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Host-associated microbiomes drive structure and function of marine ecosystems

Abstract

The significance of symbioses between eukaryotic hosts and microbes extends from the organismal to the ecosystem level and underpins the health of Earth’s most threatened marine ecosystems. Despite rapid growth in research on host-associated microbes, from individual microbial symbionts to host-associated consortia of significantly relevant taxa, little is known about their interactions with the vast majority of marine host species. We outline research priorities to strengthen our current knowledge of host–microbiome interactions and how they shape marine ecosystems. We argue that such advances in research will help predict responses of species, communities, and ecosystems to stressors driven by human activity and inform future management strategies.

Introduction

Within the vast and dazzling biological diversity that inhabits the world’s oceans, it would be challenging to find a eukaryotic organism that does not live in close relationship with a microbial partner. Such symbioses, i.e., persistent interactions between host and microbe in which none of the partners gets harmed and at least one of them benefits (Box 1), are ubiquitous from shallow reefs to deep-sea hydrothermal vents. Studies on corals [1], sponges [2], and mollusks [35] have revealed some of the profoundly important symbiotic roles microbes play in the lives of their hosts. These studies, however, have tended to focus on a small number of specific microbial taxa. In contrast, most hosts retain groups of many hundreds of different microbes (i.e., a microbiome [6,7]), which themselves can vary throughout the ontogeny of the host and as a result of environmental perturbations [810]. It is now clear that, rather than host-associated microbes functioning independently, complex multi-assemblage microbiomes have major impact on the fitness and function of their hosts. Studying these complex interactions and biological outcomes is difficult, but if we wish to truly understand the origin and evolution of organisms and populations and the structure and function of communities and ecosystems, we must advance our understanding of symbioses in host–microbiome systems [11,12].

Box 1. Terminology used to discuss communities of microbes and their interactions with hosts.

Following are key terms and concepts that we use in this paper (see also [7]).

Microbiome and microbiota

We use “microbiome” to refer to a community of microbes (organisms too small to see without the aid of a microscope) found at a specific place and/or a specific time. We avoid using the term “microbiota,” which has a complicated history (see [7]). Ideally, the place and/or time should be specified when discussing the microbiome. For example, “the seagrass microbiome” is the total of microbial communities found in association with seagrass, and “the seagrass root microbiome” would be those microbial communities found in/on the roots of seagrass. We also consider host-associated microbiomes broadly to include any and all kinds of microbes (e.g., bacteria, archaea, microbial eukaryotes, or viruses), which can be transient or persistent, and have variable functional impacts from beneficial to unimpactful to detrimental. Microbiomes can inhabit the external and internal surfaces of virtually every eukaryote, from microscopic unicellular diatoms to macroscopic organisms such as kelp, coral, seagrass, cephalopods, and vertebrates [8].

Symbiosis

We use “symbiosis” here in the broad sense, meaning a persistent relationship between two or more organisms in which at least one of them benefits. Symbioses come in three subcategories: in “mutualism,” both or many partners benefit; in “parasitism,” one partner benefits and the other(s) is/are harmed; in “commensalism,” at least one partner benefits and the other(s) is/are unaffected. In many discussions of microbes or microbial communities living in and on a host organism, it is frequently assumed that the microbe is benefitting in some way, and the question then becomes, “What is the effect on the host?” If the host benefits, this is a mutualism; if the host is unaffected, this is a commensalism; and if the host is harmed, this is a parasitism. It is important to note that these categories are fluid in that the type of interaction between two species is often conditional and depends on many factors including genotype (of all partners), environmental conditions, and developmental stage, among others.

Health status and microbiomes

Much of the work on host-associated microbiomes revolves around whether the community of microbes in some way affects the health status of the host [87]. In some cases, researchers have used terms like “healthy” or “dysbiotic” or “optimal” to describe a particular microbiome (e.g., of one host individual at one time) or pattern of change documented among particular groups. Although these terms can sometimes be useful in general discussions of microbiomes, they are hard to define quantitatively or apply and therefore more likely to confuse than to illuminate in practice. For example, an “optimal” microbiome could vary between individuals and across environmental conditions. Similarly, there could be numerous and equivalent alternative microbiome states, each of which could be referred to as “healthy,” which include transient or permanent neutral members and/or active symbiotic players. The inverse of a healthy association is “dysbiosis,” often suggested to be any change in the composition and/or variability of a microbial community that can cause any negative impact on the host. Generally, we believe such terms need to be used with extreme caution and to be clearly and quantitatively defined when in practice (see a useful discussion of this topic in [91]).

Ecosystem functions

“Ecosystem functions or processes” are generally considered to be aggregate fluxes of energy or materials [14]. Ecosystem function has also sometimes been defined as the joint effects of all processes, including fluxes of energy and chemical compounds, that sustain an ecosystem over time and space through biological activities [92]. Generally, ecosystem functioning depends disproportionately on a small subset of species in the system. These include particularly “foundation species” (dominant sessile invertebrates, plants, or algae that provide physical structure and have a strong role in structuring the community [93]) and “keystone species,” (taxa that have a large effect on other species that is disproportionate to their own relatively low abundance and that, if they were removed, would drastically change the ecosystem). “Resilience” is the capacity of an ecosystem to respond to a perturbation or disturbance by recovering quickly. Another form of response is “evolutionary adaptation,” in which species change genetically to adapt to a new environment. Over several generations and through the process of natural selection, physical and behavioral features of organisms may adapt to function better in the new environment. If hosts and their associated microbes change in concert, this is termed “coevolution.” Moreover, when two coevolving organisms also undergo speciation, this can lead to the formation of new species, i.e., co-speciation and co-diversification.

