Hyperphosphorylation of histone H2A.X and dephosphorylation of histone H1 subtypes in the course of apoptosis.

Chromatin condensation paralleled by DNA fragmentation is one of the most important nuclear events occurring during apoptosis. Histone modifications, and in particular phosphorylation, have been suggested to affect chromatin function and structure during both cell cycle and cell death. We report here that phosphate incorporation into all H1 subtypes decreased rapidly after induction of apoptosis, evidently causing a strong reduction in phosphorylated forms of main H1 histone subtypes. H1 dephosphorylation is accompanied by chromatin condensation preceding the onset of typical chromatin oligonucleosomal fragmentation, whereas H2A.X hyperphosphorylation is strongly correlated to apoptotic chromatin fragmentation. Using various kinase inhibitors we were able to exclude some of the possible kinases which can be involved directly or indirectly in phosphorylation of histone H2A.X. Neither DNA-dependent protein kinase, protein kinase A, protein kinase G, nor the kinases driven by the mitogen-activated protein kinase (MAP) pathway appear to be responsible for H2A.X phosphorylation. The protein kinase C activator phorbol 12-myristate 13-acetate (PMA), however, markedly reduced the induction of apoptosis in TNFalpha-treated cells with a simultaneous change in the phosphorylation pattern of histone H2A.X. Hyperphosphorylation of H2A.X in apoptotic cells depends indirectly on activation of caspases and nuclear scaffold proteases as shown in zVAD-(OMe)-fmk- or zAPF-cmk-treated cells, whereas the dephosphorylation of H1 subtypes seems to be influenced solely by caspase inhibitors. Together, these results illustrate that H1 dephosphorylation and H2A.X hyperphosphorylation are necessary steps on the apoptotic pathway.

Intravital lectin perfusion analysis of vascular permeability in human micro- and macro- blood vessels.

We previously applied intravital lectin perfusion in mouse models to elucidate mechanisms underlying vascular permeability. The present work transfers this technique to human models, analysing vascular permeability in macro- and microvessels. Human vascular endothelial surface carbohydrate biochemistry differs significantly from its murine counterpart, lacking alpha-galactosyl epitopes and expressing the L-fucose moiety in the glycocalyx; the poly-N-lactosamine glycan backbone is common to all mammals. We examined extensively lectin binding specificities in sections and in vivo, and then applied the poly-N-lactosamine-specific lectin LEA and the L-fucose-specific lectin UEA-I in human intravital perfusions. Transendothelial transport differed in macrovessels and microvessels. In microvessels of adult human fat tissue, rectal wall and rectal carcinomas, slow transendothelial transport by vesicles was followed by significant retention at the subendothelial basement membrane; paracellular passage was not observed. Passage time exceeded 1 h. Thus we found barrier mechanisms resembling those we described previously in murine tissues. In both adult and fetal macrovessels, the vena saphena magna and the umbilical vein, respectively, rapid passage across the endothelial lining was observed, the tracer localising completely in the subendothelial tissues within 15 min; vesicular transport was more rapid than in microvessels, and retention at the subendothelial basement membrane briefer.

Vascular permeability and hyperpermeability in a murine adenocarcinoma after fractionated radiotherapy: an ultrastructural tracer study.

Large radiation doses cause postradiation vascular hyperpermeability by disrupting endothelia. The cumulative sequences of small doses (fractionated radiotherapy) standard in clinical practice cause it too, but not by endothelial disruption: the mechanisms are unknown. In this study, correlated fluorescent and ultrastructural localisation of a tracer revealed the architecture, fine structure and function of microvessels in mouse AT17 tumours, before and after 42 Gy fractionated radiation. Before irradiation, tumour vascular permeability lay in the normophysiological range defined by the gut and cerebral cortex. A double barrier regulated permeability: vesicular transport through the endothelial wall required approximately 2 h and then the basement membrane charge barrier trapped tracer for 2 h longer. Irradiation abolished the double barrier: tracer passed instantly through both endothelial wall and underlying basement membrane, forming diffusion haloes around microvessels within 2-5 min. Structurally, irradiated tumour microvessels were lined by a continuous and vital endothelium with closed interendothelial junctions; endothelial basement membranes were intact, though loosened. Irradiated endothelia exhibited extremely active membrane motility and intracellular vesicle trafficking. Radiation treatment raised vascular permeability by enhancing transendothelial transcytosis, and by altering the passive filter properties of the subendothelial basement membrane. This type of vascular hyperpermeability should be susceptible to pharmacological modulation.

