Abstract. Zooplankton play an important role in global biogeochemistry and their secondary production supports valuable fisheries of the world's oceans. Currently, zooplankton abundances cannot be estimated using remote sensing techniques. Hence, coupled physical-biogeochemical models (PBMs) provide an important tool for studying zooplankton on regional and global scales. However, evaluating the accuracy of zooplankton abundance estimates from PBMs has been a major challenge as a result of sparse observations. In this study, we configure a PBM for the Gulf of Mexico (GoM) from 1993–2012 and validate the model against an extensive combination of in situ biomass and rate measurements including total mesozooplankton biomass, size-fractionated mesozooplankton biomass and grazing rates, microzooplankton specific grazing rates, surface chlorophyll, deep chlorophyll maximum depth, phytoplankton specific growth rates, and net primary production. Spatial variability in mesozooplankton biomass climatology observed in a multi-decadal database for the northern GoM is well resolved by the model with a statistically significant (p
Abstract. Zooplankton play an important role in global biogeochemistry, and their
secondary production supports valuable fisheries of the world's oceans.
Currently, zooplankton standing stocks cannot be estimated using remote
sensing techniques. Hence, coupled physical–biogeochemical models (PBMs)
provide an important tool for studying zooplankton on regional and global
scales. However, evaluating the accuracy of zooplankton biomass estimates
from PBMs has been a major challenge due to sparse observations. In this
study, we configure a PBM for the Gulf of Mexico (GoM) from 1993 to 2012 and
validate the model against an extensive combination of biomass and rate
measurements. Spatial variability in a multidecadal database of
mesozooplankton biomass for the northern GoM is well resolved by the model
with a statistically significant (p < 0.01) correlation of 0.90.
Mesozooplankton secondary production for the region averaged 66±8×109 kg C yr−1, equivalent to ∼10 % of
net primary production (NPP), and ranged from 51 to 82×109 kg C yr−1, with higher secondary production inside cyclonic eddies and
substantially reduced secondary production in anticyclonic eddies. Model
results from the shelf regions suggest that herbivory is the dominant
feeding mode for small mesozooplankton (< 1 mm), whereas larger mesozooplankton are primarily carnivorous. In open-ocean oligotrophic
waters, however, both mesozooplankton groups show proportionally greater
reliance on heterotrophic protists as a food source. This highlights an
important role of microbial and protistan food webs in sustaining
mesozooplankton biomass in the GoM, which serves as the primary food source
for early life stages of many commercially important fish species, including
tuna.
Globally, tunas are among the most valuable fish stocks, but are also inherently difficult to monitor and assess. Samples of larvae of Western Atlantic bluefin tuna Thunnus thynnus (Linnaeus, 1758) from standardized annual surveys in the northern Gulf of Mexico provide a potential source of “offspring” for close-kin mark-recapture (CKMR) estimates of abundance. However, the spatial patchiness and highly skewed numbers of larvae per tow suggest sampled larvae may come from a small number of parents, compromising the precision of CKMR. We used high throughput genomic profiling to study sibship within and among larval tows from the 2016 standardized Gulf-wide survey compared to targeted sampling carried out in 2017. Full- and half-siblings were found within both years, with 12% of 156 samples in 2016 and 56% of 317 samples in 2017 having at least one sibling. There were also two pairs of cross cohort half-siblings. Targeted sampling increased the number of larvae collected per sampling event but resulted in a higher proportion of siblings. The combined effective sample size across both years was about 75% of the nominal size, indicating that Gulf of Mexico larval collections could be a suitable source of juveniles for CKMR in Western Atlantic bluefin tuna.
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