Here, we report on the opportunities in studies of marine eukaryotic host-associated microbiomes. First, we highlight our current knowledge with key examples of known ecosystem functions of host-associated marine microbes. Second, we outline ways in which comparative and experimental studies across hosts and habitats could be integrated to show how microbial symbioses at the microbiome level contribute to host evolution, resilience, and conservation strategies. There is a plethora of outstanding questions in ecology and evolution that could be addressed by expanding the phylogenetic and ecological breadth of host-associated microbiome studies, including all possible interactions throughout the microbiome. We list two questions that we believe would move the research field significantly forward, and we give specific examples of how these questions could be answered. There is strong empirical evidence and new consensus that biodiversity (i.e., the richness of species and their interactions) pervasively influences the functioning of Earth’s ecosystems, including ecosystem productivity [13,14]. However, this research has focused almost exclusively on macroorganisms. Because microbial symbionts are integral parts of most living organisms [9,15], broadening our understanding of how microbial symbionts contribute to host performance and adaptability is essential.

How microbial symbiosis impacts marine ecosystem functioning

Foundations of productive ecosystems

Ecosystem engineers, such as many types of corals, deep-sea mussels, and hydrothermal vent tubeworms, contribute to primary productivity and create the structural habitats and nutrient resources that are the foundation of their respective ecosystems [16]. All of these taxa engage in mutualistic nutritional symbioses with microbes. There are many examples of marine nutritional mutualisms in which microbes enable hosts to utilize resources or substrates otherwise unavailable to the host alone. Such symbioses have been described in detail in reduced and anoxic sediments (e.g., lucinid clams, stilbonematid nematodes, and gutless oligochaetes) and hydrothermal vents (e.g., the giant tube worm Riftia pachyptila or Bathymodiolus deep-sea mussels) [17]. Moreover, many foundational species of marine macroalgae are vitamin auxotrophs (for example, half of more than 300 surveyed species were unable to synthesize cobalamin), and their productivity depends on provisioning from their epiphytic bacteria [18]. Reefs often consist of scleractinian corals, one of the most well-known examples of a mutualistic symbiosis, in which the dinoflagellate alga Symbiodiniaceae supplies the coral with glucose, glycerol, and amino acids, while the coral provides the algae with a protected environment and limiting compounds (e.g., nitrogen species) needed for photosynthesis. However, this is a classic example of a mutualistic symbiosis that is sensitive to environmental disturbances, which can disrupt the fragile interactions between host and microbe. When reefs become warm and eutrophic, mutualistic Symbiodiniaceae may induce cellular damage to the host and/or sequester more resources for their own growth, thereby injuring and parasitizing their hosts [19,20]. Reef fishes, which seek homes on coral reefs, are important in fostering coral recovery in the wake of disturbance. Epulopiscium bacteria in the guts of surgeonfishes produce enzymes that allow their hosts to digest complex polysaccharides, enabling the host fish to feed on tough, leathery red and brown macroalgae [21]. This trophic innovation has facilitated niche diversification among coral reef herbivores. Surgeonfishes are critical to the functioning of Indo-Pacific coral reefs, as they are among the only fishes capable of consuming large macroalgae that bloom in the wake of ecosystem disturbance and suppress coral recovery [22].

Along with more standard examples of nutritional symbioses in animals, recent advances in genome sequencing technology have led to the discovery of many endosymbiotic associations in “protists” (a general term to refer to a non-monophyletic collection of unicellular eukaryotes that are not fungi or in the Plantae group) that illustrate the incorporation of various new biochemical functions, such as photosynthesis, nitrogen fixation and recycling, and methanogenesis, into protist hosts by endosymbionts [23]. Endosymbiosis in protists is widespread and represents an important source of innovation. Previously unrecognized metabolic innovations of marine microbial symbioses that are ecologically important are discovered regularly [24]. For example, Candidatus Kentron (a clade of Gammaproteobacteria found in association with ciliates) nourish their ciliate hosts in the genus Kentrophoros and recycle acetate and propionate, which are low-value cellular waste products from their hosts, into biomass [25]. Another interesting example is found in the anaerobic marine ciliate Strombidium purpureum [26]. The ciliate lives under anaerobic conditions and harbors endosymbiotic purple nonsulfur bacteria that contain both bacteriochlorophyll a and spirilloxanthin. The endosymbionts are photosynthetically active; hence, this symbiosis represents an evolutionary transition of an aerobic organism to an anaerobic one while incorporating organelles.

Reproduction and host development

Extending beyond nutritional symbioses, microbial symbionts can alter the reproduction, development, and growth of their hosts. Specific bacterial strains in marine biofilms often directly control the recruitment of planktonic larvae and propagules, either by inhibiting settlement or by serving as a settlement cue [27,28]. For example, the settlement of zoospores from the green alga Ulva intestinalis onto the biofilms of specific bacteria is mediated by their attraction to the quorum-sensing molecule, acyl-homoserine lactone, secreted by the bacteria [29]. Classic examples of marine host–microbe developmental dependence include the observation that algal cultures grown in isolation exhibited abnormal morphologies [30] and the subsequent discovery of morphogenesis-inducing compounds, such as thallusin, secreted by epiphytic bacterial symbionts [31]. Bacteria are also known to influence the growth of marine plants, macroalgae, and phytoplankton by secreting phytohormones such as indole acetic acid and cytokinin-type hormones [3234]. In the marine choanoflagellate Salpingoeca rosetta, both multicellularity and reproduction are triggered by specific bacterial cues, offering a view into the origins of bacterial control over animal development (reviewed by Woznica and King [35]). The benefit to the bacteria, in return, is that they receive physical space to colonize at particular points in the water column typically accessible only to planktonic microbes. Perhaps the best-studied example of intimate host–microbe interactions controlling animal development is the Hawaiian bobtail squid Euprymna scolopes [36]. It lives in a mutualistic symbiosis with the bioluminescent bacteria Aliivibrio fischeri. The bacteria are fed a solution of sugars and amino acids by the host and, in return, provide bioluminescence for countershading and predator avoidance [5]. This mutualism with microbes provides a selective advantage for the squid in predator–prey interactions. Another invertebrate example can be found in tubeworms, in which Hydroides elegans metamorphosis is mediated by a bacterial inducer and mitogen-activated protein kinase (MAPK) signaling in biofilms [37].

