Your search keyword '"Samuelson AV"' showing total 19 results

1. The role of the antioxidant and longevity-promoting Nrf2 pathway in metabolic regulation.

Author

Sykiotis GP, Habeos IG, Samuelson AV, Bohmann D, Sykiotis, Gerasimos P, Habeos, Ioannis G, Samuelson, Andrew V, and Bohmann, Dirk

Published

2011

2. Den ryska "arkivrevolutionen.".

Author

Samuelson, Av Lennart and Sorokin, Andrej

Abstract

Presents a survey of the publication of primary source collections from Russian archives following the fall of the Soviet Union. The opening of the archives after 1991 has brought new material to light in a number of areas, including the Russian Civil War, the activities of the Soviet government, and social and cultural life inside the Soviet Union. The considerable breadth and depth of the published material and the research that is being done in Russian universities and colleges provides an answer to the frequently heard demand that "Russia must face its past.

Published

2007

3. The C. elegans Myc-family of transcription factors coordinate a dynamic adaptive response to dietary restriction.

Author

Cornwell AB, Zhang Y, Thondamal M, Johnson DW, Thakar J, and Samuelson AV

Subjects

Animals, Adaptation, Physiological genetics, Gene Expression Regulation, Receptors, Nicotinic, Trans-Activators, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism, Caloric Restriction, Longevity genetics, Longevity physiology, Transcription Factors genetics, Transcription Factors metabolism

Abstract

Dietary restriction (DR), the process of decreasing overall food consumption over an extended period of time, has been shown to increase longevity across evolutionarily diverse species and delay the onset of age-associated diseases in humans. In Caenorhabditis elegans, the Myc-family transcription factors (TFs) MXL-2 (Mlx) and MML-1 (MondoA/ChREBP), which function as obligate heterodimers, and PHA-4 (orthologous to FOXA) are both necessary for the full physiological benefits of DR. However, the adaptive transcriptional response to DR and the role of MML-1::MXL-2 and PHA-4 remains elusive. We identified the transcriptional signature of C. elegans DR, using the eat-2 genetic model, and demonstrate broad changes in metabolic gene expression in eat-2 DR animals, which requires both mxl-2 and pha-4. While the requirement for these factors in DR gene expression overlaps, we found many of the DR genes exhibit an opposing change in relative gene expression in eat-2;mxl-2 animals compared to wild-type, which was not observed in eat-2 animals with pha-4 loss. Surprisingly, we discovered more than 2000 genes synthetically dysregulated in eat-2;mxl-2, out of which the promoters of down-regulated genes were substantially enriched for PQM-1 and ELT-1/3 GATA TF binding motifs. We further show functional deficiencies of the mxl-2 loss in DR outside of lifespan, as eat-2;mxl-2 animals exhibit substantially smaller brood sizes and lay a proportion of dead eggs, indicating that MML-1::MXL-2 has a role in maintaining the balance between resource allocation to the soma and to reproduction under conditions of chronic food scarcity. While eat-2 animals do not show a significantly different metabolic rate compared to wild-type, we also find that loss of mxl-2 in DR does not affect the rate of oxygen consumption in young animals. The gene expression signature of eat-2 mutant animals is consistent with optimization of energy utilization and resource allocation, rather than induction of canonical gene expression changes associated with acute metabolic stress, such as induction of autophagy after TORC1 inhibition. Consistently, eat-2 animals are not substantially resistant to stress, providing further support to the idea that chronic DR may benefit healthspan and lifespan through efficient use of limited resources rather than broad upregulation of stress responses, and also indicates that MML-1::MXL-2 and PHA-4 may have distinct roles in promotion of benefits in response to different pro-longevity stimuli., (© 2024. The Author(s), under exclusive licence to American Aging Association.)