Cryopreparation provides new insight into the effects of brefeldin A on the structure of the HepG2 Golgi apparatus.

High-pressure freezing and freeze-substitution were used to study Golgi ultrastructure and its brefeldin A-induced transformations in HepG2 human hepatoma cells. Cryoimmobilization arrested subcellular dynamics within milliseconds, thus considerably improving the temporal resolution in monitoring the very early effects of high brefeldin concentrations at the ultrastructural level (i.e., 20 microg/ml brefeldin applied for 35 s to 8 min). Moreover, this approach ruled out possible cumulative and/or synergistic effects of the drug and fixatives. Several findings differed from studies based on chemical fixation. In particular, Golgi breakdown did not proceed gradually but occurred in distinct steps. We found a conspicuous lag between the absence of nonclathrin coats on Golgi membranes after 30 s of brefeldin treatment and the disassembly of the stacks, which did not start until after 90 to 120 s. At this time, domains at the trans and cis faces separated from the stacks, starting tubulation and fragmentation. After 3-5 min the Golgi apparatus was completely replaced by loose meshworks of straight tubules of different sizes and staining properties; also frequent were bent tubules and vesicles forming glomerule-like structures. After 8 min all kinds of Golgi-derived structures had aggregated within huge clusters. The morphologically highly distinct structures found after brefeldin treatment could in part be correlated with particular Golgi domains in the control cells.

Lectin intravital perfusion studies in tumor-bearing mice: micrometer-resolution, wide-area mapping of microvascular labeling, distinguishing efficiently and inefficiently perfused microregions in the tumor.

Intravital lectin perfusion was combined with computer-guided scanning digital microscopy to map the perfused elements of the vasculature in tumor-bearing mice. High-precision composite images (spatial precision 1.3 micron and optical resolution 1.5 micron) were generated to permit exact positioning, reconstruction, analysis, and mapping of entire tumor cross-sections (c. 1 cm in diameter). Collation of these mosaics with nuclear magnetic resonance maps in the same tumor plane identified sites of rapid contrast medium uptake as tumor blood vessels. Digitized imaging after intravital double labeling allowed polychromatic visualization of two different types of mismatched staining. First, simultaneous application of two lectins, each bearing a different fluorochrome, revealed organ-specific differential processing in the microvascular wall. Second, sequential application of two boluses of one lectin, bearing different fluorochromes successively, distinguished between double-labeled microvessels, representing efficiently perfused vascular segments, and single-labeled microvessels, with inefficient or intermittent perfusion. Intravital lectin perfusion images of blood vessels in the vital functional state thus highlighted biologically significant differences in vessel function and served as high-resolution adjuncts to MR imaging.

A systematic histochemical investigation in mammals of the dense glycocalyx glycosylations common to all cells bordering the interstitial fluid compartment of the brain.

Microanatomical evidence is presented that the intercellular fluid (ICF) compartment of the central nervous tissue is lined entirely and exclusively by heavily glycosylated cells, with glycoconjugates exposed primarily at the apical cell surface, fronting the CSF or blood. On both common ependymal cells and on those specialised to form the choroid plexus epithelium, oligosaccharides coat the cilia and microvilli at the apical surface, and also the smoother lateral and basal cell surfaces. In the ependyma, folded and wrinkled structures seem especially associated with freely exposed carbohydrates. On cerebral endothelial cells, oligosaccharides coat the luminal surface densely and the basal surface lightly. The patterns of carbohydrate distribution thus vary from one cell type to another, but the different cell types all bear essentially the same set of oligosaccharides, variations being due largely to degree of terminal sialylation. Furthermore, the same set of oligosaccharides borders the brain in a broad spectrum of mammals, including pouched and placental mammals. In both epithelia and endothelia, the lectin binding sites visualised in fixed and embedded preparations were shown to be exposed likewise at the cell surfaces in unfixed tissues and so able to bind molecules present in the fluid (CSF or blood) bathing the cells in vivo. This phylogenetically ancient enclosure of the ICF compartment in a "ring of sugars" is suggested to relate to regulation of the central neuronal microenvironment.

