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[
Oncogene,
2008]
The BNIP3 subfamily of BH3-only proteins consists of BNIP3 and BNIP3-like (BNIP3L) proteins. These proteins form stable homodimerization complexes that localize to the outer membrane of the mitochondria after cellular stress. This promotes either apoptotic or non-apoptotic cell death such as autophagic cell death. Although the mammalian cells contain both members of this subfamily, the genome of Caenorhabditis elegans codes for a single BNIP3 ortholog, ceBNIP3, which shares homology in the transmembrane (TM) domain and in a conserved region close to the BH3 domain of mammalian BNIP3 protein. The cell death activities of BNIP3 and BNIP3L are determined by either the BH3 domain or the C-terminal TM domain. The TM domain of BNIP3 is unique, as it is capable of autonomous stable dimerization and contributes to mitochondrial localization of BNIP3. In knockout mouse models, BNIP3L was shown to be essential for normal erythrocyte differentiation and hematopoietic homeostasis, whereas BNIP3 plays a role in cellular responses to ischemia/reperfusion injury in the heart. Both BNIP3 and BNIP3L play a role in cellular responses to stress. Under hypoxia, both BNIP3 and BNIP3L expression levels are elevated and contribute to hypoxia-induced cell death. In addition, these proteins play critical roles in disease states. In heart disease, both BNIP3 and BNIP3L play a critical role in cardiomyocyte cell death following ischemic and non-ischemic injuries. In cancer, expression of BNIP3 and BNIP3L is downregulated by promoter hypermethylation or by homozygous deletion of the gene locus in certain cancers, whereas their expression was increased in other cancers. In addition, BNIP3 expression has been correlated with poor prognosis in some cancers. The results reviewed here suggest that BNIP3 and BNIP3L may be novel therapeutic targets for intervention because of their pathological roles in regulating cell death in disease states.
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[
Science,
1994]
In 1967, Sydney Brenner isolated the first behavioral mutants of the nematode Caenorhabditis elegans, and in 1970, John White began the systematic reconstruction of its nervous system. This dual approach of genetics coupled with detailed morphological analysis, now enhanced by the tools of molecular biology and electrophysiology, still dominates the study of the function and development of the C. elegans nervous system. Although Brenner's vision of a comprehensive understanding of this simple animal has taken time to mature, findings of the past few years indicate that the tree is bearing fruit.
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[
Results Probl Cell Differ,
2000]
Aging can be defined in three ways: (1) as a progressive increase in the probability of dying of nonaccidental causes, (2) as a progressive increase in the probability of being afflicted with a number of specific diseases, such as cancer, cardiovascular diseases, and neurodegenerative diseases, and (3) as a progressive increase in the prevalence of features that are not in themselves pathological, but which are linked to chronological age, like wrinkled skin or white hair. In recent years, several investigators have used definition (1) and the measure of life span in the nematode Caenorhabditis elegans to study genetic, cellular, and molecular mechanisms that might be responsible for the aging process in all organisms.
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[
Cell,
1996]
Across the animal kingdom, fertilization requires the encounter between a large stationary egg and small motile sperm. To maximize their likelihood of reaching the egg before their competition, sperm are extraordinarily specialized cells, generally consisting of little more than a haploid nucleus, mitochondria to generate energy, and a highly efficient movement engine. Almost all animal sperm are flagellated and seek the egg by swimming quickly through a liquid environment. Nematodes, however, produce sperm that move by crawling along solid substrates. These roundworm sperm extend pseudopods that look and behave like the actin-rich pseudopods of a wide variety of cells ranging from free-living soil amoebae to human white blood cells. The crawling sperm appear by most criteria to be exploiting classic actin-based cell motility, with one important difference: the sperm contain practically no actin (Nelson et al., 1982).
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[
Int J Biochem Cell Biol,
2009]
In 1990, the discovery of three Caenorhabditis elegans genes (
unc5,
unc6,
unc40) involved in pioneer axon guidance and cell migration marked a significant advancement in neuroscience research [Hedgecock EM, Culotti JG, Hall DH. The
unc-5,
unc-6, and
unc-40 genes guide circumferential migrations of pioneer axons and mesodermal cells on the epidermis in C. elegans. Neuron 1990;4:61-85]. The importance of this molecular guidance system was exemplified in 1994, when the vertebrate orthologue of Unc6, Netrin-1, was discovered to be a key guidance cue for commissural axons projecting toward the ventral midline in the rodent embryonic spinal cord [Serafini T, Kennedy TE, Galko MJ, Mirzayan C, Jessell TM, Tessier-Lavigne M. The netrins define a family of axon outgrowth-promoting proteins homologous to C. elegans UNC-6. Cell 1994;78:409-424]. Since then, Netrin-1 has been found to be a critical component of embryonic development with functions in axon guidance, cell migration, morphogenesis and angiogenesis. Netrin-1 also plays a role in the adult brain, suggesting that manipulating netrin signals may have novel therapeutic applications.
