Coleen Murphy Position James A. Elkins, Jr. Professor in the Life Sciences, Professor, Molecular Biology and the Lewis-Sigler Institute for Integrative Genomics Role Director of Lewis-Sigler Institute, Director of Paul F. Glenn Laboratories For Aging Research, Director of Simons Foundation's Collaboration on Plasticity in the Aging Brain (SCPAB) CV Coleen Murphy CV Office Phone 609-258-9396 Email [email protected] Assistant Laura Hoffman Office 140 Carl Icahn Laboratory Bio/Description Research FocusMolecular mechanisms of agingMy lab is focused on the process of aging, which remains one of the fundamental mysteries of biology. While aging may appear to be simply an unfortunate consequence of living, recent genetic breakthroughs suggest that aging is a regulated process, rather than the result of cumulative cellular damage. Many chronic and degenerative disorders, such as diabetes, cancer, and neurodegenerative diseases develop in an age-related manner. Because more than 20% of U.S. citizens will be over the age of 65 by the year 2050, there is a growing need to better understand the mechanisms involved in aging and age-associated diseases.The emergence of model systems to study aging and the development of whole-genome approaches is providing an unprecedented glimpse into the processes underlying aging. Our understanding of aging at the molecular level will progress from identifying these global regulators, to defining the genes that they control, to describing the biochemical events that carry out the business of keeping an organism's cells alive. The goal of my lab is to enrich our understanding of the molecular basis of aging process by first identifying the genes that are controlled by these global regulators and then elucidating the cell biological and biochemical mechanisms used by these genes to affect lifespan.A model for aging: C. elegansWe have chosen the nematode C. elegans as our model system of aging. For our purposes C. elegans is ideal because lives two-three weeks, making lifespan experiments feasible, and during this time it exhibits many obvious phenotypes of aging, such as slowed motility and tissue deterioration. Importantly, C. elegans mutants with dramatically extended longevity have been identified; the genetic dissection of the pathways contributing to these mutants' longevity can shed light on the mechanisms of aging. The genes that regulate lifespan are conserved from worms to mammals, making our findings relevant for humans, as well.Transcriptional analysis of longevity pathwaysThe initial work in my lab will use microarray techniques to identify transcriptional targets of longevity pathways. For this purpose, we have built both PCR product arrays and 60-mer oligo arrays for the almost 20,000 open reading frames in C. elegans. My previous work identified the genes that act downstream of the C. elegans insulin receptor/FOXO transcription factor pathway, and found that this pathway is likely to be regulated through a feed-forward mechanism; now we would like to determine when the target genes are expressed and distinguish direct from indirect targets. Because downregulation of the insulin receptor pathway is only one of the mechanisms that increase the longevity of C. elegans, we will also use microarrays and genomic analysis to discover transcriptional targets that are shared between multiple longevity pathways.Functional analysis of candidate lifespan genesOnce the targets have been identified, we can use the extremely tractable C. elegans experimental system to test these genes for their roles in longevity. For example, C. elegans is susceptible to RNA interference by bacterial feeding, allowing us to quickly knock down gene activity and test the requirement for that gene in lifespan extension. Now that we know which genes act downstream of the insulin receptor/FOXO pathway to affect lifespan, we would like to identify the sites of action of these genes in the worm. Using fluorescent gene fusions, we can identify the localization and time of expression of specific proteins in the animal to better