Alterations in Pur(alpha) levels and intracellular localization in the CV-1 cell cycle.

Levels of the single-stranded DNA-binding protein Pur(alpha), previously implicated in control of both DNA replication and gene transcription, are altered during the CV-1 cell cycle. Just prior to the onset of S phase, Pur(alpha) levels drop precipitously, after which they recover nearly 8-fold throughout S and G2 to peak just after mitosis. As observed previously, Pur(alpha) binds the hypophosphorylated form of the retinoblastoma protein, Rb. Coimmunoprecipitation of Pur(alpha) and Rb reveals that the complex declines as cells enter S phase and does not reform as Pur(alpha) levels recover in S and G2. As Pur(alpha) levels recover, the protein is localized to nuclear foci containing newly replicated DNA, as determined by immunoelectron microscopy using different sized gold beads and antibodies against Pur(alpha) and bromodeoxyuridine-labeled DNA. These foci also contain cyclin A, and Pur(alpha) coimmunoprecipitates with cyclin A from extracts of cells in S and G2 phases. Pur(alpha) remains with these foci throughout G2, after the bulk of DNA synthesis has ceased. Changing levels of Pur(alpha) may affect Pur(alpha) functions at the onset of S phase and during progression to mitosis.

Morphological relationships of von Willebrand factor, type VI collagen, and fibrillin in human vascular subendothelium.

von Willebrand factor (vWF) plays an important role in the process of platelet adhesion after endothelial injury by serving as a bridge between constituents of the vascular subendothelium and platelet membrane receptors. We previously presented evidence that type VI collagen microfibrils serve as a binding site for vWF in human vascular subendothelium. However, others have proposed that vWF is not associated with type VI collagen but rather with the thicker elastin-associated microfibrils, which contain several proteins including fibrillin. We therefore investigated the relationships among vWF, type VI collagen, and fibrillin in human vascular subendothelium by immunoelectron microscopy using single- and double-labeling immunogold localization techniques. In addition, we observed the three-dimensional ultrastructure of vWF-microfibril complexes by stereo paired micrographs and stereo viewer. We found that vWF co-localizes only with the type VI collagen microfibrils in subendothelium but not with fibrillin microfibrils or striated collagen. The vWF is present in subendothelium in the form of electron-dense aggregates having diameters varying between 65 and 80 nm that are closely associated with, and enmesh, the type VI collagen microfibrils and have structural similarities to intracellular Weibel-Palade bodies. The occasional co-localization of type VI collagen and fibrillin adjacent to internal elastic lamina was observed. These results are consistent with the hypothesis that type VI collagen, but not fibrillin-containing microfibrils, serves as a physiologically relevant binding site for vWF in the vascular subendothelium, where the type VI collagen-vWF complex may play an important role modulating the hemostatic response to vascular injury.

The human blood-brain barrier glucose transporter (GLUT1) is a glucose transporter of gray matter astrocytes.

Human and monkey brain sections were examined by immunohistochemical light and electron microscopy to determine the distribution of GLUT1, a glucose transporter isoform associated with erythrocytes and endothelial cells of the human blood-brain barrier. Protein immunoblotting of fractionated human brain membranes was performed to determine the distribution of molecular forms of the transporter. GLUT1 staining was abundant in erythrocytes and cerebral endothelium of gray and white matter but was also present diffusely in gray matter neuropil when viewed by light microscopy. Immunoelectron microscopy confirmed the gray matter and vascular localization of GLUT1, with specific GLUT1 staining seen in erythrocytes, gray and white matter endothelial cells, astrocyte foot processes surrounding gray matter blood vessels, and in astrocyte processes adjacent to synaptic contacts. No astrocytic staining was identified in white matter. Astrocyte GLUT1 staining was identified only in mature gray matter regions; undifferentiated regions of preterm (22-23 weeks gestation) cortex had GLUT1 staining only in blood vessels and erythrocytes, as did germinal matrix. Immunoblots of adult human frontal cortex revealed that two forms of GLUT1 (45 and 52 kDa) were present in unfractionated brain homogenates. Immunoblots of vessel-depleted frontal lobe revealed only the 45 kDa form in gray matter fractions, and depleted in membranes prepared from white matter regions. We conclude that the GLUT1 isoform of glucose transporter is present both in endothelium of the blood-brain barrier and in astrocytes surrounding gray matter blood vessels and synapses. Furthermore, the form present in astrocytes is likely to have a lower molecular weight than the form found in cerebral endothelium. The GLUT1 transporter may play an important role not only in astrocyte metabolism, but also in astrocyte-associated pathways supporting neuronal energy metabolism.

