty Acid Binding Protein 4 Is a Target of VEGF and a Regulator of Cell Proliferation in Endothelial Cells”. FASEB J 23 (11): 3865-73. https://doi.org/10.1096/fj.09-134882.
Fatty acid binding protein 4 (FABP4) plays an important role in maintaining glucose and lipid homeostasis. FABP4 has been primarily regarded as an adipocyte- and macrophage-specific protein, but recent studies suggest that it may be more widely expressed. We found strong FABP4 expression in the endothelial cells (ECs) of capillaries and small veins in several mouse and human tissues, including the heart and kidney. FABP4 was also detected in the ECs of mature human placental vessels and infantile hemangiomas, the most common tumor of infancy and ECs. In most of these cases, FABP4 was detected in both the nucleus and cytoplasm. FABP4 mRNA and protein levels were significantly induced in cultured ECs by VEGF-A and bFGF treatment. The effect of VEGF-A on FABP4 expression was inhibited by chemical inhibition or short-hairpin (sh) RNA-mediated knockdown of VEGF-receptor-2 (R2), whereas the VEGFR1 agonists, placental growth factors 1 and 2, had no effect on FABP4 expression. Knockdown of FABP4 in ECs significantly reduced proliferation both under baseline conditions and in response to VEGF and bFGF. Thus, FABP4 emerged as a novel target of the VEGF/VEGFR2 pathway and a positive regulator of cell proliferation in ECs.
Dal-Bianco, Jacob, Elena Aikawa, Joyce Bischoff, Luis Guerrero, Mark Handschumacher, Suzanne Sullivan, Benjamin Johnson, et al. 2009. “Active Adaptation of the Tethered Mitral Valve: Insights into a Compensatory Mechanism for Functional Mitral Regurgitation”. Circulation 120 (4): 334-42. https://doi.org/10.1161/CIRCULATIONAHA.108.846782.
BACKGROUND: In patients with left ventricular infarction or dilatation, leaflet tethering by displaced papillary muscles frequently induces mitral regurgitation, which doubles mortality. Little is known about the biological potential of the mitral valve (MV) to compensate for ventricular remodeling. We tested the hypothesis that MV leaflet surface area increases over time with mechanical stretch created by papillary muscle displacement through cell activation, not passive stretching. METHODS AND RESULTS: Under cardiopulmonary bypass, the papillary muscle tips in 6 adult sheep were retracted apically short of producing mitral regurgitation to replicate tethering without confounding myocardial infarction or turbulence. Diastolic leaflet area was quantified by 3-dimensional echocardiography over 61+/-6 days compared with 6 unstretched sheep MVs. Total diastolic leaflet area increased by 2.4+/-1.3 cm(2) (17+/-10%) from 14.3+/-1.9 to 16.7+/-1.9 cm(2) (P=0.006) with stretch with no change in the unstretched valves despite sham open heart surgery. Stretched MVs were 2.8 times thicker than normal (1.18+/-0.14 versus 0.42+/-0.14 mm; P<0.0001) at 60 days with an increased spongiosa layer. Endothelial cells (CD31(+)) coexpressing alpha-smooth muscle actin were significantly more common by fluorescent cell sorting in tethered versus normal leaflets (41+/-19% versus 9+/-5%; P=0.02), indicating endothelial-mesenchymal transdifferentiation. alpha-Smooth muscle actin-positive cells appeared in the atrial endothelium, penetrating into the interstitium, with increased collagen deposition. Thickened chordae showed endothelial and subendothelial alpha-smooth muscle actin. Endothelial-mesenchymal transdifferentiation capacity also was demonstrated in cultured MV endothelial cells. CONCLUSIONS: Mechanical stresses imposed by papillary muscle tethering increase MV leaflet area and thickness, with cellular changes suggesting reactivated embryonic developmental pathways. Understanding such actively adaptive mechanisms can potentially provide therapeutic opportunities to augment MV area and reduce ischemic mitral regurgitation.
Boscolo, Elisa, and Joyce Bischoff. (2009) 2009. “Vasculogenesis in Infantile Hemangioma”. Angiogenesis 12 (2): 197-207. https://doi.org/10.1007/s10456-009-9148-2.
Infantile hemangioma is a vascular tumor that occurs in 5-10% of infants of European descent. A defining feature of infantile hemangioma is the dramatic growth and development into a disorganized mass of blood vessels. Subsequently, a slow spontaneous involution begins around 1 year of age and continues for 4-6 years. The growth and involution of infantile hemangioma is very different from other vascular tumors and vascular malformations, which do not regress and can occur at any time during childhood or adult life. Much has been learned from careful study of the tissue morphology and gene expression patterns during the life-cycle of hemangioma. Tissue explants and tumor-derived cell populations have provided further insight to unravel the cellular and molecular basis of infantile hemangioma. A multipotent progenitor cell capable of de novo blood vessel formation has been isolated from infantile hemangioma, which suggests that this common tumor of infancy, long considered to be a model for pathologic angiogenesis, may also represent pathologic vasculogenesis. Whether viewed as angiogenesis or vasculogenesis, infantile hemangioma represents a vascular perturbation during a critical period of post-natal growth, and as such provides a unique opportunity to decipher mechanisms of human vascular development.
Bischoff, Joyce. (2009) 2009. “Progenitor Cells in Infantile Hemangioma”. J Craniofac Surg 20 Suppl 1: 695-7. https://doi.org/10.1097/SCS.0b013e318193d6ac.
Infantile hemangioma is a vascular tumor that occurs in 5% to 10% of infants of European descent. A hallmark of infantile hemangioma is its life cycle, which is divided into 3 stages. The proliferating phase spans in the first year of postnatal life and is characterized by cellular masses without a defined vascular architecture and nascent blood vessels with red blood cells evident within the lumenal space. The involuting phase begins at 1 year of age and continues for 3 to 5 years. Proliferation slows or stops in this phase, and histologic examination shows that the blood vessel architecture becomes more obvious and vessel size is enlarged. The involuted phase reaches 5 to 8 years of age, at which point blood vessels are replaced with a fibrofatty residuum and capillary-sized channels. The growth and involution life cycle of infantile hemangioma are very different from other vascular tumors and vascular malformations, which do not regress and can occur at any time during childhood or adult life. Many laboratories have reported on the endothelial characteristics of the cellular masses that are prominent in the proliferating phase of infantile hemangioma, as well as their immature appearance. These studies, along with isolation and characterization of hemangioma-derived cell populations with progenitor cell properties, have lead to an emerging hypothesis that hemangioma is caused by an abnormal or delayed differentiation of mesodermal progenitor cells into the disorganized mass of blood vessels. In this paper, we discuss the literature that supports this emerging hypothesis.