Visualization of lectin-like proteins in human placenta by means of anti-plant lectin antibodies.

Proteins antigenically cross-reactive with lectins were sought in the placenta by immunohistochemistry using polyclonal antibodies raised in rabbit against four well-known lectins: Concanavalin A, Wheat germ agglutinin, Ulex europaeus agglutinin, and Phaseolus vulgaris leukoagglutinin (PHA-L), as well as one antibody raised in goat against PHA-L. Even at high dilutions of the primary antibody, strong staining was obtained after short incubations, in patterns generally resembling those obtained for placental lectins by other means, such as those based on binding capacity for glycosylated probes. One of the immunohistochemical patterns distinguishes with great clarity between the trophoblast cell layers, thus relating to developmental and functional parameters; another localises PHA-L-immunoreactivity to the syncytiotrophoblast. These results underline the validity of the immunohistochemical screening as an approach in its own right. Both positive and negative controls were applied to the immunohistochemical methodology. These controls showed that the staining patterns obtained relate to the specificities of the primary antibodies employed; i.e. to lectins. The PHA-L-like cross-reactivity was analysed immunochemically. In electrophoretically separated and Western-blotted placental extracts there were found anti-PHA-L-binding fractions of apparent molecular weights 30 kDa, 58 kDa and 67 kDa. Control studies of the PHA-L antigen showed anti-PHA-L-binding fractions of approximate molecular weights 32 kDa and 60 kDa. The 30 kDa fraction from placenta and the 32 kDa fraction from PHA-L antigen bound lactosylated BSA but not fucosylated BSA.(ABSTRACT TRUNCATED AT 250 WORDS)

Neoglycoprotein binding distinguishes distinct zones in the epithelia of the porcine eye.

The presence and location of specific endogenous lectins in the anterior epithelia of the porcine eye were determined by histochemical staining using biotinylated glycosylated carrier molecules. Endogenous lectins with specificities for galactosides, alpha-mannosides and beta-xylosides were present in the conjunctival epithelium, but the corneal anterior epithelium appeared essentially free of histochemically demonstrable endogenous lectins. The corneal posterior epithelium contained a rich and complex set of endogenous lectins. The transitional area between conjunctival and corneal anterior epithelia at the limbus cornea contained, in striking contrast to either of the epithelia bordering it, cells expressing endogenous lectins in considerable wealth and variety.

Malignant and normally developing trophoblastic cells of human placenta display different characteristics defined by histochemical and biochemical mapping of endogenous lectins.

Trophoblastic cells with their strictly controlled propensity for invasive growth hereby bear limited resemblance to malignant cells. Therefore, detailed description of molecular characteristics of this cell type in comparison to histologically related tumor cells may aid in defining physiologically relevant differences. In view of the potential importance of selective protein-carbohydrate interactions in recognitive processes, labelled neoglycoproteins were employed to evaluate systematically the presence and distribution of sugar receptors in tumor cells of chorionepithelioma and in trophoblastic cells of an early stage of gestation. Control reactions in glycohistochemistry, involving prolonged incubation, pH variation and use of nucleotides excluded the possibility that glycosidases or glycosyltransferases govern the sugar-specific binding to the tissue sections. Pronounced differences were detected in the expression of receptors (lectins) for alpha- and beta-glucosides as well as for N-acetylgalactosamine and N-acetylglucosamine. Further differences were revealed by probing both types of tissue with lactosylated, fucosylated, xylosylated and sialylated carrier protein. Upon developmental maturation of the normal cells in placenta the extent of binding of the neoglycoproteins decreased. The glycohistochemical differences between malignant and normally developing trophoblastic cells were found to be reflected in the alteration of expression of certain endogenous lectins, as ascertained by affinity chromatography and gel electrophoretic analysis. Consequently, we assume that the transient presence of certain endogenous lectins during early stages of gestation and their differential expression in relation to tumor cells of chorionepithelioma may be relevant for the special invasive and adhesive behavior of human trophoblastic cells.

