*Dykman LN, Davis DB, Blend CK, 2025. Neolebouria mullineauxae<\/em> n. sp. (Trematoda: Digenea) and Another Opecoelid from Deep-Sea Hydrothermal Vent Fields Off Central America and Papua New Guinea, with Species Keys and a Comparison to Mesobathylebouria<\/em>. Journal of Parasitology<\/em>, 111(4):451-478. https:\/\/doi.org\/10.1645\/24-113<\/a><\/p>\n *DiBenedetto M, Monthiller R, Eloy C, Mullineaux L. 2025. Plankton active response to turbulence enables efficient transport. J. Exp. Biol 24. https:\/\/doi.org\/10.1242\/jeb.251123<\/p>\n *Z\u00fa\u00f1iga Mouret R, Hourdez S, Curran M, DiBenedetto MH, Mills SW, Vetriani C, Arellano SM, Weston JNJ, *Dykman LN, *Best AC, Pires A, Mullineaux LS, 2025 Pressurized plankton observatory offers a new window into deep-sea larval behavior. Limnol & Oceanogr Methods https:\/\/doi.org\/10.1002\/lom3.10708https:\/\/doi.org\/10.1098\/rspb.2023.0877<\/p>\n Mullineaux LS, Beaulieu SE, Mills SW, Jones R, Weston JNJ, *Best AC, *Z\u00fa\u00f1iga Mouret R, *Meneses MJ, Tivey MK, *Harris MJ, Achberger AM, Sylvan JB, 2025. Unique gastropod community dominates fauna on inactive vent sulfide features in the eastern Pacific. Deep-Sea Res 291, https:\/\/doi.org\/10.1016\/j.dsr.2025.104475<\/p>\n *Dykman LN, Tepolt CK, Blend CK, Mullineaux LS, 2025. The discovery of indirect parasite life cycles at deep-sea hydrothermal vents. Featured Article in Mar Ecol Prog Ser, 755: 1-14, https:\/\/doi.org\/10.3354\/meps14789<\/p>\n *Meneses M., Beaulieu SE. *Best A, *Dykman LN, Mills SW, Wu J, Mullineaux LS, 2024. Vertical distributions of megafauna on inactive vent sulfide features correspond to their feeding modes. Mar Env Sci 200:106649, https:\/\/doi.org\/10.1016\/j.marenvres.2024.1066497<\/p>\n Ladd TM, Selci M, Davis DJ, Cannon O, Plowman CO, Inaba A, Mills SW, Vetriani C, Mullineaux LS, Arellano SM, 2024. Faunal colonists, including mussel settlers, respond to microbial biofilms at deep-sea hydrothermal vents. Deep Sea Res I\u00a0 https:\/\/doi.org\/10.1016\/j.dsr.2024.104314<\/a><\/p>\n Chen C, Li Y, Sun J, Beaulieu SE, Mullineaux LS. 2024. Two new melanodrymiid snails from the East Pacific Rise indicate the potential role of inactive vents as evolutionary stepping-stones. Systematics and Biodiversity 22(1):2294014. doi.org\/10.1080\/14772000.2023.2294014<\/p>\n *Dykman LN, Tepolt CK, Kuris AM, Solow AR, Mullineaux LS. 2023 Parasite diversity at isolated, disturbed hydrothermal vents. Proc. R. Soc. B 290: 20230877. https:\/\/doi.org\/10.1098\/rspb.2023.0877<\/p>\n Gaill, F, Brodie Rudolph, T, and others including Mullineaux, L, 2022. An evolution towards scientific consensus for a sustainable ocean future. npj Ocean Sustainability 1:7 \/doi.org\/10.1038\/s44183-022-00007-1<\/p>\n Fleming, B., S.E. Beaulieu, S.W. Mills, O. Gaggiotti, L.S. Mullineaux<\/strong>. 2022. Ecological connectivity in Pacific deep-sea hydrothermal vent metacommunities. Mar Ecol Prog Ser, https:\/\/doi.org\/10.3354\/meps14182<\/p>\n DiBenedetto, M., K.R. Helfrich, A Pires, E.J. Anderson, L.S. Mullineaux<\/strong>. 