Abstract
The recovery of top predators is thought to have cascading effects on vegetated ecosystems and their geomorphology1,2, but the evidence for this remains correlational and intensely debated3,4. Here we combine observational and experimental data to reveal that recolonization of sea otters in a US estuary generates a trophic cascade that facilitates coastal wetland plant biomass and suppresses the erosion of marsh edges—a process that otherwise leads to the severe loss of habitats and ecosystem services5,6. Monitoring of the Elkhorn Slough estuary over several decades suggested top-down control in the system, because the erosion of salt marsh edges has generally slowed with increasing sea otter abundance, despite the consistently increasing physical stress in the system (that is, nutrient loading, sea-level rise and tidal scour7,8,9). Predator-exclusion experiments in five marsh creeks revealed that sea otters suppress the abundance of burrowing crabs, a top-down effect that cascades to both increase marsh edge strength and reduce marsh erosion. Multi-creek surveys comparing marsh creeks pre- and post-sea otter colonization confirmed the presence of an interaction between the keystone sea otter, burrowing crabs and marsh creeks, demonstrating the spatial generality of predator control of ecosystem edge processes: densities of burrowing crabs and edge erosion have declined markedly in creeks that have high levels of sea otter recolonization. These results show that trophic downgrading could be a strong but underappreciated contributor to the loss of coastal wetlands, and suggest that restoring top predators can help to re-establish geomorphic stability.
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References
Estes, J. A. et al. Trophic downgrading of planet Earth. Science 333, 301–306 (2011).
Ren, L., Jensen, K., Porada, P. & Mueller, P. Biota‐mediated carbon cycling—a synthesis of biotic‐interaction controls on blue carbon. Ecol. Lett. 25, 521–540 (2022).
Foster, M. S. & Schiel, D. R. Loss of predators and the collapse of southern California kelp forests (?): alternatives, explanations and generalizations. J. Exp. Mar. Biol. Ecol. 393, 59–70 (2010).
Kauffman, M. J., Brodie, J. F. & Jules, E. S. Are wolves saving Yellowstone’s aspen? A landscape-level test of a behaviorally mediated trophic cascade. Ecology 91, 2742–2755 (2010).
Coverdale, T. C. et al. Indirect human impacts reverse centuries of carbon sequestration and salt marsh accretion. PLoS One 9, e93296 (2014).
Silliman, B. R. et al. Field experiments and meta-analysis reveal wetland vegetation as a crucial element in the coastal protection paradigm. Curr. Biol. 29, 1800–1806 (2019).
Wasson, K. et al. Eutrophication decreases salt marsh resilience through proliferation of algal mats. Biol. Conserv. 212, 1–11 (2017).
Hughes, B. B. et al. Recovery of a top predator mediates negative eutrophic effects on seagrass. Proc. Natl Acad. Sci. USA 110, 15313–15318 (2013).
Van Dyke, E. & Wasson, K. Historical ecology of a central California estuary: 150 years of habitat change. Estuaries 28, 173–189 (2005).
Ripple, W. J. et al. Status and ecological effects of the world’s largest carnivores. Science 343, 1241484 (2014).
McCauley, D. J. et al. Marine defaunation: animal loss in the global ocean. Science 347, 1255641 (2015).
Silliman, B. R. et al. Are the ghosts of nature’s past haunting ecology today? Curr. Biol. 28, R532–R537 (2018).
Marshall, K. N., Stier, A. C., Samhouri, J. F., Kelly, R. P. & Ward, E. J. Conservation challenges of predator recovery. Conserv. Lett. 9, 70–78 (2016).
Ripple, W. J., Larsen, E. J., Renkin, R. A. & Smith, D. W. Trophic cascades among wolves, elk and aspen on Yellowstone National Park’s northern range. Biol. Conserv. 102, 227–234 (2001).
Estes, J. A. & Palmisano, J. F. Sea otters: their role in structuring shore communities. Science 185, 1058–1060 (1974).
Gaskins, L. C., Paxton, A. B. & Silliman, B. R. Megafauna in salt marshes. Front. Mar. Sci. 7, 561476 (2020).
Barbier, E. B. et al. The value of estuarine and coastal ecosystem services. Ecol. Monogr. 81, 169–193 (2011).
Lotze, H. K. et al. Depletion, degradation, and recovery potential of estuaries and coastal seas. Science 312, 1806–1809 (2006).
