Arterial supply of the choriocapillaris of anuran amphibians (Rana temporaria,Rana esculenta)

Summary The pattern of the vascular supply to the choroid of the frog eye was studied in toto with the use of the injection-replication-SEM technique. The choroid of anuran amphibians is composed mainly of the choriocapillaris. In both species studied (Rana temporaria, Rana esculenta), an independent arterial supply to the choriocapillaris supplemented that from the ciliary arteries. This additional vascular route arises from the optic artery, a separate branch of the arteria infundibularis superficialis. The optic artery, accompanied by its vein within the vascular sheath of the optic nerve, joins the rich arterial capillary network of the choriocapillaris and supplies the posterior pole of the ocular bulb. The superficial capillary network displays a dense collar around the entrance of the optic nerve into the eye and is composed of a circular meshwork of small capillaries, several layers deep. More peripherally, however, it becomes single layered. This capillary network, as a whole, establishes numerous connections with the adjacent choriocapillaris at the posterior pole of the ocular bulb. In anuran amphibians the complex arrangement of both arterial systems supporting the choriocapillaris may be regarded as a more complete equivalent of the short posterior ciliary arteries of mammals.     

The cell surface of a restrictive fenestrated endothelium

Summary The location and chemical composition of anionic sites on the endothelium of the choriocapillaris was investigated with cationic ferritin and enzyme digestion techniques. Cationic ferritin administered intravenously initially labeled essentially all fenestral diaphragms. Within 30 min after injection, no diaphrams remained labeled, but they could be relabeled by a second cationic ferritin injection. Following perfusion of cationic ferritin, the entire luminal front of the endothelium was labeled: the plasmalemma and fenestral, vesicle, and channel diaphragms. Perfusion of neuraminidase or chondroitinase did not affect subsequent cationic ferritin binding. In contrast, heparitinase removed anionic sites on all structures except fenestral diaphragms. Cationic ferritin did not mark the endothelium following heparinase digestion. All sites were cleaved with pronase E. These results indicate that heparin is the anionic moiety on fenestral diaphragms while the glycocalcyces of the plasmalemma and vesicle and channel diaphragms are rich in a heparan sulfate proteoglycan. Furthermore, since the heparan sulfate localized to these structures was digested by both heparinase and heparitinase, it is in a form similar to heparin. These findings demonstrate that the endothelium of the choriocapillaris bears cell-surface anionic components that are different than those described for fenestrated endothelia lining other vascular beds.Supported by NIH EY 03776     

Binding and endocytosis of heparin-gold conjugates by the fenestrated endothelium of the rat choriocapillaris

Summary Heparin-gold probes were used to localize regions of heparin binding on the luminal surface of the diaphragmed-fenestrated endothelium of the rat choriocapillaris. Structures of endothelial cells were unlabeled when rats were kept on ice and perfused with solutions at 4° C. When the heparin-gold quantity was doubled, only a few heparin-gold particles marked some diaphragms spanning fenestrae, vesicles and channels, parajunctional regions of the plasmalemma, and coated pits. With solutions at 4° C, but the animals kept at room temperature, all of these structures in the endothelial cells were labeled. This binding was not altered by the perfusion of low levels of unlabeled heparin, but was eliminated following high levels of unlabeled heparin, and by digestion with trypsin and pronase. At 37° C, heparin was localized to the above structures and, in addition, was internalized into coated vesicles, endosomes, and multivesicular bodies, but not other types of lysosomes. Some particles were found in tubules adjacent to the Golgi stacks. Heparin-gold was also transported to the abluminal front of the endothelium by vesicles. A desulfated, non-anticoagulant, fraction of heparin bound to gold was localized to the endothelium in the same manner. These results demonstrate receptors for heparin on the surface of a fenestrated endothelium. Furthermore, they show the pathway of endocytosis and transport of heparin. The possible roles of heparin in the function of the endothelium is discussed.