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Characterization of normal mitochondrial inheritance in C. elegans and a reverse genetic approach to identify possible genes involved
Title
Characterization of normal mitochondrial inheritance in C. elegans and a reverse genetic approach to identify possible genes involved.
Creator
Wilson, Amber Diane, Florida Atlantic University, LaMunyon, Craig W.
Abstract/Description
Mitochondria are inherited uniparentally in almost all eukaryotic models studied to date. The fathers mitochondria are eliminated and there have been several hypothesis as to how this occurs. One hypothesis is that the sperm mitochondria are actively targeted and destroyed. Ubiquitin has been proposed a possible candidate involved in this process. My research investigated the normal mitochondrial inheritance pattern in C. elegans. I also examined the possible role of the C34F11.1 gene in...
Show moreMitochondria are inherited uniparentally in almost all eukaryotic models studied to date. The fathers mitochondria are eliminated and there have been several hypothesis as to how this occurs. One hypothesis is that the sperm mitochondria are actively targeted and destroyed. Ubiquitin has been proposed a possible candidate involved in this process. My research investigated the normal mitochondrial inheritance pattern in C. elegans. I also examined the possible role of the C34F11.1 gene in mitochondrial inheritance. This gene is sperm-specific and has ubiquitin-ligase properties. It was determined that the normal mitochondrial inheritance pattern in C. elegans is maternal and that the sperm mitochondria are eliminated. It was also concluded that the C34F11.1 gene does not have a role in normal mitochondrial inheritance.
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Date Issued
2003
PURL
http://purl.flvc.org/fcla/dt/13049
Subject Headings
Caenorhabditis elegans, Mitochondrial DNA
Format
Document (PDF)
CAENORHABDITIS ELEGANS MMP STRAINS AND THEIR POTENTIAL DRIVING FORCE IN ANTIEPILEPTIC DRUG RESEARCH
Title
CAENORHABDITIS ELEGANS MMP STRAINS AND THEIR POTENTIAL DRIVING FORCE IN ANTIEPILEPTIC DRUG RESEARCH.
Creator
Sanchez, Christina Laura, Dawson-Scully, Ken, Florida Atlantic University, Department of Biological Sciences, Charles E. Schmidt College of Science
Abstract/Description
Over 70 million people worldwide suffer from epilepsy, with 90% of those cases taking place in developing countries (Singh & Trevick, 2016). Epilepsy can be defined as at least two unprovoked seizures occurring more than 24 hours apart, one unprovoked seizure with at least 60% chance of another seizure occurring within the next 10 years, or a diagnosis of epilepsy syndrome (Fisher et al., 2005). Varying physiological, molecular, genetic, and environmental factors can contribute to epileptic...
Show moreOver 70 million people worldwide suffer from epilepsy, with 90% of those cases taking place in developing countries (Singh & Trevick, 2016). Epilepsy can be defined as at least two unprovoked seizures occurring more than 24 hours apart, one unprovoked seizure with at least 60% chance of another seizure occurring within the next 10 years, or a diagnosis of epilepsy syndrome (Fisher et al., 2005). Varying physiological, molecular, genetic, and environmental factors can contribute to epileptic episodes. Although antiepileptic drugs (AEDs) exist, the complexity and lack of understanding behind the molecular mechanisms of the syndrome leaves the few drugs available to be insufficient for many patients (Rho & White, 2018). Therefore, the discovery of genetic pathways involved in epilepsy is imperative for the innovation of antiepileptic drugs. This thesis explores a novel method to add to mutant C.elegans libraries and improve antiepileptic drug discovery in a cost-effective and efficient manner by uncovering candidate molecular pathways through the candidate genes involved with antiepileptic strains.
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Date Issued
2022
PURL
http://purl.flvc.org/fau/fd/FA00014049
Subject Headings
Caenorhabditis elegans, Epilepsy, Drug development
Format
Document (PDF)
Identification of C. elegans ortholog of spinster
Title
Identification of C. elegans ortholog of spinster.
