Structure of kinetochore fibers: Microtubule continuity and inter-microtubule bridges

To understand how microtubules interact in forming the mitotic apparatus and orienting and moving chromosomes, the precise arrangement of microtubules in kinetochore fibers in Chinese hamster ovary cells was examined. Individual microtubules were traced, using high voltage electron microscopy of serial 0.25 m sections, from the kinetochore toward the pole. Microtubule arrangement in kinetochore fibers in untreated mitotic cells and in cells recovering from Colcemid arrest were similar in two respects: the number of microtubules per kinetochore (mean 14 and 12, respectively) and the nearest neighbor intermicrotubule distance (mean90 nm). In Colcemid recovered cells, over 90% of the microtubules in kinetochore fibers were attached to the kinetochore (i.e. kinetochore microtubules) and extended most or all of the distance to the pole. Few free microtubules were present in the kinetochore fibers; most non-kinetochore microtubles terminated in the pole. Since kinetochores in this Colcemid-recovered system have been demonstrated to nucleate microtubules (Witt et al., 1980), it seems likely that most if not all of these kinetochore microtubules originated at the kinetochore. Some of the reconstructed kinetochore fibers were attached to chromosomes with bipolar orientation, suggesting that kinetochore microtubules need not interact with many polar microtubules for orientation to occur. In Colcemid recovered cells lysed to reduce cytoplasmic background, microtubules in kinetochore fibers were preferentially preserved. The parallel and near-hexagonal order typical of microtubules in kinetochore fibers was maintained, as was the number of kinetochore microtubules (mean, 13). The intermicrotubule distance was slightly reduced in lysed cells (mean, 60 nm). Crossbridges about 5 nm wide and 30–40 nm long were visible in kinetochore fibers of lysed cells. Such crossbridges probably contribute to the stabilization and parallel order of microtubules in kinetochore fibers, and may have a functional role as well.     

Ciliary dynein from sea urchin embryos.

Axonemal dynein ATPase [EC 3.6.1.3] was extracted from cilia of sea urchin embryos for a study of its enzymatic properties. Sedimentation analysis on a sucrose density gradient revealed that ATPase activity was associated with the 12S particles. The partially purified 12S enzyme was characterized mainly with regard to the optimum pH, divalent cation and ionic strength requirments and substrate specificity. Comparative investigation of the data obtained indicates that the properties of the present dyneine ATPase resemble those of other dynein(-like) ATPase hitherto reported. In addition, the possible relationship among dyneins within a single species, in particular between the ciliary dynein and cytoplasmic dynein-like ATPase, is discussed.     

Ciliary neurotrophic factor

Ciliary neurotrophic factor (CNTF) was first identified and partially purified from embryonic chick eye tissues. Subsequently, it was shown that CNTF is also present in large amounts in sciatic nerves of adult rats and rabbits, which led to its final purification and cloning. CNTF is not secreted by the classical secretory pathway involving the endoplasmatic reticulum and Golgi complex, but can be detected in high quantities within the cytoplasm of myelinating Schwann cells and astrocytes using immunohistochemistry. CNTF supports survival and / or differentiation of a variety of neuronal cell types including sensory, sympathetic and motoneurons. Also, nonneuroanl cells, such as oligodendrocytes, microglial cells, liver cells, and skeletal muscle cells, respond to exogenously administered CNTF, both in vitro and in vivo. During development, expression of CNTF is very low, if indeed it is expressed at all, and the phenotype of mice lacking endogenous CNTF, suggesting that CNTF after inactivation of the CNTF gene by homologous recombination suggests that CNTF does not play a crucial role for responsive cells during embryonic development. However, motoneurons are lost postnatally in mice lacking endogenous CNTF, suggesting that CNTF acts physiologically on the maintenance of these cells. The ability of exogenous CNTF to protect against motoneuron loss following lesion or in other animal models indicates that CNTF might be useful in the treatment of human motoneuron disorders, provided appropriate means of administration can be found. 1994 John Wiley & Sons, Inc.     

睫状神经营养因子受体

睫状神经营养因子是一种能够促进感觉、交感和运动神经元存活和分化的细胞因子．睫状神经营养因子受体复合物由三个亚基组成,α亚基是睫状神经营养因子的结合蛋白,它不是跨膜蛋白,而是通过GPI键锚在细胞膜上;信号传递体的两个亚基分别是gp130和LIFRβ．随状神经营养因子受体复合物的形成是一个有序过程、Jak／Tyk家族的激活与细胞内信号传导有关．     

Ciliary neurotrophic factor induces acute-phase protein expression in hepatocytes.