2022. Responding to the signal and the noise: behavior of planktonic larvae in turbulence. J Exp Biol 225 (3): 10.1242\/jeb.243209<\/p>\n Lebbe TB, Rey-Valette H, Chaumillon E, Camus G, Almar R, Cazenave A, Claudet J, Rocle N, Meur-Ferec C, Viard F, Mercier D, Dupuy C, Menard F, Rossel BA, Mullineaux L<\/strong>, Sicre MA, Zivian A, Gaill F, Euzen A. 2021. Designing coastal adaptation strategies to tackle sea level rise. Frontiers in Marine Science, 8, 10.3389\/fmars.2021.740602<\/a><\/p>\n Carrier, T.J., S.E. Beaulieu, S.W. Mills, L.S. Mullineaux<\/strong>, A.M. Reitzel. 2021. Larvae of deep-sea invertebrates harbor low-diversity bacterial communities. Biological Bulletin, 241: 65-76. DOI: 10.1086\/715669<\/p>\n Dykman, L.N. S.E. Beaulieu, S.W Mills, A.R. Solow, L.S. Mullineaux<\/strong>. 2021. Functional traits provide new insight into recovery and succession at deep-sea hydrothermal vents. Ecology, doi:10.1002\/ecy.3418<\/p>\n DiBenedetto, M., K.S. Meyer-Kaiser, B. Torjman, J.D. Wheeler, L.S. Mullineaux<\/strong>, 2021. Departures from isotropy: the kinematics of larval snail behavioral response to food. Journal of Experimental Biology 224: jeb239178 doi:\u00a010.1242\/jeb.239178<\/p>\n Mullineaux. 2021. Departures from isotropy: the kinematics of larval snail behavioral response to food. Journal of Experimental Biology 224: jeb239178 doi:\u00a010.1242\/jeb.239178<\/p>\n Mullineaux, L.S<\/strong>, S. W. Mills, N. Le Bris, S.E. Beaulieu, S.M. Sievert, L.N. Dykman. 2020. Prolonged recovery time after eruptive disturbance of a deep-sea hydrothermal vent community. Proceedings Royal Society B 287:20202070. https:\/\/doi.org\/10.1098\/rspb.2020.2070<\/a><\/p>\n Claudet, J., L. Bopp, W.W.L. Cheung, R. Devillers, E. Escobar-Briones, P. Haugan, J.J. Heymans, V. Masson-Delmotte, Nele Matz-Luck, P. Miloslavich, L. Mullineaux<\/strong>, M. Visbeck, R. Watson, A. M. Xivian, I Ansorge, M. Araujo, S. Arico, D. Bailly, J. Barbiere, C Barnerias, C. Bowler, V. Brun, A. Cazenave, C. Diver, A. Euzen, A.T. Gave, N. Hilmi, F. Menard, C. Moulin, N.P. Munoz, R. Parmentier, A. Pebayle, H-O Portner, S. Osvaldina, P. Ricard, R.S. Santos, M-S. Sicre, S. Thiebault, T. Thiele, R. Trouble, A. Turra, J. Uki, F. Gaill. 2020. A Roadmap for Using the UN Decade of Ocean Science for Sustainable Development in Support of Science, Policy, and Action. One Earth 2: 34-42. DOI:https:\/\/doi.org\/10.1016\/j.oneear.2019.10.012<\/a><\/p>\n Gollner, S., B. Govenar, P.M. Arbizu, L.S. Mullineaux<\/strong>, S.W. Mills, N. Le Bris, M. Weinbauer, T.M. Shank, M. Bright. Animal community dynamics at active and senescent vents at the 9\u00b0N East Pacific Rise after a volcanic eruption. 