Creator
Kobler, Patrick, Jia, Kailiang
Date Issued
2013-04-05
PURL
http://purl.flvc.org/fcla/dt/3361106
Subject Headings
Autophagy, Lysosomal storage diseases, Caenorhabditis elegans
Format
Document (PDF)
Characterization of the spinster gene ortholog C13C4.5 in Caenorhabditis elegans
Title
Characterization of the spinster gene ortholog C13C4.5 in Caenorhabditis elegans.
Creator
Zahornacky, Darrin., Harriet L. Wilkes Honors College
Abstract/Description
The dauer larva is an alternate larval stage which allows the nematode C. elegans to survive environmestress during development. Dauer formation requires autophagy, a cellular process responsible for degrading and recycling cytoplasmic components. I investigated the role of a spinster orthiolog, C13C4.5, by examining the effects of C13C4.5 loss-of-function and by generating a transgenic strain which expressed a C13C4.5::GFP fusion protein. Under normal conditions C13C4.5::GFP is expressed...
Show moreThe dauer larva is an alternate larval stage which allows the nematode C. elegans to survive environmestress during development. Dauer formation requires autophagy, a cellular process responsible for degrading and recycling cytoplasmic components. I investigated the role of a spinster orthiolog, C13C4.5, by examining the effects of C13C4.5 loss-of-function and by generating a transgenic strain which expressed a C13C4.5::GFP fusion protein. Under normal conditions C13C4.5::GFP is expressed diffusely in the intestine, but under autophagy-promoting conditions the expression pattern becomes more punctate. This is consistent with localization of C13C4.5 to autophagolysomoes during autophagy, as has been shown for spinster in D. melanogaster. Loss of C13C4.5 function in a dauer-constitutive mutant resulted in a reduction in the proportion of animals entering into the dauer stage. Together these data suggest that C13C4.5 is involved in dauer formation and the autophagy pathway.
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Date Issued
2012
PURL
http://purl.flvc.org/FAU/3359320
Subject Headings
Gene expression, Apoptosis, Caenorhabditis elegans, Proteins, Analysis
Format
Document (PDF)
Characterizing electroconvulsive seizure recovery time in the invertebrate model systems Caenorhabditis elegans and Drosophila melanogaster
Title
Characterizing electroconvulsive seizure recovery time in the invertebrate model systems Caenorhabditis elegans and Drosophila melanogaster.
Creator
Risley, Monica G., Dawson-Scully, Ken, Florida Atlantic University, Charles E. Schmidt College of Science, Department of Biological Sciences
Abstract/Description
Seizures are a symptom of epilepsy, characterized by spontaneous firing due to an imbalance of excitatory and inhibitory features. While mammalian seizure models receive the most attention, the simplicity and tractability of invertebrate model systems, specifically C. elegans and D. melanogaster, have many advantages in understanding the molecular and cellular mechanisms of seizure behavior. This research explores C. elegans and D. melanogaster as electroconvulsive seizure models to...
Show moreSeizures are a symptom of epilepsy, characterized by spontaneous firing due to an imbalance of excitatory and inhibitory features. While mammalian seizure models receive the most attention, the simplicity and tractability of invertebrate model systems, specifically C. elegans and D. melanogaster, have many advantages in understanding the molecular and cellular mechanisms of seizure behavior. This research explores C. elegans and D. melanogaster as electroconvulsive seizure models to investigate methods to both modulate and better understand seizure susceptibility. A common underlying feature of seizures in mammals, worms, and flies involves regulating excitation and inhibition. The C. elegans locomotor circuit is regulated via well characterized GABAergic and cholingeric motoneurons that innervate two rows of dorsal and ventral body wall muscles. In this research, we developed an electroconvulsive seizure assay which utilizes the locomotor circuit as a behavioral read out of neuronal function. When inhibition is decreased in the circuit, for example by decreasing GABAergic input, we find a general increase in the time to recovery from a seizure. After establishing the contribution of excitation and inhibition to seizure recovery, we explored a ubiquitin ligase, associated with comorbidity of an X-linked Intellectual Disorder and epilepsy in humans, and established that the worm homolog, eel-1, contributes to seizure susceptibility similarly to the human gene. Next, we investigated a cGMP-dependent protein kinase (PKG) that functions in the nervous system of both worms and flies and determined that increasing PKG activity, decreases the time to recovery from an electroconvulsive seizure. These experiments suggest a potential novel role for a major protein, PKG, in seizure susceptibility and that the C. elegans and D. melanogaster electroconvulsive seizure assays can be used to investigate possible genes involved in seizure susceptibility and future therapeutic to treat epilepsy.