Gedan, K. B. & Silliman, B. R. in Human Impacts on Salt Marshes: A Global Perspective (eds Silliman, B. R. et al.) 253–265 (Univ. California Press, 2009).
Silliman, B. R., Bertness, M. D. & Grosholz, E. D. (eds) Human Impacts on Salt Marshes: A Global Perspective (Univ. California Press, 2009).
Deegan, L. A. et al. Coastal eutrophication as a driver of salt marsh loss. Nature 490, 388–392 (2012).
Gutiérrez, J. L. et al. The contribution of crab burrow excavation to carbon availability in surficial salt-marsh sediments. Ecosystems 9, 647–658 (2006).
Iribarne, O., Bortolus, A. & Botto, F. Between-habitat differences in burrow characteristics and trophic modes in the southwestern Atlantic burrowing crab Chasmagnathus granulata. Mar. Ecol. Prog. Ser. 155, 137–145 (1997).
Holdredge, C., Bertness, M. D. & Altieri, A. H. Role of crab herbivory in die-off of New England salt marshes. Conserv. Biol. 23, 672–679 (2009).
He, Q. & Silliman, B. R. Consumer control as a common driver of coastal vegetation worldwide. Ecol. Monogr. 86, 278–294 (2016).
Silliman, B. R., van de Koppel, J., Bertness, M. D., Stanton, L. E. & Mendelssohn, I. A. Drought, snails, and large-scale die-off of southern U.S. salt marshes. Science 310, 1803–1806 (2005).
Mayer, K. A. et al. Surrogate rearing a keystone species to enhance population and ecosystem restoration. Oryx 55, 535–545 (2021).
Hughes, B. B., Haskins, J., Wasson, K. & Watson, E. Identifying factors that influence expression of eutrophication in a central California estuary. Mar. Ecol. Prog. Ser. 439, 31–43 (2011).
Broenkow, W. W. & Breaker, L. C. in Estuaries and Coastal Zones—Dynamics and Response to Environmental Changes (eds. Pan, J. & Devlin, A.) https://doi.org/10.5772/intechopen.88671 (IntechOpen, 2019).
Costa, D. P. & Kooyman, G. L. Oxygen consumption, thermoregulation, and the effect of fur oiling and washing on the sea otter, Enhydra lutris. Can. J. Zool. 60, 2761–2767 (1982).
Beheshti, K. M., Wasson, K., Angelini, C., Silliman, B. R. & Hughes, B. B. Long‐term study reveals top‐down effect of crabs on a California salt marsh. Ecosphere 12, e03703 (2021).
Altieri, A. H., Bertness, M. D., Coverdale, T. C., Herrmann, N. C. & Angelini, C. A trophic cascade triggers collapse of a salt-marsh ecosystem with intensive recreational fishing. Ecology 93, 1402–1410 (2012).
Escapa, M., Minkoff, D. R., Perillo, G. M. E. & Iribarne, O. Direct and indirect effects of burrowing crab Chasmagnathus granulatus activities on erosion of southwest Atlantic Sarcocornia-dominated marshes. Limnol. Oceanogr. 52, 2340–2349 (2007).
Wasson, K. et al. Pattern and scale: evaluating generalities in crab distributions and marsh dynamics from small plots to a national scale. Ecology 100, e02813 (2019).
Brown, J. A. Using the chemical composition of otoliths to evaluate the nursery role of estuaries for English sole Pleuronectes vetulus populations. Mar. Ecol. Prog. Ser. 306, 269–281 (2006).
Harvey, J. T. & Connors, S. in Changes in a California Estuary: A Profile of Elkhorn Slough (eds Caffrey, J. et al.) 187–214 (Elkhorn Slough Foundation, 2002).
Edwards, M. S. Estimating scale-dependency in disturbance impacts: El Niños and giant kelp forests in the northeast Pacific. Oecologia 138, 436–447 (2004).
Raposa, K. B. et al. Assessing tidal marsh resilience to sea-level rise at broad geographic scales with multi-metric indices. Biol. Conserv. 204, 263–275 (2016).
Fountain, M., Endris, C., Woolfolk, A. & Wasson, K. Salt Marsh Conservation, Restoration and Enhancement Opportunities in and Around Elkhorn Slough in the Face of Sea Level Rise. Elkhorn Slough Technical Report Series 2020: 2 (2020).
