Presentation is loading. Please wait.

Presentation is loading. Please wait.

Life-History Strategies of Fishes Rainer Froese IfM-GEOMAR.

Published byLambert King Modified over 8 years ago

Similar presentations

Presentation on theme: "Life-History Strategies of Fishes Rainer Froese IfM-GEOMAR."— Presentation transcript:

1 Life-History Strategies of Fishes Rainer Froese IfM-GEOMAR

2 Classes of Fishes

3 There are Six Classes of Fishes ClassesCommon ancestor (million y) Orders (n) Families (n) Genera (n) Species (n, %) Myxini (hagfishes) 600116710.2 Cephalaspidomorphi (lampreys) 450119420.1 Holocephali (chimaeras) 420136380.1 Elasmobranchii (sharks and rays) 42011451759753.4 Sarcopterygii (lobe-finned fishes) 420344110.04 Actinopterygii (ray-finned fishes) 400454704,64028,36396.1 Total 625244,84029,500100 Source: FishBase 09/2006

4 Key Trait: Size smallmediumlargevery large 23,603 species

5 Size Matters Largest fish: Whale shark, 20 m, 34 t Smallest fish: attached male anglerfish, several tiny cyprinids & gobies, 1 cm, 0.01g Max growth rate, fecundity, speed, trophic level, life span increase with size Relative metabolism, growth, brain size, gill area and M decrease with size

6 What You Eat You Are (+1) Trophic level Phytoplankton Top predators Prey fish Zooplankton................... *.......... *.*. *.*.......  10% *. 4 3 2 1

7 Key Trait: Trophic Level 7,161 species herbi- vore omnivorelow-level predatormid-level predator top- predator

8 Key Trait: Productivity (modified after Musick 1999) ParameterHighMediumLowVery low r max (1/year)> 0.50.16 – 0.500.05 – 0.15< 0.05 t d (years)<1.41.4 - 4.44.5 - 14> 14 Interest rate (%)> 6517 – 655 - 16< 5 K (1/year)> 0.30.16 – 0.300.05 – 0.15< 0.05 Fecundity (1/year)> 10,000100 – 100010 – 100< 10 t m (years)< 12 – 45 – 10> 10 t max (years)1 – 34 – 1011 – 30> 30

9 Key Traits: Productivity ProductivitySpeciesPercent Very low26310.5 Low101640.5 Medium87925.0 High35314.0 2,511 species

10 Productivity is a Proxy for Metabolism

11 Trait Correlation: Size vs Troph

12 Predators are Larger than Prey

13 Trait Correlation: Size vs Productivity

14 Phylogeny Limits Traits: Size Hagfish Lampreys Chimaeras Sharks & rays Lobe-finned Ray-finned small medium large very large

15 Phylogeny Limits Traits: Troph Hagfish Lampreys Chimaeras Sharks & rays Lobe-finned Ray-finned

16 Phylogeny Limits Traits: Productivity ClassProductivitySpeciesPercent MyxiniLow66100 CephalaspidomorphiLow1636 Medium25 HolocephaliLow37100 ElasmobranchiiVery low20621 Low52855 SarcopterygiiVery low1091 ActinopterygiiVery low470.2 Low3691.4 Medium8773.2 High3531.3

17 Life-History Strategies Of 80 possible combinations of size, trophic level and productivity, only 50 are used by recent fishes Three strategies are used by 60% of the species

18 Occupation of Size-Troph Space

19 Occupation of Size-Productivity Space

20 Occupation of Troph-Productivity Space

21 Occupation of size–productivity– troph-space for 20,480 species of fishes. Full cell width is 1000 species. Source: FishBase 11/2004

22 Occupation of size–productivity– troph-space for 620 species of sharks and rays. Full cell width is 1000 species. Source: FishBase 11/2004

23 Life Span and Growth Taylor 1958 Age at 0.95 L ∞ t max = 3/K

24 Life Span and Size

25 Life Span and Mortality where Ex is the average life expectancy after reaching age x and l are the probabilities of reaching x and subsequent ages. In adults mortality is constant and then Note that E is also the mean duration of the reproductive phase, where in stable populations one replacement spawner is produced per spawner

26 The Most Important Point in Life where growth rate is maximum where gonad growth rate is maximum where likely reproductive effort is maximum (l t m t function) where reproductive biomass of the cohort is maximum t opt = 1.65 E

27 The Most Important Point in Life t opt = 1.65 E L opt = 0.67 L ∞ W opt = 0.3 W ∞

28 Not Missing the Point Means… Include t opt in mean life expectancy Reproduce at t opt Mature so that reproductive phase E includes t opt –Early t m = t opt – E –Latet m = t opt

29 Example Atlantic Cod

30 Evolution Does Not Miss… 0.67 L ∞ = t opt 0.35 L ∞ = t opt - E live bearers sharks & rays low fecundity high fecundity survival of offspring Related to parent size survival of offspring indepenent of parent size

31 But Fishing Does… Start before first maturity Double mortality (if not more) E = 1/M Reduce reproductive phase by half Undermine the productivity on which it depends

32 Thanks to the FishBase Team

33 Thanks to our Donors

34 Thank You Comments? Questions?

Download ppt "Life-History Strategies of Fishes Rainer Froese IfM-GEOMAR."