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Date Issued
2018
PURL
http://purl.flvc.org/fau/fd/FA00005954
Subject Headings
Seizures, Epilepsy, Drosophila melanogaster, Caenorhabditis elegans
Format
Document (PDF)
RESVERATROL-INSPIRED BRIDGED BICYCLIC COMPOUNDS: CHARACTERIZING A NOVEL ANTIEPILEPTIC DRUG CLASS
Title
RESVERATROL-INSPIRED BRIDGED BICYCLIC COMPOUNDS: CHARACTERIZING A NOVEL ANTIEPILEPTIC DRUG CLASS.
Creator
Stilley, Samantha E., Dawson-Scully, Kenneth, Florida Atlantic University, Department of Biological Sciences, Charles E. Schmidt College of Science
Abstract/Description
Epilepsy is a widely prevalent disease within the United States. It is estimated that about 1.2% of the total American population has active epilepsy, a condition of the brain that causes seizures. These seizures are marked by chemical alterations in neuronal firing that can cause abnormal behavior, sensations, muscle spasms, and loss of consciousness. Although the prevalence of seizures and epilepsy is high, effective treatments are limited and fail to provide effective treatment for nearly...
Show moreEpilepsy is a widely prevalent disease within the United States. It is estimated that about 1.2% of the total American population has active epilepsy, a condition of the brain that causes seizures. These seizures are marked by chemical alterations in neuronal firing that can cause abnormal behavior, sensations, muscle spasms, and loss of consciousness. Although the prevalence of seizures and epilepsy is high, effective treatments are limited and fail to provide effective treatment for nearly one-third of adult epileptic patients. Here, I conclude results of successful screening of novel compounds that can ameliorate seizures using an electroshock assay to examine seizure susceptibility and duration in C. elegans. The use of this assay provides an excellent platform for novel antiepileptic drug (AED) discovery efficiently. Literature shows Resveratrol, a natural product from plants, provides neuroprotective effects in various model organisms and therefore, is an excellent candidate for a molecule that has never been related to seizure. However, it is easily metabolized, being a flat and planar molecule. Our research group has collaboratively identified a novel bicyclic bridge molecule derived from the scaffolding of two resveratrol molecules we named Resveramorph (RVM). We also used the candidate approach to test a number of Resveramorph analogs on this assay to find the analog with highest efficacy. The various molecules characterized with their efficacy for seizure-like behavior after an electroshock have helped elucidate the mechanism of action and the RVMs physical target to give us greater insight into this potential family of AEDs.
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Date Issued
2022
PURL
http://purl.flvc.org/fau/fd/FA00014072
Subject Headings
Anticonvulsants, Epilepsy, Drug development, Caenorhabditis elegans
Format
Document (PDF)
CHARACTERIZATION OF PROCONVULSANT MECHANISMS ON GABAERGIC NEUROTRANSMISSION IN CAENORHABDITIS ELEGANS
Title
CHARACTERIZATION OF PROCONVULSANT MECHANISMS ON GABAERGIC NEUROTRANSMISSION IN CAENORHABDITIS ELEGANS.
Creator
Suthakaran, Nirthieca, Dawson-Scully, Ken, Florida Atlantic University, Department of Biological Sciences, Charles E. Schmidt College of Science
Abstract/Description
Epilepsy is a prevalent brain disorder that affects more than 1 in 26 people in the United States. The recurring increased neuronal excitability during seizures results in sleep disturbances and muscle convulsions that reduce the quality of life and increase the healthcare costs for these patients. An epilepsy diagnosis is made when patients have had two or more seizures. There are many types of seizures and an individual can have more than one type. Seizures are classified into two groups, 1...
