Jennifer McClain Counts Jill R. Bourque Nancy G. Prouty Brian Smith Sandra Brooke Steve W. Ross Carolyn Ruppel Amanda Demopoulos 2019 <p><span>Chemosynthetic environments support distinct&nbsp;benthic communities&nbsp;capable of utilizing reduced chemical compounds for nutrition. Hundreds of&nbsp;methane&nbsp;seeps have been documented along the U.S. Atlantic margin (USAM), and detailed investigations at a few seeps have revealed distinct environments containing&nbsp;mussels,&nbsp;microbial mats, authigenic carbonates, and soft&nbsp;sediments. The dominant mussel,&nbsp;</span><i>Bathymodiolus childressi</i><span>, contains methanotrophic&nbsp;endosymbionts&nbsp;but is also capable of&nbsp;filter feeding, and&nbsp;stable isotope&nbsp;analysis (SIA) of mussel-shell periostracum suggests that these mussels are mixotrophic, assimilating multiple food resources. However, it is unknown whether&nbsp;mixotrophy&nbsp;is widespread or varies spatially and temporally. We used SIA (δ</span>¹³<span>C, δ</span>¹⁵<span>N, and δ</span>³⁴<span>S) and an&nbsp;isotope&nbsp;mixing model (MixSIAR) to estimate resource contribution to&nbsp;</span><i>B. childressi</i><span>&nbsp;and characterize&nbsp;food webs&nbsp;at two seep sites (Baltimore Seep; 400 m and Norfolk Seep; 1500 m depths) along the USAM, and applied a linear mixed-effects model to explore the role of mussel&nbsp;population density&nbsp;and tissue type in influencing SIA variance. After controlling for location and temporal variation, isotopic variability was a function of proportion of live mussels present and tissue type. Isotopic differences were also spatially discrete, possibly reflecting variations in the underlying carbon source at the two sites. Low mussel δ</span>¹³<span>C values (∼−63‰) are consistent with a dependence on microbial methane. However, MixSIAR results revealed mixotrophy for mussels at both sites, implying a reliance on a mixture of methane and phytoplankton-derived&nbsp;particulate&nbsp;organic material. The mixing model results also reveal population density-driven patterns, suggesting that resource use is a function of live mussel abundance. Mussel isotopes differed by tissue type, with&nbsp;gill&nbsp;having the lowest δ</span>¹⁵<span>N values relative to muscle and mantle tissues. Based on mass balance equations, up to 79% of the dissolved&nbsp;inorganic carbon&nbsp;(DIC) of the pore fluids within the anaerobic&nbsp;oxidation&nbsp;of the methane zone is derived from methane and available to fuel upper slope deep-sea communities, such as fishes (</span><i>Dysommina rugosa</i><span>&nbsp;and&nbsp;</span><i>Symphurus nebulosus</i><span>),&nbsp;echinoderms&nbsp;(</span><i>Odontaster robustus</i><span>,&nbsp;</span><span><i>Echinus</i>&nbsp;wallisi</span><span>, and&nbsp;</span><i>Gracilechinus affinis</i><span>), and shrimp, (</span><i>Alvinocaris markensis</i><span>). The presence of these seeps thereby increases the overall trophic and community diversity of the USAM&nbsp;continental slope. Given the presence of hundreds of seeps within the&nbsp;region,&nbsp;primary production&nbsp;at seeps may serve as an important, yet unquantified, energy source to the USAM deep-sea environment.</span></p> application/pdf 10.1016/j.dsr.2019.04.002 en Elsevier Examination of Bathymodiolus childressi nutritional sources, isotopic niches, and food-web linkages at two seeps in the US Atlantic margin using stable isotope analysis and mixing models article