Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword
- Introduction
- Chapter 1 A separate creation: diversity, distinctiveness and conservation of Australian wildlife
- Chapter 2 New Zealand – a land apart
- Chapter 3 The ecological consequences of habitat loss and fragmentation in New Zealand and Australia
- Chapter 4 The impacts of climate change on Australian and New Zealand flora and fauna
- Chapter 5 Unwelcome and unpredictable: the sorry saga of cane toads in Australia
- Chapter 6 Invasive plants and invaded ecosystems in Australia: implications for biodiversity
- Chapter 7 Environmental weeds in New Zealand: impacts and management
- Chapter 8 The insidious threat of invasive invertebrates
- Chapter 9 Pollution by antibiotics and resistance genes: dissemination into Australian wildlife
- Chapter 10 Invasive vertebrates in Australia and New Zealand
- Chapter 11 Freshwaters in New Zealand
- Chapter 12 A garden at the edge of the world; the diversity and conservation status of the New Zealand flora
- Chapter 13 The evolutionary history of the Australian flora and its relevance to biodiversity conservation
- Chapter 14 Protecting the small majority: insect conservation in Australia and New Zealand
- Chapter 15 Terrestrial mammal diversity, conservation and management in Australia
- Chapter 16 Marine mammals, back from the brink? Contemporary conservation issues
- Chapter 17 Australian reptiles and their conservation
- Chapter 18 New Zealand reptiles and their conservation
- Chapter 19 Isolation, invasion and innovation: forces of change in the conservation of New Zealand birds
- Chapter 20 Australian birds: current status and future prospects
- Chapter 21 Austral amphibians – Gondwanan relicts in peril
- Chapter 22 Predators in danger: shark conservation and management in Australia, New Zealand and their neighbours
- Chapter 23 ‘Ragged mountain ranges, droughts and flooding rains’: the evolutionary history and conservation of Australian freshwater fishes
- Chapter 24 Down under Down Under: Austral groundwater life
- Chapter 25 Fire and biodiversity in Australia
- Chapter 26 Terrestrial protected areas of Australia
- Chapter 27 Australian marine protected areas
- Chapter 28 Marine reserves in New Zealand: ecological responses to protection and network design
- Chapter 29 Conclusion: conservation onboard Austral Ark needs all hands on deck
- Index
- Plate section
- References
Chapter 28 - Marine reserves in New Zealand: ecological responses to protection and network design
Published online by Cambridge University Press: 05 November 2014
Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword
- Introduction
- Chapter 1 A separate creation: diversity, distinctiveness and conservation of Australian wildlife
- Chapter 2 New Zealand – a land apart
- Chapter 3 The ecological consequences of habitat loss and fragmentation in New Zealand and Australia
- Chapter 4 The impacts of climate change on Australian and New Zealand flora and fauna
- Chapter 5 Unwelcome and unpredictable: the sorry saga of cane toads in Australia
- Chapter 6 Invasive plants and invaded ecosystems in Australia: implications for biodiversity
- Chapter 7 Environmental weeds in New Zealand: impacts and management
- Chapter 8 The insidious threat of invasive invertebrates
- Chapter 9 Pollution by antibiotics and resistance genes: dissemination into Australian wildlife
- Chapter 10 Invasive vertebrates in Australia and New Zealand
- Chapter 11 Freshwaters in New Zealand
- Chapter 12 A garden at the edge of the world; the diversity and conservation status of the New Zealand flora
- Chapter 13 The evolutionary history of the Australian flora and its relevance to biodiversity conservation
- Chapter 14 Protecting the small majority: insect conservation in Australia and New Zealand
- Chapter 15 Terrestrial mammal diversity, conservation and management in Australia
- Chapter 16 Marine mammals, back from the brink? Contemporary conservation issues
- Chapter 17 Australian reptiles and their conservation
- Chapter 18 New Zealand reptiles and their conservation
- Chapter 19 Isolation, invasion and innovation: forces of change in the conservation of New Zealand birds
