The deep-sea mussel Bathymodiolus harbors chemosynthetic bacteria in its gills that provide it with nutrition. Symbiont colonization is assumed to occur in early life stages by uptake from the environment, but little is known about this process. In this study, we used fluorescence in situ hybridization to examine symbiont distribution and the specificity of the infection process in juvenile B. azoricus and B. puteoserpentis (4-21 mm). In the smallest juveniles, we observed symbionts, but no other bacteria, in a wide range of epithelial tissues. This suggests that despite the widespread distribution of symbionts in many different juvenile organs, the infection process is highly specific and limited to the symbiotic bacteria. Juveniles >= 9mm only had symbionts in their gills, indicating an ontogenetic shift in symbiont colonization from indiscriminate infection of almost all epithelia in early life stages to spatially restricted colonization of gills in later developmental stages

Borowski, C.

Dubilier, N.

Huang, J.

Wendeberg, A.

Wentrup, C.

English

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SHORT COMMUNICATIONShift from widespread symbiont infection ofhost tissues to specific colonization of gillsin juvenile deep-sea musselsCecilia Wentrup1, Annelie Wendeberg2, Julie Y Huang3, Christian Borowski1 andNicole Dubilier11Max Planck Institute for Marine Microbiology, Symbiosis Group, Bremen, Germany; 2Department ofEnvironmental Microbiology, UFZ, Helmholtz Centre for Environmental Research, Leipzig, Germany and3Department of Microbiology and Immunology, Stanford University, Stanford, CA, USAThe deep-sea mussel Bathymodiolus harbors chemosynthetic bacteria in its gills that provide it withnutrition. Symbiont colonization is assumed to occur in early life stages by uptake from theenvironment, but little is known about this process. In this study, we used fluorescence in situhybridization to examine symbiont distribution and the specificity of the infection process injuvenile B. azoricus and B. puteoserpentis (4–21mm). In the smallest juveniles, we observedsymbionts, but no other bacteria, in a wide range of epithelial tissues. This suggests that despite thewidespread distribution of symbionts in many different juvenile organs, the infection process ishighly specific and limited to the symbiotic bacteria. JuvenilesX9mm only had symbionts in theirgills, indicating an ontogenetic shift in symbiont colonization from indiscriminate infection of almostall epithelia in early life stages to spatially restricted colonization of gills in later developmentalstages.The ISME Journal (2013) 7, 1244–1247; doi:10.1038/ismej.2013.5; published online 7 February 2013Subject Category: microbe-microbe and microbe-host interactionsKeywords: Bathymodiolus; Mid-Atlantic Ridge; symbiont transmission; hydrothermal ventsIntroductionAssociations with chemosynthetic bacteria haveevolved independently in at least four lineages ofmarine bivalves (Dubilier et al., 2008). In all theseassociations, the symbionts are generally restrictedto the gills in adult bivalves (Taylor and Glover,2010), except hosts that transfer their symbiontsdirectly to their offspring and harbor symbionts intheir gonads (Endow and Ohta, 1990; Cary andGiovannoni, 1993). In adult Bathymodiolusmussels,symbionts have only been observed in the gills(Distel et al., 1994; Duperron, 2010). These musselsoccur worldwide at hydrothermal vents andcold seeps and harbor their intracellular sulfur-and methane-oxidizing symbionts in gill cells calledbacteriocytes. Bathymodiolus is assumed to acquireits symbionts from the environment, but the devel-opmental stage at which this occurs is not known(Won et al., 2003; Duperron et al., 2007). Post-larvalBathymodiolus azoricus and B. heckerae as small as0.12mm appear to already harbor symbionts in theirgills based on transmission electron microscopy(TEM) observations of bacteria morphologicallysimilar to the sulfur- and methane-oxidizing sym-bionts (Salerno et al., 2005). These bacterial mor-photypes were also found in the mantle epithelia ofpost-larval and juvenile B. azoricus and B. heckerae(0.12–8.4mm). Similarly, in B. childressi juveniles(4–8mm) TEM revealed