Toward understanding the role of cartilage particulates in synovial inflammation.

OBJECTIVE: Arthroscopy with lavage and synovectomy can remove tissue debris from the joint space and the synovial lining to provide pain relief to patients with osteoarthritis (OA). Here, we developed an in vitro model to study the interaction of cartilage wear particles with fibroblast-like synoviocytes (FLS) to better understand the interplay of cartilage particulates with cytokines on cells of the synovium. METHOD: In this study sub-10 µm cartilage particles or 1 µm latex particles were co-cultured with FLS ±10 ng/mL interleukin-1α (IL-1α) or tumor necrosis factor-α (TNF-α). Samples were analyzed for DNA, glycosaminoglycan (GAG), and collagen, and media samples were analyzed for media GAG, nitric oxide (NO) and prostaglandin-E2 (PGE2). The nature of the physical interaction between the particles and FLS was determined by microscopy. RESULTS: Both latex and cartilage particles could be phagocytosed by FLS. Cartilage particles were internalized and attached to the surface of both dense monolayers and individual cells. Co-culture of FLS with cartilage particulates resulted in a significant increase in cell sheet DNA and collagen content as well as NO and PGE2 synthesis compared to control and latex treated groups. CONCLUSION: The proliferative response of FLS to cartilage wear particles resulted in an overall increase in extracellular matrix (ECM) content, analogous to the thickening of the synovial lining observed in OA patients. Understanding how cartilage particles interface with the synovium may provide insight into how this interaction contributes to OA progression and may guide the role of lavage and synovectomy for degenerative disease.

Enhanced stability of microtubules enriched in detyrosinated tubulin is not a direct function of detyrosination level.

Interphase cultured monkey kidney (TC-7) cells contain distinct subsets of cellular microtubules (MTs) enriched in posttranslationally detyrosinated (Glu) or tyrosinated (Tyr) alpha tubulin (Gundersen, G. G., M. H. Kalnoski, and J. C. Bulinski. 1984. Cell. 38:779-789). To determine the relative stability of these subsets of MTs, we subjected TC-7 cells to treatments that slowly depolymerized MTs. We found Glu MTs to be more resistant than Tyr MTs to depolymerization by nocodazole in living cells, and to depolymerization by dilution in detergent-permeabilized cell models. However, in cold-treated cells, Glu and Tyr MTs did not differ significantly in their stability. Digestion of permeabilized cell models with pancreatic carboxypeptidase A, to generate Glu MTs from endogenous Tyr MTs, did not significantly alter the resistance of the endogenous Tyr MTs toward dilution-induced depolymerization. Furthermore, in human fibroblasts that contained no distinct Glu MTs, we observed a population of nocodazole-resistant MTs. These data suggest that Glu MTs possess enhanced stability against end-mediated depolymerization, yet detyrosination alone appears to be insufficient to confer this enhanced stability.

Mechanisms of trafficking in axons and dendrites: implications for development and neurodegeneration.

In the area of routing and sorting of dendritic traffic, the current phenomenological data beg questions about the cellular mechanisms utilized not only to transport material but also to modulate activity in a process, even apoptosis. To aid in formulating testable hypotheses, many plausible models are developed here and linked with some of the preliminary data that supports them. We first assume that in long dendrites the sorting of membranous proteins into transport vesicles also involves the linkage of motor proteins to the vesicles. Second, we assume that the cytoskeleton in dendrites is altered from the cytoskeleton in axons and the cell body. Viral glycoproteins, MAP2 and specific mRNA sorting into dendrites provide the simplest models for analyzing vesicular, cytoskeletal and RNA sorting. In the case of viral glycoproteins, initial sorting appears to occur at the Golgi but additional routing steps involve further complexities that could best be served by an additional sorting step at the junction of the cell body and the process. Transport of the specialized cytoskeletal proteins and specific mRNAs as well as vesicular material could be controlled by a similar gatekeeper at the mouth of a process. Studies of the microtubule-organelle motor complex, regulation of microtubule-based motility by microtubule-associated proteins, and slow axonal transport all provide insights into important aspects of the routing and sorting. These processes are in turn controlled by extracellular signals such as those generated by matrix molecules or their hydrolysis products in the case of amyloid precursor protein (APP). Routing and sorting mechanisms may be central to the development of Alzheimer's disease in view of evidence that APP processing is affected, transport is disturbed, and intracellular vesicles (early endosomes) hypertrophied. Further it is possible that routing mechanisms play a role in cell-cell interactions as, for example, the possibility that pathogenic/cellular stress signals may be passed along circuits transsynaptically.