- Chapter 20 Australian birds: current status and future prospects
- Chapter 21 Austral amphibians – Gondwanan relicts in peril
- Chapter 22 Predators in danger: shark conservation and management in Australia, New Zealand and their neighbours
- Chapter 23 ‘Ragged mountain ranges, droughts and flooding rains’: the evolutionary history and conservation of Australian freshwater fishes
- Chapter 24 Down under Down Under: Austral groundwater life
- Chapter 25 Fire and biodiversity in Australia
- Chapter 26 Terrestrial protected areas of Australia
- Chapter 27 Australian marine protected areas
- Chapter 28 Marine reserves in New Zealand: ecological responses to protection and network design
- Chapter 29 Conclusion: conservation onboard Austral Ark needs all hands on deck
- Index
- Plate section
- References
Summary
Summary
Marine reserves are simple management tools that exclude extractive and destructive human activities from areas of the ocean. Given that fishing is one of the greatest impacts in most coastal ecosystems, networks of marine reserves are recognised as a core part of implementing ecosystem-based management in marine systems. Research in New Zealand marine reserves has contributed disproportionately to the global understanding of how species and ecosystems respond to marine reserve protection. We use examples from New Zealand to demonstrate the unequivocal role that marine reserves play in protecting exploited species within their boundaries, and how the recovery of exploited species can have wider conservation and fisheries value through indirect mechanisms and the movement of individuals from reserves. Progress towards developing a comprehensive and representative network of marine reserves in New Zealand has been slow because of a lack of political will, marine protected area legislation, and clear scientific guidance on marine reserve network design. Based on progress in designing networks of marine reserves internationally, and their demonstrated role in protecting biodiversity, we recommend a set of scientific guidelines to aid future development of marine reserves networks in New Zealand, and recommend that such networks be at the core of future marine spatial planning processes.
Introduction
Marine reserves are areas of the ocean that are protected from all extractive and destructive human activities (Lubchenco et al. 2003). They are often referred to as ‘no-take’ marine reserves as fishing is the main activity that is typically eliminated from a particular stretch of coast when a marine reserve is established. Given that fishing is the most widespread and historic human impact in coastal environments worldwide (Jackson et al. 2001) marine reserves provide a simple management tool to protect defined areas of the ocean from the impacts of fishing. While management of many fisheries is improving (Worm et al. 2009), there have been widespread calls to increase the level of protection for marine species through the implementation of networks of marine reserves worldwide (Wood et al. 2008). Fishing has a myriad of impacts on species as well as ecosystems through habitat disturbance and changes to food webs (Dayton et al. 2003). While marine reserves are not a panacea, as humans have a wide variety of impacts on marine ecosystems, they can protect the species and ecosystems within their boundaries from the effects of fishing.
- Type
- Chapter
- Information
- Austral ArkThe State of Wildlife in Australia and New Zealand, pp. 600 - 623Publisher: Cambridge University PressPrint publication year: 2014
References
, & (2011). Mind the gap: addressing the shortcomings of marine protected areas through large scale marine spatial planning. Marine Policy, 35, 226–232.CrossRefGoogle Scholar
, , & (2005). A long-term, spatially replicated experimental test of the effect of marine reserves on local fish yields. Canadian Journal of Fish and Aquatic Science, 62, 98–108.CrossRefGoogle Scholar
, , & (2003). Ensuring persistence of marine reserves: catastrophes require adopting an insurance factor. Ecological Applications, 13, S8–S24.CrossRefGoogle Scholar
(1978). Cape Rodney to Okakari Point Marine Reserve Survey. Leigh Laboratory Bulletin 1.