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[
Philos Trans R Soc Lond B Biol Sci,
2015]
The article 'Structure of the nervous system of the nematode Caenorhabditis elegans' (aka 'The mind of a worm') by White et al., published for the first time the complete set of synaptic connections in the nervous system of an animal. The work was carried out as part of a programme to begin to understand how genes determine the structure of a nervous system and how a nervous system creates behaviour. It became a major stimulus to the field of C. elegans research, which has since contributed insights into all areas of biology. Twenty-six years elapsed before developments, notably more powerful computers, made new studies of this kind possible. It is hoped that one day knowledge of synaptic structure, the connectome, together with results of many other investigations, will lead to an understanding of the human brain. This commentary was written to celebrate the 350th anniversary of the journal Philosophical Transactions of the Royal Society.
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[
Front Cell Dev Biol,
2019]
Autophagy as a ubiquitous catabolic process causes degradation of cytoplasmic components and is generally considered to have beneficial effects on health and lifespan. In contrast, inefficient autophagy has been linked with detrimental effects on the organism and various diseases, such as Parkinson's disease. Previous research, however, showed that this paradigm is far from being black and white. For instance, it has been reported that increased levels of autophagy during development can be harmful, but become advantageous in the aging cell or organism, causing enhanced healthspan and even longevity. The antagonistic pleiotropy hypothesis postulates that genes, which control various traits in an organism, can be fitness-promoting in early life, but subsequently trigger aging processes later. Autophagy is controlled by the mechanistic target of rapamycin (mTOR), a key player of nutrient sensing and signaling and classic example of a pleiotropic gene. mTOR acts upstream of transcription factors such as FOXO, NRF, and TFEB, controlling protein synthesis, degradation, and cellular growth, thereby regulating fertility as well as aging. Here, we review recent findings about the pleiotropic role of autophagy during development and aging, examine the upstream factors, and contemplate specific mechanisms leading to disease, especially neurodegeneration.
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[
Curr Top Dev Biol,
1999]
Wg/Wnt signaling regulates cell proliferation and differentiation in species as divergent as nematodes, flies, frogs, and humans. Many components of this highly conserved process have been characterized and work from a number of laboratories is beginning to elucidate the mechanism by which this class of secreted growth factor triggers cellular decisions. The Wg/Wnt ligand apparently binds to Frizzled family receptor molecules to initiate a signal transduction cascade involving the novel cytosolic protein Dishevelled and the serine/threonine kinase Zeste-white 3/GSK3. Antagonism of Zw3 activity leads to stabilization of Armadillo/beta-catenin, which provides a transactivation domain when complexed with the HMG box transcription factor dTCF/LEF-1 and thereby activates expression of Wg/Wnt-responsive genes. The Wg/Wnt ligands pass through the secretory pathway and associate with extracellular matrix components; recent work shows that sulfated glycosaminoglycans are essential for proper transduction of the signal. Mutant forms of Wg in Drosophila reveal separable aspects of Wg function and suggest that proper transport of the protein across cells is essential for cell fate specification. Complex interactions with the Notch and EGF/Ras signaling pathways also play a role in cell fate decisions during different phases of Drosophila development. These many facets of Wg/Wnt signaling have been elucidated through studies in a variety of species, each with powerful and unique experimental approaches. The remarkable conservation of this pathway suggests that Wg/Wnt signal transduction represents a fundamental mechanism for the generation of diverse cell fates in animal embryos.
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[
Methods Cell Biol,
1995]
Although Caenorhabditis elegans was originally chosen as a model organism for cell biology with serial section electron microscopy (EM) methods in mind, these methods have remained a daunting challenge. There is an apocryphal story that Nichol Thomson originally advised Sydney Brenner that C. elegans was unsuitable for electron microscopy and that Brenner should choose another species. Other experienced microscopists have probably shared similar dark thoughts from time to time. Nonetheless, the worm's very small size, simple organization, and cablelike nervous system have permitted Brenner's colleagues to characterize every cell and cell contact in the wild-type animal, potentiating the genetic characterization of cellular development in remarkable detail. We attempt to provide an adequate background for anyone to initiate EM studies of C. elegans. Two decades ago, as the first of Brenner's postdoctoral fellows left his laboratory to establish new worm laboratories, it was standard practice to include an EM component in their studies. Their combined efforts to characterize the adult animal's cell types and the essential steps in its development helped to erect a lovely scaffold of key manuscripts, capped by the description of the "Mind of the Worm" in some 600 micrographs and 175 drawings. Many of these works required technical heroics or suffered long delays before publication. Most people later chose to leave electron microscopy behind in pursuit of molecular quarry. The fruits of their molecular and genetic studies should soon stimulate a renewed flowering of electron microscopy. We hope to smooth your entry or reentry into these techniques. We also summarize our methods for three-dimensional (3D) image reconstruction, based largely on film techniques introduced by John White and Randle Ware. Digital imaging techniques seem poised to make 3D reconstruction more accessible, and may simplify the exchange of morphological data between laboratories. We discuss several computer systems that the C. elegans community could adopt for high-resolution studies of structure and function. In addition, we briefly cover several specialized specimen preparation techniques for electron microscopy, including freeze fracture and electron microscopic immunocytochemistry.