Biofouling and microbial community assembly

Some host-associated microbes produce compounds that prevent biofouling and regulate microbiome assembly and maintenance in many marine organisms, including sponges, macroalgae, and corals [38,39]. For example, tropical corals harbor diverse bacteria in their surface mucus layer that produce quorum-sensing inhibitors and other antibacterial compounds as a defense against colonization and infection by potential microbial pathogens [1]. Epiphytic bacteria of marine macroalgae excrete a diverse chemical arsenal capable of selectively shaping further bacterial colonization and deterring the settlement of biofouling marine invertebrates such as bryozoans [32,40]. As in corals, these diverse, microbially secreted compounds include not only bactericidal and bacteriostatic antibiotics but also compounds like halogenated furanones, cyclic dipeptides, and acyl-homoserine lactone mimics that disrupt bacterial quorum sensing and inhibit biofilm formation [41]. The bacteria likely are able to utilize the carbon-rich exudates from their hosts [42,43]. For example, in the case of giant kelp, the alga emits approximately 20% of primary production as dissolved organic carbon [43]. Whereas these prior examples illustrate how the microbiomes can protect hosts from surface colonization, a similar phenomenon has also been observed internally in the shipworm Bankia setacea, in which symbionts produce a boronated tartrolon antibiotic thought to keep the wood-digesting cecum clear of bacterial foulants [44]. By producing antimicrobial compounds, these microbes are able to defend their niche space to prevent other organisms from crowding them out.

Biogeochemical cycling

Host-associated microbiomes also influence biogeochemical cycling within ecosystems with cascading effects on biodiversity and ecosystem processes. For example, microbial symbionts comprise up to 40% of the biomass of their sponge hosts [45]. Through a process termed the “sponge-loop,” they convert dissolved organic carbon released by reef organisms into particulate organic carbon that can be consumed by heterotrophic organisms [2]. Along with the coral–Symbiodiniaceae mutualism, this sponge-bacterial symbiosis helps explain Darwin’s paradox, i.e., how highly productive coral reef ecosystems exist within otherwise oligotrophic tropical seas. Some sponge symbionts play a significant role in the marine phosphorus cycle by sequestering nutrients in the form of polyphosphate granules in the tissue of their host [46] and nitrogen cycling, e.g., through nitrification, denitrification, and ammonia oxidation [2,39]. Many macroalgal-associated bacteria are specifically adapted to degrade complex algal polysaccharides (e.g., fucoidan, porphyran, and laminarin [47,48]) and modify both the quality and quantity of organic carbon supplied to the ecosystem [42,49]. The sulfur-oxidizing gill endosymbionts of lucinid clams contribute to primary productivity through chemosynthesis and facilitate the growth of seagrasses (important foundation species) by lowering sulfide concentrations in tropical sediments [50]. Gammaproteobacterial symbionts of lucinid clams and stilbonematid nematodes were also recently shown to be capable of nitrogen fixation (bacterial symbiont genomes encode and express nitrogenase genes [51]), highlighting the role of symbiotic microbes in nutrient cycling in shallow marine systems.

These examples demonstrate the importance of microbial symbioses for the functioning of ocean ecosystems. Understanding symbioses with this same level of detail in the context of complex communities (i.e., whole microbiomes) remains ripe for exploration and, indeed, requires a more integrated framework from the fields of microbiology, evolutionary biology, community ecology, and oceanography. Individual taxa within the microbiome may help hosts withstand a wide range of environmental conditions, including those predicted under scenarios of climate change. Next, we explore two different avenues of how interdisciplinary collaborations could advance this line of research.

Two example outstanding questions: The influence of microbiomes in a changing ocean

I. How can host-associated microbiomes influence host adaptation in a changing ocean?

Global change creates new niches and conditions to which organisms must adapt. Whether and how marine species adapt to change may depend on their microbiomes. Host-associated microbes can be treated as extended host phenotypes if host and microbe show a concerted adaptive response [17]. Geological events have played central roles in driving evolution [52]. Studying them can provide great insight into the processes of adaptive evolution [53]. The formation of the Isthmus of Panamá, for example, represents a natural evolutionary experiment. Until relatively recently (on a geological time scale), the Tropical Eastern Pacific (TEP) and Caribbean Sea were connected, and marine life could mix freely [54,55]. Before the Isthmus formed, the Caribbean and the TEP shared a homogenous, nutrient-rich biotic realm [54]. Over millions of years, the rising land bridge blocked interoceanic currents, causing the Caribbean to become oligotrophic and allowing the great tracts of reefs and seagrasses we know today to proliferate [56]. Conversely, the Pacific coast continued to be dominated by nutrient-rich ecosystems [57,58], and reefs remain rare and seagrasses all but nonexistent. Within this major environmental and ecological divergence, once-contiguous populations became isolated and followed distinct eco-evolutionary paths [55]. Today, all major groups (except corals) have representative species pairs that were split by the Isthmus, and most have examples distributed across their respective clades [55,59]. The Isthmus system therefore offers a remarkable opportunity to explore drivers and processes of speciation, diversification, and adaptation with a replicated suite of taxonomic and functional host–microbiome assemblages, often with well-calibrated phylogenetic support (Fig 1). We can explore questions of parallel versus differential evolution between hosts and their microbiomes, reveal general processes of adaptive evolution (e.g., loss/gain of genes in microbial genomes), and unveil the relative contribution of vertical and horizontal transmission in marine host communities [60].

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Fig 1. The formation of the Isthmus of Panamá split an ocean into two, creating a natural experiment to explore general processes of host–microbe evolution.

