{"id":166,"date":"2023-11-01T14:43:49","date_gmt":"2023-11-01T21:43:49","guid":{"rendered":"https:\/\/dornsife.usc.edu\/edmands\/?page_id=166"},"modified":"2025-08-26T09:26:44","modified_gmt":"2025-08-26T16:26:44","slug":"publications","status":"publish","type":"page","link":"https:\/\/dornsife.usc.edu\/edmands\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n\n \n \n\n\n\n\n\n\n\n
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*undergraduate student advisee,\u00a0 \u2020graduate student advisee, \u00a7postdoctoral advisee<\/p>\n

 <\/p>\n

Schoenberger K\u2020, X Wang & S Edmands, 2025. Increased brain size of the dwarf Channel Island fox (Urocyon littoralis<\/em>) challenges \u201cIsland Syndrome\u201d and suggests little evidence of domestication. PLoS One 20(8): e0328893. link<\/a><\/p>\n

Edmands S, JR Denova\u2020, BA Flanagan\u2020, M Jah* & SL Applebaum, 2024. Mitonuclear effects on sex ratio persist across generations in interpopulation hybrids. J Evol Biol 37(11):1386-1393. link<\/a><\/p>\n

Olsen KC\u00a7, LE Medina, FS Barreto, S Edmands, & RS Burton, 2024. Optimal outbreeding is shaped during larval life-history in the splash pool copepod Tigriopus californicus<\/em>. J Heredity. doi.org\/10.1093\/jhered\/esae039\u00a0link<\/a><\/p>\n

Coleman\u2020 A & S Edmands, 2024.<\/em> Phylogeny predicts sensitivity in aquatic animals for only a minority of chemicals. Ecotoxicology. doi:10.1007\/s10646-024-02791-7\u00a0link<\/a><\/p>\n

Li N\u00a7, BA Flanagan\u2020 & S Edmands, 2024. The role of mitochondria in sex- and age-specific gene expression in a species without sex chromosomes. PNAS 121(24): e2321267121.\u00a0link<\/a><\/p>\n

Edmands S, 2024. <\/em>Mother\u2019s Curse effects on lifespan and aging. Frontiers in Aging 5:1361396.\u00a0link<\/a><\/p>\n

Adams NE\u2020 & S Edmands, 2023. Genomic recovery lags behind demographic recovery in bottlenecked populations of the Channel Island fox, Urocyon littoralis<\/i>. Molecular Ecology 32(15):4151-4164\u00a0link<\/a><\/p>\n

Flanagan BA\u2020, E Huang* &\u00a0S Edmands, 2022. Exogenous oxidative stressors elicit differing age and sex effects in\u00a0Tigriopus californicus<\/i>.\u00a0Experimental Gerontology\u00a0166:111871. doi:10.1016\/j.exger.2022.111871\u00a0link<\/a><\/p>\n

Li N\u00a7, BA Flanagan\u2020\u00a0&\u00a0S Edmands, 2022. Food deprivation exposes sex-specific trade-offs between stress tolerance and life span in the copepod\u00a0Tigriopus californicus<\/i>.\u00a0Ecology & Evolution. doi:10.1002\/ece3.8822\u00a0pdf<\/a><\/p>\n

Coleman AL\u2020 & S\u00a0Edmands,\u00a02022. Data and diversity in the development of acute water quality criteria in the United States.\u00a0Environmental Toxicology and Chemistry.\u00a0doi: 10.1002\/etc.5302\u00a0pdf<\/a><\/p>\n

Adams NE\u2020, MA Becker* &\u00a0S Edmands, 2021.\u00a0Effect of geography and captivity on scat\u00a0<\/em>bacterial communities in the imperiled Channel Island Fox. Frontiers in Microbiology 12: 748323. 10.3389\/fmicb.2021.748323\u00a0pdf<\/a><\/p>\n

Flanagan BA\u2020, N Li\u00a7 &\u00a0S Edmands, 2021. Mitonuclear interactions alter sex-specific longevity in a species without sex chromosomes.\u00a0Proceedings Royal Society B 288:20211813. https:\/\/doi.org\/10.1098\/rspb.2021.1813\u00a0link<\/a><\/p>\n

Edmands S,\u00a02021. Sex ratios in a warming world: thermal effects on sex-biased survival, sex determination, and sex reversal.\u00a0Journal of Heredity\u00a0112(2): 155-164.\u00a0pdf<\/a><\/p>\n

