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Seagrass Wasting Disease Impact of abiotic factors and chemical defense

Abstract
Eelgrass, Zostera marina, is the dominant seagrass species in the northern hemisphere, and forms large meadows that provide several important ecosystem services. In the 1930s about 90% of the Z. marina populations in the Atlantic Ocean were killed in an epidemic caused by the wasting disease pathogen Labyrinthula zosterae. Despite the devastating impact of this disease the host-pathogen interaction is still poorly understood, and there is limited knowledge about factors that influence the disease. In this thesis I study how abiotic factors can impact the relationship between Z. marina and L. zosterae, and investigate if the seagrass can defend itself against the pathogen through production of inhibitory compounds. In two field studies I investigated if laboratory results, showing that low salinity mitigate L. zosterae infection, can be translated to the field. Surveys along the salinity gradient of the Swedish coast show that L. zosterae infection is high in high salinity areas (20 - 25 PSU), and that infection generally decreases or disappears at low salinity (<10 PSU). These findings suggest that low salinity areas can act as a refuge against seagrass wasting disease. However, in contrast to previous studies, salinities as low as 6 PSU do not always exclude infection in Z. marina meadows. The disease was detected, in low concentrations through DNA-based methods,, in several meadows in the Baltic proper. Thus, it is possible that a L. zosterae strain has adapted to the low salinity environment of the Baltic Sea. This could lead to an increased distribution of the pathogen in areas previously considered to be protected from the pathogen, and potentially result in wasting disease outbreaks also in low salinity Z. marina meadows. One way for Z. marina to withstand infection by L. zosterae is to be chemically defended through the production of secondary metabolites. All Z. marina shoots investigated in this thesis produced chemical compounds that inhibited L. zosterae growth. Laboratory experiments implied that the production is not induced by a high pathogen pressure, as previously suggested, but rather that Z. marina contains inhibitory compounds that function as a constitutive defense. Chemical analyses further detected three partially purified inhibitory fractions against the pathogen, and characterization of the compounds showed that these are new, yet unknown, compounds from Z. marina. A laboratory infection experiment was performed to investigate how individual and interactive effects of extrinsic factors affect L. zosterae infection in Z. marina. The results showed a complex host-pathogen interaction, with several interactions between light, temperature, tissue damage, and infection that affected growth, production of inhibitory compounds, and gene expression in Z. marina. Overall, light intensity had the strongest effect on wasting disease, where reduced light intensity resulted in a significant increase in lesion coverage.
Parts of work
Jakobsson-Thor S., Toth G.B., Brakel J., Bockelmann A-C., Pavia H. in press. Seagrass wasting disease varies with salinity and depth in natural Zostera marina populations. Marine Ecology Progress Series. ::doi::10.3354/meps12406
 
Jakobsson-Thor S., Toth G.B., Pavia H. Seagrass wasting disease along a naturally occurring salinity gradient. Manuscript.
 
Jakobsson-Thor S., Toth G.B., Brakel J., Pavia H. Effects of temperature, light and tissue damage on seagrass wasting disease in Zostera marina. Manuscript.
 
Jakobsson-Thor S., Poulin R.X., Toth G.B., Kubanek J., Pavia H. Chemical defense against the wasting disease pathogen Labyrinthula zosterae in eelgrass, Zostera marina. Manuscript.
 
Degree
Doctor of Philosophy
University
Göteborgs universitet. Naturvetenskapliga fakulteten
Institution
Department of Marine Sciences ; Institutionen för marina vetenskaper
Disputation
Fredagen den 15 december 2017 kl. 10.00 Hörsalen-Tjärnö, Hättebäcksvägen 7, Strömstad
Date of defence
2017-12-15
E-mail
stina.jakobsson@gu.se
URI
http://hdl.handle.net/2077/54176
Collections
  • Doctoral Theses / Doktorsavhandlingar Institutionen för marina vetenskaper
  • Doctoral Theses from University of Gothenburg / Doktorsavhandlingar från Göteborgs universitet
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Date
2017-12-04
Author
Jakobsson-Thor, Stina
Keywords
Seagrass wasting disease
Infection
Abiotic factors
Zostera marina
Labyrinthula zosterae
Eelgrass
Chemical defense
Host-pathogen interaction
Publication type
Doctoral thesis
ISBN
978-91-629-0373-2
Language
eng
Metadata
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