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Coral bleaching

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Coral bleaching

Bleached corals
Healthy corals

Coral bleaching is the loss of intracellular endosymbionts (Symbiodinium, also known as zooxanthellae) through either expulsion or loss of algal pigmentation.[1] The corals that form the structure of the great reef ecosystems of tropical seas depend upon a symbiotic relationship with algae-like unicellular flagellate protozoa that are photosynthetic and live within their tissues. Zooxanthellae give coral its coloration, with the specific color depending on the particular clade. Some scientists consider bleaching a poorly-understood type of "stress" related to high irradiance; environmental factors like sediments, harmful chemicals and freshwater; and high or low water temperatures.[1] This "stress" causes corals to expel their zooxanthellae, which leads to a lighter or completely white appearance, hence the term "bleached".[2] Bleaching has been attributed to a defense mechanism in corals; this is called the "adaptive bleaching hypothesis," from a 1993 paper by Robert Buddemeier and Daphne Fautin.[3] Bleached corals continue to live, but growth is limited until the protozoa return.

Contents

  • Causes 1
  • Triggers 2
  • Effects 3
  • Mass bleaching events 4
    • Monitoring reef sea surface temperature 4.1
    • Changes in ocean chemistry 4.2
    • Infectious disease 4.3
  • Impact 5
    • Great Barrier Reef 5.1
    • Other areas 5.2
      • Hawaii 5.2.1
    • Economic and political impact 5.3
  • Coral adaptation 6
  • Sunscreen is destroying coral reefs 7
  • See also 8
  • Notes 9
  • References 10
  • External links 11

Causes

Bleaching occurs when the conditions necessary to sustain the coral's zooxanthellae cannot be maintained.[4] Any environmental trigger that affects the coral's ability to supply the zooxanthellae with nutrients for photosynthesis (carbon dioxide, ammonium) will lead to expulsion.[4] This process is a "downward spiral", whereby the coral's failure to prevent the division of zooxanthellae leads to ever-greater amounts of the photosynthesis-derived carbon to be diverted into the algae rather than the coral. This makes the energy balance required for the coral to continue sustaining its algae more fragile, and hence the coral loses the ability to maintain its parasitic control on its zooxanthellae.[4]

Physiologically the lipid composition of the symbiont thylakoid membrane affects their structural integrity when there is a change in temperature, which combined with increased nitric acid results in damage to photosystem II. As a result of accumulated oxidative stress and the damage to the thylakoid of chloroplasts there is an increase in degradation of the symbiosis and the symbionts will eventually abandon their host. Not only does the change in temperature in the water increase the chances of bleaching, but there are other factors that play a role. Other factors include an increase in solar radiation (UV and visible light), regional weather conditions, and for intertidal corals, exposure to cold winds.[5]

Triggers

Coral bleaching is theorized to be a generalized stress response of corals that may be caused by a number of biotic and abiotic factors, including:

While most of these triggers may result in localized bleaching events (tens to hundreds of kilometers), mass coral bleaching events occur at a regional or global scale and are triggered by periods of elevated thermal stress resulting from increased sea surface temperatures.[13] The coral reefs that are more subject to continued bleaching threats are the ones located in warm and shallow water with low water flow. Physical factors that can prevent or reduce the severity of bleaching are available for the reefs located under conditions that include low light, cloud cover, high water flow and higher nutrient availability.[5]

Effects

Healthy coral at left and bleached, but still living, coral to right

The color of a coral depends largely on the species of symbiont. A reduction in concentration of zooxanthellae causes paling and an increase results in deepening of color. Stony corals have calcium carbonate skeletons and most have transparent tissues, so expulsion of the zooxanthellae causes them to lose their color and become white. Although the coral polyps feed on zooplankton and other food particles, the majority of reef-forming corals rely for a large proportion of their nutritional requirements on their zooxanthellae. This means that without them they are liable to starve. Coral growth and reproduction are reduced and the coral becomes increasingly susceptible to disease. If stress factors reduce and the zooxanthellae return, the coral can recover, but prolonged bleaching causes death of the coral.[26]

Ejection increases the polyp's chance of surviving short-term stress. It can regain symbionts, possibly of a different species, at a later time. If the stressful conditions persist, the polyp eventually dies.[27]

Mass bleaching events

Bleached Acropora coral (foreground) and normal colony (background), Keppel Islands, Great Barrier Reef

Most evidence indicates that elevated temperature is the cause of mass bleaching events. Sixty major episodes of coral bleaching have occurred between 1979 and 1990,[28][29] with the associated coral mortality affecting reefs in every part of the world. Correlative field studies have pointed to warmer-than normal conditions as being responsible for triggering mass bleaching events. These studies show a tight association between warmer-than-normal conditions (at least 1 °C higher than the summer maximum) and the incidence of coral bleaching.[30]