2020. Frontiers in Marine Science doi.org\/10.3389\/fmars.2019.00832<\/a><\/p>\n Meyer-Kaiser, K.S., E. Houlihan, J. D. Wheeler , D. C. McCorkle, L.S. Mullineaux<\/strong> 2019. Behavioral response of eastern oyster Crassostrea virginica<\/em> larvae to a chemical settlement cue is not impaired by low pH. Marine Ecology Progress Series 623:13-24, doi.org\/10.3354\/meps13014<\/a><\/p>\n Chapman, S.A; S.E. Beaulieu; A. Cola\u00e7o, A.V. Gebruk, A. Hilario, T. Kihara, E. Ramirez-Llodra, J. Sarrazin, V. Tunnicliffe, D.J. Amon, M.C. Baker, R.E. Boschen-Rose, C. Chen, I.J. Cooper, J.T. Copley, L. Corbari, E. Cordes, D.Cuvelier, S. Duperron, C. Du Preez, S. Gollner, T. Horton, S. Hourdez, E.M. Krylova, K. Linse, P.A. LokaBharathi, L. Marsh, M. Matabos, S.W. Mills, L.S. Mullineaux<\/strong>, H.T. Rapp, W.D.K. Reid,E. Rybakova (Goroslavskaya), T.R.A.Thomas, S.J. Southgate, S. Sto\u0308hr, P.J. Turner, H.K. Watanabe, M. Yasuhara, A.E. Bates. 2019. sFDvent: a global trait database for deep-sea hydrothermal vent fauna. Global Ecology and Biogeography (GEB-2018-0294) doi.org\/10.1111\/geb.12975<\/a><\/p>\n Maciejewski, M., Meyer, K.S., Wheeler, J.D., Anderson, E.J., Pittoors, N.,\u00a0Mullineaux, L.S.<\/strong>\u00a02019. Helical swimming as an exploratory behavior in competent larvae of the eastern oyster (Crassostrea virginica<\/em>). J Exp Mar Biol Ecol 510:86-94. doi: 10.1016\/j.jembe.2018.10.007<\/a><\/p>\n Xu, G., McGillicuddy, D.J., Mills, S.W., Mullineaux, L.S., 2018. Dispersal of Hydrothermal Vent Larvae at East Pacific Rise 9-10\u00b0N Segment. Journal of Geophysical Research – Oceans JGRC23170, DOI: 10.1029\/2018JC014290<\/a><\/p>\n Meyer K.S, Wheeler J.D., Houlihan E.,\u00a0Mullineaux L.S.<\/strong>\u00a02018. Desperate planktotrophs: decreased settlement selectivity with age in competent eastern oyster (Crassostrea virginica<\/em>) larvae. Marine Ecology Progress Series 599: 93-106. DOI\u00a010.3354\/meps12653<\/a><\/p>\n Mullineaux, L.S.<\/strong>, A. Metaxas, S.E. Beaulieu, M. Bright, S. Gollner, B. Grupe, S. Herrera, J. Kellner, L. Levin, S. Mitarai, M. Neubert, A. Thurnherr, V. Tunnicliffe, H.K. Watanabe, Y-J Won, 2018. Exploring the ecology of deep-sea hydrothermal vents in a metacommunity framework. Frontiers in Marine Science 5:49. doi: 10.3389\/fmars.2018.00049<\/a><\/p>\n Wheeler, J.D., E.Y. Luo, K.R. Helfrich, E.J. Anderson,\u00a0L.S. Mullineaux<\/strong>. 2017. Light stimulates swimming behavior of larval eastern oysters (Crassostrea virginica<\/em>) in turbulent flow. Mar Ecol Prog Ser 571: 109-120, doi:10.3354\/ meps12106<\/a><\/p>\n Wheeler, JD & KYK Chan (co-first authors), EJ Anderson,\u00a0LS Mullineaux<\/strong>. 2016. Ontogenetic changes in larval swimming and orientation in pre-competent sea urchin\u00a0Arbacia punctulata<\/em>. J Exp Biol 219: 1303-1310 doi: 10.1242\/jeb.129502\u00a0 Nedoncelle, K., Lartaud, F., Pereira, L. C., Yuecel, M., Thurnherr, A. M.,\u00a0Mullineaux, L.<\/strong>, & Le Bris, N. 2015. Bathymodiolus growth dynamics in relation to environmental fluctuations in vent habitats. Deep-Sea Res I, 106: 183-193. doi: 10.1016\/j.dsr.2015.10.003\u00a0 Wheeler, J.D., K.R. Helfrich, E.J. Anderson,\u00a0L.S. Mullineaux.<\/strong>\u00a02015. Isolating the hydrodynamic triggers of the dive response in eastern oyster larvae. Limnol & Oceanogr 60: 1332-1343\u00a0 Mullineaux, L.S.