Mariotti, G. & Fagherazzi, S. A numerical model for the coupled long-term evolution of salt marshes and tidal flats. J. Geophys. Res. 115, F01004 (2010).
Crotty, S. M. et al. Sea-level rise and the emergence of a keystone grazer alter the geomorphic evolution and ecology of southeast US salt marshes. Proc. Natl Acad. Sci. USA 117, 17891–17902 (2020).
Malzone, C. M. Tidal Scour and its Relation to Erosion and Sediment Transport in Elkhorn Slough. MSc thesis, San José State Univ. (1999).
Silliman, B. R. & Bertness, M. D. A trophic cascade regulates salt marsh primary production. Proc. Natl Acad. Sci. USA 99, 10500–10505 (2002).
Silliman, B. R., Hughes, B. B., Zhang, Y. S. & He, Q. in Effective Conservation Science: Data Not Dogma (eds Kareiva, P. et al.) 173–179 (Oxford Univ. Press, 2018).
Canepuccia, A. D., Fanjul, M. S. & Iribarne, O. O. Global distribution and richness of terrestrial mammals in tidal marshes. Divers. Distrib. 29, 598–612 (2023).
Silliman, B. R. et al. Facilitation shifts paradigms and can amplify coastal restoration efforts. Proc. Natl Acad. Sci. USA 112, 14295–14300 (2015).
Renzi, J. J., He, Q. & Silliman, B. R. Harnessing positive species interactions to enhance coastal wetland restoration. Front. Ecol. Evol. 7, 131 (2019).
Eby, R., Scoles, R., Hughes, B. B. & Wasson, K. Serendipity in a salt marsh: detecting frequent sea otter haul outs in a marsh ecosystem. Ecology 98, 2975–2977 (2017).
Burkholder, J. M., Tomasko, D. A. & Touchette, B. W. Seagrasses and eutrophication. J. Exp. Mar. Biol. Ecol. 350, 46–72 (2007).
Beheshti, K., Endris, C., Goodwin, P., Pavlak, A. & Wasson, K. Burrowing crabs and physical factors hasten marsh recovery at panne edges. PLoS One 17, e0249330 (2022).
Tinker, M. T. & Hatfield, B. B. Annual California Sea Otter Census—1985–2014 Spring Census Summary. USGS Data Release https://doi.org/10.5066/F7445JQ5 (2018).
Tinker, M. T. et al. Incorporating diverse data and realistic complexity into demographic estimation procedures for sea otters. Ecol. Appl. 16, 2293–2312 (2006).
Tinker, M. T., Doak, D. F. & Estes, J. A. Using demography and movement behavior to predict range expansion of the Southern Sea Otter. Ecol. Appl. 18, 1781–1794 (2008).
Hatfield, B. B., Yee, J. L., Kenner, M. C., Tomoleoni, J. A. & Tinker, M. T. California Sea Otter (Enhydra lutris nereis) Census Results, Spring 2018. USGS Data Series 1097 https://doi.org/10.3133/ds1097 (2018).
Tinker, M. T. & Hatfield, B. California Sea Otter (Enhydra lutris nereis) Census Results, Spring 2017. USGS Data Series 1018 https://doi.org/10.3133/ds1018 (2017).
Tinker, M. T. et al. Structure and mechanism of diet specialisation: testing models of individual variation in resource use with sea otters. Ecol. Lett. 15, 475–483 (2012).
Tinker, M. T. et al. The Population Status and Ecology of Sea Otters in Elkhorn Slough, California (California Coastal Conservancy and US Fish and Wildlife Service, 2018).
Drury, K. L. S. & Fabian Candelaria, J. Using model identification to analyze spatially explicit data with habitat, and temporal, variability. Ecol. Modell. 214, 305–315 (2008).
Worton, B. J. Kernel methods for estimating the utilization distribution in home-range studies. Ecology 70, 164–168 (1989).
ArcGIS Desktop: Release 10 (Environmental Systems Research Institute, 2011).
Tinker, M. T., Bentall, G. & Estes, J. A. Food limitation leads to behavioral diversification and dietary specialization in sea otters. Proc. Natl Acad. Sci. USA 105, 560–565 (2008).
