Programmed elimination of cells by caspase-independent cell extrusion in C. elegans

Programmed elimination of cells by caspase-independent cell extrusion in C. elegans

The elimination of unnecessary or defective cells from metazoans occurs during normal development and tissue homeostasis, as well as in response to infection or cellular damage. Although many cells are removed through caspase-mediated apoptosis followed by phagocytosis by engulfing cells, other mech...

Full description

Bibliographic Details
Main Authors:	Hatch, Victoria, Denning, Daniel Prudden, Horvitz, Howard Robert
Other Authors:	Massachusetts Institute of Technology. Department of Biology
Format:	Article
Language:	en_US
Published:	Nature Publishing Group 2014
Online Access:	http://hdl.handle.net/1721.1/84508 https://orcid.org/0000-0002-9964-9613

Similar Items

Both the Caspase CSP-1 and a Caspase-Independent Pathway Promote Programmed Cell Death in Parallel to the Canonical Pathway for Apoptosis in Caenorhabditis elegans
by: Denning, Daniel Prudden, et al.
Published: (2013)

Replication stress promotes cell elimination by extrusion
by: Dwivedi, Vivek Kumar, et al.
Published: (2021)

SPK-1, an SR protein kinase, inhibits programmed cell death in Caenorhabditis elegans
by: Galvin, Brendan D., et al.
Published: (2011)

SLI-1 Cbl Inhibits the Engulfment of Apoptotic Cells in C. elegans through a Ligase-Independent Function
by: Anderson, Courtney, et al.
Published: (2013)

An Sp1 transcription factor coordinates caspase-dependent and -independent apoptotic pathways
by: Hirose, Takashi, et al.
Published: (2014)

Genetic regulation of cell extrusion in caenorhabditis elegans
by: Dwivedi, Vivek Kumar.
Published: (2019)

Both the apoptotic suicide pathway and phagocytosis are required for a programmed cell death in Caenorhabditis elegans
by: Johnsen, Holly L., et al.
Published: (2016)

The regulation of programmed and pathological cell death in C. elegans
by: Galvin, Brendan D. (Brendan Daniel)
Published: (2007)

Hypoxia-inducible factor cell non-autonomously regulates C. elegans stress responses and behavior via a nuclear receptor
by: Pender, Corinne Lenore, et al.
Published: (2020)

Dopamine Signaling Is Essential for Precise Rates of Locomotion by C. elegans
by: Omura, Daniel T., et al.
Published: (2012)

Ligand-Gated Chloride Channels Are Receptors for Biogenic Amines in C. elegans
by: Ringstad, Niels, et al.
Published: (2014)

The Translational Regulators GCN-1 and ABCF-3 Act Together to Promote Apoptosis in C. elegans
by: Hirose, Takashi, et al.
Published: (2014)

C. elegans discriminates colors to guide foraging
by: Ghosh, D. Dipon, et al.
Published: (2021)

Light and Hydrogen Peroxide Inhibit C. elegans Feeding through Gustatory Receptor Orthologs and Pharyngeal Neurons
by: Bhatla, Nikhil, et al.
Published: (2017)

Replication-Coupled Chromatin Assembly Generates a Neuronal Bilateral Asymmetry in C. elegans
by: Nakano, Shunji, et al.
Published: (2014)

Abl Kinase Inhibits the Engulfment of Apoptotic [corrected] Cells in Caenorhabditis elegans
by: Hurwitz, Michael Eliezer, et al.
Published: (2010)

Genetic and molecular studies of cell-autonomous execution during programmed cell death in C. elegans
by: Driscoll, Kaitlin B. (Kaitlin Bridget)
Published: (2016)

Regulation of cell-identity maintenance in C. elegans
by: Saul, Joshua C.
Published: (2022)

The C. elegans MicroRNA mir-71 Acts in Neurons to Promote Germline-Mediated Longevity through Regulation of DAF-16/FOXO
by: Boulias, Konstantinos, et al.
Published: (2014)

Distinct Neural Circuits Control Rhythm Inhibition and Spitting by the Myogenic Pharynx of C. elegans
by: Bhatla, Nikhil, et al.
Published: (2017)

Axons Degenerate in the Absence of Mitochondria in C. elegans
by: Rawson, Randi L., et al.
Published: (2015)

Single-cell reporters for inflammatory caspase activity
by: Al-Obeidi, Arshed
Published: (2015)

Zerumbone induces apoptosis in Jurkat T-cell line via activation of caspase 3 and caspase 9
by: Rahman, Heshu Sulaiman, et al.
Published: (2012)

Many families of Caenorhabditis elegans microRNAs are not essential for development or viability
by: Alvarez-Saavedra, Ezequiel, et al.
Published: (2012)

Phagocytosis promotes programmed cell death and is controlled by Rac signaling pathway in C. elegans
by: Reddien, Peter W. (Peter Walthour), 1974-
Published: (2022)

Studies of programmed cell death in the nematode caenorhabditis elegans
by: Johnsen, Holly L. (Holly Louise)
Published: (2016)

Characterization of three Drosophila melanogaster regulators of programmed cell death that lead to caspase activation
by: Tittel, Jan N. (Jan Nils), 1971-
Published: (2005)

Wnt and EGF pathways act together to induce C. elegans male hook development
by: Yu, Hui, et al.
Published: (2010)

Cytochrome P450 Drives a HIF-Regulated Behavioral Response to Reoxygenation by C. elegans
by: Ma, Dengke, et al.
Published: (2014)

Effect of hyaluronan to inhibit caspase activation in porcine granulosa cells
by: Tunjung, Woro Anindito Sri
Published: (2009)

Mutations in the Caenorhabditis elegans U2AF Large Subunit UAF-1 Al= of a 3' Splice Site In Vivo
by: Ma, Long, et al.
Published: (2010)

Genetic analysis of timing, morphology and degradation of cell corpses in C. elegans
by: Stanfield, Gillian Marie, 1970-
Published: (2014)

Analysis of genes involved in cell-specific control of programmed cell death in Caenorhabditis elegans
by: Metzstein, Mark M. (Mark Mordecai), 1969-
Published: (2005)

In vitro and in vivo detection of mitophagy in human cells, C. elegans, and mice.
by: Fang, EF, et al.
Published: (2017)

Mutations in the Caenorhabditis elegans U2AF Large Subunit UAF-1 Alter the Choice of a 3' Splice Site In Vivo
by: Ma, Long, et al.
Published: (2010)

CYSL-1 Interacts with the O[subscript 2]-Sensing Hydroxylase EGL-9 to Promote H[subscript 2]S-Modulated Hypoxia-Induced Behavioral Plasticity in C. elegans
by: Vozdek, Roman, et al.
Published: (2014)

Genetic and molecular studies of programmed cell death in the nematod Caenorhabditis elegans
by: Shaham, Shai
Published: (2006)

The transcriptional corepressor CTBP-1 acts with the SOX family transcription factor EGL-13 to maintain AIA interneuron cell identity in Caenorhabditis elegans
by: Saul, Josh, et al.
Published: (2022)

Genetic and molecular analysis of the C.elegans cell survival gene ced-9
by: Hengartner, Michael Otmar
Published: (2005)

Two C. elegans genes that can mutate to cause degenerative cell death
by: Kim, Saechin
Published: (2005)