Published

2024

4. The C. elegans Myc-family of transcription factors coordinate a dynamic adaptive response to dietary restriction.

Author

Cornwell A, Zhang Y, Thondamal M, Johnson DW, Thakar J, and Samuelson AV

Abstract

Dietary restriction (DR), the process of decreasing overall food consumption over an extended period of time, has been shown to increase longevity across evolutionarily diverse species and delay the onset of age-associated diseases in humans. In Caenorhabditis elegans , the Myc-family transcription factors (TFs) MXL-2 (Mlx) and MML-1 (MondoA/ChREBP), which function as obligate heterodimers, and PHA-4 (orthologous to forkhead box transcription factor A) are both necessary for the full physiological benefits of DR. However, the adaptive transcriptional response to DR and the role of MML-1::MXL-2 and PHA-4 remains elusive. We identified the transcriptional signature of C. elegans DR, using the eat-2 genetic model, and demonstrate broad changes in metabolic gene expression in eat-2 DR animals, which requires both mxl-2 and pha-4 . While the requirement for these factors in DR gene expression overlaps, we found many of the DR genes exhibit an opposing change in relative gene expression in eat-2;mxl-2 animals compared to wild-type, which was not observed in eat-2 animals with pha-4 loss. We further show functional deficiencies of the mxl-2 loss in DR outside of lifespan, as eat-2;mxl-2 animals exhibit substantially smaller brood sizes and lay a proportion of dead eggs, indicating that MML-1::MXL-2 has a role in maintaining the balance between resource allocation to the soma and to reproduction under conditions of chronic food scarcity. While eat-2 animals do not show a significantly different metabolic rate compared to wild-type, we also find that loss of mxl-2 in DR does not affect the rate of oxygen consumption in young animals. The gene expression signature of eat-2 mutant animals is consistent with optimization of energy utilization and resource allocation, rather than induction of canonical gene expression changes associated with acute metabolic stress -such as induction of autophagy after TORC1 inhibition. Consistently, eat-2 animals are not substantially resistant to stress, providing further support to the idea that chronic DR may benefit healthspan and lifespan through efficient use of limited resources rather than broad upregulation of stress responses, and also indicates that MML-1::MXL-2 and PHA-4 may have different roles in promotion of benefits in response to different pro-longevity stimuli.

Published

2023

5. Homeodomain-interacting protein kinase maintains neuronal homeostasis during normal Caenorhabditis elegans aging and systemically regulates longevity from serotonergic and GABAergic neurons.

Author

Lazaro-Pena MI, Cornwell AB, Diaz-Balzac CA, Das R, Ward ZC, Macoretta N, Thakar J, and Samuelson AV

Subjects

Animals, Caenorhabditis elegans physiology, Protein Kinases metabolism, Homeodomain Proteins metabolism, Gene Expression Regulation, Aging genetics, Homeostasis, GABAergic Neurons metabolism, Longevity genetics, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism

Abstract

Aging and the age-associated decline of the proteome is determined in part through neuronal control of evolutionarily conserved transcriptional effectors, which safeguard homeostasis under fluctuating metabolic and stress conditions by regulating an expansive proteostatic network. We have discovered the Caenorhabditis elegans homeodomain-interacting protein kinase (HPK-1) acts as a key transcriptional effector to preserve neuronal integrity, function, and proteostasis during aging. Loss of hpk-1 results in drastic dysregulation in expression of neuronal genes, including genes associated with neuronal aging. During normal aging hpk-1 expression increases throughout the nervous system more broadly than any other kinase. Within the aging nervous system, hpk-1 induction overlaps with key longevity transcription factors , which suggests that hpk-1 expression mitigates natural age-associated physiological decline. Consistently, pan-neuronal overexpression of hpk-1 extends longevity, preserves proteostasis both within and outside of the nervous system, and improves stress resistance. Neuronal HPK-1 improves proteostasis through kinase activity. HPK-1 functions cell non-autonomously within serotonergic and γ-aminobutyric acid (GABA)ergic neurons to improve proteostasis in distal tissues by specifically regulating distinct components of the proteostatic network. Increased serotonergic HPK-1 enhances the heat shock response and survival to acute stress. In contrast, GABAergic HPK-1 induces basal autophagy and extends longevity, which requires mxl-2 (MLX), hlh-30 (TFEB), and daf-16 (FOXO). Our work establishes hpk-1 as a key neuronal transcriptional regulator critical for preservation of neuronal function during aging. Further, these data provide novel insight as to how the nervous system partitions acute and chronic adaptive response pathways to delay aging by maintaining organismal homeostasis., Competing Interests: ML, AC, CD, RD, ZW, NM, JT, AS No competing interests declared, (© 2023, Lazaro-Pena et al.)