(A) Panmictic populations of hosts and their microbiomes living under similar environmental conditions became (B) physically isolated when the land bridge formed between North and South America. Well-calibrated phylogenetic data are available for marine animal hosts such as clams, fishes, porcelain crabs, snapping shrimps, and urchins. (C) Example of sister species isolated by the Isthmus of Panamá (left: Eastern Pacific, right: Caribbean): fish, Abudefduf saxatilis and Abudefduf troschelii; clams, Ctena mexicana and Ctena distinguenda; and shrimps, Alpheus panamensis and Alpheus formosus. Photo credit: fish, Ross Robertson (A. saxatilis) and Ettore Balocchi (A. troschelii); clams, Laetitia G. E. Wilkins and Benedict Yuen; shrimps, Arthur Anker.

https://doi.org/10.1371/journal.pbio.3000533.g001

Vertical transmission of symbiotic microbes to the offspring is expected to stabilize the association between a given host and microbe, thereby making phenotypic traits of the host–microbe interaction potentially heritable. This stabilization could, in turn, drive adaptive evolution of host–microbe interactions if it allows host populations to adapt to new ecological niches or persist in a changing environment [15,61]. In contrast, horizontal transmission of symbiotic microbes generally requires some form of selective host filtering of beneficial symbionts and/or host sanctioning of detrimental symbionts and cheaters in order to align host and microbial interests and coordinate their adaptive responses [62]. Indeed, some corals can expulse their Symbiodiniaceae algal symbionts in exchange for a set that is better adapted to a given condition [63]. Consequently, horizontally acquired symbionts have more opportunity to exchange genes with environmental and/or free-living conspecifics and can thereby increase their adaptive potential [64]. The acquisition of novel symbionts has been postulated as a form of phenotypic plasticity that could potentially assist foundational seagrass and macroalgal species acclimatize to a changing climate [65]. Studying taxonomic, genomic, and functional microbial compositions in combination with the phylogenies and habitats of their hosts either side of the Isthmus will help identify which microbes are tightly associated with the host, their mode of transmission, and their genomic features [66,67]. The Isthmus system is not an isolated example. The relatively recent emergence of oceanic islands (e.g., Marquesas, Hawai’i, or the Galapagos Islands), for example, can be used to reveal processes of coevolution in marine hosts and their associated microbes [68]. Indeed, natural events like these have been instrumental in resolving ecological and evolutionary processes in multicellular life. So long as testable predictions and hypotheses are constructed, we propose they can offer significant insights into host–microbiome assemblage evolution and ecosystem functions.

II. How can we use marine host-associated microbiomes to inform conservation?

Human activities are directly affecting the composition of natural microbiomes. Examples include the introduction of pathogens as well as non-native species and their microbial symbionts [69] and environmental contamination with antimicrobials in offshore farms [70]. Conventional aquaculture practices can promote high numbers of diverse bacteria on farmed hosts (some of them symbionts and some pathogens), that, in combination with the use of antibiotics, can develop into hotspots for horizontal gene transfer [71] and consequent dissemination of antibiotic resistance [70]. The composition of host-associated microbiomes may also be modified by other stressors, such as elevated seawater temperatures associated with global climate change or the locally discharged water from power plants [72], oil spills [73], and contamination with heavy metals from mining activities [74], with potential effects on host biology. Microbial-based mitigation strategies can be focused on specific contaminants or threats (e.g., oil-degrading bacteria, heavy metal immobilization, biological control of pathogens) or more broadly, based on the maintenance or improvement of the host health. For example, corals exposed to high temperatures were significantly more resistant to bleaching when inoculated with a consortium of microorganisms isolated from native healthy host corals [75]. Jin Song and colleagues (2019) summarized and discussed examples of successful probiotics used to promote animal health and conservation in the wild [76]. Such mitigation strategies, like these that make use of host-associated microbiomes by direct bioaugmentation (i.e., enriching the environment with specific microbes) or through the biostimulation of specific metabolisms to enhance host resistance and recovery, are promising but remain rare and in their infancy.

Effective microbially based mitigation will benefit from a thorough understanding of the identity and physiology of beneficial microbes and the attributes of healthy microbiomes, although microbial mitigation via bioaugmentation may only be effective for horizontally acquired symbionts. To this end, during the most successful trials of microbiome engineering, scientists have considered niche-specific traits and the manipulation of stable and native groups rather than the use of generic microbial cocktails [77]. Nevertheless, manipulative approaches can succeed even without knowing the detailed mechanisms a priori, as long as a rigorous experimental design is applied, which can eventually lead to the discovery of key strains and mechanisms [39,78].

From the perspective of applied ecosystem recovery, the most promising focal organisms for such bioaugmentation projects are keystone and foundational organisms and their associated microbiomes, as such efforts can cascade throughout the ecosystem by enhancing recovery of the central food source and biological niche within the habitat. Thus, efforts to quantify and compare the net effects of microbiome functions across multiple hosts and contexts (e.g., health status, life stage, and habitat) are critical to advancing our understanding of the roles of microbiomes for threatened hosts and ecosystems [19,79]. The fact that there are microbiomes specific to different developmental stages in tropical corals suggests that microbiomes may serve distinct, specific roles throughout host life cycles [80]. Environmental stressors can compromise or eliminate mutualistic microbe species that need to be replaced by beneficial, or at least neutral, microbes to passively prevent the spread of diseases. Incubation experiments and mesocosm setups are urgently needed to study the individual and interactive effects of increasingly common disturbances such as increased temperature, changes in partial pressure of carbon dioxide and acidification, nutrient enrichment, and physical damage on foundation and keystone species’ microbiomes [81]. The main goal for future studies of microbiomes in conservation biology is understanding the degree to which important functional roles can be maintained in nonoptimal environmental conditions and whether diverse communities of transient microbes may allow hosts to broaden their realized ecological niche [82,83]. Describing and understanding the organizing principles of microbiome assembly and maintenance is critical for developing effective microbial-based mitigation strategies [84,85]. Studying shifts in microbiome taxonomic composition and functional diversity in organisms that experience drastic seasonal or thermal shifts (e.g., temperate organisms or species living in intertidal zones) will help identify these principles [86,87]. For example, the microbiome of the temperate coral Astrangia poculata resembles a diseased tropical coral microbiome in the winter months, during host quiescence, and it transitions in the spring to a community dominated by taxa that continue to be present throughout the year [88]. This seasonal shift represents an opportunity to identify the molecular basis of microbiome assembly within an animal host. Such complex interactions among microbial species and their hosts can be informed by theory and empirical generalizations in community ecology developed primarily from studies of macroorganisms, including succession, community assembly, metacommunities, multitrophic interactions, disturbance, and restoration [8486].

