Biological invasions - the establishment of species beyond their historical range - are a major force of ecological and evolutionary change. Our lab aims to understand the patterns, processes, and consequences of invasions in marine ecosystems on local to global scales. We have laboratories and staff on both coasts of North America, on Chesapeake Bay and San Francisco Bay (Tiburon Lab). These bays are focal points for our long-term, intensive research, which spans Pacific and Atlantic shorelines of the Americas --- from polar to tropical latitudes.
Most marine invasions result from human-mediated species transfers, which are often associated with commercial and recreational vessels. A major component of our research examines shipping, transportation, and trade dynamics for the United States with the National Ballast Information Clearinghouse (NBIC), a joint program with the U.S. Coast Guard that is based at SERC. NBIC tracks the status and trends of ballast water delivery and management for the Nation.
Our research encompasses a wide range of projects, exploring the ecology and management of coastal marine ecosystems. We focus primarily on invasion dynamics but also examine species interactions of both native and non-native species. Overall, we seek to: (1) characterize patterns of marine invasion across space, time, and taxonomic groups; (2) develop a mechanistic understanding of the processes that drive observed patterns; (3) advance predictive capability about the establishment, spread, and impacts of non-native species in marine ecosystems; (4) evaluate the efficacy of management strategies to limit the establishment and impact of invaders; and (5) understand the roles of species interactions, including predator-prey and host-parasite relationships, in marine communities.
Further details on the various dimensions of our work are available below.
Simkanin, C., Carlton, J.T., Steves, B., Fofonoff, P., Nelson, J., Clarke Murray, C., and Ruiz, G.M. 2019. Exploring establishment potential after long-distance dispersal: a test using marine debris species. Global Ecology and Biogeography. DOI: 10.1111/geb.12878 (Online January 29, 2019)
Cheng, B.S., Ruiz, G.S., Altieri, A.H., Torchin, M.E. 2018. The biogeography of invasion in tropical and temperate seagrass beds: Testing interactive effects of predation and propagule pressure. Biodiversity Research. https://doi.org/10.1111/ddi.12850 (Online December 11, 2018)
Batista, W.R, Fernandes, F.C., Neves, M.H., Nascimento, T.S., Lopes, R.S., Lopes, C.C., Ziegler, G.P., Soler-Figueroa, B.M., Sparks, D., Fontaine, D.N., Carney, K.J., Quiñones-Oquendo, L.E., Ruiz, G.M. 2018. Synthetic lipids as a biocide candidate for disinfection of ballast water. Mar Pollut Bull.137:702-710. doi: 10.1016/j.marpolbul.2018.11.018 (online November 28, 2018)
Davidson I.C., Cott, G.M., Devaney, J.L., Simkanin, C. 2018. Differential effects of biological invasions on coastal blue carbon: A global review and meta-analysis. Global Change Biology 24(11): 5218-5230. https://doi.org/10.1111/gcb.14426 (Online: September 30, 2018)
Jurgens, L. J., Bonfim, M., Lopez, D.P., Repetto, M.F., Freitag, G., McCann, L., Larson, K., Ruiz, G.M., and Freestone, A.L. 2018. Poleward range expansion of a non-indigenous bryozoan and new occurrences of exotic ascidians in southeast Alaska. BioInvasions Records DOI: https://doi.org/10.3391/bir.2018.7.4.02 (online: September 27, 2018)
January 29, 2019
Simkanin, C., Carlton, J.T., Steves, B., Fofonoff, P., Nelson, J., Clarke Murray, C., and Ruiz, G.M. 2019. Exploring establishment potential after long-distance dispersal: a test using marine debris species. Global Ecology and Biogeography. DOI: 10.1111/geb.12878
Aim: On 11 March 2011, the Great East Japan Earthquake triggered a massive tsunami that resulted in the largest known rafting event in recorded history. By spring 2012, marine debris began washing ashore along the Pacific coast of the United States and Canada with a wide range of Asian coastal species attached. We used this unique dataset, where the source region, date of dislodgment and landing location are known, to assess the potential for species invasions by transoceanic rafting on marine debris.
Location: Northeast Pacific from 20 to 60°N.
Time period: Current.
Major taxa studied: Forty‐eight invertebrate and algal species recorded on Japanese tsunami marine debris (JTMD).
Methods: We developed maximum entropy (MaxEnt) species distribution models for 48 species recorded on JTMD to predict establishment potential along the Pacific coast from 20 to 60°N. Models were compared within the context of historical marine introductions from Japan to this region to validate the emergence of marine debris as a novel vector for species transfer.
Results: Overall, 27% (13 species) landed with debris at locations with suitable environmental conditions for establishment and survival, indicating that these species may be able to establish new populations or introduce greater genetic diversity to already established non‐native populations. A further 21 species have an environmental match to areas where tsunami debris likely landed, but was not extensively sampled. Nearly 100 Japanese marine species previously invaded the northeastern Pacific, demonstrating this region’s environmental suitability for rafting Japanese biota. Historical invasions from Japan are highest in California and largely known from bays and harbours.
