Fine Scale Assemblage Structure of Benthic Invertebrate Megafauna on the North Pacific Seamount Mokumanamana

Morgan, Nicole B.; Goode, Savannah L.; Roark, E. Brendan; Baco, Amy R.

doi:10.3389/fmars.2019.00715

Cited by 24 publications

(38 citation statements)

References 94 publications

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“…Our observations suggest that the major large-scale drivers of seamount benthic assemblage structure in the South Atlantic include latitude, depth, longitude, FBPI, and slope (Table 2). This concurs with the current understanding that variables correlated with latitude and depth are strong drivers of epifaunal community composition on seamounts (McClain and Lundsten, 2015;Du Preez et al, 2016;De la Torriente et al, 2018Morgan et al, 2019), as well as in other deep-sea ecosystems (Rowe and Menzies, 1969;Rex, 1981;Billett et al, 2001;Ruhl and Smith, 2004). Latitude in itself is not ecologically relevant, but it acts as a proxy for other variables.…”

Section: Environmental Driverssupporting

confidence: 88%

“…Contrastingly, the EEZs of Ascension and St. Helena are characterized by less complex water mass structures, with less variability in water mass characteristics, potentially driving less divergence in faunal communities (Peterson and Stramma, 1991). Topographic variables including slope and bathymetric position index (BPI) are, as our results support, often identified as key drivers of benthic assemblages in the deep sea, both at the inter-and intra-seamount level (Boschen et al, 2015;Morgan et al, 2019). Slope and BPI can be used to infer the geomorphology of a region (Greene et al, 1999), which in turn can provide insight into the hydrodynamics, and thus substrate types observed within an area (Stephens and Diesing, 2015).…”

Section: Environmental Driversmentioning

confidence: 57%

“…There are many environmental factors that can influence both the composition and distribution of benthic assemblages on seamounts and oceanic islands, as well as their overall species richness. These include, but are not limited to, depth (Boschen et al, 2015), biogeographic region (McClain et al, 2009), local hydrodynamic regime (Levin and Thomas, 1989), surface productivity (Hernández-León et al, 2020;Bridges et al, in review), particulate organic carbon (POC) flux to depth (Morgan et al, 2019), temperature (O'Hara and Tittensor, 2010;Woolley et al, 2016), and topography and substrate type (Lundsten et al, 2009). In the South Atlantic, O'Hara et al (2010) identified distance from shore, temperature, dissolved oxygen and POC as important environmental predictors of assemblage composition along the VTC.…”

Section: Introductionmentioning

confidence: 99%

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Benthic Assemblage Composition of South Atlantic Seamounts

et al. 2021

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Seamounts and oceanic islands rise from the seafloor and provide suitable habitat for a diverse range of biological assemblages including Vulnerable Marine Ecosystems (VMEs). Whilst they have been the focus of some work globally, there has been little description of the biological and physical environments of seamounts in the South Atlantic Ocean. In this study, we characterized benthic assemblage composition from 13 seamounts and oceanic islands spanning 8–40°S within the exclusive economic zones (EEZs) of Ascension Island, Saint Helena and Tristan da Cunha. Drop camera imagery was collected between 170 and 1000 m. All fauna present in images were identified and quantified, and multivariate statistics were used to describe biological assemblages and identify their environmental drivers. Benthic communities of temperate regions (Tristan da Cunha archipelago) were shown to be distinct from those found in the tropics, with latitude and depth identified as key environmental drivers of assemblage composition. Our results are consistent with the current understanding of the biogeography of the South Atlantic, both in terms of the distinction between tropical and temperate regions, and the influence of depth and water mass structure on assemblage distribution. Faunal assemblages are similar to those observed in the North Atlantic in terms of functional groups. VMEs are present within the EEZs of all three territories and are potentially protected from some threats by large marine protected areas (MPAs). Our imagery, data and analyses provide a baseline for south Atlantic seamounts so that future monitoring can establish whether existing protected status is sufficient to conserve both unique biodiversity and considerable potential for vital ecosystem services.

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Section: Environmental Driverssupporting

confidence: 88%

Section: Environmental Driversmentioning

confidence: 57%

Section: Introductionmentioning

confidence: 99%

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Benthic Assemblage Composition of South Atlantic Seamounts

et al. 2021

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“…Features providing positive elevation above the seabed, such as seamounts, are common on abyssal plains and specifically in the far western and eastern areas of the CCZ (Yesson et al, 2011;Wedding et al, 2013;Harris et al, 2014;Washburn et al, 2021a). Large variations in seabed environmental conditions found on seamounts, particularly those related to substrate and organic matter availability, influence the benthic communities present (Fock et al, 2002;Piepenburg and Muller, 2004;Samadi et al, 2007;Clark et al, 2009;McClain et al, 2009;Bo et al, 2011;Williams et al, 2011Williams et al, , 2015Boschen et al, 2015;Rogers, 2018;Morgan et al, 2019;Cuvelier et al, 2020;Jones et al, in review). Current speeds are enhanced and directions altered around seamounts (Genin et al, 1986), resulting in enhancements to suspended particle flux and locally deposited organic matter (Kiriakoulakis et al, 2009;Vilas et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Megafaunal Ecology of the Western Clarion Clipperton Zone