Published

2023

6. HSF-1: Guardian of the Proteome Through Integration of Longevity Signals to the Proteostatic Network.

Author

Lazaro-Pena MI, Ward ZC, Yang S, Strohm A, Merrill AK, Soto CA, and Samuelson AV

Abstract

Discoveries made in the nematode Caenorhabditis elegans revealed that aging is under genetic control. Since these transformative initial studies, C. elegans has become a premier model system for aging research. Critically, the genes, pathways, and processes that have fundamental roles in organismal aging are deeply conserved throughout evolution. This conservation has led to a wealth of knowledge regarding both the processes that influence aging and the identification of molecular and cellular hallmarks that play a causative role in the physiological decline of organisms. One key feature of age-associated decline is the failure of mechanisms that maintain proper function of the proteome (proteostasis). Here we highlight components of the proteostatic network that act to maintain the proteome and how this network integrates into major longevity signaling pathways. We focus in depth on the heat shock transcription factor 1 (HSF1), the central regulator of gene expression for proteins that maintain the cytosolic and nuclear proteomes, and a key effector of longevity signals., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Lazaro-Pena, Ward, Yang, Strohm, Merrill, Soto and Samuelson.)

Published

2022

7. The Replica Set Method is a Robust, Accurate, and High-Throughput Approach for Assessing and Comparing Lifespan in C. elegans Experiments.

Author

Cornwell A, Llop JR, Salzman P, Rasmussen N, Thakar J, and Samuelson AV

Abstract

The advent of feeding based RNAi in Caenorhabditis elegans led to an era of gene discovery in aging research. Hundreds of gerogenes were discovered, and many are evolutionarily conserved, raising the exciting possibility that the underlying genetic basis for healthy aging in higher vertebrates could be quickly deciphered. Yet, the majority of putative gerogenes have still only been cursorily characterized, highlighting the need for high-throughput, quantitative assessments of changes in aging. A widely used surrogate measure of aging is lifespan. The traditional way to measure mortality in C. elegans tracks the deaths of individual animals over time within a relatively small population. This traditional method provides straightforward, direct measurements of median and maximum lifespan for the sampled population. However, this method is time consuming, often underpowered, and involves repeated handling of a set of animals over time, which in turn can introduce contamination or possibly damage increasingly fragile, aged animals. We have previously developed an alternative "Replica Set" methodology, which minimizes handling and increases throughput by at least an order of magnitude. The Replica Set method allows changes in lifespan to be measured for over one hundred feeding-based RNAi clones by one investigator in a single experiment- facilitating the generation of large quantitative phenotypic datasets, a prerequisite for development of biological models at a systems level. Here, we demonstrate through analysis of lifespan experiments simulated in silico that the Replica Set method is at least as precise and accurate as the traditional method in evaluating and estimating lifespan, and requires many fewer total animal observations across the course of an experiment. Furthermore, we show that the traditional approach to lifespan experiments is more vulnerable than the Replica Set method to experimental and measurement error. We find no compromise in statistical power for Replica Set experiments, even for moderate effect sizes, or when simulated experimental errors are introduced. We compare and contrast the statistical analysis of data generated by the two approaches, and highlight pitfalls common with the traditional methodology. Collectively, our analysis provides a standard of measure for each method across comparable parameters, which will be invaluable in both experimental design and evaluation of published data for lifespan studies., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Cornwell, Llop, Salzman, Rasmussen, Thakar and Samuelson.)

Published

2022

8. Quantifying Tissue-Specific Proteostatic Decline in Caenorhabditis elegans.

Author

Lazaro-Pena MI, Cornwell AB, and Samuelson AV

Subjects

Animals, Huntingtin Protein, Longevity, Proteome, Proteostasis, Caenorhabditis elegans genetics, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins metabolism

Abstract

The ability to maintain proper function and folding of the proteome (protein homeostasis) declines during normal aging, facilitating the onset of a growing number of age-associated diseases. For instance, proteins with polyglutamine expansions are prone to aggregation, as exemplified with the huntingtin protein and concomitant onset of Huntington's disease. The age-associated deterioration of the proteome has been widely studied through the use of transgenic Caenorhabditis elegans expressing polyQ repeats fused to a yellow fluorescent protein (YFP). This polyQ::YFP transgenic animal model facilitates the direct quantification of the age-associated decline of the proteome through imaging the progressive formation of fluorescent foci (i.e., protein aggregates) and subsequent onset of locomotion defects that develop as a result of the collapse of the proteome. Further, the expression of the polyQ::YFP transgene can be driven by tissue-specific promoters, allowing the assessment of proteostasis across tissues in the context of an intact multicellular organism. This model is highly amenable to genetic analysis, thus providing an approach to quantify aging that is complementary to lifespan assays. We describe how to accurately measure polyQ::YFP foci formation within either neurons or body wall muscle during aging, and the subsequent onset of behavioral defects. Next, we highlight how these approaches can be adapted for higher throughput, and potential future applications using other emerging strategies for C. elegans genetic analysis.