Estes, J. A., Riedman, M. L., Staedlert, M. M. & Tinkert, M. T. Individual variation in prey selection by sea otters: patterns, causes and implications. J. Anim. Ecol. 72, 144–155 (2003).
ArcGIS Desktop: Release 10.7 (Environmental Systems Research Institute, 2019).
Borer, E. T. et al. Herbivores and nutrients control grassland plant diversity via light limitation. Nature 508, 517–520 (2014).
Daleo, P. et al. Environmental heterogeneity modulates the effect of plant diversity on the spatial variability of grassland biomass. Nat. Commun. 14, 1809 (2023).
Dee, L. E. et al. Clarifying the effect of biodiversity on productivity in natural ecosystems with longitudinal data and methods for causal inference. Nat. Commun. 14, 2607 (2023).
Sanchez, M. L. Using Camera Traps and Machine Learning as Monitoring Tool for the Recovering Southern Sea Otter (Enhydra lutris nereis) in a Recolonized Ecosystem. MSc thesis, Sonoma State Univ. (2021).
Wood, S. mgcv: Mixed GAM computation vehicle with automatic smoothness estimation. R package version 1.9-0 https://CRAN.R-project.org/package=mgcv (2022).
R Core Team R: A Language and Environment for Statistical Computing (R Foundation for Statistical Computing, 2023); http://www.R-project.org/.
Wood, S. N. Generalized Additive Models: An Introduction with R (Chapman and Hall/CRC, 2017).
Guo, J. et al. rstan: R interface to Stan. R package version 2.32.3 https://CRAN.R-project.org/package=rstan (2022).
Brooks, M. E. et al. glmmTMB balances speed and flexibility among packages for zero-inflated generalized linear mixed modeling. R J. 9, 378–400 (2017).
Acknowledgements
B.B.H. was funded through the David H. Smith Research Conservation Fellowship and Cedar Tree Foundation and the Rebecca and Steve Sooy Fellowship in Marine Mammals; C.A. was supported by an NSF CAREER award (1652628); and B.R.S. was supported by the Stolarz Foundation, the Lenfest Ocean Program, Foundation of the Carolinas and an NSF CAREER award. We thank P. Daleo and M. Hensel for constructive comments on this manuscript. We also thank the staff and volunteers of the Monterey Bay Aquarium Sea Otter Program and Elkhorn Slough National Estuarine Research Reserve who contributed to sea otter abundance and foraging-data collection and experimental data collection. We dedicate this paper to J. Estes, whose pioneering career and mentorship were crucial to developing this research.
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B.B.H. conceived the idea, which was enhanced by discussions with B.R.S. B.B.H., B.R.S., K.M.B. and C.A. designed salt marsh and crab surveys and experiments. B.B.H. and K.M.B. collected salt marsh and crab data. C.E. and L.M. collected and analysed data for salt marsh and creek aerial data. M.T.T., M. Sanchez, M. Staedler, S.E. and J.A.T. designed and collected sea otter monitoring data. B.B.H., M.T.T. and S.C.A. analysed sea otter data. B.B.H. ran all other statistical analysis with guidance from B.R.S., S.C.A. and C.A. All authors contributed to editing and writing.
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Extended data figures and tables
Extended Data Fig. 1 Results from a three-year sea otter-exclusion experiment testing the effects of otters and shore crabs on salt marsh vegetation.
a–d, Response variables measured are crab burrow density (a), bulk density (ww = wet weight) (b), sediment accretion (dw = dry weight) (c), and crab burrows (d). Crab densities (Extended Data Figs. 1 and 2) were sampled over three years (measured in number of shore crab per 2 m2), the other response variables were sampled in year 2. The bars represent the mean, points are the data, and lines represent the differences in paired blocks (with the exception of d, which compares crab burrows in procedural controls and plots (n = 5) within the same creek, but are not paired). *P < 0.05 for cage treatments using linear mixed models (continuous response data) and generalized linear mixed models (count response data) with assigning paired experimental plots (block) and site (n = 5) as random factors. NS, not significant.
Extended Data Fig. 2 Changes in shore crab densities when compared to the first survey in May 2014.
a, Open circles represent counts for individual plots and lines connect the same plots through time. Solid circles and vertical line segments represent the estimated mean and 95% CI for each sampling event. There was a small but significantly greater change in density of shore crab in No Otter plots compared to Otter plots when accounting for time (P = 0.047). b,c, Smoothers for day since start (b) and month used in the GAMM (c). Note: Final shore crab densities were analysed in December 2016 (see Extended Data Fig. 1a).
