skip to main content
US FlagAn official website of the United States government
dot gov icon
Official websites use .gov
A .gov website belongs to an official government organization in the United States.
https lock icon
Secure .gov websites use HTTPS
A lock ( lock ) or https:// means you've safely connected to the .gov website. Share sensitive information only on official, secure websites.

Explore Research Products in the PAR
It may take a few hours for recently added research products to appear in PAR search results.


Title: Ocean deoxygenation and copepods: coping with oxygen minimum zone variability
Increasing deoxygenation (loss of oxygen) of the ocean, including expansion of oxygen minimum zones (OMZs), is a potentially important consequence of global warming. We examined present-day variability of vertical distributions of 23 calanoid copepod species in the Eastern Tropical North Pacific (ETNP) living in locations with different water column oxygen profiles and OMZ intensity (lowest oxygen concentration and its vertical extent in a profile). Copepods and hydrographic data were collected in vertically stratified day and night MOCNESS (Multiple Opening/Closing Net and Environmental Sensing System) tows (0–1000 m) during four cruises over a decade (2007– 2017) that sampled four ETNP locations: Costa Rica Dome, Tehuantepec Bowl, and two oceanic sites further north (21– 22 N) off Mexico. The sites had different vertical oxygen profiles: some with a shallow mixed layer, abrupt thermocline, and extensive very low oxygen OMZ core; and others with a more gradual vertical development of the OMZ (broad mixed layer and upper oxycline zone) and a less extensive OMZ core where oxygen was not as low. Calanoid copepod species (including examples from the genera Eucalanus, Pleuromamma, and Lucicutia) demonstrated different distributional strategies (implying different physiological characteristics) associated with this variability. We identified sets of species that (1) changed their vertical distributions and depth of maximum abundance associated with the depth and intensity of the OMZ and its oxycline inflection points; (2) shifted their depth of diapause; (3) adjusted their diel vertical migration, especially the nighttime upper depth; or (4) expanded or contracted their depth range within the mixed layer and upper part of the thermocline in association with the thickness of the aerobic epipelagic zone (habitat compression concept). These distribution depths changed by tens to hundreds of meters depending on the species, oxygen profile, and phenomenon. For example, at the lower oxycline, the depth of maximum abundance for Lucicutia hulsemannae shifted from  600 to  800 m, and the depth of diapause for Eucalanus inermis shifted from  500 to  775 m, in an expanded OMZ compared to a thinner OMZ, but remained at similar low oxygen levels in both situations. These species or life stages are examples of “hypoxiphilic” taxa. For the migrating copepod Pleuromamma abdominalis, its nighttime depth was shallow ( 20 m) when the aerobic mixed layer was thin and the low-oxygen OMZ broad, but it was much deeper ( 100 m) when the mixed layer and higher oxygen extended deeper; daytime depth in both situations was  300 m. Because temperature decreased with depth, these distributional depth shifts had metabolic implications. The upper ocean to mesopelagic depth range encompasses a complex interwoven ecosystem characterized by intricate relationships among its inhabitants and their environment. It is a critically important zone for oceanic biogeochemical and export processes and hosts key food web components for commercial fisheries. Among the zooplankton, there will likely be winners and losers with increasing ocean deoxygenation as species cope with environmental change. Changes in individual copepod species abundances, vertical distributions, and life history strategies may create potential perturbations to these intricate food webs and processes. Present-day variability provides a window into future scenarios and potential effects of deoxygenation.  more » « less
Award ID(s):
1459243 0526502
PAR ID:
10220708
Author(s) / Creator(s):
; ;
Date Published:
Journal Name:
Biogeosciences
Volume:
17
ISSN:
1726-4170
Page Range / eLocation ID:
2315-2339
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
More Like this
  1. ; ; ; ; ; (, Limnology and Oceanography)
    Abstract In the Eastern Tropical North Pacific Oxygen Minimum Zone (ETNP‐OMZ), fish larvae undergo development amidst highly variable dissolved oxygen environments. As OMZs expand, understanding the implications of low‐oxygen environments on fish development becomes increasingly relevant for fisheries management and ecosystem modeling. Using horizontal zooplankton tows to track five oxygen levels (oxic [200 μmol/kg], hypoxic [100 μmol/kg] suboxic [10 μmol/kg], anoxic [<1 μmol/kg], and deep [10 μmol/kg at ~ 1000 m depth]), this study analyzed the three‐dimensional distribution of fish larvae and adults across the ETNP‐OMZ. Results revealed a wide midwater anoxic core, extending from Costa Rica to Baja California, that was almost devoid of fish larvae (< 1 larvae/1000 m3). Early larval stages primarily inhabited the oxic and hypoxic levels above the core, while postflexion and transformation stages occurred across a wider oxygen gradient, including the deep level below the anoxic core. Epipelagic species (e.g.,Auxissp.) were predominantly found in the surface oxic level, whereas coastal‐demersal species (e.g.,Bregmaceros bathymaster,Ophidionspp.) were prevalent in the hypoxic level above the core. Meso‐bathypelagic species (e.g.,Diogenichthys laternatus,Cyclothonespp.) were present throughout the study area, including below the anoxic core as transformation larvae and juveniles. These findings indicate that a vertical expansion of anoxic waters in OMZs could further constrain the habitat of epipelagic species, while also affecting the ontogenic vertical movements of meso‐bathypelagic species. 