Factors that influence the outcome of a bleaching event include stress-resistance which reduces bleaching, tolerance to the absence of zooxanthellae, and how quickly new coral grows to replace the dead. Due to the patchy nature of bleaching, local climatic conditions such as shade or a stream of cooler water can reduce bleaching incidence.[31] Coral and zooxanthellae health and genetics also influence bleaching.[31]

Large coral colonies such as Porites are able to withstand extreme temperature shocks, while fragile branching corals such Acropora are far more susceptible to stress following a temperature change.[32] Corals consistently exposed to low stress levels may be more resistant to bleaching.[33][34]

Monitoring reef sea surface temperature

The US National Oceanic and Atmospheric Administration (NOAA) monitors for bleaching "hot spots", areas where sea surface temperature rises 1 °C or more above the long-term monthly average. This system detected the worldwide 1998 bleaching event,[35][36] that corresponded to an El Niño. NOAA also uses a nighttime-only satellite; these observations are taken at night to avoid the increase in temperature due to daily warming caused by solar heating at the sea surface during the day. This is also a precaution to avoid glare from the sun.[37]

Changes in ocean chemistry

Increasing ocean acidification due to rises in carbon dioxide levels exacerbates the bleaching effects of thermal stress. Acidification affects the corals' ability to create calcareous skeletons, essential to their survival.[38] A recent study from the Atkinson Center for a Sustainable Future found that with the combination of acidification and temperature rises, the levels of CO2 could become too high for coral to survive in as little as 50 years.[38]

Infectious disease

Infectious bacteria of the species Vibrio shiloi are the bleaching agent of Oculina patagonica in the Mediterranean Sea, causing this effect by attacking the zooxanthellae.[39][40][41] V. shiloi is infectious only during warm periods. Elevated temperature increases the virulence of V. shiloi, which then become able to adhere to a beta-galactoside-containing receptor in the surface mucus of the host coral.[40][42] V. shiloi then penetrates the coral's epidermis, multiplies, and produces both heat-stable and heat-sensitive toxins, which affect zooxanthellae by inhibiting photosynthesis and causing lysis.

During the summer of 2003, coral reefs in the Mediterranean Sea appeared to gain resistance to the pathogen, and further infection was not observed.[43] The main hypothesis for the emerged resistance is the presence of symbiotic communities of protective bacteria living in the corals. The bacterial species capable of lysing V. shiloi had not been identified as of 2011.

Impact

Two images of the Great Barrier Reef showing that the warmest water (top picture) coincides with the coral reefs (lower picture), setting up conditions that can cause coral bleaching

In the 2012-2040 period, coral reefs are expected to experience more frequent bleaching events. The Intergovernmental Panel on Climate Change (IPCC) sees this as the greatest threat to the world's reef systems.[44][45][46][47]

Great Barrier Reef

The Great Barrier Reef along the coast of Australia experienced bleaching events in 1980, 1982, 1992, 1994, 1998, 2002, and 2006.[47] Some locations suffered severe damage, with up to 90% mortality.[12] The most widespread and intense events occurred in the summers of 1998 and 2002, with 42% and 54% respectively of reefs bleached to some extent, and 18% strongly bleached.[48][49] However coral losses on the reef between 1995 and 2009 were largely offset by growth of new corals.[50] An overall analysis of coral loss found that coral populations on the Great Barrier Reef had declined by 50.7% from 1985 to 2012, but with only about 10% of that decline attributable to bleaching, and the remaining 90% caused about equally by tropical cyclones and by predation by crown-of-thorns starfishes.[51]

The IPCC's moderate warming scenarios (B1 to A1T, 2 °C by 2100, IPCC, 2007, Table SPM.3, p. 13[52]) forecast that corals on the Great Barrier Reef are very likely to regularly experience summer temperatures high enough to induce bleaching.[48]

Other areas

Other coral reef provinces have been permanently damaged by warm sea temperatures, most severely in the Indian Ocean. Up to 90% of coral cover has been lost in the Maldives, Sri Lanka, Kenya and Tanzania and in the Seychelles.[53]

Coral in the south Red Sea does not bleach despite summer water temperatures up to 34 °C.[33][54]

Hawaii

Evidence of thermal tolerance in Hawaiian corals and of oceanic warming from research in the 1970s led researchers in 1990 to predict mass occurrences of coral bleaching throughout Hawaii. Major bleaching occurred in 1996 and in 2002.[55] Biologists from the University of Queensland observed the first mass bleaching event for Hawaiian coral reefs in 2014, and attributed it to The Blob.[56]

