Latest Articles Include:
- Editorial Board
- Trends Cell Biol 19(10):i (2009)
- The regulation of aging: does autophagy underlie longevity?
- Trends Cell Biol 19(10):487-494 (2009)
The accumulation of cellular damage is a feature common to all aging cells and leads to decreased ability of the organism to survive. The overall rate at which damage accumulates is influenced by conserved metabolic factors (longevity pathways and regulatory proteins) that control lifespan through adjusting mechanisms for maintenance and repair. Autophagy, the major catabolic process of eukaryotic cells that degrades and recycles damaged macromolecules and organelles, is implicated in aging and in the incidence of diverse age-related pathologies. Recent evidence has revealed that autophagic activity is required for lifespan extension in various long-lived mutant organisms, and that numerous autophagy-related genes or proteins are directly regulated by longevity pathways. These findings support the emerging view that autophagy is a central regulatory mechanism for aging in diverse eukaryotic species. - Plasmodesmata – bridging the gap between neighboring plant cells
- Trends Cell Biol 19(10):495-503 (2009)
Land plants have developed highly sophisticated intercellular channels called plasmodesmata (PD) that mediate the cell-to-cell trafficking of signaling molecules, including non-cell autonomous proteins (NCAPs) and RNAs. Until recently, the biological significance of this position-dependent intercellular signaling system was underestimated, as only a limited number of endogenous NCAPs had been discovered. However, identification of an ever-increasing population of NCAPs suggests that the PD communication pathway is involved in diverse biological processes, ranging from development to pathogen defense. The identification of components involved in plasmodesmal structure and associated signaling molecules is now yielding novel insights into the evolution and function of PD in mediating the trafficking of non-cell-autonomous information macromolecules. Important future challenges are to build a detailed model for the plasmodesmal supramolecular complex and to further elucid! ate the molecular and cellular aspects of this novel plant cell-to-cell communication pathway. - The Kindlin protein family: new members to the club of focal adhesion proteins
- Trends Cell Biol 19(10):504-513 (2009)
Kindlins are a group of proteins that have recently attracted attention for their ability to bind and activate integrins. Moreover, they have also been linked to inherited and acquired human diseases including Kindler syndrome, leukocyte adhesion deficiency, and cancer. Although most studies have focused on kindlins as key regulatory components of cell–extracellular matrix junctions such as focal adhesions, preliminary data suggest the involvement of additional cellular compartments in mediating their functions, particularly at cell–cell contacts and the nucleus. Investigating the many roles of kindlins is likely to expand and sharpen our view on the versatility of integrin-mediated cell adhesion, the nuclear function of focal adhesion proteins, and the crosstalk between cell–cell and cell–matrix adhesions in health and disease. - Molecular mediators of macrophage fusion
- Trends Cell Biol 19(10):514-522 (2009)
Fusion of macrophages leads to the formation of osteoclasts in bone and of multinucleated giant cells in granulomas. The precise function of granuloma-associated multinucleates giant cells is not clear but substantial progress has recently been made in identifying the molecular machinery involved in macrophage fusion. Signaling processes mediated by DAP12 and STAT6 induce a fusion-competent status. Chemotaxis through CCL2, cell–cell adhesion mediated by E-cadherin, exposure of phosphatidylserine, lipid recognition by CD36 and cytoskeletal rearrangements depending on RAC1 are prerequisites for successful macrophage fusion. We review current knowledge on the molecular mediators of giant cell formation, compare giant cells with osteoclasts and highlight key target areas for future research and medical relevance. - Chemotaxis: finding the way forward with Dictyostelium
- Trends Cell Biol 19(10):523-530 (2009)
Understanding cell migration is centrally important to modern cell biology. However, despite years of study, progress has been hindered by experimental limitations and the complexity of the process. This has led to the popularity of Dictyostelium discoideum, with its experimentally-friendly lifestyle and small, haploid genome, as a tool to dissect the pathways involved in migration. This humble amoeba is now established at the centre of dramatic changes in our understanding of cell movement. In this review we describe the recent reinterpretation of the role of phosphatidylinositol trisphosphate (PIP3) and other intracellular messengers that connect signalling and migration, and the transition to models of chemotaxis driven by multiple, intertwined signalling pathways. In shallow gradients, pseudopods are generated with random directions, and we discuss how chemotaxis can operate by biasing this process. Overall we describe how Dictyostelium has the potential to unlock ! many fundamental questions in the cell motility field. - Mitotic phosphatases: from entry guards to exit guides
- Trends Cell Biol 19(10):531-541 (2009)
While the importance of protein kinases for the spatial and temporal control of mitotic events has long been recognized, mitotic phosphatases have only recently come into the limelight. It is now well established that protein phosphatases counteract mitotic kinases, so contributing to the generation of switch-like responses at mitotic stage transitions. In addition, the timely dephosphorylation of mitotic phosphoproteins by tightly regulated phosphatases is required for the assembly and stability of the mitotic spindle, the initiation of anaphase, and exit from mitosis. Mitotic phosphatases also emerge as effectors of the DNA damage and spindle assembly checkpoints. These new findings show that protein phosphatases regulate every step of mitosis and provide novel insights into the dynamic and versatile nature of mitotic phosphoregulation. - Crosstalk in Met receptor oncogenesis
- Trends Cell Biol 19(10):542-551 (2009)
The Met receptor tyrosine kinase (RTK) regulates several distinct biological processes, including cell scatter, cell invasion, cell survival and epithelial remodeling. MET is genetically altered through several mechanisms in multiple human cancers; these events are causally related to cancer initiation and progression, identifying Met as a potential therapeutic target. Recent evidence highlights additional roles for Met in cancer through crosstalk with other receptors and cell surface proteins. In this review, we discuss recent progress in our understanding of mechanisms of interaction between Met, the epidermal growth factor receptor family and other cell surface protein families, and how these contribute to signal crosstalk, oncogenesis and drug resistance.
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