During inflammatory states, hepatocytes are induced to synthesize and secrete a group of proteins called acute-phase proteins. It has recently been shown that besides interleukin-6 (IL-6), related cytokines such as leukemia inhibitory factor, oncostation M and interleukin-11 are also mediators of the hepatic acute-phase response. All these mediators belong to the hematopoietic family of alpha-helical cytokines. Here we show that an additional member of this cytokine family, ciliary neurotrophic factor (CNTF), induces the hepatic acute-phase protein genes haptoglobin, alpha 1-antichymotrypsin, alpha 2-macroglobulin and beta-fibrinogen in human hepatoma cells (HepG2) and in primary rat hepatocytes with a time course and dose-response comparable with that of IL-6. Our next aim was to define the receptor components used by CNTF on hepatic cells. Using a cell-free binding assay we exclude that CNTF binds to the 80 kDa IL-6 receptor, a protein with significant homology to the CNTF receptor which has recently been cloned from neuroblastoma cells. In human hepatoma cells (Hep3B) which lack the leukemia inhibitory factor receptor, CNTF was not able to induce acute-phase protein synthesis, indicating that this receptor protein may be part of the functional CNTF receptor on hepatic cells.     

Morphological Aspects of Ciliary Motility

In Elliptio complanatus lateral cilia, two distinct patterns of filament termination can be discerned. In one case, all nine filaments are present and all are single; in the second, at least one filament is missing but doublets are still present. These probably represent different configurations within one cilium in different stroke positions; to get from one to the other, some peripheral filaments must move with respect to others. The data are consistent with the hypothesis that the filaments themselves do not change length, but rather slide past one another to accommodate increasing curvature. The bent regions of the cilium are in the form of circular arcs. In a few cases, apparent displacement of filaments at the tip (Δl) can be shown to be accounted for if we assume that all differences are generated within these arcs. The displacement per degree of bend is 35 A. Regions of bent arc are initially confined to the base of the cilium but move up the shaft as straight regions appear below them. From the relationship between arc length and radius of curvature, a shaft length that is the unit that initially bends and slides may be defined. Quantal displacements of the length of one 14S dynein may perhaps occur at sites between filaments at opposite sides of such a unit as sliding occurs.     

Ciliary beat co-ordination by calcium

Motile cilia in the airway epithelium are the engine for mucociliary clearance, the mechanism responsible for cleaning the airways from inhaled particles. Human airway epithelial cilia appear to have a slow constitutive rate of beating, driven by inherent and spontaneous dynein ATPase activity. Additionally, cilia can increase their beating frequency by activation of several different control mechanisms. One of these controllers is calcium. Its intracellular concentration is regulated by purinergic and acetylcholine receptors. Besides the rate regulatory effect of calcium on ciliary beat, calcium is also involved in synchronizing the beat among cilia of one single cell as well as between cilia on different cells. This article gives an overview of the complex effects of calcium on the beating of motile cilia in the airways.     

A TACC3/ch-TOG/clathrin complex stabilises kinetochore fibres by inter-microtubule bridging

Kinetochore fibres (K-fibres) of the spindle apparatus move chromosomes during mitosis. These fibres are discrete bundles of parallel microtubules (MTs) that are crosslinked by inter-MT 'bridges' that are thought to improve fibre stability during chromosomal movement. The identity of these bridges is unknown. Clathrin is a multimeric protein that has been shown to stabilise K-fibres during early mitosis by a mechanism independent of its role in membrane trafficking. In this study, we show that clathrin at the mitotic spindle is in a transforming acidic colied-coil protein 3 (TACC3)/colonic, hepatic tumour overexpressed gene (ch-TOG)/clathrin complex. The complex is anchored to the spindle by TACC3 and ch-TOG. Ultrastructural analysis of clathrin-depleted K-fibres revealed a selective loss of a population of short inter-MT bridges and a general loss of MTs. A similar loss of short inter-MT bridges was observed in TACC3-depleted K-fibres. Finally, immunogold labelling confirmed that inter-MT bridges in K-fibres contain clathrin. Our results suggest that the TACC3/ch-TOG/clathrin complex is an inter-MT bridge that stabilises K-fibres by physical crosslinking and by reducing rates of MT catastrophe.     

