Chronic effects of herbicide exposure on photosynthesis, symbiosis and reproduction of reef building corals
Cantin, Neal (2008) Chronic effects of herbicide exposure on photosynthesis, symbiosis and reproduction of reef building corals. PhD thesis, James Cook University.
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The herbicide, diuron, is found at levels equivalent to 1 μg l-1 within sediments in the Great Barrier Reef lagoon, where it potentially reduces photosynthesis and carbon fixation within Symbiodinium, the dinoflagellate symbiont associated with reef corals. Little is known about the potential of diuron to reduce energy acquisition and change energy allocation strategies to reproduction in corals. The objective of this study was to examine the importance of carbon-based energy (carbohydrates) derived from photosynthesis for gametogenesis, gamete viability and larval quality of corals following the first long-term, experimental exposures to diuron and to investigate the influence of symbiont type on energy provisioning to host tissues under normal conditions and in the presence of diuron. This is the first study to investigate the chronic sub-lethal effects of herbicide-induced photoinhibition on coral symbionts and the subsequent flow on effects to the fitness of the coral host.
Two broadcast spawning corals, Acropora tenuis and A. valida, and a brooding coral, Pocillopora damicornis, were exposed to 0 (control), 1.0 (low) and 10 (moderate) μg l-1 diuron treatments for 2 to 3 months prior to spawning or planulation. Diuron caused rapid and consistent declines in effective quantum yields of approximately 20% at 1.0 μg l-1 and 75% at 10 μg l-1 in each species compared to controls (Chapter 2). Total lipid content (coral tissue, oocytes and planulae) was reduced by 2.5- to 5-fold for the three species in the presence of diuron, indicating significant use of storage lipid to meet nutritional demands under conditions of chronic photoinhibition. Polyp fecundity in A. tenuis was not impacted, however it was reduced by 6-fold in A. valida, and both A. valida and P. damicornis were unable to spawn or planulate following long-term exposures to 10 μg l-1 diuron.
Maternal provisioning of lipids, pigments and antioxidants to coral eggs that lack Symbiodinium provides energy and protection essential for the development, survival and dispersal of coral larvae. For corals that were able to spawn or planulate following 2-3 month experimental exposures to diuron (i.e. A. valida and P. damicornis in the 0 and 1 μg l-1 treatments; A tenuis in the 0, and 10 μg l-1 treatments), gamete fertilisation was not affected (Chapter 3). Larvae from each of these species also successfully metamorphosed into juvenile corals following parental exposures to the above diuron treatments. Although gametes were viable, gamete quality was reduced in A. valida following even low exposures to diuron. Peridinin, the major carotenoid pigment identified in A. valida eggs, was 10-fold lower in eggs derived from corals exposed to 1.0 μg l-1 diuron compared with tank controls. The tank controls in turn contained 5-fold less peridinin than field controls. In contrast, no difference in vitamin E (α – tocopherol) was detected in any of the treatments. Peridinin in combination with xanthophylls may enhance the capacity of buoyant coral eggs to absorb potentially harmful high-energy photosynthetically active radiation (PAR, 400 - 530 nm) that is not absorbed by mycosporine-like amino acids (MAAs) and vitamin E. All of these compounds are likely to work synergistically to protect eggs from oxidative damage.
Algal endosymbionts of the genus Symbiodinium play a key role in fulfilling the nutritional requirements of reef building corals, however comparisons of photosynthetic capacity among different Symbiodinium types in hospite within the same coral species have only recently become possible. A sensitive quantitative PCR assay was developed for Symbiodinium spp. (Chapter 4) based upon chloroplast (cp) large subunit (23S) ribosomal DNA sequences, to detect low level background strains of Symbiodinium spp. It was then applied to verify symbiont assemblages within juvenile colonies of Acropora millepora that had been experimentally infected with two different symbiont types (Chapter 5). Using experimentally infected C1- and D-juveniles of A. millepora, relative electron transport (rETRMAX) of PSII, was found to be 87% greater in Symbiodinium C1 than in Symbiodinium D in hospite in the control treatment, resulting in a doubling of 14C photosynthate incorporation (energy) into juvenile tissues of A. millepora (Chapter 5). Symbiodinium C1 corals, however, lost this competitive advantage in the presence of diuron, due to inhibition of rapid electron transport. There was no observable difference in phytotoxicity of diuron between genetically distinct symbionts in situ. The finding that genetically distinct Symbiondinium spp. are not functionally equivalent, highlights the importance of symbiont identity in the nutritional physiology of the coral-algal holobiont.
These results provide evidence of a link between reduced energy acquisition due to diuron exposure causing significant PSII photoinhibition and reduced reproductive output in zooxanthellate corals. Energy allocated to reproduction was directed towards maintaining and releasing fewer eggs and larvae, while ensuring the full developmental viability of these progeny. Along with diuron, other herbicides such as atrazine and Irgarol 1051 that are designed to target the PSII in the same manner as diuron, are commonly found entering the marine environment, which could create an additive effect on the chronic impacts induced by diuron exposure within the natural environment. The observed reductions in reproductive development (A. valida) and reproductive output (A. valida and P. damicornis) caused by the inhibition of energy acquisition from photosynthesis following long-term diuron exposure, highlights the importance of carbon-based energy from photosynthesis for coral reproduction and provides further evidence of physiological trade-offs that can result following events that limit the availability of energetic resources to individual coral colonies.
|Item Type:||Thesis (PhD)|
|Keywords:||herbicide exposure, corals, coral photosynthesis, coral reproduction, diuron, symbionts, herbicide-induced photoinhibition, coral spawning, chronic photoinhibition, herbicides, Great Barrier Reef, Australia|
|FoR Codes:||06 BIOLOGICAL SCIENCES > 0601 Biochemistry and Cell Biology > 060104 Cell Metabolism @ 50%|
06 BIOLOGICAL SCIENCES > 0602 Ecology > 060205 Marine and Estuarine Ecology (incl Marine Ichthyology) @ 50%
|SEO Codes:||96 ENVIRONMENT > 9608 Flora, Fauna and Biodiversity > 960808 Marine Flora, Fauna and Biodiversity @ 100%|
|Deposited On:||09 Oct 2009 09:56|
|Last Modified:||12 Feb 2011 02:49|
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