Main conclusions: Marine debris is a novel and growing vector for non‐native species introduction. By utilizing a unique dataset of JTMD species, our predictive models show capacity for new transoceanic invasions and can focus monitoring priorities to detect successful long‐distance dispersal across the world’s oceans.
December 11, 2018
Cheng, B.S., Ruiz, G.S., Altieri, A.H., Torchin, M.E. 2018. The biogeography of invasion in tropical and temperate seagrass beds: Testing interactive effects of predation and propagule pressure. Biodiversity Research. https://doi.org/10.1111/ddi.12850
Recent work has documented latitudinal gradients of biotic resistance, revealing diminished invasion success in the tropics as compared to the temperate zone. However, no studies have explored the biogeography of biotic resistance simultaneously with propagule pressure, which can greatly influence invasion dynamics and covary with latitude.
9–41° latitude, north‐western Atlantic seagrass beds.
We conducted field experiments to test the interactive effects of propagule pressure (experimentally placed recruits) and biotic resistance (predation) on invader performance in temperate and tropical seagrass beds. For these experiments, we used marine invertebrate propagules from bryozoans (Bugula neritina) and tunicates (Didemnum spp.). We also quantified natural recruitment with and without exposure to predators.
Surprisingly, predation substantially reduced invader survival at almost all latitudes. Overall, invaders experienced 15%–27% survival with predation as opposed to 75%–87% survival without predation. These patterns did not change when we increased local scale propagule pressure of Bugula by over 2‐fold. However, predation had no effect on invader survival in Florida, where natural recruitment was up to 500‐fold greater than other sites. We also measured substantial in situ recruitment of Bugula onto bare experimental surfaces that was not diminished with exposure to predators at mid‐latitudes, suggesting a regional scale predator swamping effect.
Contrary to recent findings of latitudinal variation in biotic resistance, we found that predation strongly reduced invader success in both temperate and tropical seagrass beds. However, our results also indicate that propagule pressure (natural recruitment) can influence invasion at the regional scale to overwhelm native communities. Our data suggest that predation and propagule pressure act at varying spatial scales to affect biogeographic patterns of invasion. The importance of latitudinal variation in these interactions is largely untested but deserves attention given that globalization will continue to facilitate opportunities for invasion.
November 28, 2018
Batista, W.R, Fernandes, F.C., Neves, M.H., Nascimento, T.S., Lopes, R.S., Lopes, C.C., Ziegler, G.P., Soler-Figueroa, B.M., Sparks, D., Fontaine, D.N., Carney, K.J., Quiñones-Oquendo, L.E., Ruiz, G.M. 2018. Synthetic lipids as a biocide candidate for disinfection of ballast water. Mar Pollut Bull.137:702-710. doi: 10.1016/j.marpolbul.2018.11.018
The objective of this study is to propose the use of specific synthetic lipid as an active substance (biocide) in the control of harmful aquatic microorganisms, such as pathogens and non-indigenous species, transported in ships' ballast water. The biocide candidate, without metal or halogen components, was produced from a sub-product of the edible oil industry, the lecithin. Laboratory assays were conducted with phytoplankton, zooplankton, and marine bacteria to evaluate the efficiency of the biocide. The study also considers specific biocide's characteristics related to environmental risks, such as chemical composition, persistence, bioaccumulation, and toxicity. Results showed that, in the first 24 h of treatment, the biocide effectively reduced the concentration of the planktonic micro-organisms to very low levels. Additionally, a preliminary risk evaluation pointed that biocide candidate has a low residual toxicity, also a low potential for persistence and bioaccumulation in the environment.
September 30, 2018
Davidson I.C., Cott, G.M., Devaney, J.L., Simkanin, C. 2018. Differential effects of biological invasions on coastal blue carbon: A global review and meta-analysis. Global Change Biology 24(11): 5218-5230. https://doi.org/10.1111/gcb.14426
Human‐caused shifts in carbon (C) cycling and biotic exchange are defining characteristics of the Anthropocene. In marine systems, saltmarsh, seagrass, and mangrove habitats—collectively known as “blue carbon” and coastal vegetated habitats (CVHs)—are a leading sequester of global C and increasingly impacted by exotic species invasions. There is growing interest in the effect of invasion by a diverse pool of exotic species on C storage and the implications for ecosystem‐based management of these systems. In a global meta‐analysis, we synthesized data from 104 papers that provided 345 comparisons of habitat‐level response (plant and soil C storage) from paired invaded and uninvaded sites. We found an overall net effect of significantly higher C pools in invaded CVHs amounting to 40% (±16%) higher C storage than uninvaded habitat, but effects differed among types of invaders. Elevated C storage was driven by blue C‐forming plant invaders (saltmarsh grasses, seagrasses, and mangrove trees) that intensify biomass per unit area, extend and elevate coastal wetlands, and convert coastal mudflats into C‐rich vegetated habitat. Introduced animal and structurally distinct primary producers had significant negative effects on C pools, driven by herbivory, trampling, and native species displacement. The role of invasion manifested differently among habitat types, with significant C storage increases in saltmarshes, decreases in seagrass, and no significant effect in mangroves. There were also counter‐directional effects by the same species in different systems or locations, which underscores the importance of combining data mining with analyses of mean effect sizes in meta‐analyses. Our study provides a quantitative basis for understanding differential effects of invasion on blue C habitats and will inform conservation strategies that need to balance management decisions involving invasion, C storage, and a range of other marine biodiversity and habitat functions in these coastal systems.