Similar presentations

Population Biology.

Population Biology.
Population Density Population density is total population size per unit of area. Population densities depend on: Interactions within the environment Quality.

Population Density Population density is total population size per unit of area. Population densities depend on: Interactions within the environment Quality.
The Common Fisheries Policy State of Resources and Ecosystems Rainer Froese, GEOMAR, Germany 10 December 2014 Sustainable Fisheries Internal Seminar S&D.

The Common Fisheries Policy State of Resources and Ecosystems Rainer Froese, GEOMAR, Germany 10 December 2014 Sustainable Fisheries Internal Seminar S&D.
Progress with FishBase Data and Tools for Stock Assessment Rainer Froese 8.10.2012 ECOKNOWS, Heraklion.

Progress with FishBase Data and Tools for Stock Assessment Rainer Froese ECOKNOWS, Heraklion.
Goodbye K, Welcome M The Interrelationship between Life Span, Growth and Reproduction Rainer Froese IFM-GEOMAR Kiel, Germany.

Goodbye K, Welcome M The Interrelationship between Life Span, Growth and Reproduction Rainer Froese IFM-GEOMAR Kiel, Germany.
Biodiversity of Fishes Understanding Longevity Rainer Froese 09.01.2014.

Biodiversity of Fishes Understanding Longevity Rainer Froese
Biodiversity of Fishes Death in the Sea Understanding Natural Mortality Rainer Froese GEOMAR 08.01.2015.

Biodiversity of Fishes Death in the Sea Understanding Natural Mortality Rainer Froese GEOMAR
New Approaches for the Management of Data-Limited Stocks Rainer Froese GEOMAR Rethinking paradigms & approaches in fisheries research ZMT, Bremen, 20 March.

New Approaches for the Management of Data-Limited Stocks Rainer Froese GEOMAR Rethinking paradigms & approaches in fisheries research ZMT, Bremen, 20 March.
Growth in Length and Weight Rainer Froese SS 2008.

Growth in Length and Weight Rainer Froese SS 2008.
Chapter 51 Population Ecology.

Chapter 51 Population Ecology.
Biodiversity of Fishes Phylogeny and Remarkable Fishes Rainer Froese (13.11.14)

Biodiversity of Fishes Phylogeny and Remarkable Fishes Rainer Froese ( )
Simple Approaches to Data-Poor Stock Assessment Rainer Froese March 9, 2011, Troutdale, Oregon.

Simple Approaches to Data-Poor Stock Assessment Rainer Froese March 9, 2011, Troutdale, Oregon.
What do we NOT know about Indo-Pacific Fishes? Rainer Froese IfM-GEOMAR

What do we NOT know about Indo-Pacific Fishes? Rainer Froese IfM-GEOMAR
Lesson 19: Vertebrates I Marine Biology. Vertebrates: Animals with a backbone Classification Overview Common Vertebrates Phylum Subphylum Chordata Vertebrata.

Lesson 19: Vertebrates I Marine Biology. Vertebrates: Animals with a backbone Classification Overview Common Vertebrates Phylum Subphylum Chordata Vertebrata.
Population Dynamics.

Population Dynamics.
Are we over carrying capacity?

Are we over carrying capacity?
Population Ecology. Population Dynamics Population: All the individuals of a species that live together in an area.

Population Ecology. Population Dynamics Population: All the individuals of a species that live together in an area.
Population of Ecology. Ecology Study of the interactions of organisms in their biotic and abiotic environments Organism  population  community  Ecosystem.

Population of Ecology. Ecology Study of the interactions of organisms in their biotic and abiotic environments Organism  population  community  Ecosystem.
 All members of 1 species within defined area..  Distribution is often determined by needs of the organisms (food, water, mates, shelter, etc..)

 All members of 1 species within defined area..  Distribution is often determined by needs of the organisms (food, water, mates, shelter, etc..)
POPULATION ECOLOGY Tabitha Walton and Heath Edwards.

POPULATION ECOLOGY Tabitha Walton and Heath Edwards.

Similar presentations

Ads by Google