Jutta Marzillier scite author profile

Direct intercellular communication mediated by gap junctions (GJs) is a hallmark of normal cell and tissue physiology. In addition, GJs significantly contribute to physical cell-cell adhesion. Clearly, these cellular functions require precise modulation. Typically, GJs represent arrays of hundreds to thousands of densely packed channels, each one assembled from two half-channels (connexons), that dock head-on in the extracellular space to form the channel arrays that link neighboring cells together. Interestingly, docked GJ channels cannot be separated into connexons under physiological conditions, posing potential challenges to GJ channel renewal and physical cell-cell separation. We described previously that cells continuously—and effectively after treatment with natural inflammatory mediators—internalize their GJs in an endo-/exocytosis process that utilizes clathrin-mediated endocytosis components, thus enabling these critical cellular functions. GJ internalization generates characteristic cytoplasmic double-membrane vesicles, described and termed earlier annular GJs (AGJs) or connexosomes. Here, using expression of the major fluorescent-tagged GJ protein, connexin 43 (Cx43-GFP/YFP/mApple) in HeLa cells, analysis of endogenously expressed Cx43, ultrastructural analyses, confocal colocalization microscopy, pharmacological and molecular biological RNAi approaches depleting cells of key-autophagic proteins, we provide compelling evidence that GJs, following internalization, are degraded by autophagy. The ubiquitin-binding protein p62/sequestosome 1 was identified in targeting internalized GJs to autophagic degradation. While previous studies identified proteasomal and endo-/lysosomal pathways in Cx43 and GJ degradation, our study provides novel molecular and mechanistic insights into an alternative GJ degradation pathway. Its recent link to health and disease lends additional importance to this GJ degradation mechanism and to autophagy in general.

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Cohesins coordinate gene transcriptions of related function withinSaccharomyces cerevisiae

Skibbens¹,

Marzillier²,

Eastman³

2010

Cell Cycle

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Cohesion factors pair together sister chromatids from early S-phase until anaphase onset. Numerous findings also establish an additional role in transcription. In humans, mutations in cohesion factors result in developmental abnormalities such as Cornelia de Lange, Roberts Syndrome/SC-Phocomelia, Rothman-Thompson Syndrome and others. While clinically relevant, a detailed study that links experimentally-defined cohesin defects to transcriptional changes remains lacking. Here, we report on the effects of cohesin inactivation during an early and discrete portion of the cell cycle. Even transient cohesin inactivation in α-factor arrested cells to target the G1 portion of the cell cycle results in significant and reproducible changes in transcription. Surprisingly, over a third of the affected genes exhibit inter-related functions, suggesting that cohesin positioning along chromosomes evolved to coordinate gene expression. Prior studies indicate that defects in rRNA maturation/ribosome biogenesis produce developmental maladies in humans. Thus, the identification of genes critical for rRNA maturation in this study is of particular interest.

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Identification of linear B-cell determinants of pertussis toxin associated with the receptor recognition site of the S3 subunit

et al. 1991

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Receptor recognition of pertussis toxin is mediated by the B oligomer consisting of subunits S2, S3, 2xS4, and S5. One possible way to interfere with toxin action would be the inhibition of recognition and binding of the cellular receptor(s) by preformed toxin-directed antipeptide antibodies. A prerequisite for this approach is the localization of linear antigenic determinants followed by the identification of inhibitory epitopes. Anti-S2 peptide antibodies have been shown to inhibit binding of the holotoxin to in vitro model receptor systems. For the elucidation of linear antigenic and immunogenic determinants harbored in the S3 subunit, synthetic peptides corresponding to selected linear amino acid sequences of S3 have been prepared and used to raise peptide-specific antibodies in rabbits. All peptides elicited a strong homologous response. Four synthetic peptides reacting with anti-pertussis toxin antibodies (R36-51, R87-95, R134-150, and R147-160) have been identified. Seven synthetic peptides (Rl-12, R12-23, R14-29m, R36-51, R95-107, R134-150, and R164-178) induced antibodies recognizing pertussis toxin. Thus, these segments correspond to linear antigenic determinants. Analogous to the S2 subunit, the N terminus of S3 proved to be immunorecessive in the native toxin. The highly homologous S2 subunit was only bound strongly in Western blotting (immunoblotting) by antiserum directed at peptide R164-178, which is identical in the S2 and S3 subunits. A weak recognition of S2 in Western blotting was observed with anti-R95-107 antiserum. The ability of affinity-purified anti-S3 peptide antibodies to interfere with pertussis toxin binding was investigated by hemagglutination of goose erythrocytes as a model receptor system for S3-mediated receptor recognition. Antipeptide antibodies directed at Rl-12, R12-23, R14-29m, and R36-51 inhibited hemagglutination of goose erythrocytes. This indicates that the corresponding antigenic regions in the S3 subunit are associated with the formation of the receptor binding domain. Inhibition of B-oligomer-mediated pertussis toxin binding to cellular receptors by preformed antipeptide antibodies of sufficient affinity should not only block the detrimental effects of the Si subunits, but also interfere with the mitogenic effects attributed to the B oligomer.

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New bioactive glass scaffolds with exceptional qualities for bone tissue regeneration: response of osteoblasts and osteoclasts

et al. 2018

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Tissue regeneration is a significantly improved alternative to tissue replacement by implants. It requires porous bioscaffolds for the restoration of natural tissue rather than relying on bio-inactive, often metallic implants. Recently, we developed technology for fabricating novel, nano-macroporous bioactive 'tailored amorphous multi-porous (TAMP)' hard tissue scaffolds using a 70 mol% SiO-30 mol% CaO model composition. The TAMP silicate scaffolds, fabricated by a modified sol-gel process, have shown excellent biocompatibility via the rapid formation of hydroxyapatite in biological fluids as well as in early tests with bone forming cells. Here we report an in depth investigation of the response of MC3T3-E1 pre-osteoblast cells and bone marrow derived (BMD) osteoclasts to these TAMP scaffolds. Light and electron microscopic imaging, gene and protein expression, and enzyme activity analyses demonstrate that MC3T3-E1 pre-osteoblasts adhere, proliferate, colonize, and differentiate on and inside the bioactive TAMP scaffolds. Additionally, BMD precursor cells mature into active osteoclasts and remodel the scaffold, highlighting the exceptional qualities of this novel scaffold material for bone tissue regeneration.

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