September 27, 2018
Jurgens, L. J., Bonfim, M., Lopez, D.P., Repetto, M.F., Freitag, G., McCann, L., Larson, K., Ruiz, G.M., and Freestone, A.L. 2018. Poleward range expansion of a non-indigenous bryozoan and new occurrences of exotic ascidians in southeast Alaska. BioInvasions Records 7
We report a first record of the widely invasive bryozoan Bugula neritina in Ketchikan, Alaska (USA), on Revillagigedo Island (southeast Alaska). This represents the northernmost record of this fouling organism in the northeast Pacific Ocean. We also report a new occurrence of the solitary ascidian Ciona savignyi not found in Alaska since 1903, along with recent occurrences of the invasive colonial ascidians Botryllus schlosseri and Botrylloides violaceus in new localities. The high level of vessel traffic in this region and the precedent for historical ship-borne invasions worldwide suggest that future population growth and establishment of these taxa in the Ketchikan area could set the stage for further poleward range expansion, highlighting the need for continued monitoring.
Species distributions are at the core of all ecological and evolutionary processes. Despite recognition that accelerating invasions are radically changing fundamental ecological processes, we currently lack the data for a broad scale understanding of these patterns, emergent properties, and practical implications across both spatial and temporal scales. We are collecting quality occurrence data and using these data to understand patterns and mechanisms of invasion, and making these data publicly available for broader application by the public.
The impacts of introduced species pose significant challenges for conservation and restoration because they undermine a desired outcome for target species or habitats. In addition, some invasions impose significant economic costs through loss of agriculture, forestry, and fisheries products, and others, including mosquito-borne viruses and toxic algal blooms, have severe human health effects. Detailed analysis of several high-profile species invasions have highlighted the types and potential magnitude of invasion impacts that exist, however, the effect of most non-native species and the full scope of impacts from invasions remains poorly understood. To address this gap, we use a variety of approaches to characterize and test the ecological, evolutionary, and social effects of non-native species across diverse ecosystems. This work advances understanding of how the Earth’s ecosystems function and also serve to inform resource management and conservation strategies.
Biological invasions provide opportunities to examine how species and ecosystems respond to new arrivals, and how species adapt to new environmental conditions. These types of “natural experiments” provide new insights into many biological processes, especially early in the colonization process, that are not possible with native communities. We examine invasion ecology at the population, community, and ecosystem level across a diverse range of habitats and organisms, both to advance basic science and inform management and conservation strategies.
Managing biological invasions is a worldwide endeavor that aims to (a) prevent the human-caused spread of species, (b) control and remove unwanted species, and (c) reduce negative impacts to society and the environment. We are evaluating the efficacy and consequences of invasion management strategies and policies in coastal estuaries and marine systems. Our work is often done in collaboration with local, state, federal and international partners and used actively to inform current management and policy decisions.
We study the dynamic interactions between society, trade, transport, and species in a variety of ways. These include modeling transport networks and biotic exchange, evaluating business model forecasts and their effects on trade routes and species distributions, and assessments of organism transfers across major corridors between oceans and continents.
Understanding how modes of human transportation affect the environment, and biological invasions in particular, is complicated and involves many components including both human and natural history. Human history because most invasions result from human-aided species transfers and invasion patterns often reflect human movements and transportation systems. Natural history because species identifications and their life history characteristics are paramount to knowing which species are non-native and how they have likely been introduced. We work to address these complexities and strive to understand the dynamics of species transport in marine systems.
Balanced predation and competition are key to the health of any ecosystem. We are examining predation and competition rates in several environments including in the Rhode River near SERC where we study native species in nearshore environments and in introduced fouling communities on the Atlantic and Pacific coasts.
Communities are constantly being shaped by human activities, activates that can affect hydrology, climate, chemical inputs, species richness (number of species that make up the community), as well as habitat quantity and quality. Our research focuses on how biological invasions change the marine and estuarine communities they invade and how recipient communities protect themselves from invasion. The following highlights a few of our recent projects exploring community changes resulting from nonnative species introductions.
Propagule Pressure in Marine Habitats
We are examining the complex, dynamic interactions between parasites and their hosts, including both the evolutionary and ecological mechanisms that influence these interactions. Our research includes a wide variety of hosts (e.g., seagrasses, bivalves, crustaceans) and parasites (e.g., protists, bacteria, crustaceans).