Economic and political impact

According to Brian Skoloff of The Christian Science Monitor, "If the reefs vanished, experts say, hunger, poverty and political instability could ensue."[57] Since countless sea life depends on the reefs for shelter and protection from predators, the extinction of the reefs would ultimately create a domino effect that would trickle down to the many human societies that depend on those fish for food and livelihood. There has been a 44% decline over the last 20 years in the Florida Keys, and up to 80% in the Caribbean alone.[58]

Coral adaptation

In 2010, researchers at Penn State discovered corals that were thriving while utilizing an unusual species of symbiotic algae in the warm waters of the Andaman Sea located in the Indian Ocean. Normal zooxanthellae cannot withstand temperatures as high as in that location, so this finding was unexpected. This gives researchers hope that with rising temperatures due to global warming, coral reefs will develop tolerance for different species of symbiotic algae that are resistant to high temperature, and can live within the reefs.[59][60]

Sunscreen is destroying coral reefs

On October 21, 2015 Time Magazine reported on a study published in the journal Archives Of Environmental Contamination And Toxicology , claiming that the ingredient oxybenzone found in many sunscreens is the cause for the coral destruction. This chemical causes the coral to reject the algae called zooxanthellae that gives the coral its colors. This loss of algae is known as coral bleaching. The study found that sunscreen the equivalent of a water drop in an Olympic size swimming pool is toxic to the coral.

