The specific cytochemical demonstration in the electron microscope of periodate-reactive mucosubstances and polysaccharides containing vic-glycol groups

Summary A technique is described for the localization in the electron microscope of periodate-reactive mucosubstances and polysaccharides containing vic-glycol groups. In this technique the sugar residues are oxidized by periodic acid and the resulting aldehydes condensed with pentafluorophenylhydrazine under specified conditions. Further increase in specific electron density is achieved by treating the hydrazone end-product with ammonium sulphide followed by osmium tetroxide to form an osmium black.The technique has been applied to liver and small intestine cells in which glycogen, sialomucins and sulphated mucosubstances reacted especially strongly. A marked positive reaction has also been obtained from the interstitial cell matrix and from the Golgi apparatus and multivesicular bodies of the intestinal epithelial cells.The reaction can be prevented by the omission of the periodate oxidation and, if due to glycogen, by prior treatment with diastase.     

Rate of 59Fe Uptake into Brain and Cerebrospinal Fluid and the Influence Thereon of Antibodies Against the Transferrin Receptor

Abstract: Uptake of ⁵⁹Fe from blood into brains of anaesthetized rats and mice has been studied by intravenous infusion of [⁵⁹Fe]ferrous ascorbate or of ⁵⁹Fe-transferrin, the results not being significantly different. Uptakes in the rat were linear with time, but increased at longer times in the mouse. Transfer constants, K _in (in ml/g/h × 10³), for cerebral hemispheres were 5.2 in the adult rat and 5.6 in the mouse. These K _in values corresponded to ⁵⁹Fe influxes of 145 and 322 pmol/g/h, respectively. ⁵⁹Fe uptake into the mouse brain occurred in the following order: cerebellum > brainstem > frontal cerebral cortex > parietal cortex > occipital cortex > hippocampus > caudate nucleus. In genetically hypotransferrinaemic mice, ⁵⁹Fe uptake into brain was 80–95 times greater than in To strain mice. Pretreatment of young rats and mice with monoclonal antibodies to transferrin receptors, i.e., the anti-rat immunoglobulin G OX 26 and the anti-mouse immunoglobulin M RI7 208, inhibited ⁵⁹Fe uptake into spleen by 94% and 98%, respectively, indicating saturation of receptors. The antibodies reduced ⁵⁹Fe uptake into rat brain by 35–60% and that into mouse brain by 65–85%. Although a major portion of iron transport across the blood-brain barrier is normally transferrin-mediated, non-transferrin-bound iron readily crosses it at low serum transferrin levels.     

Organization of centromeres in the decondensed nuclei of mature human sperm

The localization of centromeres in mature human sperm was shown by immunofluorescent labeling and nonisotopic in situ hybridization. In the decondensed nucleus structural elements (dimers, tetramers, linear arrays and V shape structures) formed by individual centromeres of nonhomologous chromosomes were observed. They organize the compact chromocenter, which was shown for nuclei decondensed to a low extent. The chromocenter is buried inside the nucleus; in contrast, telomeric regions of chromosomes were tentatively localized on the periphery. Thus, a gross architecture, which can influence selective unpackaging of the paternal genome upon fertilization, exists in human sperm.     

Uptake of Ga-67 into rat cerebral hemisphere and cerebellum. Comparison with Fe-59.

Transferrin and transferrin receptors play an important role in the transport of iron into the brain. To determine whether gallium enters the brain by the same mechanism, uptakes of Ga and 59Fe have been compared under controlled conditions. Rates of gallium penetration into brain (K) were four times slower than those for 59Fe. Kin for Ga when infused with citrate were 0.88 ± 0.24 and 0.94 ± 0.39 x 10 ml gh for cerebral hemisphere and cerebellum, respectively. When infused as the transferrin complex, Ga uptake into the brain was not different from that when infused with citrate. The presence of the anti-transferrin receptor antibody OX-26 significantly reduced uptake of Fe by 60% and 64% into cerebral hemisphere and cerebellum, respectively. By contrast, pretreatment of rats with OX-26 enhanced the uptake of Ga into brain, particularly when infused with citrate; mean increases in uptake of Ga were 120% and 144% for cerebral hemisphere and cerebellum, respectively. Purified Ga-transferrin was also taken up into both brain regions examined in the presence of OX-26. These results indicate that the transport of non-transferrin bound gallium is an important mechanism for gallium uptake into brain.     

Transport of Iron in the Blood-Brain-Cerebrospinal Fluid System

Abstract: Iron is an important constituent in brain and, in certain regions, e.g., the basal nuclei, reaches concentrations equivalent to those in liver. It has a role in electron transfer and is a cofactor for certain enzymes, including those involved in catecholamine and myelin synthesis. Iron in CSF is likely to be representative of that in interstitial fluid of brain. Transferrin in CSF is fully saturated, and the excess iron may be loosely bound as Fe(II). Brain iron is regulated in iron depletion, suggesting a role for the blood-brain barrier (BBB). Iron crosses the luminal membrane of the capillary endothelium by receptor-mediated endocytosis of ferric transferrin. This results in an initial linear uptake of radioactive iron into brain at an average rate relative to serum of about 3.3 × 10^?3 ml·g of brain^?1·h^?1 in the adult rat. This corresponds to about 80 nmol·kg^?1·h^?1. Much higher rates occur in the postnatal rat. These increase during the first 15 days of life and decline thereafter. Within the endothelium, most of the iron is separated from transferrin, presumably by the general mechanism of acidification within the endosome. Iron appears to be absorbed from the vesicular system into cytoplasm and transported across the abluminal plasma membrane into interstitial fluid as one or more species of low molecular weight. There is some evidence that ionic Fe(II) is involved. Certainly Fe(II) ions presented on the luminal side rapidly cross the complete BBB, i.e., luminal and abluminal membranes. Within interstitial fluid, transported iron will bind with any unsaturated transferrin synthesized or transported into the brain-CSF system. Oligodendrocytes are one site of synthesis. From interstitial fluid, ferric transferrin is taken up by neurones and glial cells by the usual receptor-mediated endocytosis. Calculations of the amount of iron leaving the system with the bulk flow of CSF indicate that most iron entering brain across the capillary endothelium finally leaves the system with the bulk outflow of CSF through arachnoid villi and other channels. A system in which influx of iron into brain is by regulated receptor-mediated transport and in which efflux is by bulk flow is ideal for homeostasis of brain iron.     

Endogenous cyclic AMP-stimulated phosphorylation of a Wolfgram protein component in rabbit central-nervous-system myelin.

Cyclic AMP-stimulated phosphorylation of membrane proteins in central-nervous-system myelin was investigated, with rabbit brain myelin. Subfractionation of a myelin membrane preparation by sucrose-density-gradient centrifugation produced a rapidly sedimenting population of membrane vesicles containing 5'-nucleotidase and acetylcholinesterase, a light membrane fraction containing myelin basic protein and 2',3'-cyclic nucleotide 3'-phosphodiesterase, and an intermediate membrane fraction containing the highest specific activity of 2',3'-cyclic nucleotide 3'-phosphodiesterase and a small proportion of myelin basic protein. Cyclic AMP stimulation of protein phosphorylation was confined to a protein of Mr 49 700, which co-electrophoresed with the upper component of the Wolfgram protein doublet. Cyclic AMP did not affect the phosphorylation of myelin basic protein. Cyclic AMP-stimulated phosphorylation of this protein followed 2',3'-cyclic nucleotide 3'-phosphodiesterase activity on subcellular fractionation and was correspondingly high in the intermediate or 'myelin-like' fraction on sucrose-density-gradient centrifugation.