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54. Mutational Analysis of the Caenorhabditis elegans Cell-Death Gene ced-3

Author

Shaham, Shai, Reddien, Peter W., Davies, Brian, and Horvitz, Robert H.

Subjects
Caenorhabditis elegans -- Genetic aspects, Proteases -- Research, Mutagenesis -- Research, Cell death -- Research, Biological sciences
Abstract

Mutations in the gene ced-3, which encodes a protease similar to interleukin-1[Beta] converting enzyme and related proteins termed caspases, prevent programmed cell death in the nematode Caenorhabditis elegans. We used site-directed mutagenesis to demonstrate that both the presumptive active-site cysteine of the CED-3 protease and the aspartate residues at sites of processing of the CED-3 proprotein are required for programmed cell death in vivo. We characterized the phenotypes caused by and the molecular lesions of 52 ced-3 alleles. These alleles can be ordered in a graded phenotypic series. Of the 30 amino acid sites altered by ced-3 missense mutations, 29 are conserved with at least one other caspase, suggesting that these residues define sites important for the functions of all caspases. Animals homozygous for the ced-3(n2452) allele, which is deleted for the region of the ced-3 gene that encodes the protease domain, seemed to be incompletely blocked in programmed cell death, suggesting that some programmed cell death can occur independently of CED-3 protease activity.

Published
1999

55. A widely employed germ cell marker is an ancient disordered protein with reproductive functions in diverse eukaryotes

Author

Carmell, Michelle A, primary, Dokshin, Gregoriy A, additional, Skaletsky, Helen, additional, Hu, Yueh-Chiang, additional, van Wolfswinkel, Josien C, additional, Igarashi, Kyomi J, additional, Bellott, Daniel W, additional, Nefedov, Michael, additional, Reddien, Peter W, additional, Enders, George C, additional, Uversky, Vladimir N, additional, Mello, Craig C, additional, and Page, David C, additional

Published
2016
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56. Author response: A widely employed germ cell marker is an ancient disordered protein with reproductive functions in diverse eukaryotes

Author

Carmell, Michelle A, primary, Dokshin, Gregoriy A, additional, Skaletsky, Helen, additional, Hu, Yueh-Chiang, additional, van Wolfswinkel, Josien C, additional, Igarashi, Kyomi J, additional, Bellott, Daniel W, additional, Nefedov, Michael, additional, Reddien, Peter W, additional, Enders, George C, additional, Uversky, Vladimir N, additional, Mello, Craig C, additional, and Page, David C, additional

Published
2016
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68. dlx and sp6-9 Control Optic Cup Regeneration in a Prototypic Eye

Author

Massachusetts Institute of Technology. Department of Biology, Whitehead Institute for Biomedical Research, Reddien, Peter W., Lapan, Sylvain William, Reddien, Peter, Lapan, Sylvain W., Massachusetts Institute of Technology. Department of Biology, Whitehead Institute for Biomedical Research, Reddien, Peter W., Lapan, Sylvain William, Reddien, Peter, and Lapan, Sylvain W.

Abstract

Optic cups are a structural feature of diverse eyes, from simple pit eyes to camera eyes of vertebrates and cephalopods. We used the planarian prototypic eye as a model to study the genetic control of optic cup formation and regeneration. We identified two genes encoding transcription factors, sp6-9 and dlx, that were expressed in the eye specifically in the optic cup and not the photoreceptor neurons. RNAi of these genes prevented formation of visible optic cups during regeneration. Planarian regeneration requires an adult proliferative cell population with stem cell-like properties called the neoblasts. We found that optic cup formation occurred only after migration of progressively differentiating progenitor cells from the neoblast population. The eye regeneration defect caused by dlx and sp6-9 RNAi can be explained by a failure to generate these early optic cup progenitors. Dlx and Sp6-9 genes function as a module during the development of diverse animal appendages, including vertebrate and insect limbs. Our work reveals a novel function for this gene pair in the development of a fundamental eye component, and it utilizes these genes to demonstrate a mechanism for total organ regeneration in which extensive cell movement separates new cell specification from organ morphogenesis., United States. National Institutes of Health (NIH R01GM080639), W. M. Keck Foundation, Howard Hughes Medical Institute

Published
2012

93. A forkhead Transcription Factor Is Wound-Induced at the Planarian Midline and Required for Anterior Pole Regeneration.

Author

Scimone, M. Lucila, Lapan, Sylvain W., and Reddien, Peter W.