Ciliary Ultrastructure In Nasal Brushings

Normal ciliary ultrastructure is thought to be necessary for effective function. There has been little or no attempt to quantify ultrastructural abnormalities in nasal disease and assess their significance. In this study we measured nasal ciliary function and examined ciliary ultrastructure in nasal brushings from 35 patients with perennial nasal symptoms refractory to treatment. Ultrastructural defects included microtubular abnormalities, compound cilia and ciliary ‘blebs’. the incidence of abnormal cilia was 16.7%, compared with 9% in controls, but there was only a poor correlation between ultrastructural defects and ciliary beat frequency. One patient had primary ciliary dyskinesia (PCD) with a typical clinical history and immotile cilia. However, only secondary ultrastructural abnormalities were seen. We have been unable to show that ciliary ultrastructural defects form the basis of impaired function. In patients with suspected PCD, nasal brushings should be taken for functional and ultrastructural studies; ideally, a further sample should be obtained for examination of possible primary ultrastructural abnormalities.     

Ciliary disorder of the skeleton

In the last 10 years, the primary cilia machinery has been implicated in more than a dozen disorders united as ciliopathies, including skeletal dysplasias, such as Jeune syndrome and short rib-polydactyly type III. Indeed, primary cilia play a vital role in transduction of signals in the hedgehog pathway that is especially important in skeletal development. In this review, we focus on skeletal conditions belonging to the ciliopathy group: the short rib-polydactyly group (SRPs) that includes Verma-Naumoff syndrome (SRP type III), Majewski syndrome (SRP type II), Jeune syndrome (ATD), as well as Ellis-van Creveld syndrome (EVC), the Sensenbrenner syndrome, and, finally, Weyers acrofacial dysostosis. Today, 10 different genes have been identified as responsible for seven "skeletal" ciliopathies. Mutations have been identified in dynein motor (DYNC2H1), in intraflagellar transport (IFT) complexes (IFT80, IFT122, IFT43, WDR35, WDR19, and TTC21B) as well as in genes responsible for the basal body (NEK1, EVC, and EVC2). The wide clinical variability observed for an individual ciliopathy gene supports the development of exome strategy specifically dedicated to cilia genes to identify mutations in this particularly heterogeneous group of disorders.     

Disulphide bridges of bovine factor X.

Evidence is presented for the disulphide bridges in bovine Factor X. The protein was degraded by chemical and enzymic means, and all 12 disulphide bridges were isolated in separate peptides except for bridges nos. 6/7 in the light chain. All the disulphide bridges were found to be in positions corresponding to those found in other homologous domains. This report is the first verification of an epidermal-growth-factor-homologous domain having the same disulphide-bonding pattern as that found in mouse epidermal growth factor.     

Interchain disulphide bridges of mouse immunoglobulin M.

Mouse IgM (immunoglobulin M) was selectively and partially reduced and treated with iodo[2-14C]acetate to label the interchain disulphide bridges. The carboxymethylation was studied in some detail. The labelled peptides were purified, sequenced and positioned by homology with human IgM. Only peptides originating from three interchain disulphide bridges were labelled, in contrast with the four labelled bridges obtained in human IgM under the same conditions. These peptides are homologous to human bridge peptides forming the heavy-light bridge and two inter-heavy bridges, one present in the CMU2 region and the other in the C-terminal region. The inter-heavy bridge in the Cmu2 region was alone cleaved and radioactively labelled in selectively reduced IgM held together as a pentamer by non-covalen interactions. The same bridge was the only one to be totally cleaved in subunits released after more extensive, though still selective, reduction. In the light of these results a possible arrangement of the disulphide bridges of the mouse IgM.     

Ciliary neurotrophic factor prevents unweighting-induced functional changes in rat soleus muscle.

The purpose of the present work was to see whether changes in rat soleus characteristics due to 3 wk of hindlimb suspension could be modified by ciliary neurotrophic factor (CNTF) treatment. Throughout the tail suspension period, the cytokine was delivered by means of an osmotic pump (flow rate 16 microg. kg(-1). h(-1)) implanted under the hindlimb skin. In contrast to extensor digitorum longus, CNTF treatment was able to reduce unweighting-induced atrophy in the soleus. Twitch and 146 mM potassium (K) tensions, measured in small bundles of unloaded soleus, decreased by 48 and 40%, respectively. Moreover, the time to peak tension and the time constant of relaxation of the twitch were 48 and 54% faster, respectively, in unloaded soleus than in normal muscle. On the contrary, twitch and 146 mM K contracture generated in CNTF-treated unloaded and normal soleus were not different. CNTF receptor-alpha mRNA expression increased in extensor digitorum longus and soleus unloaded nontreated muscles but was similar in CNTF-treated unloaded muscles. The present results demonstrate that exogenously provided CNTF could prevent functional changes occurring in soleus innervated muscle subject to unweighting.