understand the gene's organismal role. Finally, in vitro studies will be carried out on the most interesting candidate genes to understand their biochemical functions.Additionally, my lab will carry out genetic screens to identify novel genes that are critical to aging-related processes. The combination of a classic genetic system that recapitulates aging in higher organisms with powerful genomic approaches and fast functional analysis should help us to elucidate the multigenic mechanisms involved in aging.Complete list of PublicationsGoogle Scholar Selected Publications Lakhina, Vanisha, and Coleen T Murphy. (2015) 2015. “For Longevity, Perception Is Everything.”. Cell 160 (5): 807-9. Lakhina, Vanisha, Rachel Arey, Rachel Kaletsky, Amanda Kauffman, Geneva Stein, William Keyes, Daniel Xu, and Coleen T Murphy. (2015) 2015. “Genome-Wide Functional Analysis of CREB Long-Term Memory-Dependent Transcription Reveals Distinct Basal and Memory Gene Expression Programs.”. Neuron 85 (2): 330-45. Shi, Cheng, and Coleen T Murphy. (2014) 2014. “Mating Induces Shrinking and Death in Caenorhabditis Mothers.”. Science 343 (6170): 536-40. Tepper, Ronald G, Coleen T Murphy, and Harmen J Bussemaker. (2014) 2014. “DAF-16 and PQM-1: Partners in Longevity.”. Aging (Albany NY) 6 (1): 5-6. Murphy, Coleen T, and Patrick J Hu. 2013. “Insulin/Insulin-Like/Growth/Factor/Signaling/in/C./Elegans.”. WormBook, 1-43. Tepper, Ronald G, Jasmine M Ashraf, Rachel Kaletsky, Gunnar Kleemann, Coleen T Murphy, and Harmen J Bussemaker. (2013) 2013. “PQM-1 Complements DAF-16 As a Key Transcriptional Regulator of DAF-2-Mediated Development and Longevity.”. Cell 154 (3): 676-90. Stein, Geneva M, and Coleen T Murphy. 2012. “The Intersection of Aging, Longevity Pathways, and Learning and Memory in C. Elegans.”. Front Genet 3: 259. Rizki, Gizem, Terri Naoko Iwata, Ji Li, Christian G Riedel, Colette Lafontaine Picard, Max Jan, Coleen T Murphy, and Siu Sylvia Lee. (2011) 2011. “The Evolutionarily Conserved Longevity Determinants HCF-1 and SIR-2.1 SIRT1 Collaborate to Regulate DAF-16 FOXO.”. PLoS Genet 7 (9): e1002235. Liu, Gang, Jason Rogers, Coleen T Murphy, and Christopher Rongo. (2011) 2011. “EGF Signalling Activates the Ubiquitin Proteasome System to Modulate C. Elegans Lifespan.”. EMBO J 30 (15): 2990-3003. Kauffman, Amanda, Lance Parsons, Geneva Stein, Airon Wills, Rachel Kaletsky, and Coleen Murphy. (2011) 2011. “C. Elegans Positive Butanone Learning, Short-Term, and Long-Term Associative Memory Assays.”. Journal of Visualized Experiments : JoVE, no. 49. doi:10.3791/2490. View all publications Luo, Shijing, and Coleen T Murphy. (2011) 2011. “Caenorhabditis Elegans Reproductive Aging: Regulation and Underlying Mechanisms.”. Genesis 49 (2): 53-65. Murphy, Coleen T. (2010) 2010. “Aging: MiRacles of Longevity?”. Curr Biol 20 (24). Luo, Shijing, Gunnar A Kleemann, Jasmine M Ashraf, Wendy M Shaw, and Coleen T Murphy. (2010) 2010. “TGF-β and Insulin Signaling Regulate Reproductive Aging via Oocyte and Germline Quality Maintenance.”. Cell 143 (2): 299-312. Kauffman, Amanda L, Jasmine M Ashraf, Ryan Corces-Zimmerman, Jessica N Landis, and Coleen T Murphy. (2010) 2010. “Insulin Signaling and Dietary Restriction Differentially Influence the Decline of Learning and Memory With Age.”. PLoS Biol 8 (5): e1000372. Related News Coleen Murphy receives 2021 Transformative Research Award from the National Institutes of HealthColeen Murphy, Mohamed Abou Donia and Zemer Gitai receive 2021 Transformative Research Awards from the NIHResearchers in the Murphy lab discover how worms pass down knowledge of a pathogen to their offspringColeen Murphy awarded one of the three annual "Women in Cell Biology" awards from the American Society for Cell BiologyPrinceton researchers publish study on learned behaviors in C. elegansMurphy and Troyanskaya lead team to produce new resources for C. elegans research Program(s) NIH NHGRI Training Program QCB Graduate Program Research Area Experimental Genomics Systems Biology: Development/Aging Systems Biology: Metabolomics/Proteomics LSI Research Lab Murphy Research Lab