Show moreEpilepsy is a prevalent brain disorder that affects more than 1 in 26 people in the United States. The recurring increased neuronal excitability during seizures results in sleep disturbances and muscle convulsions that reduce the quality of life and increase the healthcare costs for these patients. An epilepsy diagnosis is made when patients have had two or more seizures. There are many types of seizures and an individual can have more than one type. Seizures are classified into two groups, 1) generalized seizures that affect both sides of the brain and 2) focal seizures that are located in just one area of the brain. The causes of epilepsy vary by the age of the person, some with no clear cause may have a genetic form of epilepsy. Due to the various causes and types of seizures, many treatments including invasive surgeries and antiepileptic drugs (AEDs) do not work for all epileptic/seizure patients and are merely used to ease symptoms. The physiological complexity of the disorder and limited knowledge on its specific molecular mechanisms may contribute to the lack of effective treatment. In recent years, there has been an estimated average cost in billions of dollars to bring new medicine to the market; due to the lack of novel antiseizure targets and mechanism-based therapies on seizure phenotypes. In response to this, we utilized the electroconvulsive seizure behavioral assay to characterize one generalized seizure phenotype, tonic-clonic/grand mal seizures.
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Date Issued
2023
PURL
http://purl.flvc.org/fau/fd/FA00014198
Subject Headings
Epilepsy, Epilepsy--physiopathology, Seizures, Caenorhabditis elegans
Format
Document (PDF)
A neuronal G protein-coupled receptor mediates the effect of diet on lifespan and development in Caenorhabditis elegans through autophagy
Title
A neuronal G protein-coupled receptor mediates the effect of diet on lifespan and development in Caenorhabditis elegans through autophagy.
Creator
Parker, Thomas A., Jia, Kailiang, Florida Atlantic University, Charles E. Schmidt College of Science, Department of Biological Sciences
Abstract/Description
Animals rely on the integration of a variety of external cues to understand and respond appropriately to their environment. The relative amounts of food and constitutively secreted pheromone detected by the nematode C. elegans determines how it will develop and grow. Starvation conditions cause the animal to enter a protective stage, termed dauer. Dauer animals are non-eating, long-lived and stress resistant. Yet, when these animals are introduced to food replete conditions they will recover...
Show moreAnimals rely on the integration of a variety of external cues to understand and respond appropriately to their environment. The relative amounts of food and constitutively secreted pheromone detected by the nematode C. elegans determines how it will develop and grow. Starvation conditions cause the animal to enter a protective stage, termed dauer. Dauer animals are non-eating, long-lived and stress resistant. Yet, when these animals are introduced to food replete conditions they will recover from dauer and proceed into normal development. Furthermore, food restriction has been demonstrated to extend the lifespan of a wide-range of species including C. elegans. However, the exact mechanism by which food signals are detected and transduced by C. elegans to influence development and longevity remains unknown. Here, we identify a G protein-coupled receptor (GPCR) DCAR-1 that acts in two chemosensory neurons to mediate food signaling in an autophagy-related manner. The DCAR-1 ligand Dihydrocaffeic acid (DHCA) competes with dauer-inducing pheromone to promote growth. DHCA is a key intermediate in the shikimate pathway, which is required to synthesize folate and aromatic amino acids. We report that dcar-1 mutations influence dauer formation and extend wildtype lifespan via a mechanism of dietary restriction. Moreover, we show that the lifespan extension of dcar-1 mutants is completely dependent on autophagy gene atg- 18. Furthermore, our data suggests metabolites derived from shikimate are food signals that control aging and dauer development through GPCR signaling in C. elegans. These studies will contribute to the delineation of mechanisms behind the beneficial effects of dietary restriction in eukaryotic organisms.
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Date Issued
2019
PURL
http://purl.flvc.org/fau/fd/FA00013338
Subject Headings
Caenorhabditis elegans, Autophagy, Receptors, G-Protein-Coupled, Longevity, Diet
Format
Document (PDF)
Mitochondrial DNA damage in C. elegans sperm as a function sperm activity
Title
Mitochondrial DNA damage in C. elegans sperm as a function sperm activity.
Creator
Willis, Joel P., Florida Atlantic University, Volin, John C., LaMunyon, Craig W.
Abstract/Description
Several models for the evolution of maternal inheritance of mitochondria predict that the sperm mitochondria undergo oxidative damage and pose a threat to the developing embryo. Here, I test the hypothesis that the sperm are damaged by reactive oxygen species generated by aerobic sperm activity. In my first experiment, I found no significant difference in fecundity between worms fertilized by old versus young sperm, suggesting that the sperm nuclear genome is not affected by the extent of...