<\/strong>, Deep Sea Hydrothermal Vent Communities. 2014. Ch. 17 in: Bertness, M., Bruno, M., Silliman, B, Stachowicz, J. (Eds.), Marine Community Ecology and Conservation. Sinauer, Sunderland, Massachusetts.\u00a0 White, M.M.,\u00a0L.S. Mullineaux<\/strong>, D.C. McCorkle, A.L. Cohen. 2014. Elevated pCO2<\/sub>\u00a0during fertilization of the bay scallop\u00a0Argopecten irradians<\/em>\u00a0reduces larval survival but not shell size. Mar Ecol Prog Ser 498: 173-186\u00a0 Mills, S.W.,\u00a0Mullineaux, L.S.<\/strong>, Beaulieu, S.E., Adams, D.K. 2013. Persistent effects of disturbance on larval patterns in the plankton after an eruption on the East Pacific Rise. Mar. Ecol. Prog. Ser. 491:67-76\u00a0 Mullineaux, L.S.<\/strong>, McGillicuddy, D.J., Mills, S.W., Kosnyrev, V.K., Thurnherr, A.M., Ledwell, J.R., Lavelle, J.W. 2013. Active positioning of vent larvae at a mid-ocean ridge. Deep Sea Research II 92: 46-57\u00a0 Wheeler, J.D., Anderson, E.J., Helfrich, K.R., McGann, B., Staats, P., Wargula, A.E., Wilt, K.,\u00a0Mullineaux, L.S.<\/strong>\u00a02013. Upward swimming of competent oyster larvae (Crassostrea virginica<\/em>) persists in highly turbulent flow as detected by PIV flow subtraction. Mar. Ecol. Prog. Ser. 488: 171-185.\u00a0 White, M.M., McCorkle, D.C.,\u00a0Mullineaux, L.S.,<\/strong>\u00a0Cohen, A.L. 2013. Early Exposure of Bay Scallops (Argopecten irradians) to High CO2 Causes a Decrease in Larval Shell Growth Plos One 8 (4), e61065.\u00a0 Mullineaux LS<\/strong>, Le Bris N, Mills SW, Henri P, Bayer SR, Secrist RG, Siu N. 2012. Detecting the influence of initial pioneers on succession at deep-sea vents. PLoS ONE 7: e50015. doi:10.1371\/journal.pone.0050015\u00a0 Fornari DJ, Von Damm KL, Bryce JG, Cowen JP, Ferrini V, Fundis A, Lilley MD, Luther GW,\u00a0Mullineaux LS<\/strong>, Perfit MR, Meana-Prado MF, Rubin KH, Seyfried WE, Shank TM, Soule SA, Tolstoy M, White SM. 2012. The East Pacific Rise between 9\u00b0N and 10\u00b0N: Twenty-five years of integrated, multidisciplinary oceanic spreading center studies. Oceanography 25:18-43\u00a0 Lavelle JW, Thurnherr AM,\u00a0Mullineaux LS<\/strong>, McGillicuddy DJ, Ledwell JR. 2012. The prediction, verification and significance of flank jets at mid-ocean ridges. Oceanography 25:277-283.\u00a0 Adams DK, McGillicuddy DJ, Zamudio L, Thurnherr AM, Liang X, Rouxel O, German CR,\u00a0Mullineaux LS<\/strong>. 2011. Surface-generated mesoscale eddies transport deep-sea products from hydrothermal vents. Science 332:580-583.\u00a0 Thurnherr, A. M., J. R. Ledwell, J. W. Lavelle,\u00a0L. S. Mullineaux<\/strong>. 2011. Circulation near the crest of the East Pacific Rise between 9\u25e6and 10\u25e6N. Deep-Sea Res. I 58: 365-376.\u00a0 Bayer SR,\u00a0Mullineaux LS<\/strong>, Waller RG, Solow AR 2011. Reproductive traits of pioneer gastropod species colonizing deep-sea hydrothermal vents after an eruption. Marine Biology 158:181-192.