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"Eichenberger, Jerry A"
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Platelets and Platelet Adhesion Support Angiogenesis while Preventing Excessive Hemorrhage
Platelets contain both pro- and antiangiogenic factors, but their regulatory role in angiogenesis is poorly understood. Although previous studies showed that platelets stimulate angiogenesis in vitro, the role of platelets in angiogenesis in vivo is largely uncharacterized. To address this topic, we used two in vivo approaches, the cornea micropocket assay and the Matrigel model, in four animal models: thrombocytopenic, $Lyst^{bg}$ (platelet storage pool deficiency), glycoprotein (GP) Ibα/IL4R transgenic (lacking extracellular GPIbα, the receptor for von Willebrand factor as well as other adhesive and procoagulant proteins), and $Fc\\gammaR^{-/-}$ (lacking functional GPVI, the collagen receptor) mice. Adult mice were rendered thrombocytopenic by i.p. administration of an antiplatelet antibody. The number of growing vessels in the thrombocytopenic mice was lower in the cornea assay, and they showed significantly increased appearance of hemorrhage compared with mice treated with control IgG. The thrombocytopenic mice also showed more protein leakage and developed hematomas in the Matrigel model. GPIbα/IL4R transgenic mice presented increased hemorrhage in both assays, but it was less severe than in the platelet-depleted mice. $Fc\\gammaR^{-/-}$ and $Lyst^{bg}$ mice showed no defect in experimental angiogenesis. Intravital microscopy revealed a >3-fold increase in platelet adhesion to angiogenic vessels of Matrigel compared with mature quiescent skin vessels. Our results suggest that the presence of platelets not only stimulates angiogenic vessel growth but also plays a critical role in preventing hemorrhage from the angiogenic vessels. The adhesion function of platelets, as mediated by GPIbα, significantly contributes to the process.
Journal Article
Legume genome structures and histories inferred from Cercis canadensis and Chamaecrista fasciculata genomes
The legume family originated ca. 70 million years ago and soon diversified into at least six lineages (now extant subfamilies). The signal of whole genome duplications (WGD) is apparent in species sampled from all six subfamilies. The early diversification has posed difficulties for resolving the legume backbone structure and the timing of WGDs.
In this study, we report the genome sequences and annotations for Cercis canadensis (Cercidoideae) and Chamaecrista fasciculata (Caesalpinoideae) to help resolve the relative taxonomic placements along the legume backbone, the timings of WGDs relative to subfamily origins, and the ancestral legume karyotype.
Analyses of genome assemblies from four subfamilies within Fabaceae show that the last common ancestor of all legumes likely had seven chromosomes, with a genome structure similar to the extant Cercis genome. Our analysis supports an allopolyploid origin of the subfamily Caesalpinoideae, with progenitors involving lineages along the backbone of the legume phylogeny.
A probable allopolyploid origin of Caesalpinoideae subfamily provides a partial explanation for the difficulty in resolving the structure of the legume backbone. The retained karyotype structure and lack of a WGD in the last 100+ Mya, underscore the utility of the Cercis genome as an ancestral reference for the legume family.
Paper