Insights into deep‐sea adaptations and host–symbiont interactions: A comparative transcriptome study on <i>Bathymodiolus</i> mussels and their coastal relatives

Zheng, Ping; Wang, Minxiao; Li, Chaolun; Sun, Xiaoqing; Wang, Xiaocheng; Sun, Yan; Sun, Song

doi:10.1111/mec.14160

Cited by 70 publications

(46 citation statements)

References 107 publications

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“…HSPA12A was suggested to possess cytoprotective functions in response to various stressors, especially pathogens (Libro and Vollmer 2016), toxic metals (Nicosia et al 2015), and heat stress (Wang et al 2014). RNA-directed DNA polymerase from mobile element jockey-like has RNA-directed DNA polymerase activity, and has been proven to play a key role in response to heat stress in the marine snail Nucella lapillus ) and environmental adaptation in deep-sea mussel Bathymodiolus platifrons (Zheng et al 2017). Both upregulation of HSPA12A (López-Galindo et al 2019) and RNA-directed DNA polymerase from mobile element jockey-like (Lancaster et al 2016) gene were detected in response to thermal stress.…”

Section: Discussionmentioning

confidence: 99%

Rapid climate-driven evolution of the invasive species Mytilus galloprovincialis over the past century

Han

Dong

2020

Anthropocene Coasts

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Climate-driven adaptive genetic variation is one of the most important ways for organisms to tolerate environmental change and succeed in altered environments. To understand rapid climate-driven evolution, and how this evolution might shift biogeographic distributions in response to global change, we measured the adaptive genetic variation to the local environment of a marine invasive species Mytilus galloprovincialis. The genetic structure of eight populations from the Mediterranean Sea, northeastern Atlantic, northeastern Pacific, and northwestern Pacific were determined using genome-wide screens for single nucleotide polymorphisms. The relationships of genetic variation to environmental (seawater and air) temperature were analyzed using redundancy analysis and BayeScEnv analysis to evaluate the impacts of temperature on the genetic divergences among these eight populations. We found that the genetic compositions were significantly different among populations and the adaptive genetic variation was associated with temperature variables. Further, we identified some genetic markers exhibiting signatures of divergent selection in association with environmental features that can be used in the future to closely monitor adaptive variation in this species. Our results suggest that divergent climatic factors have driven adaptive genetic variation in M. galloprovincialis over the past century. The rapid evolutionary adaptation has played a pivotal role in enabling this species to invade a wide range of thermal habitats successfully. Species like M. galloprovincialis that possess high levels of genetic variation may not only be especially capable of invading new habitats with different environmental conditions, but also poised to cope rapidly and successfully with rising global temperatures.

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Section: Discussionmentioning

confidence: 99%

Rapid climate-driven evolution of the invasive species Mytilus galloprovincialis over the past century

Han

Dong

2020

Anthropocene Coasts

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“…Conditions on the deep-sea floor are poorly known but generally are considered too harsh for the survival of most organisms, e.g., high hydrostatic pressure, darkness, hypoxia, low temperature, and limited food availability [1][2][3][4][5]. However, a macrofauna consisting of a growing range of newly discovered animals adapted to deep-sea habitats has been reported, including crustaceans [6][7][8], polychaetes [9,10], fishes [11,12], and mollusks [13,14]. Various mechanisms have adapted them for survival in deep-sea environments: e.g., squat lobsters and mussels have developed chemoautotrophic systems of symbiotic bacteria for inhabiting hydrothermal vents and cold seeps in the seafloor [15][16][17]; and snailfish have evolved special morphological and physiological characters to survive and thrive in the hadal zone [12].…”

Section: Introductionmentioning

confidence: 99%

Comparative transcriptomic analysis of deep- and shallow-water barnacle species (Cirripedia, Poecilasmatidae) provides insights into deep-sea adaptation of sessile crustaceans