Fitzpatrick CL, SE Alter, JW Boughman, F D\u00e9barre,\u00a0S Edmands, A Moehring, L Moyle, SP Otto, O Ronce, MJ Rubin & AL Sweigart, 2021.\u00a0The virus evolves: four public health priorities for reducing the evolutionary potential of SARS-CoV-2.\u00a0BioScience\u00a071(4):319.\u00a0pdf<\/a><\/p>\n

Li N\u00a7, BA Flanagan\u2020, M Partridge\u2020, EJ Huang* &\u00a0S Edmands, 2020. Sex differences in early transcriptomic responses to oxidative stress in the copepod\u00a0Tigriopus californicus<\/i>.\u00a0\u00a0BMC Genomics\u00a021: 759.\u00a0pdf<\/a><\/p>\n

Li N\u00a7, N Arief* &\u00a0S Edmands, 2019. Effects of oxidative stress on sex-specific gene expression in the copepod\u00a0Tigriopus californicus\u00a0<\/i>revealed by single individual RNA-seq.\u00a0Comparative Biochemistry and Physiology D. doi: 10.1016\/j.cbd.2019.100608\u00a0pdf<\/a><\/p>\n

Foley HB\u20201<\/sup>, PY Sun\u20201<\/sup>, R Ramirez*, BK So*, YR Venkataraman*, EN Nixon*, KJA Davies &\u00a0S Edmands, 2019. Sex-specific stress tolerance, proteolysis, and lifespan in the invertebrate\u00a0Tigriopus \u00a0<\/i>californicus<\/i>.\u00a0Experimental Gerontology\u00a0<\/strong>119:146-156.\u00a01<\/sup>co-first authors\u00a0pdf<\/a><\/p>\n

Barreto FS, ET Watson\u00a7, TG Lima, CS Willett, S Edmands, W Li & RS Burton, 2018. Genomic signatures of mitonuclear coevolution across populations of\u00a0Tigriopus californicus<\/em>. Nature Ecology and Evolution. doi.org\/10.1038\/s41559-018-0588-1.\u00a0pdf<\/a><\/p>\n

Sun PY\u2020, HB Foley\u2020, C Nguyen*, S Chaudhry*, VWW Bao, KMY Leung & S Edmands, 2018. Long-term laboratory culture causes contrasting shifts in tolerance to two marine pollutants in copepods of the genus Tigriopus.\u00a0Environmental Science and Pollution Research 25(4):3183-3192.\u00a0pdf<\/a><\/p>\n

Leong W\u2020, PY Sun\u2020 & S Edmands, 2018. Latitudinal clines in temperature and salinity tolerance in tidepool copepods. Journal of Heredity. 109(1):71-77.\u00a0pdf<\/a><\/p>\n

Hwang AS\u2020, VL Pritchard\u00a7\u00a0& S Edmands, 2016. Recovery from hybrid breakdown in a marine invertebrate is faster, stronger and more repeatable under environmental stress. Journal of Evolutionary Biology 29:1793-1803.\u00a0pdf<\/a><\/p>\n

Alexander HJ, JML Richardson, S Edmands & BR Anholt, 2015. Sex without sex chromosomes: genetic architecture of multiple loci independently segregating to determine sex ratios in the copepod\u00a0Tigriopus californicus<\/em>. Journal of Evolutionary Biology DOI: 10.1111\/jeb.12743\u00a0pdf<\/a><\/p>\n

Sun PY\u2020, HB Foley\u2020, VWW Bao, KMY Leung & S Edmands, 2015. Variation in tolerance to common marine pollutants among different populations in two species of the marine copepod\u00a0Tigriopus<\/em>. Environmental Science and Pollution Research. 22(20):16143-16152.\u00a0pdf<\/a><\/p>\n

Edmands S, 2015. Blurred lines: scientific and legislative issues surrounding hybrids and conservation. Current Zoology 61(1):128-131.\u00a0pdf<\/a><\/p>\n

Sun PY\u2020, HB Foley\u2020, L Handschumacher\u2020, A Suzuki,* T Karamanukyan* & S Edmands, 2014. Acclimation and adaptation to common marine pollutants in the copepod\u00a0Tigriopus californicus<\/em>. Chemosphere 112:465-471.\u00a0pdf<\/a><\/p>\n