\u00a0 Lavelle, J.W., A.M. Thurnherr, J. R. Ledwell, D.J. McGillicuddy, Jr.,\u00a0L.S. Mullineaux<\/strong>. 2010. Deep ocean circulation and transport where the East Pacific Rise at 9-10\u00b0N meets the Lamont Seamount chain. Journal of Geophysical Research – Oceans 115:C12073.\u00a0 Fuchs, H. L., A. R. Solow, and\u00a0L. S. Mullineaux<\/strong>. 2010. Larvae from different adult habitats have genus-specific responses to turbulence in a tidal channel. Journal of Marine Research 68:153-188.\u00a0 Adams, D.K., S.W. Mills, T.M. Shank,\u00a0L.S. Mullineaux<\/strong>. 2010. Expanding dispersal studies at hydrothermal vents through species identification of cryptic larval forms. Marine Biology 157:1049-1062.\u00a0 McGillicuddy DJ, Lavelle W, Thurnherr AM, Kosnyrev VK,\u00a0Mullineaux LS<\/strong>. 2010. Larval dispersion along an axially symmetric mid-ocean ridge. Deep Sea Res I 57:880-892.\u00a0 Mullineaux LS<\/strong>, Adams DK, Mills SW, Beaulieu SE. 2010. Larvae from afar colonize deep-sea hydrothermal vents after a catastrophic eruption. PNAS 107:7829-7834.\u00a0 Mullineaux, L.S.<\/strong>, F. Micheli, C.H. Peterson, H.S. Lenihan, N. Markus. 2009. Historical effects on succession : imprint of past conditions on structure of a deep-sea hydrothermal vent community.\u00a0Oecologia\u00a0<\/em>161:387-400.\u00a0 Rona, P. A., A. Seilacher, C. de Vargas, A. J. Gooday, J. M. Bernhard, S. Bowser, C. Vetriani, C. O. Wirsen,\u00a0L. Mullineaux<\/strong>, R. Sherrell, J. F. Grassle, S. Low, R. A. Lutz. 2009.\u00a0Paleodictyon nodosum<\/em>: A living fossil on the deep-sea floor. Deep-Sea Research II 56: 1700-1712.\u00a0 Beaulieu, S.E.,\u00a0Mullineaux, L.S.<\/strong>, Adams, D.K., and Mills, S.W. 2009. Comparison of a sediment trap and plankton pump for time-series sampling of larvae near deep-sea hydrothermal vents.\u00a0Limnology and Oceanography: Methods\u00a0<\/em>7:235-248.\u00a0 Metaxas, A.,\u00a0L.S. Mullineaux<\/strong>\u00a0and J. Sisson. 2009. Distribution of echinoderm larvae relative to the halocline of a salt wedge.\u00a0Mar. Ecol. Prog. Ser.<\/em>\u00a0377: 157-168.\u00a0 Jennings, R.M., T. M. Shank,\u00a0L. S. Mullineaux<\/strong>, and K. M. Halanych. 2009. Assessment of the Cape Cod phylogeographic break using the bamboo worm\u00a0Clymenella torquata<\/em>\u00a0reveals the role of regional water masses and dispersal .\u00a0J.<\/em>\u00a0Heredity<\/em>\u00a0100:86-96.\u00a0 Lenihan, H.S., S.W. Mills,\u00a0L.S. Mullineaux<\/strong>, C.H. Peterson, C.R. Fisher, F. Micheli. 2008. Biotic interactions at hydrothermal vents: recruitment inhibition by the mussel\u00a0Bathymodiolus thermophilus. Deep-Sea Research<\/em>\u00a0155:1707-1717.\u00a0 Strasser, C.A.,\u00a0L. S. Mullineaux<\/strong>, S. R. Thorrold. 2008. Temperature and salinity effects on elemental uptake in the shells of larval and juvenile softshell clams (Mya arenaria<\/em>).\u00a0Mar. Ecol. Prog. Ser.<\/em>\u00a0370- 155-169.\u00a0 Tyler, P.A., S. Pendlebury, S.W. Mills,\u00a0L.S. Mullineaux<\/strong>, K.J. Eckelbarger, M. Baker and C.M. Young. 