et al. 2020

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Background: Barnacles are specialized marine organisms that differ from other crustaceans in possession of a calcareous shell, which is attached to submerged surfaces. Barnacles have a wide distribution, mostly in the intertidal zone and shallow waters, but a few species inhabit the deep-sea floor. It is of interest to investigate how such sessile crustaceans became adapted to extreme deep-sea environments. We sequenced the transcriptomes of a deep-sea barnacle, Glyptelasma gigas collected at a depth of 731 m from the northern area of the Zhongjiannan Basin, and a shallow-water coordinal relative, Octolasmis warwicki. The purpose of this study was to provide genetic resources for investigating adaptation mechanisms of deep-sea barnacles.Results: Totals of 62,470 and 51,585 unigenes were assembled for G. gigas and O. warwicki, respectively, and functional annotation of these unigenes was made using public databases. Comparison of the protein-coding genes between the deep-and shallow-water barnacles, and with those of four other shallow-water crustaceans, revealed 26 gene families that had experienced significant expansion in G. gigas. Functional annotation showed that these expanded genes were predominately related to DNA repair, signal transduction and carbohydrate metabolism. Base substitution analysis on the 11,611 single-copy orthologs between G. gigas and O. warwicki indicated that 25 of them were distinctly positive selected in the deep-sea barnacle, including genes related to transcription, DNA repair, ligand binding, ion channels and energy metabolism, potentially indicating their importance for survival of G. gigas in the deep-sea environment.(Continued on next page) Conclusions: The barnacle G. gigas has adopted strategies of expansion of specific gene families and of positive selection of key genes to counteract the negative effects of high hydrostatic pressure, hypoxia, low temperature and food limitation on the deep-sea floor. These expanded gene families and genes under positive selection would tend to enhance the capacities of G. gigas for signal transduction, genetic information processing and energy metabolism, and facilitate networks for perceiving and responding physiologically to the environmental conditions in deep-sea habitats. In short, our results provide genomic evidence relating to deep-sea adaptation of G. gigas, which provide a basis for further biological studies of sessile crustaceans in the deep sea.

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“…However, these studies failed to show the host response globally without state-of-the-art molecular tools. The successful application of next generation sequencing in deep sea mussels now provides a better solution [26,32]. In the present study, expressional alternations of Gigantidas genes during either symbiotic MOB or nonsymbiotic bacterial challenges were surveyed globally.…”

Section: Global Immune Response Of Gigantidas Against Mobs and Nonsymmentioning

confidence: 99%

microRNAs Facilitate Comprehensive Responses of Bathymodiolinae Mussel Against Symbiotic and Nonsymbiotic Bacteria Stimulation

Chen

Wang

Zhang

et al. 2020

Preprint

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Background:As the dominant species inhabiting both cold seeps and hydrothermal vents,Bathymodiolinae mussels are one of the most successful megafauna in the deep sea.They thrive in dark and food-insufficient environmentsby harboring sulfur-oxidizing bacteria (SOB)and/or methane-oxidizing bacteria (MOB)ingill bacteriocytesand obtain the majority of their nutrition from them.Many attempts have been made to decode the mechanisms underlying their symbiosis, which yetremained largely undisclosedfor years due to the lack of cultivable symbionts. In the present study,the globalexpression pattern of immune-related genes and miRNAswere surveyed inGigantidasplatifronsduring bacterial challengesusing enriched symbiontsor nonsymbioticVibrio in attempting to reveal the molecular mechanisms underlying chemosynthetic symbiosis. Results: Multiple PRRs such as TLRs, LRRs and C1q were found vigorously modulated during challenges whiledistinctly clusteredbetween symbiotic and nonsymbiotic bacteria stimulation. As downstream of the immune response,dozens of immune effectors including HSP70, P450, CD82 andvacuolar protein sorting-associated proteinwere modulated simultaneously, contributing to the fine tuning of cellular homeostasis, lysosome activity and bacteria engulfment in either symbiotic and nonsymbiotic bacteria challenge.A total of 459 miRNAs were identified in gill tissue of G. platifrons while dozens of themwere differentially expressedduring the challenge.Among these miRNAs, some were also found in differentexpression patternbetween symbiont or nonsymbiontchallenges and targeting apoptosis and phagosome maturation-related genes, including caspase8, inhibitor of apoptosis, cAMP-responsive element-binding protein,IκB, Rab and integrin. Conclusion:It was suggested that G. platifrons PRRs might function cooperativelyto facilitate the specialized immune recognition to MOBs or nonsymbioticbacteria. Meanwhile, a shared expression pattern of immune effectorswas observed between bacterial challenges, indicatingthe conservative response of Bathymodiolinae mussels in promoting the adhesion andengulfment of symbionts and nonsymbiont. Nevertheless, the differentially expressed miRNAs were yet suggested to facilitate specialized modulationinsymbiosis by repressing apoptosis- and phagosome maturation-related genes.With the orchestra of immune-related genes and miRNAs, G. platifronsmussels could therefore maintain arobust immune response against invading pathogens while establishing symbiosis with chemosynthetic bacteria.

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Insights into deep‐sea adaptations and host–symbiont interactions: A comparative transcriptome study on Bathymodiolus mussels and their coastal relatives

Cited by 70 publications

References 107 publications

Rapid climate-driven evolution of the invasive species Mytilus galloprovincialis over the past century

Rapid climate-driven evolution of the invasive species Mytilus galloprovincialis over the past century

Comparative transcriptomic analysis of deep- and shallow-water barnacle species (Cirripedia, Poecilasmatidae) provides insights into deep-sea adaptation of sessile crustaceans

microRNAs Facilitate Comprehensive Responses of Bathymodiolinae Mussel Against Symbiotic and Nonsymbiotic Bacteria Stimulation

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