Detection of receptors for sulfated polysaccharides in human placenta by biotinylated probes.

Histochemical detection of binding sites for sulfated polysaccharides believed to be important mediators within recognitive interactions was carried out by application of biotinylated probes such as heparin, native and desulfated fucoidan, dermatan sulfate, and two types of carrageenans. The probes were derivatized by mild cyanogen bromide activation and subsequent aminoalkylation to allow incorporation of biotin, inserted with an epsilon-aminocaproic acid spacer to reduce charge-related and steric impediments. Specific labeling could be detected in different cell types of human placenta, dependent on the developmental stage. Sulfated polysaccharides bound predominantly to leucocytes in full-term placenta, whereas demonstration of specific binding sites in decidua, syncytiotrophoblasts, and cytotrophoblasts was restricted primarily to heparin and, less intensely, fucoidan, although not desulfated fucoidan. Heparin binding in the placenta after 8 weeks of gestation was reduced for epithelia that, at this stage of development, revealed carrageenan binding sites. Fucoidan binding was at this developmental stage measurable only for leucocytes. These results provide definite histochemical evidence for the presence and developmental regulation of expression of receptors for sulfated polysaccharides in different cell types of human placenta.

Cellular glycoconjugates and their potential endogenous receptors in the cerebral microvasculature of man: a glycohistochemical study.

Protein-carbohydrate interactions are supposed to play a pivotal role in mediation of recognitive interactions, relevant to cellular interactions and transport. The brain microvasculature is the site of numerous cell-cell and cell-matrix recognitive interactions. Assuming carbohydrate-protein interactions play important physiological roles here, then specific carbohydrate-binding proteins should be prominent components of this microvasculature, in addition to the wealth of endogenous glycoconjugates reported by other authors. Human brain and brain tumor microvessels were analyzed histochemically for expression of endogenous sugar-binding proteins using a panel of biotin-conjugated, chemically glycosylated probes with specificities for alpha-/beta-D-galactosides and -D-glucosides, alpha-L-fucosides, alpha-D-mannosides, and beta-D-xylosides, and for expression of endogenous glycoconjugates using a panel of biotin-conjugated plant lectins with specificities for fucoside, galactoside, mannoside and glucoside moieties. Wax-embedded aldehyde- or Bouin-fixed tissues or acetone-fixed frozen sections were examined. Blood-brain barrier function was checked by ascertaining immunohistochemically the extravasation of serum albumin in these tissues. Microvessels in normal human brain tissues (with intact blood-brain barrier) contained abundant endogenous sugar-binding proteins with specificities for beta-galactosides, alpha-mannosides and beta-xylosides, and lesser amounts of proteins binding alpha-galactosides, alpha-fucosides and glucosides. Endogenous glycoconjugates bearing beta-galactoside, alpha-D-mannoside/alpha-D-glucoside or alpha-L-fucoside moieties were also abundant. In brain tumors (with defective blood brain barrier) the microvessels contained altered patterns of endogenous sugar-binding proteins, particularly noticeable in glioblastomas, in which there were notable alterations in galactoside-binding proteins in the microvessels.

Identification of endogenous sugar-binding proteins (lectins) in human placenta by histochemical localization and biochemical characterization.