Co-localization of von Willebrand factor and type VI collagen in human vascular subendothelium.

The binding of von Willebrand factor (vWF) to subendothelium constitutes an important initial step in the process of platelet adhesion to exposed subendothelium following blood vessel injury. We previously demonstrated that vWF is present in human vascular subendothelium and recently found that a 150 kd vWF-binding protein, which we extracted from subendothelium, is type VI collagen. Although we have established that vWF and type VI collagen bind in vitro, it is not known whether these two proteins are associated in the vascular subendothelium in situ. We, therefore, 1) investigated the morphological effects of our biochemical extraction procedure on human umbilical veins by scanning and transmission electron microscopy, 2) analyzed the subendothelial extract by immunofluorescence for the presence of vWF and collagens and by electron microscopy for morphological characteristics, and 3) localized vWF and type VI collagen in subendothelium by immunofluorescence and by single- and double-label immunoelectron microscopic studies with protein A-conjugated gold particles. We found that the surface exposed following de-endothelialization is composed of microfibrils and contains very little fibrillar collagen. The subendothelium is stripped after sodium dodecyl sulfate-urea extraction, and the extract itself contains immunoreactive vWF and type VI collagen but no immunoreactive type I or III fibrillar collagens. Immunofluorescence and immunoelectron microscopic studies showed that vWF and type VI collagen are both present in subendothelium, where both co-localized to microfibrils. In conclusion, vWF that binds to type VI collagen in vitro, also co-localizes with type VI collagen in subendothelium, where both are associated with microfibrils. Type VI collagen, therefore appears to serve as a biologically significant binding site for vWF in vivo and may thereby play a role in mediating platelet adhesion to exposed subendothelium following vascular injury.

Localization of surface vWF on resting and stimulated platelets.

We used immunoelectron microscopic localization techniques to investigate whether platelets stimulated by ADP or ristocetin in the plasma milieu bind von Willebrand factor (vWF) to their surfaces. We found by both peroxidase- and ferritin-based methods that unstimulated platelets lack vWF on their surfaces, whereas platelets that are stimulated with ADP or ristocetin have vWF associated with their surfaces. The specificity of the findings was confirmed by absorption studies using severe von Willebrand disease (vWD) and hemophilic plasmas. The anti-vWF antibodies were blocked by incubation with hemophilic plasma but not by incubation with severe vWD plasma. Thus, in the plasma environment, in the presence of fibrinogen, vWF becomes associated with the platelet surface subsequent to stimulation with ADP or ristocetin.

Distribution of von Willebrand factor in porcine intima varies with blood vessel type and location.

The von Willebrand factor (vWF) has been generally accepted as a marker for endothelial cells. In a systematic immunolocalization study of porcine blood vessels that used indirect immunofluorescence with a monospecific polyclonal anti-vWF and two monoclonal anti-vWFs, we observed that vWF is not universally distributed in intact, fresh endothelia. vWF is consistently localized in veins, with the exception of the pulmonic vein. In arteries, vWF is generally absent except for areas of the distal abdominal aorta, the vaso vasorum of the thoracic aorta, and the pulmonic artery. We conclude that there are regional differences in the distribution of vWF in the various endothelial beds of pigs.