Histochemical study of the effects on abomasal mucins of Haemonchus contortus or Teladorsagia circumcincta infection in lambs.

Previously, chemical analysis of gastric fundic mucin showed that infection of sheep with Haemonchus contortus or Teladorsagia circumcincta changed the proportions of monosaccharides and decreased terminal mucin fucosylation and sialylation. To identify the effects of these parasites on the two mucin-secreting cell lineages, fundic and antral tissues were collected for histochemistry from 69 lambs aged from 3-4 to 9-10 months-of-age which had received a single infection of either H. contortus or T. circumcincta and euthanased at Day 21 or 28 post- infection respectively. All fundic tissues were stained separately with: (1) with Periodic Acid Schiff (PAS) for all mucins; (2) Alcian Blue (AB) pH 2.5 for acidic mucins (sialylated and sulphated); (3) AB pH 1 for sulphated mucins and (4) High Iron Diamine (HID) for sulphated mucins. Antral and fundic tissues from 24 lambs were also stained for acidic and neutral mucins or with specific lectins for α-1-linked fucose and for α-2,3- and α-2,6-linked sialic acids. Only mucin sulphation appeared to differ visually in uninfected lambs over this age range: there was weak staining with HID in tissues from lambs 3-6 months-of-age, but was generally more intense in those over 7 months-of-age. Sulphomucins were not apparent in surface mucous cells (SMC) or generally in the upper pits. Sialylomucins were located predominantly in the pits and glands, with small amounts of sialylated mucins in SMC and on the luminal surface, mainly in younger animals up to 6 months-of-age and less in the older animals. Parasitism markedly reduced the predominantly neutral surface mucin5AC of the SMC and pit cells, despite pit elongation in both antrum and fundus, whereas the acidic Muc6 secreted by mucus neck cells (MNC) increased along with MNC hyperplasia. Sulphated mucins were present mainly from the mid-pits downward and heavy staining was more common in older animals. In these sheep, the markedly reduced neutral mucin in the SMC and pit cells in both antrum and fundus contrasts with reported hypersecretion of mucus in the intestine, which is believed to aid in parasite expulsion. It has been proposed that intestinal goblet cell hypersecretion occurs only in resistant animals, therefore reduced mucins in the abomasum may be indicative of susceptibility to abomasal parasites.

Excretory/secretory products of adult Haemonchus contortus and Teladorsagia circumcincta which increase the permeability of Caco-2 cell monolayers are neutralised by antibodies from immune hosts.

The onset of abomasal pathophysiology due to parasitism coincides with the presence of adult worms in the lumen, implicating worm excretory/secretory (ES) products acting on the surface mucosa. Caco-2 cell monolayers were grown to confluence on Transwell plates and exposed on the apical side to ES products of adult Haemonchus contortus and Teladorsagia circumcincta. ES products of both species significantly (p<0.001) reduced transepithelial electrical resistance after 2h to 81.1±1.0% and 82.9±1.1% respectively. Immunocytochemical staining of the Caco-2 monolayers for zona occludens-1 and occludin confirmed that the tight junctions remained intact in control medium, but these proteins were internalised from disrupted junctions after exposure to ES products. The components of H. contortus ES products responsible for increased epithelial permeability were partially blocked by phage displaying single chain antibodies derived from sheep immune to field infection and enriched by panning with H. contortus ES products. Immune hosts may therefore be able to reduce the effects of worm chemicals on the gastric epithelium. Permeabilisation of the abomasal surface mucosa by worm chemicals would also explain how cells deep in the gastric glands could rapidly be affected by parasites emerging from the glands or within a day of transplantation of adult worms into naïve hosts, resulting in the pathophysiology typically caused by abomasal nematode parasitism.

CENP-E is essential for reliable bioriented spindle attachment, but chromosome alignment can be achieved via redundant mechanisms in mammalian cells.

CENP-E is a kinesin-like protein that when depleted from mammalian kinetochores leads to mitotic arrest with a mixture of aligned and unaligned chromosomes. In the present study, we used immunofluorescence, video, and electron microscopy to demonstrate that depletion of CENP-E from kinetochores via antibody microinjection reduces kinetochore microtubule binding by 23% at aligned chromosomes, and severely reduces microtubule binding at unaligned chromosomes. Disruption of CENP-E function also reduces tension across the centromere, increases the incidence of spindle pole fragmentation, and results in monooriented chromosomes approaching abnormally close to the spindle pole. Nevertheless, chromosomes show typical patterns of congression, fast poleward motion, and oscillatory motions. Furthermore, kinetochores of aligned and unaligned chromosomes exhibit normal patterns of checkpoint protein localization. These data are explained by a model in which redundant mechanisms enable kinetochore microtubule binding and checkpoint monitoring in the absence of CENP-E at kinetochores, but where reduced microtubule-binding efficiency, exacerbated by poor positioning at the spindle poles, results in chronically monooriented chromosomes and mitotic arrest. Chromosome position within the spindle appears to be a critical determinant of CENP-E function at kinetochores.