Foley BR\u00a7, CG Rose\u00a7, DE Rundle, W Leong\u2020 & S Edmands, 2013.\u00a0<\/em>Postzygotic isolation involves strong mitochondrial and sex-specific effects in\u00a0Tigriopus californicus<\/em>, a species lacking heteromorphic sex chromosomes. Heredity 111:391-401.\u00a0pdf<\/a>
\nPeterson DL\u2020, KB Kubow*, MJ Connolly*, LR Kaplan*, MM Wetkowski*, BC Phillips\u2020, W Leong\u2020 & S Edmands, 2013. Reproductive and phylogenetic divergence of tidepool copepod populations across a narrow geographical boundary in Baja California. Journal of Biogeography 40: 1664-1675.\u00a0pdf<\/a><\/p>\n

Pritchard VL\u00a7 & S Edmands, 2013.\u00a0<\/em>The genomic trajectory of hybrid swarms: outcomes of repeated crosses between populations of\u00a0Tigriopus californicus<\/em>. Evolution 67:774-791. [Recommended by Faculty of 1000]\u00a0pdf<\/a><\/p>\n

Pritchard VL\u00a7, V Knutson*, M Lee*, JT Zieba* & S Edmands, 2013.\u00a0<\/em>Fitness and morphological outcomes of many generations of hybridization in the copepod\u00a0Tigriopus californicus<\/em>. Journal of\u00a0Evolutionary Biology 26(2):416-433.\u00a0pdf<\/a><\/p>\n

Phillips BC\u2020 & S Edmands, 2012.<\/em>\u00a0 Does the speciation clock tick more slowly in the absence of\u00a0heteromorphic sex chromosomes? BioEssays 34:166-169. [invited paper]\u00a0pdf<\/a><\/p>\n

Hwang AS\u2020, SL Northrup, DL Peterson\u2020, Y Kim* & S Edmands, 2012.<\/em>\u00a0 Long-term experimental\u00a0hybrid swarms between nearly incompatible\u00a0Tigriopus californicus\u00a0<\/em>populations: persistent fitness\u00a0problems and assimilation by the superior population. Conservation Genetics 13:567-579.\u00a0pdf<\/a><\/p>\n

Foley BR\u00a7, CG Rose\u00a7, DE Rundle, W Leong\u2020, GW Moy, RS Burton\u00a0<\/sup>& S Edmands, 2011.\u00a0<\/em>A gene-based SNP resource and linkage map for the copepod\u00a0Tigriopus californicus.<\/em>\u00a0BMC Genomics 12:568.\u00a0pdf<\/a><\/p>\n

Purcell CM\u2020 & S Edmands, 2011. Resolving the genetic structure of striped marlin,\u00a0Kajikia audax<\/em>, in the Pacific Ocean through spatial and temporal sampling of adult and immature fish. Canadian Journal of Fisheries and Aquatic Sciences 68:1861-1875.\u00a0pdf<\/a><\/p>\n

Pritchard VL\u00a7, L Dimond*, JS Harrison, C Vel\u00e1zquez*, J Zieba*, RS Burton & S Edmands, 2011.<\/em>\u00a0 Interpopulation hybridization results in widespread viability selection across the genome of\u00a0Tigriopus californicus<\/em>. BMC Genetics 12:54. [\u201cFeatured article\u201d]\u00a0pdf<\/a><\/p>\n

Hwang, AS\u2020, SL Northrup, JK Alexander*, KT Vo* & S Edmands, 2011. Long-term experimental hybrid swarms between moderately incompatible\u00a0Tigriopus californicus<\/em>\u00a0populations: hybrid inferiority in early generations yields to hybrid superiority in later generations. Conservation Genetics 12(4):895-909.\u00a0pdf<\/a><\/p>\n

Handschumacher L\u2020, MB Steinarsd\u00f3ttir, S Edmands & A Ing\u00f3lfsson. 2010. Phylogeography of the rock-pool copepod\u00a0Tigriopus brevicornis<\/em>\u00a0(Harpacticoida) in the northern North Atlantic, and its relationship to other species of the genus. Marine Biology 157:1357-1366.\u00a0pdf<\/a><\/p>\n

Edmands S, SL Northrup & AS Hwang\u2020, 2009. Maladapted gene complexes within populations of the intertidal copepod\u00a0Tigriopus californicus<\/em>? Evolution 63(8):2184-2192.\u00a0pdf<\/a><\/p>\n

