[
Biochim Biophys Acta,
2017]
The mitochondrial role in carcinogenesis and cancer progression is an area of active research, with many unresolved questions. Various aspects of altered mitochondrial function have been implicated in tumorigenesis and tumor progression, including mitochondrial dysfunction, a metabolic switch to aerobic glycolysis, and dysregulation of mitophagy. Mitophagy is a highly specific quality control process which eliminates dysfunctional mitochondria and promotes mitochondrial turnover, and is involved in the adaptation to nutrient stress by controlling mitochondrial mass. The dysregulation of mitochondrial turnover has both a positive and negative role in cancer. This review will begin with a basic overview of the molecular mechanisms of mitophagy, and highlight recent trends in mitophagy from cancer studies. We will conclude this review by discussing areas of research in normal mitophagy that have yet to be explored in the context of cancer such as mitochondrial proteases, the mitochondrial unfolded protein response, and mitokine action. This article is part of a Special Issue entitled Mitochondria in Cancer, edited by Giuseppe Gasparre, Rodrigue Rossignol and Pierre Sonveaux.
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Biochim Biophys Acta,
2014]
As biological force-sensing systems mechanosensitive (MS) ion channels present the best example of coupling molecular dynamics of membrane proteins to the mechanics of the surrounding cell membrane. In animal cells MS channels have over the past two decades been very much in focus of mechanotransduction research. In recent years this helped to raise awareness of basic and medical researchers about the role that abnormal MS channels may play in the pathophysiology of diseases, such as cardiac hypertrophy, atrial fibrillation, muscular dystrophy or polycystic kidney disease. To date a large number of MS channels from organisms of diverse phylogenetic origins have been identified at the molecular level; however, the structure of only few of them has been determined. Although their function has extensively been studied in a great variety of cells and tissues by different experimental approaches it is, with exception of bacterial MS channels, very little known about how these channels sense mechanical force and which cellular components may contribute to their function. By focusing on MS channels found in animal cells this article discusses the ways in which the connections between cytoskeleton and ion channels may contribute to mechanosensory transduction in these cells. This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters. This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters. Guest Editor: Jean Claude Herve.
[
Methods Cell Biol,
1995]
ACeDB (A Caenorhabditis elegans Data Base) is a data management and display system that contains a wide range of genomic and other information about C. elegans. This chapter provides an overview of ACeDB for the C. elegans user, focusing in particular on the Macintosh version Macace. Previous reviews of AceDB include those of Thierry-Mieg and Durbin (1992) and Durbin and Thierry-Mieg (1994), which describe the general properties of the whole system, and that by Dunham et al. (1994), which discussed the use of AceDB for physical map data collection and assembly. ACeDB was developed by Jean Thierry-Mieg and Richard Durbin primarily for the C. elegans project, when the genomic sequencing project was just beginning in 1990. The original aim was to create a single database that integrated the genetic and physical maps with both genomic sequence data and the literature references. The forerunner of ACeDB was the program CONTIG9 (Sulston et al., 1988), which was developed to maintain and edit the physical map. CONTIG9 served researchers around the world by providing critical on-line access to the current physical map as it was being constructed (Coulson et al., 1986). This policy of immediate access allowed members of the worm community to see the same data as the people making the map, and proved very successful in maximizing use of the map. The same approach was adopted as a template for ACeDB. These two principles, developing a comprehensive database for all types of genomic and related data and providing public access to the data in the same form as used by the data-collecting laboratories, have continued to underlie developments of ACeDB. Over the last 5 years, a wide range of genome projects relating to other organisms have taken the ACeDB program and used it to develop databases for their own data. ACeDB has been used both in public projects designed to redistribute public data in a coordinated fashion and laboratory-based projects for collecting new data. Others, such as the C. elegans ACeDB, have used the database for both purposes. The reason it has been possible to adapt ACeDB so widely is that its flexible data structure allows new types of objects and new types of information about these objects to be added easily. This chapter describes (1) how to obtain ACeDB and documentation for it, (2) how to access and use the information in ACeDB, and (3) how to use ACeDB as a laboratory-based data managing system. Some of what we discuss is specific to the nematode database, but other information applies to the basic computer software program and, hence, to any database using the ACeDB program.