bacteria that looked like themethane-oxidizing symbionts in gills as well asmantle and foot epithelia, and labeling experimentsshowed that these bacteria fixed carbon frommethane (Streams et al., 1997). These studiessuggest that Bathymodiolus is colonized by itssymbionts at a very early stage and that other organsbesides the gills also contain symbionts.In this study, we focused on the followingquestions: (1) Do the symbionts indiscriminatelyinfect all host tissues of juvenile Bathymodiolus? (2)Are the symbionts the only bacteria that colonizejuvenile mussels? (3) Given that adult mussels areassumed to only have symbionts in their gills, isthere a developmental stage at which the broadCorrespondence: C Wentrup or N Dubilier, Max Planck Institutefor Marine Microbiology, Symbiosis Group, Celsiusstr. 1, Bremen28359, Germany.E-mail: cwentrup@mpi-bremen.de or ndubilie@mpi-bremen.deor A Wendeberg, Department of Environmental Microbiology,UFZ, Helmholtz Centre for Environmental Research,Permoserstrae 15, Leipzig 04318, Germany.E-mail: annelie.wendeberg@ufz.deReceived 9 July 2012; revised 15 November 2012; accepted 18December 2012; published online 7 February 2013The ISME Journal (2013) 7, 1244–1247& 2013 International Society for Microbial Ecology All rights reserved 1751-7362/13www.nature.com/ismejcolonization of host tissues ends? To answer thesequestions, we analyzed eight B. puteoserpentis andfive B. azoricus juveniles (4–21mm) from two ventsites on the Mid-Atlantic Ridge (SupplementaryTable S1) by fluorescence in situ hybridization(FISH). Semi-thin sections of whole juveniles wereexamined with symbiont-specific probes as well as ageneral eubacterial and a negative probe (seeSupplement for more details about methods).ResultsSymbionts broadly colonize tissues of smallest juvenilemusselsWe observed symbiont-specific FISH signals indi-cating the presence of both the sulfur- and themethane-oxidizing symbionts in gill bacteriocytes ofall 13 Bathymodiolus juveniles (Figure 1). In thesmallest individuals (4–7mm), we also foundFigure 1 Symbionts colonize many different epithelial tissues in juvenile B. puteoserpentis and B. azoricus. The mussels are shown inthe same orientation in all images with the anterior end on the left and the posterior end on the right. (a), (b) and (g) are B. azoricus; (c–f)are B. puteoserpentis. (a, b) Lateral view of small juvenile with (a) and without (b) shell valves. (c) Epifluorescence micrograph of a crosssection (ventral view) through entire juvenile mussel. The asterisk marks the foot tip that was curled dorsally. Mussel tissue that iscolonized throughout the mussel life cycle is colored in light red, whereas mussel tissues that are only infected in juveniles o9mm aremarked with a red dashed line. (d–g) Symbiont-specific FISH signals of the sulfur-oxidizing symbionts (green) and the methane-oxidizing symbionts (red) in epithelial cells of (d) gills and mantle, (e) mantle, (f) retractor muscle and (g) foot. In (e) and (f) signal overlapin a triple hybridization with the two symbiont-specific probes (red and green) and the eubacterial probe (EUB338 in yellow) makes themethane-oxidizing symbionts appear orange and the sulfur-oxidizing symbionts yellow-green. Owing to differences in signal intensity ofthe specific probes versus the eubacterial probe, some symbionts appear more yellow than others. The triple hybridization indicates thatonly the symbionts and no other bacteria are present. Nuclei of the host cells are stained with DAPI (blue).Symbiont colonization in juvenile BathymodiolusC Wentrup et al1245The ISME Journalsymbiont-specific FISH signals in the epithelialcells of the mantle, foot and retractor muscles(Table 1, Figure 1), but not in other tissuesor organs. The distribution and abundance of bothsymbionts was comparable in all organs exceptfor the much denser colonized gills, based onmicroscopic observations.The symbionts are the only bacteria that colonizejuvenile host tissuesExtensive FISH analyses of all 13 juveniles showedoverlap between the symbiont-specific and generaleubacterial probes (as well as with DAPI staining) inall colonized host tissues (Figure 1). This indicatesthat the sulfur- and methane-oxidizing