Published

2021

9. Analysis of Lifespan in C. elegans: Low- and High-Throughput Approaches.

Author

Cornwell AB and Samuelson AV

Subjects

Animals, Caenorhabditis elegans growth & development, Aging genetics, Biological Assay methods, Caenorhabditis elegans genetics, Longevity genetics

Abstract

Lifespan is the most straightforward surrogate measure of aging, as it is easily quantifiable. A common approach to measure Caenorhabditis elegans lifespan is to follow a population of animals over time and score viability based on movement. We previously developed an alternative approach, called the Replica Set method, to quantitatively measure lifespan of C. elegans in a high-throughput manner. The replica set method allows a single investigator to screen more treatments or conditions in the same amount of time without loss of data quality. The method requires common equipment found in most laboratories working with C. elegans and is thus simple to adopt. Unlike traditional approaches, the Replica Set method centers on assaying independent samples of a population at each observation point, rather than a single sample over time as with "traditional" longitudinal methods. The protocols provided here describe both the traditional experimental approach and the Replica Set method, as well as practical considerations for each.

Published

2020

10. The Replica Set Method: A High-throughput Approach to Quantitatively Measure Caenorhabditis elegans Lifespan.

Author

Cornwell AB, Llop JR, Salzman P, Thakar J, and Samuelson AV

Subjects

Aging, Animals, Evaluation Studies as Topic, Survival Analysis, Biological Assay methods, Caenorhabditis elegans chemistry

Abstract

The Replica Set method is an approach to quantitatively measure lifespan or survival of Caenorhabditis elegans nematodes in a high-throughput manner, thus allowing a single investigator to screen more treatments or conditions over the same amount of time without loss of data quality. The method requires common equipment found in most laboratories working with C. elegans and is thus simple to adopt. The approach centers on assaying independent samples of a population at each observation point, rather than a single sample over time as with traditional longitudinal methods. Scoring entails adding liquid to the wells of a multi-well plate, which stimulates C. elegans to move and facilitates quantifying changes in healthspan. Other major benefits of the Replica Set method include reduced exposure of agar surfaces to airborne contaminants (e.g. mold or fungus), minimal handling of animals, and robustness to sporadic mis-scoring (such as calling an animal as dead when it is still alive). To appropriately analyze and visualize the data from a Replica Set style experiment, a custom software tool was also developed. Current capabilities of the software include plotting of survival curves for both Replica Set and traditional (Kaplan-Meier) experiments, as well as statistical analysis for Replica Set. The protocols provided here describe the traditional experimental approach and the Replica Set method, as well as an overview of the corresponding data analysis.

Published

2018

11. The homeodomain-interacting protein kinase HPK-1 preserves protein homeostasis and longevity through master regulatory control of the HSF-1 chaperone network and TORC1-restricted autophagy in Caenorhabditis elegans.

Author

Das R, Melo JA, Thondamal M, Morton EA, Cornwell AB, Crick B, Kim JH, Swartz EW, Lamitina T, Douglas PM, and Samuelson AV

Subjects

Aging pathology, Animals, Autophagy genetics, Caenorhabditis elegans, Gene Expression Regulation, Homeostasis, Mechanistic Target of Rapamycin Complex 1, Molecular Chaperones genetics, Protein Processing, Post-Translational, Signal Transduction genetics, Stress, Physiological genetics, Aging genetics, Caenorhabditis elegans Proteins genetics, Longevity genetics, Multiprotein Complexes genetics, Protein Serine-Threonine Kinases genetics, TOR Serine-Threonine Kinases genetics, Transcription Factors genetics