Show moreSeveral models for the evolution of maternal inheritance of mitochondria predict that the sperm mitochondria undergo oxidative damage and pose a threat to the developing embryo. Here, I test the hypothesis that the sperm are damaged by reactive oxygen species generated by aerobic sperm activity. In my first experiment, I found no significant difference in fecundity between worms fertilized by old versus young sperm, suggesting that the sperm nuclear genome is not affected by the extent of sperm activity. In my second experiment, I found that sperm mitochondrial DNA has deletions, indicating damage, but this damage does not accumulate with sperm activity. However, problems with PCR amplification resulted in little experimental data, preventing a conclusive test of the hypothesis.
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Date Issued
2003
PURL
http://purl.flvc.org/fcla/dt/13083
Subject Headings
Caenorhabditis elegans, Worms--Spermatozoa, Worms--Genetics
Format
Document (PDF)
GABAERGIC NEUROTRANSMISSION AND POTENTIAL RESCUE METHODS FROM CHEMOTHERAPY-INDUCED PERIPHERAL NEUROPATHIES IN C. ELEGANS
Title
GABAERGIC NEUROTRANSMISSION AND POTENTIAL RESCUE METHODS FROM CHEMOTHERAPY-INDUCED PERIPHERAL NEUROPATHIES IN C. ELEGANS.
Creator
Gonzalez-Lerma, Paola X., Dawson-Scully, Kenneth, Florida Atlantic University, Department of Biological Sciences, Charles E. Schmidt College of Science
Abstract/Description
Cancer is a leading cause of death in the U.S and across the world, with estimates indicating 17 million new cancer cases in 2018, 9.5 million of which resulted in death. Statistics show that in the past 20 years cancer death rates have decreased 27% due to emerging therapies. The use of chemotherapies to kill fast-growing cells in the body has become one of the most common cancer treatments in the world today. Chemotherapy-Induced Peripheral Neuropathies (CIPNs) are the most common side...
Show moreCancer is a leading cause of death in the U.S and across the world, with estimates indicating 17 million new cancer cases in 2018, 9.5 million of which resulted in death. Statistics show that in the past 20 years cancer death rates have decreased 27% due to emerging therapies. The use of chemotherapies to kill fast-growing cells in the body has become one of the most common cancer treatments in the world today. Chemotherapy-Induced Peripheral Neuropathies (CIPNs) are the most common side effects caused by chemotherapeutic agents. CIPNs have a prevalence of up to 85% in cancer patients undergoing chemotherapy. CIPNs triggered by chemotherapeutic drug use severely damage nerves branching from either the brain or spinal cord, initiating the development of acute and/or chronic symptoms. Platinum-based and taxane-based chemotherapeutics are among the most potent and versatile drugs available for combating cancer. The two of these drugs, carboplatin and docetaxel, are known to cause peripheral neuropathies and central neurotoxicity and were the focus of this project.
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Date Issued
2024
PURL
http://purl.flvc.org/fau/fd/FA00014450
Subject Headings
Peripheral Nervous System Diseases, Chemotherapy, Caenorhabditis elegans, Cancer
Format
Document (PDF)
Elucidation of a Glial Copper Homeostasis Pathway Regulated by the Caenorhabditis elegans Gene swip-10 with Implications for Systemic Metabolism and Neurodegenerative Disease
Title
Elucidation of a Glial Copper Homeostasis Pathway Regulated by the Caenorhabditis elegans Gene swip-10 with Implications for Systemic Metabolism and Neurodegenerative Disease.
Creator
Rodriguez, Peter Jr., Blakely, Randy D., Florida Atlantic University, Department of Biomedical Science, Charles E. Schmidt College of Medicine
Abstract/Description
Using the Caenorhabditis elegans as a model we have employed forward genetic screens to uncover several novel genetic contributors to dopamine (DA) signaling(1). Follow-up characterization of some of these novel contributors have been detailed in published work from our lab(2), while follow-up studies on other pathways are still underway. Moreover, using the powerful Million Mutation Project library, we have uncovered an important link between primary cilium formation and the regulation of...
