1. Ecology and Environmental Management
Coral Reef Ecosystems
Ecology and Environmental Management

2. Lecture content Coral reef ecology Coral reef management
How they are formed
Physical Environment
Diversity patterns
Threats to coral reefs
Fisheries
Coral reef management
Assessing damage
Management for ecology and economics
Diversification
Tourism

3. Introduction to coral reefs

4. What is a “coral reef” Biological (“coral community”)
Organic, Biogenic
Coral and Algal communities
Mostly “hermatypic” corals, algae, and other sessile animals
Geological features (“reef”)
Carbonate
In situ buildup
Topographic relief
Wave resistant
Cemented, consolidated

5. Corals Phylum Anthazoa Class Cnidaria
Hermatypic (hard) corals contain symbiotic algae
Up to 500 spp. at some sites
Rosen 1981

6. CaCo3 addition - CaCo3 loss = Accumulation
Building the reef
CaCo3 addition - CaCo3 loss = Accumulation
Biological erosion
Mechanical erosion
Sediment export, dissolution
Reef Growth
Biogenic production
Sediment Import
Cementation
Kleypas et al 2001

7. Types of reef
Fringing, Barrier, Atoll, Drowned

8. Environmental requirements
Physical environment
Temperature of 25-31oC (limited Northwards by the 18oC minimum isotherm)
Salinity of ppt
Light level
Predominantly in top 30 m of water
Biological environment
Oligotrophic, highly stratified water column

9. Coral reef distribution

10. Coral diversity patterns

11. Maps
For the lecture I used maps from a variety of locations, often more for clarity than scientific detail. I would recommend the maps from the World Conservation Monitoring Centre ( which I would tend to value as reliable.
The main point being that the high population densities in many coastal areas which contain high coral reef species richness represent a serious threat.

12. Fish community Mainly Perciform teleosts
2 faunas, Diurnal and Nocturnal
Often territorial/site attached
Intraspecific interactions (pair bonding and harems) and interspecific mutualism (e.g. cleaning stations)
Mostly planktonic larvae
Estimated 4500 spp, 25% of marine total
~10% of world fishery landings

13. Fishery species
Often large, high-value fish

14. Fish distribution patterns

15. World population distribution

16. And if that wasn’t bad enough…..

17. Threats to coral reef systems
Overpopulation
Unsustainable fisheries
Coastal development
Global climate change

18. Coral reef fisheries Essential to survival of many
Managed sustainably for generations
Diverse ecosystem
Multispecies fisheries
Interspecies interactions may invalidate models
Collection of sufficient data for all species may not be practicable
Reduction of fishing effort to sustain all fish species wastes the productivity of most stocks

19. Non-selective and destructive fishing methods
Subsistence fishing occurs regardless of effort required
Muro Ami, Dynamite (Blast), and cyanide fishing
Trawling
Trapping and lines
Ghost fishing
Total fishing mortality often not known

20. Malthusian overfishing
“...occurs when poor fishermen, faced with declining catches and lacking any alternative initiate wholesale resource destruction in order to maintain their incomes.
This may involve in order of seriousness, and generally in temporal sequence...

21. 1) Use of gears and mesh sizes not sanctioned by government
2) Use of gears and mesh sizes not sanctioned within the fisherfolk community…
3) Use of gears that destroy the resource base
4) Use of gears such as dynamite or sodium cyanide that do all of the above and even endanger the fisherfolks themselves”
McManus 1997

22. Ecosystem effects of fisheries
Removal of predators
Removal of algal grazers
Change in dominance
Californian Sea Otters
Urchins
Crown of Thorns starfish “COTS” (Acanthaster planci)
Changes in size frequency of animals

23. Crown of Thorns Starfish

24. Crown of Thorns Eats coral by everting gut
Aggregations can remove 95% of coral cover
May result in collapse of remaining skeleton
Pheromone controlled aggregated spawning
Recovery takes at least 12 years
Caused by loss of predators?
Increased larval survival due to pollution?

25. Terrestrial impacts Pollution Sedimentation Eutrophication
Sewage
Agriculture
Aquaculture
Rubbish
Sedimentation
Eutrophication
Construction on reef flats
Coral mining
Mangrove destruction

26. Climate change Potential impacts on coral communities
Changes in water temperature
Increases in CO2 concentration
Changes in solar irradiation (if cloud cover changes)
Sea level rises leading to drowning of reefs
Changes in surface run-off (sedimentation)
Changes in land-use patterns leading to increased reef exploitation
Kleypas et al 2001

27. Coral bleaching Loss of symbiotic algae May cause death of animal
A symptom of climate change?

28. Coral Bleaching First described in 1984
Multiple re-occurrences at same sites
New sites impacted during 1990s
Many known triggers
Temperature (especially increases)
Solar radiation (especially UV)
Combination of UV and temperature
Reduced salinity
Infections