(2013). Leigh Marine Laboratory contributions to marine conservation. New Zealand Journal of Marine Freshwater Research, 47(3), 360–373.CrossRefGoogle Scholar
, & (2012). Incorporating behavioural variation in individual-based simulation models of marine reserve effectiveness. Environmental Conservation, 39, 282–294.CrossRefGoogle Scholar
, , , & (1999). Changes in community structure in temperate marine reserves. Marine Ecology Progress Series, 189, 125–134.CrossRefGoogle Scholar
, , , et al. (2010). Decadal trends in marine reserves reveal differential rates of change in direct and indirect effects. Proceedings of the National Academy of Sciences USA, 107, 18 256–18 261.CrossRefGoogle ScholarPubMed
& (1979). New-Zealand’s 1st Marine Reserve, Cape Rodney to Okakari Point, Leigh. Biological Conservation, 15, 273–280.CrossRefGoogle Scholar
, & (2001). Dependence of sustainability on the configuration of marine reserves and larval dispersal distance. Ecology Letters, 4, 144–150.CrossRefGoogle Scholar
, & (2010). The role of “rules of thumb” in science-based environmental policy: California’s Marine Life Protection Act as a case study. Stanford Journal of Law, Science and Policy, 2, 1–17.Google Scholar
, , & (2012). Are the scientific foundations of temperate marine reserves too warm and hard?Environmental Conservation, 39, 199–203.CrossRefGoogle Scholar
(2010). California Department of Fish and Game. The Marine Life Protection Act Master Plan for Marine Protected Areas. Google Scholar
, , , et al. (2008). Marine reserves: size and age do matter. Ecology Letters, 11, 481–489.CrossRefGoogle ScholarPubMed
(2011). Measuring New Zealanders’ Attitudes Towards their Oceans and Marine Reserves. A Colmar Brunton report for WWF-New Zealand Published 26 May 2011. Google Scholar
, & (2003). Ecological Effects of Fishing. Report to the Pew Oceans Commission, Arlington, Virginia (USA).Google Scholar
& (2004). Do partial marine reserves protect reef fish assemblages?Biological Conservation, 116, 119–129.CrossRefGoogle Scholar
, & (2004). Rapid recolonisation of snapper Pagrus auratus: Sparidae within an offshore island marine reserve after implementation of no-take status. Marine Ecology Progress Series, 272, 183–190.CrossRefGoogle Scholar
(2011). Coastal Marine Habitats and Marine Protected Areas in the New Zealand Territorial Sea: a Broad scale Gap Analysis. Department of Conservation and Ministry of Fisheries. Wellington, New Zealand.Google Scholar
(2005). Marine Protected Areas Policy and Implementation Plan. Ministry of Fisheries and Department of Conservation, Wellington, New Zealand. 54 pages.Google Scholar
(2008). Marine Protected Areas: Classification, Protection Standard and Implementation Guidelines. Ministry of Fisheries and Department of Conservation, Wellington, New Zealand. 54 pages.Google Scholar
, & (2009). Exploited reefs protected from fishing transform over decades into conservation features otherwise absent from seascapes. Ecological Applications, 19, 1967–1974.CrossRefGoogle ScholarPubMed
& (2009). Ecological effects of marine protected areas on rocky reef communities-a continental-scale analysis. Marine Ecology Progress Series, 388, 51–62.CrossRefGoogle Scholar
, , , et al. (2009). A process to design a network of marine no-take areas: Lessons from the Great Barrier Reef. Ocean & Coastal Management, 52, 439–447.CrossRefGoogle Scholar
& (2009). Healthier lobsters in a marine reserve: effects of fishing on disease incidence in the spiny lobster, Jasus edwardsii. Marine and Freshwater Research, 60, 140–145.CrossRefGoogle Scholar
, & (2012a). Use of a marine reserve to determine the direct and indirect effects of fishing on growth in a New Zealand fishery for the spiny lobster Jasus edwardsii. Canadian Journal of Fish and Aquatic Science, 69, 894–905.CrossRefGoogle Scholar
, & (2009). Habitat patches that cross marine reserve boundaries: consequences for the lobster Jasus edwardsii. Marine Ecology Progress Series, 388, 159–167.CrossRefGoogle Scholar
, , , et al. (2012b). Trajectories of spiny lobster Jasus edwardsii recovery in New Zealand marine reserves: is settlement a driver?Environmental Conservation, 39, 295–304.CrossRefGoogle Scholar
, , & (2010). Designing marine reserve networks for both conservation and fisheries management. Proceedings of the National Academy of Sciences, 107, 18 286–18 293.CrossRefGoogle ScholarPubMed
& (2003). Benefits beyond boundaries: the fishery effects of marine reserves. Trends in Ecology & Evolution, 18, 448–455.CrossRefGoogle Scholar