Human placentas of different stages of development were histochemically analyzed for expression of endogenous sugar-binding proteins using a panel of biotin-conjugated, chemically glycosylated probes with specificity for beta-galactosides, alpha-galactosides, alpha-mannosides, alpha-fucosides and alpha-glucosides. Temporal differences in the expression of sugar-binding proteins and different patterns of staining of the component cell types of human placenta were discerned, especially pronounced for alpha-fucoside-specific binding in the trophoblast and alpha-glucoside-specific binding in fetal and maternal macrophages. Fractionation of salt and detergent extracts from human placentas by affinity chromatography on columns with immobilized carbohydrates or glycoproteins substantiated the histochemically detectable temporal changes on the basis of alterations in the pattern of individual sugar-binding proteins, as determined by gel electrophoresis under denaturing conditions. Analysis of the trophoblastic layer primarily disclosed the presence of several additional sugar-binding proteins (lectins) in comparison to full-term placenta. The presence and developmental changes of such endogenous sugar receptors may lead to specific carbohydrate-protein interactions of physiological significance with similarly developmentally regulated carbohydrated portions of glyco-conjugates, already detected in human placenta by plant lectins.

The generation and regeneration of oligodendroglia. A short review.

During postnatal development of the higher vertebrate CNS, large populations of oligodendroglia are generated from precursor cells in a very dependable way. In adult lesioned CNS tissues, local populations of oligodendroglia are replenished by proliferation of this replenishment varies from one species to another and also from one lesion type another. Studies on the developmental generation of oligodendroglia are reviewed here, delineating what is known of the early relationships between the CNS glial lineages and of what regulates this development. Contributions from recent cell biological work are considered against the background of morphological and radioautographic results. The quiescent condition of extremely slow turnover in the normal adult CNS is noted, and the dramatic effects of lesions on the neural cell environment are considered. Lesions can trigger proliferation at a much greater rate in the mature oligodendroglial population, as observed both in situ and in tissue culture; in addition to persisting stem cells, the mature cells participate in replenishing the local oligodendroglial population. This regeneration from cells already committed to the oligodendroglial lineage may minimise such disturbing effects of the lesion environment as might distort replenishment of the population from precursor cells.

Rat oligodendroblasts in vitro as a long-term cell line.

A stable line of oligodendrocyte-like cells has been derived by passaging methods from initial explant cultures of postnatal Lewis rat cerebellum. These cells resemble oligodendrocytes by both light and electron microscopy. However, their ultrastructure suggests immaturity, and they express no galactocerebroside at their surfaces. They do express surface tetrasialoganglioside. They contain no intermediate filaments, and show none of the ultrastructural characteristics of astrocytes. It is suggested that they represent immediate precursors to oligodendrocytes, or "oligodendroblasts". In addition, the cell line contains a small minority of astrocytes, and interactions between these and the oligodendroblasts are suggested to account for the highly differentiated ultrastructure maintained by the oligodendroblasts over hundreds of cell generations in vitro, as well as, possibly, the high proliferative rate of the oligodendroblasts. Conversely, the failure of the oligodendroblasts to mature is related to the absence of neurons.

Affinity of chick microglia in vitro for ricin 120.

The distribution of binding sites for ricin 120 in cell cultures of spinal cord from the chick embryo was examined. A characteristic pattern was observed, which remained similar in cultures fixed by a variety of methods. Light microscopy demonstrated that the most prominent staining was of small rounded or amoeboid cells. Electron microscopy showed that ricin was bound over their entire surfaces. The ultrastructural characteristics of these cells suggest their identification as microglia.

Tubulin immunohistochemistry. Fixation methods affect the response of spinal cord cells in vitro.

We report here the results observed when tubulin fluorescence immunohistochemistry is performed upon dissociated cultures of nervous tissue, principally of chick embryo spinal cord. When fixation includes nonpolar solvents or detergents, a uniform fluorescence is seen in neuron perikarya (with the exception of their nuclei), and the processes to which they give rise. Fixation with formaldehyde or glutaraldehyde alone, however, results in a discontinuous staining of neurites, and a less regular staining of their perikarya. The former pattern of response can be elicited if aldehyde fixation is followed by exposure to non-polar solvents. Such results are obtained both in thinly spread regions of the cultures, where neurons and their processes can easily be seen, and in the cell aggregates that also characterise them. Possible interpretations of these results are discussed.