A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae

A biochemically based model was developed to simulate the growth, development and metamorphosis of larvae of the Pacific oyster, Crassostrea gigas. The model is unique in that (1) it defines larvae in terms of their protein, neutral lipid, polar lipid, carbohydrate, and ash content; (2) it tracks we...

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Bibliographic Details
Main Authors: Bochenek, Eleanor A., Klinck, John M., Powell, Eric N., Hofmann, Eileen E.
Format: Article in Journal/Newspaper
Language:unknown
Published: ODU Digital Commons 2001
Subjects:
Crassostrea gigas
Pacific oyster
Online Access:https://digitalcommons.odu.edu/ccpo_pubs/25
https://digitalcommons.odu.edu/context/ccpo_pubs/article/1024/viewcontent/bochenek_abiochemicallybasedmodeloftheg1981.pdf
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spelling ftolddominionuni:oai:digitalcommons.odu.edu:ccpo_pubs-1024 2024-09-15T18:03:12+00:00 A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae Bochenek, Eleanor A. Klinck, John M. Powell, Eric N. Hofmann, Eileen E. 2001-01-01T08:00:00Z application/pdf https://digitalcommons.odu.edu/ccpo_pubs/25 https://digitalcommons.odu.edu/context/ccpo_pubs/article/1024/viewcontent/bochenek_abiochemicallybasedmodeloftheg1981.pdf unknown ODU Digital Commons https://digitalcommons.odu.edu/ccpo_pubs/25 https://digitalcommons.odu.edu/context/ccpo_pubs/article/1024/viewcontent/bochenek_abiochemicallybasedmodeloftheg1981.pdf CCPO Publications article 2001 ftolddominionuni 2024-08-12T03:29:34Z A biochemically based model was developed to simulate the growth, development and metamorphosis of larvae of the Pacific oyster, Crassostrea gigas. The model is unique in that (1) it defines larvae in terms of their protein, neutral lipid, polar lipid, carbohydrate, and ash content; (2) it tracks weight separately from length to follow larval condition index; and (3) it includes genetic variation in growth efficiency and egg quality to better simulate cohort population dynamics. The model includes parameterizations for larval filtration, ingestion, and respiration, which determine growth rate, and processes controlling larval mortality and metamorphosis. The initial biochemical content of the larva is determined by the composition of the egg. Changes in the initial ratios of protein, carbohydrate, neutral lipid, and polar lipid occur in response to the biochemical composition of available food as the larva grows. Modeling the process of metamorphosis requires a series of size-based and biochemically based triggers: (1) larvae become potentially competent to metamorphose at 275 mum, following a decrease in filtration rate at 250 mum; (2) larvae become competent to metamorphose when a daily decline in neutral lipid of 25% or more occurs; and (3) larvae metamorphose successfully if neutral lipid stores exceed polar lipid stores. Although based on simple biochemistry, the model succeeds in simulating such basic characteristics of C. gigas larval development and metamorphosis as larval life span and size structure at metamorphosis and the influence of egg and food quality and food quantity on survival. These results suggest that simple biochemical constructs may encompass the biochemical transitions most prominent in determining cohort success. Simulations of larval development show that for the smallest larvae, assimilation does not provide adequate resources to explain observed growth, although measured filtration rates would indicate otherwise. Egg lipid stores are needed to sustain the larva, The simulations also ... Article in Journal/Newspaper Crassostrea gigas Pacific oyster Old Dominion University: ODU Digital Commons
institution Open Polar
collection Old Dominion University: ODU Digital Commons
op_collection_id ftolddominionuni
language unknown
description A biochemically based model was developed to simulate the growth, development and metamorphosis of larvae of the Pacific oyster, Crassostrea gigas. The model is unique in that (1) it defines larvae in terms of their protein, neutral lipid, polar lipid, carbohydrate, and ash content; (2) it tracks weight separately from length to follow larval condition index; and (3) it includes genetic variation in growth efficiency and egg quality to better simulate cohort population dynamics. The model includes parameterizations for larval filtration, ingestion, and respiration, which determine growth rate, and processes controlling larval mortality and metamorphosis. The initial biochemical content of the larva is determined by the composition of the egg. Changes in the initial ratios of protein, carbohydrate, neutral lipid, and polar lipid occur in response to the biochemical composition of available food as the larva grows. Modeling the process of metamorphosis requires a series of size-based and biochemically based triggers: (1) larvae become potentially competent to metamorphose at 275 mum, following a decrease in filtration rate at 250 mum; (2) larvae become competent to metamorphose when a daily decline in neutral lipid of 25% or more occurs; and (3) larvae metamorphose successfully if neutral lipid stores exceed polar lipid stores. Although based on simple biochemistry, the model succeeds in simulating such basic characteristics of C. gigas larval development and metamorphosis as larval life span and size structure at metamorphosis and the influence of egg and food quality and food quantity on survival. These results suggest that simple biochemical constructs may encompass the biochemical transitions most prominent in determining cohort success. Simulations of larval development show that for the smallest larvae, assimilation does not provide adequate resources to explain observed growth, although measured filtration rates would indicate otherwise. Egg lipid stores are needed to sustain the larva, The simulations also ...
format Article in Journal/Newspaper
author Bochenek, Eleanor A.
Klinck, John M.
Powell, Eric N.
Hofmann, Eileen E.
spellingShingle Bochenek, Eleanor A.
Klinck, John M.
Powell, Eric N.
Hofmann, Eileen E.
A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
author_facet Bochenek, Eleanor A.
Klinck, John M.
Powell, Eric N.
Hofmann, Eileen E.
author_sort Bochenek, Eleanor A.
title A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
title_short A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
title_full A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
title_fullStr A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
title_full_unstemmed A Biochemically Based Model of the Growth and Development of Crassostrea Gigas Larvae
title_sort biochemically based model of the growth and development of crassostrea gigas larvae
publisher ODU Digital Commons
publishDate 2001
url https://digitalcommons.odu.edu/ccpo_pubs/25
https://digitalcommons.odu.edu/context/ccpo_pubs/article/1024/viewcontent/bochenek_abiochemicallybasedmodeloftheg1981.pdf
genre Crassostrea gigas
Pacific oyster
genre_facet Crassostrea gigas
Pacific oyster
op_source CCPO Publications
op_relation https://digitalcommons.odu.edu/ccpo_pubs/25
https://digitalcommons.odu.edu/context/ccpo_pubs/article/1024/viewcontent/bochenek_abiochemicallybasedmodeloftheg1981.pdf
_version_ 1810440717451919360

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