Purcell CM\u2020, JS Harrison\u00a7 & S Edmands, 2009. Isolation and characterization of 10 polymorphic\u00a0microsatellite markers from striped marlin,\u00a0Tetrapturus audax.\u00a0<\/em>Molecular Ecology Resources\u00a0 9(6):1556-1559.\u00a0pdf<\/a><\/p>\n

Vogel AB\u2020, KA Selkoe, D Anderson & S Edmands, 2009. Development and inheritance of molecular markers in the kelp bass,\u00a0\u00a0Paralabrax clathratus<\/em>. Fisheries Science 75(2):525-27.\u00a0pdf<\/a><\/p>\n

Edmands S. 2008. Recombination in interpopulation hybrids of the copepod\u00a0Tigriopus californicus<\/em>: release of beneficial variation despite hybrid breakdown. Journal of Heredity 99(3):316-318.\u00a0pdf<\/a><\/p>\n

Hedgecock D, PH Barber & S Edmands, 2007. Genetic approaches to measuring connectivity.\u00a0 Oceanography 20(3):70-79. [invited review]\u00a0pdf<\/a><\/p>\n

Vogel AB\u2020, K Tenggardjaja*, S Edmands, ND Halbert, JN Derr & D Hedgecock, 2007. Detection of domestic cattle mtDNA in bison on Santa Catalina Island. Animal Genetics 38:410-412.\u00a0pdf<\/a><\/p>\n

Edmands S, 2007. Between a rock and a hard place: Evaluating the relative risks of inbreeding and outbreeding for conservation and management. Molecular Ecology 16:463-475. [invited review]\u00a0pdf<\/a><\/p>\n

Harrison JS\u00a7 & S Edmands, 2006. Chromosomal basis of viability differences in\u00a0Tigriopus\u00a0<\/em>californicus<\/em>\u00a0interpopulation hybrids. Journal of Evolutionary Biology 19(6):2040- 2051.\u00a0pdf<\/a><\/p>\n

Edmands S, HV Feaman*, JS Harrison\u00a7 & CC Timmerman, 2005. Genetic consequences of many generations of hybridization between divergent copepod populations. Journal of Heredity 96(2):114-123.\u00a0pdf<\/a><\/p>\n

Harrison JS\u00a7, DL Peterson\u2020, JR Swain* & S Edmands, 2004. Microsatellite DNA markers for the\u00a0intertidal copepod\u00a0Tigriopus californicus<\/em>. Molecular Ecology Notes 4(4):736-738.\u00a0pdf<\/a><\/p>\n

Edmands S & JK Deimler*, 2004.<\/em>\u00a0Local adaptation, intrinsic coadaptation and the effects of environmental stress on interpopulation hybrids in the copepod\u00a0Tigriopus californicus<\/em>.\u00a0 Journal of\u00a0Experimental Marine Biology and Ecology 303(2):183-196.\u00a0pdf<\/a><\/p>\n

Libertini A, R Trisolini & S Edmands, 2004. A cytogenetic study of the periwinkle\u00a0Littorina keenae<\/em>\u00a0 Rosewater, 1978 (Gastropoda, Prosobranchia). Journal of Molluscan Studies 70: 299-301.\u00a0pdf<\/a><\/p>\n

Edmands S & JS Harrison\u00a7, 2003. Molecular and quantitative trait variation within and among\u00a0populations of the intertidal copepod\u00a0Tigriopus californicus<\/em>. Evolution 57(10): 2277-2285.\u00a0pdf<\/a><\/p>\n

Edmands S & CC Timmerman, 2003. Modeling factors affecting the severity of outbreeding depression.\u00a0 Conservation Biology 17(3): 883-892.\u00a0pdf<\/a><\/p>\n

Edmands S, 2002. Does parental divergence predict reproductive compatibility? Trends in Ecology and Evolution 17(11): 520-527. [Invited review]\u00a0pdf<\/a><\/p>\n

Edmands S, 2001. Phylogeography of the marine copepod\u00a0Tigriopus californicus<\/em>\u00a0reveals\u00a0substantially reduced interpopulation divergence at northern latitudes. Molecular Ecology 10:1743-1750.\u00a0pdf<\/a><\/p>\n

Palmer C* & S Edmands, 2000.\u00a0 Mate choice in the face of both inbreeding and outbreeding\u00a0 depression in the intertidal copepod\u00a0Tigriopus californicus<\/em>. Marine Biology 136: 693-698.\u00a0pdf<\/a><\/p>\n

