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1. Bacteria-Stimulated Metamorphosis: An Ocean of Insights from Investigating a Transient Host-Microbe Interaction

   https://doi.org/10.1128/mSystems.00754-21  

   Shikuma, Nicholas J (January 2021, mSystems)

   Recent research on host-microbe interactions has focused on intimate sym- bioses. Yet transient interactions, such as the stimulation of animal metamorphosis by bac- teria, can have significant impacts on each partner. During these short-lived interactions, swimming animal larvae identify a desirable location on the seafloor and undergo meta- morphosis into a juvenile based on the presence of specific bottom-dwelling bacteria. While this phenomenon is critical for seeding new animals to establish or maintain benthic ecosystems, there is an ocean of fundamental questions that remain unanswered. Here, I propose an updated model of how bacteria stimulate animal metamorphosis based on evi- dence that bacteria inject a stimulatory protein that prompts tubeworm metamorphosis. I consider what we hope to learn about stimulatory bacterial products, how animals recog- nize these products, and the consequences for both partners. Finally, I provide examples of how studying an enigmatic host-microbe interaction can serve as an engine for scientific discovery. 

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2. A bacterial membrane-disrupting protein stimulates animal metamorphosis

   https://doi.org/10.1128/mbio.03573-24  

   Malter, Kyle E; Dunbar, Tiffany L; Westin, Carl; Darin, Emily; Alfaro, Josefa Rivera; Shikuma, Nicholas J (December 2024, mBio)

   Dubilier, Nicole (Ed.)

   ABSTRACT Diverse marine animals undergo a metamorphic larval-to-juvenile transition in response to surface-bound bacteria. Although this host-microbe interaction is critical to establishing and maintaining marine animal populations, the functional activity of bacterial products and how they activate the host’s metamorphosis program has not yet been defined for any animal. The marine bacteriumPseudoalteromonas luteoviolaceastimulates the metamorphosis of a tubeworm calledHydroides elegansby producing a molecular syringe called metamorphosis-associated contractile structures (MACs). MACs stimulate metamorphosis by injecting a protein effector termed metamorphosis-inducing factor 1 (Mif1) into tubeworm larvae. Here, we show that MACs bind to tubeworm cilia and form visible pores on the cilia membrane surface, which are smaller and less numerous in the absence of Mif1.In vitro, Mif1 associates with eukaryotic lipid membranes and possesses phospholipase activity. MACs can also deliver Mif1 to human cell lines and cause parallel phenotypes, including cell surface binding, membrane disruption, calcium flux, and mitogen-activated protein kinase activation. Finally, MACs can also stimulate metamorphosis by delivering two unrelated membrane-disrupting proteins, MLKL and RegIIIɑ. Our findings demonstrate that membrane disruption by MACs and Mif1 is necessary forHydroidesmetamorphosis, connecting the activity of a bacterial protein effector to the developmental transition of a marine animal. IMPORTANCEThis research describes a mechanism wherein a bacterium prompts the metamorphic development of an animal from larva to juvenile form by injecting a protein that disrupts membranes in the larval cilia. Specifically, results show that a bacterial contractile injection system and the protein effector it injects form pores in larval cilia, influencing critical signaling pathways like mitogen-activated protein kinase and calcium flux, ultimately driving animal metamorphosis. This discovery sheds light on how a bacterial protein effector exerts its activity through membrane disruption, a phenomenon observed in various bacterial toxins affecting cellular functions, and elicits a developmental response. This work reveals a potential strategy used by marine organisms to respond to microbial cues, which could inform efforts in coral reef restoration and biofouling prevention. The study’s insights into metamorphosis-associated contractile structures’ delivery of protein effectors to specific anatomical locations highlight prospects for future biomedical and environmental applications. 