Abstract

An extensive proteostatic network comprised of molecular chaperones and protein clearance mechanisms functions collectively to preserve the integrity and resiliency of the proteome. The efficacy of this network deteriorates during aging, coinciding with many clinical manifestations, including protein aggregation diseases of the nervous system. A decline in proteostasis can be delayed through the activation of cytoprotective transcriptional responses, which are sensitive to environmental stress and internal metabolic and physiological cues. The homeodomain-interacting protein kinase (hipk) family members are conserved transcriptional co-factors that have been implicated in both genotoxic and metabolic stress responses from yeast to mammals. We demonstrate that constitutive expression of the sole Caenorhabditis elegans Hipk homolog, hpk-1, is sufficient to delay aging, preserve proteostasis, and promote stress resistance, while loss of hpk-1 is deleterious to these phenotypes. We show that HPK-1 preserves proteostasis and extends longevity through distinct but complementary genetic pathways defined by the heat shock transcription factor (HSF-1), and the target of rapamycin complex 1 (TORC1). We demonstrate that HPK-1 antagonizes sumoylation of HSF-1, a post-translational modification associated with reduced transcriptional activity in mammals. We show that inhibition of sumoylation by RNAi enhances HSF-1-dependent transcriptional induction of chaperones in response to heat shock. We find that hpk-1 is required for HSF-1 to induce molecular chaperones after thermal stress and enhances hormetic extension of longevity. We also show that HPK-1 is required in conjunction with HSF-1 for maintenance of proteostasis in the absence of thermal stress, protecting against the formation of polyglutamine (Q35::YFP) protein aggregates and associated locomotory toxicity. These functions of HPK-1/HSF-1 undergo rapid down-regulation once animals reach reproductive maturity. We show that HPK-1 fortifies proteostasis and extends longevity by an additional independent mechanism: induction of autophagy. HPK-1 is necessary for induction of autophagosome formation and autophagy gene expression in response to dietary restriction (DR) or inactivation of TORC1. The autophagy-stimulating transcription factors pha-4/FoxA and mxl-2/Mlx, but not hlh-30/TFEB or the nuclear hormone receptor nhr-62, are necessary for extended longevity resulting from HPK-1 overexpression. HPK-1 expression is itself induced by transcriptional mechanisms after nutritional stress, and post-transcriptional mechanisms in response to thermal stress. Collectively our results position HPK-1 at a central regulatory node upstream of the greater proteostatic network, acting at the transcriptional level by promoting protein folding via chaperone expression, and protein turnover via expression of autophagy genes. HPK-1 therefore provides a promising intervention point for pharmacological agents targeting the protein homeostasis system as a means of preserving robust longevity.

Published

2017

12. Autolysosome biogenesis and developmental senescence are regulated by both Spns1 and v-ATPase.

Author

Sasaki T, Lian S, Khan A, Llop JR, Samuelson AV, Chen W, Klionsky DJ, and Kishi S

Subjects

Animals, Base Sequence, Biomarkers metabolism, CRISPR-Cas Systems genetics, Embryo, Nonmammalian cytology, Embryo, Nonmammalian metabolism, Gene Expression Regulation, Developmental, Gene Knockdown Techniques, Longevity, Membrane Fusion, Phagosomes metabolism, Survival Analysis, Zebrafish genetics, Autophagy, Cellular Senescence, Lysosomes metabolism, Membrane Proteins metabolism, Proton-Translocating ATPases metabolism, Vacuolar Proton-Translocating ATPases metabolism, Zebrafish embryology, Zebrafish Proteins metabolism

Abstract

Spns1 (Spinster homolog 1 [Drosophila]) in vertebrates, as well as Spin (Spinster) in Drosophila, is a hypothetical lysosomal H + -carbohydrate transporter, which functions at a late stage of macroautophagy (hereafter autophagy). The Spin/Spns1 defect induces aberrant autolysosome formation that leads to developmental senescence in the embryonic stage and premature aging symptoms in adulthood. However, the molecular mechanism by which loss of Spin/Spns1 leads to the specific pathogenesis remains to be elucidated. Using chemical, genetic and CRISPR/Cas9-mediated genome-editing approaches in zebrafish, we investigated and determined a mechanism that suppresses embryonic senescence as well as autolysosomal impairment mediated by Spns1 deficiency. Unexpectedly, we found that a concurrent disruption of the vacuolar-type H + -ATPase (v-ATPase) subunit gene, atp6v0ca (ATPase, H + transporting, lysosomal, V0 subunit ca) led to suppression of the senescence induced by the Spns1 defect, whereas the sole loss of Atp6v0ca led to senescent embryos similar to the single spns1 mutation. Moreover, we discovered that the combined stable defect seen in the presence of both the spns1 and atp6v0ca mutant genes still subsequently induced premature autophagosome-lysosome fusion marked by insufficient acidity, while extending developmental life span, compared with the solely mutated spns1 defect. Our data suggest that Spns1 and the v-ATPase orchestrate proper autolysosomal biogenesis with optimal acidification that is critically linked to developmental senescence and survival.