    more » « less
  2. ; ; ; (, Frontiers in marine science)
    null (Ed.)
    The Eastern Tropical North Pacific (ETNP) is a large, persistent, and intensifying oxygen minimum zone (OMZ) that accounts for almost half of the total area of global OMZs. Within the OMZ core (350–700 m depth), dissolved oxygen is typically near or below the analytical detection limit of modern sensors (10 nM). Steep oxygen gradients above and below the OMZ core lead to vertical structuring of microbial communities that also vary between particle-associated (PA) and free-living (FL) size fractions. Here, we use 16S amplicon sequencing (iTags) to analyze the diversity and distribution of prokaryotic populations between FL and PA size fractions and among the range of ambient redox conditions. The hydrographic conditions at our study area were distinct from those previously reported in the ETNP and other OMZs, such as the ETSP. Trace oxygen concentrations (0.35 mM) were present throughout the OMZ core at our sampling location. Consequently, nitrite accumulations typically reported for OMZ cores were absent as were sequences for anammox bacteria (Brocadiales genus Candidatus Scalindua), which are commonly found across oxic-anoxic boundaries in other systems. However, ammonia-oxidizing bacteria (AOB) and archaea (AOA) distributions and maximal autotrophic carbon assimilation rates (1.4 mM C d􀀀1) coincided with a pronounced ammonium concentration maximum near the top of the OMZ core. In addition, members of the genus Nitrospina, a dominant nitrite-oxidizing bacterial (NOB) clade were present suggesting that both ammonia and nitrite oxidation occur at trace oxygen concentrations. Analysis of similarity test (ANOSIM) and Non-metric Dimensional Scaling (nMDS) revealed that bacterial and archaeal phylogenetic representations were significantly different between size fractions. Based on ANOSIM and iTag profiles, composition of PA assemblages was less influenced by the prevailing depth-dependent biogeochemical regime than the FL fraction. Based on the presence of AOA, NOB and trace oxygen in the OMZ core we suggest that nitrification is an active process in the nitrogen cycle of this region of the ETNP OMZ. 
    more » « less
  3. ; ; ; ; ; (, Frontiers in Marine Science)
    Sergio Stefanni (Ed.)
    Zooplankton diversity in the deep “midnight zone” (>1000 m), where sunlight does not reach, remains largely unknown. Uncovering such diversity has been challenging because of the major difficulties in sampling deep pelagic fauna and identifying many (unknown) species that belong to these complex swimmer assemblages. In this study, we evaluated zooplankton diversity using two taxonomic marker genes: mitochondrial cytochrome oxidase subunit 1 (COI) and nuclear 18S ribosomal RNA (18S). We collected samples from plankton net tows, ranging from the surface to a depth of 5000 m above the Atacama Trench in the Southeast Pacific. Our study aimed to assess the zooplankton diversity among layers from the upper 1000 m to the ultra-deep abyssopelagic zone to test the hypothesis of decreasing diversity with depth resulting from limited carbon sources. The results showed unique, highly vertically structured communities within the five depth strata sampled, with maximal species richness observed in the upper bathypelagic layer (1000–2000 m). The high species richness of zooplankton (>750 OTUS) at these depths was higher than that found in the upper 1000 m. The vertical diversity trend exhibited a pattern similar to the well-known vertical pattern described for the benthic system. However, a large part of this diversity was either unknown (>50%) or could not be assigned to any known species in current genetic diversity databases. DNA analysis showed that the Calanoid copepods, mostly represented bySubeucalanus monachus, the Euphausiacea,Euphausia mucronata, and the halocypridade,Paraconchoecia dasyophthalma, dominated the community. Water column temperature, dissolved oxygen, particulate carbon, and nitrogen appeared to be related to the observed vertical diversity pattern. Our findings revealed rich and little-known zooplankton diversity in the deep sea, emphasizing the importance of further exploration of this ecosystem to conserve and protect its unique biota. 