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3. Genetic examination of the marine bacterium Pseudoalteromonas luteoviolacea and effects of its metamorphosis‐inducing factors

   https://doi.org/10.1111/1462-2920.15211  

   Alker, Amanda_T; Delherbe, Nathalie; Purdy, Trevor_N; Moore, Bradley_S; Shikuma, Nicholas_J (September 2020, Environmental Microbiology)

   Summary Pseudoalteromonas luteoviolaceais a globally distributed marine bacterium that stimulates the metamorphosis of marine animal larvae, an important bacteria–animal interaction that can promote the recruitment of animals to benthic ecosystems. Recently, differentP.luteoviolaceaisolates have been shown to produce two stimulatory factors that can induce tubeworm and coral metamorphosis; Metamorphosis‐Associated Contractile structures (MACs) and tetrabromopyrrole (TBP) respectively. However, it remains unclear what proportion ofP.luteoviolaceaisolates possess the genes encoding MACs, and what phenotypic effect MACs and TBP have on other larval species. Here, we show that 9 of 19 sequencedP.luteoviolaceagenomes genetically encode both MACs and TBP. WhileP.luteoviolaceabiofilms producing MACs stimulate the metamorphosis of the tubewormHydroides elegans, TBP biosynthesis genes had no effect under the conditions tested. Although MACs are lethal to larvae of the cnidarianHydractinia symbiologicarpus,P.luteoviolaceamutants unable to produce MACs are capable of stimulating metamorphosis. Our findings reveal a hidden complexity of interactions between a single bacterial species, the factors it produces and two species of larvae belonging to different phyla. 

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4. Linking bacterial tetrabromopyrrole biosynthesis to coral metamorphosis

   https://doi.org/10.1038/s43705-023-00309-6  

   Alker, Amanda T.; Farrell, Morgan V.; Demko, Alyssa M.; Purdy, Trevor N.; Adak, Sanjoy; Moore, Bradley S.; Sneed, Jennifer M.; Paul, Valerie J.; Shikuma, Nicholas J. (September 2023, ISME Communications)

   Abstract An important factor dictating coral fitness is the quality of bacteria associated with corals and coral reefs. One way that bacteria benefit corals is by stimulating the larval to juvenile life cycle transition of settlement and metamorphosis. Tetrabromopyrrole (TBP) is a small molecule produced by bacteria that stimulates metamorphosis with and without attachment in a range of coral species. A standing debate remains, however, about whether TBP biosynthesis from livePseudoalteromonasbacteria is the primary stimulant of coral metamorphosis. In this study, we create aPseudoalteromonassp. PS5 mutant lacking the TBP brominase gene,bmp2. Using this mutant, we confirm that thebmp2gene is critical for TBP biosynthesis inPseudoalteromonassp. PS5. Mutation of this gene ablates the bacterium’s ability in live cultures to stimulate the metamorphosis of the stony coralPorites astreoides. We further demonstrate that expression of TBP biosynthesis genes is strongest in stationary and biofilm modes of growth, wherePseudoalteromonassp. PS5 might exist within surface-attached biofilms on the sea floor. Finally, we create a modular transposon plasmid for genomic integration and fluorescent labeling ofPseudoalteromonassp. PS5 cells. Our results functionally link a TBP biosynthesis gene from live bacteria to a morphogenic effect in corals. The genetic techniques established here provide new tools to explore coral-bacteria interactions and could help to inform future decisions about utilizing marine bacteria or their products for coral restoration. 

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5. Do details bug you? Effects of perceptual richness in learning about biological change

   https://doi.org/10.1002/acp.3698  

   Menendez, David; Rosengren, Karl S.; Alibali, Martha W. (June 2020, Applied Cognitive Psychology)

   Summary People often have difficulty in understanding processes of biological change, and they typically reject drastic life cycle changes such as metamorphosis, except for animals with which they are familiar. Even after a lesson about metamorphosis, people often do not generalize to animals not seen during the lesson. This might be partially due to the perceptual richness of the diagrams typically used during lessons on metamorphosis, which serves to emphasize the individual animal rather than a class of animals. In two studies, we examined whether the perceptual richness of a diagram influences adults' learning and transfer of knowledge about metamorphosis. One study was conducted in a laboratory setting, and the other was online. In both studies, adults who saw the bland diagram during the lesson accurately transferred more than adults who saw the rich diagram during the lesson. 

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