Published

2017

13. The Caenorhabditis elegans Myc-Mondo/Mad complexes integrate diverse longevity signals.

Author

Johnson DW, Llop JR, Farrell SF, Yuan J, Stolzenburg LR, and Samuelson AV

Subjects

Animals, Gene Expression Regulation genetics, Insulin-Like Growth Factor I genetics, Signal Transduction genetics, Transcriptional Activation genetics, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, DNA-Binding Proteins genetics, Longevity genetics, Trans-Activators genetics

Abstract

The Myc family of transcription factors regulates a variety of biological processes, including the cell cycle, growth, proliferation, metabolism, and apoptosis. In Caenorhabditis elegans, the "Myc interaction network" consists of two opposing heterodimeric complexes with antagonistic functions in transcriptional control: the Myc-Mondo:Mlx transcriptional activation complex and the Mad:Max transcriptional repression complex. In C. elegans, Mondo, Mlx, Mad, and Max are encoded by mml-1, mxl-2, mdl-1, and mxl-1, respectively. Here we show a similar antagonistic role for the C. elegans Myc-Mondo and Mad complexes in longevity control. Loss of mml-1 or mxl-2 shortens C. elegans lifespan. In contrast, loss of mdl-1 or mxl-1 increases longevity, dependent upon MML-1:MXL-2. The MML-1:MXL-2 and MDL-1:MXL-1 complexes function in both the insulin signaling and dietary restriction pathways. Furthermore, decreased insulin-like/IGF-1 signaling (ILS) or conditions of dietary restriction increase the accumulation of MML-1, consistent with the notion that the Myc family members function as sensors of metabolic status. Additionally, we find that Myc family members are regulated by distinct mechanisms, which would allow for integrated control of gene expression from diverse signals of metabolic status. We compared putative target genes based on ChIP-sequencing data in the modENCODE project and found significant overlap in genomic DNA binding between the major effectors of ILS (DAF-16/FoxO), DR (PHA-4/FoxA), and Myc family (MDL-1/Mad/Mxd) at common target genes, which suggests that diverse signals of metabolic status converge on overlapping transcriptional programs that influence aging. Consistent with this, there is over-enrichment at these common targets for genes that function in lifespan, stress response, and carbohydrate metabolism. Additionally, we find that Myc family members are also involved in stress response and the maintenance of protein homeostasis. Collectively, these findings indicate that Myc family members integrate diverse signals of metabolic status, to coordinate overlapping metabolic and cytoprotective transcriptional programs that determine the progression of aging.

Published

2014

14. Adenovirus E1A targets p400 to induce the cellular oncoprotein Myc.

Author

Tworkowski KA, Chakraborty AA, Samuelson AV, Seger YR, Narita M, Hannon GJ, Lowe SW, and Tansey WP

Subjects

Adenovirus E1A Proteins genetics, Cell Line, Chromatin Immunoprecipitation, Humans, Proto-Oncogene Proteins c-myc genetics, Adenovirus E1A Proteins metabolism, Cell Transformation, Viral, DNA Helicases metabolism, DNA-Binding Proteins metabolism, Proto-Oncogene Proteins c-myc metabolism

Abstract

Adenovirus E1A drives oncogenesis by targeting key regulatory pathways that are critical for cellular growth control. The interaction of E1A with p400 is essential for many E1A activities, but the downstream target of this interaction is unknown. Here, we present evidence that the oncoprotein transcription factor Myc is the target of this interaction. We show that E1A stabilizes Myc protein via p400 and promotes the coassociation of Myc and p400 at Myc target genes, leading to their transcriptional induction. We also show that E1A requires Myc for its ability to activate Myc-dependent gene expression and induce apoptosis, and that forced expression of Myc is sufficient to rescue the activity of an E1A-mutant defective in p400 binding. Together, these findings establish that Myc, via p400, is an essential downstream target of E1A.