Subjects
PLANARIA, REGENERATION (Biology), PLURIPOTENT stem cells, TRANSCRIPTION factors, RNA interference
Abstract

Planarian regeneration requires positional information to specify the identity of tissues to be replaced as well as pluripotent neoblasts capable of differentiating into new cell types. We found that wounding elicits rapid expression of a gene encoding a Forkhead-family transcription factor, FoxD. Wound-induced FoxD expression is specific to the ventral midline, is regulated by Hedgehog signaling, and is neoblast-independent. FoxD is subsequently expressed within a medial subpopulation of neoblasts at wounds involving head regeneration. Ultimately, FoxD is co-expressed with multiple anterior markers at the anterior pole. Inhibition of FoxD with RNA interference (RNAi) results in the failure to specify neoblasts expressing anterior markers (notum and prep) and in anterior pole formation defects. FoxD(RNAi) animals fail to regenerate a new midline and to properly pattern the anterior blastema, consistent with a role for the anterior pole in organizing pattern of the regenerating head. Our results suggest that wound signaling activates a forkhead transcription factor at the midline and, if the head is absent, FoxD promotes specification of neoblasts at the prior midline for anterior pole regeneration. [ABSTRACT FROM AUTHOR]

Published
2014
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94. pbx is required for pole and eye regeneration in planarians.

Author

Chun-Chieh, G. Chen, Wang, Irving E., and Reddien, Peter W.

Subjects
EYE development, REGENERATION (Biology), PLANARIA, GENE expression, TRANSCRIPTION factors, HOMEOSTASIS, DEVELOPMENTAL biology
Abstract

Planarian regeneration involves regionalized gene expression that specifies the body plan. After amputation, planarians are capable of regenerating new anterior and posterior poles, as well as tissues polarized along the anterior-posterior, dorsal-ventral and mediallateral axes. Wnt and several Hox genes are expressed at the posterior pole, whereas Wnt inhibitory genes, Fgf inhibitory genes, and prep, which encodes a TALE-family homeodomain protein, are expressed at the anterior pole. We found that Smed-pbx (pbx for short), which encodes a second planarian TALE-family homeodomain transcription factor, is required for restored expression of these genes at anterior and posterior poles during regeneration. Moreover, pbx(RNAi) animals gradually lose pole gene expression during homeostasis. By contrast, pbx was not required for initial anterior-posterior polarized responses to wounds, indicating that pbx is required after wound responses for development and maintenance of poles during regeneration and homeostatic tissue turnover. Independently of the requirement for pbx in pole regeneration, pbx is required for eye precursor formation and, consequently, eye regeneration and eye replacement in homeostasis. Together, these data indicate that pbx promotes pole formation of body axes and formation of regenerative progenitors for eyes. [ABSTRACT FROM AUTHOR]

Published
2013
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95. THE ENGULFMENT PROCESS OF PROGRAMMED CELL DEATH IN CAENORHABDITIS ELEGANS.

Author

Reddien, Peter W. and Horvitz, H. Robert

Subjects
*PHAGOCYTOSIS, *APOPTOSIS, *CAENORHABDITIS elegans, *LIGANDS (Biochemistry), *METAZOA
Abstract

Programmed cell death involves the removal of cell corpses by other cells in a process termed engulfment. Genetic studies of the nematode Caenorhabditis elegans have led to a framework not only for the killing step of programmed cell death but also for the process of cell-corpse engulfment. This work has defined two signal transduction pathways that act redundantly to control engulfment. Signals expressed by dying cells probably regulate these C. elegans pathways. Components of the cell-corpse recognition system of one of the C. elegans pathways include the CED-7 ABC transporter, which likely presents a death ligand on the surface of the dying cell; the CED-1 transmembrane receptor, which recognizes this signal; and the CED-6 adaptor protein, which may transduce a signal from CED-1. The second C. elegans pathway acts in parallel and involves a novel Rac GTPase signaling pathway, with the components CED-2 CrkII, CED-5 DOCK180, CED-12 ELMO, and CED-10 Rac. The cell-corpse recognition system that activates this pathway remains to be characterized. In C. elegans, and possibly in mammals, the process of cell-corpse engulfment promotes the death process itself. The known mechanisms for cell-corpse engulfment leave much to be discovered concerning this fundamental aspect of metazoan biology. [ABSTRACT FROM AUTHOR]

Published
2004
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96. Transcriptome Analysis of the Planarian Eye Identifies ovoas a Specific Regulator of Eye Regeneration

Author

Lapan, Sylvain W. and Reddien, Peter W.

Abstract

Among the millions of invertebrate species with visual systems, the genetic basis of eye development and function is well understood only in Drosophila melanogaster. We describe an eye transcriptome for the planarian Schmidtea mediterranea. Planarian photoreceptors expressed orthologs of genes required for phototransduction and microvillus structure in Drosophilaand vertebrates, and optic pigment cells expressed solute transporters and melanin synthesis enzymes similar to those active in the vertebrate retinal pigment epithelium. Orthologs of several planarian eye genes, such as bestrophin-1and Usher syndrome genes, cause eye defects in mammals when perturbed and were not previously described to have roles in invertebrate eyes. Five previously undescribed planarian eye transcription factors were required for normal eye formation during head regeneration. In particular, a conserved, transcription-factor-encoding ovogene was expressed from the earliest stages of eye regeneration and was required for regeneration of all cell types of the eye.

Published
2012
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97. Three C. elegans Rac proteins and several alternative Rac regulators control axon guidance, cell migration and apoptotic cell phagocytosis

Author

Lundquist, Erik A., Reddien, Peter W., Hartwieg, Erika, Horvitz, H. Robert, and Bargmann, Cornelia I.