Show moreUsing the Caenorhabditis elegans as a model we have employed forward genetic screens to uncover several novel genetic contributors to dopamine (DA) signaling(1). Follow-up characterization of some of these novel contributors have been detailed in published work from our lab(2), while follow-up studies on other pathways are still underway. Moreover, using the powerful Million Mutation Project library, we have uncovered an important link between primary cilium formation and the regulation of the DA transporter dat-1(3). The focus of the body of work detailed in this manuscript is on a glial expressed gene, swip-10, uncovered from our original genetic screen(1, 4, 5). Unlike the other pathways uncovered from our genetic screening, swip-10 does not affect DA signaling via DAT-1 regulation, instead, loss of swip-10 produces excess DA signaling in a glutamate-signaling-dependent manner to cause swimming-induced paralysis (Swip)(4) as well as premature DA neuron degeneration(5). Specifically, the primary aim here was to uncover the molecular pathway by which swip-10 supports these phenotypes.
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Date Issued
2024
PURL
http://purl.flvc.org/fau/fd/FA00014511
Subject Headings
Neurodegenerative Diseases, Glial cells, Caenorhabditis elegans, Copper, Homeostasis
Format
Document (PDF)
Functional Stress Resistance: The Role of Protein Kinase G in Modulating Neuronal Excitability in Caenorhabditis Elegans and Drosophila Melanogaster
Title
Functional Stress Resistance: The Role of Protein Kinase G in Modulating Neuronal Excitability in Caenorhabditis Elegans and Drosophila Melanogaster.
Creator
Kelly, Stephanie Suzanne, Dawson-Scully, Ken, Florida Atlantic University, Charles E. Schmidt College of Science, Department of Biological Sciences
Abstract/Description
Diseases such as epilepsy, pain, and neurodegenerative disorders are associated with changes in neuronal dysfunction due to an imbalance of excitation and inhibition. This work details a novel electroconvulsive seizure assay for C. elegans using the well characterized cholinergic and GABAergic excitation and inhibition of the body wall muscles and the resulting locomotion patterns to better understand neuronal excitability. The time to recover normal locomotion from an electroconvulsive...
Show moreDiseases such as epilepsy, pain, and neurodegenerative disorders are associated with changes in neuronal dysfunction due to an imbalance of excitation and inhibition. This work details a novel electroconvulsive seizure assay for C. elegans using the well characterized cholinergic and GABAergic excitation and inhibition of the body wall muscles and the resulting locomotion patterns to better understand neuronal excitability. The time to recover normal locomotion from an electroconvulsive seizure could be modulated by increasing and decreasing inhibition. GABAergic deficits and a chemical proconvulsant resulted in an increased recovery time while anti-epileptic drugs decreased seizure duration. Successful modulation of excitation and inhibition in the new assay led to the investigation of a cGMP-dependent protein kinase (PKG) which modulates potassium (K+) channels, affecting neuronal excitability, and determined that increasing PKG activity decreases the time to recovery from an electroconvulsive seizure. The new assay was used as a forward genetic screening tool using C. elegans and several potential genes that affect seizure susceptibility were found to take longer to recover from a seizure. A naturally occurring polymorphism for PKG in D. melanogaster confirmed that both genetic and pharmacological manipulation of PKG influences seizure duration. PKG has been implicated in stress tolerance, which can be affected by changes in neuronal excitability associated with aging, so stress tolerance and locomotor behavior in senescent flies was investigated. For the first time, PKG has been implicated in aging phenotypes with high levels of PKG resulting in reduced locomotion and lifespan in senescent flies. The results suggest a potential new role for PKG in seizure susceptibility and aging.
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Date Issued
2019
PURL
http://purl.flvc.org/fau/fd/FA00013225
Subject Headings
Caenorhabditis elegans, Drosophila melanogaster, Cyclic GMP-Dependent Protein Kinases, Seizures
Format
Document (PDF)
Autophagy gene atg-18 regulates C. elegans lifespan cell nonautonomously by neuropeptide signaling
Title
Autophagy gene atg-18 regulates C. elegans lifespan cell nonautonomously by neuropeptide signaling.