Integration of information across hosts for an ecosystem-level understanding of the roles of microbial symbionts

Future progress in microbial symbioses research—and, indeed, in our understanding of ecosystem functioning generally—depends on adopting a microbiome perspective and expanding the scope of inquiry beyond single host taxa. First, this will require a broad comparative approach to identify similarities and differences across marine host species within a phylogenetic framework, especially with respect to their physiologies, microbiome profiles, and habitat distributions. Second, studies of terrestrial hosts and microbiomes can inform research priorities and generate hypotheses to be tested in marine environments [61,89]. Thus, we see great value in building a framework of broad collaborative networks. Collaborative efforts are more sustainable, and ultimately more productive, if we credit online resource generators, share data and workflows, and acknowledge others [90].

Identifying the factors that promote the contribution of microbial symbionts to host adaptability is fundamentally important to understanding ecological and evolutionary processes as well as predicting the response of populations, species, and communities to a changing environment. Key events (e.g., formation of the Isthmus of Panamá) can provide model systems to test hypotheses about the roles of marine host-associated microbiomes for ecosystem functioning. The biggest payback will likely come from a focus on taxa that have disproportionately large roles in the ecosystem, including dominant, foundational, and keystone species. We recommend special focus on how horizontally transferred microbes play critical roles in the hosts’ ability to respond to environmental change because we predict that these types of symbionts may be able to adapt quicker than their vertically transmitted counterparts. Together, these research directions will enhance our ability to predict how climate change, invasion by non-native species, food web disruption, and environmental contamination will affect species and inform practical strategies for directly assisting marine conservation in novel ways. For example, understanding the influence of the microbiome on host development and function will ultimately help prioritize management decision.

Acknowledgments

We thank the Gordon and Betty Moore Foundation and the Smithsonian Tropical Research Institute in Panamá for facilitating the #istmobiome workshop (https://istmobiome.net) where we initiated this article. We are especially thankful to Urania Gonzales, Plinio Gondola, and Fabiola Jenkins for organizing and facilitating this workshop. We also thank other workshop participants including Rachel Collin (ORCID: 0000-0001-5103-4460), Ross Robertson (ORCID: 0000-0003-3972-149X), Jarrod Scott, Jennifer McMillan, and Jon Kaye (ORCID: 0000-0002-3653-4253) for seminal discussions.