symbiontsare the only bacteria that colonize juvenile mussels.Larger Bathymodiolus mussels only have symbiontsin their gill tissuesIn contrast to B. azoricus and B. puteoserpentisjuveniles p7mm, larger juveniles of both species(9–29mm) had symbiont-specific FISH signals onlyin their gills (Supplementary Figure S1). To examineif this spatial restriction of colonization to the gillsis also maintained in adult Bathymodiolus, weexamined mantle tissues attached to gills dissectedfrom B. azoricus (n¼ 6, 55–100mm). We onlyobserved the symbionts in the gills but never inthe mantle.Discussion and ConclusionsOur study provides the first FISH-based evidencethat the symbionts of early-stage B. azoricus and B.puteoserpentis p7mm colonize a wide range ofepithelial tissues. Together with earlier studies onjuvenile B. azoricus, B. heckerae and B. childressi(Streams et al., 1997; Salerno et al., 2005), theseresults indicate a consistent pattern of indiscrimi-nate symbiont colonization of a wide range ofepithelial tissues in Bathymodiolus p8.4mm(Table 1). This is remarkable given that in mostsymbioses examined to date, infection sites arespatially limited to specific tissues or areas, evenin early life stages of the host (Bright and Bulgheresi,2010). The ontogeny of symbiont colonization hasbeen thoroughly examined in only a few of the manybacteria–eukarya symbioses, and it is possible thatwide-spread colonization of many different tissuesin early life stages is not restricted to Bathymodiolusbut may also occur in other hosts. Despite thepervasive infection of Bathymodiolus juvenileepithelia, our study shows that colonization is onlyachieved by the symbionts (although we did notcheck for the intranuclear bacterial parasite thatcan also infect these hosts (Zielinski et al., 2009).Clearly, the infection process must be highlyregulated and specific to ensure that only thesymbionts colonize host cells.The most obvious explanation for the widespreadcolonization of host epithelia in juvenileBathymodiolus is that it provides the host withadditional nutrition. In bivalves, the gills typicallydevelop after the mantle and foot (Raven, 1958;Streams et al., 1997), and symbionts in mantle andfoot epithelia could thus provide the host withnutrients before the appearance of its gills. However,filter-feeding is assumed to be common in Bathy-modiolus (Pile and Young, 1999; Riou et al., 2010)and could provide juveniles with enough food tomake the nutritional contribution from the smallnumbers of symbionts in mantle and foot epitheliairrelevant.In both Bathymodiolus species investigated in thisstudy from two vent sites separated by almost3000 km, we observed that juveniles X9mm onlyhad symbionts in their gills. This indicates anontogenetic shift in symbiont colonization fromindiscriminate infection of different epithelia to ahighly restricted spatial limitation to gill bacterio-cytes at a developmental stage between 8.4–9mm.To our knowledge, such an ontogenetic shift insymbiont distribution patterns has not been pre-viously described in Bathymodiolus or any othersymbioses. Bathymodiolus gills with their greatlyenlarged surface areas and cilial ventilation are byfar the most efficient tissues for providing thesymbionts with the oxygen and reduced compoundsthey need to gain energy. However, the thin outerlayer of non-gill epithelia apparently has sufficientaccess to oxidants and reductants to harbor sym-bionts in juveniles o9mm, and it is not clear howthis would change when mussels become larger.On the other hand, the transfer and distribution ofnutrients from the symbionts to the host in foot andmantle epithelia might be hindered because theTable 1 Relationship between shell length and symbiont colonization patterns in Bathymodiolus musselsB. puteo serpentis(this study)B. azoricus(this study)B. childressi(Streams et al., 1997)B. heckerae(Salerno et al., 2005)B. azoricus(Salerno et al., 2005)Number of specimens 2 6 3 2 24 (in total) 18 4 15 4Shell length (mm) 6–7 9–21 4–5 27–29 4–8 0.12–8.4 adult(size nd)0.12–8.4 adult(size nd)Symbionts in gills Yes Yes Yes Yes Yes Yes Yes Yes YesSymbionts in epitheliabesides gillsMantle, foot andretractor musclesNo Mantle, foot andretractor