Creator
Minnerly, Justin, Jia, Kailiang, Florida Atlantic University, Charles E. Schmidt College of Science, Department of Biological Sciences
Abstract/Description
In the round worm C. elegans, it has recently been shown that autophagy, a highly conserved lysosomal degradation pathway that is present in all eukaryotic cells, is required for maintaining healthspan and for increasing the adult lifespan of worms fed under dietary restriction conditions or with reduced IGF signaling. It is currently unknown how extracellular signals regulate autophagy activity within different tissues during these processes and whether autophagy functions cell-autonomously...
Show moreIn the round worm C. elegans, it has recently been shown that autophagy, a highly conserved lysosomal degradation pathway that is present in all eukaryotic cells, is required for maintaining healthspan and for increasing the adult lifespan of worms fed under dietary restriction conditions or with reduced IGF signaling. It is currently unknown how extracellular signals regulate autophagy activity within different tissues during these processes and whether autophagy functions cell-autonomously or nonautonomously. We have data that for the first time shows autophagy activity in the neurons and intestinal cells plays a major role in regulating adult lifespan and the longevity conferred by altered IGF signaling and dietary restriction, suggesting autophagy can control these phenotypes cell non-autonomously. We hypothesize that autophagy in the neurons and intestinal cells is an essential cellular process regulated by different signaling pathways to control wild type adult lifespan, IGF mediated longevity and dietary restriction induced longevity. Excitingly we also have found that in animals with reduced IGF signaling autophagy can control longevity in only a small subset of neurons alone. Autophagy in either specific individual chemosensory neurons or a small group of them is completely sufficient to control IGF mediated longevity. This work provides novel insight to the function and regulation of autophagy which will help shed light on understanding this essential process in higher organisms, including mammals.
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Date Issued
2017
PURL
http://purl.flvc.org/fau/fd/FA00004862, http://purl.flvc.org/fau/fd/FA00004862
Subject Headings
Caenorhabditis elegans--Molecular genetics., Aging--Molecular aspects., Life cycles (Biology), Cell death., Gene expression., Autophagic vacuoles., Apoptosis., Eukaryotic cells.
Format
Document (PDF)
Analysis of the Role of Autophagy in Dauer Formation and Dauer Recovery Regulated by TGF-β Signaling Pathway in Caenorhabditis elegans
Title
Analysis of the Role of Autophagy in Dauer Formation and Dauer Recovery Regulated by TGF-β Signaling Pathway in Caenorhabditis elegans.
Creator
Ritter, Portia, Jia, Kailiang, Florida Atlantic University, Charles E. Schmidt College of Science, Department of Biological Sciences
Abstract/Description
Caenorhabditis elegans optionally enter into a dauer diapause phase that results in a prolonged life in a semi-dormant state. Entry into and recovery from dauer diapause includes many physical changes in body structure, physiology, and gene expression. Entry into dauer diapause is regulated by several signaling pathways including transforming growth factor (TGF-β). Autophagy plays an important role in dauer formation and recover. During dauer transformation autophagy is up-regulated and may...
Show moreCaenorhabditis elegans optionally enter into a dauer diapause phase that results in a prolonged life in a semi-dormant state. Entry into and recovery from dauer diapause includes many physical changes in body structure, physiology, and gene expression. Entry into dauer diapause is regulated by several signaling pathways including transforming growth factor (TGF-β). Autophagy plays an important role in dauer formation and recover. During dauer transformation autophagy is up-regulated and may play a role in remodeling the molecular structure for long term survival during dauer diapause. This research helps determine the role of autophagy in dauer development and recovery mediated through the TGF-β signaling pathway. This research also determines in which tissue autophagy is necessary for dauer formation and recovery through TGF-β signaling. This research is shedding light on the function of autophagy in the TGF-β signaling pathway, both processes of which have been linked to tumorigenesis, heart disease and cancer.
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Date Issued
2017
PURL
http://purl.flvc.org/fau/fd/FA00004921, http://purl.flvc.org/fau/fd/FA00004921
Subject Headings
Aging--Molecular aspects., Aging--Physiological aspects., Caenorhabditis elegans--Molecular genetics., Autophagic vacuoles., Gene expression., Apoptosis., Cellular signal transduction., DNA-binding proteins., Transforming growth factors-beta--Receptors.
Format
Document (PDF)