Edmands S, 1999.\u00a0 Heterosis and outbreeding depression in interpopulation crosses spanning a wide range of divergence. Evolution 53(6): 1757-1768.\u00a0pdf<\/a><\/p>\n

Edmands S & RS Burton, 1999\u00a0 Cytochrome-c oxidase activity in interpopulation hybrids of the\u00a0marine copepod\u00a0Tigriopus californicus<\/em>: a test for nuclear-nuclear or nuclear-cytoplasmic coadaptation.\u00a0 Evolution 53(6): 1972-1978.\u00a0pdf<\/a><\/p>\n

Burton RS, PR Rawson & S Edmands, 1999.\u00a0 Genetic architecture of physiological phenotypes: empirical evidence for coadapted gene complexes.\u00a0 American Zoologist 39:451-462.\u00a0pdf<\/a><\/p>\n

Edmands, S & RS Burton, 1998.\u00a0 Variation in cytochrome-c oxidase activity is not maternally inherited in the copepod\u00a0Tigriopus californicus<\/em>.\u00a0 Heredity 80(6):668-674.\u00a0pdf<\/a><\/p>\n

Edmands S & DC Potts. 1997.\u00a0 Population genetic structure in brooding sea anemones (Epiactis<\/em>\u00a0spp.) with contrasting reproductive modes.\u00a0 Marine Biology 127:485-498.\u00a0pdf<\/a><\/p>\n

Edmands S. 1996.\u00a0 The evolution of mating systems in a group of brooding sea anemones (Epiactis<\/em>).\u00a0 Invertebrate Reproduction and Development 30:227-237.<\/p>\n

Edmands S, PE Moberg & RS Burton. 1996.\u00a0 Allozyme and mitochondrial DNA evidence of population subdivision in the purple sea urchin\u00a0Strongylocentrotus purpuratus<\/em>.\u00a0 Marine Biology\u00a0126:443-450.\u00a0pdf<\/a><\/p>\n

Jenssen TA, JD Congdon, RU Fischer, R Estes, D Kling, S Edmands & H Berna. 1996. Behavioural, thermal and metabolic characteristics of a wintering lizard (Anolis carolinensis<\/em>) from South Carolina.\u00a0 Functional Ecology 10:201-209.\u00a0pdf<\/a><\/p>\n

Jenssen TA, JD Congdon, RU Fischer, R Estes, D Kling, & S Edmands. 1995.\u00a0 Morphological characteristics of the lizard\u00a0Anolis carolinensis<\/em>\u00a0from South Carolina. Herpetologica 51(4):401-411.\u00a0pdf<\/a><\/p>\n

Edmands S. 1995.\u00a0 Mating systems in the sea anemone genus\u00a0Epiactis<\/em>. Marine Biology 123:723-733.<\/p>\n

Edmands S & DG Fautin. 1991.\u00a0 Redescription of\u00a0Aulactinia veratra<\/em>\u00a0 n. comb. (=Cnidopus veratra<\/em>\u00a0(Coelenterata: Actiniaria) from Australia. Records of the Western Australia Museum 15(1):59-68.<\/p>\n\n\n\n<\/div>\n\n\n <\/div><\/div>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":581,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":""},"class_list":["post-166","page","type-page","status-publish","hentry"],"acf":[],"yoast_head":"\nPublications - The Edmands Lab: Population & Conservation Genetics<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/dornsife.usc.edu\/edmands\/publications\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"Publications - The Edmands Lab: Population & Conservation Genetics\" \/>\n<meta property=\"og:url\" content=\"https:\/\/dornsife.usc.edu\/edmands\/publications\/\" \/>\n<meta property=\"og:site_name\" content=\"The Edmands Lab: Population & Conservation Genetics\" \/>\n<meta property=\"article:modified_time\" content=\"2025-08-26T16:26:44+00:00\" \/>\n<meta name=\"twitter:card\" content=\"summary_large_image\" \/>\n<script type=\"application\/ld+json\" class=\"yoast-schema-graph\">{\"@context\":\"https:\/\/schema.org\",\"@graph\":[{\"@type\":\"WebPage\",\"@id\":\"https:\/\/dornsife.usc.edu\/edmands\/publications\/\",\"url\":\"https:\/\/dornsife.usc.edu\/edmands\/publications\/\",\"name\":\"Publications - 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