2008. Reproduction of gastropods from vents on the East Pacific Rise and the Mid-Atlantic Ridge.\u00a0J. Shellfish Res.<\/em>\u00a027: 107-118.\u00a0 Strasser, C.A.,\u00a0L.S. Mullineaux<\/strong>\u00a0and B.D. Walther. 2008. Growth rate and ontogeny effects on\u00a0Mya arenaria\u00a0<\/em>shell chemistry: implications for biogeochemical studies.\u00a0J. Exp. Mar. Biol. Ecol.<\/em>, 355: 153 – 163.\u00a0 Adams, D.K. and\u00a0L.S. Mullineaux<\/strong>. 2008. Supply of gastropod larvae to hydrothermal vents reflects transport from local larval sources.\u00a0Limnology and Oceanography<\/em>\u00a053: 1945 – 1955.\u00a0 Strasser, C.A., S.R. Thorrold, V.R. Starczak, and\u00a0L.S. Mullineaux<\/strong>. 2007. Laser ablation ICP-MS analysis of larval shell in softshell clams (Mya arenaria<\/em>) poses challenges for natural tag studies.\u00a0Limnology and Oceanography Methods<\/em>\u00a05: 241-249.\u00a0 Fuchs, H., M. Neubert and\u00a0L.S. Mullineaux<\/strong>. 2007. Effects of turbulence-mediated larval behavior on larval supply and settlement in tidal currents.\u00a0Limnol Oceanogr\u00a0<\/em>52:1156-1165.\u00a0 Mills, S.W.,\u00a0L.S. Mullineaux<\/strong>\u00a0and P.A. Tyler. 2007. Habitat associations in gastropod species at East Pacific Rise hydrothermal vents (9\u00b050’N).\u00a0Biological Bulletin<\/em>\u00a0212: 185-194.\u00a0 Neubert, M.,\u00a0L.S. Mullineaux<\/strong>\u00a0and M.F. Hill. 2006. A metapopulation approach to interpreting diversity at deep-sea hydrothermal vents. In ‘Marine Metapopulations’, J. Kritzer and P. Sale, eds., Elsevier Academic Press, pp. 321-350.\u00a0 Pradillon, F., M. Zbinden,\u00a0L.S. Mullineaux<\/strong>\u00a0and F. Gaill. 2005. Effects of patch dynamics on size-structure and reproductive maturity of\u00a0Alvinella pompejana<\/em>\u00a0(Polychaeta: Alvinellidae) populations.\u00a0Marine Ecology Progress Series<\/em>\u00a0302:147-157.\u00a0 Mullineaux, L.S.<\/strong>, S.W. Mills, A. K. Sweetman, A.H. Beaudreau, A. Metaxas,<\/sub>\u00a0H.L. Hunt. 2005. Spatial structure and temporal variation in larval abundance at hydrothermal vents on the East Pacific Rise.\u00a0Marine Ecology Progress Series<\/em>\u00a0293:1-16.\u00a0 Sancho, G., Fisher, C.R., Mills, S. Micheli, F., Johnson, G.A., Lenihan, H.S., Peterson, C.H and\u00a0Mullineaux, L.S.<\/strong>\u00a02005. Selective predation by the zoarcid fish\u00a0Thermarces cerberus<\/em>\u00a0at hydrothermal vents.\u00a0Deep-Sea Research<\/em>\u00a0152: 837-844.\u00a0 Fuchs, H.L.,\u00a0L. S. Mullineaux<\/strong>, and A. R. Solow. 2004. Sinking behavior of gastropod larvae (Ilyanassa obsoleta<\/em>) in turbulence.\u00a0Limnology and Oceanography<\/em>\u00a049: 1937-1948.\u00a0 Hunt, H.L., A. Metaxas, R.M. Jennings, K.Halanych and\u00a0L.S. Mullineaux<\/strong>. 2004. Testing biological control of colonization by vestimentiferan tubeworms at deep-sea hydrothermal vents (East Pacific Rise, 9\u00b050’N).\u00a0Deep-Sea Research\u00a0<\/em>51: 225-234.\u00a0 Mullineaux, L.S.