See also

Notes

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  2. ^ Hoegh-Guldberg O (1999). "Climate change, coral bleaching and the future of the world's coral reefs" (PDF). Mar. Freshwater Res. 50 (8): 839–66.  
  3. ^ The Coral Reef Era: From Discovery to Decline: A history of scientific investigation from 1600 to the Anthropocene Epoch, James Bowen, Springer, Jan 6, 2015, ISBN 978-3-319-07478-8, DOI 10.1007/978-3-319-07479-5
  4. ^ a b c Wooldridge, S. A. (2010). "Is the coral-algae symbiosis really 'mutually beneficial' for the partners?". BioEssays 32 (7): 615–625.  
  5. ^ a b Baker, Andrew. Glynn, Peter. Riegl, Bernhard. 2008 "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science. 80: 435–471
  6. ^ "REEF ‘AT RISK IN CLIMATE CHANGE’". Retrieved 12 July 2007. 
  7. ^ Anthony, K. 2007; Berkelmans
  8. ^ Saxby, T.; Dennison, W. C.; Hoegh-Guldberg, O. (2003). "Photosynthetic responses of the coral Montipora digitata to cold temperature stress". Marine Ecology Progress Series 248: 85.  
  9. ^ Marimuthu, N.; Wilson, J. Jerald; Vinithkumar, N. V.; Kirubagaran, R. (2012). "Coral reef recovery status in south Andaman Islands after the bleaching event 2010". Journal of Ocean University of China 12 (1): 91–96.  
  10. ^ "Mass Coral Bleaching". fisherycrisis.com. 
  11. ^ Fitts 2001
  12. ^ a b Johnson, Johanna E; Marshall, Paul A (2007). Climate change and the Great Barrier Reef: a vulnerability assessment. Townsville, Qld.: Great Barrier Reef Marine Park Authority.  
  13. ^ a b Hoegh-Guldberg O, Mumby PJ, Hooten AJ; et al. (December 2007). "Coral reefs under rapid climate change and ocean acidification". Science 318 (5857): 1737–42.  
  14. ^ Rogers, S.R. (1990). "Responses of coral reefs and reef organisms to sedimentation" (PDF). Marine Ecology Progress Series 62: 185–202.  
  15. ^ Kushmaro, A., Rosenberg, E., Fine, M., Loya, Y.; Rosenberg; Fine; Loya (1997). "l Beaching of the coral Oculina patagonica by Vibrio AK-1" (PDF). Marine Ecology Progress Series 147: 159–165.  
  16. ^ Hoegh-Guldberg, O. and Smith, G.J. (1989). "The effect of sudden changes in temperature, light and salinity on the population density and export of zooxanthellae from the reef corals Stylophora pistillata Esper and Seriatopora hystrix Dana". Journal of Experimental Marine Biology and Ecology 129 (3): 279–303.  
  17. ^ Jones, R.J., Muller, J., Haynes, D., Schrieber, U.,; Muller; Haynes; Schreiber (2003). "Effects of herbicides diuron and atrazine on corals of the Great Barrier Reef, Australia" (PDF). Marine Ecology Progress Series 251: 153–167.  
  18. ^ Anthony, K.R.N. and Kerswell, A.P. (2007). "Coral mortality following extreme low tides and high solar radiation". Marine Ecology Progress Series 151 (5): 1623–1631.  
  19. ^ Jones, R.J. and Hoegh-Guldberg, O. (1999). Effects of cyanide on coral photosynthesis: implications for identifying the cause of coral bleaching and for assessing the environmental effects of cyanide fishing. Mar Ecol. Prog. Ser. 177: 83–91
  20. ^ U. S. Geological Survey. Coral Mortality and African Dust. Retrieved on 2007-06-10.
  21. ^ "Protect Yourself, Protect The Reef! The impacts of sunscreens on our coral reefs" (PDF). U.S. National Park Service. Retrieved 1 July 2013. 
  22. ^ Than, Ker. "Swimmers' Sunscreen Killing Off Coral". National Geographic News. National Geographic News. Retrieved January 29, 2008. 
  23. ^ "Coral Reef Safe Sunscreen". badgerbalm.com. 
  24. ^ Danovaro, Roberto; Bongiorni, Lucia; Corinaldesi, Cinzia; Giovannelli, Donato; Damiani, Elisabetta; Astolfi, Paola; Greci, Lucedio; Pusceddu, Antonio (2008). "Sunscreens Cause Coral Bleaching by Promoting Viral Infections". Environmental Health Perspectives 116 (4): 441–447.  
  25. ^ Downs, C. A., Kramarsky-Winter, E., Fauth, J. E., Segal, R., Bronstein, O., Jeger, R., ... & Loya, Y. (2014). "Stylophora pistillata"Toxicological effects of the sunscreen UV filter, benzophenone-2, on planulae and in vitro cells of the coral, . Ecotoxicology, 23 (2): 175–191. doi:10.1007/s10646-013-1161-y
  26. ^ "Symbiotic algae". NOAA coral reef conservation program. NOAA. Retrieved 2015-01-29. 
  27. ^ W. W. Toller, R. Rowan and N. Knowlton (2001). following Experimental and Disease-Associated Bleaching"M. faveolata and Montastraea annularis"Repopulation of Zooxanthellae in the Caribbean Corals . The Biological Bulletin (Marine Biological Laboratory) 201 (3): 360–373.  
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  29. ^ Huppert, Amit; Lewis Stone (September 1998). "Chaos in the Pacific's Coral Reef Bleaching Cycle". The American Naturalist 152 (3): 447–459.  
  30. ^ Baker, Andrew (2008). "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science 80 (4): 438. 
  31. ^ a b Marshall, Paul; Schuttenberg, Heidi (2006). A Reef Manager’s Guide to Coral Bleaching (PDF). Townsville, Australia:  
  32. ^ Baird and Marshall 2002
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  34. ^ Iguchi, Akira; Ozaki, Saori; Nakamura, Takashi; Inoue, Mayuri; Tanaka, Yasuaki; Suzuki, Atsushi; Kawahata, Hodaka; Sakai, Kazuhiko (2012). "Effects of acidicied seawater on coral calcification and symbiotic algae on the massive coral Porites australiensis". Marine Environmental Research 73: 32–36.  
  35. ^ "NOAA Hotspots". 
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  37. ^ NOAA Coral Reef Watch. "Methodology, Product Description, and Data Availability of Coral Reef Watch Operational and Experimental Satellite Coral Bleaching Monitoring Products". NOAA. Retrieved 27 February 2014. 
  38. ^ a b Lang, Susan (13 December 2007). "'"Major international study warns global warming is destroying coral reefs and calls for 'drastic actions. Cornell Chronicle. Retrieved 8 August 2011. 
  39. ^ Kushmaro, A.; Loya, Y.; Fine, M.; Rosenberg, E. (1996). "Bacterial infection and coral bleaching". Nature 380 (6573): 396.  
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  51. ^ De'ath, Glenn; Fabricius, Katharina E.; Sweatman, Hugh; Puotinen, Marji (October 1, 2012). "The 27–year decline of coral cover on the Great Barrier Reef and its causes". Proceedings of the National Academy of Sciences 109 (44): 17995–17999.  
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  60. ^ LaJeunesse, Todd; Smith, Robin (2010). "Host–symbiont recombination versus natural selection in the response of coral–dinoflagellate symbioses to environmental disturbance". Proceedings: Biological Sciences 277 (1696): 2925–2934.  

References

Watson, Megan E. "Coral Reefs." Encyclopedia of Environmental Issues. Rev. ed. Vol. 1. Pasadena: Salem Press, 2011. pp. 317–318. ISBN 978-1-58765-736-8

External links

  • Great Barrier Reef Marine Park Authority information on bleaching.
  • ReefBase: a global information system on coral reefs.
  • More details on coral bleaching, causes and effects.
  • Travellers Impressions
  • The Link between Overfishing and Mass Coral Bleaching
  • Discussion on Overfishing and Coral Bleaching
  • Social & Economic Costs of Coral Bleaching from "NOAA Socioeconomics" website initiative
  • Microdocs: Coral bleaching
  • Coral Bleaching at Maro Reef, September 2004
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