Published

2008

15. Gene activities that mediate increased life span of C. elegans insulin-like signaling mutants.

Author

Samuelson AV, Carr CE, and Ruvkun G

Subjects

Animals, Caenorhabditis elegans Proteins genetics, Forkhead Transcription Factors, Gene Silencing, Genes, Reporter, Green Fluorescent Proteins metabolism, RNA Interference, Receptor, Insulin genetics, Superoxide Dismutase genetics, Transcription Factors genetics, Caenorhabditis elegans physiology, Genes, Helminth, Insulin-Like Growth Factor I genetics, Mutation, Signal Transduction physiology

Abstract

Genetic and RNA interference (RNAi) screens for life span regulatory genes have revealed that the daf-2 insulin-like signaling pathway plays a major role in Caenorhabditis elegans longevity. This pathway converges on the DAF-16 transcription factor and may regulate life span by controlling the expression of a large number of genes, including free-radical detoxifying genes, stress resistance genes, and pathogen resistance genes. We conducted a genome-wide RNAi screen to identify genes necessary for the extended life span of daf-2 mutants and identified approximately 200 gene inactivations that shorten daf-2 life span. Some of these gene inactivations dramatically shorten daf-2 mutant life span but less dramatically shorten daf-2; daf-16 mutant or wild-type life span. Molecular and behavioral markers for normal aging and for extended life span in low insulin/IGF1 (insulin-like growth factor 1) signaling were assayed to distinguish accelerated aging from general sickness and to examine age-related phenotypes. Detailed demographic analysis, molecular markers of aging, and insulin signaling mutant test strains were used to filter progeric gene inactivations for specific acceleration of aging. Highly represented in the genes that mediate life span extension in the daf-2 mutant are components of endocytotic trafficking of membrane proteins to lysosomes. These gene inactivations disrupt the increased expression of the DAF-16 downstream gene superoxide dismutase sod-3 in a daf-2 mutant, suggesting trafficking between the insulin-like receptor and DAF-16. The activities of these genes may normally decline during aging.

Published

2007

16. Identification of Caenorhabditis elegans genes regulating longevity using enhanced RNAi-sensitive strains.

Author

Samuelson AV, Klimczak RR, Thompson DB, Carr CE, and Ruvkun G

Subjects

Aging genetics, Animals, Caenorhabditis elegans drug effects, Caenorhabditis elegans physiology, Caenorhabditis elegans Proteins genetics, Caenorhabditis elegans Proteins physiology, Drug Resistance genetics, Heat-Shock Response genetics, Mutation, Paraquat toxicity, Pigmentation genetics, RNA Interference, Receptor, Insulin genetics, Receptor, Insulin physiology, Caenorhabditis elegans genetics, Caenorhabditis elegans growth & development, Genes, Helminth, Longevity genetics

Abstract

A systematic genome-wide RNA interference screen was performed in the Caenorhabditis elegans lin-15b;eri-1 strain, which has an enhanced response to double-stranded RNA including the nervous system, to identify life-span regulatory factors. In total, 16,757 genes were examined, revealing 115 gene inactivations that extended life span. A more stringent longitudinal analysis revealed 18 gene inactivations that induced the greatest increase in life span (10-90%), all of which extended life span when inactivated either in eri-1 alone or in a second strain with an enhanced response to double-stranded RNA, eri-3. Most reduced the rate of aging, implying that animals aged more slowly. As was the case in previous studies, genes critical for metabolism caused the greatest extension of longevity. Extension of life span occurs through disparate mechanisms as increased resistance to thermal stress, oxidative damage, and decreased age pigment accumulation analysis of the 18 stronger positives failed to demonstrate a correlation between enhanced stress resistance and decreased lysosomal function. Consistently, aps-3 and lys-10, two genes annotated to have lysosomal functions, extended life span when inactivated without enhancing stress resistance. The results of this study reinforce the importance of metabolism, mitochondrial and lysosomal functions, genomic stability, and stress resistance on animal life-span determination.

Published

2007

17. p400 is required for E1A to promote apoptosis.

Author

Samuelson AV, Narita M, Chan HM, Jin J, de Stanchina E, McCurrach ME, Narita M, Fuchs M, Livingston DM, and Lowe SW

Subjects

ADP-Ribosylation Factors metabolism, Adenovirus E1A Proteins metabolism, Animals, Binding Sites, Blotting, Northern, Blotting, Western, Cell Line, Cell Survival, Chromatin metabolism, DNA Helicases metabolism, DNA-Binding Proteins metabolism, Dose-Response Relationship, Drug, Doxorubicin pharmacology, E1A-Associated p300 Protein, Fibroblasts metabolism, Gene Deletion, Gene Transfer Techniques, Genetic Vectors, Humans, Immunoblotting, Immunoprecipitation, Mice, Microscopy, Fluorescence, Mutation, Nuclear Proteins metabolism, Protein Binding, Protein Structure, Tertiary, RNA Interference, Retinoblastoma Protein metabolism, Retroviridae genetics, Structure-Activity Relationship, Trans-Activators metabolism, Transcriptional Activation, Tumor Suppressor Protein p53 metabolism, Adenovirus E1A Proteins physiology, Apoptosis, DNA Helicases physiology, DNA-Binding Proteins physiology, Gene Expression Regulation