References

  1. 1. Krediet CJ, Ritchie KB, Paul VJ, Teplitski M. Coral-associated micro-organisms and their roles in promoting coral health and thwarting diseases. Proc Biol Sci. 2013;280: 2012.2328. pmid:23363627
  2. 2. Webster NS, Thomas T. The Sponge Hologenome. mBio. 2016;7: e00135–16. pmid:27103626
  3. 3. Distel DL, DeLong EF, Waterbury JB. Phylogenetic characterization and in situ localization of the bacterial symbiont of shipworms (Teredinidae: Bivalvia) by using 16S rRNA sequence analysis and oligodeoxynucleotide probe hybridization. Appl Environ Microbiol. 1991;57: 2376–2382. https://www.ncbi.nlm.nih.gov/pubmed/1722662 pmid:1722662
  4. 4. Ruehland C, Blazejak A, Lott C, Loy A, Erséus C, Dubilier N. Multiple bacterial symbionts in two species of co-occurring gutless oligochaete worms from Mediterranean Sea grass sediments. Environ Microbiol. 2018;10: 3404–3416. pmid:18764872
  5. 5. Nyholm SV, McFall-Ngai MJ. The winnowing: Establishing the squid–vibrio symbiosis. Nat Rev Microbiol. 2004;2: 632–642. pmid:15263898
  6. 6. Hammer TJ, Sanders JG, Fierer N. Not all animals need a microbiome. FEMS Microbiol Lett. 2019;366: fnz117. pmid:31132110
  7. 7. Tipton L, Darcy JL, Hynson NA. A developing symbiosis: Enabling cross-talk between ecologists and microbiome scientists. Front Microbiol. 2019;10: 292. pmid:30842763
  8. 8. Apprill A. Marine animal microbiomes: Toward understanding host–microbiome interactions in a changing ocean. Front Mar Sci. 2017;4.
  9. 9. McFall-Ngai M, Hadfield MG, Bosch TCG, Carey HV, Domazet-Lošo T, Douglas AE, et al. Animals in a bacterial world, a new imperative for the life sciences. Proc Natl Acad Sci U S A. 2013;110: 3229–3236. pmid:23391737
  10. 10. Webster NS, Taylor MW. Marine sponges and their microbial symbionts: love and other relationships. Environ Microbiol. 2012;14: 335–346. pmid:21443739
  11. 11. Azam F, Worden AZ. Oceanography. Microbes, molecules, and marine ecosystems. Science. 2004;303: 1622–1624. pmid:15016987
  12. 12. Cavicchioli R, Ripple WJ, Timmis KN, Azam F, Bakken LR, Baylis M, et al. Scientists’ warning to humanity: microorganisms and climate change. Nat Rev Microbiol. 2019;17: 569–586. pmid:31213707
  13. 13. Duffy JE, Godwin CM, Cardinale BJ. Biodiversity effects in the wild are common and as strong as key drivers of productivity. Nature. 2017;549: 261–264. pmid:28869964
  14. 14. Cardinale BJ, Duffy JE, Gonzalez A, Hooper DU, Perrings C, Venail P, et al. Biodiversity loss and its impact on humanity. Nature. 2012;486: 59–67. pmid:22678280
  15. 15. Gould AL, Zhang V, Lamberti L, Jones EW, Obadia B, Korasidis N, et al. Microbiome interactions shape host fitness. Proc Natl Acad Sci U S A. 2018;115: 11951–11960. pmid:30510004
  16. 16. Seemann J, Yingst A, Stuart-Smith RD, Edgar GJ, Altieri AH. The importance of sponges and mangroves in supporting fish communities on degraded coral reefs in Caribbean Panama. PeerJ. 2018;6: e4455. pmid:29610704
  17. 17. O’Brien PA, Webster NS, Miller DJ, Bourne DG. Host-microbe coevolution: applying evidence from model systems to complex marine invertebrate holobionts. mBio. 2019;10: 02241–18. http://dx.doi.org/10.1128/mBio.02241-18
  18. 18. Croft MT, Lawrence AD, Raux-Deery E, Warren MJ, Smith AG. Algae acquire vitamin B12 through a symbiotic relationship with bacteria. Nature. 2005;438: 90–93. pmid:16267554
  19. 19. Quigley KM, Bay LK, Willis BL. Leveraging new knowledge of Symbiodinium community regulation in corals for conservation and reef restoration. Mar Ecol Prog Ser. 2018;600: 245–253.
  20. 20. Baker DM, Freeman CJ, Wong JCY, Fogel ML, Knowlton N. Climate change promotes parasitism in a coral symbiosis. ISME J. 2018;12: 921–930. pmid:29379177
  21. 21. Ngugi DK, Miyake S, Cahill M, Vinu M, Hackmann TJ, Blom J, et al. Genomic diversification of giant enteric symbionts reflects host dietary lifestyles. Proc Natl Acad Sci U S A. 2017;114: 7592–7601. pmid:28835538
  22. 22. Hoey AS, Bellwood DR. Limited functional redundancy in a high diversity system: Single species dominates key ecological process on coral reefs. Ecosystems. 2009;12: 1316–1328.
  23. 23. Nowack ECM, Melkonian M. Endosymbiotic associations within protists. Philos Trans R Soc Lond B Biol Sci. 2010;365: 699–712. pmid:20124339
  24. 24. Higgs ND, Newton J, Attrill MJ. Caribbean spiny lobster fishery is underpinned by trophic subsidies from chemosynthetic primary production. Curr Biol. 2016;26: 3393–3398. pmid:27939312
  25. 25. Seah BKB, Antony CP, Huettel B, Zarzycki J, Schada von Borzyskowski L, Erb TJ, et al. Sulfur-oxidizing symbionts without canonical genes for autotrophic CO fixation. mBio. 2019;10: e01112–19. pmid:31239380
  26. 26. Gast RJ, Sanders RW, Caron DA. Ecological strategies of protists and their symbiotic relationships with prokaryotic microbes. Trends Microbiol. 2009;17: 563–569. pmid:19828317
  27. 27. Huang Y, Callahan S, Hadfield MG. Recruitment in the sea: Bacterial genes required for inducing larval settlement in a polychaete worm. Sci Rep. 2012;2: 228. pmid:22355742
  28. 28. Morris MM, Haggerty JM, Papudeshi BN, Vega AA, Edwards MS, Dinsdale EA. Nearshore pelagic microbial community abundance affects recruitment success of Giant Kelp, Macrocystis pyrifera. Front Microbiol. 2016;7: 1–12.
  29. 29. Wheeler GL, Tait K, Taylor A, Brownlee C, Joint I. Acyl-homoserine lactones modulate the settlement rate of zoospores of the marine alga Ulva intestinalis via a novel chemokinetic mechanism. Plant Cell Environ. 2006;29: 608–618. pmid:17080611
  30. 30. Provasoli L, Pintner IJ. Bacteria induced polymorphism in an axenic laboratory strain of Ulva lactuca (Chlorophyceae). J Phycol. 1980;16: 196–201.
  31. 31. Matsuo Y. Isolation of an algal morphogenesis inducer from a marine bacterium. Science. 2005;307: 1598–1598. pmid:15761147
  32. 32. Goecke F, Labes A, Wiese J, Imhoff J. Chemical interactions between marine macroalgae and bacteria. Mar Ecol Prog Ser. 2010;409: 267–299.
