Cell adhesion is regulated by a variety of Ca2+-regulated pathways that depend on Ca2+-binding proteins. One such protein is calreticulin, an ER-resident protein. Calreticulin signalling from within the ER can affect processes outside the ER, such as expression of several adhesion-related genes, most notably vinculin and fibronectin. In addition, changes in the expression level of calreticulin strongly affect tyrosine phosphorylation of cellular proteins, which is known to affect many adhesion-related functions. While calreticulin has been localized to cellular compartments other than the ER, it appears that only the ER-resident calreticulin affects focal-contact-dependent adhesion. In contrast, calreticulin residing outside the ER may be involved in contact disassembly and other adhesion phenomena. Here, we review the role of calreticulin in focal contact initiation, stabilization, and turnover. We propose that calreticulin may regulate cell-substratum adhesion by participating in an "ER-to-nucleus" signalling and in parallel "ER-to-cell surface" signalling based on posttranslational events.
High density micromass culture of limb bud mesenchymal stem cells isolated from mouse embryos represents a well-established model to study chondro- and osteogenesis. In spite of wide usage of the limb bud model, the mechanisms underlying cartilage nodule growth remain unclear. To determine whether cartilage nodules grow solely by induction of surrounding cells or proliferation of cells within the nodules, we performed BrdU/Collagen II (Col II) double-labelling and 3D reconstruction of growing cartilage nodules. We demonstrated that Col II-positive replicating chondrocytes are present throughout the nodules with the majority of replicating cells localized on the top (cell-medium interface) and periphery/sides of nodules. Kinetic analysis of cellular proliferation within the nodules demonstrated the time-dependent reduction in number of Col II-positive replicating cells. The sequential expression of Col I, Col II, Col X, parathyroid hormone related peptide receptor 1 (Pthr1), bone sialoprotein (Bsp) and osteocalcin (Ocn) mRNAs was similar to that characterizing chondrocyte differentiation and maturation in vivo. We conclude that the limb bud model recapitulates events seen during endochondral bone formation: cellular aggregation, proliferation, differentiation and maturation to hypertrophy. We also conclude that not only induction of peri-nodular mesenchymal cells but also proliferation of chondrocytes within cartilage nodules contribute to cartilage nodule growth.
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