A procedure for the immunoblotting of proteins separated on isoelectric focusing gels.

A method has been devised for performing Western blot assays on proteins resolved by isoelectric focusing. Electrophoretic transfer of proteins directly from isoelectric focusing (IEF) tube gels to nitrocellulose sheets allowed their immunoassay without conventional second dimension SDS gel electrophoresis. The same method can also be used for IEF slab gels. For the immunostaining of nonmuscle actin isoforms in extracts of cultured cells, the resolution of this technique was much improved over that of Western blots of two-dimensional gels.

Microtubule-associated protein 4 (MAP4) regulates assembly, protomer-polymer partitioning and synthesis of tubulin in cultured cells.

We depleted MAP4, a ubiquitously expressed microtubule (MT)-associated protein previously shown to be capable of stabilizing MTs, from HeLa cells by stably expressing antisense RNA. These HeLa-AS cells, in which the MAP4 level was decreased to 33% of the wild-type level, displayed decreased content of total tubulin (65% of the wild-type level). The partitioning of cellular tubulin into protomer and polymer was altered in HeLa-AS cells: polymeric tubulin was decreased to 46% of the level in control cells, while protomeric tubulin was increased to 226% of the level in control cells. Tubulin protein synthesis was decreased, consistent with the tubulin autoregulation model, which proposes that tubulin protomer inhibits its own synthesis. Following release from drug-induced depolymerization, MTs in HeLa-AS cells reformed more slowly, and showed an increased focus on the centrosome, as compared to control cells. HeLa-AS cells also appeared to be less bipolar in shape and flatter than control cells. Our data suggest that MAP4 regulates assembly level of MTs and, perhaps through this mechanism, is involved in controlling spreading and shape of cells.

Immunochemical probing of the N-terminal segment on actin: the polymerization reaction.

The N-terminal segment of actin contains a cluster of acidic residues which are implicated in macromolecular interactions of this protein. In this work, the interrelationship between the N-terminal segment and the polymerization of actin was studied by using affinity-purified antibodies directed against the first seven N-terminal residues on alpha-skeletal actin (S alpha N). The Fab fragments of these antibodies showed equal affinities for G- and F-actin while the bivalent IgG bound preferentially to the polymerized actin. As monitored by pyrene fluorescence measurements, the binding of Fab to G-actin did not alter the kinetics of the MgCl2-induced polymerization; IgG accelerated this reaction considerably. Consistent with these observations, the binding of Fab to F-actin did not change its morphological appearance in electron micrographs and had no effect on the stability and the rate of dissociation of actin filaments. These results are discussed in terms of their implications to the spatial relationship between the N-terminal segment and the rest of the molecule and the context of the polymerization reaction of actin in vitro and in vivo.

Ser787 in the proline-rich region of human MAP4 is a critical phosphorylation site that reduces its activity to promote tubulin polymerization.

p34cdc2 kinase-phosphorylation sites in the microtubule (MT)-binding region of MAP4 were determined by peptide sequence of phosphorylated MTB3, a fragment containing the carboxy-terminal half of human MAP4. In addition to two phosphopeptides containing Ser696 and Ser787 which were previously indicated to be in vivo phosphorylation sites, two novel phosphopeptides, containing Thr892 or Thr901 and Thr917 as possible phosphorylation sites, were isolated, though only in in vitro phosphorylation. The role of phosphorylation at Ser696 and Ser787, which were differently phosphorylated during the cell cycle (Ookata et al., (1997). Biochemistry, 36: 15873-15883), was investigated in MT-polymerization, using MAP4 Ser to Glu mutants, which mimic phosphorylation at each site. Mutation of Ser787 to Glu strikingly reduced the MAP4's MT-polymerization activity, while Glu-mutation at Ser696 did not. These results suggest that Ser787 could be the critical phosphorylation site causing MTs to be dynamic at mitosis.