<\/strong>, C.H. Peterson, F. Micheli and S.W. Mills. 2003. Successional mechanism varies along a gradient in hydrothermal fluid flux at deep-sea vents.\u00a0Ecological Monographs<\/em>\u00a073: 523-542.\u00a0 Mullineaux, L.S.<\/strong>, K.G. Speer, A.M. Thurnherr, M.E. Maltrud, A. Vangriesheim. 2002..\u00a0<\/sup>Implications of cross-axis flow for larval dispersal along mid-ocean ridges.\u00a0Cahiers de Biologie Marine<\/em>\u00a043: 281-284.<\/p>\n Hunt, H.L., D.A. McLean and\u00a0L.S. Mullineaux<\/strong>. 2002. Post-settlement alteration of spatial settlement patterns of the soft shell clam\u00a0Mya arenaria<\/em>.\u00a0Estuaries<\/em>\u00a026: 72-81.\u00a0 Podar, M,\u00a0Mullineaux, L.S.<\/strong>, Huang, H.-R., Perlman, P.S. and Sogin, M.L. 2002. Bacterial group II introns in a deep sea hydrothermal vent environment.\u00a0Applied and Environmental Microbiology<\/em>\u00a068:6392-6398.\u00a0 Hunt, H.L. and\u00a0L.S. Mullineaux<\/strong>. 2002. The roles of predation and postlarval transport in recruitment of the soft shell clam\u00a0Mya arenaria<\/em>.\u00a0Limnology & Oceanography<\/em>\u00a047:151-164.\u00a0 Micheli, F., C.H. Peterson,\u00a0L.S. Mullineaux<\/strong>, C. Fisher, S.W. Mills, G. Sancho, G.A. Johnson and H.S. Lenihan. 2002. Predation structures communities at deep-sea hydrothermal vents.\u00a0Ecological Monographs<\/em>\u00a072:365-382.\u00a0 Gulmann, L.K.,\u00a0L.S. Mullineaux<\/strong>\u00a0and H.L. Hunt. 2001. Effects of caging on retention of postlarval soft-shelled clams (Mya arenaria<\/em>).\u00a0Journal of Shellfish Research<\/em>. 20: 135-142.<\/p>\n Marsh, A. G.,\u00a0L. S. Mullineaux<\/strong>, C. M. Young and D. T. Manahan. 2001. Larval dispersal potential of the tubeworm\u00a0Riftia<\/em>\u00a0pachyptila\u00a0<\/em>at deep-sea hydrothermal vents.\u00a0Nature<\/em>\u00a0411: 77-80.\u00a0 Etter, R. and\u00a0L.S. Mullineaux<\/strong>. 2001. Deep-Sea Communities. In, Bertness, M.D., S.D. Gaines and M.E. Hay, eds.,\u00a0Marine Community Ecology<\/em>, p. 367-394, Sinauer Associates Inc. Sunderland, MA.<\/p>\n Mullineaux, L. S.<\/strong>, C. R. Fisher, C. H. Peterson and S. W. Schaeffer. 2000. Vestimentiferan tubeworm succession at hydrothermal vents:\u00a0<\/strong>use of biogenic cues to reduce habitat selection error?\u00a0Oecolog<\/em>ia<\/em>\u00a0123:275-284.\u00a0 Berntson, E. A., S. C. France and\u00a0L. S. Mullineaux<\/strong>. 1999. Phylogenetic relationships within the Class Anthozoa (Phylum Cnidaria) based on 18S ribosomal DNA sequence information.\u00a0Molecular Phylogenetics and Evolution<\/em>\u00a013(2): 417-433.\u00a0 Dunn, R.,\u00a0L. S. Mullineaux<\/strong>\u00a0and S. W. Mills. 1999. Resuspension of postlarval soft-shell clams\u00a0![](\"https:\/\/www2.whoi.edu\/site\/mullineauxlab\/wp-content\/uploads\/sites\/97\/2019\/10\/icon-link.png\"){kind=icon}
<\/a>\u00a0![\"SHERPARoMEO_whitebg\"](\"https:\/\/www2.whoi.edu\/site\/mullineauxlab\/wp-content\/uploads\/sites\/97\/2019\/10\/open_25.jpg\")
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