Extended Data Fig. 3 Example of camera-trap data.
Here a sea otter is consuming a shore crab from our Procedural Control plots in one of the experimental creeks (top white box). The bottom image is a zoomed-in screenshot of the same foraging bout highlighted in the box with the sea otter floating over the Procedural Control. Shore crabs are the only known prey item for sea otters in pickleweed marshes. Photo credit: M. Sanchez.
Extended Data Fig. 4 Results of a shore crab feeding experiment on pickleweed aboveground and belowground biomass.
Each point represents a measurement of single-crab consumption (in fresh weight, fw) over a 72-h period. Controls had vegetation without crabs. Letters indicate significant differences (P < 0.05) using independent samples t-tests.
Extended Data Fig. 5 Results of a survey examining the relationship between shore crabs and sea otters in tidal creeks, and leverage analysis between sea otter crab consumption and erosion.
a, Results from a 2015 survey of crab densities on the marsh edge. Sea otter density was estimated using survey data from 2013−2015 in each replicate creek. Each point represents a mean along 100-m transects (n = 5 plots per creek) from 13 tidal creeks; grey areas represent ±95% CI, *P < 0.05. b, Leverage analysis comparing the influence of each creek on the slope of the relationship between sea otter crab consumption and erosion.
Extended Data Fig. 6 Modelling erosion rates.
Left, erosion rate modelled as a function of time with a GAM. Individual lines represent 200 samples from the posterior distribution. Right, each posterior sample is converted to a starting creek width value of 1. The vertical lines indicate the year the second-stage model started (1992).
Extended Data Fig. 7 Illustration of the modelled reduction in the base rate of creek erosion as the number of otters increases.
The shape follows a Gompertz curve defined as implied by (1 − exp(−bO)), in which O represents the number of sea otters and b represents an estimated parameter. The line and ribbon indicate the median and 95% credible interval.
Extended Data Fig. 8 Posterior parameter distributions from modelling relative creek width as a function of a base rate of widening and an adjustment given the abundance of sea otters.
This model is referred to as the ‘second-stage model’ in the Methods. In this figure, the model is fitted to mean values from the first-stage model (that is, not propagating uncertainty) as an illustration. The full model used for inference is fitted to 200 samples from the first-stage model. Histograms on the diagonal show the distribution for an individual parameter and the off-diagonals show the bivariate distribution for pairs of parameters. The parameter ‘r’ is the base rate of widening, ‘a’ is the relative channel width in the first year, ‘b’ is the maximum reduction in widening per otter and ‘sigma’ is the lognormal observation error standard deviation.
Extended Data Fig. 9 Histograms of b and r posterior distributions from the second-stage model (while propagating uncertainty from the first model).
The parameter b represents the maximum reduction in widening per otter and r represents the base rate of widening.
Extended Data Fig. 10 Model outputs describing creek changes in width relative to the starting year and erosion accounting for sea otters.
Left, values of \({\hat{W}}_{t}\) (relative creek width) from the first-stage model (blue dots = means; blue line segments = 95% credible intervals) and predicted values μt (black line = median; grey ribbon = 95% CI) from the second-stage model. Year increments start with year 1 as 1992. Right, the effective annual rate of erosion accounting for sea otters (reff) through time as determined by the estimates of r (base rate of widening), b (maximum reduction in widening per sea otter) and the number of sea otters. Line and ribbon indicate median and 95% credible interval.
Supplementary information
Supplementary Table 1
Camera trapping of sea otter behaviour. Camera trap data collected in 2020 from two experimental sites documenting sea otter behaviours and foraging around experiment and non-experimental locations.
Supplementary Table 2
Summary of all datasets used in the study. This includes information about time period, spatial scale, sample frequency, sample size, the method and purpose for data collection, the response reported, the corresponding figure, and the file name as it appears on the data repository: https://github.com/bbhughes/otters-erosion.
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Hughes, B.B., Beheshti, K.M., Tinker, M.T. et al. Top-predator recovery abates geomorphic decline of a coastal ecosystem. Nature 626, 111–118 (2024). https://doi.org/10.1038/s41586-023-06959-9
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DOI: https://doi.org/10.1038/s41586-023-06959-9
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