musclesNo Mantleand footMantle Nd Mantle Ndnd, not determined.Symbiont colonization in juvenile BathymodiolusC Wentrup et al1246The ISME Journalsymbiont-containing cells in these tissues are notimmediately adjacent to the hemolymph lacuna asare the gill bacteriocytes. The cost of harboringsymbionts in non-gill tissues might therefore out-weigh their nutritional benefit. Alternatively, theimmune system of early stage Bathymodiolus mightnot be sufficiently developed to prevent indiscrimi-nate infection (Luna-Gonzalez et al., 2004; Huanet al., 2012). Teasing apart the roles that nutritionand the host immune system have in this ontoge-netic shift will provide a better understanding ofhow bacterial colonization patterns are established,maintained and regulated in animal symbioses.AcknowledgementsWe thank Silke Wetzel and Agnes Zimmer for excellenttechnical assistance, and the chief scientists, captains andcrew of the Hydromar I M60/3 and MenezMAR M82/3cruises as well as the ROV MARUM-Quest team for theirsupport. The funding for this study was provided bythe Max Planck Society, the DFG Cluster of Excellence‘The Ocean in the Earth System’ at MARUM, Bremen, andthe DFG Program SPP 1144 ‘From Mantle to the Ocean:Energy- Material- and Life-Cycles at Spreading Axes’. CWwas supported by a scholarship of the ‘Studienstiftung desdeutschen Volkes’ and JYH by a Fulbright Fellowship.ReferencesBright M, Bulgheresi S. (2010). A complex journey:transmission of microbial symbionts. Nat RevMicrobiol 8: 218–230.Cary SC, Giovannoni SJ. (1993). Transovarial inheritanceof endosymbiotic bacteria in clams inhabitingdeep-sea hydrothermal vents and cold seeps. ProcNatl Acad Sci USA 90: 5695–5699.Distel D, Felbeck H, Cavanaugh C. (1994). Evidence forphylogenetic congruence among sulfur-oxidizingchemoautotrophic bacterial endosymbionts and theirbivalve hosts. J Mol Evol 38: 533–542.Dubilier N, Bergin C, Lott C. (2008). 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Fish Shellfish Immunol 16: 287–294.Pile AJ, Young CM. (1999). Plankton availability andretention efficiencies of cold-seep symbiotic mussels.Limnol Oceanogr 44: 1833–1839.Raven CP. (1958). Morphogenesis: the analysis ofmolluscan development. In: Harris JE, Yemm EW(eds) International Series of Monographs on Pureand Applied Biology. Pergamon Press: New York.Riou V, Colaco A, Bouillon S, Khripounoff A, Dando P,Mangion P et al. (2010). Mixotrophy in the deep sea: adual endosymbiotic hydrothermal mytilid assimilatesdissolved and particulate organic matter. Mar EcolProgr Ser 405: 187–201.Salerno JL, Macko SA, Hallam SJ, Bright M, Won YJ,McKiness Z et al. (2005). Characterization of symbiontpopulations in life-history stages of mussels fromchemosynthetic environments. Biol Bull 208: 145–155.Streams ME, Fisher CR, FialaMedioni A. (1997). Metha-notrophic symbiont location and fate of carbonincorporated from methane in a hydrocarbon seepmussel. Mar Biol 129: 465–476.Taylor JD, Glover EA. (2010). Chemosymbiotic Bivalves.Vent and Seep Biota: Aspects from Microbes toEcosystems pp 107–135.Won YJ, Hallam SJ, O’Mullan GD, Pan IL, Buck KR,Vrijenhoek RC. (2003). Environmental acquisition ofthiotrophic endosymbionts by deep-sea mussels of thegenus Bathymodiolus. Appl Environ Microbiol 69:6785–6792.Zielinski FU, Pernthaler A, Duperron S, Raggi L, Giere O,Borowski C et al. (2009). Widespread occurrenceof an intranuclear bacterial parasite in vent andseep bathymodiolin mussels. Environ Microbiol 11:1150–1167.This work is licensed under the CreativeCommons Attribution-NonCommercial-NoDerivative Works 3.0 Unported License. To view acopy of this license, visit http://creativecommons.org/licenses/by-nc-nd/3.0/Supplementary Information accompanies the paper on The ISME Journal website (http://www.nature.com/ismej)Symbiont colonization in juvenile BathymodiolusC Wentrup et al1247The ISME Journal

Shift from widespread symbiont infection of host tissues to specific colonization of gills in juvenile deep-sea mussels

http://hdl.handle.net/21.11116/0000-0006-F436-A

Shift from widespread symbiont infection of host tissues to specific colonization of gills in juvenile deep-sea mussels

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