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Marine Fisheries and conservation of marine resources.

Marine Fisheries and conservation of marine resources. What are fisheries? How do we use marine resources? How do manage marine resources?. What is a Fishery?. A Fishery is made of 3 parts: the population fished. The economics behind the fishery. The fishermen.

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Marine Fisheries and conservation of marine resources.

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  1. Marine Fisheries and conservation of marine resources. • What are fisheries? • How do we use marine resources? • How do manage marine resources?

  2. What is a Fishery? • A Fishery is made of 3 parts: • the population fished. • The economics behind the fishery. • The fishermen.

  3. Examples of several fisheries

  4. Different types of Fishermen • Large-scale commercial fishermen • Small scale commercial fishermen • Subsistence fishermen • Recreational fishermen

  5. Commercial Divers: Hookah divers in Mexico Hookah divers in Mexico use an air compressor and long hoses to fish for benthic species. Underwater these divers collect octopus, scallops, clams, oysters, benthic fish, snails, and sea cucumbers.

  6. Hookah divers near Penasco hunt for Murex snails which are taken to a plant and processed.

  7. Any questions so far?

  8. Moving on: • Types of fishing and fishing gear. • Economics of fisheries and fisheries decline.

  9. Stock - a key concept • A stock is a geographically definable population of a species that changes abundance in response to factors, relatively independently of other stocks

  10. Stock - a key concept 2 • Managers wish to identify stocks to manage and regulate crucial factors, such as controls on food eaten by the stock, crucial nursery grounds, sharing of stocks between political entities, such as different states or countries

  11. Identification of Stocks • Tags - devices inserted into fish so that they can be located subsequently and the location can be related to the site of tagging • Biochemical and molecular markers - used to distinguish between stocks. If individual populations have unique markers, they are separated evolutionarily from other stocks

  12. Gulf Coast bands Atlantic bands Mitochondrial DNA markers used to identify stocks of Striped Bass, Morone saxatilis

  13. Crucial Life History Information Needed • Range of temperatures and salinities for maximum growth • Location of spawning/nursery habitat • Location of feeding areas • Biological information that minimizes unintended mortality during fishing

  14. Stock Size • Landings from fisheries are the main means of estimating stocks, although scientific sampling is also done

  15. Stock Size 2 • Landings can be related to stock size (= local population size) if relation to fishing effort can be determined

  16. Stock Size 3 • Fishing effort is a function of (1) number of boats; (2) number of individuals fishing; (3) hours spend fishing; (4) efficiency of fishing gear

  17. Stock Size 4 • Stock estimates take into account the catch per unit effort

  18. Landings of the blue whale, as compared with effort Catch per catcher-day’s work 1931 32 40 47 50 60 1963 Year

  19. Fisheries Model • To understand the behavior of a fishery, we have to construct a model of population change • We must have an idea of the life history, which includes the mode of reproduction, the number of young produced, the survivorship, growth periodicity (seasonal) and rate of growth)

  20. Mortality Recruitment Nursery area Reproduction To produce a good fisheries model, we must account for all contributions to reproduction, growth, and mortality, throughout the life cycle of the fishery resource species.

  21. Stock Recruitment Models • Objective of model is to predict recruitment (the number of newly born that enter and are noticed in the first year class - 0+ )

  22. Stock Recruitment Models 2 • Model presumes that recruitment can be predicted on basis of stock in previous year

  23. Stock Recruitment Models 3 • Model presumes that recruitment increases with increasing stock size, up to a maximum, then recruitment decreases because a stock of increasing size will be more and more limited by food and will produce proportionally fewer new recruits

  24. 120 40 80 0 Density-dependent effects Recruitment 0 400 800 1200 1600 Stock in previous year Stock-recruitment model

  25. Maximum Sustainable Yield • Based on idea that a fishery stock will grow at a slower rate over a certain stock size • Idea is to fish the stock down to the population level where growth is maximal • Leads to management tool to determine fishing pressure • Not much evidence that this approach works, even if the theory makes some sense • Problem might be that factors other than simple density dependence affect stock size

  26. Fishing Techniques • Hooking fishes individually - e.g., long lines with rows of hooks • Entangling fishes in nets - e.g., large drift nets, nets towed below the surface and kept open with wooden boards • Traps - e.g., baited lobster traps kept on bottom • Diving for fisheries (collection by hand)

  27. Angling Hand line Floating long line Demersal long line Hooking Fishes Individually

  28. Drift nets Set nets Purse seine Pelagic trawl Bottom otter trawl Fishing with nets

  29. Stock Reduction - factors • Environmental change • “Random factors” • Overfishing

  30. Vulnerable Fisheries • Life histories with long generation times • Life histories with low fecundity • Stocks with confined populations (aggregations or geographic range in a confined area) • Resource species that are easily caught

  31. Management Problems 4 • Fisheries managed by a variety of local and federal agencies • Management recommendations not always in best interests of maintaining stock • Some policies backfire - e.g., Magnuson Act of 1976 which extended US coastal fishing zone 200 miles from shore but resulted in extensive deployment of US fishng boats, resulting in overexploitation • Magnuson Act established 8 regiona fishing commissions to help regulate domestic fishing - results good in some cases, bad in others

  32. Effects of Overfishing 4 • Great reduction of many stocks, e.g., formerly productive Georges Bank, east of New England • Effects concentrated especially on species with vulnerable life cycles (low fecundity, long generation time - e.g., sharks, whales) • Collateral effects on the bottom, where bottom trawling continually turns over the bottom, killing epibenthic animals • Elimination of species at the tops of food chains, which tend to be lower in abundance and have vulnerable life history characteristics

  33. Georges Bank Stock landings 3 Metric Tons x 10 Cod Atlantic Ocean Haddock Yellowtail Cape Cod Year GEORGES BANK Trends in landings of three major fisheries on Georges Bank on the New England continental shelf

  34. Some new management tools • Individual transferable quota (ITQ) - licenses are limited in number with quotas for each license, which can be sold • Marine Protected Areas (also known as No-Take Areas) - some portion of the stock’s geographic range is closed to fishing - protects spawning grounds, nursery grounds, or minimal crucial habitat size to preserve stock even when fishing is too high

  35. Spawning area Juvenile Feeding area No-take areas Adult feeding area Current and dispersal direction Adult feeding area Adult feeding area Hypothetical No-take Plan

  36. Mariculture - Important Factors • Desirability as food • Uncomplicated reproduction • Hardiness • Disease resistance • High growth rate per unit area (growth efficiency) • Readily met food and habitat requirements • Monoculture or polyculture • Marketability • Minimal ecological damage

  37. Mussels and Oysters • Mussels usually recruit to ropes and poles • Placement in areas of high phytoplankton density and water flow • Oyster newly settled larvae (spat) collected and then transferred to trays that are suspended from rafts • Problem: bivalve diseases, e.g., MSX in oysters - amoeboid protozoan

  38. The End

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