  33. 33. Amin SA, Hmelo LR, van Tol HM, Durham BP, Carlson LT, Heal KR, et al. Interaction and signaling between a cosmopolitan phytoplankton and associated bacteria. Nature. 2015;522: 98–101. pmid:26017307
  34. 34. Celdrán D, Espinosa E, Sánchez-Amat A, Marín A. Effects of epibiotic bacteria on leaf growth and epiphytes of the seagrass Posidonia oceanica. Mar Ecol Prog Ser. 2012;456: 21–27.
  35. 35. Woznica A, King N. Lessons from simple marine models on the bacterial regulation of eukaryotic development. Curr Opin Microbiol. 2018;43: 108–116. pmid:29331767
  36. 36. McFall-Ngai MJ. The importance of microbes in animal development: Lessons from the squid-vibrio symbiosis. Annu Rev Microbiol. 2014;68: 177–194. pmid:24995875
  37. 37. Shikuma NJ, Antoshechkin I, Medeiros JM, Pilhofer M, Newman DK. Stepwise metamorphosis of the tubeworm Hydroides elegans is mediated by a bacterial inducer and MAPK signaling. Proc Natl Acad Sci U S A. 2016;113: 10097–10102. pmid:27551098
  38. 38. Krediet CJ, Carpinone EM, Ritchie KB, Teplitski M. Characterization of the gacA-dependent surface and coral mucus colonization by an opportunistic coral pathogen Serratia marcescens. FEMS Microbiol Ecol. 2013;84: 290–301. pmid:23278392
  39. 39. Pita L, Rix L, Slaby BM, Franke A, Hentschel U. The sponge holobiont in a changing ocean: From microbes to ecosystems. Microbiome. 2018;6: 46. pmid:29523192
  40. 40. Steinberg PD, De Nys R. Chemical mediation of colonization of seaweed surfaces. J Phycol. 2002;38: 621–629.
  41. 41. Dobretsov S, Abed RMM, Teplitski M. Mini-review: Inhibition of biofouling by marine microorganisms. Biofouling. 2013;29: 423–441. pmid:23574279
  42. 42. Reed DC, Carlson CA, Halewood ER, Clinton Nelson J, Harrer SL, Rassweiler A, et al. Patterns and controls of reef-scale production of dissolved organic carbon by giant kelp Macrocystis pyrifera. Limnol Oceanogr. 1996;60: 1996–2008.
  43. 43. Vollmers J, Wiegand S, Kaster A-K. Comparing and evaluating metagenome assembly tools from a microbiologist’s perspective—Not only size matters! PLoS ONE. 2017;12(1): e0169662. pmid:28099457
  44. 44. Elshahawi SI, Trindade-Silva AE, Hanora A, Han AW, Flores MS, Vizzoni V, et al. Boronated tartrolon antibiotic produced by symbiotic cellulose-degrading bacteria in shipworm gills. Proc Natl Acad Sci U S A. 2013;110: 295–304. pmid:23288898
  45. 45. de Goeij JM, van Oevelen D, Vermeij MJA, Osinga R, Middelburg JJ, de Goeij AFPM, et al. Surviving in a marine desert: The sponge loop retains resources within coral reefs. Science. 2013;342: 108–110. pmid:24092742
  46. 46. Colman AS. Sponge symbionts and the marine P cycle. Proc Natl Acad Sci U S A. 2015;112: 4191–4192. pmid:25825737
  47. 47. Corzett CH, Elsherbini J, Chien DM, Hehemann J-H, Henschel A, Preheim SP, et al. Evolution of a vegetarian Vibrio: Metabolic specialization of Vibrio breoganii to macroalgal substrates. J Bacteriol. 2018;200: e00020–18. pmid:29632094
  48. 48. Bengtsson M, Sjøtun K, Storesund J, Øvreås J. Utilization of kelp-derived carbon sources by kelp surface-associated bacteria. Aquat Microb Ecol. 2011;62: 191–199.
  49. 49. Pfister CA, Altabet MA, Weigel BL. Kelp beds and their local effects on seawater chemistry, productivity, and microbial communities. Ecology. 2019;100: e02798. pmid:31233610
  50. 50. van der Heide T, Govers LL, de Fouw J, Olff H, van der Geest M, van Katwijk MM, et al. A three-stage symbiosis forms the foundation of seagrass ecosystems. Science. 2012;336: 1432–1434. pmid:22700927
  51. 51. Petersen JM, Kemper A, Gruber-Vodicka H, Cardini U, van der Geest M, Kleiner M, et al. Chemosynthetic symbionts of marine invertebrate animals are capable of nitrogen fixation. Nat Microbiol. 2016;2: 16195. pmid:27775707
  52. 52. Knoll AH, Nowak MA. The timetable of evolution. Sci Adv. 2017;3: e1603076. pmid:28560344
  53. 53. Jackson JBC, Budd AF, Coates AG. Evolution and Environment in Tropical America. Chicago: University of Chicago Press; 1996. Available from: https://books.google.com/books/about/Evolution_and_Environment_in_Tropical_Am.html?hl=&id=eJgcnw5p6qEC
  54. 54. Leigh EG, O’Dea A, Vermeij GJ. Historical biogeography of the Isthmus of Panama. Biol Rev Camb Philos Soc. 2014;89: 148–172. pmid:23869709
  55. 55. Lessios HA. The great American schism: Divergence of marine organisms after the rise of the Central American Isthmus. Annu Rev Ecol Evol Syst. 2008;39: 63–91.
  56. 56. O’Dea A, Jackson JBC, Fortunato H, Smith JT, D’Croz L, Johnson KG, et al. Environmental change preceded Caribbean extinction by 2 million years. Proc Natl Acad Sci U S A. 2007;104: 5501–5506. pmid:17369359
  57. 57. Smith JT, Travis Smith J, Jackson JBC. Ecology of extreme faunal turnover of tropical American scallops. Paleobiology. 2009;35: 77–93.
  58. 58. O’Dea A, Hoyos N, Rodríguez F, Degracia B, De Gracia C. History of upwelling in the Tropical Eastern Pacific and the paleogeography of the Isthmus of Panama. Palaeogeogr Palaeoclimatol Palaeoecol. 2012;348–349: 59–66.
  59. 59. O’Dea A, Lessios HA, Coates AG, Eytan RI, Restrepo-Moreno SA, Cione AL, et al. Formation of the Isthmus of Panama. Sci Adv. 2016;2: e1600883. pmid:27540590
  60. 60. Russell SL. Transmission mode is associated with environment type and taxa across bacteria-eukaryote symbioses: a systematic review and meta-analysis. FEMS Microbiol Lett. 2019;366: fnz013. pmid:30649338
  61. 61. Herre EA, Knowlton N, Mueller UG, Rehner SA. The evolution of mutualisms: Exploring the paths between conflict and cooperation. Trends Ecol Evol. 1999;14: 49–53. pmid:10234251
  62. 62. Jandér KC, Herre EA. Host sanctions and pollinator cheating in the fig tree-fig wasp mutualism. Proc Biol Sci. 2010;277: 1481–1488. pmid:20071379
  63. 63. Morris LA, Voolstra CR, Quigley KM, Bourne DG, Bay LK. Nutrient availability and metabolism affect the stability of coral-Symbiodiniaceae symbioses. Trends Microbiol. 2019;27: 678–689. pmid:30987816
  64. 64. López-Madrigal S, Gil R. Et tu, Brute? Not even intracellular mutualistic symbionts escape horizontal gene transfer. Genes. 2017;8: 247. pmid:28961177