, , , et al. (2010). Science-based and stakeholder-driven marine protected area network planning: a successful case study from north central California. Ocean & Coastal Management, 53, 52–68.CrossRefGoogle Scholar
, , , & (2010). Net contribution of spillover from a marine reserve to fishery catches. Marine Ecology Progress Series, 400, 233–243.CrossRefGoogle Scholar
, , , et al. (2008). Italian marine reserve effectiveness: does enforcement matter?Biology Conservation, 141, 699–709.CrossRefGoogle Scholar
, , , et al. (2013). Marine protected areas and resilience to sedimentation in the Solomon Islands. Coral Reefs, 32, 61–69.CrossRefGoogle Scholar
, & (2009). Spillover from marine reserves and the replenishment of fished stocks. Environmental Conservation, 36, 268–276.CrossRefGoogle Scholar
, & (2010). Placing marine protected areas onto the ecosystem-based management seascape. Proceedings of the National Academy of Sciences, 107, 18 312–18 317.CrossRefGoogle ScholarPubMed
, , , et al. (2012). Larval export from marine reserves and the recruitment benefit for fish and fisheries. Current Biology, 22, 1023–1028.CrossRefGoogle ScholarPubMed
(2012). The role of science in MPA establishment in California: a personal perspective. Environmental Conservation, 39, 195–198.CrossRefGoogle Scholar
, & (2006). Integrating marine protected areas with catch regulation. Canadian Jounral of Fish and Aquatic Science, 63, 642–649.CrossRefGoogle Scholar
, , , et al. (2004). When can marine reserves improve fisheries management?Ocean & Coastal Management, 47, 197–205.CrossRefGoogle Scholar
& (2013). A safety network against regional population collapse: mature subpopulations in refuges distributed across the landscape. Ecosphere, 4, art57.CrossRefGoogle Scholar
, , , et al. (2001). Historical overfishing and the recent collapse of coastal ecosystems. Science, 293, 629–638.CrossRefGoogle ScholarPubMed
(2013). Ecology of rocky reef fish of northeastern New Zealand: 50 years on. New Zealand Journal of Marine and Freshwater Research, 47, 334–359.CrossRefGoogle Scholar
(2001). Temporal variation in the movement of the spiny lobster Jasus edwardsii. Marine and Freshwater Research, 52, 323–331.CrossRefGoogle Scholar
& (2003). Movement patterns of mature spiny lobsters, Jasus edwardsii, from a marine reserve. New Zealand Journal of Marine and Freshwater Research, 37, 149–158.CrossRefGoogle Scholar
, & (2002). The value of a spillover fishery for spiny lobsters around a marine reserve in Northern New Zealand. Coastal Management, 30, 153–166.CrossRefGoogle Scholar
, , & (2013). Marine protected area improves yield without disadvantaging fishers. Nature Communications, 4.CrossRefGoogle ScholarPubMed
& (1999). Implications of fish home range size and relocation for marine reserve function. Environmental Biology of Fishes, 55, 65–79.CrossRefGoogle Scholar
, , & (2006). Marine reserves demonstrate trophic interactions across habitats. Oecologia, 147, 134–140.CrossRefGoogle ScholarPubMed
, , & (2012). Mapping habitats in a marine reserve showed how a 30-year trophic cascade altered ecosystem structure. Biology Conservation, 155, 193–201.CrossRefGoogle Scholar
, , , et al. (2009). Biological effects within no-take marine reserves: a global synthesis. Marine Ecology Progress Series, 384, 33–46.CrossRefGoogle Scholar
, , & (2003). Plugging a hole in the ocean: the emerging science of marine reserves. Ecological Applications, 13, S3–S7.CrossRefGoogle Scholar
& (2000). Spillover of exploitable fishes from a marine park and its effect on the adjacent fishery. Ecology Applications, 10, 1792–1805.CrossRefGoogle Scholar
, , , et al. (2010). Adaptive management of the Great Barrier Reef: A globally significant demonstration of the benefits of networks of marine reserves. Proceedings of the National Academy of Sciences, 107, 18 278–18 285.CrossRefGoogle ScholarPubMed
, , , et al. (2012). Evidence that marine reserves enhance resilience to climatic impacts. PLoS ONE, 7, e40832.CrossRefGoogle ScholarPubMed
, & (2012). Safeguarding our Oceans: Strengthening Marine Protection in New Zealand. Environmental Defence Society.Google Scholar
, , , & (2000). Large-scale closed areas as a fishery-management tool in temperate marine systems: the Georges Bank experience. Bulletin of Marine Science, 66, 775–798.Google Scholar
(2010). The Marine Conservation Zone Project: Ecological Network Guidance.