Functional analysis of a human homologue of the Drosophila actin binding protein anillin suggests a role in cytokinesis.

We have characterized a human homologue of anillin, a Drosophila actin binding protein. Like Drosophila anillin, the human protein localizes to the nucleus during interphase, the cortex following nuclear envelope breakdown, and the cleavage furrow during cytokinesis. Anillin also localizes to ectopic cleavage furrows generated between two spindles in fused PtK(1) cells. Microinjection of antianillin antibodies slows cleavage, leading to furrow regression and the generation of multinucleate cells. GFP fusions that contain the COOH-terminal 197 amino acids of anillin, which includes a pleckstrin homology (PH) domain, form ectopic cortical foci during interphase. The septin Hcdc10 localizes to these ectopic foci, whereas myosin II and actin do not, suggesting that anillin interacts with the septins at the cortex. Robust cleavage furrow localization requires both this COOH-terminal domain and additional NH(2)-terminal sequences corresponding to an actin binding domain defined by in vitro cosedimentation assays. Endogenous anillin and Hcdc10 colocalize to punctate foci associated with actin cables throughout mitosis and the accumulation of both proteins at the cell equator requires filamentous actin. These results indicate that anillin is a conserved cleavage furrow component important for cytokinesis. Interactions with at least two other furrow proteins, actin and the septins, likely contribute to anillin function.

The rate of poleward chromosome motion is attenuated in Drosophila zw10 and rod mutants.

Here we show that the rate of poleward chromosome motion in zw10-null mutants is greatly attenuated throughout the division process, and that chromosome disjunction at anaphase is highly asynchronous. Our results show that ZW10 protein, together with Rod, is involved in production and/or regulation of the force responsible for poleward chromosome motion.

Cleavage furrows formed between centrosomes lacking an intervening spindle and chromosomes contain microtubule bundles, INCENP, and CHO1 but not CENP-E.

PtK1 cells containing two independent mitotic spindles can cleave between neighboring centrosomes, in the absence of an intervening spindle, as well as at the spindle equators. We used same-cell video, immunofluorescence, and electron microscopy to compare the structure and composition of normal equatorial furrows with that of ectopic furrows formed between spindles. As in controls, ectopic furrows contained midbodies composed of microtubule bundles and an electron-opaque matrix. Despite the absence of an intervening spindle and chromosomes, the midbodies associated with ectopic furrows also contained the microtubule-bundling protein CHO1 and the chromosomal passenger protein INCENP. However, CENP-E, another passenger protein, was not found in ectopic furrows but was always present in controls. We also examined cells in which the ectopic furrow initiated but relaxed. Although relaxing furrows contained overlapping microtubules from opposing centrosomes, they lacked microtubule bundles as well as INCENP and CHO1. Together these data suggest that the mechanism defining the site of furrow formation during mitosis in vertebrates does not depend on the presence of underlying microtubule bundles and chromosomes or on the stable association of INCENP or CHO1. The data also suggest that the completion of cytokinesis requires the presence of microtubule bundles and specific proteins (e.g., INCENP, CHO1, etc.) that do not include CENP-E.

Unilateral and wandering furrows during mitosis in vertebrates: implications for the mechanism of cytokinesis.

Vertebrate somatic cells sometimes form unilateral furrows during cytokinesis that ingress from only one edge of the cell. In some cases after a cell initiates a normal symmetrical circumferential furrow, one of its edges stops furrowing and regresses while the furrow associated with the opposing edge continues across the cell. In cells containing two independent spindles unilateral furrows are sometimes formed that do not follow a linear path but instead sharply change their direction and wander for >40 microm through the cell. These observations reveal that the 'contractile ring' normally seen during cytokinesis is composed of multiple independent 'furrowing units' that are normally coordinated to form a symmetrical furrow around the cell, and that once formed this so-called contractile band does not function as a 'purse string' as commonly envisioned. Individual furrowing units can work independently of one another, and cytokinesis in vertebrates can be consummated by the formation of a single functional furrowing unit in a localized region of the cell cortex that is then propagated across the cell. How this propagation occurs remains an important question for the future.