  65. 65. Duarte B, Martins I, Rosa R, Matos AR, Roleda MY, Reusch TBH, et al. Climate change impacts on seagrass meadows and macroalgal forests: An integrative perspective on acclimation and adaptation potential. Front Mar Sci. 2018;5: 190.
  66. 66. Easson CG, Thacker RW. Phylogenetic signal in the community structure of host-specific microbiomes of tropical marine sponges. Front Microbiol. 2014;5: 532. pmid:25368606
  67. 67. Pollock FJ, McMinds R, Smith S, Bourne DG, Willis BL, Medina M, et al. Coral-associated bacteria demonstrate phylosymbiosis and co-phylogeny. Nat Commun. 2018;9: 4921. pmid:30467310
  68. 68. Cole TL, Ksepka DT, Mitchell KJ, Tennyson AJD, Thomas DB, Pan H, et al. Mitogenomes uncover extinct penguin taxa and reveal island formation as a key driver of speciation. Mol Biol Evol. 2019;36: 784–797. pmid:30722030
  69. 69. Kowalski KP, Bacon C, Bickford W, Braun H, Clay K, Leduc-Lapierre M, et al. Advancing the science of microbial symbiosis to support invasive species management: A case study on Phragmites in the Great Lakes. Front Microbiol. 2015;6: 95. pmid:25745417
  70. 70. Cabello FC, Godfrey HP, Tomova A, Ivanova L, Dölz H, Millanao A, et al. Antimicrobial use in aquaculture re-examined: Its relevance to antimicrobial resistance and to animal and human health. Environ Microbiol. 2013;15: 1917–1942. pmid:23711078
  71. 71. Watts JEM, Schreier HJ, Lanska L, Hale MS. The rising tide of antimicrobial resistance in aquaculture: Sources, sinks and solutions. Mar Drugs. 2017;15: 158. pmid:28587172
  72. 72. Keshavmurthy S, Hsu C-M, Kuo C-Y, Meng P-J, Wang J-T, Chen CA. Symbiont communities and host genetic structure of the brain coral Platygyra verweyi, at the outlet of a nuclear power plant and adjacent areas. Mol Ecol. 2012;21: 4393–4407. pmid:22809041
  73. 73. Villela HDM, Peixoto RS, Soriano AU, Carmo FL. Microbial bioremediation of oil contaminated seawater: A survey of patent deposits and the characterization of the top genera applied. Sci Total Environ. 2019;666: 743–758. pmid:30812008
  74. 74. Garcia LC, Ribeiro DB, de Oliveira Roque F, Ochoa-Quintero JM, Laurance WF. Brazil’s worst mining disaster: Corporations must be compelled to pay the actual environmental costs. Ecol Appl. 2017;27: 5–9. pmid:27770593
  75. 75. Rosado PM, Leite DCA, Duarte GAS, Chaloub RM, Jospin G, da Rocha UN, et al. Marine probiotics: Increasing coral resistance to bleaching through microbiome manipulation. ISME J. 2019;13: 921–936. pmid:30518818
  76. 76. Jin Song S, Woodhams DC, Martino C, Allaband C, Mu A, Javorschi-Miller-Montgomery S, et al. Engineering the microbiome for animal health and conservation. Exp Biol Med. 2019;244: 494–504. pmid:30776908
  77. 77. Mueller UG, Sachs JL. Engineering microbiomes to improve plant and animal health. Trends Microbiol. 2015;23: 606–617. pmid:26422463
  78. 78. Christian N, Herre EA, Mejia LC, Clay K. Exposure to the leaf litter microbiome of healthy adults protects seedlings from pathogen damage. Proc Biol Sci. 2017;284: 1858. pmid:28679727
  79. 79. McKenney EA, Koelle K, Dunn RR, Yoder AD. The ecosystem services of animal microbiomes. Mol Ecol. 2018;27: 2164–2172. pmid:29427300
  80. 80. Littman RA, Willis BL, Bourne DG. Bacterial communities of juvenile corals infected with different Symbiodinium (dinoflagellate) clades. Mar Ecol Prog Ser. 2009;389: 45–59.
  81. 81. Minich JJ, Morris MM, Brown M, Doane M, Edwards MS, Michael TP, et al. Elevated temperature drives kelp microbiome dysbiosis, while elevated carbon dioxide induces water microbiome disruption. PLoS ONE. 2018;13(2): e0192772. pmid:29474389
  82. 82. Hernandez-Agreda A, Leggat W, Bongaerts P, Ainsworth TD. The microbial signature provides insight into the mechanistic basis of coral success across reef habitats. mBio. 2016;7: e00560–16. pmid:27460792
  83. 83. Dittami SM, Duboscq-Bidot L, Perennou M, Gobet A, Corre E, Boyen C, et al. Host-microbe interactions as a driver of acclimation to salinity gradients in brown algal cultures. ISME J. 2016;10: 51–63. pmid:26114888
  84. 84. Hughes JB, Hellmann JJ, Ricketts TH, Bohannan BJ. Counting the uncountable: statistical approaches to estimating microbial diversity. Appl Environ Microbiol. 2001;67: 4399–4406. pmid:11571135
  85. 85. Prosser JI, Bohannan BJM, Curtis TP, Ellis RJ, Firestone MK, Freckleton RP, et al. The role of ecological theory in microbial ecology. Nat Rev Microbiol. 2007;5: 384–392. pmid:17435792
  86. 86. Christian N, Whitaker BK, Clay K. Microbiomes: unifying animal and plant systems through the lens of community ecology theory. Front Microbiol. 2015;6: 869. pmid:26441846
  87. 87. Mejía LC, Herre EA, Sparks JP, Winter K, García MN, Van Bael SA, et al. Pervasive effects of a dominant foliar endophytic fungus on host genetic and phenotypic expression in a tropical tree. Front Microbiol. 2014;5: 479. pmid:25309519
  88. 88. Sharp KH, Pratte ZA, Kerwin AH, Rotjan RD, Stewart FJ. Season, but not symbiont state, drives microbiome structure in the temperate coral Astrangia poculata. Microbiome. 2017;5: 120. pmid:28915923
  89. 89. Kiers ET, Duhamel M, Beesetty Y, Mensah JA, Franken O, Verbruggen E, et al. Reciprocal rewards stabilize cooperation in the mycorrhizal symbiosis. Science. 2011;333: 880–882. pmid:21836016
  90. 90. Wilkinson MD, Dumontier M, Aalbersberg IJJ, Appleton G, Axton M, Baak A, et al. The FAIR Guiding Principles for scientific data management and stewardship. Sci Data. 2016;3: 160018. pmid:26978244
  91. 91. Hooks KB, O’Malley MA. Dysbiosis and its discontents. mBio. 2017;8: 01492–17. pmid:29018121
  92. 92. Truchy A, Angeler DG, Sponseller RA, Johnson RK, McKie BG. Linking biodiversity, ecosystem functioning and services, and ecological resilience: Towards an integrative framework for improved management. In: Woodward G, Bohan DA, editors. Advances in Ecological Research. London: Academic Press; 2015. p. 55–96. https://doi.org/10.1016/bs.aecr.2015.09.004
  93. 93. Cottee-Jones HEW, Whittaker RJ. Perspective: The keystone species concept: a critical appraisal. Frontiers of Biogeography. 2012;4.