Abstract

The adenovirus E1A oncoprotein promotes proliferation and transformation by binding cellular proteins, including members of the retinoblastoma protein family, the p300/CREB-binding protein transcriptional coactivators, and the p400-TRRAP chromatin-remodeling complex. E1A also promotes apoptosis, in part, by engaging the ARF-p53 tumor suppressor pathway. We show that E1A induces ARF and p53 and promotes apoptosis in normal fibroblasts by physically associating with the retinoblastoma protein and a p400-TRRAP complex and that its interaction with p300 is largely dispensable for these effects. We further show that E1A increases p400 expression and, conversely, that suppression of p400 using stable RNA interference reduces the levels of ARF, p53, and apoptosis in E1A-expressing cells. Therefore, whereas E1A inactivates the retinoblastoma protein, it requires p400 to efficiently promote cell death. These results identify p400 as a regulator of the ARF-p53 pathway and a component of the cellular machinery that couples proliferation to cell death.

Published

2005

18. E1A signaling to p53 involves the p19(ARF) tumor suppressor.

Author

de Stanchina E, McCurrach ME, Zindy F, Shieh SY, Ferbeyre G, Samuelson AV, Prives C, Roussel MF, Sherr CJ, and Lowe SW

Subjects

Animals, Apoptosis genetics, Cell Division genetics, Cells, Cultured, DNA Damage, Gene Expression Regulation, Mice, Mice, Knockout, Signal Transduction, Tumor Suppressor Protein p14ARF, Adenovirus E1A Proteins genetics, Genes, Tumor Suppressor, Genes, Viral, Genes, p53, Proteins genetics

Abstract

The adenovirus E1A oncogene activates p53 through a signaling pathway involving the retinoblastoma protein and the tumor suppressor p19(ARF). The ability of E1A to induce p53 and its transcriptional targets is severely compromised in ARF-null cells, which remain resistant to apoptosis following serum depletion or adriamycin treatment. Reintroduction of p19(ARF) restores p53 accumulation and resensitizes ARF-null cells to apoptotic signals. Therefore, p19(ARF) functions as part of a p53-dependent failsafe mechanism to counter uncontrolled proliferation. Synergistic effects between the p19(ARF) and DNA damage pathways in inducing p53 may contribute to E1A's ability to enhance radio- and chemosensitivity.

Published

1998

19. Selective induction of p53 and chemosensitivity in RB-deficient cells by E1A mutants unable to bind the RB-related proteins.

Author

Samuelson AV and Lowe SW

Subjects

Animals, Antibiotics, Antineoplastic pharmacology, Doxorubicin pharmacology, Drug Resistance, Humans, Mice, Protein Binding, Adenovirus E1A Proteins genetics, Apoptosis genetics, Mutation, Retinoblastoma Protein metabolism, Tumor Suppressor Protein p53 biosynthesis

Abstract

The adenovirus E1A oncoprotein renders primary cells sensitive to the induction of apoptosis by diverse stimuli, including many anticancer agents. E1A-expressing cells accumulate p53 protein, and p53 potentiates drug-induced apoptosis. To determine how E1A promotes chemosensitivity, a series of E1A mutants were introduced into primary human and mouse fibroblasts using high-titer recombinant retroviruses, allowing analysis of E1A in genetically normal cells outside the context of adenovirus infection. Mutations that disrupted apoptosis and chemosensitivity separated into two complementation groups, which correlated precisely with the ability of E1A to associate with either the p300/CBP or retinoblastoma protein families. Furthermore, E1A mutants incapable of binding RB, p107, and p130 conferred chemosensitivity to fibroblasts derived from RB-deficient mice, but not fibroblasts from mice lacking p107 or p130. Hence, inactivation of RB, but not p107 or p130, is required for chemosensitivity induced by E1A. Finally, the same E1A functions that promote drug-induced apoptosis also induce p53. Together, these data demonstrate that p53 accumulation and chemosensitivity are linked to E1A's oncogenic potential, and identify a strategy to selectively induce apoptosis in RB-deficient tumor cells.

Published

1997