, , , et al. (2009). Risks of shifting baselines highlighted by anecdotal accounts of New Zealand’s snapper (Pagrus auratus) fishery. New Zealand Journal Marine and Freshwater Research, 43, 965–983.CrossRefGoogle Scholar
, & (2010). Responses to marine reserves: Decreased dispersion of the sparid Pagrus auratus (snapper). Biology Conservation, 143, 2039–2048.CrossRefGoogle Scholar
, , , & (2009). Quantifying larval export from South African marine reserves. Marine Ecology Progress Series, 394, 65–78.CrossRefGoogle Scholar
, , & (2008). Trophic modelling of a New Zealand rocky reef ecosystem using simultaneous adjustment of diet, biomass and energetic parameters. Journal of Experimental Marine Biology and Ecology, 367, 189–203.CrossRefGoogle Scholar
, , , & (2004). Marine reserve benefits local fisheries. Ecological Applications, 14, 597–606.CrossRefGoogle Scholar
, , , et al. (2013). The role of science in supporting marine protected area network planning and design in California. Ocean & Coastal Management, 74, 45–56.CrossRefGoogle Scholar
, , , et al. (2010). Key features and context-dependence of fishery-induced trophic cascades. Conservation Biology, 24, 382–394.CrossRefGoogle ScholarPubMed
, , & (2008). Cascading effects of fishing can alter carbon flow through a temperate coastal ecosystem. Ecological Applications, 18, 1874–1887.CrossRefGoogle ScholarPubMed
(2013). The other 93%: trophic cascades, stressors and managing coastlines in non-marine protected areas. New Zealand Journal of Marine and Freshwater Research, 47, 1–18.CrossRefGoogle Scholar
& (2002). Marine reserves demonstrate top-down control of community structure on temperate reefs. Oecologia, 132, 131–142.CrossRefGoogle ScholarPubMed
& (2003). Continuing trophic cascade effects after 25 years of no-take marine reserve protection. Marine Ecology Progress Series, 246, 1–16.CrossRefGoogle Scholar
& (2004). Indirect effects of marine reserves on New Zealand’s rocky coastal communities. In, Department of Conservation Science Internal Series No. 192. Department of Conservation, Wellington, New Zealand. 49p. Available from (accessed July 2007).
& (2007). Quantitative description of mainland New Zealand’s shallow subtidal reef communities. Science for Conservation, 280, 126 pages. Google Scholar
, & (2008). Context-dependent effects of fishing: variation in trophic cascades across environmental gradients. Ecology Applications, 18, 1860–1873.CrossRefGoogle ScholarPubMed
, , , & (2006). Long-term trends in lobster populations in a partially protected vs. no-take Marine Park. Biological Conservation, 132, 222–231.CrossRefGoogle Scholar
, , , et al. (2009). Thinking and managing outside the box: coalescing connectivity networks to build region-wide resilience in coral reef ecosystems. Coral Reefs, 28, 367–378.CrossRefGoogle Scholar
, , , et al. (2006). Modelling transport of larval New Zealand abalone (Haliotis iris) along an open coast. Marine and Freshwater Research, 57, 519–532.CrossRefGoogle Scholar
, , , & (2009). Trophic and benthic responses to no-take marine reserve protection in the Philippines. Marine Ecology Progress Series, 389, 1–15.CrossRefGoogle Scholar
, & (2011). Establishing baselines for recovery in a marine reserve (Poor Knights Islands, New Zealand) using local ecological knowledge. Biology Conservation, 144, 3038–3046.CrossRefGoogle Scholar
& (2003). Structure of cryptic reef fish assemblages: relationships with habitat characteristics and predator density. Marine Ecology Progress Series, 257, 209–221.CrossRefGoogle Scholar
, & (2000). Detection of spatial variability in relative density of fishes: comparison of visual census, angling, and baited underwater video. Marine Ecology Progress Series, 198, 249–260.CrossRefGoogle Scholar
, & (2003a). Protection of exploited fish in temperate regions: high density and biomass of snapper Pagrus auratus (Sparidae) in northern New Zealand marine reserves. Journal of Applied Ecology, 40, 214–227.CrossRefGoogle Scholar
, , & (2003b). Burdens of evidence and the benefits of marine reserves: putting Descartes before des horse?Environmental Conservation, 30, 97–103.CrossRefGoogle Scholar
, , & (2008). Assessing progress towards global marine protection targets: shortfalls in information and action. Oryx, 42, 340–351.CrossRefGoogle Scholar
, , , et al. (2009). Rebuilding global fisheries. Science, 325, 578–585.CrossRefGoogle ScholarPubMed