et al. 2021

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The Clarion Clipperton Zone (CCZ) is a vast area of the central Pacific Ocean where the abyssal seabed is a focus for future polymetallic nodule mining. Broad-scale environmental gradients occur east-to-west across the CCZ seabed, including organic matter supply and nodule abundance, factors that influence benthic faunal community structure and function. A network of protected areas across the CCZ, called Areas of Particular Environmental Interest (APEIs), has been designated to cover this variation. Most previous studies of the benthic environment and megafaunal communities have focussed on the eastern CCZ, leaving the impact of these large-scale gradients unexamined and the network design untested. Seamounts are a further source of heterogeneity in the region. We examined the benthic megafaunal ecology of three APEIs in the western CCZ, spanning a range of environmental conditions. We used a combination of seabed photography and direct sampling to assess the environment and megafauna on the soft sediment habitats on the abyssal plain in three APEIs, and seamounts in two of those APEIs. We found that environmental conditions on abyssal plains differed between the three APEIs in terms of water depth, nodule abundance and coverage, sediment particle size distribution, and estimated organic matter flux. Megafauna were low density and high diversity, with few common morphotypes between sites and many morphotypes being observed only once. Xenophyophores dominated the assemblages. The density and diversity of invertebrates were greater at the sites with lower organic matter inputs and greater nodule abundance. Seamounts in the same APEIs were nodule-free and had coarser sediments than on the plain. Invertebrate megafaunal diversity was lower on the seamounts than on the plains, and most morphotypes recorded on the seamounts were only found on seamounts. Low morphotype overlap also suggests little connectivity between APEIs, and between seamounts and adjacent abyssal plains. Our results provide the first evaluation of the seabed habitats and megafaunal ecology in the western CCZ, highlighting environmental gradients that influence benthic communities, and are important for evaluating the design of the network of protected areas.

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“…These organisms are called habitat-forming species and are characterized by being small-scale engineers of autogenous ecosystems. These organisms, and the biogenic structures they produce, contribute to increasing spatial complexity in soft-sediment benthic systems 25 , promoting spatial heterogeneity on seamounts 26 , but they are often easily overlooked because seamounts are sampled at much more general spatial scales 26 . In recent years, the importance of sampling at smaller scales has been accentuated with the understanding that the characteristics of the bottom and the presence of habitat-forming species increases the heterogeneity of the habitat and fulfill the function of a structural habitat 27 .…”

Section: Introductionmentioning

confidence: 99%

First description of deep benthic habitats and communities of oceanic islands and seamounts of the Nazca Desventuradas Marine Park, Chile

Tapia-Guerra

Mechó

Easton

et al. 2021

Sci Rep

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Seamounts and oceanic islands of the Chilean Exclusive Economic Zone at the intersection of the Nazca and Salas y Gómez ridges lie within one of the least explored areas in the world. The sparse information available, mainly for seamounts outside Chilean jurisdiction and shallow-water fauna of the Desventuradas Islands, suggests that the area is a hotspot of endemism. This apparent uniqueness of the fauna motivated the creation of the large Nazca-Desventuradas Marine Park (NDMP, ~ 300,000 km2) around the small islands San Felix and San Ambrosio in 2015. We report for the first time a detailed description of benthic microhabitats (i.e., centimeter to meter scale), macrohabitats (i.e., meter to kilometer-scale) and associated megafauna within the NDMP. Descriptions were based on analysis of fauna collected by trawling and ROV video observations from ~ 50 to 370 m depth. Rocky, coarse sand and silty sediment bottom habitats were observed at island slopes. In contrast, rocky and coarse sandy bottom habitats with a predominance of rhodoliths, thanatocoenosis, and other biogenic components were observed at seamounts. Mobile fauna and predators dominated the oceanic islands and nearby seamounts, whereas seamounts farther from the islands were dominated by sessile and hemisessile fauna that were mainly suspension and deposit feeders. Based on the register of 118 taxonomic units, our results provide an expanded and updated baseline for the benthic biodiversity of NDMP habitats, which seemed pristine, without evidence of trawling or anthropogenic debris.

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Fine Scale Assemblage Structure of Benthic Invertebrate Megafauna on the North Pacific Seamount Mokumanamana

Cited by 24 publications

References 94 publications

Benthic Assemblage Composition of South Atlantic Seamounts

Benthic Assemblage Composition of South Atlantic Seamounts

Megafaunal Ecology of the Western Clarion Clipperton Zone

First description of deep benthic habitats and communities of oceanic islands and seamounts of the Nazca Desventuradas Marine Park, Chile

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