29. Effects of bleaching
Loss of symbiontic algae (Zooxanthellae) algae by:
Degradation In situ
Loss of algae by exocytosis
Expulsion of intact endodermal cells containing algae
Resulting impacts
Vary between species, and even parts of the same colony
Loss of sensitive species (especially Acropora spp.)
Recovery slow and highly variable between sites

30. The Problems
A large (and growing) number of people are dependent on coral reefs
Management of a multispecies fishery is extremely complex, and often fails
Terrestrial development may destroy coastal reef systems
Global climate change may exert new pressures

31. Coral reef management

32. Management Issues Biological What does the resource consist of?
What state is it in?
Is there overfishing?
Is there habitat destruction?
Socio-ecomomic
Levels of resource exploitation
More sustainable ways of exploiting the resource
Alternatives to coral reef exploitation/damage

33. Monitoring coral reefs
What sites and parameters to monitor?
Fish
Macroinvertebrates
Water quality
Benthic habitat quality
Coral health

34. Sources
Australian Institute for Marine Science (AIMS) website contains all their standard techniques. From a comparability point of view it is extremely helpful to use common techniques.
The AIMS site and their manual (English et al, 1997) even explains how to store the data in a database and manage it. Essential reading if you can get hold of it.
The use of volunteers for some types of coral reef survey work is very common and slightly controversial. Common sense will be necessary in determining what techniques a volunteer can apply - in particular for qualitative judgements about reef “quality” and levels of impact.

35. Large-scale studies Rapid Ecological Assessment
“Manta tows”
Estimates of % cover (live and dead coral)
Abundance of highly visible species
Human impacts
Mapping and aerial photography

36. Monitoring fish Visual census Fisheries monitoring Transects
Point counts
Random searching
Often allow biomass estimates
Fisheries monitoring

37. Monitoring the benthos
Line intercept transects
Visual transects
Quadrats
Photography and video

38. Line Intercept Transect

39. Marine protected areas
Fisheries reserves
“No take zones” (NTZs)
Controlled fishing
Effects on fish populations
Coral reef fish often have small ranges
Effects on fishing revenue
Local management and ownership

40. Sources
The marine protected areas case studies are based on the work of Russ and Alcala.
I think these are classic studies because they show both the conservation and economic benefits of marine reserves AND how important co-operation with the local community can be.
These are not new references, work from Roberts’s paper for newer studies. See also Gell and Roberts 2003 – Trends in Ecology and Evolution, 18,

41. Biological effects of protection
Habitat protection
Biodiversity
Protection of vulnerable species
Allow fish to grow to maturity
Control (reference) sites

42. Economic effects of protection
Increased size and abundance of stock species
Emmigration into fishing grounds (Spillover)
Insurance against management failure
Tourism “spin-offs”
Ease of enforcement

43. Marine reserves case study

44. Effects on fish diversity

45. Effects on fish abundance and biomass

46. Factors to consider Costs? Can you sell it? Size/shape of reserve?
Staff, setup, monitoring
Initial loss of fishing revenue
Size/shape of reserve?
Life history and behaviour of fish
Fishing intensity
20-40% of fishing ground
Can you sell it?
Any spin-off benefits?
Employment of local staff?
Compromise on size of reserve?
What management outside reserve?

47. Impacts of tourism Terrestrial development
Land reclamation and creation of beaches
Mangrove removal
Sand on reef flat
Boats
Anchors
Diver/snorkeller impacts and fish feeding
Sewage
Harbour dredging

48. Ras Mohammed project

49. Growth of reef tourism

50. Sources
This section is based on the works of David Medio and Julie Hawkins. A couple of their references are included at the end.
Much other material is directly from the Egyptian Environmental Affarirs Agency (link at the end)

51. Divers reduce coral cover

52. ….and scare away fish

53. Reducing diver impact Mooring buoys
Most damage caused my minority of divers
Education
Enforcement
Ban gloves
Monitoring
Zoning / Closure / Rotation

54. Managing terrestrial impacts
Catchment management
Agriculture
Fertiliser
Seafront corridors
Controls on sewage systems
Limits on development
Dry beaches and walkways

55. Who cares what happens to coral reefs anyway?
Fisheries
Tourism
Coastal protection
Bioprospecting
Moral reasons
Many coral reef functions are Subsistence
Do not show up as economic benefits
REPLACEMENT value may be extremely high

56. Summary Coral reefs contain diverse fish and invertebrate assemblages
This makes them valuable, but difficult to manage
Coral reefs are mainly found in the poorest areas of the world
This makes them prone to over-exploitation

57. Summary Reefs must be assessed and monitored to allow management
Marine protected areas may protect biodiversity and maintain fish stocks
Diversification of local economies may be effective in reducing pressures
Tourism brings new pressures which must also be managed.