    more » « less
  4. ; (, Biogeosciences)
    Abstract. Diel vertical migration (DVM) can enhance the verticalflux of carbon (C), and so contributes to the functioning of the biologicalpump in the ocean. The magnitude and efficiency of this active transport ofC may depend on the size and taxonomic structure of the migrant zooplankton.However, the impact that a variable community structure can have onzooplankton-mediated downward C flux has not been properly addressed. Thistaxonomic effect may become critically important in highly productiveeastern boundary upwelling systems (EBUSs), where high levels of zooplanktonbiomass are found in the coastal zone and are composed by a diverse communitywith variable DVM behavior. In these systems, presence of a subsurfaceoxygen minimum zone (OMZ) can impose an additional constraint to verticalmigration and so influence the downward C export. Here, we address theseissues based on a vertically stratified zooplankton sampling at threestations off northern Chile (20–30∘ S) duringNovember–December 2015. Automated analysis of zooplankton composition andtaxa-structured biomass allowed us to estimate daily migrant biomass by taxaand their amplitude of migration. We found that a higher biomass aggregatesabove the oxycline, associated with more oxygenated surface waters and thiswas more evident upon a more intense OMZ. Some taxonomic groups, however,were found closely associated with the OMZ. Most taxa were able to performDVM in the upwelling zone withstanding severe hypoxia. Also, strongmigrants, such as eucalanid copepods and euphausiids, can exhibit a largemigration amplitude (∼500 m), remaining either temporarily orpermanently within the core of the OMZ and thus contributing to the releaseof C below the thermocline. Our estimates of DVM-mediated C flux suggestedthat a mean migrant biomass of ca. 958 mg C m−2 d−1 may contributewith about 71.3 mg C m−2 d−1 to the OMZ system through respiration,mortality and C excretion at depth, accounting for ca. 4 % of the netprimary production, and so implies the existence of an efficient mechanismto incorporate freshly produced C into the OMZ. This downward C fluxmediated by zooplankton is however spatially variable and mostly dependenton the taxonomic structure due to variable migration amplitude and DVMbehavior. 
    more » « less
  5. ; ; ; ; ; (, Biogeosciences)
    Abstract. Microfossil assemblages provide valuable records to investigatevariability in continental margin biogeochemical cycles, including dynamicsof the oxygen minimum zone (OMZ). Analyses of modern assemblages acrossenvironmental gradients are necessary to understand relationships betweenassemblage characteristics and environmental factors. Five cores wereanalyzed from the San Diego margin (32∘42′00′′ N, 117∘30′00′′ W; 300–1175 m water depth) for core top benthic foraminiferalassemblages to understand relationships between community assemblages andspatial hydrographic gradients as well as for down-core benthic foraminiferalassemblages to identify changes in the OMZ through time. Comparisons ofbenthic foraminiferal assemblages from two size fractions (63–150 and>150 µm) exhibit similar trends across the spatial and environmental gradient or in some cases exhibit more pronouncedspatial trends in the >150 µm fraction. A range of speciesdiversity exists within the modern OMZ (1.910–2.586 H, Shannon index),suggesting that diversity is not driven by oxygenation alone. We identifytwo hypoxic-associated species (B. spissa and U. peregrina), one oxic-associated species (G. subglobosa) andone OMZ edge-associated species (B. argentea). Down-core analysis of indicator speciesreveals variability in the upper margin of the OMZ (528 m water depth) whilethe core of the OMZ (800 m) and below the OMZ (1175 m) remained stable inthe last 1.5 kyr. We document expansion of the upper margin of the OMZbeginning 400 BP on the San Diego margin that is synchronous with otherregional records of oxygenation. 
    more » « less
  • Citation Formats
  • MLA
  • APA
  • Chicago
  • BibTeX
  • Save / Share this Record
  • Send to Email