Abstract

The Caenorhabditis elegans genome contains three rac-like genes, ced-10, mig-2, and rac-2. We report that ced-10, mig-2 and rac-2 act redundantly in axon pathfinding: inactivating one gene had little effect, but inactivating two or more genes perturbed both axon outgrowth and guidance. mig-2 and ced-10 also have redundant functions in some cell migrations. By contrast, ced-10 is uniquely required for cell-corpse phagocytosis, and mig-2 and rac-2 have only subtle roles in this process. Rac activators are also used differentially. The UNC-73 Trio Rac GTP exchange factor affected all Rac pathways in axon pathfinding and cell migration but did not affect cell-corpse phagocytosis. CED-5 DOCK180, which acts with CED-10 Rac in cell-corpse phagocytosis, acted with MIG-2 but not CED-10 in axon pathfinding. Thus, distinct regulatory proteins modulate Rac activation and function in different developmental processes.

Published
2001
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98. Gene nomenclature guidelines for the planarian Schmidtea mediterranea.

Author

Reddien, Peter W., Newmark, Phillip A., and Alvarado, Alejandro Sánchez

Abstract

We describe a gene nomenclature system for the freshwater planarian Schmidtea mediterranea. Guidelines are specified for designating names for genes and proteins, as well as for describing RNA-mediated genetic interference (RNAi) experiments. The proposed conventions aim to avoid multiple names being ascribed to single genes and to establish a uniform, simple method for naming genes in S. mediterranea that is readily understood by researchers working on planarians and other organisms. Developmental Dynamics 237:3099-3101, 2008. © 2008 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2008
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99. dlx and sp6-9 Control optic cup regeneration in a prototypic eye

Author

Peter W. Reddien, Sylvain W. Lapan, Massachusetts Institute of Technology. Department of Biology, Whitehead Institute for Biomedical Research, Reddien, Peter W., Lapan, Sylvain William, and Reddien, Peter

Subjects
Cancer Research, lcsh:QH426-470, genetic structures, Cellular differentiation, Population, Morphogenesis, Gene Expression, Optic cup (anatomical), 03 medical and health sciences, 0302 clinical medicine, Model Organisms, Genetics, Animals, Regeneration, Progenitor cell, education, Molecular Biology, Ocular Physiological Phenomena, Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, In Situ Hybridization, Fluorescence, 030304 developmental biology, Neurons, 0303 health sciences, education.field_of_study, Evolutionary Biology, Arrestin, biology, Regeneration (biology), Stem Cells, Cell Differentiation, Helminth Proteins, Planarians, biology.organism_classification, eye diseases, 3. Good health, Cell biology, lcsh:Genetics, Eye regeneration, Microscopy, Fluorescence, Planarian, sense organs, 030217 neurology & neurosurgery, Transcription Factors, Research Article, Developmental Biology
Abstract

Optic cups are a structural feature of diverse eyes, from simple pit eyes to camera eyes of vertebrates and cephalopods. We used the planarian prototypic eye as a model to study the genetic control of optic cup formation and regeneration. We identified two genes encoding transcription factors, sp6-9 and dlx, that were expressed in the eye specifically in the optic cup and not the photoreceptor neurons. RNAi of these genes prevented formation of visible optic cups during regeneration. Planarian regeneration requires an adult proliferative cell population with stem cell-like properties called the neoblasts. We found that optic cup formation occurred only after migration of progressively differentiating progenitor cells from the neoblast population. The eye regeneration defect caused by dlx and sp6-9 RNAi can be explained by a failure to generate these early optic cup progenitors. Dlx and Sp6-9 genes function as a module during the development of diverse animal appendages, including vertebrate and insect limbs. Our work reveals a novel function for this gene pair in the development of a fundamental eye component, and it utilizes these genes to demonstrate a mechanism for total organ regeneration in which extensive cell movement separates new cell specification from organ morphogenesis., United States. National Institutes of Health (NIH R01GM080639), W. M. Keck Foundation, Howard Hughes Medical Institute

Published
2011

100. Positional Information and Stem Cells Combine to Result in Planarian Regeneration.

Author

Reddien PW

Subjects
Animals, Signal Transduction, Planarians physiology, Pluripotent Stem Cells physiology
Abstract

The capacity for regeneration is broad in the animal kingdom. Planarians are flatworms that can regenerate any missing body part and their regenerative powers have combined with ease of experimentation to make them a classic regeneration model for more than a century. Pluripotent stem cells called neoblasts generate missing planarian tissues. Fate specification happens in the neoblasts, and this can occur in response to regeneration instructions in the form of positional information. Fate specification can lead to differentiating cells in single steps rather than requiring a long lineage hierarchy. Planarians display constitutive expression of positional information from muscle cells, which is required for patterned maintenance of tissues in tissue turnover. Amputation leads to the rapid resetting of positional information in a process triggered by wound signaling and the resetting of positional information is required for regeneration. These findings suggest a model for planarian regeneration in which adult positional information resets after injury to regulate stem cells to bring about the replacement of missing parts., (Copyright © 2022 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published
2022
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